thanks to vye16 ❤

fb5159d over 2 years ago

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	from __future__ import absolute_import

	import cython
	cython.declare(PyrexTypes=object, Naming=object, ExprNodes=object, Nodes=object,
	Options=object, UtilNodes=object, LetNode=object,
	LetRefNode=object, TreeFragment=object, EncodedString=object,
	error=object, warning=object, copy=object, hashlib=object, sys=object,
	_unicode=object)

	import copy
	import hashlib
	import sys

	from . import PyrexTypes
	from . import Naming
	from . import ExprNodes
	from . import Nodes
	from . import Options
	from . import Builtin
	from . import Errors

	from .Visitor import VisitorTransform, TreeVisitor
	from .Visitor import CythonTransform, EnvTransform, ScopeTrackingTransform
	from .UtilNodes import LetNode, LetRefNode
	from .TreeFragment import TreeFragment
	from .StringEncoding import EncodedString, _unicode
	from .Errors import error, warning, CompileError, InternalError
	from .Code import UtilityCode


	class SkipDeclarations(object):
	"""
	Variable and function declarations can often have a deep tree structure,
	and yet most transformations don't need to descend to this depth.

	Declaration nodes are removed after AnalyseDeclarationsTransform, so there
	is no need to use this for transformations after that point.
	"""
	def visit_CTypeDefNode(self, node):
	return node

	def visit_CVarDefNode(self, node):
	return node

	def visit_CDeclaratorNode(self, node):
	return node

	def visit_CBaseTypeNode(self, node):
	return node

	def visit_CEnumDefNode(self, node):
	return node

	def visit_CStructOrUnionDefNode(self, node):
	return node


	class NormalizeTree(CythonTransform):
	"""
	This transform fixes up a few things after parsing
	in order to make the parse tree more suitable for
	transforms.

	a) After parsing, blocks with only one statement will
	be represented by that statement, not by a StatListNode.
	When doing transforms this is annoying and inconsistent,
	as one cannot in general remove a statement in a consistent
	way and so on. This transform wraps any single statements
	in a StatListNode containing a single statement.

	b) The PassStatNode is a noop and serves no purpose beyond
	plugging such one-statement blocks; i.e., once parsed a
	` "pass" can just as well be represented using an empty
	StatListNode. This means less special cases to worry about
	in subsequent transforms (one always checks to see if a
	StatListNode has no children to see if the block is empty).
	"""

	def __init__(self, context):
	super(NormalizeTree, self).__init__(context)
	self.is_in_statlist = False
	self.is_in_expr = False

	def visit_ExprNode(self, node):
	stacktmp = self.is_in_expr
	self.is_in_expr = True
	self.visitchildren(node)
	self.is_in_expr = stacktmp
	return node

	def visit_StatNode(self, node, is_listcontainer=False):
	stacktmp = self.is_in_statlist
	self.is_in_statlist = is_listcontainer
	self.visitchildren(node)
	self.is_in_statlist = stacktmp
	if not self.is_in_statlist and not self.is_in_expr:
	return Nodes.StatListNode(pos=node.pos, stats=[node])
	else:
	return node

	def visit_StatListNode(self, node):
	self.is_in_statlist = True
	self.visitchildren(node)
	self.is_in_statlist = False
	return node

	def visit_ParallelAssignmentNode(self, node):
	return self.visit_StatNode(node, True)

	def visit_CEnumDefNode(self, node):
	return self.visit_StatNode(node, True)

	def visit_CStructOrUnionDefNode(self, node):
	return self.visit_StatNode(node, True)

	def visit_PassStatNode(self, node):
	"""Eliminate PassStatNode"""
	if not self.is_in_statlist:
	return Nodes.StatListNode(pos=node.pos, stats=[])
	else:
	return []

	def visit_ExprStatNode(self, node):
	"""Eliminate useless string literals"""
	if node.expr.is_string_literal:
	return self.visit_PassStatNode(node)
	else:
	return self.visit_StatNode(node)

	def visit_CDeclaratorNode(self, node):
	return node


	class PostParseError(CompileError): pass

	# error strings checked by unit tests, so define them
	ERR_CDEF_INCLASS = 'Cannot assign default value to fields in cdef classes, structs or unions'
	ERR_BUF_DEFAULTS = 'Invalid buffer defaults specification (see docs)'
	ERR_INVALID_SPECIALATTR_TYPE = 'Special attributes must not have a type declared'
	class PostParse(ScopeTrackingTransform):
	"""
	Basic interpretation of the parse tree, as well as validity
	checking that can be done on a very basic level on the parse
	tree (while still not being a problem with the basic syntax,
	as such).

	Specifically:
	- Default values to cdef assignments are turned into single
	assignments following the declaration (everywhere but in class
	bodies, where they raise a compile error)

	- Interpret some node structures into Python runtime values.
	Some nodes take compile-time arguments (currently:
	TemplatedTypeNode[args] and __cythonbufferdefaults__ = {args}),
	which should be interpreted. This happens in a general way
	and other steps should be taken to ensure validity.

	Type arguments cannot be interpreted in this way.

	- For __cythonbufferdefaults__ the arguments are checked for
	validity.

	TemplatedTypeNode has its directives interpreted:
	Any first positional argument goes into the "dtype" attribute,
	any "ndim" keyword argument goes into the "ndim" attribute and
	so on. Also it is checked that the directive combination is valid.
	- __cythonbufferdefaults__ attributes are parsed and put into the
	type information.

	Note: Currently Parsing.py does a lot of interpretation and
	reorganization that can be refactored into this transform
	if a more pure Abstract Syntax Tree is wanted.
	"""

	def __init__(self, context):
	super(PostParse, self).__init__(context)
	self.specialattribute_handlers = {
	'__cythonbufferdefaults__' : self.handle_bufferdefaults
	}

	def visit_LambdaNode(self, node):
	# unpack a lambda expression into the corresponding DefNode
	collector = YieldNodeCollector()
	collector.visitchildren(node.result_expr)
	if collector.has_yield or collector.has_await or isinstance(node.result_expr, ExprNodes.YieldExprNode):
	body = Nodes.ExprStatNode(
	node.result_expr.pos, expr=node.result_expr)
	else:
	body = Nodes.ReturnStatNode(
	node.result_expr.pos, value=node.result_expr)
	node.def_node = Nodes.DefNode(
	node.pos, name=node.name,
	args=node.args, star_arg=node.star_arg,
	starstar_arg=node.starstar_arg,
	body=body, doc=None)
	self.visitchildren(node)
	return node

	def visit_GeneratorExpressionNode(self, node):
	# unpack a generator expression into the corresponding DefNode
	collector = YieldNodeCollector()
	collector.visitchildren(node.loop)
	node.def_node = Nodes.DefNode(
	node.pos, name=node.name, doc=None,
	args=[], star_arg=None, starstar_arg=None,
	body=node.loop, is_async_def=collector.has_await)
	self.visitchildren(node)
	return node

	def visit_ComprehensionNode(self, node):
	# enforce local scope also in Py2 for async generators (seriously, that's a Py3.6 feature...)
	if not node.has_local_scope:
	collector = YieldNodeCollector()
	collector.visitchildren(node.loop)
	if collector.has_await:
	node.has_local_scope = True
	self.visitchildren(node)
	return node

	# cdef variables
	def handle_bufferdefaults(self, decl):
	if not isinstance(decl.default, ExprNodes.DictNode):
	raise PostParseError(decl.pos, ERR_BUF_DEFAULTS)
	self.scope_node.buffer_defaults_node = decl.default
	self.scope_node.buffer_defaults_pos = decl.pos

	def visit_CVarDefNode(self, node):
	# This assumes only plain names and pointers are assignable on
	# declaration. Also, it makes use of the fact that a cdef decl
	# must appear before the first use, so we don't have to deal with
	# "i = 3; cdef int i = i" and can simply move the nodes around.
	try:
	self.visitchildren(node)
	stats = [node]
	newdecls = []
	for decl in node.declarators:
	declbase = decl
	while isinstance(declbase, Nodes.CPtrDeclaratorNode):
	declbase = declbase.base
	if isinstance(declbase, Nodes.CNameDeclaratorNode):
	if declbase.default is not None:
	if self.scope_type in ('cclass', 'pyclass', 'struct'):
	if isinstance(self.scope_node, Nodes.CClassDefNode):
	handler = self.specialattribute_handlers.get(decl.name)
	if handler:
	if decl is not declbase:
	raise PostParseError(decl.pos, ERR_INVALID_SPECIALATTR_TYPE)
	handler(decl)
	continue # Remove declaration
	raise PostParseError(decl.pos, ERR_CDEF_INCLASS)
	first_assignment = self.scope_type != 'module'
	stats.append(Nodes.SingleAssignmentNode(node.pos,
	lhs=ExprNodes.NameNode(node.pos, name=declbase.name),
	rhs=declbase.default, first=first_assignment))
	declbase.default = None
	newdecls.append(decl)
	node.declarators = newdecls
	return stats
	except PostParseError as e:
	# An error in a cdef clause is ok, simply remove the declaration
	# and try to move on to report more errors
	self.context.nonfatal_error(e)
	return None

	# Split parallel assignments (a,b = b,a) into separate partial
	# assignments that are executed rhs-first using temps. This
	# restructuring must be applied before type analysis so that known
	# types on rhs and lhs can be matched directly. It is required in
	# the case that the types cannot be coerced to a Python type in
	# order to assign from a tuple.

	def visit_SingleAssignmentNode(self, node):
	self.visitchildren(node)
	return self._visit_assignment_node(node, [node.lhs, node.rhs])

	def visit_CascadedAssignmentNode(self, node):
	self.visitchildren(node)
	return self._visit_assignment_node(node, node.lhs_list + [node.rhs])

	def _visit_assignment_node(self, node, expr_list):
	"""Flatten parallel assignments into separate single
	assignments or cascaded assignments.
	"""
	if sum([ 1 for expr in expr_list
	if expr.is_sequence_constructor or expr.is_string_literal ]) < 2:
	# no parallel assignments => nothing to do
	return node

	expr_list_list = []
	flatten_parallel_assignments(expr_list, expr_list_list)
	temp_refs = []
	eliminate_rhs_duplicates(expr_list_list, temp_refs)

	nodes = []
	for expr_list in expr_list_list:
	lhs_list = expr_list[:-1]
	rhs = expr_list[-1]
	if len(lhs_list) == 1:
	node = Nodes.SingleAssignmentNode(rhs.pos,
	lhs = lhs_list[0], rhs = rhs)
	else:
	node = Nodes.CascadedAssignmentNode(rhs.pos,
	lhs_list = lhs_list, rhs = rhs)
	nodes.append(node)

	if len(nodes) == 1:
	assign_node = nodes[0]
	else:
	assign_node = Nodes.ParallelAssignmentNode(nodes[0].pos, stats = nodes)

	if temp_refs:
	duplicates_and_temps = [ (temp.expression, temp)
	for temp in temp_refs ]
	sort_common_subsequences(duplicates_and_temps)
	for _, temp_ref in duplicates_and_temps[::-1]:
	assign_node = LetNode(temp_ref, assign_node)

	return assign_node

	def _flatten_sequence(self, seq, result):
	for arg in seq.args:
	if arg.is_sequence_constructor:
	self._flatten_sequence(arg, result)
	else:
	result.append(arg)
	return result

	def visit_DelStatNode(self, node):
	self.visitchildren(node)
	node.args = self._flatten_sequence(node, [])
	return node

	def visit_ExceptClauseNode(self, node):
	if node.is_except_as:
	# except-as must delete NameNode target at the end
	del_target = Nodes.DelStatNode(
	node.pos,
	args=[ExprNodes.NameNode(
	node.target.pos, name=node.target.name)],
	ignore_nonexisting=True)
	node.body = Nodes.StatListNode(
	node.pos,
	stats=[Nodes.TryFinallyStatNode(
	node.pos,
	body=node.body,
	finally_clause=Nodes.StatListNode(
	node.pos,
	stats=[del_target]))])
	self.visitchildren(node)
	return node


	def eliminate_rhs_duplicates(expr_list_list, ref_node_sequence):
	"""Replace rhs items by LetRefNodes if they appear more than once.
	Creates a sequence of LetRefNodes that set up the required temps
	and appends them to ref_node_sequence. The input list is modified
	in-place.
	"""
	seen_nodes = set()
	ref_nodes = {}
	def find_duplicates(node):
	if node.is_literal or node.is_name:
	# no need to replace those; can't include attributes here
	# as their access is not necessarily side-effect free
	return
	if node in seen_nodes:
	if node not in ref_nodes:
	ref_node = LetRefNode(node)
	ref_nodes[node] = ref_node
	ref_node_sequence.append(ref_node)
	else:
	seen_nodes.add(node)
	if node.is_sequence_constructor:
	for item in node.args:
	find_duplicates(item)

	for expr_list in expr_list_list:
	rhs = expr_list[-1]
	find_duplicates(rhs)
	if not ref_nodes:
	return

	def substitute_nodes(node):
	if node in ref_nodes:
	return ref_nodes[node]
	elif node.is_sequence_constructor:
	node.args = list(map(substitute_nodes, node.args))
	return node

	# replace nodes inside of the common subexpressions
	for node in ref_nodes:
	if node.is_sequence_constructor:
	node.args = list(map(substitute_nodes, node.args))

	# replace common subexpressions on all rhs items
	for expr_list in expr_list_list:
	expr_list[-1] = substitute_nodes(expr_list[-1])

	def sort_common_subsequences(items):
	"""Sort items/subsequences so that all items and subsequences that
	an item contains appear before the item itself. This is needed
	because each rhs item must only be evaluated once, so its value
	must be evaluated first and then reused when packing sequences
	that contain it.

