-- Hoogle documentation, generated by Haddock
-- See Hoogle, http://www.haskell.org/hoogle/


-- | The GHC API
--   
--   GHC's functionality can be useful for more things than just compiling
--   Haskell programs. Important use cases are programs that analyse (and
--   perhaps transform) Haskell code. Others include loading Haskell code
--   dynamically in a GHCi-like manner. For this reason, a lot of GHC's
--   functionality is made available through this package.
@package ghc
@version 7.6.3

module SPARC.Cond

-- | Branch condition codes.
data Cond
ALWAYS :: Cond
EQQ :: Cond
GE :: Cond
GEU :: Cond
GTT :: Cond
GU :: Cond
LE :: Cond
LEU :: Cond
LTT :: Cond
LU :: Cond
NE :: Cond
NEG :: Cond
NEVER :: Cond
POS :: Cond
VC :: Cond
VS :: Cond
condUnsigned :: Cond -> Bool
condToSigned :: Cond -> Cond
condToUnsigned :: Cond -> Cond
instance Eq Cond

module X86.Cond
data Cond
ALWAYS :: Cond
EQQ :: Cond
GE :: Cond
GEU :: Cond
GTT :: Cond
GU :: Cond
LE :: Cond
LEU :: Cond
LTT :: Cond
LU :: Cond
NE :: Cond
NEG :: Cond
POS :: Cond
CARRY :: Cond
OFLO :: Cond
PARITY :: Cond
NOTPARITY :: Cond
condUnsigned :: Cond -> Bool
condToSigned :: Cond -> Cond
condToUnsigned :: Cond -> Cond
instance Eq Cond

module FastBool
type FastBool = Int#
fastBool :: Bool -> FastBool
isFastTrue :: FastBool -> Bool
fastOr :: FastBool -> FastBool -> FastBool
fastAnd :: FastBool -> FastBool -> FastBool

module FastMutInt
data FastMutInt
newFastMutInt :: IO FastMutInt
readFastMutInt :: FastMutInt -> IO Int
writeFastMutInt :: FastMutInt -> Int -> IO ()
data FastMutPtr
newFastMutPtr :: IO FastMutPtr
readFastMutPtr :: FastMutPtr -> IO (Ptr a)
writeFastMutPtr :: FastMutPtr -> Ptr a -> IO ()

module Encoding
utf8DecodeChar# :: Addr# -> (# Char#, Addr# #)
utf8PrevChar :: Ptr Word8 -> IO (Ptr Word8)
utf8CharStart :: Ptr Word8 -> IO (Ptr Word8)
utf8DecodeChar :: Ptr Word8 -> (Char, Ptr Word8)
utf8DecodeString :: Ptr Word8 -> Int -> IO [Char]
utf8EncodeChar :: Char -> Ptr Word8 -> IO (Ptr Word8)
utf8EncodeString :: Ptr Word8 -> String -> IO ()
utf8EncodedLength :: String -> Int
countUTF8Chars :: Ptr Word8 -> Int -> IO Int
zEncodeString :: UserString -> EncodedString
zDecodeString :: EncodedString -> UserString

module ExternalCore
data Module
Module :: Mname -> [Tdef] -> [Vdefg] -> Module
data Tdef
Data :: (Qual Tcon) -> [Tbind] -> [Cdef] -> Tdef
Newtype :: (Qual Tcon) -> (Qual Tcon) -> [Tbind] -> Ty -> Tdef
data Cdef
Constr :: (Qual Dcon) -> [Tbind] -> [Ty] -> Cdef
GadtConstr :: (Qual Dcon) -> Ty -> Cdef
data Vdefg
Rec :: [Vdef] -> Vdefg
Nonrec :: Vdef -> Vdefg
type Vdef = (Bool, Qual Var, Ty, Exp)
data Exp
Var :: (Qual Var) -> Exp
Dcon :: (Qual Dcon) -> Exp
Lit :: Lit -> Exp
App :: Exp -> Exp -> Exp
Appt :: Exp -> Ty -> Exp
Lam :: Bind -> Exp -> Exp
Let :: Vdefg -> Exp -> Exp
Case :: Exp -> Vbind -> Ty -> [Alt] -> Exp
Cast :: Exp -> Ty -> Exp
Tick :: String -> Exp -> Exp
External :: String -> String -> Ty -> Exp
DynExternal :: String -> Ty -> Exp
Label :: String -> Exp
data Bind
Vb :: Vbind -> Bind
Tb :: Tbind -> Bind
data Alt
Acon :: (Qual Dcon) -> [Tbind] -> [Vbind] -> Exp -> Alt
Alit :: Lit -> Exp -> Alt
Adefault :: Exp -> Alt
type Vbind = (Var, Ty)
type Tbind = (Tvar, Kind)
data Ty
Tvar :: Tvar -> Ty
Tcon :: (Qual Tcon) -> Ty
Tapp :: Ty -> Ty -> Ty
Tforall :: Tbind -> Ty -> Ty
TransCoercion :: Ty -> Ty -> Ty
SymCoercion :: Ty -> Ty
UnsafeCoercion :: Ty -> Ty -> Ty
InstCoercion :: Ty -> Ty -> Ty
NthCoercion :: Int -> Ty -> Ty
data Kind
Klifted :: Kind
Kunlifted :: Kind
Kunboxed :: Kind
Kopen :: Kind
Karrow :: Kind -> Kind -> Kind
data Lit
Lint :: Integer -> Ty -> Lit
Lrational :: Rational -> Ty -> Lit
Lchar :: Char -> Ty -> Lit
Lstring :: String -> Ty -> Lit
type Mname = Id
type Var = Id
type Tvar = Id
type Tcon = Id
type Dcon = Id
type Qual t = (Mname, t)
type Id = String
primMname :: Mname
tcArrow :: Qual Tcon

module PprBase
castFloatToWord8Array :: STUArray s Int Float -> ST s (STUArray s Int Word8)
castDoubleToWord8Array :: STUArray s Int Double -> ST s (STUArray s Int Word8)
floatToBytes :: Float -> [Int]
doubleToBytes :: Double -> [Int]


-- | Fast integers, characters and pointer types for use in many parts of
--   GHC
module FastTypes
type FastInt = Int#
_ILIT :: Int -> FastInt
iBox :: FastInt -> Int
iUnbox :: Int -> FastInt
(+#) :: Int# -> Int# -> Int#
(-#) :: Int# -> Int# -> Int#
(*#) :: Int# -> Int# -> Int#
quotFastInt :: FastInt -> FastInt -> FastInt
negateFastInt :: FastInt -> FastInt
(==#) :: Int# -> Int# -> Bool
(/=#) :: Int# -> Int# -> Bool
(<#) :: Int# -> Int# -> Bool
(<=#) :: Int# -> Int# -> Bool
(>=#) :: Int# -> Int# -> Bool
(>#) :: Int# -> Int# -> Bool
minFastInt :: FastInt -> FastInt -> FastInt
maxFastInt :: FastInt -> FastInt -> FastInt
shiftLFastInt :: FastInt -> FastInt -> FastInt
shiftR_FastInt :: FastInt -> FastInt -> FastInt
shiftRLFastInt :: FastInt -> FastInt -> FastInt
shiftRAFastInt :: FastInt -> FastInt -> FastInt
bitAndFastInt :: FastInt -> FastInt -> FastInt
bitOrFastInt :: FastInt -> FastInt -> FastInt
type FastChar = Char#
_CLIT :: Char -> FastChar
cBox :: FastChar -> Char
cUnbox :: Char -> FastChar
fastOrd :: FastChar -> FastInt
fastChr :: FastInt -> FastChar
eqFastChar :: FastChar -> FastChar -> Bool
type FastPtr a = Addr#
pBox :: FastPtr a -> Ptr a
pUnbox :: Ptr a -> FastPtr a
castFastPtr :: FastPtr a -> FastPtr b

module FastFunctions
unsafeChr :: Int -> Char
inlinePerformIO :: IO a -> a
unsafeDupableInterleaveIO :: IO a -> IO a
indexWord8OffFastPtr :: FastPtr Word8 -> FastInt -> Word8
indexWord8OffFastPtrAsFastChar :: FastPtr Word8 -> FastInt -> FastChar
indexWord8OffFastPtrAsFastInt :: FastPtr Word8 -> FastInt -> FastInt
global :: a -> Global a
type Global a = IORef a

module Config
data IntegerLibrary
IntegerGMP :: IntegerLibrary
IntegerSimple :: IntegerLibrary
cBuildPlatformString :: String
cHostPlatformString :: String
cTargetPlatformString :: String
cProjectName :: String
cProjectVersion :: String
cProjectVersionInt :: String
cProjectPatchLevel :: String
cBooterVersion :: String
cStage :: String
cGccLinkerOpts :: [String]
cLdLinkerOpts :: [String]
cIntegerLibrary :: String
cIntegerLibraryType :: IntegerLibrary
cSupportsSplitObjs :: String
cGhcWithInterpreter :: String
cGhcWithNativeCodeGen :: String
cGhcWithSMP :: String
cGhcRTSWays :: String
cGhcUnregisterised :: String
cGhcEnableTablesNextToCode :: String
cLeadingUnderscore :: String
cRAWCPP_FLAGS :: String
cLdHasNoCompactUnwind :: String
cLdIsGNULd :: String
cLdHasBuildId :: String
cLD_X :: String
cGHC_DRIVER_DIR :: String
cGHC_UNLIT_PGM :: String
cGHC_UNLIT_DIR :: String
cGHC_SPLIT_PGM :: String
cGHC_SPLIT_DIR :: String
cGHC_SYSMAN_PGM :: String
cGHC_SYSMAN_DIR :: String
cDEFAULT_TMPDIR :: String
cLibFFI :: Bool
instance Eq IntegerLibrary

module Maybes
data MaybeErr err val
Succeeded :: val -> MaybeErr err val
Failed :: err -> MaybeErr err val
failME :: err -> MaybeErr err val
isSuccess :: MaybeErr err val -> Bool
fmapM_maybe :: Monad m => (a -> m b) -> Maybe a -> m (Maybe b)

-- | flipped version of <tt>fromMaybe</tt>.
orElse :: Maybe a -> a -> a
mapCatMaybes :: (a -> Maybe b) -> [a] -> [b]

-- | Collects a list of <tt>Justs</tt> into a single <tt>Just</tt>,
--   returning <tt>Nothing</tt> if there are any <tt>Nothings</tt>.
allMaybes :: [Maybe a] -> Maybe [a]
firstJust :: Maybe a -> Maybe a -> Maybe a

-- | Takes a list of <tt>Maybes</tt> and returns the first <tt>Just</tt> if
--   there is one, or <tt>Nothing</tt> otherwise.
firstJusts :: [Maybe a] -> Maybe a
expectJust :: String -> Maybe a -> a
maybeToBool :: Maybe a -> Bool
newtype MaybeT m a
MaybeT :: m (Maybe a) -> MaybeT m a
runMaybeT :: MaybeT m a -> m (Maybe a)
instance Monad (MaybeErr err)
instance Monad m => Monad (MaybeT m)
instance Functor m => Functor (MaybeT m)

module FiniteMap
insertList :: Ord key => [(key, elt)] -> Map key elt -> Map key elt
insertListWith :: Ord key => (elt -> elt -> elt) -> [(key, elt)] -> Map key elt -> Map key elt
deleteList :: Ord key => [key] -> Map key elt -> Map key elt
foldRight :: (elt -> a -> a) -> a -> Map key elt -> a
foldRightWithKey :: (key -> elt -> a -> a) -> a -> Map key elt -> a

module OrdList
data OrdList a
nilOL :: OrdList a
isNilOL :: OrdList a -> Bool
unitOL :: a -> OrdList a
appOL :: OrdList a -> OrdList a -> OrdList a
consOL :: a -> OrdList a -> OrdList a
snocOL :: OrdList a -> a -> OrdList a
concatOL :: [OrdList a] -> OrdList a
mapOL :: (a -> b) -> OrdList a -> OrdList b
fromOL :: OrdList a -> [a]
toOL :: [a] -> OrdList a
foldrOL :: (a -> b -> b) -> b -> OrdList a -> b
foldlOL :: (b -> a -> b) -> b -> OrdList a -> b
instance Functor OrdList

module Constants
oFFSET_StgRegTable_rR1 :: Int
oFFSET_StgRegTable_rR2 :: Int
oFFSET_StgRegTable_rR3 :: Int
oFFSET_StgRegTable_rR4 :: Int
oFFSET_StgRegTable_rR5 :: Int
oFFSET_StgRegTable_rR6 :: Int
oFFSET_StgRegTable_rR7 :: Int
oFFSET_StgRegTable_rR8 :: Int
oFFSET_StgRegTable_rR9 :: Int
oFFSET_StgRegTable_rR10 :: Int
oFFSET_StgRegTable_rF1 :: Int
oFFSET_StgRegTable_rF2 :: Int
oFFSET_StgRegTable_rF3 :: Int
oFFSET_StgRegTable_rF4 :: Int
oFFSET_StgRegTable_rD1 :: Int
oFFSET_StgRegTable_rD2 :: Int
oFFSET_StgRegTable_rL1 :: Int
oFFSET_StgRegTable_rSp :: Int
oFFSET_StgRegTable_rSpLim :: Int
oFFSET_StgRegTable_rHp :: Int
oFFSET_StgRegTable_rHpLim :: Int
oFFSET_StgRegTable_rCCCS :: Int
oFFSET_StgRegTable_rCurrentTSO :: Int
oFFSET_StgRegTable_rCurrentNursery :: Int
oFFSET_StgRegTable_rHpAlloc :: Int
oFFSET_StgRegTable_rRet :: Int
oFFSET_StgRegTable_rNursery :: Int
oFFSET_stgEagerBlackholeInfo :: Int
oFFSET_stgGCEnter1 :: Int
oFFSET_stgGCFun :: Int
oFFSET_Capability_r :: Int
oFFSET_Capability_lock :: Int
oFFSET_Capability_no :: Int
oFFSET_Capability_mut_lists :: Int
oFFSET_Capability_context_switch :: Int
oFFSET_Capability_interrupt :: Int
oFFSET_Capability_sparks :: Int
oFFSET_bdescr_start :: Int
oFFSET_bdescr_free :: Int
oFFSET_bdescr_blocks :: Int
oFFSET_bdescr_gen_no :: Int
oFFSET_bdescr_link :: Int
sIZEOF_generation :: Int
oFFSET_generation_n_new_large_words :: Int
sIZEOF_CostCentreStack :: Int
oFFSET_CostCentreStack_ccsID :: Int
oFFSET_CostCentreStack_mem_alloc :: Int
oFFSET_CostCentreStack_scc_count :: Int
oFFSET_CostCentreStack_prevStack :: Int
oFFSET_CostCentre_ccID :: Int
oFFSET_CostCentre_link :: Int
oFFSET_StgHeader_info :: Int
oFFSET_StgHeader_ccs :: Int
oFFSET_StgHeader_ldvw :: Int
sIZEOF_StgSMPThunkHeader :: Int
oFFSET_StgClosure_payload :: Int
oFFSET_StgEntCounter_allocs :: Int
oFFSET_StgEntCounter_registeredp :: Int
oFFSET_StgEntCounter_link :: Int
oFFSET_StgEntCounter_entry_count :: Int
sIZEOF_StgUpdateFrame_NoHdr :: Int
sIZEOF_StgCatchFrame_NoHdr :: Int
sIZEOF_StgStopFrame_NoHdr :: Int
sIZEOF_StgMutArrPtrs_NoHdr :: Int
oFFSET_StgMutArrPtrs_ptrs :: Int
oFFSET_StgMutArrPtrs_size :: Int
sIZEOF_StgArrWords_NoHdr :: Int
oFFSET_StgArrWords_bytes :: Int
oFFSET_StgArrWords_payload :: Int
oFFSET_StgTSO__link :: Int
oFFSET_StgTSO_global_link :: Int
oFFSET_StgTSO_what_next :: Int
oFFSET_StgTSO_why_blocked :: Int
oFFSET_StgTSO_block_info :: Int
oFFSET_StgTSO_blocked_exceptions :: Int
oFFSET_StgTSO_id :: Int
oFFSET_StgTSO_cap :: Int
oFFSET_StgTSO_saved_errno :: Int
oFFSET_StgTSO_trec :: Int
oFFSET_StgTSO_flags :: Int
oFFSET_StgTSO_dirty :: Int
oFFSET_StgTSO_bq :: Int
oFFSET_StgTSO_cccs :: Int
oFFSET_StgTSO_stackobj :: Int
oFFSET_StgStack_sp :: Int
oFFSET_StgStack_stack :: Int
oFFSET_StgStack_stack_size :: Int
oFFSET_StgStack_dirty :: Int
sIZEOF_StgTSOProfInfo :: Int
oFFSET_StgUpdateFrame_updatee :: Int
oFFSET_StgCatchFrame_handler :: Int
oFFSET_StgCatchFrame_exceptions_blocked :: Int
sIZEOF_StgPAP_NoHdr :: Int
oFFSET_StgPAP_n_args :: Int
oFFSET_StgPAP_fun :: Int
oFFSET_StgPAP_arity :: Int
oFFSET_StgPAP_payload :: Int
sIZEOF_StgAP_NoThunkHdr :: Int
sIZEOF_StgAP_NoHdr :: Int
oFFSET_StgAP_n_args :: Int
oFFSET_StgAP_fun :: Int
oFFSET_StgAP_payload :: Int
sIZEOF_StgAP_STACK_NoThunkHdr :: Int
sIZEOF_StgAP_STACK_NoHdr :: Int
oFFSET_StgAP_STACK_size :: Int
oFFSET_StgAP_STACK_fun :: Int
oFFSET_StgAP_STACK_payload :: Int
sIZEOF_StgSelector_NoThunkHdr :: Int
sIZEOF_StgSelector_NoHdr :: Int
oFFSET_StgInd_indirectee :: Int
sIZEOF_StgMutVar_NoHdr :: Int
oFFSET_StgMutVar_var :: Int
sIZEOF_StgAtomicallyFrame_NoHdr :: Int
oFFSET_StgAtomicallyFrame_code :: Int
oFFSET_StgAtomicallyFrame_next_invariant_to_check :: Int
oFFSET_StgAtomicallyFrame_result :: Int
oFFSET_StgInvariantCheckQueue_invariant :: Int
oFFSET_StgInvariantCheckQueue_my_execution :: Int
oFFSET_StgInvariantCheckQueue_next_queue_entry :: Int
oFFSET_StgAtomicInvariant_code :: Int
oFFSET_StgTRecHeader_enclosing_trec :: Int
sIZEOF_StgCatchSTMFrame_NoHdr :: Int
oFFSET_StgCatchSTMFrame_handler :: Int
oFFSET_StgCatchSTMFrame_code :: Int
sIZEOF_StgCatchRetryFrame_NoHdr :: Int
oFFSET_StgCatchRetryFrame_running_alt_code :: Int
oFFSET_StgCatchRetryFrame_first_code :: Int
oFFSET_StgCatchRetryFrame_alt_code :: Int
oFFSET_StgTVarWatchQueue_closure :: Int
oFFSET_StgTVarWatchQueue_next_queue_entry :: Int
oFFSET_StgTVarWatchQueue_prev_queue_entry :: Int
oFFSET_StgTVar_current_value :: Int
sIZEOF_StgWeak_NoHdr :: Int
oFFSET_StgWeak_link :: Int
oFFSET_StgWeak_key :: Int
oFFSET_StgWeak_value :: Int
oFFSET_StgWeak_finalizer :: Int
oFFSET_StgWeak_cfinalizer :: Int
sIZEOF_StgDeadWeak_NoHdr :: Int
oFFSET_StgDeadWeak_link :: Int
sIZEOF_StgMVar_NoHdr :: Int
oFFSET_StgMVar_head :: Int
oFFSET_StgMVar_tail :: Int
oFFSET_StgMVar_value :: Int
sIZEOF_StgMVarTSOQueue_NoHdr :: Int
oFFSET_StgMVarTSOQueue_link :: Int
oFFSET_StgMVarTSOQueue_tso :: Int
sIZEOF_StgBCO_NoHdr :: Int
oFFSET_StgBCO_instrs :: Int
oFFSET_StgBCO_literals :: Int
oFFSET_StgBCO_ptrs :: Int
oFFSET_StgBCO_arity :: Int
oFFSET_StgBCO_size :: Int
oFFSET_StgBCO_bitmap :: Int
sIZEOF_StgStableName_NoHdr :: Int
oFFSET_StgStableName_sn :: Int
sIZEOF_StgBlockingQueue_NoHdr :: Int
oFFSET_StgBlockingQueue_bh :: Int
oFFSET_StgBlockingQueue_owner :: Int
oFFSET_StgBlockingQueue_queue :: Int
oFFSET_StgBlockingQueue_link :: Int
sIZEOF_MessageBlackHole_NoHdr :: Int
oFFSET_MessageBlackHole_link :: Int
oFFSET_MessageBlackHole_tso :: Int
oFFSET_MessageBlackHole_bh :: Int
oFFSET_RtsFlags_ProfFlags_showCCSOnException :: Int
oFFSET_RtsFlags_DebugFlags_apply :: Int
oFFSET_RtsFlags_DebugFlags_sanity :: Int
oFFSET_RtsFlags_DebugFlags_weak :: Int
oFFSET_RtsFlags_GcFlags_initialStkSize :: Int
oFFSET_RtsFlags_MiscFlags_tickInterval :: Int
sIZEOF_StgFunInfoExtraFwd :: Int
oFFSET_StgFunInfoExtraFwd_slow_apply :: Int
oFFSET_StgFunInfoExtraFwd_fun_type :: Int
oFFSET_StgFunInfoExtraFwd_arity :: Int
oFFSET_StgFunInfoExtraFwd_bitmap :: Int
sIZEOF_StgFunInfoExtraRev :: Int
oFFSET_StgFunInfoExtraRev_slow_apply_offset :: Int
oFFSET_StgFunInfoExtraRev_fun_type :: Int
oFFSET_StgFunInfoExtraRev_arity :: Int
oFFSET_StgFunInfoExtraRev_bitmap :: Int
oFFSET_StgLargeBitmap_size :: Int
oFFSET_StgLargeBitmap_bitmap :: Int
sIZEOF_snEntry :: Int
oFFSET_snEntry_sn_obj :: Int
oFFSET_snEntry_addr :: Int
mAX_TUPLE_SIZE :: Int
mAX_CONTEXT_REDUCTION_DEPTH :: Int
mAX_SPEC_THUNK_SIZE :: Int
mAX_SPEC_FUN_SIZE :: Int
mAX_SPEC_CONSTR_SIZE :: Int
mAX_SPEC_SELECTEE_SIZE :: Int
mAX_SPEC_AP_SIZE :: Int
mIN_PAYLOAD_SIZE :: Int
mIN_INTLIKE :: Int
mAX_INTLIKE :: Int
mIN_CHARLIKE :: Int
mAX_CHARLIKE :: Int
mUT_ARR_PTRS_CARD_BITS :: Int
mAX_Vanilla_REG :: Int
mAX_Float_REG :: Int
mAX_Double_REG :: Int
mAX_Long_REG :: Int
mAX_Real_Vanilla_REG :: Int
mAX_Real_Float_REG :: Int
mAX_Real_Double_REG :: Int
mAX_Real_Long_REG :: Int
sTD_HDR_SIZE :: Int
pROF_HDR_SIZE :: Int
dOUBLE_SIZE :: Int
wORD64_SIZE :: Int
iNT64_SIZE :: Int
rESERVED_C_STACK_BYTES :: Int
rESERVED_STACK_WORDS :: Int
aP_STACK_SPLIM :: Int
wORD_SIZE :: Int
wORD_SIZE_IN_BITS :: Int
type TargetInt = Int32
type TargetWord = Word32
tARGET_MIN_INT :: Integer
tARGET_MAX_WORD :: Integer
tARGET_MAX_INT :: Integer
tARGET_MAX_CHAR :: Int
tAG_BITS :: Int
tAG_MASK :: Int
mAX_PTR_TAG :: Int
cINT_SIZE :: Int
cLONG_SIZE :: Int
cLONG_LONG_SIZE :: Int
bLOCK_SIZE :: Int
bLOCK_SIZE_W :: Int
bLOCKS_PER_MBLOCK :: Int
bITMAP_BITS_SHIFT :: Int
hiVersion :: Integer


-- | Break Arrays in the IO monad
--   
--   Entries in the array are Word sized Conceptually, a zero-indexed
--   IOArray of Bools, initially False. They're represented as Words with
--   0==False, 1==True. They're used to determine whether GHCI breakpoints
--   are on or off.
--   
--   (c) The University of Glasgow 2007
module BreakArray
data BreakArray
BA :: (MutableByteArray# RealWorld) -> BreakArray
newBreakArray :: Int -> IO BreakArray
getBreak :: BreakArray -> Int -> IO (Maybe Word)
setBreakOn :: BreakArray -> Int -> IO Bool
setBreakOff :: BreakArray -> Int -> IO Bool
showBreakArray :: BreakArray -> IO ()


-- | Utilities related to Monad and Applicative classes Mostly for
--   backwards compatability.
module MonadUtils

-- | A functor with application, providing operations to
--   
--   <ul>
--   <li>embed pure expressions (<a>pure</a>), and</li>
--   <li>sequence computations and combine their results
--   (<a>&lt;*&gt;</a>).</li>
--   </ul>
--   
--   A minimal complete definition must include implementations of these
--   functions satisfying the following laws:
--   
--   <ul>
--   <li><i><i>identity</i></i> <tt><a>pure</a> <a>id</a> <a>&lt;*&gt;</a>
--   v = v</tt></li>
--   <li><i><i>composition</i></i> <tt><a>pure</a> (.) <a>&lt;*&gt;</a> u
--   <a>&lt;*&gt;</a> v <a>&lt;*&gt;</a> w = u <a>&lt;*&gt;</a> (v
--   <a>&lt;*&gt;</a> w)</tt></li>
--   <li><i><i>homomorphism</i></i> <tt><a>pure</a> f <a>&lt;*&gt;</a>
--   <a>pure</a> x = <a>pure</a> (f x)</tt></li>
--   <li><i><i>interchange</i></i> <tt>u <a>&lt;*&gt;</a> <a>pure</a> y =
--   <a>pure</a> (<a>$</a> y) <a>&lt;*&gt;</a> u</tt></li>
--   </ul>
--   
--   The other methods have the following default definitions, which may be
--   overridden with equivalent specialized implementations:
--   
--   <pre>
--   u <a>*&gt;</a> v = <a>pure</a> (<a>const</a> <a>id</a>) <a>&lt;*&gt;</a> u <a>&lt;*&gt;</a> v
--   u <a>&lt;*</a> v = <a>pure</a> <a>const</a> <a>&lt;*&gt;</a> u <a>&lt;*&gt;</a> v
--   </pre>
--   
--   As a consequence of these laws, the <a>Functor</a> instance for
--   <tt>f</tt> will satisfy
--   
--   <pre>
--   <a>fmap</a> f x = <a>pure</a> f <a>&lt;*&gt;</a> x
--   </pre>
--   
--   If <tt>f</tt> is also a <a>Monad</a>, it should satisfy
--   <tt><a>pure</a> = <a>return</a></tt> and <tt>(<a>&lt;*&gt;</a>) =
--   <a>ap</a></tt> (which implies that <a>pure</a> and <a>&lt;*&gt;</a>
--   satisfy the applicative functor laws).
class Functor f => Applicative (f :: * -> *)
pure :: Applicative f => a -> f a
(<*>) :: Applicative f => f (a -> b) -> f a -> f b
(*>) :: Applicative f => f a -> f b -> f b
(<*) :: Applicative f => f a -> f b -> f a

-- | An infix synonym for <a>fmap</a>.
(<$>) :: Functor f => (a -> b) -> f a -> f b

-- | Monads having fixed points with a 'knot-tying' semantics. Instances of
--   <a>MonadFix</a> should satisfy the following laws:
--   
--   <ul>
--   <li><i><i>purity</i></i> <tt><a>mfix</a> (<a>return</a> . h) =
--   <a>return</a> (<a>fix</a> h)</tt></li>
--   <li><i><i>left shrinking</i> (or <i>tightening</i>)</i>
--   <tt><a>mfix</a> (\x -&gt; a &gt;&gt;= \y -&gt; f x y) = a &gt;&gt;= \y
--   -&gt; <a>mfix</a> (\x -&gt; f x y)</tt></li>
--   <li><i><i>sliding</i></i> <tt><a>mfix</a> (<a>liftM</a> h . f) =
--   <a>liftM</a> h (<a>mfix</a> (f . h))</tt>, for strict <tt>h</tt>.</li>
--   <li><i><i>nesting</i></i> <tt><a>mfix</a> (\x -&gt; <a>mfix</a> (\y
--   -&gt; f x y)) = <a>mfix</a> (\x -&gt; f x x)</tt></li>
--   </ul>
--   
--   This class is used in the translation of the recursive <tt>do</tt>
--   notation supported by GHC and Hugs.
class Monad m => MonadFix (m :: * -> *)
mfix :: MonadFix m => (a -> m a) -> m a
class Monad m => MonadIO m
liftIO :: MonadIO m => IO a -> m a

-- | Lift an <a>IO</a> operation with 1 argument into another monad
liftIO1 :: MonadIO m => (a -> IO b) -> a -> m b

-- | Lift an <a>IO</a> operation with 2 arguments into another monad
liftIO2 :: MonadIO m => (a -> b -> IO c) -> a -> b -> m c

-- | Lift an <a>IO</a> operation with 3 arguments into another monad
liftIO3 :: MonadIO m => (a -> b -> c -> IO d) -> a -> b -> c -> m d

-- | Lift an <a>IO</a> operation with 4 arguments into another monad
liftIO4 :: MonadIO m => (a -> b -> c -> d -> IO e) -> a -> b -> c -> d -> m e
zipWith3M :: Monad m => (a -> b -> c -> m d) -> [a] -> [b] -> [c] -> m [d]

-- | The <a>mapAndUnzipM</a> function maps its first argument over a list,
--   returning the result as a pair of lists. This function is mainly used
--   with complicated data structures or a state-transforming monad.
mapAndUnzipM :: Monad m => (a -> m (b, c)) -> [a] -> m ([b], [c])

-- | mapAndUnzipM for triples
mapAndUnzip3M :: Monad m => (a -> m (b, c, d)) -> [a] -> m ([b], [c], [d])
mapAndUnzip4M :: Monad m => (a -> m (b, c, d, e)) -> [a] -> m ([b], [c], [d], [e])

-- | Monadic version of mapAccumL
mapAccumLM :: Monad m => (acc -> x -> m (acc, y)) -> acc -> [x] -> m (acc, [y])

-- | Monadic version of mapSnd
mapSndM :: Monad m => (b -> m c) -> [(a, b)] -> m [(a, c)]

-- | Monadic version of concatMap
concatMapM :: Monad m => (a -> m [b]) -> [a] -> m [b]

-- | Monadic version of mapMaybe
mapMaybeM :: Monad m => (a -> m (Maybe b)) -> [a] -> m [b]

-- | Monadic version of fmap
fmapMaybeM :: Monad m => (a -> m b) -> Maybe a -> m (Maybe b)

-- | Monadic version of fmap
fmapEitherM :: Monad m => (a -> m b) -> (c -> m d) -> Either a c -> m (Either b d)

-- | Monadic version of <a>any</a>, aborts the computation at the first
--   <tt>True</tt> value
anyM :: Monad m => (a -> m Bool) -> [a] -> m Bool

-- | Monad version of <a>all</a>, aborts the computation at the first
--   <tt>False</tt> value
allM :: Monad m => (a -> m Bool) -> [a] -> m Bool

-- | Monadic version of foldl
foldlM :: Monad m => (a -> b -> m a) -> a -> [b] -> m a

-- | Monadic version of foldl that discards its result
foldlM_ :: Monad m => (a -> b -> m a) -> a -> [b] -> m ()

-- | Monadic version of foldr
foldrM :: Monad m => (b -> a -> m a) -> a -> [b] -> m a

-- | Monadic version of fmap specialised for Maybe
maybeMapM :: Monad m => (a -> m b) -> (Maybe a -> m (Maybe b))
instance MonadIO IO

module State
newtype State s a
State :: (s -> (# a, s #)) -> State s a
runState' :: State s a -> s -> (# a, s #)
get :: State s s
gets :: (s -> a) -> State s a
put :: s -> State s ()
modify :: (s -> s) -> State s ()
evalState :: State s a -> s -> a
execState :: State s a -> s -> s
runState :: State s a -> s -> (a, s)

-- | Monadic version of mapAccumL
mapAccumLM :: Monad m => (acc -> x -> m (acc, y)) -> acc -> [x] -> m (acc, [y])
instance Monad (State s)
instance Applicative (State s)
instance Functor (State s)

module Stream

-- | <tt>Stream m a b</tt> is a computation in some Monad <tt>m</tt> that
--   delivers a sequence of elements of type <tt>a</tt> followed by a
--   result of type <tt>b</tt>.
--   
--   More concretely, a value of type <tt>Stream m a b</tt> can be run
--   using <tt>runStream</tt> in the Monad <tt>m</tt>, and it delivers
--   either
--   
--   <ul>
--   <li>the final result: <tt>Left b</tt>, or * <tt>Right (a,str)</tt>,
--   where <tt>a</tt> is the next element in the stream, and <tt>str</tt>
--   is a computation to get the rest of the stream.</li>
--   </ul>
--   
--   Stream is itself a Monad, and provides an operation <a>yield</a> that
--   produces a new element of the stream. This makes it convenient to turn
--   existing monadic computations into streams.
--   
--   The idea is that Stream is useful for making a monadic computation
--   that produces values from time to time. This can be used for knitting
--   together two complex monadic operations, so that the producer does not
--   have to produce all its values before the consumer starts consuming
--   them. We make the producer into a Stream, and the consumer pulls on
--   the stream each time it wants a new value.
newtype Stream m a b
Stream :: m (Either b (a, Stream m a b)) -> Stream m a b
runStream :: Stream m a b -> m (Either b (a, Stream m a b))
yield :: Monad m => a -> Stream m a ()
liftIO :: IO a -> Stream IO b a

-- | Turn a Stream into an ordinary list, by demanding all the elements.
collect :: Monad m => Stream m a () -> m [a]

-- | Turn a list into a <a>Stream</a>, by yielding each element in turn.
fromList :: Monad m => [a] -> Stream m a ()

-- | Apply a function to each element of a <a>Stream</a>, lazilly
map :: Monad m => (a -> b) -> Stream m a x -> Stream m b x

-- | Apply a monadic operation to each element of a <a>Stream</a>, lazilly
mapM :: Monad m => (a -> m b) -> Stream m a x -> Stream m b x

-- | analog of the list-based <a>mapAccumL</a> on Streams. This is a simple
--   way to map over a Stream while carrying some state around.
mapAccumL :: Monad m => (c -> a -> m (c, b)) -> c -> Stream m a () -> Stream m b c
instance Monad m => Monad (Stream m a)

module Exception
catchIO :: IO a -> (IOException -> IO a) -> IO a
handleIO :: (IOException -> IO a) -> IO a -> IO a
tryIO :: IO a -> IO (Either IOException a)

-- | A monad that can catch exceptions. A minimal definition requires a
--   definition of <a>gcatch</a>.
--   
--   Implementations on top of <a>IO</a> should implement <a>gblock</a> and
--   <a>gunblock</a> to eventually call the primitives <a>block</a> and
--   <a>unblock</a> respectively. These are used for implementations that
--   support asynchronous exceptions. The default implementations of
--   <a>gbracket</a> and <a>gfinally</a> use <a>gblock</a> and
--   <a>gunblock</a> thus rarely require overriding.
class Monad m => ExceptionMonad m where gmask f = gblock (f gunblock) gblock f = gmask (\ _ -> f) gunblock f = f gbracket before after thing = gmask $ \ restore -> do { a <- before; r <- restore (thing a) `gonException` after a; _ <- after a; return r } a gfinally sequel = gmask $ \ restore -> do { r <- restore a `gonException` sequel; _ <- sequel; return r }
gcatch :: (ExceptionMonad m, Exception e) => m a -> (e -> m a) -> m a
gmask :: ExceptionMonad m => ((m a -> m a) -> m b) -> m b
gbracket :: ExceptionMonad m => m a -> (a -> m b) -> (a -> m c) -> m c
gfinally :: ExceptionMonad m => m a -> m b -> m a
gblock :: ExceptionMonad m => m a -> m a
gunblock :: ExceptionMonad m => m a -> m a
gtry :: (ExceptionMonad m, Exception e) => m a -> m (Either e a)

-- | Generalised version of <a>handle</a>, allowing an arbitrary exception
--   handling monad instead of just <a>IO</a>.
ghandle :: (ExceptionMonad m, Exception e) => (e -> m a) -> m a -> m a

-- | Always executes the first argument. If this throws an exception the
--   second argument is executed and the exception is raised again.
gonException :: ExceptionMonad m => m a -> m b -> m a
instance ExceptionMonad IO

module Panic

-- | GHC's own exception type error messages all take the form:
--   
--   <pre>
--   <a>location</a>: <a>error</a>
--   </pre>
--   
--   If the location is on the command line, or in GHC itself, then
--   <a>location</a>=<a>ghc</a>. All of the error types below correspond to
--   a <a>location</a> of <a>ghc</a>, except for ProgramError (where the
--   string is assumed to contain a location already, so we don't print
--   one).
data GhcException
PhaseFailed :: String -> ExitCode -> GhcException

-- | Some other fatal signal (SIGHUP,SIGTERM)
Signal :: Int -> GhcException

-- | Prints the short usage msg after the error
UsageError :: String -> GhcException

-- | A problem with the command line arguments, but don't print usage.
CmdLineError :: String -> GhcException

-- | The <tt>impossible</tt> happened.
Panic :: String -> GhcException
PprPanic :: String -> SDoc -> GhcException

-- | The user tickled something that's known not to work yet, but we're not
--   counting it as a bug.
Sorry :: String -> GhcException
PprSorry :: String -> SDoc -> GhcException

-- | An installation problem.
InstallationError :: String -> GhcException

-- | An error in the user's code, probably.
ProgramError :: String -> GhcException
PprProgramError :: String -> SDoc -> GhcException

-- | Append a description of the given exception to this string.
showGhcException :: GhcException -> String -> String
throwGhcException :: GhcException -> a
handleGhcException :: ExceptionMonad m => (GhcException -> m a) -> m a -> m a

-- | Alias for <a>throwGhcException</a>
ghcError :: GhcException -> a

-- | The name of this GHC.
progName :: String

-- | Panics and asserts.
pgmError :: String -> a

-- | Panics and asserts.
panic :: String -> a

-- | Panics and asserts.
sorry :: String -> a

-- | Panic while pretending to return an unboxed int. You can't use the
--   regular panic functions in expressions producing unboxed ints because
--   they have the wrong kind.
panicFastInt :: String -> FastInt

-- | Throw an failed assertion exception for a given filename and line
--   number.
assertPanic :: String -> Int -> a

-- | The <a>trace</a> function outputs the trace message given as its first
--   argument, before returning the second argument as its result.
--   
--   For example, this returns the value of <tt>f x</tt> but first outputs
--   the message.
--   
--   <pre>
--   trace ("calling f with x = " ++ show x) (f x)
--   </pre>
--   
--   The <a>trace</a> function should <i>only</i> be used for debugging, or
--   for monitoring execution. The function is not referentially
--   transparent: its type indicates that it is a pure function but it has
--   the side effect of outputting the trace message.
trace :: String -> a -> a
panicDoc :: String -> SDoc -> a
sorryDoc :: String -> SDoc -> a
panicDocFastInt :: String -> SDoc -> FastInt
pgmErrorDoc :: String -> SDoc -> a

-- | Any type that you wish to throw or catch as an exception must be an
--   instance of the <tt>Exception</tt> class. The simplest case is a new
--   exception type directly below the root:
--   
--   <pre>
--   data MyException = ThisException | ThatException
--       deriving (Show, Typeable)
--   
--   instance Exception MyException
--   </pre>
--   
--   The default method definitions in the <tt>Exception</tt> class do what
--   we need in this case. You can now throw and catch
--   <tt>ThisException</tt> and <tt>ThatException</tt> as exceptions:
--   
--   <pre>
--   *Main&gt; throw ThisException `catch` \e -&gt; putStrLn ("Caught " ++ show (e :: MyException))
--   Caught ThisException
--   </pre>
--   
--   In more complicated examples, you may wish to define a whole hierarchy
--   of exceptions:
--   
--   <pre>
--   ---------------------------------------------------------------------
--   -- Make the root exception type for all the exceptions in a compiler
--   
--   data SomeCompilerException = forall e . Exception e =&gt; SomeCompilerException e
--       deriving Typeable
--   
--   instance Show SomeCompilerException where
--       show (SomeCompilerException e) = show e
--   
--   instance Exception SomeCompilerException
--   
--   compilerExceptionToException :: Exception e =&gt; e -&gt; SomeException
--   compilerExceptionToException = toException . SomeCompilerException
--   
--   compilerExceptionFromException :: Exception e =&gt; SomeException -&gt; Maybe e
--   compilerExceptionFromException x = do
--       SomeCompilerException a &lt;- fromException x
--       cast a
--   
--   ---------------------------------------------------------------------
--   -- Make a subhierarchy for exceptions in the frontend of the compiler
--   
--   data SomeFrontendException = forall e . Exception e =&gt; SomeFrontendException e
--       deriving Typeable
--   
--   instance Show SomeFrontendException where
--       show (SomeFrontendException e) = show e
--   
--   instance Exception SomeFrontendException where
--       toException = compilerExceptionToException
--       fromException = compilerExceptionFromException
--   
--   frontendExceptionToException :: Exception e =&gt; e -&gt; SomeException
--   frontendExceptionToException = toException . SomeFrontendException
--   
--   frontendExceptionFromException :: Exception e =&gt; SomeException -&gt; Maybe e
--   frontendExceptionFromException x = do
--       SomeFrontendException a &lt;- fromException x
--       cast a
--   
--   ---------------------------------------------------------------------
--   -- Make an exception type for a particular frontend compiler exception
--   
--   data MismatchedParentheses = MismatchedParentheses
--       deriving (Typeable, Show)
--   
--   instance Exception MismatchedParentheses where
--       toException   = frontendExceptionToException
--       fromException = frontendExceptionFromException
--   </pre>
--   
--   We can now catch a <tt>MismatchedParentheses</tt> exception as
--   <tt>MismatchedParentheses</tt>, <tt>SomeFrontendException</tt> or
--   <tt>SomeCompilerException</tt>, but not other types, e.g.
--   <tt>IOException</tt>:
--   
--   <pre>
--   *Main&gt; throw MismatchedParentheses <tt>catch</tt> e -&gt; putStrLn ("Caught " ++ show (e :: MismatchedParentheses))
--   Caught MismatchedParentheses
--   *Main&gt; throw MismatchedParentheses <tt>catch</tt> e -&gt; putStrLn ("Caught " ++ show (e :: SomeFrontendException))
--   Caught MismatchedParentheses
--   *Main&gt; throw MismatchedParentheses <tt>catch</tt> e -&gt; putStrLn ("Caught " ++ show (e :: SomeCompilerException))
--   Caught MismatchedParentheses
--   *Main&gt; throw MismatchedParentheses <tt>catch</tt> e -&gt; putStrLn ("Caught " ++ show (e :: IOException))
--   *** Exception: MismatchedParentheses
--   </pre>
class (Typeable e, Show e) => Exception e
toException :: Exception e => e -> SomeException
fromException :: Exception e => SomeException -> Maybe e

-- | Show an exception as a string.
showException :: Exception e => e -> String

-- | Show an exception which can possibly throw other exceptions. Used when
--   displaying exception thrown within TH code.
safeShowException :: Exception e => e -> IO String

-- | Similar to <a>catch</a>, but returns an <a>Either</a> result which is
--   <tt>(<a>Right</a> a)</tt> if no exception of type <tt>e</tt> was
--   raised, or <tt>(<a>Left</a> ex)</tt> if an exception of type
--   <tt>e</tt> was raised and its value is <tt>ex</tt>. If any other type
--   of exception is raised than it will be propogated up to the next
--   enclosing exception handler.
--   
--   <pre>
--   try a = catch (Right `liftM` a) (return . Left)
--   </pre>
--   
--   Note that <a>System.IO.Error</a> also exports a function called
--   <a>try</a> with a similar type to <a>try</a>, except that it catches
--   only the IO and user families of exceptions (as required by the
--   Haskell 98 <tt>IO</tt> module).
try :: Exception e => IO a -> IO (Either e a)

-- | Like try, but pass through UserInterrupt and Panic exceptions. Used
--   when we want soft failures when reading interface files, for example.
--   TODO: I'm not entirely sure if this is catching what we really want to
--   catch
tryMost :: IO a -> IO (Either SomeException a)

-- | <a>throwTo</a> raises an arbitrary exception in the target thread (GHC
--   only).
--   
--   <a>throwTo</a> does not return until the exception has been raised in
--   the target thread. The calling thread can thus be certain that the
--   target thread has received the exception. This is a useful property to
--   know when dealing with race conditions: eg. if there are two threads
--   that can kill each other, it is guaranteed that only one of the
--   threads will get to kill the other.
--   
--   Whatever work the target thread was doing when the exception was
--   raised is not lost: the computation is suspended until required by
--   another thread.
--   
--   If the target thread is currently making a foreign call, then the
--   exception will not be raised (and hence <a>throwTo</a> will not
--   return) until the call has completed. This is the case regardless of
--   whether the call is inside a <a>mask</a> or not. However, in GHC a
--   foreign call can be annotated as <tt>interruptible</tt>, in which case
--   a <a>throwTo</a> will cause the RTS to attempt to cause the call to
--   return; see the GHC documentation for more details.
--   
--   Important note: the behaviour of <a>throwTo</a> differs from that
--   described in the paper "Asynchronous exceptions in Haskell"
--   (<a>http://research.microsoft.com/~simonpj/Papers/asynch-exns.htm</a>).
--   In the paper, <a>throwTo</a> is non-blocking; but the library
--   implementation adopts a more synchronous design in which
--   <a>throwTo</a> does not return until the exception is received by the
--   target thread. The trade-off is discussed in Section 9 of the paper.
--   Like any blocking operation, <a>throwTo</a> is therefore interruptible
--   (see Section 5.3 of the paper). Unlike other interruptible operations,
--   however, <a>throwTo</a> is <i>always</i> interruptible, even if it
--   does not actually block.
--   
--   There is no guarantee that the exception will be delivered promptly,
--   although the runtime will endeavour to ensure that arbitrary delays
--   don't occur. In GHC, an exception can only be raised when a thread
--   reaches a <i>safe point</i>, where a safe point is where memory
--   allocation occurs. Some loops do not perform any memory allocation
--   inside the loop and therefore cannot be interrupted by a
--   <a>throwTo</a>.
--   
--   If the target of <a>throwTo</a> is the calling thread, then the
--   behaviour is the same as <a>throwIO</a>, except that the exception is
--   thrown as an asynchronous exception. This means that if there is an
--   enclosing pure computation, which would be the case if the current IO
--   operation is inside <a>unsafePerformIO</a> or
--   <a>unsafeInterleaveIO</a>, that computation is not permanently
--   replaced by the exception, but is suspended as if it had received an
--   asynchronous exception.
--   
--   Note that if <a>throwTo</a> is called with the current thread as the
--   target, the exception will be thrown even if the thread is currently
--   inside <a>mask</a> or <a>uninterruptibleMask</a>.
throwTo :: Exception e => ThreadId -> e -> IO ()

-- | Install standard signal handlers for catching ^C, which just throw an
--   exception in the target thread. The current target thread is the
--   thread at the head of the list in the MVar passed to
--   installSignalHandlers.
installSignalHandlers :: IO ()
pushInterruptTargetThread :: ThreadId -> IO ()
popInterruptTargetThread :: IO ()
instance Typeable GhcException
instance Show GhcException
instance Exception GhcException


-- | Highly random utility functions
module Util
ghciSupported :: Bool
debugIsOn :: Bool
ncgDebugIsOn :: Bool
ghciTablesNextToCode :: Bool
isDynamicGhcLib :: Bool
isWindowsHost :: Bool
isWindowsTarget :: Bool
isDarwinTarget :: Bool
zipEqual :: String -> [a] -> [b] -> [(a, b)]
zipWithEqual :: String -> (a -> b -> c) -> [a] -> [b] -> [c]
zipWith3Equal :: String -> (a -> b -> c -> d) -> [a] -> [b] -> [c] -> [d]
zipWith4Equal :: String -> (a -> b -> c -> d -> e) -> [a] -> [b] -> [c] -> [d] -> [e]

-- | <a>zipLazy</a> is a kind of <a>zip</a> that is lazy in the second list
--   (observe the ~)
zipLazy :: [a] -> [b] -> [(a, b)]

-- | <tt>stretchZipWith p z f xs ys</tt> stretches <tt>ys</tt> by inserting
--   <tt>z</tt> in the places where <tt>p</tt> returns <tt>True</tt>
stretchZipWith :: (a -> Bool) -> b -> (a -> b -> c) -> [a] -> [b] -> [c]
unzipWith :: (a -> b -> c) -> [(a, b)] -> [c]
mapFst :: (a -> c) -> [(a, b)] -> [(c, b)]
mapSnd :: (b -> c) -> [(a, b)] -> [(a, c)]
mapAndUnzip :: (a -> (b, c)) -> [a] -> ([b], [c])
mapAndUnzip3 :: (a -> (b, c, d)) -> [a] -> ([b], [c], [d])
mapAccumL2 :: (s1 -> s2 -> a -> (s1, s2, b)) -> s1 -> s2 -> [a] -> (s1, s2, [b])
nOfThem :: Int -> a -> [a]

-- | Like filter, only it reverses the sense of the test
filterOut :: (a -> Bool) -> [a] -> [a]

-- | Uses a function to determine which of two output lists an input
--   element should join
partitionWith :: (a -> Either b c) -> [a] -> ([b], [c])

-- | Teases a list of <a>Either</a>s apart into two lists
splitEithers :: [Either a b] -> ([a], [b])

-- | A strict version of <a>foldl1</a>
foldl1' :: (a -> a -> a) -> [a] -> a
foldl2 :: (acc -> a -> b -> acc) -> acc -> [a] -> [b] -> acc
count :: (a -> Bool) -> [a] -> Int
all2 :: (a -> b -> Bool) -> [a] -> [b] -> Bool

-- | <pre>
--   (lengthExceeds xs n) = (length xs &gt; n)
--   </pre>
lengthExceeds :: [a] -> Int -> Bool
lengthIs :: [a] -> Int -> Bool
lengthAtLeast :: [a] -> Int -> Bool
listLengthCmp :: [a] -> Int -> Ordering

-- | <tt>atLength atLen atEnd ls n</tt> unravels list <tt>ls</tt> to
--   position <tt>n</tt>. Precisely:
--   
--   <pre>
--   atLength atLenPred atEndPred ls n
--    | n &lt; 0         = atLenPred n
--    | length ls &lt; n = atEndPred (n - length ls)
--    | otherwise     = atLenPred (drop n ls)
--   </pre>
atLength :: ([a] -> b) -> (Int -> b) -> [a] -> Int -> b
equalLength :: [a] -> [b] -> Bool
compareLength :: [a] -> [b] -> Ordering
isSingleton :: [a] -> Bool
only :: [a] -> a
singleton :: a -> [a]
notNull :: [a] -> Bool
snocView :: [a] -> Maybe ([a], a)
isIn :: Eq a => String -> a -> [a] -> Bool
isn'tIn :: Eq a => String -> a -> [a] -> Bool
fstOf3 :: (a, b, c) -> a
sndOf3 :: (a, b, c) -> b
thirdOf3 :: (a, b, c) -> c
firstM :: Monad m => (a -> m c) -> (a, b) -> m (c, b)
first3M :: Monad m => (a -> m d) -> (a, b, c) -> m (d, b, c)
third3 :: (c -> d) -> (a, b, c) -> (a, b, d)
uncurry3 :: (a -> b -> c -> d) -> (a, b, c) -> d
takeList :: [b] -> [a] -> [a]
dropList :: [b] -> [a] -> [a]
splitAtList :: [b] -> [a] -> ([a], [a])
split :: Char -> String -> [String]
dropTail :: Int -> [a] -> [a]

-- | Compose a function with itself n times. (nth rather than twice)
nTimes :: Int -> (a -> a) -> (a -> a)
sortWith :: Ord b => (a -> b) -> [a] -> [a]
minWith :: Ord b => (a -> b) -> [a] -> a
isEqual :: Ordering -> Bool
eqListBy :: (a -> a -> Bool) -> [a] -> [a] -> Bool
eqMaybeBy :: (a -> a -> Bool) -> Maybe a -> Maybe a -> Bool
thenCmp :: Ordering -> Ordering -> Ordering
cmpList :: (a -> a -> Ordering) -> [a] -> [a] -> Ordering
removeSpaces :: String -> String
fuzzyMatch :: String -> [String] -> [String]

-- | Search for possible matches to the users input in the given list,
--   returning a small number of ranked results
fuzzyLookup :: String -> [(String, a)] -> [a]
transitiveClosure :: (a -> [a]) -> (a -> a -> Bool) -> [a] -> [a]
seqList :: [a] -> b -> b
looksLikeModuleName :: String -> Bool
getCmd :: String -> Either String (String, String)
toCmdArgs :: String -> Either String (String, [String])
toArgs :: String -> Either String [String]
readRational :: String -> Rational
maybeRead :: Read a => String -> Maybe a
maybeReadFuzzy :: Read a => String -> Maybe a
doesDirNameExist :: FilePath -> IO Bool
getModificationUTCTime :: FilePath -> IO UTCTime
modificationTimeIfExists :: FilePath -> IO (Maybe UTCTime)
global :: a -> IORef a
consIORef :: IORef [a] -> a -> IO ()
globalM :: IO a -> IORef a
type Suffix = String
splitLongestPrefix :: String -> (Char -> Bool) -> (String, String)
escapeSpaces :: String -> String

-- | The function splits the given string to substrings using the
--   <a>searchPathSeparator</a>.
parseSearchPath :: String -> [FilePath]
data Direction
Forwards :: Direction
Backwards :: Direction
reslash :: Direction -> FilePath -> FilePath
abstractConstr :: String -> Constr
abstractDataType :: String -> DataType

-- | Constructs a non-representation for a non-presentable type
mkNoRepType :: String -> DataType
charToC :: Word8 -> String

-- | A sample hash function for Strings. We keep multiplying by the golden
--   ratio and adding. The implementation is:
--   
--   <pre>
--   hashString = foldl' f golden
--     where f m c = fromIntegral (ord c) * magic + hashInt32 m
--           magic = 0xdeadbeef
--   </pre>
--   
--   Where hashInt32 works just as hashInt shown above.
--   
--   Knuth argues that repeated multiplication by the golden ratio will
--   minimize gaps in the hash space, and thus it's a good choice for
--   combining together multiple keys to form one.
--   
--   Here we know that individual characters c are often small, and this
--   produces frequent collisions if we use ord c alone. A particular
--   problem are the shorter low ASCII and ISO-8859-1 character strings. We
--   pre-multiply by a magic twiddle factor to obtain a good distribution.
--   In fact, given the following test:
--   
--   <pre>
--   testp :: Int32 -&gt; Int
--   testp k = (n - ) . length . group . sort . map hs . take n $ ls
--     where ls = [] : [c : l | l &lt;- ls, c &lt;- ['\0'..'\xff']]
--           hs = foldl' f golden
--           f m c = fromIntegral (ord c) * k + hashInt32 m
--           n = 100000
--   </pre>
--   
--   We discover that testp magic = 0.
hashString :: String -> Int32


-- | There are two principal string types used internally by GHC:
--   
--   <a>FastString</a>: * A compact, hash-consed, representation of
--   character strings. * Comparison is O(1), and you can get a
--   <a>Unique</a> from them. * Generated by <a>fsLit</a>. * Turn into
--   <a>SDoc</a> with <a>ftext</a>.
--   
--   <a>LitString</a>: * Just a wrapper for the <tt>Addr#</tt> of a C
--   string (<tt>Ptr CChar</tt>). * Practically no operations. * Outputing
--   them is fast. * Generated by <a>sLit</a>. * Turn into <a>SDoc</a> with
--   <a>ptext</a>
--   
--   Use <a>LitString</a> unless you want the facilities of
--   <a>FastString</a>.
module FastString

-- | A <a>FastString</a> is an array of bytes, hashed to support fast O(1)
--   comparison. It is also associated with a character encoding, so that
--   we know how to convert a <a>FastString</a> to the local encoding, or
--   to the Z-encoding used by the compiler internally.
--   
--   <a>FastString</a>s support a memoized conversion to the Z-encoding via
--   zEncodeFS.
data FastString
FastString :: {-# UNPACK #-} !Int -> {-# UNPACK #-} !Int -> {-# UNPACK #-} !Int -> {-# UNPACK #-} !(ForeignPtr Word8) -> FSEncoding -> FastString
uniq :: FastString -> {-# UNPACK #-} !Int
n_bytes :: FastString -> {-# UNPACK #-} !Int
n_chars :: FastString -> {-# UNPACK #-} !Int
buf :: FastString -> {-# UNPACK #-} !(ForeignPtr Word8)
enc :: FastString -> FSEncoding
fsLit :: String -> FastString

-- | Creates a UTF-8 encoded <a>FastString</a> from a <a>String</a>
mkFastString :: String -> FastString
mkFastStringBytes :: Ptr Word8 -> Int -> FastString

-- | Creates a <a>FastString</a> from a UTF-8 encoded <tt>[Word8]</tt>
mkFastStringByteList :: [Word8] -> FastString

-- | Create a <a>FastString</a> from an existing <a>ForeignPtr</a>; the
--   difference between this and <a>mkFastStringBytes</a> is that we don't
--   have to copy the bytes if the string is new to the table.
mkFastStringForeignPtr :: Ptr Word8 -> ForeignPtr Word8 -> Int -> IO FastString
mkFastString# :: Addr# -> FastString

-- | Creates a Z-encoded <a>FastString</a> from a <a>String</a>
mkZFastString :: String -> FastString
mkZFastStringBytes :: Ptr Word8 -> Int -> FastString

-- | Unpacks and decodes the FastString
unpackFS :: FastString -> String

-- | Gives the UTF-8 encoded bytes corresponding to a <a>FastString</a>
bytesFS :: FastString -> [Word8]

-- | Returns <tt>True</tt> if the <a>FastString</a> is Z-encoded
isZEncoded :: FastString -> Bool

-- | Returns a Z-encoded version of a <a>FastString</a>. This might be the
--   original, if it was already Z-encoded. The first time this function is
--   applied to a particular <a>FastString</a>, the results are memoized.
zEncodeFS :: FastString -> FastString
uniqueOfFS :: FastString -> FastInt

-- | Returns the length of the <a>FastString</a> in characters
lengthFS :: FastString -> Int

-- | Returns <tt>True</tt> if the <a>FastString</a> is empty
nullFS :: FastString -> Bool
appendFS :: FastString -> FastString -> FastString
headFS :: FastString -> Char
tailFS :: FastString -> FastString
concatFS :: [FastString] -> FastString
consFS :: Char -> FastString -> FastString
nilFS :: FastString

-- | Outputs a <a>FastString</a> with <i>no decoding at all</i>, that is,
--   you get the actual bytes in the <a>FastString</a> written to the
--   <a>Handle</a>.
hPutFS :: Handle -> FastString -> IO ()
getFastStringTable :: IO [[FastString]]

-- | Returns <tt>True</tt> if this <a>FastString</a> is not Z-encoded but
--   already has a Z-encoding cached (used in producing stats).
hasZEncoding :: FastString -> Bool
type LitString = Ptr Word8
sLit :: String -> LitString
mkLitString# :: Addr# -> LitString
mkLitString :: String -> LitString
unpackLitString :: LitString -> String
lengthLS :: LitString -> Int
instance Typeable FastString
instance Data FastString
instance Show FastString
instance Ord FastString
instance Eq FastString

module BufWrite
data BufHandle
BufHandle :: {-# UNPACK #-} !(Ptr Word8) -> {-# UNPACK #-} !FastMutInt -> Handle -> BufHandle
newBufHandle :: Handle -> IO BufHandle
bPutChar :: BufHandle -> Char -> IO ()
bPutStr :: BufHandle -> String -> IO ()
bPutFS :: BufHandle -> FastString -> IO ()
bPutLitString :: BufHandle -> LitString -> FastInt -> IO ()
bFlush :: BufHandle -> IO ()

module StringBuffer

-- | A StringBuffer is an internal pointer to a sized chunk of bytes. The
--   bytes are intended to be *immutable*. There are pure operations to
--   read the contents of a StringBuffer.
--   
--   A StringBuffer may have a finalizer, depending on how it was obtained.
data StringBuffer
StringBuffer :: {-# UNPACK #-} !(ForeignPtr Word8) -> {-# UNPACK #-} !Int -> {-# UNPACK #-} !Int -> StringBuffer
buf :: StringBuffer -> {-# UNPACK #-} !(ForeignPtr Word8)
len :: StringBuffer -> {-# UNPACK #-} !Int
cur :: StringBuffer -> {-# UNPACK #-} !Int
hGetStringBuffer :: FilePath -> IO StringBuffer
hGetStringBufferBlock :: Handle -> Int -> IO StringBuffer
appendStringBuffers :: StringBuffer -> StringBuffer -> IO StringBuffer
stringToStringBuffer :: String -> StringBuffer
nextChar :: StringBuffer -> (Char, StringBuffer)
currentChar :: StringBuffer -> Char
prevChar :: StringBuffer -> Char -> Char
atEnd :: StringBuffer -> Bool
stepOn :: StringBuffer -> StringBuffer
offsetBytes :: Int -> StringBuffer -> StringBuffer
byteDiff :: StringBuffer -> StringBuffer -> Int
lexemeToString :: StringBuffer -> Int -> String
lexemeToFastString :: StringBuffer -> Int -> FastString

-- | XXX assumes ASCII digits only (by using byteOff)
parseUnsignedInteger :: StringBuffer -> Int -> Integer -> (Char -> Int) -> Integer
instance Show StringBuffer

module StaticFlags
staticFlags :: [String]
initStaticOpts :: IO ()
data WayName
WayThreaded :: WayName
WayDebug :: WayName
WayProf :: WayName
WayEventLog :: WayName
WayPar :: WayName
WayGran :: WayName
WayNDP :: WayName
WayDyn :: WayName
data Way
Way :: WayName -> String -> Bool -> String -> [String] -> Way
wayName :: Way -> WayName
wayTag :: Way -> String
wayRTSOnly :: Way -> Bool
wayDesc :: Way -> String
wayOpts :: Way -> [String]
v_Ways :: IORef ([Way])
isRTSWay :: WayName -> Bool
mkBuildTag :: [Way] -> String
opt_PprStyle_Debug :: Bool
opt_NoDebugOutput :: Bool

-- | Suppress all that is suppressable in core dumps. Except for uniques,
--   as some simplifier phases introduce new varibles that have otherwise
--   identical names.
opt_SuppressAll :: Bool

-- | Suppress unique ids on variables. Except for uniques, as some
--   simplifier phases introduce new variables that have otherwise
--   identical names.
opt_SuppressUniques :: Bool

-- | Suppress all coercions, them replacing with <tt>...</tt>
opt_SuppressCoercions :: Bool

-- | Suppress module id prefixes on variables.
opt_SuppressModulePrefixes :: Bool

-- | Suppress type applications.
opt_SuppressTypeApplications :: Bool

-- | Suppress info such as arity and unfoldings on identifiers.
opt_SuppressIdInfo :: Bool

-- | Suppress separate type signatures in core, but leave types on lambda
--   bound vars
opt_SuppressTypeSignatures :: Bool
opt_SuppressVarKinds :: Bool
opt_SccProfilingOn :: Bool
opt_Hpc :: Bool
opt_DictsStrict :: Bool
opt_NoStateHack :: Bool
opt_SimpleListLiterals :: Bool
opt_CprOff :: Bool
opt_SimplNoPreInlining :: Bool
opt_SimplExcessPrecision :: Bool
opt_NoOptCoercion :: Bool
opt_MaxWorkerArgs :: Int
opt_UF_CreationThreshold :: Int
opt_UF_UseThreshold :: Int
opt_UF_FunAppDiscount :: Int
opt_UF_DictDiscount :: Int
opt_UF_KeenessFactor :: Float
opt_UF_DearOp :: Int
opt_Fuel :: Int
opt_PIC :: Bool
opt_Static :: Bool
opt_ErrorSpans :: Bool
opt_HistorySize :: Int
opt_Unregisterised :: Bool
v_Ld_inputs :: IORef ([String])
tablesNextToCode :: Bool
opt_StubDeadValues :: Bool
opt_Ticky :: Bool
addOpt :: String -> IO ()
removeOpt :: String -> IO ()
addWay :: WayName -> IO ()
getWayFlags :: IO [String]
v_opt_C_ready :: IORef (Bool)
saveStaticFlagGlobals :: IO (Bool, [String], [Way])
restoreStaticFlagGlobals :: (Bool, [String], [Way]) -> IO ()
instance Eq WayName
instance Ord WayName

module Pretty
data Doc
data Mode
PageMode :: Mode
ZigZagMode :: Mode
LeftMode :: Mode
OneLineMode :: Mode
data TextDetails
Chr :: {-# UNPACK #-} !Char -> TextDetails
Str :: String -> TextDetails
PStr :: FastString -> TextDetails
LStr :: {-# UNPACK #-} !LitString -> FastInt -> TextDetails
empty :: Doc
isEmpty :: Doc -> Bool
nest :: Int -> Doc -> Doc
char :: Char -> Doc
text :: String -> Doc
ftext :: FastString -> Doc
ptext :: LitString -> Doc

-- | Some text, but without any width. Use for non-printing text such as a
--   HTML or Latex tags
zeroWidthText :: String -> Doc
int :: Int -> Doc
integer :: Integer -> Doc
float :: Float -> Doc
double :: Double -> Doc
rational :: Rational -> Doc
parens :: Doc -> Doc
brackets :: Doc -> Doc
braces :: Doc -> Doc
quotes :: Doc -> Doc
quote :: Doc -> Doc
doubleQuotes :: Doc -> Doc
semi :: Doc
comma :: Doc
colon :: Doc
space :: Doc
equals :: Doc
lparen :: Doc
rparen :: Doc
lbrack :: Doc
rbrack :: Doc
lbrace :: Doc
rbrace :: Doc
cparen :: Bool -> Doc -> Doc
(<>) :: Doc -> Doc -> Doc
(<+>) :: Doc -> Doc -> Doc
hcat :: [Doc] -> Doc
hsep :: [Doc] -> Doc
($$) :: Doc -> Doc -> Doc
($+$) :: Doc -> Doc -> Doc
vcat :: [Doc] -> Doc
sep :: [Doc] -> Doc
cat :: [Doc] -> Doc
fsep :: [Doc] -> Doc
fcat :: [Doc] -> Doc
hang :: Doc -> Int -> Doc -> Doc
punctuate :: Doc -> [Doc] -> [Doc]
render :: Doc -> String
fullRender :: Mode -> Int -> Float -> (TextDetails -> a -> a) -> a -> Doc -> a
printDoc :: Mode -> Int -> Handle -> Doc -> IO ()
showDocWith :: Mode -> Doc -> String
bufLeftRender :: BufHandle -> Doc -> IO ()
instance Show Doc

module PprExternalCore
instance Show Lit
instance Show Kind
instance Show Ty
instance Show Alt
instance Show Exp
instance Show Vdefg
instance Show Cdef
instance Show Tdef
instance Show Module

module Ctype
is_ident :: Char -> Bool
is_symbol :: Char -> Bool
is_any :: Char -> Bool
is_space :: Char -> Bool
is_lower :: Char -> Bool
is_upper :: Char -> Bool
is_digit :: Char -> Bool
is_alphanum :: Char -> Bool
is_decdigit :: Char -> Bool
is_hexdigit :: Char -> Bool
is_octdigit :: Char -> Bool
hexDigit :: Char -> Int
octDecDigit :: Char -> Int

module PPC.Cond
data Cond
ALWAYS :: Cond
EQQ :: Cond
GE :: Cond
GEU :: Cond
GTT :: Cond
GU :: Cond
LE :: Cond
LEU :: Cond
LTT :: Cond
LU :: Cond
NE :: Cond
condNegate :: Cond -> Cond
condUnsigned :: Cond -> Bool
condToSigned :: Cond -> Cond
condToUnsigned :: Cond -> Cond
instance Eq Cond


-- | Bits and pieces on the bottom of the module dependency tree. Also
--   import the required constants, so we know what we're using.
--   
--   In the interests of cross-compilation, we want to free ourselves from
--   the autoconf generated modules like main/Constants
module SPARC.Base
wordLength :: Int
wordLengthInBits :: Int
spillAreaLength :: Int

-- | We need 8 bytes because our largest registers are 64 bit.
spillSlotSize :: Int

-- | We (allegedly) put the first six C-call arguments in registers; where
--   do we start putting the rest of them?
extraStackArgsHere :: Int

-- | Check whether an offset is representable with 13 bits.
fits13Bits :: Integral a => a -> Bool

-- | Check whether an integer will fit in 32 bits. A CmmInt is intended to
--   be truncated to the appropriate number of bits, so here we truncate it
--   to Int64. This is important because e.g. -1 as a CmmInt might be
--   either -1 or 18446744073709551615.
is32BitInteger :: Integer -> Bool

-- | Sadness.
largeOffsetError :: (Integral a, Show a) => a -> b

module ParserCoreUtils
data ParseResult a
OkP :: a -> ParseResult a
FailP :: String -> ParseResult a
type P a = String -> Int -> ParseResult a
thenP :: P a -> (a -> P b) -> P b
returnP :: a -> P a
failP :: String -> P a
getCoreModuleName :: FilePath -> IO String
data Token
TKmodule :: Token
TKdata :: Token
TKnewtype :: Token
TKforall :: Token
TKrec :: Token
TKlet :: Token
TKin :: Token
TKcase :: Token
TKof :: Token
TKcast :: Token
TKnote :: Token
TKexternal :: Token
TKlocal :: Token
TKwild :: Token
TKoparen :: Token
TKcparen :: Token
TKobrace :: Token
TKcbrace :: Token
TKhash :: Token
TKeq :: Token
TKcolon :: Token
TKcoloncolon :: Token
TKcoloneqcolon :: Token
TKstar :: Token
TKrarrow :: Token
TKlambda :: Token
TKat :: Token
TKdot :: Token
TKquestion :: Token
TKsemicolon :: Token
TKname :: String -> Token
TKcname :: String -> Token
TKinteger :: Integer -> Token
TKrational :: Rational -> Token
TKstring :: String -> Token
TKchar :: Char -> Token
TKEOF :: Token

module LexCore
isNameChar :: Char -> Bool
isKeywordChar :: Char -> Bool
lexer :: (Token -> P a) -> P a
lexChar :: (Token -> String -> Int -> ParseResult a) -> String -> Int -> ParseResult a
lexString :: String -> (Token -> [Char] -> Int -> ParseResult a) -> String -> Int -> ParseResult a
isHexEscape :: String -> Bool
hexToChar :: Char -> Char -> Char
lexNum :: (Token -> String -> a) -> String -> a
lexName :: (a -> String -> b) -> (String -> a) -> String -> b
lexKeyword :: (Token -> [Char] -> Int -> ParseResult a) -> String -> Int -> ParseResult a


-- | A description of the platform we're compiling for.
module Platform

-- | Contains enough information for the native code generator to emit code
--   for this platform.
data Platform
Platform :: Arch -> OS -> {-# UNPACK #-} !Int -> Bool -> Bool -> Bool -> Platform
platformArch :: Platform -> Arch
platformOS :: Platform -> OS
platformWordSize :: Platform -> {-# UNPACK #-} !Int
platformHasGnuNonexecStack :: Platform -> Bool
platformHasIdentDirective :: Platform -> Bool
platformHasSubsectionsViaSymbols :: Platform -> Bool

-- | Architectures that the native code generator knows about. TODO: It
--   might be nice to extend these constructors with information about what
--   instruction set extensions an architecture might support.
data Arch
ArchUnknown :: Arch
ArchX86 :: Arch
ArchX86_64 :: Arch
ArchPPC :: Arch
ArchPPC_64 :: Arch
ArchSPARC :: Arch
ArchARM :: ArmISA -> [ArmISAExt] -> ArmABI -> Arch
armISA :: Arch -> ArmISA
armISAExt :: Arch -> [ArmISAExt]
armABI :: Arch -> ArmABI

-- | Operating systems that the native code generator knows about. Having
--   OSUnknown should produce a sensible default, but no promises.
data OS
OSUnknown :: OS
OSLinux :: OS
OSDarwin :: OS
OSSolaris2 :: OS
OSMinGW32 :: OS
OSFreeBSD :: OS
OSDragonFly :: OS
OSOpenBSD :: OS
OSNetBSD :: OS
OSKFreeBSD :: OS
OSHaiku :: OS

-- | ARM Instruction Set Architecture, Extensions and ABI
data ArmISA
ARMv5 :: ArmISA
ARMv6 :: ArmISA
ARMv7 :: ArmISA
data ArmISAExt
VFPv2 :: ArmISAExt
VFPv3 :: ArmISAExt
VFPv3D16 :: ArmISAExt
NEON :: ArmISAExt
IWMMX2 :: ArmISAExt
data ArmABI
SOFT :: ArmABI
SOFTFP :: ArmABI
HARD :: ArmABI
target32Bit :: Platform -> Bool

-- | This predicates tells us whether the OS supports ELF-like shared
--   libraries.
osElfTarget :: OS -> Bool
instance Read OS
instance Show OS
instance Eq OS
instance Read ArmISA
instance Show ArmISA
instance Eq ArmISA
instance Read ArmISAExt
instance Show ArmISAExt
instance Eq ArmISAExt
instance Read ArmABI
instance Show ArmABI
instance Eq ArmABI
instance Read Arch
instance Show Arch
instance Eq Arch
instance Read Platform
instance Show Platform
instance Eq Platform


-- | This module defines classes and functions for pretty-printing. It also
--   exports a number of helpful debugging and other utilities such as
--   <a>trace</a> and <a>panic</a>.
--   
--   The interface to this module is very similar to the standard Hughes-PJ
--   pretty printing module, except that it exports a number of additional
--   functions that are rarely used, and works over the <a>SDoc</a> type.
module Outputable

-- | Class designating that some type has an <a>SDoc</a> representation
class Outputable a where ppr = pprPrec 0 pprPrec _ = ppr
ppr :: Outputable a => a -> SDoc
pprPrec :: Outputable a => Rational -> a -> SDoc

-- | When we print a binder, we often want to print its type too. The
--   <tt>OutputableBndr</tt> class encapsulates this idea.
class Outputable a => OutputableBndr a where pprBndr _b x = ppr x
pprBndr :: OutputableBndr a => BindingSite -> a -> SDoc
pprPrefixOcc, pprInfixOcc :: OutputableBndr a => a -> SDoc
data SDoc
runSDoc :: SDoc -> SDocContext -> Doc
initSDocContext :: DynFlags -> PprStyle -> SDocContext
docToSDoc :: Doc -> SDoc

-- | Returns the seperated concatenation of the pretty printed things.
interppSP :: Outputable a => [a] -> SDoc

-- | Returns the comma-seperated concatenation of the pretty printed
--   things.
interpp'SP :: Outputable a => [a] -> SDoc

-- | Returns the comma-seperated concatenation of the quoted pretty printed
--   things.
--   
--   <pre>
--   [x,y,z]  ==&gt;  `x', `y', `z'
--   </pre>
pprQuotedList :: Outputable a => [a] -> SDoc
pprWithCommas :: (a -> SDoc) -> [a] -> SDoc
quotedListWithOr :: [SDoc] -> SDoc
empty :: SDoc

-- | Indent <a>SDoc</a> some specified amount
nest :: Int -> SDoc -> SDoc
char :: Char -> SDoc
text :: String -> SDoc
ftext :: FastString -> SDoc
ptext :: LitString -> SDoc
int :: Int -> SDoc
intWithCommas :: Integral a => a -> SDoc
integer :: Integer -> SDoc
float :: Float -> SDoc
double :: Double -> SDoc
rational :: Rational -> SDoc
parens :: SDoc -> SDoc
cparen :: Bool -> SDoc -> SDoc
brackets :: SDoc -> SDoc
braces :: SDoc -> SDoc
quotes :: SDoc -> SDoc
quote :: SDoc -> SDoc
doubleQuotes :: SDoc -> SDoc
angleBrackets :: SDoc -> SDoc
paBrackets :: SDoc -> SDoc
semi :: SDoc
comma :: SDoc
colon :: SDoc
dcolon :: SDoc
space :: SDoc
equals :: SDoc
dot :: SDoc
arrow :: SDoc
darrow :: SDoc
lparen :: SDoc
rparen :: SDoc
lbrack :: SDoc
rbrack :: SDoc
lbrace :: SDoc
rbrace :: SDoc
underscore :: SDoc
blankLine :: SDoc

-- | Join two <a>SDoc</a> together horizontally without a gap
(<>) :: SDoc -> SDoc -> SDoc

-- | Join two <a>SDoc</a> together horizontally with a gap between them
(<+>) :: SDoc -> SDoc -> SDoc

-- | Concatenate <a>SDoc</a> horizontally
hcat :: [SDoc] -> SDoc

-- | Concatenate <a>SDoc</a> horizontally with a space between each one
hsep :: [SDoc] -> SDoc

-- | Join two <a>SDoc</a> together vertically; if there is no vertical
--   overlap it <a>dovetails</a> the two onto one line
($$) :: SDoc -> SDoc -> SDoc

-- | Join two <a>SDoc</a> together vertically
($+$) :: SDoc -> SDoc -> SDoc

-- | Concatenate <a>SDoc</a> vertically with dovetailing
vcat :: [SDoc] -> SDoc

-- | Separate: is either like <a>hsep</a> or like <a>vcat</a>, depending on
--   what fits
sep :: [SDoc] -> SDoc

-- | Catenate: is either like <a>hcat</a> or like <a>vcat</a>, depending on
--   what fits
cat :: [SDoc] -> SDoc

-- | A paragraph-fill combinator. It's much like sep, only it keeps fitting
--   things on one line until it can't fit any more.
fsep :: [SDoc] -> SDoc

-- | This behaves like <a>fsep</a>, but it uses <a>&lt;&gt;</a> for
--   horizontal conposition rather than <a>&lt;+&gt;</a>
fcat :: [SDoc] -> SDoc
hang :: SDoc -> Int -> SDoc -> SDoc
punctuate :: SDoc -> [SDoc] -> [SDoc]
ppWhen :: Bool -> SDoc -> SDoc
ppUnless :: Bool -> SDoc -> SDoc

-- | Converts an integer to a verbal index:
--   
--   <pre>
--   speakNth 1 = text "first"
--   speakNth 5 = text "fifth"
--   speakNth 21 = text "21st"
--   </pre>
speakNth :: Int -> SDoc

-- | Converts a strictly positive integer into a number of times:
--   
--   <pre>
--   speakNTimes 1 = text "once"
--   speakNTimes 2 = text "twice"
--   speakNTimes 4 = text "4 times"
--   </pre>
speakNTimes :: Int -> SDoc

-- | Converts an integer to a verbal multiplicity:
--   
--   <pre>
--   speakN 0 = text "none"
--   speakN 5 = text "five"
--   speakN 10 = text "10"
--   </pre>
speakN :: Int -> SDoc

-- | Converts an integer and object description to a statement about the
--   multiplicity of those objects:
--   
--   <pre>
--   speakNOf 0 (text "melon") = text "no melons"
--   speakNOf 1 (text "melon") = text "one melon"
--   speakNOf 3 (text "melon") = text "three melons"
--   </pre>
speakNOf :: Int -> SDoc -> SDoc

-- | Determines the pluralisation suffix appropriate for the length of a
--   list:
--   
--   <pre>
--   plural [] = char 's'
--   plural ["Hello"] = empty
--   plural ["Hello", "World"] = char 's'
--   </pre>
plural :: [a] -> SDoc

-- | Apply the given colour/style for the argument.
--   
--   Only takes effect if colours are enabled.
coloured :: PprColour -> SDoc -> SDoc

-- | A colour/style for use with <a>coloured</a>.
data PprColour
colType :: PprColour
colCoerc :: PprColour
colDataCon :: PprColour
colBinder :: PprColour
bold :: SDoc -> SDoc
keyword :: SDoc -> SDoc
printForC :: DynFlags -> Handle -> SDoc -> IO ()
printForAsm :: DynFlags -> Handle -> SDoc -> IO ()
printForUser :: DynFlags -> Handle -> PrintUnqualified -> SDoc -> IO ()
printForUserPartWay :: DynFlags -> Handle -> Int -> PrintUnqualified -> SDoc -> IO ()
pprCode :: CodeStyle -> SDoc -> SDoc
mkCodeStyle :: CodeStyle -> PprStyle
showSDoc :: DynFlags -> SDoc -> String
showSDocOneLine :: DynFlags -> SDoc -> String
showSDocForUser :: DynFlags -> PrintUnqualified -> SDoc -> String
showSDocDebug :: DynFlags -> SDoc -> String
showSDocDump :: DynFlags -> SDoc -> String
showSDocDumpOneLine :: DynFlags -> SDoc -> String
showPpr :: Outputable a => DynFlags -> a -> String
showSDocUnqual :: DynFlags -> SDoc -> String
renderWithStyle :: DynFlags -> SDoc -> PprStyle -> String
pprInfixVar :: Bool -> SDoc -> SDoc
pprPrefixVar :: Bool -> SDoc -> SDoc

-- | Special combinator for showing character literals.
pprHsChar :: Char -> SDoc

-- | Special combinator for showing string literals.
pprHsString :: FastString -> SDoc
pprFastFilePath :: FastString -> SDoc

-- | <a>BindingSite</a> is used to tell the thing that prints binder what
--   language construct is binding the identifier. This can be used to
--   decide how much info to print.
data BindingSite
LambdaBind :: BindingSite
CaseBind :: BindingSite
LetBind :: BindingSite
data PprStyle
data CodeStyle
CStyle :: CodeStyle
AsmStyle :: CodeStyle
type PrintUnqualified = (QueryQualifyName, QueryQualifyModule)
alwaysQualify :: PrintUnqualified
neverQualify :: PrintUnqualified
data QualifyName
NameUnqual :: QualifyName
NameQual :: ModuleName -> QualifyName
NameNotInScope1 :: QualifyName
NameNotInScope2 :: QualifyName
sdocWithDynFlags :: (DynFlags -> SDoc) -> SDoc
sdocWithPlatform :: (Platform -> SDoc) -> SDoc
getPprStyle :: (PprStyle -> SDoc) -> SDoc
withPprStyle :: PprStyle -> SDoc -> SDoc
withPprStyleDoc :: DynFlags -> PprStyle -> SDoc -> Doc
pprDeeper :: SDoc -> SDoc
pprDeeperList :: ([SDoc] -> SDoc) -> [SDoc] -> SDoc
pprSetDepth :: Depth -> SDoc -> SDoc
codeStyle :: PprStyle -> Bool
userStyle :: PprStyle -> Bool
debugStyle :: PprStyle -> Bool
dumpStyle :: PprStyle -> Bool
asmStyle :: PprStyle -> Bool
ifPprDebug :: SDoc -> SDoc
qualName :: PprStyle -> QueryQualifyName
qualModule :: PprStyle -> QueryQualifyModule

-- | Style for printing error messages
mkErrStyle :: DynFlags -> PrintUnqualified -> PprStyle
defaultErrStyle :: DynFlags -> PprStyle
defaultDumpStyle :: PprStyle
defaultUserStyle :: PprStyle
mkUserStyle :: PrintUnqualified -> Depth -> PprStyle
cmdlineParserStyle :: PprStyle
data Depth
AllTheWay :: Depth
PartWay :: Int -> Depth

-- | Throw an exception saying <a>bug in GHC</a>
pprPanic :: String -> SDoc -> a

-- | Throw an exception saying <a>this isn't finished yet</a>
pprSorry :: String -> SDoc -> a

-- | Panic with an assertation failure, recording the given file and line
--   number. Should typically be accessed with the ASSERT family of macros
assertPprPanic :: String -> Int -> SDoc -> a

-- | Specialization of pprPanic that can be safely used with <a>FastInt</a>
pprPanicFastInt :: String -> SDoc -> FastInt

-- | Throw an exception saying <a>bug in pgm being compiled</a> (used for
--   unusual program errors)
pprPgmError :: String -> SDoc -> a

-- | If debug output is on, show some <a>SDoc</a> on the screen
pprTrace :: String -> SDoc -> a -> a

-- | Same as pprTrace, but show even if -dno-debug-output is on
pprDefiniteTrace :: DynFlags -> String -> SDoc -> a -> a

-- | Just warn about an assertion failure, recording the given file and
--   line number. Should typically be accessed with the WARN macros
warnPprTrace :: Bool -> String -> Int -> SDoc -> a -> a

-- | The <a>trace</a> function outputs the trace message given as its first
--   argument, before returning the second argument as its result.
--   
--   For example, this returns the value of <tt>f x</tt> but first outputs
--   the message.
--   
--   <pre>
--   trace ("calling f with x = " ++ show x) (f x)
--   </pre>
--   
--   The <a>trace</a> function should <i>only</i> be used for debugging, or
--   for monitoring execution. The function is not referentially
--   transparent: its type indicates that it is a pure function but it has
--   the side effect of outputting the trace message.
trace :: String -> a -> a

-- | Panics and asserts.
pgmError :: String -> a

-- | Panics and asserts.
panic :: String -> a

-- | Panics and asserts.
sorry :: String -> a

-- | Panic while pretending to return an unboxed int. You can't use the
--   regular panic functions in expressions producing unboxed ints because
--   they have the wrong kind.
panicFastInt :: String -> FastInt

-- | Throw an failed assertion exception for a given filename and line
--   number.
assertPanic :: String -> Int -> a
pprDebugAndThen :: DynFlags -> (String -> a) -> String -> SDoc -> a
instance Outputable elt => Outputable (IntMap elt)
instance (Outputable key, Outputable elt) => Outputable (Map key elt)
instance Outputable FastString
instance (Outputable a, Outputable b, Outputable c, Outputable d, Outputable e, Outputable f, Outputable g) => Outputable (a, b, c, d, e, f, g)
instance (Outputable a, Outputable b, Outputable c, Outputable d, Outputable e, Outputable f) => Outputable (a, b, c, d, e, f)
instance (Outputable a, Outputable b, Outputable c, Outputable d, Outputable e) => Outputable (a, b, c, d, e)
instance (Outputable a, Outputable b, Outputable c, Outputable d) => Outputable (a, b, c, d)
instance (Outputable a, Outputable b, Outputable c) => Outputable (a, b, c)
instance (Outputable a, Outputable b) => Outputable (Either a b)
instance Outputable a => Outputable (Maybe a)
instance (Outputable a, Outputable b) => Outputable (a, b)
instance Outputable a => Outputable (Set a)
instance Outputable a => Outputable [a]
instance Outputable ()
instance Outputable Word
instance Outputable Word32
instance Outputable Word16
instance Outputable Int
instance Outputable Bool

module Fingerprint
data Fingerprint :: *
Fingerprint :: {-# UNPACK #-} !Word64 -> {-# UNPACK #-} !Word64 -> Fingerprint
fingerprint0 :: Fingerprint
readHexFingerprint :: String -> Fingerprint
fingerprintData :: Ptr Word8 -> Int -> IO Fingerprint
fingerprintString :: String -> Fingerprint
instance Outputable Fingerprint


-- | This module contains types that relate to the positions of things in
--   source files, and allow tagging of those things with locations
module SrcLoc

-- | Represents a single point within a file
data RealSrcLoc
data SrcLoc
RealSrcLoc :: {-# UNPACK #-} !RealSrcLoc -> SrcLoc
UnhelpfulLoc :: FastString -> SrcLoc
mkSrcLoc :: FastString -> Int -> Int -> SrcLoc
mkRealSrcLoc :: FastString -> Int -> Int -> RealSrcLoc

-- | Creates a <a>bad</a> <a>SrcLoc</a> that has no detailed information
--   about its location
mkGeneralSrcLoc :: FastString -> SrcLoc

-- | Built-in <a>bad</a> <a>SrcLoc</a> values for particular locations
noSrcLoc :: SrcLoc

-- | Built-in <a>bad</a> <a>SrcLoc</a> values for particular locations
generatedSrcLoc :: SrcLoc

-- | Built-in <a>bad</a> <a>SrcLoc</a> values for particular locations
interactiveSrcLoc :: SrcLoc

-- | Move the <a>SrcLoc</a> down by one line if the character is a newline,
--   to the next 8-char tabstop if it is a tab, and across by one character
--   in any other case
advanceSrcLoc :: RealSrcLoc -> Char -> RealSrcLoc

-- | Gives the filename of the <a>RealSrcLoc</a>
srcLocFile :: RealSrcLoc -> FastString

-- | Raises an error when used on a <a>bad</a> <a>SrcLoc</a>
srcLocLine :: RealSrcLoc -> Int

-- | Raises an error when used on a <a>bad</a> <a>SrcLoc</a>
srcLocCol :: RealSrcLoc -> Int

-- | A SrcSpan delimits a portion of a text file. It could be represented
--   by a pair of (line,column) coordinates, but in fact we optimise
--   slightly by using more compact representations for single-line and
--   zero-length spans, both of which are quite common.
--   
--   The end position is defined to be the column <i>after</i> the end of
--   the span. That is, a span of (1,1)-(1,2) is one character long, and a
--   span of (1,1)-(1,1) is zero characters long.
data RealSrcSpan
data SrcSpan
RealSrcSpan :: !RealSrcSpan -> SrcSpan
UnhelpfulSpan :: !FastString -> SrcSpan

-- | Create a <a>bad</a> <a>SrcSpan</a> that has not location information
mkGeneralSrcSpan :: FastString -> SrcSpan

-- | Create a <a>SrcSpan</a> between two points in a file
mkSrcSpan :: SrcLoc -> SrcLoc -> SrcSpan

-- | Create a <a>SrcSpan</a> between two points in a file
mkRealSrcSpan :: RealSrcLoc -> RealSrcLoc -> RealSrcSpan

-- | Built-in <a>bad</a> <a>SrcSpan</a>s for common sources of location
--   uncertainty
noSrcSpan :: SrcSpan

-- | Built-in <a>bad</a> <a>SrcSpan</a>s for common sources of location
--   uncertainty
wiredInSrcSpan :: SrcSpan

-- | Create a <a>SrcSpan</a> corresponding to a single point
srcLocSpan :: SrcLoc -> SrcSpan
realSrcLocSpan :: RealSrcLoc -> RealSrcSpan

-- | Combines two <a>SrcSpan</a> into one that spans at least all the
--   characters within both spans. Assumes the <a>file</a> part is the same
--   in both inputs
combineSrcSpans :: SrcSpan -> SrcSpan -> SrcSpan

-- | Returns the location at the start of the <a>SrcSpan</a> or a
--   <a>bad</a> <a>SrcSpan</a> if that is unavailable
srcSpanStart :: SrcSpan -> SrcLoc

-- | Returns the location at the end of the <a>SrcSpan</a> or a <a>bad</a>
--   <a>SrcSpan</a> if that is unavailable
srcSpanEnd :: SrcSpan -> SrcLoc
realSrcSpanStart :: RealSrcSpan -> RealSrcLoc
realSrcSpanEnd :: RealSrcSpan -> RealSrcLoc

-- | Obtains the filename for a <a>SrcSpan</a> if it is <a>good</a>
srcSpanFileName_maybe :: SrcSpan -> Maybe FastString
showUserSpan :: Bool -> SrcSpan -> String
srcSpanFile :: RealSrcSpan -> FastString
srcSpanStartLine :: RealSrcSpan -> Int
srcSpanEndLine :: RealSrcSpan -> Int
srcSpanStartCol :: RealSrcSpan -> Int
srcSpanEndCol :: RealSrcSpan -> Int

-- | Test if a <a>SrcSpan</a> is <a>good</a>, i.e. has precise location
--   information
isGoodSrcSpan :: SrcSpan -> Bool

-- | True if the span is known to straddle only one line. For <a>bad</a>
--   <a>SrcSpan</a>, it returns False
isOneLineSpan :: SrcSpan -> Bool
type Located e = GenLocated SrcSpan e
type RealLocated e = GenLocated RealSrcSpan e

-- | We attach SrcSpans to lots of things, so let's have a datatype for it.
data GenLocated l e
L :: l -> e -> GenLocated l e
noLoc :: e -> Located e
mkGeneralLocated :: String -> e -> Located e
getLoc :: GenLocated l e -> l
unLoc :: GenLocated l e -> e

-- | Tests whether the two located things are equal
eqLocated :: Eq a => Located a -> Located a -> Bool

-- | Tests the ordering of the two located things
cmpLocated :: Ord a => Located a -> Located a -> Ordering
combineLocs :: Located a -> Located b -> SrcSpan

-- | Combine locations from two <a>Located</a> things and add them to a
--   third thing
addCLoc :: Located a -> Located b -> c -> Located c

-- | Alternative strategies for ordering <a>SrcSpan</a>s
leftmost_smallest :: SrcSpan -> SrcSpan -> Ordering

-- | Alternative strategies for ordering <a>SrcSpan</a>s
leftmost_largest :: SrcSpan -> SrcSpan -> Ordering

-- | Alternative strategies for ordering <a>SrcSpan</a>s
rightmost :: SrcSpan -> SrcSpan -> Ordering

-- | Determines whether a span encloses a given line and column index
spans :: SrcSpan -> (Int, Int) -> Bool

-- | Determines whether a span is enclosed by another one
isSubspanOf :: SrcSpan -> SrcSpan -> Bool
sortLocated :: [Located a] -> [Located a]
instance Typeable RealSrcSpan
instance Typeable SrcSpan
instance Typeable2 GenLocated
instance Show RealSrcLoc
instance Eq RealSrcSpan
instance Show RealSrcSpan
instance Eq SrcSpan
instance Show SrcSpan
instance (Eq l, Eq e) => Eq (GenLocated l e)
instance (Ord l, Ord e) => Ord (GenLocated l e)
instance (Data l, Data e) => Data (GenLocated l e)
instance (Outputable l, Outputable e) => Outputable (GenLocated l e)
instance Functor (GenLocated l)
instance Outputable SrcSpan
instance Outputable RealSrcSpan
instance Ord SrcSpan
instance Data SrcSpan
instance Data RealSrcSpan
instance Outputable SrcLoc
instance Outputable RealSrcLoc
instance Ord RealSrcLoc
instance Ord SrcLoc
instance Eq RealSrcLoc
instance Eq SrcLoc

module BasicTypes
type Version = Int
bumpVersion :: Version -> Version
initialVersion :: Version

-- | The number of value arguments that can be applied to a value before it
--   does <a>real work</a>. So: fib 100 has arity 0 x -&gt; fib x has arity
--   1
type Arity = Int

-- | The number of represented arguments that can be applied to a value
--   before it does <a>real work</a>. So: fib 100 has representation arity
--   0 x -&gt; fib x has representation arity 1 () -&gt; fib (x + y) has
--   representation arity 2
type RepArity = Int
type Alignment = Int
data FunctionOrData
IsFunction :: FunctionOrData
IsData :: FunctionOrData
data WarningTxt
WarningTxt :: [FastString] -> WarningTxt
DeprecatedTxt :: [FastString] -> WarningTxt
data Fixity
Fixity :: Int -> FixityDirection -> Fixity
data FixityDirection
InfixL :: FixityDirection
InfixR :: FixityDirection
InfixN :: FixityDirection
defaultFixity :: Fixity
maxPrecedence :: Int
negateFixity :: Fixity
funTyFixity :: Fixity
compareFixity :: Fixity -> Fixity -> (Bool, Bool)
data RecFlag
Recursive :: RecFlag
NonRecursive :: RecFlag
isRec :: RecFlag -> Bool
isNonRec :: RecFlag -> Bool
boolToRecFlag :: Bool -> RecFlag
type RuleName = FastString
data TopLevelFlag
TopLevel :: TopLevelFlag
NotTopLevel :: TopLevelFlag
isTopLevel :: TopLevelFlag -> Bool
isNotTopLevel :: TopLevelFlag -> Bool
data OverlapFlag

-- | This instance must not overlap another
NoOverlap :: Bool -> OverlapFlag
isSafeOverlap :: OverlapFlag -> Bool

-- | Silently ignore this instance if you find a more specific one that
--   matches the constraint you are trying to resolve
--   
--   Example: constraint (Foo [Int]) instances (Foo [Int]) (Foo [a])
--   OverlapOk Since the second instance has the OverlapOk flag, the first
--   instance will be chosen (otherwise its ambiguous which to choose)
OverlapOk :: Bool -> OverlapFlag
isSafeOverlap :: OverlapFlag -> Bool

-- | Like OverlapOk, but also ignore this instance if it doesn't match the
--   constraint you are trying to resolve, but could match if the type
--   variables in the constraint were instantiated
--   
--   Example: constraint (Foo [b]) instances (Foo [Int]) Incoherent (Foo
--   [a]) Without the Incoherent flag, we'd complain that instantiating
--   <tt>b</tt> would change which instance was chosen
Incoherent :: Bool -> OverlapFlag
isSafeOverlap :: OverlapFlag -> Bool
data Boxity
Boxed :: Boxity
Unboxed :: Boxity
isBoxed :: Boxity -> Bool
data TupleSort
BoxedTuple :: TupleSort
UnboxedTuple :: TupleSort
ConstraintTuple :: TupleSort
tupleSortBoxity :: TupleSort -> Boxity
boxityNormalTupleSort :: Boxity -> TupleSort
tupleParens :: TupleSort -> SDoc -> SDoc

-- | Identifier occurrence information
data OccInfo

-- | There are many occurrences, or unknown occurences
NoOccInfo :: OccInfo

-- | Marks unused variables. Sometimes useful for lambda and case-bound
--   variables.
IAmDead :: OccInfo

-- | Occurs exactly once, not inside a rule
OneOcc :: !InsideLam -> !OneBranch -> !InterestingCxt -> OccInfo

-- | This identifier breaks a loop of mutually recursive functions. The
--   field marks whether it is only a loop breaker due to a reference in a
--   rule
IAmALoopBreaker :: !RulesOnly -> OccInfo
seqOccInfo :: OccInfo -> ()
zapFragileOcc :: OccInfo -> OccInfo
isOneOcc :: OccInfo -> Bool
isDeadOcc :: OccInfo -> Bool
isStrongLoopBreaker :: OccInfo -> Bool
isWeakLoopBreaker :: OccInfo -> Bool
isNoOcc :: OccInfo -> Bool
strongLoopBreaker :: OccInfo
weakLoopBreaker :: OccInfo
type InsideLam = Bool
insideLam :: InsideLam
notInsideLam :: InsideLam
type OneBranch = Bool
oneBranch :: OneBranch
notOneBranch :: OneBranch
type InterestingCxt = Bool
data EP a
EP :: a -> a -> EP a
fromEP :: EP a -> a
toEP :: EP a -> a
data HsBang
HsNoBang :: HsBang
HsStrict :: HsBang
HsUnpack :: HsBang
HsUnpackFailed :: HsBang
HsNoUnpack :: HsBang
isBanged :: HsBang -> Bool
isMarkedUnboxed :: HsBang -> Bool
data StrictnessMark
MarkedStrict :: StrictnessMark
NotMarkedStrict :: StrictnessMark
isMarkedStrict :: StrictnessMark -> Bool
data DefMethSpec
NoDM :: DefMethSpec
VanillaDM :: DefMethSpec
GenericDM :: DefMethSpec
data CompilerPhase
Phase :: PhaseNum -> CompilerPhase
InitialPhase :: CompilerPhase
type PhaseNum = Int
data Activation
NeverActive :: Activation
AlwaysActive :: Activation
ActiveBefore :: PhaseNum -> Activation
ActiveAfter :: PhaseNum -> Activation
isActive :: CompilerPhase -> Activation -> Bool
isActiveIn :: PhaseNum -> Activation -> Bool
isNeverActive :: Activation -> Bool
isAlwaysActive :: Activation -> Bool
isEarlyActive :: Activation -> Bool
data RuleMatchInfo
ConLike :: RuleMatchInfo
FunLike :: RuleMatchInfo
isConLike :: RuleMatchInfo -> Bool
isFunLike :: RuleMatchInfo -> Bool
data InlineSpec
Inline :: InlineSpec
Inlinable :: InlineSpec
NoInline :: InlineSpec
EmptyInlineSpec :: InlineSpec
isEmptyInlineSpec :: InlineSpec -> Bool
data InlinePragma
InlinePragma :: InlineSpec -> Maybe Arity -> Activation -> RuleMatchInfo -> InlinePragma
inl_inline :: InlinePragma -> InlineSpec
inl_sat :: InlinePragma -> Maybe Arity
inl_act :: InlinePragma -> Activation
inl_rule :: InlinePragma -> RuleMatchInfo
defaultInlinePragma :: InlinePragma
alwaysInlinePragma :: InlinePragma
neverInlinePragma :: InlinePragma
dfunInlinePragma :: InlinePragma
isDefaultInlinePragma :: InlinePragma -> Bool
isInlinePragma :: InlinePragma -> Bool
isInlinablePragma :: InlinePragma -> Bool
isAnyInlinePragma :: InlinePragma -> Bool
inlinePragmaSpec :: InlinePragma -> InlineSpec
inlinePragmaSat :: InlinePragma -> Maybe Arity
inlinePragmaActivation :: InlinePragma -> Activation
inlinePragmaRuleMatchInfo :: InlinePragma -> RuleMatchInfo
setInlinePragmaActivation :: InlinePragma -> Activation -> InlinePragma
setInlinePragmaRuleMatchInfo :: InlinePragma -> RuleMatchInfo -> InlinePragma
data SuccessFlag
Succeeded :: SuccessFlag
Failed :: SuccessFlag
succeeded :: SuccessFlag -> Bool
failed :: SuccessFlag -> Bool
successIf :: Bool -> SuccessFlag
data FractionalLit
FL :: String -> Rational -> FractionalLit
fl_text :: FractionalLit -> String
fl_value :: FractionalLit -> Rational
negateFractionalLit :: FractionalLit -> FractionalLit
integralFractionalLit :: Integer -> FractionalLit
instance Typeable FunctionOrData
instance Typeable WarningTxt
instance Typeable FixityDirection
instance Typeable Fixity
instance Typeable Boxity
instance Typeable RecFlag
instance Typeable OverlapFlag
instance Typeable TupleSort
instance Typeable HsBang
instance Typeable Activation
instance Typeable RuleMatchInfo
instance Typeable InlineSpec
instance Typeable InlinePragma
instance Typeable FractionalLit
instance Eq FunctionOrData
instance Ord FunctionOrData
instance Data FunctionOrData
instance Eq WarningTxt
instance Data WarningTxt
instance Eq FixityDirection
instance Data FixityDirection
instance Data Fixity
instance Eq Boxity
instance Data Boxity
instance Eq RecFlag
instance Data RecFlag
instance Eq OverlapFlag
instance Data OverlapFlag
instance Eq TupleSort
instance Data TupleSort
instance Eq HsBang
instance Data HsBang
instance Eq Activation
instance Data Activation
instance Eq RuleMatchInfo
instance Data RuleMatchInfo
instance Show RuleMatchInfo
instance Eq InlineSpec
instance Data InlineSpec
instance Show InlineSpec
instance Eq InlinePragma
instance Data InlinePragma
instance Data FractionalLit
instance Show FractionalLit
instance Outputable FractionalLit
instance Ord FractionalLit
instance Eq FractionalLit
instance Outputable InlinePragma
instance Outputable InlineSpec
instance Outputable RuleMatchInfo
instance Outputable Activation
instance Outputable CompilerPhase
instance Outputable SuccessFlag
instance Outputable DefMethSpec
instance Outputable StrictnessMark
instance Outputable HsBang
instance Outputable OccInfo
instance Outputable OverlapFlag
instance Outputable RecFlag
instance Outputable TopLevelFlag
instance Outputable FixityDirection
instance Eq Fixity
instance Outputable Fixity
instance Outputable WarningTxt
instance Outputable FunctionOrData

module Unique

-- | The type of unique identifiers that are used in many places in GHC for
--   fast ordering and equality tests. You should generate these with the
--   functions from the <tt>UniqSupply</tt> module
data Unique

-- | Class of things that we can obtain a <a>Unique</a> from
class Uniquable a
getUnique :: Uniquable a => a -> Unique
hasKey :: Uniquable a => a -> Unique -> Bool
pprUnique :: Unique -> SDoc
mkUniqueGrimily :: Int -> Unique
getKey :: Unique -> Int
getKeyFastInt :: Unique -> FastInt
mkUnique :: Char -> Int -> Unique
unpkUnique :: Unique -> (Char, Int)
incrUnique :: Unique -> Unique
deriveUnique :: Unique -> Int -> Unique
newTagUnique :: Unique -> Char -> Unique
initTyVarUnique :: Unique
mkAlphaTyVarUnique :: Int -> Unique
mkPrimOpIdUnique :: Int -> Unique
mkTupleTyConUnique :: TupleSort -> Int -> Unique
mkTupleDataConUnique :: TupleSort -> Int -> Unique
mkPreludeMiscIdUnique :: Int -> Unique
mkPreludeDataConUnique :: Int -> Unique
mkPreludeTyConUnique :: Int -> Unique
mkPreludeClassUnique :: Int -> Unique
mkPArrDataConUnique :: Int -> Unique
mkVarOccUnique :: FastString -> Unique
mkDataOccUnique :: FastString -> Unique
mkTvOccUnique :: FastString -> Unique
mkTcOccUnique :: FastString -> Unique
mkRegSingleUnique :: Int -> Unique
mkRegPairUnique :: Int -> Unique
mkRegClassUnique :: Int -> Unique
mkRegSubUnique :: Int -> Unique
mkCostCentreUnique :: Int -> Unique
mkBuiltinUnique :: Int -> Unique
mkPseudoUniqueD :: Int -> Unique
mkPseudoUniqueE :: Int -> Unique
mkPseudoUniqueH :: Int -> Unique
instance Show Unique
instance Outputable Unique
instance Uniquable Unique
instance Ord Unique
instance Eq Unique
instance Uniquable Int
instance Uniquable FastString

module UniqSupply

-- | A value of type <a>UniqSupply</a> is unique, and it can supply
--   <i>one</i> distinct <a>Unique</a>. Also, from the supply, one can also
--   manufacture an arbitrary number of further <tt>UniqueSupply</tt>
--   values, which will be distinct from the first and from all others.
data UniqSupply

-- | Obtain the <a>Unique</a> from this particular <a>UniqSupply</a>
uniqFromSupply :: UniqSupply -> Unique

-- | Obtain an infinite list of <a>Unique</a> that can be generated by
--   constant splitting of the supply
uniqsFromSupply :: UniqSupply -> [Unique]

-- | Obtain the <a>Unique</a> from this particular <a>UniqSupply</a>, and a
--   new supply
takeUniqFromSupply :: UniqSupply -> (Unique, UniqSupply)

-- | Create a unique supply out of thin air. The character given must be
--   distinct from those of all calls to this function in the compiler for
--   the values generated to be truly unique.
mkSplitUniqSupply :: Char -> IO UniqSupply

-- | Build two <a>UniqSupply</a> from a single one, each of which can
--   supply its own <a>Unique</a>.
splitUniqSupply :: UniqSupply -> (UniqSupply, UniqSupply)

-- | Create an infinite list of <a>UniqSupply</a> from a single one
listSplitUniqSupply :: UniqSupply -> [UniqSupply]

-- | A monad which just gives the ability to obtain <a>Unique</a>s
data UniqSM result

-- | A monad for generating unique identifiers
class Monad m => MonadUnique m where getUniqueM = liftM uniqFromSupply getUniqueSupplyM getUniquesM = liftM uniqsFromSupply getUniqueSupplyM
getUniqueSupplyM :: MonadUnique m => m UniqSupply
getUniqueM :: MonadUnique m => m Unique
getUniquesM :: MonadUnique m => m [Unique]

-- | Run the <a>UniqSM</a> action, returning the final <a>UniqSupply</a>
initUs :: UniqSupply -> UniqSM a -> (a, UniqSupply)

-- | Run the <a>UniqSM</a> action, discarding the final <a>UniqSupply</a>
initUs_ :: UniqSupply -> UniqSM a -> a
lazyThenUs :: UniqSM a -> (a -> UniqSM b) -> UniqSM b
lazyMapUs :: (a -> UniqSM b) -> [a] -> UniqSM [b]
getUniqueUs :: UniqSM Unique
getUs :: UniqSM UniqSupply
instance MonadUnique UniqSM
instance MonadFix UniqSM
instance Applicative UniqSM
instance Functor UniqSM
instance Monad UniqSM

module Hoopl.Dataflow

-- | A transfer function might want to use the logging flag to control
--   debugging, as in for example, it updates just one element in a big
--   finite map. We don't want Hoopl to show the whole fact, and only the
--   transfer function knows exactly what changed.
data DataflowLattice a :: * -> *
DataflowLattice :: String -> a -> JoinFun a -> DataflowLattice a
fact_name :: DataflowLattice a -> String
fact_bot :: DataflowLattice a -> a
fact_join :: DataflowLattice a -> JoinFun a
newtype OldFact a :: * -> *
OldFact :: a -> OldFact a
newtype NewFact a :: * -> *
NewFact :: a -> NewFact a

-- | <a>mkFactBase</a> creates a <a>FactBase</a> from a list of
--   (<a>Label</a>, fact) pairs. If the same label appears more than once,
--   the relevant facts are joined.
mkFactBase :: DataflowLattice f -> [(Label, f)] -> FactBase f
data ChangeFlag :: *
NoChange :: ChangeFlag
SomeChange :: ChangeFlag
data FwdPass (m :: * -> *) (n :: * -> * -> *) f :: (* -> *) -> (* -> * -> *) -> * -> *
FwdPass :: DataflowLattice f -> FwdTransfer n f -> FwdRewrite m n f -> FwdPass f
fp_lattice :: FwdPass f -> DataflowLattice f
fp_transfer :: FwdPass f -> FwdTransfer n f
fp_rewrite :: FwdPass f -> FwdRewrite m n f
data FwdTransfer (n :: * -> * -> *) f :: (* -> * -> *) -> * -> *
mkFTransfer :: (forall e x. n e x -> f -> Fact x f) -> FwdTransfer n f
mkFTransfer3 :: (n C O -> f -> f) -> (n O O -> f -> f) -> (n O C -> f -> FactBase f) -> FwdTransfer n f
getFTransfer3 :: FwdTransfer n f -> (n C O -> f -> f, n O O -> f -> f, n O C -> f -> FactBase f)
data FwdRewrite (m :: * -> *) (n :: * -> * -> *) f :: (* -> *) -> (* -> * -> *) -> * -> *

-- | Functions passed to <a>mkFRewrite</a> should not be aware of the fuel
--   supply. The result returned by <a>mkFRewrite</a> respects fuel.
mkFRewrite :: FuelMonad m => (forall e x. n e x -> f -> m (Maybe (Graph n e x))) -> FwdRewrite m n f

-- | Functions passed to <a>mkFRewrite3</a> should not be aware of the fuel
--   supply. The result returned by <a>mkFRewrite3</a> respects fuel.
mkFRewrite3 :: (n C O -> f -> UniqSM (Maybe (Graph n C O))) -> (n O O -> f -> UniqSM (Maybe (Graph n O O))) -> (n O C -> f -> UniqSM (Maybe (Graph n O C))) -> FwdRewrite UniqSM n f
getFRewrite3 :: FwdRewrite m n f -> (n C O -> f -> m (Maybe (Graph n C O, FwdRewrite m n f)), n O O -> f -> m (Maybe (Graph n O O, FwdRewrite m n f)), n O C -> f -> m (Maybe (Graph n O C, FwdRewrite m n f)))
noFwdRewrite :: FwdRewrite UniqSM n f
wrapFR :: (forall e x. (n e x -> f -> m (Maybe (Graph n e x, FwdRewrite m n f))) -> n' e x -> f' -> m' (Maybe (Graph n' e x, FwdRewrite m' n' f'))) -> FwdRewrite m n f -> FwdRewrite m' n' f'
wrapFR2 :: (forall e x. (n1 e x -> f1 -> m1 (Maybe (Graph n1 e x, FwdRewrite m1 n1 f1))) -> (n2 e x -> f2 -> m2 (Maybe (Graph n2 e x, FwdRewrite m2 n2 f2))) -> n3 e x -> f3 -> m3 (Maybe (Graph n3 e x, FwdRewrite m3 n3 f3))) -> FwdRewrite m1 n1 f1 -> FwdRewrite m2 n2 f2 -> FwdRewrite m3 n3 f3
data BwdPass (m :: * -> *) (n :: * -> * -> *) f :: (* -> *) -> (* -> * -> *) -> * -> *
BwdPass :: DataflowLattice f -> BwdTransfer n f -> BwdRewrite m n f -> BwdPass f
bp_lattice :: BwdPass f -> DataflowLattice f
bp_transfer :: BwdPass f -> BwdTransfer n f
bp_rewrite :: BwdPass f -> BwdRewrite m n f
data BwdTransfer (n :: * -> * -> *) f :: (* -> * -> *) -> * -> *
mkBTransfer :: (forall e x. n e x -> Fact x f -> f) -> BwdTransfer n f
mkBTransfer3 :: (n C O -> f -> f) -> (n O O -> f -> f) -> (n O C -> FactBase f -> f) -> BwdTransfer n f
getBTransfer3 :: BwdTransfer n f -> (n C O -> f -> f, n O O -> f -> f, n O C -> FactBase f -> f)
wrapBR :: (forall e x. Shape x -> (n e x -> Fact x f -> m (Maybe (Graph n e x, BwdRewrite m n f))) -> n' e x -> Fact x f' -> m' (Maybe (Graph n' e x, BwdRewrite m' n' f'))) -> BwdRewrite m n f -> BwdRewrite m' n' f'
wrapBR2 :: (forall e x. Shape x -> (n1 e x -> Fact x f1 -> m1 (Maybe (Graph n1 e x, BwdRewrite m1 n1 f1))) -> (n2 e x -> Fact x f2 -> m2 (Maybe (Graph n2 e x, BwdRewrite m2 n2 f2))) -> n3 e x -> Fact x f3 -> m3 (Maybe (Graph n3 e x, BwdRewrite m3 n3 f3))) -> BwdRewrite m1 n1 f1 -> BwdRewrite m2 n2 f2 -> BwdRewrite m3 n3 f3
data BwdRewrite (m :: * -> *) (n :: * -> * -> *) f :: (* -> *) -> (* -> * -> *) -> * -> *

-- | Functions passed to <a>mkBRewrite</a> should not be aware of the fuel
--   supply. The result returned by <a>mkBRewrite</a> respects fuel.
mkBRewrite :: FuelMonad m => (forall e x. n e x -> Fact x f -> m (Maybe (Graph n e x))) -> BwdRewrite m n f
mkBRewrite3 :: (n C O -> f -> UniqSM (Maybe (Graph n C O))) -> (n O O -> f -> UniqSM (Maybe (Graph n O O))) -> (n O C -> FactBase f -> UniqSM (Maybe (Graph n O C))) -> BwdRewrite UniqSM n f
getBRewrite3 :: BwdRewrite m n f -> (n C O -> f -> m (Maybe (Graph n C O, BwdRewrite m n f)), n O O -> f -> m (Maybe (Graph n O O, BwdRewrite m n f)), n O C -> FactBase f -> m (Maybe (Graph n O C, BwdRewrite m n f)))
noBwdRewrite :: BwdRewrite UniqSM n f

-- | if the graph being analyzed is open at the entry, there must be no
--   other entry point, or all goes horribly wrong...
analyzeAndRewriteFwd :: NonLocal n => FwdPass UniqSM n f -> MaybeC e [Label] -> Graph n e x -> Fact e f -> UniqSM (Graph n e x, FactBase f, MaybeO x f)

-- | if the graph being analyzed is open at the exit, I don't quite
--   understand the implications of possible other exits
analyzeAndRewriteBwd :: NonLocal n => BwdPass UniqSM n f -> MaybeC e [Label] -> Graph n e x -> Fact x f -> UniqSM (Graph n e x, FactBase f, MaybeO e f)

-- | if the graph being analyzed is open at the entry, there must be no
--   other entry point, or all goes horribly wrong...
analyzeFwd :: NonLocal n => FwdPass UniqSM n f -> MaybeC e [Label] -> Graph n e C -> Fact e f -> FactBase f

-- | if the graph being analyzed is open at the entry, there must be no
--   other entry point, or all goes horribly wrong...
analyzeFwdBlocks :: NonLocal n => FwdPass UniqSM n f -> MaybeC e [Label] -> Graph n e C -> Fact e f -> FactBase f

-- | if the graph being analyzed is open at the entry, there must be no
--   other entry point, or all goes horribly wrong...
analyzeBwd :: NonLocal n => BwdPass UniqSM n f -> MaybeC e [Label] -> Graph n e C -> Fact C f -> FactBase f
instance ShapeLifter O C
instance ShapeLifter O O
instance ShapeLifter C O
instance NonLocal n => NonLocal (DBlock f n)

module Hoopl
deepFwdRw :: (forall e x. n e x -> f -> UniqSM (Maybe (Graph n e x))) -> FwdRewrite UniqSM n f
deepFwdRw3 :: (n C O -> f -> UniqSM (Maybe (Graph n C O))) -> (n O O -> f -> UniqSM (Maybe (Graph n O O))) -> (n O C -> f -> UniqSM (Maybe (Graph n O C))) -> (FwdRewrite UniqSM n f)
deepBwdRw :: (forall e x. n e x -> Fact x f -> UniqSM (Maybe (Graph n e x))) -> BwdRewrite UniqSM n f
deepBwdRw3 :: (n C O -> f -> UniqSM (Maybe (Graph n C O))) -> (n O O -> f -> UniqSM (Maybe (Graph n O O))) -> (n O C -> FactBase f -> UniqSM (Maybe (Graph n O C))) -> (BwdRewrite UniqSM n f)
thenFwdRw :: FwdRewrite UniqSM n f -> FwdRewrite UniqSM n f -> FwdRewrite UniqSM n f


-- | The LLVM Type System.
module Llvm.Types

-- | A global mutable variable. Maybe defined or external
type LMGlobal = (LlvmVar, Maybe LlvmStatic)

-- | A String in LLVM
type LMString = FastString

-- | A type alias
type LlvmAlias = (LMString, LlvmType)

-- | Llvm Types
data LlvmType

-- | An integer with a given width in bits.
LMInt :: Int -> LlvmType

-- | 32 bit floating point
LMFloat :: LlvmType

-- | 64 bit floating point
LMDouble :: LlvmType

-- | 80 bit (x86 only) floating point
LMFloat80 :: LlvmType

-- | 128 bit floating point
LMFloat128 :: LlvmType

-- | A pointer to a <a>LlvmType</a>
LMPointer :: LlvmType -> LlvmType

-- | An array of <a>LlvmType</a>
LMArray :: Int -> LlvmType -> LlvmType

-- | A <a>LlvmVar</a> can represent a label (address)
LMLabel :: LlvmType

-- | Void type
LMVoid :: LlvmType

-- | Structure type
LMStruct :: [LlvmType] -> LlvmType

-- | A type alias
LMAlias :: LlvmAlias -> LlvmType

-- | Function type, used to create pointers to functions
LMFunction :: LlvmFunctionDecl -> LlvmType

-- | LLVM metadata values. Used for representing debug and optimization
--   information.
data LlvmMetaVal

-- | Metadata string
MetaStr :: LMString -> LlvmMetaVal

-- | Metadata node
MetaNode :: LlvmMetaUnamed -> LlvmMetaVal

-- | Normal value type as metadata
MetaVar :: LlvmVar -> LlvmMetaVal

-- | LLVM metadata nodes.
data LlvmMeta

-- | Unamed metadata
MetaUnamed :: LlvmMetaUnamed -> [LlvmMetaVal] -> LlvmMeta

-- | Named metadata
MetaNamed :: LMString -> [LlvmMetaUnamed] -> LlvmMeta

-- | Unamed metadata variable.
newtype LlvmMetaUnamed
LMMetaUnamed :: Int -> LlvmMetaUnamed

-- | An LLVM section definition. If Nothing then let LLVM decide the
--   section
type LMSection = Maybe LMString
type LMAlign = Maybe Int
type LMConst = Bool

-- | LLVM Variables
data LlvmVar

-- | Variables with a global scope.
LMGlobalVar :: LMString -> LlvmType -> LlvmLinkageType -> LMSection -> LMAlign -> LMConst -> LlvmVar

-- | Variables local to a function or parameters.
LMLocalVar :: Unique -> LlvmType -> LlvmVar

-- | Named local variables. Sometimes we need to be able to explicitly name
--   variables (e.g for function arguments).
LMNLocalVar :: LMString -> LlvmType -> LlvmVar

-- | A constant variable
LMLitVar :: LlvmLit -> LlvmVar

-- | Llvm Literal Data.
--   
--   These can be used inline in expressions.
data LlvmLit

-- | Refers to an integer constant (i64 42).
LMIntLit :: Integer -> LlvmType -> LlvmLit

-- | Floating point literal
LMFloatLit :: Double -> LlvmType -> LlvmLit

-- | Literal NULL, only applicable to pointer types
LMNullLit :: LlvmType -> LlvmLit

-- | Undefined value, random bit pattern. Useful for optimisations.
LMUndefLit :: LlvmType -> LlvmLit

-- | Llvm Static Data.
--   
--   These represent the possible global level variables and constants.
data LlvmStatic

-- | A comment in a static section
LMComment :: LMString -> LlvmStatic

-- | A static variant of a literal value
LMStaticLit :: LlvmLit -> LlvmStatic

-- | For uninitialised data
LMUninitType :: LlvmType -> LlvmStatic

-- | Defines a static <a>LMString</a>
LMStaticStr :: LMString -> LlvmType -> LlvmStatic

-- | A static array
LMStaticArray :: [LlvmStatic] -> LlvmType -> LlvmStatic

-- | A static structure type
LMStaticStruc :: [LlvmStatic] -> LlvmType -> LlvmStatic

-- | A pointer to other data
LMStaticPointer :: LlvmVar -> LlvmStatic

-- | Pointer to Pointer conversion
LMBitc :: LlvmStatic -> LlvmType -> LlvmStatic

-- | Pointer to Integer conversion
LMPtoI :: LlvmStatic -> LlvmType -> LlvmStatic

-- | Constant addition operation
LMAdd :: LlvmStatic -> LlvmStatic -> LlvmStatic

-- | Constant subtraction operation
LMSub :: LlvmStatic -> LlvmStatic -> LlvmStatic

-- | Concatenate an array together, separated by commas
commaCat :: Show a => [a] -> String

-- | Return the variable name or value of the <a>LlvmVar</a> in Llvm IR
--   textual representation (e.g. <tt>@x</tt>, <tt>%y</tt> or <tt>42</tt>).
getName :: LlvmVar -> String

-- | Return the variable name or value of the <a>LlvmVar</a> in a plain
--   textual representation (e.g. <tt>x</tt>, <tt>y</tt> or <tt>42</tt>).
getPlainName :: LlvmVar -> String

-- | Print a literal value. No type.
getLit :: LlvmLit -> String

-- | Return the <a>LlvmType</a> of the <a>LlvmVar</a>
getVarType :: LlvmVar -> LlvmType

-- | Return the <a>LlvmType</a> of a <a>LlvmLit</a>
getLitType :: LlvmLit -> LlvmType

-- | Return the <a>LlvmType</a> of the <a>LlvmStatic</a>
getStatType :: LlvmStatic -> LlvmType

-- | Return the <a>LlvmType</a> of the <a>LMGlobal</a>
getGlobalType :: LMGlobal -> LlvmType

-- | Return the <a>LlvmVar</a> part of a <a>LMGlobal</a>
getGlobalVar :: LMGlobal -> LlvmVar

-- | Return the <a>LlvmLinkageType</a> for a <a>LlvmVar</a>
getLink :: LlvmVar -> LlvmLinkageType

-- | Add a pointer indirection to the supplied type. <a>LMLabel</a> and
--   <a>LMVoid</a> cannot be lifted.
pLift :: LlvmType -> LlvmType

-- | Lower a variable of <a>LMPointer</a> type.
pVarLift :: LlvmVar -> LlvmVar

-- | Remove the pointer indirection of the supplied type. Only
--   <a>LMPointer</a> constructors can be lowered.
pLower :: LlvmType -> LlvmType

-- | Lower a variable of <a>LMPointer</a> type.
pVarLower :: LlvmVar -> LlvmVar

-- | Test if the given <a>LlvmType</a> is an integer
isInt :: LlvmType -> Bool

-- | Test if the given <a>LlvmType</a> is a floating point type
isFloat :: LlvmType -> Bool

-- | Test if the given <a>LlvmType</a> is an <a>LMPointer</a> construct
isPointer :: LlvmType -> Bool

-- | Test if a <a>LlvmVar</a> is global.
isGlobal :: LlvmVar -> Bool

-- | Width in bits of an <a>LlvmType</a>, returns 0 if not applicable
llvmWidthInBits :: LlvmType -> Int
i128 :: LlvmType
i8Ptr :: LlvmType
i1 :: LlvmType
i8 :: LlvmType
i16 :: LlvmType
i32 :: LlvmType
i64 :: LlvmType

-- | The target architectures word size
llvmWord :: LlvmType

-- | The target architectures word size
llvmWordPtr :: LlvmType

-- | An LLVM Function
data LlvmFunctionDecl
LlvmFunctionDecl :: LMString -> LlvmLinkageType -> LlvmCallConvention -> LlvmType -> LlvmParameterListType -> [LlvmParameter] -> LMAlign -> LlvmFunctionDecl

-- | Unique identifier of the function
decName :: LlvmFunctionDecl -> LMString

-- | LinkageType of the function
funcLinkage :: LlvmFunctionDecl -> LlvmLinkageType

-- | The calling convention of the function
funcCc :: LlvmFunctionDecl -> LlvmCallConvention

-- | Type of the returned value
decReturnType :: LlvmFunctionDecl -> LlvmType

-- | Indicates if this function uses varargs
decVarargs :: LlvmFunctionDecl -> LlvmParameterListType

-- | Parameter types and attributes
decParams :: LlvmFunctionDecl -> [LlvmParameter]

-- | Function align value, must be power of 2
funcAlign :: LlvmFunctionDecl -> LMAlign
type LlvmFunctionDecls = [LlvmFunctionDecl]
type LlvmParameter = (LlvmType, [LlvmParamAttr])

-- | LLVM Parameter Attributes.
--   
--   Parameter attributes are used to communicate additional information
--   about the result or parameters of a function
data LlvmParamAttr

-- | This indicates to the code generator that the parameter or return
--   value should be zero-extended to a 32-bit value by the caller (for a
--   parameter) or the callee (for a return value).
ZeroExt :: LlvmParamAttr

-- | This indicates to the code generator that the parameter or return
--   value should be sign-extended to a 32-bit value by the caller (for a
--   parameter) or the callee (for a return value).
SignExt :: LlvmParamAttr

-- | This indicates that this parameter or return value should be treated
--   in a special target-dependent fashion during while emitting code for a
--   function call or return (usually, by putting it in a register as
--   opposed to memory).
InReg :: LlvmParamAttr

-- | This indicates that the pointer parameter should really be passed by
--   value to the function.
ByVal :: LlvmParamAttr

-- | This indicates that the pointer parameter specifies the address of a
--   structure that is the return value of the function in the source
--   program.
SRet :: LlvmParamAttr

-- | This indicates that the pointer does not alias any global or any other
--   parameter.
NoAlias :: LlvmParamAttr

-- | This indicates that the callee does not make any copies of the pointer
--   that outlive the callee itself
NoCapture :: LlvmParamAttr

-- | This indicates that the pointer parameter can be excised using the
--   trampoline intrinsics.
Nest :: LlvmParamAttr

-- | Llvm Function Attributes.
--   
--   Function attributes are set to communicate additional information
--   about a function. Function attributes are considered to be part of the
--   function, not of the function type, so functions with different
--   parameter attributes can have the same function type. Functions can
--   have multiple attributes.
--   
--   Descriptions taken from
--   <a>http://llvm.org/docs/LangRef.html#fnattrs</a>
data LlvmFuncAttr

-- | This attribute indicates that the inliner should attempt to inline
--   this function into callers whenever possible, ignoring any active
--   inlining size threshold for this caller.
AlwaysInline :: LlvmFuncAttr

-- | This attribute indicates that the source code contained a hint that
--   inlining this function is desirable (such as the "inline" keyword in
--   C/C++). It is just a hint; it imposes no requirements on the inliner.
InlineHint :: LlvmFuncAttr

-- | This attribute indicates that the inliner should never inline this
--   function in any situation. This attribute may not be used together
--   with the alwaysinline attribute.
NoInline :: LlvmFuncAttr

-- | This attribute suggests that optimization passes and code generator
--   passes make choices that keep the code size of this function low, and
--   otherwise do optimizations specifically to reduce code size.
OptSize :: LlvmFuncAttr

-- | This function attribute indicates that the function never returns
--   normally. This produces undefined behavior at runtime if the function
--   ever does dynamically return.
NoReturn :: LlvmFuncAttr

-- | This function attribute indicates that the function never returns with
--   an unwind or exceptional control flow. If the function does unwind,
--   its runtime behavior is undefined.
NoUnwind :: LlvmFuncAttr

-- | This attribute indicates that the function computes its result (or
--   decides to unwind an exception) based strictly on its arguments,
--   without dereferencing any pointer arguments or otherwise accessing any
--   mutable state (e.g. memory, control registers, etc) visible to caller
--   functions. It does not write through any pointer arguments (including
--   byval arguments) and never changes any state visible to callers. This
--   means that it cannot unwind exceptions by calling the C++ exception
--   throwing methods, but could use the unwind instruction.
ReadNone :: LlvmFuncAttr

-- | This attribute indicates that the function does not write through any
--   pointer arguments (including byval arguments) or otherwise modify any
--   state (e.g. memory, control registers, etc) visible to caller
--   functions. It may dereference pointer arguments and read state that
--   may be set in the caller. A readonly function always returns the same
--   value (or unwinds an exception identically) when called with the same
--   set of arguments and global state. It cannot unwind an exception by
--   calling the C++ exception throwing methods, but may use the unwind
--   instruction.
ReadOnly :: LlvmFuncAttr

-- | This attribute indicates that the function should emit a stack
--   smashing protector. It is in the form of a "canary"—a random value
--   placed on the stack before the local variables that's checked upon
--   return from the function to see if it has been overwritten. A
--   heuristic is used to determine if a function needs stack protectors or
--   not.
--   
--   If a function that has an ssp attribute is inlined into a function
--   that doesn't have an ssp attribute, then the resulting function will
--   have an ssp attribute.
Ssp :: LlvmFuncAttr

-- | This attribute indicates that the function should always emit a stack
--   smashing protector. This overrides the ssp function attribute.
--   
--   If a function that has an sspreq attribute is inlined into a function
--   that doesn't have an sspreq attribute or which has an ssp attribute,
--   then the resulting function will have an sspreq attribute.
SspReq :: LlvmFuncAttr

-- | This attribute indicates that the code generator should not use a red
--   zone, even if the target-specific ABI normally permits it.
NoRedZone :: LlvmFuncAttr

-- | This attributes disables implicit floating point instructions.
NoImplicitFloat :: LlvmFuncAttr

-- | This attribute disables prologue / epilogue emission for the function.
--   This can have very system-specific consequences.
Naked :: LlvmFuncAttr

-- | Different types to call a function.
data LlvmCallType

-- | Normal call, allocate a new stack frame.
StdCall :: LlvmCallType

-- | Tail call, perform the call in the current stack frame.
TailCall :: LlvmCallType

-- | Different calling conventions a function can use.
data LlvmCallConvention

-- | The C calling convention. This calling convention (the default if no
--   other calling convention is specified) matches the target C calling
--   conventions. This calling convention supports varargs function calls
--   and tolerates some mismatch in the declared prototype and implemented
--   declaration of the function (as does normal C).
CC_Ccc :: LlvmCallConvention

-- | This calling convention attempts to make calls as fast as possible
--   (e.g. by passing things in registers). This calling convention allows
--   the target to use whatever tricks it wants to produce fast code for
--   the target, without having to conform to an externally specified ABI
--   (Application Binary Interface). Implementations of this convention
--   should allow arbitrary tail call optimization to be supported. This
--   calling convention does not support varargs and requires the prototype
--   of al callees to exactly match the prototype of the function
--   definition.
CC_Fastcc :: LlvmCallConvention

-- | This calling convention attempts to make code in the caller as
--   efficient as possible under the assumption that the call is not
--   commonly executed. As such, these calls often preserve all registers
--   so that the call does not break any live ranges in the caller side.
--   This calling convention does not support varargs and requires the
--   prototype of all callees to exactly match the prototype of the
--   function definition.
CC_Coldcc :: LlvmCallConvention

-- | Any calling convention may be specified by number, allowing
--   target-specific calling conventions to be used. Target specific
--   calling conventions start at 64.
CC_Ncc :: Int -> LlvmCallConvention

-- | X86 Specific <a>StdCall</a> convention. LLVM includes a specific alias
--   for it rather than just using CC_Ncc.
CC_X86_Stdcc :: LlvmCallConvention

-- | Functions can have a fixed amount of parameters, or a variable amount.
data LlvmParameterListType
FixedArgs :: LlvmParameterListType
VarArgs :: LlvmParameterListType

-- | Linkage type of a symbol.
--   
--   The description of the constructors is copied from the Llvm Assembly
--   Language Reference Manual
--   <a>http://www.llvm.org/docs/LangRef.html#linkage</a>, because they
--   correspond to the Llvm linkage types.
data LlvmLinkageType

-- | Global values with internal linkage are only directly accessible by
--   objects in the current module. In particular, linking code into a
--   module with an internal global value may cause the internal to be
--   renamed as necessary to avoid collisions. Because the symbol is
--   internal to the module, all references can be updated. This
--   corresponds to the notion of the <tt>static</tt> keyword in C.
Internal :: LlvmLinkageType

-- | Globals with <tt>linkonce</tt> linkage are merged with other globals
--   of the same name when linkage occurs. This is typically used to
--   implement inline functions, templates, or other code which must be
--   generated in each translation unit that uses it. Unreferenced linkonce
--   globals are allowed to be discarded.
LinkOnce :: LlvmLinkageType

-- | <tt>weak</tt> linkage is exactly the same as linkonce linkage, except
--   that unreferenced weak globals may not be discarded. This is used for
--   globals that may be emitted in multiple translation units, but that
--   are not guaranteed to be emitted into every translation unit that uses
--   them. One example of this are common globals in C, such as <tt>int
--   X;</tt> at global scope.
Weak :: LlvmLinkageType

-- | <tt>appending</tt> linkage may only be applied to global variables of
--   pointer to array type. When two global variables with appending
--   linkage are linked together, the two global arrays are appended
--   together. This is the Llvm, typesafe, equivalent of having the system
--   linker append together <tt>sections</tt> with identical names when .o
--   files are linked.
Appending :: LlvmLinkageType

-- | The semantics of this linkage follow the ELF model: the symbol is weak
--   until linked, if not linked, the symbol becomes null instead of being
--   an undefined reference.
ExternWeak :: LlvmLinkageType

-- | The symbol participates in linkage and can be used to resolve external
--   symbol references.
ExternallyVisible :: LlvmLinkageType

-- | Alias for <a>ExternallyVisible</a> but with explicit textual form in
--   LLVM assembly.
External :: LlvmLinkageType

-- | Llvm binary operators machine operations.
data LlvmMachOp

-- | add two integer, floating point or vector values.
LM_MO_Add :: LlvmMachOp

-- | subtract two ...
LM_MO_Sub :: LlvmMachOp

-- | multiply ..
LM_MO_Mul :: LlvmMachOp

-- | unsigned integer or vector division.
LM_MO_UDiv :: LlvmMachOp

-- | signed integer ..
LM_MO_SDiv :: LlvmMachOp

-- | unsigned integer or vector remainder (mod)
LM_MO_URem :: LlvmMachOp

-- | signed ...
LM_MO_SRem :: LlvmMachOp

-- | add two floating point or vector values.
LM_MO_FAdd :: LlvmMachOp

-- | subtract two ...
LM_MO_FSub :: LlvmMachOp

-- | multiply ...
LM_MO_FMul :: LlvmMachOp

-- | divide ...
LM_MO_FDiv :: LlvmMachOp

-- | remainder ...
LM_MO_FRem :: LlvmMachOp

-- | Left shift
LM_MO_Shl :: LlvmMachOp

-- | Logical shift right Shift right, filling with zero
LM_MO_LShr :: LlvmMachOp

-- | Arithmetic shift right The most significant bits of the result will be
--   equal to the sign bit of the left operand.
LM_MO_AShr :: LlvmMachOp

-- | AND bitwise logical operation.
LM_MO_And :: LlvmMachOp

-- | OR bitwise logical operation.
LM_MO_Or :: LlvmMachOp

-- | XOR bitwise logical operation.
LM_MO_Xor :: LlvmMachOp

-- | Llvm compare operations.
data LlvmCmpOp

-- | Equal (Signed and Unsigned)
LM_CMP_Eq :: LlvmCmpOp

-- | Not equal (Signed and Unsigned)
LM_CMP_Ne :: LlvmCmpOp

-- | Unsigned greater than
LM_CMP_Ugt :: LlvmCmpOp

-- | Unsigned greater than or equal
LM_CMP_Uge :: LlvmCmpOp

-- | Unsigned less than
LM_CMP_Ult :: LlvmCmpOp

-- | Unsigned less than or equal
LM_CMP_Ule :: LlvmCmpOp

-- | Signed greater than
LM_CMP_Sgt :: LlvmCmpOp

-- | Signed greater than or equal
LM_CMP_Sge :: LlvmCmpOp

-- | Signed less than
LM_CMP_Slt :: LlvmCmpOp

-- | Signed less than or equal
LM_CMP_Sle :: LlvmCmpOp

-- | Float equal
LM_CMP_Feq :: LlvmCmpOp

-- | Float not equal
LM_CMP_Fne :: LlvmCmpOp

-- | Float greater than
LM_CMP_Fgt :: LlvmCmpOp

-- | Float greater than or equal
LM_CMP_Fge :: LlvmCmpOp

-- | Float less than
LM_CMP_Flt :: LlvmCmpOp

-- | Float less than or equal
LM_CMP_Fle :: LlvmCmpOp

-- | Llvm cast operations.
data LlvmCastOp

-- | Integer truncate
LM_Trunc :: LlvmCastOp

-- | Integer extend (zero fill)
LM_Zext :: LlvmCastOp

-- | Integer extend (sign fill)
LM_Sext :: LlvmCastOp

-- | Float truncate
LM_Fptrunc :: LlvmCastOp

-- | Float extend
LM_Fpext :: LlvmCastOp

-- | Float to unsigned Integer
LM_Fptoui :: LlvmCastOp

-- | Float to signed Integer
LM_Fptosi :: LlvmCastOp

-- | Unsigned Integer to Float
LM_Uitofp :: LlvmCastOp

-- | Signed Int to Float
LM_Sitofp :: LlvmCastOp

-- | Pointer to Integer
LM_Ptrtoint :: LlvmCastOp

-- | Integer to Pointer
LM_Inttoptr :: LlvmCastOp

-- | Cast between types where no bit manipulation is needed
LM_Bitcast :: LlvmCastOp

-- | Convert a Haskell Double to an LLVM hex encoded floating point form.
--   In Llvm float literals can be printed in a big-endian hexadecimal
--   format, regardless of underlying architecture.
dToStr :: Double -> String

-- | Convert a Haskell Float to an LLVM hex encoded floating point form.
--   LLVM uses the same encoding for both floats and doubles (16 digit hex
--   string) but floats must have the last half all zeroes so it can fit
--   into a float size type.
fToStr :: Float -> String

-- | Reverse or leave byte data alone to fix endianness on this target.
fixEndian :: [a] -> [a]
instance Eq LlvmParamAttr
instance Eq LlvmFuncAttr
instance Eq LlvmCallType
instance Show LlvmCallType
instance Eq LlvmCallConvention
instance Eq LlvmParameterListType
instance Show LlvmParameterListType
instance Eq LlvmLinkageType
instance Eq LlvmFunctionDecl
instance Eq LlvmType
instance Eq LlvmLit
instance Eq LlvmVar
instance Eq LlvmMetaVal
instance Eq LlvmMeta
instance Eq LlvmMachOp
instance Eq LlvmCmpOp
instance Eq LlvmCastOp
instance Show LlvmCastOp
instance Show LlvmCmpOp
instance Show LlvmMachOp
instance Show LlvmLinkageType
instance Show LlvmCallConvention
instance Show LlvmFuncAttr
instance Show LlvmParamAttr
instance Show LlvmFunctionDecl
instance Show LlvmStatic
instance Show LlvmLit
instance Show LlvmVar
instance Show LlvmMeta
instance Show LlvmMetaUnamed
instance Show LlvmMetaVal
instance Eq LlvmMetaUnamed
instance Show LlvmType


-- | The LLVM abstract syntax.
module Llvm.AbsSyn

-- | Block labels
type LlvmBlockId = Unique

-- | A block of LLVM code.
data LlvmBlock
LlvmBlock :: LlvmBlockId -> [LlvmStatement] -> LlvmBlock

-- | The code label for this block
blockLabel :: LlvmBlock -> LlvmBlockId

-- | A list of LlvmStatement's representing the code for this block. This
--   list must end with a control flow statement.
blockStmts :: LlvmBlock -> [LlvmStatement]
type LlvmBlocks = [LlvmBlock]

-- | An LLVM Module. This is a top level container in LLVM.
data LlvmModule
LlvmModule :: [LMString] -> [LlvmAlias] -> [LlvmMeta] -> [LMGlobal] -> LlvmFunctionDecls -> LlvmFunctions -> LlvmModule

-- | Comments to include at the start of the module.
modComments :: LlvmModule -> [LMString]

-- | LLVM Alias type definitions.
modAliases :: LlvmModule -> [LlvmAlias]

-- | LLVM meta data.
modMeta :: LlvmModule -> [LlvmMeta]

-- | Global variables to include in the module.
modGlobals :: LlvmModule -> [LMGlobal]

-- | LLVM Functions used in this module but defined in other modules.
modFwdDecls :: LlvmModule -> LlvmFunctionDecls

-- | LLVM Functions defined in this module.
modFuncs :: LlvmModule -> LlvmFunctions

-- | An LLVM Function
data LlvmFunction
LlvmFunction :: LlvmFunctionDecl -> [LMString] -> [LlvmFuncAttr] -> LMSection -> LlvmBlocks -> LlvmFunction

-- | The signature of this declared function.
funcDecl :: LlvmFunction -> LlvmFunctionDecl

-- | The functions arguments
funcArgs :: LlvmFunction -> [LMString]

-- | The function attributes.
funcAttrs :: LlvmFunction -> [LlvmFuncAttr]

-- | The section to put the function into,
funcSect :: LlvmFunction -> LMSection

-- | The body of the functions.
funcBody :: LlvmFunction -> LlvmBlocks
type LlvmFunctions = [LlvmFunction]

-- | LLVM ordering types for synchronization purposes. (Introduced in LLVM
--   3.0). Please see the LLVM documentation for a better description.
data LlvmSyncOrdering

-- | Some partial order of operations exists.
SyncUnord :: LlvmSyncOrdering

-- | A single total order for operations at a single address exists.
SyncMonotonic :: LlvmSyncOrdering

-- | Acquire synchronization operation.
SyncAcquire :: LlvmSyncOrdering

-- | Release synchronization operation.
SyncRelease :: LlvmSyncOrdering

-- | Acquire + Release synchronization operation.
SyncAcqRel :: LlvmSyncOrdering

-- | Full sequential Consistency operation.
SyncSeqCst :: LlvmSyncOrdering

-- | Llvm Statements
data LlvmStatement

-- | Assign an expression to an variable: * dest: Variable to assign to *
--   source: Source expression
Assignment :: LlvmVar -> LlvmExpression -> LlvmStatement

-- | Memory fence operation
Fence :: Bool -> LlvmSyncOrdering -> LlvmStatement

-- | Always branch to the target label
Branch :: LlvmVar -> LlvmStatement

-- | Branch to label targetTrue if cond is true otherwise to label
--   targetFalse * cond: condition that will be tested, must be of type i1
--   * targetTrue: label to branch to if cond is true * targetFalse: label
--   to branch to if cond is false
BranchIf :: LlvmVar -> LlvmVar -> LlvmVar -> LlvmStatement

-- | Comment Plain comment.
Comment :: [LMString] -> LlvmStatement

-- | Set a label on this position. * name: Identifier of this label, unique
--   for this module
MkLabel :: LlvmBlockId -> LlvmStatement

-- | Store variable value in pointer ptr. If value is of type t then ptr
--   must be of type t*. * value: Variable/Constant to store. * ptr:
--   Location to store the value in
Store :: LlvmVar -> LlvmVar -> LlvmStatement

-- | Mutliway branch * scrutinee: Variable or constant which must be of
--   integer type that is determines which arm is chosen. * def: The
--   default label if there is no match in target. * target: A list of
--   (value,label) where the value is an integer constant and label the
--   corresponding label to jump to if the scrutinee matches the value.
Switch :: LlvmVar -> LlvmVar -> [(LlvmVar, LlvmVar)] -> LlvmStatement

-- | Return a result. * result: The variable or constant to return
Return :: (Maybe LlvmVar) -> LlvmStatement

-- | An instruction for the optimizer that the code following is not
--   reachable
Unreachable :: LlvmStatement

-- | Raise an expression to a statement (if don't want result or want to
--   use Llvm unnamed values.
Expr :: LlvmExpression -> LlvmStatement

-- | A nop LLVM statement. Useful as its often more efficient to use this
--   then to wrap LLvmStatement in a Just or [].
Nop :: LlvmStatement

-- | A LLVM statement with metadata attached to it.
MetaStmt :: [MetaData] -> LlvmStatement -> LlvmStatement
type MetaData = (LMString, LlvmMetaUnamed)

-- | Llvm Expressions
data LlvmExpression

-- | Allocate amount * sizeof(tp) bytes on the stack * tp: LlvmType to
--   reserve room for * amount: The nr of tp's which must be allocated
Alloca :: LlvmType -> Int -> LlvmExpression

-- | Perform the machine operator op on the operands left and right * op:
--   operator * left: left operand * right: right operand
LlvmOp :: LlvmMachOp -> LlvmVar -> LlvmVar -> LlvmExpression

-- | Perform a compare operation on the operands left and right * op:
--   operator * left: left operand * right: right operand
Compare :: LlvmCmpOp -> LlvmVar -> LlvmVar -> LlvmExpression

-- | Allocate amount * sizeof(tp) bytes on the heap * tp: LlvmType to
--   reserve room for * amount: The nr of tp's which must be allocated
Malloc :: LlvmType -> Int -> LlvmExpression

-- | Load the value at location ptr
Load :: LlvmVar -> LlvmExpression

-- | Navigate in an structure, selecting elements * inbound: Is the pointer
--   inbounds? (computed pointer doesn't overflow) * ptr: Location of the
--   structure * indexes: A list of indexes to select the correct value.
GetElemPtr :: Bool -> LlvmVar -> [LlvmVar] -> LlvmExpression

-- | Cast the variable from to the to type. This is an abstraction of three
--   cast operators in Llvm, inttoptr, prttoint and bitcast. * cast: Cast
--   type * from: Variable to cast * to: type to cast to
Cast :: LlvmCastOp -> LlvmVar -> LlvmType -> LlvmExpression

-- | Call a function. The result is the value of the expression. *
--   tailJumps: CallType to signal if the function should be tail called *
--   fnptrval: An LLVM value containing a pointer to a function to be
--   invoked. Can be indirect. Should be LMFunction type. * args: Concrete
--   arguments for the parameters * attrs: A list of function attributes
--   for the call. Only NoReturn, NoUnwind, ReadOnly and ReadNone are valid
--   here.
Call :: LlvmCallType -> LlvmVar -> [LlvmVar] -> [LlvmFuncAttr] -> LlvmExpression

-- | Merge variables from different basic blocks which are predecessors of
--   this basic block in a new variable of type tp. * tp: type of the
--   merged variable, must match the types of the predecessor variables. *
--   precessors: A list of variables and the basic block that they
--   originate from.
Phi :: LlvmType -> [(LlvmVar, LlvmVar)] -> LlvmExpression

-- | Inline assembly expression. Syntax is very similar to the style used
--   by GCC. * assembly: Actual inline assembly code. * contraints: Operand
--   constraints. * return ty: Return type of function. * vars: Any
--   variables involved in the assembly code. * sideeffect: Does the
--   expression have side effects not visible from the constraints list. *
--   alignstack: Should the stack be conservatively aligned before this
--   expression is executed.
Asm :: LMString -> LMString -> LlvmType -> [LlvmVar] -> Bool -> Bool -> LlvmExpression

-- | A LLVM expression with metadata attached to it.
MetaExpr :: [MetaData] -> LlvmExpression -> LlvmExpression
instance Show LlvmSyncOrdering
instance Eq LlvmSyncOrdering
instance Show LlvmExpression
instance Eq LlvmExpression
instance Show LlvmStatement
instance Eq LlvmStatement

module ObjLink
initObjLinker :: IO ()

-- | loadDLL loads a dynamic library using the OS's native linker (i.e.
--   dlopen() on Unix, LoadLibrary() on Windows). It takes either an
--   absolute pathname to the file, or a relative filename (e.g.
--   <a>libfoo.so</a> or <a>foo.dll</a>). In the latter case, loadDLL
--   searches the standard locations for the appropriate library.
loadDLL :: String -> IO (Maybe String)
loadArchive :: String -> IO ()
loadObj :: String -> IO ()
unloadObj :: String -> IO ()
insertSymbol :: String -> String -> Ptr a -> IO ()
lookupSymbol :: String -> IO (Maybe (Ptr a))
resolveObjs :: IO SuccessFlag

module Bag
data Bag a
emptyBag :: Bag a
unitBag :: a -> Bag a
unionBags :: Bag a -> Bag a -> Bag a
unionManyBags :: [Bag a] -> Bag a
mapBag :: (a -> b) -> Bag a -> Bag b
elemBag :: Eq a => a -> Bag a -> Bool
lengthBag :: Bag a -> Int
filterBag :: (a -> Bool) -> Bag a -> Bag a
partitionBag :: (a -> Bool) -> Bag a -> (Bag a, Bag a)
partitionBagWith :: (a -> Either b c) -> Bag a -> (Bag b, Bag c)
concatBag :: Bag (Bag a) -> Bag a
foldBag :: (r -> r -> r) -> (a -> r) -> r -> Bag a -> r
foldrBag :: (a -> r -> r) -> r -> Bag a -> r
foldlBag :: (r -> a -> r) -> r -> Bag a -> r
isEmptyBag :: Bag a -> Bool
isSingletonBag :: Bag a -> Bool
consBag :: a -> Bag a -> Bag a
snocBag :: Bag a -> a -> Bag a
anyBag :: (a -> Bool) -> Bag a -> Bool
listToBag :: [a] -> Bag a
bagToList :: Bag a -> [a]
foldrBagM :: Monad m => (a -> b -> m b) -> b -> Bag a -> m b
foldlBagM :: Monad m => (b -> a -> m b) -> b -> Bag a -> m b
mapBagM :: Monad m => (a -> m b) -> Bag a -> m (Bag b)
mapBagM_ :: Monad m => (a -> m b) -> Bag a -> m ()
flatMapBagM :: Monad m => (a -> m (Bag b)) -> Bag a -> m (Bag b)
flatMapBagPairM :: Monad m => (a -> m (Bag b, Bag c)) -> Bag a -> m (Bag b, Bag c)
mapAndUnzipBagM :: Monad m => (a -> m (b, c)) -> Bag a -> m (Bag b, Bag c)
mapAccumBagLM :: Monad m => (acc -> x -> m (acc, y)) -> acc -> Bag x -> m (acc, Bag y)
instance Typeable1 Bag
instance Data a => Data (Bag a)
instance Outputable a => Outputable (Bag a)

module Pair
data Pair a
Pair :: a -> a -> Pair a
pFst :: Pair a -> a
pSnd :: Pair a -> a
unPair :: Pair a -> (a, a)
toPair :: (a, a) -> Pair a
swap :: Pair a -> Pair a
instance Outputable a => Outputable (Pair a)
instance Traversable Pair
instance Foldable Pair
instance Applicative Pair
instance Functor Pair

module SMRep
type StgWord = Word32
type StgHalfWord = Word16
hALF_WORD_SIZE :: ByteOff
hALF_WORD_SIZE_IN_BITS :: Int
type WordOff = Int
type ByteOff = Int
roundUpToWords :: ByteOff -> ByteOff

-- | A description of the layout of a closure. Corresponds directly to the
--   closure types in includes<i>rts</i>storage/ClosureTypes.h.
data SMRep
HeapRep :: IsStatic -> !WordOff -> !WordOff -> ClosureTypeInfo -> SMRep
StackRep :: Liveness -> SMRep
RTSRep :: StgHalfWord -> SMRep -> SMRep

-- | True <a>=</a> This is a static closure. Affects how we garbage-collect
--   it. Static closure have an extra static link field at the end.
type IsStatic = Bool
data ClosureTypeInfo
Constr :: ConstrTag -> ConstrDescription -> ClosureTypeInfo
Fun :: FunArity -> ArgDescr -> ClosureTypeInfo
Thunk :: ClosureTypeInfo
ThunkSelector :: SelectorOffset -> ClosureTypeInfo
BlackHole :: ClosureTypeInfo
data ArgDescr
ArgSpec :: !StgHalfWord -> ArgDescr
ArgGen :: Liveness -> ArgDescr
type Liveness = [Bool]
type ConstrDescription = [Word8]
mkHeapRep :: IsStatic -> WordOff -> WordOff -> ClosureTypeInfo -> SMRep
blackHoleRep :: SMRep
mkStackRep :: [Bool] -> SMRep
mkRTSRep :: StgHalfWord -> SMRep -> SMRep
isStaticRep :: SMRep -> IsStatic
isConRep :: SMRep -> Bool
isThunkRep :: SMRep -> Bool
isFunRep :: SMRep -> Bool
isStaticNoCafCon :: SMRep -> Bool
heapClosureSize :: SMRep -> WordOff

-- | Size of a closure header (StgHeader in
--   includes<i>rts</i>storage/Closures.h)
fixedHdrSize :: WordOff
arrWordsHdrSize :: ByteOff
arrPtrsHdrSize :: ByteOff

-- | Size of the profiling part of a closure header (StgProfHeader in
--   includes<i>rts</i>storage/Closures.h)
profHdrSize :: WordOff
thunkHdrSize :: WordOff
nonHdrSize :: SMRep -> WordOff

-- | Derives the RTS closure type from an <a>SMRep</a>
rtsClosureType :: SMRep -> StgHalfWord
rET_SMALL :: StgHalfWord
rET_BIG :: StgHalfWord
aRG_GEN :: StgHalfWord
aRG_GEN_BIG :: StgHalfWord
pprWord8String :: [Word8] -> SDoc
stringToWord8s :: String -> [Word8]
instance Outputable ArgDescr
instance Outputable SMRep
instance Outputable ClosureTypeInfo

module Bitmap

-- | A bitmap represented by a sequence of <a>StgWord</a>s on the
--   <i>target</i> architecture. These are used for bitmaps in info tables
--   and other generated code which need to be emitted as sequences of
--   StgWords.
type Bitmap = [StgWord]

-- | Make a bitmap from a sequence of bits
mkBitmap :: [Bool] -> Bitmap

-- | Make a bitmap where the slots specified are the <i>ones</i> in the
--   bitmap. eg. <tt>[0,1,3], size 4 ==&gt; 0xb</tt>.
--   
--   The list of <tt>Int</tt>s <i>must</i> be already sorted.
intsToBitmap :: Int -> [Int] -> Bitmap

-- | Make a bitmap where the slots specified are the <i>zeros</i> in the
--   bitmap. eg. <tt>[0,1,3], size 4 ==&gt; 0x4</tt> (we leave any bits
--   outside the size as zero, just to make the bitmap easier to read).
--   
--   The list of <tt>Int</tt>s <i>must</i> be already sorted and
--   duplicate-free.
intsToReverseBitmap :: Int -> [Int] -> Bitmap

