Metadata-Version: 1.2
Name: lupa
Version: 1.8
Summary: Python wrapper around Lua and LuaJIT
Home-page: https://github.com/scoder/lupa
Author: Stefan Behnel
Author-email: stefan_ml@behnel.de
Maintainer: Lupa-dev mailing list
Maintainer-email: lupa-dev@freelists.org
License: MIT style
Description: Lupa
        ====
        
        .. image:: logo/logo-220x200.png
        
        Lupa integrates the runtimes of Lua_ or LuaJIT2_ into CPython.
        It is a partial rewrite of LunaticPython_ in Cython_ with some
        additional features such as proper coroutine support.
        
        .. _Lua: http://lua.org/
        .. _LuaJIT2: http://luajit.org/
        .. _LunaticPython: http://labix.org/lunatic-python
        .. _Cython: http://cython.org
        
        For questions not answered here, please contact the `Lupa mailing list`_.
        
        .. _`Lupa mailing list`: http://www.freelists.org/list/lupa-dev
        
        .. contents:: :local:
        
        
        Major features
        --------------
        
        * separate Lua runtime states through a ``LuaRuntime`` class
        
        * Python coroutine wrapper for Lua coroutines
        
        * iteration support for Python objects in Lua and Lua objects in
          Python
        
        * proper encoding and decoding of strings (configurable per runtime,
          UTF-8 by default)
        
        * frees the GIL and supports threading in separate runtimes when
          calling into Lua
        
        * tested with Python 2.6/3.2 and later
        
        * written for LuaJIT2 (tested with LuaJIT 2.0.2), but also works
          with the normal Lua interpreter (5.1 and 5.2)
        
        * easy to hack on and extend as it is written in Cython, not C
        
        
        Why the name?
        -------------
        
        In Latin, "lupa" is a female wolf, as elegant and wild as it sounds.
        If you don't like this kind of straight forward allegory to an
        endangered species, you may also happily assume it's just an
        amalgamation of the phonetic sounds that start the words "Lua" and
        "Python", two from each to keep the balance.
        
        
        Why use it?
        -----------
        
        It complements Python very well.  Lua is a language as dynamic as
        Python, but LuaJIT compiles it to very fast machine code, sometimes
        faster than many statically compiled languages for computational code.
        The language runtime is very small and carefully designed for
        embedding.  The complete binary module of Lupa, including a statically
        linked LuaJIT2 runtime, only weighs some 700KB on a 64 bit machine.
        With standard Lua 5.1, it's less than 400KB.
        
        However, the Lua ecosystem lacks many of the batteries that Python
        readily includes, either directly in its standard library or as third
        party packages. This makes real-world Lua applications harder to write
        than equivalent Python applications. Lua is therefore not commonly
        used as primary language for large applications, but it makes for a
        fast, high-level and resource-friendly backup language inside of
        Python when raw speed is required and the edit-compile-run cycle of
        binary extension modules is too heavy and too static for agile
        development or hot-deployment.
        
        Lupa is a very fast and thin wrapper around Lua or LuaJIT.  It makes it
        easy to write dynamic Lua code that accompanies dynamic Python code by
        switching between the two languages at runtime, based on the tradeoff
        between simplicity and speed.
        
        
        Examples
        --------
        
        ..
              ## doctest helpers:
              >>> try: _ = sorted
              ... except NameError:
              ...     def sorted(seq):
              ...         l = list(seq)
              ...         l.sort()
              ...         return l
        
        .. code:: python
        
              >>> import lupa
              >>> from lupa import LuaRuntime
              >>> lua = LuaRuntime(unpack_returned_tuples=True)
        
              >>> lua.eval('1+1')
              2
        
              >>> lua_func = lua.eval('function(f, n) return f(n) end')
        
              >>> def py_add1(n): return n+1
              >>> lua_func(py_add1, 2)
              3
        
              >>> lua.eval('python.eval(" 2 ** 2 ")') == 4
              True
              >>> lua.eval('python.builtins.str(4)') == '4'
              True
        
        The function ``lua_type(obj)`` can be used to find out the type of a
        wrapped Lua object in Python code, as provided by Lua's ``type()``
        function:
        
        .. code:: python
        
              >>> lupa.lua_type(lua_func)
              'function'
              >>> lupa.lua_type(lua.eval('{}'))
              'table'
        
        To help in distinguishing between wrapped Lua objects and normal
        Python objects, it returns ``None`` for the latter:
        
        .. code:: python
        
              >>> lupa.lua_type(123) is None
              True
              >>> lupa.lua_type('abc') is None
              True
              >>> lupa.lua_type({}) is None
              True
        
        Note the flag ``unpack_returned_tuples=True`` that is passed to create
        the Lua runtime.  It is new in Lupa 0.21 and changes the behaviour of
        tuples that get returned by Python functions.  With this flag, they
        explode into separate Lua values:
        
        .. code:: python
        
              >>> lua.execute('a,b,c = python.eval("(1,2)")')
              >>> g = lua.globals()
              >>> g.a
              1
              >>> g.b
              2
              >>> g.c is None
              True
        
        When set to False, functions that return a tuple pass it through to the
        Lua code:
        
        .. code:: python
        
              >>> non_explode_lua = lupa.LuaRuntime(unpack_returned_tuples=False)
              >>> non_explode_lua.execute('a,b,c = python.eval("(1,2)")')
              >>> g = non_explode_lua.globals()
              >>> g.a
              (1, 2)
              >>> g.b is None
              True
              >>> g.c is None
              True
        
        Since the default behaviour (to not explode tuples) might change in a
        later version of Lupa, it is best to always pass this flag explicitly.
        
        
        Python objects in Lua
        ---------------------
        
        Python objects are either converted when passed into Lua (e.g.
        numbers and strings) or passed as wrapped object references.
        
