Lichen (annotate inspector.py in f92610e27e92)

Lichen

Annotated inspector.py

604:d11ceeafd2d7

600:f92610e27e92

598:29d9facbcfa3

2017-02-19

Paul Boddie

Merged changes from the default branch.

method-wrapper-for-context

paul@0	1	#!/usr/bin/env python
paul@0	2
paul@0	3	"""
paul@0	4	Inspect and obtain module structure.
paul@0	5
paul@0	6	Copyright (C) 2007, 2008, 2009, 2010, 2011, 2012, 2013,
paul@479	7	2014, 2015, 2016, 2017 Paul Boddie <paul@boddie.org.uk>
paul@0	8
paul@0	9	This program is free software; you can redistribute it and/or modify it under
paul@0	10	the terms of the GNU General Public License as published by the Free Software
paul@0	11	Foundation; either version 3 of the License, or (at your option) any later
paul@0	12	version.
paul@0	13
paul@0	14	This program is distributed in the hope that it will be useful, but WITHOUT
paul@0	15	ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
paul@0	16	FOR A PARTICULAR PURPOSE. See the GNU General Public License for more
paul@0	17	details.
paul@0	18
paul@0	19	You should have received a copy of the GNU General Public License along with
paul@0	20	this program. If not, see <http://www.gnu.org/licenses/>.
paul@0	21	"""
paul@0	22
paul@0	23	from branching import BranchTracker
paul@538	24	from common import CommonModule, get_argnames, init_item, predefined_constants
paul@26	25	from modules import BasicModule, CacheWritingModule, InspectionNaming
paul@3	26	from errors import InspectError
paul@0	27	from referencing import Reference
paul@12	28	from resolving import NameResolving
paul@12	29	from results import AccessRef, InstanceRef, InvocationRef, LiteralSequenceRef, \
paul@226	30	LocalNameRef, NameRef, ResolvedNameRef, VariableRef
paul@0	31	import compiler
paul@0	32	import sys
paul@0	33
paul@26	34	class InspectedModule(BasicModule, CacheWritingModule, NameResolving, InspectionNaming):
paul@0	35
paul@0	36	"A module inspector."
paul@0	37
paul@0	38	def __init__(self, name, importer):
paul@13	39
paul@13	40	"Initialise the module with basic details."
paul@13	41
paul@0	42	BasicModule.__init__(self, name, importer)
paul@12	43
paul@0	44	self.in_class = False
paul@0	45	self.in_conditional = False
paul@110	46
paul@110	47	# Accesses to global attributes.
paul@110	48
paul@0	49	self.global_attr_accesses = {}
paul@0	50
paul@0	51	# Usage tracking.
paul@0	52
paul@0	53	self.trackers = []
paul@0	54	self.attr_accessor_branches = {}
paul@0	55
paul@0	56	def __repr__(self):
paul@0	57	return "InspectedModule(%r, %r)" % (self.name, self.importer)
paul@0	58
paul@27	59	# Principal methods.
paul@27	60
paul@0	61	def parse(self, filename):
paul@0	62
paul@0	63	"Parse the file having the given 'filename'."
paul@0	64
paul@0	65	self.parse_file(filename)
paul@0	66
paul@0	67	# Inspect the module.
paul@0	68
paul@0	69	self.start_tracking_in_module()
paul@0	70
paul@0	71	# Detect and record imports and globals declared in the module.
paul@0	72
paul@0	73	self.process_structure(self.astnode)
paul@0	74
paul@0	75	# Set the class of the module after the definition has occurred.
paul@0	76
paul@269	77	ref = self.get_builtin("module")
paul@0	78	self.set_name("__class__", ref)
paul@499	79	self.set_name("__name__", self.get_constant("string", self.name).reference())
paul@271	80	self.set_name("__file__", self.get_constant("string", filename).reference())
paul@0	81
paul@406	82	# Reserve a constant for the encoding.
paul@406	83
paul@406	84	if self.encoding:
paul@406	85	self.get_constant("string", self.encoding)
paul@406	86
paul@0	87	# Get module-level attribute usage details.
paul@0	88
paul@0	89	self.stop_tracking_in_module()
paul@0	90
paul@27	91	# Collect external name references.
paul@0	92
paul@27	93	self.collect_names()
paul@0	94
paul@12	95	def complete(self):
paul@0	96
paul@12	97	"Complete the module inspection."
paul@0	98
paul@12	99	# Resolve names not definitively mapped to objects.
paul@0	100
paul@12	101	self.resolve()
paul@0	102
paul@12	103	# Define the invocation requirements in each namespace.
paul@0	104
paul@12	105	self.set_invocation_usage()
paul@0	106
paul@12	107	# Propagate to the importer information needed in subsequent activities.
paul@0	108
paul@12	109	self.propagate()
paul@0	110
paul@27	111	# Accessory methods.
paul@0	112
paul@27	113	def collect_names(self):
paul@0	114
paul@27	115	"Collect the names used by each scope."
paul@0	116
paul@0	117	for path in self.names_used.keys():
paul@27	118	self.collect_names_for_path(path)
paul@27	119
paul@27	120	def collect_names_for_path(self, path):
paul@0	121
paul@33	122	"""
paul@33	123	Collect the names used by the given 'path'. These are propagated to the
paul@33	124	importer in advance of any dependency resolution.
paul@33	125	"""
paul@0	126
paul@0	127	names = self.names_used.get(path)
paul@0	128	if not names:
paul@0	129	return
paul@0	130
paul@0	131	in_function = self.function_locals.has_key(path)
paul@0	132
paul@0	133	for name in names:
paul@135	134	if in_function and name in self.function_locals[path]:
paul@135	135	continue
paul@135	136
paul@135	137	key = "%s.%s" % (path, name)
paul@135	138
paul@35	139	# Find local definitions (within dynamic namespaces).
paul@0	140
paul@27	141	ref = self.get_resolved_object(key)
paul@0	142	if ref:
paul@40	143	self.set_name_reference(key, ref)
paul@0	144	continue
paul@0	145
paul@142	146	# Find global.
paul@0	147
paul@142	148	ref = self.get_global(name)
paul@27	149	if ref:
paul@40	150	self.set_name_reference(key, ref)
paul@0	151	continue
paul@0	152
paul@40	153	# Find presumed built-in definitions.
paul@0	154
paul@40	155	ref = self.get_builtin(name)
paul@40	156	self.set_name_reference(key, ref)
paul@0	157
paul@40	158	def set_name_reference(self, path, ref):
paul@0	159
paul@40	160	"Map the given name 'path' to 'ref'."