-- | Magic number, must agree with <tt>BITMAP_BITS_SHIFT</tt> in
--   InfoTables.h. Some kinds of bitmap pack a size/bitmap into a single
--   word if possible, or fall back to an external pointer when the bitmap
--   is too large. This value represents the largest size of bitmap that
--   can be packed into a single word.
mAX_SMALL_BITMAP_SIZE :: Int
seqBitmap :: Bitmap -> a -> a

module DriverPhases
data HscSource
HsSrcFile :: HscSource
HsBootFile :: HscSource
ExtCoreFile :: HscSource
isHsBoot :: HscSource -> Bool
hscSourceString :: HscSource -> String
data Phase
Unlit :: HscSource -> Phase
Cpp :: HscSource -> Phase
HsPp :: HscSource -> Phase
Hsc :: HscSource -> Phase
Ccpp :: Phase
Cc :: Phase
Cobjc :: Phase
Cobjcpp :: Phase
HCc :: Phase
Splitter :: Phase
SplitAs :: Phase
As :: Phase
LlvmOpt :: Phase
LlvmLlc :: Phase
LlvmMangle :: Phase
CmmCpp :: Phase
Cmm :: Phase
MergeStub :: Phase
StopLn :: Phase
happensBefore :: Phase -> Phase -> Bool
eqPhase :: Phase -> Phase -> Bool
anyHsc :: Phase
isStopLn :: Phase -> Bool
startPhase :: String -> Phase
phaseInputExt :: Phase -> String
isHaskellishSuffix :: String -> Bool
isHaskellSrcSuffix :: String -> Bool
isObjectSuffix :: String -> Bool
isCishSuffix :: String -> Bool
isExtCoreSuffix :: String -> Bool
isDynLibSuffix :: String -> Bool
isHaskellUserSrcSuffix :: String -> Bool
isSourceSuffix :: String -> Bool
isHaskellishFilename :: FilePath -> Bool
isHaskellSrcFilename :: FilePath -> Bool
isObjectFilename :: FilePath -> Bool
isCishFilename :: FilePath -> Bool
isExtCoreFilename :: FilePath -> Bool
isDynLibFilename :: FilePath -> Bool
isHaskellUserSrcFilename :: FilePath -> Bool
isSourceFilename :: FilePath -> Bool
instance Eq HscSource
instance Ord HscSource
instance Show HscSource
instance Eq Phase
instance Show Phase
instance Outputable Phase

module UniqFM
data UniqFM ele
emptyUFM :: UniqFM elt
unitUFM :: Uniquable key => key -> elt -> UniqFM elt
unitDirectlyUFM :: Unique -> elt -> UniqFM elt
listToUFM :: Uniquable key => [(key, elt)] -> UniqFM elt
listToUFM_Directly :: [(Unique, elt)] -> UniqFM elt
listToUFM_C :: Uniquable key => (elt -> elt -> elt) -> [(key, elt)] -> UniqFM elt
addToUFM :: Uniquable key => UniqFM elt -> key -> elt -> UniqFM elt
addToUFM_C :: Uniquable key => (elt -> elt -> elt) -> UniqFM elt -> key -> elt -> UniqFM elt
addToUFM_Acc :: Uniquable key => (elt -> elts -> elts) -> (elt -> elts) -> UniqFM elts -> key -> elt -> UniqFM elts
addListToUFM :: Uniquable key => UniqFM elt -> [(key, elt)] -> UniqFM elt
addListToUFM_C :: Uniquable key => (elt -> elt -> elt) -> UniqFM elt -> [(key, elt)] -> UniqFM elt
addToUFM_Directly :: UniqFM elt -> Unique -> elt -> UniqFM elt
addListToUFM_Directly :: UniqFM elt -> [(Unique, elt)] -> UniqFM elt
adjustUFM :: Uniquable key => (elt -> elt) -> UniqFM elt -> key -> UniqFM elt
alterUFM :: Uniquable key => (Maybe elt -> Maybe elt) -> UniqFM elt -> key -> UniqFM elt
adjustUFM_Directly :: (elt -> elt) -> UniqFM elt -> Unique -> UniqFM elt
delFromUFM :: Uniquable key => UniqFM elt -> key -> UniqFM elt
delFromUFM_Directly :: UniqFM elt -> Unique -> UniqFM elt
delListFromUFM :: Uniquable key => UniqFM elt -> [key] -> UniqFM elt
plusUFM :: UniqFM elt -> UniqFM elt -> UniqFM elt
plusUFM_C :: (elt -> elt -> elt) -> UniqFM elt -> UniqFM elt -> UniqFM elt
minusUFM :: UniqFM elt1 -> UniqFM elt2 -> UniqFM elt1
intersectUFM :: UniqFM elt -> UniqFM elt -> UniqFM elt
intersectUFM_C :: (elt1 -> elt2 -> elt3) -> UniqFM elt1 -> UniqFM elt2 -> UniqFM elt3
foldUFM :: (elt -> a -> a) -> a -> UniqFM elt -> a
foldUFM_Directly :: (Unique -> elt -> a -> a) -> a -> UniqFM elt -> a
mapUFM :: (elt1 -> elt2) -> UniqFM elt1 -> UniqFM elt2
mapUFM_Directly :: (Unique -> elt1 -> elt2) -> UniqFM elt1 -> UniqFM elt2
elemUFM :: Uniquable key => key -> UniqFM elt -> Bool
elemUFM_Directly :: Unique -> UniqFM elt -> Bool
filterUFM :: (elt -> Bool) -> UniqFM elt -> UniqFM elt
filterUFM_Directly :: (Unique -> elt -> Bool) -> UniqFM elt -> UniqFM elt
sizeUFM :: UniqFM elt -> Int
isNullUFM :: UniqFM elt -> Bool
lookupUFM :: Uniquable key => UniqFM elt -> key -> Maybe elt
lookupUFM_Directly :: UniqFM elt -> Unique -> Maybe elt
lookupWithDefaultUFM :: Uniquable key => UniqFM elt -> elt -> key -> elt
lookupWithDefaultUFM_Directly :: UniqFM elt -> elt -> Unique -> elt
eltsUFM :: UniqFM elt -> [elt]
keysUFM :: UniqFM elt -> [Unique]
splitUFM :: Uniquable key => UniqFM elt -> key -> (UniqFM elt, Maybe elt, UniqFM elt)
ufmToList :: UniqFM elt -> [(Unique, elt)]
joinUFM :: JoinFun v -> JoinFun (UniqFM v)
instance Typeable1 UniqFM
instance Data ele => Data (UniqFM ele)
instance Traversable UniqFM
instance Functor UniqFM
instance Outputable a => Outputable (UniqFM a)
instance Foldable UniqFM
instance Eq ele => Eq (UniqFM ele)

module UniqSet
type UniqSet a = UniqFM a
emptyUniqSet :: UniqSet a
unitUniqSet :: Uniquable a => a -> UniqSet a
mkUniqSet :: Uniquable a => [a] -> UniqSet a
addOneToUniqSet :: Uniquable a => UniqSet a -> a -> UniqSet a
addOneToUniqSet_C :: Uniquable a => (a -> a -> a) -> UniqSet a -> a -> UniqSet a
addListToUniqSet :: Uniquable a => UniqSet a -> [a] -> UniqSet a
delOneFromUniqSet :: Uniquable a => UniqSet a -> a -> UniqSet a
delOneFromUniqSet_Directly :: Uniquable a => UniqSet a -> Unique -> UniqSet a
delListFromUniqSet :: Uniquable a => UniqSet a -> [a] -> UniqSet a
unionUniqSets :: UniqSet a -> UniqSet a -> UniqSet a
unionManyUniqSets :: [UniqSet a] -> UniqSet a
minusUniqSet :: UniqSet a -> UniqSet a -> UniqSet a
intersectUniqSets :: UniqSet a -> UniqSet a -> UniqSet a
foldUniqSet :: (a -> b -> b) -> b -> UniqSet a -> b
mapUniqSet :: (a -> b) -> UniqSet a -> UniqSet b
elementOfUniqSet :: Uniquable a => a -> UniqSet a -> Bool
elemUniqSet_Directly :: Unique -> UniqSet a -> Bool
filterUniqSet :: (a -> Bool) -> UniqSet a -> UniqSet a
sizeUniqSet :: UniqSet a -> Int
isEmptyUniqSet :: UniqSet a -> Bool
lookupUniqSet :: Uniquable a => UniqSet a -> a -> Maybe a
uniqSetToList :: UniqSet a -> [a]


-- | Utils for calculating general worst, bound, squeese and free,
--   functions.
--   
--   as per: <a>A Generalized Algorithm for Graph-Coloring Register
--   Allocation</a> Michael Smith, Normal Ramsey, Glenn Holloway. PLDI 2004
--   
--   These general versions are not used in GHC proper because they are too
--   slow. Instead, hand written optimised versions are provided for each
--   architecture in MachRegs*.hs
--   
--   This code is here because we can test the architecture specific code
--   against it.
module RegAlloc.Graph.ArchBase
data RegClass
ClassG32 :: RegClass
ClassG16 :: RegClass
ClassG8 :: RegClass
ClassF64 :: RegClass

-- | A register of some class
data Reg
Reg :: RegClass -> Int -> Reg
RegSub :: RegSub -> Reg -> Reg

-- | A subcomponent of another register
data RegSub
SubL16 :: RegSub
SubL8 :: RegSub
SubL8H :: RegSub

-- | Worst case displacement
--   
--   a node N of classN has some number of neighbors, all of which are from
--   classC.
--   
--   (worst neighbors classN classC) is the maximum number of potential
--   colors for N that can be lost by coloring its neighbors.
worst :: (RegClass -> UniqSet Reg) -> (Reg -> UniqSet Reg) -> Int -> RegClass -> RegClass -> Int

-- | For a node N of classN and neighbors of classesC (bound classN
--   classesC) is the maximum number of potential colors for N that can be
--   lost by coloring its neighbors.
bound :: (RegClass -> UniqSet Reg) -> (Reg -> UniqSet Reg) -> RegClass -> [RegClass] -> Int

-- | The total squeese on a particular node with a list of neighbors.
--   
--   A version of this should be constructed for each particular
--   architecture, possibly including uses of bound, so that alised
--   registers don't get counted twice, as per the paper.
squeese :: (RegClass -> UniqSet Reg) -> (Reg -> UniqSet Reg) -> RegClass -> [(Int, RegClass)] -> Int
instance Show RegClass
instance Eq RegClass
instance Enum RegClass
instance Show RegSub
instance Enum RegSub
instance Ord RegSub
instance Eq RegSub
instance Show Reg
instance Eq Reg
instance Uniquable Reg


-- | A description of the register set of the X86. This isn't used directly
--   in GHC proper.
--   
--   See RegArchBase.hs for the reference. See MachRegs.hs for the actual
--   trivColorable function used in GHC.
module RegAlloc.Graph.ArchX86

-- | Determine the class of a register
classOfReg :: Reg -> RegClass

-- | Determine all the regs that make up a certain class.
regsOfClass :: RegClass -> UniqSet Reg

-- | Determine the common name of a reg returns Nothing if this reg is not
--   part of the machine.
regName :: Reg -> Maybe String

-- | Which regs alias what other regs
regAlias :: Reg -> UniqSet Reg

-- | Optimised versions of RegColorBase.{worst, squeese} specific to x86
worst :: Int -> RegClass -> RegClass -> Int
squeese :: RegClass -> [(Int, RegClass)] -> Int

module Binary
data Bin a
class Binary a where put_ bh a = do { _ <- put bh a; return () } put bh a = do { p <- tellBin bh; put_ bh a; return p }
put_ :: Binary a => BinHandle -> a -> IO ()
put :: Binary a => BinHandle -> a -> IO (Bin a)
get :: Binary a => BinHandle -> IO a
data BinHandle
type SymbolTable = Array Int Name
type Dictionary = Array Int FastString
openBinIO :: Handle -> IO BinHandle
openBinIO_ :: Handle -> IO BinHandle
openBinMem :: Int -> IO BinHandle
seekBin :: BinHandle -> Bin a -> IO ()
seekBy :: BinHandle -> Int -> IO ()
tellBin :: BinHandle -> IO (Bin a)
castBin :: Bin a -> Bin b
writeBinMem :: BinHandle -> FilePath -> IO ()
readBinMem :: FilePath -> IO BinHandle
fingerprintBinMem :: BinHandle -> IO Fingerprint
computeFingerprint :: Binary a => (BinHandle -> Name -> IO ()) -> a -> IO Fingerprint
isEOFBin :: BinHandle -> IO Bool
putAt :: Binary a => BinHandle -> Bin a -> a -> IO ()
getAt :: Binary a => BinHandle -> Bin a -> IO a
putByte :: BinHandle -> Word8 -> IO ()
getByte :: BinHandle -> IO Word8
lazyGet :: Binary a => BinHandle -> IO a
lazyPut :: Binary a => BinHandle -> a -> IO ()
data ByteArray
BA :: ByteArray# -> ByteArray
getByteArray :: BinHandle -> Int -> IO ByteArray
putByteArray :: BinHandle -> ByteArray# -> Int# -> IO ()
data UserData
UserData :: (BinHandle -> IO Name) -> (BinHandle -> IO FastString) -> (BinHandle -> Name -> IO ()) -> (BinHandle -> FastString -> IO ()) -> UserData
ud_get_name :: UserData -> BinHandle -> IO Name
ud_get_fs :: UserData -> BinHandle -> IO FastString
ud_put_name :: UserData -> BinHandle -> Name -> IO ()
ud_put_fs :: UserData -> BinHandle -> FastString -> IO ()
getUserData :: BinHandle -> UserData
setUserData :: BinHandle -> UserData -> BinHandle
newReadState :: (BinHandle -> IO Name) -> (BinHandle -> IO FastString) -> UserData
newWriteState :: (BinHandle -> Name -> IO ()) -> (BinHandle -> FastString -> IO ()) -> UserData
putDictionary :: BinHandle -> Int -> UniqFM (Int, FastString) -> IO ()
getDictionary :: BinHandle -> IO Dictionary
putFS :: BinHandle -> FastString -> IO ()
instance Eq (Bin a)
instance Ord (Bin a)
instance Show (Bin a)
instance Bounded (Bin a)
instance Binary FunctionOrData
instance Binary Fingerprint
instance Binary FastString
instance Binary TypeRep
instance Binary TyCon
instance Binary (Bin a)
instance (Integral a, Binary a) => Binary (Ratio a)
instance Binary Integer
instance Binary DiffTime
instance Binary Day
instance Binary UTCTime
instance (Binary a, Binary b) => Binary (Either a b)
instance Binary a => Binary (Maybe a)
instance (Binary a, Binary b, Binary c, Binary d, Binary e, Binary f) => Binary (a, b, c, d, e, f)
instance (Binary a, Binary b, Binary c, Binary d, Binary e) => Binary (a, b, c, d, e)
instance (Binary a, Binary b, Binary c, Binary d) => Binary (a, b, c, d)
instance (Binary a, Binary b, Binary c) => Binary (a, b, c)
instance (Binary a, Binary b) => Binary (a, b)
instance Binary a => Binary [a]
instance Binary Int
instance Binary Char
instance Binary Bool
instance Binary ()
instance Binary Int64
instance Binary Int32
instance Binary Int16
instance Binary Int8
instance Binary Word64
instance Binary Word32
instance Binary Word16
instance Binary Word8


-- | GHC uses several kinds of name internally:
--   
--   <ul>
--   <li><a>OccName</a> represents names as strings with just a little more
--   information: the "namespace" that the name came from, e.g. the
--   namespace of value, type constructors or data constructors</li>
--   <li><a>RdrName</a>: see <a>RdrName#name_types</a></li>
--   <li><a>Name</a>: see <a>Name#name_types</a></li>
--   <li><a>Id</a>: see <a>Id#name_types</a></li>
--   <li><a>Var</a>: see <a>Var#name_types</a></li>
--   </ul>
module OccName
data NameSpace
tcName :: NameSpace
clsName :: NameSpace
tcClsName :: NameSpace
dataName :: NameSpace
varName :: NameSpace
tvName :: NameSpace
srcDataName :: NameSpace
pprNameSpace :: NameSpace -> SDoc
pprNonVarNameSpace :: NameSpace -> SDoc
pprNameSpaceBrief :: NameSpace -> SDoc
data OccName
pprOccName :: OccName -> SDoc
mkOccName :: NameSpace -> String -> OccName
mkOccNameFS :: NameSpace -> FastString -> OccName
mkVarOcc :: String -> OccName
mkVarOccFS :: FastString -> OccName
mkDataOcc :: String -> OccName
mkDataOccFS :: FastString -> OccName
mkTyVarOcc :: String -> OccName
mkTyVarOccFS :: FastString -> OccName
mkTcOcc :: String -> OccName
mkTcOccFS :: FastString -> OccName
mkClsOcc :: String -> OccName
mkClsOccFS :: FastString -> OccName
mkDFunOcc :: String -> Bool -> OccSet -> OccName
mkTupleOcc :: NameSpace -> TupleSort -> Arity -> OccName
setOccNameSpace :: NameSpace -> OccName -> OccName
demoteOccName :: OccName -> Maybe OccName

-- | Other names in the compiler add aditional information to an OccName.
--   This class provides a consistent way to access the underlying OccName.
class HasOccName name
occName :: HasOccName name => name -> OccName
isDerivedOccName :: OccName -> Bool
mkDataConWrapperOcc :: OccName -> OccName
mkWorkerOcc :: OccName -> OccName
mkDefaultMethodOcc :: OccName -> OccName
mkGenDefMethodOcc :: OccName -> OccName
mkDerivedTyConOcc :: OccName -> OccName
mkNewTyCoOcc :: OccName -> OccName
mkClassOpAuxOcc :: OccName -> OccName
mkCon2TagOcc :: OccName -> OccName
mkTag2ConOcc :: OccName -> OccName
mkMaxTagOcc :: OccName -> OccName
mkClassDataConOcc :: OccName -> OccName
mkDictOcc :: OccName -> OccName
mkIPOcc :: OccName -> OccName
mkSpecOcc :: OccName -> OccName
mkForeignExportOcc :: OccName -> OccName
mkGenOcc1 :: OccName -> OccName
mkGenOcc2 :: OccName -> OccName
mkGenD :: OccName -> OccName
mkGenR :: OccName -> OccName
mkGen1R :: OccName -> OccName
mkGenRCo :: OccName -> OccName
mkGenC :: OccName -> Int -> OccName
mkGenS :: OccName -> Int -> Int -> OccName
mkDataTOcc :: OccName -> OccName
mkDataCOcc :: OccName -> OccName
mkDataConWorkerOcc :: OccName -> OccName
mkSuperDictSelOcc :: Int -> OccName -> OccName
mkLocalOcc :: Unique -> OccName -> OccName
mkMethodOcc :: OccName -> OccName

-- | Derive a name for the representation type constructor of a
--   <tt>data</tt>/<tt>newtype</tt> instance.
mkInstTyTcOcc :: String -> OccSet -> OccName
mkInstTyCoOcc :: OccName -> OccName
mkEqPredCoOcc :: OccName -> OccName
mkVectOcc :: Maybe String -> OccName -> OccName
mkVectTyConOcc :: Maybe String -> OccName -> OccName
mkVectDataConOcc :: Maybe String -> OccName -> OccName
mkVectIsoOcc :: Maybe String -> OccName -> OccName
mkPDataTyConOcc :: Maybe String -> OccName -> OccName
mkPDataDataConOcc :: Maybe String -> OccName -> OccName
mkPDatasTyConOcc :: Maybe String -> OccName -> OccName
mkPDatasDataConOcc :: Maybe String -> OccName -> OccName
mkPReprTyConOcc :: Maybe String -> OccName -> OccName
mkPADFunOcc :: Maybe String -> OccName -> OccName
occNameFS :: OccName -> FastString
occNameString :: OccName -> String
occNameSpace :: OccName -> NameSpace
isVarOcc :: OccName -> Bool
isTvOcc :: OccName -> Bool
isTcOcc :: OccName -> Bool
isDataOcc :: OccName -> Bool

-- | Test if the <a>OccName</a> is a data constructor that starts with a
--   symbol (e.g. <tt>:</tt>, or <tt>[]</tt>)
isDataSymOcc :: OccName -> Bool

-- | Test if the <a>OccName</a> is that for any operator (whether it is a
--   data constructor or variable or whatever)
isSymOcc :: OccName -> Bool

-- | <i>Value</i> <tt>OccNames</tt>s are those that are either in the
--   variable or data constructor namespaces
isValOcc :: OccName -> Bool

-- | Wrap parens around an operator
parenSymOcc :: OccName -> SDoc -> SDoc

-- | Haskell 98 encourages compilers to suppress warnings about unsed names
--   in a pattern if they start with <tt>_</tt>: this implements that test
startsWithUnderscore :: OccName -> Bool
isTcClsNameSpace :: NameSpace -> Bool
isTvNameSpace :: NameSpace -> Bool
isDataConNameSpace :: NameSpace -> Bool
isVarNameSpace :: NameSpace -> Bool
isValNameSpace :: NameSpace -> Bool
isTupleOcc_maybe :: OccName -> Maybe (NameSpace, TupleSort, Arity)
data OccEnv a
emptyOccEnv :: OccEnv a
unitOccEnv :: OccName -> a -> OccEnv a
extendOccEnv :: OccEnv a -> OccName -> a -> OccEnv a
mapOccEnv :: (a -> b) -> OccEnv a -> OccEnv b
lookupOccEnv :: OccEnv a -> OccName -> Maybe a
mkOccEnv :: [(OccName, a)] -> OccEnv a
mkOccEnv_C :: (a -> a -> a) -> [(OccName, a)] -> OccEnv a
extendOccEnvList :: OccEnv a -> [(OccName, a)] -> OccEnv a
elemOccEnv :: OccName -> OccEnv a -> Bool
occEnvElts :: OccEnv a -> [a]
foldOccEnv :: (a -> b -> b) -> b -> OccEnv a -> b
plusOccEnv :: OccEnv a -> OccEnv a -> OccEnv a
plusOccEnv_C :: (a -> a -> a) -> OccEnv a -> OccEnv a -> OccEnv a
extendOccEnv_C :: (a -> a -> a) -> OccEnv a -> OccName -> a -> OccEnv a
extendOccEnv_Acc :: (a -> b -> b) -> (a -> b) -> OccEnv b -> OccName -> a -> OccEnv b
filterOccEnv :: (elt -> Bool) -> OccEnv elt -> OccEnv elt
delListFromOccEnv :: OccEnv a -> [OccName] -> OccEnv a
delFromOccEnv :: OccEnv a -> OccName -> OccEnv a
type OccSet = UniqSet OccName
emptyOccSet :: OccSet
unitOccSet :: OccName -> OccSet
mkOccSet :: [OccName] -> OccSet
extendOccSet :: OccSet -> OccName -> OccSet
extendOccSetList :: OccSet -> [OccName] -> OccSet
unionOccSets :: OccSet -> OccSet -> OccSet
unionManyOccSets :: [OccSet] -> OccSet
minusOccSet :: OccSet -> OccSet -> OccSet
elemOccSet :: OccName -> OccSet -> Bool
occSetElts :: OccSet -> [OccName]
foldOccSet :: (OccName -> b -> b) -> b -> OccSet -> b
isEmptyOccSet :: OccSet -> Bool
intersectOccSet :: OccSet -> OccSet -> OccSet
intersectsOccSet :: OccSet -> OccSet -> Bool
type TidyOccEnv = OccEnv Int
emptyTidyOccEnv :: TidyOccEnv
tidyOccName :: TidyOccEnv -> OccName -> (TidyOccEnv, OccName)
initTidyOccEnv :: [OccName] -> TidyOccEnv
isLexCon :: FastString -> Bool
isLexVar :: FastString -> Bool
isLexId :: FastString -> Bool
isLexSym :: FastString -> Bool
isLexConId :: FastString -> Bool
isLexConSym :: FastString -> Bool
isLexVarId :: FastString -> Bool
isLexVarSym :: FastString -> Bool
startsVarSym :: Char -> Bool
startsVarId :: Char -> Bool
startsConSym :: Char -> Bool
startsConId :: Char -> Bool
instance Typeable OccName
instance Eq NameSpace
instance Ord NameSpace
instance Binary OccName
instance Binary NameSpace
instance Outputable a => Outputable (OccEnv a)
instance Uniquable OccName
instance Outputable OccName
instance Data OccName
instance Ord OccName
instance Eq OccName

module Module

-- | A ModuleName is essentially a simple string, e.g. <tt>Data.List</tt>.
data ModuleName
pprModuleName :: ModuleName -> SDoc
moduleNameFS :: ModuleName -> FastString
moduleNameString :: ModuleName -> String

-- | Returns the string version of the module name, with dots replaced by
--   slashes.
moduleNameSlashes :: ModuleName -> String

-- | Returns the string version of the module name, with dots replaced by
--   underscores.
moduleNameColons :: ModuleName -> String
mkModuleName :: String -> ModuleName
mkModuleNameFS :: FastString -> ModuleName

-- | Compares module names lexically, rather than by their <a>Unique</a>s
stableModuleNameCmp :: ModuleName -> ModuleName -> Ordering

-- | Essentially just a string identifying a package, including the
--   version: e.g. parsec-1.0
data PackageId
fsToPackageId :: FastString -> PackageId
packageIdFS :: PackageId -> FastString
stringToPackageId :: String -> PackageId
packageIdString :: PackageId -> String

-- | Compares package ids lexically, rather than by their <a>Unique</a>s
stablePackageIdCmp :: PackageId -> PackageId -> Ordering
primPackageId :: PackageId
integerPackageId :: PackageId
basePackageId :: PackageId
rtsPackageId :: PackageId
thPackageId :: PackageId
dphSeqPackageId :: PackageId
dphParPackageId :: PackageId

-- | This is the package Id for the current program. It is the default
--   package Id if you don't specify a package name. We don't add this
--   prefix to symbol names, since there can be only one main package per
--   program.
mainPackageId :: PackageId
thisGhcPackageId :: PackageId

-- | A Module is a pair of a <a>PackageId</a> and a <a>ModuleName</a>.
data Module
modulePackageId :: Module -> PackageId
moduleName :: Module -> ModuleName
pprModule :: Module -> SDoc
mkModule :: PackageId -> ModuleName -> Module

-- | This gives a stable ordering, as opposed to the Ord instance which
--   gives an ordering based on the <a>Unique</a>s of the components, which
--   may not be stable from run to run of the compiler.
stableModuleCmp :: Module -> Module -> Ordering

-- | Where a module lives on the file system: the actual locations of the
--   .hs, .hi and .o files, if we have them
data ModLocation
ModLocation :: Maybe FilePath -> FilePath -> FilePath -> ModLocation
ml_hs_file :: ModLocation -> Maybe FilePath
ml_hi_file :: ModLocation -> FilePath
ml_obj_file :: ModLocation -> FilePath

-- | Add the <tt>-boot</tt> suffix to .hs, .hi and .o files
addBootSuffix :: FilePath -> FilePath

-- | Add the <tt>-boot</tt> suffix if the <tt>Bool</tt> argument is
--   <tt>True</tt>
addBootSuffix_maybe :: Bool -> FilePath -> FilePath

-- | Add the <tt>-boot</tt> suffix to all file paths associated with the
--   module
addBootSuffixLocn :: ModLocation -> ModLocation

-- | A map keyed off of <a>Module</a>s
data ModuleEnv elt
elemModuleEnv :: Module -> ModuleEnv a -> Bool
extendModuleEnv :: ModuleEnv a -> Module -> a -> ModuleEnv a
extendModuleEnvList :: ModuleEnv a -> [(Module, a)] -> ModuleEnv a
extendModuleEnvList_C :: (a -> a -> a) -> ModuleEnv a -> [(Module, a)] -> ModuleEnv a
plusModuleEnv_C :: (a -> a -> a) -> ModuleEnv a -> ModuleEnv a -> ModuleEnv a
delModuleEnvList :: ModuleEnv a -> [Module] -> ModuleEnv a
delModuleEnv :: ModuleEnv a -> Module -> ModuleEnv a
plusModuleEnv :: ModuleEnv a -> ModuleEnv a -> ModuleEnv a
lookupModuleEnv :: ModuleEnv a -> Module -> Maybe a
lookupWithDefaultModuleEnv :: ModuleEnv a -> a -> Module -> a
mapModuleEnv :: (a -> b) -> ModuleEnv a -> ModuleEnv b
mkModuleEnv :: [(Module, a)] -> ModuleEnv a
emptyModuleEnv :: ModuleEnv a
moduleEnvKeys :: ModuleEnv a -> [Module]
moduleEnvElts :: ModuleEnv a -> [a]
moduleEnvToList :: ModuleEnv a -> [(Module, a)]
unitModuleEnv :: Module -> a -> ModuleEnv a
isEmptyModuleEnv :: ModuleEnv a -> Bool
foldModuleEnv :: (a -> b -> b) -> b -> ModuleEnv a -> b
extendModuleEnvWith :: (a -> a -> a) -> ModuleEnv a -> Module -> a -> ModuleEnv a
filterModuleEnv :: (Module -> a -> Bool) -> ModuleEnv a -> ModuleEnv a

-- | A map keyed off of <a>ModuleName</a>s (actually, their <a>Unique</a>s)
type ModuleNameEnv elt = UniqFM elt

-- | A set of <a>Module</a>s
type ModuleSet = Map Module ()
emptyModuleSet :: ModuleSet
mkModuleSet :: [Module] -> ModuleSet
moduleSetElts :: ModuleSet -> [Module]
extendModuleSet :: ModuleSet -> Module -> ModuleSet
elemModuleSet :: Module -> ModuleSet -> Bool
instance Typeable PackageId
instance Typeable ModuleName
instance Typeable Module
instance Show ModLocation
instance Eq PackageId
instance Eq Module
instance Ord Module
instance Binary PackageId
instance Outputable PackageId
instance Data PackageId
instance Ord PackageId
instance Uniquable PackageId
instance Data Module
instance Binary Module
instance Outputable Module
instance Uniquable Module
instance Data ModuleName
instance Binary ModuleName
instance Outputable ModuleName
instance Ord ModuleName
instance Eq ModuleName
instance Uniquable ModuleName
instance Outputable ModLocation


-- | GHC uses several kinds of name internally:
--   
--   <ul>
--   <li><a>OccName</a>: see <a>OccName#name_types</a></li>
--   <li><a>RdrName</a>: see <a>RdrName#name_types</a></li>
--   <li><a>Name</a> is the type of names that have had their scoping and
--   binding resolved. They have an <a>OccName</a> but also a <a>Unique</a>
--   that disambiguates Names that have the same <a>OccName</a> and indeed
--   is used for all <a>Name</a> comparison. Names also contain information
--   about where they originated from, see <a>Name#name_sorts</a></li>
--   <li><a>Id</a>: see <a>Id#name_types</a></li>
--   <li><a>Var</a>: see <a>Var#name_types</a></li>
--   </ul>
--   
--   Names are one of:
--   
--   <ul>
--   <li>External, if they name things declared in other modules. Some
--   external Names are wired in, i.e. they name primitives defined in the
--   compiler itself</li>
--   <li>Internal, if they name things in the module being compiled. Some
--   internal Names are system names, if they are names manufactured by the
--   compiler</li>
--   </ul>
module Name

-- | A unique, unambigious name for something, containing information about
--   where that thing originated.
data Name

-- | BuiltInSyntax is for things like <tt>(:)</tt>, <tt>[]</tt> and tuples,
--   which have special syntactic forms. They aren't in scope as such.
data BuiltInSyntax
BuiltInSyntax :: BuiltInSyntax
UserSyntax :: BuiltInSyntax

-- | Create a name brought into being by the compiler
mkSystemName :: Unique -> OccName -> Name
mkSystemNameAt :: Unique -> OccName -> SrcSpan -> Name

-- | Create a name which is (for now at least) local to the current module
--   and hence does not need a <a>Module</a> to disambiguate it from other
--   <a>Name</a>s
mkInternalName :: Unique -> OccName -> SrcSpan -> Name
mkDerivedInternalName :: (OccName -> OccName) -> Unique -> Name -> Name
mkSystemVarName :: Unique -> FastString -> Name
mkSysTvName :: Unique -> FastString -> Name

-- | Make a name for a foreign call
mkFCallName :: Unique -> String -> Name

-- | Create a name which definitely originates in the given module
mkExternalName :: Unique -> Module -> OccName -> SrcSpan -> Name

-- | Create a name which is actually defined by the compiler itself
mkWiredInName :: Module -> OccName -> Unique -> TyThing -> BuiltInSyntax -> Name
nameUnique :: Name -> Unique
setNameUnique :: Name -> Unique -> Name
nameOccName :: Name -> OccName
nameModule :: Name -> Module
nameModule_maybe :: Name -> Maybe Module
tidyNameOcc :: Name -> OccName -> Name
hashName :: Name -> Int

-- | Make the <a>Name</a> into an internal name, regardless of what it was
--   to begin with
localiseName :: Name -> Name

-- | Create a localised variant of a name.
--   
--   If the name is external, encode the original's module name to
--   disambiguate.
mkLocalisedOccName :: Module -> (Maybe String -> OccName -> OccName) -> Name -> OccName
nameSrcLoc :: Name -> SrcLoc
nameSrcSpan :: Name -> SrcSpan
pprNameDefnLoc :: Name -> SDoc
pprDefinedAt :: Name -> SDoc
isSystemName :: Name -> Bool
isInternalName :: Name -> Bool
isExternalName :: Name -> Bool
isTyVarName :: Name -> Bool
isTyConName :: Name -> Bool
isDataConName :: Name -> Bool
isValName :: Name -> Bool
isVarName :: Name -> Bool
isWiredInName :: Name -> Bool
isBuiltInSyntax :: Name -> Bool
wiredInNameTyThing_maybe :: Name -> Maybe TyThing
nameIsLocalOrFrom :: Module -> Name -> Bool
stableNameCmp :: Name -> Name -> Ordering

-- | A class allowing convenient access to the <a>Name</a> of various
--   datatypes
class NamedThing a where getOccName n = nameOccName (getName n)
getOccName :: NamedThing a => a -> OccName
getName :: NamedThing a => a -> Name
getSrcLoc :: NamedThing a => a -> SrcLoc
getSrcSpan :: NamedThing a => a -> SrcSpan
getOccString :: NamedThing a => a -> String
pprInfixName :: (Outputable a, NamedThing a) => a -> SDoc
pprPrefixName :: (Outputable a, NamedThing a) => a -> SDoc
pprModulePrefix :: PprStyle -> Module -> Name -> SDoc
instance Typeable Name
instance OutputableBndr Name
instance Outputable Name
instance Binary Name
instance Data Name
instance NamedThing Name
instance Uniquable Name
instance Ord Name
instance Eq Name
instance HasOccName Name


-- | GHC uses several kinds of name internally:
--   
--   <ul>
--   <li><a>OccName</a>: see <a>OccName#name_types</a></li>
--   <li><a>RdrName</a>: see <a>RdrName#name_types</a></li>
--   <li><a>Name</a>: see <a>Name#name_types</a></li>
--   <li><a>Id</a>: see <a>Id#name_types</a></li>
--   <li><a>Var</a> is a synonym for the <a>Id</a> type but it may
--   additionally potentially contain type variables, which have a
--   <a>Kind</a> rather than a <a>Type</a> and only contain some extra
--   details during typechecking.</li>
--   </ul>
--   
--   These <a>Var</a> names may either be global or local, see
--   <a>Var#globalvslocal</a>
--   
--   Global <a>Id</a>s and <a>Var</a>s are those that are imported or
--   correspond to a data constructor, primitive operation, or record
--   selectors. Local <a>Id</a>s and <a>Var</a>s are those bound within an
--   expression (e.g. by a lambda) or at the top level of the module being
--   compiled.
module Var

-- | Essentially a typed <a>Name</a>, that may also contain some additional
--   information about the <a>Var</a> and it's use sites.
data Var
type CoVar = Id
type Id = Var
type DictId = EvId
type DFunId = Id
type EvVar = EvId
type EqVar = EvId
type EvId = Id
type IpId = EvId
type TyVar = Var
type TypeVar = Var
type KindVar = Var
type TKVar = Var
varName :: Var -> Name
varUnique :: Var -> Unique

-- | The type or kind of the <a>Var</a> in question
varType :: Var -> Kind
setVarName :: Var -> Name -> Var
setVarUnique :: Var -> Unique -> Var
setVarType :: Id -> Type -> Id
mkGlobalVar :: IdDetails -> Name -> Type -> IdInfo -> Id
mkLocalVar :: IdDetails -> Name -> Type -> IdInfo -> Id

-- | Exported <a>Var</a>s will not be removed as dead code
mkExportedLocalVar :: IdDetails -> Name -> Type -> IdInfo -> Id
mkCoVar :: Name -> Type -> CoVar
idInfo :: Id -> IdInfo
idDetails :: Id -> IdDetails
lazySetIdInfo :: Id -> IdInfo -> Var
setIdDetails :: Id -> IdDetails -> Id

-- | If it's a local, make it global
globaliseId :: Id -> Id

-- | Exports the given local <a>Id</a>. Can also be called on global
--   <a>Id</a>s, such as data constructors and class operations, which are
--   born as global <a>Id</a>s and automatically exported
setIdExported :: Id -> Id

-- | We can only do this to LocalIds
setIdNotExported :: Id -> Id
isId :: Var -> Bool
isTKVar :: Var -> Bool
isTyVar :: Var -> Bool
isTcTyVar :: Var -> Bool

-- | <a>isLocalVar</a> returns <tt>True</tt> for type variables as well as
--   local <a>Id</a>s These are the variables that we need to pay attention
--   to when finding free variables, or doing dependency analysis.
isLocalVar :: Var -> Bool
isLocalId :: Var -> Bool
isGlobalId :: Var -> Bool

-- | <tt>isExportedIdVar</tt> means "don't throw this away"
isExportedId :: Var -> Bool

-- | <a>mustHaveLocalBinding</a> returns <tt>True</tt> of <a>Id</a>s and
--   <a>TyVar</a>s that must have a binding in this module. The converse is
--   not quite right: there are some global <a>Id</a>s that must have
--   bindings, such as record selectors. But that doesn't matter, because
--   it's only used for assertions
mustHaveLocalBinding :: Var -> Bool
mkTyVar :: Name -> Kind -> TyVar
mkTcTyVar :: Name -> Kind -> TcTyVarDetails -> TyVar
mkKindVar :: Name -> SuperKind -> KindVar
tyVarName :: TyVar -> Name
tyVarKind :: TyVar -> Kind
tcTyVarDetails :: TyVar -> TcTyVarDetails
setTcTyVarDetails :: TyVar -> TcTyVarDetails -> TyVar
setTyVarName :: TyVar -> Name -> TyVar
setTyVarUnique :: TyVar -> Unique -> TyVar
setTyVarKind :: TyVar -> Kind -> TyVar
updateTyVarKind :: (Kind -> Kind) -> TyVar -> TyVar
updateTyVarKindM :: Monad m => (Kind -> m Kind) -> TyVar -> m TyVar
instance Typeable Var
instance Data Var
instance Ord Var
instance Eq Var
instance Uniquable Var
instance NamedThing Var
instance Outputable Var

module VarSet
type VarSet = UniqSet Var
type IdSet = UniqSet Id
type TyVarSet = UniqSet TyVar
type CoVarSet = UniqSet CoVar
emptyVarSet :: VarSet
unitVarSet :: Var -> VarSet
mkVarSet :: [Var] -> VarSet
extendVarSet :: VarSet -> Var -> VarSet
extendVarSetList :: VarSet -> [Var] -> VarSet
extendVarSet_C :: (Var -> Var -> Var) -> VarSet -> Var -> VarSet
elemVarSet :: Var -> VarSet -> Bool
varSetElems :: VarSet -> [Var]
subVarSet :: VarSet -> VarSet -> Bool
unionVarSet :: VarSet -> VarSet -> VarSet
unionVarSets :: [VarSet] -> VarSet
intersectVarSet :: VarSet -> VarSet -> VarSet
intersectsVarSet :: VarSet -> VarSet -> Bool
disjointVarSet :: VarSet -> VarSet -> Bool
isEmptyVarSet :: VarSet -> Bool
delVarSet :: VarSet -> Var -> VarSet
delVarSetList :: VarSet -> [Var] -> VarSet
delVarSetByKey :: VarSet -> Unique -> VarSet
minusVarSet :: VarSet -> VarSet -> VarSet
foldVarSet :: (Var -> a -> a) -> a -> VarSet -> a
filterVarSet :: (Var -> Bool) -> VarSet -> VarSet
fixVarSet :: (VarSet -> VarSet) -> VarSet -> VarSet
lookupVarSet :: VarSet -> Var -> Maybe Var
mapVarSet :: (Var -> Var) -> VarSet -> VarSet
sizeVarSet :: VarSet -> Int
seqVarSet :: VarSet -> ()
elemVarSetByKey :: Unique -> VarSet -> Bool

module Class
data Class
type ClassOpItem = (Id, DefMeth)
data DefMeth
NoDefMeth :: DefMeth
DefMeth :: Name -> DefMeth
GenDefMeth :: Name -> DefMeth
type ClassATItem = (TyCon, [ATDefault])
data ATDefault
ATD :: [TyVar] -> [Type] -> Type -> SrcSpan -> ATDefault
atDefaultTys :: ATDefault -> [TyVar]
atDefaultPats :: ATDefault -> [Type]
atDefaultRhs :: ATDefault -> Type
atDefaultSrcSpan :: ATDefault -> SrcSpan

-- | Convert a <a>DefMethSpec</a> to a <a>DefMeth</a>, which discards the
--   name field in the <a>DefMeth</a> constructor of the <a>DefMeth</a>.
defMethSpecOfDefMeth :: DefMeth -> DefMethSpec
type FunDep a = ([a], [a])
pprFundeps :: Outputable a => [FunDep a] -> SDoc
pprFunDep :: Outputable a => FunDep a -> SDoc
mkClass :: [TyVar] -> [([TyVar], [TyVar])] -> [PredType] -> [Id] -> [ClassATItem] -> [ClassOpItem] -> TyCon -> Class
classTyVars :: Class -> [TyVar]
classArity :: Class -> Arity
classKey :: Class -> Unique
className :: Class -> Name
classATs :: Class -> [TyCon]
classATItems :: Class -> [ClassATItem]
classTyCon :: Class -> TyCon
classMethods :: Class -> [Id]
classOpItems :: Class -> [ClassOpItem]
classBigSig :: Class -> ([TyVar], [PredType], [Id], [ClassOpItem])
classExtraBigSig :: Class -> ([TyVar], [FunDep TyVar], [PredType], [Id], [ClassATItem], [ClassOpItem])
classTvsFds :: Class -> ([TyVar], [FunDep TyVar])
classSCTheta :: Class -> [PredType]
classAllSelIds :: Class -> [Id]
classSCSelId :: Class -> Int -> Id
instance Typeable Class
instance Eq DefMeth
instance Data Class
instance Outputable DefMeth
instance Outputable Class
instance NamedThing Class
instance Uniquable Class
instance Ord Class
instance Eq Class

module NameSet
type NameSet = UniqSet Name
emptyNameSet :: NameSet
unitNameSet :: Name -> NameSet
mkNameSet :: [Name] -> NameSet
unionNameSets :: NameSet -> NameSet -> NameSet
unionManyNameSets :: [NameSet] -> NameSet
minusNameSet :: NameSet -> NameSet -> NameSet
elemNameSet :: Name -> NameSet -> Bool
nameSetToList :: NameSet -> [Name]
addOneToNameSet :: NameSet -> Name -> NameSet
addListToNameSet :: NameSet -> [Name] -> NameSet
delFromNameSet :: NameSet -> Name -> NameSet
delListFromNameSet :: NameSet -> [Name] -> NameSet
isEmptyNameSet :: NameSet -> Bool
foldNameSet :: (Name -> b -> b) -> b -> NameSet -> b
filterNameSet :: (Name -> Bool) -> NameSet -> NameSet

-- | True if there is a non-empty intersection. <tt>s1
--   <a>intersectsNameSet</a> s2</tt> doesn't compute <tt>s2</tt> if
--   <tt>s1</tt> is empty
intersectsNameSet :: NameSet -> NameSet -> Bool
intersectNameSet :: NameSet -> NameSet -> NameSet
type FreeVars = NameSet
isEmptyFVs :: NameSet -> Bool
emptyFVs :: FreeVars
plusFVs :: [FreeVars] -> FreeVars
plusFV :: FreeVars -> FreeVars -> FreeVars
mkFVs :: [Name] -> FreeVars
addOneFV :: FreeVars -> Name -> FreeVars
unitFV :: Name -> FreeVars
delFV :: Name -> FreeVars -> FreeVars
delFVs :: [Name] -> FreeVars -> FreeVars

-- | A set of names that are defined somewhere
type Defs = NameSet

-- | A set of names that are used somewhere
type Uses = NameSet

-- | <tt>(Just ds, us) =&gt;</tt> The use of any member of the <tt>ds</tt>
--   implies that all the <tt>us</tt> are used too. Also, <tt>us</tt> may
--   mention <tt>ds</tt>.
--   
--   <tt>Nothing =&gt;</tt> Nothing is defined in this group, but
--   nevertheless all the uses are essential. Used for instance
--   declarations, for example
type DefUse = (Maybe Defs, Uses)

-- | A number of <a>DefUse</a>s in dependency order: earlier <a>Defs</a>
--   scope over later <a>Uses</a> In a single (def, use) pair, the defs
--   also scope over the uses
type DefUses = [DefUse]
emptyDUs :: DefUses
usesOnly :: Uses -> DefUses
mkDUs :: [(Defs, Uses)] -> DefUses
plusDU :: DefUses -> DefUses -> DefUses

-- | Given some <a>DefUses</a> and some <a>Uses</a>, find all the uses,
--   transitively. The result is a superset of the input <a>Uses</a>; and
--   includes things defined in the input <a>DefUses</a> (but only if they
--   are used)
findUses :: DefUses -> Uses -> Uses
duDefs :: DefUses -> Defs

-- | Collect all <a>Uses</a>, regardless of whether the group is itself
--   used, but remove <a>Defs</a> on the way
duUses :: DefUses -> Uses

-- | Just like <a>duUses</a>, but <a>Defs</a> are not eliminated from the
--   <a>Uses</a> returned
allUses :: DefUses -> Uses

module CostCentre

-- | A Cost Centre is a single <tt>{--}</tt> annotation.
data CostCentre
NormalCC :: {-# UNPACK #-} !Int -> CcName -> Module -> SrcSpan -> IsCafCC -> CostCentre

-- | Two cost centres may have the same name and module but different
--   SrcSpans, so we need a way to distinguish them easily and give them
--   different object-code labels. So every CostCentre has a Unique that is
--   distinct from every other CostCentre in the same module.
--   
--   XXX: should really be using Unique here, but we need to derive Data
--   below and there's no Data instance for Unique.
cc_key :: CostCentre -> {-# UNPACK #-} !Int

-- | Name of the cost centre itself
cc_name :: CostCentre -> CcName

-- | Name of module defining this CC.
cc_mod :: CostCentre -> Module
cc_loc :: CostCentre -> SrcSpan
cc_is_caf :: CostCentre -> IsCafCC
AllCafsCC :: Module -> SrcSpan -> CostCentre

-- | Name of module defining this CC.
cc_mod :: CostCentre -> Module
cc_loc :: CostCentre -> SrcSpan
type CcName = FastString
data IsCafCC
NotCafCC :: IsCafCC
CafCC :: IsCafCC

-- | A Cost Centre Stack is something that can be attached to a closure.
--   This is either:
--   
--   <ul>
--   <li>the current cost centre stack (CCCS) * a pre-defined cost centre
--   stack (there are several pre-defined CCSs, see below).</li>
--   </ul>
data CostCentreStack
type CollectedCCs = ([CostCentre], [CostCentre], [CostCentreStack])
noCCS :: CostCentreStack
currentCCS :: CostCentreStack
dontCareCCS :: CostCentreStack
noCCSAttached :: CostCentreStack -> Bool
isCurrentCCS :: CostCentreStack -> Bool
maybeSingletonCCS :: CostCentreStack -> Maybe CostCentre
mkUserCC :: FastString -> Module -> SrcSpan -> Unique -> CostCentre
mkAutoCC :: Id -> Module -> IsCafCC -> CostCentre
mkAllCafsCC :: Module -> SrcSpan -> CostCentre
mkSingletonCCS :: CostCentre -> CostCentreStack
isCafCCS :: CostCentreStack -> Bool
isCafCC :: CostCentre -> Bool

-- | Is this a cost-centre which records scc counts
isSccCountCC :: CostCentre -> Bool

-- | Is this a cost-centre which can be sccd ?
sccAbleCC :: CostCentre -> Bool
ccFromThisModule :: CostCentre -> Module -> Bool
pprCostCentreCore :: CostCentre -> SDoc
costCentreUserName :: CostCentre -> String
costCentreUserNameFS :: CostCentre -> FastString
costCentreSrcSpan :: CostCentre -> SrcSpan
cmpCostCentre :: CostCentre -> CostCentre -> Ordering
instance Typeable IsCafCC
instance Typeable CostCentre
instance Eq IsCafCC
instance Ord IsCafCC
instance Data IsCafCC
instance Data CostCentre
instance Eq CostCentreStack
instance Ord CostCentreStack
instance Outputable CostCentre
instance Outputable CostCentreStack
instance Ord CostCentre
instance Eq CostCentre


-- | GHC uses several kinds of name internally:
--   
--   <ul>
--   <li><a>OccName</a>: see <a>OccName#name_types</a></li>
--   <li><a>RdrName</a> is the type of names that come directly from the
--   parser. They have not yet had their scoping and binding resolved by
--   the renamer and can be thought of to a first approximation as an
--   <a>OccName</a> with an optional module qualifier</li>
--   <li><a>Name</a>: see <a>Name#name_types</a></li>
--   <li><a>Id</a>: see <a>Id#name_types</a></li>
--   <li><a>Var</a>: see <a>Var#name_types</a></li>
--   </ul>
module RdrName

-- | Do not use the data constructors of RdrName directly: prefer the
--   family of functions that creates them, such as <a>mkRdrUnqual</a>
data RdrName

-- | Used for ordinary, unqualified occurrences, e.g. <tt>x</tt>,
--   <tt>y</tt> or <tt>Foo</tt>. Create such a <a>RdrName</a> with
--   <a>mkRdrUnqual</a>
Unqual :: OccName -> RdrName

-- | A qualified name written by the user in <i>source</i> code. The module
--   isn't necessarily the module where the thing is defined; just the one
--   from which it is imported. Examples are <tt>Bar.x</tt>, <tt>Bar.y</tt>
--   or <tt>Bar.Foo</tt>. Create such a <a>RdrName</a> with
--   <a>mkRdrQual</a>
Qual :: ModuleName -> OccName -> RdrName

-- | An original name; the module is the <i>defining</i> module. This is
--   used when GHC generates code that will be fed into the renamer (e.g.
--   from deriving clauses), but where we want to say "Use Prelude.map
--   dammit". One of these can be created with <a>mkOrig</a>
Orig :: Module -> OccName -> RdrName

-- | We know exactly the <a>Name</a>. This is used:
--   
--   <ol>
--   <li>When the parser parses built-in syntax like <tt>[]</tt> and
--   <tt>(,)</tt>, but wants a <a>RdrName</a> from it</li>
--   <li>By Template Haskell, when TH has generated a unique name</li>
--   </ol>
--   
--   Such a <a>RdrName</a> can be created by using <a>getRdrName</a> on a
--   <a>Name</a>
Exact :: Name -> RdrName
mkRdrUnqual :: OccName -> RdrName
mkRdrQual :: ModuleName -> OccName -> RdrName
mkUnqual :: NameSpace -> FastString -> RdrName
mkVarUnqual :: FastString -> RdrName

-- | Make a qualified <a>RdrName</a> in the given namespace and where the
--   <a>ModuleName</a> and the <a>OccName</a> are taken from the first and
--   second elements of the tuple respectively
mkQual :: NameSpace -> (FastString, FastString) -> RdrName
mkOrig :: Module -> OccName -> RdrName
nameRdrName :: Name -> RdrName
getRdrName :: NamedThing thing => thing -> RdrName
rdrNameOcc :: RdrName -> OccName
rdrNameSpace :: RdrName -> NameSpace

-- | This rather gruesome function is used mainly by the parser. When
--   parsing:
--   
--   <pre>
--   data T a = T | T1 Int
--   </pre>
--   
--   we parse the data constructors as <i>types</i> because of parser
--   ambiguities, so then we need to change the <i>type constr</i> to a
--   <i>data constr</i>
--   
--   The exact-name case <i>can</i> occur when parsing:
--   
--   <pre>
--   data [] a = [] | a : [a]
--   </pre>
--   
--   For the exact-name case we return an original name.
setRdrNameSpace :: RdrName -> NameSpace -> RdrName
demoteRdrName :: RdrName -> Maybe RdrName
isRdrDataCon :: RdrName -> Bool
isRdrTyVar :: RdrName -> Bool
isRdrTc :: RdrName -> Bool
isQual :: RdrName -> Bool
isQual_maybe :: RdrName -> Maybe (ModuleName, OccName)
isUnqual :: RdrName -> Bool
isOrig :: RdrName -> Bool
isOrig_maybe :: RdrName -> Maybe (Module, OccName)
isExact :: RdrName -> Bool
isExact_maybe :: RdrName -> Maybe Name
isSrcRdrName :: RdrName -> Bool

-- | This environment is used to store local bindings (<tt>let</tt>,
--   <tt>where</tt>, lambda, <tt>case</tt>). It is keyed by OccName,
--   because we never use it for qualified names We keep the current
--   mapping, *and* the set of all Names in scope Reason: see Note
--   [Splicing Exact Names] in RnEnv
type LocalRdrEnv = (OccEnv Name, NameSet)
emptyLocalRdrEnv :: LocalRdrEnv
extendLocalRdrEnv :: LocalRdrEnv -> Name -> LocalRdrEnv
extendLocalRdrEnvList :: LocalRdrEnv -> [Name] -> LocalRdrEnv
lookupLocalRdrEnv :: LocalRdrEnv -> RdrName -> Maybe Name
lookupLocalRdrOcc :: LocalRdrEnv -> OccName -> Maybe Name
elemLocalRdrEnv :: RdrName -> LocalRdrEnv -> Bool
inLocalRdrEnvScope :: Name -> LocalRdrEnv -> Bool
localRdrEnvElts :: LocalRdrEnv -> [Name]
delLocalRdrEnvList :: LocalRdrEnv -> [OccName] -> LocalRdrEnv

-- | Keyed by <a>OccName</a>; when looking up a qualified name we look up
--   the <a>OccName</a> part, and then check the <a>Provenance</a> to see
--   if the appropriate qualification is valid. This saves routinely
--   doubling the size of the env by adding both qualified and unqualified
--   names to the domain.
--   
--   The list in the codomain is required because there may be name clashes
--   These only get reported on lookup, not on construction
--   
--   INVARIANT: All the members of the list have distinct <a>gre_name</a>
--   fields; that is, no duplicate Names
--   
--   INVARIANT: Imported provenance =&gt; Name is an ExternalName However
--   LocalDefs can have an InternalName. This happens only when
--   type-checking a [d| ... |] Template Haskell quotation; see this note
--   in RnNames Note [Top-level Names in Template Haskell decl quotes]
type GlobalRdrEnv = OccEnv [GlobalRdrElt]
emptyGlobalRdrEnv :: GlobalRdrEnv
mkGlobalRdrEnv :: [GlobalRdrElt] -> GlobalRdrEnv
plusGlobalRdrEnv :: GlobalRdrEnv -> GlobalRdrEnv -> GlobalRdrEnv
lookupGlobalRdrEnv :: GlobalRdrEnv -> OccName -> [GlobalRdrElt]
extendGlobalRdrEnv :: GlobalRdrEnv -> GlobalRdrElt -> GlobalRdrEnv
pprGlobalRdrEnv :: GlobalRdrEnv -> SDoc
globalRdrEnvElts :: GlobalRdrEnv -> [GlobalRdrElt]
lookupGRE_RdrName :: RdrName -> GlobalRdrEnv -> [GlobalRdrElt]
lookupGRE_Name :: GlobalRdrEnv -> Name -> [GlobalRdrElt]
getGRE_NameQualifier_maybes :: GlobalRdrEnv -> Name -> [Maybe [ModuleName]]

-- | Apply a transformation function to the GREs for these OccNames
transformGREs :: (GlobalRdrElt -> GlobalRdrElt) -> [OccName] -> GlobalRdrEnv -> GlobalRdrEnv

-- | For each <a>OccName</a>, see if there are multiple local definitions
--   for it; return a list of all such and return a list of the duplicate
--   bindings
findLocalDupsRdrEnv :: GlobalRdrEnv -> [OccName] -> [[Name]]

-- | Take a list of GREs which have the right OccName Pick those GREs that
--   are suitable for this RdrName And for those, keep only only the
--   Provenances that are suitable Only used for Qual and Unqual, not Orig
--   or Exact
--   
--   Consider:
--   
--   <pre>
--   module A ( f ) where
--   import qualified Foo( f )
--   import Baz( f )
--   f = undefined
--   </pre>
--   
--   Let's suppose that <tt>Foo.f</tt> and <tt>Baz.f</tt> are the same
--   entity really. The export of <tt>f</tt> is ambiguous because it's in
--   scope from the local def and the import. The lookup of <tt>Unqual
--   f</tt> should return a GRE for the locally-defined <tt>f</tt>, and a
--   GRE for the imported <tt>f</tt>, with a <i>single</i> provenance,
--   namely the one for <tt>Baz(f)</tt>.
pickGREs :: RdrName -> [GlobalRdrElt] -> [GlobalRdrElt]

-- | An element of the <a>GlobalRdrEnv</a>
data GlobalRdrElt
GRE :: Name -> Parent -> Provenance -> GlobalRdrElt
gre_name :: GlobalRdrElt -> Name
gre_par :: GlobalRdrElt -> Parent

-- | Why it's in scope
gre_prov :: GlobalRdrElt -> Provenance
isLocalGRE :: GlobalRdrElt -> Bool

-- | Test if an unqualifed version of this thing would be in scope
unQualOK :: GlobalRdrElt -> Bool

-- | Is in scope qualified with the given module?
qualSpecOK :: ModuleName -> ImportSpec -> Bool

-- | Is in scope unqualified?
unQualSpecOK :: ImportSpec -> Bool

-- | The <a>Provenance</a> of something says how it came to be in scope.
--   It's quite elaborate so that we can give accurate unused-name
--   warnings.
data Provenance

-- | The thing was defined locally
LocalDef :: Provenance

-- | The thing was imported.
--   
--   INVARIANT: the list of <a>ImportSpec</a> is non-empty
Imported :: [ImportSpec] -> Provenance

-- | Print out the place where the name was imported
pprNameProvenance :: GlobalRdrElt -> SDoc

-- | The children of a Name are the things that are abbreviated by the
--   <a>..</a> notation in export lists. See Note [Parents]
data Parent
NoParent :: Parent
ParentIs :: Name -> Parent
data ImportSpec
ImpSpec :: ImpDeclSpec -> ImpItemSpec -> ImportSpec
is_decl :: ImportSpec -> ImpDeclSpec
is_item :: ImportSpec -> ImpItemSpec

-- | Describes a particular import declaration and is shared among all the
--   <a>Provenance</a>s for that decl
data ImpDeclSpec
ImpDeclSpec :: ModuleName -> ModuleName -> Bool -> SrcSpan -> ImpDeclSpec

-- | Module imported, e.g. <tt>import Muggle</tt> Note the <tt>Muggle</tt>
--   may well not be the defining module for this thing!
is_mod :: ImpDeclSpec -> ModuleName

-- | Import alias, e.g. from <tt>as M</tt> (or <tt>Muggle</tt> if there is
--   no <tt>as</tt> clause)
is_as :: ImpDeclSpec -> ModuleName

-- | Was this import qualified?
is_qual :: ImpDeclSpec -> Bool

-- | The location of the entire import declaration
is_dloc :: ImpDeclSpec -> SrcSpan

-- | Describes import info a particular Name
data ImpItemSpec

-- | The import had no import list, or had a hiding list
ImpAll :: ImpItemSpec

-- | The import had an import list. The <a>is_explicit</a> field is
--   <tt>True</tt> iff the thing was named <i>explicitly</i> in the import
--   specs rather than being imported as part of a <a>...</a> group.
--   Consider:
--   
--   <pre>
--   import C( T(..) )
--   </pre>
--   
--   Here the constructors of <tt>T</tt> are not named explicitly; only
--   <tt>T</tt> is named explicitly.
ImpSome :: Bool -> SrcSpan -> ImpItemSpec
is_explicit :: ImpItemSpec -> Bool
is_iloc :: ImpItemSpec -> SrcSpan
importSpecLoc :: ImportSpec -> SrcSpan
importSpecModule :: ImportSpec -> ModuleName
isExplicitItem :: ImpItemSpec -> Bool
instance Typeable RdrName
instance Data RdrName
instance Eq Parent
instance Eq ImportSpec
instance Ord ImportSpec
instance Outputable ImportSpec
instance Ord ImpItemSpec
instance Ord ImpDeclSpec
instance Ord Provenance
instance Eq ImpItemSpec
instance Eq ImpDeclSpec
instance Eq Provenance
instance Outputable GlobalRdrElt
instance Outputable Parent
instance Ord RdrName
instance Eq RdrName
instance OutputableBndr RdrName
instance Outputable RdrName
instance HasOccName RdrName

module PrelNames

-- | The type of unique identifiers that are used in many places in GHC for
--   fast ordering and equality tests. You should generate these with the
--   functions from the <tt>UniqSupply</tt> module
data Unique

-- | Class of things that we can obtain a <a>Unique</a> from
class Uniquable a
getUnique :: Uniquable a => a -> Unique
hasKey :: Uniquable a => a -> Unique -> Bool
itName :: Unique -> SrcSpan -> Name
mkUnboundName :: RdrName -> Name
isUnboundName :: Name -> Bool
basicKnownKeyNames :: [Name]
genericTyConNames :: [Name]
pRELUDE :: Module
gHC_PRIM :: Module
gHC_IP :: Module
gHC_TYPELITS :: Module
cONTROL_EXCEPTION_BASE :: Module
gHC_EXTS :: Module
rANDOM :: Module
gHC_DESUGAR :: Module
cONTROL_APPLICATIVE :: Module
aRROW :: Module
mONAD_ZIP :: Module
mONAD_FIX :: Module
mONAD :: Module
gHC_WORD :: Module
gHC_INT :: Module
lEX :: Module
rEAD_PREC :: Module
dOTNET :: Module
gENERICS :: Module
tYPEABLE_INTERNAL :: Module
tYPEABLE :: Module
dYNAMIC :: Module
sYSTEM_IO :: Module
gHC_TOP_HANDLER :: Module
gHC_FLOAT :: Module
gHC_REAL :: Module
gHC_ERR :: Module
gHC_PTR :: Module
gHC_STABLE :: Module
gHC_ARR :: Module
gHC_ST :: Module
gHC_IO_Exception :: Module
gHC_IO :: Module
gHC_CONC :: Module
dATA_TRAVERSABLE :: Module
dATA_FOLDABLE :: Module
dATA_STRING :: Module
dATA_EITHER :: Module
dATA_TUPLE :: Module
gHC_TUPLE :: Module
gHC_LIST :: Module
gHC_INTEGER_TYPE :: Module
gHC_NUM :: Module
gHC_READ :: Module
gHC_SHOW :: Module
gHC_CSTRING :: Module
gHC_GHCI :: Module
gHC_ENUM :: Module
gHC_BASE :: Module
gHC_CLASSES :: Module
gHC_MAGIC :: Module
gHC_GENERICS :: Module
gHC_TYPES :: Module
gHC_PARR' :: Module
mAIN :: Module
rOOT_MAIN :: Module
iNTERACTIVE :: Module
pRELUDE_NAME :: ModuleName
mAIN_NAME :: ModuleName
dATA_ARRAY_PARALLEL_NAME :: ModuleName
dATA_ARRAY_PARALLEL_PRIM_NAME :: ModuleName
mkPrimModule :: FastString -> Module
mkIntegerModule :: FastString -> Module
mkBaseModule :: FastString -> Module
mkBaseModule_ :: ModuleName -> Module
mkThisGhcModule :: FastString -> Module
mkThisGhcModule_ :: ModuleName -> Module
mkMainModule :: FastString -> Module
mkMainModule_ :: ModuleName -> Module
mkTupleModule :: TupleSort -> Arity -> Module
main_RDR_Unqual :: RdrName
forall_tv_RDR :: RdrName
dot_tv_RDR :: RdrName
eq_RDR :: RdrName
gtTag_RDR :: RdrName
eqTag_RDR :: RdrName
ltTag_RDR :: RdrName
compare_RDR :: RdrName
gt_RDR :: RdrName
lt_RDR :: RdrName
le_RDR :: RdrName
ne_RDR :: RdrName
ge_RDR :: RdrName
eqClass_RDR :: RdrName
monadClass_RDR :: RdrName
enumClass_RDR :: RdrName
ordClass_RDR :: RdrName
numClass_RDR :: RdrName
map_RDR :: RdrName
append_RDR :: RdrName
foldr_RDR :: RdrName
failM_RDR :: RdrName
bindM_RDR :: RdrName
returnM_RDR :: RdrName
build_RDR :: RdrName
left_RDR :: RdrName
right_RDR :: RdrName
fromEnum_RDR :: RdrName
toEnum_RDR :: RdrName
enumFrom_RDR :: RdrName
enumFromThenTo_RDR :: RdrName
enumFromThen_RDR :: RdrName
enumFromTo_RDR :: RdrName
ratioDataCon_RDR :: RdrName
timesInteger_RDR :: RdrName
plusInteger_RDR :: RdrName
ioDataCon_RDR :: RdrName
eqString_RDR :: RdrName
unpackCStringUtf8_RDR :: RdrName
unpackCStringFoldr_RDR :: RdrName
unpackCString_RDR :: RdrName
newStablePtr_RDR :: RdrName
wordDataCon_RDR :: RdrName
bindIO_RDR :: RdrName
returnIO_RDR :: RdrName
fromInteger_RDR :: RdrName
plus_RDR :: RdrName
times_RDR :: RdrName
minus_RDR :: RdrName
fromRational_RDR :: RdrName
fromString_RDR :: RdrName
compose_RDR :: RdrName
not_RDR :: RdrName
unsafeRangeSize_RDR :: RdrName
unsafeIndex_RDR :: RdrName
index_RDR :: RdrName
inRange_RDR :: RdrName
range_RDR :: RdrName
and_RDR :: RdrName
maxBound_RDR :: RdrName
minBound_RDR :: RdrName
pred_RDR :: RdrName
succ_RDR :: RdrName
getTag_RDR :: RdrName
readList_RDR :: RdrName
lexP_RDR :: RdrName
choose_RDR :: RdrName
parens_RDR :: RdrName
readPrec_RDR :: RdrName
readListPrecDefault_RDR :: RdrName
readListPrec_RDR :: RdrName
readListDefault_RDR :: RdrName
punc_RDR :: RdrName
symbol_RDR :: RdrName
ident_RDR :: RdrName
step_RDR :: RdrName
prec_RDR :: RdrName
reset_RDR :: RdrName
alt_RDR :: RdrName
showList_RDR :: RdrName
showParen_RDR :: RdrName
showSpace_RDR :: RdrName
showString_RDR :: RdrName
showsPrec_RDR :: RdrName
showList___RDR :: RdrName
typeOf_RDR :: RdrName
mkTyConApp_RDR :: RdrName
mkTyCon_RDR :: RdrName
undefined_RDR :: RdrName
error_RDR :: RdrName
u1DataCon_RDR :: RdrName
notAssocDataCon_RDR :: RdrName
rightAssocDataCon_RDR :: RdrName
leftAssocDataCon_RDR :: RdrName
infixDataCon_RDR :: RdrName
prefixDataCon_RDR :: RdrName
selName_RDR :: RdrName
arityDataCon_RDR :: RdrName
noArityDataCon_RDR :: RdrName
conIsRecord_RDR :: RdrName
conFixity_RDR :: RdrName
conName_RDR :: RdrName
moduleName_RDR :: RdrName
datatypeName_RDR :: RdrName
to1_RDR :: RdrName
to_RDR :: RdrName
from1_RDR :: RdrName
from_RDR :: RdrName
unComp1_RDR :: RdrName
unK1_RDR :: RdrName
unRec1_RDR :: RdrName
unPar1_RDR :: RdrName
comp1DataCon_RDR :: RdrName
prodDataCon_RDR :: RdrName
r1DataCon_RDR :: RdrName
l1DataCon_RDR :: RdrName
m1DataCon_RDR :: RdrName
k1DataCon_RDR :: RdrName
rec1DataCon_RDR :: RdrName
par1DataCon_RDR :: RdrName
fmap_RDR :: RdrName
traverse_RDR :: RdrName
foldable_foldr_RDR :: RdrName
ap_RDR :: RdrName
pure_RDR :: RdrName
varQual_RDR :: Module -> FastString -> RdrName
dataQual_RDR :: Module -> FastString -> RdrName
clsQual_RDR :: Module -> FastString -> RdrName
tcQual_RDR :: Module -> FastString -> RdrName
wildCardName :: Name
runMainIOName :: Name
orderingTyConName :: Name
gtDataConName :: Name
eqDataConName :: Name
ltDataConName :: Name
eitherTyConName :: Name
rightDataConName :: Name
leftDataConName :: Name
v1TyConName :: Name
rep1TyConName :: Name
repTyConName :: Name
noSelTyConName :: Name
s1TyConName :: Name
c1TyConName :: Name
d1TyConName :: Name
par0TyConName :: Name
rec0TyConName :: Name
sTyConName :: Name
cTyConName :: Name
dTyConName :: Name
pTyConName :: Name
rTyConName :: Name
compTyConName :: Name
prodTyConName :: Name
sumTyConName :: Name
m1TyConName :: Name
k1TyConName :: Name
rec1TyConName :: Name
par1TyConName :: Name
u1TyConName :: Name
unpackCStringName :: Name
stringTyConName :: Name
eqStringName :: Name
unpackCStringUtf8Name :: Name
unpackCStringFoldrName :: Name
inlineIdName :: Name
undefinedName :: Name
fmapName :: Name
functorClassName :: Name
geName :: Name
ordClassName :: Name
eqName :: Name
eqClassName :: Name
monadClassName :: Name
failMName :: Name
returnMName :: Name
bindMName :: Name
thenMName :: Name
applicativeClassName :: Name
traversableClassName :: Name
foldableClassName :: Name
groupWithName :: Name
fromStringName :: Name
opaqueTyConName :: Name
dollarName :: Name
breakpointAutoName :: Name
breakpointCondName :: Name
breakpointName :: Name
assertName :: Name
appendName :: Name
mapName :: Name
augmentName :: Name
buildName :: Name
foldrName :: Name
otherwiseIdName :: Name
breakpointJumpName :: Name
breakpointCondJumpName :: Name
breakpointAutoJumpName :: Name
fstName :: Name
sndName :: Name
numClassName :: Name
negateName :: Name
minusName :: Name
fromIntegerName :: Name
integerTyConName :: Name
shiftRIntegerName :: Name
shiftLIntegerName :: Name
complementIntegerName :: Name
xorIntegerName :: Name
orIntegerName :: Name
andIntegerName :: Name
lcmIntegerName :: Name
gcdIntegerName :: Name
decodeDoubleIntegerName :: Name
encodeDoubleIntegerName :: Name
encodeFloatIntegerName :: Name
doubleFromIntegerName :: Name
floatFromIntegerName :: Name
remIntegerName :: Name
quotIntegerName :: Name
divModIntegerName :: Name
quotRemIntegerName :: Name
compareIntegerName :: Name
geIntegerName :: Name
ltIntegerName :: Name
gtIntegerName :: Name
leIntegerName :: Name
signumIntegerName :: Name
absIntegerName :: Name
neqIntegerName :: Name
eqIntegerName :: Name
negateIntegerName :: Name
minusIntegerName :: Name
integerToIntName :: Name
integerToWordName :: Name
wordToIntegerName :: Name
smallIntegerName :: Name
timesIntegerName :: Name
plusIntegerName :: Name
int64ToIntegerName :: Name
word64ToIntegerName :: Name
integerToInt64Name :: Name
integerToWord64Name :: Name
mkIntegerName :: Name
rationalTyConName :: Name
realToFracName :: Name
fromIntegralName :: Name
toRationalName :: Name
toIntegerName :: Name
fromRationalName :: Name
fractionalClassName :: Name
realFracClassName :: Name
integralClassName :: Name
realClassName :: Name
ratioDataConName :: Name
ratioTyConName :: Name
floatingClassName :: Name
realFloatClassName :: Name
ixClassName :: Name
typeableClassName :: Name
typeable7ClassName :: Name
typeable6ClassName :: Name
typeable5ClassName :: Name
typeable4ClassName :: Name
typeable3ClassName :: Name
typeable2ClassName :: Name
typeable1ClassName :: Name
typeableClassNames :: [Name]
dataClassName :: Name
assertErrorName :: Name
enumClassName :: Name
boundedClassName :: Name
enumFromThenToName :: Name
enumFromThenName :: Name
enumFromToName :: Name
enumFromName :: Name
concatName :: Name
zipName :: Name
filterName :: Name
showClassName :: Name
readClassName :: Name
genClassName :: Name
selectorClassName :: Name
constructorClassName :: Name
datatypeClassName :: Name
gen1ClassName :: Name
ghciIoClassName :: Name
ghciStepIoMName :: Name
ioTyConName :: Name
failIOName :: Name
returnIOName :: Name
bindIOName :: Name
thenIOName :: Name
ioDataConName :: Name
printName :: Name
int8TyConName :: Name
int64TyConName :: Name
int32TyConName :: Name
int16TyConName :: Name
word8TyConName :: Name
wordDataConName :: Name
wordTyConName :: Name
word64TyConName :: Name
word32TyConName :: Name
word16TyConName :: Name
ptrTyConName :: Name
funPtrTyConName :: Name
stablePtrTyConName :: Name
newStablePtrName :: Name
runSTRepName :: Name
monadFixClassName :: Name
mfixName :: Name
arrAName :: Name
loopAName :: Name
choiceAName :: Name
appAName :: Name
firstAName :: Name
composeAName :: Name
guardMName :: Name
mzipName :: Name
liftMName :: Name
toAnnotationWrapperName :: Name
monadPlusClassName :: Name
isStringClassName :: Name
randomGenClassName :: Name
randomClassName :: Name
typeNatKindConName :: Name
typeNatExpTyFamName :: Name
typeNatMulTyFamName :: Name
typeNatAddTyFamName :: Name
typeNatLeqClassName :: Name
singIClassName :: Name
typeStringKindConName :: Name
ipClassName :: Name
objectTyConName :: Name
unmarshalObjectName :: Name
checkDotnetResName :: Name
unmarshalStringName :: Name
marshalStringName :: Name
marshalObjectName :: Name
cORE_MONAD :: Module
pluginTyConName :: Name
varQual :: Module -> FastString -> Unique -> Name
clsQual :: Module -> FastString -> Unique -> Name
tcQual :: Module -> FastString -> Unique -> Name
mk_known_key_name :: NameSpace -> Module -> FastString -> Unique -> Name
conName :: Module -> FastString -> Unique -> Name
methName :: Module -> FastString -> Unique -> Name
boundedClassKey :: Unique
ixClassKey :: Unique
showClassKey :: Unique
realFracClassKey :: Unique
realFloatClassKey :: Unique
realClassKey :: Unique
readClassKey :: Unique
ordClassKey :: Unique
numClassKey :: Unique
functorClassKey :: Unique
dataClassKey :: Unique
monadClassKey :: Unique
integralClassKey :: Unique
fractionalClassKey :: Unique
floatingClassKey :: Unique
eqClassKey :: Unique
enumClassKey :: Unique
typeableClassKey :: Unique
typeable7ClassKey :: Unique
typeable6ClassKey :: Unique
typeable5ClassKey :: Unique
typeable4ClassKey :: Unique
typeable3ClassKey :: Unique
typeable2ClassKey :: Unique
typeable1ClassKey :: Unique
monadFixClassKey :: Unique
monadPlusClassKey :: Unique
randomGenClassKey :: Unique
randomClassKey :: Unique
isStringClassKey :: Unique
applicativeClassKey :: Unique
traversableClassKey :: Unique
foldableClassKey :: Unique
genClassKey :: Unique
selectorClassKey :: Unique
constructorClassKey :: Unique
datatypeClassKey :: Unique
gen1ClassKey :: Unique
singIClassNameKey :: Unique
typeNatLeqClassNameKey :: Unique
ghciIoClassKey :: Unique
ipClassNameKey :: Unique
addrPrimTyConKey :: Unique
eqTyConKey :: Unique
anyTyConKey :: Unique
stablePtrTyConKey :: Unique
stablePtrPrimTyConKey :: Unique
realWorldTyConKey :: Unique
rationalTyConKey :: Unique
ratioTyConKey :: Unique
mVarPrimTyConKey :: Unique
orderingTyConKey :: Unique
mutableByteArrayPrimTyConKey :: Unique
mutableArrayArrayPrimTyConKey :: Unique
mutableArrayPrimTyConKey :: Unique
weakPrimTyConKey :: Unique
foreignObjPrimTyConKey :: Unique
listTyConKey :: Unique
digitsTyConKey :: Unique
integerTyConKey :: Unique
int64TyConKey :: Unique
int64PrimTyConKey :: Unique
int32TyConKey :: Unique
int32PrimTyConKey :: Unique
int16TyConKey :: Unique
int8TyConKey :: Unique
intTyConKey :: Unique
intPrimTyConKey :: Unique
funTyConKey :: Unique
floatTyConKey :: Unique
floatPrimTyConKey :: Unique
doubleTyConKey :: Unique
doublePrimTyConKey :: Unique
charTyConKey :: Unique
charPrimTyConKey :: Unique
byteArrayPrimTyConKey :: Unique
boolTyConKey :: Unique
arrayArrayPrimTyConKey :: Unique
arrayPrimTyConKey :: Unique
statePrimTyConKey :: Unique
eqPrimTyConKey :: Unique
tVarPrimTyConKey :: Unique
funPtrTyConKey :: Unique
ptrTyConKey :: Unique
bcoPrimTyConKey :: Unique
threadIdPrimTyConKey :: Unique
typeConKey :: Unique
boxityConKey :: Unique
kindConKey :: Unique
anyBoxConKey :: Unique
unliftedConKey :: Unique
liftedConKey :: Unique
word64TyConKey :: Unique
word64PrimTyConKey :: Unique
word32TyConKey :: Unique
word32PrimTyConKey :: Unique
word16TyConKey :: Unique
word8TyConKey :: Unique
wordTyConKey :: Unique
wordPrimTyConKey :: Unique
ioTyConKey :: Unique
mutVarPrimTyConKey :: Unique
stableNameTyConKey :: Unique
stableNamePrimTyConKey :: Unique
parrTyConKey :: Unique
objectTyConKey :: Unique
eitherTyConKey :: Unique
superKindTyConKey :: Unique
liftedTypeKindTyConKey :: Unique
constraintKindTyConKey :: Unique
unliftedTypeKindTyConKey :: Unique
openTypeKindTyConKey :: Unique
anyKindTyConKey :: Unique
symCoercionTyConKey :: Unique
cselRCoercionTyConKey :: Unique
csel2CoercionTyConKey :: Unique
csel1CoercionTyConKey :: Unique
unsafeCoercionTyConKey :: Unique
instCoercionTyConKey :: Unique
rightCoercionTyConKey :: Unique
leftCoercionTyConKey :: Unique
transCoercionTyConKey :: Unique
pluginTyConKey :: Unique
unknownTyConKey :: Unique
opaqueTyConKey :: Unique
unknown3TyConKey :: Unique
unknown2TyConKey :: Unique
unknown1TyConKey :: Unique
stringTyConKey :: Unique
v1TyConKey :: Unique
rep1TyConKey :: Unique
repTyConKey :: Unique
noSelTyConKey :: Unique
s1TyConKey :: Unique
c1TyConKey :: Unique
d1TyConKey :: Unique
par0TyConKey :: Unique
rec0TyConKey :: Unique
sTyConKey :: Unique
cTyConKey :: Unique
dTyConKey :: Unique
pTyConKey :: Unique
rTyConKey :: Unique
compTyConKey :: Unique
prodTyConKey :: Unique
sumTyConKey :: Unique
m1TyConKey :: Unique
k1TyConKey :: Unique
rec1TyConKey :: Unique
par1TyConKey :: Unique
u1TyConKey :: Unique
typeNatKindConNameKey :: Unique
typeNatExpTyFamNameKey :: Unique
typeNatMulTyFamNameKey :: Unique
typeNatAddTyFamNameKey :: Unique
typeStringKindConNameKey :: Unique
unitTyConKey :: Unique
charDataConKey :: Unique
eqBoxDataConKey :: Unique
integerDataConKey :: Unique
ioDataConKey :: Unique
wordDataConKey :: Unique
trueDataConKey :: Unique
stableNameDataConKey :: Unique
ratioDataConKey :: Unique
nilDataConKey :: Unique
intDataConKey :: Unique
floatDataConKey :: Unique
falseDataConKey :: Unique
doubleDataConKey :: Unique
consDataConKey :: Unique
crossDataConKey :: Unique
genUnitDataConKey :: Unique
inrDataConKey :: Unique
inlDataConKey :: Unique
parrDataConKey :: Unique
leftDataConKey :: Unique
rightDataConKey :: Unique
ltDataConKey :: Unique
gtDataConKey :: Unique
eqDataConKey :: Unique
integerGmpSDataConKey :: Unique
integerGmpJDataConKey :: Unique
wildCardKey :: Unique
unpackCStringIdKey :: Unique
unpackCStringFoldrIdKey :: Unique
unpackCStringAppendIdKey :: Unique
unpackCStringUtf8IdKey :: Unique
recConErrorIdKey :: Unique
realWorldPrimIdKey :: Unique
patErrorIdKey :: Unique
runtimeErrorIdKey :: Unique
nonExhaustiveGuardsErrorIdKey :: Unique
noMethodBindingErrorIdKey :: Unique
eqStringIdKey :: Unique
irrefutPatErrorIdKey :: Unique
seqIdKey :: Unique
recSelErrorIdKey :: Unique
foldrIdKey :: Unique
errorIdKey :: Unique
buildIdKey :: Unique
appendIdKey :: Unique
augmentIdKey :: Unique
absentErrorIdKey :: Unique
unsafeCoerceIdKey :: Unique
runSTRepIdKey :: Unique
assertIdKey :: Unique
otherwiseIdKey :: Unique
sndIdKey :: Unique
fstIdKey :: Unique
voidArgIdKey :: Unique
nullAddrIdKey :: Unique
failIOIdKey :: Unique
printIdKey :: Unique
newStablePtrIdKey :: Unique
returnIOIdKey :: Unique
bindIOIdKey :: Unique
zipIdKey :: Unique
filterIdKey :: Unique
concatIdKey :: Unique
mkIntegerIdKey :: Unique
shiftRIntegerIdKey :: Unique
shiftLIntegerIdKey :: Unique
complementIntegerIdKey :: Unique
xorIntegerIdKey :: Unique
orIntegerIdKey :: Unique
andIntegerIdKey :: Unique
lcmIntegerIdKey :: Unique
gcdIntegerIdKey :: Unique
decodeDoubleIntegerIdKey :: Unique
encodeDoubleIntegerIdKey :: Unique
encodeFloatIntegerIdKey :: Unique
doubleFromIntegerIdKey :: Unique
floatFromIntegerIdKey :: Unique
remIntegerIdKey :: Unique
quotIntegerIdKey :: Unique
divModIntegerIdKey :: Unique
quotRemIntegerIdKey :: Unique
compareIntegerIdKey :: Unique
geIntegerIdKey :: Unique
ltIntegerIdKey :: Unique
gtIntegerIdKey :: Unique
leIntegerIdKey :: Unique
signumIntegerIdKey :: Unique
absIntegerIdKey :: Unique
neqIntegerIdKey :: Unique
eqIntegerIdKey :: Unique
negateIntegerIdKey :: Unique
minusIntegerIdKey :: Unique
timesIntegerIdKey :: Unique
plusIntegerIdKey :: Unique
int64ToIntegerIdKey :: Unique
word64ToIntegerIdKey :: Unique
integerToInt64IdKey :: Unique
integerToWord64IdKey :: Unique
integerToIntIdKey :: Unique
integerToWordIdKey :: Unique
wordToIntegerIdKey :: Unique
smallIntegerIdKey :: Unique
rootMainKey :: Unique
runMainKey :: Unique
thenIOIdKey :: Unique
assertErrorIdKey :: Unique
lazyIdKey :: Unique
breakpointIdKey :: Unique
breakpointAutoJumpIdKey :: Unique
breakpointCondJumpIdKey :: Unique
breakpointJumpIdKey :: Unique
breakpointAutoIdKey :: Unique
breakpointCondIdKey :: Unique
inlineIdKey :: Unique
mapIdKey :: Unique
dollarIdKey :: Unique
groupWithIdKey :: Unique
coercionTokenIdKey :: Unique
unmarshalObjectIdKey :: Unique
checkDotnetResNameIdKey :: Unique
unmarshalStringIdKey :: Unique
marshalStringIdKey :: Unique
marshalObjectIdKey :: Unique
undefinedKey :: Unique
unboundKey :: Unique
fromIntegerClassOpKey :: Unique
fmapClassOpKey :: Unique
returnMClassOpKey :: Unique
thenMClassOpKey :: Unique
bindMClassOpKey :: Unique
failMClassOpKey :: Unique
negateClassOpKey :: Unique
geClassOpKey :: Unique
eqClassOpKey :: Unique
enumFromThenToClassOpKey :: Unique
enumFromToClassOpKey :: Unique
enumFromThenClassOpKey :: Unique
enumFromClassOpKey :: Unique
fromRationalClassOpKey :: Unique
minusClassOpKey :: Unique
mfixIdKey :: Unique
arrAIdKey :: Unique
loopAIdKey :: Unique
choiceAIdKey :: Unique
appAIdKey :: Unique
firstAIdKey :: Unique
composeAIdKey :: Unique
fromStringClassOpKey :: Unique
toAnnotationWrapperIdKey :: Unique
fromIntegralIdKey :: Unique
toRationalClassOpKey :: Unique
toIntegerClassOpKey :: Unique
realToFracIdKey :: Unique
guardMIdKey :: Unique
mzipIdKey :: Unique
liftMIdKey :: Unique
ghciStepIoMClassOpKey :: Unique
numericClassKeys :: [Unique]
fractionalClassKeys :: [Unique]
standardClassKeys :: [Unique]
derivableClassKeys :: [Unique]


-- | Package configuration information: essentially the interface to Cabal,
--   with some utilities
--   
--   (c) The University of Glasgow, 2004
module PackageConfig

-- | Turn a Cabal <a>PackageIdentifier</a> into a GHC <a>PackageId</a>
mkPackageId :: PackageIdentifier -> PackageId

-- | Get the GHC <a>PackageId</a> right out of a Cabalish
--   <a>PackageConfig</a>
packageConfigId :: PackageConfig -> PackageId
type PackageConfig = InstalledPackageInfo_ ModuleName
data InstalledPackageInfo_ m :: * -> *
InstalledPackageInfo :: InstalledPackageId -> PackageId -> License -> String -> String -> String -> String -> String -> String -> String -> String -> String -> Bool -> [m] -> [m] -> Bool -> [FilePath] -> [FilePath] -> [String] -> [String] -> [String] -> [FilePath] -> [String] -> [InstalledPackageId] -> [String] -> [String] -> [String] -> [FilePath] -> [String] -> [FilePath] -> [FilePath] -> InstalledPackageInfo_ m
installedPackageId :: InstalledPackageInfo_ m -> InstalledPackageId
sourcePackageId :: InstalledPackageInfo_ m -> PackageId
license :: InstalledPackageInfo_ m -> License
copyright :: InstalledPackageInfo_ m -> String
maintainer :: InstalledPackageInfo_ m -> String
author :: InstalledPackageInfo_ m -> String
stability :: InstalledPackageInfo_ m -> String
homepage :: InstalledPackageInfo_ m -> String
pkgUrl :: InstalledPackageInfo_ m -> String
synopsis :: InstalledPackageInfo_ m -> String
description :: InstalledPackageInfo_ m -> String
category :: InstalledPackageInfo_ m -> String
exposed :: InstalledPackageInfo_ m -> Bool
exposedModules :: InstalledPackageInfo_ m -> [m]
hiddenModules :: InstalledPackageInfo_ m -> [m]
trusted :: InstalledPackageInfo_ m -> Bool
importDirs :: InstalledPackageInfo_ m -> [FilePath]
libraryDirs :: InstalledPackageInfo_ m -> [FilePath]
hsLibraries :: InstalledPackageInfo_ m -> [String]
extraLibraries :: InstalledPackageInfo_ m -> [String]
extraGHCiLibraries :: InstalledPackageInfo_ m -> [String]
includeDirs :: InstalledPackageInfo_ m -> [FilePath]
includes :: InstalledPackageInfo_ m -> [String]
depends :: InstalledPackageInfo_ m -> [InstalledPackageId]
hugsOptions :: InstalledPackageInfo_ m -> [String]
ccOptions :: InstalledPackageInfo_ m -> [String]
ldOptions :: InstalledPackageInfo_ m -> [String]
frameworkDirs :: InstalledPackageInfo_ m -> [FilePath]
frameworks :: InstalledPackageInfo_ m -> [String]
haddockInterfaces :: InstalledPackageInfo_ m -> [FilePath]
haddockHTMLs :: InstalledPackageInfo_ m -> [FilePath]
display :: Text a => a -> String

-- | A <a>Version</a> represents the version of a software entity.
--   
--   An instance of <a>Eq</a> is provided, which implements exact equality
--   modulo reordering of the tags in the <a>versionTags</a> field.
--   
--   An instance of <a>Ord</a> is also provided, which gives lexicographic
--   ordering on the <a>versionBranch</a> fields (i.e. 2.1 &gt; 2.0, 1.2.3
--   &gt; 1.2.2, etc.). This is expected to be sufficient for many uses,
--   but note that you may need to use a more specific ordering for your
--   versioning scheme. For example, some versioning schemes may include
--   pre-releases which have tags <tt>"pre1"</tt>, <tt>"pre2"</tt>, and so
--   on, and these would need to be taken into account when determining
--   ordering. In some cases, date ordering may be more appropriate, so the
--   application would have to look for <tt>date</tt> tags in the
--   <a>versionTags</a> field and compare those. The bottom line is, don't
--   always assume that <a>compare</a> and other <a>Ord</a> operations are
--   the right thing for every <a>Version</a>.
--   
--   Similarly, concrete representations of versions may differ. One
--   possible concrete representation is provided (see <a>showVersion</a>
--   and <a>parseVersion</a>), but depending on the application a different
--   concrete representation may be more appropriate.
data Version :: *
Version :: [Int] -> [String] -> Version

-- | The numeric branch for this version. This reflects the fact that most
--   software versions are tree-structured; there is a main trunk which is
--   tagged with versions at various points (1,2,3...), and the first
--   branch off the trunk after version 3 is 3.1, the second branch off the
--   trunk after version 3 is 3.2, and so on. The tree can be branched
--   arbitrarily, just by adding more digits.
--   
--   We represent the branch as a list of <a>Int</a>, so version 3.2.1
--   becomes [3,2,1]. Lexicographic ordering (i.e. the default instance of
--   <a>Ord</a> for <tt>[Int]</tt>) gives the natural ordering of branches.
versionBranch :: Version -> [Int]

-- | A version can be tagged with an arbitrary list of strings. The
--   interpretation of the list of tags is entirely dependent on the entity
--   that this version applies to.
versionTags :: Version -> [String]

-- | The name and version of a package.
data PackageIdentifier :: *
PackageIdentifier :: PackageName -> Version -> PackageIdentifier

-- | The name of this package, eg. foo
pkgName :: PackageIdentifier -> PackageName

-- | the version of this package, eg 1.2
pkgVersion :: PackageIdentifier -> Version
defaultPackageConfig :: PackageConfig

-- | Turn a <a>PackageConfig</a>, which contains GHC <a>ModuleName</a>s
--   into a Cabal specific <a>InstalledPackageInfo</a> which contains Cabal
--   <a>ModuleName</a>s
packageConfigToInstalledPackageInfo :: PackageConfig -> InstalledPackageInfo

-- | Turn an <a>InstalledPackageInfo</a>, which contains Cabal
--   <a>ModuleName</a>s into a GHC specific <a>PackageConfig</a> which
--   contains GHC <a>ModuleName</a>s
installedPackageInfoToPackageConfig :: InstalledPackageInfo_ String -> PackageConfig

module ForeignCall
newtype ForeignCall
CCall :: CCallSpec -> ForeignCall
isSafeForeignCall :: ForeignCall -> Bool
data Safety
PlaySafe :: Safety
PlayInterruptible :: Safety
PlayRisky :: Safety
playSafe :: Safety -> Bool
playInterruptible :: Safety -> Bool
data CExportSpec
CExportStatic :: CLabelString -> CCallConv -> CExportSpec
type CLabelString = FastString
isCLabelString :: CLabelString -> Bool
pprCLabelString :: CLabelString -> SDoc
data CCallSpec
CCallSpec :: CCallTarget -> CCallConv -> Safety -> CCallSpec

-- | How to call a particular function in C-land.
data CCallTarget
StaticTarget :: CLabelString -> (Maybe PackageId) -> Bool -> CCallTarget
DynamicTarget :: CCallTarget
isDynamicTarget :: CCallTarget -> Bool
data CCallConv
CCallConv :: CCallConv
CApiConv :: CCallConv
StdCallConv :: CCallConv
CmmCallConv :: CCallConv
PrimCallConv :: CCallConv
defaultCCallConv :: CCallConv
ccallConvToInt :: CCallConv -> Int
ccallConvAttribute :: CCallConv -> SDoc
newtype Header
Header :: FastString -> Header

-- | A C type, used in CAPI FFI calls
data CType
CType :: (Maybe Header) -> FastString -> CType
instance Typeable Safety
instance Typeable CCallConv
instance Typeable CCallTarget
instance Typeable CExportSpec
instance Typeable Header
instance Typeable CType
instance Eq Safety
instance Show Safety
instance Data Safety
instance Eq CCallConv
instance Data CCallConv
instance Eq CCallTarget
instance Data CCallTarget
instance Eq CCallSpec
instance Eq ForeignCall
instance Data CExportSpec
instance Eq Header
instance Data Header
instance Data CType
instance Binary Header
instance Binary CType
instance Binary CCallConv
instance Binary CCallTarget
instance Binary CCallSpec
instance Binary CExportSpec
instance Binary Safety
instance Binary ForeignCall
instance Outputable CType
instance Outputable Header
instance Outputable CCallSpec
instance Outputable CExportSpec
instance Outputable CCallConv
instance Outputable Safety
instance Outputable ForeignCall

module TyCon

-- | TyCons represent type constructors. Type constructors are introduced
--   by things such as:
--   
--   1) Data declarations: <tt>data Foo = ...</tt> creates the <tt>Foo</tt>
--   type constructor of kind <tt>*</tt>
--   
--   2) Type synonyms: <tt>type Foo = ...</tt> creates the <tt>Foo</tt>
--   type constructor
--   
--   3) Newtypes: <tt>newtype Foo a = MkFoo ...</tt> creates the
--   <tt>Foo</tt> type constructor of kind <tt>* -&gt; *</tt>
--   
--   4) Class declarations: <tt>class Foo where</tt> creates the
--   <tt>Foo</tt> type constructor of kind <tt>*</tt>
--   
--   This data type also encodes a number of primitive, built in type
--   constructors such as those for function and tuple types.
data TyCon

-- | Names of the fields in an algebraic record type
type FieldLabel = Name

-- | Represents right-hand-sides of <a>TyCon</a>s for algebraic types
data AlgTyConRhs

-- | Says that we know nothing about this data type, except that it's
--   represented by a pointer. Used when we export a data type abstractly
--   into an .hi file.
AbstractTyCon :: Bool -> AlgTyConRhs

-- | Represents an open type family without a fixed right hand side.
--   Additional instances can appear at any time.
--   
--   These are introduced by either a top level declaration:
--   
--   <pre>
--   data T a :: *
--   </pre>
--   
--   Or an associated data type declaration, within a class declaration:
--   
--   <pre>
--   class C a b where
--     data T b :: *
--   </pre>
DataFamilyTyCon :: AlgTyConRhs

-- | Information about those <a>TyCon</a>s derived from a <tt>data</tt>
--   declaration. This includes data types with no constructors at all.
DataTyCon :: [DataCon] -> Bool -> AlgTyConRhs

-- | The data type constructors; can be empty if the user declares the type
--   to have no constructors
--   
--   INVARIANT: Kept in order of increasing <a>DataCon</a> tag (see the tag
--   assignment in DataCon.mkDataCon)
data_cons :: AlgTyConRhs -> [DataCon]

-- | Cached value: is this an enumeration type? See Note [Enumeration
--   types]
is_enum :: AlgTyConRhs -> Bool

-- | Information about those <a>TyCon</a>s derived from a <tt>newtype</tt>
--   declaration
NewTyCon :: DataCon -> Type -> ([TyVar], Type) -> CoAxiom -> AlgTyConRhs

-- | The unique constructor for the <tt>newtype</tt>. It has no
--   existentials
data_con :: AlgTyConRhs -> DataCon

-- | Cached value: the argument type of the constructor, which is just the
--   representation type of the <a>TyCon</a> (remember that
--   <tt>newtype</tt>s do not exist at runtime so need a different
--   representation type).
--   
--   The free <a>TyVar</a>s of this type are the <a>tyConTyVars</a> from
--   the corresponding <a>TyCon</a>
nt_rhs :: AlgTyConRhs -> Type

-- | Same as the <a>nt_rhs</a>, but this time eta-reduced. Hence the list
--   of <a>TyVar</a>s in this field may be shorter than the declared arity
--   of the <a>TyCon</a>.
nt_etad_rhs :: AlgTyConRhs -> ([TyVar], Type)
nt_co :: AlgTyConRhs -> CoAxiom

-- | Both type classes as well as family instances imply implicit type
--   constructors. These implicit type constructors refer to their parent
--   structure (ie, the class or family from which they derive) using a
--   type of the following form. We use <a>TyConParent</a> for both
--   algebraic and synonym types, but the variant <a>ClassTyCon</a> will
--   only be used by algebraic <a>TyCon</a>s.
--   
--   Extract those <a>DataCon</a>s that we are able to learn about. Note
--   that visibility in this sense does not correspond to visibility in the
--   context of any particular user program!
visibleDataCons :: AlgTyConRhs -> [DataCon]
data TyConParent

-- | An ordinary type constructor has no parent.
NoParentTyCon :: TyConParent

-- | Type constructors representing a class dictionary. See Note [ATyCon
--   for classes] in TypeRep
ClassTyCon :: Class -> TyConParent

-- | An *associated* type of a class.
AssocFamilyTyCon :: Class -> TyConParent

-- | Type constructors representing an instance of a *data* family.
--   Parameters:
--   
--   1) The type family in question
--   
--   2) Instance types; free variables are the <a>tyConTyVars</a> of the
--   current <a>TyCon</a> (not the family one). INVARIANT: the number of
--   types matches the arity of the family <a>TyCon</a>
--   
--   3) A <tt>CoTyCon</tt> identifying the representation type with the
--   type instance family
FamInstTyCon :: CoAxiom -> TyCon -> [Type] -> TyConParent
isNoParent :: TyConParent -> Bool

-- | Information pertaining to the expansion of a type synonym
--   (<tt>type</tt>)
data SynTyConRhs

-- | An ordinary type synonyn.
SynonymTyCon :: Type -> SynTyConRhs

-- | A type synonym family e.g. <tt>type family F x y :: * -&gt; *</tt>
SynFamilyTyCon :: SynTyConRhs

-- | A <a>CoAxiom</a> is a "coercion constructor", i.e. a named equality
--   axiom.
data CoAxiom
CoAxiom :: Unique -> Name -> [TyVar] -> Type -> Type -> Bool -> CoAxiom
co_ax_unique :: CoAxiom -> Unique
co_ax_name :: CoAxiom -> Name
co_ax_tvs :: CoAxiom -> [TyVar]
co_ax_lhs :: CoAxiom -> Type
co_ax_rhs :: CoAxiom -> Type
co_ax_implicit :: CoAxiom -> Bool
coAxiomName :: CoAxiom -> Name
coAxiomArity :: CoAxiom -> Arity
coAxiomTyVars :: CoAxiom -> [TyVar]
coAxiomLHS :: CoAxiom -> Type
coAxiomRHS :: CoAxiom -> Type
isImplicitCoAxiom :: CoAxiom -> Bool

-- | This is the making of an algebraic <a>TyCon</a>. Notably, you have to
--   pass in the generic (in the -XGenerics sense) information about the
--   type constructor - you can get hold of it easily (see Generics module)
mkAlgTyCon :: Name -> Kind -> [TyVar] -> Maybe CType -> [PredType] -> AlgTyConRhs -> TyConParent -> RecFlag -> Bool -> TyCon

-- | Simpler specialization of <a>mkAlgTyCon</a> for classes
mkClassTyCon :: Name -> Kind -> [TyVar] -> AlgTyConRhs -> Class -> RecFlag -> TyCon

-- | Given the name of the function type constructor and it's kind, create
--   the corresponding <a>TyCon</a>. It is reccomended to use
--   <a>funTyCon</a> if you want this functionality
mkFunTyCon :: Name -> Kind -> TyCon

-- | Create an unlifted primitive <a>TyCon</a>, such as <tt>Int#</tt>
mkPrimTyCon :: Name -> Kind -> Arity -> PrimRep -> TyCon

-- | Kind constructors
mkKindTyCon :: Name -> Kind -> TyCon

-- | Create a lifted primitive <a>TyCon</a> such as <tt>RealWorld</tt>
mkLiftedPrimTyCon :: Name -> Kind -> Arity -> PrimRep -> TyCon

-- | Foreign-imported (.NET) type constructors are represented as
--   primitive, but <i>lifted</i>, <tt>TyCons</tt> for now. They are lifted
--   because the Haskell type <tt>T</tt> representing the (foreign) .NET
--   type <tt>T</tt> is actually implemented (in ILX) as a
--   <tt>thunk<a>T</a></tt>
mkTupleTyCon :: Name -> Kind -> Arity -> [TyVar] -> DataCon -> TupleSort -> TyCon

-- | Create a type synonym <a>TyCon</a>
mkSynTyCon :: Name -> Kind -> [TyVar] -> SynTyConRhs -> TyConParent -> TyCon
mkForeignTyCon :: Name -> Maybe FastString -> Kind -> Arity -> TyCon

-- | Create a promoted data constructor <a>TyCon</a> Somewhat dodgily, we
--   give it the same Name as the data constructor itself; when we
--   pretty-print the TyCon we add a quote; see the Outputable TyCon
--   instance
mkPromotedDataCon :: DataCon -> Name -> Unique -> Kind -> Arity -> TyCon

-- | Create a promoted type constructor <a>TyCon</a> Somewhat dodgily, we
--   give it the same Name as the type constructor itself
mkPromotedTyCon :: TyCon -> Kind -> TyCon

-- | Returns <tt>True</tt> if the supplied <a>TyCon</a> resulted from
--   either a <tt>data</tt> or <tt>newtype</tt> declaration
isAlgTyCon :: TyCon -> Bool

-- | Is this <a>TyCon</a> that for a class instance?
isClassTyCon :: TyCon -> Bool

-- | Is this <a>TyCon</a> that for a family instance, be that for a synonym
--   or an algebraic family instance?
isFamInstTyCon :: TyCon -> Bool
isFunTyCon :: TyCon -> Bool

-- | Does this <a>TyCon</a> represent something that cannot be defined in
--   Haskell?
isPrimTyCon :: TyCon -> Bool

-- | Does this <a>TyCon</a> represent a tuple?
--   
--   NB: when compiling <tt>Data.Tuple</tt>, the tycons won't reply
--   <tt>True</tt> to <a>isTupleTyCon</a>, becuase they are built as
--   <tt>AlgTyCons</tt>. However they get spat into the interface file as
--   tuple tycons, so I don't think it matters.
isTupleTyCon :: TyCon -> Bool

-- | Is this the <a>TyCon</a> for an unboxed tuple?
isUnboxedTupleTyCon :: TyCon -> Bool

-- | Is this the <a>TyCon</a> for a boxed tuple?
isBoxedTupleTyCon :: TyCon -> Bool

-- | Is this a <a>TyCon</a> representing a type synonym (<tt>type</tt>)?
isSynTyCon :: TyCon -> Bool

-- | Is this a synonym <a>TyCon</a> that can have no further instances
--   appear?
isClosedSynTyCon :: TyCon -> Bool
isDecomposableTyCon :: TyCon -> Bool

-- | Is this the <a>TyCon</a> of a foreign-imported type constructor?
isForeignTyCon :: TyCon -> Bool

-- | Is this a PromotedDataCon?
isPromotedDataCon :: TyCon -> Bool

-- | Is this a PromotedTyCon?
isPromotedTyCon :: TyCon -> Bool

-- | Injective <a>TyCon</a>s can be decomposed, so that T ty1 ~ T ty2 =&gt;
--   ty1 ~ ty2
isInjectiveTyCon :: TyCon -> Bool

-- | Returns <tt>True</tt> for data types that are <i>definitely</i>
--   represented by heap-allocated constructors. These are scrutinised by
--   Core-level <tt>case</tt> expressions, and they get info tables
--   allocated for them.
--   
--   Generally, the function will be true for all <tt>data</tt> types and
--   false for <tt>newtype</tt>s, unboxed tuples and type family
--   <a>TyCon</a>s. But it is not guaranteed to return <tt>True</tt> in all
--   cases that it could.
--   
--   NB: for a data type family, only the <i>instance</i> <a>TyCon</a>s get
--   an info table. The family declaration <a>TyCon</a> does not
isDataTyCon :: TyCon -> Bool

-- | A <i>product</i> <a>TyCon</a> must both:
--   
--   <ol>
--   <li>Have <i>one</i> constructor</li>
--   <li><i>Not</i> be existential</li>
--   </ol>
--   
--   However other than this there are few restrictions: they may be
--   <tt>data</tt> or <tt>newtype</tt> <a>TyCon</a>s of any boxity and may
--   even be recursive.
isProductTyCon :: TyCon -> Bool

-- | Is this an algebraic <a>TyCon</a> which is just an enumeration of
--   values?
isEnumerationTyCon :: TyCon -> Bool

-- | Is this <a>TyCon</a> that for a <tt>newtype</tt>
isNewTyCon :: TyCon -> Bool

-- | Test if the <a>TyCon</a> is algebraic but abstract (invisible data
--   constructors)
isAbstractTyCon :: TyCon -> Bool

-- | Is this a <a>TyCon</a>, synonym or otherwise, that may have further
--   instances appear?
isFamilyTyCon :: TyCon -> Bool

-- | Is this a synonym <a>TyCon</a> that can have may have further
--   instances appear?
isSynFamilyTyCon :: TyCon -> Bool

-- | Is this a synonym <a>TyCon</a> that can have may have further
--   instances appear?
isDataFamilyTyCon :: TyCon -> Bool

-- | Is this <a>TyCon</a> unlifted (i.e. cannot contain bottom)? Note that
--   this can only be true for primitive and unboxed-tuple <a>TyCon</a>s
isUnLiftedTyCon :: TyCon -> Bool

-- | Is this an algebraic <a>TyCon</a> declared with the GADT syntax?
isGadtSyntaxTyCon :: TyCon -> Bool

-- | <a>isDistinctTyCon</a> is true of <a>TyCon</a>s that are equal only to
--   themselves, even via coercions (except for unsafeCoerce). This
--   excludes newtypes, type functions, type synonyms. It relates directly
--   to the FC consistency story: If the axioms are consistent, and co : S
--   tys ~ T tys, and S,T are <a>distinct</a> TyCons, then S=T. Cf Note
--   [Pruning dead case alternatives] in Unify
isDistinctTyCon :: TyCon -> Bool
isDistinctAlgRhs :: AlgTyConRhs -> Bool

-- | Are we able to extract informationa <a>TyVar</a> to class argument
--   list mappping from a given <a>TyCon</a>?
isTyConAssoc :: TyCon -> Bool
tyConAssoc_maybe :: TyCon -> Maybe Class

-- | Is this a recursive <a>TyCon</a>?
isRecursiveTyCon :: TyCon -> Bool

-- | Identifies implicit tycons that, in particular, do not go into
--   interface files (because they are implicitly reconstructed when the
--   interface is read).
--   
--   Note that:
--   
--   <ul>
--   <li>Associated families are implicit, as they are re-constructed from
--   the class declaration in which they reside, and</li>
--   <li>Family instances are <i>not</i> implicit as they represent the
--   instance body (similar to a <tt>dfun</tt> does that for a class
--   instance).</li>
--   </ul>
isImplicitTyCon :: TyCon -> Bool

-- | Same Name as the type constructor
--   
--   Same Name as the data constructor
tyConName :: TyCon -> Name
tyConKind :: TyCon -> Kind

-- | Same Unique as the type constructor
--   
--   Same Unique as the data constructor
tyConUnique :: TyCon -> Unique

-- | The kind and type variables used in the type constructor. Invariant:
--   length tyvars = arity Precisely, this list scopes over:
--   
--   <ol>
--   <li>The <a>algTcStupidTheta</a> 2. The cached types in
--   'algTyConRhs.NewTyCon' 3. The family instance types if present</li>
--   </ol>
--   
--   Note that it does <i>not</i> scope over the data constructors.
tyConTyVars :: TyCon -> [TyVar]
tyConCType :: TyCon -> Maybe CType
tyConCType_maybe :: TyCon -> Maybe CType

-- | As <a>tyConDataCons_maybe</a>, but returns the empty list of
--   constructors if no constructors could be found
tyConDataCons :: TyCon -> [DataCon]

-- | Determine the <a>DataCon</a>s originating from the given <a>TyCon</a>,
--   if the <a>TyCon</a> is the sort that can have any constructors (note:
--   this does not include abstract algebraic types)
tyConDataCons_maybe :: TyCon -> Maybe [DataCon]

-- | If the given <a>TyCon</a> has a <i>single</i> data constructor, i.e.
--   it is a <tt>data</tt> type with one alternative, a tuple type or a
--   <tt>newtype</tt> then that constructor is returned. If the
--   <a>TyCon</a> has more than one constructor, or represents a primitive
--   or function type constructor then <tt>Nothing</tt> is returned. In any
--   other case, the function panics
tyConSingleDataCon_maybe :: TyCon -> Maybe DataCon

-- | Determine the number of value constructors a <a>TyCon</a> has. Panics
--   if the <a>TyCon</a> is not algebraic or a tuple
tyConFamilySize :: TyCon -> Int

-- | Find the "stupid theta" of the <a>TyCon</a>. A "stupid theta" is the
--   context to the left of an algebraic type declaration, e.g. <tt>Eq
--   a</tt> in the declaration <tt>data Eq a =&gt; T a ...</tt>
tyConStupidTheta :: TyCon -> [PredType]

-- | n if ty_con :: * -&gt; ... -&gt; * n times
tyConArity :: TyCon -> Arity
tyConParent :: TyCon -> TyConParent
tyConTuple_maybe :: TyCon -> Maybe TupleSort

-- | If this <a>TyCon</a> is that for a class instance, return the class it
--   is for. Otherwise returns <tt>Nothing</tt>
tyConClass_maybe :: TyCon -> Maybe Class

-- | If this <a>TyCon</a> is that of a family instance, return the family
--   in question and the instance types. Otherwise, return <tt>Nothing</tt>
tyConFamInst_maybe :: TyCon -> Maybe (TyCon, [Type])
tyConFamInstSig_maybe :: TyCon -> Maybe (TyCon, [Type], CoAxiom)

-- | If this <a>TyCon</a> is that of a family instance, return a
--   <a>TyCon</a> which represents a coercion identifying the
--   representation type with the type instance family. Otherwise, return
--   <tt>Nothing</tt>
tyConFamilyCoercion_maybe :: TyCon -> Maybe CoAxiom

-- | Extract the <a>TyVar</a>s bound by a type synonym and the
--   corresponding (unsubstituted) right hand side. If the given
--   <a>TyCon</a> is not a type synonym, panics
synTyConDefn :: TyCon -> ([TyVar], Type)

-- | Extract the information pertaining to the right hand side of a type
--   synonym (<tt>type</tt>) declaration. Panics if the given <a>TyCon</a>
--   is not a type synonym
synTyConRhs :: TyCon -> SynTyConRhs

-- | Find the expansion of the type synonym represented by the given
--   <a>TyCon</a>. The free variables of this type will typically include
--   those <a>TyVar</a>s bound by the <a>TyCon</a>. Panics if the
--   <a>TyCon</a> is not that of a type synonym
synTyConType :: TyCon -> Type

-- | <tt>Just e</tt> for foreign-imported types, holds the name of the
--   imported thing
tyConExtName :: TyCon -> Maybe FastString

-- | Extract an <a>AlgTyConRhs</a> with information about data constructors
--   from an algebraic or tuple <a>TyCon</a>. Panics for any other sort of
--   <a>TyCon</a>
algTyConRhs :: TyCon -> AlgTyConRhs

-- | Extract the bound type variables and type expansion of a type synonym
--   <a>TyCon</a>. Panics if the <a>TyCon</a> is not a synonym
newTyConRhs :: TyCon -> ([TyVar], Type)

-- | Extract the bound type variables and type expansion of an
--   eta-contracted type synonym <a>TyCon</a>. Panics if the <a>TyCon</a>
--   is not a synonym
newTyConEtadRhs :: TyCon -> ([TyVar], Type)

-- | Take a <a>TyCon</a> apart into the <a>TyVar</a>s it scopes over, the
--   <a>Type</a> it expands into, and (possibly) a coercion from the
--   representation type to the <tt>newtype</tt>. Returns <tt>Nothing</tt>
--   if this is not possible.
unwrapNewTyCon_maybe :: TyCon -> Maybe ([TyVar], Type, CoAxiom)

-- | Extract the boxity of the given <a>TyCon</a>, if it is a
--   <a>TupleTyCon</a>. Panics otherwise
tupleTyConBoxity :: TyCon -> Boxity

-- | Extract the <a>TupleSort</a> of the given <a>TyCon</a>, if it is a
--   <a>TupleTyCon</a>. Panics otherwise
tupleTyConSort :: TyCon -> TupleSort

-- | Extract the arity of the given <a>TyCon</a>, if it is a
--   <a>TupleTyCon</a>. Panics otherwise
tupleTyConArity :: TyCon -> Arity

-- | Retrieves the promoted DataCon if this is a PromotedDataTyCon; Panics
--   otherwise
promotedDataCon :: TyCon -> DataCon

-- | Retrieves the promoted TypeCon if this is a PromotedTypeTyCon; Panics
--   otherwise
promotedTyCon :: TyCon -> TyCon

-- | Used to create the view <i>Core</i> has on <a>TyCon</a>s. We expand
--   not only closed synonyms like <a>tcExpandTyCon_maybe</a>, but also
--   non-recursive <tt>newtype</tt>s
--   
--   Used to create the view the <i>typechecker</i> has on <a>TyCon</a>s.
--   We expand (closed) synonyms only, cf. <a>coreExpandTyCon_maybe</a>
tcExpandTyCon_maybe :: TyCon -> [tyco] -> Maybe ([(TyVar, tyco)], Type, [tyco])

-- | Used to create the view the <i>typechecker</i> has on <a>TyCon</a>s.
--   We expand (closed) synonyms only, cf. <a>coreExpandTyCon_maybe</a>
coreExpandTyCon_maybe :: TyCon -> [tyco] -> Maybe ([(TyVar, tyco)], Type, [tyco])

-- | Make an algebraic <a>TyCon</a> abstract. Panics if the supplied
--   <a>TyCon</a> is not algebraic
makeTyConAbstract :: TyCon -> TyCon
newTyConCo :: TyCon -> CoAxiom

-- | Extracts the <tt>newtype</tt> coercion from such a <a>TyCon</a>, which
--   can be used to construct something with the <tt>newtype</tt>s type
--   from its representation type (right hand side). If the supplied
--   <a>TyCon</a> is not a <tt>newtype</tt>, returns <tt>Nothing</tt>
newTyConCo_maybe :: TyCon -> Maybe CoAxiom
pprPromotionQuote :: TyCon -> SDoc

-- | A <a>PrimRep</a> is an abstraction of a type. It contains information
--   that the code generator needs in order to pass arguments, return
--   results, and store values of this type.
data PrimRep
VoidRep :: PrimRep
PtrRep :: PrimRep

-- | Signed, word-sized value
IntRep :: PrimRep

-- | Unsigned, word-sized value
WordRep :: PrimRep

-- | Signed, 64 bit value (with 32-bit words only)
Int64Rep :: PrimRep

-- | Unsigned, 64 bit value (with 32-bit words only)
Word64Rep :: PrimRep

-- | A pointer, but <i>not</i> to a Haskell value (use <a>PtrRep</a>)
AddrRep :: PrimRep
FloatRep :: PrimRep
DoubleRep :: PrimRep

-- | Find the primitive representation of a <a>TyCon</a>
tyConPrimRep :: TyCon -> PrimRep

-- | Find the size of a <a>PrimRep</a>, in words
primRepSizeW :: PrimRep -> Int
instance Typeable TyCon
instance Typeable CoAxiom
instance Eq PrimRep
instance Show PrimRep
instance Data CoAxiom
instance NamedThing CoAxiom
instance Outputable CoAxiom
instance Uniquable CoAxiom
instance Ord CoAxiom
instance Eq CoAxiom
instance Data TyCon
instance NamedThing TyCon
instance Outputable TyCon
instance Uniquable TyCon
instance Ord TyCon
instance Eq TyCon
instance Outputable PrimRep
instance Outputable TyConParent

module LibFFI
type ForeignCallToken = C_ffi_cif
prepForeignCall :: CCallConv -> [PrimRep] -> PrimRep -> IO (Ptr ForeignCallToken)

module Serialized

-- | Represents a serialized value of a particular type. Attempts can be
--   made to deserialize it at certain types
data Serialized

-- | Force the contents of the Serialized value so weknow it doesn't
--   contain any bottoms
seqSerialized :: Serialized -> ()

-- | Put a Typeable value that we are able to actually turn into bytes into
--   a <a>Serialized</a> value ready for deserialization later
toSerialized :: Typeable a => (a -> [Word8]) -> a -> Serialized

-- | If the <a>Serialized</a> value contains something of the given type,
--   then use the specified deserializer to return <tt>Just</tt> that.
--   Otherwise return <tt>Nothing</tt>.
fromSerialized :: Typeable a => ([Word8] -> a) -> Serialized -> Maybe a

-- | Use a <a>Data</a> instance to implement a serialization scheme dual to
--   that of <a>deserializeWithData</a>
serializeWithData :: Data a => a -> [Word8]

-- | Use a <a>Data</a> instance to implement a deserialization scheme dual
--   to that of <a>serializeWithData</a>
deserializeWithData :: Data a => [Word8] -> a
instance Binary Serialized
instance Outputable Serialized


-- | Support for source code annotation feature of GHC. That is the ANN
--   pragma.
--   
--   (c) The University of Glasgow 2006 (c) The GRASP/AQUA Project, Glasgow
--   University, 1992-1998
module Annotations

-- | Represents an annotation after it has been sufficiently desugared from
--   it's initial form of <a>AnnDecl</a>
data Annotation
Annotation :: CoreAnnTarget -> Serialized -> Annotation

-- | The target of the annotation
ann_target :: Annotation -> CoreAnnTarget

-- | <a>Serialized</a> version of the annotation that allows recovery of
--   its value or can be persisted to an interface file
ann_value :: Annotation -> Serialized

-- | An annotation target
data AnnTarget name

-- | We are annotating something with a name: a type or identifier
NamedTarget :: name -> AnnTarget name

-- | We are annotating a particular module
ModuleTarget :: Module -> AnnTarget name

-- | The kind of annotation target found in the middle end of the compiler
type CoreAnnTarget = AnnTarget Name

-- | Get the <tt>name</tt> of an annotation target if it exists.
getAnnTargetName_maybe :: AnnTarget name -> Maybe name

-- | A collection of annotations Can't use a type synonym or we hit bug
--   #2412 due to source import
data AnnEnv

-- | Construct a new annotation environment that contains the list of
--   annotations provided.
mkAnnEnv :: [Annotation] -> AnnEnv

-- | Add the given annotation to the environment.
extendAnnEnvList :: AnnEnv -> [Annotation] -> AnnEnv

-- | Union two annotation environments.
plusAnnEnv :: AnnEnv -> AnnEnv -> AnnEnv

-- | An empty annotation environment.
emptyAnnEnv :: AnnEnv

-- | Find the annotations attached to the given target as <a>Typeable</a>
--   values of your choice. If no deserializer is specified, only transient
--   annotations will be returned.
findAnns :: Typeable a => ([Word8] -> a) -> AnnEnv -> CoreAnnTarget -> [a]

-- | Deserialize all annotations of a given type. This happens lazily, that
--   is no deserialization will take place until the [a] is actually
--   demanded and the [a] can also be empty (the UniqFM is not filtered).
deserializeAnns :: Typeable a => ([Word8] -> a) -> AnnEnv -> UniqFM [a]
instance Outputable Annotation
instance Outputable name => Outputable (AnnTarget name)
instance Uniquable name => Uniquable (AnnTarget name)
instance Functor AnnTarget


-- | Types for the general graph colorer.
module GraphBase

-- | A fn to check if a node is trivially colorable For graphs who's color
--   classes are disjoint then a node is 'trivially colorable' when it has
--   less neighbors and exclusions than available colors for that node.
--   
--   For graph's who's color classes overlap, ie some colors alias other
--   colors, then this can be a bit more tricky. There is a general way to
--   calculate this, but it's likely be too slow for use in the code. The
--   coloring algorithm takes a canned function which can be optimised by
--   the user to be specific to the specific graph being colored.
--   
--   for details, see <a>A Generalised Algorithm for Graph-Coloring
--   Register Allocation</a> Smith, Ramsey, Holloway - PLDI 2004.
type Triv k cls color = cls -> UniqSet k -> UniqSet color -> Bool

-- | The Interference graph. There used to be more fields, but they were
--   turfed out in a previous revision. maybe we'll want more later..
data Graph k cls color
Graph :: UniqFM (Node k cls color) -> Graph k cls color

-- | All active nodes in the graph.
graphMap :: Graph k cls color -> UniqFM (Node k cls color)

-- | An empty graph.
initGraph :: Graph k cls color

-- | Modify the finite map holding the nodes in the graph.
graphMapModify :: (UniqFM (Node k cls color) -> UniqFM (Node k cls color)) -> Graph k cls color -> Graph k cls color

-- | Graph nodes. Represents a thing that can conflict with another thing.
--   For the register allocater the nodes represent registers.
data Node k cls color
Node :: k -> cls -> Maybe color -> UniqSet k -> UniqSet color -> [color] -> UniqSet k -> Node k cls color

-- | A unique identifier for this node.
nodeId :: Node k cls color -> k

-- | The class of this node, determines the set of colors that can be used.
nodeClass :: Node k cls color -> cls

-- | The color of this node, if any.
nodeColor :: Node k cls color -> Maybe color

-- | Neighbors which must be colored differently to this node.
nodeConflicts :: Node k cls color -> UniqSet k

-- | Colors that cannot be used by this node.
nodeExclusions :: Node k cls color -> UniqSet color

-- | Colors that this node would prefer to be, in decending order.
nodePreference :: Node k cls color -> [color]

-- | Neighbors that this node would like to be colored the same as.
nodeCoalesce :: Node k cls color -> UniqSet k

-- | An empty node.
newNode :: k -> cls -> Node k cls color

module ListSetOps
unionLists :: (Outputable a, Eq a) => [a] -> [a] -> [a]
minusList :: Eq a => [a] -> [a] -> [a]
insertList :: Eq a => a -> [a] -> [a]
type Assoc a b = [(a, b)]
assoc :: Eq a => String -> Assoc a b -> a -> b
assocMaybe :: Eq a => Assoc a b -> a -> Maybe b
assocUsing :: (a -> a -> Bool) -> String -> Assoc a b -> a -> b
assocDefault :: Eq a => b -> Assoc a b -> a -> b
assocDefaultUsing :: (a -> a -> Bool) -> b -> Assoc a b -> a -> b
hasNoDups :: Eq a => [a] -> Bool
runs :: (a -> a -> Bool) -> [a] -> [[a]]
removeDups :: (a -> a -> Ordering) -> [a] -> ([a], [[a]])
findDupsEq :: (a -> a -> Bool) -> [a] -> [[a]]
equivClasses :: (a -> a -> Ordering) -> [a] -> [[a]]
equivClassesByUniq :: (a -> Unique) -> [a] -> [[a]]

module VarEnv
type VarEnv elt = UniqFM elt
type IdEnv elt = VarEnv elt
type TyVarEnv elt = VarEnv elt
type CoVarEnv elt = VarEnv elt
emptyVarEnv :: VarEnv a
unitVarEnv :: Var -> a -> VarEnv a
mkVarEnv :: [(Var, a)] -> VarEnv a
elemVarEnv :: Var -> VarEnv a -> Bool
varEnvElts :: VarEnv a -> [a]
varEnvKeys :: VarEnv a -> [Unique]
extendVarEnv :: VarEnv a -> Var -> a -> VarEnv a
extendVarEnv_C :: (a -> a -> a) -> VarEnv a -> Var -> a -> VarEnv a
extendVarEnv_Acc :: (a -> b -> b) -> (a -> b) -> VarEnv b -> Var -> a -> VarEnv b
extendVarEnvList :: VarEnv a -> [(Var, a)] -> VarEnv a
plusVarEnv :: VarEnv a -> VarEnv a -> VarEnv a
plusVarEnv_C :: (a -> a -> a) -> VarEnv a -> VarEnv a -> VarEnv a
alterVarEnv :: (Maybe a -> Maybe a) -> VarEnv a -> Var -> VarEnv a
delVarEnvList :: VarEnv a -> [Var] -> VarEnv a
delVarEnv :: VarEnv a -> Var -> VarEnv a
minusVarEnv :: VarEnv a -> VarEnv b -> VarEnv a
intersectsVarEnv :: VarEnv a -> VarEnv a -> Bool
lookupVarEnv :: VarEnv a -> Var -> Maybe a
lookupVarEnv_NF :: VarEnv a -> Var -> a
lookupWithDefaultVarEnv :: VarEnv a -> a -> Var -> a
mapVarEnv :: (a -> b) -> VarEnv a -> VarEnv b
zipVarEnv :: [Var] -> [a] -> VarEnv a
modifyVarEnv :: (a -> a) -> VarEnv a -> Var -> VarEnv a
modifyVarEnv_Directly :: (a -> a) -> UniqFM a -> Unique -> UniqFM a
isEmptyVarEnv :: VarEnv a -> Bool
foldVarEnv :: (a -> b -> b) -> b -> VarEnv a -> b
elemVarEnvByKey :: Unique -> VarEnv a -> Bool
lookupVarEnv_Directly :: VarEnv a -> Unique -> Maybe a
filterVarEnv_Directly :: (Unique -> a -> Bool) -> VarEnv a -> VarEnv a
restrictVarEnv :: VarEnv a -> VarSet -> VarEnv a

-- | A set of variables that are in scope at some point
data InScopeSet
emptyInScopeSet :: InScopeSet
mkInScopeSet :: VarEnv Var -> InScopeSet
delInScopeSet :: InScopeSet -> Var -> InScopeSet
extendInScopeSet :: InScopeSet -> Var -> InScopeSet
extendInScopeSetList :: InScopeSet -> [Var] -> InScopeSet
extendInScopeSetSet :: InScopeSet -> VarEnv Var -> InScopeSet
getInScopeVars :: InScopeSet -> VarEnv Var

-- | Look up a variable the <a>InScopeSet</a>. This lets you map from the
--   variable's identity (unique) to its full value.
lookupInScope :: InScopeSet -> Var -> Maybe Var
lookupInScope_Directly :: InScopeSet -> Unique -> Maybe Var
unionInScope :: InScopeSet -> InScopeSet -> InScopeSet
elemInScopeSet :: Var -> InScopeSet -> Bool

-- | <tt>uniqAway in_scope v</tt> finds a unique that is not used in the
--   in-scope set, and gives that to v.
uniqAway :: InScopeSet -> Var -> Var

-- | When we are comparing (or matching) types or terms, we are faced with
--   "going under" corresponding binders. E.g. when comparing:
--   
--   <pre>
--   \x. e1	~   \y. e2
--   </pre>
--   
--   Basically we want to rename [<tt>x</tt> -&gt; <tt>y</tt>] or
--   [<tt>y</tt> -&gt; <tt>x</tt>], but there are lots of things we must be
--   careful of. In particular, <tt>x</tt> might be free in <tt>e2</tt>, or
--   y in <tt>e1</tt>. So the idea is that we come up with a fresh binder
--   that is free in neither, and rename <tt>x</tt> and <tt>y</tt>
--   respectively. That means we must maintain:
--   
--   <ol>
--   <li>A renaming for the left-hand expression</li>
--   <li>A renaming for the right-hand expressions</li>
--   <li>An in-scope set</li>
--   </ol>
--   
--   Furthermore, when matching, we want to be able to have an 'occurs
--   check', to prevent:
--   
--   <pre>
--   \x. f   ~   \y. y
--   </pre>
--   
--   matching with [<tt>f</tt> -&gt; <tt>y</tt>]. So for each expression we
--   want to know that set of locally-bound variables. That is precisely
--   the domain of the mappings 1. and 2., but we must ensure that we
--   always extend the mappings as we go in.
--   
--   All of this information is bundled up in the <a>RnEnv2</a>
data RnEnv2
mkRnEnv2 :: InScopeSet -> RnEnv2

-- | <tt>rnBndr2 env bL bR</tt> goes under a binder <tt>bL</tt> in the Left
--   term, and binder <tt>bR</tt> in the Right term. It finds a new binder,
--   <tt>new_b</tt>, and returns an environment mapping <tt>bL -&gt;
--   new_b</tt> and <tt>bR -&gt; new_b</tt>
rnBndr2 :: RnEnv2 -> Var -> Var -> RnEnv2

-- | Applies <a>rnBndr2</a> to several variables: the two variable lists
--   must be of equal length
rnBndrs2 :: RnEnv2 -> [Var] -> [Var] -> RnEnv2

-- | Look up the renaming of an occurrence in the left or right term
rnOccL :: RnEnv2 -> Var -> Var

-- | Look up the renaming of an occurrence in the left or right term
rnOccR :: RnEnv2 -> Var -> Var

-- | Tells whether a variable is locally bound
inRnEnvL :: RnEnv2 -> Var -> Bool

-- | Tells whether a variable is locally bound
inRnEnvR :: RnEnv2 -> Var -> Bool

-- | Look up the renaming of an occurrence in the left or right term
rnOccL_maybe :: RnEnv2 -> Var -> Maybe Var

-- | Look up the renaming of an occurrence in the left or right term
rnOccR_maybe :: RnEnv2 -> Var -> Maybe Var

-- | Similar to <a>rnBndr2</a> but used when there's a binder on the left
--   side only.
rnBndrL :: RnEnv2 -> Var -> (RnEnv2, Var)

-- | Similar to <a>rnBndr2</a> but used when there's a binder on the right
--   side only.
rnBndrR :: RnEnv2 -> Var -> (RnEnv2, Var)

-- | Wipe the left or right side renaming
nukeRnEnvL :: RnEnv2 -> RnEnv2

-- | Wipe the left or right side renaming
nukeRnEnvR :: RnEnv2 -> RnEnv2
delBndrL :: RnEnv2 -> Var -> RnEnv2
delBndrR :: RnEnv2 -> Var -> RnEnv2
delBndrsL :: RnEnv2 -> [Var] -> RnEnv2
delBndrsR :: RnEnv2 -> [Var] -> RnEnv2
addRnInScopeSet :: RnEnv2 -> VarEnv Var -> RnEnv2

-- | Similar to <a>rnBndrL</a> but used for eta expansion See Note [Eta
--   expansion]
rnEtaL :: RnEnv2 -> Var -> (RnEnv2, Var)

-- | Similar to <a>rnBndr2</a> but used for eta expansion See Note [Eta
--   expansion]
rnEtaR :: RnEnv2 -> Var -> (RnEnv2, Var)
rnInScope :: Var -> RnEnv2 -> Bool
rnInScopeSet :: RnEnv2 -> InScopeSet
lookupRnInScope :: RnEnv2 -> Var -> Var

-- | When tidying up print names, we keep a mapping of in-scope occ-names
--   (the <a>TidyOccEnv</a>) and a Var-to-Var of the current renamings
type TidyEnv = (TidyOccEnv, VarEnv Var)
emptyTidyEnv :: TidyEnv
instance Outputable InScopeSet


-- | This module defines TyCons that can't be expressed in Haskell. They
--   are all, therefore, wired-in TyCons. C.f module TysWiredIn
module TysPrim
mkPrimTyConName :: FastString -> Unique -> TyCon -> Name
tyVarList :: Kind -> [TyVar]
alphaTyVars :: [TyVar]
betaTyVars :: [TyVar]
alphaTyVar :: TyVar
betaTyVar :: TyVar
gammaTyVar :: TyVar
deltaTyVar :: TyVar
alphaTy :: Type
betaTy :: Type
gammaTy :: Type
deltaTy :: Type
openAlphaTy :: Type
openBetaTy :: Type
openAlphaTyVar :: TyVar
openBetaTyVar :: TyVar
openAlphaTyVars :: [TyVar]
kKiVar :: KindVar

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   the <a>Kind</a> <a>TyCon</a>s
superKindTyCon :: TyCon

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
superKind :: Kind

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   the <a>Kind</a> <a>TyCon</a>s
anyKindTyCon :: TyCon

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   the <a>Kind</a> <a>TyCon</a>s
liftedTypeKindTyCon :: TyCon

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   the <a>Kind</a> <a>TyCon</a>s
openTypeKindTyCon :: TyCon

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   the <a>Kind</a> <a>TyCon</a>s
unliftedTypeKindTyCon :: TyCon

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   the <a>Kind</a> <a>TyCon</a>s
constraintKindTyCon :: TyCon
superKindTyConName :: Name
anyKindTyConName :: Name
liftedTypeKindTyConName :: Name
openTypeKindTyConName :: Name
unliftedTypeKindTyConName :: Name
constraintKindTyConName :: Name

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
anyKind :: Kind

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
liftedTypeKind :: Kind

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
unliftedTypeKind :: Kind

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
openTypeKind :: Kind

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
constraintKind :: Kind

-- | Given two kinds <tt>k1</tt> and <tt>k2</tt>, creates the <a>Kind</a>
--   <tt>k1 -&gt; k2</tt>
mkArrowKind :: Kind -> Kind -> Kind

-- | Iterated application of <a>mkArrowKind</a>
mkArrowKinds :: [Kind] -> Kind -> Kind
typeNatKind :: Kind
typeStringKind :: Kind
funTyCon :: TyCon
funTyConName :: Name
primTyCons :: [TyCon]
charPrimTyCon :: TyCon
charPrimTy :: Type
intPrimTyCon :: TyCon
intPrimTy :: Type
wordPrimTyCon :: TyCon
wordPrimTy :: Type
addrPrimTyCon :: TyCon
addrPrimTy :: Type
floatPrimTyCon :: TyCon
floatPrimTy :: Type
doublePrimTyCon :: TyCon
doublePrimTy :: Type
statePrimTyCon :: TyCon
mkStatePrimTy :: Type -> Type
realWorldTyCon :: TyCon
realWorldTy :: Type
realWorldStatePrimTy :: Type
arrayPrimTyCon :: TyCon
mkArrayPrimTy :: Type -> Type
byteArrayPrimTyCon :: TyCon
byteArrayPrimTy :: Type
arrayArrayPrimTyCon :: TyCon
mkArrayArrayPrimTy :: Type
mutableArrayPrimTyCon :: TyCon
mkMutableArrayPrimTy :: Type -> Type -> Type
mutableByteArrayPrimTyCon :: TyCon
mkMutableByteArrayPrimTy :: Type -> Type
mutableArrayArrayPrimTyCon :: TyCon
mkMutableArrayArrayPrimTy :: Type -> Type
mutVarPrimTyCon :: TyCon
mkMutVarPrimTy :: Type -> Type -> Type
mVarPrimTyCon :: TyCon
mkMVarPrimTy :: Type -> Type -> Type
tVarPrimTyCon :: TyCon
mkTVarPrimTy :: Type -> Type -> Type
stablePtrPrimTyCon :: TyCon
mkStablePtrPrimTy :: Type -> Type
stableNamePrimTyCon :: TyCon
mkStableNamePrimTy :: Type -> Type
bcoPrimTyCon :: TyCon
bcoPrimTy :: Type
weakPrimTyCon :: TyCon
mkWeakPrimTy :: Type -> Type
threadIdPrimTyCon :: TyCon
threadIdPrimTy :: Type
int32PrimTyCon :: TyCon
int32PrimTy :: Type
word32PrimTyCon :: TyCon
word32PrimTy :: Type
int64PrimTyCon :: TyCon
int64PrimTy :: Type
word64PrimTyCon :: TyCon
word64PrimTy :: Type
eqPrimTyCon :: TyCon
anyTy :: Type
anyTyCon :: TyCon
anyTypeOfKind :: Kind -> Type

module Kind

-- | <a>Super kinds</a>, used to help encode <a>Kind</a>s as types.
--   Invariant: a super kind is always of this form:
--   
--   <pre>
--   TyConApp SuperKindTyCon ...
--   </pre>
type SuperKind = Type

-- | The key type representing kinds in the compiler. Invariant: a kind is
--   always in one of these forms:
--   
--   <pre>
--   FunTy k1 k2
--   TyConApp PrimTyCon [...]
--   TyVar kv   -- (during inference only)
--   ForAll ... -- (for top-level coercions)
--   </pre>
type Kind = Type
typeKind :: Type -> Kind

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
anyKind :: Kind

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
liftedTypeKind :: Kind

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
unliftedTypeKind :: Kind

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
openTypeKind :: Kind

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
constraintKind :: Kind

-- | Given two kinds <tt>k1</tt> and <tt>k2</tt>, creates the <a>Kind</a>
--   <tt>k1 -&gt; k2</tt>
mkArrowKind :: Kind -> Kind -> Kind

-- | Iterated application of <a>mkArrowKind</a>
mkArrowKinds :: [Kind] -> Kind -> Kind
typeNatKind :: Kind
typeStringKind :: Kind

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   the <a>Kind</a> <a>TyCon</a>s
anyKindTyCon :: TyCon

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   the <a>Kind</a> <a>TyCon</a>s
liftedTypeKindTyCon :: TyCon

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   the <a>Kind</a> <a>TyCon</a>s
openTypeKindTyCon :: TyCon

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   the <a>Kind</a> <a>TyCon</a>s
unliftedTypeKindTyCon :: TyCon

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   the <a>Kind</a> <a>TyCon</a>s
constraintKindTyCon :: TyCon

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
superKind :: Kind

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   the <a>Kind</a> <a>TyCon</a>s
superKindTyCon :: TyCon
pprKind :: Kind -> SDoc
pprParendKind :: Kind -> SDoc
kindAppResult :: Kind -> [Type] -> Kind

-- | Find the result <a>Kind</a> of a type synonym, after applying it to
--   its <tt>arity</tt> number of type variables Actually this function
--   works fine on data types too, but they'd always return <a>*</a>, so we
--   never need to ask
synTyConResKind :: TyCon -> Kind

-- | Essentially <tt>splitFunTys</tt> on kinds
splitKindFunTys :: Kind -> ([Kind], Kind)

-- | Essentially <tt>splitFunTysN</tt> on kinds
splitKindFunTysN :: Int -> Kind -> ([Kind], Kind)
splitKindFunTy_maybe :: Kind -> Maybe (Kind, Kind)
isLiftedTypeKind :: Kind -> Bool

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
isUnliftedTypeKind :: Kind -> Bool

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
isOpenTypeKind :: Kind -> Bool

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
isConstraintKind :: Kind -> Bool

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
isConstraintOrLiftedKind :: Kind -> Bool
returnsConstraintKind :: Kind -> Bool

-- | Is this a kind (i.e. a type-of-types)?
isKind :: Kind -> Bool
isKindVar :: Var -> Bool

-- | Is this a super-kind (i.e. a type-of-kinds)?
isSuperKind :: Type -> Bool
isSuperKindTyCon :: TyCon -> Bool
isLiftedTypeKindCon :: TyCon -> Bool
isConstraintKindCon :: TyCon -> Bool

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
isAnyKind :: Kind -> Bool
isAnyKindCon :: TyCon -> Bool
okArrowArgKind :: Kind -> Bool
okArrowResultKind :: Kind -> Bool

-- | True of any sub-kind of OpenTypeKind
isSubOpenTypeKind :: Kind -> Bool

-- | <tt>k1 `isSubKind` k2</tt> checks that <tt>k1</tt> &lt;: <tt>k2</tt>
--   Sub-kinding is extremely simple and does not look under arrrows or
--   type constructors
isSubKind :: Kind -> Kind -> Bool

-- | <tt>kc1 `isSubKindCon` kc2</tt> checks that <tt>kc1</tt> &lt;:
--   <tt>kc2</tt>
isSubKindCon :: TyCon -> TyCon -> Bool
tcIsSubKind :: Kind -> Kind -> Bool
tcIsSubKindCon :: TyCon -> TyCon -> Bool

-- | Used when generalising: default OpenKind and ArgKind to *. See
--   <a>Type#kind_subtyping</a> for more information on what that means
defaultKind :: Kind -> Kind
kiVarsOfKind :: Kind -> VarSet
kiVarsOfKinds :: [Kind] -> VarSet


-- | Main functions for manipulating types and type-related things
module Type

-- | A typecheckable-thing, essentially anything that has a name
data TyThing
AnId :: Id -> TyThing
ADataCon :: DataCon -> TyThing
ATyCon :: TyCon -> TyThing
ACoAxiom :: CoAxiom -> TyThing

-- | The key representation of types within the compiler
data Type
type KindOrType = Type

-- | A type of the form <tt>p</tt> of kind <tt>Constraint</tt> represents a
--   value whose type is the Haskell predicate <tt>p</tt>, where a
--   predicate is what occurs before the <tt>=&gt;</tt> in a Haskell type.
--   
--   We use <a>PredType</a> as documentation to mark those types that we
--   guarantee to have this kind.
--   
--   It can be expanded into its representation, but:
--   
--   <ul>
--   <li>The type checker must treat it as opaque</li>
--   <li>The rest of the compiler treats it as transparent</li>
--   </ul>
--   
--   Consider these examples:
--   
--   <pre>
--   f :: (Eq a) =&gt; a -&gt; Int
--   g :: (?x :: Int -&gt; Int) =&gt; a -&gt; Int
--   h :: (r\l) =&gt; {r} =&gt; {l::Int | r}
--   </pre>
--   
--   Here the <tt>Eq a</tt> and <tt>?x :: Int -&gt; Int</tt> and
--   <tt>rl</tt> are all called "predicates"
type PredType = Type

-- | A collection of <a>PredType</a>s
type ThetaType = [PredType]

-- | Essentially a typed <a>Name</a>, that may also contain some additional
--   information about the <a>Var</a> and it's use sites.
data Var
type TyVar = Var
isTyVar :: Var -> Bool
mkTyVarTy :: TyVar -> Type
mkTyVarTys :: [TyVar] -> [Type]

-- | Attempts to obtain the type variable underlying a <a>Type</a>, and
--   panics with the given message if this is not a type variable type. See
--   also <a>getTyVar_maybe</a>
getTyVar :: String -> Type -> TyVar

-- | Attempts to obtain the type variable underlying a <a>Type</a>
getTyVar_maybe :: Type -> Maybe TyVar

-- | Applies a type to another, as in e.g. <tt>k a</tt>
mkAppTy :: Type -> Type -> Type
mkAppTys :: Type -> [Type] -> Type
mkNakedAppTys :: Type -> [Type] -> Type

-- | Attempts to take a type application apart, as in
--   <a>splitAppTy_maybe</a>, and panics if this is not possible
splitAppTy :: Type -> (Type, Type)

-- | Recursively splits a type as far as is possible, leaving a residual
--   type being applied to and the type arguments applied to it. Never
--   fails, even if that means returning an empty list of type
--   applications.
splitAppTys :: Type -> (Type, [Type])

-- | Attempt to take a type application apart, whether it is a function,
--   type constructor, or plain type application. Note that type family
--   applications are NEVER unsaturated by this!
splitAppTy_maybe :: Type -> Maybe (Type, Type)

-- | Does the AppTy split as in <a>splitAppTy_maybe</a>, but assumes that
--   any Core view stuff is already done
repSplitAppTy_maybe :: Type -> Maybe (Type, Type)

-- | Creates a function type from the given argument and result type
mkFunTy :: Type -> Type -> Type
mkFunTys :: [Type] -> Type -> Type

-- | Attempts to extract the argument and result types from a type, and
--   panics if that is not possible. See also <a>splitFunTy_maybe</a>
splitFunTy :: Type -> (Type, Type)

-- | Attempts to extract the argument and result types from a type
splitFunTy_maybe :: Type -> Maybe (Type, Type)
splitFunTys :: Type -> ([Type], Type)

-- | Split off exactly the given number argument types, and panics if that
--   is not possible
splitFunTysN :: Int -> Type -> ([Type], Type)

-- | Extract the function result type and panic if that is not possible
funResultTy :: Type -> Type

-- | Extract the function argument type and panic if that is not possible
funArgTy :: Type -> Type

-- | Splits off argument types from the given type and associating them
--   with the things in the input list from left to right. The final result
--   type is returned, along with the resulting pairs of objects and types,
--   albeit with the list of pairs in reverse order. Panics if there are
--   not enough argument types for the input list.
zipFunTys :: Outputable a => [a] -> Type -> ([(a, Type)], Type)

-- | A key function: builds a <a>TyConApp</a> or <a>FunTy</a> as
--   apppropriate to its arguments. Applies its arguments to the
--   constructor from left to right.
mkTyConApp :: TyCon -> [Type] -> Type

-- | Create the plain type constructor type which has been applied to no
--   type arguments at all.
mkTyConTy :: TyCon -> Type

-- | The same as <tt>fst . splitTyConApp</tt>
tyConAppTyCon_maybe :: Type -> Maybe TyCon

-- | The same as <tt>snd . splitTyConApp</tt>
tyConAppArgs_maybe :: Type -> Maybe [Type]
tyConAppTyCon :: Type -> TyCon
tyConAppArgs :: Type -> [Type]

-- | Attempts to tease a type apart into a type constructor and the
--   application of a number of arguments to that constructor
splitTyConApp_maybe :: Type -> Maybe (TyCon, [Type])

-- | Attempts to tease a type apart into a type constructor and the
--   application of a number of arguments to that constructor. Panics if
--   that is not possible. See also <a>splitTyConApp_maybe</a>
splitTyConApp :: Type -> (TyCon, [Type])
tyConAppArgN :: Int -> Type -> Type
mkForAllTy :: TyVar -> Type -> Type

-- | Wraps foralls over the type using the provided <a>TyVar</a>s from left
--   to right
mkForAllTys :: [TyVar] -> Type -> Type

-- | Attempts to take a forall type apart, returning the bound type
--   variable and the remainder of the type
splitForAllTy_maybe :: Type -> Maybe (TyVar, Type)

-- | Attempts to take a forall type apart, returning all the immediate such
--   bound type variables and the remainder of the type. Always suceeds,
--   even if that means returning an empty list of <a>TyVar</a>s
splitForAllTys :: Type -> ([TyVar], Type)
mkPiKinds :: [TyVar] -> Kind -> Kind

-- | Makes a <tt>(-&gt;)</tt> type or a forall type, depending on whether
--   it is given a type variable or a term variable.
mkPiType :: Var -> Type -> Type

-- | <a>mkPiType</a> for multiple type or value arguments
mkPiTypes :: [Var] -> Type -> Type

-- | Instantiate a forall type with one or more type arguments. Used when
--   we have a polymorphic function applied to type args:
--   
--   <pre>
--   f t1 t2
--   </pre>
--   
--   We use <tt>applyTys type-of-f [t1,t2]</tt> to compute the type of the
--   expression. Panics if no application is possible.
applyTy :: Type -> KindOrType -> Type

-- | This function is interesting because:
--   
--   <ol>
--   <li>The function may have more for-alls than there are args</li>
--   <li>Less obviously, it may have fewer for-alls</li>
--   </ol>
--   
--   For case 2. think of:
--   
--   <pre>
--   applyTys (forall a.a) [forall b.b, Int]
--   </pre>
--   
--   This really can happen, but only (I think) in situations involving
--   undefined. For example: undefined :: forall a. a Term: undefined
--   <tt>(forall b. b-&gt;b) </tt>Int This term should have type (Int -&gt;
--   Int), but notice that there are more type args than foralls in
--   <a>undefined</a>s type.
applyTys :: Type -> [KindOrType] -> Type
applyTysD :: SDoc -> Type -> [Type] -> Type
isForAllTy :: Type -> Bool

-- | Equivalent to <tt>snd . splitForAllTys</tt>
dropForAlls :: Type -> Type
mkNumLitTy :: Integer -> Type
isNumLitTy :: Type -> Maybe Integer
mkStrLitTy :: FastString -> Type
isStrLitTy :: Type -> Maybe FastString

-- | Unwrap one <tt>layer</tt> of newtype on a type constructor and its
--   arguments, using an eta-reduced version of the <tt>newtype</tt> if
--   possible
newTyConInstRhs :: TyCon -> [Type] -> Type
carefullySplitNewType_maybe :: NameSet -> TyCon -> [Type] -> Maybe (NameSet, Type)

-- | Given a family instance TyCon and its arg types, return the
--   corresponding family type. E.g:
--   
--   <pre>
--   data family T a
--   data instance T (Maybe b) = MkT b
--   </pre>
--   
--   Where the instance tycon is :RTL, so:
--   
--   <pre>
--   mkFamilyTyConApp :RTL Int  =  T (Maybe Int)
--   </pre>
mkFamilyTyConApp :: TyCon -> [Type] -> Type
isDictLikeTy :: Type -> Bool

-- | Creates a type equality predicate
mkEqPred :: Type -> Type -> PredType
mkPrimEqPred :: Type -> Type -> Type
mkClassPred :: Class -> [Type] -> PredType
noParenPred :: PredType -> Bool
isClassPred :: PredType -> Bool
isEqPred :: PredType -> Bool
isIPPred :: PredType -> Bool
isIPPred_maybe :: Type -> Maybe (FastString, Type)
data PredTree
ClassPred :: Class -> [Type] -> PredTree
EqPred :: Type -> Type -> PredTree
TuplePred :: [PredType] -> PredTree
IrredPred :: PredType -> PredTree
predTreePredType :: PredTree -> PredType
classifyPredType :: PredType -> PredTree
getClassPredTys :: PredType -> (Class, [Type])
getClassPredTys_maybe :: PredType -> Maybe (Class, [Type])
getEqPredTys :: PredType -> (Type, Type)
getEqPredTys_maybe :: PredType -> Maybe (Type, Type)
funTyCon :: TyCon
isTypeVar :: Var -> Bool
isKindVar :: Var -> Bool
isTyVarTy :: Type -> Bool
isFunTy :: Type -> Bool
isDictTy :: Type -> Bool
isPredTy :: Type -> Bool
isKindTy :: Type -> Bool

-- | See <a>Type#type_classification</a> for what an unlifted type is
isUnLiftedType :: Type -> Bool
isUnboxedTupleType :: Type -> Bool

-- | See <a>Type#type_classification</a> for what an algebraic type is.
--   Should only be applied to <i>types</i>, as opposed to e.g. partially
--   saturated type constructors
isAlgType :: Type -> Bool

-- | See <a>Type#type_classification</a> for what an algebraic type is.
--   Should only be applied to <i>types</i>, as opposed to e.g. partially
--   saturated type constructors. Closed type constructors are those with a
--   fixed right hand side, as opposed to e.g. associated types
isClosedAlgType :: Type -> Bool

-- | Returns true of types that are opaque to Haskell. Most of these are
--   unlifted, but now that we interact with .NET, we may have primtive
--   (foreign-imported) types that are lifted
isPrimitiveType :: Type -> Bool

-- | Computes whether an argument (or let right hand side) should be
--   computed strictly or lazily, based only on its type. Works just like
--   <a>isUnLiftedType</a>, except that it has a special case for
--   dictionaries (i.e. does not work purely on representation types)
isStrictType :: Type -> Bool

-- | The key type representing kinds in the compiler. Invariant: a kind is
--   always in one of these forms:
--   
--   <pre>
--   FunTy k1 k2
--   TyConApp PrimTyCon [...]
--   TyVar kv   -- (during inference only)
--   ForAll ... -- (for top-level coercions)
--   </pre>
type Kind = Type
type SimpleKind = Kind
type MetaKindVar = TyVar
typeKind :: Type -> Kind

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
anyKind :: Kind

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
liftedTypeKind :: Kind

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
unliftedTypeKind :: Kind

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
openTypeKind :: Kind

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
constraintKind :: Kind

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
superKind :: Kind

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   the <a>Kind</a> <a>TyCon</a>s
liftedTypeKindTyCon :: TyCon

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   the <a>Kind</a> <a>TyCon</a>s
openTypeKindTyCon :: TyCon

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   the <a>Kind</a> <a>TyCon</a>s
unliftedTypeKindTyCon :: TyCon

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   the <a>Kind</a> <a>TyCon</a>s
constraintKindTyCon :: TyCon

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   the <a>Kind</a> <a>TyCon</a>s
anyKindTyCon :: TyCon

-- | NB: for type synonyms tyVarsOfType does <i>not</i> expand the synonym
--   tyVarsOfType returns only the free variables of a type For example,
--   tyVarsOfType (a::k) returns {a}, not including the kind variable {k}
tyVarsOfType :: Type -> VarSet
tyVarsOfTypes :: [Type] -> TyVarSet

-- | Expand out all type synonyms. Actually, it'd suffice to expand out
--   just the ones that discard type variables (e.g. type Funny a = Int)
--   But we don't know which those are currently, so we just expand all.
expandTypeSynonyms :: Type -> Type
typeSize :: Type -> Int
varSetElemsKvsFirst :: VarSet -> [TyVar]

-- | Type equality on source types. Does not look through <tt>newtypes</tt>
--   or <a>PredType</a>s, but it does look through type synonyms.
eqType :: Type -> Type -> Bool
eqTypeX :: RnEnv2 -> Type -> Type -> Bool
eqTypes :: [Type] -> [Type] -> Bool
cmpType :: Type -> Type -> Ordering
cmpTypes :: [Type] -> [Type] -> Ordering
eqPred :: PredType -> PredType -> Bool
eqPredX :: RnEnv2 -> PredType -> PredType -> Bool
cmpPred :: PredType -> PredType -> Ordering
eqKind :: Kind -> Kind -> Bool
eqTyVarBndrs :: RnEnv2 -> [TyVar] -> [TyVar] -> Maybe RnEnv2
seqType :: Type -> ()
seqTypes :: [Type] -> ()

-- | In Core, we "look through" non-recursive newtypes and
--   <tt>PredTypes</tt>: this function tries to obtain a different view of
--   the supplied type given this
--   
--   Strips off the <i>top layer only</i> of a type to give its underlying
--   representation type. Returns Nothing if there is nothing to look
--   through.
--   
--   By being non-recursive and inlined, this case analysis gets
--   efficiently joined onto the case analysis that the caller is already
--   doing
coreView :: Type -> Maybe Type

-- | Similar to <a>coreView</a>, but for the type checker, which just looks
--   through synonyms
tcView :: Type -> Maybe Type
type UnaryType = Type
data RepType
UbxTupleRep :: [UnaryType] -> RepType
UnaryRep :: UnaryType -> RepType
flattenRepType :: RepType -> [UnaryType]

-- | Looks through:
--   
--   <ol>
--   <li>For-alls 2. Synonyms 3. Predicates 4. All newtypes, including
--   recursive ones, but not newtype families</li>
--   </ol>
--   
--   It's useful in the back end of the compiler.
repType :: Type -> RepType