        .. code:: python
        
              >>> wrapped_type = lua.globals().type     # Lua's own type() function
              >>> wrapped_type(1) == 'number'
              True
              >>> wrapped_type('abc') == 'string'
              True
        
        Wrapped Lua objects get unwrapped when they are passed back into Lua,
        and arbitrary Python objects get wrapped in different ways:
        
        .. code:: python
        
              >>> wrapped_type(wrapped_type) == 'function'  # unwrapped Lua function
              True
              >>> wrapped_type(len) == 'userdata'       # wrapped Python function
              True
              >>> wrapped_type([]) == 'userdata'        # wrapped Python object
              True
        
        Lua supports two main protocols on objects: calling and indexing.  It
        does not distinguish between attribute access and item access like
        Python does, so the Lua operations ``obj[x]`` and ``obj.x`` both map
        to indexing.  To decide which Python protocol to use for Lua wrapped
        objects, Lupa employs a simple heuristic.
        
        Pratically all Python objects allow attribute access, so if the object
        also has a ``__getitem__`` method, it is preferred when turning it
        into an indexable Lua object.  Otherwise, it becomes a simple object
        that uses attribute access for indexing from inside Lua.
        
        Obviously, this heuristic will fail to provide the required behaviour
        in many cases, e.g. when attribute access is required to an object
        that happens to support item access.  To be explicit about the
        protocol that should be used, Lupa provides the helper functions
        ``as_attrgetter()`` and ``as_itemgetter()`` that restrict the view on
        an object to a certain protocol, both from Python and from inside
        Lua:
        
        .. code:: python
        
              >>> lua_func = lua.eval('function(obj) return obj["get"] end')
              >>> d = {'get' : 'value'}
        
              >>> value = lua_func(d)
              >>> value == d['get'] == 'value'
              True
        
              >>> value = lua_func( lupa.as_itemgetter(d) )
              >>> value == d['get'] == 'value'
              True
        
              >>> dict_get = lua_func( lupa.as_attrgetter(d) )
              >>> dict_get == d.get
              True
              >>> dict_get('get') == d.get('get') == 'value'
              True
        
              >>> lua_func = lua.eval(
              ...     'function(obj) return python.as_attrgetter(obj)["get"] end')
              >>> dict_get = lua_func(d)
              >>> dict_get('get') == d.get('get') == 'value'
              True
        
        Note that unlike Lua function objects, callable Python objects support
        indexing in Lua:
        
        .. code:: python
        
              >>> def py_func(): pass
              >>> py_func.ATTR = 2
        
              >>> lua_func = lua.eval('function(obj) return obj.ATTR end')
              >>> lua_func(py_func)
              2
              >>> lua_func = lua.eval(
              ...     'function(obj) return python.as_attrgetter(obj).ATTR end')
              >>> lua_func(py_func)
              2
              >>> lua_func = lua.eval(
              ...     'function(obj) return python.as_attrgetter(obj)["ATTR"] end')
              >>> lua_func(py_func)
              2
        
        
        Iteration in Lua
        ----------------
        
        Iteration over Python objects from Lua's for-loop is fully supported.
        However, Python iterables need to be converted using one of the
        utility functions which are described here.  This is similar to the
        functions like ``pairs()`` in Lua.
        
        To iterate over a plain Python iterable, use the ``python.iter()``
        function.  For example, you can manually copy a Python list into a Lua
        table like this:
        
        .. code:: python
        
              >>> lua_copy = lua.eval('''
              ...     function(L)
              ...         local t, i = {}, 1
              ...         for item in python.iter(L) do
              ...             t[i] = item
              ...             i = i + 1
              ...         end
              ...         return t
              ...     end
              ... ''')
        
              >>> table = lua_copy([1,2,3,4])
              >>> len(table)
              4
              >>> table[1]   # Lua indexing
              1
        
        Python's ``enumerate()`` function is also supported, so the above
        could be simplified to:
        
        .. code:: python
        
              >>> lua_copy = lua.eval('''
              ...     function(L)
              ...         local t = {}
              ...         for index, item in python.enumerate(L) do
              ...             t[ index+1 ] = item
              ...         end
              ...         return t
              ...     end
              ... ''')
        
              >>> table = lua_copy([1,2,3,4])
              >>> len(table)
              4
              >>> table[1]   # Lua indexing
              1
        
        For iterators that return tuples, such as ``dict.iteritems()``, it is
        convenient to use the special ``python.iterex()`` function that
        automatically explodes the tuple items into separate Lua arguments:
        
        .. code:: python
        
              >>> lua_copy = lua.eval('''
              ...     function(d)
              ...         local t = {}
              ...         for key, value in python.iterex(d.items()) do
              ...             t[key] = value
              ...         end
              ...         return t
              ...     end
              ... ''')
        
              >>> d = dict(a=1, b=2, c=3)
              >>> table = lua_copy( lupa.as_attrgetter(d) )
              >>> table['b']
              2
        
        Note that accessing the ``d.items`` method from Lua requires passing
        the dict as ``attrgetter``.  Otherwise, attribute access in Lua would
        use the ``getitem`` protocol of Python dicts and look up ``d['items']``
        instead.
        
        
        None vs. nil
        ------------
        
        While ``None`` in Python and ``nil`` in Lua differ in their semantics, they
        usually just mean the same thing: no value.  Lupa therefore tries to map one
        directly to the other whenever possible:
        
        .. code:: python
        
              >>> lua.eval('nil') is None
              True
              >>> is_nil = lua.eval('function(x) return x == nil end')
              >>> is_nil(None)
              True
        
        The only place where this cannot work is during iteration, because Lua
        considers a ``nil`` value the termination marker of iterators.  Therefore,
        Lupa special cases ``None`` values here and replaces them by a constant
        ``python.none`` instead of returning ``nil``:
        
        .. code:: python
        
              >>> _ = lua.require("table")
              >>> func = lua.eval('''
              ...     function(items)
              ...         local t = {}
              ...         for value in python.iter(items) do
              ...             table.insert(t, value == python.none)
              ...         end
              ...         return t
              ...     end
              ... ''')
        
              >>> items = [1, None ,2]
              >>> list(func(items).values())
              [False, True, False]
        
        Lupa avoids this value escaping whenever it's obviously not necessary.
        Thus, when unpacking tuples during iteration, only the first value will
        be subject to ``python.none`` replacement, as Lua does not look at the
        other items for loop termination anymore.  And on ``enumerate()``
        iteration, the first value is known to be always a number and never None,
        so no replacement is needed.
        