paul@0	161
paul@40	162	self.importer.all_name_references[path] = self.name_references[path] = ref
paul@0	163
paul@0	164	# Module structure traversal.
paul@0	165
paul@0	166	def process_structure_node(self, n):
paul@0	167
paul@0	168	"Process the individual node 'n'."
paul@0	169
paul@205	170	path = self.get_namespace_path()
paul@205	171
paul@0	172	# Module global detection.
paul@0	173
paul@0	174	if isinstance(n, compiler.ast.Global):
paul@0	175	self.process_global_node(n)
paul@0	176
paul@0	177	# Module import declarations.
paul@0	178
paul@0	179	elif isinstance(n, compiler.ast.From):
paul@0	180	self.process_from_node(n)
paul@0	181
paul@0	182	elif isinstance(n, compiler.ast.Import):
paul@0	183	self.process_import_node(n)
paul@0	184
paul@0	185	# Nodes using operator module functions.
paul@0	186
paul@0	187	elif isinstance(n, compiler.ast.Operator):
paul@0	188	return self.process_operator_node(n)
paul@0	189
paul@0	190	elif isinstance(n, compiler.ast.AugAssign):
paul@0	191	self.process_augassign_node(n)
paul@0	192
paul@0	193	elif isinstance(n, compiler.ast.Compare):
paul@0	194	return self.process_compare_node(n)
paul@0	195
paul@0	196	elif isinstance(n, compiler.ast.Slice):
paul@0	197	return self.process_slice_node(n)
paul@0	198
paul@0	199	elif isinstance(n, compiler.ast.Sliceobj):
paul@0	200	return self.process_sliceobj_node(n)
paul@0	201
paul@0	202	elif isinstance(n, compiler.ast.Subscript):
paul@0	203	return self.process_subscript_node(n)
paul@0	204
paul@0	205	# Namespaces within modules.
paul@0	206
paul@0	207	elif isinstance(n, compiler.ast.Class):
paul@0	208	self.process_class_node(n)
paul@0	209
paul@0	210	elif isinstance(n, compiler.ast.Function):
paul@0	211	self.process_function_node(n, n.name)
paul@0	212
paul@0	213	elif isinstance(n, compiler.ast.Lambda):
paul@0	214	return self.process_lambda_node(n)
paul@0	215
paul@0	216	# Assignments.
paul@0	217
paul@0	218	elif isinstance(n, compiler.ast.Assign):
paul@0	219
paul@0	220	# Handle each assignment node.
paul@0	221
paul@0	222	for node in n.nodes:
paul@0	223	self.process_assignment_node(node, n.expr)
paul@0	224
paul@0	225	# Assignments within non-Assign nodes.
paul@0	226
paul@0	227	elif isinstance(n, compiler.ast.AssName):
paul@205	228	raise InspectError("Name assignment appearing outside assignment statement.", path, n)
paul@0	229
paul@0	230	elif isinstance(n, compiler.ast.AssAttr):
paul@205	231	raise InspectError("Attribute assignment appearing outside assignment statement.", path, n)
paul@0	232
paul@0	233	# Accesses.
paul@0	234
paul@0	235	elif isinstance(n, compiler.ast.Getattr):
paul@0	236	return self.process_attribute_access(n)
paul@0	237
paul@0	238	# Name recording for later testing.
paul@0	239
paul@0	240	elif isinstance(n, compiler.ast.Name):
paul@0	241	return self.process_name_node(n)
paul@0	242
paul@0	243	# Conditional statement tracking.
paul@0	244
paul@0	245	elif isinstance(n, compiler.ast.For):
paul@0	246	self.process_for_node(n)
paul@0	247
paul@0	248	elif isinstance(n, compiler.ast.While):
paul@0	249	self.process_while_node(n)
paul@0	250
paul@0	251	elif isinstance(n, compiler.ast.If):
paul@0	252	self.process_if_node(n)
paul@0	253
paul@0	254	elif isinstance(n, (compiler.ast.And, compiler.ast.Or)):
paul@0	255	return self.process_logical_node(n)
paul@0	256
paul@0	257	# Exception control-flow tracking.
paul@0	258
paul@0	259	elif isinstance(n, compiler.ast.TryExcept):
paul@0	260	self.process_try_node(n)
paul@0	261
paul@0	262	elif isinstance(n, compiler.ast.TryFinally):
paul@0	263	self.process_try_finally_node(n)
paul@0	264
paul@0	265	# Control-flow modification statements.
paul@0	266
paul@0	267	elif isinstance(n, compiler.ast.Break):
paul@0	268	self.trackers[-1].suspend_broken_branch()
paul@0	269
paul@0	270	elif isinstance(n, compiler.ast.Continue):
paul@0	271	self.trackers[-1].suspend_continuing_branch()
paul@0	272
paul@0	273	elif isinstance(n, compiler.ast.Raise):
paul@0	274	self.process_structure(n)
paul@0	275	self.trackers[-1].abandon_branch()
paul@0	276
paul@0	277	elif isinstance(n, compiler.ast.Return):
paul@0	278	self.process_structure(n)
paul@0	279	self.trackers[-1].abandon_returning_branch()
paul@0	280
paul@173	281	# Print statements.
paul@173	282
paul@173	283	elif isinstance(n, (compiler.ast.Print, compiler.ast.Printnl)):
paul@173	284	self.process_print_node(n)
paul@173	285
paul@0	286	# Invocations.
paul@0	287
paul@0	288	elif isinstance(n, compiler.ast.CallFunc):
paul@0	289	return self.process_invocation_node(n)
paul@0	290
paul@0	291	# Constant usage.
paul@0	292
paul@0	293	elif isinstance(n, compiler.ast.Const):
paul@405	294	return self.get_literal_instance(n)
paul@0	295
paul@0	296	elif isinstance(n, compiler.ast.Dict):
paul@0	297	return self.get_literal_instance(n, "dict")
paul@0	298
paul@0	299	elif isinstance(n, compiler.ast.List):
paul@0	300	return self.get_literal_instance(n, "list")
paul@0	301
paul@0	302	elif isinstance(n, compiler.ast.Tuple):
paul@0	303	return self.get_literal_instance(n, "tuple")
paul@0	304
paul@0	305	# All other nodes are processed depth-first.
paul@0	306
paul@0	307	else:
paul@0	308	self.process_structure(n)
paul@0	309
paul@0	310	# By default, no expression details are returned.
paul@0	311
paul@0	312	return None
paul@0	313
paul@0	314	# Specific node handling.