-- | Discovers the primitive representation of a more abstract
--   <a>UnaryType</a>
typePrimRep :: UnaryType -> PrimRep
typeRepArity :: Arity -> Type -> RepArity

-- | A substitition of <a>Type</a>s for <a>TyVar</a>s and <a>Kind</a>s for
--   <a>KindVar</a>s
type TvSubstEnv = TyVarEnv Type

-- | Type substitution
--   
--   The following invariants must hold of a <a>TvSubst</a>:
--   
--   <ol>
--   <li>The in-scope set is needed <i>only</i> to guide the generation of
--   fresh uniques</li>
--   <li>In particular, the <i>kind</i> of the type variables in the
--   in-scope set is not relevant</li>
--   <li>The substition is only applied ONCE! This is because in general
--   such application will not reached a fixed point.</li>
--   </ol>
data TvSubst
TvSubst :: InScopeSet -> TvSubstEnv -> TvSubst
emptyTvSubstEnv :: TvSubstEnv
emptyTvSubst :: TvSubst
mkTvSubst :: InScopeSet -> TvSubstEnv -> TvSubst

-- | Generates the in-scope set for the <a>TvSubst</a> from the types in
--   the incoming environment, hence <a>open</a>
mkOpenTvSubst :: TvSubstEnv -> TvSubst

-- | Generates the in-scope set for the <a>TvSubst</a> from the types in
--   the incoming environment, hence <a>open</a>
zipOpenTvSubst :: [TyVar] -> [Type] -> TvSubst
zipTopTvSubst :: [TyVar] -> [Type] -> TvSubst

-- | Called when doing top-level substitutions. Here we expect that the
--   free vars of the range of the substitution will be empty.
mkTopTvSubst :: [(TyVar, Type)] -> TvSubst
notElemTvSubst :: CoVar -> TvSubst -> Bool
getTvSubstEnv :: TvSubst -> TvSubstEnv
setTvSubstEnv :: TvSubst -> TvSubstEnv -> TvSubst
zapTvSubstEnv :: TvSubst -> TvSubst
getTvInScope :: TvSubst -> InScopeSet
extendTvInScope :: TvSubst -> Var -> TvSubst
extendTvInScopeList :: TvSubst -> [Var] -> TvSubst
extendTvSubst :: TvSubst -> TyVar -> Type -> TvSubst
extendTvSubstList :: TvSubst -> [TyVar] -> [Type] -> TvSubst
isInScope :: Var -> TvSubst -> Bool

-- | <tt>(compose env1 env2)(x)</tt> is <tt>env1(env2(x))</tt>; i.e. apply
--   <tt>env2</tt> then <tt>env1</tt>. It assumes that both are idempotent.
--   Typically, <tt>env1</tt> is the refinement to a base substitution
--   <tt>env2</tt>
composeTvSubst :: InScopeSet -> TvSubstEnv -> TvSubstEnv -> TvSubstEnv
zipTyEnv :: [TyVar] -> [Type] -> TvSubstEnv
isEmptyTvSubst :: TvSubst -> Bool
unionTvSubst :: TvSubst -> TvSubst -> TvSubst

-- | Substitute within a <a>Type</a>
substTy :: TvSubst -> Type -> Type

-- | Substitute within several <a>Type</a>s
substTys :: TvSubst -> [Type] -> [Type]

-- | Type substitution making use of an <a>TvSubst</a> that is assumed to
--   be open, see <a>zipOpenTvSubst</a>
substTyWith :: [TyVar] -> [Type] -> Type -> Type

-- | Type substitution making use of an <a>TvSubst</a> that is assumed to
--   be open, see <a>zipOpenTvSubst</a>
substTysWith :: [TyVar] -> [Type] -> [Type] -> [Type]

-- | Substitute within a <a>ThetaType</a>
substTheta :: TvSubst -> ThetaType -> ThetaType
substTyVar :: TvSubst -> TyVar -> Type
substTyVars :: TvSubst -> [TyVar] -> [Type]
substTyVarBndr :: TvSubst -> TyVar -> (TvSubst, TyVar)
cloneTyVarBndr :: TvSubst -> TyVar -> Unique -> (TvSubst, TyVar)

-- | Remove any nested binders mentioning the <a>TyVar</a>s in the
--   <a>TyVarSet</a>
deShadowTy :: TyVarSet -> Type -> Type
lookupTyVar :: TvSubst -> TyVar -> Maybe Type
substKiWith :: [KindVar] -> [Kind] -> Kind -> Kind
substKisWith :: [KindVar] -> [Kind] -> [Kind] -> [Kind]
pprType :: Type -> SDoc
pprParendType :: Type -> SDoc
pprTypeApp :: NamedThing a => a -> [Type] -> SDoc
pprTyThingCategory :: TyThing -> SDoc
pprTyThing :: TyThing -> SDoc
pprTvBndr :: TyVar -> SDoc
pprTvBndrs :: [TyVar] -> SDoc
pprForAll :: [TyVar] -> SDoc
pprSigmaType :: Type -> SDoc
pprEqPred :: Pair Type -> SDoc
pprTheta :: ThetaType -> SDoc
pprThetaArrowTy :: ThetaType -> SDoc
pprClassPred :: Class -> [Type] -> SDoc
pprKind :: Kind -> SDoc
pprParendKind :: Kind -> SDoc

-- | Pretty prints a <a>TyCon</a>, using the family instance in case of a
--   representation tycon. For example:
--   
--   <pre>
--   data T [a] = ...
--   </pre>
--   
--   In that case we want to print <tt>T [a]</tt>, where <tt>T</tt> is the
--   family <a>TyCon</a>
pprSourceTyCon :: TyCon -> SDoc
instance Outputable TvSubst

module Literal

-- | So-called <a>Literal</a>s are one of:
--   
--   <ul>
--   <li>An unboxed (<i>machine</i>) literal (<a>MachInt</a>,
--   <a>MachFloat</a>, etc.), which is presumed to be surrounded by
--   appropriate constructors (<tt>Int#</tt>, etc.), so that the overall
--   thing makes sense.</li>
--   <li>The literal derived from the label mentioned in a "foreign label"
--   declaration (<a>MachLabel</a>)</li>
--   </ul>
data Literal

-- | <tt>Char#</tt> - at least 31 bits. Create with <a>mkMachChar</a>
MachChar :: Char -> Literal

-- | A string-literal: stored and emitted UTF-8 encoded, we'll arrange to
--   decode it at runtime. Also emitted with a <tt>'\0'</tt> terminator.
--   Create with <a>mkMachString</a>
MachStr :: FastString -> Literal

-- | The <tt>NULL</tt> pointer, the only pointer value that can be
--   represented as a Literal. Create with <a>nullAddrLit</a>
MachNullAddr :: Literal

-- | <tt>Int#</tt> - at least <tt>WORD_SIZE_IN_BITS</tt> bits. Create with
--   <a>mkMachInt</a>
MachInt :: Integer -> Literal

-- | <tt>Int64#</tt> - at least 64 bits. Create with <a>mkMachInt64</a>
MachInt64 :: Integer -> Literal

-- | <tt>Word#</tt> - at least <tt>WORD_SIZE_IN_BITS</tt> bits. Create with
--   <a>mkMachWord</a>
MachWord :: Integer -> Literal

-- | <tt>Word64#</tt> - at least 64 bits. Create with <a>mkMachWord64</a>
MachWord64 :: Integer -> Literal

-- | <tt>Float#</tt>. Create with <a>mkMachFloat</a>
MachFloat :: Rational -> Literal

-- | <tt>Double#</tt>. Create with <a>mkMachDouble</a>
MachDouble :: Rational -> Literal

-- | A label literal. Parameters:
--   
--   1) The name of the symbol mentioned in the declaration
--   
--   2) The size (in bytes) of the arguments the label expects. Only
--   applicable with <tt>stdcall</tt> labels. <tt>Just x</tt> =&gt;
--   <tt>&lt;x&gt;</tt> will be appended to label name when emitting
--   assembly.
MachLabel :: FastString -> (Maybe Int) -> FunctionOrData -> Literal
LitInteger :: Integer -> Type -> Literal

-- | Creates a <a>Literal</a> of type <tt>Int#</tt>
mkMachInt :: Integer -> Literal

-- | Creates a <a>Literal</a> of type <tt>Word#</tt>
mkMachWord :: Integer -> Literal

-- | Creates a <a>Literal</a> of type <tt>Int64#</tt>
mkMachInt64 :: Integer -> Literal

-- | Creates a <a>Literal</a> of type <tt>Word64#</tt>
mkMachWord64 :: Integer -> Literal

-- | Creates a <a>Literal</a> of type <tt>Float#</tt>
mkMachFloat :: Rational -> Literal

-- | Creates a <a>Literal</a> of type <tt>Double#</tt>
mkMachDouble :: Rational -> Literal

-- | Creates a <a>Literal</a> of type <tt>Char#</tt>
mkMachChar :: Char -> Literal

-- | Creates a <a>Literal</a> of type <tt>Addr#</tt>, which is appropriate
--   for passing to e.g. some of the "error" functions in GHC.Err such as
--   <tt>GHC.Err.runtimeError</tt>
mkMachString :: String -> Literal
mkLitInteger :: Integer -> Type -> Literal

-- | Find the Haskell <a>Type</a> the literal occupies
literalType :: Literal -> Type
hashLiteral :: Literal -> Int
absentLiteralOf :: TyCon -> Maybe Literal
pprLiteral :: (SDoc -> SDoc) -> Literal -> SDoc

-- | True if code space does not go bad if we duplicate this literal
--   Currently we treat it just like <a>litIsTrivial</a>
litIsDupable :: Literal -> Bool

-- | True if there is absolutely no penalty to duplicating the literal.
--   False principally of strings
litIsTrivial :: Literal -> Bool
litIsLifted :: Literal -> Bool
inIntRange :: Integer -> Bool
inWordRange :: Integer -> Bool
tARGET_MAX_INT :: Integer
inCharRange :: Char -> Bool

-- | Tests whether the literal represents a zero of whatever type it is
isZeroLit :: Literal -> Bool
litFitsInChar :: Literal -> Bool
word2IntLit :: Literal -> Literal
int2WordLit :: Literal -> Literal
narrow8IntLit :: Literal -> Literal
narrow16IntLit :: Literal -> Literal
narrow32IntLit :: Literal -> Literal
narrow8WordLit :: Literal -> Literal
narrow16WordLit :: Literal -> Literal
narrow32WordLit :: Literal -> Literal
char2IntLit :: Literal -> Literal
int2CharLit :: Literal -> Literal
float2IntLit :: Literal -> Literal
int2FloatLit :: Literal -> Literal
double2IntLit :: Literal -> Literal
int2DoubleLit :: Literal -> Literal
nullAddrLit :: Literal
float2DoubleLit :: Literal -> Literal
double2FloatLit :: Literal -> Literal
instance Typeable Literal
instance Data Literal
instance Ord Literal
instance Eq Literal
instance Outputable Literal
instance Binary Literal

module Demand
data Demand
Top :: Demand
Abs :: Demand
Call :: Demand -> Demand
Eval :: Demands -> Demand
Defer :: Demands -> Demand
Box :: Demand -> Demand
Bot :: Demand
topDmd :: Demand
lazyDmd :: Demand
seqDmd :: Demand
evalDmd :: Demand
errDmd :: Demand
isStrictDmd :: Demand -> Bool
isTop :: Demand -> Bool
isAbsent :: Demand -> Bool
seqDemand :: Demand -> ()
data DmdType
DmdType :: DmdEnv -> [Demand] -> DmdResult -> DmdType
topDmdType :: DmdType
botDmdType :: DmdType
mkDmdType :: DmdEnv -> [Demand] -> DmdResult -> DmdType
mkTopDmdType :: [Demand] -> DmdResult -> DmdType
dmdTypeDepth :: DmdType -> Arity
seqDmdType :: DmdType -> ()
type DmdEnv = VarEnv Demand
emptyDmdEnv :: VarEnv Demand
data DmdResult
TopRes :: DmdResult
RetCPR :: DmdResult
BotRes :: DmdResult
retCPR :: DmdResult
isBotRes :: DmdResult -> Bool
returnsCPR :: DmdResult -> Bool
resTypeArgDmd :: DmdResult -> Demand
data Demands
Poly :: Demand -> Demands
Prod :: [Demand] -> Demands
mapDmds :: (Demand -> Demand) -> Demands -> Demands
zipWithDmds :: (Demand -> Demand -> Demand) -> Demands -> Demands -> Demands
allTop :: Demands -> Bool
seqDemands :: Demands -> ()
newtype StrictSig
StrictSig :: DmdType -> StrictSig
mkStrictSig :: DmdType -> StrictSig
topSig :: StrictSig
botSig :: StrictSig
cprSig :: StrictSig
isTopSig :: StrictSig -> Bool
splitStrictSig :: StrictSig -> ([Demand], DmdResult)
increaseStrictSigArity :: Int -> StrictSig -> StrictSig
pprIfaceStrictSig :: StrictSig -> SDoc
appIsBottom :: StrictSig -> Int -> Bool
isBottomingSig :: StrictSig -> Bool
seqStrictSig :: StrictSig -> ()
instance Eq Demands
instance Eq Demand
instance Eq DmdResult
instance Show DmdResult
instance Eq StrictSig
instance Outputable StrictSig
instance Outputable DmdResult
instance Outputable DmdType
instance Eq DmdType
instance Outputable Demands
instance Outputable Demand


-- | Pretty print LLVM IR Code.
module Llvm.PpLlvm

-- | Print out a whole LLVM module.
ppLlvmModule :: LlvmModule -> SDoc

-- | Print out a multi-line comment, can be inside a function or on its own
ppLlvmComments :: [LMString] -> SDoc

-- | Print out a comment, can be inside a function or on its own
ppLlvmComment :: LMString -> SDoc

-- | Print out a list of global mutable variable definitions
ppLlvmGlobals :: [LMGlobal] -> SDoc

-- | Print out a global mutable variable definition
ppLlvmGlobal :: LMGlobal -> SDoc

-- | Print out a list of LLVM type aliases.
ppLlvmAliases :: [LlvmAlias] -> SDoc

-- | Print out an LLVM type alias.
ppLlvmAlias :: LlvmAlias -> SDoc

-- | Print out a list of LLVM metadata.
ppLlvmMetas :: [LlvmMeta] -> SDoc

-- | Print out an LLVM metadata definition.
ppLlvmMeta :: LlvmMeta -> SDoc

-- | Print out a list of function declaration.
ppLlvmFunctionDecls :: LlvmFunctionDecls -> SDoc

-- | Print out a function declaration. Declarations define the function
--   type but don't define the actual body of the function.
ppLlvmFunctionDecl :: LlvmFunctionDecl -> SDoc

-- | Print out a list of function definitions.
ppLlvmFunctions :: LlvmFunctions -> SDoc

-- | Print out a function definition.
ppLlvmFunction :: LlvmFunction -> SDoc


-- | This module supplies bindings to generate Llvm IR from Haskell
--   (<a>http://www.llvm.org/docs/LangRef.html</a>).
--   
--   Note: this module is developed in a demand driven way. It is no
--   complete LLVM binding library in Haskell, but enough to generate code
--   for GHC.
--   
--   This code is derived from code taken from the Essential Haskell
--   Compiler (EHC) project (<a>http://www.cs.uu.nl/wiki/Ehc/WebHome</a>).
module Llvm

-- | An LLVM Module. This is a top level container in LLVM.
data LlvmModule
LlvmModule :: [LMString] -> [LlvmAlias] -> [LlvmMeta] -> [LMGlobal] -> LlvmFunctionDecls -> LlvmFunctions -> LlvmModule

-- | Comments to include at the start of the module.
modComments :: LlvmModule -> [LMString]

-- | LLVM Alias type definitions.
modAliases :: LlvmModule -> [LlvmAlias]

-- | LLVM meta data.
modMeta :: LlvmModule -> [LlvmMeta]

-- | Global variables to include in the module.
modGlobals :: LlvmModule -> [LMGlobal]

-- | LLVM Functions used in this module but defined in other modules.
modFwdDecls :: LlvmModule -> LlvmFunctionDecls

-- | LLVM Functions defined in this module.
modFuncs :: LlvmModule -> LlvmFunctions

-- | An LLVM Function
data LlvmFunction
LlvmFunction :: LlvmFunctionDecl -> [LMString] -> [LlvmFuncAttr] -> LMSection -> LlvmBlocks -> LlvmFunction

-- | The signature of this declared function.
funcDecl :: LlvmFunction -> LlvmFunctionDecl

-- | The functions arguments
funcArgs :: LlvmFunction -> [LMString]

-- | The function attributes.
funcAttrs :: LlvmFunction -> [LlvmFuncAttr]

-- | The section to put the function into,
funcSect :: LlvmFunction -> LMSection

-- | The body of the functions.
funcBody :: LlvmFunction -> LlvmBlocks

-- | An LLVM Function
data LlvmFunctionDecl
LlvmFunctionDecl :: LMString -> LlvmLinkageType -> LlvmCallConvention -> LlvmType -> LlvmParameterListType -> [LlvmParameter] -> LMAlign -> LlvmFunctionDecl

-- | Unique identifier of the function
decName :: LlvmFunctionDecl -> LMString

-- | LinkageType of the function
funcLinkage :: LlvmFunctionDecl -> LlvmLinkageType

-- | The calling convention of the function
funcCc :: LlvmFunctionDecl -> LlvmCallConvention

-- | Type of the returned value
decReturnType :: LlvmFunctionDecl -> LlvmType

-- | Indicates if this function uses varargs
decVarargs :: LlvmFunctionDecl -> LlvmParameterListType

-- | Parameter types and attributes
decParams :: LlvmFunctionDecl -> [LlvmParameter]

-- | Function align value, must be power of 2
funcAlign :: LlvmFunctionDecl -> LMAlign
type LlvmFunctions = [LlvmFunction]
type LlvmFunctionDecls = [LlvmFunctionDecl]

-- | Llvm Statements
data LlvmStatement

-- | Assign an expression to an variable: * dest: Variable to assign to *
--   source: Source expression
Assignment :: LlvmVar -> LlvmExpression -> LlvmStatement

-- | Memory fence operation
Fence :: Bool -> LlvmSyncOrdering -> LlvmStatement

-- | Always branch to the target label
Branch :: LlvmVar -> LlvmStatement

-- | Branch to label targetTrue if cond is true otherwise to label
--   targetFalse * cond: condition that will be tested, must be of type i1
--   * targetTrue: label to branch to if cond is true * targetFalse: label
--   to branch to if cond is false
BranchIf :: LlvmVar -> LlvmVar -> LlvmVar -> LlvmStatement

-- | Comment Plain comment.
Comment :: [LMString] -> LlvmStatement

-- | Set a label on this position. * name: Identifier of this label, unique
--   for this module
MkLabel :: LlvmBlockId -> LlvmStatement

-- | Store variable value in pointer ptr. If value is of type t then ptr
--   must be of type t*. * value: Variable/Constant to store. * ptr:
--   Location to store the value in
Store :: LlvmVar -> LlvmVar -> LlvmStatement

-- | Mutliway branch * scrutinee: Variable or constant which must be of
--   integer type that is determines which arm is chosen. * def: The
--   default label if there is no match in target. * target: A list of
--   (value,label) where the value is an integer constant and label the
--   corresponding label to jump to if the scrutinee matches the value.
Switch :: LlvmVar -> LlvmVar -> [(LlvmVar, LlvmVar)] -> LlvmStatement

-- | Return a result. * result: The variable or constant to return
Return :: (Maybe LlvmVar) -> LlvmStatement

-- | An instruction for the optimizer that the code following is not
--   reachable
Unreachable :: LlvmStatement

-- | Raise an expression to a statement (if don't want result or want to
--   use Llvm unnamed values.
Expr :: LlvmExpression -> LlvmStatement

-- | A nop LLVM statement. Useful as its often more efficient to use this
--   then to wrap LLvmStatement in a Just or [].
Nop :: LlvmStatement

-- | A LLVM statement with metadata attached to it.
MetaStmt :: [MetaData] -> LlvmStatement -> LlvmStatement

-- | Llvm Expressions
data LlvmExpression

-- | Allocate amount * sizeof(tp) bytes on the stack * tp: LlvmType to
--   reserve room for * amount: The nr of tp's which must be allocated
Alloca :: LlvmType -> Int -> LlvmExpression

-- | Perform the machine operator op on the operands left and right * op:
--   operator * left: left operand * right: right operand
LlvmOp :: LlvmMachOp -> LlvmVar -> LlvmVar -> LlvmExpression

-- | Perform a compare operation on the operands left and right * op:
--   operator * left: left operand * right: right operand
Compare :: LlvmCmpOp -> LlvmVar -> LlvmVar -> LlvmExpression

-- | Allocate amount * sizeof(tp) bytes on the heap * tp: LlvmType to
--   reserve room for * amount: The nr of tp's which must be allocated
Malloc :: LlvmType -> Int -> LlvmExpression

-- | Load the value at location ptr
Load :: LlvmVar -> LlvmExpression

-- | Navigate in an structure, selecting elements * inbound: Is the pointer
--   inbounds? (computed pointer doesn't overflow) * ptr: Location of the
--   structure * indexes: A list of indexes to select the correct value.
GetElemPtr :: Bool -> LlvmVar -> [LlvmVar] -> LlvmExpression

-- | Cast the variable from to the to type. This is an abstraction of three
--   cast operators in Llvm, inttoptr, prttoint and bitcast. * cast: Cast
--   type * from: Variable to cast * to: type to cast to
Cast :: LlvmCastOp -> LlvmVar -> LlvmType -> LlvmExpression

-- | Call a function. The result is the value of the expression. *
--   tailJumps: CallType to signal if the function should be tail called *
--   fnptrval: An LLVM value containing a pointer to a function to be
--   invoked. Can be indirect. Should be LMFunction type. * args: Concrete
--   arguments for the parameters * attrs: A list of function attributes
--   for the call. Only NoReturn, NoUnwind, ReadOnly and ReadNone are valid
--   here.
Call :: LlvmCallType -> LlvmVar -> [LlvmVar] -> [LlvmFuncAttr] -> LlvmExpression

-- | Merge variables from different basic blocks which are predecessors of
--   this basic block in a new variable of type tp. * tp: type of the
--   merged variable, must match the types of the predecessor variables. *
--   precessors: A list of variables and the basic block that they
--   originate from.
Phi :: LlvmType -> [(LlvmVar, LlvmVar)] -> LlvmExpression

-- | Inline assembly expression. Syntax is very similar to the style used
--   by GCC. * assembly: Actual inline assembly code. * contraints: Operand
--   constraints. * return ty: Return type of function. * vars: Any
--   variables involved in the assembly code. * sideeffect: Does the
--   expression have side effects not visible from the constraints list. *
--   alignstack: Should the stack be conservatively aligned before this
--   expression is executed.
Asm :: LMString -> LMString -> LlvmType -> [LlvmVar] -> Bool -> Bool -> LlvmExpression

-- | A LLVM expression with metadata attached to it.
MetaExpr :: [MetaData] -> LlvmExpression -> LlvmExpression
type LlvmBlocks = [LlvmBlock]

-- | A block of LLVM code.
data LlvmBlock
LlvmBlock :: LlvmBlockId -> [LlvmStatement] -> LlvmBlock

-- | The code label for this block
blockLabel :: LlvmBlock -> LlvmBlockId

-- | A list of LlvmStatement's representing the code for this block. This
--   list must end with a control flow statement.
blockStmts :: LlvmBlock -> [LlvmStatement]

-- | Block labels
type LlvmBlockId = Unique

-- | LLVM Parameter Attributes.
--   
--   Parameter attributes are used to communicate additional information
--   about the result or parameters of a function
data LlvmParamAttr

-- | This indicates to the code generator that the parameter or return
--   value should be zero-extended to a 32-bit value by the caller (for a
--   parameter) or the callee (for a return value).
ZeroExt :: LlvmParamAttr

-- | This indicates to the code generator that the parameter or return
--   value should be sign-extended to a 32-bit value by the caller (for a
--   parameter) or the callee (for a return value).
SignExt :: LlvmParamAttr

-- | This indicates that this parameter or return value should be treated
--   in a special target-dependent fashion during while emitting code for a
--   function call or return (usually, by putting it in a register as
--   opposed to memory).
InReg :: LlvmParamAttr

-- | This indicates that the pointer parameter should really be passed by
--   value to the function.
ByVal :: LlvmParamAttr

-- | This indicates that the pointer parameter specifies the address of a
--   structure that is the return value of the function in the source
--   program.
SRet :: LlvmParamAttr

-- | This indicates that the pointer does not alias any global or any other
--   parameter.
NoAlias :: LlvmParamAttr

-- | This indicates that the callee does not make any copies of the pointer
--   that outlive the callee itself
NoCapture :: LlvmParamAttr

-- | This indicates that the pointer parameter can be excised using the
--   trampoline intrinsics.
Nest :: LlvmParamAttr
type LlvmParameter = (LlvmType, [LlvmParamAttr])

-- | LLVM ordering types for synchronization purposes. (Introduced in LLVM
--   3.0). Please see the LLVM documentation for a better description.
data LlvmSyncOrdering

-- | Some partial order of operations exists.
SyncUnord :: LlvmSyncOrdering

-- | A single total order for operations at a single address exists.
SyncMonotonic :: LlvmSyncOrdering

-- | Acquire synchronization operation.
SyncAcquire :: LlvmSyncOrdering

-- | Release synchronization operation.
SyncRelease :: LlvmSyncOrdering

-- | Acquire + Release synchronization operation.
SyncAcqRel :: LlvmSyncOrdering

-- | Full sequential Consistency operation.
SyncSeqCst :: LlvmSyncOrdering

-- | Different calling conventions a function can use.
data LlvmCallConvention

-- | The C calling convention. This calling convention (the default if no
--   other calling convention is specified) matches the target C calling
--   conventions. This calling convention supports varargs function calls
--   and tolerates some mismatch in the declared prototype and implemented
--   declaration of the function (as does normal C).
CC_Ccc :: LlvmCallConvention

-- | This calling convention attempts to make calls as fast as possible
--   (e.g. by passing things in registers). This calling convention allows
--   the target to use whatever tricks it wants to produce fast code for
--   the target, without having to conform to an externally specified ABI
--   (Application Binary Interface). Implementations of this convention
--   should allow arbitrary tail call optimization to be supported. This
--   calling convention does not support varargs and requires the prototype
--   of al callees to exactly match the prototype of the function
--   definition.
CC_Fastcc :: LlvmCallConvention

-- | This calling convention attempts to make code in the caller as
--   efficient as possible under the assumption that the call is not
--   commonly executed. As such, these calls often preserve all registers
--   so that the call does not break any live ranges in the caller side.
--   This calling convention does not support varargs and requires the
--   prototype of all callees to exactly match the prototype of the
--   function definition.
CC_Coldcc :: LlvmCallConvention

-- | Any calling convention may be specified by number, allowing
--   target-specific calling conventions to be used. Target specific
--   calling conventions start at 64.
CC_Ncc :: Int -> LlvmCallConvention

-- | X86 Specific <a>StdCall</a> convention. LLVM includes a specific alias
--   for it rather than just using CC_Ncc.
CC_X86_Stdcc :: LlvmCallConvention

-- | Different types to call a function.
data LlvmCallType

-- | Normal call, allocate a new stack frame.
StdCall :: LlvmCallType

-- | Tail call, perform the call in the current stack frame.
TailCall :: LlvmCallType

-- | Functions can have a fixed amount of parameters, or a variable amount.
data LlvmParameterListType
FixedArgs :: LlvmParameterListType
VarArgs :: LlvmParameterListType

-- | Linkage type of a symbol.
--   
--   The description of the constructors is copied from the Llvm Assembly
--   Language Reference Manual
--   <a>http://www.llvm.org/docs/LangRef.html#linkage</a>, because they
--   correspond to the Llvm linkage types.
data LlvmLinkageType

-- | Global values with internal linkage are only directly accessible by
--   objects in the current module. In particular, linking code into a
--   module with an internal global value may cause the internal to be
--   renamed as necessary to avoid collisions. Because the symbol is
--   internal to the module, all references can be updated. This
--   corresponds to the notion of the <tt>static</tt> keyword in C.
Internal :: LlvmLinkageType

-- | Globals with <tt>linkonce</tt> linkage are merged with other globals
--   of the same name when linkage occurs. This is typically used to
--   implement inline functions, templates, or other code which must be
--   generated in each translation unit that uses it. Unreferenced linkonce
--   globals are allowed to be discarded.
LinkOnce :: LlvmLinkageType

-- | <tt>weak</tt> linkage is exactly the same as linkonce linkage, except
--   that unreferenced weak globals may not be discarded. This is used for
--   globals that may be emitted in multiple translation units, but that
--   are not guaranteed to be emitted into every translation unit that uses
--   them. One example of this are common globals in C, such as <tt>int
--   X;</tt> at global scope.
Weak :: LlvmLinkageType

-- | <tt>appending</tt> linkage may only be applied to global variables of
--   pointer to array type. When two global variables with appending
--   linkage are linked together, the two global arrays are appended
--   together. This is the Llvm, typesafe, equivalent of having the system
--   linker append together <tt>sections</tt> with identical names when .o
--   files are linked.
Appending :: LlvmLinkageType

-- | The semantics of this linkage follow the ELF model: the symbol is weak
--   until linked, if not linked, the symbol becomes null instead of being
--   an undefined reference.
ExternWeak :: LlvmLinkageType

-- | The symbol participates in linkage and can be used to resolve external
--   symbol references.
ExternallyVisible :: LlvmLinkageType

-- | Alias for <a>ExternallyVisible</a> but with explicit textual form in
--   LLVM assembly.
External :: LlvmLinkageType

-- | Llvm Function Attributes.
--   
--   Function attributes are set to communicate additional information
--   about a function. Function attributes are considered to be part of the
--   function, not of the function type, so functions with different
--   parameter attributes can have the same function type. Functions can
--   have multiple attributes.
--   
--   Descriptions taken from
--   <a>http://llvm.org/docs/LangRef.html#fnattrs</a>
data LlvmFuncAttr

-- | This attribute indicates that the inliner should attempt to inline
--   this function into callers whenever possible, ignoring any active
--   inlining size threshold for this caller.
AlwaysInline :: LlvmFuncAttr

-- | This attribute indicates that the source code contained a hint that
--   inlining this function is desirable (such as the "inline" keyword in
--   C/C++). It is just a hint; it imposes no requirements on the inliner.
InlineHint :: LlvmFuncAttr

-- | This attribute indicates that the inliner should never inline this
--   function in any situation. This attribute may not be used together
--   with the alwaysinline attribute.
NoInline :: LlvmFuncAttr

-- | This attribute suggests that optimization passes and code generator
--   passes make choices that keep the code size of this function low, and
--   otherwise do optimizations specifically to reduce code size.
OptSize :: LlvmFuncAttr

-- | This function attribute indicates that the function never returns
--   normally. This produces undefined behavior at runtime if the function
--   ever does dynamically return.
NoReturn :: LlvmFuncAttr

-- | This function attribute indicates that the function never returns with
--   an unwind or exceptional control flow. If the function does unwind,
--   its runtime behavior is undefined.
NoUnwind :: LlvmFuncAttr

-- | This attribute indicates that the function computes its result (or
--   decides to unwind an exception) based strictly on its arguments,
--   without dereferencing any pointer arguments or otherwise accessing any
--   mutable state (e.g. memory, control registers, etc) visible to caller
--   functions. It does not write through any pointer arguments (including
--   byval arguments) and never changes any state visible to callers. This
--   means that it cannot unwind exceptions by calling the C++ exception
--   throwing methods, but could use the unwind instruction.
ReadNone :: LlvmFuncAttr

-- | This attribute indicates that the function does not write through any
--   pointer arguments (including byval arguments) or otherwise modify any
--   state (e.g. memory, control registers, etc) visible to caller
--   functions. It may dereference pointer arguments and read state that
--   may be set in the caller. A readonly function always returns the same
--   value (or unwinds an exception identically) when called with the same
--   set of arguments and global state. It cannot unwind an exception by
--   calling the C++ exception throwing methods, but may use the unwind
--   instruction.
ReadOnly :: LlvmFuncAttr

-- | This attribute indicates that the function should emit a stack
--   smashing protector. It is in the form of a "canary"—a random value
--   placed on the stack before the local variables that's checked upon
--   return from the function to see if it has been overwritten. A
--   heuristic is used to determine if a function needs stack protectors or
--   not.
--   
--   If a function that has an ssp attribute is inlined into a function
--   that doesn't have an ssp attribute, then the resulting function will
--   have an ssp attribute.
Ssp :: LlvmFuncAttr

-- | This attribute indicates that the function should always emit a stack
--   smashing protector. This overrides the ssp function attribute.
--   
--   If a function that has an sspreq attribute is inlined into a function
--   that doesn't have an sspreq attribute or which has an ssp attribute,
--   then the resulting function will have an sspreq attribute.
SspReq :: LlvmFuncAttr

-- | This attribute indicates that the code generator should not use a red
--   zone, even if the target-specific ABI normally permits it.
NoRedZone :: LlvmFuncAttr

-- | This attributes disables implicit floating point instructions.
NoImplicitFloat :: LlvmFuncAttr

-- | This attribute disables prologue / epilogue emission for the function.
--   This can have very system-specific consequences.
Naked :: LlvmFuncAttr

-- | Llvm compare operations.
data LlvmCmpOp

-- | Equal (Signed and Unsigned)
LM_CMP_Eq :: LlvmCmpOp

-- | Not equal (Signed and Unsigned)
LM_CMP_Ne :: LlvmCmpOp

-- | Unsigned greater than
LM_CMP_Ugt :: LlvmCmpOp

-- | Unsigned greater than or equal
LM_CMP_Uge :: LlvmCmpOp

-- | Unsigned less than
LM_CMP_Ult :: LlvmCmpOp

-- | Unsigned less than or equal
LM_CMP_Ule :: LlvmCmpOp

-- | Signed greater than
LM_CMP_Sgt :: LlvmCmpOp

-- | Signed greater than or equal
LM_CMP_Sge :: LlvmCmpOp

-- | Signed less than
LM_CMP_Slt :: LlvmCmpOp

-- | Signed less than or equal
LM_CMP_Sle :: LlvmCmpOp

-- | Float equal
LM_CMP_Feq :: LlvmCmpOp

-- | Float not equal
LM_CMP_Fne :: LlvmCmpOp

-- | Float greater than
LM_CMP_Fgt :: LlvmCmpOp

-- | Float greater than or equal
LM_CMP_Fge :: LlvmCmpOp

-- | Float less than
LM_CMP_Flt :: LlvmCmpOp

-- | Float less than or equal
LM_CMP_Fle :: LlvmCmpOp

-- | Llvm binary operators machine operations.
data LlvmMachOp

-- | add two integer, floating point or vector values.
LM_MO_Add :: LlvmMachOp

-- | subtract two ...
LM_MO_Sub :: LlvmMachOp

-- | multiply ..
LM_MO_Mul :: LlvmMachOp

-- | unsigned integer or vector division.
LM_MO_UDiv :: LlvmMachOp

-- | signed integer ..
LM_MO_SDiv :: LlvmMachOp

-- | unsigned integer or vector remainder (mod)
LM_MO_URem :: LlvmMachOp

-- | signed ...
LM_MO_SRem :: LlvmMachOp

-- | add two floating point or vector values.
LM_MO_FAdd :: LlvmMachOp

-- | subtract two ...
LM_MO_FSub :: LlvmMachOp

-- | multiply ...
LM_MO_FMul :: LlvmMachOp

-- | divide ...
LM_MO_FDiv :: LlvmMachOp

-- | remainder ...
LM_MO_FRem :: LlvmMachOp

-- | Left shift
LM_MO_Shl :: LlvmMachOp

-- | Logical shift right Shift right, filling with zero
LM_MO_LShr :: LlvmMachOp

-- | Arithmetic shift right The most significant bits of the result will be
--   equal to the sign bit of the left operand.
LM_MO_AShr :: LlvmMachOp

-- | AND bitwise logical operation.
LM_MO_And :: LlvmMachOp

-- | OR bitwise logical operation.
LM_MO_Or :: LlvmMachOp

-- | XOR bitwise logical operation.
LM_MO_Xor :: LlvmMachOp

-- | Llvm cast operations.
data LlvmCastOp

-- | Integer truncate
LM_Trunc :: LlvmCastOp

-- | Integer extend (zero fill)
LM_Zext :: LlvmCastOp

-- | Integer extend (sign fill)
LM_Sext :: LlvmCastOp

-- | Float truncate
LM_Fptrunc :: LlvmCastOp

-- | Float extend
LM_Fpext :: LlvmCastOp

-- | Float to unsigned Integer
LM_Fptoui :: LlvmCastOp

-- | Float to signed Integer
LM_Fptosi :: LlvmCastOp

-- | Unsigned Integer to Float
LM_Uitofp :: LlvmCastOp

-- | Signed Int to Float
LM_Sitofp :: LlvmCastOp

-- | Pointer to Integer
LM_Ptrtoint :: LlvmCastOp

-- | Integer to Pointer
LM_Inttoptr :: LlvmCastOp

-- | Cast between types where no bit manipulation is needed
LM_Bitcast :: LlvmCastOp

-- | LLVM Variables
data LlvmVar

-- | Variables with a global scope.
LMGlobalVar :: LMString -> LlvmType -> LlvmLinkageType -> LMSection -> LMAlign -> LMConst -> LlvmVar

-- | Variables local to a function or parameters.
LMLocalVar :: Unique -> LlvmType -> LlvmVar

-- | Named local variables. Sometimes we need to be able to explicitly name
--   variables (e.g for function arguments).
LMNLocalVar :: LMString -> LlvmType -> LlvmVar

-- | A constant variable
LMLitVar :: LlvmLit -> LlvmVar

-- | Llvm Static Data.
--   
--   These represent the possible global level variables and constants.
data LlvmStatic

-- | A comment in a static section
LMComment :: LMString -> LlvmStatic

-- | A static variant of a literal value
LMStaticLit :: LlvmLit -> LlvmStatic

-- | For uninitialised data
LMUninitType :: LlvmType -> LlvmStatic

-- | Defines a static <a>LMString</a>
LMStaticStr :: LMString -> LlvmType -> LlvmStatic

-- | A static array
LMStaticArray :: [LlvmStatic] -> LlvmType -> LlvmStatic

-- | A static structure type
LMStaticStruc :: [LlvmStatic] -> LlvmType -> LlvmStatic

-- | A pointer to other data
LMStaticPointer :: LlvmVar -> LlvmStatic

-- | Pointer to Pointer conversion
LMBitc :: LlvmStatic -> LlvmType -> LlvmStatic

-- | Pointer to Integer conversion
LMPtoI :: LlvmStatic -> LlvmType -> LlvmStatic

-- | Constant addition operation
LMAdd :: LlvmStatic -> LlvmStatic -> LlvmStatic

-- | Constant subtraction operation
LMSub :: LlvmStatic -> LlvmStatic -> LlvmStatic

-- | Llvm Literal Data.
--   
--   These can be used inline in expressions.
data LlvmLit

-- | Refers to an integer constant (i64 42).
LMIntLit :: Integer -> LlvmType -> LlvmLit

-- | Floating point literal
LMFloatLit :: Double -> LlvmType -> LlvmLit

-- | Literal NULL, only applicable to pointer types
LMNullLit :: LlvmType -> LlvmLit

-- | Undefined value, random bit pattern. Useful for optimisations.
LMUndefLit :: LlvmType -> LlvmLit

-- | Llvm Types
data LlvmType

-- | An integer with a given width in bits.
LMInt :: Int -> LlvmType

-- | 32 bit floating point
LMFloat :: LlvmType

-- | 64 bit floating point
LMDouble :: LlvmType

-- | 80 bit (x86 only) floating point
LMFloat80 :: LlvmType

-- | 128 bit floating point
LMFloat128 :: LlvmType

-- | A pointer to a <a>LlvmType</a>
LMPointer :: LlvmType -> LlvmType

-- | An array of <a>LlvmType</a>
LMArray :: Int -> LlvmType -> LlvmType

-- | A <a>LlvmVar</a> can represent a label (address)
LMLabel :: LlvmType

-- | Void type
LMVoid :: LlvmType

-- | Structure type
LMStruct :: [LlvmType] -> LlvmType

-- | A type alias
LMAlias :: LlvmAlias -> LlvmType

-- | Function type, used to create pointers to functions
LMFunction :: LlvmFunctionDecl -> LlvmType

-- | A type alias
type LlvmAlias = (LMString, LlvmType)

-- | A global mutable variable. Maybe defined or external
type LMGlobal = (LlvmVar, Maybe LlvmStatic)

-- | A String in LLVM
type LMString = FastString

-- | An LLVM section definition. If Nothing then let LLVM decide the
--   section
type LMSection = Maybe LMString
type LMAlign = Maybe Int
i64 :: LlvmType
i32 :: LlvmType
i16 :: LlvmType
i8 :: LlvmType
i1 :: LlvmType
i8Ptr :: LlvmType

-- | The target architectures word size
llvmWord :: LlvmType

-- | The target architectures word size
llvmWordPtr :: LlvmType

-- | LLVM metadata values. Used for representing debug and optimization
--   information.
data LlvmMetaVal

-- | Metadata string
MetaStr :: LMString -> LlvmMetaVal

-- | Metadata node
MetaNode :: LlvmMetaUnamed -> LlvmMetaVal

-- | Normal value type as metadata
MetaVar :: LlvmVar -> LlvmMetaVal

-- | Unamed metadata variable.
newtype LlvmMetaUnamed
LMMetaUnamed :: Int -> LlvmMetaUnamed

-- | LLVM metadata nodes.
data LlvmMeta

-- | Unamed metadata
MetaUnamed :: LlvmMetaUnamed -> [LlvmMetaVal] -> LlvmMeta

-- | Named metadata
MetaNamed :: LMString -> [LlvmMetaUnamed] -> LlvmMeta
type MetaData = (LMString, LlvmMetaUnamed)

-- | Test if a <a>LlvmVar</a> is global.
isGlobal :: LlvmVar -> Bool

-- | Return the <a>LlvmType</a> of a <a>LlvmLit</a>
getLitType :: LlvmLit -> LlvmType

-- | Print a literal value. No type.
getLit :: LlvmLit -> String

-- | Return the variable name or value of the <a>LlvmVar</a> in Llvm IR
--   textual representation (e.g. <tt>@x</tt>, <tt>%y</tt> or <tt>42</tt>).
getName :: LlvmVar -> String

-- | Return the variable name or value of the <a>LlvmVar</a> in a plain
--   textual representation (e.g. <tt>x</tt>, <tt>y</tt> or <tt>42</tt>).
getPlainName :: LlvmVar -> String

-- | Return the <a>LlvmType</a> of the <a>LlvmVar</a>
getVarType :: LlvmVar -> LlvmType

-- | Return the <a>LlvmLinkageType</a> for a <a>LlvmVar</a>
getLink :: LlvmVar -> LlvmLinkageType

-- | Return the <a>LlvmType</a> of the <a>LlvmStatic</a>
getStatType :: LlvmStatic -> LlvmType

-- | Return the <a>LlvmVar</a> part of a <a>LMGlobal</a>
getGlobalVar :: LMGlobal -> LlvmVar

-- | Return the <a>LlvmType</a> of the <a>LMGlobal</a>
getGlobalType :: LMGlobal -> LlvmType

-- | Lower a variable of <a>LMPointer</a> type.
pVarLift :: LlvmVar -> LlvmVar

-- | Lower a variable of <a>LMPointer</a> type.
pVarLower :: LlvmVar -> LlvmVar

-- | Add a pointer indirection to the supplied type. <a>LMLabel</a> and
--   <a>LMVoid</a> cannot be lifted.
pLift :: LlvmType -> LlvmType

-- | Remove the pointer indirection of the supplied type. Only
--   <a>LMPointer</a> constructors can be lowered.
pLower :: LlvmType -> LlvmType

-- | Test if the given <a>LlvmType</a> is an integer
isInt :: LlvmType -> Bool

-- | Test if the given <a>LlvmType</a> is a floating point type
isFloat :: LlvmType -> Bool

-- | Test if the given <a>LlvmType</a> is an <a>LMPointer</a> construct
isPointer :: LlvmType -> Bool

-- | Width in bits of an <a>LlvmType</a>, returns 0 if not applicable
llvmWidthInBits :: LlvmType -> Int

-- | Print out a whole LLVM module.
ppLlvmModule :: LlvmModule -> SDoc

-- | Print out a multi-line comment, can be inside a function or on its own
ppLlvmComments :: [LMString] -> SDoc

-- | Print out a comment, can be inside a function or on its own
ppLlvmComment :: LMString -> SDoc

-- | Print out a list of global mutable variable definitions
ppLlvmGlobals :: [LMGlobal] -> SDoc

-- | Print out a global mutable variable definition
ppLlvmGlobal :: LMGlobal -> SDoc

-- | Print out a list of function declaration.
ppLlvmFunctionDecls :: LlvmFunctionDecls -> SDoc

-- | Print out a function declaration. Declarations define the function
--   type but don't define the actual body of the function.
ppLlvmFunctionDecl :: LlvmFunctionDecl -> SDoc

-- | Print out a list of function definitions.
ppLlvmFunctions :: LlvmFunctions -> SDoc

-- | Print out a function definition.
ppLlvmFunction :: LlvmFunction -> SDoc

-- | Print out an LLVM type alias.
ppLlvmAlias :: LlvmAlias -> SDoc

-- | Print out a list of LLVM type aliases.
ppLlvmAliases :: [LlvmAlias] -> SDoc

-- | Print out a list of LLVM metadata.
ppLlvmMetas :: [LlvmMeta] -> SDoc

-- | Print out an LLVM metadata definition.
ppLlvmMeta :: LlvmMeta -> SDoc

module Digraph
data Graph node
graphFromVerticesAndAdjacency :: Ord key => [(node, key)] -> [(key, key)] -> Graph (node, key)
graphFromEdgedVertices :: Ord key => [Node key payload] -> Graph (Node key payload)
data SCC vertex
AcyclicSCC :: vertex -> SCC vertex
CyclicSCC :: [vertex] -> SCC vertex
type Node key payload = (payload, key, [key])
flattenSCC :: SCC a -> [a]
flattenSCCs :: [SCC a] -> [a]
stronglyConnCompG :: Graph node -> [SCC node]
topologicalSortG :: Graph node -> [node]
dfsTopSortG :: Graph node -> [[node]]
verticesG :: Graph node -> [node]
edgesG :: Graph node -> [Edge node]
hasVertexG :: Graph node -> node -> Bool
reachableG :: Graph node -> node -> [node]
transposeG :: Graph node -> Graph node
outdegreeG :: Graph node -> node -> Maybe Int
indegreeG :: Graph node -> node -> Maybe Int
vertexGroupsG :: Graph node -> [[node]]
emptyG :: Graph node -> Bool
componentsG :: Graph node -> [[node]]

-- | Find a reasonably short cycle a-&gt;b-&gt;c-&gt;a, in a strongly
--   connected component. The input nodes are presumed to be a SCC, so you
--   can start anywhere.
findCycle :: Ord key => [Node key payload] -> Maybe [payload]
stronglyConnCompFromEdgedVertices :: Ord key => [Node key payload] -> [SCC payload]
stronglyConnCompFromEdgedVerticesR :: Ord key => [Node key payload] -> [SCC (Node key payload)]
tabulate :: Bounds -> [Vertex] -> Table Int
preArr :: Bounds -> Forest Vertex -> Table Int
components :: IntGraph -> Forest Vertex
undirected :: IntGraph -> IntGraph
back :: IntGraph -> Table Int -> IntGraph
cross :: IntGraph -> Table Int -> Table Int -> IntGraph
forward :: IntGraph -> IntGraph -> Table Int -> IntGraph
path :: IntGraph -> Vertex -> Vertex -> Bool
bcc :: IntGraph -> Forest [Vertex]
do_label :: IntGraph -> Table Int -> Tree Vertex -> Tree (Vertex, Int, Int)
bicomps :: Tree (Vertex, Int, Int) -> Forest [Vertex]
collect :: Tree (Vertex, Int, Int) -> (Int, Tree [Vertex])
instance Show a => Show (Tree a)
instance Outputable node => Outputable (Edge node)
instance Outputable node => Outputable (Graph node)
instance Outputable a => Outputable (SCC a)
instance Functor SCC

module NameEnv
type NameEnv a = UniqFM a
mkNameEnv :: [(Name, a)] -> NameEnv a
emptyNameEnv :: NameEnv a
unitNameEnv :: Name -> a -> NameEnv a
nameEnvElts :: NameEnv a -> [a]
nameEnvUniqueElts :: NameEnv a -> [(Unique, a)]
extendNameEnv_C :: (a -> a -> a) -> NameEnv a -> Name -> a -> NameEnv a
extendNameEnv_Acc :: (a -> b -> b) -> (a -> b) -> NameEnv b -> Name -> a -> NameEnv b
extendNameEnv :: NameEnv a -> Name -> a -> NameEnv a
extendNameEnvList :: NameEnv a -> [(Name, a)] -> NameEnv a
extendNameEnvList_C :: (a -> a -> a) -> NameEnv a -> [(Name, a)] -> NameEnv a
foldNameEnv :: (a -> b -> b) -> b -> NameEnv a -> b
filterNameEnv :: (elt -> Bool) -> NameEnv elt -> NameEnv elt
plusNameEnv :: NameEnv a -> NameEnv a -> NameEnv a
plusNameEnv_C :: (a -> a -> a) -> NameEnv a -> NameEnv a -> NameEnv a
alterNameEnv :: (Maybe a -> Maybe a) -> NameEnv a -> Name -> NameEnv a
lookupNameEnv :: NameEnv a -> Name -> Maybe a
lookupNameEnv_NF :: NameEnv a -> Name -> a
delFromNameEnv :: NameEnv a -> Name -> NameEnv a
delListFromNameEnv :: NameEnv a -> [Name] -> NameEnv a
elemNameEnv :: Name -> NameEnv a -> Bool
mapNameEnv :: (elt1 -> elt2) -> NameEnv elt1 -> NameEnv elt2
depAnal :: (node -> [Name]) -> (node -> [Name]) -> [node] -> [SCC node]

module Avail

-- | A collection of <a>AvailInfo</a> - several things that are "available"
type Avails = [AvailInfo]

-- | Records what things are <a>available</a>, i.e. in scope
data AvailInfo

-- | An ordinary identifier in scope
Avail :: Name -> AvailInfo

-- | A type or class in scope. Parameters:
--   
--   1) The name of the type or class 2) The available pieces of type or
--   class.
--   
--   The AvailTC Invariant: * If the type or class is itself to be in
--   scope, it must be *first* in this list. Thus, typically: <tt>AvailTC
--   Eq [Eq, ==, /=]</tt>
AvailTC :: Name -> [Name] -> AvailInfo
availsToNameSet :: [AvailInfo] -> NameSet
availsToNameEnv :: [AvailInfo] -> NameEnv AvailInfo

-- | Just the main name made available, i.e. not the available pieces of
--   type or class brought into scope by the <tt>GenAvailInfo</tt>
availName :: AvailInfo -> Name

-- | All names made available by the availability information
availNames :: AvailInfo -> [Name]

-- | Compare lexicographically
stableAvailCmp :: AvailInfo -> AvailInfo -> Ordering

-- | make a <a>GlobalRdrEnv</a> where all the elements point to the same
--   Provenance (useful for <a>hiding</a> imports, or imports with no
--   details).
gresFromAvails :: Provenance -> [AvailInfo] -> [GlobalRdrElt]
gresFromAvail :: (Name -> Provenance) -> AvailInfo -> [GlobalRdrElt]
instance Eq AvailInfo
instance Outputable AvailInfo

module CmmType
data CmmType
b8 :: CmmType
b16 :: CmmType
b32 :: CmmType
b64 :: CmmType
f32 :: CmmType
f64 :: CmmType
bWord :: CmmType
bHalfWord :: CmmType
gcWord :: CmmType
cInt :: CmmType
cLong :: CmmType
cmmBits :: Width -> CmmType
cmmFloat :: Width -> CmmType
typeWidth :: CmmType -> Width
cmmEqType :: CmmType -> CmmType -> Bool
cmmEqType_ignoring_ptrhood :: CmmType -> CmmType -> Bool
isFloatType :: CmmType -> Bool
isGcPtrType :: CmmType -> Bool
isWord32 :: CmmType -> Bool
isWord64 :: CmmType -> Bool
isFloat64 :: CmmType -> Bool
isFloat32 :: CmmType -> Bool
data Width
W8 :: Width
W16 :: Width
W32 :: Width
W64 :: Width
W80 :: Width
W128 :: Width
widthInBits :: Width -> Int
widthInBytes :: Width -> Int
widthInLog :: Width -> Int
widthFromBytes :: Int -> Width
wordWidth :: Width
halfWordWidth :: Width
cIntWidth :: Width
cLongWidth :: Width
halfWordMask :: Integer
narrowU :: Width -> Integer -> Integer
narrowS :: Width -> Integer -> Integer
instance Eq CmmCat
instance Eq Width
instance Ord Width
instance Show Width
instance Outputable Width
instance Outputable CmmCat
instance Outputable CmmType

module CmmMachOp

-- | Machine-level primops; ones which we can reasonably delegate to the
--   native code generators to handle.
--   
--   Most operations are parameterised by the <a>Width</a> that they
--   operate on. Some operations have separate signed and unsigned
--   versions, and float and integer versions.
data MachOp
MO_Add :: Width -> MachOp
MO_Sub :: Width -> MachOp
MO_Eq :: Width -> MachOp
MO_Ne :: Width -> MachOp
MO_Mul :: Width -> MachOp
MO_S_MulMayOflo :: Width -> MachOp
MO_S_Quot :: Width -> MachOp
MO_S_Rem :: Width -> MachOp
MO_S_Neg :: Width -> MachOp
MO_U_MulMayOflo :: Width -> MachOp
MO_U_Quot :: Width -> MachOp
MO_U_Rem :: Width -> MachOp
MO_S_Ge :: Width -> MachOp
MO_S_Le :: Width -> MachOp
MO_S_Gt :: Width -> MachOp
MO_S_Lt :: Width -> MachOp
MO_U_Ge :: Width -> MachOp
MO_U_Le :: Width -> MachOp
MO_U_Gt :: Width -> MachOp
MO_U_Lt :: Width -> MachOp
MO_F_Add :: Width -> MachOp
MO_F_Sub :: Width -> MachOp
MO_F_Neg :: Width -> MachOp
MO_F_Mul :: Width -> MachOp
MO_F_Quot :: Width -> MachOp
MO_F_Eq :: Width -> MachOp
MO_F_Ne :: Width -> MachOp
MO_F_Ge :: Width -> MachOp
MO_F_Le :: Width -> MachOp
MO_F_Gt :: Width -> MachOp
MO_F_Lt :: Width -> MachOp
MO_And :: Width -> MachOp
MO_Or :: Width -> MachOp
MO_Xor :: Width -> MachOp
MO_Not :: Width -> MachOp
MO_Shl :: Width -> MachOp
MO_U_Shr :: Width -> MachOp
MO_S_Shr :: Width -> MachOp
MO_SF_Conv :: Width -> Width -> MachOp
MO_FS_Conv :: Width -> Width -> MachOp
MO_SS_Conv :: Width -> Width -> MachOp
MO_UU_Conv :: Width -> Width -> MachOp
MO_FF_Conv :: Width -> Width -> MachOp
pprMachOp :: MachOp -> SDoc

-- | Returns <a>True</a> if the MachOp has commutable arguments. This is
--   used in the platform-independent Cmm optimisations.
--   
--   If in doubt, return <a>False</a>. This generates worse code on the
--   native routes, but is otherwise harmless.
isCommutableMachOp :: MachOp -> Bool

-- | Returns <a>True</a> if the MachOp is associative (i.e. <tt>(x+y)+z ==
--   x+(y+z)</tt>) This is used in the platform-independent Cmm
--   optimisations.
--   
--   If in doubt, return <a>False</a>. This generates worse code on the
--   native routes, but is otherwise harmless.
isAssociativeMachOp :: MachOp -> Bool

-- | Returns <a>True</a> if the MachOp is a comparison.
--   
--   If in doubt, return False. This generates worse code on the native
--   routes, but is otherwise harmless.
isComparisonMachOp :: MachOp -> Bool

-- | Returns the MachRep of the result of a MachOp.
machOpResultType :: MachOp -> [CmmType] -> CmmType

-- | This function is used for debugging only: we can check whether an
--   application of a MachOp is <a>type-correct</a> by checking that the
--   MachReps of its arguments are the same as the MachOp expects. This is
--   used when linting a CmmExpr.
machOpArgReps :: MachOp -> [Width]
maybeInvertComparison :: MachOp -> Maybe MachOp
mo_wordAdd :: MachOp
mo_wordSub :: MachOp
mo_wordEq :: MachOp
mo_wordNe :: MachOp
mo_wordMul :: MachOp
mo_wordSQuot :: MachOp
mo_wordSRem :: MachOp
mo_wordSNeg :: MachOp
mo_wordUQuot :: MachOp
mo_wordURem :: MachOp
mo_wordSGe :: MachOp
mo_wordSLe :: MachOp
mo_wordSGt :: MachOp
mo_wordSLt :: MachOp
mo_wordUGe :: MachOp
mo_wordULe :: MachOp
mo_wordUGt :: MachOp
mo_wordULt :: MachOp
mo_wordAnd :: MachOp
mo_wordOr :: MachOp
mo_wordXor :: MachOp
mo_wordNot :: MachOp
mo_wordShl :: MachOp
mo_wordSShr :: MachOp
mo_wordUShr :: MachOp
mo_u_8To32 :: MachOp
mo_s_8To32 :: MachOp
mo_u_16To32 :: MachOp
mo_s_16To32 :: MachOp
mo_u_8ToWord :: MachOp
mo_s_8ToWord :: MachOp
mo_u_16ToWord :: MachOp
mo_s_16ToWord :: MachOp
mo_u_32ToWord :: MachOp
mo_s_32ToWord :: MachOp
mo_32To8 :: MachOp
mo_32To16 :: MachOp
mo_WordTo8 :: MachOp
mo_WordTo16 :: MachOp
mo_WordTo32 :: MachOp
data CallishMachOp
MO_F64_Pwr :: CallishMachOp
MO_F64_Sin :: CallishMachOp
MO_F64_Cos :: CallishMachOp
MO_F64_Tan :: CallishMachOp
MO_F64_Sinh :: CallishMachOp
MO_F64_Cosh :: CallishMachOp
MO_F64_Tanh :: CallishMachOp
MO_F64_Asin :: CallishMachOp
MO_F64_Acos :: CallishMachOp
MO_F64_Atan :: CallishMachOp
MO_F64_Log :: CallishMachOp
MO_F64_Exp :: CallishMachOp
MO_F64_Sqrt :: CallishMachOp
MO_F32_Pwr :: CallishMachOp
MO_F32_Sin :: CallishMachOp
MO_F32_Cos :: CallishMachOp
MO_F32_Tan :: CallishMachOp
MO_F32_Sinh :: CallishMachOp
MO_F32_Cosh :: CallishMachOp
MO_F32_Tanh :: CallishMachOp
MO_F32_Asin :: CallishMachOp
MO_F32_Acos :: CallishMachOp
MO_F32_Atan :: CallishMachOp
MO_F32_Log :: CallishMachOp
MO_F32_Exp :: CallishMachOp
MO_F32_Sqrt :: CallishMachOp
MO_S_QuotRem :: Width -> CallishMachOp
MO_U_QuotRem :: Width -> CallishMachOp
MO_U_QuotRem2 :: Width -> CallishMachOp
MO_Add2 :: Width -> CallishMachOp
MO_U_Mul2 :: Width -> CallishMachOp
MO_WriteBarrier :: CallishMachOp
MO_Touch :: CallishMachOp
MO_Memcpy :: CallishMachOp
MO_Memset :: CallishMachOp
MO_Memmove :: CallishMachOp
MO_PopCnt :: Width -> CallishMachOp
pprCallishMachOp :: CallishMachOp -> SDoc
instance Eq MachOp
instance Show MachOp
instance Eq CallishMachOp
instance Show CallishMachOp


-- | Generating C symbol names emitted by the compiler.
module CPrim
popCntLabel :: Width -> String

module HsLit
type PostTcKind = Kind
type PostTcType = Type
placeHolderType :: PostTcType
placeHolderKind :: PostTcKind
data HsLit
HsChar :: Char -> HsLit
HsCharPrim :: Char -> HsLit
HsString :: FastString -> HsLit
HsStringPrim :: FastString -> HsLit
HsInt :: Integer -> HsLit
HsIntPrim :: Integer -> HsLit
HsWordPrim :: Integer -> HsLit
HsInt64Prim :: Integer -> HsLit
HsWord64Prim :: Integer -> HsLit
HsInteger :: Integer -> Type -> HsLit
HsRat :: FractionalLit -> Type -> HsLit
HsFloatPrim :: FractionalLit -> HsLit
HsDoublePrim :: FractionalLit -> HsLit
data HsOverLit id
OverLit :: OverLitVal -> Bool -> SyntaxExpr id -> PostTcType -> HsOverLit id
ol_val :: HsOverLit id -> OverLitVal
ol_rebindable :: HsOverLit id -> Bool
ol_witness :: HsOverLit id -> SyntaxExpr id
ol_type :: HsOverLit id -> PostTcType
data OverLitVal
HsIntegral :: !Integer -> OverLitVal
HsFractional :: !FractionalLit -> OverLitVal
HsIsString :: !FastString -> OverLitVal
overLitType :: HsOverLit a -> Type
instance Typeable HsLit
instance Typeable OverLitVal
instance Typeable1 HsOverLit
instance Data HsLit
instance Data OverLitVal
instance Data id => Data (HsOverLit id)
instance Outputable OverLitVal
instance OutputableBndr id => Outputable (HsOverLit id)
instance Outputable HsLit
instance Ord OverLitVal
instance Ord (HsOverLit id)
instance Eq OverLitVal
instance Eq (HsOverLit id)
instance Eq HsLit

module HsDoc
newtype HsDocString
HsDocString :: FastString -> HsDocString
type LHsDocString = Located HsDocString
ppr_mbDoc :: Maybe LHsDocString -> SDoc
instance Typeable HsDocString
instance Eq HsDocString
instance Show HsDocString
instance Data HsDocString
instance Outputable HsDocString

module HsTypes
data HsType name
HsForAllTy :: HsExplicitFlag -> (LHsTyVarBndrs name) -> (LHsContext name) -> (LHsType name) -> HsType name
HsTyVar :: name -> HsType name
HsAppTy :: (LHsType name) -> (LHsType name) -> HsType name
HsFunTy :: (LHsType name) -> (LHsType name) -> HsType name
HsListTy :: (LHsType name) -> HsType name
HsPArrTy :: (LHsType name) -> HsType name
HsTupleTy :: HsTupleSort -> [LHsType name] -> HsType name
HsOpTy :: (LHsType name) -> (LHsTyOp name) -> (LHsType name) -> HsType name
HsParTy :: (LHsType name) -> HsType name
HsIParamTy :: HsIPName -> (LHsType name) -> HsType name
HsEqTy :: (LHsType name) -> (LHsType name) -> HsType name
HsKindSig :: (LHsType name) -> (LHsKind name) -> HsType name
HsQuasiQuoteTy :: (HsQuasiQuote name) -> HsType name
HsSpliceTy :: (HsSplice name) -> FreeVars -> PostTcKind -> HsType name
HsDocTy :: (LHsType name) -> LHsDocString -> HsType name
HsBangTy :: HsBang -> (LHsType name) -> HsType name
HsRecTy :: [ConDeclField name] -> HsType name
HsCoreTy :: Type -> HsType name
HsExplicitListTy :: PostTcKind -> [LHsType name] -> HsType name
HsExplicitTupleTy :: [PostTcKind] -> [LHsType name] -> HsType name
HsTyLit :: HsTyLit -> HsType name
HsWrapTy :: HsTyWrapper -> (HsType name) -> HsType name
type LHsType name = Located (HsType name)
type HsKind name = HsType name
type LHsKind name = Located (HsKind name)
data HsTyVarBndr name
UserTyVar :: name -> HsTyVarBndr name
KindedTyVar :: name -> (LHsKind name) -> HsTyVarBndr name
type LHsTyVarBndr name = Located (HsTyVarBndr name)
data LHsTyVarBndrs name
HsQTvs :: [Name] -> [LHsTyVarBndr name] -> LHsTyVarBndrs name
hsq_kvs :: LHsTyVarBndrs name -> [Name]
hsq_tvs :: LHsTyVarBndrs name -> [LHsTyVarBndr name]
data HsWithBndrs thing
HsWB :: thing -> [Name] -> [Name] -> HsWithBndrs thing
hswb_cts :: HsWithBndrs thing -> thing
hswb_kvs :: HsWithBndrs thing -> [Name]
hswb_tvs :: HsWithBndrs thing -> [Name]
data HsTupleSort
HsUnboxedTuple :: HsTupleSort
HsBoxedTuple :: HsTupleSort
HsConstraintTuple :: HsTupleSort
HsBoxedOrConstraintTuple :: HsTupleSort
data HsExplicitFlag
Explicit :: HsExplicitFlag
Implicit :: HsExplicitFlag
type HsContext name = [LHsType name]
type LHsContext name = Located (HsContext name)
data HsQuasiQuote id
HsQuasiQuote :: id -> SrcSpan -> FastString -> HsQuasiQuote id
data HsTyWrapper
WpKiApps :: [Kind] -> HsTyWrapper
data HsTyLit
HsNumTy :: Integer -> HsTyLit
HsStrTy :: FastString -> HsTyLit

-- | These names are used eary on to store the names of implicit
--   parameters. They completely disappear after type-checking.
newtype HsIPName
HsIPName :: FastString -> HsIPName
hsIPNameFS :: HsIPName -> FastString
type LBangType name = Located (BangType name)
type BangType name = HsType name
data HsBang
HsNoBang :: HsBang
HsStrict :: HsBang
HsUnpack :: HsBang
HsUnpackFailed :: HsBang
HsNoUnpack :: HsBang
getBangType :: LHsType a -> LHsType a
getBangStrictness :: LHsType a -> HsBang
data ConDeclField name
ConDeclField :: Located name -> LBangType name -> Maybe LHsDocString -> ConDeclField name
cd_fld_name :: ConDeclField name -> Located name
cd_fld_type :: ConDeclField name -> LBangType name
cd_fld_doc :: ConDeclField name -> Maybe LHsDocString
pprConDeclFields :: OutputableBndr name => [ConDeclField name] -> SDoc
mkHsQTvs :: [LHsTyVarBndr RdrName] -> LHsTyVarBndrs RdrName
hsQTvBndrs :: LHsTyVarBndrs name -> [LHsTyVarBndr name]
mkExplicitHsForAllTy :: [LHsTyVarBndr RdrName] -> LHsContext RdrName -> LHsType RdrName -> HsType RdrName
mkImplicitHsForAllTy :: LHsContext RdrName -> LHsType RdrName -> HsType RdrName
hsExplicitTvs :: LHsType name -> [name]
hsTyVarName :: HsTyVarBndr name -> name
mkHsWithBndrs :: thing -> HsWithBndrs thing
hsLKiTyVarNames :: LHsTyVarBndrs Name -> [Name]
hsLTyVarName :: LHsTyVarBndr name -> name
hsLTyVarNames :: LHsTyVarBndrs name -> [name]
hsLTyVarLocName :: LHsTyVarBndr name -> Located name
hsLTyVarLocNames :: LHsTyVarBndrs name -> [Located name]
splitLHsInstDeclTy_maybe :: LHsType name -> Maybe (LHsTyVarBndrs name, HsContext name, Located name, [LHsType name])
splitHsClassTy_maybe :: HsType name -> Maybe (name, [LHsType name])
splitLHsClassTy_maybe :: LHsType name -> Maybe (Located name, [LHsType name])
splitHsFunType :: LHsType name -> ([LHsType name], LHsType name)
splitHsAppTys :: LHsType n -> [LHsType n] -> (LHsType n, [LHsType n])
mkHsAppTys :: OutputableBndr n => LHsType n -> [LHsType n] -> HsType n
mkHsOpTy :: LHsType name -> Located name -> LHsType name -> HsType name
pprParendHsType :: OutputableBndr name => HsType name -> SDoc
pprHsForAll :: OutputableBndr name => HsExplicitFlag -> LHsTyVarBndrs name -> LHsContext name -> SDoc
pprHsContext :: OutputableBndr name => HsContext name -> SDoc
ppr_hs_context :: OutputableBndr name => HsContext name -> SDoc
instance Typeable1 HsQuasiQuote
instance Typeable1 HsWithBndrs
instance Typeable HsIPName
instance Typeable HsTyLit
instance Typeable HsTyWrapper
instance Typeable HsTupleSort
instance Typeable HsExplicitFlag
instance Typeable1 ConDeclField
instance Typeable1 HsType
instance Typeable1 LHsTyVarBndrs
instance Typeable1 HsTyVarBndr
instance Data id => Data (HsQuasiQuote id)
instance Data thing => Data (HsWithBndrs thing)
instance Eq HsIPName
instance Data HsIPName
instance Data HsTyLit
instance Data HsTyWrapper
instance Data HsTupleSort
instance Data HsExplicitFlag
instance Data name => Data (ConDeclField name)
instance Data name => Data (HsType name)
instance Data name => Data (LHsTyVarBndrs name)
instance Data name => Data (HsTyVarBndr name)
instance Outputable thing => Outputable (HsWithBndrs thing)
instance OutputableBndr name => Outputable (HsTyVarBndr name)
instance OutputableBndr name => Outputable (LHsTyVarBndrs name)
instance Outputable HsTyLit
instance OutputableBndr name => Outputable (HsType name)
instance OutputableBndr HsIPName
instance Outputable HsIPName
instance OutputableBndr id => Outputable (HsQuasiQuote id)

module HsImpExp
type LImportDecl name = Located (ImportDecl name)

-- | A single Haskell <tt>import</tt> declaration.
data ImportDecl name
ImportDecl :: Located ModuleName -> Maybe FastString -> Bool -> Bool -> Bool -> Bool -> Maybe ModuleName -> Maybe (Bool, [LIE name]) -> ImportDecl name

-- | Module name.
ideclName :: ImportDecl name -> Located ModuleName

-- | Package qualifier.
ideclPkgQual :: ImportDecl name -> Maybe FastString

-- | True <a>=</a> {--} import
ideclSource :: ImportDecl name -> Bool

-- | True =&gt; safe import
ideclSafe :: ImportDecl name -> Bool

-- | True =&gt; qualified
ideclQualified :: ImportDecl name -> Bool

-- | True =&gt; implicit import (of Prelude)
ideclImplicit :: ImportDecl name -> Bool

-- | as Module
ideclAs :: ImportDecl name -> Maybe ModuleName

-- | (True =&gt; hiding, names)
ideclHiding :: ImportDecl name -> Maybe (Bool, [LIE name])
simpleImportDecl :: ModuleName -> ImportDecl name
type LIE name = Located (IE name)

-- | Imported or exported entity.
data IE name
IEVar :: name -> IE name

-- | Class/Type (can't tell)
IEThingAbs :: name -> IE name

-- | Class<i>Type plus all methods</i>constructors
IEThingAll :: name -> IE name

-- | Class<i>Type plus some methods</i>constructors
IEThingWith :: name -> [name] -> IE name

-- | (Export Only)
IEModuleContents :: ModuleName -> IE name

-- | Doc section heading
IEGroup :: Int -> HsDocString -> IE name

-- | Some documentation
IEDoc :: HsDocString -> IE name

-- | Reference to named doc
IEDocNamed :: String -> IE name
ieName :: IE name -> name
ieNames :: IE a -> [a]
pprImpExp :: (HasOccName name, OutputableBndr name) => name -> SDoc
instance Typeable1 IE
instance Typeable1 ImportDecl
instance Eq name => Eq (IE name)
instance Data name => Data (IE name)
instance Data name => Data (ImportDecl name)
instance (HasOccName name, OutputableBndr name) => Outputable (IE name)
instance (OutputableBndr name, HasOccName name) => Outputable (ImportDecl name)


-- | Command-line parser
--   
--   This is an abstract command-line parser used by both StaticFlags and
--   DynFlags.
--   
--   (c) The University of Glasgow 2005
module CmdLineParser
processArgs :: Monad m => [Flag m] -> [Located String] -> m ([Located String], [Located String], [Located String])
data OptKind m
NoArg :: (EwM m ()) -> OptKind m
HasArg :: (String -> EwM m ()) -> OptKind m
SepArg :: (String -> EwM m ()) -> OptKind m
Prefix :: (String -> EwM m ()) -> OptKind m
OptPrefix :: (String -> EwM m ()) -> OptKind m
OptIntSuffix :: (Maybe Int -> EwM m ()) -> OptKind m
IntSuffix :: (Int -> EwM m ()) -> OptKind m
PassFlag :: (String -> EwM m ()) -> OptKind m
AnySuffix :: (String -> EwM m ()) -> OptKind m
PrefixPred :: (String -> Bool) -> (String -> EwM m ()) -> OptKind m
AnySuffixPred :: (String -> Bool) -> (String -> EwM m ()) -> OptKind m
newtype CmdLineP s a
CmdLineP :: (s -> (a, s)) -> CmdLineP s a
runCmdLine :: CmdLineP s a -> s -> (a, s)
getCmdLineState :: CmdLineP s s
putCmdLineState :: s -> CmdLineP s ()
data Flag m
Flag :: String -> OptKind m -> Flag m
flagName :: Flag m -> String
flagOptKind :: Flag m -> OptKind m
errorsToGhcException :: [Located String] -> GhcException
data EwM m a
addErr :: Monad m => String -> EwM m ()
addWarn :: Monad m => String -> EwM m ()
getArg :: Monad m => EwM m String
getCurLoc :: Monad m => EwM m SrcSpan
liftEwM :: Monad m => m a -> EwM m a
deprecate :: Monad m => String -> EwM m ()
instance Monad (CmdLineP s)
instance Monad m => Monad (EwM m)

module StaticFlagParser

-- | Parses GHC's static flags from a list of command line arguments.
--   
--   These flags are static in the sense that they can be set only once and
--   they are global, meaning that they affect every instance of GHC
--   running; multiple GHC threads will use the same flags.
--   
--   This function must be called before any session is started, i.e.,
--   before the first call to <a>withGhc</a>.
--   
--   Static flags are more of a hack and are static for more or less
--   historical reasons. In the long run, most static flags should
--   eventually become dynamic flags.
--   
--   XXX: can we add an auto-generated list of static flags here?
parseStaticFlags :: [Located String] -> IO ([Located String], [Located String])

-- | Parse GHC's static flags as <tt>parseStaticFlags</tt> does. However it
--   also takes a list of available static flags, such that certain flags
--   can be enabled or disabled through this argument.
parseStaticFlagsFull :: [Flag IO] -> [Located String] -> IO ([Located String], [Located String])
flagsStatic :: [Flag IO]


-- | Basic operations on graphs.
module GraphOps

-- | Add a node to the graph, linking up its edges
addNode :: Uniquable k => k -> Node k cls color -> Graph k cls color -> Graph k cls color

-- | Delete a node and all its edges from the graph.
delNode :: (Uniquable k, Outputable k) => k -> Graph k cls color -> Maybe (Graph k cls color)

-- | Get a node from the graph, throwing an error if it's not there
getNode :: Uniquable k => Graph k cls color -> k -> Node k cls color

-- | Lookup a node from the graph.
lookupNode :: Uniquable k => Graph k cls color -> k -> Maybe (Node k cls color)

-- | Modify a node in the graph. returns Nothing if the node isn't present.
modNode :: Uniquable k => (Node k cls color -> Node k cls color) -> k -> Graph k cls color -> Maybe (Graph k cls color)

-- | Get the size of the graph, O(n)
size :: Uniquable k => Graph k cls color -> Int

-- | Union two graphs together.
union :: Uniquable k => Graph k cls color -> Graph k cls color -> Graph k cls color

-- | Add a conflict between nodes to the graph, creating the nodes
--   required. Conflicts are virtual regs which need to be colored
--   differently.
addConflict :: Uniquable k => (k, cls) -> (k, cls) -> Graph k cls color -> Graph k cls color

-- | Delete a conflict edge. k1 -&gt; k2 returns Nothing if the node isn't
--   in the graph
delConflict :: Uniquable k => k -> k -> Graph k cls color -> Maybe (Graph k cls color)

-- | Add some conflicts to the graph, creating nodes if required. All the
--   nodes in the set are taken to conflict with each other.
addConflicts :: Uniquable k => UniqSet k -> (k -> cls) -> Graph k cls color -> Graph k cls color

-- | Add a coalescence edge to the graph, creating nodes if requried. It is
--   considered adventageous to assign the same color to nodes in a
--   coalesence.
addCoalesce :: Uniquable k => (k, cls) -> (k, cls) -> Graph k cls color -> Graph k cls color

-- | Delete a coalescence edge (k1 -&gt; k2) from the graph.
delCoalesce :: Uniquable k => k -> k -> Graph k cls color -> Maybe (Graph k cls color)

-- | Add an exclusion to the graph, creating nodes if required. These are
--   extra colors that the node cannot use.
addExclusion :: (Uniquable k, Uniquable color) => k -> (k -> cls) -> color -> Graph k cls color -> Graph k cls color
addExclusions :: (Uniquable k, Uniquable color) => k -> (k -> cls) -> [color] -> Graph k cls color -> Graph k cls color

-- | Add a color preference to the graph, creating nodes if required. The
--   most recently added preference is the most prefered. The algorithm
--   tries to assign a node it's prefered color if possible.
addPreference :: Uniquable k => (k, cls) -> color -> Graph k cls color -> Graph k cls color

-- | Coalesce this pair of nodes unconditionally / agressively. The
--   resulting node is the one with the least key.
--   
--   returns: Just the pair of keys if the nodes were coalesced the second
--   element of the pair being the least one
--   
--   Nothing if either of the nodes weren't in the graph
coalesceNodes :: (Uniquable k, Ord k, Eq cls, Outputable k) => Bool -> Triv k cls color -> Graph k cls color -> (k, k) -> (Graph k cls color, Maybe (k, k))

-- | Do agressive coalescing on this graph. returns the new graph and the
--   list of pairs of nodes that got coaleced together. for each pair, the
--   resulting node will have the least key and be second in the pair.
coalesceGraph :: (Uniquable k, Ord k, Eq cls, Outputable k) => Bool -> Triv k cls color -> Graph k cls color -> (Graph k cls color, [(k, k)])

-- | Freeze a node This is for the iterative coalescer. By freezing a node
--   we give up on ever coalescing it. Move all its coalesce edges into the
--   frozen set - and update back edges from other nodes.
freezeNode :: Uniquable k => k -> Graph k cls color -> Graph k cls color

-- | Freeze one node in the graph This if for the iterative coalescer. Look
--   for a move related node of low degree and freeze it.
--   
--   We probably don't need to scan the whole graph looking for the node of
--   absolute lowest degree. Just sample the first few and choose the one
--   with the lowest degree out of those. Also, we don't make any
--   distinction between conflicts of different classes.. this is just a
--   heuristic, after all.
--   
--   IDEA: freezing a node might free it up for Simplify.. would be good to
--   check for triv right here, and add it to a worklist if known
--   triv/non-move nodes.
freezeOneInGraph :: (Uniquable k, Outputable k) => Graph k cls color -> (Graph k cls color, Bool)

-- | Freeze all the nodes in the graph for debugging the iterative
--   allocator.
freezeAllInGraph :: (Uniquable k, Outputable k) => Graph k cls color -> Graph k cls color

-- | Find all the nodes in the graph that meet some criteria
scanGraph :: Uniquable k => (Node k cls color -> Bool) -> Graph k cls color -> [Node k cls color]

-- | Set the color of a certain node
setColor :: Uniquable k => k -> color -> Graph k cls color -> Graph k cls color

-- | validate the internal structure of a graph all its edges should point
--   to valid nodes If they don't then throw an error
validateGraph :: (Uniquable k, Outputable k, Eq color) => SDoc -> Bool -> Graph k cls color -> Graph k cls color

-- | Slurp out a map of how many nodes had a certain number of conflict
--   neighbours
slurpNodeConflictCount :: Uniquable k => Graph k cls color -> UniqFM (Int, Int)


-- | Pretty printing of graphs.
module GraphPpr

-- | Pretty print a graph in a somewhat human readable format.
dumpGraph :: (Outputable k, Outputable cls, Outputable color) => Graph k cls color -> SDoc

-- | Pretty print a graph in graphviz .dot format. Conflicts get solid
--   edges. Coalescences get dashed edges.
dotGraph :: (Uniquable k, Outputable k, Outputable cls, Outputable color) => (color -> SDoc) -> Triv k cls color -> Graph k cls color -> SDoc


-- | Graph Coloring. This is a generic graph coloring library, abstracted
--   over the type of the node keys, nodes and colors.
module GraphColor

-- | Try to color a graph with this set of colors. Uses Chaitin's algorithm
--   to color the graph. The graph is scanned for nodes which are deamed
--   'trivially colorable'. These nodes are pushed onto a stack and removed
--   from the graph. Once this process is complete the graph can be colored
--   by removing nodes from the stack (ie in reverse order) and assigning
--   them colors different to their neighbors.
colorGraph :: (Uniquable k, Uniquable cls, Uniquable color, Eq color, Eq cls, Ord k, Outputable k, Outputable cls, Outputable color) => Bool -> Int -> UniqFM (UniqSet color) -> Triv k cls color -> (Graph k cls color -> k) -> Graph k cls color -> (Graph k cls color, UniqSet k, UniqFM k)


-- | An architecture independent description of a register's class.
module RegClass

-- | The class of a register. Used in the register allocator. We treat all
--   registers in a class as being interchangable.
data RegClass
RcInteger :: RegClass
RcFloat :: RegClass
RcDouble :: RegClass
RcDoubleSSE :: RegClass
instance Eq RegClass
instance Outputable RegClass
instance Uniquable RegClass


-- | An architecture independent description of a register. This needs to
--   stay architecture independent because it is used by NCGMonad and the
--   register allocators, which are shared by all architectures.
module Reg

-- | An identifier for a primitive real machine register.
type RegNo = Int

-- | A register, either virtual or real
data Reg
RegVirtual :: !VirtualReg -> Reg
RegReal :: !RealReg -> Reg
regPair :: RegNo -> RegNo -> Reg
regSingle :: RegNo -> Reg
isRealReg :: Reg -> Bool
takeRealReg :: Reg -> Maybe RealReg
isVirtualReg :: Reg -> Bool
takeVirtualReg :: Reg -> Maybe VirtualReg
data VirtualReg
VirtualRegI :: {-# UNPACK #-} !Unique -> VirtualReg
VirtualRegHi :: {-# UNPACK #-} !Unique -> VirtualReg
VirtualRegF :: {-# UNPACK #-} !Unique -> VirtualReg
VirtualRegD :: {-# UNPACK #-} !Unique -> VirtualReg
VirtualRegSSE :: {-# UNPACK #-} !Unique -> VirtualReg
renameVirtualReg :: Unique -> VirtualReg -> VirtualReg
classOfVirtualReg :: VirtualReg -> RegClass
getHiVirtualRegFromLo :: VirtualReg -> VirtualReg
getHiVRegFromLo :: Reg -> Reg

-- | RealRegs are machine regs which are available for allocation, in the
--   usual way. We know what class they are, because that's part of the
--   processor's architecture.
--   
--   RealRegPairs are pairs of real registers that are allocated together
--   to hold a larger value, such as with Double regs on SPARC.
data RealReg
RealRegSingle :: {-# UNPACK #-} !RegNo -> RealReg
RealRegPair :: {-# UNPACK #-} !RegNo -> {-# UNPACK #-} !RegNo -> RealReg
regNosOfRealReg :: RealReg -> [RegNo]
realRegsAlias :: RealReg -> RealReg -> Bool

-- | The patch function supplied by the allocator maps VirtualReg to
--   RealReg regs, but sometimes we want to apply it to plain old Reg.
liftPatchFnToRegReg :: (VirtualReg -> RealReg) -> (Reg -> Reg)
instance Eq VirtualReg
instance Show VirtualReg
instance Ord VirtualReg
instance Eq RealReg
instance Show RealReg
instance Ord RealReg
instance Eq Reg
instance Ord Reg
instance Outputable Reg
instance Uniquable Reg
instance Outputable RealReg
instance Uniquable RealReg
instance Outputable VirtualReg
instance Uniquable VirtualReg


-- | Dynamic flags
--   
--   Most flags are dynamic flags, which means they can change from
--   compilation to compilation using <tt>OPTIONS_GHC</tt> pragmas, and in
--   a multi-session GHC each session can be using different dynamic flags.
--   Dynamic flags can also be set at the prompt in GHCi.
--   
--   (c) The University of Glasgow 2005
module DynFlags

-- | Enumerates the simple on-or-off dynamic flags
data DynFlag
Opt_D_dump_cmm :: DynFlag
Opt_D_dump_raw_cmm :: DynFlag
Opt_D_dump_cmmz :: DynFlag
Opt_D_dump_cmmz_cfg :: DynFlag
Opt_D_dump_cmmz_cbe :: DynFlag
Opt_D_dump_cmmz_proc :: DynFlag
Opt_D_dump_cmmz_spills :: DynFlag
Opt_D_dump_cmmz_rewrite :: DynFlag
Opt_D_dump_cmmz_dead :: DynFlag
Opt_D_dump_cmmz_stub :: DynFlag
Opt_D_dump_cmmz_sp :: DynFlag
Opt_D_dump_cmmz_procmap :: DynFlag
Opt_D_dump_cmmz_split :: DynFlag
Opt_D_dump_cmmz_lower :: DynFlag
Opt_D_dump_cmmz_info :: DynFlag
Opt_D_dump_cmmz_cafs :: DynFlag
Opt_D_dump_cps_cmm :: DynFlag
Opt_D_dump_cvt_cmm :: DynFlag
Opt_D_dump_asm :: DynFlag
Opt_D_dump_asm_native :: DynFlag
Opt_D_dump_asm_liveness :: DynFlag
Opt_D_dump_asm_coalesce :: DynFlag
Opt_D_dump_asm_regalloc :: DynFlag
Opt_D_dump_asm_regalloc_stages :: DynFlag
Opt_D_dump_asm_conflicts :: DynFlag
Opt_D_dump_asm_stats :: DynFlag
Opt_D_dump_asm_expanded :: DynFlag
Opt_D_dump_llvm :: DynFlag
Opt_D_dump_core_stats :: DynFlag
Opt_D_dump_cpranal :: DynFlag
Opt_D_dump_deriv :: DynFlag
Opt_D_dump_ds :: DynFlag
Opt_D_dump_flatC :: DynFlag
Opt_D_dump_foreign :: DynFlag
Opt_D_dump_inlinings :: DynFlag
Opt_D_dump_rule_firings :: DynFlag
Opt_D_dump_rule_rewrites :: DynFlag
Opt_D_dump_occur_anal :: DynFlag
Opt_D_dump_parsed :: DynFlag
Opt_D_dump_rn :: DynFlag
Opt_D_dump_core_pipeline :: DynFlag
Opt_D_dump_simpl :: DynFlag
Opt_D_dump_simpl_iterations :: DynFlag
Opt_D_dump_simpl_phases :: DynFlag
Opt_D_dump_spec :: DynFlag
Opt_D_dump_prep :: DynFlag
Opt_D_dump_stg :: DynFlag
Opt_D_dump_stranal :: DynFlag
Opt_D_dump_tc :: DynFlag
Opt_D_dump_types :: DynFlag
Opt_D_dump_rules :: DynFlag
Opt_D_dump_cse :: DynFlag
Opt_D_dump_worker_wrapper :: DynFlag
Opt_D_dump_rn_trace :: DynFlag
Opt_D_dump_rn_stats :: DynFlag
Opt_D_dump_opt_cmm :: DynFlag
Opt_D_dump_simpl_stats :: DynFlag
Opt_D_dump_cs_trace :: DynFlag
Opt_D_dump_tc_trace :: DynFlag
Opt_D_dump_if_trace :: DynFlag
Opt_D_dump_vt_trace :: DynFlag
Opt_D_dump_splices :: DynFlag
Opt_D_dump_BCOs :: DynFlag
Opt_D_dump_vect :: DynFlag
Opt_D_dump_avoid_vect :: DynFlag
Opt_D_dump_ticked :: DynFlag
Opt_D_dump_rtti :: DynFlag
Opt_D_source_stats :: DynFlag
Opt_D_verbose_core2core :: DynFlag
Opt_D_verbose_stg2stg :: DynFlag
Opt_D_dump_hi :: DynFlag
Opt_D_dump_hi_diffs :: DynFlag
Opt_D_dump_minimal_imports :: DynFlag
Opt_D_dump_mod_cycles :: DynFlag
Opt_D_dump_view_pattern_commoning :: DynFlag
Opt_D_faststring_stats :: DynFlag

-- | Append dump output to files instead of stdout.
Opt_DumpToFile :: DynFlag
Opt_D_no_debug_output :: DynFlag
Opt_DoCoreLinting :: DynFlag
Opt_DoStgLinting :: DynFlag
Opt_DoCmmLinting :: DynFlag
Opt_DoAsmLinting :: DynFlag
Opt_NoLlvmMangler :: DynFlag
Opt_WarnIsError :: DynFlag
Opt_PrintExplicitForalls :: DynFlag
Opt_Strictness :: DynFlag
Opt_FullLaziness :: DynFlag
Opt_FloatIn :: DynFlag
Opt_Specialise :: DynFlag
Opt_StaticArgumentTransformation :: DynFlag
Opt_CSE :: DynFlag
Opt_LiberateCase :: DynFlag
Opt_SpecConstr :: DynFlag
Opt_DoLambdaEtaExpansion :: DynFlag
Opt_IgnoreAsserts :: DynFlag
Opt_DoEtaReduction :: DynFlag
Opt_CaseMerge :: DynFlag
Opt_UnboxStrictFields :: DynFlag
Opt_DictsCheap :: DynFlag
Opt_EnableRewriteRules :: DynFlag
Opt_Vectorise :: DynFlag
Opt_AvoidVect :: DynFlag
Opt_RegsGraph :: DynFlag
Opt_RegsIterative :: DynFlag
Opt_PedanticBottoms :: DynFlag
Opt_LlvmTBAA :: DynFlag
Opt_RegLiveness :: DynFlag
Opt_IrrefutableTuples :: DynFlag
Opt_IgnoreInterfacePragmas :: DynFlag
Opt_OmitInterfacePragmas :: DynFlag
Opt_ExposeAllUnfoldings :: DynFlag
Opt_AutoSccsOnIndividualCafs :: DynFlag
Opt_ProfCountEntries :: DynFlag
Opt_Pp :: DynFlag
Opt_ForceRecomp :: DynFlag
Opt_ExcessPrecision :: DynFlag
Opt_EagerBlackHoling :: DynFlag
Opt_NoHsMain :: DynFlag
Opt_SplitObjs :: DynFlag
Opt_StgStats :: DynFlag
Opt_HideAllPackages :: DynFlag
Opt_PrintBindResult :: DynFlag
Opt_Haddock :: DynFlag
Opt_HaddockOptions :: DynFlag
Opt_Hpc_No_Auto :: DynFlag
Opt_BreakOnException :: DynFlag
Opt_BreakOnError :: DynFlag
Opt_PrintEvldWithShow :: DynFlag
Opt_PrintBindContents :: DynFlag
Opt_GenManifest :: DynFlag
Opt_EmbedManifest :: DynFlag
Opt_EmitExternalCore :: DynFlag
Opt_SharedImplib :: DynFlag
Opt_BuildingCabalPackage :: DynFlag
Opt_SSE2 :: DynFlag
Opt_SSE4_2 :: DynFlag
Opt_IgnoreDotGhci :: DynFlag
Opt_GhciSandbox :: DynFlag
Opt_GhciHistory :: DynFlag
Opt_HelpfulErrors :: DynFlag
Opt_DeferTypeErrors :: DynFlag
Opt_Parallel :: DynFlag
Opt_GranMacros :: DynFlag
Opt_PprCaseAsLet :: DynFlag
Opt_RunCPS :: DynFlag
Opt_RunCPSZ :: DynFlag
Opt_AutoLinkPackages :: DynFlag
Opt_ImplicitImportQualified :: DynFlag
Opt_TryNewCodeGen :: DynFlag
Opt_KeepHiDiffs :: DynFlag
Opt_KeepHcFiles :: DynFlag
Opt_KeepSFiles :: DynFlag
Opt_KeepTmpFiles :: DynFlag
Opt_KeepRawTokenStream :: DynFlag
Opt_KeepLlvmFiles :: DynFlag
Opt_DistrustAllPackages :: DynFlag
Opt_PackageTrust :: DynFlag
data WarningFlag
Opt_WarnDuplicateExports :: WarningFlag
Opt_WarnHiShadows :: WarningFlag
Opt_WarnImplicitPrelude :: WarningFlag
Opt_WarnIncompletePatterns :: WarningFlag
Opt_WarnIncompleteUniPatterns :: WarningFlag
Opt_WarnIncompletePatternsRecUpd :: WarningFlag
Opt_WarnMissingFields :: WarningFlag
Opt_WarnMissingImportList :: WarningFlag
Opt_WarnMissingMethods :: WarningFlag
Opt_WarnMissingSigs :: WarningFlag
Opt_WarnMissingLocalSigs :: WarningFlag
Opt_WarnNameShadowing :: WarningFlag
Opt_WarnOverlappingPatterns :: WarningFlag
Opt_WarnTypeDefaults :: WarningFlag
Opt_WarnMonomorphism :: WarningFlag
Opt_WarnUnusedBinds :: WarningFlag
Opt_WarnUnusedImports :: WarningFlag
Opt_WarnUnusedMatches :: WarningFlag
Opt_WarnWarningsDeprecations :: WarningFlag
Opt_WarnDeprecatedFlags :: WarningFlag
Opt_WarnDodgyExports :: WarningFlag
Opt_WarnDodgyImports :: WarningFlag
Opt_WarnOrphans :: WarningFlag
Opt_WarnAutoOrphans :: WarningFlag
Opt_WarnIdentities :: WarningFlag
Opt_WarnTabs :: WarningFlag
Opt_WarnUnrecognisedPragmas :: WarningFlag
Opt_WarnDodgyForeignImports :: WarningFlag
Opt_WarnLazyUnliftedBindings :: WarningFlag
Opt_WarnUnusedDoBind :: WarningFlag
Opt_WarnWrongDoBind :: WarningFlag
Opt_WarnAlternativeLayoutRuleTransitional :: WarningFlag
Opt_WarnUnsafe :: WarningFlag
Opt_WarnSafe :: WarningFlag
Opt_WarnPointlessPragmas :: WarningFlag
Opt_WarnUnsupportedCallingConventions :: WarningFlag
data ExtensionFlag
Opt_Cpp :: ExtensionFlag
Opt_OverlappingInstances :: ExtensionFlag
Opt_UndecidableInstances :: ExtensionFlag
Opt_IncoherentInstances :: ExtensionFlag
Opt_MonomorphismRestriction :: ExtensionFlag
Opt_MonoPatBinds :: ExtensionFlag
Opt_MonoLocalBinds :: ExtensionFlag
Opt_RelaxedPolyRec :: ExtensionFlag
Opt_ExtendedDefaultRules :: ExtensionFlag
Opt_ForeignFunctionInterface :: ExtensionFlag
Opt_UnliftedFFITypes :: ExtensionFlag
Opt_InterruptibleFFI :: ExtensionFlag
Opt_CApiFFI :: ExtensionFlag
Opt_GHCForeignImportPrim :: ExtensionFlag
Opt_ParallelArrays :: ExtensionFlag
Opt_Arrows :: ExtensionFlag
Opt_TemplateHaskell :: ExtensionFlag
Opt_QuasiQuotes :: ExtensionFlag
Opt_ImplicitParams :: ExtensionFlag
Opt_ImplicitPrelude :: ExtensionFlag
Opt_ScopedTypeVariables :: ExtensionFlag
Opt_UnboxedTuples :: ExtensionFlag
Opt_BangPatterns :: ExtensionFlag
Opt_TypeFamilies :: ExtensionFlag
Opt_OverloadedStrings :: ExtensionFlag
Opt_DisambiguateRecordFields :: ExtensionFlag
Opt_RecordWildCards :: ExtensionFlag
Opt_RecordPuns :: ExtensionFlag
Opt_ViewPatterns :: ExtensionFlag
Opt_GADTs :: ExtensionFlag
Opt_GADTSyntax :: ExtensionFlag
Opt_NPlusKPatterns :: ExtensionFlag
Opt_DoAndIfThenElse :: ExtensionFlag
Opt_RebindableSyntax :: ExtensionFlag
Opt_ConstraintKinds :: ExtensionFlag
Opt_PolyKinds :: ExtensionFlag
Opt_DataKinds :: ExtensionFlag
Opt_InstanceSigs :: ExtensionFlag
Opt_StandaloneDeriving :: ExtensionFlag
Opt_DeriveDataTypeable :: ExtensionFlag
Opt_DeriveFunctor :: ExtensionFlag
Opt_DeriveTraversable :: ExtensionFlag
Opt_DeriveFoldable :: ExtensionFlag
Opt_DeriveGeneric :: ExtensionFlag
Opt_DefaultSignatures :: ExtensionFlag
Opt_TypeSynonymInstances :: ExtensionFlag
Opt_FlexibleContexts :: ExtensionFlag
Opt_FlexibleInstances :: ExtensionFlag
Opt_ConstrainedClassMethods :: ExtensionFlag
Opt_MultiParamTypeClasses :: ExtensionFlag
Opt_FunctionalDependencies :: ExtensionFlag
Opt_UnicodeSyntax :: ExtensionFlag
Opt_PolymorphicComponents :: ExtensionFlag
Opt_ExistentialQuantification :: ExtensionFlag
Opt_MagicHash :: ExtensionFlag
Opt_EmptyDataDecls :: ExtensionFlag
Opt_KindSignatures :: ExtensionFlag
Opt_ParallelListComp :: ExtensionFlag
Opt_TransformListComp :: ExtensionFlag
Opt_MonadComprehensions :: ExtensionFlag
Opt_GeneralizedNewtypeDeriving :: ExtensionFlag
Opt_RecursiveDo :: ExtensionFlag
Opt_PostfixOperators :: ExtensionFlag
Opt_TupleSections :: ExtensionFlag
Opt_PatternGuards :: ExtensionFlag
Opt_LiberalTypeSynonyms :: ExtensionFlag
Opt_Rank2Types :: ExtensionFlag
Opt_RankNTypes :: ExtensionFlag
Opt_ImpredicativeTypes :: ExtensionFlag
Opt_TypeOperators :: ExtensionFlag
Opt_ExplicitNamespaces :: ExtensionFlag
Opt_PackageImports :: ExtensionFlag
Opt_ExplicitForAll :: ExtensionFlag
Opt_AlternativeLayoutRule :: ExtensionFlag
Opt_AlternativeLayoutRuleTransitional :: ExtensionFlag
Opt_DatatypeContexts :: ExtensionFlag
Opt_NondecreasingIndentation :: ExtensionFlag
Opt_RelaxedLayout :: ExtensionFlag
Opt_TraditionalRecordSyntax :: ExtensionFlag
Opt_LambdaCase :: ExtensionFlag
Opt_MultiWayIf :: ExtensionFlag
data Language
Haskell98 :: Language
Haskell2010 :: Language
type FatalMessager = String -> IO ()
type LogAction = DynFlags -> Severity -> SrcSpan -> PprStyle -> MsgDoc -> IO ()
newtype FlushOut
FlushOut :: (IO ()) -> FlushOut
newtype FlushErr
FlushErr :: (IO ()) -> FlushErr
data ProfAuto

-- | no SCC annotations added
NoProfAuto :: ProfAuto

-- | top-level and nested functions are annotated
ProfAutoAll :: ProfAuto

-- | top-level functions annotated only
ProfAutoTop :: ProfAuto

-- | exported functions annotated only
ProfAutoExports :: ProfAuto

-- | annotate call-sites
ProfAutoCalls :: ProfAuto
glasgowExtsFlags :: [ExtensionFlag]

-- | Test whether a <a>DynFlag</a> is set
dopt :: DynFlag -> DynFlags -> Bool

-- | Set a <a>DynFlag</a>
dopt_set :: DynFlags -> DynFlag -> DynFlags

-- | Unset a <a>DynFlag</a>
dopt_unset :: DynFlags -> DynFlag -> DynFlags

-- | Test whether a <a>WarningFlag</a> is set
wopt :: WarningFlag -> DynFlags -> Bool

-- | Set a <a>WarningFlag</a>
wopt_set :: DynFlags -> WarningFlag -> DynFlags

-- | Unset a <a>WarningFlag</a>
wopt_unset :: DynFlags -> WarningFlag -> DynFlags

-- | Test whether a <a>ExtensionFlag</a> is set
xopt :: ExtensionFlag -> DynFlags -> Bool

-- | Set a <a>ExtensionFlag</a>
xopt_set :: DynFlags -> ExtensionFlag -> DynFlags

-- | Unset a <a>ExtensionFlag</a>
xopt_unset :: DynFlags -> ExtensionFlag -> DynFlags
lang_set :: DynFlags -> Maybe Language -> DynFlags

-- | Contains not only a collection of <a>DynFlag</a>s but also a plethora
--   of information relating to the compilation of a single file or GHC
--   session
data DynFlags
DynFlags :: GhcMode -> GhcLink -> HscTarget -> Settings -> String -> String -> Int -> Int -> Int -> Int -> Maybe String -> Maybe String -> [Int] -> Int -> Maybe Int -> Maybe Int -> Maybe Int -> Maybe Int -> [String] -> [FilePath] -> Module -> Maybe String -> Int -> PackageId -> [Way] -> String -> String -> Maybe (String, Int) -> Maybe String -> Maybe String -> Maybe String -> Maybe String -> Maybe String -> String -> String -> String -> Maybe String -> Maybe String -> DynLibLoader -> Maybe FilePath -> Maybe FilePath -> [String] -> [String] -> [String] -> [String] -> Maybe String -> RtsOptsEnabled -> String -> [ModuleName] -> [(ModuleName, String)] -> FilePath -> Bool -> [ModuleName] -> [String] -> ([PkgConfRef] -> [PkgConfRef]) -> [PackageFlag] -> Maybe [PackageConfig] -> PackageState -> IORef [FilePath] -> IORef (Map FilePath FilePath) -> IORef (Set FilePath) -> IntSet -> IntSet -> Maybe Language -> SafeHaskellMode -> SrcSpan -> SrcSpan -> SrcSpan -> SrcSpan -> SrcSpan -> [OnOff ExtensionFlag] -> IntSet -> LogAction -> FlushOut -> FlushErr -> Maybe String -> [String] -> Int -> Int -> Int -> ProfAuto -> Maybe String -> IORef (Int) -> DynFlags
ghcMode :: DynFlags -> GhcMode
ghcLink :: DynFlags -> GhcLink
hscTarget :: DynFlags -> HscTarget
settings :: DynFlags -> Settings

-- | Name of the output file
hscOutName :: DynFlags -> String

-- | Name of the .hcr output file
extCoreName :: DynFlags -> String

-- | Verbosity level: see Note [Verbosity levels]
verbosity :: DynFlags -> Int

-- | Optimisation level
optLevel :: DynFlags -> Int

-- | Number of simplifier phases
simplPhases :: DynFlags -> Int

-- | Max simplifier iterations
maxSimplIterations :: DynFlags -> Int
shouldDumpSimplPhase :: DynFlags -> Maybe String
ruleCheck :: DynFlags -> Maybe String

-- | Additional demand analysis
strictnessBefore :: DynFlags -> [Int]

-- | Multiplier for simplifier ticks
simplTickFactor :: DynFlags -> Int

-- | Threshold for SpecConstr
specConstrThreshold :: DynFlags -> Maybe Int

-- | Max number of specialisations for any one function
specConstrCount :: DynFlags -> Maybe Int

-- | Threshold for LiberateCase
liberateCaseThreshold :: DynFlags -> Maybe Int

-- | Arg count for lambda floating See CoreMonad.FloatOutSwitches
floatLamArgs :: DynFlags -> Maybe Int

-- | <pre>
--   -#includes
--   </pre>
cmdlineHcIncludes :: DynFlags -> [String]
importPaths :: DynFlags -> [FilePath]
mainModIs :: DynFlags -> Module
mainFunIs :: DynFlags -> Maybe String

-- | Typechecker context stack depth
ctxtStkDepth :: DynFlags -> Int

-- | name of package currently being compiled
thisPackage :: DynFlags -> PackageId

-- | Way flags from the command line
ways :: DynFlags -> [Way]

-- | The global "way" (e.g. "p" for prof)
buildTag :: DynFlags -> String

-- | The RTS "way"
rtsBuildTag :: DynFlags -> String
splitInfo :: DynFlags -> Maybe (String, Int)
objectDir :: DynFlags -> Maybe String
dylibInstallName :: DynFlags -> Maybe String
hiDir :: DynFlags -> Maybe String
stubDir :: DynFlags -> Maybe String
dumpDir :: DynFlags -> Maybe String
objectSuf :: DynFlags -> String
hcSuf :: DynFlags -> String
hiSuf :: DynFlags -> String
outputFile :: DynFlags -> Maybe String
outputHi :: DynFlags -> Maybe String
dynLibLoader :: DynFlags -> DynLibLoader

-- | This is set by <a>runPipeline</a> based on where its output is going.
dumpPrefix :: DynFlags -> Maybe FilePath

-- | Override the <a>dumpPrefix</a> set by <a>runPipeline</a>. Set by
--   <tt>-ddump-file-prefix</tt>
dumpPrefixForce :: DynFlags -> Maybe FilePath
includePaths :: DynFlags -> [String]
libraryPaths :: DynFlags -> [String]
frameworkPaths :: DynFlags -> [String]
cmdlineFrameworks :: DynFlags -> [String]
rtsOpts :: DynFlags -> Maybe String
rtsOptsEnabled :: DynFlags -> RtsOptsEnabled

-- | Path to store the .mix files
hpcDir :: DynFlags -> String
pluginModNames :: DynFlags -> [ModuleName]
pluginModNameOpts :: DynFlags -> [(ModuleName, String)]
depMakefile :: DynFlags -> FilePath
depIncludePkgDeps :: DynFlags -> Bool
depExcludeMods :: DynFlags -> [ModuleName]
depSuffixes :: DynFlags -> [String]

-- | The <tt>-package-db</tt> flags given on the command line, in the order
--   they appeared.
extraPkgConfs :: DynFlags -> [PkgConfRef] -> [PkgConfRef]

-- | The <tt>-package</tt> and <tt>-hide-package</tt> flags from the
--   command-line
packageFlags :: DynFlags -> [PackageFlag]
pkgDatabase :: DynFlags -> Maybe [PackageConfig]
pkgState :: DynFlags -> PackageState
filesToClean :: DynFlags -> IORef [FilePath]
dirsToClean :: DynFlags -> IORef (Map FilePath FilePath)
generatedDumps :: DynFlags -> IORef (Set FilePath)
flags :: DynFlags -> IntSet
warningFlags :: DynFlags -> IntSet
language :: DynFlags -> Maybe Language

-- | Safe Haskell mode
safeHaskell :: DynFlags -> SafeHaskellMode
thOnLoc :: DynFlags -> SrcSpan
newDerivOnLoc :: DynFlags -> SrcSpan
pkgTrustOnLoc :: DynFlags -> SrcSpan
warnSafeOnLoc :: DynFlags -> SrcSpan
warnUnsafeOnLoc :: DynFlags -> SrcSpan
extensions :: DynFlags -> [OnOff ExtensionFlag]
extensionFlags :: DynFlags -> IntSet

-- | MsgDoc output action: use <a>ErrUtils</a> instead of this if you can
log_action :: DynFlags -> LogAction
flushOut :: DynFlags -> FlushOut
flushErr :: DynFlags -> FlushErr
haddockOptions :: DynFlags -> Maybe String
ghciScripts :: DynFlags -> [String]
pprUserLength :: DynFlags -> Int
pprCols :: DynFlags -> Int
traceLevel :: DynFlags -> Int

-- | what kind of {--} to add automatically
profAuto :: DynFlags -> ProfAuto
interactivePrint :: DynFlags -> Maybe String
llvmVersion :: DynFlags -> IORef (Int)
class HasDynFlags m
getDynFlags :: HasDynFlags m => m DynFlags
class ContainsDynFlags t
extractDynFlags :: ContainsDynFlags t => t -> DynFlags
data RtsOptsEnabled
RtsOptsNone :: RtsOptsEnabled
RtsOptsSafeOnly :: RtsOptsEnabled
RtsOptsAll :: RtsOptsEnabled

-- | The target code type of the compilation (if any).
--   
--   Whenever you change the target, also make sure to set <a>ghcLink</a>
--   to something sensible.
--   
--   <a>HscNothing</a> can be used to avoid generating any output, however,
--   note that:
--   
--   <ul>
--   <li>This will not run the desugaring step, thus no warnings generated
--   in this step will be output. In particular, this includes warnings
--   related to pattern matching. You can run the desugarer manually using
--   <a>desugarModule</a>.</li>
--   <li>If a program uses Template Haskell the typechecker may try to run
--   code from an imported module. This will fail if no code has been
--   generated for this module. You can use <a>needsTemplateHaskell</a> to
--   detect whether this might be the case and choose to either switch to a
--   different target or avoid typechecking such modules. (The latter may
--   be preferable for security reasons.)</li>
--   </ul>
data HscTarget

-- | Generate C code.
HscC :: HscTarget

-- | Generate assembly using the native code generator.
HscAsm :: HscTarget

-- | Generate assembly using the llvm code generator.
HscLlvm :: HscTarget

-- | Generate bytecode. (Requires <a>LinkInMemory</a>)
HscInterpreted :: HscTarget

-- | Don't generate any code. See notes above.
HscNothing :: HscTarget

-- | Will this target result in an object file on the disk?
isObjectTarget :: HscTarget -> Bool

-- | The <a>HscTarget</a> value corresponding to the default way to create
--   object files on the current platform.
defaultObjectTarget :: HscTarget

-- | Does this target retain *all* top-level bindings for a module, rather
--   than just the exported bindings, in the TypeEnv and compiled code (if
--   any)? In interpreted mode we do this, so that GHCi can call functions
--   inside a module. In HscNothing mode we also do it, so that Haddock can
--   get access to the GlobalRdrEnv for a module after typechecking it.
targetRetainsAllBindings :: HscTarget -> Bool

-- | The <a>GhcMode</a> tells us whether we're doing multi-module
--   compilation (controlled via the <a>GHC</a> API) or one-shot
--   (single-module) compilation. This makes a difference primarily to the
--   <a>Finder</a>: in one-shot mode we look for interface files for
--   imported modules, but in multi-module mode we look for source files in
--   order to check whether they need to be recompiled.
data GhcMode

-- | <tt>--make</tt>, GHCi, etc.
CompManager :: GhcMode

-- | <pre>
--   ghc -c Foo.hs
--   </pre>
OneShot :: GhcMode

-- | <tt>ghc -M</tt>, see <a>Finder</a> for why we need this
MkDepend :: GhcMode
isOneShot :: GhcMode -> Bool

-- | What to do in the link step, if there is one.
data GhcLink

-- | Don't link at all
NoLink :: GhcLink

-- | Link object code into a binary
LinkBinary :: GhcLink

-- | Use the in-memory dynamic linker (works for both bytecode and object
--   code).
LinkInMemory :: GhcLink

-- | Link objects into a dynamic lib (DLL on Windows, DSO on ELF platforms)
LinkDynLib :: GhcLink
isNoLink :: GhcLink -> Bool
data PackageFlag
ExposePackage :: String -> PackageFlag
ExposePackageId :: String -> PackageFlag
HidePackage :: String -> PackageFlag
IgnorePackage :: String -> PackageFlag
TrustPackage :: String -> PackageFlag
DistrustPackage :: String -> PackageFlag
data PkgConfRef
GlobalPkgConf :: PkgConfRef
UserPkgConf :: PkgConfRef
PkgConfFile :: FilePath -> PkgConfRef

-- | When invoking external tools as part of the compilation pipeline, we
--   pass these a sequence of options on the command-line. Rather than just
--   using a list of Strings, we use a type that allows us to distinguish
--   between filepaths and 'other stuff'. The reason for this is that this
--   type gives us a handle on transforming filenames, and filenames only,
--   to whatever format they're expected to be on a particular platform.
data Option
FileOption :: String -> String -> Option
Option :: String -> Option
showOpt :: Option -> String
data DynLibLoader
Deployable :: DynLibLoader
SystemDependent :: DynLibLoader

-- | These <tt>-f&lt;blah&gt;</tt> flags can all be reversed with
--   <tt>-fno-&lt;blah&gt;</tt>
fFlags :: [FlagSpec DynFlag]

-- | These <tt>-f&lt;blah&gt;</tt> flags can all be reversed with
--   <tt>-fno-&lt;blah&gt;</tt>
fWarningFlags :: [FlagSpec WarningFlag]

-- | These <tt>-f&lt;blah&gt;</tt> flags can all be reversed with
--   <tt>-fno-&lt;blah&gt;</tt>
fLangFlags :: [FlagSpec ExtensionFlag]

-- | These -X<a>blah</a> flags can all be reversed with -XNo<a>blah</a>
xFlags :: [FlagSpec ExtensionFlag]
wayNames :: DynFlags -> [WayName]

-- | Some modules have dependencies on others through the DynFlags rather
--   than textual imports
dynFlagDependencies :: DynFlags -> [ModuleName]
printOutputForUser :: DynFlags -> PrintUnqualified -> SDoc -> IO ()
printInfoForUser :: DynFlags -> PrintUnqualified -> SDoc -> IO ()

-- | The various Safe Haskell modes
data SafeHaskellMode
Sf_None :: SafeHaskellMode
Sf_Unsafe :: SafeHaskellMode
Sf_Trustworthy :: SafeHaskellMode
Sf_Safe :: SafeHaskellMode
Sf_SafeInferred :: SafeHaskellMode

-- | Is Safe Haskell on in some way (including inference mode)
safeHaskellOn :: DynFlags -> Bool

-- | Test if Safe Imports are on in some form
safeImportsOn :: DynFlags -> Bool

-- | Is the Safe Haskell safe language in use
safeLanguageOn :: DynFlags -> Bool

-- | Is the Safe Haskell safe inference mode active
safeInferOn :: DynFlags -> Bool

-- | Is the -fpackage-trust mode on
packageTrustOn :: DynFlags -> Bool

-- | Are all direct imports required to be safe for this Safe Haskell mode?
--   Direct imports are when the code explicitly imports a module
safeDirectImpsReq :: DynFlags -> Bool

-- | Are all implicit imports required to be safe for this Safe Haskell
--   mode? Implicit imports are things in the prelude. e.g System.IO when
--   print is used.
safeImplicitImpsReq :: DynFlags -> Bool

-- | A list of unsafe flags under Safe Haskell. Tuple elements are: * name
--   of the flag * function to get srcspan that enabled the flag * function
--   to test if the flag is on * function to turn the flag off
unsafeFlags :: [(String, DynFlags -> SrcSpan, DynFlags -> Bool, DynFlags -> DynFlags)]
data Settings
Settings :: Platform -> FilePath -> FilePath -> FilePath -> String -> [(String, String)] -> [String] -> FilePath -> String -> (String, [Option]) -> String -> (String, [Option]) -> (String, [Option]) -> (String, [Option]) -> (String, [Option]) -> (String, [Option]) -> String -> String -> String -> (String, [Option]) -> (String, [Option]) -> [String] -> [String] -> [String] -> [String] -> [String] -> [String] -> [String] -> [String] -> [String] -> Settings
sTargetPlatform :: Settings -> Platform
sGhcUsagePath :: Settings -> FilePath
sGhciUsagePath :: Settings -> FilePath
sTopDir :: Settings -> FilePath
sTmpDir :: Settings -> String
sRawSettings :: Settings -> [(String, String)]
sExtraGccViaCFlags :: Settings -> [String]
sSystemPackageConfig :: Settings -> FilePath
sPgm_L :: Settings -> String
sPgm_P :: Settings -> (String, [Option])
sPgm_F :: Settings -> String
sPgm_c :: Settings -> (String, [Option])
sPgm_s :: Settings -> (String, [Option])
sPgm_a :: Settings -> (String, [Option])
sPgm_l :: Settings -> (String, [Option])
sPgm_dll :: Settings -> (String, [Option])
sPgm_T :: Settings -> String
sPgm_sysman :: Settings -> String
sPgm_windres :: Settings -> String
sPgm_lo :: Settings -> (String, [Option])
sPgm_lc :: Settings -> (String, [Option])
sOpt_L :: Settings -> [String]
sOpt_P :: Settings -> [String]
sOpt_F :: Settings -> [String]
sOpt_c :: Settings -> [String]
sOpt_a :: Settings -> [String]
sOpt_l :: Settings -> [String]
sOpt_windres :: Settings -> [String]
sOpt_lo :: Settings -> [String]
sOpt_lc :: Settings -> [String]
targetPlatform :: DynFlags -> Platform
ghcUsagePath :: DynFlags -> FilePath
ghciUsagePath :: DynFlags -> FilePath
topDir :: DynFlags -> FilePath
tmpDir :: DynFlags -> String
rawSettings :: DynFlags -> [(String, String)]
extraGccViaCFlags :: DynFlags -> [String]
systemPackageConfig :: DynFlags -> FilePath
pgm_L :: DynFlags -> String
pgm_P :: DynFlags -> (String, [Option])
pgm_F :: DynFlags -> String
pgm_c :: DynFlags -> (String, [Option])
pgm_s :: DynFlags -> (String, [Option])
pgm_a :: DynFlags -> (String, [Option])
pgm_l :: DynFlags -> (String, [Option])
pgm_dll :: DynFlags -> (String, [Option])
pgm_T :: DynFlags -> String
pgm_sysman :: DynFlags -> String
pgm_windres :: DynFlags -> String
pgm_lo :: DynFlags -> (String, [Option])
pgm_lc :: DynFlags -> (String, [Option])
opt_L :: DynFlags -> [String]
opt_P :: DynFlags -> [String]
opt_F :: DynFlags -> [String]
opt_c :: DynFlags -> [String]
opt_a :: DynFlags -> [String]
opt_l :: DynFlags -> [String]
opt_windres :: DynFlags -> [String]
opt_lo :: DynFlags -> [String]
opt_lc :: DynFlags -> [String]

-- | The normal <a>DynFlags</a>. Note that they is not suitable for use in
--   this form and must be fully initialized by <a>newSession</a> first.
defaultDynFlags :: Settings -> DynFlags

-- | Used by <a>newSession</a> to partially initialize a new
--   <a>DynFlags</a> value
initDynFlags :: DynFlags -> IO DynFlags
defaultFatalMessager :: FatalMessager
defaultLogAction :: LogAction
defaultLogActionHPrintDoc :: DynFlags -> Handle -> SDoc -> PprStyle -> IO ()
defaultFlushOut :: FlushOut
defaultFlushErr :: FlushErr

-- | Retrieve the options corresponding to a particular <tt>opt_*</tt>
--   field in the correct order
getOpts :: DynFlags -> (DynFlags -> [a]) -> [a]

-- | Gets the verbosity flag for the current verbosity level. This is fed
--   to other tools, so GHC-specific verbosity flags like
--   <tt>-ddump-most</tt> are not included
getVerbFlags :: DynFlags -> [String]

-- | Sets the <a>DynFlags</a> to be appropriate to the optimisation level
updOptLevel :: Int -> DynFlags -> DynFlags
setTmpDir :: FilePath -> DynFlags -> DynFlags
setPackageName :: String -> DynFlags -> DynFlags
doingTickyProfiling :: DynFlags -> Bool

-- | Parse dynamic flags from a list of command line arguments. Returns the
--   the parsed <a>DynFlags</a>, the left-over arguments, and a list of
--   warnings. Throws a <a>UsageError</a> if errors occurred during parsing
--   (such as unknown flags or missing arguments).
parseDynamicFlagsCmdLine :: Monad m => DynFlags -> [Located String] -> m (DynFlags, [Located String], [Located String])

-- | Like <a>parseDynamicFlagsCmdLine</a> but does not allow the package
--   flags (-package, -hide-package, -ignore-package, -hide-all-packages,
--   -package-db). Used to parse flags set in a modules pragma.
parseDynamicFilePragma :: Monad m => DynFlags -> [Located String] -> m (DynFlags, [Located String], [Located String])

-- | Parses the dynamically set flags for GHC. This is the most general
--   form of the dynamic flag parser that the other methods simply wrap. It
--   allows saying which flags are valid flags and indicating if we are
--   parsing arguments from the command line or from a file pragma.
parseDynamicFlagsFull :: Monad m => [Flag (CmdLineP DynFlags)] -> Bool -> DynFlags -> [Located String] -> m (DynFlags, [Located String], [Located String])

-- | All dynamic flags option strings. These are the user facing strings
--   for enabling and disabling options.
allFlags :: [String]
flagsAll :: [Flag (CmdLineP DynFlags)]
flagsDynamic :: [Flag (CmdLineP DynFlags)]
flagsPackage :: [Flag (CmdLineP DynFlags)]
supportedLanguagesAndExtensions :: [String]
picCCOpts :: DynFlags -> [String]
data StgToDo
StgDoMassageForProfiling :: StgToDo
D_stg_stats :: StgToDo
getStgToDo :: DynFlags -> [StgToDo]
compilerInfo :: DynFlags -> [(String, String)]
rtsIsProfiled :: Bool
tracingDynFlags :: DynFlags
instance Eq DynFlag
instance Show DynFlag
instance Enum DynFlag
instance Eq WarningFlag
instance Show WarningFlag
instance Enum WarningFlag
instance Enum Language
instance Eq SafeHaskellMode
instance Eq ExtensionFlag
instance Enum ExtensionFlag
instance Show ExtensionFlag
instance Enum ProfAuto
instance Eq HscTarget
instance Show HscTarget
instance Eq GhcMode
instance Eq GhcLink
instance Show GhcLink
instance Eq PackageFlag
instance Eq DynLibLoader
instance Show RtsOptsEnabled
instance Eq Option
instance Outputable GhcMode
instance Outputable SafeHaskellMode
instance Show SafeHaskellMode

module ErrUtils
data ErrMsg
type WarnMsg = ErrMsg
data Severity
SevOutput :: Severity
SevDump :: Severity
SevInfo :: Severity
SevWarning :: Severity
SevError :: Severity
SevFatal :: Severity
type Messages = (WarningMessages, ErrorMessages)
type ErrorMessages = Bag ErrMsg
type WarningMessages = Bag WarnMsg
errMsgSpans :: ErrMsg -> [SrcSpan]
errMsgContext :: ErrMsg -> PrintUnqualified
errMsgShortDoc :: ErrMsg -> MsgDoc
errMsgExtraInfo :: ErrMsg -> MsgDoc
type MsgDoc = SDoc
mkLocMessage :: Severity -> SrcSpan -> MsgDoc -> MsgDoc
pprMessageBag :: Bag MsgDoc -> SDoc
pprErrMsgBag :: Bag ErrMsg -> [SDoc]
pprErrMsgBagWithLoc :: Bag ErrMsg -> [SDoc]
pprLocErrMsg :: ErrMsg -> SDoc
makeIntoWarning :: ErrMsg -> ErrMsg
errorsFound :: DynFlags -> Messages -> Bool
emptyMessages :: Messages
isEmptyMessages :: Messages -> Bool
mkErrMsg :: DynFlags -> SrcSpan -> PrintUnqualified -> MsgDoc -> ErrMsg
mkPlainErrMsg :: DynFlags -> SrcSpan -> MsgDoc -> ErrMsg
mkLongErrMsg :: DynFlags -> SrcSpan -> PrintUnqualified -> MsgDoc -> MsgDoc -> ErrMsg
mkWarnMsg :: DynFlags -> SrcSpan -> PrintUnqualified -> MsgDoc -> ErrMsg
mkPlainWarnMsg :: DynFlags -> SrcSpan -> MsgDoc -> ErrMsg
printBagOfErrors :: DynFlags -> Bag ErrMsg -> IO ()
warnIsErrorMsg :: DynFlags -> ErrMsg
mkLongWarnMsg :: DynFlags -> SrcSpan -> PrintUnqualified -> MsgDoc -> MsgDoc -> ErrMsg
ghcExit :: DynFlags -> Int -> IO ()
doIfSet :: Bool -> IO () -> IO ()
doIfSet_dyn :: DynFlags -> DynFlag -> IO () -> IO ()
dumpIfSet :: DynFlags -> Bool -> String -> SDoc -> IO ()
dumpIfSet_dyn :: DynFlags -> DynFlag -> String -> SDoc -> IO ()
dumpIfSet_dyn_or :: DynFlags -> [DynFlag] -> String -> SDoc -> IO ()
mkDumpDoc :: String -> SDoc -> SDoc

-- | Write out a dump. If --dump-to-file is set then this goes to a file.
--   otherwise emit to stdout.
--   
--   When hdr is empty, we print in a more compact format (no separators
--   and blank lines)
dumpSDoc :: DynFlags -> DynFlag -> String -> SDoc -> IO ()
putMsg :: DynFlags -> MsgDoc -> IO ()
putMsgWith :: DynFlags -> PrintUnqualified -> MsgDoc -> IO ()
errorMsg :: DynFlags -> MsgDoc -> IO ()
fatalErrorMsg :: DynFlags -> MsgDoc -> IO ()
fatalErrorMsg' :: LogAction -> DynFlags -> MsgDoc -> IO ()
fatalErrorMsg'' :: FatalMessager -> String -> IO ()
compilationProgressMsg :: DynFlags -> String -> IO ()
showPass :: DynFlags -> String -> IO ()
debugTraceMsg :: DynFlags -> Int -> MsgDoc -> IO ()
prettyPrintGhcErrors :: ExceptionMonad m => DynFlags -> m a -> m a
instance Show ErrMsg

module Unify
tcMatchTy :: TyVarSet -> Type -> Type -> Maybe TvSubst
tcMatchTys :: TyVarSet -> [Type] -> [Type] -> Maybe TvSubst
tcMatchTyX :: TyVarSet -> TvSubst -> Type -> Type -> Maybe TvSubst
ruleMatchTyX :: MatchEnv -> TvSubstEnv -> Type -> Type -> Maybe TvSubstEnv
tcMatchPreds :: [TyVar] -> [PredType] -> [PredType] -> Maybe TvSubstEnv
data MatchEnv
ME :: VarSet -> RnEnv2 -> MatchEnv
me_tmpls :: MatchEnv -> VarSet
me_env :: MatchEnv -> RnEnv2
matchList :: (env -> a -> b -> Maybe env) -> env -> [a] -> [b] -> Maybe env
typesCantMatch :: [(Type, Type)] -> Bool
tcUnifyTys :: (TyVar -> BindFlag) -> [Type] -> [Type] -> Maybe TvSubst
data BindFlag
BindMe :: BindFlag
Skolem :: BindFlag
niFixTvSubst :: TvSubstEnv -> TvSubst
niSubstTvSet :: TvSubstEnv -> TyVarSet -> TyVarSet
instance Monad UM


-- | Module for (a) type kinds and (b) type coercions, as used in System
--   FC. See <a>Expr</a> for more on System FC and how coercions fit into
--   it.
module Coercion

-- | A <a>Coercion</a> is concrete evidence of the equality/convertibility
--   of two types.
data Coercion
Refl :: Type -> Coercion
TyConAppCo :: TyCon -> [Coercion] -> Coercion
AppCo :: Coercion -> Coercion -> Coercion
ForAllCo :: TyVar -> Coercion -> Coercion
CoVarCo :: CoVar -> Coercion
AxiomInstCo :: CoAxiom -> [Coercion] -> Coercion
UnsafeCo :: Type -> Type -> Coercion
SymCo :: Coercion -> Coercion
TransCo :: Coercion -> Coercion -> Coercion
NthCo :: Int -> Coercion -> Coercion
InstCo :: Coercion -> Type -> Coercion

-- | Essentially a typed <a>Name</a>, that may also contain some additional
--   information about the <a>Var</a> and it's use sites.
data Var
type CoVar = Id
coVarKind :: CoVar -> (Type, Type)
coercionType :: Coercion -> Type

-- | If it is the case that
--   
--   <pre>
--   c :: (t1 ~ t2)
--   </pre>
--   
--   i.e. the kind of <tt>c</tt> relates <tt>t1</tt> and <tt>t2</tt>, then
--   <tt>coercionKind c = Pair t1 t2</tt>.
coercionKind :: Coercion -> Pair Type

-- | Apply <a>coercionKind</a> to multiple <a>Coercion</a>s
coercionKinds :: [Coercion] -> Pair [Type]
isReflCo :: Coercion -> Bool
isReflCo_maybe :: Coercion -> Maybe Type

-- | Makes a coercion type from two types: the types whose equality is
--   proven by the relevant <a>Coercion</a>
mkCoercionType :: Type -> Type -> Type
coAxiomSplitLHS :: CoAxiom -> (TyCon, [Type])
mkReflCo :: Type -> Coercion
mkCoVarCo :: CoVar -> Coercion
mkAxInstCo :: CoAxiom -> [Type] -> Coercion
mkAxInstRHS :: CoAxiom -> [Type] -> Type
mkPiCo :: Var -> Coercion -> Coercion
mkPiCos :: [Var] -> Coercion -> Coercion
mkCoCast :: Coercion -> Coercion -> Coercion

-- | Create a symmetric version of the given <a>Coercion</a> that asserts
--   equality between the same types but in the other <a>direction</a>, so
--   a kind of <tt>t1 ~ t2</tt> becomes the kind <tt>t2 ~ t1</tt>.
mkSymCo :: Coercion -> Coercion

-- | Create a new <a>Coercion</a> by composing the two given
--   <a>Coercion</a>s transitively.
mkTransCo :: Coercion -> Coercion -> Coercion
mkNthCo :: Int -> Coercion -> Coercion

-- | Instantiates a <a>Coercion</a> with a <a>Type</a> argument.
mkInstCo :: Coercion -> Type -> Coercion

-- | Apply a <a>Coercion</a> to another <a>Coercion</a>.
mkAppCo :: Coercion -> Coercion -> Coercion

-- | Apply a type constructor to a list of coercions.
mkTyConAppCo :: TyCon -> [Coercion] -> Coercion

-- | Make a function <a>Coercion</a> between two other <a>Coercion</a>s
mkFunCo :: Coercion -> Coercion -> Coercion

-- | Make a <a>Coercion</a> which binds a variable within an inner
--   <a>Coercion</a>
mkForAllCo :: Var -> Coercion -> Coercion

-- | Manufacture a coercion from thin air. Needless to say, this is not
--   usually safe, but it is used when we know we are dealing with bottom,
--   which is one case in which it is safe. This is also used to implement
--   the <tt>unsafeCoerce#</tt> primitive. Optimise by pushing down through
--   type constructors.
mkUnsafeCo :: Type -> Type -> Coercion

-- | Create a coercion constructor (axiom) suitable for the given newtype
--   <a>TyCon</a>. The <a>Name</a> should be that of a new coercion
--   <a>CoAxiom</a>, the <a>TyVar</a>s the arguments expected by the
--   <tt>newtype</tt> and the type the appropriate right hand side of the
--   <tt>newtype</tt>, with the free variables a subset of those
--   <a>TyVar</a>s.
mkNewTypeCo :: Name -> TyCon -> [TyVar] -> Type -> CoAxiom

-- | Sometimes we want to look through a <tt>newtype</tt> and get its
--   associated coercion. This function only strips *one layer* of
--   <tt>newtype</tt> off, so the caller will usually call itself
--   recursively. Furthermore, this function should only be applied to
--   types of kind <tt>*</tt>, hence the newtype is always saturated. If
--   <tt>co : ty ~ ty'</tt> then:
--   
--   <pre>
--   splitNewTypeRepCo_maybe ty = Just (ty', co)
--   </pre>
--   
--   The function returns <tt>Nothing</tt> for non-<tt>newtypes</tt> or
--   fully-transparent <tt>newtype</tt>s.
splitNewTypeRepCo_maybe :: Type -> Maybe (Type, Coercion)

-- | If <tt>co :: T ts ~ rep_ty</tt> then:
--   
--   <pre>
--   instNewTyCon_maybe T ts = Just (rep_ty, co)
--   </pre>
instNewTyCon_maybe :: TyCon -> [Type] -> Maybe (Type, Coercion)

-- | This breaks a <a>Coercion</a> with type <tt>T A B C ~ T D E F</tt>
--   into a list of <a>Coercion</a>s of kinds <tt>A ~ D</tt>, <tt>B ~
--   E</tt> and <tt>E ~ F</tt>. Hence:
--   
--   <pre>
--   decomposeCo 3 c = [nth 0 c, nth 1 c, nth 2 c]
--   </pre>
decomposeCo :: Arity -> Coercion -> [Coercion]

-- | Attempts to obtain the type variable underlying a <a>Coercion</a>
getCoVar_maybe :: Coercion -> Maybe CoVar

-- | Attempts to tease a coercion apart into a type constructor and the
--   application of a number of coercion arguments to that constructor
splitTyConAppCo_maybe :: Coercion -> Maybe (TyCon, [Coercion])

-- | Attempt to take a coercion application apart.
splitAppCo_maybe :: Coercion -> Maybe (Coercion, Coercion)
splitForAllCo_maybe :: Coercion -> Maybe (TyVar, Coercion)
mkCoVar :: Name -> Type -> CoVar
isCoVar :: Var -> Bool
isCoVarType :: Type -> Bool
coVarName :: CoVar -> Name
setCoVarName :: CoVar -> Name -> CoVar
setCoVarUnique :: CoVar -> Unique -> CoVar
tyCoVarsOfCo :: Coercion -> VarSet
tyCoVarsOfCos :: [Coercion] -> VarSet
coVarsOfCo :: Coercion -> VarSet
coercionSize :: Coercion -> Int

-- | A substitution of <a>Coercion</a>s for <a>CoVar</a>s (OR
--   <a>TyVar</a>s, when doing a "lifting" substitution)
type CvSubstEnv = VarEnv Coercion
emptyCvSubstEnv :: CvSubstEnv
data CvSubst
CvSubst :: InScopeSet -> TvSubstEnv -> CvSubstEnv -> CvSubst
emptyCvSubst :: CvSubst
lookupTyVar :: CvSubst -> TyVar -> Maybe Type
lookupCoVar :: CvSubst -> Var -> Maybe Coercion
isEmptyCvSubst :: CvSubst -> Bool
zapCvSubstEnv :: CvSubst -> CvSubst
getCvInScope :: CvSubst -> InScopeSet

-- | Substitute within a <a>Coercion</a>
substCo :: CvSubst -> Coercion -> Coercion

-- | Substitute within several <a>Coercion</a>s
substCos :: CvSubst -> [Coercion] -> [Coercion]
substCoVar :: CvSubst -> CoVar -> Coercion
substCoVars :: CvSubst -> [CoVar] -> [Coercion]
substCoWithTy :: InScopeSet -> TyVar -> Type -> Coercion -> Coercion
substCoWithTys :: InScopeSet -> [TyVar] -> [Type] -> Coercion -> Coercion
cvTvSubst :: CvSubst -> TvSubst
tvCvSubst :: TvSubst -> CvSubst
mkCvSubst :: InScopeSet -> [(Var, Coercion)] -> CvSubst
zipOpenCvSubst :: [Var] -> [Coercion] -> CvSubst
substTy :: CvSubst -> Type -> Type
extendTvSubst :: CvSubst -> TyVar -> Type -> CvSubst
extendCvSubstAndInScope :: CvSubst -> CoVar -> Coercion -> CvSubst
substTyVarBndr :: CvSubst -> TyVar -> (CvSubst, TyVar)
substCoVarBndr :: CvSubst -> CoVar -> (CvSubst, CoVar)

-- | <a>liftCoMatch</a> is sort of inverse to <a>liftCoSubst</a>. In
--   particular, if <tt>liftCoMatch vars ty co == Just s</tt>, then
--   <tt>tyCoSubst s ty == co</tt>. That is, it matches a type against a
--   coercion of the same <a>shape</a>, and returns a lifting substitution
--   which could have been used to produce the given coercion from the
--   given type.
liftCoMatch :: TyVarSet -> Type -> Coercion -> Maybe LiftCoSubst
liftCoSubstTyVar :: LiftCoSubst -> TyVar -> Maybe Coercion
liftCoSubstWith :: [TyVar] -> [Coercion] -> Type -> Coercion

-- | Determines syntactic equality of coercions
coreEqCoercion :: Coercion -> Coercion -> Bool
coreEqCoercion2 :: RnEnv2 -> Coercion -> Coercion -> Bool
seqCo :: Coercion -> ()
pprCo :: Coercion -> SDoc
pprParendCo :: Coercion -> SDoc
pprCoAxiom :: CoAxiom -> SDoc
applyCo :: Type -> Coercion -> Type
instance Typeable Coercion
instance Data Coercion
instance Outputable CvSubst
instance Outputable Coercion

module DataCon

-- | A data constructor
data DataCon

-- | Contains the Ids of the data constructor functions
data DataConIds
DCIds :: (Maybe Id) -> Id -> DataConIds

-- | Type of the tags associated with each constructor possibility
type ConTag = Int

-- | Build a new data constructor
mkDataCon :: Name -> Bool -> [HsBang] -> [FieldLabel] -> [TyVar] -> [TyVar] -> [(TyVar, Type)] -> ThetaType -> [Type] -> Type -> TyCon -> ThetaType -> DataConIds -> DataCon

-- | Tags are allocated from here for real constructors
fIRST_TAG :: ConTag

-- | The representation type of the data constructor, i.e. the sort type
--   that will represent values of this type at runtime
dataConRepType :: DataCon -> Type

-- | The "signature" of the <a>DataCon</a> returns, in order:
--   
--   1) The result of <a>dataConAllTyVars</a>,
--   
--   2) All the <a>ThetaType</a>s relating to the <a>DataCon</a> (coercion,
--   dictionary, implicit parameter - whatever)
--   
--   3) The type arguments to the constructor
--   
--   4) The <i>original</i> result type of the <a>DataCon</a>
dataConSig :: DataCon -> ([TyVar], ThetaType, [Type], Type)

-- | The "full signature" of the <a>DataCon</a> returns, in order:
--   
--   1) The result of <a>dataConUnivTyVars</a>
--   
--   2) The result of <a>dataConExTyVars</a>
--   
--   3) The result of <a>dataConEqSpec</a>
--   
--   4) The result of <tt>dataConDictTheta</tt>
--   
--   5) The original argument types to the <a>DataCon</a> (i.e. before any
--   change of the representation of the type)
--   
--   6) The original result type of the <a>DataCon</a>
dataConFullSig :: DataCon -> ([TyVar], [TyVar], [(TyVar, Type)], ThetaType, [Type], Type)

-- | The <a>Name</a> of the <a>DataCon</a>, giving it a unique, rooted
--   identification
dataConName :: DataCon -> Name

-- | The string <tt>package:module.name</tt> identifying a constructor,
--   which is attached to its info table and used by the GHCi debugger and
--   the heap profiler
dataConIdentity :: DataCon -> [Word8]

-- | The tag used for ordering <a>DataCon</a>s
dataConTag :: DataCon -> ConTag

-- | The type constructor that we are building via this data constructor
dataConTyCon :: DataCon -> TyCon

-- | The original type constructor used in the definition of this data
--   constructor. In case of a data family instance, that will be the
--   family type constructor.
dataConOrigTyCon :: DataCon -> TyCon

-- | The user-declared type of the data constructor in the nice-to-read
--   form:
--   
--   <pre>
--   T :: forall a b. a -&gt; b -&gt; T [a]
--   </pre>
--   
--   rather than:
--   
--   <pre>
--   T :: forall a c. forall b. (c~[a]) =&gt; a -&gt; b -&gt; T c
--   </pre>
--   
--   NB: If the constructor is part of a data instance, the result type
--   mentions the family tycon, not the internal one.
dataConUserType :: DataCon -> Type

-- | The universally-quantified type variables of the constructor
dataConUnivTyVars :: DataCon -> [TyVar]

-- | The existentially-quantified type variables of the constructor
dataConExTyVars :: DataCon -> [TyVar]

-- | Both the universal and existentiatial type variables of the
--   constructor
dataConAllTyVars :: DataCon -> [TyVar]

-- | Equalities derived from the result type of the data constructor, as
--   written by the programmer in any GADT declaration
dataConEqSpec :: DataCon -> [(TyVar, Type)]
eqSpecPreds :: [(TyVar, Type)] -> ThetaType

-- | The *full* constraints on the constructor type
dataConTheta :: DataCon -> ThetaType

-- | The "stupid theta" of the <a>DataCon</a>, such as <tt>data Eq a</tt>
--   in:
--   
--   <pre>
--   data Eq a =&gt; T a = ...
--   </pre>
dataConStupidTheta :: DataCon -> ThetaType

-- | Finds the instantiated types of the arguments required to construct a
--   <a>DataCon</a> representation NB: these INCLUDE any dictionary args
--   but EXCLUDE the data-declaration context, which is discarded It's all
--   post-flattening etc; this is a representation type
dataConInstArgTys :: DataCon -> [Type] -> [Type]

-- | Returns the argument types of the wrapper, excluding all dictionary
--   arguments and without substituting for any type variables
dataConOrigArgTys :: DataCon -> [Type]
dataConOrigResTy :: DataCon -> Type

-- | Returns just the instantiated <i>value</i> argument types of a
--   <a>DataCon</a>, (excluding dictionary args)
dataConInstOrigArgTys :: DataCon -> [Type] -> [Type]

-- | Returns the arg types of the worker, including all dictionaries, after
--   any flattening has been done and without substituting for any type
--   variables
dataConRepArgTys :: DataCon -> [Type]

-- | The labels for the fields of this particular <a>DataCon</a>
dataConFieldLabels :: DataCon -> [FieldLabel]

-- | Extract the type for any given labelled field of the <a>DataCon</a>
dataConFieldType :: DataCon -> FieldLabel -> Type

-- | The strictness markings decided on by the compiler. Does not include
--   those for existential dictionaries. The list is in one-to-one
--   correspondence with the arity of the <a>DataCon</a>
dataConStrictMarks :: DataCon -> [HsBang]

-- | Strictness of evidence arguments to the wrapper function
dataConExStricts :: DataCon -> [HsBang]

-- | Source-level arity of the data constructor
dataConSourceArity :: DataCon -> Arity

-- | Gives the number of actual fields in the <i>representation</i> of the
--   data constructor. This may be more than appear in the source code; the
--   extra ones are the existentially quantified dictionaries
dataConRepArity :: DataCon -> Arity

-- | The number of fields in the <i>representation</i> of the constructor
--   AFTER taking into account the unpacking of any unboxed tuple fields
dataConRepRepArity :: DataCon -> RepArity

-- | Should the <a>DataCon</a> be presented infix?
dataConIsInfix :: DataCon -> Bool

-- | Get the Id of the <a>DataCon</a> worker: a function that is the
--   <a>actual</a> constructor and has no top level binding in the program.
--   The type may be different from the obvious one written in the source
--   program. Panics if there is no such <a>Id</a> for this <a>DataCon</a>
dataConWorkId :: DataCon -> Id

-- | Returns an Id which looks like the Haskell-source constructor by using
--   the wrapper if it exists (see <a>dataConWrapId_maybe</a>) and failing
--   over to the worker (see <a>dataConWorkId</a>)
dataConWrapId :: DataCon -> Id

-- | Get the Id of the <a>DataCon</a> wrapper: a function that wraps the
--   <a>actual</a> constructor so it has the type visible in the source
--   program: c.f. <a>dataConWorkId</a>. Returns Nothing if there is no
--   wrapper, which occurs for an algebraic data constructor and also for a
--   newtype (whose constructor is inlined compulsorily)
dataConWrapId_maybe :: DataCon -> Maybe Id

-- | Find all the <a>Id</a>s implicitly brought into scope by the data
--   constructor. Currently, the union of the <a>dataConWorkId</a> and the
--   <a>dataConWrapId</a>
dataConImplicitIds :: DataCon -> [Id]

-- | Give the demands on the arguments of a Core constructor application
--   (Con dc args)
dataConRepStrictness :: DataCon -> [StrictnessMark]

-- | Return whether there are any argument types for this <a>DataCon</a>s
--   original source type
isNullarySrcDataCon :: DataCon -> Bool

-- | Return whether there are any argument types for this <a>DataCon</a>s
--   runtime representation type
isNullaryRepDataCon :: DataCon -> Bool
isTupleCon :: DataCon -> Bool
isUnboxedTupleCon :: DataCon -> Bool

-- | Vanilla <a>DataCon</a>s are those that are nice boring Haskell 98
--   constructors
isVanillaDataCon :: DataCon -> Bool
classDataCon :: Class -> DataCon
dataConCannotMatch :: [Type] -> DataCon -> Bool

-- | Extract the type constructor, type argument, data constructor and it's
--   <i>representation</i> argument types from a type if it is a product
--   type.
--   
--   Precisely, we return <tt>Just</tt> for any type that is all of:
--   
--   <ul>
--   <li>Concrete (i.e. constructors visible)</li>
--   <li>Single-constructor</li>
--   <li>Not existentially quantified</li>
--   </ul>
--   
--   Whether the type is a <tt>data</tt> type or a <tt>newtype</tt>
splitProductType_maybe :: Type -> Maybe (TyCon, [Type], DataCon, [Type])

-- | As <a>splitProductType_maybe</a>, but panics if the <a>Type</a> is not
--   a product type
splitProductType :: String -> Type -> (TyCon, [Type], DataCon, [Type])

-- | As <a>deepSplitProductType_maybe</a>, but panics if the <a>Type</a> is
--   not a product type
deepSplitProductType :: String -> Type -> (TyCon, [Type], DataCon, [Type])

-- | As <a>splitProductType_maybe</a>, but in turn instantiates the
--   <a>TyCon</a> returned and hence recursively tries to unpack it as far
--   as it able to
deepSplitProductType_maybe :: Type -> Maybe (TyCon, [Type], DataCon, [Type])
isPromotableTyCon :: TyCon -> Maybe Int
promoteTyCon :: TyCon -> TyCon
promoteDataCon :: DataCon -> TyCon
promoteDataCon_maybe :: DataCon -> Maybe TyCon
instance Typeable DataCon
instance Data DataCon
instance Outputable DataCon
instance NamedThing DataCon
instance Uniquable DataCon
instance Ord DataCon
instance Eq DataCon


-- | CoreSyn holds all the main data types for use by for the Glasgow
--   Haskell Compiler midsection
module CoreSyn

-- | This is the data type that represents GHCs core intermediate language.
--   Currently GHC uses System FC
--   <a>http://research.microsoft.com/~simonpj/papers/ext-f/</a> for this
--   purpose, which is closely related to the simpler and better known
--   System F <a>http://en.wikipedia.org/wiki/System_F</a>.
--   
--   We get from Haskell source to this Core language in a number of
--   stages:
--   
--   <ol>
--   <li>The source code is parsed into an abstract syntax tree, which is
--   represented by the data type <a>HsExpr</a> with the names being
--   <a>RdrNames</a></li>
--   <li>This syntax tree is <i>renamed</i>, which attaches a <a>Unique</a>
--   to every <a>RdrName</a> (yielding a <a>Name</a>) to disambiguate
--   identifiers which are lexically identical. For example, this
--   program:</li>
--   </ol>
--   
--   <pre>
--   f x = let f x = x + 1
--         in f (x - 2)
--   </pre>
--   
--   Would be renamed by having <tt>Unique</tt>s attached so it looked
--   something like this:
--   
--   <pre>
--   f_1 x_2 = let f_3 x_4 = x_4 + 1
--             in f_3 (x_2 - 2)
--   </pre>
--   
--   <ol>
--   <li>The resulting syntax tree undergoes type checking (which also
--   deals with instantiating type class arguments) to yield a
--   <a>HsExpr</a> type that has <a>Id</a> as it's names.</li>
--   <li>Finally the syntax tree is <i>desugared</i> from the expressive
--   <a>HsExpr</a> type into this <a>Expr</a> type, which has far fewer
--   constructors and hence is easier to perform optimization, analysis and
--   code generation on.</li>
--   </ol>
--   
--   The type parameter <tt>b</tt> is for the type of binders in the
--   expression tree.
--   
--   The language consists of the following elements:
--   
--   <ul>
--   <li>Variables</li>
--   <li>Primitive literals</li>
--   <li>Applications: note that the argument may be a <a>Type</a>.</li>
--   </ul>
--   
--   See <a>CoreSyn#let_app_invariant</a> for another invariant
--   
--   <ul>
--   <li>Lambda abstraction</li>
--   <li>Recursive and non recursive <tt>let</tt>s. Operationally this
--   corresponds to allocating a thunk for the things bound and then
--   executing the sub-expression.</li>
--   </ul>
--   
--   
--   The right hand sides of all top-level and recursive <tt>let</tt>s
--   <i>must</i> be of lifted type (see <a>Type#type_classification</a> for
--   the meaning of <i>lifted</i> vs. <i>unlifted</i>).
--   
--   The right hand side of of a non-recursive <a>Let</a> _and_ the
--   argument of an <a>App</a>, <i>may</i> be of unlifted type, but only if
--   the expression is ok-for-speculation. This means that the let can be
--   floated around without difficulty. For example, this is OK:
--   
--   <pre>
--   y::Int# = x +# 1#
--   </pre>
--   
--   But this is not, as it may affect termination if the expression is
--   floated out:
--   
--   <pre>
--   y::Int# = fac 4#
--   </pre>
--   
--   In this situation you should use <tt>case</tt> rather than a
--   <tt>let</tt>. The function <a>needsCaseBinding</a> can help you
--   determine which to generate, or alternatively use <a>mkCoreLet</a>
--   rather than this constructor directly, which will generate a
--   <tt>case</tt> if necessary
--   
--   We allow a <i>non-recursive</i> let to bind a type variable, thus:
--   
--   <pre>
--   Let (NonRec tv (Type ty)) body
--   </pre>
--   
--   This can be very convenient for postponing type substitutions until
--   the next run of the simplifier.
--   
--   At the moment, the rest of the compiler only deals with type-let in a
--   Let expression, rather than at top level. We may want to revist this
--   choice.
--   
--   <ul>
--   <li>Case split. Operationally this corresponds to evaluating the
--   scrutinee (expression examined) to weak head normal form and then
--   examining at most one level of resulting constructor (i.e. you cannot
--   do nested pattern matching directly with this).</li>
--   </ul>
--   
--   The binder gets bound to the value of the scrutinee, and the
--   <a>Type</a> must be that of all the case alternatives
--   
--   This is one of the more complicated elements of the Core language, and
--   comes with a number of restrictions:
--   
--   <ol>
--   <li>The list of alternatives may be empty; See Note [Empty case
--   alternatives]</li>
--   <li>The <a>DEFAULT</a> case alternative must be first in the list, if
--   it occurs at all.</li>
--   <li>The remaining cases are in order of increasing tag (for
--   <tt>DataAlts</tt>) or lit (for <tt>LitAlts</tt>). This makes finding
--   the relevant constructor easy, and makes comparison easier too.</li>
--   <li>The list of alternatives must be exhaustive. An <i>exhaustive</i>
--   case does not necessarily mention all constructors:</li>
--   </ol>
--   
--   <pre>
--        data Foo = Red | Green | Blue
--   ... case x of 
--        Red   -&gt; True
--        other -&gt; f (case x of 
--                        Green -&gt; ...
--                        Blue  -&gt; ... ) ...
--   </pre>
--   
--   The inner case does not need a <tt>Red</tt> alternative, because
--   <tt>x</tt> can't be <tt>Red</tt> at that program point.
--   
--   <ul>
--   <li>Cast an expression to a particular type. This is used to implement
--   <tt>newtype</tt>s (a <tt>newtype</tt> constructor or destructor just
--   becomes a <a>Cast</a> in Core) and GADTs.</li>
--   <li>Notes. These allow general information to be added to expressions
--   in the syntax tree</li>
--   <li>A type: this should only show up at the top level of an Arg</li>
--   <li>A coercion</li>
--   </ul>
data Expr b
Var :: Id -> Expr b
Lit :: Literal -> Expr b
App :: (Expr b) -> (Arg b) -> Expr b
Lam :: b -> (Expr b) -> Expr b
Let :: (Bind b) -> (Expr b) -> Expr b
Case :: (Expr b) -> b -> Type -> [Alt b] -> Expr b
Cast :: (Expr b) -> Coercion -> Expr b
Tick :: (Tickish Id) -> (Expr b) -> Expr b
Type :: Type -> Expr b
Coercion :: Coercion -> Expr b

-- | A case split alternative. Consists of the constructor leading to the
--   alternative, the variables bound from the constructor, and the
--   expression to be executed given that binding. The default alternative
--   is <tt>(DEFAULT, [], rhs)</tt>
type Alt b = (AltCon, [b], Expr b)

-- | Binding, used for top level bindings in a module and local bindings in
--   a <tt>let</tt>.
data Bind b
NonRec :: b -> (Expr b) -> Bind b
Rec :: [(b, Expr b)] -> Bind b

-- | A case alternative constructor (i.e. pattern match)
data AltCon
DataAlt :: DataCon -> AltCon

-- | A literal: <tt>case e of { 1 -&gt; ... }</tt> Invariant: always an
--   *unlifted* literal See Note [Literal alternatives]
LitAlt :: Literal -> AltCon

-- | Trivial alternative: <tt>case e of { _ -&gt; ... }</tt>
DEFAULT :: AltCon

-- | Type synonym for expressions that occur in function argument
--   positions. Only <a>Arg</a> should contain a <a>Type</a> at top level,
--   general <a>Expr</a> should not
type Arg b = Expr b

-- | Allows attaching extra information to points in expressions
data Tickish id

-- | An <tt>{--}</tt> profiling annotation, either automatically added by
--   the desugarer as a result of -auto-all, or added by the user.
ProfNote :: CostCentre -> !Bool -> !Bool -> Tickish id

-- | the cost centre
profNoteCC :: Tickish id -> CostCentre

-- | bump the entry count?
profNoteCount :: Tickish id -> !Bool

-- | scopes over the enclosed expression (i.e. not just a tick)
profNoteScope :: Tickish id -> !Bool

-- | A <a>tick</a> used by HPC to track the execution of each subexpression
--   in the original source code.
HpcTick :: Module -> !Int -> Tickish id
tickModule :: Tickish id -> Module
tickId :: Tickish id -> !Int

-- | A breakpoint for the GHCi debugger. This behaves like an HPC tick, but
--   has a list of free variables which will be available for inspection in
--   GHCi when the program stops at the breakpoint.
--   
--   NB. we must take account of these Ids when (a) counting free
--   variables, and (b) substituting (don't substitute for them)
Breakpoint :: !Int -> [id] -> Tickish id
breakpointId :: Tickish id -> !Int

-- | the order of this list is important: it matches the order of the lists
--   in the appropriate entry in HscTypes.ModBreaks.
--   
--   Careful about substitution! See Note [substTickish] in CoreSubst.
breakpointFVs :: Tickish id -> [id]
type CoreProgram = [CoreBind]

-- | Expressions where binders are <a>CoreBndr</a>s
type CoreExpr = Expr CoreBndr

-- | Case alternatives where binders are <a>CoreBndr</a>s
type CoreAlt = Alt CoreBndr

-- | Binding groups where binders are <a>CoreBndr</a>s
type CoreBind = Bind CoreBndr

-- | Argument expressions where binders are <a>CoreBndr</a>s
type CoreArg = Arg CoreBndr

-- | The common case for the type of binders and variables when we are
--   manipulating the Core language within GHC
type CoreBndr = Var
type TaggedExpr t = Expr (TaggedBndr t)
type TaggedAlt t = Alt (TaggedBndr t)
type TaggedBind t = Bind (TaggedBndr t)
type TaggedArg t = Arg (TaggedBndr t)

-- | Binders are <i>tagged</i> with a t
data TaggedBndr t
TB :: CoreBndr -> t -> TaggedBndr t

-- | Bind all supplied binding groups over an expression in a nested let
--   expression. Prefer to use <a>mkCoreLets</a> if possible
mkLets :: [Bind b] -> Expr b -> Expr b

-- | Bind all supplied binders over an expression in a nested lambda
--   expression. Prefer to use <a>mkCoreLams</a> if possible
mkLams :: [b] -> Expr b -> Expr b