        .. code:: python
        
              >>> func = lua.eval('''
              ...     function(items)
              ...         for a, b, c, d in python.iterex(items) do
              ...             return {a == python.none, a == nil,   -->  a == python.none
              ...                     b == python.none, b == nil,   -->  b == nil
              ...                     c == python.none, c == nil,   -->  c == nil
              ...                     d == python.none, d == nil}   -->  d == nil ...
              ...         end
              ...     end
              ... ''')
        
              >>> items = [(None, None, None, None)]
              >>> list(func(items).values())
              [True, False, False, True, False, True, False, True]
        
              >>> items = [(None, None)]   # note: no values for c/d => nil in Lua
              >>> list(func(items).values())
              [True, False, False, True, False, True, False, True]
        
        
        Note that this behaviour changed in Lupa 1.0.  Previously, the ``python.none``
        replacement was done in more places, which made it not always very predictable.
        
        
        Lua Tables
        ----------
        
        Lua tables mimic Python's mapping protocol.  For the special case of
        array tables, Lua automatically inserts integer indices as keys into
        the table.  Therefore, indexing starts from 1 as in Lua instead of 0
        as in Python.  For the same reason, negative indexing does not work.
        It is best to think of Lua tables as mappings rather than arrays, even
        for plain array tables.
        
        .. code:: python
        
              >>> table = lua.eval('{10,20,30,40}')
              >>> table[1]
              10
              >>> table[4]
              40
              >>> list(table)
              [1, 2, 3, 4]
              >>> list(table.values())
              [10, 20, 30, 40]
              >>> len(table)
              4
        
              >>> mapping = lua.eval('{ [1] = -1 }')
              >>> list(mapping)
              [1]
        
              >>> mapping = lua.eval('{ [20] = -20; [3] = -3 }')
              >>> mapping[20]
              -20
              >>> mapping[3]
              -3
              >>> sorted(mapping.values())
              [-20, -3]
              >>> sorted(mapping.items())
              [(3, -3), (20, -20)]
        
              >>> mapping[-3] = 3     # -3 used as key, not index!
              >>> mapping[-3]
              3
              >>> sorted(mapping)
              [-3, 3, 20]
              >>> sorted(mapping.items())
              [(-3, 3), (3, -3), (20, -20)]
        
        To simplify the table creation from Python, the ``LuaRuntime`` comes with
        a helper method that creates a Lua table from Python arguments:
        
        .. code:: python
        
              >>> t = lua.table(1, 2, 3, 4)
              >>> lupa.lua_type(t)
              'table'
              >>> list(t)
              [1, 2, 3, 4]
        
              >>> t = lua.table(1, 2, 3, 4, a=1, b=2)
              >>> t[3]
              3
              >>> t['b']
              2
        
        A second helper method, ``.table_from()``, is new in Lupa 1.1 and accepts
        any number of mappings and sequences/iterables as arguments.  It collects
        all values and key-value pairs and builds a single Lua table from them.
        Any keys that appear in multiple mappings get overwritten with their last
        value (going from left to right).
        
        .. code:: python
        
              >>> t = lua.table_from([1, 2, 3], {'a': 1, 'b': 2}, (4, 5), {'b': 42})
              >>> t['b']
              42
              >>> t[5]
              5
        
        A lookup of non-existing keys or indices returns None (actually ``nil``
        inside of Lua).  A lookup is therefore more similar to the ``.get()``
        method of Python dicts than to a mapping lookup in Python.
        
        .. code:: python
        
              >>> table[1000000] is None
              True
              >>> table['no such key'] is None
              True
              >>> mapping['no such key'] is None
              True
        
        Note that ``len()`` does the right thing for array tables but does not
        work on mappings:
        
        .. code:: python
        
              >>> len(table)
              4
              >>> len(mapping)
              0
        
        This is because ``len()`` is based on the ``#`` (length) operator in
        Lua and because of the way Lua defines the length of a table.
        Remember that unset table indices always return ``nil``, including
        indices outside of the table size.  Thus, Lua basically looks for an
        index that returns ``nil`` and returns the index before that.  This
        works well for array tables that do not contain ``nil`` values, gives
        barely predictable results for tables with 'holes' and does not work
        at all for mapping tables.  For tables with both sequential and
        mapping content, this ignores the mapping part completely.
        
        Note that it is best not to rely on the behaviour of len() for
        mappings.  It might change in a later version of Lupa.
        
        Similar to the table interface provided by Lua, Lupa also supports
        attribute access to table members:
        
        .. code:: python
        
              >>> table = lua.eval('{ a=1, b=2 }')
              >>> table.a, table.b
              (1, 2)
              >>> table.a == table['a']
              True
        
        This enables access to Lua 'methods' that are associated with a table,
        as used by the standard library modules:
        
        .. code:: python
        
              >>> string = lua.eval('string')    # get the 'string' library table
              >>> print( string.lower('A') )
              a
        
        
        Python Callables
        ----------------
        
        As discussed earlier, Lupa allows Lua scripts to call Python functions
        and methods:
        
        .. code:: python
        
              >>> def add_one(num):
              ...     return num + 1
              >>> lua_func = lua.eval('function(num, py_func) return py_func(num) end')
              >>> lua_func(48, add_one)
              49
        
              >>> class MyClass():
              ...     def my_method(self):
              ...         return 345
              >>> obj = MyClass()
              >>> lua_func = lua.eval('function(py_obj) return py_obj:my_method() end')
              >>> lua_func(obj)
              345
        
        Lua doesn't have a dedicated syntax for named arguments, so by default
        Python callables can only be called using positional arguments.
        
        A common pattern for implementing named arguments in Lua is passing them
        in a table as the first and only function argument.  See
        http://lua-users.org/wiki/NamedParameters for more details.  Lupa supports
        this pattern by providing two decorators: ``lupa.unpacks_lua_table``
        for Python functions and ``lupa.unpacks_lua_table_method`` for methods
        of Python objects.
        