	This implies a partial order, and the sort must be stable to
	preserve the original order as much as possible, so we use a
	simple insertion sort (which is very fast for short sequences, the
	normal case in practice).
	"""
	def contains(seq, x):
	for item in seq:
	if item is x:
	return True
	elif item.is_sequence_constructor and contains(item.args, x):
	return True
	return False
	def lower_than(a,b):
	return b.is_sequence_constructor and contains(b.args, a)

	for pos, item in enumerate(items):
	key = item[1] # the ResultRefNode which has already been injected into the sequences
	new_pos = pos
	for i in range(pos-1, -1, -1):
	if lower_than(key, items[i][0]):
	new_pos = i
	if new_pos != pos:
	for i in range(pos, new_pos, -1):
	items[i] = items[i-1]
	items[new_pos] = item

	def unpack_string_to_character_literals(literal):
	chars = []
	pos = literal.pos
	stype = literal.__class__
	sval = literal.value
	sval_type = sval.__class__
	for char in sval:
	cval = sval_type(char)
	chars.append(stype(pos, value=cval, constant_result=cval))
	return chars

	def flatten_parallel_assignments(input, output):
	# The input is a list of expression nodes, representing the LHSs
	# and RHS of one (possibly cascaded) assignment statement. For
	# sequence constructors, rearranges the matching parts of both
	# sides into a list of equivalent assignments between the
	# individual elements. This transformation is applied
	# recursively, so that nested structures get matched as well.
	rhs = input[-1]
	if (not (rhs.is_sequence_constructor or isinstance(rhs, ExprNodes.UnicodeNode))
	or not sum([lhs.is_sequence_constructor for lhs in input[:-1]])):
	output.append(input)
	return

	complete_assignments = []

	if rhs.is_sequence_constructor:
	rhs_args = rhs.args
	elif rhs.is_string_literal:
	rhs_args = unpack_string_to_character_literals(rhs)

	rhs_size = len(rhs_args)
	lhs_targets = [[] for _ in range(rhs_size)]
	starred_assignments = []
	for lhs in input[:-1]:
	if not lhs.is_sequence_constructor:
	if lhs.is_starred:
	error(lhs.pos, "starred assignment target must be in a list or tuple")
	complete_assignments.append(lhs)
	continue
	lhs_size = len(lhs.args)
	starred_targets = sum([1 for expr in lhs.args if expr.is_starred])
	if starred_targets > 1:
	error(lhs.pos, "more than 1 starred expression in assignment")
	output.append([lhs,rhs])
	continue
	elif lhs_size - starred_targets > rhs_size:
	error(lhs.pos, "need more than %d value%s to unpack"
	% (rhs_size, (rhs_size != 1) and 's' or ''))
	output.append([lhs,rhs])
	continue
	elif starred_targets:
	map_starred_assignment(lhs_targets, starred_assignments,
	lhs.args, rhs_args)
	elif lhs_size < rhs_size:
	error(lhs.pos, "too many values to unpack (expected %d, got %d)"
	% (lhs_size, rhs_size))
	output.append([lhs,rhs])
	continue
	else:
	for targets, expr in zip(lhs_targets, lhs.args):
	targets.append(expr)

	if complete_assignments:
	complete_assignments.append(rhs)
	output.append(complete_assignments)

	# recursively flatten partial assignments
	for cascade, rhs in zip(lhs_targets, rhs_args):
	if cascade:
	cascade.append(rhs)
	flatten_parallel_assignments(cascade, output)

	# recursively flatten starred assignments
	for cascade in starred_assignments:
	if cascade[0].is_sequence_constructor:
	flatten_parallel_assignments(cascade, output)
	else:
	output.append(cascade)

	def map_starred_assignment(lhs_targets, starred_assignments, lhs_args, rhs_args):
	# Appends the fixed-position LHS targets to the target list that
	# appear left and right of the starred argument.
	#
	# The starred_assignments list receives a new tuple
	# (lhs_target, rhs_values_list) that maps the remaining arguments
	# (those that match the starred target) to a list.

	# left side of the starred target
	for i, (targets, expr) in enumerate(zip(lhs_targets, lhs_args)):
	if expr.is_starred:
	starred = i
	lhs_remaining = len(lhs_args) - i - 1
	break
	targets.append(expr)
	else:
	raise InternalError("no starred arg found when splitting starred assignment")

	# right side of the starred target
	for i, (targets, expr) in enumerate(zip(lhs_targets[-lhs_remaining:],
	lhs_args[starred + 1:])):
	targets.append(expr)

	# the starred target itself, must be assigned a (potentially empty) list
	target = lhs_args[starred].target # unpack starred node
	starred_rhs = rhs_args[starred:]
	if lhs_remaining:
	starred_rhs = starred_rhs[:-lhs_remaining]
	if starred_rhs:
	pos = starred_rhs[0].pos
	else:
	pos = target.pos
	starred_assignments.append([
	target, ExprNodes.ListNode(pos=pos, args=starred_rhs)])


	class PxdPostParse(CythonTransform, SkipDeclarations):
	"""
	Basic interpretation/validity checking that should only be
	done on pxd trees.

	A lot of this checking currently happens in the parser; but
	what is listed below happens here.

	- "def" functions are let through only if they fill the
	getbuffer/releasebuffer slots

	- cdef functions are let through only if they are on the
	top level and are declared "inline"
	"""
	ERR_INLINE_ONLY = "function definition in pxd file must be declared 'cdef inline'"
	ERR_NOGO_WITH_INLINE = "inline function definition in pxd file cannot be '%s'"

	def __call__(self, node):
	self.scope_type = 'pxd'
	return super(PxdPostParse, self).__call__(node)

	def visit_CClassDefNode(self, node):
	old = self.scope_type
	self.scope_type = 'cclass'
	self.visitchildren(node)
	self.scope_type = old
	return node

	def visit_FuncDefNode(self, node):
	# FuncDefNode always come with an implementation (without
	# an imp they are CVarDefNodes..)
	err = self.ERR_INLINE_ONLY

	if (isinstance(node, Nodes.DefNode) and self.scope_type == 'cclass'
	and node.name in ('__getbuffer__', '__releasebuffer__')):
	err = None # allow these slots

	if isinstance(node, Nodes.CFuncDefNode):
	if (u'inline' in node.modifiers and
	self.scope_type in ('pxd', 'cclass')):
	node.inline_in_pxd = True
	if node.visibility != 'private':
	err = self.ERR_NOGO_WITH_INLINE % node.visibility
	elif node.api:
	err = self.ERR_NOGO_WITH_INLINE % 'api'
	else:
	err = None # allow inline function
	else:
	err = self.ERR_INLINE_ONLY

	if err:
	self.context.nonfatal_error(PostParseError(node.pos, err))
	return None
	else:
	return node


	class TrackNumpyAttributes(VisitorTransform, SkipDeclarations):
	# TODO: Make name handling as good as in InterpretCompilerDirectives() below - probably best to merge the two.
	def __init__(self):
	super(TrackNumpyAttributes, self).__init__()
	self.numpy_module_names = set()

	def visit_CImportStatNode(self, node):
	if node.module_name == u"numpy":
	self.numpy_module_names.add(node.as_name or u"numpy")
	return node

	def visit_AttributeNode(self, node):
	self.visitchildren(node)
	obj = node.obj
	if (obj.is_name and obj.name in self.numpy_module_names) or obj.is_numpy_attribute:
	node.is_numpy_attribute = True
	return node

	visit_Node = VisitorTransform.recurse_to_children


	class InterpretCompilerDirectives(CythonTransform):
	"""
	After parsing, directives can be stored in a number of places:
	- #cython-comments at the top of the file (stored in ModuleNode)
	- Command-line arguments overriding these
	- @cython.directivename decorators
	- with cython.directivename: statements

	This transform is responsible for interpreting these various sources
	and store the directive in two ways:
	- Set the directives attribute of the ModuleNode for global directives.
	- Use a CompilerDirectivesNode to override directives for a subtree.

	(The first one is primarily to not have to modify with the tree
	structure, so that ModuleNode stay on top.)

	The directives are stored in dictionaries from name to value in effect.
	Each such dictionary is always filled in for all possible directives,
	using default values where no value is given by the user.

	The available directives are controlled in Options.py.

	Note that we have to run this prior to analysis, and so some minor
	duplication of functionality has to occur: We manually track cimports
	and which names the "cython" module may have been imported to.
	"""
	unop_method_nodes = {
	'typeof': ExprNodes.TypeofNode,

	'operator.address': ExprNodes.AmpersandNode,
	'operator.dereference': ExprNodes.DereferenceNode,
	'operator.preincrement' : ExprNodes.inc_dec_constructor(True, '++'),
	'operator.predecrement' : ExprNodes.inc_dec_constructor(True, '--'),
	'operator.postincrement': ExprNodes.inc_dec_constructor(False, '++'),
	'operator.postdecrement': ExprNodes.inc_dec_constructor(False, '--'),
	'operator.typeid' : ExprNodes.TypeidNode,

	# For backwards compatibility.
	'address': ExprNodes.AmpersandNode,
	}

	binop_method_nodes = {
	'operator.comma' : ExprNodes.c_binop_constructor(','),
	}

	special_methods = set(['declare', 'union', 'struct', 'typedef',
	'sizeof', 'cast', 'pointer', 'compiled',
	'NULL', 'fused_type', 'parallel'])
	special_methods.update(unop_method_nodes)

	valid_parallel_directives = set([
	"parallel",
	"prange",
	"threadid",
	#"threadsavailable",
	])

	def __init__(self, context, compilation_directive_defaults):
	super(InterpretCompilerDirectives, self).__init__(context)
	self.cython_module_names = set()
	self.directive_names = {'staticmethod': 'staticmethod'}
	self.parallel_directives = {}
	directives = copy.deepcopy(Options.get_directive_defaults())
	for key, value in compilation_directive_defaults.items():
	directives[_unicode(key)] = copy.deepcopy(value)
	self.directives = directives

	def check_directive_scope(self, pos, directive, scope):
	legal_scopes = Options.directive_scopes.get(directive, None)
	if legal_scopes and scope not in legal_scopes:
	self.context.nonfatal_error(PostParseError(pos, 'The %s compiler directive '
	'is not allowed in %s scope' % (directive, scope)))
	return False
	else:
	if directive not in Options.directive_types:
	error(pos, "Invalid directive: '%s'." % (directive,))
	return True

	# Set up processing and handle the cython: comments.
	def visit_ModuleNode(self, node):
	for key in sorted(node.directive_comments):
	if not self.check_directive_scope(node.pos, key, 'module'):
	self.wrong_scope_error(node.pos, key, 'module')
	del node.directive_comments[key]

	self.module_scope = node.scope

	self.directives.update(node.directive_comments)
	node.directives = self.directives
	node.parallel_directives = self.parallel_directives
	self.visitchildren(node)
	node.cython_module_names = self.cython_module_names
	return node

	# The following four functions track imports and cimports that
	# begin with "cython"
	def is_cython_directive(self, name):
	return (name in Options.directive_types or
	name in self.special_methods or
	PyrexTypes.parse_basic_type(name))

	def is_parallel_directive(self, full_name, pos):
	"""
	Checks to see if fullname (e.g. cython.parallel.prange) is a valid
	parallel directive. If it is a star import it also updates the
	parallel_directives.
	"""
	result = (full_name + ".").startswith("cython.parallel.")

	if result:
	directive = full_name.split('.')
	if full_name == u"cython.parallel":
	self.parallel_directives[u"parallel"] = u"cython.parallel"
	elif full_name == u"cython.parallel.*":
	for name in self.valid_parallel_directives:
	self.parallel_directives[name] = u"cython.parallel.%s" % name
	elif (len(directive) != 3 or
	directive[-1] not in self.valid_parallel_directives):
	error(pos, "No such directive: %s" % full_name)

	self.module_scope.use_utility_code(
	UtilityCode.load_cached("InitThreads", "ModuleSetupCode.c"))

	return result

	def visit_CImportStatNode(self, node):
	if node.module_name == u"cython":
	self.cython_module_names.add(node.as_name or u"cython")
	elif node.module_name.startswith(u"cython."):
	if node.module_name.startswith(u"cython.parallel."):
	error(node.pos, node.module_name + " is not a module")
	if node.module_name == u"cython.parallel":
	if node.as_name and node.as_name != u"cython":
	self.parallel_directives[node.as_name] = node.module_name
	else:
	self.cython_module_names.add(u"cython")
	self.parallel_directives[
	u"cython.parallel"] = node.module_name
	self.module_scope.use_utility_code(
	UtilityCode.load_cached("InitThreads", "ModuleSetupCode.c"))
	elif node.as_name:
	self.directive_names[node.as_name] = node.module_name[7:]
	else:
	self.cython_module_names.add(u"cython")
	# if this cimport was a compiler directive, we don't
	# want to leave the cimport node sitting in the tree
	return None
	return node

	def visit_FromCImportStatNode(self, node):
	if not node.relative_level and (
	node.module_name == u"cython" or node.module_name.startswith(u"cython.")):
	submodule = (node.module_name + u".")[7:]
	newimp = []

	for pos, name, as_name, kind in node.imported_names:
	full_name = submodule + name
	qualified_name = u"cython." + full_name

	if self.is_parallel_directive(qualified_name, node.pos):
	# from cython cimport parallel, or
	# from cython.parallel cimport parallel, prange, ...
	self.parallel_directives[as_name or name] = qualified_name
	elif self.is_cython_directive(full_name):
	self.directive_names[as_name or name] = full_name
	if kind is not None:
	self.context.nonfatal_error(PostParseError(pos,
	"Compiler directive imports must be plain imports"))
	else:
	newimp.append((pos, name, as_name, kind))

	if not newimp:
	return None

	node.imported_names = newimp
	return node

	def visit_FromImportStatNode(self, node):
	if (node.module.module_name.value == u"cython") or \
	node.module.module_name.value.startswith(u"cython."):
	submodule = (node.module.module_name.value + u".")[7:]
	newimp = []
	for name, name_node in node.items:
	full_name = submodule + name
	qualified_name = u"cython." + full_name
	if self.is_parallel_directive(qualified_name, node.pos):
	self.parallel_directives[name_node.name] = qualified_name
	elif self.is_cython_directive(full_name):
	self.directive_names[name_node.name] = full_name
	else:
	newimp.append((name, name_node))
	if not newimp:
	return None
	node.items = newimp
	return node

	def visit_SingleAssignmentNode(self, node):
	if isinstance(node.rhs, ExprNodes.ImportNode):
	module_name = node.rhs.module_name.value
	is_parallel = (module_name + u".").startswith(u"cython.parallel.")