-- | Apply a list of argument expressions to a function expression in a
--   nested fashion. Prefer to use <a>mkCoreApps</a> if possible
mkApps :: Expr b -> [Arg b] -> Expr b

-- | Apply a list of type argument expressions to a function expression in
--   a nested fashion
mkTyApps :: Expr b -> [Type] -> Expr b

-- | Apply a list of coercion argument expressions to a function expression
--   in a nested fashion
mkCoApps :: Expr b -> [Coercion] -> Expr b

-- | Apply a list of type or value variables to a function expression in a
--   nested fashion
mkVarApps :: Expr b -> [Var] -> Expr b

-- | Create a machine integer literal expression of type <tt>Int#</tt> from
--   an <tt>Integer</tt>. If you want an expression of type <tt>Int</tt>
--   use <a>mkIntExpr</a>
mkIntLit :: Integer -> Expr b

-- | Create a machine integer literal expression of type <tt>Int#</tt> from
--   an <tt>Int</tt>. If you want an expression of type <tt>Int</tt> use
--   <a>mkIntExpr</a>
mkIntLitInt :: Int -> Expr b

-- | Create a machine word literal expression of type <tt>Word#</tt> from
--   an <tt>Integer</tt>. If you want an expression of type <tt>Word</tt>
--   use <a>mkWordExpr</a>
mkWordLit :: Integer -> Expr b

-- | Create a machine word literal expression of type <tt>Word#</tt> from a
--   <tt>Word</tt>. If you want an expression of type <tt>Word</tt> use
--   <a>mkWordExpr</a>
mkWordLitWord :: Word -> Expr b
mkWord64LitWord64 :: Word64 -> Expr b
mkInt64LitInt64 :: Int64 -> Expr b

-- | Create a machine character literal expression of type <tt>Char#</tt>.
--   If you want an expression of type <tt>Char</tt> use <a>mkCharExpr</a>
mkCharLit :: Char -> Expr b

-- | Create a machine string literal expression of type <tt>Addr#</tt>. If
--   you want an expression of type <tt>String</tt> use <a>mkStringExpr</a>
mkStringLit :: String -> Expr b

-- | Create a machine single precision literal expression of type
--   <tt>Float#</tt> from a <tt>Rational</tt>. If you want an expression of
--   type <tt>Float</tt> use <a>mkFloatExpr</a>
mkFloatLit :: Rational -> Expr b

-- | Create a machine single precision literal expression of type
--   <tt>Float#</tt> from a <tt>Float</tt>. If you want an expression of
--   type <tt>Float</tt> use <a>mkFloatExpr</a>
mkFloatLitFloat :: Float -> Expr b

-- | Create a machine double precision literal expression of type
--   <tt>Double#</tt> from a <tt>Rational</tt>. If you want an expression
--   of type <tt>Double</tt> use <a>mkDoubleExpr</a>
mkDoubleLit :: Rational -> Expr b

-- | Create a machine double precision literal expression of type
--   <tt>Double#</tt> from a <tt>Double</tt>. If you want an expression of
--   type <tt>Double</tt> use <a>mkDoubleExpr</a>
mkDoubleLitDouble :: Double -> Expr b

-- | Apply a list of argument expressions to a data constructor in a nested
--   fashion. Prefer to use <a>mkCoreConApps</a> if possible
mkConApp :: DataCon -> [Arg b] -> Expr b

-- | Create a binding group where a type variable is bound to a type. Per
--   <a>CoreSyn#type_let</a>, this can only be used to bind something in a
--   non-recursive <tt>let</tt> expression
mkTyBind :: TyVar -> Type -> CoreBind

-- | Create a binding group where a type variable is bound to a type. Per
--   <a>CoreSyn#type_let</a>, this can only be used to bind something in a
--   non-recursive <tt>let</tt> expression
mkCoBind :: CoVar -> Coercion -> CoreBind

-- | Convert a binder into either a <a>Var</a> or <a>Type</a> <a>Expr</a>
--   appropriately
varToCoreExpr :: CoreBndr -> Expr b
varsToCoreExprs :: [CoreBndr] -> [Expr b]
isId :: Var -> Bool

-- | Compares <a>AltCon</a>s within a single list of alternatives
cmpAltCon :: AltCon -> AltCon -> Ordering
cmpAlt :: (AltCon, a, b) -> (AltCon, a, b) -> Ordering
ltAlt :: (AltCon, a, b) -> (AltCon, a, b) -> Bool

-- | Extract every variable by this group
bindersOf :: Bind b -> [b]

-- | <a>bindersOf</a> applied to a list of binding groups
bindersOfBinds :: [Bind b] -> [b]
rhssOfBind :: Bind b -> [Expr b]
rhssOfAlts :: [Alt b] -> [Expr b]

-- | We often want to strip off leading lambdas before getting down to
--   business. This function is your friend.
collectBinders :: Expr b -> ([b], Expr b)

-- | Collect as many type bindings as possible from the front of a nested
--   lambda
collectTyBinders :: CoreExpr -> ([TyVar], CoreExpr)

-- | Collect as many value bindings as possible from the front of a nested
--   lambda
collectValBinders :: CoreExpr -> ([Id], CoreExpr)

-- | Collect type binders from the front of the lambda first, then follow
--   up by collecting as many value bindings as possible from the resulting
--   stripped expression
collectTyAndValBinders :: CoreExpr -> ([TyVar], [Id], CoreExpr)

-- | Takes a nested application expression and returns the the function
--   being applied and the arguments to which it is applied
collectArgs :: Expr b -> (Expr b, [Arg b])

-- | Collapse all the bindings in the supplied groups into a single list of
--   lhs/rhs pairs suitable for binding in a <a>Rec</a> binding group
flattenBinds :: [Bind b] -> [(b, Expr b)]

-- | Returns <tt>False</tt> iff the expression is a <a>Type</a> or
--   <a>Coercion</a> expression at its top level
isValArg :: Expr b -> Bool

-- | Returns <tt>True</tt> iff the expression is a <a>Type</a> expression
--   at its top level. Note this does NOT include <a>Coercion</a>s.
isTypeArg :: Expr b -> Bool

-- | Returns <tt>True</tt> iff the expression is a <a>Type</a> or
--   <a>Coercion</a> expression at its top level
isTyCoArg :: Expr b -> Bool

-- | The number of argument expressions that are values rather than types
--   at their top level
valArgCount :: [Arg b] -> Int

-- | The number of binders that bind values rather than types
valBndrCount :: [CoreBndr] -> Int

-- | Will this argument expression exist at runtime?
isRuntimeArg :: CoreExpr -> Bool

-- | Will this variable exist at runtime?
isRuntimeVar :: Var -> Bool

-- | A <a>tick</a> note is one that counts evaluations in some way. We
--   cannot discard a tick, and the compiler should preserve the number of
--   ticks as far as possible.
--   
--   Hwever, we stil allow the simplifier to increase or decrease sharing,
--   so in practice the actual number of ticks may vary, except that we
--   never change the value from zero to non-zero or vice versa.
tickishCounts :: Tickish id -> Bool
tickishScoped :: Tickish id -> Bool

-- | Return True if this source annotation compiles to some code, or will
--   disappear before the backend.
tickishIsCode :: Tickish id -> Bool
mkNoTick :: Tickish id -> Tickish id
mkNoScope :: Tickish id -> Tickish id

-- | Return True if this Tick can be split into (tick,scope) parts with
--   <a>mkNoScope</a> and <a>mkNoTick</a> respectively.
tickishCanSplit :: Tickish Id -> Bool

-- | Records the <i>unfolding</i> of an identifier, which is approximately
--   the form the identifier would have if we substituted its definition in
--   for the identifier. This type should be treated as abstract everywhere
--   except in <a>CoreUnfold</a>
data Unfolding

-- | We have no information about the unfolding
NoUnfolding :: Unfolding

-- | It ain't one of these constructors. <tt>OtherCon xs</tt> also
--   indicates that something has been evaluated and hence there's no point
--   in re-evaluating it. <tt>OtherCon []</tt> is used even for
--   non-data-type values to indicated evaluated-ness. Notably:
--   
--   <pre>
--   data C = C !(Int -&gt; Int)
--   case x of { C f -&gt; ... }
--   </pre>
--   
--   Here, <tt>f</tt> gets an <tt>OtherCon []</tt> unfolding.
OtherCon :: [AltCon] -> Unfolding
DFunUnfolding :: Arity -> DataCon -> [DFunArg CoreExpr] -> Unfolding

-- | An unfolding with redundant cached information. Parameters:
--   
--   uf_tmpl: Template used to perform unfolding; NB: Occurrence info is
--   guaranteed correct: see Note [OccInfo in unfoldings and rules]
--   
--   uf_is_top: Is this a top level binding?
--   
--   uf_is_value: <tt>exprIsHNF</tt> template (cached); it is ok to discard
--   a <a>seq</a> on this variable
--   
--   uf_is_work_free: Does this waste only a little work if we expand it
--   inside an inlining? Basically this is a cached version of
--   <tt>exprIsWorkFree</tt>
--   
--   uf_guidance: Tells us about the <i>size</i> of the unfolding template
CoreUnfolding :: CoreExpr -> UnfoldingSource -> Bool -> Arity -> Bool -> Bool -> Bool -> Bool -> UnfoldingGuidance -> Unfolding
uf_tmpl :: Unfolding -> CoreExpr
uf_src :: Unfolding -> UnfoldingSource
uf_is_top :: Unfolding -> Bool
uf_arity :: Unfolding -> Arity
uf_is_value :: Unfolding -> Bool
uf_is_conlike :: Unfolding -> Bool
uf_is_work_free :: Unfolding -> Bool
uf_expandable :: Unfolding -> Bool
uf_guidance :: Unfolding -> UnfoldingGuidance

-- | <a>UnfoldingGuidance</a> says when unfolding should take place
data UnfoldingGuidance
UnfWhen :: Bool -> Bool -> UnfoldingGuidance
ug_unsat_ok :: UnfoldingGuidance -> Bool
ug_boring_ok :: UnfoldingGuidance -> Bool
UnfIfGoodArgs :: [Int] -> Int -> Int -> UnfoldingGuidance
ug_args :: UnfoldingGuidance -> [Int]
ug_size :: UnfoldingGuidance -> Int
ug_res :: UnfoldingGuidance -> Int
UnfNever :: UnfoldingGuidance
data UnfoldingSource
InlineRhs :: UnfoldingSource
InlineStable :: UnfoldingSource
InlineCompulsory :: UnfoldingSource
InlineWrapper :: Id -> UnfoldingSource
data DFunArg e
DFunPolyArg :: e -> DFunArg e
DFunLamArg :: Int -> DFunArg e
dfunArgExprs :: [DFunArg e] -> [e]

-- | There is no known <a>Unfolding</a>
noUnfolding :: Unfolding

-- | This unfolding marks the associated thing as being evaluated
evaldUnfolding :: Unfolding
mkOtherCon :: [AltCon] -> Unfolding
unSaturatedOk :: Bool
needSaturated :: Bool
boringCxtOk :: Bool
boringCxtNotOk :: Bool

-- | Retrieves the template of an unfolding: panics if none is known
unfoldingTemplate :: Unfolding -> CoreExpr
setUnfoldingTemplate :: Unfolding -> CoreExpr -> Unfolding
expandUnfolding_maybe :: Unfolding -> Maybe CoreExpr

-- | Retrieves the template of an unfolding if possible
maybeUnfoldingTemplate :: Unfolding -> Maybe CoreExpr

-- | The constructors that the unfolding could never be: returns
--   <tt>[]</tt> if no information is available
otherCons :: Unfolding -> [AltCon]
unfoldingArity :: Unfolding -> Arity

-- | Determines if it is certainly the case that the unfolding will yield a
--   value (something in HNF): returns <tt>False</tt> if unsure
isValueUnfolding :: Unfolding -> Bool

-- | Determines if it possibly the case that the unfolding will yield a
--   value. Unlike <a>isValueUnfolding</a> it returns <tt>True</tt> for
--   <a>OtherCon</a>
isEvaldUnfolding :: Unfolding -> Bool

-- | Is the thing we will unfold into certainly cheap?
isCheapUnfolding :: Unfolding -> Bool
isExpandableUnfolding :: Unfolding -> Bool

-- | <tt>True</tt> if the unfolding is a constructor application, the
--   application of a CONLIKE function or <a>OtherCon</a>
isConLikeUnfolding :: Unfolding -> Bool
isCompulsoryUnfolding :: Unfolding -> Bool
isStableUnfolding :: Unfolding -> Bool
isStableCoreUnfolding_maybe :: Unfolding -> Maybe UnfoldingSource
isClosedUnfolding :: Unfolding -> Bool

-- | Only returns False if there is no unfolding information available at
--   all
hasSomeUnfolding :: Unfolding -> Bool
canUnfold :: Unfolding -> Bool
neverUnfoldGuidance :: UnfoldingGuidance -> Bool
isStableSource :: UnfoldingSource -> Bool
seqExpr :: CoreExpr -> ()
seqExprs :: [CoreExpr] -> ()
seqUnfolding :: Unfolding -> ()

-- | Annotated core: allows annotation at every node in the tree
type AnnExpr bndr annot = (annot, AnnExpr' bndr annot)

-- | A clone of the <a>Expr</a> type but allowing annotation at every tree
--   node
data AnnExpr' bndr annot
AnnVar :: Id -> AnnExpr' bndr annot
AnnLit :: Literal -> AnnExpr' bndr annot
AnnLam :: bndr -> (AnnExpr bndr annot) -> AnnExpr' bndr annot
AnnApp :: (AnnExpr bndr annot) -> (AnnExpr bndr annot) -> AnnExpr' bndr annot
AnnCase :: (AnnExpr bndr annot) -> bndr -> Type -> [AnnAlt bndr annot] -> AnnExpr' bndr annot
AnnLet :: (AnnBind bndr annot) -> (AnnExpr bndr annot) -> AnnExpr' bndr annot
AnnCast :: (AnnExpr bndr annot) -> (annot, Coercion) -> AnnExpr' bndr annot
AnnTick :: (Tickish Id) -> (AnnExpr bndr annot) -> AnnExpr' bndr annot
AnnType :: Type -> AnnExpr' bndr annot
AnnCoercion :: Coercion -> AnnExpr' bndr annot

-- | A clone of the <a>Bind</a> type but allowing annotation at every tree
--   node
data AnnBind bndr annot
AnnNonRec :: bndr -> (AnnExpr bndr annot) -> AnnBind bndr annot
AnnRec :: [(bndr, AnnExpr bndr annot)] -> AnnBind bndr annot

-- | A clone of the <a>Alt</a> type but allowing annotation at every tree
--   node
type AnnAlt bndr annot = (AltCon, [bndr], AnnExpr bndr annot)

-- | Takes a nested application expression and returns the the function
--   being applied and the arguments to which it is applied
collectAnnArgs :: AnnExpr b a -> (AnnExpr b a, [AnnExpr b a])
deAnnotate :: AnnExpr bndr annot -> Expr bndr
deAnnotate' :: AnnExpr' bndr annot -> Expr bndr
deAnnAlt :: AnnAlt bndr annot -> Alt bndr

-- | As <a>collectBinders</a> but for <a>AnnExpr</a> rather than
--   <a>Expr</a>
collectAnnBndrs :: AnnExpr bndr annot -> ([bndr], AnnExpr bndr annot)

-- | A <a>CoreRule</a> is:
--   
--   <ul>
--   <li>"Local" if the function it is a rule for is defined in the same
--   module as the rule itself.</li>
--   <li>"Orphan" if nothing on the LHS is defined in the same module as
--   the rule itself</li>
--   </ul>
data CoreRule
Rule :: RuleName -> Activation -> Name -> [Maybe Name] -> [CoreBndr] -> [CoreExpr] -> CoreExpr -> Bool -> Bool -> CoreRule

-- | As above
--   
--   Name of the rule, for communication with the user
ru_name :: CoreRule -> RuleName

-- | When the rule is active
ru_act :: CoreRule -> Activation

-- | As above
--   
--   Name of the <a>Id</a> at the head of this rule
ru_fn :: CoreRule -> Name

-- | Name at the head of each argument to the left hand side
ru_rough :: CoreRule -> [Maybe Name]

-- | Variables quantified over
ru_bndrs :: CoreRule -> [CoreBndr]

-- | Left hand side arguments
ru_args :: CoreRule -> [CoreExpr]

-- | Right hand side of the rule Occurrence info is guaranteed correct See
--   Note [OccInfo in unfoldings and rules]
ru_rhs :: CoreRule -> CoreExpr

-- | <tt>True</tt> <a>=</a> this rule is auto-generated <tt>False</tt>
--   <a>=</a> generated at the users behest Main effect: reporting of
--   orphan-hood
ru_auto :: CoreRule -> Bool

-- | <tt>True</tt> iff the fn at the head of the rule is defined in the
--   same module as the rule and is not an implicit <a>Id</a> (like a
--   record selector, class operation, or data constructor)
ru_local :: CoreRule -> Bool

-- | Built-in rules are used for constant folding and suchlike. They have
--   no free variables.
BuiltinRule :: RuleName -> Name -> Int -> (Id -> IdUnfoldingFun -> [CoreExpr] -> Maybe CoreExpr) -> CoreRule

-- | As above
--   
--   Name of the rule, for communication with the user
ru_name :: CoreRule -> RuleName

-- | As above
--   
--   Name of the <a>Id</a> at the head of this rule
ru_fn :: CoreRule -> Name

-- | Number of arguments that <a>ru_try</a> consumes, if it fires,
--   including type arguments
ru_nargs :: CoreRule -> Int

-- | This function does the rewrite. It given too many arguments, it simply
--   discards them; the returned <a>CoreExpr</a> is just the rewrite of
--   <a>ru_fn</a> applied to the first <a>ru_nargs</a> args
ru_try :: CoreRule -> Id -> IdUnfoldingFun -> [CoreExpr] -> Maybe CoreExpr
type RuleName = FastString
type IdUnfoldingFun = Id -> Unfolding
seqRules :: [CoreRule] -> ()

-- | The number of arguments the <a>ru_fn</a> must be applied to before the
--   rule can match on it
ruleArity :: CoreRule -> Int
ruleName :: CoreRule -> RuleName

-- | The <a>Name</a> of the <a>Id</a> at the head of the rule left hand
--   side
ruleIdName :: CoreRule -> Name
ruleActivation :: CoreRule -> Activation

-- | Set the <a>Name</a> of the <a>Id</a> at the head of the rule left hand
--   side
setRuleIdName :: Name -> CoreRule -> CoreRule
isBuiltinRule :: CoreRule -> Bool
isLocalRule :: CoreRule -> Bool
data CoreVect
Vect :: Id -> (Maybe CoreExpr) -> CoreVect
NoVect :: Id -> CoreVect
VectType :: Bool -> TyCon -> (Maybe TyCon) -> CoreVect
VectClass :: TyCon -> CoreVect
VectInst :: Id -> CoreVect
instance Typeable AltCon
instance Typeable1 Tickish
instance Typeable1 Expr
instance Typeable1 Bind
instance Eq AltCon
instance Ord AltCon
instance Data AltCon
instance Eq id => Eq (Tickish id)
instance Ord id => Ord (Tickish id)
instance Data id => Data (Tickish id)
instance Data b => Data (Expr b)
instance Data b => Data (Bind b)
instance Functor DFunArg
instance Outputable b => OutputableBndr (TaggedBndr b)
instance Outputable b => Outputable (TaggedBndr b)
instance Outputable AltCon


-- | Simple vectorised constructors and projections.
module Vectorise.Vect

-- | Contains the vectorised and lifted versions of some thing.
type Vect a = (a, a)
type VVar = Vect Var
type VExpr = Vect CoreExpr
type VBind = Vect CoreBind

-- | Get the vectorised version of a thing.
vectorised :: Vect a -> a

-- | Get the lifted version of a thing.
lifted :: Vect a -> a

-- | Apply some function to both the vectorised and lifted versions of a
--   thing.
mapVect :: (a -> b) -> Vect a -> Vect b

-- | Get the type of a vectorised variable.
vVarType :: VVar -> Type

-- | Make a vectorised non-recursive binding.
vNonRec :: VVar -> VExpr -> VBind

-- | Make a vectorised recursive binding.
vRec :: [VVar] -> [VExpr] -> VBind

-- | Wrap a vectorised variable as a vectorised expression.
vVar :: VVar -> VExpr

-- | Wrap a vectorised type as a vectorised expression.
vType :: Type -> VExpr

-- | Make a vectorised note.
vTick :: Tickish Id -> VExpr -> VExpr

-- | Make a vectorised let expresion.
vLet :: VBind -> VExpr -> VExpr

-- | Make a vectorised lambda abstraction.
--   
--   The lifted version also binds the lifting context <tt>lc</tt>.
vLams :: Var -> [VVar] -> VExpr -> VExpr

-- | Apply an expression to a set of argument variables.
--   
--   The lifted version is also applied to the variable of the lifting
--   context.
vVarApps :: Var -> VExpr -> [VVar] -> VExpr
vCaseDEFAULT :: VExpr -> VVar -> Type -> Type -> VExpr -> VExpr

module IdInfo

-- | The <a>IdDetails</a> of an <tt>Id</tt> give stable, and necessary,
--   information about the Id.
data IdDetails
VanillaId :: IdDetails

-- | The <tt>Id</tt> for a record selector
RecSelId :: TyCon -> Bool -> IdDetails

-- | For a data type family, this is the <i>instance</i> <a>TyCon</a> not
--   the family <a>TyCon</a>
sel_tycon :: IdDetails -> TyCon
sel_naughty :: IdDetails -> Bool

-- | The <tt>Id</tt> is for a data constructor <i>worker</i>
DataConWorkId :: DataCon -> IdDetails

-- | The <tt>Id</tt> is for a data constructor <i>wrapper</i>
DataConWrapId :: DataCon -> IdDetails

-- | The <tt>Id</tt> is an superclass selector or class operation of a
--   class
ClassOpId :: Class -> IdDetails

-- | The <tt>Id</tt> is for a primitive operator
PrimOpId :: PrimOp -> IdDetails

-- | The <tt>Id</tt> is for a foreign call
FCallId :: ForeignCall -> IdDetails

-- | The <tt>Id</tt> is for a HPC tick box (both traditional and binary)
TickBoxOpId :: TickBoxOp -> IdDetails

-- | A dictionary function. Int = the number of <a>silent</a> arguments to
--   the dfun e.g. class D a =&gt; C a where ... instance C a =&gt; C [a]
--   has is_silent = 1, because the dfun has type dfun :: (D a, C a) =&gt;
--   C [a] See the DFun Superclass Invariant in TcInstDcls
--   
--   Bool = True <a>=</a> the class has only one method, so may be
--   implemented with a newtype, so it might be bad to be strict on this
--   dictionary
DFunId :: Int -> Bool -> IdDetails
pprIdDetails :: IdDetails -> SDoc
coVarDetails :: IdDetails

-- | An <a>IdInfo</a> gives <i>optional</i> information about an
--   <tt>Id</tt>. If present it never lies, but it may not be present, in
--   which case there is always a conservative assumption which can be
--   made.
--   
--   Two <tt>Id</tt>s may have different info even though they have the
--   same <tt>Unique</tt> (and are hence the same <tt>Id</tt>); for
--   example, one might lack the properties attached to the other.
--   
--   The <a>IdInfo</a> gives information about the value, or definition, of
--   the <tt>Id</tt>. It does not contain information about the
--   <tt>Id'</tt>s usage, except for <a>demandInfo</a> and
--   <a>lbvarInfo</a>.
data IdInfo

-- | Basic <a>IdInfo</a> that carries no useful information whatsoever
vanillaIdInfo :: IdInfo

-- | More informative <a>IdInfo</a> we can use when we know the <tt>Id</tt>
--   has no CAF references
noCafIdInfo :: IdInfo

-- | Just evaluate the <a>IdInfo</a> to WHNF
seqIdInfo :: IdInfo -> ()

-- | Evaluate all the fields of the <a>IdInfo</a> that are generally
--   demanded by the compiler
megaSeqIdInfo :: IdInfo -> ()

-- | This is used to remove information on lambda binders that we have
--   setup as part of a lambda group, assuming they will be applied all at
--   once, but turn out to be part of an unsaturated lambda as in e.g:
--   
--   <pre>
--   (\x1. \x2. e) arg1
--   </pre>
zapLamInfo :: IdInfo -> Maybe IdInfo

-- | Remove demand info on the <a>IdInfo</a> if it is present, otherwise
--   return <tt>Nothing</tt>
zapDemandInfo :: IdInfo -> Maybe IdInfo

-- | Zap info that depends on free variables
zapFragileInfo :: IdInfo -> Maybe IdInfo

-- | An <a>ArityInfo</a> of <tt>n</tt> tells us that partial application of
--   this <tt>Id</tt> to up to <tt>n-1</tt> value arguments does
--   essentially no work.
--   
--   That is not necessarily the same as saying that it has <tt>n</tt>
--   leading lambdas, because coerces may get in the way.
--   
--   The arity might increase later in the compilation process, if an extra
--   lambda floats up to the binding site.
type ArityInfo = Arity

-- | It is always safe to assume that an <tt>Id</tt> has an arity of 0
unknownArity :: Arity

-- | <tt>Id</tt> arity
arityInfo :: IdInfo -> ArityInfo
setArityInfo :: IdInfo -> ArityInfo -> IdInfo
ppArityInfo :: Int -> SDoc

-- | Id strictness information. Reason for Maybe: the DmdAnal phase needs
--   to know whether this is the first visit, so it can assign botSig.
--   Other customers want topSig. So <tt>Nothing</tt> is good.
strictnessInfo :: IdInfo -> Maybe StrictSig
setStrictnessInfo :: IdInfo -> Maybe StrictSig -> IdInfo

-- | Id demand information. Similarly we want to know if there's no known
--   demand yet, for when we are looking for CPR info
demandInfo :: IdInfo -> Maybe Demand
setDemandInfo :: IdInfo -> Maybe Demand -> IdInfo
pprStrictness :: Maybe StrictSig -> SDoc

-- | The <tt>Id</tt>s unfolding
unfoldingInfo :: IdInfo -> Unfolding
setUnfoldingInfo :: IdInfo -> Unfolding -> IdInfo
setUnfoldingInfoLazily :: IdInfo -> Unfolding -> IdInfo

-- | Tells when the inlining is active. When it is active the thing may be
--   inlined, depending on how big it is.
--   
--   If there was an <tt>INLINE</tt> pragma, then as a separate matter, the
--   RHS will have been made to look small with a Core inline <tt>Note</tt>
--   
--   The default <a>InlinePragInfo</a> is <a>AlwaysActive</a>, so the info
--   serves entirely as a way to inhibit inlining until we want it
type InlinePragInfo = InlinePragma

-- | Any inline pragma atached to the <tt>Id</tt>
inlinePragInfo :: IdInfo -> InlinePragma
setInlinePragInfo :: IdInfo -> InlinePragma -> IdInfo

-- | Identifier occurrence information
data OccInfo

-- | There are many occurrences, or unknown occurences
NoOccInfo :: OccInfo

-- | Marks unused variables. Sometimes useful for lambda and case-bound
--   variables.
IAmDead :: OccInfo

-- | Occurs exactly once, not inside a rule
OneOcc :: !InsideLam -> !OneBranch -> !InterestingCxt -> OccInfo

-- | This identifier breaks a loop of mutually recursive functions. The
--   field marks whether it is only a loop breaker due to a reference in a
--   rule
IAmALoopBreaker :: !RulesOnly -> OccInfo
isDeadOcc :: OccInfo -> Bool
isStrongLoopBreaker :: OccInfo -> Bool
isWeakLoopBreaker :: OccInfo -> Bool

-- | How the <tt>Id</tt> occurs in the program
occInfo :: IdInfo -> OccInfo
setOccInfo :: IdInfo -> OccInfo -> IdInfo
type InsideLam = Bool
type OneBranch = Bool
insideLam :: InsideLam
notInsideLam :: InsideLam
oneBranch :: OneBranch
notOneBranch :: OneBranch

-- | Records the specializations of this <tt>Id</tt> that we know about in
--   the form of rewrite <a>CoreRule</a>s that target them
data SpecInfo
SpecInfo :: [CoreRule] -> VarSet -> SpecInfo

-- | Assume that no specilizations exist: always safe
emptySpecInfo :: SpecInfo
isEmptySpecInfo :: SpecInfo -> Bool

-- | Retrieve the locally-defined free variables of both the left and right
--   hand sides of the specialization rules
specInfoFreeVars :: SpecInfo -> VarSet
specInfoRules :: SpecInfo -> [CoreRule]
seqSpecInfo :: SpecInfo -> ()

-- | Change the name of the function the rule is keyed on on all of the
--   <a>CoreRule</a>s
setSpecInfoHead :: Name -> SpecInfo -> SpecInfo

-- | Specialisations of the <tt>Id</tt>s function which exist See Note
--   [Specialisations and RULES in IdInfo]
specInfo :: IdInfo -> SpecInfo
setSpecInfo :: IdInfo -> SpecInfo -> IdInfo

-- | Records whether an <tt>Id</tt> makes Constant Applicative Form
--   references
data CafInfo

-- | Indicates that the <tt>Id</tt> is for either:
--   
--   <ol>
--   <li>A function or static constructor that refers to one or more CAFs,
--   or</li>
--   <li>A real live CAF</li>
--   </ol>
MayHaveCafRefs :: CafInfo

-- | A function or static constructor that refers to no CAFs.
NoCafRefs :: CafInfo
ppCafInfo :: CafInfo -> SDoc
mayHaveCafRefs :: CafInfo -> Bool

-- | <tt>Id</tt> CAF info
cafInfo :: IdInfo -> CafInfo
setCafInfo :: IdInfo -> CafInfo -> IdInfo

-- | If the <tt>Id</tt> is a lambda-bound variable then it may have
--   lambda-bound variable info. Sometimes we know whether the lambda
--   binding this variable is a "one-shot" lambda; that is, whether it is
--   applied at most once.
--   
--   This information may be useful in optimisation, as computations may
--   safely be floated inside such a lambda without risk of duplicating
--   work.
data LBVarInfo

-- | No information
NoLBVarInfo :: LBVarInfo

-- | The lambda is applied at most once).
IsOneShotLambda :: LBVarInfo

-- | It is always safe to assume that an <tt>Id</tt> has no lambda-bound
--   variable information
noLBVarInfo :: LBVarInfo
hasNoLBVarInfo :: LBVarInfo -> Bool

-- | Info about a lambda-bound variable, if the <tt>Id</tt> is one
lbvarInfo :: IdInfo -> LBVarInfo
setLBVarInfo :: IdInfo -> LBVarInfo -> IdInfo

-- | Tick box for Hpc-style coverage
data TickBoxOp
TickBox :: Module -> {-# UNPACK #-} !TickBoxId -> TickBoxOp
type TickBoxId = Int
instance Eq CafInfo
instance Ord CafInfo
instance Outputable TickBoxOp
instance Outputable LBVarInfo
instance Outputable CafInfo
instance Outputable IdDetails


-- | GHC uses several kinds of name internally:
--   
--   <ul>
--   <li><a>OccName</a>: see <a>OccName#name_types</a></li>
--   <li><a>RdrName</a>: see <a>RdrName#name_types</a></li>
--   <li><a>Name</a>: see <a>Name#name_types</a></li>
--   <li><a>Id</a> represents names that not only have a <a>Name</a> but
--   also a <a>Type</a> and some additional details (a <a>IdInfo</a> and
--   one of <a>LocalIdDetails</a> or <a>GlobalIdDetails</a>) that are
--   added, modified and inspected by various compiler passes. These
--   <a>Var</a> names may either be global or local, see
--   <a>Var#globalvslocal</a></li>
--   <li><a>Var</a>: see <a>Var#name_types</a></li>
--   </ul>
module Id

-- | Essentially a typed <a>Name</a>, that may also contain some additional
--   information about the <a>Var</a> and it's use sites.
data Var
type Id = Var
isId :: Var -> Bool

-- | For an explanation of global vs. local <a>Id</a>s, see
--   <a>Var#globalvslocal</a>
mkGlobalId :: IdDetails -> Name -> Type -> IdInfo -> Id

-- | Make a global <a>Id</a> without any extra information at all
mkVanillaGlobal :: Name -> Type -> Id

-- | Make a global <a>Id</a> with no global information but some generic
--   <a>IdInfo</a>
mkVanillaGlobalWithInfo :: Name -> Type -> IdInfo -> Id

-- | For an explanation of global vs. local <a>Id</a>s, see
--   <a>Var#globalvslocal</a>
mkLocalId :: Name -> Type -> Id
mkLocalIdWithInfo :: Name -> Type -> IdInfo -> Id

-- | Create a local <a>Id</a> that is marked as exported. This prevents
--   things attached to it from being removed as dead code.
mkExportedLocalId :: Name -> Type -> Id

-- | Create a system local <a>Id</a>. These are local <a>Id</a>s (see
--   <a>Var#globalvslocal</a>) that are created by the compiler out of thin
--   air
mkSysLocal :: FastString -> Unique -> Type -> Id
mkSysLocalM :: MonadUnique m => FastString -> Type -> m Id

-- | Create a user local <a>Id</a>. These are local <a>Id</a>s (see
--   <a>Var#globalvslocal</a>) with a name and location that the user might
--   recognize
mkUserLocal :: OccName -> Unique -> Type -> SrcSpan -> Id
mkUserLocalM :: MonadUnique m => OccName -> Type -> SrcSpan -> m Id

-- | Create a template local for a series of types
mkTemplateLocals :: [Type] -> [Id]

-- | Create a template local for a series of type, but start from a
--   specified template local
mkTemplateLocalsNum :: Int -> [Type] -> [Id]

-- | Create a <i>template local</i>: a family of system local <a>Id</a>s in
--   bijection with <tt>Int</tt>s, typically used in unfoldings
mkTemplateLocal :: Int -> Type -> Id

-- | Workers get local names. <a>CoreTidy</a> will externalise these if
--   necessary
mkWorkerId :: Unique -> Id -> Type -> Id
mkWiredInIdName :: Module -> FastString -> Unique -> Id -> Name
idName :: Id -> Name
idType :: Id -> Kind
idUnique :: Id -> Unique
idInfo :: Id -> IdInfo
idDetails :: Id -> IdDetails
idRepArity :: Id -> RepArity

-- | If the <a>Id</a> is that for a record selector, extract the
--   <a>sel_tycon</a> and label. Panic otherwise
recordSelectorFieldLabel :: Id -> (TyCon, FieldLabel)
setIdName :: Id -> Name -> Id
setIdUnique :: Id -> Unique -> Id

-- | Not only does this set the <a>Id</a> <a>Type</a>, it also evaluates
--   the type to try and reduce space usage
setIdType :: Id -> Type -> Id
setIdExported :: Id -> Id
setIdNotExported :: Id -> Id

-- | If it's a local, make it global
globaliseId :: Id -> Id
localiseId :: Id -> Id
setIdInfo :: Id -> IdInfo -> Id
lazySetIdInfo :: Id -> IdInfo -> Id
modifyIdInfo :: (IdInfo -> IdInfo) -> Id -> Id
maybeModifyIdInfo :: Maybe IdInfo -> Id -> Id
zapLamIdInfo :: Id -> Id
zapDemandIdInfo :: Id -> Id
zapFragileIdInfo :: Id -> Id
transferPolyIdInfo :: Id -> [Var] -> Id -> Id

-- | <a>isImplicitId</a> tells whether an <a>Id</a>s info is implied by
--   other declarations, so we don't need to put its signature in an
--   interface file, even if it's mentioned in some other interface
--   unfolding.
isImplicitId :: Id -> Bool
isDeadBinder :: Id -> Bool

-- | This predicate says whether the <a>Id</a> has a strict demand placed
--   on it or has a type such that it can always be evaluated strictly
--   (e.g., an unlifted type, but see the comment for <a>isStrictType</a>).
--   We need to check separately whether the <a>Id</a> has a so-called
--   "strict type" because if the demand for the given <tt>id</tt> hasn't
--   been computed yet but <tt>id</tt> has a strict type, we still want
--   <tt>isStrictId id</tt> to be <tt>True</tt>.
isStrictId :: Id -> Bool

-- | <tt>isExportedIdVar</tt> means "don't throw this away"
isExportedId :: Var -> Bool
isLocalId :: Var -> Bool
isGlobalId :: Var -> Bool
isRecordSelector :: Id -> Bool
isNaughtyRecordSelector :: Id -> Bool
isClassOpId_maybe :: Id -> Maybe Class
isDFunId :: Id -> Bool
isPrimOpId :: Id -> Bool
isPrimOpId_maybe :: Id -> Maybe PrimOp
isFCallId :: Id -> Bool
isFCallId_maybe :: Id -> Maybe ForeignCall
isDataConWorkId :: Id -> Bool
isDataConWorkId_maybe :: Id -> Maybe DataCon
isDataConId_maybe :: Id -> Maybe DataCon

-- | Get from either the worker or the wrapper <a>Id</a> to the
--   <a>DataCon</a>. Currently used only in the desugarer.
--   
--   INVARIANT: <tt>idDataCon (dataConWrapId d) = d</tt>: remember,
--   <a>dataConWrapId</a> can return either the wrapper or the worker
idDataCon :: Id -> DataCon
isConLikeId :: Id -> Bool

-- | Returns true if an application to n args would diverge
isBottomingId :: Id -> Bool
idIsFrom :: Module -> Id -> Bool

-- | Returns <tt>True</tt> of an <a>Id</a> which may not have a binding,
--   even though it is defined in this module.
hasNoBinding :: Id -> Bool
type DictId = EvId
isDictId :: Id -> Bool
dfunNSilent :: Id -> Int
isEvVar :: Var -> Bool
idInlinePragma :: Id -> InlinePragma
setInlinePragma :: Id -> InlinePragma -> Id
modifyInlinePragma :: Id -> (InlinePragma -> InlinePragma) -> Id
idInlineActivation :: Id -> Activation
setInlineActivation :: Id -> Activation -> Id
idRuleMatchInfo :: Id -> RuleMatchInfo

-- | Returns whether the lambda associated with the <a>Id</a> is certainly
--   applied at most once OR we are applying the "state hack" which makes
--   it appear as if theis is the case for lambdas used in <tt>IO</tt>. You
--   should prefer using this over <a>isOneShotLambda</a>
isOneShotBndr :: Id -> Bool

-- | Returns whether the lambda associated with the <a>Id</a> is certainly
--   applied at most once. You probably want to use <a>isOneShotBndr</a>
--   instead
isOneShotLambda :: Id -> Bool

-- | Should we apply the state hack to values of this <a>Type</a>?
isStateHackType :: Type -> Bool
setOneShotLambda :: Id -> Id
clearOneShotLambda :: Id -> Id
idArity :: Id -> Arity
idDemandInfo :: Id -> Demand
idDemandInfo_maybe :: Id -> Maybe Demand
idStrictness :: Id -> StrictSig
idStrictness_maybe :: Id -> Maybe StrictSig
idUnfolding :: Id -> Unfolding
realIdUnfolding :: Id -> Unfolding
idSpecialisation :: Id -> SpecInfo
idCoreRules :: Id -> [CoreRule]
idHasRules :: Id -> Bool
idCafInfo :: Id -> CafInfo
idLBVarInfo :: Id -> LBVarInfo
idOccInfo :: Id -> OccInfo
setIdUnfoldingLazily :: Id -> Unfolding -> Id
setIdUnfolding :: Id -> Unfolding -> Id
setIdArity :: Id -> Arity -> Id
setIdDemandInfo :: Id -> Demand -> Id
setIdStrictness :: Id -> StrictSig -> Id
zapIdStrictness :: Id -> Id
setIdSpecialisation :: Id -> SpecInfo -> Id
setIdCafInfo :: Id -> CafInfo -> Id
setIdOccInfo :: Id -> OccInfo -> Id
zapIdOccInfo :: Id -> Id


-- | This module is about types that can be defined in Haskell, but which
--   must be wired into the compiler nonetheless. C.f module TysPrim
module TysWiredIn
wiredInTyCons :: [TyCon]
boolTy :: Type
boolTyCon :: TyCon
boolTyCon_RDR :: RdrName
boolTyConName :: Name
trueDataCon :: DataCon
trueDataConId :: Id
true_RDR :: RdrName
falseDataCon :: DataCon
falseDataConId :: Id
false_RDR :: RdrName
ltDataCon :: DataCon
ltDataConId :: Id
eqDataCon :: DataCon
eqDataConId :: Id
gtDataCon :: DataCon
gtDataConId :: Id
charTyCon :: TyCon
charDataCon :: DataCon
charTyCon_RDR :: RdrName
charTy :: Type
stringTy :: Type
charTyConName :: Name
integerGmpSDataCon :: DataCon
doubleTyCon :: TyCon
doubleDataCon :: DataCon
doubleTy :: Type
doubleTyConName :: Name
floatTyCon :: TyCon
floatDataCon :: DataCon
floatTy :: Type
floatTyConName :: Name
intTyCon :: TyCon
intDataCon :: DataCon
intTyCon_RDR :: RdrName
intDataCon_RDR :: RdrName
intTyConName :: Name
intTy :: Type
wordTyCon :: TyCon
wordDataCon :: DataCon
wordTyConName :: Name
wordTy :: Type
listTyCon :: TyCon
nilDataCon :: DataCon
consDataCon :: DataCon
consDataConName :: Name
listTyCon_RDR :: RdrName
consDataCon_RDR :: RdrName
listTyConName :: Name
mkListTy :: Type -> Type
mkPromotedListTy :: Type -> Type
mkTupleTy :: TupleSort -> [Type] -> Type

-- | Build the type of a small tuple that holds the specified type of thing
mkBoxedTupleTy :: [Type] -> Type
tupleTyCon :: TupleSort -> Arity -> TyCon
tupleCon :: TupleSort -> Arity -> DataCon
promotedTupleTyCon :: TupleSort -> Arity -> TyCon
promotedTupleDataCon :: TupleSort -> Arity -> TyCon
unitTyCon :: TyCon
unitDataCon :: DataCon
unitDataConId :: Id
pairTyCon :: TyCon
unboxedUnitTyCon :: TyCon
unboxedUnitDataCon :: DataCon
unboxedSingletonTyCon :: TyCon
unboxedSingletonDataCon :: DataCon
unboxedPairTyCon :: TyCon
unboxedPairDataCon :: DataCon
unitTy :: Type

-- | Construct a type representing the application of the parallel array
--   constructor
mkPArrTy :: Type -> Type

-- | Represents the type constructor of parallel arrays
--   
--   <ul>
--   <li>This must match the definition in <tt>PrelPArr</tt></li>
--   </ul>
--   
--   NB: Although the constructor is given here, it will not be accessible
--   in user code as it is not in the environment of any compiled module
--   except <tt>PrelPArr</tt>.
parrTyCon :: TyCon

-- | Fake array constructors
--   
--   <ul>
--   <li>These constructors are never really used to represent array
--   values; however, they are very convenient during desugaring (and, in
--   particular, in the pattern matching compiler) to treat array pattern
--   just like yet another constructor pattern</li>
--   </ul>
parrFakeCon :: Arity -> DataCon

-- | Check whether a type constructor is the constructor for parallel
--   arrays
isPArrTyCon :: TyCon -> Bool

-- | Checks whether a data constructor is a fake constructor for parallel
--   arrays
isPArrFakeCon :: DataCon -> Bool
parrTyCon_RDR :: RdrName
parrTyConName :: Name
eqTyCon_RDR :: RdrName
eqTyCon :: TyCon
eqTyConName :: Name
eqBoxDataCon :: DataCon

module TcType
type TcType = Type
type TcSigmaType = TcType
type TcRhoType = TcType
type TcTauType = TcType
type TcPredType = PredType
type TcThetaType = ThetaType
type TcTyVar = TyVar
type TcTyVarSet = TyVarSet
type TcKind = Kind
type TcCoVar = CoVar
data UserTypeCtxt
FunSigCtxt :: Name -> UserTypeCtxt
InfSigCtxt :: Name -> UserTypeCtxt
ExprSigCtxt :: UserTypeCtxt
ConArgCtxt :: Name -> UserTypeCtxt
TySynCtxt :: Name -> UserTypeCtxt
LamPatSigCtxt :: UserTypeCtxt
BindPatSigCtxt :: UserTypeCtxt
RuleSigCtxt :: Name -> UserTypeCtxt
ResSigCtxt :: UserTypeCtxt
ForSigCtxt :: Name -> UserTypeCtxt
DefaultDeclCtxt :: UserTypeCtxt
InstDeclCtxt :: UserTypeCtxt
SpecInstCtxt :: UserTypeCtxt
ThBrackCtxt :: UserTypeCtxt
GenSigCtxt :: UserTypeCtxt
GhciCtxt :: UserTypeCtxt
ClassSCCtxt :: Name -> UserTypeCtxt
SigmaCtxt :: UserTypeCtxt
DataTyCtxt :: Name -> UserTypeCtxt
pprUserTypeCtxt :: UserTypeCtxt -> SDoc
data TcTyVarDetails
SkolemTv :: Bool -> TcTyVarDetails
RuntimeUnk :: TcTyVarDetails
FlatSkol :: TcType -> TcTyVarDetails
MetaTv :: MetaInfo -> (IORef MetaDetails) -> TcTyVarDetails
pprTcTyVarDetails :: TcTyVarDetails -> SDoc
vanillaSkolemTv :: TcTyVarDetails
superSkolemTv :: TcTyVarDetails
data MetaDetails
Flexi :: MetaDetails
Indirect :: TcType -> MetaDetails
data MetaInfo
TauTv :: MetaInfo
SigTv :: MetaInfo
TcsTv :: MetaInfo
isImmutableTyVar :: TyVar -> Bool
isSkolemTyVar :: TcTyVar -> Bool
isMetaTyVar :: TcTyVar -> Bool
isMetaTyVarTy :: TcType -> Bool
isTyVarTy :: Type -> Bool
isSigTyVar :: Var -> Bool
isOverlappableTyVar :: TcTyVar -> Bool
isTyConableTyVar :: TcTyVar -> Bool
isAmbiguousTyVar :: TcTyVar -> Bool
metaTvRef :: TyVar -> IORef MetaDetails
isFlexi :: MetaDetails -> Bool
isIndirect :: MetaDetails -> Bool
isRuntimeUnkSkol :: TyVar -> Bool
isTypeVar :: Var -> Bool
isKindVar :: Var -> Bool
mkPhiTy :: [PredType] -> Type -> Type
mkSigmaTy :: [TyVar] -> [PredType] -> Type -> Type
mkTcEqPred :: TcType -> TcType -> Type

-- | Similar to <a>coreView</a>, but for the type checker, which just looks
--   through synonyms
tcView :: Type -> Maybe Type
tcSplitForAllTys :: Type -> ([TyVar], Type)
tcSplitPhiTy :: Type -> (ThetaType, Type)
tcSplitPredFunTy_maybe :: Type -> Maybe (PredType, Type)
tcSplitFunTy_maybe :: Type -> Maybe (Type, Type)
tcSplitFunTys :: Type -> ([Type], Type)
tcFunArgTy :: Type -> Type
tcFunResultTy :: Type -> Type
tcSplitFunTysN :: TcRhoType -> Arity -> ([TcSigmaType], TcSigmaType)
tcSplitTyConApp :: Type -> (TyCon, [Type])
tcSplitTyConApp_maybe :: Type -> Maybe (TyCon, [Type])
tcTyConAppTyCon :: Type -> TyCon
tcTyConAppArgs :: Type -> [Type]
tcSplitAppTy_maybe :: Type -> Maybe (Type, Type)
tcSplitAppTy :: Type -> (Type, Type)
tcSplitAppTys :: Type -> (Type, [Type])

-- | Does the AppTy split as in <a>splitAppTy_maybe</a>, but assumes that
--   any Core view stuff is already done
repSplitAppTy_maybe :: Type -> Maybe (Type, Type)
tcInstHeadTyNotSynonym :: Type -> Bool
tcInstHeadTyAppAllTyVars :: Type -> Bool
tcGetTyVar_maybe :: Type -> Maybe TyVar
tcGetTyVar :: String -> Type -> TyVar
tcSplitSigmaTy :: Type -> ([TyVar], ThetaType, Type)
tcDeepSplitSigmaTy_maybe :: TcSigmaType -> Maybe ([TcType], [TyVar], ThetaType, TcSigmaType)

-- | Type equality on source types. Does not look through <tt>newtypes</tt>
--   or <a>PredType</a>s, but it does look through type synonyms.
eqType :: Type -> Type -> Bool
eqTypes :: [Type] -> [Type] -> Bool
eqPred :: PredType -> PredType -> Bool
cmpType :: Type -> Type -> Ordering
cmpTypes :: [Type] -> [Type] -> Ordering
cmpPred :: PredType -> PredType -> Ordering
eqTypeX :: RnEnv2 -> Type -> Type -> Bool
pickyEqType :: TcType -> TcType -> Bool
eqKind :: Kind -> Kind -> Bool
isSigmaTy :: Type -> Bool
isOverloadedTy :: Type -> Bool
isDoubleTy :: Type -> Bool
isFloatTy :: Type -> Bool
isIntTy :: Type -> Bool
isWordTy :: Type -> Bool
isStringTy :: Type -> Bool
isIntegerTy :: Type -> Bool
isBoolTy :: Type -> Bool
isUnitTy :: Type -> Bool
isCharTy :: Type -> Bool
isTauTy :: Type -> Bool
isTauTyCon :: TyCon -> Bool
tcIsTyVarTy :: Type -> Bool
tcIsForAllTy :: Type -> Bool
isSynFamilyTyConApp :: TcTauType -> Bool
isPredTy :: Type -> Bool
isTyVarClassPred :: PredType -> Bool
deNoteType :: Type -> Type
orphNamesOfType :: Type -> NameSet
orphNamesOfDFunHead :: Type -> NameSet
orphNamesOfCo :: Coercion -> NameSet
getDFunTyKey :: Type -> OccName
evVarPred_maybe :: EvVar -> Maybe PredType
evVarPred :: EvVar -> PredType
mkMinimalBySCs :: [PredType] -> [PredType]
transSuperClasses :: Class -> [Type] -> [PredType]
immSuperClasses :: Class -> [Type] -> [PredType]

-- | Finds outermost type-family applications occuring in a type, after
--   expanding synonyms.
tcTyFamInsts :: Type -> [(TyCon, [Type])]
exactTyVarsOfType :: Type -> TyVarSet
exactTyVarsOfTypes :: [Type] -> TyVarSet
tidyType :: TidyEnv -> Type -> Type
tidyTypes :: TidyEnv -> [Type] -> [Type]

-- | Grabs the free type variables, tidies them and then uses
--   <a>tidyType</a> to work over the type itself
tidyOpenType :: TidyEnv -> Type -> (TidyEnv, Type)
tidyOpenTypes :: TidyEnv -> [Type] -> (TidyEnv, [Type])
tidyOpenKind :: TidyEnv -> Kind -> (TidyEnv, Kind)
tidyTyVarBndr :: TidyEnv -> TyVar -> (TidyEnv, TyVar)

-- | This tidies up a type for printing in an error message, or in an
--   interface file.
--   
--   It doesn't change the uniques at all, just the print names.
tidyTyVarBndrs :: TidyEnv -> [TyVar] -> (TidyEnv, [TyVar])

-- | Add the free <a>TyVar</a>s to the env in tidy form, so that we can
--   tidy the type they are free in
tidyFreeTyVars :: TidyEnv -> TyVarSet -> TidyEnv

-- | Treat a new <a>TyVar</a> as a binder, and give it a fresh tidy name
--   using the environment if one has not already been allocated. See also
--   <a>tidyTyVarBndr</a>
tidyOpenTyVar :: TidyEnv -> TyVar -> (TidyEnv, TyVar)
tidyOpenTyVars :: TidyEnv -> [TyVar] -> (TidyEnv, [TyVar])
tidyTyVarOcc :: TidyEnv -> TyVar -> Type

-- | Calls <a>tidyType</a> on a top-level type (i.e. with an empty tidying
--   environment)
tidyTopType :: Type -> Type
tidyKind :: TidyEnv -> Kind -> Kind
tidyCo :: TidyEnv -> Coercion -> Coercion
tidyCos :: TidyEnv -> [Coercion] -> [Coercion]
isFFIArgumentTy :: DynFlags -> Safety -> Type -> Bool
isFFIImportResultTy :: DynFlags -> Type -> Bool
isFFIExportResultTy :: Type -> Bool
isFFIExternalTy :: Type -> Bool
isFFIDynTy :: Type -> Type -> Bool
isFFIPrimArgumentTy :: DynFlags -> Type -> Bool
isFFIPrimResultTy :: DynFlags -> Type -> Bool
isFFILabelTy :: Type -> Bool
isFFIDotnetTy :: DynFlags -> Type -> Bool
isFFIDotnetObjTy :: Type -> Bool
isFFITy :: Type -> Bool
isFunPtrTy :: Type -> Bool
tcSplitIOType_maybe :: Type -> Maybe (TyCon, Type)

-- | The key type representing kinds in the compiler. Invariant: a kind is
--   always in one of these forms:
--   
--   <pre>
--   FunTy k1 k2
--   TyConApp PrimTyCon [...]
--   TyVar kv   -- (during inference only)
--   ForAll ... -- (for top-level coercions)
--   </pre>
type Kind = Type
typeKind :: Type -> Kind

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
unliftedTypeKind :: Kind

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
liftedTypeKind :: Kind

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
openTypeKind :: Kind

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
constraintKind :: Kind

-- | Given two kinds <tt>k1</tt> and <tt>k2</tt>, creates the <a>Kind</a>
--   <tt>k1 -&gt; k2</tt>
mkArrowKind :: Kind -> Kind -> Kind

-- | Iterated application of <a>mkArrowKind</a>
mkArrowKinds :: [Kind] -> Kind -> Kind
isLiftedTypeKind :: Kind -> Bool

-- | See <a>Type#kind_subtyping</a> for details of the distinction between
--   these <a>Kind</a>s
isUnliftedTypeKind :: Kind -> Bool

-- | True of any sub-kind of OpenTypeKind
isSubOpenTypeKind :: Kind -> Bool
tcIsSubKind :: Kind -> Kind -> Bool

-- | Essentially <tt>splitFunTys</tt> on kinds
splitKindFunTys :: Kind -> ([Kind], Kind)

-- | Used when generalising: default OpenKind and ArgKind to *. See
--   <a>Type#kind_subtyping</a> for more information on what that means
defaultKind :: Kind -> Kind
mkMetaKindVar :: Unique -> IORef MetaDetails -> MetaKindVar

-- | The key representation of types within the compiler
data Type

-- | A type of the form <tt>p</tt> of kind <tt>Constraint</tt> represents a
--   value whose type is the Haskell predicate <tt>p</tt>, where a
--   predicate is what occurs before the <tt>=&gt;</tt> in a Haskell type.
--   
--   We use <a>PredType</a> as documentation to mark those types that we
--   guarantee to have this kind.
--   
--   It can be expanded into its representation, but:
--   
--   <ul>
--   <li>The type checker must treat it as opaque</li>
--   <li>The rest of the compiler treats it as transparent</li>
--   </ul>
--   
--   Consider these examples:
--   
--   <pre>
--   f :: (Eq a) =&gt; a -&gt; Int
--   g :: (?x :: Int -&gt; Int) =&gt; a -&gt; Int
--   h :: (r\l) =&gt; {r} =&gt; {l::Int | r}
--   </pre>
--   
--   Here the <tt>Eq a</tt> and <tt>?x :: Int -&gt; Int</tt> and
--   <tt>rl</tt> are all called "predicates"
type PredType = Type

-- | A collection of <a>PredType</a>s
type ThetaType = [PredType]
mkForAllTy :: TyVar -> Type -> Type

-- | Wraps foralls over the type using the provided <a>TyVar</a>s from left
--   to right
mkForAllTys :: [TyVar] -> Type -> Type

-- | Creates a function type from the given argument and result type
mkFunTy :: Type -> Type -> Type
mkFunTys :: [Type] -> Type -> Type

-- | Splits off argument types from the given type and associating them
--   with the things in the input list from left to right. The final result
--   type is returned, along with the resulting pairs of objects and types,
--   albeit with the list of pairs in reverse order. Panics if there are
--   not enough argument types for the input list.
zipFunTys :: Outputable a => [a] -> Type -> ([(a, Type)], Type)

-- | A key function: builds a <a>TyConApp</a> or <a>FunTy</a> as
--   apppropriate to its arguments. Applies its arguments to the
--   constructor from left to right.
mkTyConApp :: TyCon -> [Type] -> Type

-- | Applies a type to another, as in e.g. <tt>k a</tt>
mkAppTy :: Type -> Type -> Type
mkAppTys :: Type -> [Type] -> Type

-- | Instantiate a forall type with one or more type arguments. Used when
--   we have a polymorphic function applied to type args:
--   
--   <pre>
--   f t1 t2
--   </pre>
--   
--   We use <tt>applyTys type-of-f [t1,t2]</tt> to compute the type of the
--   expression. Panics if no application is possible.
applyTy :: Type -> KindOrType -> Type

-- | This function is interesting because:
--   
--   <ol>
--   <li>The function may have more for-alls than there are args</li>
--   <li>Less obviously, it may have fewer for-alls</li>
--   </ol>
--   
--   For case 2. think of:
--   
--   <pre>
--   applyTys (forall a.a) [forall b.b, Int]
--   </pre>
--   
--   This really can happen, but only (I think) in situations involving
--   undefined. For example: undefined :: forall a. a Term: undefined
--   <tt>(forall b. b-&gt;b) </tt>Int This term should have type (Int -&gt;
--   Int), but notice that there are more type args than foralls in
--   <a>undefined</a>s type.
applyTys :: Type -> [KindOrType] -> Type
mkTyVarTy :: TyVar -> Type
mkTyVarTys :: [TyVar] -> [Type]

-- | Create the plain type constructor type which has been applied to no
--   type arguments at all.
mkTyConTy :: TyCon -> Type
isClassPred :: PredType -> Bool
isEqPred :: PredType -> Bool
isIPPred :: PredType -> Bool
mkClassPred :: Class -> [Type] -> PredType
isDictLikeTy :: Type -> Bool
tcSplitDFunTy :: Type -> ([TyVar], Int, Class, [Type])
tcSplitDFunHead :: Type -> (Class, [Type])

-- | Creates a type equality predicate
mkEqPred :: Type -> Type -> PredType

-- | Type substitution
--   
--   The following invariants must hold of a <a>TvSubst</a>:
--   
--   <ol>
--   <li>The in-scope set is needed <i>only</i> to guide the generation of
--   fresh uniques</li>
--   <li>In particular, the <i>kind</i> of the type variables in the
--   in-scope set is not relevant</li>
--   <li>The substition is only applied ONCE! This is because in general
--   such application will not reached a fixed point.</li>
--   </ol>
data TvSubst
TvSubst :: InScopeSet -> TvSubstEnv -> TvSubst

-- | A substitition of <a>Type</a>s for <a>TyVar</a>s and <a>Kind</a>s for
--   <a>KindVar</a>s
type TvSubstEnv = TyVarEnv Type
emptyTvSubst :: TvSubst

-- | Generates the in-scope set for the <a>TvSubst</a> from the types in
--   the incoming environment, hence <a>open</a>
mkOpenTvSubst :: TvSubstEnv -> TvSubst

-- | Generates the in-scope set for the <a>TvSubst</a> from the types in
--   the incoming environment, hence <a>open</a>
zipOpenTvSubst :: [TyVar] -> [Type] -> TvSubst
zipTopTvSubst :: [TyVar] -> [Type] -> TvSubst

-- | Called when doing top-level substitutions. Here we expect that the
--   free vars of the range of the substitution will be empty.
mkTopTvSubst :: [(TyVar, Type)] -> TvSubst
notElemTvSubst :: CoVar -> TvSubst -> Bool
unionTvSubst :: TvSubst -> TvSubst -> TvSubst
getTvSubstEnv :: TvSubst -> TvSubstEnv
setTvSubstEnv :: TvSubst -> TvSubstEnv -> TvSubst
getTvInScope :: TvSubst -> InScopeSet
extendTvInScope :: TvSubst -> Var -> TvSubst
lookupTyVar :: TvSubst -> TyVar -> Maybe Type
extendTvSubst :: TvSubst -> TyVar -> Type -> TvSubst
substTyVarBndr :: TvSubst -> TyVar -> (TvSubst, TyVar)
extendTvSubstList :: TvSubst -> [TyVar] -> [Type] -> TvSubst
isInScope :: Var -> TvSubst -> Bool
mkTvSubst :: InScopeSet -> TvSubstEnv -> TvSubst
zipTyEnv :: [TyVar] -> [Type] -> TvSubstEnv

-- | Substitute within a <a>Type</a>
substTy :: TvSubst -> Type -> Type

-- | Substitute within several <a>Type</a>s
substTys :: TvSubst -> [Type] -> [Type]

-- | Type substitution making use of an <a>TvSubst</a> that is assumed to
--   be open, see <a>zipOpenTvSubst</a>
substTyWith :: [TyVar] -> [Type] -> Type -> Type

-- | Substitute within a <a>ThetaType</a>
substTheta :: TvSubst -> ThetaType -> ThetaType
substTyVar :: TvSubst -> TyVar -> Type
substTyVars :: TvSubst -> [TyVar] -> [Type]

-- | See <a>Type#type_classification</a> for what an unlifted type is
isUnLiftedType :: Type -> Bool
isUnboxedTupleType :: Type -> Bool

-- | Returns true of types that are opaque to Haskell. Most of these are
--   unlifted, but now that we interact with .NET, we may have primtive
--   (foreign-imported) types that are lifted
isPrimitiveType :: Type -> Bool

-- | NB: for type synonyms tyVarsOfType does <i>not</i> expand the synonym
--   tyVarsOfType returns only the free variables of a type For example,
--   tyVarsOfType (a::k) returns {a}, not including the kind variable {k}
tyVarsOfType :: Type -> VarSet
tyVarsOfTypes :: [Type] -> TyVarSet
tcTyVarsOfType :: Type -> TcTyVarSet
tcTyVarsOfTypes :: [Type] -> TyVarSet
pprKind :: Kind -> SDoc
pprParendKind :: Kind -> SDoc
pprSigmaType :: Type -> SDoc
pprType :: Type -> SDoc
pprParendType :: Type -> SDoc
pprTypeApp :: NamedThing a => a -> [Type] -> SDoc
pprTyThingCategory :: TyThing -> SDoc
pprTheta :: ThetaType -> SDoc
pprThetaArrowTy :: ThetaType -> SDoc
pprClassPred :: Class -> [Type] -> SDoc
instance Outputable MetaDetails

module InstEnv
type DFunId = Id
data OverlapFlag

-- | This instance must not overlap another
NoOverlap :: Bool -> OverlapFlag
isSafeOverlap :: OverlapFlag -> Bool

-- | Silently ignore this instance if you find a more specific one that
--   matches the constraint you are trying to resolve
--   
--   Example: constraint (Foo [Int]) instances (Foo [Int]) (Foo [a])
--   OverlapOk Since the second instance has the OverlapOk flag, the first
--   instance will be chosen (otherwise its ambiguous which to choose)
OverlapOk :: Bool -> OverlapFlag
isSafeOverlap :: OverlapFlag -> Bool

-- | Like OverlapOk, but also ignore this instance if it doesn't match the
--   constraint you are trying to resolve, but could match if the type
--   variables in the constraint were instantiated
--   
--   Example: constraint (Foo [b]) instances (Foo [Int]) Incoherent (Foo
--   [a]) Without the Incoherent flag, we'd complain that instantiating
--   <tt>b</tt> would change which instance was chosen
Incoherent :: Bool -> OverlapFlag
isSafeOverlap :: OverlapFlag -> Bool
type InstMatch = (ClsInst, [DFunInstType])
type ClsInstLookupResult = ([InstMatch], [ClsInst], Bool)
data ClsInst
ClsInst :: Name -> [Maybe Name] -> TyVarSet -> [Type] -> DFunId -> OverlapFlag -> ClsInst
is_cls :: ClsInst -> Name
is_tcs :: ClsInst -> [Maybe Name]
is_tvs :: ClsInst -> TyVarSet
is_tys :: ClsInst -> [Type]
is_dfun :: ClsInst -> DFunId
is_flag :: ClsInst -> OverlapFlag
type DFunInstType = Maybe Type
pprInstance :: ClsInst -> SDoc
pprInstanceHdr :: ClsInst -> SDoc
pprInstances :: [ClsInst] -> SDoc
instanceHead :: ClsInst -> ([TyVar], ThetaType, Class, [Type])
mkLocalInstance :: DFunId -> OverlapFlag -> ClsInst
mkImportedInstance :: Name -> [Maybe Name] -> DFunId -> OverlapFlag -> ClsInst
instanceDFunId :: ClsInst -> DFunId
setInstanceDFunId :: ClsInst -> DFunId -> ClsInst
instanceRoughTcs :: ClsInst -> [Maybe Name]
type InstEnv = UniqFM ClsInstEnv
emptyInstEnv :: InstEnv
extendInstEnv :: InstEnv -> ClsInst -> InstEnv
overwriteInstEnv :: InstEnv -> ClsInst -> InstEnv
extendInstEnvList :: InstEnv -> [ClsInst] -> InstEnv

-- | Look up an instance in the given instance environment. The given class
--   application must match exactly one instance and the match may not
--   contain any flexi type variables. If the lookup is unsuccessful, yield
--   'Left errorMessage'.
lookupUniqueInstEnv :: (InstEnv, InstEnv) -> Class -> [Type] -> Either MsgDoc (ClsInst, [Type])
lookupInstEnv' :: InstEnv -> Class -> [Type] -> ([InstMatch], [ClsInst])
lookupInstEnv :: (InstEnv, InstEnv) -> Class -> [Type] -> ClsInstLookupResult
instEnvElts :: InstEnv -> [ClsInst]
classInstances :: (InstEnv, InstEnv) -> Class -> [ClsInst]
instanceBindFun :: TyVar -> BindFlag
instanceCantMatch :: [Maybe Name] -> [Maybe Name] -> Bool
roughMatchTcs :: [Type] -> [Maybe Name]
instance Typeable ClsInst
instance Data ClsInst
instance Outputable ClsInstEnv
instance Outputable ClsInst
instance NamedThing ClsInst

module FamInstEnv
data FamInst
FamInst :: CoAxiom -> FamFlavor -> Name -> [Maybe Name] -> TyVarSet -> TyCon -> [Type] -> FamInst
fi_axiom :: FamInst -> CoAxiom
fi_flavor :: FamInst -> FamFlavor
fi_fam :: FamInst -> Name
fi_tcs :: FamInst -> [Maybe Name]
fi_tvs :: FamInst -> TyVarSet
fi_fam_tc :: FamInst -> TyCon
fi_tys :: FamInst -> [Type]
data FamFlavor
SynFamilyInst :: FamFlavor
DataFamilyInst :: TyCon -> FamFlavor
famInstAxiom :: FamInst -> CoAxiom
famInstsRepTyCons :: [FamInst] -> [TyCon]
famInstRepTyCon_maybe :: FamInst -> Maybe TyCon
dataFamInstRepTyCon :: FamInst -> TyCon
famInstLHS :: FamInst -> (TyCon, [Type])
pprFamInst :: FamInst -> SDoc
pprFamInstHdr :: FamInst -> SDoc
pprFamInsts :: [FamInst] -> SDoc

-- | Create a coercion identifying a <tt>type</tt> family instance. It has
--   the form <tt>Co tvs :: F ts ~ R</tt>, where <tt>Co</tt> is the
--   coercion constructor built here, <tt>F</tt> the family tycon and
--   <tt>R</tt> the right-hand side of the type family instance.
mkSynFamInst :: Name -> [TyVar] -> TyCon -> [Type] -> Type -> FamInst

-- | Create a coercion identifying a <tt>data</tt> or <tt>newtype</tt>
--   representation type and its family instance. It has the form <tt>Co
--   tvs :: F ts ~ R tvs</tt>, where <tt>Co</tt> is the coercion
--   constructor built here, <tt>F</tt> the family tycon and <tt>R</tt> the
--   (derived) representation tycon.
mkDataFamInst :: Name -> [TyVar] -> TyCon -> [Type] -> TyCon -> FamInst
mkImportedFamInst :: Name -> [Maybe Name] -> CoAxiom -> FamInst
type FamInstEnvs = (FamInstEnv, FamInstEnv)
type FamInstEnv = UniqFM FamilyInstEnv
emptyFamInstEnv :: FamInstEnv
emptyFamInstEnvs :: (FamInstEnv, FamInstEnv)
extendFamInstEnv :: FamInstEnv -> FamInst -> FamInstEnv
deleteFromFamInstEnv :: FamInstEnv -> FamInst -> FamInstEnv
extendFamInstEnvList :: FamInstEnv -> [FamInst] -> FamInstEnv
identicalFamInst :: FamInst -> FamInst -> Bool
famInstEnvElts :: FamInstEnv -> [FamInst]
familyInstances :: (FamInstEnv, FamInstEnv) -> TyCon -> [FamInst]
lookupFamInstEnv :: FamInstEnvs -> TyCon -> [Type] -> [FamInstMatch]
lookupFamInstEnvConflicts :: FamInstEnvs -> FamInst -> [TyVar] -> [FamInstMatch]
lookupFamInstEnvConflicts' :: FamInstEnv -> FamInst -> [TyVar] -> [FamInstMatch]
topNormaliseType :: FamInstEnvs -> Type -> Maybe (Coercion, Type)
normaliseType :: FamInstEnvs -> Type -> (Coercion, Type)
normaliseTcApp :: FamInstEnvs -> TyCon -> [Type] -> (Coercion, Type)
instance Outputable FamilyInstEnv
instance Outputable FamInst
instance NamedThing FamInst

module PrimOp
data PrimOp
CharGtOp :: PrimOp
CharGeOp :: PrimOp
CharEqOp :: PrimOp
CharNeOp :: PrimOp
CharLtOp :: PrimOp
CharLeOp :: PrimOp
OrdOp :: PrimOp
IntAddOp :: PrimOp
IntSubOp :: PrimOp
IntMulOp :: PrimOp
IntMulMayOfloOp :: PrimOp
IntQuotOp :: PrimOp
IntRemOp :: PrimOp
IntQuotRemOp :: PrimOp
IntNegOp :: PrimOp
IntAddCOp :: PrimOp
IntSubCOp :: PrimOp
IntGtOp :: PrimOp
IntGeOp :: PrimOp
IntEqOp :: PrimOp
IntNeOp :: PrimOp
IntLtOp :: PrimOp
IntLeOp :: PrimOp
ChrOp :: PrimOp
Int2WordOp :: PrimOp
Int2FloatOp :: PrimOp
Int2DoubleOp :: PrimOp
ISllOp :: PrimOp
ISraOp :: PrimOp
ISrlOp :: PrimOp
WordAddOp :: PrimOp
WordAdd2Op :: PrimOp
WordSubOp :: PrimOp
WordMulOp :: PrimOp
WordMul2Op :: PrimOp
WordQuotOp :: PrimOp
WordRemOp :: PrimOp
WordQuotRemOp :: PrimOp
WordQuotRem2Op :: PrimOp
AndOp :: PrimOp
OrOp :: PrimOp
XorOp :: PrimOp
NotOp :: PrimOp
SllOp :: PrimOp
SrlOp :: PrimOp
Word2IntOp :: PrimOp
WordGtOp :: PrimOp
WordGeOp :: PrimOp
WordEqOp :: PrimOp
WordNeOp :: PrimOp
WordLtOp :: PrimOp
WordLeOp :: PrimOp
PopCnt8Op :: PrimOp
PopCnt16Op :: PrimOp
PopCnt32Op :: PrimOp
PopCnt64Op :: PrimOp
PopCntOp :: PrimOp
Narrow8IntOp :: PrimOp
Narrow16IntOp :: PrimOp
Narrow32IntOp :: PrimOp
Narrow8WordOp :: PrimOp
Narrow16WordOp :: PrimOp
Narrow32WordOp :: PrimOp
DoubleGtOp :: PrimOp
DoubleGeOp :: PrimOp
DoubleEqOp :: PrimOp
DoubleNeOp :: PrimOp
DoubleLtOp :: PrimOp
DoubleLeOp :: PrimOp
DoubleAddOp :: PrimOp
DoubleSubOp :: PrimOp
DoubleMulOp :: PrimOp
DoubleDivOp :: PrimOp
DoubleNegOp :: PrimOp
Double2IntOp :: PrimOp
Double2FloatOp :: PrimOp
DoubleExpOp :: PrimOp
DoubleLogOp :: PrimOp
DoubleSqrtOp :: PrimOp
DoubleSinOp :: PrimOp
DoubleCosOp :: PrimOp
DoubleTanOp :: PrimOp
DoubleAsinOp :: PrimOp
DoubleAcosOp :: PrimOp
DoubleAtanOp :: PrimOp
DoubleSinhOp :: PrimOp
DoubleCoshOp :: PrimOp
DoubleTanhOp :: PrimOp
DoublePowerOp :: PrimOp
DoubleDecode_2IntOp :: PrimOp
FloatGtOp :: PrimOp
FloatGeOp :: PrimOp
FloatEqOp :: PrimOp
FloatNeOp :: PrimOp
FloatLtOp :: PrimOp
FloatLeOp :: PrimOp
FloatAddOp :: PrimOp
FloatSubOp :: PrimOp
FloatMulOp :: PrimOp
FloatDivOp :: PrimOp
FloatNegOp :: PrimOp
Float2IntOp :: PrimOp
FloatExpOp :: PrimOp
FloatLogOp :: PrimOp
FloatSqrtOp :: PrimOp
FloatSinOp :: PrimOp
FloatCosOp :: PrimOp
FloatTanOp :: PrimOp
FloatAsinOp :: PrimOp
FloatAcosOp :: PrimOp
FloatAtanOp :: PrimOp
FloatSinhOp :: PrimOp
FloatCoshOp :: PrimOp
FloatTanhOp :: PrimOp
FloatPowerOp :: PrimOp
Float2DoubleOp :: PrimOp
FloatDecode_IntOp :: PrimOp
NewArrayOp :: PrimOp
SameMutableArrayOp :: PrimOp
ReadArrayOp :: PrimOp
WriteArrayOp :: PrimOp
SizeofArrayOp :: PrimOp
SizeofMutableArrayOp :: PrimOp
IndexArrayOp :: PrimOp
UnsafeFreezeArrayOp :: PrimOp
UnsafeThawArrayOp :: PrimOp
CopyArrayOp :: PrimOp
CopyMutableArrayOp :: PrimOp
CloneArrayOp :: PrimOp
CloneMutableArrayOp :: PrimOp
FreezeArrayOp :: PrimOp
ThawArrayOp :: PrimOp
NewByteArrayOp_Char :: PrimOp
NewPinnedByteArrayOp_Char :: PrimOp
NewAlignedPinnedByteArrayOp_Char :: PrimOp
ByteArrayContents_Char :: PrimOp
SameMutableByteArrayOp :: PrimOp
UnsafeFreezeByteArrayOp :: PrimOp
SizeofByteArrayOp :: PrimOp
SizeofMutableByteArrayOp :: PrimOp
IndexByteArrayOp_Char :: PrimOp
IndexByteArrayOp_WideChar :: PrimOp
IndexByteArrayOp_Int :: PrimOp
IndexByteArrayOp_Word :: PrimOp
IndexByteArrayOp_Addr :: PrimOp
IndexByteArrayOp_Float :: PrimOp
IndexByteArrayOp_Double :: PrimOp
IndexByteArrayOp_StablePtr :: PrimOp
IndexByteArrayOp_Int8 :: PrimOp
IndexByteArrayOp_Int16 :: PrimOp
IndexByteArrayOp_Int32 :: PrimOp
IndexByteArrayOp_Int64 :: PrimOp
IndexByteArrayOp_Word8 :: PrimOp
IndexByteArrayOp_Word16 :: PrimOp
IndexByteArrayOp_Word32 :: PrimOp
IndexByteArrayOp_Word64 :: PrimOp
ReadByteArrayOp_Char :: PrimOp
ReadByteArrayOp_WideChar :: PrimOp
ReadByteArrayOp_Int :: PrimOp
ReadByteArrayOp_Word :: PrimOp
ReadByteArrayOp_Addr :: PrimOp
ReadByteArrayOp_Float :: PrimOp
ReadByteArrayOp_Double :: PrimOp
ReadByteArrayOp_StablePtr :: PrimOp
ReadByteArrayOp_Int8 :: PrimOp
ReadByteArrayOp_Int16 :: PrimOp
ReadByteArrayOp_Int32 :: PrimOp
ReadByteArrayOp_Int64 :: PrimOp
ReadByteArrayOp_Word8 :: PrimOp
ReadByteArrayOp_Word16 :: PrimOp
ReadByteArrayOp_Word32 :: PrimOp
ReadByteArrayOp_Word64 :: PrimOp
WriteByteArrayOp_Char :: PrimOp
WriteByteArrayOp_WideChar :: PrimOp
WriteByteArrayOp_Int :: PrimOp
WriteByteArrayOp_Word :: PrimOp
WriteByteArrayOp_Addr :: PrimOp
WriteByteArrayOp_Float :: PrimOp
WriteByteArrayOp_Double :: PrimOp
WriteByteArrayOp_StablePtr :: PrimOp
WriteByteArrayOp_Int8 :: PrimOp
WriteByteArrayOp_Int16 :: PrimOp
WriteByteArrayOp_Int32 :: PrimOp
WriteByteArrayOp_Int64 :: PrimOp
WriteByteArrayOp_Word8 :: PrimOp
WriteByteArrayOp_Word16 :: PrimOp
WriteByteArrayOp_Word32 :: PrimOp
WriteByteArrayOp_Word64 :: PrimOp
CopyByteArrayOp :: PrimOp
CopyMutableByteArrayOp :: PrimOp
SetByteArrayOp :: PrimOp
NewArrayArrayOp :: PrimOp
SameMutableArrayArrayOp :: PrimOp
UnsafeFreezeArrayArrayOp :: PrimOp
SizeofArrayArrayOp :: PrimOp
SizeofMutableArrayArrayOp :: PrimOp
IndexArrayArrayOp_ByteArray :: PrimOp
IndexArrayArrayOp_ArrayArray :: PrimOp
ReadArrayArrayOp_ByteArray :: PrimOp
ReadArrayArrayOp_MutableByteArray :: PrimOp
ReadArrayArrayOp_ArrayArray :: PrimOp
ReadArrayArrayOp_MutableArrayArray :: PrimOp
WriteArrayArrayOp_ByteArray :: PrimOp
WriteArrayArrayOp_MutableByteArray :: PrimOp
WriteArrayArrayOp_ArrayArray :: PrimOp
WriteArrayArrayOp_MutableArrayArray :: PrimOp
CopyArrayArrayOp :: PrimOp
CopyMutableArrayArrayOp :: PrimOp
AddrAddOp :: PrimOp
AddrSubOp :: PrimOp
AddrRemOp :: PrimOp
Addr2IntOp :: PrimOp
Int2AddrOp :: PrimOp
AddrGtOp :: PrimOp
AddrGeOp :: PrimOp
AddrEqOp :: PrimOp
AddrNeOp :: PrimOp
AddrLtOp :: PrimOp
AddrLeOp :: PrimOp
IndexOffAddrOp_Char :: PrimOp
IndexOffAddrOp_WideChar :: PrimOp
IndexOffAddrOp_Int :: PrimOp
IndexOffAddrOp_Word :: PrimOp
IndexOffAddrOp_Addr :: PrimOp
IndexOffAddrOp_Float :: PrimOp
IndexOffAddrOp_Double :: PrimOp
IndexOffAddrOp_StablePtr :: PrimOp
IndexOffAddrOp_Int8 :: PrimOp
IndexOffAddrOp_Int16 :: PrimOp
IndexOffAddrOp_Int32 :: PrimOp
IndexOffAddrOp_Int64 :: PrimOp
IndexOffAddrOp_Word8 :: PrimOp
IndexOffAddrOp_Word16 :: PrimOp
IndexOffAddrOp_Word32 :: PrimOp
IndexOffAddrOp_Word64 :: PrimOp
ReadOffAddrOp_Char :: PrimOp
ReadOffAddrOp_WideChar :: PrimOp
ReadOffAddrOp_Int :: PrimOp
ReadOffAddrOp_Word :: PrimOp
ReadOffAddrOp_Addr :: PrimOp
ReadOffAddrOp_Float :: PrimOp
ReadOffAddrOp_Double :: PrimOp
ReadOffAddrOp_StablePtr :: PrimOp
ReadOffAddrOp_Int8 :: PrimOp
ReadOffAddrOp_Int16 :: PrimOp
ReadOffAddrOp_Int32 :: PrimOp
ReadOffAddrOp_Int64 :: PrimOp
ReadOffAddrOp_Word8 :: PrimOp
ReadOffAddrOp_Word16 :: PrimOp
ReadOffAddrOp_Word32 :: PrimOp
ReadOffAddrOp_Word64 :: PrimOp
WriteOffAddrOp_Char :: PrimOp
WriteOffAddrOp_WideChar :: PrimOp
WriteOffAddrOp_Int :: PrimOp
WriteOffAddrOp_Word :: PrimOp
WriteOffAddrOp_Addr :: PrimOp
WriteOffAddrOp_Float :: PrimOp
WriteOffAddrOp_Double :: PrimOp
WriteOffAddrOp_StablePtr :: PrimOp
WriteOffAddrOp_Int8 :: PrimOp
WriteOffAddrOp_Int16 :: PrimOp
WriteOffAddrOp_Int32 :: PrimOp
WriteOffAddrOp_Int64 :: PrimOp
WriteOffAddrOp_Word8 :: PrimOp
WriteOffAddrOp_Word16 :: PrimOp
WriteOffAddrOp_Word32 :: PrimOp
WriteOffAddrOp_Word64 :: PrimOp
NewMutVarOp :: PrimOp
ReadMutVarOp :: PrimOp
WriteMutVarOp :: PrimOp
SameMutVarOp :: PrimOp
AtomicModifyMutVarOp :: PrimOp
CasMutVarOp :: PrimOp
CatchOp :: PrimOp
RaiseOp :: PrimOp
RaiseIOOp :: PrimOp
MaskAsyncExceptionsOp :: PrimOp
MaskUninterruptibleOp :: PrimOp
UnmaskAsyncExceptionsOp :: PrimOp
MaskStatus :: PrimOp
AtomicallyOp :: PrimOp
RetryOp :: PrimOp
CatchRetryOp :: PrimOp
CatchSTMOp :: PrimOp
Check :: PrimOp
NewTVarOp :: PrimOp
ReadTVarOp :: PrimOp
ReadTVarIOOp :: PrimOp
WriteTVarOp :: PrimOp
SameTVarOp :: PrimOp
NewMVarOp :: PrimOp
TakeMVarOp :: PrimOp
TryTakeMVarOp :: PrimOp
PutMVarOp :: PrimOp
TryPutMVarOp :: PrimOp
SameMVarOp :: PrimOp
IsEmptyMVarOp :: PrimOp
DelayOp :: PrimOp
WaitReadOp :: PrimOp
WaitWriteOp :: PrimOp
ForkOp :: PrimOp
ForkOnOp :: PrimOp
KillThreadOp :: PrimOp
YieldOp :: PrimOp
MyThreadIdOp :: PrimOp
LabelThreadOp :: PrimOp
IsCurrentThreadBoundOp :: PrimOp
NoDuplicateOp :: PrimOp
ThreadStatusOp :: PrimOp
MkWeakOp :: PrimOp
MkWeakNoFinalizerOp :: PrimOp
MkWeakForeignEnvOp :: PrimOp
DeRefWeakOp :: PrimOp
FinalizeWeakOp :: PrimOp
TouchOp :: PrimOp
MakeStablePtrOp :: PrimOp
DeRefStablePtrOp :: PrimOp
EqStablePtrOp :: PrimOp
MakeStableNameOp :: PrimOp
EqStableNameOp :: PrimOp
StableNameToIntOp :: PrimOp
ReallyUnsafePtrEqualityOp :: PrimOp
ParOp :: PrimOp
SparkOp :: PrimOp
SeqOp :: PrimOp
GetSparkOp :: PrimOp
NumSparks :: PrimOp
ParGlobalOp :: PrimOp
ParLocalOp :: PrimOp
ParAtOp :: PrimOp
ParAtAbsOp :: PrimOp
ParAtRelOp :: PrimOp
ParAtForNowOp :: PrimOp
DataToTagOp :: PrimOp
TagToEnumOp :: PrimOp
AddrToAnyOp :: PrimOp
MkApUpd0_Op :: PrimOp
NewBCOOp :: PrimOp
UnpackClosureOp :: PrimOp
GetApStackValOp :: PrimOp
GetCCSOfOp :: PrimOp
GetCurrentCCSOp :: PrimOp
TraceEventOp :: PrimOp
allThePrimOps :: [PrimOp]
primOpType :: PrimOp -> Type
primOpSig :: PrimOp -> ([TyVar], [Type], Type, Arity, StrictSig)
primOpTag :: PrimOp -> Int
maxPrimOpTag :: Int
primOpOcc :: PrimOp -> OccName
tagToEnumKey :: Unique
primOpOutOfLine :: PrimOp -> Bool
primOpCodeSize :: PrimOp -> Int
primOpOkForSpeculation :: PrimOp -> Bool
primOpOkForSideEffects :: PrimOp -> Bool
primOpIsCheap :: PrimOp -> Bool
getPrimOpResultInfo :: PrimOp -> PrimOpResultInfo
data PrimOpResultInfo
ReturnsPrim :: PrimRep -> PrimOpResultInfo
ReturnsAlg :: TyCon -> PrimOpResultInfo
data PrimCall
PrimCall :: CLabelString -> PackageId -> PrimCall
instance Outputable PrimCall
instance Outputable PrimOp
instance Ord PrimOp
instance Eq PrimOp


-- | Builtin types and functions used by the vectoriser. These are all
--   defined in <a>Prim</a>.
module Vectorise.Builtins.Base
mAX_DPH_PROD :: Int
mAX_DPH_SUM :: Int
mAX_DPH_COMBINE :: Int
mAX_DPH_SCALAR_ARGS :: Int
aLL_DPH_PRIM_TYCONS :: [Name]

-- | Holds the names of the types and functions from <a>Prim</a> that are
--   used by the vectoriser.
data Builtins
Builtins :: TyCon -> TyCon -> Class -> TyCon -> TyCon -> Class -> TyCon -> DataCon -> Var -> Var -> NameEnv Var -> Var -> NameEnv Var -> Var -> NameEnv Var -> Array Int Var -> Array Int (NameEnv Var) -> Class -> Array Int Var -> TyCon -> Var -> Var -> Array Int TyCon -> TyCon -> Var -> Var -> TyCon -> Var -> Var -> Var -> Var -> Array Int Var -> Array Int Type -> Array Int Type -> Array Int CoreExpr -> Array Int CoreExpr -> Array Int CoreExpr -> Array (Int, Int) CoreExpr -> Var -> Builtins

-- | PData
pdataTyCon :: Builtins -> TyCon

-- | PDatas
pdatasTyCon :: Builtins -> TyCon

-- | PR
prClass :: Builtins -> Class

-- | PR
prTyCon :: Builtins -> TyCon

-- | PRepr
preprTyCon :: Builtins -> TyCon

-- | PA
paClass :: Builtins -> Class

-- | PA
paTyCon :: Builtins -> TyCon

-- | PA
paDataCon :: Builtins -> DataCon

-- | PA
paPRSel :: Builtins -> Var

-- | replicatePD
replicatePDVar :: Builtins -> Var

-- | replicatePD_Int# etc.
replicatePD_PrimVars :: Builtins -> NameEnv Var

-- | emptyPD
emptyPDVar :: Builtins -> Var

-- | emptyPD_Int# etc.
emptyPD_PrimVars :: Builtins -> NameEnv Var

-- | packByTagPD
packByTagPDVar :: Builtins -> Var

-- | packByTagPD_Int# etc.
packByTagPD_PrimVars :: Builtins -> NameEnv Var

-- | combinePD
combinePDVars :: Builtins -> Array Int Var

-- | combine2PD_Int# etc.
combinePD_PrimVarss :: Builtins -> Array Int (NameEnv Var)

-- | Scalar
scalarClass :: Builtins -> Class

-- | map, zipWith, zipWith3
scalarZips :: Builtins -> Array Int Var

-- | Void
voidTyCon :: Builtins -> TyCon

-- | void
voidVar :: Builtins -> Var

-- | fromVoid
fromVoidVar :: Builtins -> Var

-- | Sum2 .. Sum3
sumTyCons :: Builtins -> Array Int TyCon

-- | Wrap
wrapTyCon :: Builtins -> TyCon

-- | pvoid
pvoidVar :: Builtins -> Var

-- | pvoids
pvoidsVar :: Builtins -> Var

-- | :-&gt;
closureTyCon :: Builtins -> TyCon

-- | closure
closureVar :: Builtins -> Var

-- | liftedClosure
liftedClosureVar :: Builtins -> Var

-- | $:
applyVar :: Builtins -> Var

-- | liftedApply
liftedApplyVar :: Builtins -> Var

-- | closure1 .. closure3
closureCtrFuns :: Builtins -> Array Int Var

-- | Sel2
selTys :: Builtins -> Array Int Type

-- | Sels2
selsTys :: Builtins -> Array Int Type

-- | lengthSels2
selsLengths :: Builtins -> Array Int CoreExpr

-- | replicate2
selReplicates :: Builtins -> Array Int CoreExpr

-- | tagsSel2
selTagss :: Builtins -> Array Int CoreExpr

-- | elementsSel2_0 .. elementsSel_2_1
selElementss :: Builtins -> Array (Int, Int) CoreExpr

-- | lc
liftingContext :: Builtins -> Var
selTy :: Int -> Builtins -> Type
selsTy :: Int -> Builtins -> Type
selReplicate :: Int -> Builtins -> CoreExpr
selTags :: Int -> Builtins -> CoreExpr
selElements :: Int -> Int -> Builtins -> CoreExpr
selsLength :: Int -> Builtins -> CoreExpr
sumTyCon :: Int -> Builtins -> TyCon
prodTyCon :: Int -> Builtins -> TyCon
prodDataCon :: Int -> Builtins -> DataCon
replicatePD_PrimVar :: TyCon -> Builtins -> Var
emptyPD_PrimVar :: TyCon -> Builtins -> Var
packByTagPD_PrimVar :: TyCon -> Builtins -> Var
combinePDVar :: Int -> Builtins -> Var
combinePD_PrimVar :: Int -> TyCon -> Builtins -> Var
scalarZip :: Int -> Builtins -> Var
closureCtrFun :: Int -> Builtins -> Var

module Vectorise.Type.Classify
classifyTyCons :: UniqFM Bool -> [TyCon] -> ([TyCon], [TyCon], [TyCon])


-- | A module concerned with finding the free variables of an expression.
module CoreFVs

-- | Find all locally-defined free Ids or type variables in an expression
exprFreeVars :: CoreExpr -> VarSet

-- | Find all locally-defined free Ids in an expression
exprFreeIds :: CoreExpr -> IdSet

-- | Find all locally-defined free Ids or type variables in several
--   expressions
exprsFreeVars :: [CoreExpr] -> VarSet

-- | Find all locally defined free Ids in a binding group
bindFreeVars :: CoreBind -> VarSet

-- | Predicate on possible free variables: returns <tt>True</tt> iff the
--   variable is interesting
type InterestingVarFun = Var -> Bool

-- | Finds free variables in an expression selected by a predicate
exprSomeFreeVars :: InterestingVarFun -> CoreExpr -> VarSet

-- | Finds free variables in several expressions selected by a predicate
exprsSomeFreeVars :: InterestingVarFun -> [CoreExpr] -> VarSet
varTypeTyVars :: Var -> TyVarSet
idUnfoldingVars :: Id -> VarSet
idFreeVars :: Id -> VarSet
idRuleAndUnfoldingVars :: Id -> VarSet
idRuleVars :: Id -> VarSet
idRuleRhsVars :: (Activation -> Bool) -> Id -> VarSet
stableUnfoldingVars :: InterestingVarFun -> Unfolding -> Maybe VarSet

-- | Those variables free in the right hand side of a rule
ruleRhsFreeVars :: CoreRule -> VarSet

-- | Those variables free in the right hand side of several rules
rulesFreeVars :: [CoreRule] -> VarSet

-- | ruleLhsOrphNames is used when deciding whether a rule is an orphan. In
--   particular, suppose that T is defined in this module; we want to avoid
--   declaring that a rule like:
--   
--   <pre>
--   fromIntegral T = fromIntegral_T
--   </pre>
--   
--   is an orphan. Of course it isn't, and declaring it an orphan would
--   make the whole module an orphan module, which is bad.
ruleLhsOrphNames :: CoreRule -> NameSet

-- | This finds all locally-defined free Ids on the left hand side of a
--   rule
ruleLhsFreeIds :: CoreRule -> VarSet

-- | Free variables of a vectorisation declaration
vectsFreeVars :: [CoreVect] -> VarSet

-- | Every node in an expression annotated with its (non-global) free
--   variables, both Ids and TyVars
type CoreExprWithFVs = AnnExpr Id VarSet

-- | Every node in a binding group annotated with its (non-global) free
--   variables, both Ids and TyVars
type CoreBindWithFVs = AnnBind Id VarSet

-- | Annotate a <a>CoreExpr</a> with its (non-global) free type and value
--   variables at every tree node
freeVars :: CoreExpr -> CoreExprWithFVs

-- | Inverse function to <a>freeVars</a>
freeVarsOf :: CoreExprWithFVs -> IdSet

module OptCoercion

-- | optCoercion applies a substitution to a coercion, *and* optimises it
--   to reduce its size
optCoercion :: CvSubst -> Coercion -> NormalCo

module IfaceType
type IfExtName = Name
type IfLclName = FastString
data IfaceType
IfaceTyVar :: IfLclName -> IfaceType
IfaceAppTy :: IfaceType -> IfaceType -> IfaceType
IfaceFunTy :: IfaceType -> IfaceType -> IfaceType
IfaceForAllTy :: IfaceTvBndr -> IfaceType -> IfaceType
IfaceTyConApp :: IfaceTyCon -> [IfaceType] -> IfaceType
IfaceCoConApp :: IfaceCoCon -> [IfaceType] -> IfaceType
IfaceLitTy :: IfaceTyLit -> IfaceType
type IfacePredType = IfaceType
type IfaceKind = IfaceType
newtype IfaceTyCon
IfaceTc :: IfExtName -> IfaceTyCon
ifaceTyConName :: IfaceTyCon -> IfExtName
data IfaceCoCon
IfaceCoAx :: IfExtName -> IfaceCoCon
IfaceReflCo :: IfaceCoCon
IfaceUnsafeCo :: IfaceCoCon
IfaceSymCo :: IfaceCoCon
IfaceTransCo :: IfaceCoCon
IfaceInstCo :: IfaceCoCon
IfaceNthCo :: Int -> IfaceCoCon
data IfaceTyLit
IfaceNumTyLit :: Integer -> IfaceTyLit
IfaceStrTyLit :: FastString -> IfaceTyLit
type IfaceContext = [IfacePredType]
data IfaceBndr
IfaceIdBndr :: {-# UNPACK #-} !IfaceIdBndr -> IfaceBndr
IfaceTvBndr :: {-# UNPACK #-} !IfaceTvBndr -> IfaceBndr
type IfaceTvBndr = (IfLclName, IfaceKind)
type IfaceIdBndr = (IfLclName, IfaceType)
type IfaceCoercion = IfaceType
toIfaceType :: Type -> IfaceType
toIfaceKind :: Type -> IfaceType
toIfaceContext :: ThetaType -> IfaceContext
toIfaceBndr :: Var -> IfaceBndr
toIfaceIdBndr :: Id -> (IfLclName, IfaceType)
toIfaceTvBndrs :: [TyVar] -> [(IfLclName, IfaceType)]
toIfaceTyCon :: TyCon -> IfaceTyCon
toIfaceTyCon_name :: Name -> IfaceTyCon
coToIfaceType :: Coercion -> IfaceType
pprIfaceType :: IfaceType -> SDoc
pprParendIfaceType :: IfaceType -> SDoc
pprIfaceContext :: IfaceContext -> SDoc
pprIfaceIdBndr :: (IfLclName, IfaceType) -> SDoc
pprIfaceTvBndr :: IfaceTvBndr -> SDoc
pprIfaceTvBndrs :: [IfaceTvBndr] -> SDoc
pprIfaceBndrs :: [IfaceBndr] -> SDoc
tOP_PREC :: Int
tYCON_PREC :: Int
noParens :: SDoc -> SDoc
maybeParen :: Int -> Int -> SDoc -> SDoc
pprIfaceForAllPart :: [IfaceTvBndr] -> IfaceContext -> SDoc -> SDoc
instance Outputable IfaceTyLit
instance Outputable IfaceCoCon
instance Outputable IfaceTyCon
instance Outputable IfaceType
instance Outputable IfaceBndr

module TrieMap
data CoreMap a
emptyCoreMap :: CoreMap a
extendCoreMap :: CoreMap a -> CoreExpr -> a -> CoreMap a
lookupCoreMap :: CoreMap a -> CoreExpr -> Maybe a
foldCoreMap :: (a -> b -> b) -> b -> CoreMap a -> b
data TypeMap a
foldTypeMap :: (a -> b -> b) -> b -> TypeMap a -> b
lookupTypeMap_mod :: TyVarEnv a -> (a -> Type) -> Type -> TypeMap b -> Maybe b
data CoercionMap a
data MaybeMap m a
data ListMap m a
class TrieMap m where type family Key m :: *
emptyTM :: TrieMap m => m a
lookupTM :: TrieMap m => Key m -> m b -> Maybe b
alterTM :: TrieMap m => Key m -> XT b -> m b -> m b
foldTM :: TrieMap m => (a -> b -> b) -> m a -> b -> b
instance TrieMap VarMap
instance TrieMap TypeMap
instance Outputable a => Outputable (TypeMap a)
instance TrieMap CoercionMap
instance TrieMap AltMap
instance Outputable a => Outputable (CoreMap a)
instance TrieMap CoreMap
instance TrieMap m => TrieMap (ListMap m)
instance TrieMap m => TrieMap (MaybeMap m)
instance TrieMap UniqFM
instance Ord k => TrieMap (Map k)
instance TrieMap IntMap

module FunDeps
data FDEq
FDEq :: Int -> Type -> Type -> FDEq
fd_pos :: FDEq -> Int
fd_ty_left :: FDEq -> Type
fd_ty_right :: FDEq -> Type
data Equation
FDEqn :: [TyVar] -> [FDEq] -> Pred_Loc -> Pred_Loc -> Equation
fd_qtvs :: Equation -> [TyVar]
fd_eqs :: Equation -> [FDEq]
fd_pred1 :: Equation -> Pred_Loc
fd_pred2 :: Equation -> Pred_Loc
pprEquation :: Equation -> SDoc
oclose :: [PredType] -> TyVarSet -> TyVarSet
improveFromInstEnv :: (InstEnv, InstEnv) -> Pred_Loc -> [Equation]
improveFromAnother :: Pred_Loc -> Pred_Loc -> [Equation]
checkInstCoverage :: Class -> [Type] -> Bool
checkFunDeps :: (InstEnv, InstEnv) -> ClsInst -> Maybe [ClsInst]
pprFundeps :: Outputable a => [FunDep a] -> SDoc
instance Outputable FDEq

module PprCore
pprCoreExpr :: OutputableBndr b => Expr b -> SDoc
pprParendExpr :: OutputableBndr b => Expr b -> SDoc
pprCoreBinding :: OutputableBndr b => Bind b -> SDoc
pprCoreBindings :: OutputableBndr b => [Bind b] -> SDoc
pprCoreAlt :: OutputableBndr a => (AltCon, [a], Expr a) -> SDoc
pprRules :: [CoreRule] -> SDoc
instance Outputable CoreVect
instance Outputable id => Outputable (Tickish id)
instance Outputable CoreRule
instance Outputable e => Outputable (DFunArg e)
instance Outputable Unfolding
instance Outputable UnfoldingSource
instance Outputable UnfoldingGuidance
instance OutputableBndr Var
instance OutputableBndr b => Outputable (Expr b)
instance OutputableBndr b => Outputable (Bind b)


-- | Commonly useful utilites for manipulating the Core language
module CoreUtils

-- | Wrap the given expression in the coercion safely, dropping identity
--   coercions and coalescing nested coercions
mkCast :: CoreExpr -> Coercion -> CoreExpr

-- | Wraps the given expression in the source annotation, dropping the
--   annotation if possible.
mkTick :: Tickish Id -> CoreExpr -> CoreExpr
mkTickNoHNF :: Tickish Id -> CoreExpr -> CoreExpr

-- | <tt>bindNonRec x r b</tt> produces either:
--   
--   <pre>
--   let x = r in b
--   </pre>
--   
--   or:
--   
--   <pre>
--   case r of x { _DEFAULT_ -&gt; b }
--   </pre>
--   
--   depending on whether we have to use a <tt>case</tt> or <tt>let</tt>
--   binding for the expression (see <a>needsCaseBinding</a>). It's used by
--   the desugarer to avoid building bindings that give Core Lint a heart
--   attack, although actually the simplifier deals with them perfectly
--   well. See also <a>mkCoreLet</a>
bindNonRec :: Id -> CoreExpr -> CoreExpr -> CoreExpr

-- | Tests whether we have to use a <tt>case</tt> rather than <tt>let</tt>
--   binding for this expression as per the invariants of <a>CoreExpr</a>:
--   see <a>CoreSyn#let_app_invariant</a>
needsCaseBinding :: Type -> CoreExpr -> Bool

-- | This guy constructs the value that the scrutinee must have given that
--   you are in one particular branch of a case
mkAltExpr :: AltCon -> [CoreBndr] -> [Type] -> CoreExpr

-- | Extract the default case alternative
findDefault :: [(AltCon, [a], b)] -> ([(AltCon, [a], b)], Maybe b)

-- | Find the case alternative corresponding to a particular constructor:
--   panics if no such constructor exists
findAlt :: AltCon -> [(AltCon, a, b)] -> Maybe (AltCon, a, b)
isDefaultAlt :: (AltCon, a, b) -> Bool

-- | Merge alternatives preserving order; alternatives in the first
--   argument shadow ones in the second
mergeAlts :: [(AltCon, a, b)] -> [(AltCon, a, b)] -> [(AltCon, a, b)]

-- | Given:
--   
--   <pre>
--   case (C a b x y) of
--          C b x y -&gt; ...
--   </pre>
--   
--   We want to drop the leading type argument of the scrutinee leaving the
--   arguments to match agains the pattern
trimConArgs :: AltCon -> [CoreArg] -> [CoreArg]
filterAlts :: [Unique] -> Type -> [AltCon] -> [(AltCon, [Var], a)] -> ([AltCon], Bool, [(AltCon, [Var], a)])

-- | Recover the type of a well-typed Core expression. Fails when applied
--   to the actual <a>Type</a> expression as it cannot really be said to
--   have a type
exprType :: CoreExpr -> Type

-- | Returns the type of the alternatives right hand side
coreAltType :: CoreAlt -> Type

-- | Returns the type of the first alternative, which should be the same as
--   for all alternatives
coreAltsType :: [CoreAlt] -> Type
exprIsDupable :: CoreExpr -> Bool
exprIsTrivial :: CoreExpr -> Bool
getIdFromTrivialExpr :: CoreExpr -> Id
exprIsBottom :: CoreExpr -> Bool
exprIsCheap :: CoreExpr -> Bool
exprIsExpandable :: CoreExpr -> Bool
exprIsCheap' :: CheapAppFun -> CoreExpr -> Bool
type CheapAppFun = Id -> Int -> Bool

-- | exprIsHNF returns true for expressions that are certainly
--   <i>already</i> evaluated to <i>head</i> normal form. This is used to
--   decide whether it's ok to change:
--   
--   <pre>
--   case x of _ -&gt; e
--   </pre>
--   
--   into:
--   
--   <pre>
--   e
--   </pre>
--   
--   and to decide whether it's safe to discard a <a>seq</a>.
--   
--   So, it does <i>not</i> treat variables as evaluated, unless they say
--   they are. However, it <i>does</i> treat partial applications and
--   constructor applications as values, even if their arguments are
--   non-trivial, provided the argument type is lifted. For example, both
--   of these are values:
--   
--   <pre>
--   (:) (f x) (map f xs)
--   map (...redex...)
--   </pre>
--   
--   because <a>seq</a> on such things completes immediately.
--   
--   For unlifted argument types, we have to be careful:
--   
--   <pre>
--   C (f x :: Int#)
--   </pre>
--   
--   Suppose <tt>f x</tt> diverges; then <tt>C (f x)</tt> is not a value.
--   However this can't happen: see <a>CoreSyn#let_app_invariant</a>. This
--   invariant states that arguments of unboxed type must be
--   ok-for-speculation (or trivial).
exprIsHNF :: CoreExpr -> Bool

-- | <a>exprOkForSpeculation</a> returns True of an expression that is:
--   
--   <ul>
--   <li>Safe to evaluate even if normal order eval might not evaluate the
--   expression at all, or</li>
--   <li>Safe <i>not</i> to evaluate even if normal order would do so</li>
--   </ul>
--   
--   It is usually called on arguments of unlifted type, but not always In
--   particular, Simplify.rebuildCase calls it on lifted types when a
--   'case' is a plain <a>seq</a>. See the example in Note
--   [exprOkForSpeculation: case expressions] below
--   
--   Precisely, it returns <tt>True</tt> iff:
--   
--   <ul>
--   <li>The expression guarantees to terminate, * soon, * without raising
--   an exception, * without causing a side effect (e.g. writing a mutable
--   variable)</li>
--   </ul>
--   
--   Note that if <tt>exprIsHNF e</tt>, then <tt>exprOkForSpecuation
--   e</tt>. As an example of the considerations in this test, consider:
--   
--   <pre>
--   let x = case y# +# 1# of { r# -&gt; I# r# }
--   in E
--   </pre>
--   
--   being translated to:
--   
--   <pre>
--   case y# +# 1# of { r# -&gt;
--      let x = I# r#
--      in E
--   }
--   </pre>
--   
--   We can only do this if the <tt>y + 1</tt> is ok for speculation: it
--   has no side effects, and can't diverge or raise an exception.
exprOkForSpeculation :: Expr b -> Bool

-- | <a>exprOkForSpeculation</a> returns True of an expression that is:
--   
--   <ul>
--   <li>Safe to evaluate even if normal order eval might not evaluate the
--   expression at all, or</li>
--   <li>Safe <i>not</i> to evaluate even if normal order would do so</li>
--   </ul>
--   
--   It is usually called on arguments of unlifted type, but not always In
--   particular, Simplify.rebuildCase calls it on lifted types when a
--   'case' is a plain <a>seq</a>. See the example in Note
--   [exprOkForSpeculation: case expressions] below
--   
--   Precisely, it returns <tt>True</tt> iff:
--   
--   <ul>
--   <li>The expression guarantees to terminate, * soon, * without raising
--   an exception, * without causing a side effect (e.g. writing a mutable
--   variable)</li>
--   </ul>
--   
--   Note that if <tt>exprIsHNF e</tt>, then <tt>exprOkForSpecuation
--   e</tt>. As an example of the considerations in this test, consider:
--   
--   <pre>
--   let x = case y# +# 1# of { r# -&gt; I# r# }
--   in E
--   </pre>
--   
--   being translated to:
--   
--   <pre>
--   case y# +# 1# of { r# -&gt;
--      let x = I# r#
--      in E
--   }
--   </pre>
--   
--   We can only do this if the <tt>y + 1</tt> is ok for speculation: it
--   has no side effects, and can't diverge or raise an exception.
exprOkForSideEffects :: Expr b -> Bool
exprIsWorkFree :: CoreExpr -> Bool

-- | Returns <tt>True</tt> of expressions that are too big to be compared
--   by <a>cheapEqExpr</a>
exprIsBig :: Expr b -> Bool

-- | Similar to <a>exprIsHNF</a> but includes CONLIKE functions as well as
--   data constructors. Conlike arguments are considered interesting by the
--   inliner.
exprIsConLike :: CoreExpr -> Bool

-- | This function is called only on *top-level* right-hand sides. Returns
--   <tt>True</tt> if the RHS can be allocated statically in the output,
--   with no thunks involved at all.
rhsIsStatic :: (Name -> Bool) -> CoreExpr -> Bool
isCheapApp :: CheapAppFun
isExpandableApp :: CheapAppFun
coreBindsSize :: [CoreBind] -> Int

-- | A measure of the size of the expressions, strictly greater than 0 It
--   also forces the expression pretty drastically as a side effect Counts
--   *leaves*, not internal nodes. Types and coercions are not counted.
exprSize :: CoreExpr -> Int
data CoreStats
CS :: Int -> Int -> Int -> CoreStats
cs_tm :: CoreStats -> Int
cs_ty :: CoreStats -> Int
cs_co :: CoreStats -> Int
coreBindsStats :: [CoreBind] -> CoreStats

-- | Two expressions that hash to the same <tt>Int</tt> may be equal (but
--   may not be) Two expressions that hash to the different Ints are
--   definitely unequal.
--   
--   The emphasis is on a crude, fast hash, rather than on high precision.
--   
--   But unequal here means "not identical"; two alpha-equivalent
--   expressions may hash to the different Ints.
--   
--   We must be careful that <tt>\x.x</tt> and <tt>\y.y</tt> map to the
--   same hash code, (at least if we want the above invariant to be true).
hashExpr :: CoreExpr -> Int

-- | A cheap equality test which bales out fast! If it returns
--   <tt>True</tt> the arguments are definitely equal, otherwise, they may
--   or may not be equal.
--   
--   See also <a>exprIsBig</a>
cheapEqExpr :: Expr b -> Expr b -> Bool
eqExpr :: InScopeSet -> CoreExpr -> CoreExpr -> Bool

-- | Compares expressions for equality, modulo alpha. Does <i>not</i> look
--   through newtypes or predicate types Used in rule matching, and also
--   CSE
eqExprX :: IdUnfoldingFun -> RnEnv2 -> CoreExpr -> CoreExpr -> Bool
tryEtaReduce :: [Var] -> CoreExpr -> Maybe CoreExpr

-- | A more efficient version of <a>applyTypeToArg</a> when we have several
--   arguments. The first argument is just for debugging, and gives some
--   context
applyTypeToArgs :: CoreExpr -> Type -> [CoreExpr] -> Type

-- | Determines the type resulting from applying an expression to a
--   function with the given type
applyTypeToArg :: Type -> CoreExpr -> Type
dataConRepInstPat :: [Unique] -> DataCon -> [Type] -> ([TyVar], [Id])
dataConRepFSInstPat :: [FastString] -> [Unique] -> DataCon -> [Type] -> ([TyVar], [Id])
instance Outputable CoreStats

module OccurAnal
occurAnalysePgm :: Module -> (Activation -> Bool) -> [CoreRule] -> [CoreVect] -> CoreProgram -> CoreProgram
occurAnalyseExpr :: CoreExpr -> CoreExpr
instance Outputable OccEncl
instance Outputable Details

module SAT
doStaticArgs :: UniqSupply -> CoreProgram -> CoreProgram

module TcEvidence
data HsWrapper
WpHole :: HsWrapper
WpCompose :: HsWrapper -> HsWrapper -> HsWrapper
WpCast :: TcCoercion -> HsWrapper
WpEvLam :: EvVar -> HsWrapper
WpEvApp :: EvTerm -> HsWrapper
WpTyLam :: TyVar -> HsWrapper
WpTyApp :: KindOrType -> HsWrapper
WpLet :: TcEvBinds -> HsWrapper
(<.>) :: HsWrapper -> HsWrapper -> HsWrapper
mkWpTyApps :: [Type] -> HsWrapper
mkWpEvApps :: [EvTerm] -> HsWrapper
mkWpEvVarApps :: [EvVar] -> HsWrapper
mkWpTyLams :: [TyVar] -> HsWrapper
mkWpLams :: [Var] -> HsWrapper
mkWpLet :: TcEvBinds -> HsWrapper
idHsWrapper :: HsWrapper
isIdHsWrapper :: HsWrapper -> Bool
pprHsWrapper :: SDoc -> HsWrapper -> SDoc
data TcEvBinds
TcEvBinds :: EvBindsVar -> TcEvBinds
EvBinds :: (Bag EvBind) -> TcEvBinds
data EvBindsVar
EvBindsVar :: (IORef EvBindMap) -> Unique -> EvBindsVar
newtype EvBindMap
EvBindMap :: VarEnv EvBind -> EvBindMap
ev_bind_varenv :: EvBindMap -> VarEnv EvBind
emptyEvBindMap :: EvBindMap
extendEvBinds :: EvBindMap -> EvVar -> EvTerm -> EvBindMap
lookupEvBind :: EvBindMap -> EvVar -> Maybe EvBind
evBindMapBinds :: EvBindMap -> Bag EvBind
data EvBind
EvBind :: EvVar -> EvTerm -> EvBind
emptyTcEvBinds :: TcEvBinds
isEmptyTcEvBinds :: TcEvBinds -> Bool
data EvTerm
EvId :: EvId -> EvTerm
EvCoercion :: TcCoercion -> EvTerm
EvCast :: EvTerm -> TcCoercion -> EvTerm
EvDFunApp :: DFunId -> [Type] -> [EvTerm] -> EvTerm
EvTupleSel :: EvTerm -> Int -> EvTerm
EvTupleMk :: [EvTerm] -> EvTerm
EvDelayedError :: Type -> FastString -> EvTerm
EvSuperClass :: EvTerm -> Int -> EvTerm
EvKindCast :: EvTerm -> TcCoercion -> EvTerm
EvLit :: EvLit -> EvTerm
mkEvCast :: EvTerm -> TcCoercion -> EvTerm
evVarsOfTerm :: EvTerm -> VarSet
mkEvKindCast :: EvTerm -> TcCoercion -> EvTerm
data EvLit
EvNum :: Integer -> EvLit
EvStr :: FastString -> EvLit
evTermCoercion :: EvTerm -> TcCoercion
data TcCoercion
TcRefl :: TcType -> TcCoercion
TcTyConAppCo :: TyCon -> [TcCoercion] -> TcCoercion
TcAppCo :: TcCoercion -> TcCoercion -> TcCoercion
TcForAllCo :: TyVar -> TcCoercion -> TcCoercion
TcInstCo :: TcCoercion -> TcType -> TcCoercion
TcCoVarCo :: EqVar -> TcCoercion
TcAxiomInstCo :: CoAxiom -> [TcType] -> TcCoercion
TcSymCo :: TcCoercion -> TcCoercion
TcTransCo :: TcCoercion -> TcCoercion -> TcCoercion
TcNthCo :: Int -> TcCoercion -> TcCoercion
TcCastCo :: TcCoercion -> TcCoercion -> TcCoercion
TcLetCo :: TcEvBinds -> TcCoercion -> TcCoercion
mkTcReflCo :: TcType -> TcCoercion
mkTcTyConAppCo :: TyCon -> [TcCoercion] -> TcCoercion
mkTcAppCo :: TcCoercion -> TcCoercion -> TcCoercion
mkTcAppCos :: TcCoercion -> [TcCoercion] -> TcCoercion
mkTcFunCo :: TcCoercion -> TcCoercion -> TcCoercion
mkTcAxInstCo :: CoAxiom -> [TcType] -> TcCoercion
mkTcForAllCo :: Var -> TcCoercion -> TcCoercion
mkTcForAllCos :: [Var] -> TcCoercion -> TcCoercion
mkTcSymCo :: TcCoercion -> TcCoercion
mkTcTransCo :: TcCoercion -> TcCoercion -> TcCoercion
mkTcNthCo :: Int -> TcCoercion -> TcCoercion
mkTcInstCos :: TcCoercion -> [TcType] -> TcCoercion
tcCoercionKind :: TcCoercion -> Pair Type
coVarsOfTcCo :: TcCoercion -> VarSet
isEqVar :: Var -> Bool
mkTcCoVarCo :: EqVar -> TcCoercion
isTcReflCo :: TcCoercion -> Bool
isTcReflCo_maybe :: TcCoercion -> Maybe TcType
getTcCoVar_maybe :: TcCoercion -> Maybe CoVar
liftTcCoSubstWith :: [TyVar] -> [TcCoercion] -> TcType -> TcCoercion
instance Typeable EvLit
instance Typeable EvTerm
instance Typeable TcCoercion
instance Typeable TcEvBinds
instance Typeable HsWrapper
instance Data EvLit
instance Data EvTerm
instance Data TcCoercion
instance Data HsWrapper
instance Outputable EvLit
instance Outputable EvTerm
instance Outputable EvBind
instance Outputable EvBindsVar
instance Outputable TcEvBinds
instance Outputable HsWrapper
instance Data TcEvBinds
instance Outputable TcCoercion

module CoreLint
lintCoreBindings :: CoreProgram -> (Bag MsgDoc, Bag MsgDoc)
lintUnfolding :: SrcLoc -> [Var] -> CoreExpr -> Maybe MsgDoc
instance Monad LintM

module HsBinds
type HsLocalBinds id = HsLocalBindsLR id id
data HsLocalBindsLR idL idR
HsValBinds :: (HsValBindsLR idL idR) -> HsLocalBindsLR idL idR
HsIPBinds :: (HsIPBinds idR) -> HsLocalBindsLR idL idR
EmptyLocalBinds :: HsLocalBindsLR idL idR
type HsValBinds id = HsValBindsLR id id
data HsValBindsLR idL idR
ValBindsIn :: (LHsBindsLR idL idR) -> [LSig idR] -> HsValBindsLR idL idR
ValBindsOut :: [(RecFlag, LHsBinds idL)] -> [LSig Name] -> HsValBindsLR idL idR
type LHsBind id = LHsBindLR id id
type LHsBinds id = LHsBindsLR id id
type HsBind id = HsBindLR id id
type LHsBindsLR idL idR = Bag (LHsBindLR idL idR)
type LHsBindLR idL idR = Located (HsBindLR idL idR)
data HsBindLR idL idR

-- | FunBind is used for both functions <tt>f x = e</tt> and variables
--   <tt>f = x -&gt; e</tt>
--   
--   Reason 1: Special case for type inference: see <a>tcMonoBinds</a>.
--   
--   Reason 2: Instance decls can only have FunBinds, which is convenient.
--   If you change this, you'll need to change e.g. rnMethodBinds
--   
--   But note that the form <tt>f :: a-&gt;a = ...</tt> parses as a pattern
--   binding, just like <tt>(f :: a -&gt; a) = ... </tt>
FunBind :: Located idL -> Bool -> MatchGroup idR -> HsWrapper -> NameSet -> Maybe (Tickish Id) -> HsBindLR idL idR
fun_id :: HsBindLR idL idR -> Located idL

-- | True =&gt; infix declaration
fun_infix :: HsBindLR idL idR -> Bool

-- | The payload
fun_matches :: HsBindLR idL idR -> MatchGroup idR

-- | Coercion from the type of the MatchGroup to the type of the Id.
--   Example: <tt> f :: Int -&gt; forall a. a -&gt; a f x y = y </tt> Then
--   the MatchGroup will have type (Int -&gt; a' -&gt; a') (with a free
--   type variable a'). The coercion will take a CoreExpr of this type and
--   convert it to a CoreExpr of type Int -&gt; forall a'. a' -&gt; a'
--   Notice that the coercion captures the free a'.
fun_co_fn :: HsBindLR idL idR -> HsWrapper

-- | After the renamer, this contains the locally-bound free variables of
--   this defn. See Note [Bind free vars]
bind_fvs :: HsBindLR idL idR -> NameSet

-- | Tick to put on the rhs, if any
fun_tick :: HsBindLR idL idR -> Maybe (Tickish Id)
PatBind :: LPat idL -> GRHSs idR -> PostTcType -> NameSet -> (Maybe (Tickish Id), [Maybe (Tickish Id)]) -> HsBindLR idL idR
pat_lhs :: HsBindLR idL idR -> LPat idL
pat_rhs :: HsBindLR idL idR -> GRHSs idR
pat_rhs_ty :: HsBindLR idL idR -> PostTcType

-- | After the renamer, this contains the locally-bound free variables of
--   this defn. See Note [Bind free vars]
bind_fvs :: HsBindLR idL idR -> NameSet

-- | Tick to put on the rhs, if any, and ticks to put on the bound
--   variables.
pat_ticks :: HsBindLR idL idR -> (Maybe (Tickish Id), [Maybe (Tickish Id)])
VarBind :: idL -> LHsExpr idR -> Bool -> HsBindLR idL idR
var_id :: HsBindLR idL idR -> idL
var_rhs :: HsBindLR idL idR -> LHsExpr idR
var_inline :: HsBindLR idL idR -> Bool
AbsBinds :: [TyVar] -> [EvVar] -> [ABExport idL] -> TcEvBinds -> LHsBinds idL -> HsBindLR idL idR
abs_tvs :: HsBindLR idL idR -> [TyVar]
abs_ev_vars :: HsBindLR idL idR -> [EvVar]
abs_exports :: HsBindLR idL idR -> [ABExport idL]
abs_ev_binds :: HsBindLR idL idR -> TcEvBinds
abs_binds :: HsBindLR idL idR -> LHsBinds idL
data ABExport id
ABE :: id -> id -> HsWrapper -> TcSpecPrags -> ABExport id
abe_poly :: ABExport id -> id
abe_mono :: ABExport id -> id
abe_wrap :: ABExport id -> HsWrapper
abe_prags :: ABExport id -> TcSpecPrags
placeHolderNames :: NameSet
pprLHsBinds :: (OutputableBndr idL, OutputableBndr idR) => LHsBindsLR idL idR -> SDoc
pprLHsBindsForUser :: (OutputableBndr idL, OutputableBndr idR, OutputableBndr id2) => LHsBindsLR idL idR -> [LSig id2] -> [SDoc]
pprDeclList :: [SDoc] -> SDoc
emptyLocalBinds :: HsLocalBindsLR a b
isEmptyLocalBinds :: HsLocalBindsLR a b -> Bool
isEmptyValBinds :: HsValBindsLR a b -> Bool
emptyValBindsIn :: HsValBindsLR a b
emptyValBindsOut :: HsValBindsLR a b
emptyLHsBinds :: LHsBindsLR idL idR
isEmptyLHsBinds :: LHsBindsLR idL idR -> Bool
plusHsValBinds :: HsValBinds a -> HsValBinds a -> HsValBinds a
getTypeSigNames :: HsValBinds a -> NameSet
ppr_monobind :: (OutputableBndr idL, OutputableBndr idR) => HsBindLR idL idR -> SDoc
pprTicks :: SDoc -> SDoc -> SDoc
data HsIPBinds id
IPBinds :: [LIPBind id] -> TcEvBinds -> HsIPBinds id
isEmptyIPBinds :: HsIPBinds id -> Bool
type LIPBind id = Located (IPBind id)

-- | Implicit parameter bindings.
data IPBind id
IPBind :: (Either HsIPName id) -> (LHsExpr id) -> IPBind id
type LSig name = Located (Sig name)
data Sig name
TypeSig :: [Located name] -> (LHsType name) -> Sig name
GenericSig :: [Located name] -> (LHsType name) -> Sig name
IdSig :: Id -> Sig name
FixSig :: (FixitySig name) -> Sig name
InlineSig :: (Located name) -> InlinePragma -> Sig name
SpecSig :: (Located name) -> (LHsType name) -> InlinePragma -> Sig name
SpecInstSig :: (LHsType name) -> Sig name
type LFixitySig name = Located (FixitySig name)
data FixitySig name
FixitySig :: (Located name) -> Fixity -> FixitySig name
data TcSpecPrags
IsDefaultMethod :: TcSpecPrags
SpecPrags :: [LTcSpecPrag] -> TcSpecPrags
type LTcSpecPrag = Located TcSpecPrag
data TcSpecPrag
SpecPrag :: Id -> HsWrapper -> InlinePragma -> TcSpecPrag
noSpecPrags :: TcSpecPrags
hasSpecPrags :: TcSpecPrags -> Bool
isDefaultMethod :: TcSpecPrags -> Bool
isFixityLSig :: LSig name -> Bool
isVanillaLSig :: LSig name -> Bool
isTypeLSig :: LSig name -> Bool
isSpecLSig :: LSig name -> Bool
isSpecInstLSig :: LSig name -> Bool
isPragLSig :: LSig name -> Bool
isInlineLSig :: LSig name -> Bool
hsSigDoc :: Sig name -> SDoc
ppr_sig :: OutputableBndr name => Sig name -> SDoc
pragBrackets :: SDoc -> SDoc
pprVarSig :: Outputable id => [id] -> SDoc -> SDoc
pprSpec :: Outputable id => id -> SDoc -> InlinePragma -> SDoc
pprTcSpecPrags :: TcSpecPrags -> SDoc
instance Typeable1 IPBind
instance Typeable1 HsIPBinds
instance Typeable1 FixitySig
instance Typeable1 Sig
instance Typeable TcSpecPrag
instance Typeable TcSpecPrags
instance Typeable1 ABExport
instance Typeable2 HsBindLR
instance Typeable2 HsValBindsLR
instance Typeable2 HsLocalBindsLR
instance Data id => Data (IPBind id)
instance Data id => Data (HsIPBinds id)
instance Data name => Data (FixitySig name)
instance Data name => Data (Sig name)
instance Data TcSpecPrag
instance Data TcSpecPrags
instance Data id => Data (ABExport id)
instance (Data idL, Data idR) => Data (HsBindLR idL idR)
instance (Data idL, Data idR) => Data (HsValBindsLR idL idR)
instance (Data idL, Data idR) => Data (HsLocalBindsLR idL idR)
instance Outputable TcSpecPrag
instance Outputable name => Outputable (FixitySig name)
instance OutputableBndr name => Outputable (Sig name)
instance OutputableBndr id => Outputable (IPBind id)
instance OutputableBndr id => Outputable (HsIPBinds id)
instance OutputableBndr id => Outputable (ABExport id)
instance (OutputableBndr idL, OutputableBndr idR) => Outputable (HsBindLR idL idR)
instance (OutputableBndr idL, OutputableBndr idR) => Outputable (HsValBindsLR idL idR)
instance (OutputableBndr idL, OutputableBndr idR) => Outputable (HsLocalBindsLR idL idR)

module HsPat
data Pat id
WildPat :: PostTcType -> Pat id
VarPat :: id -> Pat id
LazyPat :: (LPat id) -> Pat id
AsPat :: (Located id) -> (LPat id) -> Pat id
ParPat :: (LPat id) -> Pat id
BangPat :: (LPat id) -> Pat id
ListPat :: [LPat id] -> PostTcType -> Pat id
TuplePat :: [LPat id] -> Boxity -> PostTcType -> Pat id
PArrPat :: [LPat id] -> PostTcType -> Pat id
ConPatIn :: (Located id) -> (HsConPatDetails id) -> Pat id
ConPatOut :: Located DataCon -> [TyVar] -> [EvVar] -> TcEvBinds -> HsConPatDetails id -> Type -> Pat id
pat_con :: Pat id -> Located DataCon
pat_tvs :: Pat id -> [TyVar]
pat_dicts :: Pat id -> [EvVar]
pat_binds :: Pat id -> TcEvBinds
pat_args :: Pat id -> HsConPatDetails id
pat_ty :: Pat id -> Type
ViewPat :: (LHsExpr id) -> (LPat id) -> PostTcType -> Pat id
QuasiQuotePat :: (HsQuasiQuote id) -> Pat id
LitPat :: HsLit -> Pat id
NPat :: (HsOverLit id) -> (Maybe (SyntaxExpr id)) -> (SyntaxExpr id) -> Pat id
NPlusKPat :: (Located id) -> (HsOverLit id) -> (SyntaxExpr id) -> (SyntaxExpr id) -> Pat id
SigPatIn :: (LPat id) -> (HsWithBndrs (LHsType id)) -> Pat id
SigPatOut :: (LPat id) -> Type -> Pat id
CoPat :: HsWrapper -> (Pat id) -> Type -> Pat id
type InPat id = LPat id
type OutPat id = LPat id
type LPat id = Located (Pat id)
data HsConDetails arg rec
PrefixCon :: [arg] -> HsConDetails arg rec
RecCon :: rec -> HsConDetails arg rec
InfixCon :: arg -> arg -> HsConDetails arg rec
type HsConPatDetails id = HsConDetails (LPat id) (HsRecFields id (LPat id))
hsConPatArgs :: HsConPatDetails id -> [LPat id]
data HsRecFields id arg
HsRecFields :: [HsRecField id arg] -> Maybe Int -> HsRecFields id arg
rec_flds :: HsRecFields id arg -> [HsRecField id arg]
rec_dotdot :: HsRecFields id arg -> Maybe Int
data HsRecField id arg
HsRecField :: Located id -> arg -> Bool -> HsRecField id arg
hsRecFieldId :: HsRecField id arg -> Located id
hsRecFieldArg :: HsRecField id arg -> arg
hsRecPun :: HsRecField id arg -> Bool
hsRecFields :: HsRecFields id arg -> [id]
mkPrefixConPat :: DataCon -> [OutPat id] -> Type -> OutPat id
mkCharLitPat :: Char -> OutPat id
mkNilPat :: Type -> OutPat id
isBangHsBind :: HsBind id -> Bool
isLiftedPatBind :: HsBind id -> Bool
isBangLPat :: LPat id -> Bool
hsPatNeedsParens :: Pat a -> Bool
isIrrefutableHsPat :: OutputableBndr id => LPat id -> Bool
pprParendLPat :: OutputableBndr name => LPat name -> SDoc
instance Typeable2 HsConDetails
instance Typeable1 Pat
instance Typeable2 HsRecFields
instance Typeable2 HsRecField
instance (Data arg, Data rec) => Data (HsConDetails arg rec)
instance Data id => Data (Pat id)
instance (Data id, Data arg) => Data (HsRecFields id arg)
instance (Data id, Data arg) => Data (HsRecField id arg)
instance (OutputableBndr id, Outputable arg) => Outputable (HsRecField id arg)
instance (OutputableBndr id, Outputable arg) => Outputable (HsRecFields id arg)
instance OutputableBndr name => Outputable (Pat name)


-- | Abstract syntax of global declarations.
--   
--   Definitions for: <tt>TyDecl</tt> and <tt>ConDecl</tt>,
--   <tt>ClassDecl</tt>, <tt>InstDecl</tt>, <tt>DefaultDecl</tt> and
--   <tt>ForeignDecl</tt>.
module HsDecls

-- | A Haskell Declaration
data HsDecl id

-- | A type or class declaration.
TyClD :: (TyClDecl id) -> HsDecl id

-- | An instance declaration.
InstD :: (InstDecl id) -> HsDecl id
DerivD :: (DerivDecl id) -> HsDecl id
ValD :: (HsBind id) -> HsDecl id
SigD :: (Sig id) -> HsDecl id
DefD :: (DefaultDecl id) -> HsDecl id
ForD :: (ForeignDecl id) -> HsDecl id
WarningD :: (WarnDecl id) -> HsDecl id
AnnD :: (AnnDecl id) -> HsDecl id
RuleD :: (RuleDecl id) -> HsDecl id
VectD :: (VectDecl id) -> HsDecl id
SpliceD :: (SpliceDecl id) -> HsDecl id
DocD :: (DocDecl) -> HsDecl id
QuasiQuoteD :: (HsQuasiQuote id) -> HsDecl id
type LHsDecl id = Located (HsDecl id)
data HsTyDefn name

-- | Synonym expansion
TySynonym :: LHsType name -> HsTyDefn name
td_synRhs :: HsTyDefn name -> LHsType name

-- | Declares a data type or newtype, giving its construcors <tt>
--   data/newtype T a = <a>constrs</a> data/newtype instance T [a] =
--   <a>constrs</a> </tt>
TyData :: NewOrData -> LHsContext name -> Maybe CType -> Maybe (LHsKind name) -> [LConDecl name] -> Maybe [LHsType name] -> HsTyDefn name
td_ND :: HsTyDefn name -> NewOrData

-- | Context
td_ctxt :: HsTyDefn name -> LHsContext name
td_cType :: HsTyDefn name -> Maybe CType

-- | Optional kind signature.
--   
--   <tt>(Just k)</tt> for a GADT-style <tt>data</tt>, or <tt>data
--   instance</tt> decl, with explicit kind sig
--   
--   Always <tt>Nothing</tt> for H98-syntax decls
td_kindSig :: HsTyDefn name -> Maybe (LHsKind name)

-- | Data constructors
--   
--   For <tt>data T a = T1 | T2 a</tt> the <a>LConDecl</a>s all have
--   <a>ResTyH98</a>. For <tt>data T a where { T1 :: T a }</tt> the
--   <tt>LConDecls</tt> all have <a>ResTyGADT</a>.
td_cons :: HsTyDefn name -> [LConDecl name]

-- | Derivings; <tt>Nothing</tt> =&gt; not specified, <tt>Just []</tt>
--   =&gt; derive exactly what is asked
--   
--   These <a>types</a> must be of form <tt> forall ab. C ty1 ty2 </tt>
--   Typically the foralls and ty args are empty, but they are non-empty
--   for the newtype-deriving case
td_derivs :: HsTyDefn name -> Maybe [LHsType name]

-- | A type or class declaration.
data TyClDecl name
ForeignType :: Located name -> Maybe FastString -> TyClDecl name

-- | Name of the class
--   
--   Type constructor
tcdLName :: TyClDecl name -> Located name
tcdExtName :: TyClDecl name -> Maybe FastString

-- | <pre>
--   type/data family T :: *-&gt;*
--   </pre>
TyFamily :: FamilyFlavour -> Located name -> LHsTyVarBndrs name -> Maybe (LHsKind name) -> TyClDecl name
tcdFlavour :: TyClDecl name -> FamilyFlavour

-- | Name of the class
--   
--   Type constructor
tcdLName :: TyClDecl name -> Located name

-- | Class type variables
--   
--   Type variables; for an associated type these include outer binders Eg
--   class T a where type F a :: * type F a = a -&gt; a Here the type decl
--   for <tt>f</tt> includes <tt>a</tt> in its tcdTyVars
tcdTyVars :: TyClDecl name -> LHsTyVarBndrs name
tcdKindSig :: TyClDecl name -> Maybe (LHsKind name)
TyDecl :: Located name -> LHsTyVarBndrs name -> HsTyDefn name -> NameSet -> TyClDecl name

-- | Name of the class
--   
--   Type constructor
tcdLName :: TyClDecl name -> Located name

-- | Class type variables
--   
--   Type variables; for an associated type these include outer binders Eg
--   class T a where type F a :: * type F a = a -&gt; a Here the type decl
--   for <tt>f</tt> includes <tt>a</tt> in its tcdTyVars
tcdTyVars :: TyClDecl name -> LHsTyVarBndrs name
tcdTyDefn :: TyClDecl name -> HsTyDefn name
tcdFVs :: TyClDecl name -> NameSet
ClassDecl :: LHsContext name -> Located name -> LHsTyVarBndrs name -> [Located (FunDep name)] -> [LSig name] -> LHsBinds name -> [LTyClDecl name] -> [LFamInstDecl name] -> [LDocDecl] -> NameSet -> TyClDecl name

-- | Context...
tcdCtxt :: TyClDecl name -> LHsContext name

-- | Name of the class
--   
--   Type constructor
tcdLName :: TyClDecl name -> Located name

-- | Class type variables
--   
--   Type variables; for an associated type these include outer binders Eg
--   class T a where type F a :: * type F a = a -&gt; a Here the type decl
--   for <tt>f</tt> includes <tt>a</tt> in its tcdTyVars
tcdTyVars :: TyClDecl name -> LHsTyVarBndrs name

-- | Functional deps
tcdFDs :: TyClDecl name -> [Located (FunDep name)]

-- | Methods' signatures
tcdSigs :: TyClDecl name -> [LSig name]

-- | Default methods
tcdMeths :: TyClDecl name -> LHsBinds name

-- | Associated types; ie only <a>TyFamily</a>
tcdATs :: TyClDecl name -> [LTyClDecl name]

-- | Associated type defaults; ie only <a>TySynonym</a>
tcdATDefs :: TyClDecl name -> [LFamInstDecl name]

-- | Haddock docs
tcdDocs :: TyClDecl name -> [LDocDecl]
tcdFVs :: TyClDecl name -> NameSet
type LTyClDecl name = Located (TyClDecl name)
type TyClGroup name = [LTyClDecl name]

-- | type class
isClassDecl :: TyClDecl name -> Bool

-- | <tt>True</tt> <a>=</a> argument is a <tt>data</tt>/<tt>newtype</tt>
--   declaration.
isDataDecl :: TyClDecl name -> Bool

-- | type or type instance declaration
isSynDecl :: TyClDecl name -> Bool

-- | type family declaration
isFamilyDecl :: TyClDecl name -> Bool
isHsDataDefn :: HsTyDefn name -> Bool
isHsSynDefn :: HsTyDefn name -> Bool
tcdName :: TyClDecl name -> name
famInstDeclName :: LFamInstDecl a -> a
countTyClDecls :: [TyClDecl name] -> (Int, Int, Int, Int, Int)
pprTyDefnFlavour :: HsTyDefn a -> SDoc
pprTyClDeclFlavour :: TyClDecl a -> SDoc
data InstDecl name
ClsInstD :: LHsType name -> LHsBinds name -> [LSig name] -> [LFamInstDecl name] -> InstDecl name
cid_poly_ty :: InstDecl name -> LHsType name
cid_binds :: InstDecl name -> LHsBinds name
cid_sigs :: InstDecl name -> [LSig name]
cid_fam_insts :: InstDecl name -> [LFamInstDecl name]
FamInstD :: FamInstDecl name -> InstDecl name
lid_inst :: InstDecl name -> FamInstDecl name
type LInstDecl name = Located (InstDecl name)
data NewOrData

-- | <pre>
--   newtype Blah ...
--   </pre>
NewType :: NewOrData

-- | <pre>
--   data Blah ...
--   </pre>
DataType :: NewOrData
data FamilyFlavour

-- | <pre>
--   type family ...
--   </pre>
TypeFamily :: FamilyFlavour

-- | <pre>
--   data family ...
--   </pre>
DataFamily :: FamilyFlavour
data FamInstDecl name
FamInstDecl :: Located name -> HsWithBndrs [LHsType name] -> HsTyDefn name -> NameSet -> FamInstDecl name
fid_tycon :: FamInstDecl name -> Located name

-- | Type patterns (with kind and type bndrs) See Note [Family instance
--   declaration binders]
fid_pats :: FamInstDecl name -> HsWithBndrs [LHsType name]
fid_defn :: FamInstDecl name -> HsTyDefn name
fid_fvs :: FamInstDecl name -> NameSet
type LFamInstDecl name = Located (FamInstDecl name)
instDeclFamInsts :: [LInstDecl name] -> [FamInstDecl name]
data DerivDecl name
DerivDecl :: LHsType name -> DerivDecl name
deriv_type :: DerivDecl name -> LHsType name
type LDerivDecl name = Located (DerivDecl name)
data RuleDecl name
HsRule :: RuleName -> Activation -> [RuleBndr name] -> (Located (HsExpr name)) -> NameSet -> (Located (HsExpr name)) -> NameSet -> RuleDecl name
type LRuleDecl name = Located (RuleDecl name)
data RuleBndr name
RuleBndr :: (Located name) -> RuleBndr name
RuleBndrSig :: (Located name) -> (HsWithBndrs (LHsType name)) -> RuleBndr name
collectRuleBndrSigTys :: [RuleBndr name] -> [HsWithBndrs (LHsType name)]
data VectDecl name
HsVect :: (Located name) -> (Maybe (LHsExpr name)) -> VectDecl name
HsNoVect :: (Located name) -> VectDecl name
HsVectTypeIn :: Bool -> (Located name) -> (Maybe (Located name)) -> VectDecl name
HsVectTypeOut :: Bool -> TyCon -> (Maybe TyCon) -> VectDecl name
HsVectClassIn :: (Located name) -> VectDecl name
HsVectClassOut :: Class -> VectDecl name
HsVectInstIn :: (LHsType name) -> VectDecl name
HsVectInstOut :: ClsInst -> VectDecl name
type LVectDecl name = Located (VectDecl name)
lvectDeclName :: NamedThing name => LVectDecl name -> Name
lvectInstDecl :: LVectDecl name -> Bool
data DefaultDecl name
DefaultDecl :: [LHsType name] -> DefaultDecl name
type LDefaultDecl name = Located (DefaultDecl name)
data SpliceDecl id
SpliceDecl :: (Located (HsExpr id)) -> HsExplicitFlag -> SpliceDecl id
data ForeignDecl name
ForeignImport :: (Located name) -> (LHsType name) -> Coercion -> ForeignImport -> ForeignDecl name
ForeignExport :: (Located name) -> (LHsType name) -> Coercion -> ForeignExport -> ForeignDecl name
type LForeignDecl name = Located (ForeignDecl name)
data ForeignImport
CImport :: CCallConv -> Safety -> (Maybe Header) -> CImportSpec -> ForeignImport
data ForeignExport
CExport :: CExportSpec -> ForeignExport
noForeignImportCoercionYet :: Coercion
noForeignExportCoercionYet :: Coercion
data CImportSpec
CLabel :: CLabelString -> CImportSpec
CFunction :: CCallTarget -> CImportSpec
CWrapper :: CImportSpec
data ConDecl name
ConDecl :: Located name -> HsExplicitFlag -> LHsTyVarBndrs name -> LHsContext name -> HsConDeclDetails name -> ResType (LHsType name) -> Maybe LHsDocString -> Bool -> ConDecl name

-- | Constructor name. This is used for the DataCon itself, and for the
--   user-callable wrapper Id.
con_name :: ConDecl name -> Located name

-- | Is there an user-written forall? (cf. <a>HsForAllTy</a>)
con_explicit :: ConDecl name -> HsExplicitFlag

-- | Type variables. Depending on <a>con_res</a> this describes the
--   following entities
--   
--   <ul>
--   <li>ResTyH98: the constructor's *existential* type variables -
--   ResTyGADT: *all* the constructor's quantified type variables</li>
--   </ul>
--   
--   If con_explicit is Implicit, then con_qvars is irrelevant until after
--   renaming.
con_qvars :: ConDecl name -> LHsTyVarBndrs name

-- | The context. This <i>does not</i> include the "stupid theta" which
--   lives only in the <a>TyData</a> decl.
con_cxt :: ConDecl name -> LHsContext name

-- | The main payload
con_details :: ConDecl name -> HsConDeclDetails name

-- | Result type of the constructor
con_res :: ConDecl name -> ResType (LHsType name)

-- | A possible Haddock comment.
con_doc :: ConDecl name -> Maybe LHsDocString

-- | TEMPORARY field; True <a>=</a> user has employed now-deprecated syntax
--   for GADT-style record decl C { blah } :: T a b Remove this when we no
--   longer parse this stuff, and hence do not need to report decprecated
--   use
con_old_rec :: ConDecl name -> Bool
type LConDecl name = Located (ConDecl name)
data ResType ty
ResTyH98 :: ResType ty
ResTyGADT :: ty -> ResType ty
type HsConDeclDetails name = HsConDetails (LBangType name) [ConDeclField name]
hsConDeclArgTys :: HsConDeclDetails name -> [LBangType name]
data DocDecl
DocCommentNext :: HsDocString -> DocDecl
DocCommentPrev :: HsDocString -> DocDecl
DocCommentNamed :: String -> HsDocString -> DocDecl
DocGroup :: Int -> HsDocString -> DocDecl
type LDocDecl = Located (DocDecl)
docDeclDoc :: DocDecl -> HsDocString
data WarnDecl name
Warning :: name -> WarningTxt -> WarnDecl name
type LWarnDecl name = Located (WarnDecl name)
data AnnDecl name
HsAnnotation :: (AnnProvenance name) -> (Located (HsExpr name)) -> AnnDecl name
type LAnnDecl name = Located (AnnDecl name)
data AnnProvenance name
ValueAnnProvenance :: name -> AnnProvenance name
TypeAnnProvenance :: name -> AnnProvenance name
ModuleAnnProvenance :: AnnProvenance name
annProvenanceName_maybe :: AnnProvenance name -> Maybe name
modifyAnnProvenanceNameM :: Monad m => (before -> m after) -> AnnProvenance before -> m (AnnProvenance after)

-- | A <a>HsDecl</a> is categorised into a <a>HsGroup</a> before being fed
--   to the renamer.
data HsGroup id
HsGroup :: HsValBinds id -> [[LTyClDecl id]] -> [LInstDecl id] -> [LDerivDecl id] -> [LFixitySig id] -> [LDefaultDecl id] -> [LForeignDecl id] -> [LWarnDecl id] -> [LAnnDecl id] -> [LRuleDecl id] -> [LVectDecl id] -> [LDocDecl] -> HsGroup id
hs_valds :: HsGroup id -> HsValBinds id
hs_tyclds :: HsGroup id -> [[LTyClDecl id]]
hs_instds :: HsGroup id -> [LInstDecl id]
hs_derivds :: HsGroup id -> [LDerivDecl id]
hs_fixds :: HsGroup id -> [LFixitySig id]
hs_defds :: HsGroup id -> [LDefaultDecl id]
hs_fords :: HsGroup id -> [LForeignDecl id]
hs_warnds :: HsGroup id -> [LWarnDecl id]
hs_annds :: HsGroup id -> [LAnnDecl id]
hs_ruleds :: HsGroup id -> [LRuleDecl id]
hs_vects :: HsGroup id -> [LVectDecl id]
hs_docs :: HsGroup id -> [LDocDecl]
emptyRdrGroup :: HsGroup a
emptyRnGroup :: HsGroup a
appendGroups :: HsGroup a -> HsGroup a -> HsGroup a
instance Typeable1 SpliceDecl
instance Typeable NewOrData
instance Typeable FamilyFlavour
instance Typeable1 ResType
instance Typeable1 ConDecl
instance Typeable1 HsTyDefn
instance Typeable1 FamInstDecl
instance Typeable1 InstDecl
instance Typeable1 DerivDecl
instance Typeable1 DefaultDecl
instance Typeable CImportSpec
instance Typeable ForeignImport
instance Typeable ForeignExport
instance Typeable1 ForeignDecl
instance Typeable1 RuleBndr
instance Typeable1 RuleDecl
instance Typeable1 VectDecl
instance Typeable DocDecl
instance Typeable1 TyClDecl
instance Typeable1 WarnDecl
instance Typeable1 AnnProvenance
instance Typeable1 AnnDecl
instance Typeable1 HsGroup
instance Typeable1 HsDecl
instance Data id => Data (SpliceDecl id)
instance Eq NewOrData
instance Data NewOrData
instance Data FamilyFlavour
instance Data ty => Data (ResType ty)
instance Data name => Data (ConDecl name)
instance Data name => Data (HsTyDefn name)
instance Data name => Data (FamInstDecl name)
instance Data name => Data (InstDecl name)
instance Data name => Data (DerivDecl name)
instance Data name => Data (DefaultDecl name)
instance Data CImportSpec
instance Data ForeignImport
instance Data ForeignExport
instance Data name => Data (ForeignDecl name)
instance Data name => Data (RuleBndr name)
instance Data name => Data (RuleDecl name)
instance Data name => Data (VectDecl name)
instance Data DocDecl
instance Data name => Data (TyClDecl name)
instance Data name => Data (WarnDecl name)
instance Data name => Data (AnnProvenance name)
instance Data name => Data (AnnDecl name)
instance Data id => Data (HsGroup id)
instance Data id => Data (HsDecl id)
instance OutputableBndr name => Outputable (AnnDecl name)
instance OutputableBndr name => Outputable (WarnDecl name)
instance Outputable DocDecl
instance OutputableBndr name => Outputable (VectDecl name)
instance OutputableBndr name => Outputable (RuleBndr name)
instance OutputableBndr name => Outputable (RuleDecl name)
instance Outputable ForeignExport
instance Outputable ForeignImport
instance OutputableBndr name => Outputable (ForeignDecl name)
instance OutputableBndr name => Outputable (DefaultDecl name)
instance OutputableBndr name => Outputable (DerivDecl name)
instance OutputableBndr name => Outputable (InstDecl name)
instance OutputableBndr name => Outputable (FamInstDecl name)
instance OutputableBndr name => Outputable (ConDecl name)
instance Outputable ty => Outputable (ResType ty)
instance Outputable NewOrData
instance OutputableBndr name => Outputable (HsTyDefn name)
instance OutputableBndr name => Outputable (TyClDecl name)
instance OutputableBndr name => Outputable (SpliceDecl name)
instance OutputableBndr name => Outputable (HsGroup name)
instance OutputableBndr name => Outputable (HsDecl name)


-- | Abstract Haskell syntax for expressions.
module HsExpr
type LHsExpr id = Located (HsExpr id)

-- | PostTcExpr is an evidence expression attached to the syntax tree by
--   the type checker (c.f. postTcType).
type PostTcExpr = HsExpr Id

-- | We use a PostTcTable where there are a bunch of pieces of evidence,
--   more than is convenient to keep individually.
type PostTcTable = [(Name, PostTcExpr)]
noPostTcExpr :: PostTcExpr
noPostTcTable :: PostTcTable

-- | SyntaxExpr is like <a>PostTcExpr</a>, but it's filled in a little
--   earlier, by the renamer. It's used for rebindable syntax.
--   
--   E.g. <tt>(&gt;&gt;=)</tt> is filled in before the renamer by the
--   appropriate <a>Name</a> for <tt>(&gt;&gt;=)</tt>, and then
--   instantiated by the type checker with its type args etc
type SyntaxExpr id = HsExpr id
noSyntaxExpr :: SyntaxExpr id

-- | Currently used only for <tt>CmdTop</tt> (sigh)
--   
--   <ul>
--   <li>Before the renamer, this list is <a>noSyntaxTable</a></li>
--   <li>After the renamer, it takes the form <tt>[(std_name, HsVar
--   actual_name)]</tt> For example, for the <a>return</a> op of a
--   monad</li>
--   <li>normal case: <tt>(GHC.Base.return, HsVar
--   GHC.Base.return)</tt></li>
--   <li>with rebindable syntax: <tt>(GHC.Base.return, return_22)</tt>
--   where <tt>return_22</tt> is whatever <tt>return</tt> is in scope</li>
--   <li>After the type checker, it takes the form <tt>[(std_name,
--   <a>expression</a>)]</tt> where <tt><a>expression</a></tt> is the
--   evidence for the method</li>
--   </ul>
type SyntaxTable id = [(Name, SyntaxExpr id)]
noSyntaxTable :: SyntaxTable id

-- | A Haskell expression.
data HsExpr id

-- | variable
HsVar :: id -> HsExpr id

-- | implicit parameter
HsIPVar :: HsIPName -> HsExpr id

-- | Overloaded literals
HsOverLit :: (HsOverLit id) -> HsExpr id

-- | Simple (non-overloaded) literals
HsLit :: HsLit -> HsExpr id
HsLam :: (MatchGroup id) -> HsExpr id
HsLamCase :: PostTcType -> (MatchGroup id) -> HsExpr id
HsApp :: (LHsExpr id) -> (LHsExpr id) -> HsExpr id
OpApp :: (LHsExpr id) -> (LHsExpr id) -> Fixity -> (LHsExpr id) -> HsExpr id
NegApp :: (LHsExpr id) -> (SyntaxExpr id) -> HsExpr id
HsPar :: (LHsExpr id) -> HsExpr id
SectionL :: (LHsExpr id) -> (LHsExpr id) -> HsExpr id
SectionR :: (LHsExpr id) -> (LHsExpr id) -> HsExpr id
ExplicitTuple :: [HsTupArg id] -> Boxity -> HsExpr id
HsCase :: (LHsExpr id) -> (MatchGroup id) -> HsExpr id
HsIf :: (Maybe (SyntaxExpr id)) -> (LHsExpr id) -> (LHsExpr id) -> (LHsExpr id) -> HsExpr id
HsMultiIf :: PostTcType -> [LGRHS id] -> HsExpr id
HsLet :: (HsLocalBinds id) -> (LHsExpr id) -> HsExpr id
HsDo :: (HsStmtContext Name) -> [LStmt id] -> PostTcType -> HsExpr id
ExplicitList :: PostTcType -> [LHsExpr id] -> HsExpr id
ExplicitPArr :: PostTcType -> [LHsExpr id] -> HsExpr id
RecordCon :: (Located id) -> PostTcExpr -> (HsRecordBinds id) -> HsExpr id
RecordUpd :: (LHsExpr id) -> (HsRecordBinds id) -> [DataCon] -> [PostTcType] -> [PostTcType] -> HsExpr id
ExprWithTySig :: (LHsExpr id) -> (LHsType id) -> HsExpr id
ExprWithTySigOut :: (LHsExpr id) -> (LHsType Name) -> HsExpr id
ArithSeq :: PostTcExpr -> (ArithSeqInfo id) -> HsExpr id
PArrSeq :: PostTcExpr -> (ArithSeqInfo id) -> HsExpr id
HsSCC :: FastString -> (LHsExpr id) -> HsExpr id
HsCoreAnn :: FastString -> (LHsExpr id) -> HsExpr id
HsBracket :: (HsBracket id) -> HsExpr id
HsBracketOut :: (HsBracket Name) -> [PendingSplice] -> HsExpr id
HsSpliceE :: (HsSplice id) -> HsExpr id
HsQuasiQuoteE :: (HsQuasiQuote id) -> HsExpr id
HsProc :: (LPat id) -> (LHsCmdTop id) -> HsExpr id
HsArrApp :: (LHsExpr id) -> (LHsExpr id) -> PostTcType -> HsArrAppType -> Bool -> HsExpr id
HsArrForm :: (LHsExpr id) -> (Maybe Fixity) -> [LHsCmdTop id] -> HsExpr id
HsTick :: (Tickish id) -> (LHsExpr id) -> HsExpr id
HsBinTick :: Int -> Int -> (LHsExpr id) -> HsExpr id
HsTickPragma :: (FastString, (Int, Int), (Int, Int)) -> (LHsExpr id) -> HsExpr id
EWildPat :: HsExpr id
EAsPat :: (Located id) -> (LHsExpr id) -> HsExpr id
EViewPat :: (LHsExpr id) -> (LHsExpr id) -> HsExpr id
ELazyPat :: (LHsExpr id) -> HsExpr id
HsType :: (LHsType id) -> HsExpr id
HsWrap :: HsWrapper -> (HsExpr id) -> HsExpr id
data HsTupArg id
Present :: (LHsExpr id) -> HsTupArg id
Missing :: PostTcType -> HsTupArg id
tupArgPresent :: HsTupArg id -> Bool
type PendingSplice = (Name, LHsExpr Id)
pprLExpr :: OutputableBndr id => LHsExpr id -> SDoc
pprExpr :: OutputableBndr id => HsExpr id -> SDoc
isQuietHsExpr :: HsExpr id -> Bool
pprBinds :: (OutputableBndr idL, OutputableBndr idR) => HsLocalBindsLR idL idR -> SDoc
ppr_lexpr :: OutputableBndr id => LHsExpr id -> SDoc
ppr_expr :: OutputableBndr id => HsExpr id -> SDoc
pprCmdArg :: OutputableBndr id => HsCmdTop id -> SDoc
pprDebugParendExpr :: OutputableBndr id => LHsExpr id -> SDoc
pprParendExpr :: OutputableBndr id => LHsExpr id -> SDoc
hsExprNeedsParens :: HsExpr id -> Bool
isAtomicHsExpr :: HsExpr id -> Bool
type HsCmd id = HsExpr id
type LHsCmd id = LHsExpr id
data HsArrAppType
HsHigherOrderApp :: HsArrAppType
HsFirstOrderApp :: HsArrAppType
type LHsCmdTop id = Located (HsCmdTop id)
data HsCmdTop id
HsCmdTop :: (LHsCmd id) -> [PostTcType] -> PostTcType -> (SyntaxTable id) -> HsCmdTop id
type HsRecordBinds id = HsRecFields id (LHsExpr id)
data MatchGroup id
MatchGroup :: [LMatch id] -> PostTcType -> MatchGroup id
type LMatch id = Located (Match id)
data Match id
Match :: [LPat id] -> (Maybe (LHsType id)) -> (GRHSs id) -> Match id
isEmptyMatchGroup :: MatchGroup id -> Bool
matchGroupArity :: MatchGroup id -> Arity
hsLMatchPats :: LMatch id -> [LPat id]

-- | GRHSs are used both for pattern bindings and for Matches
data GRHSs id
GRHSs :: [LGRHS id] -> (HsLocalBinds id) -> GRHSs id