paul@0	315
paul@0	316	def process_assignment_node(self, n, expr):
paul@0	317
paul@0	318	"Process the individual node 'n' to be assigned the contents of 'expr'."
paul@0	319
paul@0	320	# Names and attributes are assigned the entire expression.
paul@0	321
paul@0	322	if isinstance(n, compiler.ast.AssName):
paul@61	323	if n.name == "self":
paul@61	324	raise InspectError("Redefinition of self is not allowed.", self.get_namespace_path(), n)
paul@0	325
paul@0	326	name_ref = expr and self.process_structure_node(expr)
paul@0	327
paul@0	328	# Name assignments populate either function namespaces or the
paul@0	329	# general namespace hierarchy.
paul@0	330
paul@0	331	self.assign_general_local(n.name, name_ref)
paul@0	332
paul@0	333	# Record usage of the name.
paul@0	334
paul@0	335	self.record_name(n.name)
paul@0	336
paul@0	337	elif isinstance(n, compiler.ast.AssAttr):
paul@124	338	if expr:
paul@124	339	expr = self.process_structure_node(expr)
paul@107	340
paul@107	341	in_assignment = self.in_assignment
paul@389	342	self.in_assignment = True
paul@0	343	self.process_attribute_access(n)
paul@107	344	self.in_assignment = in_assignment
paul@0	345
paul@0	346	# Lists and tuples are matched against the expression and their
paul@0	347	# items assigned to expression items.
paul@0	348
paul@0	349	elif isinstance(n, (compiler.ast.AssList, compiler.ast.AssTuple)):
paul@0	350	self.process_assignment_node_items(n, expr)
paul@0	351
paul@0	352	# Slices and subscripts are permitted within assignment nodes.
paul@0	353
paul@0	354	elif isinstance(n, compiler.ast.Slice):
paul@0	355	self.process_slice_node(n, expr)
paul@0	356
paul@0	357	elif isinstance(n, compiler.ast.Subscript):
paul@0	358	self.process_subscript_node(n, expr)
paul@0	359
paul@0	360	def process_attribute_access(self, n):
paul@0	361
paul@0	362	"Process the given attribute access node 'n'."
paul@0	363
paul@107	364	# Obtain any completed chain and return the reference to it.
paul@107	365
paul@0	366	name_ref = self.process_attribute_chain(n)
paul@107	367
paul@0	368	if self.have_access_expression(n):
paul@0	369	return name_ref
paul@0	370
paul@0	371	# Where the start of the chain of attributes has been reached, determine
paul@0	372	# the complete access.
paul@0	373
paul@0	374	# Given a non-access node, this chain can be handled in its entirety,
paul@0	375	# either being name-based and thus an access rooted on a name, or being
paul@0	376	# based on some other node and thus an anonymous access of some kind.
paul@0	377
paul@0	378	path = self.get_namespace_path()
paul@0	379
paul@0	380	# Start with the the full attribute chain.
paul@0	381
paul@0	382	remaining = self.attrs
paul@0	383	attrnames = ".".join(remaining)
paul@0	384
paul@0	385	# If the accessor cannot be identified, or where attributes
paul@0	386	# remain in an attribute chain, record the anonymous accesses.
paul@0	387
paul@0	388	if not isinstance(name_ref, NameRef): # includes ResolvedNameRef
paul@0	389
paul@0	390	init_item(self.attr_accesses, path, set)
paul@0	391	self.attr_accesses[path].add(attrnames)
paul@0	392
paul@117	393	self.record_access_details(None, attrnames, self.in_assignment,
paul@117	394	self.in_invocation)
paul@0	395	del self.attrs[0]
paul@0	396	return
paul@0	397
paul@0	398	# Name-based accesses will handle the first attribute in a
paul@0	399	# chain.
paul@0	400
paul@0	401	else:
paul@0	402	attrname = remaining[0]
paul@0	403
paul@0	404	# Attribute assignments are used to identify instance attributes.
paul@0	405
paul@0	406	if isinstance(n, compiler.ast.AssAttr) and \
paul@0	407	self.in_class and self.in_function and n.expr.name == "self":
paul@0	408
paul@0	409	self.set_instance_attr(attrname)
paul@0	410
paul@0	411	# Record attribute usage using any name local to this namespace,
paul@0	412	# if assigned in the namespace, or using an external name
paul@0	413	# (presently just globals within classes).
paul@0	414
paul@597	415	name = self.get_name_for_tracking(name_ref.name, name_ref.reference())
paul@0	416	tracker = self.trackers[-1]
paul@0	417
paul@0	418	immediate_access = len(self.attrs) == 1
paul@0	419	assignment = immediate_access and isinstance(n, compiler.ast.AssAttr)
paul@0	420
paul@0	421	# Record global-based chains for subsequent resolution.
paul@0	422
paul@0	423	is_global = self.in_function and not self.function_locals[path].has_key(name) or \
paul@0	424	not self.in_function
paul@0	425
paul@0	426	if is_global:
paul@0	427	self.record_global_access_details(name, attrnames)
paul@0	428
paul@0	429	# Make sure the name is being tracked: global names will not
paul@0	430	# already be initialised in a branch and must be added
paul@0	431	# explicitly.
paul@0	432
paul@0	433	if not tracker.have_name(name):
paul@0	434	tracker.assign_names([name])
paul@0	435	if self.in_function:
paul@0	436	self.scope_globals[path].add(name)
paul@0	437
paul@0	438	# Record attribute usage in the tracker, and record the branch
paul@0	439	# information for the access.
paul@0	440
paul@557	441	branches = tracker.use_attribute(name, attrname,
paul@557	442	self.in_invocation is not None, assignment)
paul@0	443
paul@0	444	if not branches:
paul@84	445	raise InspectError("Name %s is accessed using %s before an assignment." % (
paul@84	446	name, attrname), path, n)
paul@0	447
paul@0	448	self.record_branches_for_access(branches, name, attrnames)
paul@117	449	access_number = self.record_access_details(name, attrnames,
paul@117	450	self.in_assignment, self.in_invocation)
paul@107	451
paul@107	452	del self.attrs[0]
paul@0	453	return AccessRef(name, attrnames, access_number)
paul@0	454
paul@0	455	def process_class_node(self, n):
paul@0	456
paul@0	457	"Process the given class node 'n'."
paul@0	458
paul@0	459	path = self.get_namespace_path()
paul@0	460
paul@0	461	# To avoid notions of class "versions" where the same definition
paul@0	462	# might be parameterised with different state and be referenced
paul@0	463	# elsewhere (as base classes, for example), classes in functions or
paul@0	464	# conditions are forbidden.