	if module_name != u"cython" and not is_parallel:
	return node

	module_name = node.rhs.module_name.value
	as_name = node.lhs.name

	node = Nodes.CImportStatNode(node.pos,
	module_name = module_name,
	as_name = as_name)
	node = self.visit_CImportStatNode(node)
	else:
	self.visitchildren(node)

	return node

	def visit_NameNode(self, node):
	if node.name in self.cython_module_names:
	node.is_cython_module = True
	else:
	directive = self.directive_names.get(node.name)
	if directive is not None:
	node.cython_attribute = directive
	return node

	def visit_NewExprNode(self, node):
	self.visit(node.cppclass)
	self.visitchildren(node)
	return node

	def try_to_parse_directives(self, node):
	# If node is the contents of an directive (in a with statement or
	# decorator), returns a list of (directivename, value) pairs.
	# Otherwise, returns None
	if isinstance(node, ExprNodes.CallNode):
	self.visit(node.function)
	optname = node.function.as_cython_attribute()
	if optname:
	directivetype = Options.directive_types.get(optname)
	if directivetype:
	args, kwds = node.explicit_args_kwds()
	directives = []
	key_value_pairs = []
	if kwds is not None and directivetype is not dict:
	for keyvalue in kwds.key_value_pairs:
	key, value = keyvalue
	sub_optname = "%s.%s" % (optname, key.value)
	if Options.directive_types.get(sub_optname):
	directives.append(self.try_to_parse_directive(sub_optname, [value], None, keyvalue.pos))
	else:
	key_value_pairs.append(keyvalue)
	if not key_value_pairs:
	kwds = None
	else:
	kwds.key_value_pairs = key_value_pairs
	if directives and not kwds and not args:
	return directives
	directives.append(self.try_to_parse_directive(optname, args, kwds, node.function.pos))
	return directives
	elif isinstance(node, (ExprNodes.AttributeNode, ExprNodes.NameNode)):
	self.visit(node)
	optname = node.as_cython_attribute()
	if optname:
	directivetype = Options.directive_types.get(optname)
	if directivetype is bool:
	arg = ExprNodes.BoolNode(node.pos, value=True)
	return [self.try_to_parse_directive(optname, [arg], None, node.pos)]
	elif directivetype is None:
	return [(optname, None)]
	else:
	raise PostParseError(
	node.pos, "The '%s' directive should be used as a function call." % optname)
	return None

	def try_to_parse_directive(self, optname, args, kwds, pos):
	if optname == 'np_pythran' and not self.context.cpp:
	raise PostParseError(pos, 'The %s directive can only be used in C++ mode.' % optname)
	elif optname == 'exceptval':
	# default: exceptval(None, check=True)
	arg_error = len(args) > 1
	check = True
	if kwds and kwds.key_value_pairs:
	kw = kwds.key_value_pairs[0]
	if (len(kwds.key_value_pairs) == 1 and
	kw.key.is_string_literal and kw.key.value == 'check' and
	isinstance(kw.value, ExprNodes.BoolNode)):
	check = kw.value.value
	else:
	arg_error = True
	if arg_error:
	raise PostParseError(
	pos, 'The exceptval directive takes 0 or 1 positional arguments and the boolean keyword "check"')
	return ('exceptval', (args[0] if args else None, check))

	directivetype = Options.directive_types.get(optname)
	if len(args) == 1 and isinstance(args[0], ExprNodes.NoneNode):
	return optname, Options.get_directive_defaults()[optname]
	elif directivetype is bool:
	if kwds is not None or len(args) != 1 or not isinstance(args[0], ExprNodes.BoolNode):
	raise PostParseError(pos,
	'The %s directive takes one compile-time boolean argument' % optname)
	return (optname, args[0].value)
	elif directivetype is int:
	if kwds is not None or len(args) != 1 or not isinstance(args[0], ExprNodes.IntNode):
	raise PostParseError(pos,
	'The %s directive takes one compile-time integer argument' % optname)
	return (optname, int(args[0].value))
	elif directivetype is str:
	if kwds is not None or len(args) != 1 or not isinstance(
	args[0], (ExprNodes.StringNode, ExprNodes.UnicodeNode)):
	raise PostParseError(pos,
	'The %s directive takes one compile-time string argument' % optname)
	return (optname, str(args[0].value))
	elif directivetype is type:
	if kwds is not None or len(args) != 1:
	raise PostParseError(pos,
	'The %s directive takes one type argument' % optname)
	return (optname, args[0])
	elif directivetype is dict:
	if len(args) != 0:
	raise PostParseError(pos,
	'The %s directive takes no prepositional arguments' % optname)
	return optname, dict([(key.value, value) for key, value in kwds.key_value_pairs])
	elif directivetype is list:
	if kwds and len(kwds.key_value_pairs) != 0:
	raise PostParseError(pos,
	'The %s directive takes no keyword arguments' % optname)
	return optname, [ str(arg.value) for arg in args ]
	elif callable(directivetype):
	if kwds is not None or len(args) != 1 or not isinstance(
	args[0], (ExprNodes.StringNode, ExprNodes.UnicodeNode)):
	raise PostParseError(pos,
	'The %s directive takes one compile-time string argument' % optname)
	return (optname, directivetype(optname, str(args[0].value)))
	else:
	assert False

	def visit_with_directives(self, node, directives):
	if not directives:
	return self.visit_Node(node)

	old_directives = self.directives
	new_directives = dict(old_directives)
	new_directives.update(directives)

	if new_directives == old_directives:
	return self.visit_Node(node)

	self.directives = new_directives
	retbody = self.visit_Node(node)
	self.directives = old_directives

	if not isinstance(retbody, Nodes.StatListNode):
	retbody = Nodes.StatListNode(node.pos, stats=[retbody])
	return Nodes.CompilerDirectivesNode(
	pos=retbody.pos, body=retbody, directives=new_directives)

	# Handle decorators
	def visit_FuncDefNode(self, node):
	directives = self._extract_directives(node, 'function')
	return self.visit_with_directives(node, directives)

	def visit_CVarDefNode(self, node):
	directives = self._extract_directives(node, 'function')
	for name, value in directives.items():
	if name == 'locals':
	node.directive_locals = value
	elif name not in ('final', 'staticmethod'):
	self.context.nonfatal_error(PostParseError(
	node.pos,
	"Cdef functions can only take cython.locals(), "
	"staticmethod, or final decorators, got %s." % name))
	return self.visit_with_directives(node, directives)

	def visit_CClassDefNode(self, node):
	directives = self._extract_directives(node, 'cclass')
	return self.visit_with_directives(node, directives)

	def visit_CppClassNode(self, node):
	directives = self._extract_directives(node, 'cppclass')
	return self.visit_with_directives(node, directives)

	def visit_PyClassDefNode(self, node):
	directives = self._extract_directives(node, 'class')
	return self.visit_with_directives(node, directives)

	def _extract_directives(self, node, scope_name):
	if not node.decorators:
	return {}
	# Split the decorators into two lists -- real decorators and directives
	directives = []
	realdecs = []
	both = []
	# Decorators coming first take precedence.
	for dec in node.decorators[::-1]:
	new_directives = self.try_to_parse_directives(dec.decorator)
	if new_directives is not None:
	for directive in new_directives:
	if self.check_directive_scope(node.pos, directive[0], scope_name):
	name, value = directive
	if self.directives.get(name, object()) != value:
	directives.append(directive)
	if directive[0] == 'staticmethod':
	both.append(dec)
	# Adapt scope type based on decorators that change it.
	if directive[0] == 'cclass' and scope_name == 'class':
	scope_name = 'cclass'
	else:
	realdecs.append(dec)
	if realdecs and (scope_name == 'cclass' or
	isinstance(node, (Nodes.CFuncDefNode, Nodes.CClassDefNode, Nodes.CVarDefNode))):
	raise PostParseError(realdecs[0].pos, "Cdef functions/classes cannot take arbitrary decorators.")
	node.decorators = realdecs[::-1] + both[::-1]
	# merge or override repeated directives
	optdict = {}
	for directive in directives:
	name, value = directive
	if name in optdict:
	old_value = optdict[name]
	# keywords and arg lists can be merged, everything
	# else overrides completely
	if isinstance(old_value, dict):
	old_value.update(value)
	elif isinstance(old_value, list):
	old_value.extend(value)
	else:
	optdict[name] = value
	else:
	optdict[name] = value
	return optdict

	# Handle with-statements
	def visit_WithStatNode(self, node):
	directive_dict = {}
	for directive in self.try_to_parse_directives(node.manager) or []:
	if directive is not None:
	if node.target is not None:
	self.context.nonfatal_error(
	PostParseError(node.pos, "Compiler directive with statements cannot contain 'as'"))
	else:
	name, value = directive
	if name in ('nogil', 'gil'):
	# special case: in pure mode, "with nogil" spells "with cython.nogil"
	node = Nodes.GILStatNode(node.pos, state = name, body = node.body)
	return self.visit_Node(node)
	if self.check_directive_scope(node.pos, name, 'with statement'):
	directive_dict[name] = value
	if directive_dict:
	return self.visit_with_directives(node.body, directive_dict)
	return self.visit_Node(node)


	class ParallelRangeTransform(CythonTransform, SkipDeclarations):
	"""
	Transform cython.parallel stuff. The parallel_directives come from the
	module node, set there by InterpretCompilerDirectives.

	x = cython.parallel.threadavailable() -> ParallelThreadAvailableNode
	with nogil, cython.parallel.parallel(): -> ParallelWithBlockNode
	print cython.parallel.threadid() -> ParallelThreadIdNode
	for i in cython.parallel.prange(...): -> ParallelRangeNode
	...
	"""

	# a list of names, maps 'cython.parallel.prange' in the code to
	# ['cython', 'parallel', 'prange']
	parallel_directive = None

	# Indicates whether a namenode in an expression is the cython module
	namenode_is_cython_module = False

	# Keep track of whether we are the context manager of a 'with' statement
	in_context_manager_section = False

	# One of 'prange' or 'with parallel'. This is used to disallow closely
	# nested 'with parallel:' blocks
	state = None

	directive_to_node = {
	u"cython.parallel.parallel": Nodes.ParallelWithBlockNode,
	# u"cython.parallel.threadsavailable": ExprNodes.ParallelThreadsAvailableNode,
	u"cython.parallel.threadid": ExprNodes.ParallelThreadIdNode,
	u"cython.parallel.prange": Nodes.ParallelRangeNode,
	}

	def node_is_parallel_directive(self, node):
	return node.name in self.parallel_directives or node.is_cython_module

	def get_directive_class_node(self, node):
	"""
	Figure out which parallel directive was used and return the associated
	Node class.

	E.g. for a cython.parallel.prange() call we return ParallelRangeNode
	"""
	if self.namenode_is_cython_module:
	directive = '.'.join(self.parallel_directive)
	else:
	directive = self.parallel_directives[self.parallel_directive[0]]
	directive = '%s.%s' % (directive,
	'.'.join(self.parallel_directive[1:]))
	directive = directive.rstrip('.')

	cls = self.directive_to_node.get(directive)
	if cls is None and not (self.namenode_is_cython_module and
	self.parallel_directive[0] != 'parallel'):
	error(node.pos, "Invalid directive: %s" % directive)

	self.namenode_is_cython_module = False
	self.parallel_directive = None

	return cls

	def visit_ModuleNode(self, node):
	"""
	If any parallel directives were imported, copy them over and visit
	the AST
	"""
	if node.parallel_directives:
	self.parallel_directives = node.parallel_directives
	return self.visit_Node(node)

	# No parallel directives were imported, so they can't be used :)
	return node

	def visit_NameNode(self, node):
	if self.node_is_parallel_directive(node):
	self.parallel_directive = [node.name]
	self.namenode_is_cython_module = node.is_cython_module
	return node

	def visit_AttributeNode(self, node):
	self.visitchildren(node)
	if self.parallel_directive:
	self.parallel_directive.append(node.attribute)
	return node

	def visit_CallNode(self, node):
	self.visit(node.function)
	if not self.parallel_directive:
	self.visitchildren(node, exclude=('function',))
	return node

	# We are a parallel directive, replace this node with the
	# corresponding ParallelSomethingSomething node

	if isinstance(node, ExprNodes.GeneralCallNode):
	args = node.positional_args.args
	kwargs = node.keyword_args
	else:
	args = node.args
	kwargs = {}

	parallel_directive_class = self.get_directive_class_node(node)
	if parallel_directive_class:
	# Note: in case of a parallel() the body is set by
	# visit_WithStatNode
	node = parallel_directive_class(node.pos, args=args, kwargs=kwargs)

	return node

	def visit_WithStatNode(self, node):
	"Rewrite with cython.parallel.parallel() blocks"
	newnode = self.visit(node.manager)

	if isinstance(newnode, Nodes.ParallelWithBlockNode):
	if self.state == 'parallel with':
	error(node.manager.pos,
	"Nested parallel with blocks are disallowed")

	self.state = 'parallel with'
	body = self.visit(node.body)
	self.state = None

	newnode.body = body
	return newnode
	elif self.parallel_directive:
	parallel_directive_class = self.get_directive_class_node(node)

	if not parallel_directive_class:
	# There was an error, stop here and now
	return None

	if parallel_directive_class is Nodes.ParallelWithBlockNode:
	error(node.pos, "The parallel directive must be called")
	return None

	node.body = self.visit(node.body)
	return node

	def visit_ForInStatNode(self, node):
	"Rewrite 'for i in cython.parallel.prange(...):'"
	self.visit(node.iterator)
	self.visit(node.target)

	in_prange = isinstance(node.iterator.sequence,
	Nodes.ParallelRangeNode)
	previous_state = self.state

	if in_prange:
	# This will replace the entire ForInStatNode, so copy the
	# attributes
	parallel_range_node = node.iterator.sequence

	parallel_range_node.target = node.target
	parallel_range_node.body = node.body
	parallel_range_node.else_clause = node.else_clause

	node = parallel_range_node

	if not isinstance(node.target, ExprNodes.NameNode):
	error(node.target.pos,
	"Can only iterate over an iteration variable")

	self.state = 'prange'

	self.visit(node.body)
	self.state = previous_state
	self.visit(node.else_clause)
	return node

	def visit(self, node):
	"Visit a node that may be None"
	if node is not None:
	return super(ParallelRangeTransform, self).visit(node)


	class WithTransform(CythonTransform, SkipDeclarations):
	def visit_WithStatNode(self, node):
	self.visitchildren(node, 'body')
	pos = node.pos
	is_async = node.is_async
	body, target, manager = node.body, node.target, node.manager
	node.enter_call = ExprNodes.SimpleCallNode(
	pos, function=ExprNodes.AttributeNode(
	pos, obj=ExprNodes.CloneNode(manager),
	attribute=EncodedString('__aenter__' if is_async else '__enter__'),
	is_special_lookup=True),
	args=[],
	is_temp=True)

	if is_async:
	node.enter_call = ExprNodes.AwaitExprNode(pos, arg=node.enter_call)

	if target is not None:
	body = Nodes.StatListNode(
	pos, stats=[
	Nodes.WithTargetAssignmentStatNode(
	pos, lhs=target, with_node=node),
	body])

	excinfo_target = ExprNodes.TupleNode(pos, slow=True, args=[
	ExprNodes.ExcValueNode(pos) for _ in range(3)])
	except_clause = Nodes.ExceptClauseNode(
	pos, body=Nodes.IfStatNode(
	pos, if_clauses=[
	Nodes.IfClauseNode(
	pos, condition=ExprNodes.NotNode(
	pos, operand=ExprNodes.WithExitCallNode(
	pos, with_stat=node,
	test_if_run=False,
	args=excinfo_target,
	await_expr=ExprNodes.AwaitExprNode(pos, arg=None) if is_async else None)),
	body=Nodes.ReraiseStatNode(pos),
	),
	],
	else_clause=None),
	pattern=None,
	target=None,
	excinfo_target=excinfo_target,
	)

	node.body = Nodes.TryFinallyStatNode(
	pos, body=Nodes.TryExceptStatNode(
	pos, body=body,
	except_clauses=[except_clause],
	else_clause=None,
	),
	finally_clause=Nodes.ExprStatNode(
	pos, expr=ExprNodes.WithExitCallNode(
	pos, with_stat=node,
	test_if_run=True,
	args=ExprNodes.TupleNode(
	pos, args=[ExprNodes.NoneNode(pos) for _ in range(3)]),
	await_expr=ExprNodes.AwaitExprNode(pos, arg=None) if is_async else None)),
	handle_error_case=False,
	)
	return node

	def visit_ExprNode(self, node):
	# With statements are never inside expressions.
	return node


	class DecoratorTransform(ScopeTrackingTransform, SkipDeclarations):
	"""
	Transforms method decorators in cdef classes into nested calls or properties.