-- | Guarded RHSs
grhssGRHSs :: GRHSs id -> [LGRHS id]

-- | The where clause
grhssLocalBinds :: GRHSs id -> (HsLocalBinds id)
type LGRHS id = Located (GRHS id)

-- | Guarded Right Hand Side.
data GRHS id
GRHS :: [LStmt id] -> (LHsExpr id) -> GRHS id
pprMatches :: (OutputableBndr idL, OutputableBndr idR) => HsMatchContext idL -> MatchGroup idR -> SDoc
pprFunBind :: (OutputableBndr idL, OutputableBndr idR) => idL -> Bool -> MatchGroup idR -> SDoc
pprPatBind :: (OutputableBndr bndr, OutputableBndr id) => LPat bndr -> GRHSs id -> SDoc
pprMatch :: (OutputableBndr idL, OutputableBndr idR) => HsMatchContext idL -> Match idR -> SDoc
pprGRHSs :: (OutputableBndr idL, OutputableBndr idR) => HsMatchContext idL -> GRHSs idR -> SDoc
pprGRHS :: (OutputableBndr idL, OutputableBndr idR) => HsMatchContext idL -> GRHS idR -> SDoc
pp_rhs :: OutputableBndr idR => HsMatchContext idL -> LHsExpr idR -> SDoc
type LStmt id = Located (StmtLR id id)
type LStmtLR idL idR = Located (StmtLR idL idR)
type Stmt id = StmtLR id id
data StmtLR idL idR
LastStmt :: (LHsExpr idR) -> (SyntaxExpr idR) -> StmtLR idL idR
BindStmt :: (LPat idL) -> (LHsExpr idR) -> (SyntaxExpr idR) -> (SyntaxExpr idR) -> StmtLR idL idR
ExprStmt :: (LHsExpr idR) -> (SyntaxExpr idR) -> (SyntaxExpr idR) -> PostTcType -> StmtLR idL idR
LetStmt :: (HsLocalBindsLR idL idR) -> StmtLR idL idR
ParStmt :: [ParStmtBlock idL idR] -> (SyntaxExpr idR) -> (SyntaxExpr idR) -> StmtLR idL idR
TransStmt :: TransForm -> [LStmt idL] -> [(idR, idR)] -> LHsExpr idR -> Maybe (LHsExpr idR) -> SyntaxExpr idR -> SyntaxExpr idR -> SyntaxExpr idR -> StmtLR idL idR
trS_form :: StmtLR idL idR -> TransForm
trS_stmts :: StmtLR idL idR -> [LStmt idL]
trS_bndrs :: StmtLR idL idR -> [(idR, idR)]
trS_using :: StmtLR idL idR -> LHsExpr idR
trS_by :: StmtLR idL idR -> Maybe (LHsExpr idR)
trS_ret :: StmtLR idL idR -> SyntaxExpr idR
trS_bind :: StmtLR idL idR -> SyntaxExpr idR
trS_fmap :: StmtLR idL idR -> SyntaxExpr idR
RecStmt :: [LStmtLR idL idR] -> [idR] -> [idR] -> SyntaxExpr idR -> SyntaxExpr idR -> SyntaxExpr idR -> [PostTcExpr] -> [PostTcExpr] -> PostTcType -> StmtLR idL idR
recS_stmts :: StmtLR idL idR -> [LStmtLR idL idR]
recS_later_ids :: StmtLR idL idR -> [idR]
recS_rec_ids :: StmtLR idL idR -> [idR]
recS_bind_fn :: StmtLR idL idR -> SyntaxExpr idR
recS_ret_fn :: StmtLR idL idR -> SyntaxExpr idR
recS_mfix_fn :: StmtLR idL idR -> SyntaxExpr idR
recS_later_rets :: StmtLR idL idR -> [PostTcExpr]
recS_rec_rets :: StmtLR idL idR -> [PostTcExpr]
recS_ret_ty :: StmtLR idL idR -> PostTcType
data TransForm
ThenForm :: TransForm
GroupForm :: TransForm
data ParStmtBlock idL idR
ParStmtBlock :: [LStmt idL] -> [idR] -> (SyntaxExpr idR) -> ParStmtBlock idL idR
pprStmt :: (OutputableBndr idL, OutputableBndr idR) => (StmtLR idL idR) -> SDoc
pprTransformStmt :: OutputableBndr id => [id] -> LHsExpr id -> Maybe (LHsExpr id) -> SDoc
pprTransStmt :: OutputableBndr id => Maybe (LHsExpr id) -> LHsExpr id -> TransForm -> SDoc
pprBy :: OutputableBndr id => Maybe (LHsExpr id) -> SDoc
pprDo :: OutputableBndr id => HsStmtContext any -> [LStmt id] -> SDoc
ppr_do_stmts :: (OutputableBndr idL, OutputableBndr idR) => [LStmtLR idL idR] -> SDoc
pprComp :: OutputableBndr id => [LStmt id] -> SDoc
pprQuals :: OutputableBndr id => [LStmt id] -> SDoc
data HsSplice id
HsSplice :: id -> (LHsExpr id) -> HsSplice id
pprSplice :: OutputableBndr id => HsSplice id -> SDoc
data HsBracket id
ExpBr :: (LHsExpr id) -> HsBracket id
PatBr :: (LPat id) -> HsBracket id
DecBrL :: [LHsDecl id] -> HsBracket id
DecBrG :: (HsGroup id) -> HsBracket id
TypBr :: (LHsType id) -> HsBracket id
VarBr :: Bool -> id -> HsBracket id
pprHsBracket :: OutputableBndr id => HsBracket id -> SDoc
thBrackets :: SDoc -> SDoc -> SDoc
data ArithSeqInfo id
From :: (LHsExpr id) -> ArithSeqInfo id
FromThen :: (LHsExpr id) -> (LHsExpr id) -> ArithSeqInfo id
FromTo :: (LHsExpr id) -> (LHsExpr id) -> ArithSeqInfo id
FromThenTo :: (LHsExpr id) -> (LHsExpr id) -> (LHsExpr id) -> ArithSeqInfo id
pp_dotdot :: SDoc
data HsMatchContext id
FunRhs :: id -> Bool -> HsMatchContext id
LambdaExpr :: HsMatchContext id
CaseAlt :: HsMatchContext id
IfAlt :: HsMatchContext id
ProcExpr :: HsMatchContext id
PatBindRhs :: HsMatchContext id
RecUpd :: HsMatchContext id
StmtCtxt :: (HsStmtContext id) -> HsMatchContext id
ThPatQuote :: HsMatchContext id
data HsStmtContext id
ListComp :: HsStmtContext id
MonadComp :: HsStmtContext id
PArrComp :: HsStmtContext id
DoExpr :: HsStmtContext id
MDoExpr :: HsStmtContext id
ArrowExpr :: HsStmtContext id
GhciStmt :: HsStmtContext id
PatGuard :: (HsMatchContext id) -> HsStmtContext id
ParStmtCtxt :: (HsStmtContext id) -> HsStmtContext id
TransStmtCtxt :: (HsStmtContext id) -> HsStmtContext id
isListCompExpr :: HsStmtContext id -> Bool
isMonadCompExpr :: HsStmtContext id -> Bool
matchSeparator :: HsMatchContext id -> SDoc
pprMatchContext :: Outputable id => HsMatchContext id -> SDoc
pprMatchContextNoun :: Outputable id => HsMatchContext id -> SDoc
pprAStmtContext :: Outputable id => HsStmtContext id -> SDoc
pprStmtContext :: Outputable id => HsStmtContext id -> SDoc
matchContextErrString :: Outputable id => HsMatchContext id -> SDoc
pprMatchInCtxt :: (OutputableBndr idL, OutputableBndr idR) => HsMatchContext idL -> Match idR -> SDoc
pprStmtInCtxt :: (OutputableBndr idL, OutputableBndr idR) => HsStmtContext idL -> StmtLR idL idR -> SDoc
instance Typeable HsArrAppType
instance Typeable TransForm
instance Typeable1 GRHSs
instance Typeable1 MatchGroup
instance Typeable1 HsSplice
instance Typeable1 HsExpr
instance Typeable1 HsStmtContext
instance Typeable1 HsMatchContext
instance Typeable1 ArithSeqInfo
instance Typeable1 HsBracket
instance Typeable2 StmtLR
instance Typeable2 ParStmtBlock
instance Typeable1 GRHS
instance Typeable1 HsCmdTop
instance Typeable1 HsTupArg
instance Typeable1 Match
instance Data HsArrAppType
instance Data TransForm
instance Data id => Data (GRHSs id)
instance Data id => Data (MatchGroup id)
instance Data id => Data (HsSplice id)
instance Data id => Data (HsExpr id)
instance Data id => Data (HsStmtContext id)
instance Data id => Data (HsMatchContext id)
instance Data id => Data (ArithSeqInfo id)
instance Data id => Data (HsBracket id)
instance (Data idL, Data idR) => Data (StmtLR idL idR)
instance (Data idL, Data idR) => Data (ParStmtBlock idL idR)
instance Data id => Data (GRHS id)
instance Data id => Data (HsCmdTop id)
instance Data id => Data (HsTupArg id)
instance Data id => Data (Match id)
instance OutputableBndr id => Outputable (ArithSeqInfo id)
instance OutputableBndr id => Outputable (HsBracket id)
instance OutputableBndr id => Outputable (HsSplice id)
instance (OutputableBndr idL, OutputableBndr idR) => Outputable (StmtLR idL idR)
instance (OutputableBndr idL, OutputableBndr idR) => Outputable (ParStmtBlock idL idR)
instance OutputableBndr id => Outputable (HsCmdTop id)
instance OutputableBndr id => Outputable (HsExpr id)

module HsUtils
mkHsPar :: LHsExpr id -> LHsExpr id
mkHsApp :: LHsExpr name -> LHsExpr name -> LHsExpr name
mkHsConApp :: DataCon -> [Type] -> [HsExpr Id] -> LHsExpr Id
mkSimpleHsAlt :: LPat id -> LHsExpr id -> LMatch id
mkSimpleMatch :: [LPat id] -> LHsExpr id -> LMatch id
unguardedGRHSs :: LHsExpr id -> GRHSs id
unguardedRHS :: LHsExpr id -> [LGRHS id]
mkMatchGroup :: [LMatch id] -> MatchGroup id
mkMatch :: [LPat id] -> LHsExpr id -> HsLocalBinds id -> LMatch id
mkHsLam :: [LPat id] -> LHsExpr id -> LHsExpr id
mkHsIf :: LHsExpr id -> LHsExpr id -> LHsExpr id -> HsExpr id
mkHsWrap :: HsWrapper -> HsExpr id -> HsExpr id
mkLHsWrap :: HsWrapper -> LHsExpr id -> LHsExpr id
mkHsWrapCo :: TcCoercion -> HsExpr id -> HsExpr id
mkLHsWrapCo :: TcCoercion -> LHsExpr id -> LHsExpr id
coToHsWrapper :: TcCoercion -> HsWrapper
mkHsDictLet :: TcEvBinds -> LHsExpr Id -> LHsExpr Id
mkHsLams :: [TyVar] -> [EvVar] -> LHsExpr Id -> LHsExpr Id
mkHsOpApp :: LHsExpr id -> id -> LHsExpr id -> HsExpr id
mkHsDo :: HsStmtContext Name -> [LStmt id] -> HsExpr id
mkHsComp :: HsStmtContext Name -> [LStmt id] -> LHsExpr id -> HsExpr id
mkHsWrapPat :: HsWrapper -> Pat id -> Type -> Pat id
mkHsWrapPatCo :: TcCoercion -> Pat id -> Type -> Pat id
mkLHsPar :: LHsExpr name -> LHsExpr name
nlHsTyApp :: name -> [Type] -> LHsExpr name
nlHsVar :: id -> LHsExpr id
nlHsLit :: HsLit -> LHsExpr id
nlHsApp :: LHsExpr id -> LHsExpr id -> LHsExpr id
nlHsApps :: id -> [LHsExpr id] -> LHsExpr id
nlHsIntLit :: Integer -> LHsExpr id
nlHsVarApps :: id -> [id] -> LHsExpr id
nlHsDo :: HsStmtContext Name -> [LStmt id] -> LHsExpr id
nlHsOpApp :: LHsExpr id -> id -> LHsExpr id -> LHsExpr id
nlHsLam :: LMatch id -> LHsExpr id
nlHsPar :: LHsExpr id -> LHsExpr id
nlHsIf :: LHsExpr id -> LHsExpr id -> LHsExpr id -> LHsExpr id
nlHsCase :: LHsExpr id -> [LMatch id] -> LHsExpr id
nlList :: [LHsExpr id] -> LHsExpr id
mkLHsTupleExpr :: [LHsExpr a] -> LHsExpr a
mkLHsVarTuple :: [a] -> LHsExpr a
missingTupArg :: HsTupArg a
mkFunBind :: Located RdrName -> [LMatch RdrName] -> HsBind RdrName
mkVarBind :: id -> LHsExpr id -> LHsBind id
mkHsVarBind :: SrcSpan -> RdrName -> LHsExpr RdrName -> LHsBind RdrName
mk_easy_FunBind :: SrcSpan -> RdrName -> [LPat RdrName] -> LHsExpr RdrName -> LHsBind RdrName
mkTopFunBind :: Located Name -> [LMatch Name] -> HsBind Name
mkHsIntegral :: Integer -> PostTcType -> HsOverLit id
mkHsFractional :: FractionalLit -> PostTcType -> HsOverLit id
mkHsIsString :: FastString -> PostTcType -> HsOverLit id
mkHsString :: String -> HsLit
mkNPat :: HsOverLit id -> Maybe (SyntaxExpr id) -> Pat id
mkNPlusKPat :: Located id -> HsOverLit id -> Pat id
nlVarPat :: id -> LPat id
nlLitPat :: HsLit -> LPat id
nlConVarPat :: id -> [id] -> LPat id
nlConPat :: id -> [LPat id] -> LPat id
nlInfixConPat :: id -> LPat id -> LPat id -> LPat id
nlNullaryConPat :: id -> LPat id
nlWildConPat :: DataCon -> LPat RdrName
nlWildPat :: LPat id
nlTuplePat :: [LPat id] -> Boxity -> LPat id
mkParPat :: LPat name -> LPat name
mkHsAppTy :: LHsType name -> LHsType name -> LHsType name
userHsTyVarBndrs :: SrcSpan -> [name] -> [Located (HsTyVarBndr name)]
nlHsAppTy :: LHsType name -> LHsType name -> LHsType name
nlHsTyVar :: name -> LHsType name
nlHsFunTy :: LHsType name -> LHsType name -> LHsType name
nlHsTyConApp :: name -> [LHsType name] -> LHsType name
mkTransformStmt :: [LStmt idL] -> LHsExpr idR -> StmtLR idL idR
mkTransformByStmt :: [LStmt idL] -> LHsExpr idR -> LHsExpr idR -> StmtLR idL idR
mkExprStmt :: LHsExpr idR -> StmtLR idL idR
mkBindStmt :: LPat idL -> LHsExpr idR -> StmtLR idL idR
mkLastStmt :: LHsExpr idR -> StmtLR idL idR
emptyTransStmt :: StmtLR idL idR
mkGroupUsingStmt :: [LStmt idL] -> LHsExpr idR -> StmtLR idL idR
mkGroupByUsingStmt :: [LStmt idL] -> LHsExpr idR -> LHsExpr idR -> StmtLR idL idR
emptyRecStmt :: StmtLR idL idR
mkRecStmt :: [LStmtLR idL idR] -> StmtLR idL idR
unqualSplice :: RdrName
mkHsSpliceTy :: LHsExpr RdrName -> HsType RdrName
mkHsSplice :: LHsExpr RdrName -> HsSplice RdrName
mkHsQuasiQuote :: RdrName -> SrcSpan -> FastString -> HsQuasiQuote RdrName
unqualQuasiQuote :: RdrName
noRebindableInfo :: Bool
collectLocalBinders :: HsLocalBindsLR idL idR -> [idL]
collectHsValBinders :: HsValBindsLR idL idR -> [idL]
collectHsBindListBinders :: [LHsBindLR idL idR] -> [idL]
collectHsBindsBinders :: LHsBindsLR idL idR -> [idL]
collectHsBindBinders :: HsBindLR idL idR -> [idL]
collectMethodBinders :: LHsBindsLR RdrName idR -> [Located RdrName]
collectPatBinders :: LPat a -> [a]
collectPatsBinders :: [LPat a] -> [a]
collectLStmtsBinders :: [LStmtLR idL idR] -> [idL]
collectStmtsBinders :: [StmtLR idL idR] -> [idL]
collectLStmtBinders :: LStmtLR idL idR -> [idL]
collectStmtBinders :: StmtLR idL idR -> [idL]

-- | Returns all the <i>binding</i> names of the decl, along with their
--   SrcLocs. The first one is guaranteed to be the name of the decl. For
--   record fields mentioned in multiple constructors, the SrcLoc will be
--   from the first occurence. We use the equality to filter out duplicate
--   field names
hsLTyClDeclBinders :: Eq name => Located (TyClDecl name) -> [Located name]
hsTyClDeclBinders :: Eq name => TyClDecl name -> [Located name]
hsTyClDeclsBinders :: [[LTyClDecl Name]] -> [Located (InstDecl Name)] -> [Name]
hsForeignDeclsBinders :: [LForeignDecl Name] -> [Name]
hsGroupBinders :: HsGroup Name -> [Name]
hsFamInstBinders :: Eq name => FamInstDecl name -> [Located name]
lStmtsImplicits :: [LStmtLR Name idR] -> NameSet
hsValBindsImplicits :: HsValBindsLR Name idR -> NameSet
lPatImplicits :: LPat Name -> NameSet

module IfaceSyn
data IfaceDecl
IfaceId :: OccName -> IfaceType -> IfaceIdDetails -> IfaceIdInfo -> IfaceDecl
ifName :: IfaceDecl -> OccName
ifType :: IfaceDecl -> IfaceType
ifIdDetails :: IfaceDecl -> IfaceIdDetails
ifIdInfo :: IfaceDecl -> IfaceIdInfo
IfaceData :: OccName -> Maybe CType -> [IfaceTvBndr] -> IfaceContext -> IfaceConDecls -> RecFlag -> Bool -> Maybe IfExtName -> IfaceDecl
ifName :: IfaceDecl -> OccName
ifCType :: IfaceDecl -> Maybe CType
ifTyVars :: IfaceDecl -> [IfaceTvBndr]
ifCtxt :: IfaceDecl -> IfaceContext
ifCons :: IfaceDecl -> IfaceConDecls
ifRec :: IfaceDecl -> RecFlag
ifGadtSyntax :: IfaceDecl -> Bool
ifAxiom :: IfaceDecl -> Maybe IfExtName
IfaceSyn :: OccName -> [IfaceTvBndr] -> IfaceKind -> Maybe IfaceType -> IfaceDecl
ifName :: IfaceDecl -> OccName
ifTyVars :: IfaceDecl -> [IfaceTvBndr]
ifSynKind :: IfaceDecl -> IfaceKind
ifSynRhs :: IfaceDecl -> Maybe IfaceType
IfaceClass :: IfaceContext -> OccName -> [IfaceTvBndr] -> [FunDep FastString] -> [IfaceAT] -> [IfaceClassOp] -> RecFlag -> IfaceDecl
ifCtxt :: IfaceDecl -> IfaceContext
ifName :: IfaceDecl -> OccName
ifTyVars :: IfaceDecl -> [IfaceTvBndr]
ifFDs :: IfaceDecl -> [FunDep FastString]
ifATs :: IfaceDecl -> [IfaceAT]
ifSigs :: IfaceDecl -> [IfaceClassOp]
ifRec :: IfaceDecl -> RecFlag
IfaceAxiom :: OccName -> [IfaceTvBndr] -> IfaceType -> IfaceType -> IfaceDecl
ifName :: IfaceDecl -> OccName
ifTyVars :: IfaceDecl -> [IfaceTvBndr]
ifLHS :: IfaceDecl -> IfaceType
ifRHS :: IfaceDecl -> IfaceType
IfaceForeign :: OccName -> Maybe FastString -> IfaceDecl
ifName :: IfaceDecl -> OccName
ifExtName :: IfaceDecl -> Maybe FastString
data IfaceClassOp
IfaceClassOp :: OccName -> DefMethSpec -> IfaceType -> IfaceClassOp
data IfaceAT
IfaceAT :: IfaceDecl -> [IfaceATDefault] -> IfaceAT
data IfaceATDefault
IfaceATD :: [IfaceTvBndr] -> [IfaceType] -> IfaceType -> IfaceATDefault
data IfaceConDecl
IfCon :: OccName -> Bool -> Bool -> [IfaceTvBndr] -> [IfaceTvBndr] -> [(OccName, IfaceType)] -> IfaceContext -> [IfaceType] -> [OccName] -> [HsBang] -> IfaceConDecl
ifConOcc :: IfaceConDecl -> OccName
ifConWrapper :: IfaceConDecl -> Bool
ifConInfix :: IfaceConDecl -> Bool
ifConUnivTvs :: IfaceConDecl -> [IfaceTvBndr]
ifConExTvs :: IfaceConDecl -> [IfaceTvBndr]
ifConEqSpec :: IfaceConDecl -> [(OccName, IfaceType)]
ifConCtxt :: IfaceConDecl -> IfaceContext
ifConArgTys :: IfaceConDecl -> [IfaceType]
ifConFields :: IfaceConDecl -> [OccName]
ifConStricts :: IfaceConDecl -> [HsBang]
data IfaceConDecls
IfAbstractTyCon :: Bool -> IfaceConDecls
IfDataFamTyCon :: IfaceConDecls
IfDataTyCon :: [IfaceConDecl] -> IfaceConDecls
IfNewTyCon :: IfaceConDecl -> IfaceConDecls
data IfaceExpr
IfaceLcl :: IfLclName -> IfaceExpr
IfaceExt :: IfExtName -> IfaceExpr
IfaceType :: IfaceType -> IfaceExpr
IfaceCo :: IfaceType -> IfaceExpr
IfaceTuple :: TupleSort -> [IfaceExpr] -> IfaceExpr
IfaceLam :: IfaceBndr -> IfaceExpr -> IfaceExpr
IfaceApp :: IfaceExpr -> IfaceExpr -> IfaceExpr
IfaceCase :: IfaceExpr -> IfLclName -> [IfaceAlt] -> IfaceExpr
IfaceECase :: IfaceExpr -> IfaceType -> IfaceExpr
IfaceLet :: IfaceBinding -> IfaceExpr -> IfaceExpr
IfaceCast :: IfaceExpr -> IfaceCoercion -> IfaceExpr
IfaceLit :: Literal -> IfaceExpr
IfaceFCall :: ForeignCall -> IfaceType -> IfaceExpr
IfaceTick :: IfaceTickish -> IfaceExpr -> IfaceExpr
type IfaceAlt = (IfaceConAlt, [IfLclName], IfaceExpr)
data IfaceLetBndr
IfLetBndr :: IfLclName -> IfaceType -> IfaceIdInfo -> IfaceLetBndr
data IfaceBinding
IfaceNonRec :: IfaceLetBndr -> IfaceExpr -> IfaceBinding
IfaceRec :: [(IfaceLetBndr, IfaceExpr)] -> IfaceBinding
data IfaceConAlt
IfaceDefault :: IfaceConAlt
IfaceDataAlt :: IfExtName -> IfaceConAlt
IfaceLitAlt :: Literal -> IfaceConAlt
data IfaceIdInfo
NoInfo :: IfaceIdInfo
HasInfo :: [IfaceInfoItem] -> IfaceIdInfo
data IfaceIdDetails
IfVanillaId :: IfaceIdDetails
IfRecSelId :: IfaceTyCon -> Bool -> IfaceIdDetails
IfDFunId :: Int -> IfaceIdDetails
data IfaceUnfolding
IfCoreUnfold :: Bool -> IfaceExpr -> IfaceUnfolding
IfCompulsory :: IfaceExpr -> IfaceUnfolding
IfInlineRule :: Arity -> Bool -> Bool -> IfaceExpr -> IfaceUnfolding
IfExtWrapper :: Arity -> IfExtName -> IfaceUnfolding
IfLclWrapper :: Arity -> IfLclName -> IfaceUnfolding
IfDFunUnfold :: [DFunArg IfaceExpr] -> IfaceUnfolding
data IfaceInfoItem
HsArity :: Arity -> IfaceInfoItem
HsStrictness :: StrictSig -> IfaceInfoItem
HsInline :: InlinePragma -> IfaceInfoItem
HsUnfold :: Bool -> IfaceUnfolding -> IfaceInfoItem
HsNoCafRefs :: IfaceInfoItem
data IfaceRule
IfaceRule :: RuleName -> Activation -> [IfaceBndr] -> IfExtName -> [IfaceExpr] -> IfaceExpr -> Bool -> Maybe OccName -> IfaceRule
ifRuleName :: IfaceRule -> RuleName
ifActivation :: IfaceRule -> Activation
ifRuleBndrs :: IfaceRule -> [IfaceBndr]
ifRuleHead :: IfaceRule -> IfExtName
ifRuleArgs :: IfaceRule -> [IfaceExpr]
ifRuleRhs :: IfaceRule -> IfaceExpr
ifRuleAuto :: IfaceRule -> Bool
ifRuleOrph :: IfaceRule -> Maybe OccName
data IfaceAnnotation
IfaceAnnotation :: IfaceAnnTarget -> Serialized -> IfaceAnnotation
ifAnnotatedTarget :: IfaceAnnotation -> IfaceAnnTarget
ifAnnotatedValue :: IfaceAnnotation -> Serialized
type IfaceAnnTarget = AnnTarget OccName
data IfaceClsInst
IfaceClsInst :: IfExtName -> [Maybe IfaceTyCon] -> IfExtName -> OverlapFlag -> Maybe OccName -> IfaceClsInst
ifInstCls :: IfaceClsInst -> IfExtName
ifInstTys :: IfaceClsInst -> [Maybe IfaceTyCon]
ifDFun :: IfaceClsInst -> IfExtName
ifOFlag :: IfaceClsInst -> OverlapFlag
ifInstOrph :: IfaceClsInst -> Maybe OccName
data IfaceFamInst
IfaceFamInst :: IfExtName -> [Maybe IfaceTyCon] -> IfExtName -> Maybe OccName -> IfaceFamInst
ifFamInstFam :: IfaceFamInst -> IfExtName
ifFamInstTys :: IfaceFamInst -> [Maybe IfaceTyCon]
ifFamInstAxiom :: IfaceFamInst -> IfExtName
ifFamInstOrph :: IfaceFamInst -> Maybe OccName
data IfaceTickish
IfaceHpcTick :: Module -> Int -> IfaceTickish
IfaceSCC :: CostCentre -> Bool -> Bool -> IfaceTickish
ifaceDeclImplicitBndrs :: IfaceDecl -> [OccName]
visibleIfConDecls :: IfaceConDecls -> [IfaceConDecl]
ifaceDeclFingerprints :: Fingerprint -> IfaceDecl -> [(OccName, Fingerprint)]

-- | Finding the Names in IfaceSyn
freeNamesIfDecl :: IfaceDecl -> NameSet
freeNamesIfRule :: IfaceRule -> NameSet
freeNamesIfFamInst :: IfaceFamInst -> NameSet

-- | Pretty Print an IfaceExpre
--   
--   The first argument should be a function that adds parens in context
--   that need an atomic value (e.g. function args)
pprIfaceExpr :: (SDoc -> SDoc) -> IfaceExpr -> SDoc
pprIfaceDeclHead :: IfaceContext -> OccName -> [IfaceTvBndr] -> SDoc
instance Outputable IfaceUnfolding
instance Outputable IfaceInfoItem
instance Outputable IfaceIdInfo
instance Outputable IfaceIdDetails
instance Outputable IfaceConAlt
instance Outputable IfaceExpr
instance Outputable IfaceFamInst
instance Outputable IfaceClsInst
instance Outputable IfaceRule
instance Outputable IfaceATDefault
instance Outputable IfaceAT
instance Outputable IfaceClassOp
instance Outputable IfaceDecl

module HsSyn
data Fixity

-- | All we actually declare here is the top-level structure for a module.
data HsModule name
HsModule :: Maybe (Located ModuleName) -> Maybe [LIE name] -> [LImportDecl name] -> [LHsDecl name] -> Maybe WarningTxt -> Maybe LHsDocString -> HsModule name

-- | <tt>Nothing</tt>: "module X where" is omitted (in which case the next
--   field is Nothing too)
hsmodName :: HsModule name -> Maybe (Located ModuleName)

-- | Export list
--   
--   <ul>
--   <li><tt>Nothing</tt>: export list omitted, so export everything</li>
--   <li><tt>Just []</tt>: export <i>nothing</i></li>
--   <li><tt>Just [...]</tt>: as you would expect...</li>
--   </ul>
hsmodExports :: HsModule name -> Maybe [LIE name]

-- | We snaffle interesting stuff out of the imported interfaces early on,
--   adding that info to TyDecls/etc; so this list is often empty,
--   downstream.
hsmodImports :: HsModule name -> [LImportDecl name]

-- | Type, class, value, and interface signature decls
hsmodDecls :: HsModule name -> [LHsDecl name]

-- | reason/explanation for warning/deprecation of this module
hsmodDeprecMessage :: HsModule name -> Maybe WarningTxt

-- | Haddock module info and description, unparsed
hsmodHaddockModHeader :: HsModule name -> Maybe LHsDocString
data HsExtCore name
HsExtCore :: Module -> [TyClDecl name] -> [IfaceBinding] -> HsExtCore name
instance Typeable1 HsModule
instance Data name => Data (HsModule name)
instance (OutputableBndr name, HasOccName name) => Outputable (HsModule name)
instance Outputable Char


-- | Statistics for per-module compilations
--   
--   (c) The GRASP/AQUA Project, Glasgow University, 1993-1998
module HscStats

-- | Source Statistics
ppSourceStats :: Bool -> Located (HsModule RdrName) -> SDoc

module HaddockUtils
addFieldDoc :: ConDeclField a -> Maybe LHsDocString -> ConDeclField a
addFieldDocs :: [ConDeclField a] -> Maybe LHsDocString -> [ConDeclField a]
addConDoc :: LConDecl a -> Maybe LHsDocString -> LConDecl a
addConDocs :: [LConDecl a] -> Maybe LHsDocString -> [LConDecl a]
addConDocFirst :: [LConDecl a] -> Maybe LHsDocString -> [LConDecl a]


-- | Package manipulation
module Packages

-- | A PackageConfigMap maps a <a>PackageId</a> to a <a>PackageConfig</a>
type PackageConfigMap = UniqFM PackageConfig
emptyPackageConfigMap :: PackageConfigMap

-- | Find the package we know about with the given id (e.g. "foo-1.0"), if
--   any
lookupPackage :: PackageConfigMap -> PackageId -> Maybe PackageConfig
extendPackageConfigMap :: PackageConfigMap -> [PackageConfig] -> PackageConfigMap

-- | Show package info on console, if verbosity is &gt;= 3
dumpPackages :: DynFlags -> IO ()

-- | Package state is all stored in <a>DynFlag</a>s, including the details
--   of all packages, which packages are exposed, and which modules they
--   provide.
--   
--   The package state is computed by <a>initPackages</a>, and kept in
--   DynFlags.
--   
--   <ul>
--   <li><tt>-package <a>pkg</a></tt> causes <tt><a>pkg</a></tt> to become
--   exposed, and all other packages with the same name to become
--   hidden.</li>
--   <li><tt>-hide-package <a>pkg</a></tt> causes <tt><a>pkg</a></tt> to
--   become hidden.</li>
--   <li>Let <tt>exposedPackages</tt> be the set of packages thus exposed.
--   Let <tt>depExposedPackages</tt> be the transitive closure from
--   <tt>exposedPackages</tt> of their dependencies.</li>
--   <li>When searching for a module from an preload import declaration,
--   only the exposed modules in <tt>exposedPackages</tt> are valid.</li>
--   <li>When searching for a module from an implicit import, all modules
--   from <tt>depExposedPackages</tt> are valid.</li>
--   <li>When linking in a compilation manager mode, we link in packages
--   the program depends on (the compiler knows this list by the time it
--   gets to the link step). Also, we link in all packages which were
--   mentioned with preload <tt>-package</tt> flags on the command-line, or
--   are a transitive dependency of same, or are "base"/"rts". The reason
--   for this is that we might need packages which don't contain any
--   Haskell modules, and therefore won't be discovered by the normal
--   mechanism of dependency tracking.</li>
--   </ul>
data PackageState
PackageState :: PackageConfigMap -> [PackageId] -> UniqFM [(PackageConfig, Bool)] -> InstalledPackageIdMap -> PackageState
pkgIdMap :: PackageState -> PackageConfigMap
preloadPackages :: PackageState -> [PackageId]
moduleToPkgConfAll :: PackageState -> UniqFM [(PackageConfig, Bool)]
installedPackageIdMap :: PackageState -> InstalledPackageIdMap

-- | Call this after <a>parseDynFlags</a>. It reads the package database
--   files, and sets up various internal tables of package information,
--   according to the package-related flags on the command-line
--   (<tt>-package</tt>, <tt>-hide-package</tt> etc.)
--   
--   Returns a list of packages to link in if we're doing dynamic linking.
--   This list contains the packages that the user explicitly mentioned
--   with <tt>-package</tt> flags.
--   
--   <a>initPackages</a> can be called again subsequently after updating
--   the <a>packageFlags</a> field of the <a>DynFlags</a>, and it will
--   update the <a>pkgState</a> in <a>DynFlags</a> and return a list of
--   packages to link in.
initPackages :: DynFlags -> IO (DynFlags, [PackageId])

-- | Looks up the package with the given id in the package state, panicing
--   if it is not found
getPackageDetails :: PackageState -> PackageId -> PackageConfig

-- | Takes a <a>Module</a>, and if the module is in a package returns
--   <tt>(pkgconf, exposed)</tt> where pkgconf is the PackageConfig for
--   that package, and exposed is <tt>True</tt> if the package exposes the
--   module.
lookupModuleInAllPackages :: DynFlags -> ModuleName -> [(PackageConfig, Bool)]
lookupModuleWithSuggestions :: DynFlags -> ModuleName -> Either [Module] [(PackageConfig, Bool)]

-- | Find all the include directories in these and the preload packages
getPackageIncludePath :: DynFlags -> [PackageId] -> IO [String]

-- | Find all the library paths in these and the preload packages
getPackageLibraryPath :: DynFlags -> [PackageId] -> IO [String]

-- | Find all the link options in these and the preload packages
getPackageLinkOpts :: DynFlags -> [PackageId] -> IO [String]

-- | Find all the C-compiler options in these and the preload packages
getPackageExtraCcOpts :: DynFlags -> [PackageId] -> IO [String]

-- | Find all the package framework paths in these and the preload packages
getPackageFrameworkPath :: DynFlags -> [PackageId] -> IO [String]

-- | Find all the package frameworks in these and the preload packages
getPackageFrameworks :: DynFlags -> [PackageId] -> IO [String]

-- | Find all the <a>PackageConfig</a> in both the preload packages from
--   <a>DynFlags</a> and corresponding to the list of <a>PackageConfig</a>s
getPreloadPackagesAnd :: DynFlags -> [PackageId] -> IO [PackageConfig]
collectIncludeDirs :: [PackageConfig] -> [FilePath]
collectLibraryPaths :: [PackageConfig] -> [FilePath]
collectLinkOpts :: DynFlags -> [PackageConfig] -> [String]
packageHsLibs :: DynFlags -> PackageConfig -> [String]

-- | Will the <a>Name</a> come from a dynamically linked library?
isDllName :: PackageId -> Name -> Bool

module Lexer
data Token
ITas :: Token
ITcase :: Token
ITclass :: Token
ITdata :: Token
ITdefault :: Token
ITderiving :: Token
ITdo :: Token
ITelse :: Token
IThiding :: Token
ITif :: Token
ITimport :: Token
ITin :: Token
ITinfix :: Token
ITinfixl :: Token
ITinfixr :: Token
ITinstance :: Token
ITlet :: Token
ITmodule :: Token
ITnewtype :: Token
ITof :: Token
ITqualified :: Token
ITthen :: Token
ITtype :: Token
ITwhere :: Token
ITscc :: Token
ITforall :: Token
ITforeign :: Token
ITexport :: Token
ITlabel :: Token
ITdynamic :: Token
ITsafe :: Token
ITinterruptible :: Token
ITunsafe :: Token
ITstdcallconv :: Token
ITccallconv :: Token
ITcapiconv :: Token
ITprimcallconv :: Token
ITmdo :: Token
ITfamily :: Token
ITgroup :: Token
ITby :: Token
ITusing :: Token
ITinline_prag :: InlineSpec -> RuleMatchInfo -> Token
ITspec_prag :: Token
ITspec_inline_prag :: Bool -> Token
ITsource_prag :: Token
ITrules_prag :: Token
ITwarning_prag :: Token
ITdeprecated_prag :: Token
ITline_prag :: Token
ITscc_prag :: Token
ITgenerated_prag :: Token
ITcore_prag :: Token
ITunpack_prag :: Token
ITnounpack_prag :: Token
ITann_prag :: Token
ITclose_prag :: Token
IToptions_prag :: String -> Token
ITinclude_prag :: String -> Token
ITlanguage_prag :: Token
ITvect_prag :: Token
ITvect_scalar_prag :: Token
ITnovect_prag :: Token
ITctype :: Token
ITdotdot :: Token
ITcolon :: Token
ITdcolon :: Token
ITequal :: Token
ITlam :: Token
ITlcase :: Token
ITvbar :: Token
ITlarrow :: Token
ITrarrow :: Token
ITat :: Token
ITtilde :: Token
ITtildehsh :: Token
ITdarrow :: Token
ITminus :: Token
ITbang :: Token
ITstar :: Token
ITdot :: Token
ITbiglam :: Token
ITocurly :: Token
ITccurly :: Token
ITvocurly :: Token
ITvccurly :: Token
ITobrack :: Token
ITopabrack :: Token
ITcpabrack :: Token
ITcbrack :: Token
IToparen :: Token
ITcparen :: Token
IToubxparen :: Token
ITcubxparen :: Token
ITsemi :: Token
ITcomma :: Token
ITunderscore :: Token
ITbackquote :: Token
ITsimpleQuote :: Token
ITvarid :: FastString -> Token
ITconid :: FastString -> Token
ITvarsym :: FastString -> Token
ITconsym :: FastString -> Token
ITqvarid :: (FastString, FastString) -> Token
ITqconid :: (FastString, FastString) -> Token
ITqvarsym :: (FastString, FastString) -> Token
ITqconsym :: (FastString, FastString) -> Token
ITprefixqvarsym :: (FastString, FastString) -> Token
ITprefixqconsym :: (FastString, FastString) -> Token
ITdupipvarid :: FastString -> Token
ITchar :: Char -> Token
ITstring :: FastString -> Token
ITinteger :: Integer -> Token
ITrational :: FractionalLit -> Token
ITprimchar :: Char -> Token
ITprimstring :: FastString -> Token
ITprimint :: Integer -> Token
ITprimword :: Integer -> Token
ITprimfloat :: FractionalLit -> Token
ITprimdouble :: FractionalLit -> Token
ITopenExpQuote :: Token
ITopenPatQuote :: Token
ITopenDecQuote :: Token
ITopenTypQuote :: Token
ITcloseQuote :: Token
ITidEscape :: FastString -> Token
ITparenEscape :: Token
ITtyQuote :: Token
ITquasiQuote :: (FastString, FastString, RealSrcSpan) -> Token
ITqQuasiQuote :: (FastString, FastString, FastString, RealSrcSpan) -> Token
ITproc :: Token
ITrec :: Token
IToparenbar :: Token
ITcparenbar :: Token
ITlarrowtail :: Token
ITrarrowtail :: Token
ITLarrowtail :: Token
ITRarrowtail :: Token
ITunknown :: String -> Token
ITeof :: Token
ITdocCommentNext :: String -> Token
ITdocCommentPrev :: String -> Token
ITdocCommentNamed :: String -> Token
ITdocSection :: Int -> String -> Token
ITdocOptions :: String -> Token
ITdocOptionsOld :: String -> Token
ITlineComment :: String -> Token
ITblockComment :: String -> Token
lexer :: (Located Token -> P a) -> P a
pragState :: DynFlags -> StringBuffer -> RealSrcLoc -> PState
mkPState :: DynFlags -> StringBuffer -> RealSrcLoc -> PState
data PState
PState :: StringBuffer -> DynFlags -> Messages -> Maybe Token -> RealSrcSpan -> !Int -> RealSrcLoc -> !Int -> [LayoutContext] -> [Int] -> [FastString] -> [RealLocated Token] -> Maybe (RealLocated Token) -> RealSrcSpan -> [ALRContext] -> Maybe ALRLayout -> Bool -> PState
buffer :: PState -> StringBuffer
dflags :: PState -> DynFlags
messages :: PState -> Messages
last_tk :: PState -> Maybe Token
last_loc :: PState -> RealSrcSpan
last_len :: PState -> !Int
loc :: PState -> RealSrcLoc
extsBitmap :: PState -> !Int
context :: PState -> [LayoutContext]
lex_state :: PState -> [Int]
srcfiles :: PState -> [FastString]
alr_pending_implicit_tokens :: PState -> [RealLocated Token]
alr_next_token :: PState -> Maybe (RealLocated Token)
alr_last_loc :: PState -> RealSrcSpan
alr_context :: PState -> [ALRContext]
alr_expecting_ocurly :: PState -> Maybe ALRLayout
alr_justClosedExplicitLetBlock :: PState -> Bool
newtype P a
P :: (PState -> ParseResult a) -> P a
unP :: P a -> PState -> ParseResult a
data ParseResult a
POk :: PState -> a -> ParseResult a
PFailed :: SrcSpan -> MsgDoc -> ParseResult a
getSrcLoc :: P RealSrcLoc
getPState :: P PState
getDynFlags :: HasDynFlags m => m DynFlags
withThisPackage :: (PackageId -> a) -> P a
failLocMsgP :: RealSrcLoc -> RealSrcLoc -> String -> P a
failSpanMsgP :: SrcSpan -> SDoc -> P a
srcParseFail :: P a
getMessages :: PState -> Messages
popContext :: P ()
pushCurrentContext :: P ()
setLastToken :: RealSrcSpan -> Int -> P ()
setSrcLoc :: RealSrcLoc -> P ()
activeContext :: P Bool
nextIsEOF :: P Bool
getLexState :: P Int
popLexState :: P Int
pushLexState :: Int -> P ()
extension :: (Int -> Bool) -> P Bool
bangPatEnabled :: Int -> Bool
datatypeContextsEnabled :: Int -> Bool
traditionalRecordSyntaxEnabled :: Int -> Bool
typeLiteralsEnabled :: Int -> Bool
explicitNamespacesEnabled :: Int -> Bool
addWarning :: WarningFlag -> SrcSpan -> SDoc -> P ()
lexTokenStream :: StringBuffer -> RealSrcLoc -> DynFlags -> ParseResult [Located Token]
instance Show Token
instance Show LayoutContext
instance Functor AlexLastAcc
instance HasDynFlags P
instance Monad P

module RdrHsSyn
mkHsOpApp :: LHsExpr id -> id -> LHsExpr id -> HsExpr id
mkHsIntegral :: Integer -> PostTcType -> HsOverLit id
mkHsFractional :: FractionalLit -> PostTcType -> HsOverLit id
mkHsIsString :: FastString -> PostTcType -> HsOverLit id
mkHsDo :: HsStmtContext Name -> [LStmt id] -> HsExpr id
mkHsSplice :: LHsExpr RdrName -> HsSplice RdrName
mkTopSpliceDecl :: LHsExpr RdrName -> HsDecl RdrName
mkClassDecl :: SrcSpan -> Located (Maybe (LHsContext RdrName), LHsType RdrName) -> Located [Located (FunDep RdrName)] -> Located (OrdList (LHsDecl RdrName)) -> P (LTyClDecl RdrName)
mkTyData :: SrcSpan -> NewOrData -> Maybe CType -> Located (Maybe (LHsContext RdrName), LHsType RdrName) -> Maybe (LHsKind RdrName) -> [LConDecl RdrName] -> Maybe [LHsType RdrName] -> P (LTyClDecl RdrName)
mkFamInstData :: SrcSpan -> NewOrData -> Maybe CType -> Located (Maybe (LHsContext RdrName), LHsType RdrName) -> Maybe (LHsKind RdrName) -> [LConDecl RdrName] -> Maybe [LHsType RdrName] -> P (LFamInstDecl RdrName)
mkTySynonym :: SrcSpan -> LHsType RdrName -> LHsType RdrName -> P (LTyClDecl RdrName)
mkFamInstSynonym :: SrcSpan -> LHsType RdrName -> LHsType RdrName -> P (LFamInstDecl RdrName)
mkTyFamily :: SrcSpan -> FamilyFlavour -> LHsType RdrName -> Maybe (LHsKind RdrName) -> P (LTyClDecl RdrName)
splitCon :: LHsType RdrName -> P (Located RdrName, HsConDeclDetails RdrName)
mkInlinePragma :: (InlineSpec, RuleMatchInfo) -> Maybe Activation -> InlinePragma
mkRecConstrOrUpdate :: LHsExpr RdrName -> SrcSpan -> ([HsRecField RdrName (LHsExpr RdrName)], Bool) -> P (HsExpr RdrName)
mkTyLit :: Located (HsTyLit) -> P (LHsType RdrName)
cvBindGroup :: OrdList (LHsDecl RdrName) -> HsValBinds RdrName
cvBindsAndSigs :: OrdList (LHsDecl RdrName) -> (Bag (LHsBind RdrName), [LSig RdrName], [LTyClDecl RdrName], [LFamInstDecl RdrName], [LDocDecl])
cvTopDecls :: OrdList (LHsDecl RdrName) -> [LHsDecl RdrName]
placeHolderPunRhs :: LHsExpr RdrName
mkImport :: CCallConv -> Safety -> (Located FastString, Located RdrName, LHsType RdrName) -> P (HsDecl RdrName)
parseCImport :: CCallConv -> Safety -> FastString -> String -> Maybe ForeignImport
mkExport :: CCallConv -> (Located FastString, Located RdrName, LHsType RdrName) -> P (HsDecl RdrName)
mkExtName :: RdrName -> CLabelString
mkGadtDecl :: [Located RdrName] -> LHsType RdrName -> [ConDecl RdrName]
mkSimpleConDecl :: Located RdrName -> [LHsTyVarBndr RdrName] -> LHsContext RdrName -> HsConDeclDetails RdrName -> ConDecl RdrName
mkDeprecatedGadtRecordDecl :: SrcSpan -> Located RdrName -> [ConDeclField RdrName] -> LHsType RdrName -> P (LConDecl RdrName)
checkPrecP :: Located Int -> P Int
checkContext :: LHsType RdrName -> P (LHsContext RdrName)
checkTyVars :: LHsType RdrName -> [LHsType RdrName] -> P (LHsTyVarBndrs RdrName)
checkPattern :: LHsExpr RdrName -> P (LPat RdrName)
bang_RDR :: RdrName
checkPatterns :: [LHsExpr RdrName] -> P [LPat RdrName]
checkMonadComp :: P (HsStmtContext Name)
checkValDef :: LHsExpr RdrName -> Maybe (LHsType RdrName) -> Located (GRHSs RdrName) -> P (HsBind RdrName)
checkValSig :: LHsExpr RdrName -> LHsType RdrName -> P (Sig RdrName)
checkDoAndIfThenElse :: LHsExpr RdrName -> Bool -> LHsExpr RdrName -> Bool -> LHsExpr RdrName -> P ()
checkRecordSyntax :: Outputable a => Located a -> P (Located a)
parseError :: SrcSpan -> String -> P a
parseErrorSDoc :: SrcSpan -> SDoc -> P a
data ImpExpSubSpec
ImpExpAbs :: ImpExpSubSpec
ImpExpAll :: ImpExpSubSpec
ImpExpList :: [RdrName] -> ImpExpSubSpec
mkModuleImpExp :: RdrName -> ImpExpSubSpec -> IE RdrName
mkTypeImpExp :: Located RdrName -> P (Located RdrName)

module Convert
convertToHsExpr :: SrcSpan -> Exp -> Either MsgDoc (LHsExpr RdrName)
convertToPat :: SrcSpan -> Pat -> Either MsgDoc (LPat RdrName)
convertToHsDecls :: SrcSpan -> [Dec] -> Either MsgDoc [LHsDecl RdrName]
convertToHsType :: SrcSpan -> Type -> Either MsgDoc (LHsType RdrName)
thRdrNameGuesses :: Name -> [RdrName]
instance Monad CvtM

module ParserCore
parseCore :: P (HsExtCore RdrName)

module CoreSubst

-- | A substitution environment, containing both <a>Id</a> and <a>TyVar</a>
--   substitutions.
--   
--   Some invariants apply to how you use the substitution:
--   
--   <ol>
--   <li>The in-scope set contains at least those <a>Id</a>s and
--   <a>TyVar</a>s that will be in scope <i>after</i> applying the
--   substitution to a term. Precisely, the in-scope set must be a superset
--   of the free vars of the substitution range that might possibly clash
--   with locally-bound variables in the thing being substituted in.</li>
--   <li>You may apply the substitution only <i>once</i></li>
--   </ol>
--   
--   There are various ways of setting up the in-scope set such that the
--   first of these invariants hold:
--   
--   <ul>
--   <li>Arrange that the in-scope set really is all the things in
--   scope</li>
--   <li>Arrange that it's the free vars of the range of the
--   substitution</li>
--   <li>Make it empty, if you know that all the free vars of the
--   substitution are fresh, and hence can't possibly clash</li>
--   </ul>
data Subst
Subst :: InScopeSet -> IdSubstEnv -> TvSubstEnv -> CvSubstEnv -> Subst

-- | A substitition of <a>Type</a>s for <a>TyVar</a>s and <a>Kind</a>s for
--   <a>KindVar</a>s
type TvSubstEnv = TyVarEnv Type

-- | An environment for substituting for <a>Id</a>s
type IdSubstEnv = IdEnv CoreExpr

-- | A set of variables that are in scope at some point
data InScopeSet

-- | De-shadowing the program is sometimes a useful pre-pass. It can be
--   done simply by running over the bindings with an empty substitution,
--   becuase substitution returns a result that has no-shadowing
--   guaranteed.
--   
--   (Actually, within a single <i>type</i> there might still be shadowing,
--   because <a>substTy</a> is a no-op for the empty substitution, but
--   that's probably OK.)
--   
--   <ul>
--   <li><i>Aug 09</i> This function is not used in GHC at the moment, but
--   seems so short and simple that I'm going to leave it here</li>
--   </ul>
deShadowBinds :: CoreProgram -> CoreProgram

-- | Substitutes for the <a>Id</a>s within the <tt>WorkerInfo</tt> given
--   the new function <a>Id</a>
substSpec :: Subst -> Id -> SpecInfo -> SpecInfo
substRulesForImportedIds :: Subst -> [CoreRule] -> [CoreRule]

-- | See <a>substTy</a>
substTy :: Subst -> Type -> Type

-- | See <a>substCo</a>
substCo :: Subst -> Coercion -> Coercion
substExpr :: SDoc -> Subst -> CoreExpr -> CoreExpr

-- | Apply a substititon to an entire <a>CoreExpr</a>. Rememeber, you may
--   only apply the substitution <i>once</i>: see
--   <a>CoreSubst#apply_once</a>
--   
--   Do *not* attempt to short-cut in the case of an empty substitution!
--   See Note [Extending the Subst]
substExprSC :: SDoc -> Subst -> CoreExpr -> CoreExpr

-- | Apply a substititon to an entire <a>CoreBind</a>, additionally
--   returning an updated <a>Subst</a> that should be used by subsequent
--   substitutons.
substBind :: Subst -> CoreBind -> (Subst, CoreBind)

-- | Apply a substititon to an entire <a>CoreBind</a>, additionally
--   returning an updated <a>Subst</a> that should be used by subsequent
--   substitutons.
substBindSC :: Subst -> CoreBind -> (Subst, CoreBind)

-- | Substitutes for the <a>Id</a>s within an unfolding
substUnfolding :: Subst -> Unfolding -> Unfolding

-- | Substitutes for the <a>Id</a>s within an unfolding
substUnfoldingSC :: Subst -> Unfolding -> Unfolding
substUnfoldingSource :: Subst -> UnfoldingSource -> UnfoldingSource

-- | Find the substitution for an <a>Id</a> in the <a>Subst</a>
lookupIdSubst :: SDoc -> Subst -> Id -> CoreExpr

-- | Find the substitution for a <a>TyVar</a> in the <a>Subst</a>
lookupTvSubst :: Subst -> TyVar -> Type

-- | Find the coercion substitution for a <a>CoVar</a> in the <a>Subst</a>
lookupCvSubst :: Subst -> CoVar -> Coercion
substIdOcc :: Subst -> Id -> Id
substTickish :: Subst -> Tickish Id -> Tickish Id
emptySubst :: Subst
mkEmptySubst :: InScopeSet -> Subst
mkSubst :: InScopeSet -> TvSubstEnv -> CvSubstEnv -> IdSubstEnv -> Subst

-- | Simultaneously substitute for a bunch of variables No left-right
--   shadowing ie the substitution for (x y. e) a1 a2 so neither x nor y
--   scope over a1 a2
mkOpenSubst :: InScopeSet -> [(Var, CoreArg)] -> Subst

-- | Find the in-scope set: see <a>CoreSubst#in_scope_invariant</a>
substInScope :: Subst -> InScopeSet
isEmptySubst :: Subst -> Bool

-- | Add a substitution for an <a>Id</a> to the <a>Subst</a>: you must
--   ensure that the in-scope set is such that the
--   <a>CoreSubst#in_scope_invariant</a> is true after extending the
--   substitution like this
extendIdSubst :: Subst -> Id -> CoreExpr -> Subst

-- | Adds multiple <a>Id</a> substitutions to the <a>Subst</a>: see also
--   <a>extendIdSubst</a>
extendIdSubstList :: Subst -> [(Id, CoreExpr)] -> Subst

-- | Add a substitution for a <a>TyVar</a> to the <a>Subst</a>: you must
--   ensure that the in-scope set is such that the
--   <a>CoreSubst#in_scope_invariant</a> is true after extending the
--   substitution like this
extendTvSubst :: Subst -> TyVar -> Type -> Subst

-- | Adds multiple <a>TyVar</a> substitutions to the <a>Subst</a>: see also
--   <a>extendTvSubst</a>
extendTvSubstList :: Subst -> [(TyVar, Type)] -> Subst

-- | Add a substitution from a <a>CoVar</a> to a <a>Coercion</a> to the
--   <a>Subst</a>: you must ensure that the in-scope set is such that the
--   <a>CoreSubst#in_scope_invariant</a> is true after extending the
--   substitution like this
extendCvSubst :: Subst -> CoVar -> Coercion -> Subst

-- | Adds multiple <a>CoVar</a> -&gt; <a>Coercion</a> substitutions to the
--   <a>Subst</a>: see also <a>extendCvSubst</a>
extendCvSubstList :: Subst -> [(CoVar, Coercion)] -> Subst

-- | Add a substitution appropriate to the thing being substituted (whether
--   an expression, type, or coercion). See also <a>extendIdSubst</a>,
--   <a>extendTvSubst</a>, and <a>extendCvSubst</a>.
extendSubst :: Subst -> Var -> CoreArg -> Subst

-- | Add a substitution as appropriate to each of the terms being
--   substituted (whether expressions, types, or coercions). See also
--   <a>extendSubst</a>.
extendSubstList :: Subst -> [(Var, CoreArg)] -> Subst
extendSubstWithVar :: Subst -> Var -> Var -> Subst

-- | Remove all substitutions for <a>Id</a>s and <a>Var</a>s that might
--   have been built up while preserving the in-scope set
zapSubstEnv :: Subst -> Subst

-- | Add the <a>Var</a> to the in-scope set, but do not remove any existing
--   substitutions for it
addInScopeSet :: Subst -> VarSet -> Subst

-- | Add the <a>Var</a> to the in-scope set: as a side effect, and remove
--   any existing substitutions for it
extendInScope :: Subst -> Var -> Subst

-- | Add the <a>Var</a>s to the in-scope set: see also <a>extendInScope</a>
extendInScopeList :: Subst -> [Var] -> Subst

-- | Optimized version of <a>extendInScopeList</a> that can be used if you
--   are certain all the things being added are <a>Id</a>s and hence none
--   are <a>TyVar</a>s or <a>CoVar</a>s
extendInScopeIds :: Subst -> [Id] -> Subst
isInScope :: Var -> Subst -> Bool
setInScope :: Subst -> InScopeSet -> Subst
delBndr :: Subst -> Var -> Subst
delBndrs :: Subst -> [Var] -> Subst

-- | Substitutes a <a>Var</a> for another one according to the <a>Subst</a>
--   given, returning the result and an updated <a>Subst</a> that should be
--   used by subsequent substitutons. <a>IdInfo</a> is preserved by this
--   process, although it is substituted into appropriately.
substBndr :: Subst -> Var -> (Subst, Var)

-- | Applies <a>substBndr</a> to a number of <a>Var</a>s, accumulating a
--   new <a>Subst</a> left-to-right
substBndrs :: Subst -> [Var] -> (Subst, [Var])

-- | Substitute in a mutually recursive group of <a>Id</a>s
substRecBndrs :: Subst -> [Id] -> (Subst, [Id])
cloneBndr :: Subst -> Unique -> Var -> (Subst, Var)
cloneBndrs :: Subst -> UniqSupply -> [Var] -> (Subst, [Var])

-- | Very similar to <a>substBndr</a>, but it always allocates a new
--   <a>Unique</a> for each variable in its output. It substitutes the
--   IdInfo though.
cloneIdBndr :: Subst -> UniqSupply -> Id -> (Subst, Id)

-- | Applies <a>cloneIdBndr</a> to a number of <a>Id</a>s, accumulating a
--   final substitution from left to right
cloneIdBndrs :: Subst -> UniqSupply -> [Id] -> (Subst, [Id])

-- | Clone a mutually recursive group of <a>Id</a>s
cloneRecIdBndrs :: Subst -> UniqSupply -> [Id] -> (Subst, [Id])
simpleOptPgm :: DynFlags -> Module -> CoreProgram -> [CoreRule] -> [CoreVect] -> IO (CoreProgram, [CoreRule], [CoreVect])
simpleOptExpr :: CoreExpr -> CoreExpr
simpleOptExprWith :: Subst -> InExpr -> OutExpr

-- | Returns <tt>Just (dc, [t1..tk], [x1..xn])</tt> if the argument
--   expression is a *saturated* constructor application of the form <tt>dc
--   t1..tk x1 .. xn</tt>, where t1..tk are the *universally-qantified*
--   type args of <tt>dc</tt>
exprIsConApp_maybe :: IdUnfoldingFun -> CoreExpr -> Maybe (DataCon, [Type], [CoreExpr])
exprIsLiteral_maybe :: IdUnfoldingFun -> CoreExpr -> Maybe Literal
instance Outputable Subst


-- | Arit and eta expansion
module CoreArity

-- | manifestArity sees how many leading value lambdas there are
manifestArity :: CoreExpr -> Arity

-- | An approximate, fast, version of <a>exprEtaExpandArity</a>
exprArity :: CoreExpr -> Arity
exprBotStrictness_maybe :: CoreExpr -> Maybe (Arity, StrictSig)
exprEtaExpandArity :: DynFlags -> CheapAppFun -> CoreExpr -> Arity
type CheapFun = CoreExpr -> Maybe Type -> Bool

-- | <tt>etaExpand n us e ty</tt> returns an expression with the same
--   meaning as <tt>e</tt>, but with arity <tt>n</tt>.
--   
--   Given:
--   
--   <pre>
--   e' = etaExpand n us e ty
--   </pre>
--   
--   We should have that:
--   
--   <pre>
--   ty = exprType e = exprType e'
--   </pre>
etaExpand :: Arity -> CoreExpr -> CoreExpr
instance Outputable EtaInfo

module CoreUnfold

-- | Records the <i>unfolding</i> of an identifier, which is approximately
--   the form the identifier would have if we substituted its definition in
--   for the identifier. This type should be treated as abstract everywhere
--   except in <a>CoreUnfold</a>
data Unfolding

-- | <a>UnfoldingGuidance</a> says when unfolding should take place
data UnfoldingGuidance

-- | There is no known <a>Unfolding</a>
noUnfolding :: Unfolding
mkImplicitUnfolding :: CoreExpr -> Unfolding
mkUnfolding :: UnfoldingSource -> Bool -> Bool -> CoreExpr -> Unfolding
mkCoreUnfolding :: UnfoldingSource -> Bool -> CoreExpr -> Arity -> UnfoldingGuidance -> Unfolding
mkTopUnfolding :: Bool -> CoreExpr -> Unfolding
mkSimpleUnfolding :: CoreExpr -> Unfolding
mkInlineUnfolding :: Maybe Arity -> CoreExpr -> Unfolding
mkInlinableUnfolding :: CoreExpr -> Unfolding
mkWwInlineRule :: Id -> CoreExpr -> Arity -> Unfolding
mkCompulsoryUnfolding :: CoreExpr -> Unfolding
mkDFunUnfolding :: Type -> [DFunArg CoreExpr] -> Unfolding
interestingArg :: CoreExpr -> ArgSummary
data ArgSummary
TrivArg :: ArgSummary
NonTrivArg :: ArgSummary
ValueArg :: ArgSummary
couldBeSmallEnoughToInline :: Int -> CoreExpr -> Bool
inlineBoringOk :: CoreExpr -> Bool
certainlyWillInline :: Unfolding -> Bool
smallEnoughToInline :: Unfolding -> Bool
callSiteInline :: DynFlags -> Id -> Bool -> Bool -> [ArgSummary] -> CallCtxt -> Maybe CoreExpr
data CallCtxt
BoringCtxt :: CallCtxt
ArgCtxt :: Bool -> CallCtxt
ValAppCtxt :: CallCtxt
CaseCtxt :: CallCtxt

-- | Returns <tt>Just (dc, [t1..tk], [x1..xn])</tt> if the argument
--   expression is a *saturated* constructor application of the form <tt>dc
--   t1..tk x1 .. xn</tt>, where t1..tk are the *universally-qantified*
--   type args of <tt>dc</tt>
exprIsConApp_maybe :: IdUnfoldingFun -> CoreExpr -> Maybe (DataCon, [Type], [CoreExpr])
exprIsLiteral_maybe :: IdUnfoldingFun -> CoreExpr -> Maybe Literal
instance Outputable CallCtxt
instance Outputable ArgSummary
instance Outputable ExprSize

module CoreTidy
tidyExpr :: TidyEnv -> CoreExpr -> CoreExpr
tidyVarOcc :: TidyEnv -> Var -> Var
tidyRule :: TidyEnv -> CoreRule -> CoreRule
tidyRules :: TidyEnv -> [CoreRule] -> [CoreRule]
tidyUnfolding :: TidyEnv -> Unfolding -> Unfolding -> Unfolding


-- | Functions for collecting together and applying rewrite rules to a
--   module. The <a>CoreRule</a> datatype itself is declared elsewhere.
module Rules

-- | Gathers a collection of <a>CoreRule</a>s. Maps (the name of) an
--   <a>Id</a> to its rules
type RuleBase = NameEnv [CoreRule]
emptyRuleBase :: RuleBase
mkRuleBase :: [CoreRule] -> RuleBase
extendRuleBaseList :: RuleBase -> [CoreRule] -> RuleBase
unionRuleBase :: RuleBase -> RuleBase -> RuleBase
pprRuleBase :: RuleBase -> SDoc

-- | Report partial matches for rules beginning with the specified string
--   for the purposes of error reporting
ruleCheckProgram :: CompilerPhase -> String -> RuleBase -> CoreProgram -> SDoc

-- | Make a <a>SpecInfo</a> containing a number of <a>CoreRule</a>s,
--   suitable for putting into an <tt>IdInfo</tt>
mkSpecInfo :: [CoreRule] -> SpecInfo
extendSpecInfo :: SpecInfo -> [CoreRule] -> SpecInfo
addSpecInfo :: SpecInfo -> SpecInfo -> SpecInfo
addIdSpecialisations :: Id -> [CoreRule] -> Id

-- | Gather all the rules for locally bound identifiers from the supplied
--   bindings
rulesOfBinds :: [CoreBind] -> [CoreRule]
getRules :: RuleBase -> Id -> [CoreRule]
pprRulesForUser :: [CoreRule] -> SDoc

-- | The main rule matching function. Attempts to apply all (active)
--   supplied rules to this instance of an application in a given context,
--   returning the rule applied and the resulting expression if successful.
lookupRule :: (Activation -> Bool) -> IdUnfoldingFun -> InScopeSet -> Id -> [CoreExpr] -> [CoreRule] -> Maybe (CoreRule, CoreExpr)

-- | Used to make <a>CoreRule</a> for an <a>Id</a> defined in the module
--   being compiled. See also <a>CoreRule</a>
mkRule :: Bool -> Bool -> RuleName -> Activation -> Name -> [CoreBndr] -> [CoreExpr] -> CoreExpr -> CoreRule

-- | Find the "top" free names of several expressions. Such names are
--   either:
--   
--   <ol>
--   <li>The function finally being applied to in an application chain (if
--   that name is a GlobalId: see <a>Var#globalvslocal</a>), or</li>
--   <li>The <tt>TyCon</tt> if the expression is a <a>Type</a></li>
--   </ol>
--   
--   This is used for the fast-match-check for rules; if the top names
--   don't match, the rest can't
roughTopNames :: [CoreExpr] -> [Maybe Name]

module CSE
cseProgram :: CoreProgram -> CoreProgram

module IOEnv
data IOEnv env a
failM :: IOEnv env a
failWithM :: String -> IOEnv env a
data IOEnvFailure
IOEnvFailure :: IOEnvFailure
getEnv :: IOEnv env env

-- | Perform a computation with a different environment
setEnv :: env' -> IOEnv env' a -> IOEnv env a

-- | Perform a computation with an altered environment
updEnv :: (env -> env') -> IOEnv env' a -> IOEnv env a
runIOEnv :: env -> IOEnv env a -> IO a
unsafeInterleaveM :: IOEnv env a -> IOEnv env a
tryM :: IOEnv env r -> IOEnv env (Either IOEnvFailure r)
tryAllM :: IOEnv env r -> IOEnv env (Either SomeException r)
tryMostM :: IOEnv env r -> IOEnv env (Either SomeException r)
fixM :: (a -> IOEnv env a) -> IOEnv env a

-- | A mutable variable in the <a>IO</a> monad
data IORef a :: * -> *
newMutVar :: a -> IOEnv env (IORef a)
readMutVar :: IORef a -> IOEnv env a
writeMutVar :: IORef a -> a -> IOEnv env ()
updMutVar :: IORef a -> (a -> a) -> IOEnv env ()

-- | Atomically update the reference. Does not force the evaluation of the
--   new variable contents. For strict update, use <a>atomicUpdMutVar'</a>.
atomicUpdMutVar :: IORef a -> (a -> (a, b)) -> IOEnv env b

-- | Strict variant of <a>atomicUpdMutVar</a>.
atomicUpdMutVar' :: IORef a -> (a -> (a, b)) -> IOEnv env b
instance Typeable IOEnvFailure
instance MonadIO (IOEnv env)
instance MonadPlus IO => MonadPlus (IOEnv env)
instance ContainsDynFlags env => HasDynFlags (IOEnv env)
instance Exception IOEnvFailure
instance Show IOEnvFailure
instance Functor (IOEnv m)
instance Applicative (IOEnv m)
instance Monad (IOEnv m)

module LiberateCase
liberateCase :: DynFlags -> CoreProgram -> CoreProgram

module DmdAnal
dmdAnalPgm :: DynFlags -> CoreProgram -> IO CoreProgram
dmdAnalTopRhs :: CoreExpr -> (StrictSig, CoreExpr)
both :: Demand -> Demand -> Demand
instance Outputable AnalEnv

module SysTools
initSysTools :: Maybe String -> IO Settings
runUnlit :: DynFlags -> [Option] -> IO ()
runCpp :: DynFlags -> [Option] -> IO ()
runCc :: DynFlags -> [Option] -> IO ()
runPp :: DynFlags -> [Option] -> IO ()
runSplit :: DynFlags -> [Option] -> IO ()
runAs :: DynFlags -> [Option] -> IO ()
runLink :: DynFlags -> [Option] -> IO ()
runMkDLL :: DynFlags -> [Option] -> IO ()
runWindres :: DynFlags -> [Option] -> IO ()

-- | Run the LLVM Optimiser
runLlvmOpt :: DynFlags -> [Option] -> IO ()

-- | Run the LLVM Compiler
runLlvmLlc :: DynFlags -> [Option] -> IO ()

-- | Run the clang compiler (used as an assembler for the LLVM backend on
--   OS X as LLVM doesn't support the OS X system assembler)
runClang :: DynFlags -> [Option] -> IO ()

-- | Figure out which version of LLVM we are running this session
figureLlvmVersion :: DynFlags -> IO (Maybe Int)

-- | read the contents of the named section in an ELF object as a String.
readElfSection :: DynFlags -> String -> FilePath -> IO (Maybe String)
askCc :: DynFlags -> [Option] -> IO String
touch :: DynFlags -> String -> String -> IO ()
copy :: DynFlags -> String -> FilePath -> FilePath -> IO ()
copyWithHeader :: DynFlags -> String -> Maybe String -> FilePath -> FilePath -> IO ()
setTmpDir :: FilePath -> DynFlags -> DynFlags
newTempName :: DynFlags -> Suffix -> IO FilePath
cleanTempDirs :: DynFlags -> IO ()
cleanTempFiles :: DynFlags -> IO ()
cleanTempFilesExcept :: DynFlags -> [FilePath] -> IO ()
addFilesToClean :: DynFlags -> [FilePath] -> IO ()

-- | When invoking external tools as part of the compilation pipeline, we
--   pass these a sequence of options on the command-line. Rather than just
--   using a list of Strings, we use a type that allows us to distinguish
--   between filepaths and 'other stuff'. The reason for this is that this
--   type gives us a handle on transforming filenames, and filenames only,
--   to whatever format they're expected to be on a particular platform.
data Option
FileOption :: String -> String -> Option
Option :: String -> Option

module CLabel
data CLabel

-- | Record where a foreign label is stored.
data ForeignLabelSource

-- | Label is in a named package
ForeignLabelInPackage :: PackageId -> ForeignLabelSource

-- | Label is in some external, system package that doesn't also contain
--   compiled Haskell code, and is not associated with any .hi files. We
--   don't have to worry about Haskell code being inlined from external
--   packages. It is safe to treat the RTS package as <a>external</a>.
ForeignLabelInExternalPackage :: ForeignLabelSource

-- | Label is in the package currenly being compiled. This is only used for
--   creating hacky tmp labels during code generation. Don't use it in any
--   code that might be inlined across a package boundary (ie, core code)
--   else the information will be wrong relative to the destination module.
ForeignLabelInThisPackage :: ForeignLabelSource

-- | For debugging problems with the CLabel representation. We can't make a
--   Show instance for CLabel because lots of its components don't have
--   instances. The regular Outputable instance only shows the label name,
--   and not its other info.
pprDebugCLabel :: CLabel -> SDoc
mkClosureLabel :: Name -> CafInfo -> CLabel
mkSRTLabel :: Name -> CafInfo -> CLabel
mkInfoTableLabel :: Name -> CafInfo -> CLabel
mkEntryLabel :: Name -> CafInfo -> CLabel
mkSlowEntryLabel :: Name -> CafInfo -> CLabel
mkConEntryLabel :: Name -> CafInfo -> CLabel
mkStaticConEntryLabel :: Name -> CafInfo -> CLabel
mkRednCountsLabel :: Name -> CafInfo -> CLabel
mkConInfoTableLabel :: Name -> CafInfo -> CLabel
mkStaticInfoTableLabel :: Name -> CafInfo -> CLabel
mkLargeSRTLabel :: Unique -> CLabel
mkApEntryLabel :: Bool -> Int -> CLabel
mkApInfoTableLabel :: Bool -> Int -> CLabel
mkClosureTableLabel :: Name -> CafInfo -> CLabel
mkLocalClosureLabel :: Name -> CafInfo -> CLabel
mkLocalInfoTableLabel :: Name -> CafInfo -> CLabel
mkLocalEntryLabel :: Name -> CafInfo -> CLabel
mkLocalConEntryLabel :: CafInfo -> Name -> CLabel
mkLocalStaticConEntryLabel :: CafInfo -> Name -> CLabel
mkLocalConInfoTableLabel :: CafInfo -> Name -> CLabel
mkLocalStaticInfoTableLabel :: CafInfo -> Name -> CLabel
mkLocalClosureTableLabel :: Name -> CafInfo -> CLabel
mkReturnPtLabel :: Unique -> CLabel
mkReturnInfoLabel :: Unique -> CLabel
mkAltLabel :: Unique -> ConTag -> CLabel
mkDefaultLabel :: Unique -> CLabel
mkBitmapLabel :: Unique -> CLabel
mkStringLitLabel :: Unique -> CLabel
mkAsmTempLabel :: Uniquable a => a -> CLabel
mkPlainModuleInitLabel :: Module -> CLabel
mkSplitMarkerLabel :: CLabel
mkDirty_MUT_VAR_Label :: CLabel
mkUpdInfoLabel :: CLabel
mkBHUpdInfoLabel :: CLabel
mkIndStaticInfoLabel :: CLabel
mkMainCapabilityLabel :: CLabel
mkMAP_FROZEN_infoLabel :: CLabel
mkMAP_DIRTY_infoLabel :: CLabel
mkEMPTY_MVAR_infoLabel :: CLabel
mkTopTickyCtrLabel :: CLabel
mkCAFBlackHoleInfoTableLabel :: CLabel
mkCAFBlackHoleEntryLabel :: CLabel
mkRtsPrimOpLabel :: PrimOp -> CLabel
mkRtsSlowTickyCtrLabel :: String -> CLabel
mkSelectorInfoLabel :: Bool -> Int -> CLabel
mkSelectorEntryLabel :: Bool -> Int -> CLabel
mkCmmInfoLabel :: PackageId -> FastString -> CLabel
mkCmmEntryLabel :: PackageId -> FastString -> CLabel
mkCmmRetInfoLabel :: PackageId -> FastString -> CLabel
mkCmmRetLabel :: PackageId -> FastString -> CLabel
mkCmmCodeLabel :: PackageId -> FastString -> CLabel
mkCmmDataLabel :: PackageId -> FastString -> CLabel
mkCmmGcPtrLabel :: PackageId -> FastString -> CLabel
mkRtsApFastLabel :: FastString -> CLabel
mkPrimCallLabel :: PrimCall -> CLabel

-- | Make a foreign label
mkForeignLabel :: FastString -> Maybe Int -> ForeignLabelSource -> FunctionOrData -> CLabel

-- | Update the label size field in a ForeignLabel
addLabelSize :: CLabel -> Int -> CLabel

-- | Get the label size field from a ForeignLabel
foreignLabelStdcallInfo :: CLabel -> Maybe Int
mkCCLabel :: CostCentre -> CLabel
mkCCSLabel :: CostCentreStack -> CLabel
data DynamicLinkerLabelInfo
CodeStub :: DynamicLinkerLabelInfo
SymbolPtr :: DynamicLinkerLabelInfo
GotSymbolPtr :: DynamicLinkerLabelInfo
GotSymbolOffset :: DynamicLinkerLabelInfo
mkDynamicLinkerLabel :: DynamicLinkerLabelInfo -> CLabel -> CLabel
dynamicLinkerLabelInfo :: CLabel -> Maybe (DynamicLinkerLabelInfo, CLabel)
mkPicBaseLabel :: CLabel
mkDeadStripPreventer :: CLabel -> CLabel
mkHpcTicksLabel :: Module -> CLabel
hasCAF :: CLabel -> Bool
needsCDecl :: CLabel -> Bool

-- | Check whether a label is a local temporary for native code generation
isAsmTemp :: CLabel -> Bool

-- | If a label is a local temporary used for native code generation then
--   return just its unique, otherwise nothing.
maybeAsmTemp :: CLabel -> Maybe Unique

-- | Is a CLabel visible outside this object file or not? From the point of
--   view of the code generator, a name is externally visible if it has to
--   be declared as exported in the .o file's symbol table; that is, made
--   non-static.
externallyVisibleCLabel :: CLabel -> Bool

-- | Check whether a label corresponds to a C function that has a prototype
--   in a system header somehere, or is built-in to the C compiler. For
--   these labels we avoid generating our own C prototypes.
isMathFun :: CLabel -> Bool
isCFunctionLabel :: CLabel -> Bool
isGcPtrLabel :: CLabel -> Bool
labelDynamic :: DynFlags -> PackageId -> CLabel -> Bool
toClosureLbl :: CLabel -> CLabel
toSlowEntryLbl :: CLabel -> CLabel
toEntryLbl :: CLabel -> CLabel
toInfoLbl :: CLabel -> CLabel
toRednCountsLbl :: CLabel -> CLabel
pprCLabel :: Platform -> CLabel -> SDoc
instance Eq ForeignLabelSource
instance Ord ForeignLabelSource
instance Eq IdLabelInfo
instance Ord IdLabelInfo
instance Eq CaseLabelInfo
instance Ord CaseLabelInfo
instance Eq RtsLabelInfo
instance Ord RtsLabelInfo
instance Eq CmmLabelInfo
instance Ord CmmLabelInfo
instance Eq DynamicLinkerLabelInfo
instance Ord DynamicLinkerLabelInfo
instance Eq CLabel
instance Ord CLabel
instance Outputable ForeignLabelSource
instance Outputable CLabel

module BlockId
type BlockId = Label
mkBlockId :: Unique -> BlockId
type BlockSet = LabelSet
type BlockEnv a = LabelMap a
class IsSet set where type family ElemOf set1 :: *
setNull :: IsSet set => set -> Bool
setSize :: IsSet set => set -> Int
setMember :: IsSet set => ElemOf set -> set -> Bool
setEmpty :: IsSet set => set
setSingleton :: IsSet set => ElemOf set -> set
setInsert :: IsSet set => ElemOf set -> set -> set
setDelete :: IsSet set => ElemOf set -> set -> set
setUnion :: IsSet set => set -> set -> set
setDifference :: IsSet set => set -> set -> set
setIntersection :: IsSet set => set -> set -> set
setIsSubsetOf :: IsSet set => set -> set -> Bool
setFold :: IsSet set => (ElemOf set -> b -> b) -> b -> set -> b
setElems :: IsSet set => set -> [ElemOf set]
setFromList :: IsSet set => [ElemOf set] -> set
setInsertList :: IsSet set => [ElemOf set] -> set -> set
setDeleteList :: IsSet set => [ElemOf set] -> set -> set
setUnions :: IsSet set => [set] -> set
class IsMap (map :: * -> *) where type family KeyOf (map1 :: * -> *) :: *
mapNull :: IsMap map => map a -> Bool
mapSize :: IsMap map => map a -> Int
mapMember :: IsMap map => KeyOf map -> map a -> Bool
mapLookup :: IsMap map => KeyOf map -> map a -> Maybe a
mapFindWithDefault :: IsMap map => a -> KeyOf map -> map a -> a
mapEmpty :: IsMap map => map a
mapSingleton :: IsMap map => KeyOf map -> a -> map a
mapInsert :: IsMap map => KeyOf map -> a -> map a -> map a
mapInsertWith :: IsMap map => (a -> a -> a) -> KeyOf map -> a -> map a -> map a
mapDelete :: IsMap map => KeyOf map -> map a -> map a
mapUnion :: IsMap map => map a -> map a -> map a
mapUnionWithKey :: IsMap map => (KeyOf map -> a -> a -> a) -> map a -> map a -> map a
mapDifference :: IsMap map => map a -> map a -> map a
mapIntersection :: IsMap map => map a -> map a -> map a
mapIsSubmapOf :: (IsMap map, Eq a) => map a -> map a -> Bool
mapMap :: IsMap map => (a -> b) -> map a -> map b
mapMapWithKey :: IsMap map => (KeyOf map -> a -> b) -> map a -> map b
mapFold :: IsMap map => (a -> b -> b) -> b -> map a -> b
mapFoldWithKey :: IsMap map => (KeyOf map -> a -> b -> b) -> b -> map a -> b
mapElems :: IsMap map => map a -> [a]
mapKeys :: IsMap map => map a -> [KeyOf map]
mapToList :: IsMap map => map a -> [(KeyOf map, a)]
mapFromList :: IsMap map => [(KeyOf map, a)] -> map a
mapFromListWith :: IsMap map => (a -> a -> a) -> [(KeyOf map, a)] -> map a
mapInsertList :: IsMap map => [(KeyOf map, a)] -> map a -> map a
mapDeleteList :: IsMap map => [KeyOf map] -> map a -> map a
mapUnions :: IsMap map => [map a] -> map a
emptyBlockSet :: BlockSet
emptyBlockMap :: BlockEnv a
blockLbl :: BlockId -> CLabel
infoTblLbl :: BlockId -> CLabel
retPtLbl :: BlockId -> CLabel
instance Outputable BlockSet
instance Outputable a => Outputable (BlockEnv a)
instance Outputable BlockId
instance Uniquable BlockId

module CmmExpr
data CmmExpr
CmmLit :: CmmLit -> CmmExpr
CmmLoad :: !CmmExpr -> !CmmType -> CmmExpr
CmmReg :: !CmmReg -> CmmExpr
CmmMachOp :: MachOp -> [CmmExpr] -> CmmExpr
CmmStackSlot :: Area -> {-# UNPACK #-} !Int -> CmmExpr
CmmRegOff :: !CmmReg -> Int -> CmmExpr
cmmExprType :: CmmExpr -> CmmType
cmmExprWidth :: CmmExpr -> Width
maybeInvertCmmExpr :: CmmExpr -> Maybe CmmExpr
data CmmReg
CmmLocal :: {-# UNPACK #-} !LocalReg -> CmmReg
CmmGlobal :: GlobalReg -> CmmReg
cmmRegType :: CmmReg -> CmmType
data CmmLit
CmmInt :: !Integer -> Width -> CmmLit
CmmFloat :: Rational -> Width -> CmmLit
CmmLabel :: CLabel -> CmmLit
CmmLabelOff :: CLabel -> Int -> CmmLit
CmmLabelDiffOff :: CLabel -> CLabel -> Int -> CmmLit
CmmBlock :: {-# UNPACK #-} !BlockId -> CmmLit
CmmHighStackMark :: CmmLit
cmmLitType :: CmmLit -> CmmType
data LocalReg

-- | Parameters: 1. Identifier 2. Type
LocalReg :: {-# UNPACK #-} !Unique -> CmmType -> LocalReg
localRegType :: LocalReg -> CmmType
data GlobalReg
VanillaReg :: {-# UNPACK #-} !Int -> VGcPtr -> GlobalReg
FloatReg :: {-# UNPACK #-} !Int -> GlobalReg
DoubleReg :: {-# UNPACK #-} !Int -> GlobalReg
LongReg :: {-# UNPACK #-} !Int -> GlobalReg
Sp :: GlobalReg
SpLim :: GlobalReg
Hp :: GlobalReg
HpLim :: GlobalReg
CCCS :: GlobalReg
CurrentTSO :: GlobalReg
CurrentNursery :: GlobalReg
HpAlloc :: GlobalReg
EagerBlackholeInfo :: GlobalReg
GCEnter1 :: GlobalReg
GCFun :: GlobalReg
BaseReg :: GlobalReg
PicBaseReg :: GlobalReg
globalRegType :: GlobalReg -> CmmType
spReg :: CmmReg
hpReg :: CmmReg
spLimReg :: CmmReg
nodeReg :: CmmReg
node :: GlobalReg
baseReg :: CmmReg
data VGcPtr
VGcPtr :: VGcPtr
VNonGcPtr :: VGcPtr
vgcFlag :: CmmType -> VGcPtr
class DefinerOfLocalRegs a
foldRegsDefd :: DefinerOfLocalRegs a => (b -> LocalReg -> b) -> b -> a -> b
class UserOfLocalRegs a
foldRegsUsed :: UserOfLocalRegs a => (b -> LocalReg -> b) -> b -> a -> b
filterRegsUsed :: UserOfLocalRegs e => (LocalReg -> Bool) -> e -> RegSet

-- | Sets of local registers
type RegSet = Set LocalReg
emptyRegSet :: RegSet
elemRegSet :: LocalReg -> RegSet -> Bool
extendRegSet :: RegSet -> LocalReg -> RegSet
deleteFromRegSet :: RegSet -> LocalReg -> RegSet
mkRegSet :: [LocalReg] -> RegSet
plusRegSet :: RegSet -> RegSet -> RegSet
minusRegSet :: RegSet -> RegSet -> RegSet
timesRegSet :: RegSet -> RegSet -> RegSet
sizeRegSet :: RegSet -> Int
nullRegSet :: RegSet -> Bool
regSetToList :: RegSet -> [LocalReg]
regUsedIn :: CmmReg -> CmmExpr -> Bool

-- | A stack area is either the stack slot where a variable is spilled or
--   the stack space where function arguments and results are passed.
data Area
Old :: Area
Young :: {-# UNPACK #-} !BlockId -> Area
instance Eq Area
instance Ord Area
instance Eq CmmLit
instance Eq VGcPtr
instance Show VGcPtr
instance Show GlobalReg
instance Eq CmmReg
instance Ord CmmReg
instance Ord GlobalReg
instance Eq GlobalReg
instance DefinerOfLocalRegs a => DefinerOfLocalRegs (Maybe a)
instance DefinerOfLocalRegs a => DefinerOfLocalRegs [a]
instance UserOfLocalRegs a => UserOfLocalRegs [a]
instance UserOfLocalRegs CmmExpr
instance UserOfLocalRegs RegSet
instance DefinerOfLocalRegs LocalReg
instance UserOfLocalRegs LocalReg
instance DefinerOfLocalRegs CmmReg
instance UserOfLocalRegs CmmReg
instance UserOfLocalRegs a => UserOfLocalRegs (Maybe a)
instance Uniquable LocalReg
instance Ord LocalReg
instance Eq LocalReg
instance Eq CmmExpr


-- | Deal with Cmm registers
module LlvmCodeGen.Regs

-- | Get the LlvmVar function argument storing the real register
lmGlobalRegArg :: GlobalReg -> LlvmVar

-- | Get the LlvmVar function variable storing the real register
lmGlobalRegVar :: GlobalReg -> LlvmVar

-- | A list of STG Registers that should always be considered alive
alwaysLive :: [GlobalReg]

-- | STG Type Based Alias Analysis metadata
stgTBAA :: [LlvmMeta]

-- | The various TBAA types
top :: MetaData

-- | The various TBAA types
base :: MetaData

-- | The various TBAA types
stack :: MetaData

-- | The various TBAA types
heap :: MetaData

-- | The various TBAA types
rx :: MetaData

-- | The various TBAA types
other :: MetaData

-- | The TBAA metadata identifier
tbaa :: LMString

-- | Get the correct TBAA metadata information for this register type
getTBAA :: GlobalReg -> MetaData

module CmmNode
data CmmNode e x
CmmEntry :: {-# UNPACK #-} !Label -> CmmNode C O
CmmComment :: FastString -> CmmNode O O
CmmAssign :: !CmmReg -> !CmmExpr -> CmmNode O O
CmmStore :: !CmmExpr -> !CmmExpr -> CmmNode O O
CmmUnsafeForeignCall :: ForeignTarget -> [CmmFormal] -> [CmmActual] -> CmmNode O O
CmmBranch :: {-# UNPACK #-} !Label -> CmmNode O C
CmmCondBranch :: CmmExpr -> {-# UNPACK #-} !Label -> {-# UNPACK #-} !Label -> CmmNode O C
cml_pred :: CmmNode O C -> CmmExpr
cml_true :: CmmNode O C -> {-# UNPACK #-} !Label
cml_false :: CmmNode O C -> {-# UNPACK #-} !Label
CmmSwitch :: CmmExpr -> [Maybe Label] -> CmmNode O C
CmmCall :: CmmExpr -> Maybe Label -> [GlobalReg] -> ByteOff -> ByteOff -> ByteOff -> CmmNode O C
cml_target :: CmmNode O C -> CmmExpr
cml_cont :: CmmNode O C -> Maybe Label
cml_args_regs :: CmmNode O C -> [GlobalReg]
cml_args :: CmmNode O C -> ByteOff
cml_ret_args :: CmmNode O C -> ByteOff
cml_ret_off :: CmmNode O C -> ByteOff
CmmForeignCall :: ForeignTarget -> [CmmFormal] -> [CmmActual] -> {-# UNPACK #-} !Label -> UpdFrameOffset -> Bool -> CmmNode O C
tgt :: CmmNode O C -> ForeignTarget
res :: CmmNode O C -> [CmmFormal]
args :: CmmNode O C -> [CmmActual]
succ :: CmmNode O C -> {-# UNPACK #-} !Label
updfr :: CmmNode O C -> UpdFrameOffset
intrbl :: CmmNode O C -> Bool
data ForeignHint
NoHint :: ForeignHint
AddrHint :: ForeignHint
SignedHint :: ForeignHint
type CmmFormal = LocalReg
type CmmActual = CmmExpr
type UpdFrameOffset = ByteOff
data Convention
NativeDirectCall :: Convention
NativeNodeCall :: Convention
NativeReturn :: Convention
Slow :: Convention
GC :: Convention
PrimOpCall :: Convention
PrimOpReturn :: Convention
data ForeignConvention
ForeignConvention :: CCallConv -> [ForeignHint] -> [ForeignHint] -> ForeignConvention
data ForeignTarget
ForeignTarget :: CmmExpr -> ForeignConvention -> ForeignTarget
PrimTarget :: CallishMachOp -> ForeignTarget
mapExp :: (CmmExpr -> CmmExpr) -> CmmNode e x -> CmmNode e x
mapExpDeep :: (CmmExpr -> CmmExpr) -> CmmNode e x -> CmmNode e x
wrapRecExp :: (CmmExpr -> CmmExpr) -> CmmExpr -> CmmExpr
foldExp :: (CmmExpr -> z -> z) -> CmmNode e x -> z -> z
foldExpDeep :: (CmmExpr -> z -> z) -> CmmNode e x -> z -> z
wrapRecExpf :: (CmmExpr -> z -> z) -> CmmExpr -> z -> z
mapExpM :: (CmmExpr -> Maybe CmmExpr) -> CmmNode e x -> Maybe (CmmNode e x)
mapExpDeepM :: (CmmExpr -> Maybe CmmExpr) -> CmmNode e x -> Maybe (CmmNode e x)
wrapRecExpM :: (CmmExpr -> Maybe CmmExpr) -> (CmmExpr -> Maybe CmmExpr)
mapSuccessors :: (Label -> Label) -> CmmNode O C -> CmmNode O C
instance Eq Convention
instance Eq ForeignHint
instance Eq ForeignConvention
instance Eq ForeignTarget
instance DefinerOfLocalRegs (CmmNode e x)
instance UserOfLocalRegs ForeignTarget
instance UserOfLocalRegs (CmmNode e x)
instance NonLocal CmmNode
instance Eq (CmmNode e x)

module PprCmmExpr
pprExpr :: CmmExpr -> SDoc
pprLit :: CmmLit -> SDoc
pprExpr9 :: CmmExpr -> SDoc
instance Outputable GlobalReg
instance Outputable Area
instance Outputable LocalReg
instance Outputable CmmLit
instance Outputable CmmReg
instance Outputable CmmExpr


-- | Nasty #ifdefery that generates the definitions for freeReg and
--   globalRegMaybe from the information in includes/MachRegs.h.
--   
--   If the current TARGET_ARCH isn't sparc then these functions will be
--   wrong.
module SPARC.RegPlate
freeReg :: RegNo -> FastBool
globalRegMaybe :: GlobalReg -> Maybe RealReg

module Cmm
type CmmProgram = [CmmGroup]
type CmmGroup = GenCmmGroup CmmStatics CmmTopInfo CmmGraph
type GenCmmGroup d h g = [GenCmmDecl d h g]
type CmmDecl = GenCmmDecl CmmStatics CmmTopInfo CmmGraph

-- | A top-level chunk, abstracted over the type of the contents of the
--   basic blocks (Cmm or instructions are the likely instantiations).
data GenCmmDecl d h g
CmmProc :: h -> CLabel -> g -> GenCmmDecl d h g
CmmData :: Section -> d -> GenCmmDecl d h g
type CmmGraph = GenCmmGraph CmmNode
data GenCmmGraph n
CmmGraph :: BlockId -> Graph n C C -> GenCmmGraph n
g_entry :: GenCmmGraph n -> BlockId
g_graph :: GenCmmGraph n -> Graph n C C
type CmmBlock = Block CmmNode C C
data Section
Text :: Section
Data :: Section
ReadOnlyData :: Section
RelocatableReadOnlyData :: Section
UninitialisedData :: Section
ReadOnlyData16 :: Section
OtherSection :: String -> Section
data CmmStatics
Statics :: CLabel -> [CmmStatic] -> CmmStatics
data CmmStatic
CmmStaticLit :: CmmLit -> CmmStatic
CmmUninitialised :: Int -> CmmStatic
CmmString :: [Word8] -> CmmStatic
type CmmReplGraph e x = GenCmmReplGraph CmmNode e x
type GenCmmReplGraph n e x = UniqSM (Maybe (Graph n e x))
type CmmFwdRewrite f = FwdRewrite UniqSM CmmNode f
type CmmBwdRewrite f = BwdRewrite UniqSM CmmNode f
data CmmTopInfo
TopInfo :: CmmInfoTable -> CmmStackInfo -> CmmTopInfo
info_tbl :: CmmTopInfo -> CmmInfoTable
stack_info :: CmmTopInfo -> CmmStackInfo
data CmmStackInfo
StackInfo :: ByteOff -> Maybe ByteOff -> CmmStackInfo
arg_space :: CmmStackInfo -> ByteOff
updfr_space :: CmmStackInfo -> Maybe ByteOff

-- | Info table as a haskell data type
data CmmInfoTable
CmmInfoTable :: CLabel -> SMRep -> ProfilingInfo -> C_SRT -> CmmInfoTable
cit_lbl :: CmmInfoTable -> CLabel
cit_rep :: CmmInfoTable -> SMRep
cit_prof :: CmmInfoTable -> ProfilingInfo
cit_srt :: CmmInfoTable -> C_SRT
CmmNonInfoTable :: CmmInfoTable
data ClosureTypeInfo
Constr :: ConstrTag -> ConstrDescription -> ClosureTypeInfo
Fun :: FunArity -> ArgDescr -> ClosureTypeInfo
Thunk :: ClosureTypeInfo
ThunkSelector :: SelectorOffset -> ClosureTypeInfo
BlackHole :: ClosureTypeInfo
data C_SRT
NoC_SRT :: C_SRT
C_SRT :: !CLabel -> !WordOff -> !StgHalfWord -> C_SRT
needsSRT :: C_SRT -> Bool
data ProfilingInfo
NoProfilingInfo :: ProfilingInfo
ProfilingInfo :: [Word8] -> [Word8] -> ProfilingInfo
type ConstrDescription = [Word8]
instance Eq C_SRT

module CmmUtils
primRepCmmType :: PrimRep -> CmmType
primRepForeignHint :: PrimRep -> ForeignHint
typeCmmType :: UnaryType -> CmmType
typeForeignHint :: UnaryType -> ForeignHint
zeroCLit :: CmmLit
mkIntCLit :: Int -> CmmLit
mkWordCLit :: StgWord -> CmmLit
packHalfWordsCLit :: (Integral a, Integral b) => a -> b -> CmmLit
mkByteStringCLit :: Unique -> [Word8] -> (CmmLit, GenCmmDecl CmmStatics info stmt)
mkDataLits :: Section -> CLabel -> [CmmLit] -> GenCmmDecl CmmStatics info stmt
mkRODataLits :: CLabel -> [CmmLit] -> GenCmmDecl CmmStatics info stmt
mkLblExpr :: CLabel -> CmmExpr
cmmRegOff :: CmmReg -> Int -> CmmExpr
cmmOffset :: CmmExpr -> Int -> CmmExpr
cmmLabelOff :: CLabel -> Int -> CmmLit
cmmOffsetLit :: CmmLit -> Int -> CmmLit
cmmOffsetExpr :: CmmExpr -> CmmExpr -> CmmExpr
cmmRegOffB :: CmmReg -> ByteOff -> CmmExpr
cmmOffsetB :: CmmExpr -> ByteOff -> CmmExpr
cmmLabelOffB :: CLabel -> ByteOff -> CmmLit
cmmOffsetLitB :: CmmLit -> ByteOff -> CmmLit
cmmOffsetExprB :: CmmExpr -> CmmExpr -> CmmExpr
cmmRegOffW :: CmmReg -> WordOff -> CmmExpr
cmmOffsetW :: CmmExpr -> WordOff -> CmmExpr
cmmLabelOffW :: CLabel -> WordOff -> CmmLit
cmmOffsetLitW :: CmmLit -> WordOff -> CmmLit
cmmOffsetExprW :: CmmExpr -> CmmExpr -> CmmExpr

-- | Useful for creating an index into an array, with a staticaly known
--   offset. The type is the element type; used for making the multiplier
cmmIndex :: Width -> CmmExpr -> Int -> CmmExpr

-- | Useful for creating an index into an array, with an unknown offset.
cmmIndexExpr :: Width -> CmmExpr -> CmmExpr -> CmmExpr
cmmLoadIndex :: CmmType -> CmmExpr -> Int -> CmmExpr
cmmLoadIndexW :: CmmExpr -> Int -> CmmType -> CmmExpr
cmmNegate :: CmmExpr -> CmmExpr
cmmULtWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmUGeWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmUGtWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmSubWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmNeWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmEqWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmOrWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmAndWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmUShrWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmAddWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmMulWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmQuotWord :: CmmExpr -> CmmExpr -> CmmExpr
isTrivialCmmExpr :: CmmExpr -> Bool
hasNoGlobalRegs :: CmmExpr -> Bool
blankWord :: CmmStatic
cmmTagMask :: CmmExpr
cmmPointerMask :: CmmExpr
cmmUntag :: CmmExpr -> CmmExpr
cmmGetTag :: CmmExpr -> CmmExpr
cmmIsTagged :: CmmExpr -> CmmExpr
cmmConstrTag :: CmmExpr -> CmmExpr
cmmConstrTag1 :: CmmExpr -> CmmExpr
mkLiveness :: [Maybe LocalReg] -> Liveness
modifyGraph :: (Graph n C C -> Graph n' C C) -> GenCmmGraph n -> GenCmmGraph n'
lastNode :: Block n x C -> n O C
replaceLastNode :: Block n x C -> n O C -> Block n x C
ofBlockMap :: BlockId -> BlockEnv CmmBlock -> CmmGraph
toBlockMap :: CmmGraph -> BlockEnv CmmBlock
insertBlock :: CmmBlock -> BlockEnv CmmBlock -> BlockEnv CmmBlock
ofBlockList :: BlockId -> [CmmBlock] -> CmmGraph
toBlockList :: CmmGraph -> [CmmBlock]
bodyToBlockList :: Body CmmNode -> [CmmBlock]
foldGraphBlocks :: (CmmBlock -> a -> a) -> a -> CmmGraph -> a
mapGraphNodes :: (CmmNode C O -> CmmNode C O, CmmNode O O -> CmmNode O O, CmmNode O C -> CmmNode O C) -> CmmGraph -> CmmGraph
postorderDfs :: CmmGraph -> [CmmBlock]
mapGraphNodes1 :: (forall e x. CmmNode e x -> CmmNode e x) -> CmmGraph -> CmmGraph
analFwd :: DataflowLattice f -> FwdTransfer n f -> FwdPass UniqSM n f
analBwd :: DataflowLattice f -> BwdTransfer n f -> BwdPass UniqSM n f
analRewFwd :: DataflowLattice f -> FwdTransfer n f -> FwdRewrite UniqSM n f -> FwdPass UniqSM n f
analRewBwd :: DataflowLattice f -> BwdTransfer n f -> BwdRewrite UniqSM n f -> BwdPass UniqSM n f
dataflowPassFwd :: NonLocal n => GenCmmGraph n -> [(BlockId, f)] -> FwdPass UniqSM n f -> UniqSM (GenCmmGraph n, BlockEnv f)
dataflowPassBwd :: NonLocal n => GenCmmGraph n -> [(BlockId, f)] -> BwdPass UniqSM n f -> UniqSM (GenCmmGraph n, BlockEnv f)
dataflowAnalFwd :: NonLocal n => GenCmmGraph n -> [(BlockId, f)] -> FwdPass UniqSM n f -> BlockEnv f
dataflowAnalBwd :: NonLocal n => GenCmmGraph n -> [(BlockId, f)] -> BwdPass UniqSM n f -> BlockEnv f
dataflowAnalFwdBlocks :: NonLocal n => GenCmmGraph n -> [(BlockId, f)] -> FwdPass UniqSM n f -> UniqSM (BlockEnv f)

module CmmContFlowOpt
cmmCfgOpts :: CmmGraph -> CmmGraph
cmmCfgOptsProc :: CmmDecl -> CmmDecl
removeUnreachableBlocks :: CmmGraph -> CmmGraph
replaceLabels :: BlockEnv BlockId -> CmmGraph -> CmmGraph

module CmmCommonBlockElim
elimCommonBlocks :: CmmGraph -> CmmGraph

module CmmLive

-- | The variables live on entry to a block
type CmmLive = RegSet

-- | Calculated liveness info for a CmmGraph
cmmLiveness :: CmmGraph -> BlockEntryLiveness

-- | The dataflow lattice
liveLattice :: DataflowLattice CmmLive

-- | On entry to the procedure, there had better not be any LocalReg's
--   live-in.
noLiveOnEntry :: BlockId -> CmmLive -> a -> a

-- | The transfer function
xferLive :: BwdTransfer CmmNode CmmLive

-- | The transfer equations use the traditional <a>gen</a> and <a>kill</a>
--   notations, which should be familiar from the Dragon Book.
gen :: UserOfLocalRegs a => a -> RegSet -> RegSet
kill :: DefinerOfLocalRegs a => a -> RegSet -> RegSet
gen_kill :: (DefinerOfLocalRegs a, UserOfLocalRegs a) => a -> CmmLive -> CmmLive
removeDeadAssignments :: CmmGraph -> UniqSM (CmmGraph, BlockEnv CmmLive)

module CmmSink
cmmSink :: CmmGraph -> CmmGraph
cmmPeepholeInline :: CmmGraph -> CmmGraph

module ProfInit
profilingInitCode :: Module -> CollectedCCs -> SDoc

module PprCmmDecl
writeCmms :: (Outputable info, Outputable g) => DynFlags -> Handle -> [GenCmmGroup CmmStatics info g] -> IO ()
pprCmms :: (Outputable info, Outputable g) => [GenCmmGroup CmmStatics info g] -> SDoc
pprCmmGroup :: (Outputable d, Outputable info, Outputable g) => GenCmmGroup d info g -> SDoc
pprSection :: Section -> SDoc
pprStatic :: CmmStatic -> SDoc
instance Outputable ForeignHint
instance Outputable C_SRT
instance Outputable CmmInfoTable
instance Outputable CmmStatic
instance Outputable CmmStatics
instance (Outputable d, Outputable info, Outputable i) => Outputable (GenCmmDecl d info i)

module PprCmm
instance Outputable CmmGraph
instance Outputable (Graph CmmNode e x)
instance Outputable (Block CmmNode O O)
instance Outputable (Block CmmNode O C)
instance Outputable (Block CmmNode C O)
instance Outputable (Block CmmNode C C)
instance Outputable ForeignTarget
instance Outputable ForeignConvention
instance Outputable Convention
instance Outputable (CmmNode e x)
instance Outputable CmmTopInfo
instance Outputable CmmStackInfo

module CmmLint
cmmLint :: (Outputable d, Outputable h) => GenCmmGroup d h CmmGraph -> Maybe SDoc
cmmLintGraph :: CmmGraph -> Maybe SDoc
instance Monad CmmLint

module CmmCallConv
data ParamLocation
RegisterParam :: GlobalReg -> ParamLocation
StackParam :: ByteOff -> ParamLocation

-- | JD: For the new stack story, I want arguments passed on the stack to
--   manifest as positive offsets in a CallArea, not negative offsets from
--   the stack pointer. Also, I want byte offsets, not word offsets.
assignArgumentsPos :: Convention -> (a -> CmmType) -> [a] -> [(a, ParamLocation)]
globalArgRegs :: [GlobalReg]
instance Outputable ParamLocation

module MkGraph

-- | CmmAGraph is a chunk of code consisting of:
--   
--   <ul>
--   <li>ordinary statements (assignments, stores etc.) * jumps * labels *
--   out-of-line labelled blocks</li>
--   </ul>
--   
--   The semantics is that control falls through labels and out-of-line
--   blocks. Everything after a jump up to the next label is by definition
--   unreachable code, and will be discarded.
--   
--   Two CmmAGraphs can be stuck together with <a>*</a>, with the meaning
--   that control flows from the first to the second.
--   
--   A <a>CmmAGraph</a> can be turned into a <a>CmmGraph</a> (closed at
--   both ends) by providing a label for the entry point; see
--   <a>labelAGraph</a>.
type CmmAGraph = OrdList CgStmt
data CgStmt
CgLabel :: BlockId -> CgStmt
CgStmt :: (CmmNode O O) -> CgStmt
CgLast :: (CmmNode O C) -> CgStmt
CgFork :: BlockId -> CmmAGraph -> CgStmt
(<*>) :: CmmAGraph -> CmmAGraph -> CmmAGraph
catAGraphs :: [CmmAGraph] -> CmmAGraph

-- | created a sequence <a>goto id; id:</a> as an AGraph
mkLabel :: BlockId -> CmmAGraph

-- | creates an open AGraph from a given node
mkMiddle :: CmmNode O O -> CmmAGraph

-- | created a closed AGraph from a given node
mkLast :: CmmNode O C -> CmmAGraph

-- | A labelled code block; should end in a last node
outOfLine :: BlockId -> CmmAGraph -> CmmAGraph

-- | allocate a fresh label for the entry point
lgraphOfAGraph :: CmmAGraph -> UniqSM CmmGraph

-- | use the given BlockId as the label of the entry point
labelAGraph :: BlockId -> CmmAGraph -> UniqSM CmmGraph
stackStubExpr :: Width -> CmmExpr
mkNop :: CmmAGraph
mkAssign :: CmmReg -> CmmExpr -> CmmAGraph
mkStore :: CmmExpr -> CmmExpr -> CmmAGraph
mkUnsafeCall :: ForeignTarget -> [CmmFormal] -> [CmmActual] -> CmmAGraph
mkFinalCall :: CmmExpr -> CCallConv -> [CmmActual] -> UpdFrameOffset -> CmmAGraph
mkCallReturnsTo :: CmmExpr -> Convention -> [CmmActual] -> BlockId -> ByteOff -> UpdFrameOffset -> (ByteOff, [(CmmExpr, ByteOff)]) -> CmmAGraph
mkJump :: CmmExpr -> [CmmActual] -> UpdFrameOffset -> CmmAGraph
mkDirectJump :: CmmExpr -> [CmmActual] -> UpdFrameOffset -> CmmAGraph
mkForeignJump :: Convention -> CmmExpr -> [CmmActual] -> UpdFrameOffset -> CmmAGraph
mkForeignJumpExtra :: Convention -> CmmExpr -> [CmmActual] -> UpdFrameOffset -> (ByteOff, [(CmmExpr, ByteOff)]) -> CmmAGraph
mkJumpGC :: CmmExpr -> [CmmActual] -> UpdFrameOffset -> CmmAGraph
mkCbranch :: CmmExpr -> BlockId -> BlockId -> CmmAGraph
mkSwitch :: CmmExpr -> [Maybe BlockId] -> CmmAGraph
mkReturn :: CmmExpr -> [CmmActual] -> UpdFrameOffset -> CmmAGraph
mkReturnSimple :: [CmmActual] -> UpdFrameOffset -> CmmAGraph
mkComment :: FastString -> CmmAGraph
mkCallEntry :: Convention -> [CmmFormal] -> (Int, CmmAGraph)
mkBranch :: BlockId -> CmmAGraph
copyInOflow :: Convention -> Area -> [CmmFormal] -> (Int, CmmAGraph)
copyOutOflow :: Convention -> Transfer -> Area -> [CmmActual] -> UpdFrameOffset -> (ByteOff, [(CmmExpr, ByteOff)]) -> (Int, [GlobalReg], CmmAGraph)
noExtraStack :: (ByteOff, [(CmmExpr, ByteOff)])
toCall :: CmmExpr -> Maybe BlockId -> UpdFrameOffset -> ByteOff -> ByteOff -> [GlobalReg] -> CmmAGraph
data Transfer
Call :: Transfer
Jump :: Transfer
Ret :: Transfer
instance Eq Transfer

module StgSyn
data GenStgArg occ
StgVarArg :: occ -> GenStgArg occ
StgLitArg :: Literal -> GenStgArg occ
type GenStgLiveVars occ = UniqSet occ
data GenStgBinding bndr occ
StgNonRec :: bndr -> (GenStgRhs bndr occ) -> GenStgBinding bndr occ
StgRec :: [(bndr, GenStgRhs bndr occ)] -> GenStgBinding bndr occ
data GenStgExpr bndr occ
StgApp :: occ -> [GenStgArg occ] -> GenStgExpr bndr occ
StgLit :: Literal -> GenStgExpr bndr occ
StgConApp :: DataCon -> [GenStgArg occ] -> GenStgExpr bndr occ
StgOpApp :: StgOp -> [GenStgArg occ] -> Type -> GenStgExpr bndr occ
StgLam :: [bndr] -> StgExpr -> GenStgExpr bndr occ
StgCase :: (GenStgExpr bndr occ) -> (GenStgLiveVars occ) -> (GenStgLiveVars occ) -> bndr -> SRT -> AltType -> [GenStgAlt bndr occ] -> GenStgExpr bndr occ
StgLet :: (GenStgBinding bndr occ) -> (GenStgExpr bndr occ) -> GenStgExpr bndr occ
StgLetNoEscape :: (GenStgLiveVars occ) -> (GenStgLiveVars occ) -> (GenStgBinding bndr occ) -> (GenStgExpr bndr occ) -> GenStgExpr bndr occ
StgSCC :: CostCentre -> !Bool -> !Bool -> (GenStgExpr bndr occ) -> GenStgExpr bndr occ
StgTick :: Module -> Int -> (GenStgExpr bndr occ) -> GenStgExpr bndr occ
data GenStgRhs bndr occ
StgRhsClosure :: CostCentreStack -> StgBinderInfo -> [occ] -> !UpdateFlag -> SRT -> [bndr] -> (GenStgExpr bndr occ) -> GenStgRhs bndr occ
StgRhsCon :: CostCentreStack -> DataCon -> [GenStgArg occ] -> GenStgRhs bndr occ
type GenStgAlt bndr occ = (AltCon, [bndr], [Bool], GenStgExpr bndr occ)
data AltType
PolyAlt :: AltType
UbxTupAlt :: Int -> AltType
AlgAlt :: TyCon -> AltType
PrimAlt :: TyCon -> AltType
data UpdateFlag
ReEntrant :: UpdateFlag
Updatable :: UpdateFlag
SingleEntry :: UpdateFlag
isUpdatable :: UpdateFlag -> Bool
data StgBinderInfo
noBinderInfo :: StgBinderInfo
stgSatOcc :: StgBinderInfo
stgUnsatOcc :: StgBinderInfo
satCallsOnly :: StgBinderInfo -> Bool
combineStgBinderInfo :: StgBinderInfo -> StgBinderInfo -> StgBinderInfo
type StgArg = GenStgArg Id
type StgLiveVars = GenStgLiveVars Id
type StgBinding = GenStgBinding Id Id
type StgExpr = GenStgExpr Id Id
type StgRhs = GenStgRhs Id Id
type StgAlt = GenStgAlt Id Id
data StgOp
StgPrimOp :: PrimOp -> StgOp
StgPrimCallOp :: PrimCall -> StgOp
StgFCallOp :: ForeignCall -> Unique -> StgOp
data SRT
NoSRT :: SRT
SRTEntries :: IdSet -> SRT
SRT :: !Int -> !Int -> !Bitmap -> SRT
stgBindHasCafRefs :: GenStgBinding bndr Id -> Bool
stgArgHasCafRefs :: GenStgArg Id -> Bool
stgRhsArity :: StgRhs -> Int

-- | Does this constructor application refer to anything in a different
--   *Windows* DLL? If so, we can't allocate it statically
isDllConApp :: DynFlags -> DataCon -> [StgArg] -> Bool

-- | Type of an <tt>StgArg</tt>
--   
--   Very half baked becase we have lost the type arguments.
stgArgType :: StgArg -> Type
pprStgBinding :: StgBinding -> SDoc
pprStgBindings :: [StgBinding] -> SDoc
pprStgBindingsWithSRTs :: [(StgBinding, [(Id, [Id])])] -> SDoc
pprStgLVs :: Outputable occ => GenStgLiveVars occ -> SDoc
instance Outputable AltType
instance (OutputableBndr bndr, Outputable bdee, Ord bdee) => Outputable (GenStgRhs bndr bdee)
instance (OutputableBndr bndr, Outputable bdee, Ord bdee) => Outputable (GenStgExpr bndr bdee)
instance (OutputableBndr bndr, Outputable bdee, Ord bdee) => Outputable (GenStgBinding bndr bdee)
instance Outputable bdee => Outputable (GenStgArg bdee)
instance Outputable UpdateFlag

module ClosureInfo
idRepArity :: Id -> RepArity
data ClosureInfo
ClosureInfo :: !Name -> !LambdaFormInfo -> !SMRep -> !C_SRT -> !Type -> !String -> Bool -> ClosureInfo
closureName :: ClosureInfo -> !Name
closureLFInfo :: ClosureInfo -> !LambdaFormInfo
closureSMRep :: ClosureInfo -> !SMRep
closureSRT :: ClosureInfo -> !C_SRT
closureType :: ClosureInfo -> !Type
closureDescr :: ClosureInfo -> !String
closureInfLcl :: ClosureInfo -> Bool
ConInfo :: !DataCon -> !SMRep -> ClosureInfo
closureCon :: ClosureInfo -> !DataCon
closureSMRep :: ClosureInfo -> !SMRep
data LambdaFormInfo
LFReEntrant :: TopLevelFlag -> !RepArity -> !Bool -> ArgDescr -> LambdaFormInfo
LFCon :: DataCon -> LambdaFormInfo
LFThunk :: TopLevelFlag -> !Bool -> !Bool -> StandardFormInfo -> !Bool -> LambdaFormInfo
LFUnknown :: !Bool -> LambdaFormInfo
LFLetNoEscape :: !RepArity -> LambdaFormInfo
LFBlackHole :: LambdaFormInfo
data StandardFormInfo
NonStandardThunk :: StandardFormInfo
SelectorThunk :: WordOff -> StandardFormInfo
ApThunk :: RepArity -> StandardFormInfo

-- | A description of the layout of a closure. Corresponds directly to the
--   closure types in includes<i>rts</i>storage/ClosureTypes.h.
data SMRep
data ArgDescr
ArgSpec :: !StgHalfWord -> ArgDescr
ArgGen :: Liveness -> ArgDescr
type Liveness = [Bool]
data C_SRT
NoC_SRT :: C_SRT
C_SRT :: !CLabel -> !WordOff -> !StgHalfWord -> C_SRT
needsSRT :: C_SRT -> Bool
mkLFThunk :: Type -> TopLevelFlag -> [Var] -> UpdateFlag -> LambdaFormInfo
mkLFReEntrant :: TopLevelFlag -> [Id] -> [Id] -> ArgDescr -> LambdaFormInfo
mkConLFInfo :: DataCon -> LambdaFormInfo
mkSelectorLFInfo :: Id -> WordOff -> Bool -> LambdaFormInfo
mkApLFInfo :: Id -> UpdateFlag -> RepArity -> LambdaFormInfo
mkLFImported :: Id -> LambdaFormInfo
mkLFArgument :: Id -> LambdaFormInfo
mkLFLetNoEscape :: RepArity -> LambdaFormInfo
mkClosureInfo :: Bool -> Id -> LambdaFormInfo -> Int -> Int -> C_SRT -> String -> ClosureInfo
mkConInfo :: Bool -> DataCon -> Int -> Int -> ClosureInfo
maybeIsLFCon :: LambdaFormInfo -> Maybe DataCon
closureSize :: ClosureInfo -> WordOff
type ConTagZ = Int
dataConTagZ :: DataCon -> ConTagZ
infoTableLabelFromCI :: ClosureInfo -> CLabel
entryLabelFromCI :: ClosureInfo -> CLabel
closureLabelFromCI :: ClosureInfo -> CLabel
isLFThunk :: LambdaFormInfo -> Bool
closureUpdReqd :: ClosureInfo -> Bool
closureNeedsUpdSpace :: ClosureInfo -> Bool
closureIsThunk :: ClosureInfo -> Bool
closureSingleEntry :: ClosureInfo -> Bool
closureReEntrant :: ClosureInfo -> Bool
isConstrClosure_maybe :: ClosureInfo -> Maybe DataCon
closureFunInfo :: ClosureInfo -> Maybe (RepArity, ArgDescr)
isKnownFun :: LambdaFormInfo -> Bool
funTag :: ClosureInfo -> Int
funTagLFInfo :: LambdaFormInfo -> Int
tagForArity :: RepArity -> Maybe Int
clHasCafRefs :: ClosureInfo -> CafInfo
enterIdLabel :: Name -> CafInfo -> CLabel
enterReturnPtLabel :: Unique -> CLabel
nodeMustPointToIt :: LambdaFormInfo -> Bool
data CallMethod
EnterIt :: CallMethod
JumpToIt :: CLabel -> CallMethod
ReturnIt :: CallMethod
ReturnCon :: DataCon -> CallMethod
SlowCall :: CallMethod
DirectEntry :: CLabel -> RepArity -> CallMethod
getCallMethod :: DynFlags -> Name -> CafInfo -> LambdaFormInfo -> RepArity -> CallMethod
blackHoleOnEntry :: ClosureInfo -> Bool
staticClosureRequired :: Name -> StgBinderInfo -> LambdaFormInfo -> Bool
isToplevClosure :: ClosureInfo -> Bool
closureValDescr :: ClosureInfo -> String
closureTypeDescr :: ClosureInfo -> String
isStaticClosure :: ClosureInfo -> Bool
cafBlackHoleClosureInfo :: ClosureInfo -> ClosureInfo
staticClosureNeedsLink :: ClosureInfo -> Bool
data CgRep
VoidArg :: CgRep
PtrArg :: CgRep
NonPtrArg :: CgRep
LongArg :: CgRep
FloatArg :: CgRep
DoubleArg :: CgRep
nonVoidArg :: CgRep -> Bool
argMachRep :: CgRep -> CmmType
primRepToCgRep :: PrimRep -> CgRep
isFollowableArg :: CgRep -> Bool
isVoidArg :: CgRep -> Bool
isFloatingArg :: CgRep -> Bool
is64BitArg :: CgRep -> Bool
separateByPtrFollowness :: [(CgRep, a)] -> ([(CgRep, a)], [(CgRep, a)])
cgRepSizeW :: CgRep -> ByteOff
cgRepSizeB :: CgRep -> ByteOff
retAddrSizeW :: WordOff
typeCgRep :: UnaryType -> CgRep
idCgRep :: Id -> CgRep
tyConCgRep :: TyCon -> CgRep
instance Eq CgRep
instance Outputable CgRep

module OldCmm

-- | Cmm with the info table as a data type
type CmmGroup = GenCmmGroup CmmStatics CmmInfoTable (ListGraph CmmStmt)
type GenCmmGroup d h g = [GenCmmDecl d h g]

-- | Cmm with the info tables converted to a list of <a>CmmStatic</a> along
--   with the info table label. If we are building without
--   tables-next-to-code there will be no statics
--   
--   INVARIANT: if there is an info table, it has at least one CmmStatic
type RawCmmGroup = GenCmmGroup CmmStatics (Maybe CmmStatics) (ListGraph CmmStmt)
type CmmDecl = GenCmmDecl CmmStatics CmmInfoTable (ListGraph CmmStmt)
type RawCmmDecl = GenCmmDecl CmmStatics (Maybe CmmStatics) (ListGraph CmmStmt)

-- | A control-flow graph represented as a list of extended basic blocks.
--   
--   Code, may be empty. The first block is the entry point. The order is
--   otherwise initially unimportant, but at some point the code gen will
--   fix the order.
--   
--   BlockIds must be unique across an entire compilation unit, since they
--   are translated to assembly-language labels, which scope across a whole
--   compilation unit.
newtype ListGraph i
ListGraph :: [GenBasicBlock i] -> ListGraph i

-- | Info table as a haskell data type
data CmmInfoTable
CmmInfoTable :: CLabel -> SMRep -> ProfilingInfo -> C_SRT -> CmmInfoTable
cit_lbl :: CmmInfoTable -> CLabel
cit_rep :: CmmInfoTable -> SMRep
cit_prof :: CmmInfoTable -> ProfilingInfo
cit_srt :: CmmInfoTable -> C_SRT
CmmNonInfoTable :: CmmInfoTable
data ClosureTypeInfo
Constr :: ConstrTag -> ConstrDescription -> ClosureTypeInfo
Fun :: FunArity -> ArgDescr -> ClosureTypeInfo
Thunk :: ClosureTypeInfo
ThunkSelector :: SelectorOffset -> ClosureTypeInfo
BlackHole :: ClosureTypeInfo
data CmmStatic
CmmStaticLit :: CmmLit -> CmmStatic
CmmUninitialised :: Int -> CmmStatic
CmmString :: [Word8] -> CmmStatic
data CmmStatics
Statics :: CLabel -> [CmmStatic] -> CmmStatics
type CmmFormal = LocalReg
type CmmActual = CmmExpr
cmmMapGraph :: (g -> g') -> GenCmmGroup d h g -> GenCmmGroup d h g'
cmmTopMapGraph :: (g -> g') -> GenCmmDecl d h g -> GenCmmDecl d h g'
data GenBasicBlock i
BasicBlock :: BlockId -> [i] -> GenBasicBlock i
type CmmBasicBlock = GenBasicBlock CmmStmt

-- | The branch block id is that of the first block in the branch, which is
--   that branch's entry point
blockId :: GenBasicBlock i -> BlockId
blockStmts :: GenBasicBlock i -> [i]
mapBlockStmts :: (i -> i') -> GenBasicBlock i -> GenBasicBlock i'
data CmmStmt
CmmNop :: CmmStmt
CmmComment :: FastString -> CmmStmt
CmmAssign :: CmmReg -> CmmExpr -> CmmStmt
CmmStore :: CmmExpr -> CmmExpr -> CmmStmt
CmmCall :: CmmCallTarget -> [HintedCmmFormal] -> [HintedCmmActual] -> CmmReturnInfo -> CmmStmt
CmmBranch :: BlockId -> CmmStmt
CmmCondBranch :: CmmExpr -> BlockId -> CmmStmt
CmmSwitch :: CmmExpr -> [Maybe BlockId] -> CmmStmt
CmmJump :: CmmExpr -> (Maybe [GlobalReg]) -> CmmStmt
CmmReturn :: CmmStmt
data CmmReturnInfo
CmmMayReturn :: CmmReturnInfo
CmmNeverReturns :: CmmReturnInfo
data CmmHinted a
CmmHinted :: a -> ForeignHint -> CmmHinted a
hintlessCmm :: CmmHinted a -> a
cmmHint :: CmmHinted a -> ForeignHint
type HintedCmmFormal = CmmHinted CmmFormal
type HintedCmmActual = CmmHinted CmmActual
data CmmSafety
CmmUnsafe :: CmmSafety
CmmSafe :: C_SRT -> CmmSafety
CmmInterruptible :: CmmSafety
data CmmCallTarget
CmmCallee :: CmmExpr -> CCallConv -> CmmCallTarget
CmmPrim :: CallishMachOp -> (Maybe [CmmStmt]) -> CmmCallTarget

-- | A top-level chunk, abstracted over the type of the contents of the
--   basic blocks (Cmm or instructions are the likely instantiations).
data GenCmmDecl d h g
CmmProc :: h -> CLabel -> g -> GenCmmDecl d h g
CmmData :: Section -> d -> GenCmmDecl d h g
data ForeignHint
NoHint :: ForeignHint
AddrHint :: ForeignHint
SignedHint :: ForeignHint
data Section
Text :: Section
Data :: Section
ReadOnlyData :: Section
RelocatableReadOnlyData :: Section
UninitialisedData :: Section
ReadOnlyData16 :: Section
OtherSection :: String -> Section
data ProfilingInfo
NoProfilingInfo :: ProfilingInfo
ProfilingInfo :: [Word8] -> [Word8] -> ProfilingInfo
data C_SRT
NoC_SRT :: C_SRT
C_SRT :: !CLabel -> !WordOff -> !StgHalfWord -> C_SRT
instance Eq CmmReturnInfo
instance Eq a => Eq (CmmHinted a)
instance DefinerOfLocalRegs a => DefinerOfLocalRegs (CmmHinted a)
instance UserOfLocalRegs a => UserOfLocalRegs (CmmHinted a)
instance UserOfLocalRegs CmmCallTarget
instance UserOfLocalRegs CmmStmt
instance UserOfLocalRegs i => UserOfLocalRegs (GenBasicBlock i)


-- | Sizes on this architecture A Size is a combination of width and class
--   
--   TODO: Rename this to <a>Format</a> instead of <a>Size</a> to reflect
--   the fact that it represents floating point vs integer.
--   
--   TODO: Signed vs unsigned?
--   
--   TODO: This module is currenly shared by all architectures because
--   NCGMonad need to know about it to make a VReg. It would be better to
--   have architecture specific formats, and do the overloading properly.
--   eg SPARC doesn't care about FF80.
module Size
data Size
II8 :: Size
II16 :: Size
II32 :: Size
II64 :: Size
FF32 :: Size
FF64 :: Size
FF80 :: Size

-- | Get the integer size of this width.
intSize :: Width -> Size

-- | Get the float size of this width.
floatSize :: Width -> Size

-- | Check if a size represents a floating point value.
isFloatSize :: Size -> Bool

-- | Convert a Cmm type to a Size.
cmmTypeSize :: CmmType -> Size

-- | Get the Width of a Size.
sizeToWidth :: Size -> Width
sizeInBytes :: Size -> Int
instance Show Size
instance Eq Size

module SPARC.Regs

-- | Get the standard name for the register with this number.
showReg :: RegNo -> String

-- | regSqueeze_class reg Calculuate the maximum number of register colors
--   that could be denied to a node of this class due to having this reg as
--   a neighbour.
virtualRegSqueeze :: RegClass -> VirtualReg -> FastInt
realRegSqueeze :: RegClass -> RealReg -> FastInt
classOfRealReg :: RealReg -> RegClass

-- | All the allocatable registers in the machine, including register
--   pairs.
allRealRegs :: [RealReg]

-- | Get the regno for this sort of reg
gReg :: Int -> RegNo

-- | Get the regno for this sort of reg
iReg :: Int -> RegNo

-- | Get the regno for this sort of reg
lReg :: Int -> RegNo

-- | Get the regno for this sort of reg
oReg :: Int -> RegNo

-- | Get the regno for this sort of reg
fReg :: Int -> RegNo

-- | Some specific regs used by the code generator.
fp :: Reg

-- | Some specific regs used by the code generator.
sp :: Reg

-- | Some specific regs used by the code generator.
g0 :: Reg

-- | Some specific regs used by the code generator.
g1 :: Reg

-- | Some specific regs used by the code generator.
g2 :: Reg

-- | Some specific regs used by the code generator.
o0 :: Reg

-- | Some specific regs used by the code generator.
o1 :: Reg

-- | Some specific regs used by the code generator.
f0 :: Reg

-- | Some specific regs used by the code generator.
f1 :: Reg

-- | Some specific regs used by the code generator.
f6 :: Reg

-- | Some specific regs used by the code generator.
f8 :: Reg

-- | Some specific regs used by the code generator.
f22 :: Reg

-- | Some specific regs used by the code generator.
f26 :: Reg

-- | Some specific regs used by the code generator.
f27 :: Reg

-- | Produce the second-half-of-a-double register given the first half.
--   
--   All the regs that the register allocator can allocate to, with the the
--   fixed use regs removed.
allocatableRegs :: [RealReg]

-- | The registers to place arguments for function calls, for some number
--   of arguments.
argRegs :: RegNo -> [Reg]

-- | All all the regs that could possibly be returned by argRegs
allArgRegs :: [Reg]
callClobberedRegs :: [Reg]

-- | Make a virtual reg with this size.
mkVirtualReg :: Unique -> Size -> VirtualReg
regDotColor :: RealReg -> SDoc


-- | Free regs map for SPARC
module RegAlloc.Linear.SPARC.FreeRegs
data FreeRegs
FreeRegs :: !Word32 -> !Word32 -> !Word32 -> FreeRegs

-- | A reg map where no regs are free to be allocated.
noFreeRegs :: FreeRegs

-- | The initial set of free regs.
initFreeRegs :: FreeRegs

-- | Get all the free registers of this class.
getFreeRegs :: RegClass -> FreeRegs -> [RealReg]

-- | Grab a register.
allocateReg :: RealReg -> FreeRegs -> FreeRegs

-- | Release a register from allocation. The register liveness information
--   says that most regs die after a C call, but we still don't want to
--   allocate to some of them.
releaseReg :: RealReg -> FreeRegs -> FreeRegs
bitMask :: Int -> Word32
showFreeRegs :: FreeRegs -> String
instance Show FreeRegs

module OldPprCmm
pprStmt :: CmmStmt -> SDoc
instance Outputable a => Outputable (CmmHinted a)
instance Outputable CmmSafety
instance Outputable CmmStmt
instance Outputable instr => Outputable (GenBasicBlock instr)
instance Outputable instr => Outputable (ListGraph instr)

module CmmCvt
cmmOfZgraph :: CmmGroup -> CmmGroup

module CmmInfo
mkEmptyContInfoTable :: CLabel -> CmmInfoTable
cmmToRawCmm :: Platform -> Stream IO CmmGroup () -> IO (Stream IO RawCmmGroup ())
mkInfoTable :: Platform -> CmmDecl -> UniqSM [RawCmmDecl]

module CmmProcPoint
type ProcPointSet = BlockSet
data Status
ReachedBy :: ProcPointSet -> Status
ProcPoint :: Status
callProcPoints :: CmmGraph -> ProcPointSet
minimalProcPointSet :: Platform -> ProcPointSet -> CmmGraph -> UniqSM ProcPointSet
splitAtProcPoints :: CLabel -> ProcPointSet -> ProcPointSet -> BlockEnv Status -> CmmDecl -> UniqSM [CmmDecl]
procPointAnalysis :: ProcPointSet -> CmmGraph -> UniqSM (BlockEnv Status)
instance Outputable Status

module CmmLex
data CmmToken
CmmT_SpecChar :: Char -> CmmToken
CmmT_DotDot :: CmmToken
CmmT_DoubleColon :: CmmToken
CmmT_Shr :: CmmToken
CmmT_Shl :: CmmToken
CmmT_Ge :: CmmToken
CmmT_Le :: CmmToken
CmmT_Eq :: CmmToken
CmmT_Ne :: CmmToken
CmmT_BoolAnd :: CmmToken
CmmT_BoolOr :: CmmToken
CmmT_CLOSURE :: CmmToken
CmmT_INFO_TABLE :: CmmToken
CmmT_INFO_TABLE_RET :: CmmToken
CmmT_INFO_TABLE_FUN :: CmmToken
CmmT_INFO_TABLE_CONSTR :: CmmToken
CmmT_INFO_TABLE_SELECTOR :: CmmToken
CmmT_else :: CmmToken
CmmT_export :: CmmToken
CmmT_section :: CmmToken
CmmT_align :: CmmToken
CmmT_goto :: CmmToken
CmmT_if :: CmmToken
CmmT_jump :: CmmToken
CmmT_foreign :: CmmToken
CmmT_never :: CmmToken
CmmT_prim :: CmmToken
CmmT_return :: CmmToken
CmmT_returns :: CmmToken
CmmT_import :: CmmToken
CmmT_switch :: CmmToken
CmmT_case :: CmmToken
CmmT_default :: CmmToken
CmmT_bits8 :: CmmToken
CmmT_bits16 :: CmmToken
CmmT_bits32 :: CmmToken
CmmT_bits64 :: CmmToken
CmmT_float32 :: CmmToken
CmmT_float64 :: CmmToken
CmmT_gcptr :: CmmToken
CmmT_GlobalReg :: GlobalReg -> CmmToken
CmmT_Name :: FastString -> CmmToken
CmmT_String :: String -> CmmToken
CmmT_Int :: Integer -> CmmToken
CmmT_Float :: Rational -> CmmToken
CmmT_EOF :: CmmToken
cmmlex :: (Located CmmToken -> P a) -> P a
instance Show CmmToken
instance Functor AlexLastAcc

module CmmOpt
cmmEliminateDeadBlocks :: [CmmBasicBlock] -> [CmmBasicBlock]
cmmMiniInline :: DynFlags -> [CmmBasicBlock] -> [CmmBasicBlock]
cmmMachOpFold :: Platform -> MachOp -> [CmmExpr] -> CmmExpr
cmmMachOpFoldM :: Platform -> MachOp -> [CmmExpr] -> Maybe CmmExpr
cmmLoopifyForC :: RawCmmDecl -> RawCmmDecl

module OldCmmLint
cmmLint :: (Outputable d, Outputable h) => Platform -> GenCmmGroup d h (ListGraph CmmStmt) -> Maybe SDoc
cmmLintTop :: (Outputable d, Outputable h) => Platform -> GenCmmDecl d h (ListGraph CmmStmt) -> Maybe SDoc
instance Monad CmmLint

module OldCmmUtils
type CmmStmts = OrdList CmmStmt
noStmts :: CmmStmts
oneStmt :: CmmStmt -> CmmStmts
mkStmts :: [CmmStmt] -> CmmStmts
plusStmts :: CmmStmts -> CmmStmts -> CmmStmts
stmtList :: CmmStmts -> [CmmStmt]
isNopStmt :: CmmStmt -> Bool
maybeAssignTemp :: [Unique] -> CmmExpr -> ([Unique], [CmmStmt], CmmExpr)
loadArgsIntoTemps :: [Unique] -> [HintedCmmActual] -> ([Unique], [CmmStmt], [HintedCmmActual])

module PprC
writeCs :: DynFlags -> Handle -> [RawCmmGroup] -> IO ()
pprStringInCStyle :: [Word8] -> SDoc
instance Monad TE

module PPC.Regs

-- | regSqueeze_class reg Calculuate the maximum number of register colors
--   that could be denied to a node of this class due to having this reg as
--   a neighbour.
virtualRegSqueeze :: RegClass -> VirtualReg -> FastInt
realRegSqueeze :: RegClass -> RealReg -> FastInt
mkVirtualReg :: Unique -> Size -> VirtualReg
regDotColor :: RealReg -> SDoc
data Imm
ImmInt :: Int -> Imm
ImmInteger :: Integer -> Imm
ImmCLbl :: CLabel -> Imm
ImmLit :: SDoc -> Imm
ImmIndex :: CLabel -> Int -> Imm
ImmFloat :: Rational -> Imm
ImmDouble :: Rational -> Imm
ImmConstantSum :: Imm -> Imm -> Imm
ImmConstantDiff :: Imm -> Imm -> Imm
LO :: Imm -> Imm
HI :: Imm -> Imm
HA :: Imm -> Imm
strImmLit :: String -> Imm
litToImm :: CmmLit -> Imm
data AddrMode
AddrRegReg :: Reg -> Reg -> AddrMode
AddrRegImm :: Reg -> Imm -> AddrMode
addrOffset :: AddrMode -> Int -> Maybe AddrMode
spRel :: Int -> AddrMode
argRegs :: RegNo -> [Reg]
allArgRegs :: [Reg]
callClobberedRegs :: [Reg]
allMachRegNos :: [RegNo]
classOfRealReg :: RealReg -> RegClass
showReg :: RegNo -> String
allFPArgRegs :: [Reg]
fits16Bits :: Integral a => a -> Bool
makeImmediate :: Integral a => Width -> Bool -> a -> Maybe Imm
fReg :: Int -> RegNo
sp :: Reg
r3 :: Reg
r4 :: Reg
r27 :: Reg
r28 :: Reg
f1 :: Reg
f20 :: Reg
f21 :: Reg
freeReg :: RegNo -> FastBool
globalRegMaybe :: GlobalReg -> Maybe Reg
allocatableRegs :: [RealReg]


-- | Free regs map for PowerPC
module RegAlloc.Linear.PPC.FreeRegs
data FreeRegs
FreeRegs :: !Word32 -> !Word32 -> FreeRegs
noFreeRegs :: FreeRegs
releaseReg :: RealReg -> FreeRegs -> FreeRegs
initFreeRegs :: FreeRegs
getFreeRegs :: RegClass -> FreeRegs -> [RealReg]
allocateReg :: RealReg -> FreeRegs -> FreeRegs
instance Show FreeRegs

module SPARC.Imm

-- | An immediate value. Not all of these are directly representable by the
--   machine. Things like ImmLit are slurped out and put in a data segment
--   instead.
data Imm
ImmInt :: Int -> Imm
ImmInteger :: Integer -> Imm
ImmCLbl :: CLabel -> Imm
ImmLit :: SDoc -> Imm
ImmIndex :: CLabel -> Int -> Imm
ImmFloat :: Rational -> Imm
ImmDouble :: Rational -> Imm
ImmConstantSum :: Imm -> Imm -> Imm
ImmConstantDiff :: Imm -> Imm -> Imm
LO :: Imm -> Imm
HI :: Imm -> Imm

-- | Create a ImmLit containing this string.
strImmLit :: String -> Imm

-- | Convert a CmmLit to an Imm. Narrow to the width: a CmmInt might be out
--   of range, but we assume that ImmInteger only contains in-range values.
--   A signed value should be fine here.
litToImm :: CmmLit -> Imm

module SPARC.AddrMode

-- | Represents a memory address in an instruction. Being a RISC machine,
--   the SPARC addressing modes are very regular.
data AddrMode
AddrRegReg :: Reg -> Reg -> AddrMode
AddrRegImm :: Reg -> Imm -> AddrMode

-- | Add an integer offset to the address in an AddrMode.
addrOffset :: AddrMode -> Int -> Maybe AddrMode

module SPARC.Stack

-- | Get an AddrMode relative to the address in sp. This gives us a stack
--   relative addressing mode for volatile temporaries and for excess call
--   arguments.
spRel :: Int -> AddrMode

-- | Get an address relative to the frame pointer. This doesn't work work
--   for offsets greater than 13 bits; we just hope for the best
fpRel :: Int -> AddrMode

-- | Convert a spill slot number to a *byte* offset, with no sign.
spillSlotToOffset :: Int -> Int

-- | The maximum number of spill slots available on the C stack. If we use
--   up all of the slots, then we're screwed.
--   
--   Why do we reserve 64 bytes, instead of using the whole thing?? -- BL
--   2009<i>02</i>15
maxSpillSlots :: Int

module CgMonad
type Code = FCode ()
data FCode a
initC :: IO CgState
runC :: DynFlags -> Module -> CgState -> FCode a -> (a, CgState)
thenC :: Code -> FCode a -> FCode a
thenFC :: FCode a -> (a -> FCode c) -> FCode c
listCs :: [Code] -> Code
listFCs :: [FCode a] -> FCode [a]
mapCs :: (a -> Code) -> [a] -> Code
mapFCs :: (a -> FCode b) -> [a] -> FCode [b]
returnFC :: a -> FCode a

-- | Knot-tying combinator for <tt>FCode</tt>
fixC :: (a -> FCode a) -> FCode a

-- | Knot-tying combinator that throws result away
fixC_ :: (a -> FCode a) -> FCode ()
checkedAbsC :: CmmStmt -> Code
stmtC :: CmmStmt -> Code
stmtsC :: [CmmStmt] -> Code
labelC :: BlockId -> Code
emitStmts :: CmmStmts -> Code
nopC :: Code
whenC :: Bool -> Code -> Code
newLabelC :: FCode BlockId
newUnique :: FCode Unique
newUniqSupply :: FCode UniqSupply
type CgStmts = OrdList CgStmt
emitCgStmts :: CgStmts -> Code
forkCgStmts :: CgStmts -> FCode BlockId
cgStmtsToBlocks :: CgStmts -> FCode [CmmBasicBlock]
getCgStmts' :: FCode a -> FCode (a, CgStmts)
getCgStmts :: FCode a -> FCode CgStmts
noCgStmts :: CgStmts
oneCgStmt :: CmmStmt -> CgStmts
consCgStmt :: CmmStmt -> CgStmts -> CgStmts
getCmm :: Code -> FCode CmmGroup
emitDecl :: CmmDecl -> Code
emitProc :: CmmInfoTable -> CLabel -> [CmmFormal] -> [CmmBasicBlock] -> Code
emitSimpleProc :: CLabel -> Code -> Code
forkLabelledCode :: Code -> FCode BlockId

-- | Takes code and compiles it in a completely fresh environment, except
--   that compilation info and statics are passed in unchanged. The current
--   environment is passed on completely unaltered, except that the Cmm
--   code from the fork is incorporated.
forkClosureBody :: Code -> Code

-- | <tt>forkStatics</tt> $fc$ compiles $fc$ in an environment whose
--   statics come from the current bindings, but which is otherwise freshly
--   initialised. The Cmm returned is attached to the current state, but
--   the bindings and usage information is otherwise unchanged.
forkStatics :: FCode a -> FCode a

-- | <tt>forkAlts</tt> $bs~d$ takes fcodes $bs$ for the branches of a
--   <tt>case</tt>, and an an fcode for the default case $d$, and compiles
--   each in the current environment. The current environment is passed on
--   unmodified, except that: * the worst stack high-water mark is
--   incorporated * the virtual Hp is moved on to the worst virtual Hp for
--   the branches
forkAlts :: [FCode a] -> FCode [a]

-- | <tt>forkEval</tt> takes two blocks of code.
--   
--   <ul>
--   <li>The first meddles with the environment to set it up as expected by
--   the alternatives of a <tt>case</tt> which does an eval (or gc-possible
--   primop). * The second block is the code for the alternatives. (plus
--   info for semi-tagging purposes)</li>
--   </ul>
--   
--   <tt>forkEval</tt> picks up the virtual stack pointer and returns a
--   suitable <tt>EndOfBlockInfo</tt> for the caller to use, together with
--   whatever value is returned by the second block.
--   
--   It uses <tt>initEnvForAlternatives</tt> to initialise the environment,
--   and <tt>stateIncUsageAlt</tt> to incorporate usage; the latter ignores
--   the heap usage.
forkEval :: EndOfBlockInfo -> Code -> FCode Sequel -> FCode EndOfBlockInfo
forkEvalHelp :: EndOfBlockInfo -> Code -> FCode a -> FCode (VirtualSpOffset, a)

-- | <tt>forkProc</tt> takes a code and compiles it in the current
--   environment, returning the basic blocks thus constructed. The current
--   environment is passed on completely unchanged. It is pretty similar to
--   <tt>getBlocks</tt>, except that the latter does affect the
--   environment.
forkProc :: Code -> FCode CgStmts
codeOnly :: Code -> Code
type SemiTaggingStuff = Maybe ([(ConTagZ, CmmLit)], CmmLit)
type ConTagZ = Int

-- | <tt>EndOfBlockInfo</tt> tells what to do at the end of this block of
--   code or, if the expression is a <tt>case</tt>, what to do at the end
--   of each alternative.
data EndOfBlockInfo
EndOfBlockInfo :: VirtualSpOffset -> Sequel -> EndOfBlockInfo
setEndOfBlockInfo :: EndOfBlockInfo -> Code -> Code
getEndOfBlockInfo :: FCode EndOfBlockInfo
setSRT :: SRT -> FCode a -> FCode a
getSRT :: FCode SRT
setSRTLabel :: CLabel -> FCode a -> FCode a
getSRTLabel :: FCode CLabel
setTickyCtrLabel :: CLabel -> Code -> Code
getTickyCtrLabel :: FCode CLabel

-- | Stack usage information during code generation.
--   
--   INVARIANT: The environment contains no Stable references to stack
--   slots below (lower offset) frameSp It can contain volatile references
--   to this area though.
data StackUsage
StackUsage :: VirtualSpOffset -> VirtualSpOffset -> [VirtualSpOffset] -> VirtualSpOffset -> VirtualSpOffset -> StackUsage
virtSp :: StackUsage -> VirtualSpOffset
frameSp :: StackUsage -> VirtualSpOffset
freeStk :: StackUsage -> [VirtualSpOffset]
realSp :: StackUsage -> VirtualSpOffset
hwSp :: StackUsage -> VirtualSpOffset

-- | Heap usage information during code generation.
--   
--   virtHp keeps track of the next location to allocate an object at.
--   realHp keeps track of what the Hp STG register actually points to. The
--   reason these aren't always the same is that we want to be able to move
--   the realHp in one go when allocating numerous objects to save having
--   to bump it each time. virtHp we do bump each time but it doesn't
--   create corresponding inefficient machine code.
data HeapUsage
HeapUsage :: VirtualHpOffset -> VirtualHpOffset -> HeapUsage
virtHp :: HeapUsage -> VirtualHpOffset
realHp :: HeapUsage -> VirtualHpOffset
type VirtualSpOffset = WordOff
type VirtualHpOffset = WordOff

-- | Initial stack usage
initStkUsage :: StackUsage

-- | Initial heap usage
initHpUsage :: HeapUsage
getHpUsage :: FCode HeapUsage
setHpUsage :: HeapUsage -> Code

-- | Return the heap usage high water mark
heapHWM :: HeapUsage -> VirtualHpOffset
getModuleName :: FCode Module

-- | <tt>Sequel</tt> is a representation of the next continuation to jump
--   to after the current function.
--   
--   Any addressing modes inside <tt>Sequel</tt> must be ``robust,'' in the
--   sense that it must survive stack pointer adjustments at the end of the
--   block.
data Sequel
OnStack :: Sequel
CaseAlts :: CLabel -> SemiTaggingStuff -> Id -> Sequel
getState :: FCode CgState
setState :: CgState -> FCode ()
getInfoDown :: FCode CgInfoDownwards
getDynFlags :: HasDynFlags m => m DynFlags
getThisPackage :: FCode PackageId
getStkUsage :: FCode StackUsage
setStkUsage :: StackUsage -> Code
getBinds :: FCode CgBindings
setBinds :: CgBindings -> FCode ()
getStaticBinds :: FCode CgBindings

-- | State only passed *downwards* by the monad
data CgInfoDownwards
MkCgInfoDown :: DynFlags -> Module -> CgBindings -> CLabel -> SRT -> CLabel -> EndOfBlockInfo -> CgInfoDownwards
cgd_dflags :: CgInfoDownwards -> DynFlags
cgd_mod :: CgInfoDownwards -> Module
cgd_statics :: CgInfoDownwards -> CgBindings
cgd_srt_lbl :: CgInfoDownwards -> CLabel
cgd_srt :: CgInfoDownwards -> SRT
cgd_ticky :: CgInfoDownwards -> CLabel
cgd_eob :: CgInfoDownwards -> EndOfBlockInfo

-- | State passed around and modified during code generation
data CgState
MkCgState :: OrdList CgStmt -> OrdList CmmDecl -> CgBindings -> StackUsage -> HeapUsage -> UniqSupply -> CgState
cgs_stmts :: CgState -> OrdList CgStmt
cgs_tops :: CgState -> OrdList CmmDecl
cgs_binds :: CgState -> CgBindings
cgs_stk_usg :: CgState -> StackUsage
cgs_hp_usg :: CgState -> HeapUsage
cgs_uniqs :: CgState -> UniqSupply
instance HasDynFlags FCode
instance Monad FCode

module CgUtils
addIdReps :: [Id] -> [(CgRep, Id)]
cgLit :: Literal -> FCode CmmLit
emitDataLits :: CLabel -> [CmmLit] -> Code
mkDataLits :: Section -> CLabel -> [CmmLit] -> GenCmmDecl CmmStatics info stmt
emitRODataLits :: String -> CLabel -> [CmmLit] -> Code
mkRODataLits :: CLabel -> [CmmLit] -> GenCmmDecl CmmStatics info stmt
emitIf :: CmmExpr -> Code -> Code
emitIfThenElse :: CmmExpr -> Code -> Code -> Code

-- | Emit code to call a Cmm function.
emitRtsCall :: PackageId -> FastString -> [CmmHinted CmmExpr] -> Code
emitRtsCallWithVols :: PackageId -> FastString -> [CmmHinted CmmExpr] -> [GlobalReg] -> Code
emitRtsCallWithResult :: LocalReg -> ForeignHint -> PackageId -> FastString -> [CmmHinted CmmExpr] -> Code
emitRtsCallGen :: [CmmHinted LocalReg] -> PackageId -> FastString -> [CmmHinted CmmExpr] -> Maybe [GlobalReg] -> Code

-- | If the expression is trivial, return it. Otherwise, assign the
--   expression to a temporary register and return an expression referring
--   to this register.
assignTemp :: CmmExpr -> FCode CmmExpr

-- | If the expression is trivial and doesn't refer to a global register,
--   return it. Otherwise, assign the expression to a temporary register
--   and return an expression referring to this register.
assignTemp_ :: CmmExpr -> FCode CmmExpr
newTemp :: CmmType -> FCode LocalReg
emitSimultaneously :: CmmStmts -> Code
emitSwitch :: CmmExpr -> [(ConTagZ, CgStmts)] -> Maybe CgStmts -> ConTagZ -> ConTagZ -> Code
emitLitSwitch :: CmmExpr -> [(Literal, CgStmts)] -> CgStmts -> Code
tagToClosure :: TyCon -> CmmExpr -> CmmExpr

-- | Returns <tt>True</tt> if this global register is stored in a
--   caller-saves machine register.
callerSaves :: GlobalReg -> Bool
callerSaveVolatileRegs :: Maybe [GlobalReg] -> ([CmmStmt], [CmmStmt])

-- | We map STG registers onto appropriate CmmExprs. Either they map to
--   real machine registers or stored as offsets from BaseReg. Given a
--   GlobalReg, get_GlobalReg_addr always produces the register table
--   address for it.
get_GlobalReg_addr :: GlobalReg -> CmmExpr

-- | Here is where the STG register map is defined for each target arch.
--   The order matters (for the llvm backend anyway)! We must make sure to
--   maintain the order here with the order used in the LLVM calling
--   conventions. Note that also, this isn't all registers, just the ones
--   that are currently possbily mapped to real registers.
activeStgRegs :: [GlobalReg]

-- | Fixup global registers so that they assign to locations within the
--   RegTable if they aren't pinned for the current target.
fixStgRegisters :: RawCmmDecl -> RawCmmDecl
cmmAndWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmOrWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmNegate :: CmmExpr -> CmmExpr
cmmEqWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmNeWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmUGtWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmSubWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmMulWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmAddWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmUShrWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmOffsetExprW :: CmmExpr -> CmmExpr -> CmmExpr
cmmOffsetExprB :: CmmExpr -> CmmExpr -> CmmExpr
cmmRegOffW :: CmmReg -> WordOff -> CmmExpr
cmmRegOffB :: CmmReg -> ByteOff -> CmmExpr
cmmLabelOffW :: CLabel -> WordOff -> CmmLit
cmmLabelOffB :: CLabel -> ByteOff -> CmmLit
cmmOffsetW :: CmmExpr -> WordOff -> CmmExpr
cmmOffsetB :: CmmExpr -> ByteOff -> CmmExpr
cmmOffsetLitW :: CmmLit -> WordOff -> CmmLit
cmmOffsetLitB :: CmmLit -> ByteOff -> CmmLit
cmmLoadIndexW :: CmmExpr -> Int -> CmmType -> CmmExpr
cmmConstrTag :: CmmExpr -> CmmExpr
cmmConstrTag1 :: CmmExpr -> CmmExpr
tagForCon :: DataCon -> ConTagZ
tagCons :: DataCon -> CmmExpr -> CmmExpr
isSmallFamily :: Int -> Bool
cmmUntag :: CmmExpr -> CmmExpr
cmmIsTagged :: CmmExpr -> CmmExpr
cmmGetTag :: CmmExpr -> CmmExpr
addToMem :: Width -> CmmExpr -> Int -> CmmStmt
addToMemE :: Width -> CmmExpr -> CmmExpr -> CmmStmt
mkWordCLit :: StgWord -> CmmLit
newStringCLit :: String -> FCode CmmLit
newByteStringCLit :: [Word8] -> FCode CmmLit
packHalfWordsCLit :: (Integral a, Integral b) => a -> b -> CmmLit
blankWord :: CmmStatic
getSRTInfo :: FCode C_SRT


-- | Base LLVM Code Generation module
--   
--   Contains functions useful through out the code generator.
module LlvmCodeGen.Base
type LlvmCmmDecl = GenCmmDecl [LlvmData] (Maybe CmmStatics) (ListGraph LlvmStatement)
type LlvmBasicBlock = GenBasicBlock LlvmStatement

-- | Unresolved code. Of the form: (data label, data type, unresolved data)
type LlvmUnresData = (CLabel, Section, LlvmType, [UnresStatic])

-- | Top level LLVM Data (globals and type aliases)
type LlvmData = ([LMGlobal], [LlvmType])

-- | An unresolved Label.
--   
--   Labels are unresolved when we haven't yet determined if they are
--   defined in the module we are currently compiling, or an external one.
type UnresLabel = CmmLit
type UnresStatic = Either UnresLabel LlvmStatic

-- | LLVM Version Number
type LlvmVersion = Int

-- | The LLVM Version we assume if we don't know
defaultLlvmVersion :: LlvmVersion
minSupportLlvmVersion :: LlvmVersion
maxSupportLlvmVersion :: LlvmVersion
data LlvmEnv

-- | Get initial Llvm environment.
initLlvmEnv :: DynFlags -> LlvmEnv

-- | Clear variables from the environment.
clearVars :: LlvmEnv -> LlvmEnv

-- | Lookup local variables in the environment.
varLookup :: Uniquable key => key -> LlvmEnv -> Maybe LlvmType

-- | Insert local variables into the environment.
varInsert :: Uniquable key => key -> LlvmType -> LlvmEnv -> LlvmEnv

-- | Lookup functions in the environment.
funLookup :: Uniquable key => key -> LlvmEnv -> Maybe LlvmType

-- | Insert functions into the environment.
funInsert :: Uniquable key => key -> LlvmType -> LlvmEnv -> LlvmEnv

-- | Get the LLVM version we are generating code for
getLlvmVer :: LlvmEnv -> LlvmVersion

-- | Set the LLVM version we are generating code for
setLlvmVer :: LlvmVersion -> LlvmEnv -> LlvmEnv

-- | Get the platform we are generating code for
getLlvmPlatform :: LlvmEnv -> Platform

-- | Get the DynFlags for this compilation pass
getDflags :: LlvmEnv -> DynFlags

-- | Here we pre-initialise some functions that are used internally by GHC
--   so as to make sure they have the most general type in the case that
--   user code also uses these functions but with a different type than GHC
--   internally. (Main offender is treating return type as <tt>void</tt>
--   instead of 'void *'. Fixes trac #5486.
ghcInternalFunctions :: [(LMString, LlvmFunctionDecl)]

-- | Translate a basic CmmType to an LlvmType.
cmmToLlvmType :: CmmType -> LlvmType

-- | Translate a Cmm Float Width to a LlvmType.
widthToLlvmFloat :: Width -> LlvmType

-- | Translate a Cmm Bit Width to a LlvmType.
widthToLlvmInt :: Width -> LlvmType

-- | Llvm Function type for Cmm function
llvmFunTy :: LlvmType

-- | Llvm Function signature
llvmFunSig :: LlvmEnv -> CLabel -> LlvmLinkageType -> LlvmFunctionDecl

-- | Llvm standard fun attributes
llvmStdFunAttrs :: [LlvmFuncAttr]

-- | Alignment to use for functions
llvmFunAlign :: LMAlign

-- | Alignment to use for into tables
llvmInfAlign :: LMAlign

-- | Pointer width
llvmPtrBits :: Int

-- | Create a Haskell function in LLVM.
mkLlvmFunc :: LlvmEnv -> CLabel -> LlvmLinkageType -> LMSection -> LlvmBlocks -> LlvmFunction