        Python functions/methods wrapped in these decorators can be called from
        Lua code as ``func(foo, bar)``, ``func{foo=foo, bar=bar}``
        or ``func{foo, bar=bar}``.  Example:
        
        .. code:: python
        
              >>> @lupa.unpacks_lua_table
              ... def add(a, b):
              ...     return a + b
              >>> lua_func = lua.eval('function(a, b, py_func) return py_func{a=a, b=b} end')
              >>> lua_func(5, 6, add)
              11
              >>> lua_func = lua.eval('function(a, b, py_func) return py_func{a, b=b} end')
              >>> lua_func(5, 6, add)
              11
        
        If you do not control the function implementation, you can also just
        manually wrap a callable object when passing it into Lupa:
        
        .. code:: python
        
              >>> import operator
              >>> wrapped_py_add = lupa.unpacks_lua_table(operator.add)
        
              >>> lua_func = lua.eval('function(a, b, py_func) return py_func{a, b} end')
              >>> lua_func(5, 6, wrapped_py_add)
              11
        
        There are some limitations:
        
        1. Avoid using ``lupa.unpacks_lua_table`` and ``lupa.unpacks_lua_table_method``
           for functions where the first argument can be a Lua table.  In this case
           ``py_func{foo=bar}`` (which is the same as ``py_func({foo=bar})`` in Lua)
           becomes ambiguous: it could mean either "call ``py_func`` with a named
           ``foo`` argument" or "call ``py_func`` with a positional ``{foo=bar}``
           argument".
        
        2. One should be careful with passing ``nil`` values to callables wrapped in
           ``lupa.unpacks_lua_table`` or ``lupa.unpacks_lua_table_method`` decorators.
           Depending on the context, passing ``nil`` as a parameter can mean either
           "omit a parameter" or "pass None".  This even depends on the Lua version.
        
           It is possible to use ``python.none`` instead of ``nil`` to pass None values
           robustly.  Arguments with ``nil`` values are also fine when standard braces
           ``func(a, b, c)`` syntax is used.
        
        Because of these limitations lupa doesn't enable named arguments for all
        Python callables automatically.  Decorators allow to enable named arguments
        on a per-callable basis.
        
        
        Lua Coroutines
        --------------
        
        The next is an example of Lua coroutines.  A wrapped Lua coroutine
        behaves exactly like a Python coroutine.  It needs to get created at
        the beginning, either by using the ``.coroutine()`` method of a
        function or by creating it in Lua code.  Then, values can be sent into
        it using the ``.send()`` method or it can be iterated over.  Note that
        the ``.throw()`` method is not supported, though.
        
        .. code:: python
        
              >>> lua_code = '''\
              ...     function(N)
              ...         for i=0,N do
              ...             coroutine.yield( i%2 )
              ...         end
              ...     end
              ... '''
              >>> lua = LuaRuntime()
              >>> f = lua.eval(lua_code)
        
              >>> gen = f.coroutine(4)
              >>> list(enumerate(gen))
              [(0, 0), (1, 1), (2, 0), (3, 1), (4, 0)]
        
        An example where values are passed into the coroutine using its
        ``.send()`` method:
        
        .. code:: python
        
              >>> lua_code = '''\
              ...     function()
              ...         local t,i = {},0
              ...         local value = coroutine.yield()
              ...         while value do
              ...             t[i] = value
              ...             i = i + 1
              ...             value = coroutine.yield()
              ...         end
              ...         return t
              ...     end
              ... '''
              >>> f = lua.eval(lua_code)
        
              >>> co = f.coroutine()   # create coroutine
              >>> co.send(None)        # start coroutine (stops at first yield)
        
              >>> for i in range(3):
              ...     co.send(i*2)
        
              >>> mapping = co.send(None)   # loop termination signal
              >>> sorted(mapping.items())
              [(0, 0), (1, 2), (2, 4)]
        
        It also works to create coroutines in Lua and to pass them back into
        Python space:
        
        .. code:: python
        
              >>> lua_code = '''\
              ...   function f(N)
              ...         for i=0,N do
              ...             coroutine.yield( i%2 )
              ...         end
              ...   end ;
              ...   co1 = coroutine.create(f) ;
              ...   co2 = coroutine.create(f) ;
              ...
              ...   status, first_result = coroutine.resume(co2, 2) ;   -- starting!
              ...
              ...   return f, co1, co2, status, first_result
              ... '''
        
              >>> lua = LuaRuntime()
              >>> f, co, lua_gen, status, first_result = lua.execute(lua_code)
        
              >>> # a running coroutine:
        
              >>> status
              True
              >>> first_result
              0
              >>> list(lua_gen)
              [1, 0]
              >>> list(lua_gen)
              []
        
              >>> # an uninitialised coroutine:
        
              >>> gen = co(4)
              >>> list(enumerate(gen))
              [(0, 0), (1, 1), (2, 0), (3, 1), (4, 0)]
        
              >>> gen = co(2)
              >>> list(enumerate(gen))
              [(0, 0), (1, 1), (2, 0)]
        
              >>> # a plain function:
        
              >>> gen = f.coroutine(4)
              >>> list(enumerate(gen))
              [(0, 0), (1, 1), (2, 0), (3, 1), (4, 0)]
        
        
        Threading
        ---------
        
        The following example calculates a mandelbrot image in parallel
        threads and displays the result in PIL. It is based on a `benchmark
        implementation`_ for the `Computer Language Benchmarks Game`_.
        
        .. _`Computer Language Benchmarks Game`: http://shootout.alioth.debian.org/u64/benchmark.php?test=all&lang=luajit&lang2=python3
        .. _`benchmark implementation`: http://shootout.alioth.debian.org/u64/program.php?test=mandelbrot&lang=luajit&id=1
        