	Python-style decorator properties are transformed into a PropertyNode
	with up to the three getter, setter and deleter DefNodes.
	The functional style isn't supported yet.
	"""
	_properties = None

	_map_property_attribute = {
	'getter': '__get__',
	'setter': '__set__',
	'deleter': '__del__',
	}.get

	def visit_CClassDefNode(self, node):
	if self._properties is None:
	self._properties = []
	self._properties.append({})
	super(DecoratorTransform, self).visit_CClassDefNode(node)
	self._properties.pop()
	return node

	def visit_PropertyNode(self, node):
	# Low-level warning for other code until we can convert all our uses over.
	level = 2 if isinstance(node.pos[0], str) else 0
	warning(node.pos, "'property %s:' syntax is deprecated, use '@property'" % node.name, level)
	return node

	def visit_DefNode(self, node):
	scope_type = self.scope_type
	node = self.visit_FuncDefNode(node)
	if scope_type != 'cclass' or not node.decorators:
	return node

	# transform @property decorators
	properties = self._properties[-1]
	for decorator_node in node.decorators[::-1]:
	decorator = decorator_node.decorator
	if decorator.is_name and decorator.name == 'property':
	if len(node.decorators) > 1:
	return self._reject_decorated_property(node, decorator_node)
	name = node.name
	node.name = EncodedString('__get__')
	node.decorators.remove(decorator_node)
	stat_list = [node]
	if name in properties:
	prop = properties[name]
	prop.pos = node.pos
	prop.doc = node.doc
	prop.body.stats = stat_list
	return []
	prop = Nodes.PropertyNode(node.pos, name=name)
	prop.doc = node.doc
	prop.body = Nodes.StatListNode(node.pos, stats=stat_list)
	properties[name] = prop
	return [prop]
	elif decorator.is_attribute and decorator.obj.name in properties:
	handler_name = self._map_property_attribute(decorator.attribute)
	if handler_name:
	if decorator.obj.name != node.name:
	# CPython does not generate an error or warning, but not something useful either.
	error(decorator_node.pos,
	"Mismatching property names, expected '%s', got '%s'" % (
	decorator.obj.name, node.name))
	elif len(node.decorators) > 1:
	return self._reject_decorated_property(node, decorator_node)
	else:
	return self._add_to_property(properties, node, handler_name, decorator_node)

	# we clear node.decorators, so we need to set the
	# is_staticmethod/is_classmethod attributes now
	for decorator in node.decorators:
	func = decorator.decorator
	if func.is_name:
	node.is_classmethod \|= func.name == 'classmethod'
	node.is_staticmethod \|= func.name == 'staticmethod'

	# transform normal decorators
	decs = node.decorators
	node.decorators = None
	return self.chain_decorators(node, decs, node.name)

	@staticmethod
	def _reject_decorated_property(node, decorator_node):
	# restrict transformation to outermost decorator as wrapped properties will probably not work
	for deco in node.decorators:
	if deco != decorator_node:
	error(deco.pos, "Property methods with additional decorators are not supported")
	return node

	@staticmethod
	def _add_to_property(properties, node, name, decorator):
	prop = properties[node.name]
	node.name = name
	node.decorators.remove(decorator)
	stats = prop.body.stats
	for i, stat in enumerate(stats):
	if stat.name == name:
	stats[i] = node
	break
	else:
	stats.append(node)
	return []

	@staticmethod
	def chain_decorators(node, decorators, name):
	"""
	Decorators are applied directly in DefNode and PyClassDefNode to avoid
	reassignments to the function/class name - except for cdef class methods.
	For those, the reassignment is required as methods are originally
	defined in the PyMethodDef struct.

	The IndirectionNode allows DefNode to override the decorator.
	"""
	decorator_result = ExprNodes.NameNode(node.pos, name=name)
	for decorator in decorators[::-1]:
	decorator_result = ExprNodes.SimpleCallNode(
	decorator.pos,
	function=decorator.decorator,
	args=[decorator_result])

	name_node = ExprNodes.NameNode(node.pos, name=name)
	reassignment = Nodes.SingleAssignmentNode(
	node.pos,
	lhs=name_node,
	rhs=decorator_result)

	reassignment = Nodes.IndirectionNode([reassignment])
	node.decorator_indirection = reassignment
	return [node, reassignment]


	class CnameDirectivesTransform(CythonTransform, SkipDeclarations):
	"""
	Only part of the CythonUtilityCode pipeline. Must be run before
	DecoratorTransform in case this is a decorator for a cdef class.
	It filters out @cname('my_cname') decorators and rewrites them to
	CnameDecoratorNodes.
	"""

	def handle_function(self, node):
	if not getattr(node, 'decorators', None):
	return self.visit_Node(node)

	for i, decorator in enumerate(node.decorators):
	decorator = decorator.decorator

	if (isinstance(decorator, ExprNodes.CallNode) and
	decorator.function.is_name and
	decorator.function.name == 'cname'):
	args, kwargs = decorator.explicit_args_kwds()

	if kwargs:
	raise AssertionError(
	"cname decorator does not take keyword arguments")

	if len(args) != 1:
	raise AssertionError(
	"cname decorator takes exactly one argument")

	if not (args[0].is_literal and
	args[0].type == Builtin.str_type):
	raise AssertionError(
	"argument to cname decorator must be a string literal")

	cname = args[0].compile_time_value(None)
	del node.decorators[i]
	node = Nodes.CnameDecoratorNode(pos=node.pos, node=node,
	cname=cname)
	break

	return self.visit_Node(node)

	visit_FuncDefNode = handle_function
	visit_CClassDefNode = handle_function
	visit_CEnumDefNode = handle_function
	visit_CStructOrUnionDefNode = handle_function


	class ForwardDeclareTypes(CythonTransform):

	def visit_CompilerDirectivesNode(self, node):
	env = self.module_scope
	old = env.directives
	env.directives = node.directives
	self.visitchildren(node)
	env.directives = old
	return node

	def visit_ModuleNode(self, node):
	self.module_scope = node.scope
	self.module_scope.directives = node.directives
	self.visitchildren(node)
	return node

	def visit_CDefExternNode(self, node):
	old_cinclude_flag = self.module_scope.in_cinclude
	self.module_scope.in_cinclude = 1
	self.visitchildren(node)
	self.module_scope.in_cinclude = old_cinclude_flag
	return node

	def visit_CEnumDefNode(self, node):
	node.declare(self.module_scope)
	return node

	def visit_CStructOrUnionDefNode(self, node):
	if node.name not in self.module_scope.entries:
	node.declare(self.module_scope)
	return node

	def visit_CClassDefNode(self, node):
	if node.class_name not in self.module_scope.entries:
	node.declare(self.module_scope)
	# Expand fused methods of .pxd declared types to construct the final vtable order.
	type = self.module_scope.entries[node.class_name].type
	if type is not None and type.is_extension_type and not type.is_builtin_type and type.scope:
	scope = type.scope
	for entry in scope.cfunc_entries:
	if entry.type and entry.type.is_fused:
	entry.type.get_all_specialized_function_types()
	return node


	class AnalyseDeclarationsTransform(EnvTransform):

	basic_property = TreeFragment(u"""
	property NAME:
	def __get__(self):
	return ATTR
	def __set__(self, value):
	ATTR = value
	""", level='c_class', pipeline=[NormalizeTree(None)])
	basic_pyobject_property = TreeFragment(u"""
	property NAME:
	def __get__(self):
	return ATTR
	def __set__(self, value):
	ATTR = value
	def __del__(self):
	ATTR = None
	""", level='c_class', pipeline=[NormalizeTree(None)])
	basic_property_ro = TreeFragment(u"""
	property NAME:
	def __get__(self):
	return ATTR
	""", level='c_class', pipeline=[NormalizeTree(None)])

	struct_or_union_wrapper = TreeFragment(u"""
	cdef class NAME:
	cdef TYPE value
	def __init__(self, MEMBER=None):
	cdef int count
	count = 0
	INIT_ASSIGNMENTS
	if IS_UNION and count > 1:
	raise ValueError, "At most one union member should be specified."
	def __str__(self):
	return STR_FORMAT % MEMBER_TUPLE
	def __repr__(self):
	return REPR_FORMAT % MEMBER_TUPLE
	""", pipeline=[NormalizeTree(None)])

	init_assignment = TreeFragment(u"""
	if VALUE is not None:
	ATTR = VALUE
	count += 1
	""", pipeline=[NormalizeTree(None)])

	fused_function = None
	in_lambda = 0

	def __call__(self, root):
	# needed to determine if a cdef var is declared after it's used.
	self.seen_vars_stack = []
	self.fused_error_funcs = set()
	super_class = super(AnalyseDeclarationsTransform, self)
	self._super_visit_FuncDefNode = super_class.visit_FuncDefNode
	return super_class.__call__(root)

	def visit_NameNode(self, node):
	self.seen_vars_stack[-1].add(node.name)
	return node

	def visit_ModuleNode(self, node):
	# Pickling support requires injecting module-level nodes.
	self.extra_module_declarations = []
	self.seen_vars_stack.append(set())
	node.analyse_declarations(self.current_env())
	self.visitchildren(node)
	self.seen_vars_stack.pop()
	node.body.stats.extend(self.extra_module_declarations)
	return node

	def visit_LambdaNode(self, node):
	self.in_lambda += 1
	node.analyse_declarations(self.current_env())
	self.visitchildren(node)
	self.in_lambda -= 1
	return node

	def visit_CClassDefNode(self, node):
	node = self.visit_ClassDefNode(node)
	if node.scope and node.scope.implemented and node.body:
	stats = []
	for entry in node.scope.var_entries:
	if entry.needs_property:
	property = self.create_Property(entry)
	property.analyse_declarations(node.scope)
	self.visit(property)
	stats.append(property)
	if stats:
	node.body.stats += stats
	if (node.visibility != 'extern'
	and not node.scope.lookup('__reduce__')
	and not node.scope.lookup('__reduce_ex__')):
	self._inject_pickle_methods(node)
	return node

	def _inject_pickle_methods(self, node):
	env = self.current_env()
	if node.scope.directives['auto_pickle'] is False: # None means attempt it.
	# Old behavior of not doing anything.
	return
	auto_pickle_forced = node.scope.directives['auto_pickle'] is True

	all_members = []
	cls = node.entry.type
	cinit = None
	inherited_reduce = None
	while cls is not None:
	all_members.extend(e for e in cls.scope.var_entries if e.name not in ('__weakref__', '__dict__'))
	cinit = cinit or cls.scope.lookup('__cinit__')
	inherited_reduce = inherited_reduce or cls.scope.lookup('__reduce__') or cls.scope.lookup('__reduce_ex__')
	cls = cls.base_type
	all_members.sort(key=lambda e: e.name)

	if inherited_reduce:
	# This is not failsafe, as we may not know whether a cimported class defines a __reduce__.
	# This is why we define __reduce_cython__ and only replace __reduce__
	# (via ExtensionTypes.SetupReduce utility code) at runtime on class creation.
	return

	non_py = [
	e for e in all_members
	if not e.type.is_pyobject and (not e.type.can_coerce_to_pyobject(env)
	or not e.type.can_coerce_from_pyobject(env))
	]

	structs = [e for e in all_members if e.type.is_struct_or_union]

	if cinit or non_py or (structs and not auto_pickle_forced):
	if cinit:
	# TODO(robertwb): We could allow this if __cinit__ has no require arguments.
	msg = 'no default __reduce__ due to non-trivial __cinit__'
	elif non_py:
	msg = "%s cannot be converted to a Python object for pickling" % ','.join("self.%s" % e.name for e in non_py)
	else:
	# Extern structs may be only partially defined.
	# TODO(robertwb): Limit the restriction to extern
	# (and recursively extern-containing) structs.
	msg = ("Pickling of struct members such as %s must be explicitly requested "
	"with @auto_pickle(True)" % ','.join("self.%s" % e.name for e in structs))

	if auto_pickle_forced:
	error(node.pos, msg)

	pickle_func = TreeFragment(u"""
	def __reduce_cython__(self):
	raise TypeError("%(msg)s")
	def __setstate_cython__(self, __pyx_state):
	raise TypeError("%(msg)s")
	""" % {'msg': msg},
	level='c_class', pipeline=[NormalizeTree(None)]).substitute({})
	pickle_func.analyse_declarations(node.scope)
	self.visit(pickle_func)
	node.body.stats.append(pickle_func)

	else:
	for e in all_members:
	if not e.type.is_pyobject:
	e.type.create_to_py_utility_code(env)
	e.type.create_from_py_utility_code(env)
	all_members_names = [e.name for e in all_members]
	checksums = _calculate_pickle_checksums(all_members_names)

	unpickle_func_name = '__pyx_unpickle_%s' % node.class_name

	# TODO(robertwb): Move the state into the third argument
	# so it can be pickled after self is memoized.
	unpickle_func = TreeFragment(u"""
	def %(unpickle_func_name)s(__pyx_type, long __pyx_checksum, __pyx_state):
	cdef object __pyx_PickleError
	cdef object __pyx_result
	if __pyx_checksum not in %(checksums)s:
	from pickle import PickleError as __pyx_PickleError
	raise __pyx_PickleError("Incompatible checksums (0x%%x vs %(checksums)s = (%(members)s))" %% __pyx_checksum)
	__pyx_result = %(class_name)s.__new__(__pyx_type)
	if __pyx_state is not None:
	%(unpickle_func_name)s__set_state(<%(class_name)s> __pyx_result, __pyx_state)
	return __pyx_result