paul@0	465
paul@0	466	if self.in_function or self.in_conditional:
paul@0	467	print >>sys.stderr, "In %s, class %s in function or conditional statement ignored." % (
paul@0	468	path, n.name)
paul@0	469	return
paul@0	470
paul@0	471	# Resolve base classes.
paul@0	472
paul@0	473	bases = []
paul@0	474
paul@0	475	for base in n.bases:
paul@0	476	base_class = self.get_class(base)
paul@0	477
paul@0	478	if not base_class:
paul@12	479	print >>sys.stderr, "In %s, class %s has unidentifiable base class: %s" % (
paul@12	480	path, n.name, base)
paul@0	481	return
paul@0	482	else:
paul@0	483	bases.append(base_class)
paul@0	484
paul@348	485	# Detect conflicting definitions. Such definitions cause conflicts in
paul@348	486	# the storage of namespace-related information.
paul@348	487
paul@348	488	class_name = self.get_object_path(n.name)
paul@422	489	ref = self.get_object(class_name, defer=False)
paul@348	490
paul@422	491	if ref and ref.static():
paul@348	492	raise InspectError("Multiple definitions for the same name are not permitted.", class_name, n)
paul@348	493
paul@0	494	# Record bases for the class and retain the class name.
paul@107	495	# Note that the function class does not inherit from the object class.
paul@0	496
paul@107	497	if not bases and class_name != "__builtins__.core.object" and \
paul@107	498	class_name != "__builtins__.core.function":
paul@107	499
paul@0	500	ref = self.get_object("__builtins__.object")
paul@0	501	bases.append(ref)
paul@0	502
paul@0	503	self.importer.classes[class_name] = self.classes[class_name] = bases
paul@0	504	self.importer.subclasses[class_name] = set()
paul@0	505	self.scope_globals[class_name] = set()
paul@0	506
paul@0	507	# Set the definition before entering the namespace rather than
paul@0	508	# afterwards because methods may reference it. In normal Python,
paul@0	509	# a class is not accessible until the definition is complete, but
paul@0	510	# methods can generally reference it since upon being called the
paul@0	511	# class will already exist.
paul@0	512
paul@0	513	self.set_definition(n.name, "<class>")
paul@0	514
paul@0	515	in_class = self.in_class
paul@0	516	self.in_class = class_name
paul@0	517	self.set_instance_attr("__class__", Reference("<class>", class_name))
paul@0	518	self.enter_namespace(n.name)
paul@107	519
paul@107	520	# Do not provide the special instantiator attributes on the function
paul@107	521	# class. Function instances provide these attributes.
paul@107	522
paul@107	523	if class_name != "__builtins__.core.function":
paul@577	524
paul@107	525	self.set_name("__fn__") # special instantiator attribute
paul@107	526	self.set_name("__args__") # special instantiator attribute
paul@107	527
paul@577	528	# Provide leafname, parent and context attributes.
paul@489	529
paul@499	530	parent, leafname = class_name.rsplit(".", 1)
paul@499	531	self.set_name("__name__", self.get_constant("string", leafname).reference())
paul@577	532
paul@577	533	if class_name != "__builtins__.core.function":
paul@577	534	self.set_name("__parent__")
paul@274	535
paul@0	536	self.process_structure_node(n.code)
paul@0	537	self.exit_namespace()
paul@0	538	self.in_class = in_class
paul@0	539
paul@0	540	def process_from_node(self, n):
paul@0	541
paul@0	542	"Process the given node 'n', importing from another module."
paul@0	543
paul@0	544	path = self.get_namespace_path()
paul@0	545
paul@12	546	module_name, names = self.get_module_name(n)
paul@12	547	if module_name == self.name:
paul@12	548	raise InspectError("Cannot import from the current module.", path, n)
paul@0	549
paul@18	550	self.queue_module(module_name)
paul@0	551
paul@0	552	# Attempt to obtain the referenced objects.
paul@0	553
paul@0	554	for name, alias in n.names:
paul@0	555	if name == "*":
paul@12	556	raise InspectError("Only explicitly specified names can be imported from modules.", path, n)
paul@0	557
paul@0	558	# Explicit names.
paul@0	559
paul@12	560	ref = self.import_name_from_module(name, module_name)
paul@0	561	value = ResolvedNameRef(alias or name, ref)
paul@0	562	self.set_general_local(alias or name, value)
paul@0	563
paul@0	564	def process_function_node(self, n, name):
paul@0	565
paul@0	566	"""
paul@0	567	Process the given function or lambda node 'n' with the given 'name'.
paul@0	568	"""
paul@0	569
paul@0	570	is_lambda = isinstance(n, compiler.ast.Lambda)
paul@0	571
paul@0	572	# Where a function is declared conditionally, use a separate name for
paul@0	573	# the definition, and assign the definition to the stated name.
paul@0	574
paul@0	575	if (self.in_conditional or self.in_function) and not is_lambda:
paul@0	576	original_name = name
paul@0	577	name = self.get_lambda_name()
paul@0	578	else:
paul@0	579	original_name = None
paul@0	580
paul@348	581	# Detect conflicting definitions. Such definitions cause conflicts in
paul@348	582	# the storage of namespace-related information.
paul@348	583
paul@348	584	function_name = self.get_object_path(name)
paul@422	585	ref = self.get_object(function_name, defer=False)
paul@348	586
paul@422	587	if ref and ref.static():
paul@348	588	raise InspectError("Multiple definitions for the same name are not permitted.", function_name, n)
paul@348	589
paul@0	590	# Initialise argument and local records.
paul@0	591
paul@46	592	argnames = get_argnames(n.argnames)
paul@48	593	is_method = self.in_class and not self.in_function
paul@0	594
paul@48	595	# Remove explicit "self" from method parameters.
paul@46	596
paul@48	597	if is_method and argnames and argnames[0] == "self":
paul@48	598	del argnames[0]
paul@48	599
paul@48	600	# Copy and propagate the parameters.
paul@46	601
paul@46	602	self.importer.function_parameters[function_name] = \
paul@109	603	self.function_parameters[function_name] = argnames[:]
paul@46	604
paul@46	605	# Define all arguments/parameters in the local namespace.
paul@46	606
paul@109	607	locals = \
paul@109	608	self.importer.function_locals[function_name] = \
paul@109	609	self.function_locals[function_name] = {}
paul@0	610
paul@48	611	# Insert "self" into method locals.