-- | Convert a list of types to a list of function parameters (each with no
--   parameter attributes)
tysToParams :: [LlvmType] -> [LlvmParameter]

-- | Pretty print a <a>CLabel</a>.
strCLabel_llvm :: LlvmEnv -> CLabel -> LMString

-- | Create an external definition for a <a>CLabel</a> defined in another
--   module.
genCmmLabelRef :: LlvmEnv -> CLabel -> LMGlobal

-- | As above (<a>genCmmLabelRef</a>) but taking a <a>LMString</a>, not
--   <a>CLabel</a>.
genStringLabelRef :: LMString -> LMGlobal


-- | Handle conversion of CmmData to LLVM code.
module LlvmCodeGen.Data

-- | Pass a CmmStatic section to an equivalent Llvm code. Can't complete
--   this completely though as we need to pass all CmmStatic sections
--   before all references can be resolved. This last step is done by
--   <a>resolveLlvmData</a>.
genLlvmData :: LlvmEnv -> (Section, CmmStatics) -> LlvmUnresData
resolveLlvmDatas :: LlvmEnv -> [LlvmUnresData] -> (LlvmEnv, [LlvmData])

-- | Fix up CLabel references now that we should have passed all CmmData.
resolveLlvmData :: LlvmEnv -> LlvmUnresData -> (LlvmEnv, LlvmData)


-- | Pretty print helpers for the LLVM Code generator.
module LlvmCodeGen.Ppr

-- | Header code for LLVM modules
pprLlvmHeader :: SDoc

-- | Pretty print LLVM code
pprLlvmCmmDecl :: LlvmEnv -> Int -> LlvmCmmDecl -> (SDoc, [LlvmVar])

-- | Pretty print LLVM data code
pprLlvmData :: LlvmData -> SDoc

-- | The section we are putting info tables and their entry code into,
--   should be unique since we process the assembly pattern matching this.
infoSection :: String

-- | We generate labels for info tables by converting them to the same
--   label as for the entry code but adding this string as a suffix.
iTableSuf :: String


-- | GHC LLVM Mangler
--   
--   This script processes the assembly produced by LLVM, rearranging the
--   code so that an info table appears before its corresponding function.
module LlvmMangler

-- | Read in assembly file and process
llvmFixupAsm :: DynFlags -> FilePath -> FilePath -> IO ()


-- | Handle conversion of CmmProc to LLVM code.
module LlvmCodeGen.CodeGen

-- | Top-level of the LLVM proc Code generator
genLlvmProc :: LlvmEnv -> RawCmmDecl -> UniqSM (LlvmEnv, [LlvmCmmDecl])


-- | This is the top-level module in the LLVM code generator.
module LlvmCodeGen

-- | Top-level of the LLVM Code generator
llvmCodeGen :: DynFlags -> Handle -> UniqSupply -> [RawCmmGroup] -> IO ()

-- | Read in assembly file and process
llvmFixupAsm :: DynFlags -> FilePath -> FilePath -> IO ()


-- | Our extended FCode monad.
module CgExtCode

-- | Does a computation in the FCode monad, with a current environment and
--   a list of local declarations. Returns the resulting list of
--   declarations.
newtype ExtFCode a
EC :: (Env -> Decls -> FCode (Decls, a)) -> ExtFCode a
unEC :: ExtFCode a -> Env -> Decls -> FCode (Decls, a)
type ExtCode = ExtFCode ()

-- | The environment contains variable definitions or blockids.
data Named

-- | Holds CmmLit(CmmLabel ..) which gives the label type, eg, RtsLabel,
--   ForeignLabel, CmmLabel etc.
VarN :: CmmExpr -> Named

-- | A function name from this package
FunN :: PackageId -> Named

-- | A blockid of some code or data.
LabelN :: BlockId -> Named

-- | An environment of named things.
type Env = UniqFM Named

-- | Takes the variable decarations and imports from the monad and makes an
--   environment, which is looped back into the computation. In this way,
--   we can have embedded declarations that scope over the whole procedure,
--   and imports that scope over the entire module. Discards the local
--   declaration contained within decl'
loopDecls :: ExtFCode a -> ExtFCode a

-- | Get the current environment from the monad.
getEnv :: ExtFCode Env

-- | Create a fresh local variable of a given type.
newLocal :: CmmType -> FastString -> ExtFCode LocalReg

-- | Allocate a fresh label.
newLabel :: FastString -> ExtFCode BlockId

-- | Add add a local function to the environment.
newFunctionName :: FastString -> PackageId -> ExtCode

-- | Add an imported foreign label to the list of local declarations. If
--   this is done at the start of the module the declaration will scope
--   over the whole module.
newImport :: (FastString, CLabel) -> ExtFCode ()

-- | Lookup the BlockId bound to the label with this name. If one hasn't
--   been bound yet, create a fresh one based on the Unique of the name.
lookupLabel :: FastString -> ExtFCode BlockId

-- | Lookup the location of a named variable. Unknown names are treated as
--   if they had been 'import'ed from the runtime system. This saves us a
--   lot of bother in the RTS sources, at the expense of deferring some
--   errors to link time.
lookupName :: FastString -> ExtFCode CmmExpr

-- | Lift an FCode computation into the ExtFCode monad
code :: FCode a -> ExtFCode a
code2 :: (FCode (Decls, b) -> FCode ((Decls, b), c)) -> ExtFCode b -> ExtFCode c

-- | Do nothing in the ExtFCode monad.
nopEC :: ExtFCode ()

-- | Accumulate a CmmStmt into the monad state.
stmtEC :: CmmStmt -> ExtFCode ()

-- | Accumulate some CmmStmts into the monad state.
stmtsEC :: [CmmStmt] -> ExtFCode ()

-- | Get the generated statements out of the monad state.
getCgStmtsEC :: ExtFCode a -> ExtFCode CgStmts

-- | Get the generated statements, and the return value out of the monad
--   state.
getCgStmtsEC' :: ExtFCode a -> ExtFCode (a, CgStmts)

-- | Emit a chunk of code outside the instruction stream, and return its
--   block id.
forkLabelledCodeEC :: ExtFCode a -> ExtFCode BlockId
instance Monad ExtFCode

module CgProf
mkCCostCentre :: CostCentre -> CmmLit
mkCCostCentreStack :: CostCentreStack -> CmmLit
dynProfHdr :: CmmExpr -> [CmmExpr]

-- | Record the allocation of a closure. The CmmExpr is the cost centre
--   stack to which to attribute the allocation.
profDynAlloc :: ClosureInfo -> CmmExpr -> Code

-- | Record the allocation of a closure (size is given by a CmmExpr) The
--   size must be in words, because the allocation counter in a CCS counts
--   in words.
--   
--   This API is used by the <tt>CCS_ALLOC()</tt> macro in <tt>.cmm</tt>
--   code.
profAlloc :: CmmExpr -> CmmExpr -> Code
staticProfHdr :: CostCentreStack -> [CmmLit]
initUpdFrameProf :: CmmExpr -> Code
enterCostCentreThunk :: CmmExpr -> Code
enterCostCentreFun :: CostCentreStack -> CmmExpr -> [GlobalReg] -> Code
costCentreFrom :: CmmExpr -> CmmExpr
curCCS :: CmmExpr
storeCurCCS :: CmmExpr -> CmmStmt
emitCostCentreDecl :: CostCentre -> Code
emitCostCentreStackDecl :: CostCentreStack -> Code
emitSetCCC :: CostCentre -> Bool -> Bool -> Code
ldvEnter :: CmmExpr -> Code
ldvEnterClosure :: ClosureInfo -> Code
ldvRecordCreate :: CmmExpr -> Code

module CgTicky
emitTickyCounter :: ClosureInfo -> [Id] -> Int -> Code
tickyDynAlloc :: ClosureInfo -> Code
tickyAllocHeap :: VirtualHpOffset -> Code
tickyAllocPrim :: CmmExpr -> CmmExpr -> CmmExpr -> Code
tickyAllocThunk :: CmmExpr -> CmmExpr -> Code
tickyAllocPAP :: CmmExpr -> CmmExpr -> Code
tickyPushUpdateFrame :: Code
tickyUpdateFrameOmitted :: Code
tickyEnterDynCon :: Code
tickyEnterStaticCon :: Code
tickyEnterViaNode :: Code
tickyEnterFun :: ClosureInfo -> Code
tickyEnterThunk :: ClosureInfo -> Code
tickyUpdateBhCaf :: ClosureInfo -> Code
tickyBlackHole :: Bool -> Code
tickyUnboxedTupleReturn :: Int -> Code
tickyVectoredReturn :: Int -> Code
tickyReturnOldCon :: Arity -> Code
tickyReturnNewCon :: Arity -> Code
tickyKnownCallTooFewArgs :: Code
tickyKnownCallExact :: Code
tickyKnownCallExtraArgs :: Code
tickyUnknownCall :: Code
tickySlowCallPat :: [CgRep] -> Code
staticTickyHdr :: [CmmLit]

module CgStackery
spRel :: VirtualSpOffset -> VirtualSpOffset -> WordOff
getVirtSp :: FCode VirtualSpOffset
getRealSp :: FCode VirtualSpOffset
setRealSp :: VirtualSpOffset -> Code
setRealAndVirtualSp :: VirtualSpOffset -> Code
getSpRelOffset :: VirtualSpOffset -> FCode CmmExpr
allocPrimStack :: CgRep -> FCode VirtualSpOffset
allocStackTop :: WordOff -> FCode ()
deAllocStackTop :: WordOff -> FCode ()
adjustStackHW :: VirtualSpOffset -> Code
getFinalStackHW :: (VirtualSpOffset -> Code) -> Code
setStackFrame :: VirtualSpOffset -> Code
getStackFrame :: FCode VirtualSpOffset
mkVirtStkOffsets :: VirtualSpOffset -> [(CgRep, a)] -> (VirtualSpOffset, [(a, VirtualSpOffset)])

-- | <a>mkStkAmodes</a> is a higher-level version of
--   <a>mkVirtStkOffsets</a>. It starts from the tail-call locations. It
--   returns a single list of addressing modes for the stack locations, and
--   therefore is in the monad. It <i>doesn't</i> adjust the high water
--   mark.
mkStkAmodes :: VirtualSpOffset -> [(CgRep, CmmExpr)] -> FCode (VirtualSpOffset, CmmStmts)
freeStackSlots :: [VirtualSpOffset] -> Code
pushUpdateFrame :: CmmExpr -> Code -> Code
pushBHUpdateFrame :: CmmExpr -> Code -> Code
emitPushUpdateFrame :: CmmExpr -> CmmExpr -> Code

module CgCallConv
mkArgDescr :: Name -> [Id] -> FCode ArgDescr
mkRegLiveness :: [(Id, GlobalReg)] -> Int -> Int -> StgWord
assignCallRegs :: [(CgRep, a)] -> ([(a, GlobalReg)], [(CgRep, a)])
assignReturnRegs :: [(CgRep, a)] -> ([(a, GlobalReg)], [(CgRep, a)])
assignPrimOpCallRegs :: [(CgRep, a)] -> ([(a, GlobalReg)], [(CgRep, a)])
constructSlowCall :: [(CgRep, CmmExpr)] -> (CLabel, [(CgRep, CmmExpr)], [(CgRep, CmmExpr)])

-- | <a>slowArgs</a> takes a list of function arguments and prepares them
--   for pushing on the stack for <a>extra</a> arguments to a function
--   which requires fewer arguments than we currently have.
slowArgs :: [(CgRep, CmmExpr)] -> [(CgRep, CmmExpr)]
slowCallPattern :: [CgRep] -> (FastString, Int)
dataReturnConvPrim :: CgRep -> CmmReg
getSequelAmode :: FCode CmmExpr

module CgParallel
staticGranHdr :: [CmmLit]
staticParHdr :: [CmmLit]
granFetchAndReschedule :: [(Id, GlobalReg)] -> Bool -> Code
granYield :: [(Id, GlobalReg)] -> Bool -> Code
doGranAllocate :: CmmExpr -> Code

module CgHeapery
initHeapUsage :: (VirtualHpOffset -> Code) -> Code
getVirtHp :: FCode VirtualHpOffset
setVirtHp :: VirtualHpOffset -> Code
setRealHp :: VirtualHpOffset -> Code
getHpRelOffset :: VirtualHpOffset -> FCode CmmExpr
hpRel :: VirtualHpOffset -> VirtualHpOffset -> WordOff
funEntryChecks :: ClosureInfo -> CmmStmts -> Maybe [GlobalReg] -> Code -> Code
thunkEntryChecks :: ClosureInfo -> Code -> Code
altHeapCheck :: AltType -> Code -> Code
unbxTupleHeapCheck :: [(Id, GlobalReg)] -> WordOff -> WordOff -> CmmStmts -> Code -> Code
hpChkGen :: CmmExpr -> CmmExpr -> CmmExpr -> Code
hpChkNodePointsAssignSp0 :: CmmExpr -> CmmExpr -> Code
stkChkGen :: CmmExpr -> CmmExpr -> CmmExpr -> Code
stkChkNodePoints :: CmmExpr -> Code
layOutDynConstr :: DataCon -> [(CgRep, a)] -> (ClosureInfo, [(a, VirtualHpOffset)])
layOutStaticConstr :: DataCon -> [(CgRep, a)] -> (ClosureInfo, [(a, VirtualHpOffset)])
mkVirtHeapOffsets :: Bool -> [(CgRep, a)] -> (WordOff, WordOff, [(a, VirtualHpOffset)])
mkStaticClosureFields :: ClosureInfo -> CostCentreStack -> Bool -> [CmmLit] -> [CmmLit]
mkStaticClosure :: CLabel -> CostCentreStack -> [CmmLit] -> [CmmLit] -> [CmmLit] -> [CmmLit] -> [CmmLit]
allocDynClosure :: ClosureInfo -> CmmExpr -> CmmExpr -> [(CmmExpr, VirtualHpOffset)] -> FCode VirtualHpOffset
emitSetDynHdr :: CmmExpr -> CmmExpr -> CmmExpr -> Code

module ByteCodeItbls
type ItblEnv = NameEnv (Name, ItblPtr)
newtype ItblPtr
ItblPtr :: (Ptr ()) -> ItblPtr
itblCode :: ItblPtr -> Ptr ()
mkITbls :: [TyCon] -> IO ItblEnv
data StgInfoTable
StgInfoTable :: HalfWord -> HalfWord -> HalfWord -> HalfWord -> [ItblCode] -> StgInfoTable
ptrs :: StgInfoTable -> HalfWord
nptrs :: StgInfoTable -> HalfWord
tipe :: StgInfoTable -> HalfWord
srtlen :: StgInfoTable -> HalfWord
code :: StgInfoTable -> [ItblCode]
newtype State s m a
State :: (s -> m (s, a)) -> State s m a
runState :: Monad m => s -> State s m a -> m (s, a)
evalState :: Monad m => s -> State s m a -> m a
execState :: Monad m => s -> State s m a -> m s
class (Monad m, Monad (t m)) => MonadT t m
lift :: MonadT t m => m a -> t m a
instance Show ItblPtr
instance Monad m => MonadT (State s) m
instance Monad m => Monad (State s m)
instance Storable StgInfoTable
instance Storable StgConInfoTable

module ByteCodeInstr
data BCInstr
STKCHECK :: Word -> BCInstr
PUSH_L :: !Word16 -> BCInstr
PUSH_LL :: !Word16 -> !Word16 -> BCInstr
PUSH_LLL :: !Word16 -> !Word16 -> !Word16 -> BCInstr
PUSH_G :: Name -> BCInstr
PUSH_PRIMOP :: PrimOp -> BCInstr
PUSH_BCO :: (ProtoBCO Name) -> BCInstr
PUSH_ALTS :: (ProtoBCO Name) -> BCInstr
PUSH_ALTS_UNLIFTED :: (ProtoBCO Name) -> CgRep -> BCInstr
PUSH_UBX :: (Either Literal (Ptr ())) -> Word16 -> BCInstr
PUSH_APPLY_N :: BCInstr
PUSH_APPLY_V :: BCInstr
PUSH_APPLY_F :: BCInstr
PUSH_APPLY_D :: BCInstr
PUSH_APPLY_L :: BCInstr
PUSH_APPLY_P :: BCInstr
PUSH_APPLY_PP :: BCInstr
PUSH_APPLY_PPP :: BCInstr
PUSH_APPLY_PPPP :: BCInstr
PUSH_APPLY_PPPPP :: BCInstr
PUSH_APPLY_PPPPPP :: BCInstr
SLIDE :: Word16 -> Word16 -> BCInstr
ALLOC_AP :: !Word16 -> BCInstr
ALLOC_AP_NOUPD :: !Word16 -> BCInstr
ALLOC_PAP :: !Word16 -> !Word16 -> BCInstr
MKAP :: !Word16 -> !Word16 -> BCInstr
MKPAP :: !Word16 -> !Word16 -> BCInstr
UNPACK :: !Word16 -> BCInstr
PACK :: DataCon -> !Word16 -> BCInstr
LABEL :: LocalLabel -> BCInstr
TESTLT_I :: Int -> LocalLabel -> BCInstr
TESTEQ_I :: Int -> LocalLabel -> BCInstr
TESTLT_W :: Word -> LocalLabel -> BCInstr
TESTEQ_W :: Word -> LocalLabel -> BCInstr
TESTLT_F :: Float -> LocalLabel -> BCInstr
TESTEQ_F :: Float -> LocalLabel -> BCInstr
TESTLT_D :: Double -> LocalLabel -> BCInstr
TESTEQ_D :: Double -> LocalLabel -> BCInstr
TESTLT_P :: Word16 -> LocalLabel -> BCInstr
TESTEQ_P :: Word16 -> LocalLabel -> BCInstr
CASEFAIL :: BCInstr
JMP :: LocalLabel -> BCInstr
CCALL :: Word16 -> (Ptr ()) -> Word16 -> BCInstr
SWIZZLE :: Word16 -> Word16 -> BCInstr
ENTER :: BCInstr
RETURN :: BCInstr
RETURN_UBX :: CgRep -> BCInstr
BRK_FUN :: (MutableByteArray# RealWorld) -> Word16 -> BreakInfo -> BCInstr
data ProtoBCO a
ProtoBCO :: a -> [BCInstr] -> [StgWord] -> Word16 -> Int -> Either [AnnAlt Id VarSet] (AnnExpr Id VarSet) -> [Either ItblPtr (Ptr ())] -> ProtoBCO a
protoBCOName :: ProtoBCO a -> a
protoBCOInstrs :: ProtoBCO a -> [BCInstr]
protoBCOBitmap :: ProtoBCO a -> [StgWord]
protoBCOBitmapSize :: ProtoBCO a -> Word16
protoBCOArity :: ProtoBCO a -> Int
protoBCOExpr :: ProtoBCO a -> Either [AnnAlt Id VarSet] (AnnExpr Id VarSet)
protoBCOPtrs :: ProtoBCO a -> [Either ItblPtr (Ptr ())]
bciStackUse :: BCInstr -> Word
data BreakInfo
BreakInfo :: Module -> {-# UNPACK #-} !Int -> [(Id, Word16)] -> Type -> BreakInfo
breakInfo_module :: BreakInfo -> Module
breakInfo_number :: BreakInfo -> {-# UNPACK #-} !Int
breakInfo_vars :: BreakInfo -> [(Id, Word16)]
breakInfo_resty :: BreakInfo -> Type
instance Outputable BCInstr
instance Outputable a => Outputable (ProtoBCO a)
instance Outputable BreakInfo

module ByteCodeAsm
assembleBCOs :: DynFlags -> [ProtoBCO Name] -> [TyCon] -> IO CompiledByteCode
assembleBCO :: DynFlags -> ProtoBCO Name -> IO UnlinkedBCO
data CompiledByteCode
ByteCode :: [UnlinkedBCO] -> ItblEnv -> CompiledByteCode
data UnlinkedBCO
UnlinkedBCO :: Name -> Int -> ByteArray# -> ByteArray# -> (SizedSeq BCONPtr) -> (SizedSeq BCOPtr) -> UnlinkedBCO
unlinkedBCOName :: UnlinkedBCO -> Name
unlinkedBCOArity :: UnlinkedBCO -> Int
unlinkedBCOInstrs :: UnlinkedBCO -> ByteArray#
unlinkedBCOBitmap :: UnlinkedBCO -> ByteArray#
unlinkedBCOLits :: UnlinkedBCO -> (SizedSeq BCONPtr)
unlinkedBCOPtrs :: UnlinkedBCO -> (SizedSeq BCOPtr)
data BCOPtr
BCOPtrName :: Name -> BCOPtr
BCOPtrPrimOp :: PrimOp -> BCOPtr
BCOPtrBCO :: UnlinkedBCO -> BCOPtr
BCOPtrBreakInfo :: BreakInfo -> BCOPtr
BCOPtrArray :: (MutableByteArray# RealWorld) -> BCOPtr
data BCONPtr
BCONPtrWord :: Word -> BCONPtr
BCONPtrLbl :: FastString -> BCONPtr
BCONPtrItbl :: Name -> BCONPtr

-- | Finds external references. Remember to remove the names defined by
--   this group of BCOs themselves
bcoFreeNames :: UnlinkedBCO -> NameSet
data SizedSeq a
sizeSS :: SizedSeq a -> Word
ssElts :: SizedSeq a -> [a]
iNTERP_STACK_CHECK_THRESH :: Int
instance Monad Assembler
instance Outputable UnlinkedBCO
instance Outputable CompiledByteCode


-- | Types for the per-module compiler
module HscTypes

-- | Hscenv is like <tt>Session</tt>, except that some of the fields are
--   immutable. An HscEnv is used to compile a single module from plain
--   Haskell source code (after preprocessing) to either C, assembly or
--   C--. Things like the module graph don't change during a single
--   compilation.
--   
--   Historical note: "hsc" used to be the name of the compiler binary,
--   when there was a separate driver and compiler. To compile a single
--   module, the driver would invoke hsc on the source code... so nowadays
--   we think of hsc as the layer of the compiler that deals with compiling
--   a single module.
data HscEnv
HscEnv :: DynFlags -> [Target] -> ModuleGraph -> InteractiveContext -> HomePackageTable -> {-# UNPACK #-} !(IORef ExternalPackageState) -> {-# UNPACK #-} !(IORef NameCache) -> {-# UNPACK #-} !(IORef FinderCache) -> {-# UNPACK #-} !(IORef ModLocationCache) -> Maybe (Module, IORef TypeEnv) -> HscEnv

-- | The dynamic flag settings
hsc_dflags :: HscEnv -> DynFlags

-- | The targets (or roots) of the current session
hsc_targets :: HscEnv -> [Target]

-- | The module graph of the current session
hsc_mod_graph :: HscEnv -> ModuleGraph

-- | The context for evaluating interactive statements
hsc_IC :: HscEnv -> InteractiveContext

-- | The home package table describes already-compiled home-package
--   modules, <i>excluding</i> the module we are compiling right now. (In
--   one-shot mode the current module is the only home-package module, so
--   hsc_HPT is empty. All other modules count as "external-package"
--   modules. However, even in GHCi mode, hi-boot interfaces are
--   demand-loaded into the external-package table.)
--   
--   <a>hsc_HPT</a> is not mutable because we only demand-load external
--   packages; the home package is eagerly loaded, module by module, by the
--   compilation manager.
--   
--   The HPT may contain modules compiled earlier by <tt>--make</tt> but
--   not actually below the current module in the dependency graph.
--   
--   (This changes a previous invariant: changed Jan 05.)
hsc_HPT :: HscEnv -> HomePackageTable

-- | Information about the currently loaded external packages. This is
--   mutable because packages will be demand-loaded during a compilation
--   run as required.
hsc_EPS :: HscEnv -> {-# UNPACK #-} !(IORef ExternalPackageState)

-- | As with <a>hsc_EPS</a>, this is side-effected by compiling to reflect
--   sucking in interface files. They cache the state of external interface
--   files, in effect.
hsc_NC :: HscEnv -> {-# UNPACK #-} !(IORef NameCache)

-- | The cached result of performing finding in the file system
hsc_FC :: HscEnv -> {-# UNPACK #-} !(IORef FinderCache)

-- | This caches the location of modules, so we don't have to search the
--   filesystem multiple times. See also <a>hsc_FC</a>.
hsc_MLC :: HscEnv -> {-# UNPACK #-} !(IORef ModLocationCache)

-- | Used for one-shot compilation only, to initialise the
--   <tt>IfGblEnv</tt>. See <a>tcg_type_env_var</a> for <a>TcGblEnv</a>
hsc_type_env_var :: HscEnv -> Maybe (Module, IORef TypeEnv)

-- | Retrieve the ExternalPackageState cache.
hscEPS :: HscEnv -> IO ExternalPackageState

-- | The <a>FinderCache</a> maps home module names to the result of
--   searching for that module. It records the results of searching for
--   modules along the search path. On <tt>:load</tt>, we flush the entire
--   contents of this cache.
--   
--   Although the <tt>FinderCache</tt> range is <a>FindResult</a> for
--   convenience, in fact it will only ever contain <a>Found</a> or
--   <a>NotFound</a> entries.
type FinderCache = ModuleNameEnv FindResult

-- | The result of searching for an imported module.
data FindResult

-- | The module was found
Found :: ModLocation -> Module -> FindResult

-- | The requested package was not found
NoPackage :: PackageId -> FindResult

-- | _Error_: both in multiple packages
FoundMultiple :: [PackageId] -> FindResult

-- | Not found
NotFound :: [FilePath] -> Maybe PackageId -> [PackageId] -> [PackageId] -> [Module] -> FindResult
fr_paths :: FindResult -> [FilePath]
fr_pkg :: FindResult -> Maybe PackageId
fr_mods_hidden :: FindResult -> [PackageId]
fr_pkgs_hidden :: FindResult -> [PackageId]
fr_suggestions :: FindResult -> [Module]

-- | Cache that remembers where we found a particular module. Contains both
--   home modules and package modules. On <tt>:load</tt>, only home modules
--   are purged from this cache.
type ModLocationCache = ModuleEnv ModLocation

-- | A compilation target.
--   
--   A target may be supplied with the actual text of the module. If so,
--   use this instead of the file contents (this is for use in an IDE where
--   the file hasn't been saved by the user yet).
data Target
Target :: TargetId -> Bool -> Maybe (StringBuffer, UTCTime) -> Target

-- | module or filename
targetId :: Target -> TargetId

-- | object code allowed?
targetAllowObjCode :: Target -> Bool

-- | in-memory text buffer?
targetContents :: Target -> Maybe (StringBuffer, UTCTime)
data TargetId

-- | A module name: search for the file
TargetModule :: ModuleName -> TargetId

-- | A filename: preprocess &amp; parse it to find the module name. If
--   specified, the Phase indicates how to compile this file (which phase
--   to start from). Nothing indicates the starting phase should be
--   determined from the suffix of the filename.
TargetFile :: FilePath -> (Maybe Phase) -> TargetId
pprTarget :: Target -> SDoc
pprTargetId :: TargetId -> SDoc

-- | A ModuleGraph contains all the nodes from the home package (only).
--   There will be a node for each source module, plus a node for each
--   hi-boot module.
--   
--   The graph is not necessarily stored in topologically-sorted order. Use
--   <a>topSortModuleGraph</a> and <a>flattenSCC</a> to achieve this.
type ModuleGraph = [ModSummary]
emptyMG :: ModuleGraph

-- | The <a>ModDetails</a> is essentially a cache for information in the
--   <a>ModIface</a> for home modules only. Information relating to
--   packages will be loaded into global environments in
--   <a>ExternalPackageState</a>.
data ModDetails
ModDetails :: [AvailInfo] -> !TypeEnv -> ![ClsInst] -> ![FamInst] -> ![CoreRule] -> ![Annotation] -> !VectInfo -> ModDetails
md_exports :: ModDetails -> [AvailInfo]

-- | Local type environment for this particular module
md_types :: ModDetails -> !TypeEnv

-- | <a>DFunId</a>s for the instances in this module
md_insts :: ModDetails -> ![ClsInst]
md_fam_insts :: ModDetails -> ![FamInst]

-- | Domain may include <a>Id</a>s from other modules
md_rules :: ModDetails -> ![CoreRule]

-- | Annotations present in this module: currently they only annotate
--   things also declared in this module
md_anns :: ModDetails -> ![Annotation]

-- | Module vectorisation information
md_vect_info :: ModDetails -> !VectInfo

-- | Constructs an empty ModDetails
emptyModDetails :: ModDetails

-- | A ModGuts is carried through the compiler, accumulating stuff as it
--   goes There is only one ModGuts at any time, the one for the module
--   being compiled right now. Once it is compiled, a <a>ModIface</a> and
--   <a>ModDetails</a> are extracted and the ModGuts is discarded.
data ModGuts
ModGuts :: !Module -> IsBootInterface -> ![AvailInfo] -> !Dependencies -> !ImportedMods -> !NameSet -> !Bool -> !GlobalRdrEnv -> !FixityEnv -> ![TyCon] -> ![ClsInst] -> ![FamInst] -> ![CoreRule] -> !CoreProgram -> !ForeignStubs -> !Warnings -> [Annotation] -> !HpcInfo -> !ModBreaks -> ![CoreVect] -> !VectInfo -> InstEnv -> FamInstEnv -> SafeHaskellMode -> Bool -> [FilePath] -> ModGuts

-- | Module being compiled
mg_module :: ModGuts -> !Module

-- | Whether it's an hs-boot module
mg_boot :: ModGuts -> IsBootInterface

-- | What it exports
mg_exports :: ModGuts -> ![AvailInfo]

-- | What it depends on, directly or otherwise
mg_deps :: ModGuts -> !Dependencies

-- | Directly-imported modules; used to generate initialisation code
mg_dir_imps :: ModGuts -> !ImportedMods

-- | What the module needed (used in <a>mkIface</a>)
mg_used_names :: ModGuts -> !NameSet

-- | Did we run a TH splice?
mg_used_th :: ModGuts -> !Bool

-- | Top-level lexical environment
mg_rdr_env :: ModGuts -> !GlobalRdrEnv

-- | Fixities declared in this module ToDo: I'm unconvinced this is
--   actually used anywhere
mg_fix_env :: ModGuts -> !FixityEnv

-- | TyCons declared in this module (includes TyCons for classes)
mg_tcs :: ModGuts -> ![TyCon]

-- | Class instances declared in this module
mg_insts :: ModGuts -> ![ClsInst]

-- | Family instances declared in this module
mg_fam_insts :: ModGuts -> ![FamInst]

-- | Before the core pipeline starts, contains See Note [Overall plumbing
--   for rules] in Rules.lhs
mg_rules :: ModGuts -> ![CoreRule]

-- | Bindings for this module
mg_binds :: ModGuts -> !CoreProgram

-- | Foreign exports declared in this module
mg_foreign :: ModGuts -> !ForeignStubs

-- | Warnings declared in the module
mg_warns :: ModGuts -> !Warnings

-- | Annotations declared in this module
mg_anns :: ModGuts -> [Annotation]

-- | Coverage tick boxes in the module
mg_hpc_info :: ModGuts -> !HpcInfo

-- | Breakpoints for the module
mg_modBreaks :: ModGuts -> !ModBreaks

-- | Vectorisation declarations in this module (produced by desugarer &amp;
--   consumed by vectoriser)
mg_vect_decls :: ModGuts -> ![CoreVect]

-- | Pool of vectorised declarations in the module
mg_vect_info :: ModGuts -> !VectInfo

-- | Class instance environment from <i>home-package</i> modules (including
--   this one); c.f. <tt>tcg_inst_env</tt>
mg_inst_env :: ModGuts -> InstEnv

-- | Type-family instance enviroment for <i>home-package</i> modules
--   (including this one); c.f. <tt>tcg_fam_inst_env</tt>
mg_fam_inst_env :: ModGuts -> FamInstEnv

-- | Safe Haskell mode
mg_safe_haskell :: ModGuts -> SafeHaskellMode

-- | Do we need to trust our own package for Safe Haskell? See Note
--   [RnNames . Trust Own Package]
mg_trust_pkg :: ModGuts -> Bool

-- | dependencies from addDependentFile
mg_dependent_files :: ModGuts -> [FilePath]

-- | A restricted form of <a>ModGuts</a> for code generation purposes
data CgGuts
CgGuts :: !Module -> [TyCon] -> CoreProgram -> !ForeignStubs -> ![PackageId] -> !HpcInfo -> !ModBreaks -> CgGuts

-- | Module being compiled
cg_module :: CgGuts -> !Module

-- | Algebraic data types (including ones that started life as classes);
--   generate constructors and info tables. Includes newtypes, just for the
--   benefit of External Core
cg_tycons :: CgGuts -> [TyCon]

-- | The tidied main bindings, including previously-implicit bindings for
--   record and class selectors, and data construtor wrappers. But *not*
--   data constructor workers; reason: we we regard them as part of the
--   code-gen of tycons
cg_binds :: CgGuts -> CoreProgram

-- | Foreign export stubs
cg_foreign :: CgGuts -> !ForeignStubs

-- | Dependent packages, used to generate #includes for C code gen
cg_dep_pkgs :: CgGuts -> ![PackageId]

-- | Program coverage tick box information
cg_hpc_info :: CgGuts -> !HpcInfo

-- | Module breakpoints
cg_modBreaks :: CgGuts -> !ModBreaks

-- | Foreign export stubs
data ForeignStubs

-- | We don't have any stubs
NoStubs :: ForeignStubs

-- | There are some stubs. Parameters:
--   
--   1) Header file prototypes for <a>foreign exported</a> functions
--   
--   2) C stubs to use when calling <a>foreign exported</a> functions
ForeignStubs :: SDoc -> SDoc -> ForeignStubs
appendStubC :: ForeignStubs -> SDoc -> ForeignStubs

-- | Records the modules directly imported by a module for extracting e.g.
--   usage information
type ImportedMods = ModuleEnv [ImportedModsVal]
type ImportedModsVal = (ModuleName, Bool, SrcSpan, IsSafeImport)

-- | A single node in a 'ModuleGraph. The nodes of the module graph are one
--   of:
--   
--   <ul>
--   <li>A regular Haskell source module</li>
--   <li>A hi-boot source module</li>
--   <li>An external-core source module</li>
--   </ul>
data ModSummary
ModSummary :: Module -> HscSource -> ModLocation -> UTCTime -> Maybe UTCTime -> [Located (ImportDecl RdrName)] -> [Located (ImportDecl RdrName)] -> FilePath -> DynFlags -> Maybe StringBuffer -> ModSummary

-- | Identity of the module
ms_mod :: ModSummary -> Module

-- | The module source either plain Haskell, hs-boot or external core
ms_hsc_src :: ModSummary -> HscSource

-- | Location of the various files belonging to the module
ms_location :: ModSummary -> ModLocation

-- | Timestamp of source file
ms_hs_date :: ModSummary -> UTCTime

-- | Timestamp of object, if we have one
ms_obj_date :: ModSummary -> Maybe UTCTime

-- | Source imports of the module
ms_srcimps :: ModSummary -> [Located (ImportDecl RdrName)]

-- | Non-source imports of the module from the module *text*
ms_textual_imps :: ModSummary -> [Located (ImportDecl RdrName)]

-- | Filename of preprocessed source file
ms_hspp_file :: ModSummary -> FilePath

-- | Cached flags from <tt>OPTIONS</tt>, <tt>INCLUDE</tt> and
--   <tt>LANGUAGE</tt> pragmas in the modules source code
ms_hspp_opts :: ModSummary -> DynFlags

-- | The actual preprocessed source, if we have it
ms_hspp_buf :: ModSummary -> Maybe StringBuffer
ms_imps :: ModSummary -> [Located (ImportDecl RdrName)]
ms_mod_name :: ModSummary -> ModuleName
showModMsg :: DynFlags -> HscTarget -> Bool -> ModSummary -> String

-- | Did this <a>ModSummary</a> originate from a hs-boot file?
isBootSummary :: ModSummary -> Bool
msHsFilePath :: ModSummary -> FilePath
msHiFilePath :: ModSummary -> FilePath
msObjFilePath :: ModSummary -> FilePath

-- | Indicates whether a given module's source has been modified since it
--   was last compiled.
data SourceModified

-- | the source has been modified
SourceModified :: SourceModified

-- | the source has not been modified. Compilation may or may not be
--   necessary, depending on whether any dependencies have changed since we
--   last compiled.
SourceUnmodified :: SourceModified

-- | the source has not been modified, and furthermore all of its
--   (transitive) dependencies are up to date; it definitely does not need
--   to be recompiled. This is important for two reasons: (a) we can omit
--   the version check in checkOldIface, and (b) if the module used TH
--   splices we don't need to force recompilation.
SourceUnmodifiedAndStable :: SourceModified
data HscSource
HsSrcFile :: HscSource
HsBootFile :: HscSource
ExtCoreFile :: HscSource
isHsBoot :: HscSource -> Bool
hscSourceString :: HscSource -> String

-- | Helps us find information about modules in the home package
type HomePackageTable = ModuleNameEnv HomeModInfo

-- | Information about modules in the package being compiled
data HomeModInfo
HomeModInfo :: !ModIface -> !ModDetails -> !(Maybe Linkable) -> HomeModInfo

-- | The basic loaded interface file: every loaded module has one of these,
--   even if it is imported from another package
hm_iface :: HomeModInfo -> !ModIface

-- | Extra information that has been created from the <a>ModIface</a> for
--   the module, typically during typechecking
hm_details :: HomeModInfo -> !ModDetails

-- | The actual artifact we would like to link to access things in this
--   module.
--   
--   <a>hm_linkable</a> might be Nothing:
--   
--   <ol>
--   <li>If this is an .hs-boot module</li>
--   <li>Temporarily during compilation if we pruned away the old linkable
--   because it was out of date.</li>
--   </ol>
--   
--   After a complete compilation (<a>load</a>), all <a>hm_linkable</a>
--   fields in the <a>HomePackageTable</a> will be <tt>Just</tt>.
--   
--   When re-linking a module (<a>HscNoRecomp</a>), we construct the
--   <a>HomeModInfo</a> by building a new <a>ModDetails</a> from the old
--   <a>ModIface</a> (only).
hm_linkable :: HomeModInfo -> !(Maybe Linkable)

-- | Constructs an empty HomePackageTable
emptyHomePackageTable :: HomePackageTable

-- | Find all the instance declarations (of classes and families) that are
--   in modules imported by this one, directly or indirectly, and are in
--   the Home Package Table. This ensures that we don't see instances from
--   modules <tt>--make</tt> compiled before this one, but which are not
--   below this one.
hptInstances :: HscEnv -> (ModuleName -> Bool) -> ([ClsInst], [FamInst])

-- | Get rules from modules <a>below</a> this one (in the dependency sense)
hptRules :: HscEnv -> [(ModuleName, IsBootInterface)] -> [CoreRule]

-- | Get the combined VectInfo of all modules in the home package table. In
--   contrast to instances and rules, we don't care whether the modules are
--   <a>below</a> us in the dependency sense. The VectInfo of those modules
--   not <a>below</a> us does not affect the compilation of the current
--   module.
hptVectInfo :: HscEnv -> VectInfo
hptObjs :: HomePackageTable -> [FilePath]

-- | Information about other packages that we have slurped in by reading
--   their interface files
data ExternalPackageState
EPS :: !(ModuleNameEnv (ModuleName, IsBootInterface)) -> !PackageIfaceTable -> !PackageTypeEnv -> !PackageInstEnv -> !PackageFamInstEnv -> !PackageRuleBase -> !PackageVectInfo -> !PackageAnnEnv -> !(ModuleEnv FamInstEnv) -> !EpsStats -> ExternalPackageState

-- | In OneShot mode (only), home-package modules accumulate in the
--   external package state, and are sucked in lazily. For these home-pkg
--   modules (only) we need to record which are boot modules. We set this
--   field after loading all the explicitly-imported interfaces, but before
--   doing anything else
--   
--   The <a>ModuleName</a> part is not necessary, but it's useful for debug
--   prints, and it's convenient because this field comes direct from
--   <a>imp_dep_mods</a>
eps_is_boot :: ExternalPackageState -> !(ModuleNameEnv (ModuleName, IsBootInterface))

-- | The <a>ModIface</a>s for modules in external packages whose interfaces
--   we have opened. The declarations in these interface files are held in
--   the <tt>eps_decls</tt>, <a>eps_inst_env</a>, <a>eps_fam_inst_env</a>
--   and <tt>eps_rules</tt> fields of this record, not in the
--   <a>mi_decls</a> fields of the interface we have sucked in.
--   
--   What <i>is</i> in the PIT is:
--   
--   <ul>
--   <li>The Module</li>
--   <li>Fingerprint info</li>
--   <li>Its exports</li>
--   <li>Fixities</li>
--   <li>Deprecations and warnings</li>
--   </ul>
eps_PIT :: ExternalPackageState -> !PackageIfaceTable

-- | Result of typechecking all the external package interface files we
--   have sucked in. The domain of the mapping is external-package modules
eps_PTE :: ExternalPackageState -> !PackageTypeEnv

-- | The total <a>InstEnv</a> accumulated from all the external-package
--   modules
eps_inst_env :: ExternalPackageState -> !PackageInstEnv

-- | The total <a>FamInstEnv</a> accumulated from all the external-package
--   modules
eps_fam_inst_env :: ExternalPackageState -> !PackageFamInstEnv

-- | The total <tt>RuleEnv</tt> accumulated from all the external-package
--   modules
eps_rule_base :: ExternalPackageState -> !PackageRuleBase

-- | The total <a>VectInfo</a> accumulated from all the external-package
--   modules
eps_vect_info :: ExternalPackageState -> !PackageVectInfo

-- | The total <a>AnnEnv</a> accumulated from all the external-package
--   modules
eps_ann_env :: ExternalPackageState -> !PackageAnnEnv

-- | The family instances accumulated from external packages, keyed off the
--   module that declared them
eps_mod_fam_inst_env :: ExternalPackageState -> !(ModuleEnv FamInstEnv)

-- | Stastics about what was loaded from external packages
eps_stats :: ExternalPackageState -> !EpsStats

-- | Accumulated statistics about what we are putting into the
--   <a>ExternalPackageState</a>. "In" means stuff that is just <i>read</i>
--   from interface files, "Out" means actually sucked in and type-checked
data EpsStats
EpsStats :: !Int -> !Int -> !Int -> !Int -> !Int -> !Int -> !Int -> EpsStats
n_ifaces_in :: EpsStats -> !Int
n_decls_in :: EpsStats -> !Int
n_decls_out :: EpsStats -> !Int
n_rules_in :: EpsStats -> !Int
n_rules_out :: EpsStats -> !Int
n_insts_in :: EpsStats -> !Int
n_insts_out :: EpsStats -> !Int

-- | Add stats for one newly-read interface
addEpsInStats :: EpsStats -> Int -> Int -> Int -> EpsStats
type PackageTypeEnv = TypeEnv

-- | Helps us find information about modules in the imported packages
type PackageIfaceTable = ModuleEnv ModIface

-- | Constructs an empty PackageIfaceTable
emptyPackageIfaceTable :: PackageIfaceTable

-- | Find the <a>ModIface</a> for a <a>Module</a>, searching in both the
--   loaded home and external package module information
lookupIfaceByModule :: DynFlags -> HomePackageTable -> PackageIfaceTable -> Module -> Maybe ModIface

-- | Constructs an empty ModIface
emptyModIface :: Module -> ModIface
type PackageInstEnv = InstEnv
type PackageRuleBase = RuleBase

-- | Deal with gathering annotations in from all possible places and
--   combining them into a single <a>AnnEnv</a>
prepareAnnotations :: HscEnv -> Maybe ModGuts -> IO AnnEnv

-- | Interactive context, recording information about the state of the
--   context in which statements are executed in a GHC session.
data InteractiveContext
InteractiveContext :: DynFlags -> Name -> [InteractiveImport] -> GlobalRdrEnv -> [TyThing] -> [Id] -> ([ClsInst], [FamInst]) -> FixityEnv -> Name -> Maybe [Type] -> [Resume] -> Maybe FilePath -> InteractiveContext

-- | The <a>DynFlags</a> used to evaluate interative expressions and
--   statements.
ic_dflags :: InteractiveContext -> DynFlags

-- | The monad that GHCi is executing in
ic_monad :: InteractiveContext -> Name

-- | The GHCi context is extended with these imports
--   
--   This field is only stored here so that the client can retrieve it with
--   GHC.getContext. GHC itself doesn't use it, but does reset it to empty
--   sometimes (such as before a GHC.load). The context is set with
--   GHC.setContext.
ic_imports :: InteractiveContext -> [InteractiveImport]

-- | The cached <a>GlobalRdrEnv</a>, built by <a>setContext</a> and updated
--   regularly
ic_rn_gbl_env :: InteractiveContext -> GlobalRdrEnv

-- | TyThings defined by the user, in reverse order of definition. At a
--   breakpoint, this list includes the local variables in scope at that
--   point
ic_tythings :: InteractiveContext -> [TyThing]

-- | Variables defined automatically by the system (e.g. record field
--   selectors). See Notes [ic_sys_vars]
ic_sys_vars :: InteractiveContext -> [Id]

-- | All instances and family instances created during this session. These
--   are grabbed en masse after each update to be sure that proper
--   overlapping is retained. That is, rather than re-check the overlapping
--   each time we update the context, we just take the results from the
--   instance code that already does that.
ic_instances :: InteractiveContext -> ([ClsInst], [FamInst])

-- | Fixities declared in let statements
ic_fix_env :: InteractiveContext -> FixityEnv

-- | The function that is used for printing results of expressions in ghci
--   and -e mode.
ic_int_print :: InteractiveContext -> Name

-- | The current default types, set by a 'default' declaration
ic_default :: InteractiveContext -> Maybe [Type]

-- | The stack of breakpoint contexts
ic_resume :: InteractiveContext -> [Resume]
ic_cwd :: InteractiveContext -> Maybe FilePath

-- | Constructs an empty InteractiveContext.
emptyInteractiveContext :: DynFlags -> InteractiveContext

-- | Get the PrintUnqualified function based on the flags and this
--   InteractiveContext
icPrintUnqual :: DynFlags -> InteractiveContext -> PrintUnqualified

-- | This function returns the list of visible TyThings (useful for e.g.
--   showBindings)
icInScopeTTs :: InteractiveContext -> [TyThing]

-- | Add TyThings to the GlobalRdrEnv, earlier ones in the list shadowing
--   later ones, and shadowing existing entries in the GlobalRdrEnv.
icPlusGblRdrEnv :: [TyThing] -> GlobalRdrEnv -> GlobalRdrEnv

-- | This function is called with new TyThings recently defined to update
--   the InteractiveContext to include them. Ids are easily removed when
--   shadowed, but Classes and TyCons are not. Some work could be done to
--   determine whether they are entirely shadowed, but as you could still
--   have references to them (e.g. instances for classes or values of the
--   type for TyCons), it's not clear whether removing them is even the
--   appropriate behavior.
extendInteractiveContext :: InteractiveContext -> [TyThing] -> InteractiveContext
substInteractiveContext :: InteractiveContext -> TvSubst -> InteractiveContext
setInteractivePrintName :: InteractiveContext -> Name -> InteractiveContext
data InteractiveImport

-- | Bring the exports of a particular module (filtered by an import decl)
--   into scope
IIDecl :: (ImportDecl RdrName) -> InteractiveImport

-- | Bring into scope the entire top-level envt of of this module,
--   including the things imported into it.
IIModule :: ModuleName -> InteractiveImport

-- | Creates some functions that work out the best ways to format names for
--   the user according to a set of heuristics
mkPrintUnqualified :: DynFlags -> GlobalRdrEnv -> PrintUnqualified
pprModulePrefix :: PprStyle -> Module -> Name -> SDoc

-- | A <a>ModIface</a> plus a <a>ModDetails</a> summarises everything we
--   know about a compiled module. The <a>ModIface</a> is the stuff
--   *before* linking, and can be written out to an interface file. The
--   'ModDetails is after linking and can be completely recovered from just
--   the <a>ModIface</a>.
--   
--   When we read an interface file, we also construct a <a>ModIface</a>
--   from it, except that we explicitly make the <a>mi_decls</a> and a few
--   other fields empty; as when reading we consolidate the declarations
--   etc. into a number of indexed maps and environments in the
--   <a>ExternalPackageState</a>.
data ModIface
ModIface :: !Module -> !Fingerprint -> !Fingerprint -> !Fingerprint -> !WhetherHasOrphans -> !WhetherHasFamInst -> !IsBootInterface -> Dependencies -> [Usage] -> ![IfaceExport] -> !Fingerprint -> !Bool -> [(OccName, Fixity)] -> Warnings -> [IfaceAnnotation] -> [(Fingerprint, IfaceDecl)] -> !(Maybe GlobalRdrEnv) -> [IfaceClsInst] -> [IfaceFamInst] -> [IfaceRule] -> !Fingerprint -> !IfaceVectInfo -> (Name -> Maybe WarningTxt) -> (OccName -> Fixity) -> (OccName -> Maybe (OccName, Fingerprint)) -> !AnyHpcUsage -> !IfaceTrustInfo -> !Bool -> ModIface

-- | Name of the module we are for
mi_module :: ModIface -> !Module

-- | Hash of the whole interface
mi_iface_hash :: ModIface -> !Fingerprint

-- | Hash of the ABI only
mi_mod_hash :: ModIface -> !Fingerprint

-- | Hash of the important flags used when compiling this module
mi_flag_hash :: ModIface -> !Fingerprint

-- | Whether this module has orphans
mi_orphan :: ModIface -> !WhetherHasOrphans

-- | Whether this module has family instances
mi_finsts :: ModIface -> !WhetherHasFamInst

-- | Read from an hi-boot file?
mi_boot :: ModIface -> !IsBootInterface

-- | The dependencies of the module. This is consulted for
--   directly-imported modules, but not for anything else (hence lazy)
mi_deps :: ModIface -> Dependencies

-- | Usages; kept sorted so that it's easy to decide whether to write a new
--   iface file (changing usages doesn't affect the hash of this module)
--   NOT STRICT! we read this field lazily from the interface file It is
--   *only* consulted by the recompilation checker
mi_usages :: ModIface -> [Usage]

-- | Exports Kept sorted by (mod,occ), to make version comparisons easier
--   Records the modules that are the declaration points for things
--   exported by this module, and the <a>OccName</a>s of those things
mi_exports :: ModIface -> ![IfaceExport]

-- | Hash of export list
mi_exp_hash :: ModIface -> !Fingerprint

-- | Module required TH splices when it was compiled. This disables
--   recompilation avoidance (see #481).
mi_used_th :: ModIface -> !Bool

-- | Fixities NOT STRICT! we read this field lazily from the interface file
mi_fixities :: ModIface -> [(OccName, Fixity)]

-- | Warnings NOT STRICT! we read this field lazily from the interface file
mi_warns :: ModIface -> Warnings

-- | Annotations NOT STRICT! we read this field lazily from the interface
--   file
mi_anns :: ModIface -> [IfaceAnnotation]

-- | Type, class and variable declarations The hash of an Id changes if its
--   fixity or deprecations change (as well as its type of course) Ditto
--   data constructors, class operations, except that the hash of the
--   parent class/tycon changes
mi_decls :: ModIface -> [(Fingerprint, IfaceDecl)]

-- | Binds all the things defined at the top level in the <i>original
--   source</i> code for this module. which is NOT the same as mi_exports,
--   nor mi_decls (which may contains declarations for things not actually
--   defined by the user). Used for GHCi and for inspecting the contents of
--   modules via the GHC API only.
--   
--   (We need the source file to figure out the top-level environment, if
--   we didn't compile this module from source then this field contains
--   <tt>Nothing</tt>).
--   
--   Strictly speaking this field should live in the <a>HomeModInfo</a>,
--   but that leads to more plumbing.
mi_globals :: ModIface -> !(Maybe GlobalRdrEnv)

-- | Sorted class instance
mi_insts :: ModIface -> [IfaceClsInst]

-- | Sorted family instances
mi_fam_insts :: ModIface -> [IfaceFamInst]

-- | Sorted rules
mi_rules :: ModIface -> [IfaceRule]

-- | Hash for orphan rules, class and family instances, and vectorise
--   pragmas combined
mi_orphan_hash :: ModIface -> !Fingerprint

-- | Vectorisation information
mi_vect_info :: ModIface -> !IfaceVectInfo

-- | Cached lookup for <a>mi_warns</a>
mi_warn_fn :: ModIface -> Name -> Maybe WarningTxt

-- | Cached lookup for <a>mi_fixities</a>
mi_fix_fn :: ModIface -> OccName -> Fixity

-- | Cached lookup for <a>mi_decls</a>. The <tt>Nothing</tt> in
--   <a>mi_hash_fn</a> means that the thing isn't in decls. It's useful to
--   know that when seeing if we are up to date wrt. the old interface. The
--   <a>OccName</a> is the parent of the name, if it has one.
mi_hash_fn :: ModIface -> OccName -> Maybe (OccName, Fingerprint)

-- | True if this program uses Hpc at any point in the program.
mi_hpc :: ModIface -> !AnyHpcUsage

-- | Safe Haskell Trust information for this module.
mi_trust :: ModIface -> !IfaceTrustInfo

-- | Do we require the package this module resides in be trusted to trust
--   this module? This is used for the situation where a module is Safe (so
--   doesn't require the package be trusted itself) but imports some
--   trustworthy modules from its own package (which does require its own
--   package be trusted). See Note [RnNames . Trust Own Package]
mi_trust_pkg :: ModIface -> !Bool

-- | Constructs the cache for the <a>mi_warn_fn</a> field of a
--   <a>ModIface</a>
mkIfaceWarnCache :: Warnings -> Name -> Maybe WarningTxt

-- | Constructs cache for the <a>mi_hash_fn</a> field of a <a>ModIface</a>
mkIfaceHashCache :: [(Fingerprint, IfaceDecl)] -> (OccName -> Maybe (OccName, Fingerprint))

-- | Creates cached lookup for the <a>mi_fix_fn</a> field of
--   <a>ModIface</a>
mkIfaceFixCache :: [(OccName, Fixity)] -> OccName -> Fixity
emptyIfaceWarnCache :: Name -> Maybe WarningTxt

-- | Fixity environment mapping names to their fixities
type FixityEnv = NameEnv FixItem

-- | Fixity information for an <a>Name</a>. We keep the OccName in the
--   range so that we can generate an interface from it
data FixItem
FixItem :: OccName -> Fixity -> FixItem
lookupFixity :: FixityEnv -> Name -> Fixity
emptyFixityEnv :: FixityEnv

-- | A typecheckable-thing, essentially anything that has a name
data TyThing
AnId :: Id -> TyThing
ADataCon :: DataCon -> TyThing
ATyCon :: TyCon -> TyThing
ACoAxiom :: CoAxiom -> TyThing

-- | The Names that a TyThing should bring into scope. Used to build the
--   GlobalRdrEnv for the InteractiveContext.
tyThingAvailInfo :: TyThing -> AvailInfo

-- | Get the <a>TyCon</a> from a <a>TyThing</a> if it is a type constructor
--   thing. Panics otherwise
tyThingTyCon :: TyThing -> TyCon

-- | Get the <a>DataCon</a> from a <a>TyThing</a> if it is a data
--   constructor thing. Panics otherwise
tyThingDataCon :: TyThing -> DataCon

-- | Get the <a>Id</a> from a <a>TyThing</a> if it is a id *or* data
--   constructor thing. Panics otherwise
tyThingId :: TyThing -> Id

-- | Get the <a>CoAxiom</a> from a <a>TyThing</a> if it is a coercion axiom
--   thing. Panics otherwise
tyThingCoAxiom :: TyThing -> CoAxiom

-- | tyThingParent_maybe x returns (Just p) when pprTyThingInContext sould
--   print a declaration for p (albeit with some <a>...</a> in it) when
--   asked to show x It returns the *immediate* parent. So a datacon
--   returns its tycon but the tycon could be the associated type of a
--   class, so it in turn might have a parent.
tyThingParent_maybe :: TyThing -> Maybe TyThing
tyThingsTyVars :: [TyThing] -> TyVarSet

-- | Determine the <a>TyThing</a>s brought into scope by another
--   <a>TyThing</a> <i>other</i> than itself. For example, Id's don't have
--   any implicit TyThings as they just bring themselves into scope, but
--   classes bring their dictionary datatype, type constructor and some
--   selector functions into scope, just for a start!
implicitTyThings :: TyThing -> [TyThing]
implicitTyConThings :: TyCon -> [TyThing]
implicitClassThings :: Class -> [TyThing]

-- | Returns <tt>True</tt> if there should be no interface-file declaration
--   for this thing on its own: either it is built-in, or it is part of
--   some other declaration, or it is generated implicitly by some other
--   declaration.
isImplicitTyThing :: TyThing -> Bool

-- | A map from <a>Name</a>s to <a>TyThing</a>s, constructed by
--   typechecking local declarations or interface files
type TypeEnv = NameEnv TyThing

-- | Find the <a>TyThing</a> for the given <a>Name</a> by using all the
--   resources at our disposal: the compiled modules in the
--   <a>HomePackageTable</a> and the compiled modules in other packages
--   that live in <a>PackageTypeEnv</a>. Note that this does NOT look up
--   the <a>TyThing</a> in the module being compiled: you have to do that
--   yourself, if desired
lookupType :: DynFlags -> HomePackageTable -> PackageTypeEnv -> Name -> Maybe TyThing

-- | As <a>lookupType</a>, but with a marginally easier-to-use interface if
--   you have a <a>HscEnv</a>
lookupTypeHscEnv :: HscEnv -> Name -> IO (Maybe TyThing)
mkTypeEnv :: [TyThing] -> TypeEnv
emptyTypeEnv :: TypeEnv
typeEnvFromEntities :: [Id] -> [TyCon] -> [FamInst] -> TypeEnv
mkTypeEnvWithImplicits :: [TyThing] -> TypeEnv
extendTypeEnv :: TypeEnv -> TyThing -> TypeEnv
extendTypeEnvList :: TypeEnv -> [TyThing] -> TypeEnv
extendTypeEnvWithIds :: TypeEnv -> [Id] -> TypeEnv
lookupTypeEnv :: TypeEnv -> Name -> Maybe TyThing
typeEnvElts :: TypeEnv -> [TyThing]
typeEnvTyCons :: TypeEnv -> [TyCon]
typeEnvIds :: TypeEnv -> [Id]
typeEnvDataCons :: TypeEnv -> [DataCon]
typeEnvCoAxioms :: TypeEnv -> [CoAxiom]
typeEnvClasses :: TypeEnv -> [Class]

-- | Class that abstracts out the common ability of the monads in GHC to
--   lookup a <a>TyThing</a> in the monadic environment by <a>Name</a>.
--   Provides a number of related convenience functions for accessing
--   particular kinds of <a>TyThing</a>
class Monad m => MonadThings m where lookupId = liftM tyThingId . lookupThing lookupDataCon = liftM tyThingDataCon . lookupThing lookupTyCon = liftM tyThingTyCon . lookupThing
lookupThing :: MonadThings m => Name -> m TyThing
lookupId :: MonadThings m => Name -> m Id
lookupDataCon :: MonadThings m => Name -> m DataCon
lookupTyCon :: MonadThings m => Name -> m TyCon

-- | Records whether a module has orphans. An "orphan" is one of:
--   
--   <ul>
--   <li>An instance declaration in a module other than the definition
--   module for one of the type constructors or classes in the instance
--   head</li>
--   <li>A transformation rule in a module other than the one defining the
--   function in the head of the rule</li>
--   <li>A vectorisation pragma</li>
--   </ul>
type WhetherHasOrphans = Bool

-- | Did this module originate from a *-boot file?
type IsBootInterface = Bool

-- | Records modules that we depend on by making a direct import from
data Usage

-- | Module from another package
UsagePackageModule :: Module -> Fingerprint -> IsSafeImport -> Usage

-- | External package module depended on
usg_mod :: Usage -> Module

-- | Cached module fingerprint
--   
--   Cached module fingerprint
usg_mod_hash :: Usage -> Fingerprint

-- | Was this module imported as a safe import
--   
--   Was this module imported as a safe import
usg_safe :: Usage -> IsSafeImport

-- | Module from the current package
UsageHomeModule :: ModuleName -> Fingerprint -> [(OccName, Fingerprint)] -> Maybe Fingerprint -> IsSafeImport -> Usage

-- | Name of the module
usg_mod_name :: Usage -> ModuleName

-- | Cached module fingerprint
--   
--   Cached module fingerprint
usg_mod_hash :: Usage -> Fingerprint

-- | Entities we depend on, sorted by occurrence name and fingerprinted.
--   NB: usages are for parent names only, e.g. type constructors but not
--   the associated data constructors.
usg_entities :: Usage -> [(OccName, Fingerprint)]

-- | Fingerprint for the export list we used to depend on this module, if
--   we depend on the export list
usg_exports :: Usage -> Maybe Fingerprint

-- | Was this module imported as a safe import
--   
--   Was this module imported as a safe import
usg_safe :: Usage -> IsSafeImport
UsageFile :: FilePath -> UTCTime -> Usage
usg_file_path :: Usage -> FilePath

-- | External file dependency. From a CPP #include or TH addDependentFile.
--   Should be absolute.
usg_mtime :: Usage -> UTCTime

-- | Dependency information about modules and packages below this one in
--   the import hierarchy.
--   
--   Invariant: the dependencies of a module <tt>M</tt> never includes
--   <tt>M</tt>.
--   
--   Invariant: none of the lists contain duplicates.
data Dependencies
Deps :: [(ModuleName, IsBootInterface)] -> [(PackageId, Bool)] -> [Module] -> [Module] -> Dependencies

-- | Home-package module dependencies
dep_mods :: Dependencies -> [(ModuleName, IsBootInterface)]

-- | External package dependencies. The bool indicates if the package is
--   required to be trusted when the module is imported as a safe import
--   (Safe Haskell). See Note [RnNames . Tracking Trust Transitively]
dep_pkgs :: Dependencies -> [(PackageId, Bool)]

-- | Orphan modules (whether home or external pkg), *not* including family
--   instance orphans as they are anyway included in <a>dep_finsts</a>
dep_orphs :: Dependencies -> [Module]

-- | Modules that contain family instances (whether the instances are from
--   the home or an external package)
dep_finsts :: Dependencies -> [Module]
noDependencies :: Dependencies

-- | The NameCache makes sure that there is just one Unique assigned for
--   each original name; i.e. (module-name, occ-name) pair and provides
--   something of a lookup mechanism for those names.
data NameCache
NameCache :: UniqSupply -> OrigNameCache -> NameCache

-- | Supply of uniques
nsUniqs :: NameCache -> UniqSupply

-- | Ensures that one original name gets one unique
nsNames :: NameCache -> OrigNameCache

-- | Per-module cache of original <a>OccName</a>s given <a>Name</a>s
type OrigNameCache = ModuleEnv (OccEnv Name)

-- | The original names declared of a certain module that are exported
type IfaceExport = AvailInfo

-- | Warning information for a module
data Warnings

-- | Nothing deprecated
NoWarnings :: Warnings

-- | Whole module deprecated
WarnAll :: WarningTxt -> Warnings

-- | Some specific things deprecated
WarnSome :: [(OccName, WarningTxt)] -> Warnings
data WarningTxt
WarningTxt :: [FastString] -> WarningTxt
DeprecatedTxt :: [FastString] -> WarningTxt
plusWarns :: Warnings -> Warnings -> Warnings

-- | Information we can use to dynamically link modules into the compiler
data Linkable
LM :: UTCTime -> Module -> [Unlinked] -> Linkable

-- | Time at which this linkable was built (i.e. when the bytecodes were
--   produced, or the mod date on the files)
linkableTime :: Linkable -> UTCTime

-- | The linkable module itself
linkableModule :: Linkable -> Module

-- | Those files and chunks of code we have yet to link.
--   
--   INVARIANT: A valid linkable always has at least one <a>Unlinked</a>
--   item. If this list is empty, the Linkable represents a fake linkable,
--   which is generated in HscNothing mode to avoid recompiling modules.
--   
--   ToDo: Do items get removed from this list when they get linked?
linkableUnlinked :: Linkable -> [Unlinked]
isObjectLinkable :: Linkable -> Bool
linkableObjs :: Linkable -> [FilePath]

-- | Objects which have yet to be linked by the compiler
data Unlinked

-- | An object file (.o)
DotO :: FilePath -> Unlinked

-- | Static archive file (.a)
DotA :: FilePath -> Unlinked

-- | Dynamically linked library file (.so, .dll, .dylib)
DotDLL :: FilePath -> Unlinked

-- | A byte-code object, lives only in memory
BCOs :: CompiledByteCode -> ModBreaks -> Unlinked
data CompiledByteCode

-- | Is this an actual file on disk we can link in somehow?
isObject :: Unlinked -> Bool

-- | Retrieve the filename of the linkable if possible. Panic if it is a
--   byte-code object
nameOfObject :: Unlinked -> FilePath

-- | Is this a bytecode linkable with no file on disk?
isInterpretable :: Unlinked -> Bool

-- | Retrieve the compiled byte-code if possible. Panic if it is a
--   file-based linkable
byteCodeOfObject :: Unlinked -> CompiledByteCode

-- | Information about a modules use of Haskell Program Coverage
data HpcInfo
HpcInfo :: Int -> Int -> HpcInfo
hpcInfoTickCount :: HpcInfo -> Int
hpcInfoHash :: HpcInfo -> Int
NoHpcInfo :: AnyHpcUsage -> HpcInfo

-- | Is hpc used anywhere on the module *tree*?
hpcUsed :: HpcInfo -> AnyHpcUsage
emptyHpcInfo :: AnyHpcUsage -> HpcInfo

-- | Find out if HPC is used by this module or any of the modules it
--   depends upon
isHpcUsed :: HpcInfo -> AnyHpcUsage

-- | This is used to signal if one of my imports used HPC instrumentation
--   even if there is no module-local HPC usage
type AnyHpcUsage = Bool

-- | All the information about the breakpoints for a given module
data ModBreaks
ModBreaks :: BreakArray -> !(Array BreakIndex SrcSpan) -> !(Array BreakIndex [OccName]) -> !(Array BreakIndex [String]) -> ModBreaks

-- | The array of flags, one per breakpoint, indicating which breakpoints
--   are enabled.
modBreaks_flags :: ModBreaks -> BreakArray

-- | An array giving the source span of each breakpoint.
modBreaks_locs :: ModBreaks -> !(Array BreakIndex SrcSpan)

-- | An array giving the names of the free variables at each breakpoint.
modBreaks_vars :: ModBreaks -> !(Array BreakIndex [OccName])

-- | An array giving the names of the declarations enclosing each
--   breakpoint.
modBreaks_decls :: ModBreaks -> !(Array BreakIndex [String])

-- | Breakpoint index
type BreakIndex = Int

-- | Construct an empty ModBreaks
emptyModBreaks :: ModBreaks

-- | Vectorisation information for <a>ModGuts</a>, <a>ModDetails</a> and
--   <a>ExternalPackageState</a>; see also documentation at
--   <a>GlobalEnv</a>.
--   
--   NB: The following tables may also include <a>Var</a>s, <a>TyCon</a>s
--   and <a>DataCon</a>s from imported modules, which have been
--   subsequently vectorised in the current module.
data VectInfo
VectInfo :: VarEnv (Var, Var) -> NameEnv (TyCon, TyCon) -> NameEnv (DataCon, DataCon) -> VarSet -> NameSet -> VectInfo

-- | <tt>(f, f_v)</tt> keyed on <tt>f</tt>
vectInfoVar :: VectInfo -> VarEnv (Var, Var)

-- | <tt>(T, T_v)</tt> keyed on <tt>T</tt>
vectInfoTyCon :: VectInfo -> NameEnv (TyCon, TyCon)

-- | <tt>(C, C_v)</tt> keyed on <tt>C</tt>
vectInfoDataCon :: VectInfo -> NameEnv (DataCon, DataCon)

-- | set of purely scalar variables
vectInfoScalarVars :: VectInfo -> VarSet

-- | set of scalar type constructors
vectInfoScalarTyCons :: VectInfo -> NameSet

-- | Vectorisation information for <a>ModIface</a>; i.e, the vectorisation
--   information propagated across module boundaries.
--   
--   NB: The field <a>ifaceVectInfoVar</a> explicitly contains the workers
--   of data constructors as well as class selectors — i.e., their mappings
--   are <i>not</i> implicitly generated from the data types. Moreover,
--   whether the worker of a data constructor is in <a>ifaceVectInfoVar</a>
--   determines whether that data constructor was vectorised (or is part of
--   an abstractly vectorised type constructor).
data IfaceVectInfo
IfaceVectInfo :: [Name] -> [Name] -> [Name] -> [Name] -> [Name] -> IfaceVectInfo

-- | All variables in here have a vectorised variant
ifaceVectInfoVar :: IfaceVectInfo -> [Name]

-- | All <a>TyCon</a>s in here have a vectorised variant; the name of the
--   vectorised variant and those of its data constructors are determined
--   by <a>mkVectTyConOcc</a> and <a>mkVectDataConOcc</a>; the names of the
--   isomorphisms are determined by <a>mkVectIsoOcc</a>
ifaceVectInfoTyCon :: IfaceVectInfo -> [Name]

-- | The vectorised form of all the <a>TyCon</a>s in here coincides with
--   the unconverted form; the name of the isomorphisms is determined by
--   <a>mkVectIsoOcc</a>
ifaceVectInfoTyConReuse :: IfaceVectInfo -> [Name]
ifaceVectInfoScalarVars :: IfaceVectInfo -> [Name]
ifaceVectInfoScalarTyCons :: IfaceVectInfo -> [Name]
noVectInfo :: VectInfo
plusVectInfo :: VectInfo -> VectInfo -> VectInfo
noIfaceVectInfo :: IfaceVectInfo
isNoIfaceVectInfo :: IfaceVectInfo -> Bool

-- | Safe Haskell information for <a>ModIface</a> Simply a wrapper around
--   SafeHaskellMode to sepperate iface and flags
data IfaceTrustInfo
getSafeMode :: IfaceTrustInfo -> SafeHaskellMode
setSafeMode :: SafeHaskellMode -> IfaceTrustInfo
noIfaceTrustInfo :: IfaceTrustInfo
trustInfoToNum :: IfaceTrustInfo -> Word8
numToTrustInfo :: Word8 -> IfaceTrustInfo

-- | Is an import a safe import?
type IsSafeImport = Bool
data HsParsedModule
HsParsedModule :: Located (HsModule RdrName) -> [FilePath] -> HsParsedModule
hpm_module :: HsParsedModule -> Located (HsModule RdrName)

-- | extra source files (e.g. from #includes). The lexer collects these
--   from '# <a>file</a> <a>line</a>' pragmas, which the C preprocessor
--   leaves behind. These files and their timestamps are stored in the .hi
--   file, so that we can force recompilation if any of them change (#3589)
hpm_src_files :: HsParsedModule -> [FilePath]

-- | A source error is an error that is caused by one or more errors in the
--   source code. A <a>SourceError</a> is thrown by many functions in the
--   compilation pipeline. Inside GHC these errors are merely printed via
--   <a>log_action</a>, but API clients may treat them differently, for
--   example, insert them into a list box. If you want the default
--   behaviour, use the idiom:
--   
--   <pre>
--   handleSourceError printExceptionAndWarnings $ do
--     ... api calls that may fail ...
--   </pre>
--   
--   The <a>SourceError</a>s error messages can be accessed via
--   <a>srcErrorMessages</a>. This list may be empty if the compiler failed
--   due to <tt>-Werror</tt> (<a>Opt_WarnIsError</a>).
--   
--   See <tt>printExceptionAndWarnings</tt> for more information on what to
--   take care of when writing a custom error handler.
data SourceError

-- | An error thrown if the GHC API is used in an incorrect fashion.
data GhcApiError
mkSrcErr :: ErrorMessages -> SourceError
srcErrorMessages :: SourceError -> ErrorMessages
mkApiErr :: DynFlags -> SDoc -> GhcApiError
throwOneError :: MonadIO m => ErrMsg -> m ab

-- | Perform the given action and call the exception handler if the action
--   throws a <a>SourceError</a>. See <a>SourceError</a> for more
--   information.
handleSourceError :: ExceptionMonad m => (SourceError -> m a) -> m a -> m a
handleFlagWarnings :: DynFlags -> [Located String] -> IO ()

-- | Given a bag of warnings, turn them into an exception if -Werror is
--   enabled, or print them out otherwise.
printOrThrowWarnings :: DynFlags -> Bag WarnMsg -> IO ()
instance Typeable SourceError
instance Typeable GhcApiError
instance Eq TargetId
instance Eq Warnings
instance Eq Dependencies
instance Eq Usage
instance Outputable Unlinked
instance Outputable Linkable
instance Outputable IfaceTrustInfo
instance Outputable VectInfo
instance Outputable ModSummary
instance Outputable FixItem
instance Outputable InteractiveImport
instance Outputable TargetId
instance Outputable Target
instance Exception GhcApiError
instance Show GhcApiError
instance Exception SourceError
instance Show SourceError

module Parser
parseModule :: P (Located (HsModule RdrName))
parseStmt :: P (Maybe (LStmt RdrName))
parseIdentifier :: P (Located RdrName)
parseType :: P (LHsType RdrName)
parseHeader :: P (Located (HsModule RdrName))


-- | Handy functions for creating much Core syntax
module MkCore

-- | Bind a binding group over an expression, using a <tt>let</tt> or
--   <tt>case</tt> as appropriate (see <a>CoreSyn#let_app_invariant</a>)
mkCoreLet :: CoreBind -> CoreExpr -> CoreExpr

-- | Bind a list of binding groups over an expression. The leftmost binding
--   group becomes the outermost group in the resulting expression
mkCoreLets :: [CoreBind] -> CoreExpr -> CoreExpr

-- | Construct an expression which represents the application of one
--   expression to the other
mkCoreApp :: CoreExpr -> CoreExpr -> CoreExpr

-- | Construct an expression which represents the application of a number
--   of expressions to another. The leftmost expression in the list is
--   applied first
mkCoreApps :: CoreExpr -> [CoreExpr] -> CoreExpr

-- | Construct an expression which represents the application of a number
--   of expressions to that of a data constructor expression. The leftmost
--   expression in the list is applied first
mkCoreConApps :: DataCon -> [CoreExpr] -> CoreExpr

-- | Create a lambda where the given expression has a number of variables
--   bound over it. The leftmost binder is that bound by the outermost
--   lambda in the result
mkCoreLams :: [CoreBndr] -> CoreExpr -> CoreExpr
mkWildCase :: CoreExpr -> Type -> Type -> [CoreAlt] -> CoreExpr
mkIfThenElse :: CoreExpr -> CoreExpr -> CoreExpr -> CoreExpr

-- | Make a <i>wildcard binder</i>. This is typically used when you need a
--   binder that you expect to use only at a *binding* site. Do not use it
--   at occurrence sites because it has a single, fixed unique, and it's
--   very easy to get into difficulties with shadowing. That's why it is
--   used so little. See Note [WildCard binders] in SimplEnv
mkWildValBinder :: Type -> Id
mkWildEvBinder :: PredType -> EvVar
sortQuantVars :: [Var] -> [Var]
castBottomExpr :: CoreExpr -> Type -> CoreExpr

-- | Create a <a>CoreExpr</a> which will evaluate to the a <tt>Word</tt>
--   with the given value
mkWordExpr :: Integer -> CoreExpr

-- | Create a <a>CoreExpr</a> which will evaluate to the given
--   <tt>Word</tt>
mkWordExprWord :: Word -> CoreExpr

-- | Create a <a>CoreExpr</a> which will evaluate to the given <tt>Int</tt>
mkIntExpr :: Integer -> CoreExpr

-- | Create a <a>CoreExpr</a> which will evaluate to the given <tt>Int</tt>
mkIntExprInt :: Int -> CoreExpr

-- | Create a <a>CoreExpr</a> which will evaluate to the given
--   <tt>Integer</tt>
mkIntegerExpr :: MonadThings m => Integer -> m CoreExpr

-- | Create a <a>CoreExpr</a> which will evaluate to the given
--   <tt>Float</tt>
mkFloatExpr :: Float -> CoreExpr

-- | Create a <a>CoreExpr</a> which will evaluate to the given
--   <tt>Double</tt>
mkDoubleExpr :: Double -> CoreExpr

-- | Create a <a>CoreExpr</a> which will evaluate to the given
--   <tt>Char</tt>
mkCharExpr :: Char -> CoreExpr

-- | Create a <a>CoreExpr</a> which will evaluate to the given
--   <tt>String</tt>
mkStringExpr :: MonadThings m => String -> m CoreExpr

-- | Create a <a>CoreExpr</a> which will evaluate to a string morally
--   equivalent to the given <tt>FastString</tt>
mkStringExprFS :: MonadThings m => FastString -> m CoreExpr
data FloatBind
FloatLet :: CoreBind -> FloatBind
FloatCase :: CoreExpr -> Id -> AltCon -> [Var] -> FloatBind
wrapFloat :: FloatBind -> CoreExpr -> CoreExpr
mkEqBox :: Coercion -> CoreExpr

-- | Lifts a "small" constructor into a "big" constructor by recursive
--   decompositon
mkChunkified :: ([a] -> a) -> [a] -> a

-- | Build a small tuple holding the specified variables
mkCoreVarTup :: [Id] -> CoreExpr

-- | Bulid the type of a small tuple that holds the specified variables
mkCoreVarTupTy :: [Id] -> Type

-- | Build a small tuple holding the specified expressions
mkCoreTup :: [CoreExpr] -> CoreExpr

-- | Build a big tuple holding the specified variables
mkBigCoreVarTup :: [Id] -> CoreExpr

-- | Build the type of a big tuple that holds the specified variables
mkBigCoreVarTupTy :: [Id] -> Type

-- | Build a big tuple holding the specified expressions
mkBigCoreTup :: [CoreExpr] -> CoreExpr

-- | Build the type of a big tuple that holds the specified type of thing
mkBigCoreTupTy :: [Type] -> Type

-- | Like <a>mkTupleSelector</a> but for tuples that are guaranteed never
--   to be "big".
--   
--   <pre>
--   mkSmallTupleSelector [x] x v e = [| e |]
--   mkSmallTupleSelector [x,y,z] x v e = [| case e of v { (x,y,z) -&gt; x } |]
--   </pre>
mkSmallTupleSelector :: [Id] -> Id -> Id -> CoreExpr -> CoreExpr

-- | As <a>mkTupleCase</a>, but for a tuple that is small enough to be
--   guaranteed not to need nesting.
mkSmallTupleCase :: [Id] -> CoreExpr -> Id -> CoreExpr -> CoreExpr

-- | Builds a selector which scrutises the given expression and extracts
--   the one name from the list given. If you want the no-shadowing rule to
--   apply, the caller is responsible for making sure that none of these
--   names are in scope.
--   
--   If there is just one <a>Id</a> in the tuple, then the selector is just
--   the identity.
--   
--   If necessary, we pattern match on a "big" tuple.
mkTupleSelector :: [Id] -> Id -> Id -> CoreExpr -> CoreExpr

-- | A generalization of <a>mkTupleSelector</a>, allowing the body of the
--   case to be an arbitrary expression.
--   
--   To avoid shadowing, we use uniques to invent new variables.
--   
--   If necessary we pattern match on a "big" tuple.
mkTupleCase :: UniqSupply -> [Id] -> CoreExpr -> Id -> CoreExpr -> CoreExpr

-- | Makes a list <tt>[]</tt> for lists of the specified type
mkNilExpr :: Type -> CoreExpr

-- | Makes a list <tt>(:)</tt> for lists of the specified type
mkConsExpr :: Type -> CoreExpr -> CoreExpr -> CoreExpr

-- | Make a list containing the given expressions, where the list has the
--   given type
mkListExpr :: Type -> [CoreExpr] -> CoreExpr

-- | Make a fully applied <a>foldr</a> expression
mkFoldrExpr :: MonadThings m => Type -> Type -> CoreExpr -> CoreExpr -> CoreExpr -> m CoreExpr

-- | Make a <tt>build</tt> expression applied to a locally-bound worker
--   function
mkBuildExpr :: (MonadThings m, MonadUnique m) => Type -> ((Id, Type) -> (Id, Type) -> m CoreExpr) -> m CoreExpr
mkRuntimeErrorApp :: Id -> Type -> String -> CoreExpr
mkImpossibleExpr :: Type -> CoreExpr
errorIds :: [Id]
rEC_CON_ERROR_ID :: Id
iRREFUT_PAT_ERROR_ID :: Id
rUNTIME_ERROR_ID :: Id
nON_EXHAUSTIVE_GUARDS_ERROR_ID :: Id
nO_METHOD_BINDING_ERROR_ID :: Id
pAT_ERROR_ID :: Id
eRROR_ID :: Id
rEC_SEL_ERROR_ID :: Id
aBSENT_ERROR_ID :: Id

module PrelRules
primOpRules :: PrimOp -> Name -> [CoreRule]
builtinRules :: [CoreRule]

module MkId
mkDictFunId :: Name -> [TyVar] -> ThetaType -> Class -> [Type] -> Id
mkDictFunTy :: [TyVar] -> ThetaType -> Class -> [Type] -> (Int, Type)
mkDictSelId :: Bool -> Name -> Class -> Id
mkDataConIds :: Name -> Name -> DataCon -> DataConIds
mkPrimOpId :: PrimOp -> Id
mkFCallId :: DynFlags -> Unique -> ForeignCall -> Type -> Id
mkReboxingAlt :: [Unique] -> DataCon -> [Var] -> CoreExpr -> CoreAlt
wrapNewTypeBody :: TyCon -> [Type] -> CoreExpr -> CoreExpr
unwrapNewTypeBody :: TyCon -> [Type] -> CoreExpr -> CoreExpr
wrapFamInstBody :: TyCon -> [Type] -> CoreExpr -> CoreExpr
unwrapFamInstScrut :: TyCon -> [Type] -> CoreExpr -> CoreExpr
wrapTypeFamInstBody :: CoAxiom -> [Type] -> CoreExpr -> CoreExpr
unwrapTypeFamInstScrut :: CoAxiom -> [Type] -> CoreExpr -> CoreExpr
mkUnpackCase :: Id -> CoreExpr -> [Id] -> DataCon -> CoreExpr -> CoreExpr
mkProductBox :: [Id] -> Type -> CoreExpr
wiredInIds :: [Id]
ghcPrimIds :: [Id]
unsafeCoerceName :: Name
unsafeCoerceId :: Id
realWorldPrimId :: Id
voidArgId :: Id
nullAddrId :: Id
seqId :: Id
lazyId :: Id
lazyIdKey :: Unique
coercionTokenId :: Id

module FloatIn
floatInwards :: CoreProgram -> CoreProgram

module WwLib
mkWwBodies :: DynFlags -> Type -> [Demand] -> DmdResult -> [Bool] -> UniqSM ([Demand], Id -> CoreExpr, CoreExpr -> CoreExpr)
mkWWstr :: DynFlags -> [Var] -> UniqSM ([Var], CoreExpr -> CoreExpr, CoreExpr -> CoreExpr)
mkWorkerArgs :: [Var] -> Type -> ([Var], [Var])

module WorkWrap
wwTopBinds :: DynFlags -> UniqSupply -> CoreProgram -> CoreProgram
mkWrapper :: DynFlags -> Type -> StrictSig -> UniqSM (Id -> CoreExpr)

module GhcMonad

-- | A monad that has all the features needed by GHC API calls.
--   
--   In short, a GHC monad
--   
--   <ul>
--   <li>allows embedding of IO actions,</li>
--   <li>can log warnings,</li>
--   <li>allows handling of (extensible) exceptions, and</li>
--   <li>maintains a current session.</li>
--   </ul>
--   
--   If you do not use <a>Ghc</a> or <a>GhcT</a>, make sure to call
--   <a>initGhcMonad</a> before any call to the GHC API functions can
--   occur.
class (Functor m, MonadIO m, ExceptionMonad m, HasDynFlags m) => GhcMonad m
getSession :: GhcMonad m => m HscEnv
setSession :: GhcMonad m => HscEnv -> m ()

-- | A minimal implementation of a <a>GhcMonad</a>. If you need a custom
--   monad, e.g., to maintain additional state consider wrapping this monad
--   or using <a>GhcT</a>.
newtype Ghc a
Ghc :: (Session -> IO a) -> Ghc a
unGhc :: Ghc a -> Session -> IO a

-- | A monad transformer to add GHC specific features to another monad.
--   
--   Note that the wrapped monad must support IO and handling of
--   exceptions.
newtype GhcT m a
GhcT :: (Session -> m a) -> GhcT m a
unGhcT :: GhcT m a -> Session -> m a
liftGhcT :: Monad m => m a -> GhcT m a

-- | Reflect a computation in the <a>Ghc</a> monad into the <a>IO</a>
--   monad.
--   
--   You can use this to call functions returning an action in the
--   <a>Ghc</a> monad inside an <a>IO</a> action. This is needed for some
--   (too restrictive) callback arguments of some library functions:
--   
--   <pre>
--   libFunc :: String -&gt; (Int -&gt; IO a) -&gt; IO a
--   ghcFunc :: Int -&gt; Ghc a
--   
--   ghcFuncUsingLibFunc :: String -&gt; Ghc a -&gt; Ghc a
--   ghcFuncUsingLibFunc str =
--     reifyGhc $ \s -&gt;
--       libFunc $ \i -&gt; do
--         reflectGhc (ghcFunc i) s
--   </pre>
reflectGhc :: Ghc a -> Session -> IO a
reifyGhc :: (Session -> IO a) -> Ghc a

-- | Grabs the DynFlags from the Session
getSessionDynFlags :: GhcMonad m => m DynFlags
liftIO :: MonadIO m => IO a -> m a

-- | The Session is a handle to the complete state of a compilation
--   session. A compilation session consists of a set of modules
--   constituting the current program or library, the context for
--   interactive evaluation, and various caches.
data Session
Session :: !(IORef HscEnv) -> Session

-- | Call the argument with the current session.
withSession :: GhcMonad m => (HscEnv -> m a) -> m a

-- | Set the current session to the result of applying the current session
--   to the argument.
modifySession :: GhcMonad m => (HscEnv -> HscEnv) -> m ()

-- | Call an action with a temporarily modified Session.
withTempSession :: GhcMonad m => (HscEnv -> HscEnv) -> m a -> m a

-- | A monad that allows logging of warnings.
logWarnings :: GhcMonad m => WarningMessages -> m ()

-- | Print the error message and all warnings. Useful inside exception
--   handlers. Clears warnings after printing.
printException :: GhcMonad m => SourceError -> m ()

-- | <i>Deprecated: use printException instead </i>
printExceptionAndWarnings :: GhcMonad m => SourceError -> m ()

-- | A function called to log warnings and errors.
type WarnErrLogger = GhcMonad m => Maybe SourceError -> m ()
defaultWarnErrLogger :: WarnErrLogger
instance (Functor m, ExceptionMonad m, MonadIO m) => GhcMonad (GhcT m)
instance (Functor m, ExceptionMonad m, MonadIO m) => HasDynFlags (GhcT m)
instance ExceptionMonad m => ExceptionMonad (GhcT m)
instance MonadIO m => MonadIO (GhcT m)
instance Monad m => Monad (GhcT m)
instance Functor m => Functor (GhcT m)
instance GhcMonad Ghc
instance HasDynFlags Ghc
instance ExceptionMonad Ghc
instance MonadFix Ghc
instance MonadIO Ghc
instance Monad Ghc
instance Functor Ghc

module Finder
flushFinderCaches :: HscEnv -> IO ()

-- | The result of searching for an imported module.
data FindResult

-- | The module was found
Found :: ModLocation -> Module -> FindResult

-- | The requested package was not found
NoPackage :: PackageId -> FindResult

-- | _Error_: both in multiple packages
FoundMultiple :: [PackageId] -> FindResult

-- | Not found
NotFound :: [FilePath] -> Maybe PackageId -> [PackageId] -> [PackageId] -> [Module] -> FindResult
fr_paths :: FindResult -> [FilePath]
fr_pkg :: FindResult -> Maybe PackageId
fr_mods_hidden :: FindResult -> [PackageId]
fr_pkgs_hidden :: FindResult -> [PackageId]
fr_suggestions :: FindResult -> [Module]

-- | Locate a module that was imported by the user. We have the module's
--   name, and possibly a package name. Without a package name, this
--   function will use the search path and the known exposed packages to
--   find the module, if a package is specified then only that package is
--   searched for the module.
findImportedModule :: HscEnv -> ModuleName -> Maybe FastString -> IO FindResult

-- | Locate a specific <a>Module</a>. The purpose of this function is to
--   create a <a>ModLocation</a> for a given <a>Module</a>, that is to find
--   out where the files associated with this module live. It is used when
--   reading the interface for a module mentioned by another interface, for
--   example (a <a>system import</a>).
findExactModule :: HscEnv -> Module -> IO FindResult

-- | Search for a module in the home package only.
findHomeModule :: HscEnv -> ModuleName -> IO FindResult
findExposedPackageModule :: HscEnv -> ModuleName -> Maybe FastString -> IO FindResult
mkHomeModLocation :: DynFlags -> ModuleName -> FilePath -> IO ModLocation
mkHomeModLocation2 :: DynFlags -> ModuleName -> FilePath -> String -> IO ModLocation
mkHiOnlyModLocation :: DynFlags -> Suffix -> FilePath -> String -> IO ModLocation
addHomeModuleToFinder :: HscEnv -> ModuleName -> ModLocation -> IO Module
uncacheModule :: HscEnv -> ModuleName -> IO ()
mkStubPaths :: DynFlags -> ModuleName -> ModLocation -> FilePath
findObjectLinkableMaybe :: Module -> ModLocation -> IO (Maybe Linkable)
findObjectLinkable :: Module -> FilePath -> UTCTime -> IO Linkable
cannotFindModule :: DynFlags -> ModuleName -> FindResult -> SDoc
cannotFindInterface :: DynFlags -> ModuleName -> FindResult -> SDoc

module TcRnTypes
type TcRnIf a b c = IOEnv (Env a b) c
type TcRn a = TcRnIf TcGblEnv TcLclEnv a
type TcM a = TcRn a
type RnM a = TcRn a
type IfM lcl a = TcRnIf IfGblEnv lcl a
type IfL a = IfM IfLclEnv a
type IfG a = IfM () a
type TcRef a = IORef a
data Env gbl lcl
Env :: HscEnv -> {-# UNPACK #-} !(IORef UniqSupply) -> gbl -> lcl -> Env gbl lcl
env_top :: Env gbl lcl -> HscEnv
env_us :: Env gbl lcl -> {-# UNPACK #-} !(IORef UniqSupply)
env_gbl :: Env gbl lcl -> gbl
env_lcl :: Env gbl lcl -> lcl
data TcGblEnv
TcGblEnv :: Module -> HscSource -> GlobalRdrEnv -> Maybe [Type] -> FixityEnv -> RecFieldEnv -> TypeEnv -> TcRef TypeEnv -> InstEnv -> FamInstEnv -> [AvailInfo] -> ImportAvails -> DefUses -> TcRef NameSet -> TcRef Bool -> TcRef Bool -> TcRef OccSet -> Maybe [Located (IE Name)] -> [LImportDecl Name] -> TcRef (Set RdrName) -> Maybe (HsGroup Name) -> TcRef [FilePath] -> Bag EvBind -> LHsBinds Id -> NameSet -> [LTcSpecPrag] -> Warnings -> [Annotation] -> [TyCon] -> [ClsInst] -> [FamInst] -> [LRuleDecl Id] -> [LForeignDecl Id] -> [LVectDecl Id] -> Maybe LHsDocString -> AnyHpcUsage -> Maybe Name -> TcRef Bool -> TcGblEnv

-- | Module being compiled
tcg_mod :: TcGblEnv -> Module

-- | What kind of module (regular Haskell, hs-boot, ext-core)
tcg_src :: TcGblEnv -> HscSource

-- | Top level envt; used during renaming
tcg_rdr_env :: TcGblEnv -> GlobalRdrEnv

-- | Types used for defaulting. <tt>Nothing</tt> =&gt; no <tt>default</tt>
--   decl
tcg_default :: TcGblEnv -> Maybe [Type]

-- | Just for things in this module
tcg_fix_env :: TcGblEnv -> FixityEnv

-- | Just for things in this module
tcg_field_env :: TcGblEnv -> RecFieldEnv

-- | Global type env for the module we are compiling now. All TyCons and
--   Classes (for this module) end up in here right away, along with their
--   derived constructors, selectors.
--   
--   (Ids defined in this module start in the local envt, though they move
--   to the global envt during zonking)
tcg_type_env :: TcGblEnv -> TypeEnv
tcg_type_env_var :: TcGblEnv -> TcRef TypeEnv

-- | Instance envt for all <i>home-package</i> modules; Includes the dfuns
--   in tcg_insts
tcg_inst_env :: TcGblEnv -> InstEnv

-- | Ditto for family instances
tcg_fam_inst_env :: TcGblEnv -> FamInstEnv

-- | What is exported
tcg_exports :: TcGblEnv -> [AvailInfo]

-- | Information about what was imported from where, including things bound
--   in this module. Also store Safe Haskell info here about transative
--   trusted packaage requirements.
tcg_imports :: TcGblEnv -> ImportAvails

-- | What is defined in this module and what is used. The latter is used to
--   generate
--   
--   (a) version tracking; no need to recompile if these things have not
--   changed version stamp
--   
--   (b) unused-import info
tcg_dus :: TcGblEnv -> DefUses

-- | Locally-defined top-level names to keep alive.
--   
--   <a>Keep alive</a> means give them an Exported flag, so that the
--   simplifier does not discard them as dead code, and so that they are
--   exposed in the interface file (but not to export to the user).
--   
--   Some things, like dict-fun Ids and default-method Ids are <a>born</a>
--   with the Exported flag on, for exactly the above reason, but some we
--   only discover as we go. Specifically:
--   
--   <ul>
--   <li>The to/from functions for generic data types</li>
--   <li>Top-level variables appearing free in the RHS of an orphan
--   rule</li>
--   <li>Top-level variables appearing free in a TH bracket</li>
--   </ul>
tcg_keep :: TcGblEnv -> TcRef NameSet

-- | <tt>True</tt> <a>=</a> Template Haskell syntax used.
--   
--   We need this so that we can generate a dependency on the Template
--   Haskell package, becuase the desugarer is going to emit loads of
--   references to TH symbols. The reference is implicit rather than
--   explicit, so we have to zap a mutable variable.
tcg_th_used :: TcGblEnv -> TcRef Bool

-- | <tt>True</tt> <a>=</a> A Template Haskell splice was used.
--   
--   Splices disable recompilation avoidance (see #481)
tcg_th_splice_used :: TcGblEnv -> TcRef Bool

-- | Allows us to choose unique DFun names.
tcg_dfun_n :: TcGblEnv -> TcRef OccSet
tcg_rn_exports :: TcGblEnv -> Maybe [Located (IE Name)]
tcg_rn_imports :: TcGblEnv -> [LImportDecl Name]
tcg_used_rdrnames :: TcGblEnv -> TcRef (Set RdrName)

-- | Renamed decls, maybe. <tt>Nothing</tt> <a>=</a> Don't retain renamed
--   decls.
tcg_rn_decls :: TcGblEnv -> Maybe (HsGroup Name)

-- | dependencies from addDependentFile
tcg_dependent_files :: TcGblEnv -> TcRef [FilePath]
tcg_ev_binds :: TcGblEnv -> Bag EvBind
tcg_binds :: TcGblEnv -> LHsBinds Id
tcg_sigs :: TcGblEnv -> NameSet
tcg_imp_specs :: TcGblEnv -> [LTcSpecPrag]
tcg_warns :: TcGblEnv -> Warnings
tcg_anns :: TcGblEnv -> [Annotation]
tcg_tcs :: TcGblEnv -> [TyCon]
tcg_insts :: TcGblEnv -> [ClsInst]
tcg_fam_insts :: TcGblEnv -> [FamInst]
tcg_rules :: TcGblEnv -> [LRuleDecl Id]
tcg_fords :: TcGblEnv -> [LForeignDecl Id]
tcg_vects :: TcGblEnv -> [LVectDecl Id]

-- | Maybe Haddock header docs
tcg_doc_hdr :: TcGblEnv -> Maybe LHsDocString

-- | <tt>True</tt> if any part of the prog uses hpc instrumentation.
tcg_hpc :: TcGblEnv -> AnyHpcUsage

-- | The Name of the main function, if this module is the main module.
tcg_main :: TcGblEnv -> Maybe Name
tcg_safeInfer :: TcGblEnv -> TcRef Bool
data TcLclEnv
TcLclEnv :: SrcSpan -> [ErrCtxt] -> TcRef Messages -> ThStage -> ArrowCtxt -> LocalRdrEnv -> TcTypeEnv -> TidyEnv -> TcRef TcTyVarSet -> TcRef WantedConstraints -> TcRef Unique -> Unique -> TcLclEnv
tcl_loc :: TcLclEnv -> SrcSpan
tcl_ctxt :: TcLclEnv -> [ErrCtxt]
tcl_errs :: TcLclEnv -> TcRef Messages
tcl_th_ctxt :: TcLclEnv -> ThStage
tcl_arrow_ctxt :: TcLclEnv -> ArrowCtxt
tcl_rdr :: TcLclEnv -> LocalRdrEnv
tcl_env :: TcLclEnv -> TcTypeEnv
tcl_tidy :: TcLclEnv -> TidyEnv
tcl_tyvars :: TcLclEnv -> TcRef TcTyVarSet
tcl_lie :: TcLclEnv -> TcRef WantedConstraints
tcl_meta :: TcLclEnv -> TcRef Unique
tcl_untch :: TcLclEnv -> Unique
data IfGblEnv
IfGblEnv :: Maybe (Module, IfG TypeEnv) -> IfGblEnv
if_rec_types :: IfGblEnv -> Maybe (Module, IfG TypeEnv)
data IfLclEnv
IfLclEnv :: Module -> SDoc -> UniqFM TyVar -> UniqFM Id -> IfLclEnv
if_mod :: IfLclEnv -> Module
if_loc :: IfLclEnv -> SDoc
if_tv_env :: IfLclEnv -> UniqFM TyVar
if_id_env :: IfLclEnv -> UniqFM Id
type ErrCtxt = (Bool, TidyEnv -> TcM (TidyEnv, MsgDoc))
data RecFieldEnv
RecFields :: (NameEnv [Name]) -> NameSet -> RecFieldEnv

-- | <a>ImportAvails</a> summarises what was imported from where,
--   irrespective of whether the imported things are actually used or not.
--   It is used:
--   
--   <ul>
--   <li>when processing the export list,</li>
--   <li>when constructing usage info for the interface file,</li>
--   <li>to identify the list of directly imported modules for
--   initialisation purposes and for optimised overlap checking of family
--   instances,</li>
--   <li>when figuring out what things are really unused</li>
--   </ul>
data ImportAvails
ImportAvails :: ImportedMods -> ModuleNameEnv (ModuleName, IsBootInterface) -> [PackageId] -> [PackageId] -> Bool -> [Module] -> [Module] -> ImportAvails

-- | Domain is all directly-imported modules The <a>ModuleName</a> is what
--   the module was imported as, e.g. in <tt> import Foo as Bar </tt> it is
--   <tt>Bar</tt>.
--   
--   The <a>Bool</a> means:
--   
--   <ul>
--   <li><tt>True</tt> =&gt; import was <tt>import Foo ()</tt></li>
--   <li><tt>False</tt> =&gt; import was some other form</li>
--   </ul>
--   
--   Used
--   
--   (a) to help construct the usage information in the interface file; if
--   we import somethign we need to recompile if the export version changes
--   
--   (b) to specify what child modules to initialise
--   
--   We need a full ModuleEnv rather than a ModuleNameEnv here, because we
--   might be importing modules of the same name from different packages.
--   (currently not the case, but might be in the future).
imp_mods :: ImportAvails -> ImportedMods

-- | Home-package modules needed by the module being compiled
--   
--   It doesn't matter whether any of these dependencies are actually
--   <i>used</i> when compiling the module; they are listed if they are
--   below it at all. For example, suppose M imports A which imports X.
--   Then compiling M might not need to consult X.hi, but X is still listed
--   in M's dependencies.
imp_dep_mods :: ImportAvails -> ModuleNameEnv (ModuleName, IsBootInterface)

-- | Packages needed by the module being compiled, whether directly, or via
--   other modules in this package, or via modules imported from other
--   packages.
imp_dep_pkgs :: ImportAvails -> [PackageId]

-- | This is strictly a subset of imp_dep_pkgs and records the packages the
--   current module needs to trust for Safe Haskell compilation to succeed.
--   A package is required to be trusted if we are dependent on a
--   trustworthy module in that package. While perhaps making imp_dep_pkgs
--   a tuple of (PackageId, Bool) where True for the bool indicates the
--   package is required to be trusted is the more logical design, doing so
--   complicates a lot of code not concerned with Safe Haskell. See Note
--   [RnNames . Tracking Trust Transitively]
imp_trust_pkgs :: ImportAvails -> [PackageId]

-- | Do we require that our own package is trusted? This is to handle
--   efficiently the case where a Safe module imports a Trustworthy module
--   that resides in the same package as it. See Note [RnNames . Trust Own
--   Package]
imp_trust_own_pkg :: ImportAvails -> Bool

-- | Orphan modules below us in the import tree (and maybe including us for
--   imported modules)
imp_orphs :: ImportAvails -> [Module]

-- | Family instance modules below us in the import tree (and maybe
--   including us for imported modules)
imp_finsts :: ImportAvails -> [Module]
emptyImportAvails :: ImportAvails

-- | Union two ImportAvails
--   
--   This function is a key part of Import handling, basically for each
--   import we create a seperate ImportAvails structure and then union them
--   all together with this function.
plusImportAvails :: ImportAvails -> ImportAvails -> ImportAvails
data WhereFrom
ImportByUser :: IsBootInterface -> WhereFrom
ImportBySystem :: WhereFrom
mkModDeps :: [(ModuleName, IsBootInterface)] -> ModuleNameEnv (ModuleName, IsBootInterface)
type TcTypeEnv = NameEnv TcTyThing
data TcTyThing
AGlobal :: TyThing -> TcTyThing
ATcId :: TcId -> TopLevelFlag -> ThLevel -> TcTyThing
tct_id :: TcTyThing -> TcId
tct_closed :: TcTyThing -> TopLevelFlag
tct_level :: TcTyThing -> ThLevel
ATyVar :: Name -> TcTyVar -> TcTyThing
AThing :: TcKind -> TcTyThing
APromotionErr :: PromotionErr -> TcTyThing
data PromotionErr
TyConPE :: PromotionErr
ClassPE :: PromotionErr
FamDataConPE :: PromotionErr
RecDataConPE :: PromotionErr
NoDataKinds :: PromotionErr
pprTcTyThingCategory :: TcTyThing -> SDoc
pprPECategory :: PromotionErr -> SDoc
data ThStage
Splice :: ThStage
Comp :: ThStage
Brack :: ThStage -> (TcRef [PendingSplice]) -> (TcRef WantedConstraints) -> ThStage
topStage :: ThStage
topAnnStage :: ThStage
topSpliceStage :: ThStage
type ThLevel = Int
impLevel :: ThLevel
outerLevel :: ThLevel
thLevel :: ThStage -> ThLevel
data ArrowCtxt
NoArrowCtxt :: ArrowCtxt
newArrowScope :: TcM a -> TcM a
escapeArrowScope :: TcM a -> TcM a
data Untouchables
NoUntouchables :: Untouchables
TouchableRange :: Unique -> Unique -> Untouchables
inTouchableRange :: Untouchables -> TcTyVar -> Bool
isNoUntouchables :: Untouchables -> Bool
type Xi = Type
data Ct
CDictCan :: CtEvidence -> Class -> [Xi] -> SubGoalDepth -> Ct
cc_ev :: Ct -> CtEvidence
cc_class :: Ct -> Class
cc_tyargs :: Ct -> [Xi]
cc_depth :: Ct -> SubGoalDepth
CIrredEvCan :: CtEvidence -> Xi -> SubGoalDepth -> Ct
cc_ev :: Ct -> CtEvidence
cc_ty :: Ct -> Xi
cc_depth :: Ct -> SubGoalDepth
CTyEqCan :: CtEvidence -> TcTyVar -> Xi -> SubGoalDepth -> Ct
cc_ev :: Ct -> CtEvidence
cc_tyvar :: Ct -> TcTyVar
cc_rhs :: Ct -> Xi
cc_depth :: Ct -> SubGoalDepth
CFunEqCan :: CtEvidence -> TyCon -> [Xi] -> Xi -> SubGoalDepth -> Ct
cc_ev :: Ct -> CtEvidence
cc_fun :: Ct -> TyCon
cc_tyargs :: Ct -> [Xi]
cc_rhs :: Ct -> Xi
cc_depth :: Ct -> SubGoalDepth
CNonCanonical :: CtEvidence -> SubGoalDepth -> Ct
cc_ev :: Ct -> CtEvidence
cc_depth :: Ct -> SubGoalDepth
type Cts = Bag Ct
emptyCts :: Cts
andCts :: Cts -> Cts -> Cts
andManyCts :: [Cts] -> Cts
keepWanted :: Cts -> Cts
singleCt :: Ct -> Cts
extendCts :: Cts -> Ct -> Cts
isEmptyCts :: Cts -> Bool
isCTyEqCan :: Ct -> Bool
isCFunEqCan :: Ct -> Bool
isCDictCan_Maybe :: Ct -> Maybe Class
isCFunEqCan_Maybe :: Ct -> Maybe TyCon
isCIrredEvCan :: Ct -> Bool
isCNonCanonical :: Ct -> Bool
isWantedCt :: Ct -> Bool
isDerivedCt :: Ct -> Bool
isGivenCt :: Ct -> Bool
ctWantedLoc :: Ct -> WantedLoc
ctEvidence :: Ct -> CtEvidence
type SubGoalDepth = Int
mkNonCanonical :: CtEvidence -> Ct
ctPred :: Ct -> PredType
ctEvPred :: CtEvidence -> TcPredType
ctEvTerm :: CtEvidence -> EvTerm
ctEvId :: CtEvidence -> TcId
data WantedConstraints
WC :: Cts -> Bag Implication -> Cts -> WantedConstraints
wc_flat :: WantedConstraints -> Cts
wc_impl :: WantedConstraints -> Bag Implication
wc_insol :: WantedConstraints -> Cts
insolubleWC :: WantedConstraints -> Bool
emptyWC :: WantedConstraints
isEmptyWC :: WantedConstraints -> Bool
andWC :: WantedConstraints -> WantedConstraints -> WantedConstraints
addFlats :: WantedConstraints -> Bag Ct -> WantedConstraints
addImplics :: WantedConstraints -> Bag Implication -> WantedConstraints
mkFlatWC :: [Ct] -> WantedConstraints
data Implication
Implic :: Untouchables -> TcTypeEnv -> [TcTyVar] -> [EvVar] -> GivenLoc -> WantedConstraints -> Bool -> EvBindsVar -> Implication
ic_untch :: Implication -> Untouchables
ic_env :: Implication -> TcTypeEnv
ic_skols :: Implication -> [TcTyVar]
ic_given :: Implication -> [EvVar]
ic_loc :: Implication -> GivenLoc
ic_wanted :: Implication -> WantedConstraints
ic_insol :: Implication -> Bool
ic_binds :: Implication -> EvBindsVar
data CtLoc orig
CtLoc :: orig -> SrcSpan -> [ErrCtxt] -> CtLoc orig
ctLocSpan :: CtLoc o -> SrcSpan
ctLocOrigin :: CtLoc o -> o
setCtLocOrigin :: CtLoc o -> o' -> CtLoc o'
data CtOrigin
OccurrenceOf :: Name -> CtOrigin
AppOrigin :: CtOrigin
SpecPragOrigin :: Name -> CtOrigin
TypeEqOrigin :: EqOrigin -> CtOrigin
IPOccOrigin :: HsIPName -> CtOrigin
LiteralOrigin :: (HsOverLit Name) -> CtOrigin
NegateOrigin :: CtOrigin
ArithSeqOrigin :: (ArithSeqInfo Name) -> CtOrigin
PArrSeqOrigin :: (ArithSeqInfo Name) -> CtOrigin
SectionOrigin :: CtOrigin
TupleOrigin :: CtOrigin
AmbigOrigin :: Name -> CtOrigin
ExprSigOrigin :: CtOrigin
PatSigOrigin :: CtOrigin
PatOrigin :: CtOrigin
RecordUpdOrigin :: CtOrigin
ViewPatOrigin :: CtOrigin
ScOrigin :: CtOrigin
DerivOrigin :: CtOrigin
StandAloneDerivOrigin :: CtOrigin
DefaultOrigin :: CtOrigin
DoOrigin :: CtOrigin
MCompOrigin :: CtOrigin
IfOrigin :: CtOrigin
ProcOrigin :: CtOrigin
AnnOrigin :: CtOrigin
FunDepOrigin :: CtOrigin
data EqOrigin
UnifyOrigin :: TcType -> TcType -> EqOrigin
uo_actual :: EqOrigin -> TcType
uo_expected :: EqOrigin -> TcType
type WantedLoc = CtLoc CtOrigin
type GivenLoc = CtLoc SkolemInfo
pushErrCtxt :: orig -> ErrCtxt -> CtLoc orig -> CtLoc orig
pushErrCtxtSameOrigin :: ErrCtxt -> CtLoc orig -> CtLoc orig
data SkolemInfo
SigSkol :: UserTypeCtxt -> Type -> SkolemInfo
ClsSkol :: Class -> SkolemInfo
InstSkol :: SkolemInfo
DataSkol :: SkolemInfo
FamInstSkol :: SkolemInfo
PatSkol :: DataCon -> (HsMatchContext Name) -> SkolemInfo
ArrowSkol :: SkolemInfo
IPSkol :: [HsIPName] -> SkolemInfo
RuleSkol :: RuleName -> SkolemInfo
InferSkol :: [(Name, TcType)] -> SkolemInfo
BracketSkol :: SkolemInfo
UnifyForAllSkol :: [TcTyVar] -> TcType -> SkolemInfo
UnkSkol :: SkolemInfo
data CtEvidence
Given :: GivenLoc -> TcPredType -> EvTerm -> CtEvidence
ctev_gloc :: CtEvidence -> GivenLoc
ctev_pred :: CtEvidence -> TcPredType
ctev_evtm :: CtEvidence -> EvTerm
Wanted :: WantedLoc -> TcPredType -> EvVar -> CtEvidence
ctev_wloc :: CtEvidence -> WantedLoc
ctev_pred :: CtEvidence -> TcPredType
ctev_evar :: CtEvidence -> EvVar
Derived :: WantedLoc -> TcPredType -> CtEvidence
ctev_wloc :: CtEvidence -> WantedLoc
ctev_pred :: CtEvidence -> TcPredType
pprFlavorArising :: CtEvidence -> SDoc
mkGivenLoc :: WantedLoc -> SkolemInfo -> GivenLoc
isWanted :: CtEvidence -> Bool
isGiven :: CtEvidence -> Bool
isDerived :: CtEvidence -> Bool
getWantedLoc :: CtEvidence -> WantedLoc
getGivenLoc :: CtEvidence -> GivenLoc
canSolve :: CtEvidence -> CtEvidence -> Bool
canRewrite :: CtEvidence -> CtEvidence -> Bool
pprEvVarTheta :: [EvVar] -> SDoc
pprWantedsWithLocs :: WantedConstraints -> SDoc
pprEvVars :: [EvVar] -> SDoc
pprEvVarWithType :: EvVar -> SDoc
pprArising :: CtOrigin -> SDoc
pprArisingAt :: Outputable o => CtLoc o -> SDoc
type TcId = Id
type TcIdSet = IdSet
data TcTyVarBind
TcTyVarBind :: TcTyVar -> TcType -> TcTyVarBind
type TcTyVarBinds = Bag TcTyVarBind
instance Outputable EqOrigin
instance Outputable CtOrigin
instance Outputable SkolemInfo
instance Outputable CtEvidence
instance Outputable Implication
instance Outputable Untouchables
instance Outputable WantedConstraints
instance Outputable Ct
instance Outputable WhereFrom
instance Outputable PromotionErr
instance Outputable TcTyThing
instance Outputable ThStage
instance ContainsDynFlags (Env gbl lcl)
instance Outputable TcTyVarBind

module TcRnMonad

-- | Setup the initial typechecking environment
initTc :: HscEnv -> HscSource -> Bool -> Module -> TcM r -> IO (Messages, Maybe r)
initTcPrintErrors :: HscEnv -> Module -> TcM r -> IO (Messages, Maybe r)
initTcForLookup :: HscEnv -> TcM a -> IO a
initTcRnIf :: Char -> HscEnv -> gbl -> lcl -> TcRnIf gbl lcl a -> IO a
discardResult :: TcM a -> TcM ()
getTopEnv :: TcRnIf gbl lcl HscEnv
getGblEnv :: TcRnIf gbl lcl gbl
updGblEnv :: (gbl -> gbl) -> TcRnIf gbl lcl a -> TcRnIf gbl lcl a
setGblEnv :: gbl -> TcRnIf gbl lcl a -> TcRnIf gbl lcl a
getLclEnv :: TcRnIf gbl lcl lcl
updLclEnv :: (lcl -> lcl) -> TcRnIf gbl lcl a -> TcRnIf gbl lcl a
setLclEnv :: lcl' -> TcRnIf gbl lcl' a -> TcRnIf gbl lcl a
getEnvs :: TcRnIf gbl lcl (gbl, lcl)
setEnvs :: (gbl', lcl') -> TcRnIf gbl' lcl' a -> TcRnIf gbl lcl a
xoptM :: ExtensionFlag -> TcRnIf gbl lcl Bool
doptM :: DynFlag -> TcRnIf gbl lcl Bool
woptM :: WarningFlag -> TcRnIf gbl lcl Bool
setXOptM :: ExtensionFlag -> TcRnIf gbl lcl a -> TcRnIf gbl lcl a
unsetDOptM :: DynFlag -> TcRnIf gbl lcl a -> TcRnIf gbl lcl a
unsetWOptM :: WarningFlag -> TcRnIf gbl lcl a -> TcRnIf gbl lcl a

-- | Do it flag is true
ifDOptM :: DynFlag -> TcRnIf gbl lcl () -> TcRnIf gbl lcl ()
ifWOptM :: WarningFlag -> TcRnIf gbl lcl () -> TcRnIf gbl lcl ()
ifXOptM :: ExtensionFlag -> TcRnIf gbl lcl () -> TcRnIf gbl lcl ()
getGhcMode :: TcRnIf gbl lcl GhcMode
getEpsVar :: TcRnIf gbl lcl (TcRef ExternalPackageState)
getEps :: TcRnIf gbl lcl ExternalPackageState

-- | Update the external package state. Returns the second result of the
--   modifier function.
--   
--   This is an atomic operation and forces evaluation of the modified EPS
--   in order to avoid space leaks.
updateEps :: (ExternalPackageState -> (ExternalPackageState, a)) -> TcRnIf gbl lcl a

-- | Update the external package state.
--   
--   This is an atomic operation and forces evaluation of the modified EPS
--   in order to avoid space leaks.
updateEps_ :: (ExternalPackageState -> ExternalPackageState) -> TcRnIf gbl lcl ()
getHpt :: TcRnIf gbl lcl HomePackageTable
getEpsAndHpt :: TcRnIf gbl lcl (ExternalPackageState, HomePackageTable)
newMetaUnique :: TcM Unique
newUnique :: TcRnIf gbl lcl Unique
newUniqueSupply :: TcRnIf gbl lcl UniqSupply
newLocalName :: Name -> TcRnIf gbl lcl Name
newSysLocalIds :: FastString -> [TcType] -> TcRnIf gbl lcl [TcId]
newName :: OccName -> TcM Name
newTcRef :: a -> TcRnIf gbl lcl (TcRef a)
readTcRef :: TcRef a -> TcRnIf gbl lcl a
writeTcRef :: TcRef a -> a -> TcRnIf gbl lcl ()
updTcRef :: TcRef a -> (a -> a) -> TcRnIf gbl lcl ()
traceTc :: String -> SDoc -> TcRn ()
traceTcN :: Int -> String -> SDoc -> TcRn ()
traceRn :: SDoc -> TcRn ()
traceSplice :: SDoc -> TcRn ()
traceIf :: SDoc -> TcRnIf m n ()
traceHiDiffs :: SDoc -> TcRnIf m n ()
traceOptIf :: DynFlag -> SDoc -> TcRnIf m n ()
traceOptTcRn :: DynFlag -> SDoc -> TcRn ()
dumpTcRn :: SDoc -> TcRn ()
debugDumpTcRn :: SDoc -> TcRn ()
dumpOptTcRn :: DynFlag -> SDoc -> TcRn ()
getModule :: TcRn Module
setModule :: Module -> TcRn a -> TcRn a
getIsGHCi :: TcRn Bool
getGHCiMonad :: TcRn Name
getInteractivePrintName :: TcRn Name
tcIsHsBoot :: TcRn Bool
getGlobalRdrEnv :: TcRn GlobalRdrEnv
getRdrEnvs :: TcRn (GlobalRdrEnv, LocalRdrEnv)
getImports :: TcRn ImportAvails
getFixityEnv :: TcRn FixityEnv
extendFixityEnv :: [(Name, FixItem)] -> RnM a -> RnM a
getRecFieldEnv :: TcRn RecFieldEnv
getDeclaredDefaultTys :: TcRn (Maybe [Type])
addDependentFiles :: [FilePath] -> TcRn ()
getSrcSpanM :: TcRn SrcSpan
setSrcSpan :: SrcSpan -> TcRn a -> TcRn a
addLocM :: (a -> TcM b) -> Located a -> TcM b
wrapLocM :: (a -> TcM b) -> Located a -> TcM (Located b)
wrapLocFstM :: (a -> TcM (b, c)) -> Located a -> TcM (Located b, c)
wrapLocSndM :: (a -> TcM (b, c)) -> Located a -> TcM (b, Located c)
getErrsVar :: TcRn (TcRef Messages)
setErrsVar :: TcRef Messages -> TcRn a -> TcRn a
addErr :: MsgDoc -> TcRn ()
failWith :: MsgDoc -> TcRn a
addErrAt :: SrcSpan -> MsgDoc -> TcRn ()
addErrs :: [(SrcSpan, MsgDoc)] -> TcRn ()
checkErr :: Bool -> MsgDoc -> TcRn ()
warnIf :: Bool -> MsgDoc -> TcRn ()
addMessages :: Messages -> TcRn ()
discardWarnings :: TcRn a -> TcRn a
mkLongErrAt :: SrcSpan -> MsgDoc -> MsgDoc -> TcRn ErrMsg
addLongErrAt :: SrcSpan -> MsgDoc -> MsgDoc -> TcRn ()
reportErrors :: [ErrMsg] -> TcM ()
reportError :: ErrMsg -> TcRn ()
reportWarning :: ErrMsg -> TcRn ()
dumpDerivingInfo :: SDoc -> TcM ()
try_m :: TcRn r -> TcRn (Either IOEnvFailure r)
recoverM :: TcRn r -> TcRn r -> TcRn r
mapAndRecoverM :: (a -> TcRn b) -> [a] -> TcRn [b]
tryTc :: TcRn a -> TcRn (Messages, Maybe a)
tryTcErrs :: TcRn a -> TcRn (Messages, Maybe a)
tryTcLIE :: TcM a -> TcM (Messages, Maybe a)
tryTcLIE_ :: TcM r -> TcM r -> TcM r
checkNoErrs :: TcM r -> TcM r
ifErrsM :: TcRn r -> TcRn r -> TcRn r
failIfErrsM :: TcRn ()
getErrCtxt :: TcM [ErrCtxt]
setErrCtxt :: [ErrCtxt] -> TcM a -> TcM a
addErrCtxt :: MsgDoc -> TcM a -> TcM a
addErrCtxtM :: (TidyEnv -> TcM (TidyEnv, MsgDoc)) -> TcM a -> TcM a
addLandmarkErrCtxt :: MsgDoc -> TcM a -> TcM a
updCtxt :: ([ErrCtxt] -> [ErrCtxt]) -> TcM a -> TcM a
popErrCtxt :: TcM a -> TcM a
getCtLoc :: orig -> TcM (CtLoc orig)
setCtLoc :: CtLoc orig -> TcM a -> TcM a
addErrTc :: MsgDoc -> TcM ()
addErrsTc :: [MsgDoc] -> TcM ()
addErrTcM :: (TidyEnv, MsgDoc) -> TcM ()
mkErrTcM :: (TidyEnv, MsgDoc) -> TcM ErrMsg
failWithTc :: MsgDoc -> TcM a
failWithTcM :: (TidyEnv, MsgDoc) -> TcM a
checkTc :: Bool -> MsgDoc -> TcM ()
warnTc :: Bool -> MsgDoc -> TcM ()
addWarnTc :: MsgDoc -> TcM ()
addWarnTcM :: (TidyEnv, MsgDoc) -> TcM ()
addWarn :: MsgDoc -> TcRn ()
addWarnAt :: SrcSpan -> MsgDoc -> TcRn ()
add_warn :: MsgDoc -> MsgDoc -> TcRn ()
add_warn_at :: SrcSpan -> MsgDoc -> MsgDoc -> TcRn ()
tcInitTidyEnv :: TcM TidyEnv
add_err_tcm :: TidyEnv -> MsgDoc -> SrcSpan -> [ErrCtxt] -> TcM ()
mkErrInfo :: TidyEnv -> [ErrCtxt] -> TcM SDoc
mAX_CONTEXTS :: Int
debugTc :: TcM () -> TcM ()
newTcEvBinds :: TcM EvBindsVar
addTcEvBind :: EvBindsVar -> EvVar -> EvTerm -> TcM ()
getTcEvBinds :: EvBindsVar -> TcM (Bag EvBind)
chooseUniqueOccTc :: (OccSet -> OccName) -> TcM OccName
getConstraintVar :: TcM (TcRef WantedConstraints)
setConstraintVar :: TcRef WantedConstraints -> TcM a -> TcM a
emitConstraints :: WantedConstraints -> TcM ()
emitFlat :: Ct -> TcM ()
emitFlats :: Cts -> TcM ()
emitImplication :: Implication -> TcM ()
emitImplications :: Bag Implication -> TcM ()
captureConstraints :: TcM a -> TcM (a, WantedConstraints)
captureUntouchables :: TcM a -> TcM (a, Untouchables)
isUntouchable :: TcTyVar -> TcM Bool
getLclTypeEnv :: TcM TcTypeEnv
setLclTypeEnv :: TcLclEnv -> TcM a -> TcM a
traceTcConstraints :: String -> TcM ()
recordThUse :: TcM ()
recordThSpliceUse :: TcM ()
keepAliveTc :: Id -> TcM ()
keepAliveSetTc :: NameSet -> TcM ()
getStage :: TcM ThStage
setStage :: ThStage -> TcM a -> TcM a

-- | Mark that safe inference has failed
recordUnsafeInfer :: TcM ()

-- | Figure out the final correct safe haskell mode
finalSafeMode :: DynFlags -> TcGblEnv -> IO SafeHaskellMode
getLocalRdrEnv :: RnM LocalRdrEnv
setLocalRdrEnv :: LocalRdrEnv -> RnM a -> RnM a
mkIfLclEnv :: Module -> SDoc -> IfLclEnv
initIfaceTcRn :: IfG a -> TcRn a
initIfaceExtCore :: IfL a -> TcRn a
initIfaceCheck :: HscEnv -> IfG a -> IO a
initIfaceTc :: ModIface -> (TcRef TypeEnv -> IfL a) -> TcRnIf gbl lcl a
initIfaceLcl :: Module -> SDoc -> IfL a -> IfM lcl a
getIfModule :: IfL Module
failIfM :: MsgDoc -> IfL a
forkM_maybe :: SDoc -> IfL a -> IfL (Maybe a)
forkM :: SDoc -> IfL a -> IfL a
instance MonadUnique (IOEnv (Env gbl lcl))

module TcMType
type TcTyVar = TyVar
type TcKind = Kind
type TcType = Type
type TcTauType = TcType
type TcThetaType = ThetaType
type TcTyVarSet = TyVarSet
newFlexiTyVar :: Kind -> TcM TcTyVar
newFlexiTyVarTy :: Kind -> TcM TcType
newFlexiTyVarTys :: Int -> Kind -> TcM [TcType]
newMetaKindVar :: TcM TcKind
newMetaKindVars :: Int -> TcM [TcKind]
mkKindSigVar :: Name -> KindVar
mkTcTyVarName :: Unique -> FastString -> Name
newMetaTyVar :: MetaInfo -> Kind -> TcM TcTyVar
readMetaTyVar :: TyVar -> TcM MetaDetails
writeMetaTyVar :: TcTyVar -> TcType -> TcM ()
writeMetaTyVarRef :: TcTyVar -> TcRef MetaDetails -> TcType -> TcM ()
isFilledMetaTyVar :: TyVar -> TcM Bool
isFlexiMetaTyVar :: TyVar -> TcM Bool
newEvVar :: TcPredType -> TcM EvVar
newEvVars :: TcThetaType -> TcM [EvVar]
newEq :: TcType -> TcType -> TcM EvVar
newDict :: Class -> [TcType] -> TcM DictId
newWantedEvVar :: TcPredType -> TcM EvVar
newWantedEvVars :: TcThetaType -> TcM [EvVar]
newTcEvBinds :: TcM EvBindsVar
addTcEvBind :: EvBindsVar -> EvVar -> EvTerm -> TcM ()
tcInstTyVars :: [TKVar] -> TcM ([TcTyVar], [TcType], TvSubst)
tcInstSigTyVars :: [TyVar] -> TcM (TvSubst, [TcTyVar])
newSigTyVar :: Name -> Kind -> TcM TcTyVar
tcInstType :: ([TyVar] -> TcM (TvSubst, [TcTyVar])) -> TcType -> TcM ([TcTyVar], TcThetaType, TcType)
tcInstSkolTyVars :: [TyVar] -> TcM (TvSubst, [TcTyVar])
tcInstSuperSkolTyVars :: [TyVar] -> TcM [TcTyVar]
tcInstSkolTyVarsX :: TvSubst -> [TyVar] -> TcM (TvSubst, [TcTyVar])
tcInstSuperSkolTyVarsX :: TvSubst -> [TyVar] -> TcM (TvSubst, [TcTyVar])
tcInstSkolTyVar :: Bool -> TvSubst -> TyVar -> TcM (TvSubst, TcTyVar)
tcInstSkolType :: TcType -> TcM ([TcTyVar], TcThetaType, TcType)
tcSkolDFunType :: Type -> TcM ([TcTyVar], TcThetaType, TcType)
tcSuperSkolTyVars :: [TyVar] -> (TvSubst, [TcTyVar])
data Rank
data UserTypeCtxt
FunSigCtxt :: Name -> UserTypeCtxt
InfSigCtxt :: Name -> UserTypeCtxt
ExprSigCtxt :: UserTypeCtxt
ConArgCtxt :: Name -> UserTypeCtxt
TySynCtxt :: Name -> UserTypeCtxt
LamPatSigCtxt :: UserTypeCtxt
BindPatSigCtxt :: UserTypeCtxt
RuleSigCtxt :: Name -> UserTypeCtxt
ResSigCtxt :: UserTypeCtxt
ForSigCtxt :: Name -> UserTypeCtxt
DefaultDeclCtxt :: UserTypeCtxt
InstDeclCtxt :: UserTypeCtxt
SpecInstCtxt :: UserTypeCtxt
ThBrackCtxt :: UserTypeCtxt
GenSigCtxt :: UserTypeCtxt
GhciCtxt :: UserTypeCtxt
ClassSCCtxt :: Name -> UserTypeCtxt
SigmaCtxt :: UserTypeCtxt
DataTyCtxt :: Name -> UserTypeCtxt
checkValidType :: UserTypeCtxt -> Type -> TcM ()
checkValidMonoType :: Type -> TcM ()
expectedKindInCtxt :: UserTypeCtxt -> Maybe Kind
checkValidTheta :: UserTypeCtxt -> ThetaType -> TcM ()
checkValidInstHead :: UserTypeCtxt -> Class -> [Type] -> TcM ()
checkValidInstance :: UserTypeCtxt -> LHsType Name -> Type -> TcM ([TyVar], ThetaType, Class, [Type])
validDerivPred :: TyVarSet -> PredType -> Bool
checkInstTermination :: [TcType] -> ThetaType -> TcM ()
checkValidFamInst :: [Type] -> Type -> TcM ()
checkTyFamFreeness :: Type -> TcM ()
arityErr :: Outputable a => String -> a -> Int -> Int -> SDoc
growThetaTyVars :: TcThetaType -> TyVarSet -> TyVarSet
quantifyPred :: TyVarSet -> PredType -> Bool
zonkTcPredType :: TcPredType -> TcM TcPredType
skolemiseSigTv :: TcTyVar -> TcM TcTyVar
skolemiseUnboundMetaTyVar :: TcTyVar -> TcTyVarDetails -> TcM TyVar
zonkTcTyVar :: TcTyVar -> TcM TcType
zonkTcTyVars :: [TcTyVar] -> TcM [TcType]
zonkTyVarsAndFV :: TyVarSet -> TcM TyVarSet
zonkQuantifiedTyVar :: TcTyVar -> TcM TcTyVar
zonkQuantifiedTyVars :: [TcTyVar] -> TcM [TcTyVar]
zonkTcType :: TcType -> TcM TcType
zonkTcTypes :: [TcType] -> TcM [TcType]
zonkTcThetaType :: TcThetaType -> TcM TcThetaType
zonkTcKind :: TcKind -> TcM TcKind
defaultKindVarToStar :: TcTyVar -> TcM Kind
zonkCt :: Ct -> TcM Ct
zonkCts :: Cts -> TcM Cts
zonkImplication :: Implication -> TcM Implication
zonkEvVar :: EvVar -> TcM EvVar
zonkWC :: WantedConstraints -> TcM WantedConstraints
zonkId :: TcId -> TcM TcId
tcGetGlobalTyVars :: TcM TcTyVarSet

module TcHsSyn
mkHsConApp :: DataCon -> [Type] -> [HsExpr Id] -> LHsExpr Id
mkHsDictLet :: TcEvBinds -> LHsExpr Id -> LHsExpr Id
mkHsApp :: LHsExpr name -> LHsExpr name -> LHsExpr name
hsLitType :: HsLit -> TcType
hsLPatType :: OutPat Id -> Type
hsPatType :: Pat Id -> Type
mkHsAppTy :: LHsType name -> LHsType name -> LHsType name
mkSimpleHsAlt :: LPat id -> LHsExpr id -> LMatch id
nlHsIntLit :: Integer -> LHsExpr id
shortCutLit :: OverLitVal -> TcType -> Maybe (HsExpr TcId)
hsOverLitName :: OverLitVal -> Name
type TcId = Id
type TcIdSet = IdSet
zonkTopDecls :: Bag EvBind -> LHsBinds TcId -> NameSet -> [LRuleDecl TcId] -> [LVectDecl TcId] -> [LTcSpecPrag] -> [LForeignDecl TcId] -> TcM ([Id], Bag EvBind, Bag (LHsBind Id), [LForeignDecl Id], [LTcSpecPrag], [LRuleDecl Id], [LVectDecl Id])
zonkTopExpr :: HsExpr TcId -> TcM (HsExpr Id)
zonkTopLExpr :: LHsExpr TcId -> TcM (LHsExpr Id)
zonkTopBndrs :: [TcId] -> TcM [Id]
zonkTyBndrsX :: ZonkEnv -> [TyVar] -> TcM (ZonkEnv, [TyVar])
emptyZonkEnv :: ZonkEnv
mkEmptyZonkEnv :: UnboundTyVarZonker -> ZonkEnv
mkTyVarZonkEnv :: [TyVar] -> ZonkEnv
zonkTcTypeToType :: ZonkEnv -> TcType -> TcM Type
zonkTcTypeToTypes :: ZonkEnv -> [TcType] -> TcM [Type]
zonkTyVarOcc :: ZonkEnv -> TyVar -> TcM TcType
instance Outputable ZonkEnv

module RnHsDoc
rnHsDoc :: HsDocString -> RnM HsDocString
rnLHsDoc :: LHsDocString -> RnM LHsDocString
rnMbLHsDoc :: Maybe LHsDocString -> RnM (Maybe LHsDocString)

module IfaceEnv
newGlobalBinder :: Module -> OccName -> SrcSpan -> TcRnIf a b Name
newImplicitBinder :: Name -> (OccName -> OccName) -> TcRnIf m n Name
lookupIfaceTop :: OccName -> IfL Name
lookupOrig :: Module -> OccName -> TcRnIf a b Name
lookupOrigNameCache :: OrigNameCache -> Module -> OccName -> Maybe Name
extendNameCache :: OrigNameCache -> Module -> OccName -> Name -> OrigNameCache
newIfaceName :: OccName -> IfL Name
newIfaceNames :: [OccName] -> IfL [Name]
extendIfaceIdEnv :: [Id] -> IfL a -> IfL a
extendIfaceTyVarEnv :: [TyVar] -> IfL a -> IfL a
tcIfaceLclId :: FastString -> IfL Id
tcIfaceTyVar :: FastString -> IfL TyVar
lookupIfaceTyVar :: FastString -> IfL (Maybe TyVar)
ifaceExportNames :: [IfaceExport] -> TcRnIf gbl lcl [AvailInfo]
allocateGlobalBinder :: NameCache -> Module -> OccName -> SrcSpan -> (NameCache, Name)
initNameCache :: UniqSupply -> [Name] -> NameCache
updNameCache :: (NameCache -> (NameCache, c)) -> TcRnIf a b c
getNameCache :: TcRnIf a b NameCache

-- | Return a function to atomically update the name cache.
mkNameCacheUpdater :: TcRnIf a b NameCacheUpdater

-- | A function that atomically updates the name cache given a modifier
--   function. The second result of the modifier function will be the
--   result of the IO action.
data NameCacheUpdater
NCU :: (forall c. (NameCache -> (NameCache, c)) -> IO c) -> NameCacheUpdater
updateNameCache :: NameCacheUpdater -> forall c. (NameCache -> (NameCache, c)) -> IO c

module BuildTyCl
buildSynTyCon :: Name -> [TyVar] -> SynTyConRhs -> Kind -> TyConParent -> TcRnIf m n TyCon
buildAlgTyCon :: Name -> [TyVar] -> Maybe CType -> ThetaType -> AlgTyConRhs -> RecFlag -> Bool -> TyConParent -> TyCon
buildDataCon :: Name -> Bool -> [HsBang] -> [Name] -> [TyVar] -> [TyVar] -> [(TyVar, Type)] -> ThetaType -> [Type] -> Type -> TyCon -> TcRnIf m n DataCon
type TcMethInfo = (Name, DefMethSpec, Type)
buildClass :: Bool -> Name -> [TyVar] -> ThetaType -> [FunDep TyVar] -> [ClassATItem] -> [TcMethInfo] -> RecFlag -> TcRnIf m n Class
distinctAbstractTyConRhs :: AlgTyConRhs
totallyAbstractTyConRhs :: AlgTyConRhs

-- | Monadic because it makes a Name for the coercion TyCon We pass the
--   Name of the parent TyCon, as well as the TyCon itself, because the
--   latter is part of a knot, whereas the former is not.
mkNewTyConRhs :: Name -> TyCon -> DataCon -> TcRnIf m n AlgTyConRhs
mkDataTyConRhs :: [DataCon] -> AlgTyConRhs
newImplicitBinder :: Name -> (OccName -> OccName) -> TcRnIf m n Name

module PrelInfo
wiredInIds :: [Id]
ghcPrimIds :: [Id]
primOpRules :: PrimOp -> Name -> [CoreRule]
builtinRules :: [CoreRule]
ghcPrimExports :: [IfaceExport]
wiredInThings :: [TyThing]
basicKnownKeyNames :: [Name]
primOpId :: PrimOp -> Id
maybeCharLikeCon :: DataCon -> Bool
maybeIntLikeCon :: DataCon -> Bool
isNumericClass :: Class -> Bool
isStandardClass :: Class -> Bool

module MkExternalCore
emitExternalCore :: DynFlags -> CgGuts -> IO ()
instance HasDynFlags CoreM
instance Monad CoreM


-- | Parsing the top of a Haskell source file to get its module name,
--   imports and options.
--   
--   (c) Simon Marlow 2005 (c) Lemmih 2006
module HeaderInfo

-- | Parse the imports of a source file.
--   
--   Throws a <a>SourceError</a> if parsing fails.
getImports :: DynFlags -> StringBuffer -> FilePath -> FilePath -> IO ([Located (ImportDecl RdrName)], [Located (ImportDecl RdrName)], Located ModuleName)
mkPrelImports :: ModuleName -> SrcSpan -> Bool -> [LImportDecl RdrName] -> [LImportDecl RdrName]

-- | Parse OPTIONS and LANGUAGE pragmas of the source file.
--   
--   Throws a <a>SourceError</a> if flag parsing fails (including
--   unsupported flags.)
getOptionsFromFile :: DynFlags -> FilePath -> IO [Located String]

-- | Parse OPTIONS and LANGUAGE pragmas of the source file.
--   
--   Throws a <a>SourceError</a> if flag parsing fails (including
--   unsupported flags.)
getOptions :: DynFlags -> StringBuffer -> FilePath -> [Located String]
optionsErrorMsgs :: DynFlags -> [String] -> [Located String] -> FilePath -> Messages

-- | Complain about non-dynamic flags in OPTIONS pragmas.
--   
--   Throws a <a>SourceError</a> if the input list is non-empty claiming
--   that the input flags are unknown.
checkProcessArgsResult :: MonadIO m => DynFlags -> [Located String] -> m ()

module TcTyDecls
calcRecFlags :: ModDetails -> [TyThing] -> (Name -> RecFlag)
calcSynCycles :: [LTyClDecl Name] -> [SCC (LTyClDecl Name)]
calcClassCycles :: Class -> [[TyCon]]

module Vectorise.Env

-- | Indicates what scope something (a variable) is in.
data Scope a b
Global :: a -> Scope a b
Local :: b -> Scope a b

-- | The local environment.
data LocalEnv
LocalEnv :: VarEnv (Var, Var) -> [TyVar] -> VarEnv CoreExpr -> FastString -> LocalEnv
local_vars :: LocalEnv -> VarEnv (Var, Var)
local_tyvars :: LocalEnv -> [TyVar]
local_tyvar_pa :: LocalEnv -> VarEnv CoreExpr
local_bind_name :: LocalEnv -> FastString

-- | Create an empty local environment.
emptyLocalEnv :: LocalEnv

-- | The global environment: entities that exist at top-level.
data GlobalEnv
GlobalEnv :: VarEnv Var -> VarEnv (Type, CoreExpr) -> VarSet -> NameSet -> VarSet -> NameEnv TyCon -> NameEnv DataCon -> NameEnv Var -> NameEnv Var -> (InstEnv, InstEnv) -> FamInstEnvs -> [(Var, CoreExpr)] -> GlobalEnv

-- | Mapping from global variables to their vectorised versions — aka the
--   /vectorisation map/.
global_vars :: GlobalEnv -> VarEnv Var

-- | Mapping from global variables that have a vectorisation declaration to
--   the right-hand side of that declaration and its type. This mapping
--   only applies to non-scalar vectorisation declarations. All variables
--   with a scalar vectorisation declaration are mentioned in
--   <tt>global_scalars_vars</tt>.
global_vect_decls :: GlobalEnv -> VarEnv (Type, CoreExpr)

-- | Purely scalar variables. Code which mentions only these variables
--   doesn't have to be lifted. This includes variables from the current
--   module that have a scalar vectorisation declaration and those that the
--   vectoriser determines to be scalar.
global_scalar_vars :: GlobalEnv -> VarSet

-- | Type constructors whose values can only contain scalar data. This
--   includes type constructors that appear in a 'VECTORISE SCALAR type'
--   pragma or 'VECTORISE type' pragma *without* a right-hand side in the
--   current or an imported module as well as type constructors that are
--   automatically identified as scalar by the vectoriser (in <a>Env</a>).
--   Scalar code may only operate on such data.
--   
--   NB: Not all type constructors in that set are members of the
--   <tt>Scalar</tt> type class (which can be trivially marshalled across
--   scalar code boundaries).
global_scalar_tycons :: GlobalEnv -> NameSet

-- | Variables that are not vectorised. (They may be referenced in the
--   right-hand sides of vectorisation declarations, though.)
global_novect_vars :: GlobalEnv -> VarSet

-- | Mapping from TyCons to their vectorised versions. TyCons which do not
--   have to be vectorised are mapped to themselves.
global_tycons :: GlobalEnv -> NameEnv TyCon

-- | Mapping from DataCons to their vectorised versions.
global_datacons :: GlobalEnv -> NameEnv DataCon

-- | Mapping from TyCons to their PA dfuns.
global_pa_funs :: GlobalEnv -> NameEnv Var

-- | Mapping from TyCons to their PR dfuns.
global_pr_funs :: GlobalEnv -> NameEnv Var

-- | External package inst-env &amp; home-package inst-env for class
--   instances.
global_inst_env :: GlobalEnv -> (InstEnv, InstEnv)

-- | External package inst-env &amp; home-package inst-env for family
--   instances.
global_fam_inst_env :: GlobalEnv -> FamInstEnvs

-- | Hoisted bindings.
global_bindings :: GlobalEnv -> [(Var, CoreExpr)]

-- | Create an initial global environment.
--   
--   We add scalar variables and type constructors identified by
--   vectorisation pragmas already here to the global table, so that we can
--   query scalarness during vectorisation, and especially, when
--   vectorising the scalar entities' definitions themselves.
initGlobalEnv :: VectInfo -> [CoreVect] -> (InstEnv, InstEnv) -> FamInstEnvs -> GlobalEnv

-- | Extend the list of global variables in an environment.
extendImportedVarsEnv :: [(Var, Var)] -> GlobalEnv -> GlobalEnv

-- | Extend the list of type family instances.
extendFamEnv :: [FamInst] -> GlobalEnv -> GlobalEnv

-- | Set the list of PA functions in an environment.
setPAFunsEnv :: [(Name, Var)] -> GlobalEnv -> GlobalEnv

-- | Set the list of PR functions in an environment.
setPRFunsEnv :: [(Name, Var)] -> GlobalEnv -> GlobalEnv

-- | Compute vectorisation information that goes into <a>ModGuts</a> (and
--   is stored in interface files). The incoming <tt>vectInfo</tt> is that
--   from the <a>HscEnv</a> and <a>EPS</a>. The outgoing one contains only
--   the declarations for the currently compiled module; this includes
--   variables, type constructors, and data constructors referenced in
--   VECTORISE pragmas, even if they are defined in an imported module.
--   
--   The variables explicitly include class selectors and dfuns.
modVectInfo :: GlobalEnv -> [Id] -> [TyCon] -> [CoreVect] -> VectInfo -> VectInfo

module ByteCodeLink
data HValue
type ClosureEnv = NameEnv (Name, HValue)
emptyClosureEnv :: ClosureEnv
extendClosureEnv :: ClosureEnv -> [(Name, HValue)] -> ClosureEnv
linkBCO :: ItblEnv -> ClosureEnv -> UnlinkedBCO -> IO HValue
lookupStaticPtr :: FastString -> IO (Ptr ())
lookupName :: ClosureEnv -> Name -> IO HValue
lookupIE :: ItblEnv -> Name -> IO (Ptr a)
instance MArray IOArray e IO

module ByteCodeGen
data UnlinkedBCO
byteCodeGen :: DynFlags -> Module -> CoreProgram -> [TyCon] -> ModBreaks -> IO CompiledByteCode
coreExprToBCOs :: DynFlags -> Module -> CoreExpr -> IO UnlinkedBCO
instance Eq Discr
instance Ord Discr
instance Monad BcM
instance Outputable Discr

module CgHpc
cgTickBox :: Module -> Int -> Code
hpcTable :: Module -> HpcInfo -> Code

module CgBindery
type CgBindings = IdEnv CgIdInfo
data CgIdInfo
data StableLoc
data VolatileLoc
cgIdInfoId :: CgIdInfo -> Id
cgIdInfoArgRep :: CgIdInfo -> CgRep
cgIdInfoLF :: CgIdInfo -> LambdaFormInfo
stableIdInfo :: Id -> CmmExpr -> LambdaFormInfo -> CgIdInfo
heapIdInfo :: Id -> VirtualHpOffset -> LambdaFormInfo -> CgIdInfo
taggedStableIdInfo :: Id -> CmmExpr -> LambdaFormInfo -> DataCon -> CgIdInfo
taggedHeapIdInfo :: Id -> VirtualHpOffset -> LambdaFormInfo -> DataCon -> CgIdInfo
letNoEscapeIdInfo :: Id -> VirtualSpOffset -> LambdaFormInfo -> CgIdInfo
idInfoToAmode :: CgIdInfo -> FCode CmmExpr
addBindC :: Id -> CgIdInfo -> Code
addBindsC :: [(Id, CgIdInfo)] -> Code
nukeVolatileBinds :: CgBindings -> CgBindings
nukeDeadBindings :: StgLiveVars -> Code
getLiveStackSlots :: FCode [VirtualSpOffset]
getLiveStackBindings :: FCode [(VirtualSpOffset, CgIdInfo)]
bindArgsToStack :: [(Id, VirtualSpOffset)] -> Code
rebindToStack :: Id -> VirtualSpOffset -> Code
bindNewToNode :: Id -> VirtualHpOffset -> LambdaFormInfo -> Code
bindNewToUntagNode :: Id -> VirtualHpOffset -> LambdaFormInfo -> Int -> Code
bindNewToReg :: Id -> CmmReg -> LambdaFormInfo -> Code
bindArgsToRegs :: [(Id, GlobalReg)] -> Code
bindNewToTemp :: Id -> FCode LocalReg
getArgAmode :: StgArg -> FCode (CgRep, CmmExpr)
getArgAmodes :: [StgArg] -> FCode [(CgRep, CmmExpr)]
getCgIdInfo :: Id -> FCode CgIdInfo
getCAddrModeIfVolatile :: Id -> FCode (Maybe CmmExpr)
getVolatileRegs :: StgLiveVars -> FCode [GlobalReg]
maybeLetNoEscape :: CgIdInfo -> Maybe VirtualSpOffset
instance Outputable StableLoc
instance Outputable VolatileLoc
instance Outputable CgIdInfo

module CgInfoTbls
emitClosureCodeAndInfoTable :: ClosureInfo -> [CmmFormal] -> CgStmts -> Code
emitInfoTableAndCode :: CLabel -> CmmInfoTable -> [CmmFormal] -> [CmmBasicBlock] -> Code
emitReturnTarget :: Name -> CgStmts -> FCode CLabel
emitAlgReturnTarget :: Name -> [(ConTagZ, CgStmts)] -> Maybe CgStmts -> Int -> FCode (CLabel, SemiTaggingStuff)
emitReturnInstr :: Maybe [GlobalReg] -> Code
stdInfoTableSizeB :: ByteOff
entryCode :: CmmExpr -> CmmExpr
closureInfoPtr :: CmmExpr -> CmmExpr
getConstrTag :: CmmExpr -> CmmExpr
cmmGetClosureType :: CmmExpr -> CmmExpr
infoTable :: CmmExpr -> CmmExpr
infoTableClosureType :: CmmExpr -> CmmExpr
infoTablePtrs :: CmmExpr -> CmmExpr
infoTableNonPtrs :: CmmExpr -> CmmExpr
funInfoTable :: CmmExpr -> CmmExpr

module DebuggerUtils

-- | Given a data constructor in the heap, find its Name. The info tables
--   for data constructors have a field which records the source name of
--   the constructor as a Ptr Word8 (UTF-8 encoded string). The format is:
--   
--   <pre>
--   Package:Module.Name
--   </pre>
--   
--   We use this string to lookup the interpreter's internal representation
--   of the name using the lookupOrig.
dataConInfoPtrToName :: Ptr () -> TcM (Either String Name)

module CgForeignCall
cgForeignCall :: [HintedCmmFormal] -> ForeignCall -> [StgArg] -> StgLiveVars -> Code
emitForeignCall :: [HintedCmmFormal] -> ForeignCall -> [CmmHinted CmmExpr] -> StgLiveVars -> Code
emitForeignCall' :: Safety -> [HintedCmmFormal] -> CmmCallTarget -> [CmmHinted CmmExpr] -> Maybe [GlobalReg] -> C_SRT -> CmmReturnInfo -> Code
shimForeignCallArg :: StgArg -> CmmExpr -> CmmExpr
emitSaveThreadState :: Code
emitLoadThreadState :: Code
emitCloseNursery :: Code
emitOpenNursery :: Code

module CgTailCall
cgTailCall :: Id -> [StgArg] -> Code
performTailCall :: CgIdInfo -> [(CgRep, CmmExpr)] -> CmmStmts -> Code
performReturn :: Code -> Code
performPrimReturn :: CgRep -> CmmExpr -> Code
returnUnboxedTuple :: [(CgRep, CmmExpr)] -> Code
ccallReturnUnboxedTuple :: [(CgRep, CmmExpr)] -> Code -> Code
pushUnboxedTuple :: VirtualSpOffset -> [(CgRep, CmmExpr)] -> FCode (VirtualSpOffset, CmmStmts, [GlobalReg])
tailCallPrimOp :: PrimOp -> [StgArg] -> Code
tailCallPrimCall :: PrimCall -> [StgArg] -> Code
pushReturnAddress :: EndOfBlockInfo -> Code

module CgClosure
cgTopRhsClosure :: Id -> CostCentreStack -> StgBinderInfo -> UpdateFlag -> [Id] -> StgExpr -> FCode (Id, CgIdInfo)
cgStdRhsClosure :: Id -> CostCentreStack -> StgBinderInfo -> [Id] -> [Id] -> StgExpr -> LambdaFormInfo -> [StgArg] -> FCode (Id, CgIdInfo)
cgRhsClosure :: Id -> CostCentreStack -> StgBinderInfo -> [Id] -> UpdateFlag -> [Id] -> StgExpr -> FCode (Id, CgIdInfo)
emitBlackHoleCode :: Bool -> Code

module CmmParse
parseCmmFile :: DynFlags -> FilePath -> IO (Messages, Maybe CmmGroup)

module CgPrimOp
cgPrimOp :: [CmmFormal] -> PrimOp -> [StgArg] -> StgLiveVars -> Code

module SRT
computeSRTs :: [StgBinding] -> [(StgBinding, [(Id, [Id])])]

module StgCmmClosure
type DynTag = Int
tagForCon :: DataCon -> DynTag
isSmallFamily :: Int -> Bool
type ConTagZ = Int
dataConTagZ :: DataCon -> ConTagZ
idPrimRep :: Id -> PrimRep
isVoidRep :: PrimRep -> Bool
isGcPtrRep :: PrimRep -> Bool
addIdReps :: [Id] -> [(PrimRep, Id)]
addArgReps :: [StgArg] -> [(PrimRep, StgArg)]
argPrimRep :: StgArg -> PrimRep
data LambdaFormInfo
data StandardFormInfo
mkLFThunk :: Type -> TopLevelFlag -> [Id] -> UpdateFlag -> LambdaFormInfo
mkLFReEntrant :: TopLevelFlag -> [Id] -> [Id] -> ArgDescr -> LambdaFormInfo
mkConLFInfo :: DataCon -> LambdaFormInfo
mkSelectorLFInfo :: Id -> Int -> Bool -> LambdaFormInfo
mkApLFInfo :: Id -> UpdateFlag -> Arity -> LambdaFormInfo
mkLFImported :: Id -> LambdaFormInfo
mkLFArgument :: Id -> LambdaFormInfo
mkLFLetNoEscape :: LambdaFormInfo
mkLFBlackHole :: LambdaFormInfo
lfDynTag :: LambdaFormInfo -> DynTag
maybeIsLFCon :: LambdaFormInfo -> Maybe DataCon
isLFThunk :: LambdaFormInfo -> Bool
isLFReEntrant :: LambdaFormInfo -> Bool
lfUpdatable :: LambdaFormInfo -> Bool
nodeMustPointToIt :: LambdaFormInfo -> Bool
data CallMethod
EnterIt :: CallMethod
JumpToIt :: CallMethod
ReturnIt :: CallMethod
SlowCall :: CallMethod
DirectEntry :: CLabel -> RepArity -> CallMethod
getCallMethod :: DynFlags -> Name -> CafInfo -> LambdaFormInfo -> RepArity -> CallMethod
isKnownFun :: LambdaFormInfo -> Bool
funTag :: ClosureInfo -> DynTag
tagForArity :: RepArity -> DynTag
data ClosureInfo
mkClosureInfo :: Bool -> Id -> LambdaFormInfo -> Int -> Int -> String -> ClosureInfo