	cdef %(unpickle_func_name)s__set_state(%(class_name)s __pyx_result, tuple __pyx_state):
	%(assignments)s
	if len(__pyx_state) > %(num_members)d and hasattr(__pyx_result, '__dict__'):
	__pyx_result.__dict__.update(__pyx_state[%(num_members)d])
	""" % {
	'unpickle_func_name': unpickle_func_name,
	'checksums': "(%s)" % ', '.join(checksums),
	'members': ', '.join(all_members_names),
	'class_name': node.class_name,
	'assignments': '; '.join(
	'__pyx_result.%s = __pyx_state[%s]' % (v, ix)
	for ix, v in enumerate(all_members_names)),
	'num_members': len(all_members_names),
	}, level='module', pipeline=[NormalizeTree(None)]).substitute({})
	unpickle_func.analyse_declarations(node.entry.scope)
	self.visit(unpickle_func)
	self.extra_module_declarations.append(unpickle_func)

	pickle_func = TreeFragment(u"""
	def __reduce_cython__(self):
	cdef tuple state
	cdef object _dict
	cdef bint use_setstate
	state = (%(members)s)
	_dict = getattr(self, '__dict__', None)
	if _dict is not None:
	state += (_dict,)
	use_setstate = True
	else:
	use_setstate = %(any_notnone_members)s
	if use_setstate:
	return %(unpickle_func_name)s, (type(self), %(checksum)s, None), state
	else:
	return %(unpickle_func_name)s, (type(self), %(checksum)s, state)

	def __setstate_cython__(self, __pyx_state):
	%(unpickle_func_name)s__set_state(self, __pyx_state)
	""" % {
	'unpickle_func_name': unpickle_func_name,
	'checksum': checksums[0],
	'members': ', '.join('self.%s' % v for v in all_members_names) + (',' if len(all_members_names) == 1 else ''),
	# Even better, we could check PyType_IS_GC.
	'any_notnone_members' : ' or '.join(['self.%s is not None' % e.name for e in all_members if e.type.is_pyobject] or ['False']),
	},
	level='c_class', pipeline=[NormalizeTree(None)]).substitute({})
	pickle_func.analyse_declarations(node.scope)
	self.enter_scope(node, node.scope) # functions should be visited in the class scope
	self.visit(pickle_func)
	self.exit_scope()
	node.body.stats.append(pickle_func)

	def _handle_fused_def_decorators(self, old_decorators, env, node):
	"""
	Create function calls to the decorators and reassignments to
	the function.
	"""
	# Delete staticmethod and classmethod decorators, this is
	# handled directly by the fused function object.
	decorators = []
	for decorator in old_decorators:
	func = decorator.decorator
	if (not func.is_name or
	func.name not in ('staticmethod', 'classmethod') or
	env.lookup_here(func.name)):
	# not a static or classmethod
	decorators.append(decorator)

	if decorators:
	transform = DecoratorTransform(self.context)
	def_node = node.node
	_, reassignments = transform.chain_decorators(
	def_node, decorators, def_node.name)
	reassignments.analyse_declarations(env)
	node = [node, reassignments]

	return node

	def _handle_def(self, decorators, env, node):
	"Handle def or cpdef fused functions"
	# Create PyCFunction nodes for each specialization
	node.stats.insert(0, node.py_func)
	node.py_func = self.visit(node.py_func)
	node.update_fused_defnode_entry(env)
	pycfunc = ExprNodes.PyCFunctionNode.from_defnode(node.py_func, binding=True)
	pycfunc = ExprNodes.ProxyNode(pycfunc.coerce_to_temp(env))
	node.resulting_fused_function = pycfunc
	# Create assignment node for our def function
	node.fused_func_assignment = self._create_assignment(
	node.py_func, ExprNodes.CloneNode(pycfunc), env)

	if decorators:
	node = self._handle_fused_def_decorators(decorators, env, node)

	return node

	def _create_fused_function(self, env, node):
	"Create a fused function for a DefNode with fused arguments"
	from . import FusedNode

	if self.fused_function or self.in_lambda:
	if self.fused_function not in self.fused_error_funcs:
	if self.in_lambda:
	error(node.pos, "Fused lambdas not allowed")
	else:
	error(node.pos, "Cannot nest fused functions")

	self.fused_error_funcs.add(self.fused_function)

	node.body = Nodes.PassStatNode(node.pos)
	for arg in node.args:
	if arg.type.is_fused:
	arg.type = arg.type.get_fused_types()[0]

	return node

	decorators = getattr(node, 'decorators', None)
	node = FusedNode.FusedCFuncDefNode(node, env)
	self.fused_function = node
	self.visitchildren(node)
	self.fused_function = None
	if node.py_func:
	node = self._handle_def(decorators, env, node)

	return node

	def _handle_nogil_cleanup(self, lenv, node):
	"Handle cleanup for 'with gil' blocks in nogil functions."
	if lenv.nogil and lenv.has_with_gil_block:
	# Acquire the GIL for cleanup in 'nogil' functions, by wrapping
	# the entire function body in try/finally.
	# The corresponding release will be taken care of by
	# Nodes.FuncDefNode.generate_function_definitions()
	node.body = Nodes.NogilTryFinallyStatNode(
	node.body.pos,
	body=node.body,
	finally_clause=Nodes.EnsureGILNode(node.body.pos),
	finally_except_clause=Nodes.EnsureGILNode(node.body.pos))

	def _handle_fused(self, node):
	if node.is_generator and node.has_fused_arguments:
	node.has_fused_arguments = False
	error(node.pos, "Fused generators not supported")
	node.gbody = Nodes.StatListNode(node.pos,
	stats=[],
	body=Nodes.PassStatNode(node.pos))

	return node.has_fused_arguments

	def visit_FuncDefNode(self, node):
	"""
	Analyse a function and its body, as that hasn't happened yet. Also
	analyse the directive_locals set by @cython.locals().

	Then, if we are a function with fused arguments, replace the function
	(after it has declared itself in the symbol table!) with a
	FusedCFuncDefNode, and analyse its children (which are in turn normal
	functions). If we're a normal function, just analyse the body of the
	function.
	"""
	env = self.current_env()

	self.seen_vars_stack.append(set())
	lenv = node.local_scope
	node.declare_arguments(lenv)

	# @cython.locals(...)
	for var, type_node in node.directive_locals.items():
	if not lenv.lookup_here(var): # don't redeclare args
	type = type_node.analyse_as_type(lenv)
	if type:
	lenv.declare_var(var, type, type_node.pos)
	else:
	error(type_node.pos, "Not a type")

	if self._handle_fused(node):
	node = self._create_fused_function(env, node)
	else:
	node.body.analyse_declarations(lenv)
	self._handle_nogil_cleanup(lenv, node)
	self._super_visit_FuncDefNode(node)

	self.seen_vars_stack.pop()
	return node

	def visit_DefNode(self, node):
	node = self.visit_FuncDefNode(node)
	env = self.current_env()
	if isinstance(node, Nodes.DefNode) and node.is_wrapper:
	env = env.parent_scope
	if (not isinstance(node, Nodes.DefNode) or
	node.fused_py_func or node.is_generator_body or
	not node.needs_assignment_synthesis(env)):
	return node
	return [node, self._synthesize_assignment(node, env)]

	def visit_GeneratorBodyDefNode(self, node):
	return self.visit_FuncDefNode(node)

	def _synthesize_assignment(self, node, env):
	# Synthesize assignment node and put it right after defnode
	genv = env
	while genv.is_py_class_scope or genv.is_c_class_scope:
	genv = genv.outer_scope

	if genv.is_closure_scope:
	rhs = node.py_cfunc_node = ExprNodes.InnerFunctionNode(
	node.pos, def_node=node,
	pymethdef_cname=node.entry.pymethdef_cname,
	code_object=ExprNodes.CodeObjectNode(node))
	else:
	binding = self.current_directives.get('binding')
	rhs = ExprNodes.PyCFunctionNode.from_defnode(node, binding)
	node.code_object = rhs.code_object
	if node.is_generator:
	node.gbody.code_object = node.code_object

	if env.is_py_class_scope:
	rhs.binding = True

	node.is_cyfunction = rhs.binding
	return self._create_assignment(node, rhs, env)

	def _create_assignment(self, def_node, rhs, env):
	if def_node.decorators:
	for decorator in def_node.decorators[::-1]:
	rhs = ExprNodes.SimpleCallNode(
	decorator.pos,
	function = decorator.decorator,
	args = [rhs])
	def_node.decorators = None

	assmt = Nodes.SingleAssignmentNode(
	def_node.pos,
	lhs=ExprNodes.NameNode(def_node.pos, name=def_node.name),
	rhs=rhs)
	assmt.analyse_declarations(env)
	return assmt

	def visit_ScopedExprNode(self, node):
	env = self.current_env()
	node.analyse_declarations(env)
	# the node may or may not have a local scope
	if node.has_local_scope:
	self.seen_vars_stack.append(set(self.seen_vars_stack[-1]))
	self.enter_scope(node, node.expr_scope)
	node.analyse_scoped_declarations(node.expr_scope)
	self.visitchildren(node)
	self.exit_scope()
	self.seen_vars_stack.pop()
	else:
	node.analyse_scoped_declarations(env)
	self.visitchildren(node)
	return node

	def visit_TempResultFromStatNode(self, node):
	self.visitchildren(node)
	node.analyse_declarations(self.current_env())
	return node

	def visit_CppClassNode(self, node):
	if node.visibility == 'extern':
	return None
	else:
	return self.visit_ClassDefNode(node)

	def visit_CStructOrUnionDefNode(self, node):
	# Create a wrapper node if needed.
	# We want to use the struct type information (so it can't happen
	# before this phase) but also create new objects to be declared
	# (so it can't happen later).
	# Note that we don't return the original node, as it is
	# never used after this phase.
	if True: # private (default)
	return None

	self_value = ExprNodes.AttributeNode(
	pos = node.pos,
	obj = ExprNodes.NameNode(pos=node.pos, name=u"self"),
	attribute = EncodedString(u"value"))
	var_entries = node.entry.type.scope.var_entries
	attributes = []
	for entry in var_entries:
	attributes.append(ExprNodes.AttributeNode(pos = entry.pos,
	obj = self_value,
	attribute = entry.name))
	# __init__ assignments
	init_assignments = []
	for entry, attr in zip(var_entries, attributes):
	# TODO: branch on visibility
	init_assignments.append(self.init_assignment.substitute({
	u"VALUE": ExprNodes.NameNode(entry.pos, name = entry.name),
	u"ATTR": attr,
	}, pos = entry.pos))

	# create the class
	str_format = u"%s(%s)" % (node.entry.type.name, ("%s, " * len(attributes))[:-2])
	wrapper_class = self.struct_or_union_wrapper.substitute({
	u"INIT_ASSIGNMENTS": Nodes.StatListNode(node.pos, stats = init_assignments),
	u"IS_UNION": ExprNodes.BoolNode(node.pos, value = not node.entry.type.is_struct),
	u"MEMBER_TUPLE": ExprNodes.TupleNode(node.pos, args=attributes),
	u"STR_FORMAT": ExprNodes.StringNode(node.pos, value = EncodedString(str_format)),
	u"REPR_FORMAT": ExprNodes.StringNode(node.pos, value = EncodedString(str_format.replace("%s", "%r"))),
	}, pos = node.pos).stats[0]
	wrapper_class.class_name = node.name
	wrapper_class.shadow = True
	class_body = wrapper_class.body.stats

	# fix value type
	assert isinstance(class_body[0].base_type, Nodes.CSimpleBaseTypeNode)
	class_body[0].base_type.name = node.name

	# fix __init__ arguments
	init_method = class_body[1]
	assert isinstance(init_method, Nodes.DefNode) and init_method.name == '__init__'
	arg_template = init_method.args[1]
	if not node.entry.type.is_struct:
	arg_template.kw_only = True
	del init_method.args[1]
	for entry, attr in zip(var_entries, attributes):
	arg = copy.deepcopy(arg_template)
	arg.declarator.name = entry.name
	init_method.args.append(arg)

	# setters/getters
	for entry, attr in zip(var_entries, attributes):
	# TODO: branch on visibility
	if entry.type.is_pyobject:
	template = self.basic_pyobject_property
	else:
	template = self.basic_property
	property = template.substitute({
	u"ATTR": attr,
	}, pos = entry.pos).stats[0]
	property.name = entry.name
	wrapper_class.body.stats.append(property)

	wrapper_class.analyse_declarations(self.current_env())
	return self.visit_CClassDefNode(wrapper_class)

	# Some nodes are no longer needed after declaration
	# analysis and can be dropped. The analysis was performed
	# on these nodes in a separate recursive process from the
	# enclosing function or module, so we can simply drop them.
	def visit_CDeclaratorNode(self, node):
	# necessary to ensure that all CNameDeclaratorNodes are visited.
	self.visitchildren(node)
	return node

	def visit_CTypeDefNode(self, node):
	return node

	def visit_CBaseTypeNode(self, node):
	return None

	def visit_CEnumDefNode(self, node):
	if node.visibility == 'public':
	return node
	else:
	return None

	def visit_CNameDeclaratorNode(self, node):
	if node.name in self.seen_vars_stack[-1]:
	entry = self.current_env().lookup(node.name)
	if (entry is None or entry.visibility != 'extern'
	and not entry.scope.is_c_class_scope):
	warning(node.pos, "cdef variable '%s' declared after it is used" % node.name, 2)
	self.visitchildren(node)
	return node

	def visit_CVarDefNode(self, node):
	# to ensure all CNameDeclaratorNodes are visited.
	self.visitchildren(node)
	return None

	def visit_CnameDecoratorNode(self, node):
	child_node = self.visit(node.node)
	if not child_node:
	return None
	if type(child_node) is list: # Assignment synthesized
	node.child_node = child_node[0]
	return [node] + child_node[1:]
	node.node = child_node
	return node

	def create_Property(self, entry):
	if entry.visibility == 'public':
	if entry.type.is_pyobject:
	template = self.basic_pyobject_property
	else:
	template = self.basic_property
	elif entry.visibility == 'readonly':
	template = self.basic_property_ro
	property = template.substitute({
	u"ATTR": ExprNodes.AttributeNode(pos=entry.pos,
	obj=ExprNodes.NameNode(pos=entry.pos, name="self"),
	attribute=entry.name),
	}, pos=entry.pos).stats[0]
	property.name = entry.name
	property.doc = entry.doc
	return property


	def _calculate_pickle_checksums(member_names):
	# Cython 0.x used MD5 for the checksum, which a few Python installations remove for security reasons.
	# SHA-256 should be ok for years to come, but early Cython 3.0 alpha releases used SHA-1,
	# which may not be.
	member_names_string = ' '.join(member_names).encode('utf-8')
	hash_kwargs = {'usedforsecurity': False} if sys.version_info >= (3, 9) else {}
	checksums = []
	for algo_name in ['md5', 'sha256', 'sha1']:
	try:
	mkchecksum = getattr(hashlib, algo_name)
	checksum = mkchecksum(member_names_string, **hash_kwargs).hexdigest()
	except (AttributeError, ValueError):
	# The algorithm (i.e. MD5) might not be there at all, or might be blocked at runtime.
	continue
	checksums.append('0x' + checksum[:7])
	return checksums