paul@48	612
paul@48	613	if is_method:
paul@48	614	argnames.insert(0, "self")
paul@48	615
paul@47	616	# Define "self" in terms of the class if in a method.
paul@47	617	# This does not diminish the need for type-narrowing in the deducer.
paul@47	618
paul@47	619	if argnames:
paul@48	620	if self.in_class and not self.in_function and argnames[0] == "self":
paul@47	621	locals[argnames[0]] = Reference("<instance>", self.in_class)
paul@47	622	else:
paul@47	623	locals[argnames[0]] = Reference("<var>")
paul@47	624
paul@47	625	for argname in argnames[1:]:
paul@0	626	locals[argname] = Reference("<var>")
paul@0	627
paul@0	628	globals = self.scope_globals[function_name] = set()
paul@0	629
paul@0	630	# Process the defaults.
paul@0	631
paul@0	632	defaults = self.importer.function_defaults[function_name] = \
paul@0	633	self.function_defaults[function_name] = []
paul@0	634
paul@0	635	for argname, default in compiler.ast.get_defaults(n):
paul@0	636	if default:
paul@0	637
paul@0	638	# Obtain any reference for the default.
paul@0	639
paul@0	640	name_ref = self.process_structure_node(default)
paul@0	641	defaults.append((argname, name_ref.is_name() and name_ref.reference() or Reference("<var>")))
paul@0	642
paul@0	643	# Reset conditional tracking to focus on the function contents.
paul@0	644
paul@0	645	in_conditional = self.in_conditional
paul@0	646	self.in_conditional = False
paul@0	647
paul@0	648	in_function = self.in_function
paul@0	649	self.in_function = function_name
paul@0	650
paul@0	651	self.enter_namespace(name)
paul@0	652
paul@499	653	# Define a leafname attribute value for the function instance.
paul@251	654
paul@251	655	ref = self.get_builtin_class("string")
paul@489	656	self.reserve_constant(function_name, name, ref.get_origin())
paul@251	657
paul@0	658	# Track attribute usage within the namespace.
paul@0	659
paul@0	660	path = self.get_namespace_path()
paul@0	661
paul@0	662	self.start_tracking(locals)
paul@0	663	self.process_structure_node(n.code)
paul@0	664	self.stop_tracking()
paul@0	665
paul@1	666	# Exit to the parent.
paul@0	667
paul@0	668	self.exit_namespace()
paul@0	669
paul@0	670	# Update flags.
paul@0	671
paul@0	672	self.in_function = in_function
paul@0	673	self.in_conditional = in_conditional
paul@0	674
paul@0	675	# Define the function using the appropriate name.
paul@0	676
paul@0	677	self.set_definition(name, "<function>")
paul@0	678
paul@0	679	# Where a function is set conditionally, assign the name.
paul@0	680
paul@0	681	if original_name:
paul@322	682	self.process_assignment_for_object(original_name, compiler.ast.Name(name))
paul@0	683
paul@0	684	def process_global_node(self, n):
paul@0	685
paul@0	686	"""
paul@0	687	Process the given "global" node 'n'.
paul@0	688	"""
paul@0	689
paul@0	690	path = self.get_namespace_path()
paul@0	691
paul@0	692	if path != self.name:
paul@0	693	self.scope_globals[path].update(n.names)
paul@0	694
paul@0	695	def process_if_node(self, n):
paul@0	696
paul@0	697	"""
paul@0	698	Process the given "if" node 'n'.
paul@0	699	"""
paul@0	700
paul@0	701	tracker = self.trackers[-1]
paul@0	702	tracker.new_branchpoint()
paul@0	703
paul@0	704	for test, body in n.tests:
paul@0	705	self.process_structure_node(test)
paul@0	706
paul@0	707	tracker.new_branch()
paul@0	708
paul@0	709	in_conditional = self.in_conditional
paul@0	710	self.in_conditional = True
paul@0	711	self.process_structure_node(body)
paul@0	712	self.in_conditional = in_conditional
paul@0	713
paul@0	714	tracker.shelve_branch()
paul@0	715
paul@0	716	# Maintain a branch for the else clause.
paul@0	717
paul@0	718	tracker.new_branch()
paul@0	719	if n.else_:
paul@0	720	self.process_structure_node(n.else_)
paul@0	721	tracker.shelve_branch()
paul@0	722
paul@0	723	tracker.merge_branches()
paul@0	724
paul@0	725	def process_import_node(self, n):
paul@0	726
paul@0	727	"Process the given import node 'n'."
paul@0	728
paul@0	729	path = self.get_namespace_path()
paul@0	730
paul@0	731	# Load the mentioned module.
paul@0	732
paul@0	733	for name, alias in n.names:
paul@12	734	if name == self.name:
paul@12	735	raise InspectError("Cannot import the current module.", path, n)
paul@0	736
paul@13	737	self.set_module(alias or name.split(".")[-1], name)
paul@18	738	self.queue_module(name, True)
paul@0	739
paul@0	740	def process_invocation_node(self, n):
paul@0	741
paul@0	742	"Process the given invocation node 'n'."
paul@0	743
paul@0	744	path = self.get_namespace_path()
paul@0	745
paul@0	746	self.allocate_arguments(path, n.args)
paul@0	747
paul@0	748	try:
paul@557	749	in_invocation = self.in_invocation
paul@557	750	self.in_invocation = None
paul@557	751
paul@557	752	# Process the arguments.
paul@557	753
paul@557	754	keywords = set()
paul@557	755
paul@557	756	for arg in n.args:
paul@557	757	self.process_structure_node(arg)
paul@557	758	if isinstance(arg, compiler.ast.Keyword):
paul@557	759	keywords.add(arg.name)
paul@557	760
paul@557	761	keywords = list(keywords)
paul@557	762	keywords.sort()
paul@557	763
paul@107	764	# Communicate to the invocation target expression that it forms the
paul@107	765	# target of an invocation, potentially affecting attribute accesses.
paul@0	766
paul@557	767	self.in_invocation = len(n.args), keywords
paul@107	768
paul@107	769	# Process the expression, obtaining any identified reference.
paul@107	770
paul@0	771	name_ref = self.process_structure_node(n.node)
paul@223	772	self.in_invocation = in_invocation
paul@223	773
paul@0	774	# Detect class invocations.
paul@0	775
paul@0	776	if isinstance(name_ref, ResolvedNameRef) and name_ref.has_kind("<class>"):
paul@0	777	return InstanceRef(name_ref.reference().instance_of())
paul@0	778
paul@0	779	elif isinstance(name_ref, NameRef):
paul@0	780	return InvocationRef(name_ref)
paul@0	781
paul@226	782	# Provide a general reference to indicate that something is produced
paul@226	783	# by the invocation, useful for retaining assignment expression
paul@226	784	# details.