        .. code:: python
        
            lua_code = '''\
                function(N, i, total)
                    local char, unpack = string.char, unpack
                    local result = ""
                    local M, ba, bb, buf = 2/N, 2^(N%8+1)-1, 2^(8-N%8), {}
                    local start_line, end_line = N/total * (i-1), N/total * i - 1
                    for y=start_line,end_line do
                        local Ci, b, p = y*M-1, 1, 0
                        for x=0,N-1 do
                            local Cr = x*M-1.5
                            local Zr, Zi, Zrq, Ziq = Cr, Ci, Cr*Cr, Ci*Ci
                            b = b + b
                            for i=1,49 do
                                Zi = Zr*Zi*2 + Ci
                                Zr = Zrq-Ziq + Cr
                                Ziq = Zi*Zi
                                Zrq = Zr*Zr
                                if Zrq+Ziq > 4.0 then b = b + 1; break; end
                            end
                            if b >= 256 then p = p + 1; buf[p] = 511 - b; b = 1; end
                        end
                        if b ~= 1 then p = p + 1; buf[p] = (ba-b)*bb; end
                        result = result .. char(unpack(buf, 1, p))
                    end
                    return result
                end
            '''
        
            image_size = 1280   # == 1280 x 1280
            thread_count = 8
        
            from lupa import LuaRuntime
            lua_funcs = [ LuaRuntime(encoding=None).eval(lua_code)
                          for _ in range(thread_count) ]
        
            results = [None] * thread_count
            def mandelbrot(i, lua_func):
                results[i] = lua_func(image_size, i+1, thread_count)
        
            import threading
            threads = [ threading.Thread(target=mandelbrot, args=(i,lua_func))
                        for i, lua_func in enumerate(lua_funcs) ]
            for thread in threads:
                thread.start()
            for thread in threads:
                thread.join()
        
            result_buffer = b''.join(results)
        
            # use PIL to display the image
            import Image
            image = Image.fromstring('1', (image_size, image_size), result_buffer)
            image.show()
        
        Note how the example creates a separate ``LuaRuntime`` for each thread
        to enable parallel execution.  Each ``LuaRuntime`` is protected by a
        global lock that prevents concurrent access to it.  The low memory
        footprint of Lua makes it reasonable to use multiple runtimes, but
        this setup also means that values cannot easily be exchanged between
        threads inside of Lua.  They must either get copied through Python
        space (passing table references will not work, either) or use some Lua
        mechanism for explicit communication, such as a pipe or some kind of
        shared memory setup.
        
        
        Restricting Lua access to Python objects
        ----------------------------------------
        
        ..
                >>> try: unicode = unicode
                ... except NameError: unicode = str
        
        Lupa provides a simple mechanism to control access to Python objects.
        Each attribute access can be passed through a filter function as
        follows:
        
        .. code:: python
        
                >>> def filter_attribute_access(obj, attr_name, is_setting):
                ...     if isinstance(attr_name, unicode):
                ...         if not attr_name.startswith('_'):
                ...             return attr_name
                ...     raise AttributeError('access denied')
        
                >>> lua = lupa.LuaRuntime(
                ...           register_eval=False,
                ...           attribute_filter=filter_attribute_access)
                >>> func = lua.eval('function(x) return x.__class__ end')
                >>> func(lua)
                Traceback (most recent call last):
                 ...
                AttributeError: access denied
        
        The ``is_setting`` flag indicates whether the attribute is being read
        or set.
        
        Note that the attributes of Python functions provide access to the
        current ``globals()`` and therefore to the builtins etc.  If you want
        to safely restrict access to a known set of Python objects, it is best
        to work with a whitelist of safe attribute names.  One way to do that
        could be to use a well selected list of dedicated API objects that you
        provide to Lua code, and to only allow Python attribute access to the
        set of public attribute/method names of these objects.
        
        Since Lupa 1.0, you can alternatively provide dedicated getter and
        setter function implementations for a ``LuaRuntime``:
        
        .. code:: python
        
                >>> def getter(obj, attr_name):
                ...     if attr_name == 'yes':
                ...         return getattr(obj, attr_name)
                ...     raise AttributeError(
                ...         'not allowed to read attribute "%s"' % attr_name)
        
                >>> def setter(obj, attr_name, value):
                ...     if attr_name == 'put':
                ...         setattr(obj, attr_name, value)
                ...         return
                ...     raise AttributeError(
                ...         'not allowed to write attribute "%s"' % attr_name)
        
                >>> class X(object):
                ...     yes = 123
                ...     put = 'abc'
                ...     noway = 2.1
        
                >>> x = X()
        
                >>> lua = lupa.LuaRuntime(attribute_handlers=(getter, setter))
                >>> func = lua.eval('function(x) return x.yes end')
                >>> func(x)  # getting 'yes'
                123
                >>> func = lua.eval('function(x) x.put = "ABC"; end')
                >>> func(x)  # setting 'put'
                >>> print(x.put)
                ABC
                >>> func = lua.eval('function(x) x.noway = 42; end')
                >>> func(x)  # setting 'noway'
                Traceback (most recent call last):
                 ...
                AttributeError: not allowed to write attribute "noway"
        
        
        Importing Lua binary modules
        ----------------------------
        
        **This will usually work as is**, but here are the details, in case
        anything goes wrong for you.
        
        To use binary modules in Lua, you need to compile them against the
        header files of the LuaJIT sources that you used to build Lupa, but do
        not link them against the LuaJIT library.
        
        Furthermore, CPython needs to enable global symbol visibility for
        shared libraries before loading the Lupa module.  This can be done by
        calling ``sys.setdlopenflags(flag_values)``.  Importing the ``lupa``
        module will automatically try to set up the correct ``dlopen`` flags
        if it can find the platform specific ``DLFCN`` Python module that
        defines the necessary flag constants.  In that case, using binary
        modules in Lua should work out of the box.
        
        If this setup fails, however, you have to set the flags manually.
        When using the above configuration call, the argument ``flag_values``
        must represent the sum of your system's values for ``RTLD_NEW`` and
        ``RTLD_GLOBAL``.  If ``RTLD_NEW`` is 2 and ``RTLD_GLOBAL`` is 256, you
        need to call ``sys.setdlopenflags(258)``.
        
        Assuming that the Lua luaposix_ (``posix``) module is available, the
        following should work on a Linux system:
        
        .. code:: python
        
              >>> import sys
              >>> orig_dlflags = sys.getdlopenflags()
              >>> sys.setdlopenflags(258)
              >>> import lupa
              >>> sys.setdlopenflags(orig_dlflags)
        
              >>> lua = lupa.LuaRuntime()
              >>> posix_module = lua.require('posix')     # doctest: +SKIP
        
        .. _luaposix: http://git.alpinelinux.org/cgit/luaposix
        
        
        Installing lupa
        ===============
        
        Building with LuaJIT2
        ---------------------
        
        #) Download and unpack lupa
        
           http://pypi.python.org/pypi/lupa
        
        #) Download LuaJIT2
        
           http://luajit.org/download.html
        
        #) Unpack the archive into the lupa base directory, e.g.::
        
             .../lupa-0.1/LuaJIT-2.0.2
        
        #) Build LuaJIT::
        
             cd LuaJIT-2.0.2
             make
             cd ..
        