	class CalculateQualifiedNamesTransform(EnvTransform):
	"""
	Calculate and store the '__qualname__' and the global
	module name on some nodes.
	"""
	def visit_ModuleNode(self, node):
	self.module_name = self.global_scope().qualified_name
	self.qualified_name = []
	_super = super(CalculateQualifiedNamesTransform, self)
	self._super_visit_FuncDefNode = _super.visit_FuncDefNode
	self._super_visit_ClassDefNode = _super.visit_ClassDefNode
	self.visitchildren(node)
	return node

	def _set_qualname(self, node, name=None):
	if name:
	qualname = self.qualified_name[:]
	qualname.append(name)
	else:
	qualname = self.qualified_name
	node.qualname = EncodedString('.'.join(qualname))
	node.module_name = self.module_name

	def _append_entry(self, entry):
	if entry.is_pyglobal and not entry.is_pyclass_attr:
	self.qualified_name = [entry.name]
	else:
	self.qualified_name.append(entry.name)

	def visit_ClassNode(self, node):
	self._set_qualname(node, node.name)
	self.visitchildren(node)
	return node

	def visit_PyClassNamespaceNode(self, node):
	# class name was already added by parent node
	self._set_qualname(node)
	self.visitchildren(node)
	return node

	def visit_PyCFunctionNode(self, node):
	orig_qualified_name = self.qualified_name[:]
	if node.def_node.is_wrapper and self.qualified_name and self.qualified_name[-1] == '<locals>':
	self.qualified_name.pop()
	self._set_qualname(node)
	else:
	self._set_qualname(node, node.def_node.name)
	self.visitchildren(node)
	self.qualified_name = orig_qualified_name
	return node

	def visit_DefNode(self, node):
	if node.is_wrapper and self.qualified_name:
	assert self.qualified_name[-1] == '<locals>', self.qualified_name
	orig_qualified_name = self.qualified_name[:]
	self.qualified_name.pop()
	self._set_qualname(node)
	self._super_visit_FuncDefNode(node)
	self.qualified_name = orig_qualified_name
	else:
	self._set_qualname(node, node.name)
	self.visit_FuncDefNode(node)
	return node

	def visit_FuncDefNode(self, node):
	orig_qualified_name = self.qualified_name[:]
	if getattr(node, 'name', None) == '<lambda>':
	self.qualified_name.append('<lambda>')
	else:
	self._append_entry(node.entry)
	self.qualified_name.append('<locals>')
	self._super_visit_FuncDefNode(node)
	self.qualified_name = orig_qualified_name
	return node

	def visit_ClassDefNode(self, node):
	orig_qualified_name = self.qualified_name[:]
	entry = (getattr(node, 'entry', None) or # PyClass
	self.current_env().lookup_here(node.name)) # CClass
	self._append_entry(entry)
	self._super_visit_ClassDefNode(node)
	self.qualified_name = orig_qualified_name
	return node


	class AnalyseExpressionsTransform(CythonTransform):

	def visit_ModuleNode(self, node):
	node.scope.infer_types()
	node.body = node.body.analyse_expressions(node.scope)
	self.visitchildren(node)
	return node

	def visit_FuncDefNode(self, node):
	node.local_scope.infer_types()
	node.body = node.body.analyse_expressions(node.local_scope)
	self.visitchildren(node)
	return node

	def visit_ScopedExprNode(self, node):
	if node.has_local_scope:
	node.expr_scope.infer_types()
	node = node.analyse_scoped_expressions(node.expr_scope)
	self.visitchildren(node)
	return node

	def visit_IndexNode(self, node):
	"""
	Replace index nodes used to specialize cdef functions with fused
	argument types with the Attribute- or NameNode referring to the
	function. We then need to copy over the specialization properties to
	the attribute or name node.

	Because the indexing might be a Python indexing operation on a fused
	function, or (usually) a Cython indexing operation, we need to
	re-analyse the types.
	"""
	self.visit_Node(node)
	if node.is_fused_index and not node.type.is_error:
	node = node.base
	return node


	class FindInvalidUseOfFusedTypes(CythonTransform):

	def visit_FuncDefNode(self, node):
	# Errors related to use in functions with fused args will already
	# have been detected
	if not node.has_fused_arguments:
	if not node.is_generator_body and node.return_type.is_fused:
	error(node.pos, "Return type is not specified as argument type")
	else:
	self.visitchildren(node)

	return node

	def visit_ExprNode(self, node):
	if node.type and node.type.is_fused:
	error(node.pos, "Invalid use of fused types, type cannot be specialized")
	else:
	self.visitchildren(node)

	return node


	class ExpandInplaceOperators(EnvTransform):

	def visit_InPlaceAssignmentNode(self, node):
	lhs = node.lhs
	rhs = node.rhs
	if lhs.type.is_cpp_class:
	# No getting around this exact operator here.
	return node
	if isinstance(lhs, ExprNodes.BufferIndexNode):
	# There is code to handle this case in InPlaceAssignmentNode
	return node

	env = self.current_env()
	def side_effect_free_reference(node, setting=False):
	if node.is_name:
	return node, []
	elif node.type.is_pyobject and not setting:
	node = LetRefNode(node)
	return node, [node]
	elif node.is_subscript:
	base, temps = side_effect_free_reference(node.base)
	index = LetRefNode(node.index)
	return ExprNodes.IndexNode(node.pos, base=base, index=index), temps + [index]
	elif node.is_attribute:
	obj, temps = side_effect_free_reference(node.obj)
	return ExprNodes.AttributeNode(node.pos, obj=obj, attribute=node.attribute), temps
	elif isinstance(node, ExprNodes.BufferIndexNode):
	raise ValueError("Don't allow things like attributes of buffer indexing operations")
	else:
	node = LetRefNode(node)
	return node, [node]
	try:
	lhs, let_ref_nodes = side_effect_free_reference(lhs, setting=True)
	except ValueError:
	return node
	dup = lhs.__class__(**lhs.__dict__)
	binop = ExprNodes.binop_node(node.pos,
	operator = node.operator,
	operand1 = dup,
	operand2 = rhs,
	inplace=True)
	# Manually analyse types for new node.
	lhs.analyse_target_types(env)
	dup.analyse_types(env)
	binop.analyse_operation(env)
	node = Nodes.SingleAssignmentNode(
	node.pos,
	lhs = lhs,
	rhs=binop.coerce_to(lhs.type, env))
	# Use LetRefNode to avoid side effects.
	let_ref_nodes.reverse()
	for t in let_ref_nodes:
	node = LetNode(t, node)
	return node

	def visit_ExprNode(self, node):
	# In-place assignments can't happen within an expression.
	return node


	class AdjustDefByDirectives(CythonTransform, SkipDeclarations):
	"""
	Adjust function and class definitions by the decorator directives:

	@cython.cfunc
	@cython.cclass
	@cython.ccall
	@cython.inline
	@cython.nogil
	"""

	def visit_ModuleNode(self, node):
	self.directives = node.directives
	self.in_py_class = False
	self.visitchildren(node)
	return node

	def visit_CompilerDirectivesNode(self, node):
	old_directives = self.directives
	self.directives = node.directives
	self.visitchildren(node)
	self.directives = old_directives
	return node

	def visit_DefNode(self, node):
	modifiers = []
	if 'inline' in self.directives:
	modifiers.append('inline')
	nogil = self.directives.get('nogil')
	except_val = self.directives.get('exceptval')
	return_type_node = self.directives.get('returns')
	if return_type_node is None and self.directives['annotation_typing']:
	return_type_node = node.return_type_annotation
	# for Python anntations, prefer safe exception handling by default
	if return_type_node is not None and except_val is None:
	except_val = (None, True) # except *
	elif except_val is None:
	# backward compatible default: no exception check
	except_val = (None, False)
	if 'ccall' in self.directives:
	node = node.as_cfunction(
	overridable=True, modifiers=modifiers, nogil=nogil,
	returns=return_type_node, except_val=except_val)
	return self.visit(node)
	if 'cfunc' in self.directives:
	if self.in_py_class:
	error(node.pos, "cfunc directive is not allowed here")
	else:
	node = node.as_cfunction(
	overridable=False, modifiers=modifiers, nogil=nogil,
	returns=return_type_node, except_val=except_val)
	return self.visit(node)
	if 'inline' in modifiers:
	error(node.pos, "Python functions cannot be declared 'inline'")
	if nogil:
	# TODO: turn this into a "with gil" declaration.
	error(node.pos, "Python functions cannot be declared 'nogil'")
	self.visitchildren(node)
	return node

	def visit_LambdaNode(self, node):
	# No directives should modify lambdas or generator expressions (and also nothing in them).
	return node

	def visit_PyClassDefNode(self, node):
	if 'cclass' in self.directives:
	node = node.as_cclass()
	return self.visit(node)
	else:
	old_in_pyclass = self.in_py_class
	self.in_py_class = True
	self.visitchildren(node)
	self.in_py_class = old_in_pyclass
	return node

	def visit_CClassDefNode(self, node):
	old_in_pyclass = self.in_py_class
	self.in_py_class = False
	self.visitchildren(node)
	self.in_py_class = old_in_pyclass
	return node


	class AlignFunctionDefinitions(CythonTransform):
	"""
	This class takes the signatures from a .pxd file and applies them to
	the def methods in a .py file.
	"""

	def visit_ModuleNode(self, node):
	self.scope = node.scope
	self.directives = node.directives
	self.imported_names = set() # hack, see visit_FromImportStatNode()
	self.visitchildren(node)
	return node

	def visit_PyClassDefNode(self, node):
	pxd_def = self.scope.lookup(node.name)
	if pxd_def:
	if pxd_def.is_cclass:
	return self.visit_CClassDefNode(node.as_cclass(), pxd_def)
	elif not pxd_def.scope or not pxd_def.scope.is_builtin_scope:
	error(node.pos, "'%s' redeclared" % node.name)
	if pxd_def.pos:
	error(pxd_def.pos, "previous declaration here")
	return None
	return node

	def visit_CClassDefNode(self, node, pxd_def=None):
	if pxd_def is None:
	pxd_def = self.scope.lookup(node.class_name)
	if pxd_def:
	if not pxd_def.defined_in_pxd:
	return node
	outer_scope = self.scope
	self.scope = pxd_def.type.scope
	self.visitchildren(node)
	if pxd_def:
	self.scope = outer_scope
	return node

	def visit_DefNode(self, node):
	pxd_def = self.scope.lookup(node.name)
	if pxd_def and (not pxd_def.scope or not pxd_def.scope.is_builtin_scope):
	if not pxd_def.is_cfunction:
	error(node.pos, "'%s' redeclared" % node.name)
	if pxd_def.pos:
	error(pxd_def.pos, "previous declaration here")
	return None
	node = node.as_cfunction(pxd_def)
	elif (self.scope.is_module_scope and self.directives['auto_cpdef']
	and not node.name in self.imported_names
	and node.is_cdef_func_compatible()):
	# FIXME: cpdef-ing should be done in analyse_declarations()
	node = node.as_cfunction(scope=self.scope)
	# Enable this when nested cdef functions are allowed.
	# self.visitchildren(node)
	return node

	def visit_FromImportStatNode(self, node):
	# hack to prevent conditional import fallback functions from
	# being cdpef-ed (global Python variables currently conflict
	# with imports)
	if self.scope.is_module_scope:
	for name, _ in node.items:
	self.imported_names.add(name)
	return node

	def visit_ExprNode(self, node):
	# ignore lambdas and everything else that appears in expressions
	return node


	class RemoveUnreachableCode(CythonTransform):
	def visit_StatListNode(self, node):
	if not self.current_directives['remove_unreachable']:
	return node
	self.visitchildren(node)
	for idx, stat in enumerate(node.stats):
	idx += 1
	if stat.is_terminator:
	if idx < len(node.stats):
	if self.current_directives['warn.unreachable']:
	warning(node.stats[idx].pos, "Unreachable code", 2)
	node.stats = node.stats[:idx]
	node.is_terminator = True
	break
	return node

	def visit_IfClauseNode(self, node):
	self.visitchildren(node)
	if node.body.is_terminator:
	node.is_terminator = True
	return node

	def visit_IfStatNode(self, node):
	self.visitchildren(node)
	if node.else_clause and node.else_clause.is_terminator:
	for clause in node.if_clauses:
	if not clause.is_terminator:
	break
	else:
	node.is_terminator = True
	return node

	def visit_TryExceptStatNode(self, node):
	self.visitchildren(node)
	if node.body.is_terminator and node.else_clause:
	if self.current_directives['warn.unreachable']:
	warning(node.else_clause.pos, "Unreachable code", 2)
	node.else_clause = None
	return node

	def visit_TryFinallyStatNode(self, node):
	self.visitchildren(node)
	if node.finally_clause.is_terminator:
	node.is_terminator = True
	return node


	class YieldNodeCollector(TreeVisitor):

	def __init__(self):
	super(YieldNodeCollector, self).__init__()
	self.yields = []
	self.returns = []
	self.finallys = []
	self.excepts = []
	self.has_return_value = False
	self.has_yield = False
	self.has_await = False

	def visit_Node(self, node):
	self.visitchildren(node)

	def visit_YieldExprNode(self, node):
	self.yields.append(node)
	self.has_yield = True
	self.visitchildren(node)

	def visit_AwaitExprNode(self, node):
	self.yields.append(node)
	self.has_await = True
	self.visitchildren(node)

	def visit_ReturnStatNode(self, node):
	self.visitchildren(node)
	if node.value:
	self.has_return_value = True
	self.returns.append(node)

	def visit_TryFinallyStatNode(self, node):
	self.visitchildren(node)
	self.finallys.append(node)

	def visit_TryExceptStatNode(self, node):
	self.visitchildren(node)
	self.excepts.append(node)

	def visit_ClassDefNode(self, node):
	pass

	def visit_FuncDefNode(self, node):
	pass

	def visit_LambdaNode(self, node):
	pass

	def visit_GeneratorExpressionNode(self, node):
	pass

	def visit_CArgDeclNode(self, node):
	# do not look into annotations
	# FIXME: support (yield) in default arguments (currently crashes)
	pass


	class MarkClosureVisitor(CythonTransform):

	def visit_ModuleNode(self, node):
	self.needs_closure = False
	self.visitchildren(node)
	return node

	def visit_FuncDefNode(self, node):
	self.needs_closure = False
	self.visitchildren(node)
	node.needs_closure = self.needs_closure
	self.needs_closure = True

	collector = YieldNodeCollector()
	collector.visitchildren(node)

	if node.is_async_def:
	coroutine_type = Nodes.AsyncDefNode
	if collector.has_yield:
	coroutine_type = Nodes.AsyncGenNode
	for yield_expr in collector.yields + collector.returns:
	yield_expr.in_async_gen = True
	elif self.current_directives['iterable_coroutine']:
	coroutine_type = Nodes.IterableAsyncDefNode
	elif collector.has_await:
	found = next(y for y in collector.yields if y.is_await)
	error(found.pos, "'await' not allowed in generators (use 'yield')")
	return node
	elif collector.has_yield:
	coroutine_type = Nodes.GeneratorDefNode
	else:
	return node

	for i, yield_expr in enumerate(collector.yields, 1):
	yield_expr.label_num = i
	for retnode in collector.returns + collector.finallys + collector.excepts:
	retnode.in_generator = True

	gbody = Nodes.GeneratorBodyDefNode(
	pos=node.pos, name=node.name, body=node.body,
	is_async_gen_body=node.is_async_def and collector.has_yield)
	coroutine = coroutine_type(
	pos=node.pos, name=node.name, args=node.args,
	star_arg=node.star_arg, starstar_arg=node.starstar_arg,
	doc=node.doc, decorators=node.decorators,
	gbody=gbody, lambda_name=node.lambda_name,
	return_type_annotation=node.return_type_annotation)
	return coroutine

	def visit_CFuncDefNode(self, node):
	self.needs_closure = False
	self.visitchildren(node)
	node.needs_closure = self.needs_closure
	self.needs_closure = True
	if node.needs_closure and node.overridable:
	error(node.pos, "closures inside cpdef functions not yet supported")
	return node

	def visit_LambdaNode(self, node):
	self.needs_closure = False
	self.visitchildren(node)
	node.needs_closure = self.needs_closure
	self.needs_closure = True
	return node

	def visit_ClassDefNode(self, node):
	self.visitchildren(node)
	self.needs_closure = True
	return node


	class CreateClosureClasses(CythonTransform):
	# Output closure classes in module scope for all functions
	# that really need it.