paul@226	785
paul@226	786	return VariableRef()
paul@0	787
paul@0	788	finally:
paul@0	789	self.deallocate_arguments(path, n.args)
paul@0	790
paul@0	791	def process_lambda_node(self, n):
paul@0	792
paul@0	793	"Process the given lambda node 'n'."
paul@0	794
paul@0	795	name = self.get_lambda_name()
paul@0	796	self.process_function_node(n, name)
paul@0	797
paul@0	798	origin = self.get_object_path(name)
paul@210	799
paul@210	800	if self.function_defaults.get(origin):
paul@210	801	return None
paul@210	802	else:
paul@210	803	return ResolvedNameRef(name, Reference("<function>", origin))
paul@0	804
paul@0	805	def process_logical_node(self, n):
paul@0	806
paul@0	807	"Process the given operator node 'n'."
paul@0	808
paul@0	809	self.process_operator_chain(n.nodes, self.process_structure_node)
paul@0	810
paul@0	811	def process_name_node(self, n):
paul@0	812
paul@0	813	"Process the given name node 'n'."
paul@0	814
paul@0	815	path = self.get_namespace_path()
paul@0	816
paul@420	817	# Find predefined constant names before anything else.
paul@420	818
paul@420	819	if n.name in predefined_constants:
paul@420	820	ref = self.get_builtin(n.name)
paul@420	821	value = ResolvedNameRef(n.name, ref)
paul@420	822	return value
paul@420	823
paul@173	824	# Special names that have already been identified.
paul@0	825
paul@0	826	if n.name.startswith("$"):
paul@0	827	value = self.get_special(n.name)
paul@0	828	if value:
paul@0	829	return value
paul@0	830
paul@0	831	# Special case for operator functions introduced through code
paul@0	832	# transformations.
paul@0	833
paul@0	834	if n.name.startswith("$op"):
paul@0	835
paul@0	836	# Obtain the location of the actual function defined in the operator
paul@0	837	# package.
paul@0	838
paul@0	839	op = n.name[len("$op"):]
paul@0	840
paul@0	841	# Attempt to get a reference.
paul@0	842
paul@12	843	ref = self.import_name_from_module(op, "operator")
paul@0	844
paul@0	845	# Record the imported name and provide the resolved name reference.
paul@0	846
paul@0	847	value = ResolvedNameRef(n.name, ref)
paul@0	848	self.set_special(n.name, value)
paul@0	849	return value
paul@0	850
paul@173	851	# Special case for print operations.
paul@173	852
paul@173	853	elif n.name.startswith("$print"):
paul@173	854
paul@173	855	# Attempt to get a reference.
paul@173	856
paul@173	857	ref = self.get_builtin("print_")
paul@173	858
paul@173	859	# Record the imported name and provide the resolved name reference.
paul@173	860
paul@173	861	value = ResolvedNameRef(n.name, ref)
paul@173	862	self.set_special(n.name, value)
paul@173	863	return value
paul@173	864
paul@60	865	# Test for self usage, which is only allowed in methods.
paul@60	866
paul@60	867	if n.name == "self" and not (self.in_function and self.in_class):
paul@60	868	raise InspectError("Use of self is only allowed in methods.", path, n)
paul@60	869
paul@0	870	# Record usage of the name.
paul@0	871
paul@0	872	self.record_name(n.name)
paul@0	873
paul@0	874	# Search for unknown names in non-function scopes immediately.
paul@0	875	# External names in functions are resolved later.
paul@0	876
paul@0	877	ref = self.find_name(n.name)
paul@0	878	if ref:
paul@0	879	return ResolvedNameRef(n.name, ref)
paul@0	880
paul@40	881	# Explicitly-declared global names.
paul@0	882
paul@0	883	elif self.in_function and n.name in self.scope_globals[path]:
paul@0	884	return NameRef(n.name)
paul@0	885
paul@0	886	# Examine other names.
paul@0	887
paul@0	888	else:
paul@0	889	tracker = self.trackers[-1]
paul@0	890
paul@0	891	# Check local names.
paul@0	892
paul@0	893	branches = tracker.tracking_name(n.name)
paul@0	894
paul@1	895	# Local name.
paul@0	896
paul@0	897	if branches:
paul@0	898	self.record_branches_for_access(branches, n.name, None)
paul@553	899	access_number = self.record_access_details(n.name, None, None, None)
paul@0	900	return LocalNameRef(n.name, access_number)
paul@0	901
paul@40	902	# Possible global or built-in name.
paul@0	903
paul@0	904	else:
paul@0	905	return NameRef(n.name)
paul@0	906
paul@0	907	def process_operator_chain(self, nodes, fn):
paul@0	908
paul@0	909	"""
paul@0	910	Process the given chain of 'nodes', applying 'fn' to each node or item.
paul@0	911	Each node starts a new conditional region, effectively making a deeply-
paul@0	912	nested collection of if-like statements.
paul@0	913	"""
paul@0	914
paul@0	915	tracker = self.trackers[-1]
paul@0	916
paul@0	917	for item in nodes:
paul@0	918	tracker.new_branchpoint()
paul@0	919	tracker.new_branch()
paul@0	920	fn(item)
paul@0	921
paul@0	922	for item in nodes[:-1]:
paul@0	923	tracker.shelve_branch()
paul@0	924	tracker.new_branch()
paul@0	925	tracker.shelve_branch()
paul@0	926	tracker.merge_branches()
paul@0	927
paul@0	928	tracker.shelve_branch()
paul@0	929	tracker.merge_branches()
paul@0	930
paul@0	931	def process_try_node(self, n):
paul@0	932
paul@0	933	"""
paul@0	934	Process the given "try...except" node 'n'.
paul@0	935	"""
paul@0	936
paul@479	937	self.record_exception_handler()
paul@479	938
paul@0	939	tracker = self.trackers[-1]
paul@0	940	tracker.new_branchpoint()
paul@0	941
paul@0	942	self.process_structure_node(n.body)
paul@0	943
paul@0	944	for name, var, handler in n.handlers:
paul@0	945	if name is not None:
paul@0	946	self.process_structure_node(name)
paul@0	947
paul@0	948	# Any abandoned branches from the body can now be resumed in a new
paul@0	949	# branch.
paul@0	950
paul@0	951	tracker.resume_abandoned_branches()
paul@0	952
paul@0	953	# Establish the local for the handler.