           If you need specific C compiler flags, pass them to ``make`` as follows::
        
             make CFLAGS="..."
        
           For trickier target platforms like Windows and MacOS-X, please see
           the official `installation instructions for LuaJIT`_.
        
           NOTE: When building on Windows, make sure that lua51.lib is made in addition
           to lua51.dll. The MSVC build produces this file, MinGW does NOT.
        
        #) Build lupa::
        
             python setup.py install
        
           Or any other distutils target of your choice, such as ``build``
           or one of the ``bdist`` targets.  See the `distutils
           documentation`_ for help, also the `hints on building extension
           modules`_.
        
           Note that on 64bit MacOS-X installations, the following additional
           compiler flags are reportedly required due to the embedded LuaJIT::
        
             -pagezero_size 10000 -image_base 100000000
        
           You can find additional installation hints for MacOS-X in this
           `somewhat unclear blog post`_, which may or may not tell you at
           which point in the installation process to provide these flags.
        
           Also, on 64bit MacOS-X, you will typically have to set the
           environment variable ``ARCHFLAGS`` to make sure it only builds
           for your system instead of trying to generate a fat binary with
           both 32bit and 64bit support::
        
             export ARCHFLAGS="-arch x86_64"
        
           Note that this applies to both LuaJIT and Lupa, so make sure
           you try a clean build of everything if you forgot to set it
           initially.
        
        .. _`installation instructions for LuaJIT`: http://luajit.org/install.html
        .. _`somewhat unclear blog post`: http://t-p-j.blogspot.com/2010/11/lupa-on-os-x-with-macports-python-26.html
        .. _`distutils documentation`: http://docs.python.org/install/index.html#install-index
        .. _`hints on building extension modules`: http://docs.python.org/install/index.html#building-extensions-tips-and-tricks
        
        
        Building with Lua 5.1
        ---------------------
        
        Reportedly, it also works to use Lupa with the standard (non-JIT) Lua
        runtime.  To that end, install Lua 5.1 instead of LuaJIT2, including
        any development packages (header files etc.).
        
        On systems that use the "pkg-config" configuration mechanism, Lupa's
        setup.py will pick up either LuaJIT2 or Lua automatically, with a
        preference for LuaJIT2 if it is found.  Pass the ``--no-luajit`` option
        to the setup.py script if you have both installed but do not want to
        use LuaJIT2.
        
        On other systems, you may have to supply the build parameters
        externally, e.g. using environment variables or by changing the
        setup.py script manually.  Pass the ``--no-luajit`` option to the
        setup.py script in order to ignore the failure you get when neither
        LuaJIT2 nor Lua are found automatically.
        
        For further information, read this mailing list post:
        
        http://article.gmane.org/gmane.comp.python.lupa.devel/31
        
        
        Installing lupa from packages
        =============================
        
        Debian/Ubuntu + Lua 5.2
        -----------------------
        
        #) Install Lua 5.2 development package::
        
             $ apt-get install liblua5.2-dev
        
        #) Install lupa::
        
             $ pip install lupa
        
        Debian/Ubuntu + LuaJIT2
        -----------------------
        
        #) Install LuaJIT2 development package::
        
             $ apt-get install libluajit-5.1-dev
        
        #) Install lupa::
        
             $ pip install lupa
        
        Depending on OS version, you might get an older LuaJIT2 version.
        
        OS X + Lua 5.2 + Homebrew
        -------------------------
        
        #) Install Lua::
        
             $ brew install lua
        
        #) Install pkg-config::
        
             $ brew install pkg-config
        
        #) Install lupa::
        
             $ pip install lupa
        
        
        
        Lupa change log
        ===============
        
        1.8 (2019-02-01)
        ----------------
        
        * GH#107: Fix a deprecated import in Py3.
        
        * Built with Cython 0.29.3 for better Py3.7 compatibility.
        
        
        1.7 (2018-08-06)
        ----------------
        
        * GH#103: Provide wheels for MS Windows and fix MSVC build on Py2.7.
        
        
        1.6 (2017-12-15)
        ----------------
        
        * GH#95: Improved compatibility with Lua 5.3.
          (patch by TitanSnow)
        
        
        1.5 (2017-09-16)
        ----------------
        
        * GH#93: New method ``LuaRuntime.compile()`` to compile Lua code
          without executing it.
          (patch by TitanSnow)
        
        * GH#91: Lua 5.3 is bundled in the source distribution to simplify
          one-shot installs.
          (patch by TitanSnow)
        
        * GH#87: Lua stack trace is included in output in debug mode.
          (patch by aaiyer)
        
        * GH#78: Allow Lua code to intercept Python exceptions.
          (patch by Sergey Dobrov)
        
        * Built with Cython 0.26.1.
        
        
        1.4 (2016-12-10)
        ----------------
        
        * GH#82: Lua coroutines were using the wrong runtime state
          (patch by Sergey Dobrov)
        
        * GH#81: copy locally provided Lua DLL into installed package on Windows
          (patch by Gareth Coles)
        
        * built with Cython 0.25.2
        
        
        1.3 (2016-04-12)
        ----------------
        
        * GH#70: ``eval()`` and ``execute()`` accept optional positional arguments
          (patch by John Vandenberg)
        
        * GH#65: calling ``str()`` on a Python object from Lua could fail if the
          ``LuaRuntime`` is set up without auto-encoding (patch by Mikhail Korobov)
        
        * GH#63: attribute/keyword names were not properly encoded if the
          ``LuaRuntime`` is set up without auto-encoding (patch by Mikhail Korobov)
        
        * built with Cython 0.24
        
        
        1.2 (2015-10-10)
        ----------------
        
        * callbacks returned from Lua coroutines were incorrectly mixing
          coroutine state with global Lua state (patch by Mikhail Korobov)
        
        * availability of ``python.builtins`` in Lua can be disabled via
          ``LuaRuntime`` option.
        