	def __init__(self, context):
	super(CreateClosureClasses, self).__init__(context)
	self.path = []
	self.in_lambda = False

	def visit_ModuleNode(self, node):
	self.module_scope = node.scope
	self.visitchildren(node)
	return node

	def find_entries_used_in_closures(self, node):
	from_closure = []
	in_closure = []
	for scope in node.local_scope.iter_local_scopes():
	for name, entry in scope.entries.items():
	if not name:
	continue
	if entry.from_closure:
	from_closure.append((name, entry))
	elif entry.in_closure:
	in_closure.append((name, entry))
	return from_closure, in_closure

	def create_class_from_scope(self, node, target_module_scope, inner_node=None):
	# move local variables into closure
	if node.is_generator:
	for scope in node.local_scope.iter_local_scopes():
	for entry in scope.entries.values():
	if not (entry.from_closure or entry.is_pyglobal or entry.is_cglobal):
	entry.in_closure = True

	from_closure, in_closure = self.find_entries_used_in_closures(node)
	in_closure.sort()

	# Now from the beginning
	node.needs_closure = False
	node.needs_outer_scope = False

	func_scope = node.local_scope
	cscope = node.entry.scope
	while cscope.is_py_class_scope or cscope.is_c_class_scope:
	cscope = cscope.outer_scope

	if not from_closure and (self.path or inner_node):
	if not inner_node:
	if not node.py_cfunc_node:
	raise InternalError("DefNode does not have assignment node")
	inner_node = node.py_cfunc_node
	inner_node.needs_self_code = False
	node.needs_outer_scope = False

	if node.is_generator:
	pass
	elif not in_closure and not from_closure:
	return
	elif not in_closure:
	func_scope.is_passthrough = True
	func_scope.scope_class = cscope.scope_class
	node.needs_outer_scope = True
	return

	# entry.cname can contain periods (eg. a derived C method of a class).
	# We want to use the cname as part of a C struct name, so we replace
	# periods with double underscores.
	as_name = '%s_%s' % (
	target_module_scope.next_id(Naming.closure_class_prefix),
	node.entry.cname.replace('.','__'))

	entry = target_module_scope.declare_c_class(
	name=as_name, pos=node.pos, defining=True,
	implementing=True)
	entry.type.is_final_type = True

	func_scope.scope_class = entry
	class_scope = entry.type.scope
	class_scope.is_internal = True
	class_scope.is_closure_class_scope = True
	if node.is_async_def or node.is_generator:
	# Generators need their closure intact during cleanup as they resume to handle GeneratorExit
	class_scope.directives['no_gc_clear'] = True
	if Options.closure_freelist_size:
	class_scope.directives['freelist'] = Options.closure_freelist_size

	if from_closure:
	assert cscope.is_closure_scope
	class_scope.declare_var(pos=node.pos,
	name=Naming.outer_scope_cname,
	cname=Naming.outer_scope_cname,
	type=cscope.scope_class.type,
	is_cdef=True)
	node.needs_outer_scope = True
	for name, entry in in_closure:
	closure_entry = class_scope.declare_var(
	pos=entry.pos,
	name=entry.name if not entry.in_subscope else None,
	cname=entry.cname,
	type=entry.type,
	is_cdef=True)
	if entry.is_declared_generic:
	closure_entry.is_declared_generic = 1
	node.needs_closure = True
	# Do it here because other classes are already checked
	target_module_scope.check_c_class(func_scope.scope_class)

	def visit_LambdaNode(self, node):
	if not isinstance(node.def_node, Nodes.DefNode):
	# fused function, an error has been previously issued
	return node

	was_in_lambda = self.in_lambda
	self.in_lambda = True
	self.create_class_from_scope(node.def_node, self.module_scope, node)
	self.visitchildren(node)
	self.in_lambda = was_in_lambda
	return node

	def visit_FuncDefNode(self, node):
	if self.in_lambda:
	self.visitchildren(node)
	return node
	if node.needs_closure or self.path:
	self.create_class_from_scope(node, self.module_scope)
	self.path.append(node)
	self.visitchildren(node)
	self.path.pop()
	return node

	def visit_GeneratorBodyDefNode(self, node):
	self.visitchildren(node)
	return node

	def visit_CFuncDefNode(self, node):
	if not node.overridable:
	return self.visit_FuncDefNode(node)
	else:
	self.visitchildren(node)
	return node


	class InjectGilHandling(VisitorTransform, SkipDeclarations):
	"""
	Allow certain Python operations inside of nogil blocks by implicitly acquiring the GIL.

	Must run before the AnalyseDeclarationsTransform to make sure the GILStatNodes get
	set up, parallel sections know that the GIL is acquired inside of them, etc.
	"""
	def __call__(self, root):
	self.nogil = False
	return super(InjectGilHandling, self).__call__(root)

	# special node handling

	def visit_RaiseStatNode(self, node):
	"""Allow raising exceptions in nogil sections by wrapping them in a 'with gil' block."""
	if self.nogil:
	node = Nodes.GILStatNode(node.pos, state='gil', body=node)
	return node

	# further candidates:
	# def visit_AssertStatNode(self, node):
	# def visit_ReraiseStatNode(self, node):

	# nogil tracking

	def visit_GILStatNode(self, node):
	was_nogil = self.nogil
	self.nogil = (node.state == 'nogil')
	self.visitchildren(node)
	self.nogil = was_nogil
	return node

	def visit_CFuncDefNode(self, node):
	was_nogil = self.nogil
	if isinstance(node.declarator, Nodes.CFuncDeclaratorNode):
	self.nogil = node.declarator.nogil and not node.declarator.with_gil
	self.visitchildren(node)
	self.nogil = was_nogil
	return node

	def visit_ParallelRangeNode(self, node):
	was_nogil = self.nogil
	self.nogil = node.nogil
	self.visitchildren(node)
	self.nogil = was_nogil
	return node

	def visit_ExprNode(self, node):
	# No special GIL handling inside of expressions for now.
	return node

	visit_Node = VisitorTransform.recurse_to_children


	class GilCheck(VisitorTransform):
	"""
	Call `node.gil_check(env)` on each node to make sure we hold the
	GIL when we need it. Raise an error when on Python operations
	inside a `nogil` environment.

	Additionally, raise exceptions for closely nested with gil or with nogil
	statements. The latter would abort Python.
	"""

	def __call__(self, root):
	self.env_stack = [root.scope]
	self.nogil = False

	# True for 'cdef func() nogil:' functions, as the GIL may be held while
	# calling this function (thus contained 'nogil' blocks may be valid).
	self.nogil_declarator_only = False
	return super(GilCheck, self).__call__(root)

	def _visit_scoped_children(self, node, gil_state):
	was_nogil = self.nogil
	outer_attrs = node.outer_attrs
	if outer_attrs and len(self.env_stack) > 1:
	self.nogil = self.env_stack[-2].nogil
	self.visitchildren(node, outer_attrs)

	self.nogil = gil_state
	self.visitchildren(node, attrs=None, exclude=outer_attrs)
	self.nogil = was_nogil

	def visit_FuncDefNode(self, node):
	self.env_stack.append(node.local_scope)
	inner_nogil = node.local_scope.nogil

	if inner_nogil:
	self.nogil_declarator_only = True

	if inner_nogil and node.nogil_check:
	node.nogil_check(node.local_scope)

	self._visit_scoped_children(node, inner_nogil)

	# This cannot be nested, so it doesn't need backup/restore
	self.nogil_declarator_only = False

	self.env_stack.pop()
	return node

	def visit_GILStatNode(self, node):
	if self.nogil and node.nogil_check:
	node.nogil_check()

	was_nogil = self.nogil
	is_nogil = (node.state == 'nogil')

	if was_nogil == is_nogil and not self.nogil_declarator_only:
	if not was_nogil:
	error(node.pos, "Trying to acquire the GIL while it is "
	"already held.")
	else:
	error(node.pos, "Trying to release the GIL while it was "
	"previously released.")

	if isinstance(node.finally_clause, Nodes.StatListNode):
	# The finally clause of the GILStatNode is a GILExitNode,
	# which is wrapped in a StatListNode. Just unpack that.
	node.finally_clause, = node.finally_clause.stats

	self._visit_scoped_children(node, is_nogil)
	return node

	def visit_ParallelRangeNode(self, node):
	if node.nogil:
	node.nogil = False
	node = Nodes.GILStatNode(node.pos, state='nogil', body=node)
	return self.visit_GILStatNode(node)

	if not self.nogil:
	error(node.pos, "prange() can only be used without the GIL")
	# Forget about any GIL-related errors that may occur in the body
	return None

	node.nogil_check(self.env_stack[-1])
	self.visitchildren(node)
	return node

	def visit_ParallelWithBlockNode(self, node):
	if not self.nogil:
	error(node.pos, "The parallel section may only be used without "
	"the GIL")
	return None

	if node.nogil_check:
	# It does not currently implement this, but test for it anyway to
	# avoid potential future surprises
	node.nogil_check(self.env_stack[-1])

	self.visitchildren(node)
	return node

	def visit_TryFinallyStatNode(self, node):
	"""
	Take care of try/finally statements in nogil code sections.
	"""
	if not self.nogil or isinstance(node, Nodes.GILStatNode):
	return self.visit_Node(node)

	node.nogil_check = None
	node.is_try_finally_in_nogil = True
	self.visitchildren(node)
	return node

	def visit_Node(self, node):
	if self.env_stack and self.nogil and node.nogil_check:
	node.nogil_check(self.env_stack[-1])
	if node.outer_attrs:
	self._visit_scoped_children(node, self.nogil)
	else:
	self.visitchildren(node)
	if self.nogil:
	node.in_nogil_context = True
	return node


	class TransformBuiltinMethods(EnvTransform):
	"""
	Replace Cython's own cython.* builtins by the corresponding tree nodes.
	"""

	def visit_SingleAssignmentNode(self, node):
	if node.declaration_only:
	return None
	else:
	self.visitchildren(node)
	return node

	def visit_AttributeNode(self, node):
	self.visitchildren(node)
	return self.visit_cython_attribute(node)

	def visit_NameNode(self, node):
	return self.visit_cython_attribute(node)

	def visit_cython_attribute(self, node):
	attribute = node.as_cython_attribute()
	if attribute:
	if attribute == u'compiled':
	node = ExprNodes.BoolNode(node.pos, value=True)
	elif attribute == u'__version__':
	from .. import __version__ as version
	node = ExprNodes.StringNode(node.pos, value=EncodedString(version))
	elif attribute == u'NULL':
	node = ExprNodes.NullNode(node.pos)
	elif attribute in (u'set', u'frozenset', u'staticmethod'):
	node = ExprNodes.NameNode(node.pos, name=EncodedString(attribute),
	entry=self.current_env().builtin_scope().lookup_here(attribute))
	elif PyrexTypes.parse_basic_type(attribute):
	pass
	elif self.context.cython_scope.lookup_qualified_name(attribute):
	pass
	else:
	error(node.pos, u"'%s' not a valid cython attribute or is being used incorrectly" % attribute)
	return node

	def visit_ExecStatNode(self, node):
	lenv = self.current_env()
	self.visitchildren(node)
	if len(node.args) == 1:
	node.args.append(ExprNodes.GlobalsExprNode(node.pos))
	if not lenv.is_module_scope:
	node.args.append(
	ExprNodes.LocalsExprNode(
	node.pos, self.current_scope_node(), lenv))
	return node

	def _inject_locals(self, node, func_name):
	# locals()/dir()/vars() builtins
	lenv = self.current_env()
	entry = lenv.lookup_here(func_name)
	if entry:
	# not the builtin
	return node
	pos = node.pos
	if func_name in ('locals', 'vars'):
	if func_name == 'locals' and len(node.args) > 0:
	error(self.pos, "Builtin 'locals()' called with wrong number of args, expected 0, got %d"
	% len(node.args))
	return node
	elif func_name == 'vars':
	if len(node.args) > 1:
	error(self.pos, "Builtin 'vars()' called with wrong number of args, expected 0-1, got %d"
	% len(node.args))
	if len(node.args) > 0:
	return node # nothing to do
	return ExprNodes.LocalsExprNode(pos, self.current_scope_node(), lenv)
	else: # dir()
	if len(node.args) > 1:
	error(self.pos, "Builtin 'dir()' called with wrong number of args, expected 0-1, got %d"
	% len(node.args))
	if len(node.args) > 0:
	# optimised in Builtin.py
	return node
	if lenv.is_py_class_scope or lenv.is_module_scope:
	if lenv.is_py_class_scope:
	pyclass = self.current_scope_node()
	locals_dict = ExprNodes.CloneNode(pyclass.dict)
	else:
	locals_dict = ExprNodes.GlobalsExprNode(pos)
	return ExprNodes.SortedDictKeysNode(locals_dict)
	local_names = sorted(var.name for var in lenv.entries.values() if var.name)
	items = [ExprNodes.IdentifierStringNode(pos, value=var)
	for var in local_names]
	return ExprNodes.ListNode(pos, args=items)