paul@0	954
paul@0	955	if var is not None:
paul@261	956	self.process_assignment_node(var, None)
paul@0	957	if handler is not None:
paul@0	958	self.process_structure_node(handler)
paul@0	959
paul@0	960	tracker.shelve_branch()
paul@0	961
paul@0	962	# The else clause maintains the usage from the body but without the
paul@0	963	# abandoned branches since they would never lead to the else clause
paul@0	964	# being executed.
paul@0	965
paul@0	966	if n.else_:
paul@0	967	tracker.new_branch()
paul@0	968	self.process_structure_node(n.else_)
paul@0	969	tracker.shelve_branch()
paul@0	970
paul@0	971	# Without an else clause, a null branch propagates the successful
paul@0	972	# outcome.
paul@0	973
paul@0	974	else:
paul@0	975	tracker.new_branch()
paul@0	976	tracker.shelve_branch()
paul@0	977
paul@0	978	tracker.merge_branches()
paul@0	979
paul@0	980	def process_try_finally_node(self, n):
paul@0	981
paul@0	982	"""
paul@0	983	Process the given "try...finally" node 'n'.
paul@0	984	"""
paul@0	985
paul@479	986	self.record_exception_handler()
paul@479	987
paul@0	988	tracker = self.trackers[-1]
paul@0	989	self.process_structure_node(n.body)
paul@0	990
paul@0	991	# Any abandoned branches from the body can now be resumed.
paul@0	992
paul@0	993	branches = tracker.resume_all_abandoned_branches()
paul@0	994	self.process_structure_node(n.final)
paul@0	995
paul@0	996	# At the end of the finally clause, abandoned branches are discarded.
paul@0	997
paul@0	998	tracker.restore_active_branches(branches)
paul@0	999
paul@0	1000	def process_while_node(self, n):
paul@0	1001
paul@0	1002	"Process the given while node 'n'."
paul@0	1003
paul@0	1004	tracker = self.trackers[-1]
paul@0	1005	tracker.new_branchpoint(loop_node=True)
paul@0	1006
paul@0	1007	# Evaluate any test or iterator outside the loop.
paul@0	1008
paul@0	1009	self.process_structure_node(n.test)
paul@0	1010
paul@0	1011	# Propagate attribute usage to branches.
paul@0	1012
paul@0	1013	tracker.new_branch(loop_node=True)
paul@0	1014
paul@0	1015	# Enter the loop.
paul@0	1016
paul@0	1017	in_conditional = self.in_conditional
paul@0	1018	self.in_conditional = True
paul@0	1019	self.process_structure_node(n.body)
paul@0	1020	self.in_conditional = in_conditional
paul@0	1021
paul@0	1022	# Continuing branches are resumed before any test.
paul@0	1023
paul@0	1024	tracker.resume_continuing_branches()
paul@0	1025
paul@0	1026	# Evaluate any continuation test within the body.
paul@0	1027
paul@0	1028	self.process_structure_node(n.test)
paul@0	1029
paul@0	1030	tracker.shelve_branch(loop_node=True)
paul@0	1031
paul@0	1032	# Support the non-looping condition.
paul@0	1033
paul@0	1034	tracker.new_branch()
paul@0	1035	tracker.shelve_branch()
paul@0	1036
paul@0	1037	tracker.merge_branches()
paul@0	1038
paul@0	1039	# Evaluate any else clause outside branches.
paul@0	1040
paul@0	1041	if n.else_:
paul@0	1042	self.process_structure_node(n.else_)
paul@0	1043
paul@0	1044	# Connect broken branches to the code after any loop.
paul@0	1045
paul@0	1046	tracker.resume_broken_branches()
paul@0	1047
paul@0	1048	# Branch tracking methods.
paul@0	1049
paul@0	1050	def start_tracking(self, names):
paul@0	1051
paul@0	1052	"""
paul@0	1053	Start tracking attribute usage for names in the current namespace,
paul@0	1054	immediately registering the given 'names'.
paul@0	1055	"""
paul@0	1056
paul@0	1057	path = self.get_namespace_path()
paul@0	1058	parent = self.trackers[-1]
paul@0	1059	tracker = BranchTracker()
paul@0	1060	self.trackers.append(tracker)
paul@0	1061
paul@0	1062	# Record the given names established as new branches.
paul@0	1063
paul@0	1064	tracker.assign_names(names)
paul@0	1065
paul@0	1066	def assign_name(self, name, name_ref):
paul@0	1067
paul@0	1068	"Assign to 'name' the given 'name_ref' in the current namespace."
paul@0	1069
paul@0	1070	name = self.get_name_for_tracking(name)
paul@0	1071	self.trackers[-1].assign_names([name], [name_ref])
paul@0	1072
paul@0	1073	def stop_tracking(self):
paul@0	1074
paul@0	1075	"""
paul@0	1076	Stop tracking attribute usage, recording computed usage for the current
paul@0	1077	namespace.
paul@0	1078	"""
paul@0	1079
paul@0	1080	path = self.get_namespace_path()
paul@0	1081	tracker = self.trackers.pop()
paul@0	1082	self.record_assignments_for_access(tracker)
paul@0	1083
paul@0	1084	self.attr_usage[path] = tracker.get_all_usage()
paul@0	1085	self.name_initialisers[path] = tracker.get_all_values()
paul@0	1086
paul@0	1087	def start_tracking_in_module(self):
paul@0	1088
paul@0	1089	"Start tracking attribute usage in the module."
paul@0	1090
paul@0	1091	tracker = BranchTracker()
paul@0	1092	self.trackers.append(tracker)
paul@0	1093
paul@0	1094	def stop_tracking_in_module(self):
paul@0	1095
paul@0	1096	"Stop tracking attribute usage in the module."
paul@0	1097
paul@0	1098	tracker = self.trackers[0]
paul@0	1099	self.record_assignments_for_access(tracker)
paul@0	1100	self.attr_usage[self.name] = tracker.get_all_usage()
paul@0	1101	self.name_initialisers[self.name] = tracker.get_all_values()
paul@0	1102
paul@0	1103	def record_assignments_for_access(self, tracker):
paul@0	1104
paul@0	1105	"""
paul@0	1106	For the current path, use the given 'tracker' to record assignment
paul@0	1107	version information for attribute accesses.
paul@0	1108	"""
paul@0	1109
paul@0	1110	path = self.get_path_for_access()
paul@0	1111
paul@0	1112	if not self.attr_accessor_branches.has_key(path):
paul@0	1113	return
paul@0	1114
paul@0	1115	init_item(self.attr_accessors, path, dict)
paul@0	1116	attr_accessors = self.attr_accessors[path]
paul@0	1117
paul@0	1118	# Obtain the branches applying during each access.