        * built with Cython 0.23.4
        
        
        1.1 (2014-11-21)
        ----------------
        
        * new module function ``lupa.lua_type()`` that returns the Lua type of
          a wrapped object as string, or ``None`` for normal Python objects
        
        * new helper method ``LuaRuntime.table_from(...)`` that creates a Lua
          table from one or more Python mappings and/or sequences
        
        * new ``lupa.unpacks_lua_table`` and ``lupa.unpacks_lua_table_method``
          decorators to allow calling Python functions from Lua using named
          arguments
        
        * fix a hang on shutdown where the LuaRuntime failed to deallocate due
          to reference cycles
        
        * Lupa now plays more nicely with other Lua extensions that create
          userdata objects
        
        
        1.0.1 (2014-10-11)
        ------------------
        
        * fix a crash when requesting attributes of wrapped Lua coroutine objects
        
        * looking up attributes on Lua objects that do not support it now always
          raises an AttributeError instead of sometimes raising a TypeError depending
          on the attribute name
        
        
        1.0 (2014-09-28)
        ----------------
        
        * NOTE: this release includes the major backwards incompatible changes listed
          below.  It is believed that they simplify the interaction between Python code
          and Lua code by more strongly following idiomatic Lua on the Lua side.
        
          * Instead of passing a wrapped ``python.none`` object into Lua, ``None``
            return values are now mapped to ``nil``, making them more straight forward
            to handle in Lua code.  This makes the behaviour more consistent, as it
            was previously somewhat arbitrary where ``none`` could appear and where a
            ``nil`` value was used.  The only remaining exception is during iteration,
            where the first returned value must not be ``nil`` in Lua, or otherwise
            the loop terminates prematurely.  To prevent this, any ``None`` value
            that the iterator returns, or any first item in exploded tuples that is
            ``None``, is still mapped to ``python.none``. Any further values
            returned in the same iteration will be mapped to ``nil`` if they are
            ``None``, not to ``none``.  This means that only the first argument
            needs to be manually checked for this special case.  For the
            ``enumerate()`` iterator, the counter is never ``None`` and thus the
            following unpacked items will never be mapped to ``python.none``.
        
          * When ``unpack_returned_tuples=True``, iteration now also unpacks tuple
            values, including ``enumerate()`` iteration, which yields a flat sequence
            of counter and unpacked values.
        
          * When calling bound Python methods from Lua as "obj:meth()", Lupa now
            prevents Python from prepending the self argument a second time, so that
            the Python method is now called as "obj.meth()".  Previously, it was called
            as "obj.meth(obj)".  Note that this can be undesired when the object itself
            is explicitly passed as first argument from Lua, e.g. when calling
            "func(obj)" where "func" is "obj.meth", but these constellations should be
            rare.  As a work-around for this case, user code can wrap the bound method
            in another function so that the final call comes from Python.
        
        * garbage collection works for reference cycles that span both runtimes,
          Python and Lua
        
        * calling from Python into Lua and back into Python did not clean up the
          Lua call arguments before the innermost call, so that they could leak
          into the nested Python call or its return arguments
        
        * support for Lua 5.2 (in addition to Lua 5.1 and LuaJIT 2.0)
        
        * Lua tables support Python's "del" statement for item deletion
          (patch by Jason Fried)
        
        * Attribute lookup can use a more fine-grained control mechanism by
          implementing explicit getter and setter functions for a LuaRuntime
          (``attribute_handlers`` argument).  Patch by Brian Moe.
        
        * item assignments/lookups on Lua objects from Python no longer
          special case double underscore names (as opposed to attribute lookups)
        
        
        0.21 (2014-02-12)
        -----------------
        
        * some garbage collection issues were cleaned up using new Cython features
        
        * new ``LuaRuntime`` option ``unpack_returned_tuples`` which automatically
          unpacks tuples returned from Python functions into separate Lua objects
          (instead of returning a single Python tuple object)
        
        * some internal wrapper classes were removed from the module API
        
        * Windows build fixes
        
        * Py3.x build fixes
        
        * support for building with Lua 5.1 instead of LuaJIT (setup.py --no-luajit)
        
        * no longer uses Cython by default when building from released sources (pass
          ``--with-cython`` to explicitly request a rebuild)
        
        * requires Cython 0.20+ when building from unreleased sources
        
        * built with Cython 0.20.1
        
        
        0.20 (2011-05-22)
        -----------------
        
        * fix "deallocating None" crash while iterating over Lua tables in
          Python code
        
        * support for filtering attribute access to Python objects for Lua
          code
        
        * fix: setting source encoding for Lua code was broken
        
        
        0.19 (2011-03-06)
        -----------------
        
        * fix serious resource leak when creating multiple LuaRuntime instances
        
        * portability fix for binary module importing
        
        
        0.18 (2010-11-06)
        -----------------
        
        * fix iteration by returning ``Py_None`` object for ``None`` instead
          of ``nil``, which would terminate the iteration
        
        * when converting Python values to Lua, represent ``None`` as a
          ``Py_None`` object in places where ``nil`` has a special meaning,
          but leave it as ``nil`` where it doesn't hurt
        
        * support for counter start value in ``python.enumerate()``
        
        * native implementation for ``python.enumerate()`` that is several
          times faster
        
        * much faster Lua iteration over Python objects
        
        
        0.17 (2010-11-05)
        -----------------
        
        * new helper function ``python.enumerate()`` in Lua that returns a Lua
          iterator for a Python object and adds the 0-based index to each
          item.
        
        * new helper function ``python.iterex()`` in Lua that returns a Lua
          iterator for a Python object and unpacks any tuples that the
          iterator yields.
        
        * new helper function ``python.iter()`` in Lua that returns a Lua
          iterator for a Python object.
        
        * reestablished the ``python.as_function()`` helper function for Lua
          code as it can be needed in cases where Lua cannot determine how to
          run a Python function.
        