	def visit_PrimaryCmpNode(self, node):
	# special case: for in/not-in test, we do not need to sort locals()
	self.visitchildren(node)
	if node.operator in 'not_in': # in/not_in
	if isinstance(node.operand2, ExprNodes.SortedDictKeysNode):
	arg = node.operand2.arg
	if isinstance(arg, ExprNodes.NoneCheckNode):
	arg = arg.arg
	node.operand2 = arg
	return node

	def visit_CascadedCmpNode(self, node):
	return self.visit_PrimaryCmpNode(node)

	def _inject_eval(self, node, func_name):
	lenv = self.current_env()
	entry = lenv.lookup_here(func_name)
	if entry or len(node.args) != 1:
	return node
	# Inject globals and locals
	node.args.append(ExprNodes.GlobalsExprNode(node.pos))
	if not lenv.is_module_scope:
	node.args.append(
	ExprNodes.LocalsExprNode(
	node.pos, self.current_scope_node(), lenv))
	return node

	def _inject_super(self, node, func_name):
	lenv = self.current_env()
	entry = lenv.lookup_here(func_name)
	if entry or node.args:
	return node
	# Inject no-args super
	def_node = self.current_scope_node()
	if (not isinstance(def_node, Nodes.DefNode) or not def_node.args or
	len(self.env_stack) < 2):
	return node
	class_node, class_scope = self.env_stack[-2]
	if class_scope.is_py_class_scope:
	def_node.requires_classobj = True
	class_node.class_cell.is_active = True
	node.args = [
	ExprNodes.ClassCellNode(
	node.pos, is_generator=def_node.is_generator),
	ExprNodes.NameNode(node.pos, name=def_node.args[0].name)
	]
	elif class_scope.is_c_class_scope:
	node.args = [
	ExprNodes.NameNode(
	node.pos, name=class_node.scope.name,
	entry=class_node.entry),
	ExprNodes.NameNode(node.pos, name=def_node.args[0].name)
	]
	return node

	def visit_SimpleCallNode(self, node):
	# cython.foo
	function = node.function.as_cython_attribute()
	if function:
	if function in InterpretCompilerDirectives.unop_method_nodes:
	if len(node.args) != 1:
	error(node.function.pos, u"%s() takes exactly one argument" % function)
	else:
	node = InterpretCompilerDirectives.unop_method_nodes[function](
	node.function.pos, operand=node.args[0])
	elif function in InterpretCompilerDirectives.binop_method_nodes:
	if len(node.args) != 2:
	error(node.function.pos, u"%s() takes exactly two arguments" % function)
	else:
	node = InterpretCompilerDirectives.binop_method_nodes[function](
	node.function.pos, operand1=node.args[0], operand2=node.args[1])
	elif function == u'cast':
	if len(node.args) != 2:
	error(node.function.pos,
	u"cast() takes exactly two arguments and an optional typecheck keyword")
	else:
	type = node.args[0].analyse_as_type(self.current_env())
	if type:
	node = ExprNodes.TypecastNode(
	node.function.pos, type=type, operand=node.args[1], typecheck=False)
	else:
	error(node.args[0].pos, "Not a type")
	elif function == u'sizeof':
	if len(node.args) != 1:
	error(node.function.pos, u"sizeof() takes exactly one argument")
	else:
	type = node.args[0].analyse_as_type(self.current_env())
	if type:
	node = ExprNodes.SizeofTypeNode(node.function.pos, arg_type=type)
	else:
	node = ExprNodes.SizeofVarNode(node.function.pos, operand=node.args[0])
	elif function == 'cmod':
	if len(node.args) != 2:
	error(node.function.pos, u"cmod() takes exactly two arguments")
	else:
	node = ExprNodes.binop_node(node.function.pos, '%', node.args[0], node.args[1])
	node.cdivision = True
	elif function == 'cdiv':
	if len(node.args) != 2:
	error(node.function.pos, u"cdiv() takes exactly two arguments")
	else:
	node = ExprNodes.binop_node(node.function.pos, '/', node.args[0], node.args[1])
	node.cdivision = True
	elif function == u'set':
	node.function = ExprNodes.NameNode(node.pos, name=EncodedString('set'))
	elif function == u'staticmethod':
	node.function = ExprNodes.NameNode(node.pos, name=EncodedString('staticmethod'))
	elif self.context.cython_scope.lookup_qualified_name(function):
	pass
	else:
	error(node.function.pos,
	u"'%s' not a valid cython language construct" % function)

	self.visitchildren(node)

	if isinstance(node, ExprNodes.SimpleCallNode) and node.function.is_name:
	func_name = node.function.name
	if func_name in ('dir', 'locals', 'vars'):
	return self._inject_locals(node, func_name)
	if func_name == 'eval':
	return self._inject_eval(node, func_name)
	if func_name == 'super':
	return self._inject_super(node, func_name)
	return node

	def visit_GeneralCallNode(self, node):
	function = node.function.as_cython_attribute()
	if function == u'cast':
	# NOTE: assuming simple tuple/dict nodes for positional_args and keyword_args
	args = node.positional_args.args
	kwargs = node.keyword_args.compile_time_value(None)
	if (len(args) != 2 or len(kwargs) > 1 or
	(len(kwargs) == 1 and 'typecheck' not in kwargs)):
	error(node.function.pos,
	u"cast() takes exactly two arguments and an optional typecheck keyword")
	else:
	type = args[0].analyse_as_type(self.current_env())
	if type:
	typecheck = kwargs.get('typecheck', False)
	node = ExprNodes.TypecastNode(
	node.function.pos, type=type, operand=args[1], typecheck=typecheck)
	else:
	error(args[0].pos, "Not a type")

	self.visitchildren(node)
	return node


	class ReplaceFusedTypeChecks(VisitorTransform):
	"""
	This is not a transform in the pipeline. It is invoked on the specific
	versions of a cdef function with fused argument types. It filters out any
	type branches that don't match. e.g.

	if fused_t is mytype:
	...
	elif fused_t in other_fused_type:
	...
	"""
	def __init__(self, local_scope):
	super(ReplaceFusedTypeChecks, self).__init__()
	self.local_scope = local_scope
	# defer the import until now to avoid circular import time dependencies
	from .Optimize import ConstantFolding
	self.transform = ConstantFolding(reevaluate=True)

	def visit_IfStatNode(self, node):
	"""
	Filters out any if clauses with false compile time type check
	expression.
	"""
	self.visitchildren(node)
	return self.transform(node)

	def visit_PrimaryCmpNode(self, node):
	with Errors.local_errors(ignore=True):
	type1 = node.operand1.analyse_as_type(self.local_scope)
	type2 = node.operand2.analyse_as_type(self.local_scope)

	if type1 and type2:
	false_node = ExprNodes.BoolNode(node.pos, value=False)
	true_node = ExprNodes.BoolNode(node.pos, value=True)

	type1 = self.specialize_type(type1, node.operand1.pos)
	op = node.operator

	if op in ('is', 'is_not', '==', '!='):
	type2 = self.specialize_type(type2, node.operand2.pos)

	is_same = type1.same_as(type2)
	eq = op in ('is', '==')

	if (is_same and eq) or (not is_same and not eq):
	return true_node

	elif op in ('in', 'not_in'):
	# We have to do an instance check directly, as operand2
	# needs to be a fused type and not a type with a subtype
	# that is fused. First unpack the typedef
	if isinstance(type2, PyrexTypes.CTypedefType):
	type2 = type2.typedef_base_type

	if type1.is_fused:
	error(node.operand1.pos, "Type is fused")
	elif not type2.is_fused:
	error(node.operand2.pos,
	"Can only use 'in' or 'not in' on a fused type")
	else:
	types = PyrexTypes.get_specialized_types(type2)

	for specialized_type in types:
	if type1.same_as(specialized_type):
	if op == 'in':
	return true_node
	else:
	return false_node

	if op == 'not_in':
	return true_node

	return false_node

	return node

	def specialize_type(self, type, pos):
	try:
	return type.specialize(self.local_scope.fused_to_specific)
	except KeyError:
	error(pos, "Type is not specific")
	return type

	def visit_Node(self, node):
	self.visitchildren(node)
	return node


	class DebugTransform(CythonTransform):
	"""
	Write debug information for this Cython module.
	"""

	def __init__(self, context, options, result):
	super(DebugTransform, self).__init__(context)
	self.visited = set()
	# our treebuilder and debug output writer
	# (see Cython.Debugger.debug_output.CythonDebugWriter)
	self.tb = self.context.gdb_debug_outputwriter
	#self.c_output_file = options.output_file
	self.c_output_file = result.c_file

	# Closure support, basically treat nested functions as if the AST were
	# never nested
	self.nested_funcdefs = []

	# tells visit_NameNode whether it should register step-into functions
	self.register_stepinto = False

	def visit_ModuleNode(self, node):
	self.tb.module_name = node.full_module_name
	attrs = dict(
	module_name=node.full_module_name,
	filename=node.pos[0].filename,
	c_filename=self.c_output_file)

	self.tb.start('Module', attrs)

	# serialize functions
	self.tb.start('Functions')
	# First, serialize functions normally...
	self.visitchildren(node)

	# ... then, serialize nested functions
	for nested_funcdef in self.nested_funcdefs:
	self.visit_FuncDefNode(nested_funcdef)

	self.register_stepinto = True
	self.serialize_modulenode_as_function(node)
	self.register_stepinto = False
	self.tb.end('Functions')

	# 2.3 compatibility. Serialize global variables
	self.tb.start('Globals')
	entries = {}

	for k, v in node.scope.entries.items():
	if (v.qualified_name not in self.visited and not
	v.name.startswith('__pyx_') and not
	v.type.is_cfunction and not
	v.type.is_extension_type):
	entries[k]= v

	self.serialize_local_variables(entries)
	self.tb.end('Globals')
	# self.tb.end('Module') # end Module after the line number mapping in
	# Cython.Compiler.ModuleNode.ModuleNode._serialize_lineno_map
	return node

	def visit_FuncDefNode(self, node):
	self.visited.add(node.local_scope.qualified_name)

	if getattr(node, 'is_wrapper', False):
	return node

	if self.register_stepinto:
	self.nested_funcdefs.append(node)
	return node

	# node.entry.visibility = 'extern'
	if node.py_func is None:
	pf_cname = ''
	else:
	pf_cname = node.py_func.entry.func_cname

	attrs = dict(
	name=node.entry.name or getattr(node, 'name', '<unknown>'),
	cname=node.entry.func_cname,
	pf_cname=pf_cname,
	qualified_name=node.local_scope.qualified_name,
	lineno=str(node.pos[1]))

	self.tb.start('Function', attrs=attrs)

	self.tb.start('Locals')
	self.serialize_local_variables(node.local_scope.entries)
	self.tb.end('Locals')

	self.tb.start('Arguments')
	for arg in node.local_scope.arg_entries:
	self.tb.start(arg.name)
	self.tb.end(arg.name)
	self.tb.end('Arguments')

	self.tb.start('StepIntoFunctions')
	self.register_stepinto = True
	self.visitchildren(node)
	self.register_stepinto = False
	self.tb.end('StepIntoFunctions')
	self.tb.end('Function')

	return node

	def visit_NameNode(self, node):
	if (self.register_stepinto and
	node.type is not None and
	node.type.is_cfunction and
	getattr(node, 'is_called', False) and
	node.entry.func_cname is not None):
	# don't check node.entry.in_cinclude, as 'cdef extern: ...'
	# declared functions are not 'in_cinclude'.
	# This means we will list called 'cdef' functions as
	# "step into functions", but this is not an issue as they will be
	# recognized as Cython functions anyway.
	attrs = dict(name=node.entry.func_cname)
	self.tb.start('StepIntoFunction', attrs=attrs)
	self.tb.end('StepIntoFunction')

	self.visitchildren(node)
	return node

	def serialize_modulenode_as_function(self, node):
	"""
	Serialize the module-level code as a function so the debugger will know
	it's a "relevant frame" and it will know where to set the breakpoint
	for 'break modulename'.
	"""
	name = node.full_module_name.rpartition('.')[-1]

	cname_py2 = 'init' + name
	cname_py3 = 'PyInit_' + name

	py2_attrs = dict(
	name=name,
	cname=cname_py2,
	pf_cname='',
	# Ignore the qualified_name, breakpoints should be set using
	# `cy break modulename:lineno` for module-level breakpoints.
	qualified_name='',
	lineno='1',
	is_initmodule_function="True",
	)

	py3_attrs = dict(py2_attrs, cname=cname_py3)

	self._serialize_modulenode_as_function(node, py2_attrs)
	self._serialize_modulenode_as_function(node, py3_attrs)

	def _serialize_modulenode_as_function(self, node, attrs):
	self.tb.start('Function', attrs=attrs)

	self.tb.start('Locals')
	self.serialize_local_variables(node.scope.entries)
	self.tb.end('Locals')

	self.tb.start('Arguments')
	self.tb.end('Arguments')

	self.tb.start('StepIntoFunctions')
	self.register_stepinto = True
	self.visitchildren(node)
	self.register_stepinto = False
	self.tb.end('StepIntoFunctions')

	self.tb.end('Function')

	def serialize_local_variables(self, entries):
	for entry in entries.values():
	if not entry.cname:
	# not a local variable
	continue
	if entry.type.is_pyobject:
	vartype = 'PythonObject'
	else:
	vartype = 'CObject'

	if entry.from_closure:
	# We're dealing with a closure where a variable from an outer
	# scope is accessed, get it from the scope object.
	cname = '%s->%s' % (Naming.cur_scope_cname,
	entry.outer_entry.cname)

	qname = '%s.%s.%s' % (entry.scope.outer_scope.qualified_name,
	entry.scope.name,
	entry.name)
	elif entry.in_closure:
	cname = '%s->%s' % (Naming.cur_scope_cname,
	entry.cname)
	qname = entry.qualified_name
	else:
	cname = entry.cname
	qname = entry.qualified_name

	if not entry.pos:
	# this happens for variables that are not in the user's code,
	# e.g. for the global __builtins__, __doc__, etc. We can just
	# set the lineno to 0 for those.
	lineno = '0'
	else:
	lineno = str(entry.pos[1])

	attrs = dict(
	name=entry.name,
	cname=cname,
	qualified_name=qname,
	type=vartype,
	lineno=lineno)

	self.tb.start('LocalVar', attrs)
	self.tb.end('LocalVar')