-- | Convert from <a>ClosureInfo</a> to <a>CmmInfoTable</a>.
mkCmmInfo :: ClosureInfo -> CmmInfoTable
closureLFInfo :: ClosureInfo -> LambdaFormInfo
closureName :: ClosureInfo -> Name
closureInfoLabel :: ClosureInfo -> CLabel
staticClosureLabel :: ClosureInfo -> CLabel
closureRednCountsLabel :: ClosureInfo -> CLabel
closureSlowEntryLabel :: ClosureInfo -> CLabel
closureLocalEntryLabel :: ClosureInfo -> CLabel
closureUpdReqd :: ClosureInfo -> Bool
closureSingleEntry :: ClosureInfo -> Bool
closureReEntrant :: ClosureInfo -> Bool
closureFunInfo :: ClosureInfo -> Maybe (RepArity, ArgDescr)
isToplevClosure :: ClosureInfo -> Bool
blackHoleOnEntry :: ClosureInfo -> Bool
isStaticClosure :: ClosureInfo -> Bool
mkDataConInfoTable :: DataCon -> Bool -> Int -> Int -> CmmInfoTable
cafBlackHoleInfoTable :: CmmInfoTable
staticClosureNeedsLink :: Bool -> CmmInfoTable -> Bool

module StgCmmMonad
data FCode a
initC :: IO CgState
runC :: DynFlags -> Module -> CgState -> FCode a -> (a, CgState)
thenC :: FCode () -> FCode a -> FCode a
thenFC :: FCode a -> (a -> FCode c) -> FCode c
listCs :: [FCode ()] -> FCode ()
listFCs :: [FCode a] -> FCode [a]
mapCs :: (a -> FCode ()) -> [a] -> FCode ()
mapFCs :: (a -> FCode b) -> [a] -> FCode [b]
returnFC :: a -> FCode a
fixC :: (a -> FCode a) -> FCode a
fixC_ :: (a -> FCode a) -> FCode ()
nopC :: FCode ()
whenC :: Bool -> FCode () -> FCode ()
newUnique :: FCode Unique
newUniqSupply :: FCode UniqSupply
newLabelC :: FCode BlockId
emitLabel :: BlockId -> FCode ()
emit :: CmmAGraph -> FCode ()
emitDecl :: CmmDecl -> FCode ()
emitProc :: CmmInfoTable -> CLabel -> [CmmFormal] -> CmmAGraph -> FCode ()
emitProcWithConvention :: Convention -> CmmInfoTable -> CLabel -> [CmmFormal] -> CmmAGraph -> FCode ()
emitSimpleProc :: CLabel -> CmmAGraph -> FCode ()
emitOutOfLine :: BlockId -> CmmAGraph -> FCode ()
emitAssign :: CmmReg -> CmmExpr -> FCode ()
emitStore :: CmmExpr -> CmmExpr -> FCode ()
emitComment :: FastString -> FCode ()
getCmm :: FCode () -> FCode CmmGroup
cgStmtsToBlocks :: CmmAGraph -> FCode CmmGraph
getCodeR :: FCode a -> FCode (a, CmmAGraph)
getCode :: FCode a -> FCode CmmAGraph
getHeapUsage :: (VirtualHpOffset -> FCode a) -> FCode a
mkCmmIfThenElse :: CmmExpr -> CmmAGraph -> CmmAGraph -> FCode CmmAGraph
mkCmmIfThen :: CmmExpr -> CmmAGraph -> FCode CmmAGraph
mkCmmIfGoto :: CmmExpr -> BlockId -> FCode CmmAGraph
mkCall :: CmmExpr -> (Convention, Convention) -> [CmmFormal] -> [CmmActual] -> UpdFrameOffset -> (ByteOff, [(CmmExpr, ByteOff)]) -> FCode CmmAGraph
mkCmmCall :: CmmExpr -> [CmmFormal] -> [CmmActual] -> UpdFrameOffset -> FCode CmmAGraph
mkSafeCall :: ForeignTarget -> [CmmFormal] -> [CmmActual] -> UpdFrameOffset -> Bool -> FCode CmmAGraph
forkClosureBody :: FCode () -> FCode ()
forkStatics :: FCode a -> FCode a
forkAlts :: [FCode a] -> FCode [a]
forkProc :: FCode a -> FCode a
codeOnly :: FCode () -> FCode ()
type ConTagZ = Int
data Sequel
Return :: Bool -> Sequel
AssignTo :: [LocalReg] -> Bool -> Sequel
withSequel :: Sequel -> FCode () -> FCode ()
getSequel :: FCode Sequel
setSRTLabel :: CLabel -> FCode a -> FCode a
getSRTLabel :: FCode CLabel
setTickyCtrLabel :: CLabel -> FCode () -> FCode ()
getTickyCtrLabel :: FCode CLabel
withUpdFrameOff :: UpdFrameOffset -> FCode () -> FCode ()
getUpdFrameOff :: FCode UpdFrameOffset
initUpdFrameOff :: UpdFrameOffset
data HeapUsage
HeapUsage :: VirtualHpOffset -> VirtualHpOffset -> HeapUsage
virtHp :: HeapUsage -> VirtualHpOffset
realHp :: HeapUsage -> VirtualHpOffset
type VirtualHpOffset = WordOff
initHpUsage :: HeapUsage
getHpUsage :: FCode HeapUsage
setHpUsage :: HeapUsage -> FCode ()
heapHWM :: HeapUsage -> VirtualHpOffset
setVirtHp :: VirtualHpOffset -> FCode ()
getVirtHp :: FCode VirtualHpOffset
setRealHp :: VirtualHpOffset -> FCode ()
getModuleName :: FCode Module
getState :: FCode CgState
setState :: CgState -> FCode ()
getInfoDown :: FCode CgInfoDownwards
getDynFlags :: HasDynFlags m => m DynFlags
getThisPackage :: FCode PackageId
data CgIdInfo
CgIdInfo :: Id -> LambdaFormInfo -> CgLoc -> {-# UNPACK #-} !DynTag -> CgIdInfo
cg_id :: CgIdInfo -> Id
cg_lf :: CgIdInfo -> LambdaFormInfo
cg_loc :: CgIdInfo -> CgLoc
cg_tag :: CgIdInfo -> {-# UNPACK #-} !DynTag
data CgLoc
CmmLoc :: CmmExpr -> CgLoc
LneLoc :: BlockId -> [LocalReg] -> CgLoc
getBinds :: FCode CgBindings
setBinds :: CgBindings -> FCode ()
getStaticBinds :: FCode CgBindings
data CgInfoDownwards
MkCgInfoDown :: DynFlags -> Module -> CgBindings -> CLabel -> UpdFrameOffset -> CLabel -> Sequel -> CgInfoDownwards
cgd_dflags :: CgInfoDownwards -> DynFlags
cgd_mod :: CgInfoDownwards -> Module
cgd_statics :: CgInfoDownwards -> CgBindings
cgd_srt_lbl :: CgInfoDownwards -> CLabel
cgd_updfr_off :: CgInfoDownwards -> UpdFrameOffset
cgd_ticky :: CgInfoDownwards -> CLabel
cgd_sequel :: CgInfoDownwards -> Sequel
data CgState
MkCgState :: CmmAGraph -> OrdList CmmDecl -> CgBindings -> HeapUsage -> UniqSupply -> CgState
cgs_stmts :: CgState -> CmmAGraph
cgs_tops :: CgState -> OrdList CmmDecl
cgs_binds :: CgState -> CgBindings
cgs_hp_usg :: CgState -> HeapUsage
cgs_uniqs :: CgState -> UniqSupply
instance HasDynFlags FCode
instance Show Sequel
instance Outputable CgLoc
instance Outputable CgIdInfo
instance Monad FCode

module StgCmmUtils
cgLit :: Literal -> FCode CmmLit
mkSimpleLit :: Literal -> CmmLit
emitDataLits :: CLabel -> [CmmLit] -> FCode ()
mkDataLits :: Section -> CLabel -> [CmmLit] -> GenCmmDecl CmmStatics info stmt
emitRODataLits :: CLabel -> [CmmLit] -> FCode ()
mkRODataLits :: CLabel -> [CmmLit] -> GenCmmDecl CmmStatics info stmt
emitRtsCall :: PackageId -> FastString -> [(CmmExpr, ForeignHint)] -> Bool -> FCode ()
emitRtsCallWithVols :: PackageId -> FastString -> [(CmmExpr, ForeignHint)] -> [GlobalReg] -> Bool -> FCode ()
emitRtsCallWithResult :: LocalReg -> ForeignHint -> PackageId -> FastString -> [(CmmExpr, ForeignHint)] -> Bool -> FCode ()
emitRtsCallGen :: [(LocalReg, ForeignHint)] -> PackageId -> FastString -> [(CmmExpr, ForeignHint)] -> Maybe [GlobalReg] -> Bool -> FCode ()
assignTemp :: CmmExpr -> FCode LocalReg
newTemp :: CmmType -> FCode LocalReg
newUnboxedTupleRegs :: Type -> FCode ([LocalReg], [ForeignHint])
emitMultiAssign :: [LocalReg] -> [CmmExpr] -> FCode ()
emitCmmLitSwitch :: CmmExpr -> [(Literal, CmmAGraph)] -> CmmAGraph -> FCode ()
emitSwitch :: CmmExpr -> [(ConTagZ, CmmAGraph)] -> Maybe CmmAGraph -> ConTagZ -> ConTagZ -> FCode ()
tagToClosure :: TyCon -> CmmExpr -> CmmExpr
mkTaggedObjectLoad :: LocalReg -> LocalReg -> WordOff -> DynTag -> CmmAGraph

-- | Returns <a>True</a> if this global register is stored in a
--   caller-saves machine register.
callerSaves :: GlobalReg -> Bool
callerSaveVolatileRegs :: (CmmAGraph, CmmAGraph)
get_GlobalReg_addr :: GlobalReg -> CmmExpr
cmmAndWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmOrWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmNegate :: CmmExpr -> CmmExpr
cmmEqWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmNeWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmUGtWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmSubWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmMulWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmAddWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmUShrWord :: CmmExpr -> CmmExpr -> CmmExpr
cmmOffsetExprW :: CmmExpr -> CmmExpr -> CmmExpr
cmmOffsetExprB :: CmmExpr -> CmmExpr -> CmmExpr
cmmRegOffW :: CmmReg -> WordOff -> CmmExpr
cmmRegOffB :: CmmReg -> ByteOff -> CmmExpr
cmmLabelOffW :: CLabel -> WordOff -> CmmLit
cmmLabelOffB :: CLabel -> ByteOff -> CmmLit
cmmOffsetW :: CmmExpr -> WordOff -> CmmExpr
cmmOffsetB :: CmmExpr -> ByteOff -> CmmExpr
cmmOffsetLitW :: CmmLit -> WordOff -> CmmLit
cmmOffsetLitB :: CmmLit -> ByteOff -> CmmLit
cmmLoadIndexW :: CmmExpr -> Int -> CmmType -> CmmExpr
cmmConstrTag :: CmmExpr -> CmmExpr
cmmConstrTag1 :: CmmExpr -> CmmExpr
cmmUntag :: CmmExpr -> CmmExpr
cmmIsTagged :: CmmExpr -> CmmExpr
cmmGetTag :: CmmExpr -> CmmExpr
addToMem :: CmmType -> CmmExpr -> Int -> CmmAGraph
addToMemE :: CmmType -> CmmExpr -> CmmExpr -> CmmAGraph
addToMemLbl :: CmmType -> CLabel -> Int -> CmmAGraph
mkWordCLit :: StgWord -> CmmLit
newStringCLit :: String -> FCode CmmLit
newByteStringCLit :: [Word8] -> FCode CmmLit
packHalfWordsCLit :: (Integral a, Integral b) => a -> b -> CmmLit
blankWord :: CmmStatic
srt_escape :: StgHalfWord

module CmmBuildInfoTables
type CAFSet = Set CLabel
type CAFEnv = BlockEnv CAFSet
cafAnal :: CmmGraph -> CAFEnv
doSRTs :: TopSRT -> [(CAFEnv, [CmmDecl])] -> IO (TopSRT, [CmmDecl])
data TopSRT
emptySRT :: MonadUnique m => m TopSRT
srtToData :: TopSRT -> CmmGroup
instance Outputable TopSRT

module CmmRewriteAssignments
rewriteAssignments :: Platform -> CmmGraph -> UniqSM CmmGraph
instance Ord RegUsage
instance Eq RegUsage
instance Show RegUsage
instance NonLocal n => NonLocal (WithRegUsage n)
instance DefinerOfLocalRegs (n e x) => DefinerOfLocalRegs (WithRegUsage n e x)
instance UserOfLocalRegs (n e x) => UserOfLocalRegs (WithRegUsage n e x)

module StgCmmProf
initCostCentres :: CollectedCCs -> FCode ()
ccType :: CmmType
ccsType :: CmmType
mkCCostCentre :: CostCentre -> CmmLit
mkCCostCentreStack :: CostCentreStack -> CmmLit
dynProfHdr :: CmmExpr -> [CmmExpr]

-- | Record the allocation of a closure. The CmmExpr is the cost centre
--   stack to which to attribute the allocation.
profDynAlloc :: SMRep -> CmmExpr -> FCode ()

-- | Record the allocation of a closure (size is given by a CmmExpr) The
--   size must be in words, because the allocation counter in a CCS counts
--   in words.
profAlloc :: CmmExpr -> CmmExpr -> FCode ()
staticProfHdr :: CostCentreStack -> [CmmLit]
initUpdFrameProf :: CmmExpr -> FCode ()
enterCostCentreThunk :: CmmExpr -> FCode ()
costCentreFrom :: CmmExpr -> CmmExpr
curCCS :: CmmExpr
storeCurCCS :: CmmExpr -> CmmAGraph
emitSetCCC :: CostCentre -> Bool -> Bool -> FCode ()
saveCurrentCostCentre :: FCode (Maybe LocalReg)
restoreCurrentCostCentre :: Maybe LocalReg -> FCode ()
ldvEnter :: CmmExpr -> FCode ()
ldvEnterClosure :: ClosureInfo -> FCode ()
ldvRecordCreate :: CmmExpr -> FCode ()

module StgCmmHpc
initHpc :: Module -> HpcInfo -> FCode ()
mkTickBox :: Module -> Int -> CmmAGraph

module StgCmmGran
staticGranHdr :: [CmmLit]
staticParHdr :: [CmmLit]
granThunk :: Bool -> FCode ()
granYield :: [LocalReg] -> Bool -> FCode ()
doGranAllocate :: VirtualHpOffset -> FCode ()

module StgCmmEnv
data CgIdInfo
cgIdInfoId :: CgIdInfo -> Id
cgIdInfoLF :: CgIdInfo -> LambdaFormInfo
litIdInfo :: Id -> LambdaFormInfo -> CmmLit -> CgIdInfo
lneIdInfo :: Id -> [LocalReg] -> CgIdInfo
regIdInfo :: Id -> LambdaFormInfo -> LocalReg -> CmmAGraph -> FCode (CgIdInfo, CmmAGraph)
idInfoToAmode :: CgIdInfo -> CmmExpr
newtype NonVoid a
NonVoid :: a -> NonVoid a
isVoidId :: Id -> Bool
nonVoidIds :: [Id] -> [NonVoid Id]
addBindC :: Id -> CgIdInfo -> FCode ()
addBindsC :: [CgIdInfo] -> FCode ()
bindArgsToRegs :: [NonVoid Id] -> FCode [LocalReg]
bindToReg :: NonVoid Id -> LambdaFormInfo -> FCode LocalReg
rebindToReg :: NonVoid Id -> FCode LocalReg
bindArgToReg :: NonVoid Id -> FCode LocalReg
idToReg :: NonVoid Id -> LocalReg
getArgAmode :: NonVoid StgArg -> FCode CmmExpr
getNonVoidArgAmodes :: [StgArg] -> FCode [CmmExpr]
getCgIdInfo :: Id -> FCode CgIdInfo
maybeLetNoEscape :: CgIdInfo -> Maybe (BlockId, [LocalReg])
instance Eq a => Eq (NonVoid a)
instance Show a => Show (NonVoid a)
instance Outputable a => Outputable (NonVoid a)

module StgCmmTicky
emitTickyCounter :: ClosureInfo -> [Id] -> FCode ()
tickyDynAlloc :: SMRep -> LambdaFormInfo -> FCode ()
tickyAllocHeap :: VirtualHpOffset -> FCode ()
tickyAllocPrim :: CmmExpr -> CmmExpr -> CmmExpr -> FCode ()
tickyAllocThunk :: CmmExpr -> CmmExpr -> FCode ()
tickyAllocPAP :: CmmExpr -> CmmExpr -> FCode ()
tickySlowCall :: LambdaFormInfo -> [StgArg] -> FCode ()
tickyDirectCall :: RepArity -> [StgArg] -> FCode ()
tickyPushUpdateFrame :: FCode ()
tickyUpdateFrameOmitted :: FCode ()
tickyEnterDynCon :: FCode ()
tickyEnterStaticCon :: FCode ()
tickyEnterViaNode :: FCode ()
tickyEnterFun :: ClosureInfo -> FCode ()
tickyEnterThunk :: ClosureInfo -> FCode ()
tickyUpdateBhCaf :: ClosureInfo -> FCode ()
tickyBlackHole :: Bool -> FCode ()
tickyUnboxedTupleReturn :: RepArity -> FCode ()
tickyVectoredReturn :: Int -> FCode ()
tickyReturnOldCon :: RepArity -> FCode ()
tickyReturnNewCon :: RepArity -> FCode ()
tickyKnownCallTooFewArgs :: FCode ()
tickyKnownCallExact :: FCode ()
tickyKnownCallExtraArgs :: FCode ()
tickyUnknownCall :: FCode ()
tickySlowCallPat :: [PrimRep] -> FCode ()
staticTickyHdr :: [CmmLit]

module StgCmmLayout
mkArgDescr :: Name -> [Id] -> FCode ArgDescr

-- | <tt>emitCall conv fun args</tt> makes a call to the entry-code of
--   <tt>fun</tt>, using the call/return convention <tt>conv</tt>, passing
--   <tt>args</tt>, and returning the results to the current sequel.
emitCall :: (Convention, Convention) -> CmmExpr -> [CmmExpr] -> FCode ()

-- | Return multiple values to the sequel
--   
--   If the sequel is <tt>Return</tt>
--   
--   <pre>
--   return (x,y)
--   </pre>
--   
--   If the sequel is <tt>AssignTo [p,q]</tt>
--   
--   <pre>
--   p=x; q=y;
--   </pre>
emitReturn :: [CmmExpr] -> FCode ()
adjustHpBackwards :: FCode ()
emitClosureProcAndInfoTable :: Bool -> Id -> LambdaFormInfo -> CmmInfoTable -> [NonVoid Id] -> ((Int, LocalReg, [LocalReg]) -> FCode ()) -> FCode ()
emitClosureAndInfoTable :: CmmInfoTable -> Convention -> [LocalReg] -> FCode () -> FCode ()
slowCall :: CmmExpr -> [StgArg] -> FCode ()
directCall :: Convention -> CLabel -> RepArity -> [StgArg] -> FCode ()
mkVirtHeapOffsets :: Bool -> [(PrimRep, a)] -> (WordOff, WordOff, [(NonVoid a, VirtualHpOffset)])
mkVirtConstrOffsets :: [(PrimRep, a)] -> (WordOff, WordOff, [(NonVoid a, VirtualHpOffset)])
getHpRelOffset :: VirtualHpOffset -> FCode CmmExpr
hpRel :: VirtualHpOffset -> VirtualHpOffset -> WordOff
stdInfoTableSizeB :: ByteOff
entryCode :: CmmExpr -> CmmExpr
closureInfoPtr :: CmmExpr -> CmmExpr
getConstrTag :: CmmExpr -> CmmExpr
cmmGetClosureType :: CmmExpr -> CmmExpr
infoTable :: CmmExpr -> CmmExpr
infoTableClosureType :: CmmExpr -> CmmExpr
infoTablePtrs :: CmmExpr -> CmmExpr
infoTableNonPtrs :: CmmExpr -> CmmExpr
funInfoTable :: CmmExpr -> CmmExpr
instance Outputable ArgRep

module StgCmmForeign

-- | emit code for a foreign call, and return the results to the sequel.
cgForeignCall :: ForeignCall -> [StgArg] -> Type -> FCode ()
loadThreadState :: LocalReg -> LocalReg -> CmmAGraph
saveThreadState :: CmmAGraph
emitPrimCall :: [CmmFormal] -> CallishMachOp -> [CmmActual] -> FCode ()
emitCCall :: [(CmmFormal, ForeignHint)] -> CmmExpr -> [(CmmActual, ForeignHint)] -> FCode ()
emitSaveThreadState :: BlockId -> FCode ()
emitLoadThreadState :: LocalReg -> LocalReg -> FCode ()
emitOpenNursery :: FCode ()

module CmmLayoutStack
cmmLayoutStack :: ProcPointSet -> ByteOff -> CmmGraph -> UniqSM (CmmGraph, BlockEnv StackMap)
setInfoTableStackMap :: BlockEnv StackMap -> CmmDecl -> CmmDecl
instance Outputable StackMap
instance Outputable StackSlot

module CmmPipeline

-- | Top level driver for C-- pipeline
cmmPipeline :: HscEnv -> TopSRT -> CmmGroup -> IO (TopSRT, CmmGroup)

module StgCmmHeap
getVirtHp :: FCode VirtualHpOffset
setVirtHp :: VirtualHpOffset -> FCode ()
setRealHp :: VirtualHpOffset -> FCode ()
getHpRelOffset :: VirtualHpOffset -> FCode CmmExpr
hpRel :: VirtualHpOffset -> VirtualHpOffset -> WordOff
entryHeapCheck :: ClosureInfo -> Int -> Maybe LocalReg -> Int -> [LocalReg] -> FCode () -> FCode ()
altHeapCheck :: [LocalReg] -> FCode a -> FCode a
altHeapCheckReturnsTo :: [LocalReg] -> Label -> FCode a -> FCode a
mkVirtHeapOffsets :: Bool -> [(PrimRep, a)] -> (WordOff, WordOff, [(NonVoid a, VirtualHpOffset)])
mkVirtConstrOffsets :: [(PrimRep, a)] -> (WordOff, WordOff, [(NonVoid a, VirtualHpOffset)])
mkStaticClosureFields :: CmmInfoTable -> CostCentreStack -> CafInfo -> [CmmLit] -> [CmmLit]
mkStaticClosure :: CLabel -> CostCentreStack -> [CmmLit] -> [CmmLit] -> [CmmLit] -> [CmmLit] -> [CmmLit]
allocDynClosure :: CmmInfoTable -> LambdaFormInfo -> CmmExpr -> CmmExpr -> [(NonVoid StgArg, VirtualHpOffset)] -> FCode (LocalReg, CmmAGraph)
allocDynClosureCmm :: CmmInfoTable -> LambdaFormInfo -> CmmExpr -> CmmExpr -> [(CmmExpr, VirtualHpOffset)] -> FCode (LocalReg, CmmAGraph)
emitSetDynHdr :: CmmExpr -> CmmExpr -> CmmExpr -> FCode ()

module CoreToStg
coreToStg :: DynFlags -> CoreProgram -> IO [StgBinding]
coreExprToStg :: CoreExpr -> StgExpr
instance MonadFix LneM
instance Monad LneM

module SCCfinal
stgMassageForProfiling :: DynFlags -> Module -> UniqSupply -> [StgBinding] -> (CollectedCCs, [StgBinding])
instance Monad MassageM

module StgLint
lintStgBindings :: String -> [StgBinding] -> [StgBinding]
instance Monad LintM

module StgStats
showStgStats :: [StgBinding] -> String
instance Eq CounterType
instance Ord CounterType

module UnariseStg
unarise :: UniqSupply -> [StgBinding] -> [StgBinding]

module SimplStg
stg2stg :: DynFlags -> Module -> [StgBinding] -> IO ([(StgBinding, [(Id, [Id])])], CollectedCCs)

module CgCon
cgTopRhsCon :: Id -> DataCon -> [StgArg] -> FCode (Id, CgIdInfo)
buildDynCon :: Id -> CostCentreStack -> DataCon -> [(CgRep, CmmExpr)] -> FCode CgIdInfo
bindConArgs :: DataCon -> [Id] -> Code
bindUnboxedTupleComponents :: [Id] -> FCode ([(Id, GlobalReg)], WordOff, WordOff, VirtualSpOffset)
cgReturnDataCon :: DataCon -> [(CgRep, CmmExpr)] -> Code
cgTyCon :: TyCon -> FCode CmmGroup

module CgCase
cgCase :: StgExpr -> StgLiveVars -> StgLiveVars -> Id -> AltType -> [StgAlt] -> Code
saveVolatileVarsAndRegs :: StgLiveVars -> FCode (CmmStmts, EndOfBlockInfo, Maybe VirtualSpOffset)
restoreCurrentCostCentre :: Maybe VirtualSpOffset -> Bool -> Code

module CgLetNoEscape
cgLetNoEscapeClosure :: Id -> CostCentreStack -> StgBinderInfo -> StgLiveVars -> EndOfBlockInfo -> Maybe VirtualSpOffset -> RecFlag -> [Id] -> StgExpr -> FCode (Id, CgIdInfo)

module CgExpr
cgExpr :: StgExpr -> Code

module CodeGen
codeGen :: DynFlags -> Module -> [TyCon] -> CollectedCCs -> [(StgBinding, [(Id, [Id])])] -> HpcInfo -> Stream IO CmmGroup ()

module StgCmmCon
cgTopRhsCon :: Id -> DataCon -> [StgArg] -> FCode CgIdInfo
buildDynCon :: Id -> CostCentreStack -> DataCon -> [StgArg] -> FCode (CgIdInfo, CmmAGraph)
bindConArgs :: AltCon -> LocalReg -> [Id] -> FCode [LocalReg]

module StgCmmPrim
cgOpApp :: StgOp -> [StgArg] -> Type -> FCode ()
cgPrimOp :: [LocalReg] -> PrimOp -> [StgArg] -> FCode ()

module StgCmmExpr
cgExpr :: StgExpr -> FCode ()

module StgCmmBind
cgTopRhsClosure :: Id -> CostCentreStack -> StgBinderInfo -> UpdateFlag -> [Id] -> StgExpr -> FCode CgIdInfo
cgBind :: StgBinding -> FCode ()
emitBlackHoleCode :: Bool -> FCode ()
pushUpdateFrame :: [CmmExpr] -> FCode () -> FCode ()

module StgCmm
codeGen :: DynFlags -> Module -> [TyCon] -> CollectedCCs -> [(StgBinding, [(Id, [Id])])] -> HpcInfo -> Stream IO CmmGroup ()

module Coverage
addTicksToBinds :: DynFlags -> Module -> ModLocation -> NameSet -> [TyCon] -> LHsBinds Id -> IO (LHsBinds Id, HpcInfo, ModBreaks)
hpcInitCode :: Platform -> Module -> HpcInfo -> SDoc
instance Eq TickDensity
instance Monad TM


-- | Binary interface file support.
module BinIface

-- | Write an interface file
writeBinIface :: DynFlags -> FilePath -> ModIface -> IO ()

-- | Read an interface file
readBinIface :: CheckHiWay -> TraceBinIFaceReading -> FilePath -> TcRnIf a b ModIface
getSymtabName :: NameCacheUpdater -> Dictionary -> SymbolTable -> BinHandle -> IO Name
getDictFastString :: Dictionary -> BinHandle -> IO FastString
data CheckHiWay
CheckHiWay :: CheckHiWay
IgnoreHiWay :: CheckHiWay
data TraceBinIFaceReading
TraceBinIFaceReading :: TraceBinIFaceReading
QuietBinIFaceReading :: TraceBinIFaceReading
instance Eq CheckHiWay
instance Eq TraceBinIFaceReading
instance Binary IfaceTrustInfo
instance Binary IfaceVectInfo
instance Binary name => Binary (AnnTarget name)
instance Binary IfaceAnnotation
instance Binary IfaceRule
instance Binary IfaceClassOp
instance Binary IfaceATDefault
instance Binary IfaceAT
instance Binary IfaceConDecl
instance Binary IfaceConDecls
instance Binary OverlapFlag
instance Binary IfaceFamInst
instance Binary IfaceClsInst
instance Binary IfaceDecl
instance Binary IfaceTickish
instance Binary IfaceUnfolding
instance Binary IfaceInfoItem
instance Binary IfaceIdInfo
instance Binary (DFunArg IfaceExpr)
instance Binary IfaceIdDetails
instance Binary IfaceBinding
instance Binary IfaceConAlt
instance Binary IfaceExpr
instance Binary IfaceCoCon
instance Binary IfaceTyCon
instance Binary IfaceTyLit
instance Binary IfaceType
instance Binary IfaceLetBndr
instance Binary IfaceBndr
instance Binary CostCentre
instance Binary IsCafCC
instance Binary StrictSig
instance Binary DmdResult
instance Binary Demands
instance Binary Demand
instance Binary DmdType
instance Binary Fixity
instance Binary FixityDirection
instance Binary DefMethSpec
instance Binary RecFlag
instance Binary TupleSort
instance Binary HsBang
instance Binary InlineSpec
instance Binary InlinePragma
instance Binary RuleMatchInfo
instance Binary Activation
instance Binary WarningTxt
instance Binary Warnings
instance Binary Usage
instance Binary AvailInfo
instance Binary Dependencies
instance Binary ModIface

module LoadIface

-- | Load interface for a module.
loadModuleInterface :: SDoc -> Module -> TcM ModIface

-- | Load interfaces for a collection of modules.
loadModuleInterfaces :: SDoc -> [Module] -> TcM ()

-- | Load the interface corresponding to an <tt>import</tt> directive in
--   source code. On a failure, fail in the monad with an error message.
loadSrcInterface :: SDoc -> ModuleName -> IsBootInterface -> Maybe FastString -> RnM ModIface

-- | Loads the interface for a given Name.
loadInterfaceForName :: SDoc -> Name -> TcRn ModIface
loadInterface :: SDoc -> Module -> WhereFrom -> IfM lcl (MaybeErr MsgDoc ModIface)

-- | An <a>IfM</a> function to load the home interface for a wired-in
--   thing, so that we're sure that we see its instance declarations and
--   rules See Note [Loading instances for wired-in things] in TcIface
loadWiredInHomeIface :: Name -> IfM lcl ()

-- | Loads a system interface and throws an exception if it fails
loadSysInterface :: SDoc -> Module -> IfM lcl ModIface

-- | Loads a user interface and throws an exception if it fails. The first
--   parameter indicates whether we should import the boot variant of the
--   module
loadUserInterface :: Bool -> SDoc -> Module -> IfM lcl ModIface
findAndReadIface :: SDoc -> Module -> IsBootInterface -> TcRnIf gbl lcl (MaybeErr MsgDoc (ModIface, FilePath))
readIface :: Module -> FilePath -> IsBootInterface -> TcRnIf gbl lcl (MaybeErr MsgDoc ModIface)
loadDecls :: Bool -> [(Fingerprint, IfaceDecl)] -> IfL [(Name, TyThing)]
initExternalPackageState :: ExternalPackageState
ifaceStats :: ExternalPackageState -> SDoc
pprModIface :: ModIface -> SDoc

-- | Read binary interface, and print it out
showIface :: HscEnv -> FilePath -> IO ()
instance Outputable Warnings

module TcIface
tcImportDecl :: Name -> TcM TyThing
importDecl :: Name -> IfM lcl (MaybeErr MsgDoc TyThing)
checkWiredInTyCon :: TyCon -> TcM ()
tcHiBootIface :: HscSource -> Module -> TcRn ModDetails
typecheckIface :: ModIface -> TcRnIf gbl lcl ModDetails
tcIfaceDecl :: Bool -> IfaceDecl -> IfL TyThing
tcIfaceInst :: IfaceClsInst -> IfL ClsInst
tcIfaceFamInst :: IfaceFamInst -> IfL FamInst
tcIfaceRules :: Bool -> [IfaceRule] -> IfL [CoreRule]
tcIfaceVectInfo :: Module -> TypeEnv -> IfaceVectInfo -> IfL VectInfo
tcIfaceAnnotations :: [IfaceAnnotation] -> IfL [Annotation]
tcIfaceGlobal :: Name -> IfL TyThing
tcExtCoreBindings :: [IfaceBinding] -> IfL CoreProgram

module DsMonad
type DsM result = TcRnIf DsGblEnv DsLclEnv result

-- | <tt><a>mapM</a> f</tt> is equivalent to <tt><a>sequence</a> .
--   <a>map</a> f</tt>.
mapM :: Monad m => (a -> m b) -> [a] -> m [b]

-- | The <a>mapAndUnzipM</a> function maps its first argument over a list,
--   returning the result as a pair of lists. This function is mainly used
--   with complicated data structures or a state-transforming monad.
mapAndUnzipM :: Monad m => (a -> m (b, c)) -> [a] -> m ([b], [c])
initDs :: HscEnv -> Module -> GlobalRdrEnv -> TypeEnv -> DsM a -> IO (Messages, Maybe a)
initDsTc :: DsM a -> TcM a
fixDs :: (a -> DsM a) -> DsM a

-- | Monadic version of foldl
foldlM :: Monad m => (a -> b -> m a) -> a -> [b] -> m a

-- | Monadic version of foldr
foldrM :: Monad m => (b -> a -> m a) -> a -> [b] -> m a

-- | Do it flag is true
ifDOptM :: DynFlag -> TcRnIf gbl lcl () -> TcRnIf gbl lcl ()
unsetDOptM :: DynFlag -> TcRnIf gbl lcl a -> TcRnIf gbl lcl a
unsetWOptM :: WarningFlag -> TcRnIf gbl lcl a -> TcRnIf gbl lcl a

-- | A functor with application, providing operations to
--   
--   <ul>
--   <li>embed pure expressions (<a>pure</a>), and</li>
--   <li>sequence computations and combine their results
--   (<a>&lt;*&gt;</a>).</li>
--   </ul>
--   
--   A minimal complete definition must include implementations of these
--   functions satisfying the following laws:
--   
--   <ul>
--   <li><i><i>identity</i></i> <tt><a>pure</a> <a>id</a> <a>&lt;*&gt;</a>
--   v = v</tt></li>
--   <li><i><i>composition</i></i> <tt><a>pure</a> (.) <a>&lt;*&gt;</a> u
--   <a>&lt;*&gt;</a> v <a>&lt;*&gt;</a> w = u <a>&lt;*&gt;</a> (v
--   <a>&lt;*&gt;</a> w)</tt></li>
--   <li><i><i>homomorphism</i></i> <tt><a>pure</a> f <a>&lt;*&gt;</a>
--   <a>pure</a> x = <a>pure</a> (f x)</tt></li>
--   <li><i><i>interchange</i></i> <tt>u <a>&lt;*&gt;</a> <a>pure</a> y =
--   <a>pure</a> (<a>$</a> y) <a>&lt;*&gt;</a> u</tt></li>
--   </ul>
--   
--   The other methods have the following default definitions, which may be
--   overridden with equivalent specialized implementations:
--   
--   <pre>
--   u <a>*&gt;</a> v = <a>pure</a> (<a>const</a> <a>id</a>) <a>&lt;*&gt;</a> u <a>&lt;*&gt;</a> v
--   u <a>&lt;*</a> v = <a>pure</a> <a>const</a> <a>&lt;*&gt;</a> u <a>&lt;*&gt;</a> v
--   </pre>
--   
--   As a consequence of these laws, the <a>Functor</a> instance for
--   <tt>f</tt> will satisfy
--   
--   <pre>
--   <a>fmap</a> f x = <a>pure</a> f <a>&lt;*&gt;</a> x
--   </pre>
--   
--   If <tt>f</tt> is also a <a>Monad</a>, it should satisfy
--   <tt><a>pure</a> = <a>return</a></tt> and <tt>(<a>&lt;*&gt;</a>) =
--   <a>ap</a></tt> (which implies that <a>pure</a> and <a>&lt;*&gt;</a>
--   satisfy the applicative functor laws).
class Functor f => Applicative (f :: * -> *)
pure :: Applicative f => a -> f a
(<*>) :: Applicative f => f (a -> b) -> f a -> f b
(*>) :: Applicative f => f a -> f b -> f b
(<*) :: Applicative f => f a -> f b -> f a

-- | An infix synonym for <a>fmap</a>.
(<$>) :: Functor f => (a -> b) -> f a -> f b
newLocalName :: Name -> TcRnIf gbl lcl Name
duplicateLocalDs :: Id -> DsM Id
newSysLocalDs :: Type -> DsM Id
newSysLocalsDs :: [Type] -> DsM [Id]
newUniqueId :: Id -> Type -> DsM Id
newFailLocalDs :: Type -> DsM Id
newPredVarDs :: PredType -> DsM Var
getSrcSpanDs :: DsM SrcSpan
putSrcSpanDs :: SrcSpan -> DsM a -> DsM a
getModuleDs :: DsM Module
mkPrintUnqualifiedDs :: DsM PrintUnqualified
newUnique :: TcRnIf gbl lcl Unique

-- | A value of type <a>UniqSupply</a> is unique, and it can supply
--   <i>one</i> distinct <a>Unique</a>. Also, from the supply, one can also
--   manufacture an arbitrary number of further <tt>UniqueSupply</tt>
--   values, which will be distinct from the first and from all others.
data UniqSupply
newUniqueSupply :: TcRnIf gbl lcl UniqSupply
getGhcModeDs :: DsM GhcMode
dsLookupGlobal :: Name -> DsM TyThing
dsLookupGlobalId :: Name -> DsM Id

-- | Get a name from <a>Data.Array.Parallel</a> for the desugarer, from the
--   <a>ds_parr_bi</a> component of the global desugerar environment.
dsDPHBuiltin :: (PArrBuiltin -> a) -> DsM a
dsLookupTyCon :: Name -> DsM TyCon
dsLookupDataCon :: Name -> DsM DataCon
data PArrBuiltin
PArrBuiltin :: Var -> Var -> Var -> Var -> Var -> Var -> Var -> Var -> Var -> Var -> Var -> Var -> PArrBuiltin

-- | lengthP
lengthPVar :: PArrBuiltin -> Var

-- | replicateP
replicatePVar :: PArrBuiltin -> Var

-- | singletonP
singletonPVar :: PArrBuiltin -> Var

-- | mapP
mapPVar :: PArrBuiltin -> Var

-- | filterP
filterPVar :: PArrBuiltin -> Var

-- | zipP
zipPVar :: PArrBuiltin -> Var

-- | crossMapP
crossMapPVar :: PArrBuiltin -> Var

-- | (!:)
indexPVar :: PArrBuiltin -> Var

-- | emptyP
emptyPVar :: PArrBuiltin -> Var

-- | (+:+)
appPVar :: PArrBuiltin -> Var

-- | enumFromToP
enumFromToPVar :: PArrBuiltin -> Var

-- | enumFromThenToP
enumFromThenToPVar :: PArrBuiltin -> Var

-- | Lookup a name exported by <a>Prim</a> or <a>Prim</a>. Panic if there
--   isn't one, or if it is defined multiple times.
dsLookupDPHRdrEnv :: OccName -> DsM Name

-- | Lookup a name exported by <a>Prim</a> or <a>Prim</a>, returning
--   <a>Nothing</a> if it's not defined. Panic if it's defined multiple
--   times.
dsLookupDPHRdrEnv_maybe :: OccName -> DsM (Maybe Name)
dsInitPArrBuiltin :: DsM a -> DsM a
type DsMetaEnv = NameEnv DsMetaVal
data DsMetaVal
Bound :: Id -> DsMetaVal
Splice :: (HsExpr Id) -> DsMetaVal
dsGetMetaEnv :: DsM (NameEnv DsMetaVal)
dsLookupMetaEnv :: Name -> DsM (Maybe DsMetaVal)
dsExtendMetaEnv :: DsMetaEnv -> DsM a -> DsM a
type DsWarning = (SrcSpan, SDoc)
warnDs :: SDoc -> DsM ()
failWithDs :: SDoc -> DsM a
data DsMatchContext
DsMatchContext :: (HsMatchContext Name) -> SrcSpan -> DsMatchContext
data EquationInfo
EqnInfo :: [Pat Id] -> MatchResult -> EquationInfo
eqn_pats :: EquationInfo -> [Pat Id]
eqn_rhs :: EquationInfo -> MatchResult
data MatchResult
MatchResult :: CanItFail -> (CoreExpr -> DsM CoreExpr) -> MatchResult
type DsWrapper = CoreExpr -> CoreExpr
idDsWrapper :: DsWrapper
data CanItFail
CanFail :: CanItFail
CantFail :: CanItFail
orFail :: CanItFail -> CanItFail -> CanItFail
instance MonadThings (IOEnv (Env DsGblEnv DsLclEnv))
instance Outputable EquationInfo


-- | Utility functions for constructing Core syntax, principally for
--   desugaring
module DsUtils
data EquationInfo
EqnInfo :: [Pat Id] -> MatchResult -> EquationInfo
eqn_pats :: EquationInfo -> [Pat Id]
eqn_rhs :: EquationInfo -> MatchResult
firstPat :: EquationInfo -> Pat Id
shiftEqns :: [EquationInfo] -> [EquationInfo]
data MatchResult
MatchResult :: CanItFail -> (CoreExpr -> DsM CoreExpr) -> MatchResult
data CanItFail
CanFail :: CanItFail
CantFail :: CanItFail
cantFailMatchResult :: CoreExpr -> MatchResult
alwaysFailMatchResult :: MatchResult
extractMatchResult :: MatchResult -> CoreExpr -> DsM CoreExpr
combineMatchResults :: MatchResult -> MatchResult -> MatchResult
adjustMatchResult :: DsWrapper -> MatchResult -> MatchResult
adjustMatchResultDs :: (CoreExpr -> DsM CoreExpr) -> MatchResult -> MatchResult
mkCoLetMatchResult :: CoreBind -> MatchResult -> MatchResult
mkViewMatchResult :: Id -> CoreExpr -> Id -> MatchResult -> MatchResult
mkGuardedMatchResult :: CoreExpr -> MatchResult -> MatchResult
matchCanFail :: MatchResult -> Bool
mkEvalMatchResult :: Id -> Type -> MatchResult -> MatchResult
mkCoPrimCaseMatchResult :: Id -> Type -> [(Literal, MatchResult)] -> MatchResult
mkCoAlgCaseMatchResult :: Id -> Type -> [(DataCon, [CoreBndr], MatchResult)] -> MatchResult
wrapBind :: Var -> Var -> CoreExpr -> CoreExpr
wrapBinds :: [(Var, Var)] -> CoreExpr -> CoreExpr
mkErrorAppDs :: Id -> Type -> SDoc -> DsM CoreExpr
mkCoreAppDs :: CoreExpr -> CoreExpr -> CoreExpr
mkCoreAppsDs :: CoreExpr -> [CoreExpr] -> CoreExpr
seqVar :: Var -> CoreExpr -> CoreExpr
mkLHsVarPatTup :: [Id] -> LPat Id
mkLHsPatTup :: [LPat Id] -> LPat Id
mkVanillaTuplePat :: [OutPat Id] -> Boxity -> Pat Id
mkBigLHsVarTup :: [Id] -> LHsExpr Id
mkBigLHsTup :: [LHsExpr Id] -> LHsExpr Id
mkBigLHsVarPatTup :: [Id] -> LPat Id
mkBigLHsPatTup :: [LPat Id] -> LPat Id
mkSelectorBinds :: [Maybe (Tickish Id)] -> LPat Id -> CoreExpr -> DsM [(Id, CoreExpr)]
dsSyntaxTable :: SyntaxTable Id -> DsM ([CoreBind], [(Name, Id)])
lookupEvidence :: [(Name, Id)] -> Name -> Id
selectSimpleMatchVarL :: LPat Id -> DsM Id
selectMatchVars :: [Pat Id] -> DsM [Id]
selectMatchVar :: Pat Id -> DsM Id
mkOptTickBox :: Maybe (Tickish Id) -> CoreExpr -> CoreExpr
mkBinaryTickBox :: Int -> Int -> CoreExpr -> DsM CoreExpr

module MatchLit
dsLit :: HsLit -> DsM CoreExpr
dsOverLit :: HsOverLit Id -> DsM CoreExpr
hsLitKey :: HsLit -> Literal
hsOverLitKey :: OutputableBndr a => HsOverLit a -> Bool -> Literal
tidyLitPat :: HsLit -> Pat Id
tidyNPat :: (HsLit -> Pat Id) -> HsOverLit Id -> Maybe (SyntaxExpr Id) -> SyntaxExpr Id -> Pat Id
matchLiterals :: [Id] -> Type -> [[EquationInfo]] -> DsM MatchResult
matchNPlusKPats :: [Id] -> Type -> [EquationInfo] -> DsM MatchResult
matchNPats :: [Id] -> Type -> [EquationInfo] -> DsM MatchResult

module DsMeta
dsBracket :: HsBracket Name -> [PendingSplice] -> DsM CoreExpr
templateHaskellNames :: [Name]
qTyConName :: Name
nameTyConName :: Name
liftName :: Name
liftStringName :: Name
expQTyConName :: Name
patQTyConName :: Name
decQTyConName :: Name
decsQTyConName :: Name
typeQTyConName :: Name
decTyConName :: Name
typeTyConName :: Name
mkNameG_dName :: Name
mkNameG_vName :: Name
mkNameG_tcName :: Name
quoteExpName :: Name
quotePatName :: Name
quoteDecName :: Name
quoteTypeName :: Name

module Check
check :: [EquationInfo] -> ([ExhaustivePat], [EquationInfo])
type ExhaustivePat = ([WarningPat], [(Name, [HsLit])])

module DsGRHSs
dsGuarded :: GRHSs Id -> Type -> DsM CoreExpr
dsGRHSs :: HsMatchContext Name -> [Pat Id] -> GRHSs Id -> Type -> DsM MatchResult
dsGRHS :: HsMatchContext Name -> Type -> LGRHS Id -> DsM MatchResult

module DsBinds
dsTopLHsBinds :: LHsBinds Id -> DsM (OrdList (Id, CoreExpr))
dsLHsBinds :: LHsBinds Id -> DsM [(Id, CoreExpr)]
decomposeRuleLhs :: [Var] -> CoreExpr -> Either SDoc ([Var], Id, [CoreExpr])
dsSpec :: Maybe CoreExpr -> Located TcSpecPrag -> DsM (Maybe (OrdList (Id, CoreExpr), CoreRule))
dsHsWrapper :: HsWrapper -> CoreExpr -> DsM CoreExpr
dsTcEvBinds :: TcEvBinds -> DsM [CoreBind]
dsEvBinds :: Bag EvBind -> DsM [CoreBind]

module DsCCall
dsCCall :: CLabelString -> [CoreExpr] -> Safety -> Type -> DsM CoreExpr
mkFCall :: DynFlags -> Unique -> ForeignCall -> [CoreExpr] -> Type -> CoreExpr
unboxArg :: CoreExpr -> DsM (CoreExpr, CoreExpr -> CoreExpr)
boxResult :: Type -> DsM (Type, CoreExpr -> CoreExpr)
resultWrapper :: Type -> DsM (Maybe Type, CoreExpr -> CoreExpr)

module DsForeign
dsForeigns :: [LForeignDecl Id] -> DsM (ForeignStubs, OrdList Binding)

module MatchCon
matchConFamily :: [Id] -> Type -> [[EquationInfo]] -> DsM MatchResult

module Match
match :: [Id] -> Type -> [EquationInfo] -> DsM MatchResult
matchEquations :: HsMatchContext Name -> [Id] -> [EquationInfo] -> Type -> DsM CoreExpr
matchWrapper :: HsMatchContext Name -> MatchGroup Id -> DsM ([Id], CoreExpr)
matchSimply :: CoreExpr -> HsMatchContext Name -> LPat Id -> CoreExpr -> CoreExpr -> DsM CoreExpr
matchSinglePat :: CoreExpr -> HsMatchContext Name -> LPat Id -> Type -> MatchResult -> DsM MatchResult

module DsArrows
dsProcExpr :: LPat Id -> LHsCmdTop Id -> DsM CoreExpr

module DsListComp
dsListComp :: [LStmt Id] -> Type -> DsM CoreExpr
dsPArrComp :: [Stmt Id] -> DsM CoreExpr
dsMonadComp :: [LStmt Id] -> DsM CoreExpr

module DsExpr
dsExpr :: HsExpr Id -> DsM CoreExpr
dsLExpr :: LHsExpr Id -> DsM CoreExpr
dsLocalBinds :: HsLocalBinds Id -> CoreExpr -> DsM CoreExpr
dsValBinds :: HsValBinds Id -> CoreExpr -> DsM CoreExpr
dsLit :: HsLit -> DsM CoreExpr

module Vectorise.Builtins.Initialise

-- | Create the initial map of builtin types and functions.
initBuiltins :: DsM Builtins

-- | Get the mapping of names in the Prelude to names in the DPH library.
initBuiltinVars :: Builtins -> DsM [(Var, Var)]

module Vectorise.Builtins
mAX_DPH_SCALAR_ARGS :: Int

-- | Holds the names of the types and functions from <a>Prim</a> that are
--   used by the vectoriser.
data Builtins
Builtins :: TyCon -> TyCon -> Class -> TyCon -> TyCon -> Class -> TyCon -> DataCon -> Var -> Var -> NameEnv Var -> Var -> NameEnv Var -> Var -> NameEnv Var -> Array Int Var -> Array Int (NameEnv Var) -> Class -> Array Int Var -> TyCon -> Var -> Var -> Array Int TyCon -> TyCon -> Var -> Var -> TyCon -> Var -> Var -> Var -> Var -> Array Int Var -> Array Int Type -> Array Int Type -> Array Int CoreExpr -> Array Int CoreExpr -> Array Int CoreExpr -> Array (Int, Int) CoreExpr -> Var -> Builtins

-- | PData
pdataTyCon :: Builtins -> TyCon

-- | PDatas
pdatasTyCon :: Builtins -> TyCon

-- | PR
prClass :: Builtins -> Class

-- | PR
prTyCon :: Builtins -> TyCon

-- | PRepr
preprTyCon :: Builtins -> TyCon

-- | PA
paClass :: Builtins -> Class

-- | PA
paTyCon :: Builtins -> TyCon

-- | PA
paDataCon :: Builtins -> DataCon

-- | PA
paPRSel :: Builtins -> Var

-- | replicatePD
replicatePDVar :: Builtins -> Var

-- | replicatePD_Int# etc.
replicatePD_PrimVars :: Builtins -> NameEnv Var

-- | emptyPD
emptyPDVar :: Builtins -> Var

-- | emptyPD_Int# etc.
emptyPD_PrimVars :: Builtins -> NameEnv Var

-- | packByTagPD
packByTagPDVar :: Builtins -> Var

-- | packByTagPD_Int# etc.
packByTagPD_PrimVars :: Builtins -> NameEnv Var

-- | combinePD
combinePDVars :: Builtins -> Array Int Var

-- | combine2PD_Int# etc.
combinePD_PrimVarss :: Builtins -> Array Int (NameEnv Var)

-- | Scalar
scalarClass :: Builtins -> Class

-- | map, zipWith, zipWith3
scalarZips :: Builtins -> Array Int Var

-- | Void
voidTyCon :: Builtins -> TyCon

-- | void
voidVar :: Builtins -> Var

-- | fromVoid
fromVoidVar :: Builtins -> Var

-- | Sum2 .. Sum3
sumTyCons :: Builtins -> Array Int TyCon

-- | Wrap
wrapTyCon :: Builtins -> TyCon

-- | pvoid
pvoidVar :: Builtins -> Var

-- | pvoids
pvoidsVar :: Builtins -> Var

-- | :-&gt;
closureTyCon :: Builtins -> TyCon

-- | closure
closureVar :: Builtins -> Var

-- | liftedClosure
liftedClosureVar :: Builtins -> Var

-- | $:
applyVar :: Builtins -> Var

-- | liftedApply
liftedApplyVar :: Builtins -> Var

-- | closure1 .. closure3
closureCtrFuns :: Builtins -> Array Int Var

-- | Sel2
selTys :: Builtins -> Array Int Type

-- | Sels2
selsTys :: Builtins -> Array Int Type

-- | lengthSels2
selsLengths :: Builtins -> Array Int CoreExpr

-- | replicate2
selReplicates :: Builtins -> Array Int CoreExpr

-- | tagsSel2
selTagss :: Builtins -> Array Int CoreExpr

-- | elementsSel2_0 .. elementsSel_2_1
selElementss :: Builtins -> Array (Int, Int) CoreExpr

-- | lc
liftingContext :: Builtins -> Var
selTy :: Int -> Builtins -> Type
selsTy :: Int -> Builtins -> Type
selReplicate :: Int -> Builtins -> CoreExpr
selTags :: Int -> Builtins -> CoreExpr
selElements :: Int -> Int -> Builtins -> CoreExpr
selsLength :: Int -> Builtins -> CoreExpr
sumTyCon :: Int -> Builtins -> TyCon
prodTyCon :: Int -> Builtins -> TyCon
prodDataCon :: Int -> Builtins -> DataCon
replicatePD_PrimVar :: TyCon -> Builtins -> Var
emptyPD_PrimVar :: TyCon -> Builtins -> Var
packByTagPD_PrimVar :: TyCon -> Builtins -> Var
combinePDVar :: Int -> Builtins -> Var
combinePD_PrimVar :: Int -> TyCon -> Builtins -> Var
scalarZip :: Int -> Builtins -> Var
closureCtrFun :: Int -> Builtins -> Var

-- | Create the initial map of builtin types and functions.
initBuiltins :: DsM Builtins

-- | Get the mapping of names in the Prelude to names in the DPH library.
initBuiltinVars :: Builtins -> DsM [(Var, Var)]


-- | The Vectorisation monad.
module Vectorise.Monad.Base

-- | Vectorisation can either succeed with new envionment and a value, or
--   return with failure (including a description of the reason for
--   failure).
data VResult a
Yes :: GlobalEnv -> LocalEnv -> a -> VResult a
No :: SDoc -> VResult a
newtype VM a
VM :: (Builtins -> GlobalEnv -> LocalEnv -> DsM (VResult a)) -> VM a
runVM :: VM a -> Builtins -> GlobalEnv -> LocalEnv -> DsM (VResult a)

-- | Lift a desugaring computation into the vectorisation monad.
liftDs :: DsM a -> VM a

-- | Throw a <a>pgmError</a> saying we can't vectorise something.
cantVectorise :: DynFlags -> String -> SDoc -> a

-- | Like <tt>fromJust</tt>, but <a>pgmError</a> on Nothing.
maybeCantVectorise :: DynFlags -> String -> SDoc -> Maybe a -> a

-- | Like <a>maybeCantVectorise</a> but in a <a>Monad</a>.
maybeCantVectoriseM :: (Monad m, HasDynFlags m) => String -> SDoc -> m (Maybe a) -> m a

-- | Output a trace message if -ddump-vt-trace is active.
emitVt :: String -> SDoc -> VM ()

-- | Output a trace message if -ddump-vt-trace is active.
traceVt :: String -> SDoc -> VM ()

-- | Dump the given program conditionally.
dumpOptVt :: DynFlag -> String -> SDoc -> VM ()

-- | Dump the given program unconditionally.
dumpVt :: String -> SDoc -> VM ()

-- | Return some result saying we've failed.
noV :: SDoc -> VM a

-- | Like <a>traceNoV</a> but also emit some trace message to stderr.
traceNoV :: String -> SDoc -> VM a

-- | If <a>True</a> then carry on, otherwise fail.
ensureV :: SDoc -> Bool -> VM ()

-- | Like <a>ensureV</a> but if we fail then emit some trace message to
--   stderr.
traceEnsureV :: String -> SDoc -> Bool -> VM ()

-- | If <a>True</a> then return the first argument, otherwise fail.
onlyIfV :: SDoc -> Bool -> VM a -> VM a

-- | Try some vectorisation computaton.
--   
--   If it succeeds then return <a>Just</a> the result; otherwise, return
--   <a>Nothing</a> without emitting a failure message.
tryV :: VM a -> VM (Maybe a)

-- | Try some vectorisation computaton.
--   
--   If it succeeds then return <a>Just</a> the result; otherwise, return
--   <a>Nothing</a> after emitting a failure message.
tryErrV :: VM a -> VM (Maybe a)

-- | If <a>Just</a> then return the value, otherwise fail.
maybeV :: SDoc -> VM (Maybe a) -> VM a

-- | Like <a>maybeV</a> but emit a message to stderr if we fail.
traceMaybeV :: String -> SDoc -> VM (Maybe a) -> VM a

-- | Try the first computation,
--   
--   <ul>
--   <li>if it succeeds then take the returned value, * if it fails then
--   run the second computation instead without emitting a failure
--   message.</li>
--   </ul>
orElseV :: VM a -> VM a -> VM a

-- | Try the first computation,
--   
--   <ul>
--   <li>if it succeeds then take the returned value, * if it fails then
--   run the second computation instead while emitting a failure
--   message.</li>
--   </ul>
orElseErrV :: VM a -> VM a -> VM a

-- | Fixpoint in the vectorisation monad.
fixV :: (a -> VM a) -> VM a
instance HasDynFlags VM
instance MonadIO VM
instance Functor VM
instance Applicative VM
instance Monad VM

module Vectorise.Monad.Local

-- | Project something from the local environment.
readLEnv :: (LocalEnv -> a) -> VM a

-- | Set the local environment.
setLEnv :: LocalEnv -> VM ()

-- | Update the enviroment using the provided function.
updLEnv :: (LocalEnv -> LocalEnv) -> VM ()

-- | Perform a computation in its own local environment. This does not
--   alter the environment of the current state.
localV :: VM a -> VM a

-- | Perform a computation in an empty local environment.
closedV :: VM a -> VM a

-- | Get the name of the local binding currently being vectorised.
getBindName :: VM FastString

-- | Run a vectorisation computation in a local environment, with this id
--   set as the current binding.
inBind :: Id -> VM a -> VM a

-- | Lookup a PA tyvars from the local environment.
lookupTyVarPA :: Var -> VM (Maybe CoreExpr)

-- | Add a tyvar to the local environment.
defLocalTyVar :: TyVar -> VM ()

-- | Add mapping between a tyvar and pa dictionary to the local
--   environment.
defLocalTyVarWithPA :: TyVar -> CoreExpr -> VM ()

-- | Get the set of tyvars from the local environment.
localTyVars :: VM [TyVar]

module Vectorise.Monad.Global

-- | Project something from the global environment.
readGEnv :: (GlobalEnv -> a) -> VM a

-- | Set the value of the global environment.
setGEnv :: GlobalEnv -> VM ()

-- | Update the global environment using the provided function.
updGEnv :: (GlobalEnv -> GlobalEnv) -> VM ()

-- | Add a mapping between a global var and its vectorised version to the
--   state.
defGlobalVar :: Var -> Var -> VM ()

-- | Check whether a variable has a (non-scalar) vectorisation declaration.
lookupVectDecl :: Var -> VM (Maybe (Type, CoreExpr))

-- | Check whether a variable has a <tt>NOVECTORISE</tt> declaration.
noVectDecl :: Var -> VM Bool

-- | Get the set of global scalar variables.
globalScalarVars :: VM VarSet

-- | Check whether a given variable is in the set of global scalar
--   variables.
isGlobalScalarVar :: Var -> VM Bool

-- | Get the set of global scalar type constructors including both those
--   scalar type constructors declared in an imported module and those
--   declared in the current module.
globalScalarTyCons :: VM NameSet

-- | Lookup the vectorised version of a <a>TyCon</a> from the global
--   environment.
lookupTyCon :: TyCon -> VM (Maybe TyCon)

-- | Add a mapping between plain and vectorised <a>TyCon</a>s to the global
--   environment.
--   
--   The second argument is only to enable tracing for (mutually)
--   recursively defined type constructors, where we <i>must not</i> pull
--   at the vectorised type constructors (because that would pull too early
--   at the recursive knot).
defTyConName :: TyCon -> Name -> TyCon -> VM ()

-- | Add a mapping between plain and vectorised <a>TyCon</a>s to the global
--   environment.
defTyCon :: TyCon -> TyCon -> VM ()

-- | Get the set of all vectorised type constructors.
globalVectTyCons :: VM (NameEnv TyCon)

-- | Lookup the vectorised version of a <a>DataCon</a> from the global
--   environment.
lookupDataCon :: DataCon -> VM (Maybe DataCon)

-- | Add the mapping between plain and vectorised <a>DataCon</a>s to the
--   global environment.
defDataCon :: DataCon -> DataCon -> VM ()

-- | Lookup the <tt>PA</tt> dfun of a vectorised type constructor in the
--   global environment.
lookupTyConPA :: TyCon -> VM (Maybe Var)

-- | Associate vectorised type constructors with the dfun of their
--   <tt>PA</tt> instances in the global environment.
defTyConPAs :: [(TyCon, Var)] -> VM ()
lookupTyConPR :: TyCon -> VM (Maybe Var)

module Vectorise.Monad.InstEnv
lookupInst :: Class -> [Type] -> VM (DFunId, [Type])
lookupFamInst :: TyCon -> [Type] -> VM (FamInst, [Type])


-- | Computations in the vectorisation monad concerned with naming and
--   fresh variable generation.
module Vectorise.Monad.Naming

-- | Create a localised variant of a name, using the provided function to
--   transform its <a>OccName</a>.
--   
--   If the name external, encode the orignal name's module into the new
--   <a>OccName</a>. The result is always an internal system name.
mkLocalisedName :: (Maybe String -> OccName -> OccName) -> Name -> VM Name
mkDerivedName :: (OccName -> OccName) -> Name -> VM Name

-- | Produce the vectorised variant of an <a>Id</a> with the given
--   vectorised type, while taking care that vectorised dfun ids must be
--   dfuns again.
--   
--   Force the new name to be a system name and, if the original was an
--   external name, disambiguate the new name with the module name of the
--   original.
mkVectId :: Id -> Type -> VM Id

-- | Make a fresh instance of this var, with a new unique.
cloneVar :: Var -> VM Var

-- | Make a fresh exported variable with the given type.
newExportedVar :: OccName -> Type -> VM Var

-- | Make a fresh local variable with the given type. The variable's name
--   is formed using the given string as the prefix.
newLocalVar :: FastString -> Type -> VM Var

-- | Make several fresh local variables with the given types. The
--   variable's names are formed using the given string as the prefix.
newLocalVars :: FastString -> [Type] -> VM [Var]

-- | Make a new local dummy variable.
newDummyVar :: Type -> VM Var

-- | Make a fresh type variable with the given kind. The variable's name is
--   formed using the given string as the prefix.
newTyVar :: FastString -> Kind -> VM Var

module Vectorise.Monad

-- | Run a vectorisation computation.
initV :: HscEnv -> ModGuts -> VectInfo -> VM a -> IO (Maybe (VectInfo, a))

-- | Lift a desugaring computation using the <a>Builtins</a> into the
--   vectorisation monad.
liftBuiltinDs :: (Builtins -> DsM a) -> VM a

-- | Project something from the set of builtins.
builtin :: (Builtins -> a) -> VM a

-- | Lift a function using the <a>Builtins</a> into the vectorisation
--   monad.
builtins :: (a -> Builtins -> b) -> VM (a -> b)

-- | Lookup the vectorised, and if local, also the lifted version of a
--   variable.
--   
--   <ul>
--   <li>If it's in the global environment we get the vectorised version. *
--   If it's in the local environment we get both the vectorised and lifted
--   version.</li>
--   </ul>
lookupVar :: Var -> VM (Scope Var (Var, Var))
lookupVar_maybe :: Var -> VM (Maybe (Scope Var (Var, Var)))

-- | Mark the given variable as scalar — i.e., executing the associated
--   code does not involve any parallel array computations.
addGlobalScalarVar :: Var -> VM ()

-- | Mark the given type constructor as scalar — i.e., its values cannot
--   embed parallel arrays.
addGlobalScalarTyCon :: TyCon -> VM ()

module Vectorise.Utils.Base
voidType :: VM Type
newLocalVVar :: FastString -> Type -> VM VVar
mkDataConTag :: DataCon -> CoreExpr
dataConTagZ :: DataCon -> Int

-- | Make an application of the <tt>Wrap</tt> type constructor.
mkWrapType :: Type -> VM Type

-- | Make an application of the closure type constructor.
mkClosureTypes :: [Type] -> Type -> VM Type

-- | Make an application of the <tt>PRepr</tt> type constructor.
mkPReprType :: Type -> VM Type

-- | Make an appliction of the <tt>PData</tt> tycon to some argument.
mkPDataType :: Type -> VM Type

-- | Make an application of the <tt>PDatas</tt> tycon to some argument.
mkPDatasType :: Type -> VM Type

-- | Checks if a type constructor is defined in <a>Prim</a> (e.g.,
--   <tt>Int#</tt>); if so, returns it.
splitPrimTyCon :: Type -> Maybe TyCon

-- | Make a coersion to some builtin type.
mkBuiltinCo :: (Builtins -> TyCon) -> VM Coercion

-- | Apply the constructor wrapper of the <tt>Wrap</tt> <i>newtype</i>.
wrapNewTypeBodyOfWrap :: CoreExpr -> Type -> VM CoreExpr

-- | Strip the constructor wrapper of the <tt>Wrap</tt> <i>newtype</i>.
unwrapNewTypeBodyOfWrap :: CoreExpr -> Type -> VM CoreExpr

-- | Apply the constructor wrapper of the <tt>PData</tt> <i>newtype</i>
--   instance of <tt>Wrap</tt>.
wrapNewTypeBodyOfPDataWrap :: CoreExpr -> Type -> VM CoreExpr

-- | Strip the constructor wrapper of the <tt>PData</tt> <i>newtype</i>
--   instance of <tt>Wrap</tt>.
unwrapNewTypeBodyOfPDataWrap :: CoreExpr -> Type -> VM CoreExpr

-- | Apply the constructor wrapper of the <tt>PDatas</tt> <i>newtype</i>
--   instance of <tt>Wrap</tt>.
wrapNewTypeBodyOfPDatasWrap :: CoreExpr -> Type -> VM CoreExpr

-- | Strip the constructor wrapper of the <tt>PDatas</tt> <i>newtype</i>
--   instance of <tt>Wrap</tt>.
unwrapNewTypeBodyOfPDatasWrap :: CoreExpr -> Type -> VM CoreExpr

-- | Get the representation tycon of the <tt>PData</tt> data family for a
--   given type.
--   
--   This tycon does not appear explicitly in the source program — see Note
--   [PData TyCons] in <a>Description</a>:
--   
--   <pre>
--   pdataReprTyCon {Sum2} = {PDataSum2}
--   </pre>
--   
--   The type for which we look up a <tt>PData</tt> instance may be more
--   specific than the type in the instance declaration. In that case the
--   second component of the result will be more specific than a set of
--   distinct type variables.
pdataReprTyCon :: Type -> VM (TyCon, [Type])

-- | Get the representation tycon of the <tt>PData</tt> data family for a
--   given type constructor.
--   
--   For example, for a binary type constructor <tt>T</tt>, we determine
--   the representation type constructor for 'PData (T a b)'.
pdataReprTyConExact :: TyCon -> VM TyCon

-- | Get the representation tycon of the <tt>PDatas</tt> data family for a
--   given type constructor.
--   
--   For example, for a binary type constructor <tt>T</tt>, we determine
--   the representation type constructor for 'PDatas (T a b)'.
pdatasReprTyConExact :: TyCon -> VM TyCon

-- | Unwrap a <tt>PData</tt> representation scrutinee.
pdataUnwrapScrut :: VExpr -> VM (CoreExpr, CoreExpr, DataCon)

-- | Get the representation tycon of the <tt>PRepr</tt> type family for a
--   given type.
preprSynTyCon :: Type -> VM (FamInst, [Type])

module Vectorise.Utils.PADict

-- | Construct the PA argument type for the tyvar. For the tyvar (v :: *)
--   it's just PA v. For (v :: (* -&gt; *) -&gt; *) it's
--   
--   <pre>
--   forall (a :: * -&gt; *). (forall (b :: *). PA b -&gt; PA (a b)) -&gt; PA (v a)
--   </pre>
paDictArgType :: TyVar -> VM (Maybe Type)

-- | Get the PA dictionary for some type
paDictOfType :: Type -> VM CoreExpr

-- | Produce code that refers to a method of the <tt>PA</tt> class.
paMethod :: (Builtins -> Var) -> (TyCon -> Builtins -> Var) -> Type -> VM CoreExpr

-- | Get the PR dictionary for a type. The argument must be a
--   representation type.
prDictOfReprType :: Type -> VM CoreExpr

-- | Given a type <tt>ty</tt>, its PRepr synonym tycon and its type
--   arguments, return the PR <tt>PRepr ty</tt>. Suppose we have:
--   
--   <pre>
--   type instance PRepr (T a1 ... an) = t
--   </pre>
--   
--   which is internally translated into
--   
--   <pre>
--   type :R:PRepr a1 ... an = t
--   </pre>
--   
--   and the corresponding coercion. Then,
--   
--   <pre>
--   prDictOfPReprInstTyCon (T a1 ... an) :R:PRepr u1 ... un = PR (T u1 ... un)
--   </pre>
--   
--   Note that <tt>ty</tt> is only used for error messages
prDictOfPReprInstTyCon :: Type -> CoAxiom -> [Type] -> VM CoreExpr


-- | Auxiliary functions to vectorise type abstractions.
module Vectorise.Utils.Poly

-- | Vectorise under the <tt>PA</tt> dictionary variables corresponding to
--   a set of type arguments.
--   
--   The dictionary variables are new local variables that are entered into
--   the local vectorisation map.
--   
--   The purpose of this function is to introduce the additional
--   <tt>PA</tt> dictionary arguments that are needed when vectorising type
--   abstractions.
polyAbstract :: [TyVar] -> ([Var] -> VM a) -> VM a

-- | Apply a expression to its type arguments as well as <tt>PA</tt>
--   dictionaries for these type arguments.
polyApply :: CoreExpr -> [Type] -> VM CoreExpr

-- | Apply a vectorised expression to a set of type arguments together with
--   <tt>PA</tt> dictionaries for these type arguments.
polyVApply :: VExpr -> [Type] -> VM VExpr

-- | Determine the number of <tt>PA</tt> dictionary arguments required for
--   a set of type variables (depends on their kinds).
polyArity :: [TyVar] -> VM Int

module Vectorise.Utils.Hoisting

-- | Records whether we should inline a particular binding.
data Inline
Inline :: Arity -> Inline
DontInline :: Inline

-- | Add to the arity contained within an <a>Inline</a>, if any.
addInlineArity :: Inline -> Int -> Inline

-- | Says to always inline a binding.
inlineMe :: Inline
hoistBinding :: Var -> CoreExpr -> VM ()
hoistExpr :: FastString -> CoreExpr -> Inline -> VM Var
hoistVExpr :: VExpr -> Inline -> VM VVar

-- | Hoist a polymorphic vectorised expression into a new top-level binding
--   (representing a closure function).
--   
--   The hoisted expression is parameterised by (1) a set of type variables
--   and (2) a set of value variables that are passed as conventional type
--   and value arguments. The latter is implicitly extended by the set of
--   <tt>PA</tt> dictionaries required for the type variables.
hoistPolyVExpr :: [TyVar] -> [Var] -> Inline -> VM VExpr -> VM VExpr
takeHoisted :: VM [(Var, CoreExpr)]


-- | Utils concerning closure construction and application.
module Vectorise.Utils.Closure

-- | Make a closure.
mkClosure :: Type -> Type -> Type -> VExpr -> VExpr -> VM VExpr

-- | Make a closure application.
mkClosureApp :: Type -> Type -> VExpr -> VExpr -> VM VExpr

-- | Build a set of <tt>n</tt> closures corresponding to an <tt>n</tt>-ary
--   vectorised function. The length of the list of types of arguments
--   determines the arity.
--   
--   In addition to a set of type variables, a set of value variables is
--   passed during closure <i>construction</i>. In contrast, the closure
--   environment and the arguments are passed during closure application.
buildClosures :: [TyVar] -> [Var] -> [VVar] -> [Type] -> Type -> VM VExpr -> VM VExpr

module Vectorise.Utils
collectAnnTypeArgs :: AnnExpr b ann -> (AnnExpr b ann, [Type])
collectAnnDictArgs :: AnnExpr Var ann -> (AnnExpr Var ann, [AnnExpr Var ann])
collectAnnTypeBinders :: AnnExpr Var ann -> ([Var], AnnExpr Var ann)

-- | Collect all consecutive value binders that are not dictionaries.
collectAnnValBinders :: AnnExpr Var ann -> ([Var], AnnExpr Var ann)
isAnnTypeArg :: AnnExpr b ann -> Bool

-- | Produce an array containing copies of a given element.
replicatePD :: CoreExpr -> CoreExpr -> VM CoreExpr

-- | An empty array of the given type.
emptyPD :: Type -> VM CoreExpr

-- | Select some elements from an array that correspond to a particular tag
--   value and pack them into a new array.
--   
--   <pre>
--   packByTagPD Int# [:23, 42, 95, 50, 27, 49:]  3 [:1, 2, 1, 2, 3, 2:] 2 
--     ==&gt; [:42, 50, 49:]
--   </pre>
packByTagPD :: Type -> CoreExpr -> CoreExpr -> CoreExpr -> CoreExpr -> VM CoreExpr

-- | Combine some arrays based on a selector. The selector says which
--   source array to choose for each element of the resulting array.
combinePD :: Type -> CoreExpr -> CoreExpr -> [CoreExpr] -> VM CoreExpr

-- | Like <a>replicatePD</a> but use the lifting context in the vectoriser
--   state.
liftPD :: CoreExpr -> VM CoreExpr
zipScalars :: [Type] -> Type -> VM CoreExpr
scalarClosure :: [Type] -> Type -> CoreExpr -> CoreExpr -> VM CoreExpr

-- | Make a fresh local variable with the given type. The variable's name
--   is formed using the given string as the prefix.
newLocalVar :: FastString -> Type -> VM Var


-- | Compute a description of the generic representation that we use for a
--   user defined data type.
--   
--   During vectorisation, we generate a PRepr and PA instance for each
--   user defined data type. The PA dictionary contains methods to convert
--   the user type to and from our generic representation. This module
--   computes a description of what that generic representation is.
module Vectorise.Generic.Description

-- | Describes the representation type of a data constructor field.
data CompRepr
Keep :: Type -> CoreExpr -> CompRepr
Wrap :: Type -> CompRepr

-- | Describes the representation type of the fields / components of a
--   constructor. If the data constructor has multiple fields then we
--   bundle them together into a generic product type.
data ProdRepr

-- | Data constructor has no fields.
EmptyProd :: ProdRepr

-- | Data constructor has a single field.
UnaryProd :: CompRepr -> ProdRepr

-- | Data constructor has several fields.
Prod :: TyCon -> TyCon -> TyCon -> [Type] -> [CompRepr] -> ProdRepr

-- | Representation tycon for the product (eg Tuple2)
repr_tup_tc :: ProdRepr -> TyCon

-- | PData version of the product tycon (eg PDataTuple2)
repr_ptup_tc :: ProdRepr -> TyCon

-- | PDatas version of the product tycon (eg PDatasTuple2s) Not all lifted
--   backends use <tt>PDatas</tt>.
repr_ptups_tc :: ProdRepr -> TyCon

-- | Types of each field.
repr_comp_tys :: ProdRepr -> [Type]

-- | Generic representation types for each field.
repr_comps :: ProdRepr -> [CompRepr]

-- | Describes the representation type of a data constructor.
data ConRepr
ConRepr :: DataCon -> ProdRepr -> ConRepr
repr_dc :: ConRepr -> DataCon
repr_prod :: ConRepr -> ProdRepr

-- | Describes the generic representation of a data type. If the data type
--   has multiple constructors then we bundle them together into a generic
--   sum type.
data SumRepr

-- | Data type has no data constructors.
EmptySum :: SumRepr

-- | Data type has a single constructor.
UnarySum :: ConRepr -> SumRepr

-- | Data type has multiple constructors.
Sum :: TyCon -> TyCon -> TyCon -> Type -> Type -> CoreExpr -> [Type] -> [ConRepr] -> SumRepr

-- | Representation tycon for the sum (eg Sum2)
repr_sum_tc :: SumRepr -> TyCon

-- | PData version of the sum tycon (eg PDataSum2) This TyCon doesn't
--   appear explicitly in the source program. See Note [PData TyCons].
repr_psum_tc :: SumRepr -> TyCon

-- | PDatas version of the sum tycon (eg PDatasSum2)
repr_psums_tc :: SumRepr -> TyCon

-- | Type of the selector (eg Sel2)
repr_sel_ty :: SumRepr -> Type

-- | Type of multi-selector (eg Sel2s)
repr_sels_ty :: SumRepr -> Type

-- | Function to get the length of a Sels of this type.
repr_selsLength_v :: SumRepr -> CoreExpr

-- | Type of each data constructor.
repr_con_tys :: SumRepr -> [Type]

-- | Generic representation types of each data constructor.
repr_cons :: SumRepr -> [ConRepr]

-- | Determine the generic representation of a data type, given its tycon.
tyConRepr :: TyCon -> VM SumRepr

-- | Yield the type of this sum representation.
sumReprType :: SumRepr -> VM Type

-- | Yield the original component type of a data constructor component
--   representation.
compOrigType :: CompRepr -> Type
instance Outputable CompRepr
instance Outputable ProdRepr
instance Outputable ConRepr
instance Outputable SumRepr


-- | Generate methods for the PA class.
--   
--   TODO: there is a large amount of redundancy here between the a, PData
--   a, and PDatas a forms. See if we can factor some of this out.
module Vectorise.Generic.PAMethods
buildPReprTyCon :: TyCon -> TyCon -> SumRepr -> VM FamInst
buildPAScAndMethods :: VM [(String, PAInstanceBuilder)]


-- | Build instance tycons for the PData and PDatas type families.
--   
--   TODO: the PData and PDatas cases are very similar. We should be able
--   to factor out the common parts.
module Vectorise.Generic.PData

-- | Build the PData instance tycon for a given type constructor.
buildPDataTyCon :: TyCon -> TyCon -> SumRepr -> VM FamInst

-- | Build the PDatas instance tycon for a given type constructor.
buildPDatasTyCon :: TyCon -> TyCon -> SumRepr -> VM FamInst

module Vectorise.Type.Type

-- | Vectorise a type constructor.
vectTyCon :: TyCon -> VM TyCon

-- | Produce the vectorised and lifted versions of a type.
--   
--   NB: Here we are limited to properly handle predicates at the toplevel
--   only. Anything embedded in what is called the <tt>body_ty</tt> below
--   will end up as an argument to the type family <tt>PData</tt>.
vectAndLiftType :: Type -> VM (Type, Type)

-- | Vectorise a type.
--   
--   For each quantified var we need to add a PA dictionary out the front
--   of the type. So forall a. C a =&gt; a -&gt; a turns into forall a. PA
--   a =&gt; Cv a =&gt; a :-&gt; a
vectType :: Type -> VM Type

module Vectorise.Type.TyConDecl

-- | Vectorise some (possibly recursively defined) type constructors.
vectTyConDecls :: [TyCon] -> VM [TyCon]

module Vectorise.Convert

-- | Convert a vectorised expression such that it computes the
--   non-vectorised equivalent of its value.
--   
--   For functions, we eta expand the function and convert the arguments
--   and result:
fromVect :: Type -> CoreExpr -> VM CoreExpr


-- | Vectorise variables and literals.
module Vectorise.Var

-- | Vectorise a binder variable, along with its attached type.
vectBndr :: Var -> VM VVar

-- | Vectorise a binder variable, along with its attached type, but give
--   the result a new name.
vectBndrNew :: Var -> FastString -> VM VVar

-- | Vectorise a binder then run a computation with that binder in scope.
vectBndrIn :: Var -> VM a -> VM (VVar, a)

-- | Vectorise a binder, give it a new name, then run a computation with
--   that binder in scope.
vectBndrNewIn :: Var -> FastString -> VM a -> VM (VVar, a)

-- | Vectorise some binders, then run a computation with them in scope.
vectBndrsIn :: [Var] -> VM a -> VM ([VVar], a)

-- | Vectorise a variable, producing the vectorised and lifted versions.
vectVar :: Var -> VM VExpr

-- | Constants are lifted by replication along the integer context in the
--   <a>VM</a> state for the number of elements in the result array.
vectConst :: CoreExpr -> VM VExpr


-- | Vectorisation of expressions.
module Vectorise.Exp

-- | Vectorise a polymorphic expression.
--   
--   If not yet available, precompute vectorisation avoidance information
--   before vectorising. If the vectorisation avoidance optimisation is
--   enabled, also use the vectorisation avoidance information to
--   encapsulated subexpression that do not need to be vectorised.
vectPolyExpr :: Bool -> [Var] -> CoreExprWithFVs -> Maybe VITree -> VM (Inline, Bool, VExpr)

-- | Vectorise the body of a dfun.
--   
--   Dictionary computations are special for the following reasons. The
--   application of dictionary functions are always saturated, so there is
--   no need to create closures. Dictionary computations don't depend on
--   array values, so they are always scalar computations whose result we
--   can replicate (instead of executing them in parallel).
--   
--   NB: To keep things simple, we are not rewriting any of the bindings
--   introduced in a dictionary computation. Consequently, the variable
--   case needs to deal with cases where binders are in the vectoriser
--   environments and where that is not the case.
vectDictExpr :: CoreExpr -> VM CoreExpr

-- | Vectorise an expression of functional type by lifting it by an
--   application of a member of the zipWith family (i.e., <a>map</a>,
--   <a>zipWith</a>, zipWith3', etc.) This is only a valid strategy if the
--   function does not contain parallel subcomputations and has only
--   <tt>Scalar</tt> types in its result and arguments — this is a
--   predcondition for calling this function.
--   
--   Dictionary functions are also scalar functions (as dictionaries
--   themselves are not vectorised, instead they become dictionaries of
--   vectorised methods). We treat them differently, though see <a>Note
--   [Scalar dfuns]</a> in <tt>Vectorise</tt>.
vectScalarFun :: CoreExpr -> VM VExpr

-- | Vectorise a dictionary function that has a 'VECTORISE SCALAR instance'
--   pragma.
--   
--   In other words, all methods in that dictionary are scalar functions —
--   to be vectorised with <a>vectScalarFun</a>. The dictionary
--   <a>function</a> itself may be a constant, though.
--   
--   NB: You may think that we could implement this function guided by the
--   struture of the Core expression of the right-hand side of the
--   dictionary function. We cannot proceed like this as
--   <a>vectScalarDFun</a> must also work for *imported* dfuns, where we
--   don't necessarily have access to the Core code of the unvectorised
--   dfun.
--   
--   Here an example — assume,
--   
--   <pre>
--   class Eq a where { (==) :: a -&gt; a -&gt; Bool }
--   instance (Eq a, Eq b) =&gt; Eq (a, b) where { (==) = ... }
--   {-# VECTORISE SCALAR instance Eq (a, b) }
--   </pre>
--   
--   The unvectorised dfun for the above instance has the following
--   signature:
--   
--   <pre>
--   $dEqPair :: forall a b. Eq a -&gt; Eq b -&gt; Eq (a, b)
--   </pre>
--   
--   We generate the following (scalar) vectorised dfun (liberally using TH
--   notation):
--   
--   <pre>
--   $v$dEqPair :: forall a b. V:Eq a -&gt; V:Eq b -&gt; V:Eq (a, b)
--   $v$dEqPair = /\a b -&gt; \dEqa :: V:Eq a -&gt; \dEqb :: V:Eq b -&gt;
--                  D:V:Eq $(vectScalarFun True recFns 
--                           [| (==) @(a, b) ($dEqPair @a @b $(unVect dEqa) $(unVect dEqb)) |])
--   </pre>
--   
--   NB: * '(,)' vectorises to '(,)' — hence, the type constructor in the
--   result type remains the same. * We share the '$(unVect di)'
--   sub-expressions between the different selectors, but duplicate the
--   application of the unvectorised dfun, to enable the dictionary
--   selection rules to fire.
vectScalarDFun :: Var -> VM CoreExpr
instance Eq VectAvoidInfo
instance Show VectAvoidInfo
instance Show VITree

module Vectorise.Generic.PADict

-- | Build the PA dictionary function for some type and hoist it to top
--   level.
--   
--   The PA dictionary holds fns that convert values to and from their
--   vectorised representations.
--   
--   <pre>
--   Recall the definition:
--       class PR (PRepr a) =&gt; PA a where
--         toPRepr      :: a -&gt; PRepr a
--         fromPRepr    :: PRepr a -&gt; a
--         toArrPRepr   :: PData a -&gt; PData (PRepr a)
--         fromArrPRepr :: PData (PRepr a) -&gt; PData a
--   
--   Example:
--       df :: forall a. PR (PRepr a) -&gt; PA a -&gt; PA (T a)
--       df = /a. (c:PR (PRepr a)) (d:PA a). MkPA c ($PR_df a d) ($toPRepr a d) ... 
--       $dPR_df :: forall a. PA a -&gt; PR (PRepr (T a))
--       $dPR_df = ....   
--       $toRepr :: forall a. PA a -&gt; T a -&gt; PRepr (T a)
--       $toPRepr = ...
--    The <a>...</a> stuff is filled in by buildPAScAndMethods
--   </pre>
buildPADict :: TyCon -> CoAxiom -> TyCon -> TyCon -> SumRepr -> VM Var

module Vectorise.Type.Env

-- | Vectorise type constructor including class type constructors.
vectTypeEnv :: [TyCon] -> [CoreVect] -> [CoreVect] -> VM ([TyCon], [FamInst], [(Var, CoreExpr)])

module TcEnv

-- | A typecheckable-thing, essentially anything that has a name
data TyThing
AnId :: Id -> TyThing
ADataCon :: DataCon -> TyThing
ATyCon :: TyCon -> TyThing
ACoAxiom :: CoAxiom -> TyThing
data TcTyThing
AGlobal :: TyThing -> TcTyThing
ATcId :: TcId -> TopLevelFlag -> ThLevel -> TcTyThing
tct_id :: TcTyThing -> TcId
tct_closed :: TcTyThing -> TopLevelFlag
tct_level :: TcTyThing -> ThLevel
ATyVar :: Name -> TcTyVar -> TcTyThing
AThing :: TcKind -> TcTyThing
APromotionErr :: PromotionErr -> TcTyThing
type TcId = Id
data InstInfo a
InstInfo :: ClsInst -> InstBindings a -> InstInfo a
iSpec :: InstInfo a -> ClsInst
iBinds :: InstInfo a -> InstBindings a
iDFunId :: InstInfo a -> DFunId
pprInstInfoDetails :: OutputableBndr a => InstInfo a -> SDoc
simpleInstInfoClsTy :: InstInfo a -> (Class, Type)
simpleInstInfoTy :: InstInfo a -> Type
simpleInstInfoTyCon :: InstInfo a -> TyCon
data InstBindings a
VanillaInst :: (LHsBinds a) -> [LSig a] -> Bool -> InstBindings a
NewTypeDerived :: TcCoercion -> TyCon -> InstBindings a
tcExtendGlobalEnv :: [TyThing] -> TcM r -> TcM r
tcExtendGlobalEnvImplicit :: [TyThing] -> TcM r -> TcM r
setGlobalTypeEnv :: TcGblEnv -> TypeEnv -> TcM TcGblEnv
tcExtendGlobalValEnv :: [Id] -> TcM a -> TcM a
tcLookupLocatedGlobal :: Located Name -> TcM TyThing
tcLookupGlobal :: Name -> TcM TyThing
tcLookupField :: Name -> TcM Id
tcLookupTyCon :: Name -> TcM TyCon
tcLookupClass :: Name -> TcM Class
tcLookupDataCon :: Name -> TcM DataCon
tcLookupLocatedGlobalId :: Located Name -> TcM Id
tcLookupLocatedTyCon :: Located Name -> TcM TyCon
tcLookupLocatedClass :: Located Name -> TcM Class
tcLookupInstance :: Class -> [Type] -> TcM ClsInst
tcLookupAxiom :: Name -> TcM CoAxiom
tcExtendKindEnv :: [(Name, TcKind)] -> TcM r -> TcM r
tcExtendTcTyThingEnv :: [(Name, TcTyThing)] -> TcM r -> TcM r
tcExtendTyVarEnv :: [TyVar] -> TcM r -> TcM r
tcExtendTyVarEnv2 :: [(Name, TcTyVar)] -> TcM r -> TcM r
tcExtendGhciEnv :: [TcId] -> TcM a -> TcM a
tcExtendLetEnv :: TopLevelFlag -> [TcId] -> TcM a -> TcM a
tcExtendIdEnv :: [TcId] -> TcM a -> TcM a
tcExtendIdEnv1 :: Name -> TcId -> TcM a -> TcM a
tcExtendIdEnv2 :: [(Name, TcId)] -> TcM a -> TcM a
tcLookup :: Name -> TcM TcTyThing
tcLookupLocated :: Located Name -> TcM TcTyThing
tcLookupLocalIds :: [Name] -> TcM [TcId]
tcLookupId :: Name -> TcM Id
tcLookupTyVar :: Name -> TcM TcTyVar
tcLookupLcl_maybe :: Name -> TcM (Maybe TcTyThing)
getScopedTyVarBinds :: TcM [(Name, TcTyVar)]
getInLocalScope :: TcM (Name -> Bool)
wrongThingErr :: String -> TcTyThing -> Name -> TcM a
pprBinders :: [Name] -> SDoc
tcExtendRecEnv :: [(Name, TyThing)] -> TcM r -> TcM r
tcExtendRules :: [LRuleDecl Id] -> TcM a -> TcM a
tcGetDefaultTys :: TcM ([Type], (Bool, Bool))
tcGetGlobalTyVars :: TcM TcTyVarSet
zapLclTypeEnv :: TcM a -> TcM a
checkWellStaged :: SDoc -> ThLevel -> ThLevel -> TcM ()
tcMetaTy :: Name -> TcM Type
thLevel :: ThStage -> ThLevel
topIdLvl :: Id -> ThLevel
thTopLevelId :: Id -> Bool
thRnBrack :: ThStage
isBrackStage :: ThStage -> Bool
newLocalName :: Name -> TcRnIf gbl lcl Name
newDFunName :: Class -> [Type] -> SrcSpan -> TcM Name
newFamInstTyConName :: Located Name -> [Type] -> TcM Name
newFamInstAxiomName :: Located Name -> [Type] -> TcM Name
mkStableIdFromString :: String -> Type -> SrcSpan -> (OccName -> OccName) -> TcM TcId
mkStableIdFromName :: Name -> Type -> SrcSpan -> (OccName -> OccName) -> TcM TcId
instance MonadThings (IOEnv (Env TcGblEnv TcLclEnv))

module RnEnv
newTopSrcBinder :: Located RdrName -> RnM Name
lookupLocatedTopBndrRn :: Located RdrName -> RnM (Located Name)
lookupTopBndrRn :: RdrName -> RnM Name
lookupLocatedOccRn :: Located RdrName -> RnM (Located Name)
lookupOccRn :: RdrName -> RnM Name
lookupLocalOccRn_maybe :: RdrName -> RnM (Maybe Name)
lookupTypeOccRn :: RdrName -> RnM Name
lookupKindOccRn :: RdrName -> RnM Name
lookupGlobalOccRn :: RdrName -> RnM Name
lookupGlobalOccRn_maybe :: RdrName -> RnM (Maybe Name)
data HsSigCtxt
TopSigCtxt :: NameSet -> Bool -> HsSigCtxt
LocalBindCtxt :: NameSet -> HsSigCtxt
ClsDeclCtxt :: Name -> HsSigCtxt
InstDeclCtxt :: Name -> HsSigCtxt
HsBootCtxt :: HsSigCtxt
lookupLocalTcNames :: HsSigCtxt -> SDoc -> RdrName -> RnM [Name]
lookupSigOccRn :: HsSigCtxt -> Sig RdrName -> Located RdrName -> RnM (Located Name)
lookupFixityRn :: Name -> RnM Fixity
lookupTyFixityRn :: Located Name -> RnM Fixity
lookupInstDeclBndr :: Name -> SDoc -> RdrName -> RnM Name
lookupSubBndrOcc :: Parent -> SDoc -> RdrName -> RnM Name
lookupFamInstName :: Maybe Name -> Located RdrName -> RnM (Located Name)
greRdrName :: GlobalRdrElt -> RdrName
lookupSubBndrGREs :: GlobalRdrEnv -> Parent -> RdrName -> [GlobalRdrElt]
lookupConstructorFields :: Name -> RnM [Name]
lookupSyntaxName :: Name -> RnM (SyntaxExpr Name, FreeVars)
lookupSyntaxTable :: [Name] -> RnM (SyntaxTable Name, FreeVars)
lookupIfThenElse :: RnM (Maybe (SyntaxExpr Name), FreeVars)
lookupGreRn :: RdrName -> RnM GlobalRdrElt
lookupGreLocalRn :: RdrName -> RnM (Maybe GlobalRdrElt)
lookupGreRn_maybe :: RdrName -> RnM (Maybe GlobalRdrElt)
getLookupOccRn :: RnM (Name -> Maybe Name)
addUsedRdrNames :: [RdrName] -> RnM ()
newLocalBndrRn :: Located RdrName -> RnM Name
newLocalBndrsRn :: [Located RdrName] -> RnM [Name]
bindLocalName :: Name -> RnM a -> RnM a
bindLocalNames :: [Name] -> RnM a -> RnM a
bindLocalNamesFV :: [Name] -> RnM (a, FreeVars) -> RnM (a, FreeVars)
type MiniFixityEnv = FastStringEnv (Located Fixity)
emptyFsEnv :: FastStringEnv a
extendFsEnv :: FastStringEnv a -> FastString -> a -> FastStringEnv a
lookupFsEnv :: FastStringEnv a -> FastString -> Maybe a
addLocalFixities :: MiniFixityEnv -> [Name] -> RnM a -> RnM a
bindLocatedLocalsFV :: [Located RdrName] -> ([Name] -> RnM (a, FreeVars)) -> RnM (a, FreeVars)
bindLocatedLocalsRn :: [Located RdrName] -> ([Name] -> RnM a) -> RnM a
extendTyVarEnvFVRn :: [Name] -> RnM (a, FreeVars) -> RnM (a, FreeVars)
checkDupRdrNames :: [Located RdrName] -> RnM ()
checkShadowedRdrNames :: [Located RdrName] -> RnM ()
checkDupNames :: [Name] -> RnM ()
checkDupAndShadowedNames :: (GlobalRdrEnv, LocalRdrEnv) -> [Name] -> RnM ()
checkTupSize :: Int -> RnM ()
addFvRn :: FreeVars -> RnM (thing, FreeVars) -> RnM (thing, FreeVars)
mapFvRn :: (a -> RnM (b, FreeVars)) -> [a] -> RnM ([b], FreeVars)
mapMaybeFvRn :: (a -> RnM (b, FreeVars)) -> Maybe a -> RnM (Maybe b, FreeVars)
mapFvRnCPS :: (a -> (b -> RnM c) -> RnM c) -> [a] -> ([b] -> RnM c) -> RnM c
warnUnusedMatches :: [Name] -> FreeVars -> RnM ()
warnUnusedTopBinds :: [GlobalRdrElt] -> RnM ()
warnUnusedLocalBinds :: [Name] -> FreeVars -> RnM ()
dataTcOccs :: RdrName -> [RdrName]
unknownNameErr :: SDoc -> RdrName -> SDoc
kindSigErr :: Outputable a => a -> SDoc
perhapsForallMsg :: SDoc
data HsDocContext
TypeSigCtx :: SDoc -> HsDocContext
PatCtx :: HsDocContext
SpecInstSigCtx :: HsDocContext
DefaultDeclCtx :: HsDocContext
ForeignDeclCtx :: (Located RdrName) -> HsDocContext
DerivDeclCtx :: HsDocContext
RuleCtx :: FastString -> HsDocContext
TyDataCtx :: (Located RdrName) -> HsDocContext
TySynCtx :: (Located RdrName) -> HsDocContext
TyFamilyCtx :: (Located RdrName) -> HsDocContext
ConDeclCtx :: (Located RdrName) -> HsDocContext
ClassDeclCtx :: (Located RdrName) -> HsDocContext
ExprWithTySigCtx :: HsDocContext
TypBrCtx :: HsDocContext
HsTypeCtx :: HsDocContext
GHCiCtx :: HsDocContext
SpliceTypeCtx :: (LHsType RdrName) -> HsDocContext
ClassInstanceCtx :: HsDocContext
VectDeclCtx :: (Located RdrName) -> HsDocContext
GenericCtx :: SDoc -> HsDocContext
docOfHsDocContext :: HsDocContext -> SDoc

module RnTypes
rnHsType :: HsDocContext -> HsType RdrName -> RnM (HsType Name, FreeVars)
rnLHsType :: HsDocContext -> LHsType RdrName -> RnM (LHsType Name, FreeVars)
rnLHsTypes :: HsDocContext -> [LHsType RdrName] -> RnM ([LHsType Name], FreeVars)
rnContext :: HsDocContext -> LHsContext RdrName -> RnM (LHsContext Name, FreeVars)
rnHsKind :: HsDocContext -> HsKind RdrName -> RnM (HsKind Name, FreeVars)
rnLHsKind :: HsDocContext -> LHsKind RdrName -> RnM (LHsKind Name, FreeVars)
rnLHsMaybeKind :: HsDocContext -> Maybe (LHsKind RdrName) -> RnM (Maybe (LHsKind Name), FreeVars)
rnHsSigType :: SDoc -> LHsType RdrName -> RnM (LHsType Name, FreeVars)
rnLHsInstType :: SDoc -> LHsType RdrName -> RnM (LHsType Name, FreeVars)
rnConDeclFields :: HsDocContext -> [ConDeclField RdrName] -> RnM ([ConDeclField Name], FreeVars)
newTyVarNameRn :: Maybe a -> LocalRdrEnv -> SrcSpan -> RdrName -> RnM Name
mkOpAppRn :: LHsExpr Name -> LHsExpr Name -> Fixity -> LHsExpr Name -> RnM (HsExpr Name)
mkNegAppRn :: LHsExpr id -> SyntaxExpr id -> RnM (HsExpr id)
mkOpFormRn :: LHsCmdTop Name -> LHsExpr Name -> Fixity -> LHsCmdTop Name -> RnM (HsCmd Name)
mkConOpPatRn :: Located Name -> Fixity -> LPat Name -> LPat Name -> RnM (Pat Name)
checkPrecMatch :: Name -> MatchGroup Name -> RnM ()
checkSectionPrec :: FixityDirection -> HsExpr RdrName -> LHsExpr Name -> LHsExpr Name -> RnM ()
warnUnusedForAlls :: SDoc -> LHsTyVarBndrs RdrName -> [RdrName] -> TcM ()
rnSplice :: HsSplice RdrName -> RnM (HsSplice Name, FreeVars)
checkTH :: Outputable a => a -> String -> RnM ()
bindSigTyVarsFV :: [Name] -> RnM (a, FreeVars) -> RnM (a, FreeVars)
bindHsTyVars :: HsDocContext -> Maybe a -> [RdrName] -> LHsTyVarBndrs RdrName -> (LHsTyVarBndrs Name -> RnM (b, FreeVars)) -> RnM (b, FreeVars)
rnHsBndrSig :: HsDocContext -> HsWithBndrs (LHsType RdrName) -> (HsWithBndrs (LHsType Name) -> RnM (a, FreeVars)) -> RnM (a, FreeVars)
extractHsTyRdrTyVars :: LHsType RdrName -> FreeKiTyVars
extractHsTysRdrTyVars :: [LHsType RdrName] -> FreeKiTyVars
extractRdrKindSigVars :: Maybe (LHsKind RdrName) -> [RdrName]
extractTyDefnKindVars :: HsTyDefn RdrName -> [RdrName]
filterInScope :: LocalRdrEnv -> FreeKiTyVars -> FreeKiTyVars

module RnPat
rnPat :: HsMatchContext Name -> LPat RdrName -> (LPat Name -> RnM (a, FreeVars)) -> RnM (a, FreeVars)
rnPats :: HsMatchContext Name -> [LPat RdrName] -> ([LPat Name] -> RnM (a, FreeVars)) -> RnM (a, FreeVars)
rnBindPat :: NameMaker -> LPat RdrName -> RnM (LPat Name, FreeVars)
data NameMaker
applyNameMaker :: NameMaker -> Located RdrName -> RnM Name
localRecNameMaker :: MiniFixityEnv -> NameMaker
topRecNameMaker :: MiniFixityEnv -> NameMaker
rnHsRecFields1 :: HsRecFieldContext -> (RdrName -> arg) -> HsRecFields RdrName (Located arg) -> RnM ([HsRecField Name (Located arg)], FreeVars)
data HsRecFieldContext
HsRecFieldCon :: Name -> HsRecFieldContext
HsRecFieldPat :: Name -> HsRecFieldContext
HsRecFieldUpd :: HsRecFieldContext
rnLit :: HsLit -> RnM ()
rnOverLit :: HsOverLit t -> RnM (HsOverLit Name, FreeVars)
checkTupSize :: Int -> RnM ()
patSigErr :: Outputable a => a -> SDoc
instance Monad CpsRn

module RnBinds
rnTopBindsLHS :: MiniFixityEnv -> HsValBinds RdrName -> RnM (HsValBindsLR Name RdrName)
rnTopBindsRHS :: NameSet -> HsValBindsLR Name RdrName -> RnM (HsValBinds Name, DefUses)
rnValBindsRHS :: HsSigCtxt -> HsValBindsLR Name RdrName -> RnM (HsValBinds Name, DefUses)
rnLocalBindsAndThen :: HsLocalBinds RdrName -> (HsLocalBinds Name -> RnM (result, FreeVars)) -> RnM (result, FreeVars)
rnLocalValBindsLHS :: MiniFixityEnv -> HsValBinds RdrName -> RnM ([Name], HsValBindsLR Name RdrName)
rnLocalValBindsRHS :: NameSet -> HsValBindsLR Name RdrName -> RnM (HsValBinds Name, DefUses)
rnMethodBinds :: Name -> (Name -> [Name]) -> LHsBinds RdrName -> RnM (LHsBinds Name, FreeVars)
renameSigs :: HsSigCtxt -> [LSig RdrName] -> RnM ([LSig Name], FreeVars)
mkSigTvFn :: [LSig Name] -> (Name -> [Name])
rnMatchGroup :: HsMatchContext Name -> MatchGroup RdrName -> RnM (MatchGroup Name, FreeVars)
rnGRHSs :: HsMatchContext Name -> GRHSs RdrName -> RnM (GRHSs Name, FreeVars)
rnGRHS :: HsMatchContext Name -> LGRHS RdrName -> RnM (LGRHS Name, FreeVars)
makeMiniFixityEnv :: [LFixitySig RdrName] -> RnM MiniFixityEnv
type MiniFixityEnv = FastStringEnv (Located Fixity)
data HsSigCtxt
TopSigCtxt :: NameSet -> Bool -> HsSigCtxt
LocalBindCtxt :: NameSet -> HsSigCtxt
ClsDeclCtxt :: Name -> HsSigCtxt
InstDeclCtxt :: Name -> HsSigCtxt
HsBootCtxt :: HsSigCtxt

module Inst
deeplySkolemise :: TcSigmaType -> TcM (HsWrapper, [TyVar], [EvVar], TcRhoType)
deeplyInstantiate :: CtOrigin -> TcSigmaType -> TcM (HsWrapper, TcRhoType)
instCall :: CtOrigin -> [TcType] -> TcThetaType -> TcM HsWrapper
instStupidTheta :: CtOrigin -> TcThetaType -> TcM ()
emitWanted :: CtOrigin -> TcPredType -> TcM EvVar
emitWanteds :: CtOrigin -> TcThetaType -> TcM [EvVar]
newOverloadedLit :: CtOrigin -> HsOverLit Name -> TcRhoType -> TcM (HsOverLit TcId)
mkOverLit :: OverLitVal -> TcM HsLit
tcGetInstEnvs :: TcM (InstEnv, InstEnv)
getOverlapFlag :: TcM OverlapFlag
tcExtendLocalInstEnv :: [ClsInst] -> TcM a -> TcM a
instCallConstraints :: CtOrigin -> TcThetaType -> TcM HsWrapper
newMethodFromName :: CtOrigin -> Name -> TcRhoType -> TcM (HsExpr TcId)
tcSyntaxName :: CtOrigin -> TcType -> (Name, HsExpr Name) -> TcM (Name, HsExpr TcId)
hasEqualities :: [EvVar] -> Bool
unitImplication :: Implication -> Bag Implication
tyVarsOfWC :: WantedConstraints -> TyVarSet
tyVarsOfBag :: (a -> TyVarSet) -> Bag a -> TyVarSet
tyVarsOfEvVar :: EvVar -> TyVarSet
tyVarsOfEvVars :: [EvVar] -> TyVarSet
tyVarsOfImplication :: Implication -> TyVarSet
tyVarsOfCt :: Ct -> TcTyVarSet
tyVarsOfCts :: Cts -> TcTyVarSet
tyVarsOfCDict :: Ct -> TcTyVarSet
tyVarsOfCDicts :: Cts -> TcTyVarSet
tidyEvVar :: TidyEnv -> EvVar -> EvVar
tidyCt :: TidyEnv -> Ct -> Ct
tidyGivenLoc :: TidyEnv -> GivenLoc -> GivenLoc
substEvVar :: TvSubst -> EvVar -> EvVar
substImplication :: TvSubst -> Implication -> Implication
substCt :: TvSubst -> Ct -> Ct

module TcUnify
tcWrapResult :: HsExpr TcId -> TcRhoType -> TcRhoType -> TcM (HsExpr TcId)
tcSubType :: CtOrigin -> UserTypeCtxt -> TcSigmaType -> TcSigmaType -> TcM HsWrapper
tcGen :: UserTypeCtxt -> TcType -> ([TcTyVar] -> TcRhoType -> TcM result) -> TcM (HsWrapper, result)
checkConstraints :: SkolemInfo -> [TcTyVar] -> [EvVar] -> TcM result -> TcM (TcEvBinds, result)
newImplication :: SkolemInfo -> [TcTyVar] -> [EvVar] -> TcM result -> TcM (TcEvBinds, result)
unifyType :: TcTauType -> TcTauType -> TcM TcCoercion
unifyTypeList :: [TcTauType] -> TcM ()
unifyTheta :: TcThetaType -> TcThetaType -> TcM [TcCoercion]
unifyKind :: TcKind -> TcKind -> TcM Ordering
unifyKindEq :: TcKind -> TcKind -> TcM ()
tcInfer :: (TcType -> TcM a) -> TcM (a, TcType)
matchExpectedListTy :: TcRhoType -> TcM (TcCoercion, TcRhoType)
matchExpectedPArrTy :: TcRhoType -> TcM (TcCoercion, TcRhoType)
matchExpectedTyConApp :: TyCon -> TcRhoType -> TcM (TcCoercion, [TcSigmaType])
matchExpectedAppTy :: TcRhoType -> TcM (TcCoercion, (TcSigmaType, TcSigmaType))
matchExpectedFunTys :: SDoc -> Arity -> TcRhoType -> TcM (TcCoercion, [TcSigmaType], TcRhoType)
matchExpectedFunKind :: TcKind -> TcM (Maybe (TcKind, TcKind))
wrapFunResCoercion :: [TcType] -> HsWrapper -> TcM HsWrapper
mkKindErrorCtxt :: Type -> Type -> Kind -> Kind -> TidyEnv -> TcM (TidyEnv, SDoc)
instance Outputable SwapFlag

module TcGenDeriv
type BagDerivStuff = Bag DerivStuff
data DerivStuff
DerivAuxBind :: AuxBindSpec -> DerivStuff
DerivTyCon :: TyCon -> DerivStuff
DerivFamInst :: FamInst -> DerivStuff
DerivHsBind :: (LHsBind RdrName, LSig RdrName) -> DerivStuff
DerivInst :: (InstInfo RdrName) -> DerivStuff
gen_Bounded_binds :: SrcSpan -> TyCon -> (LHsBinds RdrName, BagDerivStuff)
gen_Enum_binds :: SrcSpan -> TyCon -> (LHsBinds RdrName, BagDerivStuff)
gen_Eq_binds :: SrcSpan -> TyCon -> (LHsBinds RdrName, BagDerivStuff)
gen_Ix_binds :: SrcSpan -> TyCon -> (LHsBinds RdrName, BagDerivStuff)
gen_Ord_binds :: SrcSpan -> TyCon -> (LHsBinds RdrName, BagDerivStuff)
gen_Read_binds :: FixityEnv -> SrcSpan -> TyCon -> (LHsBinds RdrName, BagDerivStuff)
gen_Show_binds :: FixityEnv -> SrcSpan -> TyCon -> (LHsBinds RdrName, BagDerivStuff)
gen_Data_binds :: DynFlags -> SrcSpan -> TyCon -> (LHsBinds RdrName, BagDerivStuff)
gen_Typeable_binds :: SrcSpan -> TyCon -> LHsBinds RdrName
gen_Functor_binds :: SrcSpan -> TyCon -> (LHsBinds RdrName, BagDerivStuff)
data FFoldType a
FT :: a -> a -> a -> (a -> a -> a) -> (TupleSort -> [a] -> a) -> (Type -> a -> a) -> a -> (TcTyVar -> a -> a) -> FFoldType a
ft_triv :: FFoldType a -> a
ft_var :: FFoldType a -> a
ft_co_var :: FFoldType a -> a
ft_fun :: FFoldType a -> a -> a -> a
ft_tup :: FFoldType a -> TupleSort -> [a] -> a
ft_ty_app :: FFoldType a -> Type -> a -> a
ft_bad_app :: FFoldType a -> a
ft_forall :: FFoldType a -> TcTyVar -> a -> a
functorLikeTraverse :: TyVar -> FFoldType a -> Type -> a
deepSubtypesContaining :: TyVar -> Type -> [TcType]
foldDataConArgs :: FFoldType a -> DataCon -> [a]
gen_Foldable_binds :: SrcSpan -> TyCon -> (LHsBinds RdrName, BagDerivStuff)
gen_Traversable_binds :: SrcSpan -> TyCon -> (LHsBinds RdrName, BagDerivStuff)
genAuxBinds :: SrcSpan -> BagDerivStuff -> SeparateBagsDerivStuff
ordOpTbl :: [(Type, (PrimOp, PrimOp, PrimOp, PrimOp, PrimOp))]
boxConTbl :: [(Type, RdrName)]
instance Eq AuxBindSpec

module TcGenGenerics
canDoGenerics :: TyCon -> [Type] -> Maybe SDoc
canDoGenerics1 :: TyCon -> [Type] -> Maybe SDoc
data GenericKind
Gen0 :: GenericKind
Gen1 :: GenericKind
data MetaTyCons
genGenericMetaTyCons :: TyCon -> Module -> TcM (MetaTyCons, BagDerivStuff)
gen_Generic_binds :: GenericKind -> TyCon -> MetaTyCons -> Module -> TcM (LHsBinds RdrName, FamInst)
get_gen1_constrained_tys :: TyVar -> [Type] -> [Type]
instance Outputable MetaTyCons

module TcHsType
tcHsSigType :: UserTypeCtxt -> LHsType Name -> TcM Type
tcHsSigTypeNC :: UserTypeCtxt -> LHsType Name -> TcM Type
tcHsDeriv :: HsType Name -> TcM ([TyVar], Class, [Type])
tcHsVectInst :: LHsType Name -> TcM (Class, [Type])
tcHsInstHead :: UserTypeCtxt -> LHsType Name -> TcM ([TyVar], ThetaType, Class, [Type])
data UserTypeCtxt
FunSigCtxt :: Name -> UserTypeCtxt
InfSigCtxt :: Name -> UserTypeCtxt
ExprSigCtxt :: UserTypeCtxt
ConArgCtxt :: Name -> UserTypeCtxt
TySynCtxt :: Name -> UserTypeCtxt
LamPatSigCtxt :: UserTypeCtxt
BindPatSigCtxt :: UserTypeCtxt
RuleSigCtxt :: Name -> UserTypeCtxt
ResSigCtxt :: UserTypeCtxt
ForSigCtxt :: Name -> UserTypeCtxt
DefaultDeclCtxt :: UserTypeCtxt
InstDeclCtxt :: UserTypeCtxt
SpecInstCtxt :: UserTypeCtxt
ThBrackCtxt :: UserTypeCtxt
GenSigCtxt :: UserTypeCtxt
GhciCtxt :: UserTypeCtxt
ClassSCCtxt :: Name -> UserTypeCtxt
SigmaCtxt :: UserTypeCtxt
DataTyCtxt :: Name -> UserTypeCtxt
kcTyClTyVars :: Name -> LHsTyVarBndrs Name -> (TcKind -> TcM a) -> TcM a
tcTyClTyVars :: Name -> LHsTyVarBndrs Name -> ([TyVar] -> Kind -> TcM a) -> TcM a
tcHsConArgType :: NewOrData -> LHsType Name -> TcM Type
tcDataKindSig :: Kind -> TcM [TyVar]
tcClassSigType :: LHsType Name -> TcM Type
kcHsTyVarBndrs :: Bool -> LHsTyVarBndrs Name -> ([TcKind] -> TcM r) -> TcM r
tcHsTyVarBndrs :: LHsTyVarBndrs Name -> ([TyVar] -> TcM r) -> TcM r
tcHsLiftedType :: LHsType Name -> TcM TcType
tcHsOpenType :: LHsType Name -> TcM TcType
tcLHsType :: LHsType Name -> TcM (TcType, TcKind)
tcCheckLHsType :: LHsType Name -> Kind -> TcM Type
tcHsContext :: LHsContext Name -> TcM [PredType]
tcInferApps :: Outputable a => a -> TcKind -> [LHsType Name] -> TcM ([TcType], TcKind)
tcHsArgTys :: SDoc -> [LHsType Name] -> [Kind] -> TcM [TcType]
data ExpKind
EK :: TcKind -> SDoc -> ExpKind
ekConstraint :: ExpKind
expArgKind :: SDoc -> TcKind -> Int -> ExpKind
checkExpectedKind :: Outputable a => a -> TcKind -> ExpKind -> TcM ()
kindGeneralize :: TyVarSet -> [Name] -> TcM [KindVar]
tcLHsKind :: LHsKind Name -> TcM Kind
tcHsPatSigType :: UserTypeCtxt -> HsWithBndrs (LHsType Name) -> TcM (Type, [(Name, TcTyVar)])
tcPatSig :: UserTypeCtxt -> HsWithBndrs (LHsType Name) -> TcSigmaType -> TcM (TcType, [(Name, TcTyVar)], HsWrapper)
instance Outputable ExpKind

module TcPat
tcLetPat :: TcSigFun -> LetBndrSpec -> LPat Name -> TcSigmaType -> TcM a -> TcM (LPat TcId, a)
type TcSigFun = Name -> Maybe TcSigInfo
data TcSigInfo
TcSigInfo :: TcId -> [(Maybe Name, TcTyVar)] -> TcThetaType -> TcSigmaType -> SrcSpan -> TcSigInfo
sig_id :: TcSigInfo -> TcId
sig_tvs :: TcSigInfo -> [(Maybe Name, TcTyVar)]
sig_theta :: TcSigInfo -> TcThetaType
sig_tau :: TcSigInfo -> TcSigmaType
sig_loc :: TcSigInfo -> SrcSpan
type TcPragFun = Name -> [LSig Name]
data LetBndrSpec
LetLclBndr :: LetBndrSpec
LetGblBndr :: TcPragFun -> LetBndrSpec
addInlinePrags :: TcId -> [LSig Name] -> TcM TcId
warnPrags :: Id -> [LSig Name] -> SDoc -> TcM ()
tcPat :: HsMatchContext Name -> LPat Name -> TcSigmaType -> TcM a -> TcM (LPat TcId, a)
tcPats :: HsMatchContext Name -> [LPat Name] -> [TcSigmaType] -> TcM a -> TcM ([LPat TcId], a)
newNoSigLetBndr :: LetBndrSpec -> Name -> TcType -> TcM TcId
newSigLetBndr :: LetBndrSpec -> Name -> TcSigInfo -> TcM TcId
addDataConStupidTheta :: DataCon -> [TcType] -> TcM ()
badFieldCon :: DataCon -> Name -> SDoc
polyPatSig :: TcType -> SDoc
instance Outputable TcSigInfo

module FamInst
checkFamInstConsistency :: [Module] -> [Module] -> TcM ()
tcExtendLocalFamInstEnv :: [FamInst] -> TcM a -> TcM a
tcLookupFamInst :: TyCon -> [Type] -> TcM (Maybe (FamInst, [Type]))
tcLookupDataFamInst :: TyCon -> [Type] -> TcM (TyCon, [Type])
tcGetFamInstEnvs :: TcM FamInstEnvs
instance Outputable ModulePair
instance Ord ModulePair
instance Eq ModulePair

module TcSMonad
data WorkList
WorkList :: [Ct] -> [Ct] -> [Ct] -> WorkList
wl_eqs :: WorkList -> [Ct]
wl_funeqs :: WorkList -> [Ct]
wl_rest :: WorkList -> [Ct]
isEmptyWorkList :: WorkList -> Bool
emptyWorkList :: WorkList
workListFromEq :: Ct -> WorkList
workListFromNonEq :: Ct -> WorkList
workListFromCt :: Ct -> WorkList
extendWorkListEq :: Ct -> WorkList -> WorkList
extendWorkListNonEq :: Ct -> WorkList -> WorkList
extendWorkListCt :: Ct -> WorkList -> WorkList
appendWorkListCt :: [Ct] -> WorkList -> WorkList
appendWorkListEqs :: [Ct] -> WorkList -> WorkList
unionWorkList :: WorkList -> WorkList -> WorkList
selectWorkItem :: WorkList -> (Maybe Ct, WorkList)
getTcSWorkList :: TcS WorkList
updWorkListTcS :: (WorkList -> WorkList) -> TcS ()
updWorkListTcS_return :: (WorkList -> (a, WorkList)) -> TcS a
getTcSWorkListTvs :: TcS TyVarSet
getTcSImplics :: TcS (Bag Implication)
updTcSImplics :: (Bag Implication -> Bag Implication) -> TcS ()
emitTcSImplication :: Implication -> TcS ()
data Ct
CDictCan :: CtEvidence -> Class -> [Xi] -> SubGoalDepth -> Ct
cc_ev :: Ct -> CtEvidence
cc_class :: Ct -> Class
cc_tyargs :: Ct -> [Xi]
cc_depth :: Ct -> SubGoalDepth
CIrredEvCan :: CtEvidence -> Xi -> SubGoalDepth -> Ct
cc_ev :: Ct -> CtEvidence
cc_ty :: Ct -> Xi
cc_depth :: Ct -> SubGoalDepth
CTyEqCan :: CtEvidence -> TcTyVar -> Xi -> SubGoalDepth -> Ct
cc_ev :: Ct -> CtEvidence
cc_tyvar :: Ct -> TcTyVar
cc_rhs :: Ct -> Xi
cc_depth :: Ct -> SubGoalDepth
CFunEqCan :: CtEvidence -> TyCon -> [Xi] -> Xi -> SubGoalDepth -> Ct
cc_ev :: Ct -> CtEvidence
cc_fun :: Ct -> TyCon
cc_tyargs :: Ct -> [Xi]
cc_rhs :: Ct -> Xi
cc_depth :: Ct -> SubGoalDepth
CNonCanonical :: CtEvidence -> SubGoalDepth -> Ct
cc_ev :: Ct -> CtEvidence
cc_depth :: Ct -> SubGoalDepth
type Xi = Type
tyVarsOfCt :: Ct -> TcTyVarSet
tyVarsOfCts :: Cts -> TcTyVarSet
tyVarsOfCDicts :: Cts -> TcTyVarSet
emitFrozenError :: CtEvidence -> SubGoalDepth -> TcS ()
isWanted :: CtEvidence -> Bool
isDerived :: CtEvidence -> Bool
isGivenCt :: Ct -> Bool
isWantedCt :: Ct -> Bool
isDerivedCt :: Ct -> Bool
pprFlavorArising :: CtEvidence -> SDoc
isFlexiTcsTv :: TyVar -> Bool
instFlexiTcSHelperTcS :: Name -> Kind -> TcS TcType
canRewrite :: CtEvidence -> CtEvidence -> Bool
canSolve :: CtEvidence -> CtEvidence -> Bool
mkGivenLoc :: WantedLoc -> SkolemInfo -> GivenLoc
ctWantedLoc :: Ct -> WantedLoc
data TcS a
runTcS :: TcS a -> TcM (a, Bag EvBind)
runTcSWithEvBinds :: EvBindsVar -> TcS a -> TcM a
failTcS :: SDoc -> TcS a
panicTcS :: SDoc -> TcS a
traceTcS :: String -> SDoc -> TcS ()
traceFireTcS :: SubGoalDepth -> SDoc -> TcS ()
bumpStepCountTcS :: TcS ()
doWithInert :: InertSet -> TcS a -> TcS a
tryTcS :: TcS a -> TcS a
nestImplicTcS :: EvBindsVar -> TcsUntouchables -> TcS a -> TcS a
recoverTcS :: TcS a -> TcS a -> TcS a
wrapErrTcS :: TcM a -> TcS a
wrapWarnTcS :: TcM a -> TcS a
getFlatCache :: TcS CtTypeMap
updFlatCache :: Ct -> TcS ()
addSolvedDict :: CtEvidence -> TcS ()
addSolvedFunEq :: CtEvidence -> TcS ()
deferTcSForAllEq :: (WantedLoc, EvVar) -> ([TyVar], TcType) -> ([TyVar], TcType) -> TcS ()
setEvBind :: EvVar -> EvTerm -> TcS ()
data XEvTerm
XEvTerm :: ([EvTerm] -> EvTerm) -> (EvTerm -> [EvTerm]) -> XEvTerm
ev_comp :: XEvTerm -> [EvTerm] -> EvTerm
ev_decomp :: XEvTerm -> EvTerm -> [EvTerm]
data MaybeNew
Fresh :: CtEvidence -> MaybeNew
Cached :: EvTerm -> MaybeNew
isFresh :: MaybeNew -> Bool
freshGoals :: [MaybeNew] -> [CtEvidence]
getEvTerms :: [MaybeNew] -> [EvTerm]
xCtFlavor :: CtEvidence -> [TcPredType] -> XEvTerm -> TcS [CtEvidence]
rewriteCtFlavor :: CtEvidence -> TcPredType -> TcCoercion -> TcS (Maybe CtEvidence)
newWantedEvVar :: WantedLoc -> TcPredType -> TcS MaybeNew
instDFunConstraints :: WantedLoc -> TcThetaType -> TcS [MaybeNew]
newDerived :: WantedLoc -> TcPredType -> TcS (Maybe CtEvidence)
setWantedTyBind :: TcTyVar -> TcType -> TcS ()
getInstEnvs :: TcS (InstEnv, InstEnv)
getFamInstEnvs :: TcS (FamInstEnv, FamInstEnv)
getTopEnv :: TcS HscEnv
getGblEnv :: TcS TcGblEnv
getTcEvBinds :: TcS EvBindsVar
getUntouchables :: TcS TcsUntouchables
getTcEvBindsMap :: TcS EvBindMap
getTcSTyBinds :: TcS (IORef (TyVarEnv (TcTyVar, TcType)))
getTcSTyBindsMap :: TcS (TyVarEnv (TcTyVar, TcType))
newFlattenSkolemTy :: TcType -> TcS TcType
data InertSet
IS :: InertCans -> Cts -> CtFamHeadMap -> FamHeadMap CtEvidence -> PredMap CtEvidence -> InertSet
inert_cans :: InertSet -> InertCans
inert_frozen :: InertSet -> Cts
inert_flat_cache :: InertSet -> CtFamHeadMap
inert_solved_funeqs :: InertSet -> FamHeadMap CtEvidence
inert_solved_dicts :: InertSet -> PredMap CtEvidence
data InertCans
IC :: TyVarEnv Ct -> InScopeSet -> CCanMap Class -> CtFamHeadMap -> Cts -> InertCans
inert_eqs :: InertCans -> TyVarEnv Ct
inert_eq_tvs :: InertCans -> InScopeSet
inert_dicts :: InertCans -> CCanMap Class
inert_funeqs :: InertCans -> CtFamHeadMap
inert_irreds :: InertCans -> Cts
getInertEqs :: TcS (TyVarEnv Ct, InScopeSet)
getCtCoercion :: EvBindMap -> Ct -> TcCoercion
emptyInert :: InertSet
getTcSInerts :: TcS InertSet
lookupInInerts :: InertSet -> TcPredType -> Maybe CtEvidence
getInertUnsolved :: InertSet -> Cts
getInertInsols :: InertSet -> Cts
splitInertsForImplications :: InertSet -> ([Ct], InertSet)
modifyInertTcS :: (InertSet -> (a, InertSet)) -> TcS a
updInertSetTcS :: Ct -> TcS ()
partitionCCanMap :: (Ct -> Bool) -> CCanMap a -> (Cts, CCanMap a)
partitionEqMap :: (Ct -> Bool) -> TyVarEnv (Ct, TcCoercion) -> ([Ct], TyVarEnv (Ct, TcCoercion))
getRelevantCts :: Uniquable a => a -> CCanMap a -> (Cts, CCanMap a)
extractRelevantInerts :: Ct -> TcS Cts
data CCanMap a
CCanMap :: UniqFM Cts -> UniqFM Cts -> UniqFM Cts -> CCanMap a
cts_given :: CCanMap a -> UniqFM Cts
cts_derived :: CCanMap a -> UniqFM Cts
cts_wanted :: CCanMap a -> UniqFM Cts
type CtTypeMap = TypeMap Ct
type CtFamHeadMap = FamHeadMap Ct
type CtPredMap = PredMap Ct
data PredMap a
data FamHeadMap a
partCtFamHeadMap :: (Ct -> Bool) -> CtFamHeadMap -> (Cts, CtFamHeadMap)
lookupFamHead :: FamHeadMap a -> TcType -> Maybe a
filterSolved :: (CtEvidence -> Bool) -> PredMap CtEvidence -> PredMap CtEvidence
instDFunType :: DFunId -> [DFunInstType] -> TcS ([TcType], TcType)
newFlexiTcSTy :: Kind -> TcS TcType
instFlexiTcS :: [TKVar] -> TcS (TvSubst, [TcType])
compatKind :: Kind -> Kind -> Bool
mkKindErrorCtxtTcS :: Type -> Kind -> Type -> Kind -> ErrCtxt
type TcsUntouchables = (Untouchables, TcTyVarSet)
isTouchableMetaTyVar :: TcTyVar -> TcS Bool
isTouchableMetaTyVar_InRange :: TcsUntouchables -> TcTyVar -> Bool
getDefaultInfo :: TcS ([Type], (Bool, Bool))
getDynFlags :: HasDynFlags m => m DynFlags
matchClass :: Class -> [Type] -> TcS (MatchInstResult (DFunId, [Maybe TcType]))
matchFam :: TyCon -> [Type] -> TcS (Maybe (FamInst, [Type]))
data MatchInstResult mi
MatchInstNo :: MatchInstResult mi
MatchInstSingle :: mi -> MatchInstResult mi
MatchInstMany :: MatchInstResult mi
checkWellStagedDFun :: PredType -> DFunId -> WantedLoc -> TcS ()
warnTcS :: CtLoc orig -> Bool -> SDoc -> TcS ()
pprEq :: TcType -> TcType -> SDoc
instance HasDynFlags TcS
instance Monad TcS
instance Functor TcS
instance Outputable InertSet
instance Outputable InertCans
instance Outputable a => Outputable (FamHeadMap a)
instance Outputable a => Outputable (PredMap a)
instance Outputable WorkList

module TcCanonical
canonicalize :: Ct -> TcS StopOrContinue
flatten :: SubGoalDepth -> FlattenMode -> CtEvidence -> TcType -> TcS (Xi, TcCoercion)
flattenMany :: SubGoalDepth -> FlattenMode -> CtEvidence -> [Type] -> TcS ([Xi], [TcCoercion])
occurCheckExpand :: TcTyVar -> Type -> Maybe Type
data FlattenMode
FMSubstOnly :: FlattenMode
FMFullFlatten :: FlattenMode
data StopOrContinue
ContinueWith :: Ct -> StopOrContinue
Stop :: StopOrContinue
instance Outputable StopOrContinue

module TcErrors
reportUnsolved :: Bool -> WantedConstraints -> TcM (Bag EvBind)
type ErrEnv = VarEnv [ErrMsg]
warnDefaulting :: [Ct] -> Type -> TcM ()
flattenForAllErrorTcS :: CtEvidence -> TcType -> TcM a
solverDepthErrorTcS :: Int -> [Ct] -> TcM a

module TcInteract
solveInteractGiven :: GivenLoc -> [EvVar] -> TcS (Bag Implication)
solveInteractCts :: [Ct] -> TcS (Bag Implication)

module TcSimplify
simplifyInfer :: Bool -> Bool -> [(Name, TcTauType)] -> (Untouchables, WantedConstraints) -> TcM ([TcTyVar], [EvVar], Bool, TcEvBinds)
simplifyAmbiguityCheck :: Name -> WantedConstraints -> TcM (Bag EvBind)
simplifyDefault :: ThetaType -> TcM ()
simplifyDeriv :: CtOrigin -> PredType -> [TyVar] -> ThetaType -> TcM ThetaType
simplifyRule :: RuleName -> WantedConstraints -> WantedConstraints -> TcM ([EvVar], WantedConstraints)
simplifyTop :: WantedConstraints -> TcM (Bag EvBind)
simplifyInteractive :: WantedConstraints -> TcM (Bag EvBind)

module TcBinds
tcLocalBinds :: HsLocalBinds Name -> TcM thing -> TcM (HsLocalBinds TcId, thing)
tcTopBinds :: HsValBinds Name -> TcM (TcGblEnv, TcLclEnv)
tcRecSelBinds :: HsValBinds Name -> TcM TcGblEnv
tcHsBootSigs :: HsValBinds Name -> TcM [Id]
tcPolyBinds :: TopLevelFlag -> TcSigFun -> PragFun -> RecFlag -> RecFlag -> [LHsBind Name] -> TcM (LHsBinds TcId, [TcId], TopLevelFlag)
tcPolyCheck :: TcSigInfo -> PragFun -> RecFlag -> [LHsBind Name] -> TcM (LHsBinds TcId, [TcId], TopLevelFlag)
type PragFun = Name -> [LSig Name]
tcSpecPrags :: Id -> [LSig Name] -> TcM [LTcSpecPrag]
tcVectDecls :: [LVectDecl Name] -> TcM ([LVectDecl TcId])
mkPragFun :: [LSig Name] -> LHsBinds Name -> PragFun
data TcSigInfo
TcSigInfo :: TcId -> [(Maybe Name, TcTyVar)] -> TcThetaType -> TcSigmaType -> SrcSpan -> TcSigInfo
sig_id :: TcSigInfo -> TcId
sig_tvs :: TcSigInfo -> [(Maybe Name, TcTyVar)]
sig_theta :: TcSigInfo -> TcThetaType
sig_tau :: TcSigInfo -> TcSigmaType
sig_loc :: TcSigInfo -> SrcSpan
type TcSigFun = Name -> Maybe TcSigInfo
instTcTySig :: LHsType Name -> TcType -> Name -> TcM TcSigInfo
instTcTySigFromId :: SrcSpan -> Id -> TcM TcSigInfo
badBootDeclErr :: MsgDoc
instance Outputable GeneralisationPlan

module TcMatches
tcMatchesFun :: Name -> Bool -> MatchGroup Name -> TcSigmaType -> TcM (HsWrapper, MatchGroup TcId)
tcGRHSsPat :: GRHSs Name -> TcRhoType -> TcM (GRHSs TcId)
tcGRHS :: TcMatchCtxt -> TcRhoType -> GRHS Name -> TcM (GRHS TcId)
tcMatchesCase :: TcMatchCtxt -> TcRhoType -> MatchGroup Name -> TcRhoType -> TcM (MatchGroup TcId)
tcMatchLambda :: MatchGroup Name -> TcRhoType -> TcM (HsWrapper, MatchGroup TcId)
data TcMatchCtxt
MC :: HsMatchContext Name -> (LHsExpr Name -> TcRhoType -> TcM (LHsExpr TcId)) -> TcMatchCtxt
mc_what :: TcMatchCtxt -> HsMatchContext Name
mc_body :: TcMatchCtxt -> LHsExpr Name -> TcRhoType -> TcM (LHsExpr TcId)
type TcStmtChecker = forall thing. HsStmtContext Name -> Stmt Name -> TcRhoType -> (TcRhoType -> TcM thing) -> TcM (Stmt TcId, thing)
tcStmts :: HsStmtContext Name -> TcStmtChecker -> [LStmt Name] -> TcRhoType -> TcM [LStmt TcId]
tcStmtsAndThen :: HsStmtContext Name -> TcStmtChecker -> [LStmt Name] -> TcRhoType -> (TcRhoType -> TcM thing) -> TcM ([LStmt TcId], thing)
tcDoStmts :: HsStmtContext Name -> [LStmt Name] -> TcRhoType -> TcM (HsExpr TcId)
tcBody :: LHsExpr Name -> TcRhoType -> TcM (LHsExpr TcId)
tcDoStmt :: TcStmtChecker
tcGuardStmt :: TcStmtChecker

module TcArrows
tcProc :: InPat Name -> LHsCmdTop Name -> TcRhoType -> TcM (OutPat TcId, LHsCmdTop TcId, TcCoercion)

module TcExpr
tcPolyExpr :: LHsExpr Name -> TcSigmaType -> TcM (LHsExpr TcId)
tcPolyExprNC :: LHsExpr Name -> TcSigmaType -> TcM (LHsExpr TcId)
tcMonoExpr :: LHsExpr Name -> TcRhoType -> TcM (LHsExpr TcId)
tcMonoExprNC :: LHsExpr Name -> TcRhoType -> TcM (LHsExpr TcId)
tcInferRho :: LHsExpr Name -> TcM (LHsExpr TcId, TcRhoType)
tcInferRhoNC :: LHsExpr Name -> TcM (LHsExpr TcId, TcRhoType)
tcSyntaxOp :: CtOrigin -> HsExpr Name -> TcType -> TcM (HsExpr TcId)
tcCheckId :: Name -> TcRhoType -> TcM (HsExpr TcId)
addExprErrCtxt :: LHsExpr Name -> TcM a -> TcM a

module TcAnnotations
tcAnnotations :: [LAnnDecl Name] -> TcM [Annotation]

module TcClassDcl
tcClassSigs :: Name -> [LSig Name] -> LHsBinds Name -> TcM ([TcMethInfo], NameEnv Type)
tcClassDecl2 :: LTyClDecl Name -> TcM (LHsBinds Id)
findMethodBind :: Name -> LHsBinds Name -> Maybe (LHsBind Name)
instantiateMethod :: Class -> Id -> [TcType] -> TcType
tcInstanceMethodBody :: SkolemInfo -> [TcTyVar] -> [EvVar] -> Id -> TcSigInfo -> TcSpecPrags -> LHsBind Name -> TcM (LHsBind Id)
type HsSigFun = NameEnv (LHsType Name)
mkHsSigFun :: [LSig Name] -> HsSigFun
lookupHsSig :: HsSigFun -> Name -> Maybe (LHsType Name)
emptyHsSigs :: HsSigFun
tcAddDeclCtxt :: TyClDecl Name -> TcM a -> TcM a
badMethodErr :: Outputable a => a -> Name -> SDoc

module TcTyClsDecls
tcTyAndClassDecls :: ModDetails -> [TyClGroup Name] -> TcM TcGblEnv
tcAddImplicits :: [TyThing] -> TcM TcGblEnv
kcTyDefn :: HsTyDefn Name -> TcKind -> TcM ()
tcConDecls :: NewOrData -> Bool -> TyCon -> ([TyVar], Type) -> [LConDecl Name] -> TcM [DataCon]
dataDeclChecks :: Name -> NewOrData -> ThetaType -> [LConDecl Name] -> TcM ()
checkValidTyCon :: TyCon -> TcM ()
tcSynFamInstDecl :: TyCon -> FamInstDecl Name -> TcM ([TyVar], [Type], Type)
tcFamTyPats :: TyCon -> HsWithBndrs [LHsType Name] -> (TcKind -> TcM ()) -> ([TKVar] -> [TcType] -> Kind -> TcM a) -> TcM a
tcAddFamInstCtxt :: FamInstDecl Name -> TcM a -> TcM a
wrongKindOfFamily :: TyCon -> SDoc
badATErr :: Name -> Name -> SDoc
wrongATArgErr :: Type -> Type -> SDoc

module TcDefaults
tcDefaults :: [LDefaultDecl Name] -> TcM (Maybe [Type])

module TcRules
tcRules :: [LRuleDecl Name] -> TcM [LRuleDecl TcId]


-- | The dynamic linker for GHCi.
--   
--   This module deals with the top-level issues of dynamic linking,
--   calling the object-code linker and the byte-code linker where
--   necessary.
module Linker
data HValue

-- | Get the <a>HValue</a> associated with the given name.
--   
--   May cause loading the module that contains the name.
--   
--   Throws a <a>ProgramError</a> if loading fails or the name cannot be
--   found.
getHValue :: HscEnv -> Name -> IO HValue

-- | Display the persistent linker state.
showLinkerState :: DynFlags -> IO ()

-- | Link a single expression, <i>including</i> first linking packages and
--   modules that this expression depends on.
--   
--   Raises an IO exception (<a>ProgramError</a>) if it can't find a
--   compiled version of the dependents to link.
linkExpr :: HscEnv -> SrcSpan -> UnlinkedBCO -> IO HValue
linkDecls :: HscEnv -> SrcSpan -> CompiledByteCode -> IO ()

-- | Unloading old objects ready for a new compilation sweep.
--   
--   The compilation manager provides us with a list of linkables that it
--   considers "stable", i.e. won't be recompiled this time around. For
--   each of the modules current linked in memory,
--   
--   <ul>
--   <li>if the linkable is stable (and it's the same one -- the user may
--   have recompiled the module on the side), we keep it,</li>
--   <li>otherwise, we unload it.</li>
--   <li>we also implicitly unload all temporary bindings at this
--   point.</li>
--   </ul>
unload :: DynFlags -> [Linkable] -> IO ()

-- | Temporarily extend the linker state.
withExtendedLinkEnv :: (MonadIO m, ExceptionMonad m) => [(Name, HValue)] -> m a -> m a
extendLinkEnv :: [(Name, HValue)] -> IO ()
deleteFromLinkEnv :: [Name] -> IO ()
extendLoadedPkgs :: [PackageId] -> IO ()

-- | Link exactly the specified packages, and their dependents (unless of
--   course they are already linked). The dependents are linked
--   automatically, and it doesn't matter what order you specify the input
--   packages.
linkPackages :: DynFlags -> [PackageId] -> IO ()

-- | Initialise the dynamic linker. This entails
--   
--   a) Calling the C initialisation procedure,
--   
--   b) Loading any packages specified on the command line,
--   
--   c) Loading any packages specified on the command line, now held in the
--   <tt>-l</tt> options in <tt>v_Opt_l</tt>,
--   
--   d) Loading any <tt>.o/.dll</tt> files specified on the command line,
--   now held in <tt>v_Ld_inputs</tt>,
--   
--   e) Loading any MacOS frameworks.
--   
--   NOTE: This function is idempotent; if called more than once, it does
--   nothing. This is useful in Template Haskell, where we call it before
--   trying to link.
initDynLinker :: DynFlags -> IO ()
linkModule :: HscEnv -> Module -> IO ()
data PersistentLinkerState
saveLinkerGlobals :: IO (MVar PersistentLinkerState, Bool)
restoreLinkerGlobals :: (MVar PersistentLinkerState, Bool) -> IO ()

module CoreMonad
data CoreToDo
CoreDoSimplify :: Int -> SimplifierMode -> CoreToDo
CoreDoPluginPass :: String -> PluginPass -> CoreToDo
CoreDoFloatInwards :: CoreToDo
CoreDoFloatOutwards :: FloatOutSwitches -> CoreToDo
CoreLiberateCase :: CoreToDo
CoreDoPrintCore :: CoreToDo
CoreDoStaticArgs :: CoreToDo
CoreDoStrictness :: CoreToDo
CoreDoWorkerWrapper :: CoreToDo
CoreDoSpecialising :: CoreToDo
CoreDoSpecConstr :: CoreToDo
CoreCSE :: CoreToDo
CoreDoRuleCheck :: CompilerPhase -> String -> CoreToDo
CoreDoVectorisation :: CoreToDo
CoreDoNothing :: CoreToDo
CoreDoPasses :: [CoreToDo] -> CoreToDo
CoreDesugar :: CoreToDo
CoreDesugarOpt :: CoreToDo
CoreTidy :: CoreToDo
CorePrep :: CoreToDo
runWhen :: Bool -> CoreToDo -> CoreToDo
runMaybe :: Maybe a -> (a -> CoreToDo) -> CoreToDo
data SimplifierMode
SimplMode :: [String] -> CompilerPhase -> Bool -> Bool -> Bool -> Bool -> SimplifierMode
sm_names :: SimplifierMode -> [String]
sm_phase :: SimplifierMode -> CompilerPhase
sm_rules :: SimplifierMode -> Bool
sm_inline :: SimplifierMode -> Bool
sm_case_case :: SimplifierMode -> Bool
sm_eta_expand :: SimplifierMode -> Bool
data FloatOutSwitches
FloatOutSwitches :: Maybe Int -> Bool -> Bool -> FloatOutSwitches

-- | Just n <a>=</a> float lambdas to top level, if doing so will abstract
--   over n or fewer value variables Nothing <a>=</a> float all lambdas to
--   top level, regardless of how many free variables Just 0 is the vanilla
--   case: float a lambda iff it has no free vars
floatOutLambdas :: FloatOutSwitches -> Maybe Int

-- | True <a>=</a> float constants to top level, even if they do not escape
--   a lambda
floatOutConstants :: FloatOutSwitches -> Bool

-- | True <a>=</a> float out partial applications based on arity
--   information.
floatOutPartialApplications :: FloatOutSwitches -> Bool
dumpSimplPhase :: DynFlags -> SimplifierMode -> Bool
pprPassDetails :: CoreToDo -> SDoc

-- | A description of the plugin pass itself
type PluginPass = ModGuts -> CoreM ModGuts

-- | <a>Plugin</a> is the core compiler plugin data type. Try to avoid
--   constructing one of these directly, and just modify some fields of
--   <a>defaultPlugin</a> instead: this is to try and preserve source-code
--   compatability when we add fields to this.
--   
--   Nonetheless, this API is preliminary and highly likely to change in
--   the future.
data Plugin
Plugin :: ([CommandLineOption] -> [CoreToDo] -> CoreM [CoreToDo]) -> Plugin

-- | Modify the Core pipeline that will be used for compilation. This is
--   called as the Core pipeline is built for every module being compiled,
--   and plugins get the opportunity to modify the pipeline in a
--   nondeterministic order.
installCoreToDos :: Plugin -> [CommandLineOption] -> [CoreToDo] -> CoreM [CoreToDo]

-- | Command line options gathered from the -PModule.Name:stuff syntax are
--   given to you as this type
type CommandLineOption = String

-- | Default plugin: does nothing at all! For compatability reasons you
--   should base all your plugin definitions on this default value.
defaultPlugin :: Plugin
bindsOnlyPass :: (CoreProgram -> CoreM CoreProgram) -> ModGuts -> CoreM ModGuts
data SimplCount
doSimplTick :: Tick -> SimplCount -> SimplCount
doFreeSimplTick :: Tick -> SimplCount -> SimplCount
simplCountN :: SimplCount -> Int
pprSimplCount :: SimplCount -> SDoc
plusSimplCount :: SimplCount -> SimplCount -> SimplCount
zeroSimplCount :: DynFlags -> SimplCount
isZeroSimplCount :: SimplCount -> Bool
hasDetailedCounts :: SimplCount -> Bool
data Tick
PreInlineUnconditionally :: Id -> Tick
PostInlineUnconditionally :: Id -> Tick
UnfoldingDone :: Id -> Tick
RuleFired :: FastString -> Tick
LetFloatFromLet :: Tick
EtaExpansion :: Id -> Tick
EtaReduction :: Id -> Tick
BetaReduction :: Id -> Tick
CaseOfCase :: Id -> Tick
KnownBranch :: Id -> Tick
CaseMerge :: Id -> Tick
AltMerge :: Id -> Tick
CaseElim :: Id -> Tick
CaseIdentity :: Id -> Tick
FillInCaseDefault :: Id -> Tick
BottomFound :: Tick
SimplifierDone :: Tick

-- | The monad used by Core-to-Core passes to access common state, register
--   simplification statistics and so on
data CoreM a
runCoreM :: HscEnv -> RuleBase -> UniqSupply -> Module -> CoreM a -> IO (a, SimplCount)
getHscEnv :: CoreM HscEnv
getRuleBase :: CoreM RuleBase
getModule :: CoreM Module
getDynFlags :: HasDynFlags m => m DynFlags

-- | The original name cache is the current mapping from <a>Module</a> and
--   <tt>OccName</tt> to a compiler-wide unique <a>Name</a>
getOrigNameCache :: CoreM OrigNameCache
addSimplCount :: SimplCount -> CoreM ()
liftIO :: MonadIO m => IO a -> m a

-- | Lift an <a>IO</a> operation into <a>CoreM</a> while consuming its
--   <a>SimplCount</a>
liftIOWithCount :: IO (SimplCount, a) -> CoreM a

-- | Lift an <a>IO</a> operation with 1 argument into another monad
liftIO1 :: MonadIO m => (a -> IO b) -> a -> m b

-- | Lift an <a>IO</a> operation with 2 arguments into another monad
liftIO2 :: MonadIO m => (a -> b -> IO c) -> a -> b -> m c

-- | Lift an <a>IO</a> operation with 3 arguments into another monad
liftIO3 :: MonadIO m => (a -> b -> c -> IO d) -> a -> b -> c -> m d

-- | Lift an <a>IO</a> operation with 4 arguments into another monad
liftIO4 :: MonadIO m => (a -> b -> c -> d -> IO e) -> a -> b -> c -> d -> m e
reinitializeGlobals :: CoreM ()

-- | Get all annotations of a given type. This happens lazily, that is no
--   deserialization will take place until the [a] is actually demanded and
--   the [a] can also be empty (the UniqFM is not filtered).
--   
--   This should be done once at the start of a Core-to-Core pass that uses
--   annotations.
--   
--   See Note [Annotations]
getAnnotations :: Typeable a => ([Word8] -> a) -> ModGuts -> CoreM (UniqFM [a])

-- | Get at most one annotation of a given type per Unique.
getFirstAnnotations :: Typeable a => ([Word8] -> a) -> ModGuts -> CoreM (UniqFM a)
showPass :: DynFlags -> CoreToDo -> IO ()
endPass :: DynFlags -> CoreToDo -> CoreProgram -> [CoreRule] -> IO ()
dumpPassResult :: DynFlags -> Maybe DynFlag -> SDoc -> SDoc -> CoreProgram -> [CoreRule] -> IO ()
lintPassResult :: DynFlags -> CoreToDo -> CoreProgram -> IO ()
dumpIfSet :: DynFlags -> Bool -> CoreToDo -> SDoc -> SDoc -> IO ()

-- | Output a message to the screen
putMsg :: SDoc -> CoreM ()

-- | Output a String message to the screen
putMsgS :: String -> CoreM ()

-- | Output an error to the screen
errorMsg :: SDoc -> CoreM ()

-- | Output a string error to the screen
errorMsgS :: String -> CoreM ()

-- | Output a fatal error to the screen. Note this does not by itself cause
--   the compiler to die
fatalErrorMsg :: SDoc -> CoreM ()

-- | Output a fatal string error to the screen. Note this does not by
--   itself cause the compiler to die
fatalErrorMsgS :: String -> CoreM ()

-- | Outputs a debugging message at verbosity level of <tt>-v</tt> or
--   higher
debugTraceMsg :: SDoc -> CoreM ()

-- | Output a string debugging message at verbosity level of <tt>-v</tt> or
--   higher
debugTraceMsgS :: String -> CoreM ()

-- | Show some labelled <a>SDoc</a> if a particular flag is set or at a
--   verbosity level of <tt>-v -ddump-most</tt> or higher
dumpIfSet_dyn :: DynFlag -> String -> SDoc -> CoreM ()

-- | Attempt to convert a Template Haskell name to one that GHC can
--   understand. Original TH names such as those you get when you use the
--   <tt>'foo</tt> syntax will be translated to their equivalent GHC name
--   exactly. Qualified or unqualifed TH names will be dynamically bound to
--   names in the module being compiled, if possible. Exact TH names will
--   be bound to the name they represent, exactly.
thNameToGhcName :: Name -> CoreM (Maybe Name)
instance MonadThings CoreM
instance HasDynFlags CoreM
instance MonadIO CoreM
instance MonadUnique CoreM
instance MonadPlus IO => MonadPlus CoreM
instance Applicative CoreM
instance Monad CoreM
instance Functor CoreM
instance Ord Tick
instance Eq Tick
instance Outputable Tick
instance Outputable FloatOutSwitches
instance Outputable SimplifierMode
instance Outputable CoreToDo

module CorePrep
corePrepPgm :: DynFlags -> HscEnv -> CoreProgram -> [TyCon] -> IO CoreProgram
corePrepExpr :: DynFlags -> HscEnv -> CoreExpr -> IO CoreExpr
cvtLitInteger :: Id -> Integer -> CoreExpr
instance Outputable OkToSpec
instance Outputable Floats
instance Outputable FloatingBind

module TidyPgm
mkBootModDetailsTc :: HscEnv -> TcGblEnv -> IO ModDetails
tidyProgram :: HscEnv -> ModGuts -> IO (CgGuts, ModDetails)
globaliseAndTidyId :: Id -> Id
instance Monad DFFV


-- | This module is not used by GHC itself. Rather, it exports all of the
--   functions and types you are likely to need when writing a plugin for
--   GHC. So authors of plugins can probably get away simply with saying
--   <a>import GhcPlugins</a>.
--   
--   Particularly interesting modules for plugin writers include
--   <a>CoreSyn</a> and <a>CoreMonad</a>.
module GhcPlugins

module SetLevels
setLevels :: FloatOutSwitches -> CoreProgram -> UniqSupply -> [LevelledBind]
data Level
Level :: Int -> Int -> Level
tOP_LEVEL :: Level
type LevelledBind = TaggedBind FloatSpec
type LevelledExpr = TaggedExpr FloatSpec
type LevelledBndr = TaggedBndr FloatSpec
data FloatSpec
FloatMe :: Level -> FloatSpec
StayPut :: Level -> FloatSpec
floatSpecLevel :: FloatSpec -> Level
incMinorLvl :: Level -> Level
ltMajLvl :: Level -> Level -> Bool
ltLvl :: Level -> Level -> Bool
isTopLvl :: Level -> Bool
instance Eq Level
instance Outputable Level
instance Outputable FloatSpec

module FloatOut
floatOutwards :: FloatOutSwitches -> DynFlags -> UniqSupply -> CoreProgram -> IO CoreProgram
instance Outputable FloatBinds
instance Outputable FloatBind

module SimplMonad
data SimplM result
initSmpl :: DynFlags -> RuleBase -> (FamInstEnv, FamInstEnv) -> UniqSupply -> Int -> SimplM a -> IO (a, SimplCount)
getSimplRules :: SimplM RuleBase
getFamEnvs :: SimplM (FamInstEnv, FamInstEnv)

-- | A monad for generating unique identifiers
class Monad m => MonadUnique m where getUniqueM = liftM uniqFromSupply getUniqueSupplyM getUniquesM = liftM uniqsFromSupply getUniqueSupplyM
getUniqueSupplyM :: MonadUnique m => m UniqSupply
getUniqueM :: MonadUnique m => m Unique
getUniquesM :: MonadUnique m => m [Unique]
newId :: FastString -> Type -> SimplM Id
data SimplCount
tick :: Tick -> SimplM ()
freeTick :: Tick -> SimplM ()
checkedTick :: Tick -> SimplM ()
getSimplCount :: SimplM SimplCount
zeroSimplCount :: DynFlags -> SimplCount
pprSimplCount :: SimplCount -> SDoc
plusSimplCount :: SimplCount -> SimplCount -> SimplCount
isZeroSimplCount :: SimplCount -> Bool
instance MonadIO SimplM
instance HasDynFlags SimplM
instance MonadUnique SimplM
instance Monad SimplM

module SimplEnv
type InId = Id
type InBind = CoreBind
type InExpr = CoreExpr
type InAlt = CoreAlt
type InArg = CoreArg
type InType = Type
type InBndr = CoreBndr
type InVar = Var
type OutId = Id
type OutTyVar = TyVar
type OutBind = CoreBind
type OutExpr = CoreExpr
type OutAlt = CoreAlt
type OutArg = CoreArg
type OutType = Type
type OutBndr = CoreBndr
type OutVar = Var
type InCoercion = Coercion
type OutCoercion = Coercion
setMode :: SimplifierMode -> SimplEnv -> SimplEnv
getMode :: SimplEnv -> SimplifierMode
updMode :: (SimplifierMode -> SimplifierMode) -> SimplEnv -> SimplEnv
data SimplEnv
SimplEnv :: SimplifierMode -> TvSubstEnv -> CvSubstEnv -> SimplIdSubst -> InScopeSet -> Floats -> SimplEnv
seMode :: SimplEnv -> SimplifierMode
seTvSubst :: SimplEnv -> TvSubstEnv
seCvSubst :: SimplEnv -> CvSubstEnv
seIdSubst :: SimplEnv -> SimplIdSubst
seInScope :: SimplEnv -> InScopeSet
seFloats :: SimplEnv -> Floats
type StaticEnv = SimplEnv
pprSimplEnv :: SimplEnv -> SDoc
mkSimplEnv :: SimplifierMode -> SimplEnv
extendIdSubst :: SimplEnv -> Id -> SimplSR -> SimplEnv
extendTvSubst :: SimplEnv -> TyVar -> Type -> SimplEnv
extendCvSubst :: SimplEnv -> CoVar -> Coercion -> SimplEnv
zapSubstEnv :: SimplEnv -> SimplEnv
setSubstEnv :: SimplEnv -> TvSubstEnv -> CvSubstEnv -> SimplIdSubst -> SimplEnv
getInScope :: SimplEnv -> InScopeSet
setInScope :: SimplEnv -> SimplEnv -> SimplEnv
setInScopeSet :: SimplEnv -> InScopeSet -> SimplEnv
modifyInScope :: SimplEnv -> CoreBndr -> SimplEnv
addNewInScopeIds :: SimplEnv -> [CoreBndr] -> SimplEnv
getSimplRules :: SimplM RuleBase
data SimplSR
DoneEx :: OutExpr -> SimplSR
DoneId :: OutId -> SimplSR
ContEx :: TvSubstEnv -> CvSubstEnv -> SimplIdSubst -> InExpr -> SimplSR
mkContEx :: SimplEnv -> InExpr -> SimplSR
substId :: SimplEnv -> InId -> SimplSR
lookupRecBndr :: SimplEnv -> InId -> OutId
simplNonRecBndr :: SimplEnv -> InBndr -> SimplM (SimplEnv, OutBndr)
simplRecBndrs :: SimplEnv -> [InBndr] -> SimplM SimplEnv
simplLamBndr :: SimplEnv -> Var -> SimplM (SimplEnv, Var)
simplLamBndrs :: SimplEnv -> [InBndr] -> SimplM (SimplEnv, [OutBndr])
simplBinder :: SimplEnv -> InBndr -> SimplM (SimplEnv, OutBndr)
simplBinders :: SimplEnv -> [InBndr] -> SimplM (SimplEnv, [OutBndr])
addBndrRules :: SimplEnv -> InBndr -> OutBndr -> (SimplEnv, OutBndr)
substExpr :: SDoc -> SimplEnv -> CoreExpr -> CoreExpr
substTy :: SimplEnv -> Type -> Type
substTyVar :: SimplEnv -> TyVar -> Type
getTvSubst :: SimplEnv -> TvSubst
getCvSubst :: SimplEnv -> CvSubst
substCo :: SimplEnv -> Coercion -> Coercion
substCoVar :: SimplEnv -> CoVar -> Coercion
mkCoreSubst :: SDoc -> SimplEnv -> Subst
data Floats
emptyFloats :: Floats
isEmptyFloats :: SimplEnv -> Bool
addNonRec :: SimplEnv -> OutId -> OutExpr -> SimplEnv
addFloats :: SimplEnv -> SimplEnv -> SimplEnv
extendFloats :: SimplEnv -> OutBind -> SimplEnv
wrapFloats :: SimplEnv -> OutExpr -> OutExpr
floatBinds :: Floats -> [OutBind]
setFloats :: SimplEnv -> SimplEnv -> SimplEnv
zapFloats :: SimplEnv -> SimplEnv
addRecFloats :: SimplEnv -> SimplEnv -> SimplEnv
doFloatFromRhs :: TopLevelFlag -> RecFlag -> Bool -> OutExpr -> SimplEnv -> Bool
getFloatBinds :: SimplEnv -> [CoreBind]
getFloats :: SimplEnv -> Floats
mapFloats :: SimplEnv -> ((Id, CoreExpr) -> (Id, CoreExpr)) -> SimplEnv
instance Outputable FloatFlag
instance Outputable Floats
instance Outputable SimplSR

module SimplUtils
mkLam :: SimplEnv -> [OutBndr] -> OutExpr -> SimplM OutExpr
mkCase :: DynFlags -> OutExpr -> OutId -> OutType -> [OutAlt] -> SimplM OutExpr
prepareAlts :: OutExpr -> OutId -> [InAlt] -> SimplM ([AltCon], [InAlt])
tryEtaExpand :: SimplEnv -> OutId -> OutExpr -> SimplM (Arity, OutExpr)
preInlineUnconditionally :: SimplEnv -> TopLevelFlag -> InId -> InExpr -> Bool
postInlineUnconditionally :: SimplEnv -> TopLevelFlag -> OutId -> OccInfo -> OutExpr -> Unfolding -> Bool
activeUnfolding :: SimplEnv -> Id -> Bool
activeRule :: SimplEnv -> Activation -> Bool
getUnfoldingInRuleMatch :: SimplEnv -> IdUnfoldingFun
simplEnvForGHCi :: DynFlags -> SimplEnv
updModeForInlineRules :: Activation -> SimplifierMode -> SimplifierMode
data SimplCont
Stop :: OutType -> CallCtxt -> SimplCont
CoerceIt :: OutCoercion -> SimplCont -> SimplCont
ApplyTo :: DupFlag -> InExpr -> StaticEnv -> SimplCont -> SimplCont
Select :: DupFlag -> InId -> [InAlt] -> StaticEnv -> SimplCont -> SimplCont
StrictBind :: InId -> [InBndr] -> InExpr -> StaticEnv -> SimplCont -> SimplCont
StrictArg :: ArgInfo -> CallCtxt -> SimplCont -> SimplCont
TickIt :: (Tickish Id) -> SimplCont -> SimplCont
data DupFlag
NoDup :: DupFlag
Simplified :: DupFlag
OkToDup :: DupFlag
data ArgInfo
ArgInfo :: OutId -> [OutExpr] -> OutType -> [CoreRule] -> Bool -> [Bool] -> [Int] -> ArgInfo
ai_fun :: ArgInfo -> OutId
ai_args :: ArgInfo -> [OutExpr]
ai_type :: ArgInfo -> OutType
ai_rules :: ArgInfo -> [CoreRule]
ai_encl :: ArgInfo -> Bool
ai_strs :: ArgInfo -> [Bool]
ai_discs :: ArgInfo -> [Int]
isSimplified :: DupFlag -> Bool
contIsDupable :: SimplCont -> Bool
contResultType :: SimplCont -> OutType
contInputType :: SimplCont -> OutType
contIsTrivial :: SimplCont -> Bool
contArgs :: SimplCont -> (Bool, [ArgSummary], SimplCont)
dropArgs :: Int -> SimplCont -> SimplCont
pushSimplifiedArgs :: SimplEnv -> [CoreExpr] -> SimplCont -> SimplCont
countValArgs :: SimplCont -> Int
countArgs :: SimplCont -> Int
addArgTo :: ArgInfo -> OutExpr -> ArgInfo
mkBoringStop :: OutType -> SimplCont
mkRhsStop :: OutType -> SimplCont
mkLazyArgStop :: OutType -> CallCtxt -> SimplCont
contIsRhsOrArg :: SimplCont -> Bool
interestingCallContext :: SimplCont -> CallCtxt
interestingArg :: CoreExpr -> ArgSummary
mkArgInfo :: Id -> [CoreRule] -> Int -> SimplCont -> ArgInfo
abstractFloats :: [OutTyVar] -> SimplEnv -> OutExpr -> SimplM ([OutBind], OutExpr)
instance Outputable DupFlag
instance Outputable SimplCont

module Simplify
simplTopBinds :: SimplEnv -> [InBind] -> SimplM SimplEnv
simplExpr :: SimplEnv -> CoreExpr -> SimplM CoreExpr

module Specialise
specProgram :: DynFlags -> ModGuts -> CoreM ModGuts
instance HasDynFlags SpecM
instance MonadUnique SpecM
instance Monad SpecM
instance Ord CallKey
instance Eq CallKey
instance Outputable CallKey
instance Outputable CallInfoSet
instance Outputable UsageDetails

module SpecConstr
specConstrProgram :: ModGuts -> CoreM ModGuts
data SpecConstrAnnotation :: *
NoSpecConstr :: SpecConstrAnnotation
ForceSpecConstr :: SpecConstrAnnotation
instance Outputable ArgOcc
instance Outputable HowBound
instance Outputable Value

module Vectorise

-- | Vectorise a single module.
vectorise :: ModGuts -> CoreM ModGuts

module RtClosureInspect
cvObtainTerm :: HscEnv -> Int -> Bool -> RttiType -> HValue -> IO Term
cvReconstructType :: HscEnv -> Int -> GhciType -> HValue -> IO (Maybe Type)
improveRTTIType :: HscEnv -> RttiType -> RttiType -> Maybe TvSubst
data Term
Term :: RttiType -> Either String DataCon -> HValue -> [Term] -> Term
ty :: Term -> RttiType
dc :: Term -> Either String DataCon
val :: Term -> HValue
subTerms :: Term -> [Term]
Prim :: RttiType -> [Word] -> Term
ty :: Term -> RttiType
value :: Term -> [Word]
Suspension :: ClosureType -> RttiType -> HValue -> Maybe Name -> Term
ctype :: Term -> ClosureType
ty :: Term -> RttiType
val :: Term -> HValue
bound_to :: Term -> Maybe Name
NewtypeWrap :: RttiType -> Either String DataCon -> Term -> Term
ty :: Term -> RttiType
dc :: Term -> Either String DataCon
wrapped_term :: Term -> Term
RefWrap :: RttiType -> Term -> Term
ty :: Term -> RttiType
wrapped_term :: Term -> Term
isTerm :: Term -> Bool
isSuspension :: Term -> Bool
isPrim :: Term -> Bool
isFun :: Term -> Bool
isFunLike :: Term -> Bool
isNewtypeWrap :: Term -> Bool
isFullyEvaluated :: a -> IO Bool
isFullyEvaluatedTerm :: Term -> Bool
termType :: Term -> RttiType
mapTermType :: (RttiType -> Type) -> Term -> Term
termTyVars :: Term -> TyVarSet
foldTerm :: TermFold a -> Term -> a
data TermFold a
TermFold :: TermProcessor a a -> (RttiType -> [Word] -> a) -> (ClosureType -> RttiType -> HValue -> Maybe Name -> a) -> (RttiType -> Either String DataCon -> a -> a) -> (RttiType -> a -> a) -> TermFold a
fTerm :: TermFold a -> TermProcessor a a
fPrim :: TermFold a -> RttiType -> [Word] -> a
fSuspension :: TermFold a -> ClosureType -> RttiType -> HValue -> Maybe Name -> a
fNewtypeWrap :: TermFold a -> RttiType -> Either String DataCon -> a -> a
fRefWrap :: TermFold a -> RttiType -> a -> a
foldTermM :: Monad m => TermFoldM m a -> Term -> m a
data TermFoldM m a
TermFoldM :: TermProcessor a (m a) -> (RttiType -> [Word] -> m a) -> (ClosureType -> RttiType -> HValue -> Maybe Name -> m a) -> (RttiType -> Either String DataCon -> a -> m a) -> (RttiType -> a -> m a) -> TermFoldM m a
fTermM :: TermFoldM m a -> TermProcessor a (m a)
fPrimM :: TermFoldM m a -> RttiType -> [Word] -> m a
fSuspensionM :: TermFoldM m a -> ClosureType -> RttiType -> HValue -> Maybe Name -> m a
fNewtypeWrapM :: TermFoldM m a -> RttiType -> Either String DataCon -> a -> m a
fRefWrapM :: TermFoldM m a -> RttiType -> a -> m a
idTermFold :: TermFold Term
pprTerm :: TermPrinter -> TermPrinter