        
        0.16 (2010-09-03)
        -----------------
        
        * dropped ``python.as_function()`` helper function for Lua as all
          Python objects are callable from Lua now (potentially raising a
          ``TypeError`` at call time if they are not callable)
        
        * fix regression in 0.13 and later where ordinary Lua functions failed
          to print due to an accidentally used meta table
        
        * fix crash when calling ``str()`` on wrapped Lua objects without
          metatable
        
        
        0.15 (2010-09-02)
        -----------------
        
        * support for loading binary Lua modules on systems that support it
        
        
        0.14 (2010-08-31)
        -----------------
        
        * relicensed to the MIT license used by LuaJIT2 to simplify licensing
          considerations
        
        
        0.13.1 (2010-08-30)
        -------------------
        
        * fix Cython generated C file using Cython 0.13
        
        
        0.13 (2010-08-29)
        -----------------
        
        * fixed undefined behaviour on ``str(lua_object)`` when the object's
          ``__tostring()`` meta method fails
        
        * removed redundant "error:" prefix from ``LuaError`` messages
        
        * access to Python's ``python.builtins`` from Lua code
        
        * more generic wrapping rules for Python objects based on supported
          protocols (callable, getitem, getattr)
        
        * new helper functions ``as_attrgetter()`` and ``as_itemgetter()`` to
          specify the Python object protocol used by Lua indexing when
          wrapping Python objects in Python code
        
        * new helper functions ``python.as_attrgetter()``,
          ``python.as_itemgetter()`` and ``python.as_function()`` to specify
          the Python object protocol used by Lua indexing of Python objects in
          Lua code
        
        * item and attribute access for Python objects from Lua code
        
        
        0.12 (2010-08-16)
        -----------------
        
        * fix Lua stack leak during table iteration
        
        * fix lost Lua object reference after iteration
        
        
        0.11 (2010-08-07)
        -----------------
        
        * error reporting on Lua syntax errors failed to clean up the stack so
          that errors could leak into the next Lua run
        
        * Lua error messages were not properly decoded
        
        
        0.10 (2010-07-27)
        -----------------
        
        * much faster locking of the LuaRuntime, especially in the single
          threaded case (see
          http://code.activestate.com/recipes/577336-fast-re-entrant-optimistic-lock-implemented-in-cyt/)
        
        * fixed several error handling problems when executing Python code
          inside of Lua
        
        
        0.9 (2010-07-23)
        ----------------
        
        * fixed Python special double-underscore method access on LuaObject
          instances
        
        * Lua coroutine support through dedicated wrapper classes, including
          Python iteration support.  In Python space, Lua coroutines behave
          exactly like Python generators.
        
        
        0.8 (2010-07-21)
        ----------------
        
        * support for returning multiple values from Lua evaluation
        
        * ``repr()`` support for Lua objects
        
        * ``LuaRuntime.table()`` method for creating Lua tables from Python
          space
        
        * encoding fix for ``str(LuaObject)``
        
        
        0.7 (2010-07-18)
        ----------------
        
        * ``LuaRuntime.require()`` and ``LuaRuntime.globals()`` methods
        
        * renamed ``LuaRuntime.run()`` to ``LuaRuntime.execute()``
        
        * support for ``len()``, ``setattr()`` and subscripting of Lua objects
        
        * provide all built-in Lua libraries in ``LuaRuntime``, including
          support for library loading
        
        * fixed a thread locking issue
        
        * fix passing Lua objects back into the runtime from Python space
        
        
        0.6 (2010-07-18)
        ----------------
        
        * Python iteration support for Lua objects (e.g. tables)
        
        * threading fixes
        
        * fix compile warnings
        
        
        0.5 (2010-07-14)
        ----------------
        
        * explicit encoding options per LuaRuntime instance to decode/encode
          strings and Lua code
        
        
        0.4 (2010-07-14)
        ----------------
        
        * attribute read access on Lua objects, e.g. to read Lua table values
          from Python
        
        * str() on Lua objects
        
        * include .hg repository in source downloads
        
        * added missing files to source distribution
        
        
        0.3 (2010-07-13)
        ----------------
        
        * fix several threading issues
        
        * safely free the GIL when calling into Lua
        
        
        0.2 (2010-07-13)
        ----------------
        
        * propagate Python exceptions through Lua calls
        
        
        0.1 (2010-07-12)
        ----------------
        
        * first public release
        
        
        License
        =======
        
        Lupa
        ----
        
        Copyright (c) 2010-2017 Stefan Behnel.  All rights reserved.
        
        Permission is hereby granted, free of charge, to any person obtaining a copy
        of this software and associated documentation files (the "Software"), to deal
        in the Software without restriction, including without limitation the rights
        to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
        copies of the Software, and to permit persons to whom the Software is
        furnished to do so, subject to the following conditions:
        
        The above copyright notice and this permission notice shall be included in
        all copies or substantial portions of the Software.
        
        THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
        IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
        FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.  IN NO EVENT SHALL THE
        AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
        LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
        OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
        THE SOFTWARE.
        
        Lua
        ---
        
        (See https://www.lua.org/license.html)
        
        Copyright © 1994–2017 Lua.org, PUC-Rio.
        
        Permission is hereby granted, free of charge, to any person obtaining a copy
        of this software and associated documentation files (the "Software"), to deal
        in the Software without restriction, including without limitation the rights
        to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
        copies of the Software, and to permit persons to whom the Software is
        furnished to do so, subject to the following conditions:
        
        The above copyright notice and this permission notice shall be included in
        all copies or substantial portions of the Software.
        
        THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
        IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
        FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
        AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
        LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
        OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
        THE SOFTWARE.
        
Platform: UNKNOWN
Classifier: Development Status :: 5 - Production/Stable
Classifier: Intended Audience :: Developers
Classifier: Intended Audience :: Information Technology
Classifier: License :: OSI Approved :: MIT License
Classifier: Programming Language :: Cython
Classifier: Programming Language :: Python :: 2
Classifier: Programming Language :: Python :: 2.7
Classifier: Programming Language :: Python :: 3
Classifier: Programming Language :: Python :: 3.4
Classifier: Programming Language :: Python :: 3.5
Classifier: Programming Language :: Python :: 3.6
Classifier: Programming Language :: Python :: 3.7
Classifier: Programming Language :: Other Scripting Engines
Classifier: Operating System :: OS Independent
Classifier: Topic :: Software Development