-- | Takes a list of custom printers with a explicit recursion knot and a
--   term, and returns the output of the first succesful printer, or the
--   default printer
cPprTerm :: Monad m => CustomTermPrinter m -> Term -> m SDoc
cPprTermBase :: Monad m => CustomTermPrinter m
type CustomTermPrinter m = TermPrinterM m -> [Precedence -> Term -> (m (Maybe SDoc))]
data Closure
Closure :: ClosureType -> Ptr () -> StgInfoTable -> Array Int HValue -> [Word] -> Closure
tipe :: Closure -> ClosureType
infoPtr :: Closure -> Ptr ()
infoTable :: Closure -> StgInfoTable
ptrs :: Closure -> Array Int HValue
nonPtrs :: Closure -> [Word]
getClosureData :: a -> IO Closure
data ClosureType
Constr :: ClosureType
Fun :: ClosureType
Thunk :: Int -> ClosureType
ThunkSelector :: ClosureType
Blackhole :: ClosureType
AP :: ClosureType
PAP :: ClosureType
Indirection :: Int -> ClosureType
MutVar :: Int -> ClosureType
MVar :: Int -> ClosureType
Other :: Int -> ClosureType
isConstr :: ClosureType -> Bool
isIndirection :: ClosureType -> Bool
instance Show ClosureType
instance Eq ClosureType
instance Outputable ClosureType
instance Outputable Term

module RnNames

-- | Process Import Decls Do the non SOURCE ones first, so that we get a
--   helpful warning for SOURCE ones that are unnecessary
rnImports :: [LImportDecl RdrName] -> RnM ([LImportDecl Name], GlobalRdrEnv, ImportAvails, AnyHpcUsage)
getLocalNonValBinders :: MiniFixityEnv -> HsGroup RdrName -> RnM ((TcGblEnv, TcLclEnv), NameSet)
rnExports :: Bool -> Maybe [LIE RdrName] -> TcGblEnv -> RnM TcGblEnv
extendGlobalRdrEnvRn :: [AvailInfo] -> MiniFixityEnv -> RnM (TcGblEnv, TcLclEnv)

-- | make a <a>GlobalRdrEnv</a> where all the elements point to the same
--   Provenance (useful for <a>hiding</a> imports, or imports with no
--   details).
gresFromAvails :: Provenance -> [AvailInfo] -> [GlobalRdrElt]
reportUnusedNames :: Maybe [LIE RdrName] -> TcGblEnv -> RnM ()

module RnSource
rnSrcDecls :: [Name] -> HsGroup RdrName -> RnM (TcGblEnv, HsGroup Name)
addTcgDUs :: TcGblEnv -> DefUses -> TcGblEnv
rnTyClDecls :: [Name] -> [[LTyClDecl RdrName]] -> RnM ([[LTyClDecl Name]], FreeVars)
findSplice :: [LHsDecl RdrName] -> RnM (HsGroup RdrName, Maybe (SpliceDecl RdrName, [LHsDecl RdrName]))

module RnExpr
rnLExpr :: LHsExpr RdrName -> RnM (LHsExpr Name, FreeVars)
rnExpr :: HsExpr RdrName -> RnM (HsExpr Name, FreeVars)
rnStmts :: HsStmtContext Name -> [LStmt RdrName] -> ([Name] -> RnM (thing, FreeVars)) -> RnM (([LStmt Name], thing), FreeVars)

module TcDeriv
tcDeriving :: [LTyClDecl Name] -> [LInstDecl Name] -> [LDerivDecl Name] -> TcM (TcGblEnv, Bag (InstInfo Name), HsValBinds Name)
instance Outputable DerivSpec

module TcInstDcls
tcInstDecls1 :: [LTyClDecl Name] -> [LInstDecl Name] -> [LDerivDecl Name] -> TcM (TcGblEnv, [InstInfo Name], HsValBinds Name)
tcInstDecls2 :: [LTyClDecl Name] -> [InstInfo Name] -> TcM (LHsBinds Id)


-- | This module manages storing the various GHC option flags in a modules
--   interface file as part of the recompilation checking infrastructure.
module FlagChecker

-- | Produce a fingerprint of a <tt>DynFlags</tt> value. We only base the
--   finger print on important fields in <tt>DynFlags</tt> so that the
--   recompilation checker can use this fingerprint.
fingerprintDynFlags :: DynFlags -> Module -> (BinHandle -> Name -> IO ()) -> IO Fingerprint


-- | Module for constructing <tt>ModIface</tt> values (interface files),
--   writing them to disk and comparing two versions to see if
--   recompilation is required.
module MkIface
mkUsedNames :: TcGblEnv -> NameSet

-- | Extract information from the rename and typecheck phases to produce a
--   dependencies information for the module being compiled.
mkDependencies :: TcGblEnv -> IO Dependencies
mkIface :: HscEnv -> Maybe Fingerprint -> ModDetails -> ModGuts -> IO (Messages, Maybe (ModIface, Bool))

-- | make an interface from the results of typechecking only. Useful for
--   non-optimising compilation, or where we aren't generating any object
--   code at all (<a>HscNothing</a>).
mkIfaceTc :: HscEnv -> Maybe Fingerprint -> SafeHaskellMode -> ModDetails -> TcGblEnv -> IO (Messages, Maybe (ModIface, Bool))
writeIfaceFile :: DynFlags -> ModLocation -> ModIface -> IO ()

-- | Top level function to check if the version of an old interface file is
--   equivalent to the current source file the user asked us to compile. If
--   the same, we can avoid recompilation. We return a tuple where the
--   first element is a bool saying if we should recompile the object file
--   and the second is maybe the interface file, where Nothng means to
--   rebuild the interface file not use the exisitng one.
checkOldIface :: HscEnv -> ModSummary -> SourceModified -> Maybe ModIface -> IO (RecompileRequired, Maybe ModIface)
data RecompileRequired

-- | everything is up to date, recompilation is not required
UpToDate :: RecompileRequired

-- | The .hs file has been touched, or the .o/.hi file does not exist
MustCompile :: RecompileRequired

-- | The .o/.hi files are up to date, but something else has changed to
--   force recompilation; the String says what (one-line summary)
RecompBecause :: String -> RecompileRequired
recompileRequired :: RecompileRequired -> Bool
tyThingToIfaceDecl :: TyThing -> IfaceDecl
instance Eq RecompileRequired
instance Binary IfaceDeclExtras
instance Outputable IfaceDeclExtras

module Desugar

-- | Main entry point to the desugarer.
deSugar :: HscEnv -> ModLocation -> TcGblEnv -> IO (Messages, Maybe ModGuts)
deSugarExpr :: HscEnv -> Module -> GlobalRdrEnv -> TypeEnv -> LHsExpr Id -> IO (Messages, Maybe CoreExpr)

module TcForeign
tcForeignImports :: [LForeignDecl Name] -> TcM ([Id], [LForeignDecl Id])
tcForeignExports :: [LForeignDecl Name] -> TcM (LHsBinds TcId, [LForeignDecl TcId])

module TcRnDriver

-- | The returned [Id] is the list of new Ids bound by this statement. It
--   can be used to extend the InteractiveContext via
--   extendInteractiveContext.
--   
--   The returned TypecheckedHsExpr is of type IO [ () ], a list of the
--   bound values, coerced to ().
tcRnStmt :: HscEnv -> InteractiveContext -> LStmt RdrName -> IO (Messages, Maybe ([Id], LHsExpr Id, FixityEnv))
tcRnExpr :: HscEnv -> InteractiveContext -> LHsExpr RdrName -> IO (Messages, Maybe Type)
tcRnType :: HscEnv -> InteractiveContext -> Bool -> LHsType RdrName -> IO (Messages, Maybe (Type, Kind))
tcRnImportDecls :: HscEnv -> [LImportDecl RdrName] -> IO (Messages, Maybe GlobalRdrEnv)
tcRnLookupRdrName :: HscEnv -> RdrName -> IO (Messages, Maybe [Name])

-- | ASSUMES that the module is either in the <a>HomePackageTable</a> or is
--   a package module with an interface on disk. If neither of these is
--   true, then the result will be an error indicating the interface could
--   not be found.
getModuleInterface :: HscEnv -> Module -> IO (Messages, Maybe ModIface)
tcRnDeclsi :: HscEnv -> InteractiveContext -> [LHsDecl RdrName] -> IO (Messages, Maybe TcGblEnv)
isGHCiMonad :: HscEnv -> InteractiveContext -> String -> IO (Messages, Maybe Name)
tcRnLookupName :: HscEnv -> Name -> IO (Messages, Maybe TyThing)
tcRnGetInfo :: HscEnv -> Name -> IO (Messages, Maybe (TyThing, Fixity, [ClsInst]))

-- | Top level entry point for typechecker and renamer
tcRnModule :: HscEnv -> HscSource -> Bool -> HsParsedModule -> IO (Messages, Maybe TcGblEnv)
tcTopSrcDecls :: ModDetails -> HsGroup Name -> TcM (TcGblEnv, TcLclEnv)
tcRnExtCore :: HscEnv -> HsExtCore RdrName -> IO (Messages, Maybe ModGuts)


-- | Dynamically lookup up values from modules and loading them.
module DynamicLoading

-- | Force the interfaces for the given modules to be loaded. The
--   <a>SDoc</a> parameter is used for debugging (<tt>-ddump-if-trace</tt>)
--   only: it is shown as the reason why the module is being loaded.
forceLoadModuleInterfaces :: HscEnv -> SDoc -> [Module] -> IO ()

-- | Force the interface for the module containing the name to be loaded.
--   The <a>SDoc</a> parameter is used for debugging
--   (<tt>-ddump-if-trace</tt>) only: it is shown as the reason why the
--   module is being loaded.
forceLoadNameModuleInterface :: HscEnv -> SDoc -> Name -> IO ()

-- | Load the <a>TyCon</a> associated with the given name, come hell or
--   high water. Fails if:
--   
--   <ul>
--   <li>The interface could not be loaded * The name is not that of a
--   <a>TyCon</a> * The name did not exist in the loaded module</li>
--   </ul>
forceLoadTyCon :: HscEnv -> Name -> IO TyCon

-- | Finds the <a>Name</a> corresponding to the given <a>RdrName</a> in the
--   context of the <a>ModuleName</a>. Returns <tt>Nothing</tt> if no such
--   <a>Name</a> could be found. Any other condition results in an
--   exception:
--   
--   <ul>
--   <li>If the module could not be found * If we could not determine the
--   imports of the module</li>
--   </ul>
lookupRdrNameInModule :: HscEnv -> ModuleName -> RdrName -> IO (Maybe Name)

-- | Loads the value corresponding to a <a>Name</a> if that value has the
--   given <a>Type</a>. This only provides limited safety in that it is up
--   to the user to ensure that that type corresponds to the type you try
--   to use the return value at!
--   
--   If the value found was not of the correct type, returns
--   <tt>Nothing</tt>. Any other condition results in an exception:
--   
--   <ul>
--   <li>If we could not load the names module * If the thing being loaded
--   is not a value * If the Name does not exist in the module * If the
--   link failed</li>
--   </ul>
getValueSafely :: HscEnv -> Name -> Type -> IO (Maybe a)

-- | Coerce a value as usual, but:
--   
--   1) Evaluate it immediately to get a segfault early if the coercion was
--   wrong
--   
--   2) Wrap it in some debug messages at verbosity 3 or higher so we can
--   see what happened if it <i>does</i> segfault
lessUnsafeCoerce :: DynFlags -> String -> a -> IO b

module SimplCore
core2core :: HscEnv -> ModGuts -> IO ModGuts
simplifyExpr :: DynFlags -> CoreExpr -> IO CoreExpr

module X86.Regs

-- | regSqueeze_class reg Calculuate the maximum number of register colors
--   that could be denied to a node of this class due to having this reg as
--   a neighbour.
virtualRegSqueeze :: RegClass -> VirtualReg -> FastInt
realRegSqueeze :: RegClass -> RealReg -> FastInt
data Imm
ImmInt :: Int -> Imm
ImmInteger :: Integer -> Imm
ImmCLbl :: CLabel -> Imm
ImmLit :: SDoc -> Imm
ImmIndex :: CLabel -> Int -> Imm
ImmFloat :: Rational -> Imm
ImmDouble :: Rational -> Imm
ImmConstantSum :: Imm -> Imm -> Imm
ImmConstantDiff :: Imm -> Imm -> Imm
strImmLit :: String -> Imm
litToImm :: CmmLit -> Imm
data AddrMode
AddrBaseIndex :: EABase -> EAIndex -> Displacement -> AddrMode
ImmAddr :: Imm -> Int -> AddrMode
addrOffset :: AddrMode -> Int -> Maybe AddrMode
spRel :: Platform -> Int -> AddrMode
argRegs :: RegNo -> [Reg]
allArgRegs :: [(Reg, Reg)]
allIntArgRegs :: [Reg]
allHaskellArgRegs :: [Reg]
callClobberedRegs :: [Reg]
instrClobberedRegs :: [RealReg]

-- | The complete set of machine registers.
allMachRegNos :: [RegNo]

-- | Take the class of a register.
classOfRealReg :: RealReg -> RegClass

-- | Get the name of the register with this number.
showReg :: Platform -> RegNo -> String
data EABase
EABaseNone :: EABase
EABaseReg :: Reg -> EABase
EABaseRip :: EABase
data EAIndex
EAIndexNone :: EAIndex
EAIndex :: Reg -> Int -> EAIndex
addrModeRegs :: AddrMode -> [Reg]
eax :: Reg
ebx :: Reg
ecx :: Reg
edx :: Reg
esi :: Reg
edi :: Reg
ebp :: Reg
esp :: Reg
fake0 :: Reg
fake1 :: Reg
fake2 :: Reg
fake3 :: Reg
fake4 :: Reg
fake5 :: Reg
firstfake :: RegNo
rax :: Reg
rbx :: Reg
rcx :: Reg
rdx :: Reg
rsi :: Reg
rdi :: Reg
rbp :: Reg
rsp :: Reg
r8 :: Reg
r9 :: Reg
r10 :: Reg
r11 :: Reg
r12 :: Reg
r13 :: Reg
r14 :: Reg
r15 :: Reg
xmm0 :: Reg
xmm1 :: Reg
xmm2 :: Reg
xmm3 :: Reg
xmm4 :: Reg
xmm5 :: Reg
xmm6 :: Reg
xmm7 :: Reg
xmm8 :: Reg
xmm9 :: Reg
xmm10 :: Reg
xmm11 :: Reg
xmm12 :: Reg
xmm13 :: Reg
xmm14 :: Reg
xmm15 :: Reg
xmm :: RegNo -> Reg
ripRel :: Displacement -> AddrMode
allFPArgRegs :: [Reg]
freeReg :: RegNo -> FastBool
globalRegMaybe :: GlobalReg -> Maybe RealReg
allocatableRegs :: [RealReg]


-- | Free regs map for i386 and x86_64
module RegAlloc.Linear.X86.FreeRegs
type FreeRegs = Word64
noFreeRegs :: FreeRegs
releaseReg :: RealReg -> FreeRegs -> FreeRegs
initFreeRegs :: FreeRegs
getFreeRegs :: RegClass -> FreeRegs -> [RealReg]
allocateReg :: RealReg -> FreeRegs -> FreeRegs

module RegAlloc.Graph.TrivColorable
trivColorable :: Platform -> (RegClass -> VirtualReg -> FastInt) -> (RegClass -> RealReg -> FastInt) -> Triv VirtualReg RegClass RealReg

module Instruction

-- | Holds a list of source and destination registers used by a particular
--   instruction.
--   
--   Machine registers that are pre-allocated to stgRegs are filtered out,
--   because they are uninteresting from a register allocation standpoint.
--   (We wouldn't want them to end up on the free list!)
--   
--   As far as we are concerned, the fixed registers simply don't exist
--   (for allocation purposes, anyway).
data RegUsage
RU :: [Reg] -> [Reg] -> RegUsage

-- | No regs read or written to.
noUsage :: RegUsage
type NatCmm instr = GenCmmGroup CmmStatics (Maybe CmmStatics) (ListGraph instr)
type NatCmmDecl statics instr = GenCmmDecl statics (Maybe CmmStatics) (ListGraph instr)
type NatBasicBlock instr = GenBasicBlock instr

-- | Common things that we can do with instructions, on all architectures.
--   These are used by the shared parts of the native code generator,
--   specifically the register allocators.
class Instruction instr
regUsageOfInstr :: Instruction instr => instr -> RegUsage
patchRegsOfInstr :: Instruction instr => instr -> (Reg -> Reg) -> instr
isJumpishInstr :: Instruction instr => instr -> Bool
jumpDestsOfInstr :: Instruction instr => instr -> [BlockId]
patchJumpInstr :: Instruction instr => instr -> (BlockId -> BlockId) -> instr
mkSpillInstr :: Instruction instr => Platform -> Reg -> Int -> Int -> instr
mkLoadInstr :: Instruction instr => Platform -> Reg -> Int -> Int -> instr
takeDeltaInstr :: Instruction instr => instr -> Maybe Int
isMetaInstr :: Instruction instr => instr -> Bool
mkRegRegMoveInstr :: Instruction instr => Platform -> Reg -> Reg -> instr
takeRegRegMoveInstr :: Instruction instr => instr -> Maybe (Reg, Reg)
mkJumpInstr :: Instruction instr => BlockId -> [instr]

module RegAlloc.Liveness
type RegSet = UniqSet Reg
type RegMap a = UniqFM a
emptyRegMap :: UniqFM a
type BlockMap a = BlockEnv a
emptyBlockMap :: BlockEnv a

-- | A top level thing which carries liveness information.
type LiveCmmDecl statics instr = GenCmmDecl statics LiveInfo [SCC (LiveBasicBlock instr)]

-- | The register allocator also wants to use SPILL/RELOAD meta
--   instructions, so we'll keep those here.
data InstrSR instr

-- | A real machine instruction
Instr :: instr -> InstrSR instr

-- | spill this reg to a stack slot
SPILL :: Reg -> Int -> InstrSR instr

-- | reload this reg from a stack slot
RELOAD :: Int -> Reg -> InstrSR instr

-- | An instruction with liveness information.
data LiveInstr instr
LiveInstr :: (InstrSR instr) -> (Maybe Liveness) -> LiveInstr instr

-- | Liveness information. The regs which die are ones which are no longer
--   live in the *next* instruction in this sequence. (NB. if the
--   instruction is a jump, these registers might still be live at the jump
--   target(s) - you have to check the liveness at the destination block to
--   find out).
data Liveness

-- | registers that died because they were clobbered by something.
Liveness :: RegSet -> RegSet -> RegSet -> Liveness

-- | registers born in this instruction (written to for first time).
liveBorn :: Liveness -> RegSet

-- | registers that died because they were read for the last time.
liveDieRead :: Liveness -> RegSet
liveDieWrite :: Liveness -> RegSet

-- | Stash regs live on entry to each basic block in the info part of the
--   cmm code.
data LiveInfo
LiveInfo :: (Maybe CmmStatics) -> (Maybe BlockId) -> (Maybe (BlockMap RegSet)) -> (Map BlockId (Set Int)) -> LiveInfo

-- | A basic block with liveness information.
type LiveBasicBlock instr = GenBasicBlock (LiveInstr instr)

-- | map a function across all the basic blocks in this code
mapBlockTop :: (LiveBasicBlock instr -> LiveBasicBlock instr) -> LiveCmmDecl statics instr -> LiveCmmDecl statics instr

-- | map a function across all the basic blocks in this code (monadic
--   version)
mapBlockTopM :: Monad m => (LiveBasicBlock instr -> m (LiveBasicBlock instr)) -> LiveCmmDecl statics instr -> m (LiveCmmDecl statics instr)
mapSCCM :: Monad m => (a -> m b) -> SCC a -> m (SCC b)
mapGenBlockTop :: (GenBasicBlock i -> GenBasicBlock i) -> (GenCmmDecl d h (ListGraph i) -> GenCmmDecl d h (ListGraph i))

-- | map a function across all the basic blocks in this code (monadic
--   version)
mapGenBlockTopM :: Monad m => (GenBasicBlock i -> m (GenBasicBlock i)) -> (GenCmmDecl d h (ListGraph i) -> m (GenCmmDecl d h (ListGraph i)))

-- | Strip away liveness information, yielding NatCmmDecl
stripLive :: (Outputable statics, Outputable instr, Instruction instr) => Platform -> LiveCmmDecl statics instr -> NatCmmDecl statics instr

-- | Strip away liveness information from a basic block, and make real
--   spill instructions out of SPILL, RELOAD pseudos along the way.
stripLiveBlock :: Instruction instr => Platform -> LiveBasicBlock instr -> NatBasicBlock instr

-- | Slurp out the list of register conflicts and reg-reg moves from this
--   top level thing. Slurping of conflicts and moves is wrapped up
--   together so we don't have to make two passes over the same code when
--   we want to build the graph.
slurpConflicts :: Instruction instr => LiveCmmDecl statics instr -> (Bag (UniqSet Reg), Bag (Reg, Reg))

-- | For spill/reloads
--   
--   SPILL v1, slot1 ... RELOAD slot1, v2
--   
--   If we can arrange that v1 and v2 are allocated to the same hreg it's
--   more likely the spill/reload instrs can be cleaned and replaced by a
--   nop reg-reg move.
slurpReloadCoalesce :: Instruction instr => LiveCmmDecl statics instr -> Bag (Reg, Reg)

-- | Erase Delta instructions.
eraseDeltasLive :: Instruction instr => LiveCmmDecl statics instr -> LiveCmmDecl statics instr

-- | Patch the registers in this code according to this register mapping.
--   also erase reg -&gt; reg moves when the reg is the same. also erase
--   reg -&gt; reg moves when the destination dies in this instr.
patchEraseLive :: Instruction instr => (Reg -> Reg) -> LiveCmmDecl statics instr -> LiveCmmDecl statics instr

-- | Patch registers in this LiveInstr, including the liveness information.
patchRegsLiveInstr :: Instruction instr => (Reg -> Reg) -> LiveInstr instr -> LiveInstr instr

-- | If we've compute liveness info for this code already we have to
--   reverse the SCCs in each top to get them back to the right order so we
--   can do it again.
reverseBlocksInTops :: LiveCmmDecl statics instr -> LiveCmmDecl statics instr
regLiveness :: (Outputable instr, Instruction instr) => LiveCmmDecl statics instr -> UniqSM (LiveCmmDecl statics instr)

-- | Convert a NatCmmDecl to a LiveCmmDecl, with empty liveness information
natCmmTopToLive :: Instruction instr => NatCmmDecl statics instr -> LiveCmmDecl statics instr
instance Outputable LiveInfo
instance Outputable instr => Outputable (LiveInstr instr)
instance Outputable instr => Outputable (InstrSR instr)
instance Instruction instr => Instruction (InstrSR instr)


-- | When there aren't enough registers to hold all the vregs we have to
--   spill some of those vregs to slots on the stack. This module is used
--   modify the code to use those slots.
module RegAlloc.Graph.Spill

-- | Spill all these virtual regs to stack slots.
--   
--   TODO: See if we can split some of the live ranges instead of just
--   globally spilling the virtual reg. This might make the spill cleaner's
--   job easier.
--   
--   TODO: On CISCy x86 and x86_64 we don't nessesarally have to add a mov
--   instruction when making spills. If an instr is using a spilled virtual
--   we may be able to address the spill slot directly.
regSpill :: Instruction instr => [LiveCmmDecl statics instr] -> UniqSet Int -> UniqSet VirtualReg -> UniqSM ([LiveCmmDecl statics instr], UniqSet Int, SpillStats)
data SpillStats
SpillStats :: UniqFM (Reg, Int, Int) -> SpillStats
spillStoreLoad :: SpillStats -> UniqFM (Reg, Int, Int)
accSpillSL :: (Reg, Int, Int) -> (Reg, Int, Int) -> (Reg, Int, Int)
instance Outputable SpillStats

module RegAlloc.Graph.SpillCost
type SpillCostRecord = (VirtualReg, Int, Int, Int)
plusSpillCostRecord :: SpillCostRecord -> SpillCostRecord -> SpillCostRecord

-- | Show a spill cost record, including the degree from the graph and
--   final calulated spill cos
pprSpillCostRecord :: (VirtualReg -> RegClass) -> (Reg -> SDoc) -> Graph VirtualReg RegClass RealReg -> SpillCostRecord -> SDoc
type SpillCostInfo = UniqFM SpillCostRecord
zeroSpillCostInfo :: SpillCostInfo

-- | Add two spillCostInfos
plusSpillCostInfo :: SpillCostInfo -> SpillCostInfo -> SpillCostInfo

-- | Slurp out information used for determining spill costs for each vreg,
--   the number of times it was written to, read from, and the number of
--   instructions it was live on entry to (lifetime)
slurpSpillCostInfo :: (Outputable instr, Instruction instr) => LiveCmmDecl statics instr -> SpillCostInfo

-- | Choose a node to spill from this graph
chooseSpill :: SpillCostInfo -> Graph VirtualReg RegClass RealReg -> VirtualReg
lifeMapFromSpillCostInfo :: SpillCostInfo -> UniqFM (VirtualReg, Int)


-- | Register coalescing.
module RegAlloc.Graph.Coalesce

-- | Do register coalescing on this top level thing For Reg -&gt; Reg
--   moves, if the first reg dies at the same time the second reg is born
--   then the mov only serves to join live ranges. The two regs can be
--   renamed to be the same and the move instruction safely erased.
regCoalesce :: Instruction instr => [LiveCmmDecl statics instr] -> UniqSM [LiveCmmDecl statics instr]

-- | Slurp out mov instructions that only serve to join live ranges. During
--   a mov, if the source reg dies and the destiation reg is born then we
--   can rename the two regs to the same thing and eliminate the move.
slurpJoinMovs :: Instruction instr => LiveCmmDecl statics instr -> Bag (Reg, Reg)

module X86.RegInfo
mkVirtualReg :: Unique -> Size -> VirtualReg
regDotColor :: Platform -> RealReg -> SDoc


-- | Hard wired things related to registers. This is module is preventing
--   the native code generator being able to emit code for non-host
--   architectures.
--   
--   TODO: Do a better job of the overloading, and eliminate this module.
--   We'd probably do better with a Register type class, and hook this to
--   Instruction somehow.
--   
--   TODO: We should also make arch specific versions of
--   RegAlloc.Graph.TrivColorable
module TargetReg
targetVirtualRegSqueeze :: Platform -> RegClass -> VirtualReg -> FastInt
targetRealRegSqueeze :: Platform -> RegClass -> RealReg -> FastInt
targetClassOfRealReg :: Platform -> RealReg -> RegClass
targetMkVirtualReg :: Platform -> Unique -> Size -> VirtualReg
targetWordSize :: Size
targetRegDotColor :: Platform -> RealReg -> SDoc
targetClassOfReg :: Platform -> Reg -> RegClass

module X86.Instr
data Instr
COMMENT :: FastString -> Instr
LDATA :: Section -> (Alignment, CmmStatics) -> Instr
NEWBLOCK :: BlockId -> Instr
DELTA :: Int -> Instr
MOV :: Size -> Operand -> Operand -> Instr
MOVZxL :: Size -> Operand -> Operand -> Instr
MOVSxL :: Size -> Operand -> Operand -> Instr
LEA :: Size -> Operand -> Operand -> Instr
ADD :: Size -> Operand -> Operand -> Instr
ADC :: Size -> Operand -> Operand -> Instr
SUB :: Size -> Operand -> Operand -> Instr
MUL :: Size -> Operand -> Operand -> Instr
MUL2 :: Size -> Operand -> Instr
IMUL :: Size -> Operand -> Operand -> Instr
IMUL2 :: Size -> Operand -> Instr
DIV :: Size -> Operand -> Instr
IDIV :: Size -> Operand -> Instr
AND :: Size -> Operand -> Operand -> Instr
OR :: Size -> Operand -> Operand -> Instr
XOR :: Size -> Operand -> Operand -> Instr
NOT :: Size -> Operand -> Instr
NEGI :: Size -> Operand -> Instr
SHL :: Size -> Operand -> Operand -> Instr
SAR :: Size -> Operand -> Operand -> Instr
SHR :: Size -> Operand -> Operand -> Instr
BT :: Size -> Imm -> Operand -> Instr
NOP :: Instr
GMOV :: Reg -> Reg -> Instr
GLD :: Size -> AddrMode -> Reg -> Instr
GST :: Size -> Reg -> AddrMode -> Instr
GLDZ :: Reg -> Instr
GLD1 :: Reg -> Instr
GFTOI :: Reg -> Reg -> Instr
GDTOI :: Reg -> Reg -> Instr
GITOF :: Reg -> Reg -> Instr
GITOD :: Reg -> Reg -> Instr
GDTOF :: Reg -> Reg -> Instr
GADD :: Size -> Reg -> Reg -> Reg -> Instr
GDIV :: Size -> Reg -> Reg -> Reg -> Instr
GSUB :: Size -> Reg -> Reg -> Reg -> Instr
GMUL :: Size -> Reg -> Reg -> Reg -> Instr
GCMP :: Cond -> Reg -> Reg -> Instr
GABS :: Size -> Reg -> Reg -> Instr
GNEG :: Size -> Reg -> Reg -> Instr
GSQRT :: Size -> Reg -> Reg -> Instr
GSIN :: Size -> CLabel -> CLabel -> Reg -> Reg -> Instr
GCOS :: Size -> CLabel -> CLabel -> Reg -> Reg -> Instr
GTAN :: Size -> CLabel -> CLabel -> Reg -> Reg -> Instr
GFREE :: Instr
CVTSS2SD :: Reg -> Reg -> Instr
CVTSD2SS :: Reg -> Reg -> Instr
CVTTSS2SIQ :: Size -> Operand -> Reg -> Instr
CVTTSD2SIQ :: Size -> Operand -> Reg -> Instr
CVTSI2SS :: Size -> Operand -> Reg -> Instr
CVTSI2SD :: Size -> Operand -> Reg -> Instr
FDIV :: Size -> Operand -> Operand -> Instr
SQRT :: Size -> Operand -> Reg -> Instr
TEST :: Size -> Operand -> Operand -> Instr
CMP :: Size -> Operand -> Operand -> Instr
SETCC :: Cond -> Operand -> Instr
PUSH :: Size -> Operand -> Instr
POP :: Size -> Operand -> Instr
JMP :: Operand -> [Reg] -> Instr
JXX :: Cond -> BlockId -> Instr
JXX_GBL :: Cond -> Imm -> Instr
JMP_TBL :: Operand -> [Maybe BlockId] -> Section -> CLabel -> Instr
CALL :: (Either Imm Reg) -> [Reg] -> Instr
CLTD :: Size -> Instr
FETCHGOT :: Reg -> Instr
FETCHPC :: Reg -> Instr
POPCNT :: Size -> Operand -> Reg -> Instr
data Operand
OpReg :: Reg -> Operand
OpImm :: Imm -> Operand
OpAddr :: AddrMode -> Operand
getJumpDestBlockId :: JumpDest -> Maybe BlockId
canShortcut :: Instr -> Maybe JumpDest
shortcutStatics :: (BlockId -> Maybe JumpDest) -> (Alignment, CmmStatics) -> (Alignment, CmmStatics)
shortcutJump :: (BlockId -> Maybe JumpDest) -> Instr -> Instr
i386_insert_ffrees :: [GenBasicBlock Instr] -> [GenBasicBlock Instr]
maxSpillSlots :: Bool -> Int
archWordSize :: Bool -> Size
instance Instruction Instr

module X86.Ppr
pprNatCmmDecl :: Platform -> NatCmmDecl (Alignment, CmmStatics) Instr -> SDoc
pprBasicBlock :: Platform -> NatBasicBlock Instr -> SDoc
pprSectionHeader :: Platform -> Section -> SDoc
pprData :: Platform -> CmmStatic -> SDoc
pprInstr :: Platform -> Instr -> SDoc
pprSize :: Size -> SDoc
pprImm :: Platform -> Imm -> SDoc
pprDataItem :: Platform -> CmmLit -> SDoc
instance Outputable Instr

module SPARC.Instr

-- | Register or immediate
data RI
RIReg :: Reg -> RI
RIImm :: Imm -> RI

-- | Check if a RI represents a zero value. - a literal zero - register
--   %g0, which is always zero.
riZero :: RI -> Bool

-- | Calculate the effective address which would be used by the
--   corresponding fpRel sequence.
fpRelEA :: Int -> Reg -> Instr

-- | Code to shift the stack pointer by n words.
moveSp :: Int -> Instr

-- | An instruction that will cause the one after it never to be exectuted
isUnconditionalJump :: Instr -> Bool

-- | SPARC instruction set. Not complete. This is only the ones we need.
data Instr
COMMENT :: FastString -> Instr
LDATA :: Section -> CmmStatics -> Instr
NEWBLOCK :: BlockId -> Instr
DELTA :: Int -> Instr
LD :: Size -> AddrMode -> Reg -> Instr
ST :: Size -> Reg -> AddrMode -> Instr
ADD :: Bool -> Bool -> Reg -> RI -> Reg -> Instr
SUB :: Bool -> Bool -> Reg -> RI -> Reg -> Instr
UMUL :: Bool -> Reg -> RI -> Reg -> Instr
SMUL :: Bool -> Reg -> RI -> Reg -> Instr
UDIV :: Bool -> Reg -> RI -> Reg -> Instr
SDIV :: Bool -> Reg -> RI -> Reg -> Instr
RDY :: Reg -> Instr
WRY :: Reg -> Reg -> Instr
AND :: Bool -> Reg -> RI -> Reg -> Instr
ANDN :: Bool -> Reg -> RI -> Reg -> Instr
OR :: Bool -> Reg -> RI -> Reg -> Instr
ORN :: Bool -> Reg -> RI -> Reg -> Instr
XOR :: Bool -> Reg -> RI -> Reg -> Instr
XNOR :: Bool -> Reg -> RI -> Reg -> Instr
SLL :: Reg -> RI -> Reg -> Instr
SRL :: Reg -> RI -> Reg -> Instr
SRA :: Reg -> RI -> Reg -> Instr
SETHI :: Imm -> Reg -> Instr
NOP :: Instr
FABS :: Size -> Reg -> Reg -> Instr
FADD :: Size -> Reg -> Reg -> Reg -> Instr
FCMP :: Bool -> Size -> Reg -> Reg -> Instr
FDIV :: Size -> Reg -> Reg -> Reg -> Instr
FMOV :: Size -> Reg -> Reg -> Instr
FMUL :: Size -> Reg -> Reg -> Reg -> Instr
FNEG :: Size -> Reg -> Reg -> Instr
FSQRT :: Size -> Reg -> Reg -> Instr
FSUB :: Size -> Reg -> Reg -> Reg -> Instr
FxTOy :: Size -> Size -> Reg -> Reg -> Instr
BI :: Cond -> Bool -> BlockId -> Instr
BF :: Cond -> Bool -> BlockId -> Instr
JMP :: AddrMode -> Instr
JMP_TBL :: AddrMode -> [Maybe BlockId] -> CLabel -> Instr
CALL :: (Either Imm Reg) -> Int -> Bool -> Instr

-- | The maximum number of spill slots available on the C stack. If we use
--   up all of the slots, then we're screwed.
--   
--   Why do we reserve 64 bytes, instead of using the whole thing?? -- BL
--   2009<i>02</i>15
maxSpillSlots :: Int
instance Instruction Instr

module SPARC.Ppr
pprNatCmmDecl :: Platform -> NatCmmDecl CmmStatics Instr -> SDoc
pprBasicBlock :: Platform -> NatBasicBlock Instr -> SDoc

-- | Pretty print a section / segment header. On SPARC all the data
--   sections must be at least 8 byte aligned incase we store doubles in
--   them.
pprSectionHeader :: Section -> SDoc
pprData :: Platform -> CmmStatic -> SDoc

-- | Pretty print an instruction.
pprInstr :: Platform -> Instr -> SDoc

-- | Pretty print a size for an instruction suffix.
pprSize :: Size -> SDoc

-- | Pretty print an immediate value.
pprImm :: Platform -> Imm -> SDoc

-- | Pretty print a data item.
pprDataItem :: Platform -> CmmLit -> SDoc
instance Outputable Instr

module SPARC.ShortcutJump
data JumpDest
DestBlockId :: BlockId -> JumpDest
DestImm :: Imm -> JumpDest
getJumpDestBlockId :: JumpDest -> Maybe BlockId
canShortcut :: Instr -> Maybe JumpDest
shortcutJump :: (BlockId -> Maybe JumpDest) -> Instr -> Instr
shortcutStatics :: (BlockId -> Maybe JumpDest) -> CmmStatics -> CmmStatics
shortBlockId :: (BlockId -> Maybe JumpDest) -> BlockId -> CLabel


-- | Expand out synthetic instructions into single machine instrs.
module SPARC.CodeGen.Expand

-- | Expand out synthetic instructions in this top level thing
expandTop :: NatCmmDecl CmmStatics Instr -> NatCmmDecl CmmStatics Instr


-- | One ounce of sanity checking is worth 10000000000000000 ounces of
--   staring blindly at assembly code trying to find the problem..
module SPARC.CodeGen.Sanity

-- | Enforce intra-block invariants.
checkBlock :: CmmBasicBlock -> NatBasicBlock Instr -> NatBasicBlock Instr

module SPARC.CodeGen.Base

-- | <a>InstrBlock</a>s are the insn sequences generated by the insn
--   selectors. They are really trees of insns to facilitate fast
--   appending, where a left-to-right traversal yields the insns in the
--   correct order.
type InstrBlock = OrdList Instr

-- | Condition codes passed up the tree.
data CondCode
CondCode :: Bool -> Cond -> InstrBlock -> CondCode

-- | a.k.a <a>Register64</a> Reg is the lower 32-bit temporary which
--   contains the result. Use getHiVRegFromLo to find the other VRegUnique.
--   
--   Rules of this simplified insn selection game are therefore that the
--   returned Reg may be modified
data ChildCode64
ChildCode64 :: InstrBlock -> Reg -> ChildCode64

-- | Holds code that references a memory address.
data Amode
Amode :: AddrMode -> InstrBlock -> Amode

-- | Code to produce a result into a register. If the result must go in a
--   specific register, it comes out as Fixed. Otherwise, the parent can
--   decide which register to put it in.
data Register
Fixed :: Size -> Reg -> InstrBlock -> Register
Any :: Size -> (Reg -> InstrBlock) -> Register

-- | Change the size field in a Register.
setSizeOfRegister :: Register -> Size -> Register

-- | Grab the Reg for a CmmReg
getRegisterReg :: CmmReg -> Reg
mangleIndexTree :: CmmExpr -> CmmExpr

module PPC.Instr
archWordSize :: Size
data RI
RIReg :: Reg -> RI
RIImm :: Imm -> RI
data Instr
COMMENT :: FastString -> Instr
LDATA :: Section -> CmmStatics -> Instr
NEWBLOCK :: BlockId -> Instr
DELTA :: Int -> Instr
LD :: Size -> Reg -> AddrMode -> Instr
LA :: Size -> Reg -> AddrMode -> Instr
ST :: Size -> Reg -> AddrMode -> Instr
STU :: Size -> Reg -> AddrMode -> Instr
LIS :: Reg -> Imm -> Instr
LI :: Reg -> Imm -> Instr
MR :: Reg -> Reg -> Instr
CMP :: Size -> Reg -> RI -> Instr
CMPL :: Size -> Reg -> RI -> Instr
BCC :: Cond -> BlockId -> Instr
BCCFAR :: Cond -> BlockId -> Instr
JMP :: CLabel -> Instr
MTCTR :: Reg -> Instr
BCTR :: [Maybe BlockId] -> (Maybe CLabel) -> Instr
BL :: CLabel -> [Reg] -> Instr
BCTRL :: [Reg] -> Instr
ADD :: Reg -> Reg -> RI -> Instr
ADDC :: Reg -> Reg -> Reg -> Instr
ADDE :: Reg -> Reg -> Reg -> Instr
ADDIS :: Reg -> Reg -> Imm -> Instr
SUBF :: Reg -> Reg -> Reg -> Instr
MULLW :: Reg -> Reg -> RI -> Instr
DIVW :: Reg -> Reg -> Reg -> Instr
DIVWU :: Reg -> Reg -> Reg -> Instr
MULLW_MayOflo :: Reg -> Reg -> Reg -> Instr
AND :: Reg -> Reg -> RI -> Instr
OR :: Reg -> Reg -> RI -> Instr
XOR :: Reg -> Reg -> RI -> Instr
XORIS :: Reg -> Reg -> Imm -> Instr
EXTS :: Size -> Reg -> Reg -> Instr
NEG :: Reg -> Reg -> Instr
NOT :: Reg -> Reg -> Instr
SLW :: Reg -> Reg -> RI -> Instr
SRW :: Reg -> Reg -> RI -> Instr
SRAW :: Reg -> Reg -> RI -> Instr
RLWINM :: Reg -> Reg -> Int -> Int -> Int -> Instr
FADD :: Size -> Reg -> Reg -> Reg -> Instr
FSUB :: Size -> Reg -> Reg -> Reg -> Instr
FMUL :: Size -> Reg -> Reg -> Reg -> Instr
FDIV :: Size -> Reg -> Reg -> Reg -> Instr
FNEG :: Reg -> Reg -> Instr
FCMP :: Reg -> Reg -> Instr
FCTIWZ :: Reg -> Reg -> Instr
FRSP :: Reg -> Reg -> Instr
CRNOR :: Int -> Int -> Int -> Instr
MFCR :: Reg -> Instr
MFLR :: Reg -> Instr
FETCHPC :: Reg -> Instr
LWSYNC :: Instr
maxSpillSlots :: Int
instance Instruction Instr

module PPC.RegInfo
data JumpDest
DestBlockId :: BlockId -> JumpDest
getJumpDestBlockId :: JumpDest -> Maybe BlockId
canShortcut :: Instr -> Maybe JumpDest
shortcutJump :: (BlockId -> Maybe JumpDest) -> Instr -> Instr
shortcutStatics :: (BlockId -> Maybe JumpDest) -> CmmStatics -> CmmStatics

module PPC.Ppr
pprNatCmmDecl :: Platform -> NatCmmDecl CmmStatics Instr -> SDoc
pprBasicBlock :: Platform -> NatBasicBlock Instr -> SDoc
pprSectionHeader :: Platform -> Section -> SDoc
pprData :: Platform -> CmmStatic -> SDoc
pprInstr :: Platform -> Instr -> SDoc
pprSize :: Size -> SDoc
pprImm :: Platform -> Imm -> SDoc
pprDataItem :: Platform -> CmmLit -> SDoc
instance Outputable Instr


-- | Carries interesting info for debugging / profiling of the graph
--   coloring register allocator.
module RegAlloc.Graph.Stats
data RegAllocStats statics instr

-- | information to help choose which regs to spill
RegAllocStatsStart :: [LiveCmmDecl statics instr] -> Graph VirtualReg RegClass RealReg -> SpillCostInfo -> RegAllocStats statics instr

-- | initial code, with liveness
raLiveCmm :: RegAllocStats statics instr -> [LiveCmmDecl statics instr]

-- | the uncolored graph
--   
--   the partially colored graph
--   
--   the initial, uncolored graph
raGraph :: RegAllocStats statics instr -> Graph VirtualReg RegClass RealReg

-- | number of instrs each reg lives for
raSpillCosts :: RegAllocStats statics instr -> SpillCostInfo

-- | code with spill instructions added
RegAllocStatsSpill :: [LiveCmmDecl statics instr] -> Graph VirtualReg RegClass RealReg -> UniqFM VirtualReg -> SpillStats -> SpillCostInfo -> [LiveCmmDecl statics instr] -> RegAllocStats statics instr

-- | the code we tried to allocate registers for
--   
--   the code we tried to allocate registers for
raCode :: RegAllocStats statics instr -> [LiveCmmDecl statics instr]

-- | the uncolored graph
--   
--   the partially colored graph
--   
--   the initial, uncolored graph
raGraph :: RegAllocStats statics instr -> Graph VirtualReg RegClass RealReg

-- | the regs that were coaleced
--   
--   the regs that were coaleced
raCoalesced :: RegAllocStats statics instr -> UniqFM VirtualReg

-- | spiller stats
raSpillStats :: RegAllocStats statics instr -> SpillStats

-- | number of instrs each reg lives for
raSpillCosts :: RegAllocStats statics instr -> SpillCostInfo
raSpilled :: RegAllocStats statics instr -> [LiveCmmDecl statics instr]

-- | spill/reload/reg-reg moves present in this code
RegAllocStatsColored :: [LiveCmmDecl statics instr] -> Graph VirtualReg RegClass RealReg -> Graph VirtualReg RegClass RealReg -> UniqFM VirtualReg -> [LiveCmmDecl statics instr] -> [LiveCmmDecl statics instr] -> [LiveCmmDecl statics instr] -> [NatCmmDecl statics instr] -> (Int, Int, Int) -> RegAllocStats statics instr

-- | the code we tried to allocate registers for
--   
--   the code we tried to allocate registers for
raCode :: RegAllocStats statics instr -> [LiveCmmDecl statics instr]

-- | the uncolored graph
--   
--   the partially colored graph
--   
--   the initial, uncolored graph
raGraph :: RegAllocStats statics instr -> Graph VirtualReg RegClass RealReg

-- | the coalesced and colored graph
raGraphColored :: RegAllocStats statics instr -> Graph VirtualReg RegClass RealReg

-- | the regs that were coaleced
--   
--   the regs that were coaleced
raCoalesced :: RegAllocStats statics instr -> UniqFM VirtualReg

-- | code with coalescings applied
raCodeCoalesced :: RegAllocStats statics instr -> [LiveCmmDecl statics instr]

-- | code with vregs replaced by hregs
raPatched :: RegAllocStats statics instr -> [LiveCmmDecl statics instr]

-- | code with unneeded spill/reloads cleaned out
raSpillClean :: RegAllocStats statics instr -> [LiveCmmDecl statics instr]

-- | final code
raFinal :: RegAllocStats statics instr -> [NatCmmDecl statics instr]
raSRMs :: RegAllocStats statics instr -> (Int, Int, Int)

-- | Do all the different analysis on this list of RegAllocStats
pprStats :: [RegAllocStats statics instr] -> Graph VirtualReg RegClass RealReg -> SDoc

-- | Dump a table of how many spill loads / stores were inserted for each
--   vreg.
pprStatsSpills :: [RegAllocStats statics instr] -> SDoc

-- | Dump a table of how long vregs tend to live for in the initial code.
pprStatsLifetimes :: [RegAllocStats statics instr] -> SDoc

-- | Dump a table of how many conflicts vregs tend to have in the initial
--   code.
pprStatsConflict :: [RegAllocStats statics instr] -> SDoc

-- | For every vreg, dump it's how many conflicts it has and its lifetime
--   good for making a scatter plot.
pprStatsLifeConflict :: [RegAllocStats statics instr] -> Graph VirtualReg RegClass RealReg -> SDoc

-- | Count spill<i>reload</i>reg-reg moves. Lets us see how well the
--   register allocator has done.
countSRMs :: Instruction instr => LiveCmmDecl statics instr -> (Int, Int, Int)
addSRM :: (Num t, Num t1, Num t2) => (t, t1, t2) -> (t, t1, t2) -> (t, t1, t2)
instance (Outputable statics, Outputable instr) => Outputable (RegAllocStats statics instr)

module NCGMonad
data NatM_State
NatM_State :: UniqSupply -> Int -> [(CLabel)] -> Maybe Reg -> DynFlags -> NatM_State
natm_us :: NatM_State -> UniqSupply
natm_delta :: NatM_State -> Int
natm_imports :: NatM_State -> [(CLabel)]
natm_pic :: NatM_State -> Maybe Reg
natm_dflags :: NatM_State -> DynFlags
mkNatM_State :: UniqSupply -> Int -> DynFlags -> NatM_State
data NatM result
initNat :: NatM_State -> NatM a -> (a, NatM_State)
addImportNat :: CLabel -> NatM ()
getUniqueNat :: NatM Unique
mapAccumLNat :: (acc -> x -> NatM (acc, y)) -> acc -> [x] -> NatM (acc, [y])
setDeltaNat :: Int -> NatM ()
getDeltaNat :: NatM Int
getBlockIdNat :: NatM BlockId
getNewLabelNat :: NatM CLabel
getNewRegNat :: Size -> NatM Reg
getNewRegPairNat :: Size -> NatM (Reg, Reg)
getPicBaseMaybeNat :: NatM (Maybe Reg)
getPicBaseNat :: Size -> NatM Reg
getDynFlags :: HasDynFlags m => m DynFlags
instance HasDynFlags NatM
instance Monad NatM

module PIC
cmmMakeDynamicReference :: Monad m => DynFlags -> (CLabel -> m ()) -> ReferenceKind -> CLabel -> m CmmExpr
data ReferenceKind
DataReference :: ReferenceKind
CallReference :: ReferenceKind
JumpReference :: ReferenceKind
needImportedSymbols :: Arch -> OS -> Bool
pprImportedSymbol :: Platform -> CLabel -> SDoc
pprGotDeclaration :: Arch -> OS -> SDoc
initializePicBase_ppc :: Arch -> OS -> Reg -> [NatCmmDecl CmmStatics Instr] -> NatM [NatCmmDecl CmmStatics Instr]
initializePicBase_x86 :: Arch -> OS -> Reg -> [NatCmmDecl (Alignment, CmmStatics) Instr] -> NatM [NatCmmDecl (Alignment, CmmStatics) Instr]
instance Eq ReferenceKind

module X86.CodeGen
cmmTopCodeGen :: RawCmmDecl -> NatM [NatCmmDecl (Alignment, CmmStatics) Instr]
generateJumpTableForInstr :: Instr -> Maybe (NatCmmDecl (Alignment, CmmStatics) Instr)

-- | <a>InstrBlock</a>s are the insn sequences generated by the insn
--   selectors. They are really trees of insns to facilitate fast
--   appending, where a left-to-right traversal yields the insns in the
--   correct order.
type InstrBlock = OrdList Instr

module PPC.CodeGen

-- | <a>InstrBlock</a>s are the insn sequences generated by the insn
--   selectors. They are really trees of insns to facilitate fast
--   appending, where a left-to-right traversal (pre-order?) yields the
--   insns in the correct order.
cmmTopCodeGen :: RawCmmDecl -> NatM [NatCmmDecl CmmStatics Instr]
generateJumpTableForInstr :: Instr -> Maybe (NatCmmDecl CmmStatics Instr)

-- | <a>InstrBlock</a>s are the insn sequences generated by the insn
--   selectors. They are really trees of insns to facilitate fast
--   appending, where a left-to-right traversal yields the insns in the
--   correct order.
type InstrBlock = OrdList Instr

module SPARC.CodeGen.Amode

-- | Generate code to reference a memory address.
getAmode :: CmmExpr -> NatM Amode

module SPARC.CodeGen.CondCode
getCondCode :: CmmExpr -> NatM CondCode
condIntCode :: Cond -> CmmExpr -> CmmExpr -> NatM CondCode
condFltCode :: Cond -> CmmExpr -> CmmExpr -> NatM CondCode


-- | Evaluation of 64 bit values on 32 bit platforms.
module SPARC.CodeGen.Gen64

-- | Code to assign a 64 bit value to memory.
assignMem_I64Code :: CmmExpr -> CmmExpr -> NatM InstrBlock

-- | Code to assign a 64 bit value to a register.
assignReg_I64Code :: CmmReg -> CmmExpr -> NatM InstrBlock

-- | Get the value of an expression into a 64 bit register.
iselExpr64 :: CmmExpr -> NatM ChildCode64


-- | Evaluation of 32 bit values.
module SPARC.CodeGen.Gen32

-- | The dual to getAnyReg: compute an expression into a register, but we
--   don't mind which one it is.
getSomeReg :: CmmExpr -> NatM (Reg, InstrBlock)

-- | Make code to evaluate a 32 bit expression.
getRegister :: CmmExpr -> NatM Register

module SPARC.CodeGen

-- | Top level code generation
cmmTopCodeGen :: RawCmmDecl -> NatM [NatCmmDecl CmmStatics Instr]
generateJumpTableForInstr :: Instr -> Maybe (NatCmmDecl CmmStatics Instr)

-- | <a>InstrBlock</a>s are the insn sequences generated by the insn
--   selectors. They are really trees of insns to facilitate fast
--   appending, where a left-to-right traversal yields the insns in the
--   correct order.
type InstrBlock = OrdList Instr


-- | Clean out unneeded spill/reload instrs
--   
--   <ul>
--   <li>Handling of join points</li>
--   </ul>
--   
--   B1: B2: ... ... RELOAD SLOT(0), %r1 RELOAD SLOT(0), %r1 ... A ... ...
--   B ... jump B3 jump B3
--   
--   B3: ... C ... RELOAD SLOT(0), %r1 ...
--   
--   the plan: So long as %r1 hasn't been written to in A, B or C then we
--   don't need the reload in B3.
--   
--   What we really care about here is that on the entry to B3, %r1 will
--   always have the same value that is in SLOT(0) (ie, %r1 is _valid_)
--   
--   This also works if the reloads in B1/B2 were spills instead, because
--   spilling %r1 to a slot makes that slot have the same value as %r1.
module RegAlloc.Graph.SpillClean

-- | Clean out unneeded spill/reloads from this top level thing.
cleanSpills :: Instruction instr => Platform -> LiveCmmDecl statics instr -> LiveCmmDecl statics instr
instance Outputable Store
instance Uniquable Store


-- | Graph coloring register allocator.
--   
--   TODO: The colors in graphviz graphs for x86_64 and ppc could be nicer.
module RegAlloc.Graph.Main

-- | The top level of the graph coloring register allocator.
regAlloc :: (Outputable statics, Outputable instr, Instruction instr) => DynFlags -> UniqFM (UniqSet RealReg) -> UniqSet Int -> [LiveCmmDecl statics instr] -> UniqSM ([NatCmmDecl statics instr], [RegAllocStats statics instr])

module RegAlloc.Linear.FreeRegs
class Show freeRegs => FR freeRegs
frAllocateReg :: FR freeRegs => RealReg -> freeRegs -> freeRegs
frGetFreeRegs :: FR freeRegs => RegClass -> freeRegs -> [RealReg]
frInitFreeRegs :: FR freeRegs => freeRegs
frReleaseReg :: FR freeRegs => RealReg -> freeRegs -> freeRegs
maxSpillSlots :: Platform -> Int
instance FR FreeRegs
instance FR FreeRegs
instance FR FreeRegs


-- | The assignment of virtual registers to stack slots
module RegAlloc.Linear.StackMap

-- | Identifier for a stack slot.
type StackSlot = Int
data StackMap
StackMap :: [StackSlot] -> UniqFM StackSlot -> StackMap

-- | The slots that are still available to be allocated.
stackMapFreeSlots :: StackMap -> [StackSlot]

-- | Assignment of vregs to stack slots.
stackMapAssignment :: StackMap -> UniqFM StackSlot

-- | An empty stack map, with all slots available.
emptyStackMap :: Platform -> StackMap

-- | If this vreg unique already has a stack assignment then return the
--   slot number, otherwise allocate a new slot, and update the map.
getStackSlotFor :: StackMap -> Unique -> (StackMap, Int)


-- | Put common type definitions here to break recursive module
--   dependencies.
module RegAlloc.Linear.Base

-- | Used to store the register assignment on entry to a basic block. We
--   use this to handle join points, where multiple branch instructions
--   target a particular label. We have to insert fixup code to make the
--   register assignments from the different sources match up.
type BlockAssignment freeRegs = BlockMap (freeRegs, RegMap Loc)

-- | Where a vreg is currently stored A temporary can be marked as living
--   in both a register and memory (InBoth), for example if it was recently
--   loaded from a spill location. This makes it cheap to spill (no save
--   instruction required), but we have to be careful to turn this into
--   InReg if the value in the register is changed.
data Loc

-- | vreg is in a register
InReg :: !RealReg -> Loc

-- | vreg is held in a stack slot
InMem :: {-# UNPACK #-} !StackSlot -> Loc

-- | vreg is held in both a register and a stack slot
InBoth :: !RealReg -> {-# UNPACK #-} !StackSlot -> Loc

-- | Get the reg numbers stored in this Loc.
regsOfLoc :: Loc -> [RealReg]

-- | Reasons why instructions might be inserted by the spiller. Used when
--   generating stats for -ddrop-asm-stats.
data SpillReason

-- | vreg was spilled to a slot so we could use its current hreg for
--   another vreg
SpillAlloc :: !Unique -> SpillReason

-- | vreg was moved because its hreg was clobbered
SpillClobber :: !Unique -> SpillReason

-- | vreg was loaded from a spill slot
SpillLoad :: !Unique -> SpillReason

-- | reg-reg move inserted during join to targets
SpillJoinRR :: !Unique -> SpillReason

-- | reg-mem move inserted during join to targets
SpillJoinRM :: !Unique -> SpillReason

-- | Used to carry interesting stats out of the register allocator.
data RegAllocStats
RegAllocStats :: UniqFM [Int] -> RegAllocStats
ra_spillInstrs :: RegAllocStats -> UniqFM [Int]

-- | The register alloctor state
data RA_State freeRegs
RA_State :: BlockAssignment freeRegs -> !freeRegs -> RegMap Loc -> Int -> StackMap -> UniqSupply -> [SpillReason] -> RA_State freeRegs

-- | the current mapping from basic blocks to the register assignments at
--   the beginning of that block.
ra_blockassig :: RA_State freeRegs -> BlockAssignment freeRegs

-- | free machine registers
ra_freeregs :: RA_State freeRegs -> !freeRegs

-- | assignment of temps to locations
ra_assig :: RA_State freeRegs -> RegMap Loc

-- | current stack delta
ra_delta :: RA_State freeRegs -> Int

-- | free stack slots for spilling
ra_stack :: RA_State freeRegs -> StackMap

-- | unique supply for generating names for join point fixup blocks.
ra_us :: RA_State freeRegs -> UniqSupply

-- | Record why things were spilled, for -ddrop-asm-stats. Just keep a list
--   here instead of a map of regs -&gt; reasons. We don't want to slow
--   down the allocator if we're not going to emit the stats.
ra_spills :: RA_State freeRegs -> [SpillReason]

-- | The register allocator monad type.
newtype RegM freeRegs a
RegM :: (RA_State freeRegs -> (# RA_State freeRegs, a #)) -> RegM freeRegs a
unReg :: RegM freeRegs a -> RA_State freeRegs -> (# RA_State freeRegs, a #)
instance Eq Loc
instance Show Loc
instance Ord Loc
instance Outputable Loc

module RegAlloc.Linear.Stats

-- | Build a map of how many times each reg was alloced, clobbered, loaded
--   etc.
binSpillReasons :: [SpillReason] -> UniqFM [Int]

-- | Count reg-reg moves remaining in this code.
countRegRegMovesNat :: Instruction instr => NatCmmDecl statics instr -> Int

-- | Pretty print some RegAllocStats
pprStats :: Instruction instr => [NatCmmDecl statics instr] -> [RegAllocStats] -> SDoc


-- | State monad for the linear register allocator.
module RegAlloc.Linear.State

-- | The register alloctor state
data RA_State freeRegs
RA_State :: BlockAssignment freeRegs -> !freeRegs -> RegMap Loc -> Int -> StackMap -> UniqSupply -> [SpillReason] -> RA_State freeRegs

-- | the current mapping from basic blocks to the register assignments at
--   the beginning of that block.
ra_blockassig :: RA_State freeRegs -> BlockAssignment freeRegs

-- | free machine registers
ra_freeregs :: RA_State freeRegs -> !freeRegs

-- | assignment of temps to locations
ra_assig :: RA_State freeRegs -> RegMap Loc

-- | current stack delta
ra_delta :: RA_State freeRegs -> Int

-- | free stack slots for spilling
ra_stack :: RA_State freeRegs -> StackMap

-- | unique supply for generating names for join point fixup blocks.
ra_us :: RA_State freeRegs -> UniqSupply

-- | Record why things were spilled, for -ddrop-asm-stats. Just keep a list
--   here instead of a map of regs -&gt; reasons. We don't want to slow
--   down the allocator if we're not going to emit the stats.
ra_spills :: RA_State freeRegs -> [SpillReason]

-- | The register allocator monad type.
data RegM freeRegs a

-- | Run a computation in the RegM register allocator monad.
runR :: BlockAssignment freeRegs -> freeRegs -> RegMap Loc -> StackMap -> UniqSupply -> RegM freeRegs a -> (BlockAssignment freeRegs, StackMap, RegAllocStats, a)
spillR :: Instruction instr => Platform -> Reg -> Unique -> RegM freeRegs (instr, Int)
loadR :: Instruction instr => Platform -> Reg -> Int -> RegM freeRegs instr
getFreeRegsR :: RegM freeRegs freeRegs
setFreeRegsR :: freeRegs -> RegM freeRegs ()
getAssigR :: RegM freeRegs (RegMap Loc)
setAssigR :: RegMap Loc -> RegM freeRegs ()
getBlockAssigR :: RegM freeRegs (BlockAssignment freeRegs)
setBlockAssigR :: BlockAssignment freeRegs -> RegM freeRegs ()
setDeltaR :: Int -> RegM freeRegs ()
getDeltaR :: RegM freeRegs Int
getUniqueR :: RegM freeRegs Unique

-- | Record that a spill instruction was inserted, for profiling.
recordSpill :: SpillReason -> RegM freeRegs ()
instance Monad (RegM freeRegs)


-- | Handles joining of a jump instruction to its targets.
module RegAlloc.Linear.JoinToTargets

-- | For a jump instruction at the end of a block, generate fixup code so
--   its vregs are in the correct regs for its destination.
joinToTargets :: (FR freeRegs, Instruction instr) => Platform -> BlockMap RegSet -> BlockId -> instr -> RegM freeRegs ([NatBasicBlock instr], instr)

module RegAlloc.Linear.Main
regAlloc :: (Outputable instr, Instruction instr) => DynFlags -> LiveCmmDecl statics instr -> UniqSM (NatCmmDecl statics instr, Maybe RegAllocStats)

module AsmCodeGen
nativeCodeGen :: DynFlags -> Handle -> UniqSupply -> Stream IO RawCmmGroup () -> IO ()
instance HasDynFlags CmmOptM
instance Monad CmmOptM

module CodeOutput
codeOutput :: DynFlags -> Module -> ModLocation -> ForeignStubs -> [PackageId] -> Stream IO RawCmmGroup () -> IO (Bool, Maybe FilePath)
outputForeignStubs :: DynFlags -> Module -> ModLocation -> ForeignStubs -> IO (Bool, Maybe FilePath)


-- | Main API for compiling plain Haskell source code.
--   
--   This module implements compilation of a Haskell source. It is
--   <i>not</i> concerned with preprocessing of source files; this is
--   handled in <a>DriverPipeline</a>.
--   
--   There are various entry points depending on what mode we're in:
--   <a>batch</a> mode (<tt>--make</tt>), <a>one-shot</a> mode
--   (<tt>-c</tt>, <tt>-S</tt> etc.), and <a>interactive</a> mode (GHCi).
--   There are also entry points for individual passes: parsing,
--   typechecking/renaming, desugaring, and simplification.
--   
--   All the functions here take an <a>HscEnv</a> as a parameter, but none
--   of them return a new one: <a>HscEnv</a> is treated as an immutable
--   value from here on in (although it has mutable components, for the
--   caches).
--   
--   Warning messages are dealt with consistently throughout this API:
--   during compilation warnings are collected, and before any function in
--   <tt>HscMain</tt> returns, the warnings are either printed, or turned
--   into a real compialtion error if the <tt>-Werror</tt> flag is enabled.
--   
--   (c) The GRASP/AQUA Project, Glasgow University, 1993-2000
module HscMain
newHscEnv :: DynFlags -> IO HscEnv
type Compiler result = HscEnv -> ModSummary -> SourceModified -> Maybe ModIface -> Maybe (Int, Int) -> IO result

-- | Status of a compilation to hard-code or nothing.
data HscStatus' a
HscNoRecomp :: HscStatus' a
HscRecomp :: (Maybe FilePath) -> a -> HscStatus' a
type InteractiveStatus = HscStatus' (Maybe (CompiledByteCode, ModBreaks))
type HscStatus = HscStatus' ()
hscCompileOneShot :: Compiler OneShotResult

-- | Compile Haskell, boot and extCore in batch mode.
hscCompileBatch :: Compiler (HscStatus, ModIface, ModDetails)
hscCompileNothing :: Compiler (HscStatus, ModIface, ModDetails)
hscCompileInteractive :: Compiler (InteractiveStatus, ModIface, ModDetails)
hscCompileCmmFile :: HscEnv -> FilePath -> IO ()
hscCompileCore :: HscEnv -> Bool -> SafeHaskellMode -> ModSummary -> CoreProgram -> IO ()

-- | parse a file, returning the abstract syntax
hscParse :: HscEnv -> ModSummary -> IO HsParsedModule

-- | Rename and typecheck a module, additionally returning the renamed
--   syntax
hscTypecheckRename :: HscEnv -> ModSummary -> HsParsedModule -> IO (TcGblEnv, RenamedStuff)

-- | Convert a typechecked module to Core
hscDesugar :: HscEnv -> ModSummary -> TcGblEnv -> IO ModGuts

-- | Make a <a>ModIface</a> from the results of typechecking. Used when not
--   optimising, and the interface doesn't need to contain any unfoldings
--   or other cross-module optimisation info. ToDo: the old interface is
--   only needed to get the version numbers, we should use fingerprint
--   versions instead.
makeSimpleIface :: HscEnv -> Maybe ModIface -> TcGblEnv -> ModDetails -> IO (ModIface, Bool)

-- | Make a <a>ModDetails</a> from the results of typechecking. Used when
--   typechecking only, as opposed to full compilation.
makeSimpleDetails :: HscEnv -> TcGblEnv -> IO ModDetails
hscSimplify :: HscEnv -> ModGuts -> IO ModGuts
hscOneShotBackendOnly :: TcGblEnv -> Compiler OneShotResult
hscBatchBackendOnly :: TcGblEnv -> Compiler BatchResult
hscNothingBackendOnly :: TcGblEnv -> Compiler NothingResult
hscInteractiveBackendOnly :: TcGblEnv -> Compiler InteractiveResult
hscParseIdentifier :: HscEnv -> String -> IO (Located RdrName)
hscTcRcLookupName :: HscEnv -> Name -> IO (Maybe TyThing)
hscTcRnGetInfo :: HscEnv -> Name -> IO (Maybe (TyThing, Fixity, [ClsInst]))

-- | Check that a module is safe to import.
--   
--   We return True to indicate the import is safe and False otherwise
--   although in the False case an exception may be thrown first.
hscCheckSafe :: HscEnv -> Module -> SrcSpan -> IO Bool

-- | Return if a module is trusted and the pkgs it depends on to be
--   trusted.
hscGetSafe :: HscEnv -> Module -> SrcSpan -> IO (Bool, [PackageId])
hscIsGHCiMonad :: HscEnv -> String -> IO Name
hscGetModuleInterface :: HscEnv -> Module -> IO ModIface

-- | Rename some import declarations
hscRnImportDecls :: HscEnv -> [LImportDecl RdrName] -> IO GlobalRdrEnv

-- | Lookup things in the compiler's environment
hscTcRnLookupRdrName :: HscEnv -> RdrName -> IO [Name]

-- | Compile a stmt all the way to an HValue, but don't run it
--   
--   We return Nothing to indicate an empty statement (or comment only),
--   not a parse error.
hscStmt :: HscEnv -> String -> IO (Maybe ([Id], IO [HValue], FixityEnv))

-- | Compile a stmt all the way to an HValue, but don't run it
--   
--   We return Nothing to indicate an empty statement (or comment only),
--   not a parse error.
hscStmtWithLocation :: HscEnv -> String -> String -> Int -> IO (Maybe ([Id], IO [HValue], FixityEnv))

-- | Compile a decls
hscDecls :: HscEnv -> String -> IO ([TyThing], InteractiveContext)

-- | Compile a decls
hscDeclsWithLocation :: HscEnv -> String -> String -> Int -> IO ([TyThing], InteractiveContext)

-- | Typecheck an expression (but don't run it)
hscTcExpr :: HscEnv -> String -> IO Type
hscImport :: HscEnv -> String -> IO (ImportDecl RdrName)

-- | Find the kind of a type
hscKcType :: HscEnv -> Bool -> String -> IO (Type, Kind)
hscCompileCoreExpr :: HscEnv -> SrcSpan -> CoreExpr -> IO HValue
instance HasDynFlags Hsc
instance Functor Hsc
instance MonadIO Hsc
instance Monad Hsc

module TcSplice
tcSpliceType :: HsSplice Name -> FreeVars -> TcM (TcType, TcKind)
tcSpliceExpr :: HsSplice Name -> TcRhoType -> TcM (HsExpr TcId)
tcSpliceDecls :: LHsExpr Name -> TcM [LHsDecl RdrName]
tcBracket :: HsBracket Name -> TcRhoType -> TcM (LHsExpr TcId)
lookupThName_maybe :: Name -> TcM (Maybe Name)
runQuasiQuoteExpr :: HsQuasiQuote RdrName -> RnM (LHsExpr RdrName)
runQuasiQuotePat :: HsQuasiQuote RdrName -> RnM (LPat RdrName)
runQuasiQuoteDecl :: HsQuasiQuote RdrName -> RnM [LHsDecl RdrName]
runQuasiQuoteType :: HsQuasiQuote RdrName -> RnM (LHsType RdrName)
runAnnotation :: CoreAnnTarget -> LHsExpr Name -> TcM Annotation
instance Quasi (IOEnv (Env TcGblEnv TcLclEnv))

module DriverPipeline
oneShot :: HscEnv -> Phase -> [(String, Maybe Phase)] -> IO ()
compileFile :: HscEnv -> Phase -> (FilePath, Maybe Phase) -> IO FilePath
linkBinary :: DynFlags -> [FilePath] -> [PackageId] -> IO ()

-- | Just preprocess a file, put the result in a temp. file (used by the
--   compilation manager during the summary phase).
--   
--   We return the augmented DynFlags, because they contain the result of
--   slurping in the OPTIONS pragmas
preprocess :: HscEnv -> (FilePath, Maybe Phase) -> IO (DynFlags, FilePath)

-- | Compile
--   
--   Compile a single module, under the control of the compilation manager.
--   
--   This is the interface between the compilation manager and the compiler
--   proper (hsc), where we deal with tedious details like reading the
--   OPTIONS pragma from the source file, converting the C or assembly that
--   GHC produces into an object file, and compiling FFI stub files.
--   
--   NB. No old interface can also mean that the source has changed.
compile :: HscEnv -> ModSummary -> Int -> Int -> Maybe ModIface -> Maybe Linkable -> SourceModified -> IO HomeModInfo
compile' :: (Compiler (HscStatus, ModIface, ModDetails), Compiler (InteractiveStatus, ModIface, ModDetails), Compiler (HscStatus, ModIface, ModDetails)) -> HscEnv -> ModSummary -> Int -> Int -> Maybe ModIface -> Maybe Linkable -> SourceModified -> IO HomeModInfo
link :: GhcLink -> DynFlags -> Bool -> HomePackageTable -> IO SuccessFlag
instance Monad CompPipeline
instance HasDynFlags CompPipeline

module GhcMake

-- | Perform a dependency analysis starting from the current targets and
--   update the session with the new module graph.
--   
--   Dependency analysis entails parsing the <tt>import</tt> directives and
--   may therefore require running certain preprocessors.
--   
--   Note that each <a>ModSummary</a> in the module graph caches its
--   <a>DynFlags</a>. These <a>DynFlags</a> are determined by the
--   <i>current</i> session <a>DynFlags</a> and the <tt>OPTIONS</tt> and
--   <tt>LANGUAGE</tt> pragmas of the parsed module. Thus if you want to
--   changes to the <a>DynFlags</a> to take effect you need to call this
--   function again.
depanal :: GhcMonad m => [ModuleName] -> Bool -> m ModuleGraph

-- | Try to load the program. See <a>LoadHowMuch</a> for the different
--   modes.
--   
--   This function implements the core of GHC's <tt>--make</tt> mode. It
--   preprocesses, compiles and loads the specified modules, avoiding
--   re-compilation wherever possible. Depending on the target (see
--   <a>hscTarget</a>) compilating and loading may result in files being
--   created on disk.
--   
--   Calls the <tt>reportModuleCompilationResult</tt> callback after each
--   compiling each module, whether successful or not.
--   
--   Throw a <a>SourceError</a> if errors are encountered before the actual
--   compilation starts (e.g., during dependency analysis). All other
--   errors are reported using the callback.
load :: GhcMonad m => LoadHowMuch -> m SuccessFlag

-- | Describes which modules of the module graph need to be loaded.
data LoadHowMuch

-- | Load all targets and its dependencies.
LoadAllTargets :: LoadHowMuch

-- | Load only the given module and its dependencies.
LoadUpTo :: ModuleName -> LoadHowMuch

-- | Load only the dependencies of the given module, but not the module
--   itself.
LoadDependenciesOf :: ModuleName -> LoadHowMuch

-- | Topological sort of the module graph
--   
--   Calculate SCCs of the module graph, possibly dropping the hi-boot
--   nodes The resulting list of strongly-connected-components is in
--   topologically sorted order, starting with the module(s) at the bottom
--   of the dependency graph (ie compile them first) and ending with the
--   ones at the top.
--   
--   Drop hi-boot nodes (first boolean arg)?
--   
--   <ul>
--   <li><tt>False</tt>: treat the hi-boot summaries as nodes of the graph,
--   so the graph must be acyclic</li>
--   <li><tt>True</tt>: eliminate the hi-boot nodes, and instead pretend
--   the a source-import of Foo is an import of Foo The resulting graph has
--   no hi-boot nodes, but can be cyclic</li>
--   </ul>
topSortModuleGraph :: Bool -> [ModSummary] -> Maybe ModuleName -> [SCC ModSummary]
noModError :: DynFlags -> SrcSpan -> ModuleName -> FindResult -> IO ab
cyclicModuleErr :: [ModSummary] -> SDoc

module InteractiveEval
data RunResult

-- | names bound by this evaluation
RunOk :: [Name] -> RunResult

-- | statement raised an exception
RunException :: SomeException -> RunResult
RunBreak :: ThreadId -> [Name] -> (Maybe BreakInfo) -> RunResult
data Status

-- | the computation hit a breakpoint (Bool <a>=</a> was an exception)
Break :: Bool -> HValue -> BreakInfo -> ThreadId -> Status

-- | the computation completed with either an exception or a value
Complete :: (Either SomeException [HValue]) -> Status
data Resume
Resume :: String -> ThreadId -> MVar () -> MVar Status -> ([TyThing], GlobalRdrEnv) -> [Id] -> HValue -> Maybe BreakInfo -> SrcSpan -> [History] -> Int -> Resume
resumeStmt :: Resume -> String
resumeThreadId :: Resume -> ThreadId
resumeBreakMVar :: Resume -> MVar ()
resumeStatMVar :: Resume -> MVar Status
resumeBindings :: Resume -> ([TyThing], GlobalRdrEnv)
resumeFinalIds :: Resume -> [Id]
resumeApStack :: Resume -> HValue
resumeBreakInfo :: Resume -> Maybe BreakInfo
resumeSpan :: Resume -> SrcSpan
resumeHistory :: Resume -> [History]
resumeHistoryIx :: Resume -> Int
data History
History :: HValue -> BreakInfo -> [String] -> History
historyApStack :: History -> HValue
historyBreakInfo :: History -> BreakInfo
historyEnclosingDecls :: History -> [String]

-- | Run a statement in the current interactive context. Statement may bind
--   multple values.
runStmt :: GhcMonad m => String -> SingleStep -> m RunResult

-- | Run a statement in the current interactive context. Passing debug
--   information Statement may bind multple values.
runStmtWithLocation :: GhcMonad m => String -> Int -> String -> SingleStep -> m RunResult
runDecls :: GhcMonad m => String -> m [Name]
runDeclsWithLocation :: GhcMonad m => String -> Int -> String -> m [Name]
parseImportDecl :: GhcMonad m => String -> m (ImportDecl RdrName)
data SingleStep
RunToCompletion :: SingleStep
SingleStep :: SingleStep
RunAndLogSteps :: SingleStep
resume :: GhcMonad m => (SrcSpan -> Bool) -> SingleStep -> m RunResult
abandon :: GhcMonad m => m Bool
abandonAll :: GhcMonad m => m Bool
getResumeContext :: GhcMonad m => m [Resume]
getHistorySpan :: HscEnv -> History -> SrcSpan
getModBreaks :: HomeModInfo -> ModBreaks
getHistoryModule :: History -> Module
back :: GhcMonad m => m ([Name], Int, SrcSpan)
forward :: GhcMonad m => m ([Name], Int, SrcSpan)

-- | Set the interactive evaluation context.
--   
--   Setting the context doesn't throw away any bindings; the bindings
--   we've built up in the InteractiveContext simply move to the new
--   module. They always shadow anything in scope in the current context.
setContext :: GhcMonad m => [InteractiveImport] -> m ()

-- | Get the interactive evaluation context, consisting of a pair of the
--   set of modules from which we take the full top-level scope, and the
--   set of modules from which we take just the exports respectively.
getContext :: GhcMonad m => m [InteractiveImport]
availsToGlobalRdrEnv :: ModuleName -> [AvailInfo] -> GlobalRdrEnv

-- | Returns all names in scope in the current interactive context
getNamesInScope :: GhcMonad m => m [Name]
getRdrNamesInScope :: GhcMonad m => m [RdrName]

-- | Returns <tt>True</tt> if the specified module is interpreted, and
--   hence has its full top-level scope available.
moduleIsInterpreted :: GhcMonad m => Module -> m Bool

-- | Looks up an identifier in the current interactive context (for :info)
--   Filter the instances by the ones whose tycons (or clases resp) are in
--   scope (qualified or otherwise). Otherwise we list a whole lot too
--   many! The exact choice of which ones to show, and which to hide, is a
--   judgement call. (see Trac #1581)
getInfo :: GhcMonad m => Name -> m (Maybe (TyThing, Fixity, [ClsInst]))

-- | Get the type of an expression
exprType :: GhcMonad m => String -> m Type

-- | Get the kind of a type
typeKind :: GhcMonad m => Bool -> String -> m (Type, Kind)

-- | Parses a string as an identifier, and returns the list of <a>Name</a>s
--   that the identifier can refer to in the current interactive context.
parseName :: GhcMonad m => String -> m [Name]
showModule :: GhcMonad m => ModSummary -> m String
isModuleInterpreted :: GhcMonad m => ModSummary -> m Bool
compileExpr :: GhcMonad m => String -> m HValue
dynCompileExpr :: GhcMonad m => String -> m Dynamic
data Term
Term :: RttiType -> Either String DataCon -> HValue -> [Term] -> Term
ty :: Term -> RttiType
dc :: Term -> Either String DataCon
val :: Term -> HValue
subTerms :: Term -> [Term]
Prim :: RttiType -> [Word] -> Term
ty :: Term -> RttiType
value :: Term -> [Word]
Suspension :: ClosureType -> RttiType -> HValue -> Maybe Name -> Term
ctype :: Term -> ClosureType
ty :: Term -> RttiType
val :: Term -> HValue
bound_to :: Term -> Maybe Name
NewtypeWrap :: RttiType -> Either String DataCon -> Term -> Term
ty :: Term -> RttiType
dc :: Term -> Either String DataCon
wrapped_term :: Term -> Term
RefWrap :: RttiType -> Term -> Term
ty :: Term -> RttiType
wrapped_term :: Term -> Term
obtainTermFromId :: HscEnv -> Int -> Bool -> Id -> IO Term
obtainTermFromVal :: HscEnv -> Int -> Bool -> Type -> a -> IO Term
reconstructType :: HscEnv -> Int -> Id -> IO (Maybe Type)

module GHC

-- | Install some default exception handlers and run the inner computation.
--   Unless you want to handle exceptions yourself, you should wrap this
--   around the top level of your program. The default handlers output the
--   error message(s) to stderr and exit cleanly.
defaultErrorHandler :: (ExceptionMonad m, MonadIO m) => FatalMessager -> FlushOut -> m a -> m a

-- | Install a default cleanup handler to remove temporary files deposited
--   by a GHC run. This is seperate from <a>defaultErrorHandler</a>,
--   because you might want to override the error handling, but still get
--   the ordinary cleanup behaviour.
defaultCleanupHandler :: (ExceptionMonad m, MonadIO m) => DynFlags -> m a -> m a
prettyPrintGhcErrors :: ExceptionMonad m => DynFlags -> m a -> m a

-- | A minimal implementation of a <a>GhcMonad</a>. If you need a custom
--   monad, e.g., to maintain additional state consider wrapping this monad
--   or using <a>GhcT</a>.
data Ghc a

-- | A monad transformer to add GHC specific features to another monad.
--   
--   Note that the wrapped monad must support IO and handling of
--   exceptions.
data GhcT m a

-- | A monad that has all the features needed by GHC API calls.
--   
--   In short, a GHC monad
--   
--   <ul>
--   <li>allows embedding of IO actions,</li>
--   <li>can log warnings,</li>
--   <li>allows handling of (extensible) exceptions, and</li>
--   <li>maintains a current session.</li>
--   </ul>
--   
--   If you do not use <a>Ghc</a> or <a>GhcT</a>, make sure to call
--   <a>initGhcMonad</a> before any call to the GHC API functions can
--   occur.
class (Functor m, MonadIO m, ExceptionMonad m, HasDynFlags m) => GhcMonad m
getSession :: GhcMonad m => m HscEnv
setSession :: GhcMonad m => HscEnv -> m ()

-- | Hscenv is like <tt>Session</tt>, except that some of the fields are
--   immutable. An HscEnv is used to compile a single module from plain
--   Haskell source code (after preprocessing) to either C, assembly or
--   C--. Things like the module graph don't change during a single
--   compilation.
--   
--   Historical note: "hsc" used to be the name of the compiler binary,
--   when there was a separate driver and compiler. To compile a single
--   module, the driver would invoke hsc on the source code... so nowadays
--   we think of hsc as the layer of the compiler that deals with compiling
--   a single module.
data HscEnv

-- | Run function for the <a>Ghc</a> monad.
--   
--   It initialises the GHC session and warnings via <a>initGhcMonad</a>.
--   Each call to this function will create a new session which should not
--   be shared among several threads.
--   
--   Any errors not handled inside the <a>Ghc</a> action are propagated as
--   IO exceptions.
runGhc :: Maybe FilePath -> Ghc a -> IO a

-- | Run function for <a>GhcT</a> monad transformer.
--   
--   It initialises the GHC session and warnings via <a>initGhcMonad</a>.
--   Each call to this function will create a new session which should not
--   be shared among several threads.
runGhcT :: (ExceptionMonad m, Functor m, MonadIO m) => Maybe FilePath -> GhcT m a -> m a

-- | Initialise a GHC session.
--   
--   If you implement a custom <a>GhcMonad</a> you must call this function
--   in the monad run function. It will initialise the session variable and
--   clear all warnings.
--   
--   The first argument should point to the directory where GHC's library
--   files reside. More precisely, this should be the output of <tt>ghc
--   --print-libdir</tt> of the version of GHC the module using this API is
--   compiled with. For portability, you should use the <tt>ghc-paths</tt>
--   package, available at
--   <a>http://hackage.haskell.org/cgi-bin/hackage-scripts/package/ghc-paths</a>.
initGhcMonad :: GhcMonad m => Maybe FilePath -> m ()

-- | Generalised version of <a>catch</a>, allowing an arbitrary exception
--   handling monad instead of just <a>IO</a>.
gcatch :: (ExceptionMonad m, Exception e) => m a -> (e -> m a) -> m a

-- | Generalised version of <a>bracket</a>, allowing an arbitrary exception
--   handling monad instead of just <a>IO</a>.
gbracket :: ExceptionMonad m => m a -> (a -> m b) -> (a -> m c) -> m c

-- | Generalised version of <a>finally</a>, allowing an arbitrary exception
--   handling monad instead of just <a>IO</a>.
gfinally :: ExceptionMonad m => m a -> m b -> m a

-- | Print the error message and all warnings. Useful inside exception
--   handlers. Clears warnings after printing.
printException :: GhcMonad m => SourceError -> m ()

-- | <i>Deprecated: use printException instead </i>
printExceptionAndWarnings :: GhcMonad m => SourceError -> m ()

-- | Perform the given action and call the exception handler if the action
--   throws a <a>SourceError</a>. See <a>SourceError</a> for more
--   information.
handleSourceError :: ExceptionMonad m => (SourceError -> m a) -> m a -> m a

-- | Determines whether a set of modules requires Template Haskell.
--   
--   Note that if the session's <a>DynFlags</a> enabled Template Haskell
--   when <a>depanal</a> was called, then each module in the returned
--   module graph will have Template Haskell enabled whether it is actually
--   needed or not.
needsTemplateHaskell :: ModuleGraph -> Bool

-- | Contains not only a collection of <a>DynFlag</a>s but also a plethora
--   of information relating to the compilation of a single file or GHC
--   session
data DynFlags
DynFlags :: GhcMode -> GhcLink -> HscTarget -> Settings -> String -> String -> Int -> Int -> Int -> Int -> Maybe String -> Maybe String -> [Int] -> Int -> Maybe Int -> Maybe Int -> Maybe Int -> Maybe Int -> [String] -> [FilePath] -> Module -> Maybe String -> Int -> PackageId -> [Way] -> String -> String -> Maybe (String, Int) -> Maybe String -> Maybe String -> Maybe String -> Maybe String -> Maybe String -> String -> String -> String -> Maybe String -> Maybe String -> DynLibLoader -> Maybe FilePath -> Maybe FilePath -> [String] -> [String] -> [String] -> [String] -> Maybe String -> RtsOptsEnabled -> String -> [ModuleName] -> [(ModuleName, String)] -> FilePath -> Bool -> [ModuleName] -> [String] -> ([PkgConfRef] -> [PkgConfRef]) -> [PackageFlag] -> Maybe [PackageConfig] -> PackageState -> IORef [FilePath] -> IORef (Map FilePath FilePath) -> IORef (Set FilePath) -> IntSet -> IntSet -> Maybe Language -> SafeHaskellMode -> SrcSpan -> SrcSpan -> SrcSpan -> SrcSpan -> SrcSpan -> [OnOff ExtensionFlag] -> IntSet -> LogAction -> FlushOut -> FlushErr -> Maybe String -> [String] -> Int -> Int -> Int -> ProfAuto -> Maybe String -> IORef (Int) -> DynFlags
ghcMode :: DynFlags -> GhcMode
ghcLink :: DynFlags -> GhcLink
hscTarget :: DynFlags -> HscTarget
settings :: DynFlags -> Settings

-- | Name of the output file
hscOutName :: DynFlags -> String

-- | Name of the .hcr output file
extCoreName :: DynFlags -> String

-- | Verbosity level: see Note [Verbosity levels]
verbosity :: DynFlags -> Int

-- | Optimisation level
optLevel :: DynFlags -> Int

-- | Number of simplifier phases
simplPhases :: DynFlags -> Int

-- | Max simplifier iterations
maxSimplIterations :: DynFlags -> Int
shouldDumpSimplPhase :: DynFlags -> Maybe String
ruleCheck :: DynFlags -> Maybe String

-- | Additional demand analysis
strictnessBefore :: DynFlags -> [Int]

-- | Multiplier for simplifier ticks
simplTickFactor :: DynFlags -> Int

-- | Threshold for SpecConstr
specConstrThreshold :: DynFlags -> Maybe Int

-- | Max number of specialisations for any one function
specConstrCount :: DynFlags -> Maybe Int

-- | Threshold for LiberateCase
liberateCaseThreshold :: DynFlags -> Maybe Int

-- | Arg count for lambda floating See CoreMonad.FloatOutSwitches
floatLamArgs :: DynFlags -> Maybe Int

-- | <pre>
--   -#includes
--   </pre>
cmdlineHcIncludes :: DynFlags -> [String]
importPaths :: DynFlags -> [FilePath]
mainModIs :: DynFlags -> Module
mainFunIs :: DynFlags -> Maybe String

-- | Typechecker context stack depth
ctxtStkDepth :: DynFlags -> Int

-- | name of package currently being compiled
thisPackage :: DynFlags -> PackageId

-- | Way flags from the command line
ways :: DynFlags -> [Way]

-- | The global "way" (e.g. "p" for prof)
buildTag :: DynFlags -> String

-- | The RTS "way"
rtsBuildTag :: DynFlags -> String
splitInfo :: DynFlags -> Maybe (String, Int)
objectDir :: DynFlags -> Maybe String
dylibInstallName :: DynFlags -> Maybe String
hiDir :: DynFlags -> Maybe String
stubDir :: DynFlags -> Maybe String
dumpDir :: DynFlags -> Maybe String
objectSuf :: DynFlags -> String
hcSuf :: DynFlags -> String
hiSuf :: DynFlags -> String
outputFile :: DynFlags -> Maybe String
outputHi :: DynFlags -> Maybe String
dynLibLoader :: DynFlags -> DynLibLoader

-- | This is set by <a>runPipeline</a> based on where its output is going.
dumpPrefix :: DynFlags -> Maybe FilePath

-- | Override the <a>dumpPrefix</a> set by <a>runPipeline</a>. Set by
--   <tt>-ddump-file-prefix</tt>
dumpPrefixForce :: DynFlags -> Maybe FilePath
includePaths :: DynFlags -> [String]
libraryPaths :: DynFlags -> [String]
frameworkPaths :: DynFlags -> [String]
cmdlineFrameworks :: DynFlags -> [String]
rtsOpts :: DynFlags -> Maybe String
rtsOptsEnabled :: DynFlags -> RtsOptsEnabled

-- | Path to store the .mix files
hpcDir :: DynFlags -> String
pluginModNames :: DynFlags -> [ModuleName]
pluginModNameOpts :: DynFlags -> [(ModuleName, String)]
depMakefile :: DynFlags -> FilePath
depIncludePkgDeps :: DynFlags -> Bool
depExcludeMods :: DynFlags -> [ModuleName]
depSuffixes :: DynFlags -> [String]

-- | The <tt>-package-db</tt> flags given on the command line, in the order
--   they appeared.
extraPkgConfs :: DynFlags -> [PkgConfRef] -> [PkgConfRef]

-- | The <tt>-package</tt> and <tt>-hide-package</tt> flags from the
--   command-line
packageFlags :: DynFlags -> [PackageFlag]
pkgDatabase :: DynFlags -> Maybe [PackageConfig]
pkgState :: DynFlags -> PackageState
filesToClean :: DynFlags -> IORef [FilePath]
dirsToClean :: DynFlags -> IORef (Map FilePath FilePath)
generatedDumps :: DynFlags -> IORef (Set FilePath)
flags :: DynFlags -> IntSet
warningFlags :: DynFlags -> IntSet
language :: DynFlags -> Maybe Language

-- | Safe Haskell mode
safeHaskell :: DynFlags -> SafeHaskellMode
thOnLoc :: DynFlags -> SrcSpan
newDerivOnLoc :: DynFlags -> SrcSpan
pkgTrustOnLoc :: DynFlags -> SrcSpan
warnSafeOnLoc :: DynFlags -> SrcSpan
warnUnsafeOnLoc :: DynFlags -> SrcSpan
extensions :: DynFlags -> [OnOff ExtensionFlag]
extensionFlags :: DynFlags -> IntSet

-- | MsgDoc output action: use <a>ErrUtils</a> instead of this if you can
log_action :: DynFlags -> LogAction
flushOut :: DynFlags -> FlushOut
flushErr :: DynFlags -> FlushErr
haddockOptions :: DynFlags -> Maybe String
ghciScripts :: DynFlags -> [String]
pprUserLength :: DynFlags -> Int
pprCols :: DynFlags -> Int
traceLevel :: DynFlags -> Int

-- | what kind of {--} to add automatically
profAuto :: DynFlags -> ProfAuto
interactivePrint :: DynFlags -> Maybe String
llvmVersion :: DynFlags -> IORef (Int)

-- | Enumerates the simple on-or-off dynamic flags
data DynFlag
Opt_D_dump_cmm :: DynFlag
Opt_D_dump_raw_cmm :: DynFlag
Opt_D_dump_cmmz :: DynFlag
Opt_D_dump_cmmz_cfg :: DynFlag
Opt_D_dump_cmmz_cbe :: DynFlag
Opt_D_dump_cmmz_proc :: DynFlag
Opt_D_dump_cmmz_spills :: DynFlag
Opt_D_dump_cmmz_rewrite :: DynFlag
Opt_D_dump_cmmz_dead :: DynFlag
Opt_D_dump_cmmz_stub :: DynFlag
Opt_D_dump_cmmz_sp :: DynFlag
Opt_D_dump_cmmz_procmap :: DynFlag
Opt_D_dump_cmmz_split :: DynFlag
Opt_D_dump_cmmz_lower :: DynFlag
Opt_D_dump_cmmz_info :: DynFlag
Opt_D_dump_cmmz_cafs :: DynFlag
Opt_D_dump_cps_cmm :: DynFlag
Opt_D_dump_cvt_cmm :: DynFlag
Opt_D_dump_asm :: DynFlag
Opt_D_dump_asm_native :: DynFlag
Opt_D_dump_asm_liveness :: DynFlag
Opt_D_dump_asm_coalesce :: DynFlag
Opt_D_dump_asm_regalloc :: DynFlag
Opt_D_dump_asm_regalloc_stages :: DynFlag
Opt_D_dump_asm_conflicts :: DynFlag
Opt_D_dump_asm_stats :: DynFlag
Opt_D_dump_asm_expanded :: DynFlag
Opt_D_dump_llvm :: DynFlag
Opt_D_dump_core_stats :: DynFlag
Opt_D_dump_cpranal :: DynFlag
Opt_D_dump_deriv :: DynFlag
Opt_D_dump_ds :: DynFlag
Opt_D_dump_flatC :: DynFlag
Opt_D_dump_foreign :: DynFlag
Opt_D_dump_inlinings :: DynFlag
Opt_D_dump_rule_firings :: DynFlag
Opt_D_dump_rule_rewrites :: DynFlag
Opt_D_dump_occur_anal :: DynFlag
Opt_D_dump_parsed :: DynFlag
Opt_D_dump_rn :: DynFlag
Opt_D_dump_core_pipeline :: DynFlag
Opt_D_dump_simpl :: DynFlag
Opt_D_dump_simpl_iterations :: DynFlag
Opt_D_dump_simpl_phases :: DynFlag
Opt_D_dump_spec :: DynFlag
Opt_D_dump_prep :: DynFlag
Opt_D_dump_stg :: DynFlag
Opt_D_dump_stranal :: DynFlag
Opt_D_dump_tc :: DynFlag
Opt_D_dump_types :: DynFlag
Opt_D_dump_rules :: DynFlag
Opt_D_dump_cse :: DynFlag
Opt_D_dump_worker_wrapper :: DynFlag
Opt_D_dump_rn_trace :: DynFlag
Opt_D_dump_rn_stats :: DynFlag
Opt_D_dump_opt_cmm :: DynFlag
Opt_D_dump_simpl_stats :: DynFlag
Opt_D_dump_cs_trace :: DynFlag
Opt_D_dump_tc_trace :: DynFlag
Opt_D_dump_if_trace :: DynFlag
Opt_D_dump_vt_trace :: DynFlag
Opt_D_dump_splices :: DynFlag
Opt_D_dump_BCOs :: DynFlag
Opt_D_dump_vect :: DynFlag
Opt_D_dump_avoid_vect :: DynFlag
Opt_D_dump_ticked :: DynFlag
Opt_D_dump_rtti :: DynFlag
Opt_D_source_stats :: DynFlag
Opt_D_verbose_core2core :: DynFlag
Opt_D_verbose_stg2stg :: DynFlag
Opt_D_dump_hi :: DynFlag
Opt_D_dump_hi_diffs :: DynFlag
Opt_D_dump_minimal_imports :: DynFlag
Opt_D_dump_mod_cycles :: DynFlag
Opt_D_dump_view_pattern_commoning :: DynFlag
Opt_D_faststring_stats :: DynFlag

-- | Append dump output to files instead of stdout.
Opt_DumpToFile :: DynFlag
Opt_D_no_debug_output :: DynFlag
Opt_DoCoreLinting :: DynFlag
Opt_DoStgLinting :: DynFlag
Opt_DoCmmLinting :: DynFlag
Opt_DoAsmLinting :: DynFlag
Opt_NoLlvmMangler :: DynFlag
Opt_WarnIsError :: DynFlag
Opt_PrintExplicitForalls :: DynFlag
Opt_Strictness :: DynFlag
Opt_FullLaziness :: DynFlag
Opt_FloatIn :: DynFlag
Opt_Specialise :: DynFlag
Opt_StaticArgumentTransformation :: DynFlag
Opt_CSE :: DynFlag
Opt_LiberateCase :: DynFlag
Opt_SpecConstr :: DynFlag
Opt_DoLambdaEtaExpansion :: DynFlag
Opt_IgnoreAsserts :: DynFlag
Opt_DoEtaReduction :: DynFlag
Opt_CaseMerge :: DynFlag
Opt_UnboxStrictFields :: DynFlag
Opt_DictsCheap :: DynFlag
Opt_EnableRewriteRules :: DynFlag
Opt_Vectorise :: DynFlag
Opt_AvoidVect :: DynFlag
Opt_RegsGraph :: DynFlag
Opt_RegsIterative :: DynFlag
Opt_PedanticBottoms :: DynFlag
Opt_LlvmTBAA :: DynFlag
Opt_RegLiveness :: DynFlag
Opt_IrrefutableTuples :: DynFlag
Opt_IgnoreInterfacePragmas :: DynFlag
Opt_OmitInterfacePragmas :: DynFlag
Opt_ExposeAllUnfoldings :: DynFlag
Opt_AutoSccsOnIndividualCafs :: DynFlag
Opt_ProfCountEntries :: DynFlag
Opt_Pp :: DynFlag
Opt_ForceRecomp :: DynFlag
Opt_ExcessPrecision :: DynFlag
Opt_EagerBlackHoling :: DynFlag
Opt_NoHsMain :: DynFlag
Opt_SplitObjs :: DynFlag
Opt_StgStats :: DynFlag
Opt_HideAllPackages :: DynFlag
Opt_PrintBindResult :: DynFlag
Opt_Haddock :: DynFlag
Opt_HaddockOptions :: DynFlag
Opt_Hpc_No_Auto :: DynFlag
Opt_BreakOnException :: DynFlag
Opt_BreakOnError :: DynFlag
Opt_PrintEvldWithShow :: DynFlag
Opt_PrintBindContents :: DynFlag
Opt_GenManifest :: DynFlag
Opt_EmbedManifest :: DynFlag
Opt_EmitExternalCore :: DynFlag
Opt_SharedImplib :: DynFlag
Opt_BuildingCabalPackage :: DynFlag
Opt_SSE2 :: DynFlag
Opt_SSE4_2 :: DynFlag
Opt_IgnoreDotGhci :: DynFlag
Opt_GhciSandbox :: DynFlag
Opt_GhciHistory :: DynFlag
Opt_HelpfulErrors :: DynFlag
Opt_DeferTypeErrors :: DynFlag
Opt_Parallel :: DynFlag
Opt_GranMacros :: DynFlag
Opt_PprCaseAsLet :: DynFlag
Opt_RunCPS :: DynFlag
Opt_RunCPSZ :: DynFlag
Opt_AutoLinkPackages :: DynFlag
Opt_ImplicitImportQualified :: DynFlag
Opt_TryNewCodeGen :: DynFlag
Opt_KeepHiDiffs :: DynFlag
Opt_KeepHcFiles :: DynFlag
Opt_KeepSFiles :: DynFlag
Opt_KeepTmpFiles :: DynFlag
Opt_KeepRawTokenStream :: DynFlag
Opt_KeepLlvmFiles :: DynFlag
Opt_DistrustAllPackages :: DynFlag
Opt_PackageTrust :: DynFlag
data Severity
SevOutput :: Severity
SevDump :: Severity
SevInfo :: Severity
SevWarning :: Severity
SevError :: Severity
SevFatal :: Severity

-- | The target code type of the compilation (if any).
--   
--   Whenever you change the target, also make sure to set <a>ghcLink</a>
--   to something sensible.
--   
--   <a>HscNothing</a> can be used to avoid generating any output, however,
--   note that:
--   
--   <ul>
--   <li>This will not run the desugaring step, thus no warnings generated
--   in this step will be output. In particular, this includes warnings
--   related to pattern matching. You can run the desugarer manually using
--   <a>desugarModule</a>.</li>
--   <li>If a program uses Template Haskell the typechecker may try to run
--   code from an imported module. This will fail if no code has been
--   generated for this module. You can use <a>needsTemplateHaskell</a> to
--   detect whether this might be the case and choose to either switch to a
--   different target or avoid typechecking such modules. (The latter may
--   be preferable for security reasons.)</li>
--   </ul>
data HscTarget

-- | Generate C code.
HscC :: HscTarget

-- | Generate assembly using the native code generator.
HscAsm :: HscTarget

-- | Generate assembly using the llvm code generator.
HscLlvm :: HscTarget

-- | Generate bytecode. (Requires <a>LinkInMemory</a>)
HscInterpreted :: HscTarget

-- | Don't generate any code. See notes above.
HscNothing :: HscTarget

-- | Test whether a <a>DynFlag</a> is set
dopt :: DynFlag -> DynFlags -> Bool

-- | The <a>GhcMode</a> tells us whether we're doing multi-module
--   compilation (controlled via the <a>GHC</a> API) or one-shot
--   (single-module) compilation. This makes a difference primarily to the
--   <a>Finder</a>: in one-shot mode we look for interface files for
--   imported modules, but in multi-module mode we look for source files in
--   order to check whether they need to be recompiled.
data GhcMode

-- | <tt>--make</tt>, GHCi, etc.
CompManager :: GhcMode

-- | <pre>
--   ghc -c Foo.hs
--   </pre>
OneShot :: GhcMode

-- | <tt>ghc -M</tt>, see <a>Finder</a> for why we need this
MkDepend :: GhcMode

-- | What to do in the link step, if there is one.
data GhcLink

-- | Don't link at all
NoLink :: GhcLink

-- | Link object code into a binary
LinkBinary :: GhcLink

-- | Use the in-memory dynamic linker (works for both bytecode and object
--   code).
LinkInMemory :: GhcLink

-- | Link objects into a dynamic lib (DLL on Windows, DSO on ELF platforms)
LinkDynLib :: GhcLink

-- | The <a>HscTarget</a> value corresponding to the default way to create
--   object files on the current platform.
defaultObjectTarget :: HscTarget
parseDynamicFlags :: Monad m => DynFlags -> [Located String] -> m (DynFlags, [Located String], [Located String])

-- | Grabs the DynFlags from the Session
getSessionDynFlags :: GhcMonad m => m DynFlags

-- | Updates both the interactive and program DynFlags in a Session. This
--   also reads the package database (unless it has already been read), and
--   prepares the compilers knowledge about packages. It can be called
--   again to load new packages: just add new package flags to
--   (packageFlags dflags).
--   
--   Returns a list of new packages that may need to be linked in using the
--   dynamic linker (see <tt>linkPackages</tt>) as a result of new package
--   flags. If you are not doing linking or doing static linking, you can
--   ignore the list of packages returned.
setSessionDynFlags :: GhcMonad m => DynFlags -> m [PackageId]

-- | Returns the program <a>DynFlags</a>.
getProgramDynFlags :: GhcMonad m => m DynFlags

-- | Sets the program <a>DynFlags</a>.
setProgramDynFlags :: GhcMonad m => DynFlags -> m [PackageId]

-- | Get the <a>DynFlags</a> used to evaluate interactive expressions.
getInteractiveDynFlags :: GhcMonad m => m DynFlags

-- | Set the <a>DynFlags</a> used to evaluate interactive expressions.
--   Note: this cannot be used for changes to packages. Use
--   <a>setSessionDynFlags</a>, or <a>setProgramDynFlags</a> and then copy
--   the <a>pkgState</a> into the interactive <tt>DynFlags</tt>.
setInteractiveDynFlags :: GhcMonad m => DynFlags -> m ()

-- | Parses GHC's static flags from a list of command line arguments.
--   
--   These flags are static in the sense that they can be set only once and
--   they are global, meaning that they affect every instance of GHC
--   running; multiple GHC threads will use the same flags.
--   
--   This function must be called before any session is started, i.e.,
--   before the first call to <a>withGhc</a>.
--   
--   Static flags are more of a hack and are static for more or less
--   historical reasons. In the long run, most static flags should
--   eventually become dynamic flags.
--   
--   XXX: can we add an auto-generated list of static flags here?
parseStaticFlags :: [Located String] -> IO ([Located String], [Located String])

-- | A compilation target.
--   
--   A target may be supplied with the actual text of the module. If so,
--   use this instead of the file contents (this is for use in an IDE where
--   the file hasn't been saved by the user yet).
data Target
Target :: TargetId -> Bool -> Maybe (StringBuffer, UTCTime) -> Target

-- | module or filename
targetId :: Target -> TargetId

-- | object code allowed?
targetAllowObjCode :: Target -> Bool

-- | in-memory text buffer?
targetContents :: Target -> Maybe (StringBuffer, UTCTime)
data TargetId

-- | A module name: search for the file
TargetModule :: ModuleName -> TargetId

-- | A filename: preprocess &amp; parse it to find the module name. If
--   specified, the Phase indicates how to compile this file (which phase
--   to start from). Nothing indicates the starting phase should be
--   determined from the suffix of the filename.
TargetFile :: FilePath -> (Maybe Phase) -> TargetId
data Phase

-- | Sets the targets for this session. Each target may be a module name or
--   a filename. The targets correspond to the set of root modules for the
--   program/library. Unloading the current program is achieved by setting
--   the current set of targets to be empty, followed by <a>load</a>.
setTargets :: GhcMonad m => [Target] -> m ()

-- | Returns the current set of targets
getTargets :: GhcMonad m => m [Target]

-- | Add another target.
addTarget :: GhcMonad m => Target -> m ()

-- | Remove a target
removeTarget :: GhcMonad m => TargetId -> m ()

-- | Attempts to guess what Target a string refers to. This function
--   implements the <tt>--make</tt>/GHCi command-line syntax for filenames:
--   
--   <ul>
--   <li>if the string looks like a Haskell source filename, then interpret
--   it as such</li>
--   <li>if adding a .hs or .lhs suffix yields the name of an existing
--   file, then use that</li>
--   <li>otherwise interpret the string as a module name</li>
--   </ul>
guessTarget :: GhcMonad m => String -> Maybe Phase -> m Target

-- | Perform a dependency analysis starting from the current targets and
--   update the session with the new module graph.
--   
--   Dependency analysis entails parsing the <tt>import</tt> directives and
--   may therefore require running certain preprocessors.
--   
--   Note that each <a>ModSummary</a> in the module graph caches its
--   <a>DynFlags</a>. These <a>DynFlags</a> are determined by the
--   <i>current</i> session <a>DynFlags</a> and the <tt>OPTIONS</tt> and
--   <tt>LANGUAGE</tt> pragmas of the parsed module. Thus if you want to
--   changes to the <a>DynFlags</a> to take effect you need to call this
--   function again.
depanal :: GhcMonad m => [ModuleName] -> Bool -> m ModuleGraph

-- | Try to load the program. See <a>LoadHowMuch</a> for the different
--   modes.
--   
--   This function implements the core of GHC's <tt>--make</tt> mode. It
--   preprocesses, compiles and loads the specified modules, avoiding
--   re-compilation wherever possible. Depending on the target (see
--   <a>hscTarget</a>) compilating and loading may result in files being
--   created on disk.
--   
--   Calls the <tt>reportModuleCompilationResult</tt> callback after each
--   compiling each module, whether successful or not.
--   
--   Throw a <a>SourceError</a> if errors are encountered before the actual
--   compilation starts (e.g., during dependency analysis). All other
--   errors are reported using the callback.
load :: GhcMonad m => LoadHowMuch -> m SuccessFlag

-- | Describes which modules of the module graph need to be loaded.
data LoadHowMuch

-- | Load all targets and its dependencies.
LoadAllTargets :: LoadHowMuch

-- | Load only the given module and its dependencies.
LoadUpTo :: ModuleName -> LoadHowMuch

-- | Load only the dependencies of the given module, but not the module
--   itself.
LoadDependenciesOf :: ModuleName -> LoadHowMuch
data InteractiveImport

-- | Bring the exports of a particular module (filtered by an import decl)
--   into scope
IIDecl :: (ImportDecl RdrName) -> InteractiveImport

-- | Bring into scope the entire top-level envt of of this module,
--   including the things imported into it.
IIModule :: ModuleName -> InteractiveImport
data SuccessFlag
Succeeded :: SuccessFlag
Failed :: SuccessFlag
succeeded :: SuccessFlag -> Bool
failed :: SuccessFlag -> Bool
defaultWarnErrLogger :: WarnErrLogger

-- | A function called to log warnings and errors.
type WarnErrLogger = GhcMonad m => Maybe SourceError -> m ()

-- | Inform GHC that the working directory has changed. GHC will flush its
--   cache of module locations, since it may no longer be valid.
--   
--   Note: Before changing the working directory make sure all threads
--   running in the same session have stopped. If you change the working
--   directory, you should also unload the current program (set targets to
--   empty, followed by load).
workingDirectoryChanged :: GhcMonad m => m ()

-- | Parse a module.
--   
--   Throws a <a>SourceError</a> on parse error.
parseModule :: GhcMonad m => ModSummary -> m ParsedModule

-- | Typecheck and rename a parsed module.
--   
--   Throws a <a>SourceError</a> if either fails.
typecheckModule :: GhcMonad m => ParsedModule -> m TypecheckedModule

-- | Desugar a typechecked module.
desugarModule :: GhcMonad m => TypecheckedModule -> m DesugaredModule

-- | Load a module. Input doesn't need to be desugared.
--   
--   A module must be loaded before dependent modules can be typechecked.
--   This always includes generating a <a>ModIface</a> and, depending on
--   the <a>hscTarget</a>, may also include code generation.
--   
--   This function will always cause recompilation and will always
--   overwrite previous compilation results (potentially files on disk).
loadModule :: (TypecheckedMod mod, GhcMonad m) => mod -> m mod

-- | The result of successful parsing.
data ParsedModule
ParsedModule :: ModSummary -> ParsedSource -> [FilePath] -> ParsedModule
pm_mod_summary :: ParsedModule -> ModSummary
pm_parsed_source :: ParsedModule -> ParsedSource
pm_extra_src_files :: ParsedModule -> [FilePath]

-- | The result of successful typechecking. It also contains the parser
--   result.
data TypecheckedModule
TypecheckedModule :: ParsedModule -> Maybe RenamedSource -> TypecheckedSource -> ModuleInfo -> (TcGblEnv, ModDetails) -> TypecheckedModule
tm_parsed_module :: TypecheckedModule -> ParsedModule
tm_renamed_source :: TypecheckedModule -> Maybe RenamedSource
tm_typechecked_source :: TypecheckedModule -> TypecheckedSource
tm_checked_module_info :: TypecheckedModule -> ModuleInfo
tm_internals_ :: TypecheckedModule -> (TcGblEnv, ModDetails)

-- | The result of successful desugaring (i.e., translation to core). Also
--   contains all the information of a typechecked module.
data DesugaredModule
DesugaredModule :: TypecheckedModule -> ModGuts -> DesugaredModule
dm_typechecked_module :: DesugaredModule -> TypecheckedModule
dm_core_module :: DesugaredModule -> ModGuts
type TypecheckedSource = LHsBinds Id
type ParsedSource = Located (HsModule RdrName)
type RenamedSource = (HsGroup Name, [LImportDecl Name], Maybe [LIE Name], Maybe LHsDocString)
class ParsedMod m => TypecheckedMod m
renamedSource :: TypecheckedMod m => m -> Maybe RenamedSource
typecheckedSource :: TypecheckedMod m => m -> TypecheckedSource
moduleInfo :: TypecheckedMod m => m -> ModuleInfo
class ParsedMod m
parsedSource :: ParsedMod m => m -> ParsedSource
coreModule :: DesugaredMod m => m -> ModGuts

-- | A CoreModule consists of just the fields of a <a>ModGuts</a> that are
--   needed for the <a>compileToCoreModule</a> interface.
data CoreModule
CoreModule :: !Module -> !TypeEnv -> CoreProgram -> SafeHaskellMode -> CoreModule

-- | Module name
cm_module :: CoreModule -> !Module

-- | Type environment for types declared in this module
cm_types :: CoreModule -> !TypeEnv

-- | Declarations
cm_binds :: CoreModule -> CoreProgram

-- | Safe Haskell mode
cm_safe :: CoreModule -> SafeHaskellMode

-- | This is the way to get access to the Core bindings corresponding to a
--   module. <tt>compileToCore</tt> parses, typechecks, and desugars the
--   module, then returns the resulting Core module (consisting of the
--   module name, type declarations, and function declarations) if
--   successful.
compileToCoreModule :: GhcMonad m => FilePath -> m CoreModule

-- | Like compileToCoreModule, but invokes the simplifier, so as to return
--   simplified and tidied Core.
compileToCoreSimplified :: GhcMonad m => FilePath -> m CoreModule

-- | Takes a CoreModule and compiles the bindings therein to object code.
--   The first argument is a bool flag indicating whether to run the
--   simplifier. The resulting .o, .hi, and executable files, if any, are
--   stored in the current directory, and named according to the module
--   name. This has only so far been tested with a single self-contained
--   module.
compileCoreToObj :: GhcMonad m => Bool -> CoreModule -> m ()

-- | A ModuleGraph contains all the nodes from the home package (only).
--   There will be a node for each source module, plus a node for each
--   hi-boot module.
--   
--   The graph is not necessarily stored in topologically-sorted order. Use
--   <a>topSortModuleGraph</a> and <a>flattenSCC</a> to achieve this.
type ModuleGraph = [ModSummary]

-- | A single node in a 'ModuleGraph. The nodes of the module graph are one
--   of:
--   
--   <ul>
--   <li>A regular Haskell source module</li>
--   <li>A hi-boot source module</li>
--   <li>An external-core source module</li>
--   </ul>
data ModSummary
ModSummary :: Module -> HscSource -> ModLocation -> UTCTime -> Maybe UTCTime -> [Located (ImportDecl RdrName)] -> [Located (ImportDecl RdrName)] -> FilePath -> DynFlags -> Maybe StringBuffer -> ModSummary

-- | Identity of the module
ms_mod :: ModSummary -> Module

-- | The module source either plain Haskell, hs-boot or external core
ms_hsc_src :: ModSummary -> HscSource

-- | Location of the various files belonging to the module
ms_location :: ModSummary -> ModLocation

-- | Timestamp of source file
ms_hs_date :: ModSummary -> UTCTime

-- | Timestamp of object, if we have one
ms_obj_date :: ModSummary -> Maybe UTCTime

-- | Source imports of the module
ms_srcimps :: ModSummary -> [Located (ImportDecl RdrName)]

-- | Non-source imports of the module from the module *text*
ms_textual_imps :: ModSummary -> [Located (ImportDecl RdrName)]

-- | Filename of preprocessed source file
ms_hspp_file :: ModSummary -> FilePath

-- | Cached flags from <tt>OPTIONS</tt>, <tt>INCLUDE</tt> and
--   <tt>LANGUAGE</tt> pragmas in the modules source code
ms_hspp_opts :: ModSummary -> DynFlags

-- | The actual preprocessed source, if we have it
ms_hspp_buf :: ModSummary -> Maybe StringBuffer
ms_mod_name :: ModSummary -> ModuleName

-- | Where a module lives on the file system: the actual locations of the
--   .hs, .hi and .o files, if we have them
data ModLocation
ModLocation :: Maybe FilePath -> FilePath -> FilePath -> ModLocation
ml_hs_file :: ModLocation -> Maybe FilePath
ml_hi_file :: ModLocation -> FilePath
ml_obj_file :: ModLocation -> FilePath

-- | Return the <a>ModSummary</a> of a module with the given name.
--   
--   The module must be part of the module graph (see <a>hsc_mod_graph</a>
--   and <a>ModuleGraph</a>). If this is not the case, this function will
--   throw a <a>GhcApiError</a>.
--   
--   This function ignores boot modules and requires that there is only one
--   non-boot module with the given name.
getModSummary :: GhcMonad m => ModuleName -> m ModSummary

-- | Get the module dependency graph.
getModuleGraph :: GhcMonad m => m ModuleGraph

-- | Return <tt>True</tt> <a>==</a> module is loaded.
isLoaded :: GhcMonad m => ModuleName -> m Bool

-- | Topological sort of the module graph
--   
--   Calculate SCCs of the module graph, possibly dropping the hi-boot
--   nodes The resulting list of strongly-connected-components is in
--   topologically sorted order, starting with the module(s) at the bottom
--   of the dependency graph (ie compile them first) and ending with the
--   ones at the top.
--   
--   Drop hi-boot nodes (first boolean arg)?
--   
--   <ul>
--   <li><tt>False</tt>: treat the hi-boot summaries as nodes of the graph,
--   so the graph must be acyclic</li>
--   <li><tt>True</tt>: eliminate the hi-boot nodes, and instead pretend
--   the a source-import of Foo is an import of Foo The resulting graph has
--   no hi-boot nodes, but can be cyclic</li>
--   </ul>
topSortModuleGraph :: Bool -> [ModSummary] -> Maybe ModuleName -> [SCC ModSummary]

-- | Container for information about a <a>Module</a>.
data ModuleInfo

-- | Request information about a loaded <a>Module</a>
getModuleInfo :: GhcMonad m => Module -> m (Maybe ModuleInfo)

-- | The list of top-level entities defined in a module
modInfoTyThings :: ModuleInfo -> [TyThing]
modInfoTopLevelScope :: ModuleInfo -> Maybe [Name]
modInfoExports :: ModuleInfo -> [Name]

-- | Returns the instances defined by the specified module. Warning:
--   currently unimplemented for package modules.
modInfoInstances :: ModuleInfo -> [ClsInst]
modInfoIsExportedName :: ModuleInfo -> Name -> Bool
modInfoLookupName :: GhcMonad m => ModuleInfo -> Name -> m (Maybe TyThing)
modInfoIface :: ModuleInfo -> Maybe ModIface

-- | Retrieve module safe haskell mode
modInfoSafe :: ModuleInfo -> SafeHaskellMode

-- | Looks up a global name: that is, any top-level name in any visible
--   module. Unlike <a>lookupName</a>, lookupGlobalName does not use the
--   interactive context, and therefore does not require a preceding
--   <a>setContext</a>.
lookupGlobalName :: GhcMonad m => Name -> m (Maybe TyThing)
findGlobalAnns :: (GhcMonad m, Typeable a) => ([Word8] -> a) -> AnnTarget Name -> m [a]
mkPrintUnqualifiedForModule :: GhcMonad m => ModuleInfo -> m (Maybe PrintUnqualified)

-- | A <a>ModIface</a> plus a <a>ModDetails</a> summarises everything we
--   know about a compiled module. The <a>ModIface</a> is the stuff
--   *before* linking, and can be written out to an interface file. The
--   'ModDetails is after linking and can be completely recovered from just
--   the <a>ModIface</a>.
--   
--   When we read an interface file, we also construct a <a>ModIface</a>
--   from it, except that we explicitly make the <a>mi_decls</a> and a few
--   other fields empty; as when reading we consolidate the declarations
--   etc. into a number of indexed maps and environments in the
--   <a>ExternalPackageState</a>.
data ModIface
ModIface :: !Module -> !Fingerprint -> !Fingerprint -> !Fingerprint -> !WhetherHasOrphans -> !WhetherHasFamInst -> !IsBootInterface -> Dependencies -> [Usage] -> ![IfaceExport] -> !Fingerprint -> !Bool -> [(OccName, Fixity)] -> Warnings -> [IfaceAnnotation] -> [(Fingerprint, IfaceDecl)] -> !(Maybe GlobalRdrEnv) -> [IfaceClsInst] -> [IfaceFamInst] -> [IfaceRule] -> !Fingerprint -> !IfaceVectInfo -> (Name -> Maybe WarningTxt) -> (OccName -> Fixity) -> (OccName -> Maybe (OccName, Fingerprint)) -> !AnyHpcUsage -> !IfaceTrustInfo -> !Bool -> ModIface

-- | Name of the module we are for
mi_module :: ModIface -> !Module

-- | Hash of the whole interface
mi_iface_hash :: ModIface -> !Fingerprint

-- | Hash of the ABI only
mi_mod_hash :: ModIface -> !Fingerprint

-- | Hash of the important flags used when compiling this module
mi_flag_hash :: ModIface -> !Fingerprint

-- | Whether this module has orphans
mi_orphan :: ModIface -> !WhetherHasOrphans

-- | Whether this module has family instances
mi_finsts :: ModIface -> !WhetherHasFamInst

-- | Read from an hi-boot file?
mi_boot :: ModIface -> !IsBootInterface

-- | The dependencies of the module. This is consulted for
--   directly-imported modules, but not for anything else (hence lazy)
mi_deps :: ModIface -> Dependencies

-- | Usages; kept sorted so that it's easy to decide whether to write a new
--   iface file (changing usages doesn't affect the hash of this module)
--   NOT STRICT! we read this field lazily from the interface file It is
--   *only* consulted by the recompilation checker
mi_usages :: ModIface -> [Usage]

-- | Exports Kept sorted by (mod,occ), to make version comparisons easier
--   Records the modules that are the declaration points for things
--   exported by this module, and the <a>OccName</a>s of those things
mi_exports :: ModIface -> ![IfaceExport]

-- | Hash of export list
mi_exp_hash :: ModIface -> !Fingerprint

-- | Module required TH splices when it was compiled. This disables
--   recompilation avoidance (see #481).
mi_used_th :: ModIface -> !Bool

-- | Fixities NOT STRICT! we read this field lazily from the interface file
mi_fixities :: ModIface -> [(OccName, Fixity)]

-- | Warnings NOT STRICT! we read this field lazily from the interface file
mi_warns :: ModIface -> Warnings

-- | Annotations NOT STRICT! we read this field lazily from the interface
--   file
mi_anns :: ModIface -> [IfaceAnnotation]

-- | Type, class and variable declarations The hash of an Id changes if its
--   fixity or deprecations change (as well as its type of course) Ditto
--   data constructors, class operations, except that the hash of the
--   parent class/tycon changes
mi_decls :: ModIface -> [(Fingerprint, IfaceDecl)]

-- | Binds all the things defined at the top level in the <i>original
--   source</i> code for this module. which is NOT the same as mi_exports,
--   nor mi_decls (which may contains declarations for things not actually
--   defined by the user). Used for GHCi and for inspecting the contents of
--   modules via the GHC API only.
--   
--   (We need the source file to figure out the top-level environment, if
--   we didn't compile this module from source then this field contains
--   <tt>Nothing</tt>).
--   
--   Strictly speaking this field should live in the <a>HomeModInfo</a>,
--   but that leads to more plumbing.
mi_globals :: ModIface -> !(Maybe GlobalRdrEnv)

-- | Sorted class instance
mi_insts :: ModIface -> [IfaceClsInst]

-- | Sorted family instances
mi_fam_insts :: ModIface -> [IfaceFamInst]

-- | Sorted rules
mi_rules :: ModIface -> [IfaceRule]

-- | Hash for orphan rules, class and family instances, and vectorise
--   pragmas combined
mi_orphan_hash :: ModIface -> !Fingerprint

-- | Vectorisation information
mi_vect_info :: ModIface -> !IfaceVectInfo

-- | Cached lookup for <a>mi_warns</a>
mi_warn_fn :: ModIface -> Name -> Maybe WarningTxt

-- | Cached lookup for <a>mi_fixities</a>
mi_fix_fn :: ModIface -> OccName -> Fixity

-- | Cached lookup for <a>mi_decls</a>. The <tt>Nothing</tt> in
--   <a>mi_hash_fn</a> means that the thing isn't in decls. It's useful to
--   know that when seeing if we are up to date wrt. the old interface. The
--   <a>OccName</a> is the parent of the name, if it has one.
mi_hash_fn :: ModIface -> OccName -> Maybe (OccName, Fingerprint)

-- | True if this program uses Hpc at any point in the program.
mi_hpc :: ModIface -> !AnyHpcUsage

-- | Safe Haskell Trust information for this module.
mi_trust :: ModIface -> !IfaceTrustInfo

-- | Do we require the package this module resides in be trusted to trust
--   this module? This is used for the situation where a module is Safe (so
--   doesn't require the package be trusted itself) but imports some
--   trustworthy modules from its own package (which does require its own
--   package be trusted). See Note [RnNames . Trust Own Package]
mi_trust_pkg :: ModIface -> !Bool

-- | The various Safe Haskell modes
data SafeHaskellMode
Sf_None :: SafeHaskellMode
Sf_Unsafe :: SafeHaskellMode
Sf_Trustworthy :: SafeHaskellMode
Sf_Safe :: SafeHaskellMode
Sf_SafeInferred :: SafeHaskellMode

-- | Return all <i>external</i> modules available in the package database.
--   Modules from the current session (i.e., from the
--   <a>HomePackageTable</a>) are not included.
packageDbModules :: GhcMonad m => Bool -> m [Module]
type PrintUnqualified = (QueryQualifyName, QueryQualifyModule)
alwaysQualify :: PrintUnqualified

-- | Return the bindings for the current interactive session.
getBindings :: GhcMonad m => m [TyThing]

-- | Return the instances for the current interactive session.
getInsts :: GhcMonad m => m ([ClsInst], [FamInst])
getPrintUnqual :: GhcMonad m => m PrintUnqualified

-- | Takes a <a>ModuleName</a> and possibly a <a>PackageId</a>, and
--   consults the filesystem and package database to find the corresponding
--   <a>Module</a>, using the algorithm that is used for an <tt>import</tt>
--   declaration.
findModule :: GhcMonad m => ModuleName -> Maybe FastString -> m Module

-- | Like <a>findModule</a>, but differs slightly when the module refers to
--   a source file, and the file has not been loaded via <a>load</a>. In
--   this case, <a>findModule</a> will throw an error (module not loaded),
--   but <a>lookupModule</a> will check to see whether the module can also
--   be found in a package, and if so, that package <a>Module</a> will be
--   returned. If not, the usual module-not-found error will be thrown.
lookupModule :: GhcMonad m => ModuleName -> Maybe FastString -> m Module

-- | Check that a module is safe to import (according to Safe Haskell).
--   
--   We return True to indicate the import is safe and False otherwise
--   although in the False case an error may be thrown first.
isModuleTrusted :: GhcMonad m => Module -> m Bool

-- | Return if a module is trusted and the pkgs it depends on to be
--   trusted.
moduleTrustReqs :: GhcMonad m => Module -> m (Bool, [PackageId])

-- | Set the interactive evaluation context.
--   
--   Setting the context doesn't throw away any bindings; the bindings
--   we've built up in the InteractiveContext simply move to the new
--   module. They always shadow anything in scope in the current context.
setContext :: GhcMonad m => [InteractiveImport] -> m ()

-- | Get the interactive evaluation context, consisting of a pair of the
--   set of modules from which we take the full top-level scope, and the
--   set of modules from which we take just the exports respectively.
getContext :: GhcMonad m => m [InteractiveImport]

-- | Returns all names in scope in the current interactive context
getNamesInScope :: GhcMonad m => m [Name]
getRdrNamesInScope :: GhcMonad m => m [RdrName]

-- | get the GlobalRdrEnv for a session
getGRE :: GhcMonad m => m GlobalRdrEnv

-- | Returns <tt>True</tt> if the specified module is interpreted, and
--   hence has its full top-level scope available.
moduleIsInterpreted :: GhcMonad m => Module -> m Bool

-- | Looks up an identifier in the current interactive context (for :info)
--   Filter the instances by the ones whose tycons (or clases resp) are in
--   scope (qualified or otherwise). Otherwise we list a whole lot too
--   many! The exact choice of which ones to show, and which to hide, is a
--   judgement call. (see Trac #1581)
getInfo :: GhcMonad m => Name -> m (Maybe (TyThing, Fixity, [ClsInst]))

-- | Get the type of an expression
exprType :: GhcMonad m => String -> m Type

-- | Get the kind of a type
typeKind :: GhcMonad m => Bool -> String -> m (Type, Kind)

-- | Parses a string as an identifier, and returns the list of <a>Name</a>s
--   that the identifier can refer to in the current interactive context.
parseName :: GhcMonad m => String -> m [Name]
data RunResult

-- | names bound by this evaluation
RunOk :: [Name] -> RunResult

-- | statement raised an exception
RunException :: SomeException -> RunResult
RunBreak :: ThreadId -> [Name] -> (Maybe BreakInfo) -> RunResult

-- | Run a statement in the current interactive context. Statement may bind
--   multple values.
runStmt :: GhcMonad m => String -> SingleStep -> m RunResult

-- | Run a statement in the current interactive context. Passing debug
--   information Statement may bind multple values.
runStmtWithLocation :: GhcMonad m => String -> Int -> String -> SingleStep -> m RunResult
runDecls :: GhcMonad m => String -> m [Name]
runDeclsWithLocation :: GhcMonad m => String -> Int -> String -> m [Name]
parseImportDecl :: GhcMonad m => String -> m (ImportDecl RdrName)
data SingleStep
RunToCompletion :: SingleStep
SingleStep :: SingleStep
RunAndLogSteps :: SingleStep
resume :: GhcMonad m => (SrcSpan -> Bool) -> SingleStep -> m RunResult
data Resume
data History
getHistorySpan :: GhcMonad m => History -> m SrcSpan
getHistoryModule :: History -> Module
getResumeContext :: GhcMonad m => m [Resume]
abandon :: GhcMonad m => m Bool
abandonAll :: GhcMonad m => m Bool
back :: GhcMonad m => m ([Name], Int, SrcSpan)
forward :: GhcMonad m => m ([Name], Int, SrcSpan)
showModule :: GhcMonad m => ModSummary -> m String
isModuleInterpreted :: GhcMonad m => ModSummary -> m Bool
compileExpr :: GhcMonad m => String -> m HValue
data HValue
dynCompileExpr :: GhcMonad m => String -> m Dynamic
obtainTermFromId :: GhcMonad m => Int -> Bool -> Id -> m Term
obtainTermFromVal :: GhcMonad m => Int -> Bool -> Type -> a -> m Term
reconstructType :: HscEnv -> Int -> Id -> IO (Maybe Type)
modInfoModBreaks :: ModuleInfo -> ModBreaks

-- | All the information about the breakpoints for a given module
data ModBreaks
ModBreaks :: BreakArray -> !(Array BreakIndex SrcSpan) -> !(Array BreakIndex [OccName]) -> !(Array BreakIndex [String]) -> ModBreaks

-- | The array of flags, one per breakpoint, indicating which breakpoints
--   are enabled.
modBreaks_flags :: ModBreaks -> BreakArray

-- | An array giving the source span of each breakpoint.
modBreaks_locs :: ModBreaks -> !(Array BreakIndex SrcSpan)

-- | An array giving the names of the free variables at each breakpoint.
modBreaks_vars :: ModBreaks -> !(Array BreakIndex [OccName])

-- | An array giving the names of the declarations enclosing each
--   breakpoint.
modBreaks_decls :: ModBreaks -> !(Array BreakIndex [String])

-- | Breakpoint index
type BreakIndex = Int
data BreakInfo
data BreakArray
setBreakOn :: BreakArray -> Int -> IO Bool
setBreakOff :: BreakArray -> Int -> IO Bool
getBreak :: BreakArray -> Int -> IO (Maybe Word)

-- | Returns the <a>TyThing</a> for a <a>Name</a>. The <a>Name</a> may
--   refer to any entity known to GHC, including <a>Name</a>s defined using
--   <a>runStmt</a>.
lookupName :: GhcMonad m => Name -> m (Maybe TyThing)

-- | EXPERIMENTAL: DO NOT USE.
--   
--   Set the monad GHCi lifts user statements into.
--   
--   Checks that a type (in string form) is an instance of the
--   <tt>GHC.GHCi.GHCiSandboxIO</tt> type class. Sets it to be the GHCi
--   monad if it is, throws an error otherwise.

-- | <i>Warning: This is experimental! Don't use. </i>
setGHCiMonad :: GhcMonad m => String -> m ()

-- | Essentially just a string identifying a package, including the
--   version: e.g. parsec-1.0
data PackageId

-- | A Module is a pair of a <a>PackageId</a> and a <a>ModuleName</a>.
data Module
mkModule :: PackageId -> ModuleName -> Module
pprModule :: Module -> SDoc
moduleName :: Module -> ModuleName
modulePackageId :: Module -> PackageId

-- | A ModuleName is essentially a simple string, e.g. <tt>Data.List</tt>.
data ModuleName
mkModuleName :: String -> ModuleName
moduleNameString :: ModuleName -> String

-- | A unique, unambigious name for something, containing information about
--   where that thing originated.
data Name
isExternalName :: Name -> Bool
nameModule :: Name -> Module

-- | print a <a>NamedThing</a>, adding parentheses if the name is an
--   operator.
pprParenSymName :: NamedThing a => a -> SDoc
nameSrcSpan :: Name -> SrcSpan

-- | A class allowing convenient access to the <a>Name</a> of various
--   datatypes
class NamedThing a where getOccName n = nameOccName (getName n)
getOccName :: NamedThing a => a -> OccName
getName :: NamedThing a => a -> Name

-- | Do not use the data constructors of RdrName directly: prefer the
--   family of functions that creates them, such as <a>mkRdrUnqual</a>
data RdrName

-- | Used for ordinary, unqualified occurrences, e.g. <tt>x</tt>,
--   <tt>y</tt> or <tt>Foo</tt>. Create such a <a>RdrName</a> with
--   <a>mkRdrUnqual</a>
Unqual :: OccName -> RdrName

-- | A qualified name written by the user in <i>source</i> code. The module
--   isn't necessarily the module where the thing is defined; just the one
--   from which it is imported. Examples are <tt>Bar.x</tt>, <tt>Bar.y</tt>
--   or <tt>Bar.Foo</tt>. Create such a <a>RdrName</a> with
--   <a>mkRdrQual</a>
Qual :: ModuleName -> OccName -> RdrName
type Id = Var
idType :: Id -> Kind

-- | <a>isImplicitId</a> tells whether an <a>Id</a>s info is implied by
--   other declarations, so we don't need to put its signature in an
--   interface file, even if it's mentioned in some other interface
--   unfolding.
isImplicitId :: Id -> Bool
isDeadBinder :: Id -> Bool

-- | <tt>isExportedIdVar</tt> means "don't throw this away"
isExportedId :: Var -> Bool
isLocalId :: Var -> Bool
isGlobalId :: Var -> Bool
isRecordSelector :: Id -> Bool
isPrimOpId :: Id -> Bool
isFCallId :: Id -> Bool
isClassOpId_maybe :: Id -> Maybe Class
isDataConWorkId :: Id -> Bool

-- | Get from either the worker or the wrapper <a>Id</a> to the
--   <a>DataCon</a>. Currently used only in the desugarer.
--   
--   INVARIANT: <tt>idDataCon (dataConWrapId d) = d</tt>: remember,
--   <a>dataConWrapId</a> can return either the wrapper or the worker
idDataCon :: Id -> DataCon

-- | Returns true if an application to n args would diverge
isBottomingId :: Id -> Bool
isDictonaryId :: Id -> Bool

-- | If the <a>Id</a> is that for a record selector, extract the
--   <a>sel_tycon</a> and label. Panic otherwise
recordSelectorFieldLabel :: Id -> (TyCon, FieldLabel)

-- | TyCons represent type constructors. Type constructors are introduced
--   by things such as:
--   
--   1) Data declarations: <tt>data Foo = ...</tt> creates the <tt>Foo</tt>
--   type constructor of kind <tt>*</tt>
--   
--   2) Type synonyms: <tt>type Foo = ...</tt> creates the <tt>Foo</tt>
--   type constructor
--   
--   3) Newtypes: <tt>newtype Foo a = MkFoo ...</tt> creates the
--   <tt>Foo</tt> type constructor of kind <tt>* -&gt; *</tt>
--   
--   4) Class declarations: <tt>class Foo where</tt> creates the
--   <tt>Foo</tt> type constructor of kind <tt>*</tt>
--   
--   This data type also encodes a number of primitive, built in type
--   constructors such as those for function and tuple types.
data TyCon

-- | The kind and type variables used in the type constructor. Invariant:
--   length tyvars = arity Precisely, this list scopes over:
--   
--   <ol>
--   <li>The <a>algTcStupidTheta</a> 2. The cached types in
--   'algTyConRhs.NewTyCon' 3. The family instance types if present</li>
--   </ol>
--   
--   Note that it does <i>not</i> scope over the data constructors.
tyConTyVars :: TyCon -> [TyVar]

-- | As <a>tyConDataCons_maybe</a>, but returns the empty list of
--   constructors if no constructors could be found
tyConDataCons :: TyCon -> [DataCon]

-- | n if ty_con :: * -&gt; ... -&gt; * n times
tyConArity :: TyCon -> Arity

-- | Is this <a>TyCon</a> that for a class instance?
isClassTyCon :: TyCon -> Bool

-- | Is this a <a>TyCon</a> representing a type synonym (<tt>type</tt>)?
isSynTyCon :: TyCon -> Bool

-- | Is this <a>TyCon</a> that for a <tt>newtype</tt>
isNewTyCon :: TyCon -> Bool

-- | Does this <a>TyCon</a> represent something that cannot be defined in
--   Haskell?
isPrimTyCon :: TyCon -> Bool
isFunTyCon :: TyCon -> Bool

-- | Is this a <a>TyCon</a>, synonym or otherwise, that may have further
--   instances appear?
isFamilyTyCon :: TyCon -> Bool

-- | If this <a>TyCon</a> is that for a class instance, return the class it
--   is for. Otherwise returns <tt>Nothing</tt>
tyConClass_maybe :: TyCon -> Maybe Class

-- | Extract the <a>TyVar</a>s bound by a type synonym and the
--   corresponding (unsubstituted) right hand side. If the given
--   <a>TyCon</a> is not a type synonym, panics
synTyConDefn :: TyCon -> ([TyVar], Type)

-- | Find the expansion of the type synonym represented by the given
--   <a>TyCon</a>. The free variables of this type will typically include
--   those <a>TyVar</a>s bound by the <a>TyCon</a>. Panics if the
--   <a>TyCon</a> is not that of a type synonym
synTyConType :: TyCon -> Type

-- | Find the result <a>Kind</a> of a type synonym, after applying it to
--   its <tt>arity</tt> number of type variables Actually this function
--   works fine on data types too, but they'd always return <a>*</a>, so we
--   never need to ask
synTyConResKind :: TyCon -> Kind
type TyVar = Var
alphaTyVars :: [TyVar]

-- | A data constructor
data DataCon

-- | The "signature" of the <a>DataCon</a> returns, in order:
--   
--   1) The result of <a>dataConAllTyVars</a>,
--   
--   2) All the <a>ThetaType</a>s relating to the <a>DataCon</a> (coercion,
--   dictionary, implicit parameter - whatever)
--   
--   3) The type arguments to the constructor
--   
--   4) The <i>original</i> result type of the <a>DataCon</a>
dataConSig :: DataCon -> ([TyVar], ThetaType, [Type], Type)
dataConType :: DataCon -> Type

-- | The type constructor that we are building via this data constructor
dataConTyCon :: DataCon -> TyCon

-- | The labels for the fields of this particular <a>DataCon</a>
dataConFieldLabels :: DataCon -> [FieldLabel]

-- | Should the <a>DataCon</a> be presented infix?
dataConIsInfix :: DataCon -> Bool

-- | Vanilla <a>DataCon</a>s are those that are nice boring Haskell 98
--   constructors
isVanillaDataCon :: DataCon -> Bool

-- | The user-declared type of the data constructor in the nice-to-read
--   form:
--   
--   <pre>
--   T :: forall a b. a -&gt; b -&gt; T [a]
--   </pre>
--   
--   rather than:
--   
--   <pre>
--   T :: forall a c. forall b. (c~[a]) =&gt; a -&gt; b -&gt; T c
--   </pre>
--   
--   NB: If the constructor is part of a data instance, the result type
--   mentions the family tycon, not the internal one.
dataConUserType :: DataCon -> Type

-- | The strictness markings decided on by the compiler. Does not include
--   those for existential dictionaries. The list is in one-to-one
--   correspondence with the arity of the <a>DataCon</a>
dataConStrictMarks :: DataCon -> [HsBang]
data StrictnessMark
MarkedStrict :: StrictnessMark
NotMarkedStrict :: StrictnessMark
isMarkedStrict :: StrictnessMark -> Bool
data Class
classMethods :: Class -> [Id]
classSCTheta :: Class -> [PredType]
classTvsFds :: Class -> ([TyVar], [FunDep TyVar])
classATs :: Class -> [TyCon]
pprFundeps :: Outputable a => [FunDep a] -> SDoc
data ClsInst
instanceDFunId :: ClsInst -> DFunId
pprInstance :: ClsInst -> SDoc
pprInstanceHdr :: ClsInst -> SDoc
pprFamInst :: FamInst -> SDoc
pprFamInstHdr :: FamInst -> SDoc

-- | The key representation of types within the compiler
data Type

-- | Attempts to take a forall type apart, returning all the immediate such
--   bound type variables and the remainder of the type. Always suceeds,
--   even if that means returning an empty list of <a>TyVar</a>s
splitForAllTys :: Type -> ([TyVar], Type)

-- | Extract the function result type and panic if that is not possible
funResultTy :: Type -> Type
pprParendType :: Type -> SDoc
pprTypeApp :: NamedThing a => a -> [Type] -> SDoc

-- | The key type representing kinds in the compiler. Invariant: a kind is
--   always in one of these forms:
--   
--   <pre>
--   FunTy k1 k2
--   TyConApp PrimTyCon [...]
--   TyVar kv   -- (during inference only)
--   ForAll ... -- (for top-level coercions)
--   </pre>
type Kind = Type

-- | A type of the form <tt>p</tt> of kind <tt>Constraint</tt> represents a
--   value whose type is the Haskell predicate <tt>p</tt>, where a
--   predicate is what occurs before the <tt>=&gt;</tt> in a Haskell type.
--   
--   We use <a>PredType</a> as documentation to mark those types that we
--   guarantee to have this kind.
--   
--   It can be expanded into its representation, but:
--   
--   <ul>
--   <li>The type checker must treat it as opaque</li>
--   <li>The rest of the compiler treats it as transparent</li>
--   </ul>
--   
--   Consider these examples:
--   
--   <pre>
--   f :: (Eq a) =&gt; a -&gt; Int
--   g :: (?x :: Int -&gt; Int) =&gt; a -&gt; Int
--   h :: (r\l) =&gt; {r} =&gt; {l::Int | r}
--   </pre>
--   
--   Here the <tt>Eq a</tt> and <tt>?x :: Int -&gt; Int</tt> and
--   <tt>rl</tt> are all called "predicates"
type PredType = Type

-- | A collection of <a>PredType</a>s
type ThetaType = [PredType]
pprForAll :: [TyVar] -> SDoc
pprThetaArrowTy :: ThetaType -> SDoc

-- | A typecheckable-thing, essentially anything that has a name
data TyThing
AnId :: Id -> TyThing
ADataCon :: DataCon -> TyThing
ATyCon :: TyCon -> TyThing
ACoAxiom :: CoAxiom -> TyThing
data FixityDirection
InfixL :: FixityDirection
InfixR :: FixityDirection
InfixN :: FixityDirection
defaultFixity :: Fixity
maxPrecedence :: Int
negateFixity :: Fixity
compareFixity :: Fixity -> Fixity -> (Bool, Bool)
data SrcLoc
RealSrcLoc :: {-# UNPACK #-} !RealSrcLoc -> SrcLoc
UnhelpfulLoc :: FastString -> SrcLoc

-- | Represents a single point within a file
data RealSrcLoc
mkSrcLoc :: FastString -> Int -> Int -> SrcLoc

-- | Built-in <a>bad</a> <a>SrcLoc</a> values for particular locations
noSrcLoc :: SrcLoc

-- | Gives the filename of the <a>RealSrcLoc</a>
srcLocFile :: RealSrcLoc -> FastString

-- | Raises an error when used on a <a>bad</a> <a>SrcLoc</a>
srcLocLine :: RealSrcLoc -> Int

-- | Raises an error when used on a <a>bad</a> <a>SrcLoc</a>
srcLocCol :: RealSrcLoc -> Int
data SrcSpan
RealSrcSpan :: !RealSrcSpan -> SrcSpan
UnhelpfulSpan :: !FastString -> SrcSpan

-- | A SrcSpan delimits a portion of a text file. It could be represented
--   by a pair of (line,column) coordinates, but in fact we optimise
--   slightly by using more compact representations for single-line and
--   zero-length spans, both of which are quite common.
--   
--   The end position is defined to be the column <i>after</i> the end of
--   the span. That is, a span of (1,1)-(1,2) is one character long, and a
--   span of (1,1)-(1,1) is zero characters long.
data RealSrcSpan

-- | Create a <a>SrcSpan</a> between two points in a file
mkSrcSpan :: SrcLoc -> SrcLoc -> SrcSpan

-- | Create a <a>SrcSpan</a> corresponding to a single point
srcLocSpan :: SrcLoc -> SrcSpan

-- | Test if a <a>SrcSpan</a> is <a>good</a>, i.e. has precise location
--   information
isGoodSrcSpan :: SrcSpan -> Bool

-- | Built-in <a>bad</a> <a>SrcSpan</a>s for common sources of location
--   uncertainty
noSrcSpan :: SrcSpan

-- | Returns the location at the start of the <a>SrcSpan</a> or a
--   <a>bad</a> <a>SrcSpan</a> if that is unavailable
srcSpanStart :: SrcSpan -> SrcLoc

-- | Returns the location at the end of the <a>SrcSpan</a> or a <a>bad</a>
--   <a>SrcSpan</a> if that is unavailable
srcSpanEnd :: SrcSpan -> SrcLoc
srcSpanFile :: RealSrcSpan -> FastString
srcSpanStartLine :: RealSrcSpan -> Int
srcSpanEndLine :: RealSrcSpan -> Int
srcSpanStartCol :: RealSrcSpan -> Int
srcSpanEndCol :: RealSrcSpan -> Int

-- | We attach SrcSpans to lots of things, so let's have a datatype for it.
data GenLocated l e
L :: l -> e -> GenLocated l e
type Located e = GenLocated SrcSpan e
noLoc :: e -> Located e
mkGeneralLocated :: String -> e -> Located e
getLoc :: GenLocated l e -> l
unLoc :: GenLocated l e -> e

-- | Tests whether the two located things are equal
eqLocated :: Eq a => Located a -> Located a -> Bool

-- | Tests the ordering of the two located things
cmpLocated :: Ord a => Located a -> Located a -> Ordering
combineLocs :: Located a -> Located b -> SrcSpan

-- | Combine locations from two <a>Located</a> things and add them to a
--   third thing
addCLoc :: Located a -> Located b -> c -> Located c

-- | Alternative strategies for ordering <a>SrcSpan</a>s
leftmost_smallest :: SrcSpan -> SrcSpan -> Ordering

-- | Alternative strategies for ordering <a>SrcSpan</a>s
leftmost_largest :: SrcSpan -> SrcSpan -> Ordering

-- | Alternative strategies for ordering <a>SrcSpan</a>s
rightmost :: SrcSpan -> SrcSpan -> Ordering

-- | Determines whether a span encloses a given line and column index
spans :: SrcSpan -> (Int, Int) -> Bool

-- | Determines whether a span is enclosed by another one
isSubspanOf :: SrcSpan -> SrcSpan -> Bool

-- | GHC's own exception type error messages all take the form:
--   
--   <pre>
--   <a>location</a>: <a>error</a>
--   </pre>
--   
--   If the location is on the command line, or in GHC itself, then
--   <a>location</a>=<a>ghc</a>. All of the error types below correspond to
--   a <a>location</a> of <a>ghc</a>, except for ProgramError (where the
--   string is assumed to contain a location already, so we don't print
--   one).
data GhcException
PhaseFailed :: String -> ExitCode -> GhcException

-- | Some other fatal signal (SIGHUP,SIGTERM)
Signal :: Int -> GhcException

-- | Prints the short usage msg after the error
UsageError :: String -> GhcException

-- | A problem with the command line arguments, but don't print usage.
CmdLineError :: String -> GhcException

-- | The <tt>impossible</tt> happened.
Panic :: String -> GhcException
PprPanic :: String -> SDoc -> GhcException

-- | The user tickled something that's known not to work yet, but we're not
--   counting it as a bug.
Sorry :: String -> GhcException
PprSorry :: String -> SDoc -> GhcException

-- | An installation problem.
InstallationError :: String -> GhcException

-- | An error in the user's code, probably.
ProgramError :: String -> GhcException
PprProgramError :: String -> SDoc -> GhcException

-- | Append a description of the given exception to this string.
showGhcException :: GhcException -> String -> String
data Token

-- | Return module source as token stream, including comments.
--   
--   The module must be in the module graph and its source must be
--   available. Throws a <a>SourceError</a> on parse error.
getTokenStream :: GhcMonad m => Module -> m [Located Token]

-- | Give even more information on the source than <a>getTokenStream</a>
--   This function allows reconstructing the source completely with
--   <a>showRichTokenStream</a>.
getRichTokenStream :: GhcMonad m => Module -> m [(Located Token, String)]

-- | Take a rich token stream such as produced from
--   <a>getRichTokenStream</a> and return source code almost identical to
--   the original code (except for insignificant whitespace.)
showRichTokenStream :: [(Located Token, String)] -> String

-- | Given a source location and a StringBuffer corresponding to this
--   location, return a rich token stream with the source associated to the
--   tokens.
addSourceToTokens :: RealSrcLoc -> StringBuffer -> [Located Token] -> [(Located Token, String)]

-- | A pure interface to the module parser.
parser :: String -> DynFlags -> FilePath -> Either ErrorMessages (WarningMessages, Located (HsModule RdrName))
cyclicModuleErr :: [ModSummary] -> SDoc
instance Outputable CoreModule
instance DesugaredMod DesugaredModule
instance TypecheckedMod DesugaredModule
instance ParsedMod DesugaredModule
instance TypecheckedMod TypecheckedModule
instance ParsedMod TypecheckedModule
instance ParsedMod ParsedModule

module PprTyThing
type PrintExplicitForalls = Bool

-- | Pretty-prints a <a>TyThing</a>.
pprTyThing :: PrintExplicitForalls -> TyThing -> SDoc

-- | Pretty-prints a <a>TyThing</a> in context: that is, if the entity is a
--   data constructor, record selector, or class method, then the entity's
--   parent declaration is pretty-printed with irrelevant parts omitted.
pprTyThingInContext :: PrintExplicitForalls -> TyThing -> SDoc

-- | Pretty-prints a <a>TyThing</a> with its defining location.
pprTyThingLoc :: PrintExplicitForalls -> TyThing -> SDoc

-- | Like <a>pprTyThingInContext</a>, but adds the defining location.
pprTyThingInContextLoc :: PrintExplicitForalls -> TyThing -> SDoc

-- | Pretty-prints the <a>TyThing</a> header. For functions and data
--   constructors the function is equivalent to <a>pprTyThing</a> but for
--   type constructors and classes it prints only the header part of the
--   declaration.
pprTyThingHdr :: PrintExplicitForalls -> TyThing -> SDoc
pprTypeForUser :: PrintExplicitForalls -> Type -> SDoc

module Debugger

-- | The :print &amp; friends commands
pprintClosureCommand :: GhcMonad m => Bool -> Bool -> String -> m ()
showTerm :: GhcMonad m => Term -> m SDoc
pprTypeAndContents :: GhcMonad m => Id -> m SDoc

module DriverMkDepend
doMkDependHS :: GhcMonad m => [FilePath] -> m ()