paul@0	1119
paul@0	1120	for access, all_branches in self.attr_accessor_branches[path].items():
paul@0	1121	name, attrnames = access
paul@0	1122	init_item(attr_accessors, access, list)
paul@0	1123
paul@0	1124	# Obtain the assignments applying to each branch.
paul@0	1125
paul@0	1126	for branches in all_branches:
paul@0	1127	positions = tracker.get_assignment_positions_for_branches(name, branches)
paul@0	1128
paul@0	1129	# Detect missing name information.
paul@0	1130
paul@0	1131	if None in positions:
paul@0	1132	globals = self.global_attr_accesses.get(path)
paul@0	1133	accesses = globals and globals.get(name)
paul@0	1134	if not accesses:
paul@0	1135	print >>sys.stderr, "In %s, %s may not be defined when used." % (
paul@0	1136	self.get_namespace_path(), name)
paul@0	1137	positions.remove(None)
paul@0	1138
paul@0	1139	attr_accessors[access].append(positions)
paul@0	1140
paul@0	1141	def record_branches_for_access(self, branches, name, attrnames):
paul@0	1142
paul@0	1143	"""
paul@0	1144	Record the given 'branches' for an access involving the given 'name' and
paul@0	1145	'attrnames'.
paul@0	1146	"""
paul@0	1147
paul@0	1148	access = name, attrnames
paul@0	1149	path = self.get_path_for_access()
paul@0	1150
paul@0	1151	init_item(self.attr_accessor_branches, path, dict)
paul@0	1152	attr_accessor_branches = self.attr_accessor_branches[path]
paul@0	1153
paul@0	1154	init_item(attr_accessor_branches, access, list)
paul@0	1155	attr_accessor_branches[access].append(branches)
paul@0	1156
paul@117	1157	def record_access_details(self, name, attrnames, assignment, invocation):
paul@0	1158
paul@0	1159	"""
paul@0	1160	For the given 'name' and 'attrnames', record an access indicating
paul@553	1161	whether an 'assignment' or an 'invocation' is occurring.
paul@0	1162
paul@0	1163	These details correspond to accesses otherwise recorded by the attribute
paul@0	1164	accessor and attribute access dictionaries.
paul@0	1165	"""
paul@0	1166
paul@0	1167	access = name, attrnames
paul@0	1168	path = self.get_path_for_access()
paul@0	1169
paul@0	1170	init_item(self.attr_access_modifiers, path, dict)
paul@0	1171	init_item(self.attr_access_modifiers[path], access, list)
paul@0	1172
paul@0	1173	access_number = len(self.attr_access_modifiers[path][access])
paul@117	1174	self.attr_access_modifiers[path][access].append((assignment, invocation))
paul@0	1175	return access_number
paul@0	1176
paul@0	1177	def record_global_access_details(self, name, attrnames):
paul@0	1178
paul@0	1179	"""
paul@0	1180	Record details of a global access via the given 'name' involving the
paul@0	1181	indicated 'attrnames'.
paul@0	1182	"""
paul@0	1183
paul@0	1184	path = self.get_namespace_path()
paul@0	1185
paul@0	1186	init_item(self.global_attr_accesses, path, dict)
paul@0	1187	init_item(self.global_attr_accesses[path], name, set)
paul@0	1188	self.global_attr_accesses[path][name].add(attrnames)
paul@0	1189
paul@0	1190	# Namespace modification.
paul@0	1191
paul@0	1192	def record_name(self, name):
paul@0	1193
paul@0	1194	"Record the use of 'name' in a namespace."
paul@0	1195
paul@0	1196	path = self.get_namespace_path()
paul@0	1197	init_item(self.names_used, path, set)
paul@0	1198	self.names_used[path].add(name)
paul@0	1199
paul@12	1200	def set_module(self, name, module_name):
paul@0	1201
paul@0	1202	"""
paul@12	1203	Set a module in the current namespace using the given 'name' associated
paul@12	1204	with the corresponding 'module_name'.
paul@0	1205	"""
paul@0	1206
paul@0	1207	if name:
paul@12	1208	self.set_general_local(name, Reference("<module>", module_name))
paul@0	1209
paul@0	1210	def set_definition(self, name, kind):
paul@0	1211
paul@0	1212	"""
paul@0	1213	Set the definition having the given 'name' and 'kind'.
paul@0	1214
paul@0	1215	Definitions are set in the static namespace hierarchy, but they can also
paul@0	1216	be recorded for function locals.
paul@0	1217	"""
paul@0	1218
paul@0	1219	if self.is_global(name):
paul@0	1220	print >>sys.stderr, "In %s, %s is defined as being global." % (
paul@0	1221	self.get_namespace_path(), name)
paul@0	1222
paul@0	1223	path = self.get_object_path(name)
paul@0	1224	self.set_object(path, kind)
paul@0	1225
paul@0	1226	ref = self.get_object(path)
paul@0	1227	if ref.get_kind() == "<var>":
paul@0	1228	print >>sys.stderr, "In %s, %s is defined more than once." % (
paul@0	1229	self.get_namespace_path(), name)
paul@0	1230
paul@0	1231	if not self.is_global(name) and self.in_function:
paul@0	1232	self.set_function_local(name, ref)
paul@0	1233
paul@0	1234	def set_function_local(self, name, ref=None):
paul@0	1235
paul@0	1236	"Set the local with the given 'name' and optional 'ref'."
paul@0	1237
paul@0	1238	locals = self.function_locals[self.get_namespace_path()]
paul@0	1239	multiple = not ref or locals.has_key(name) and locals[name] != ref
paul@0	1240	locals[name] = multiple and Reference("<var>") or ref
paul@0	1241
paul@0	1242	def assign_general_local(self, name, name_ref):
paul@0	1243
paul@0	1244	"""
paul@0	1245	Set for 'name' the given 'name_ref', recording the name for attribute
paul@0	1246	usage tracking.
paul@0	1247	"""
paul@0	1248
paul@0	1249	self.set_general_local(name, name_ref)
paul@0	1250	self.assign_name(name, name_ref)
paul@0	1251
paul@0	1252	def set_general_local(self, name, value=None):
paul@0	1253
paul@0	1254	"""
paul@0	1255	Set the 'name' with optional 'value' in any kind of local namespace,
paul@0	1256	where the 'value' should be a reference if specified.
paul@0	1257	"""
paul@0	1258
paul@0	1259	init_value = self.get_initialising_value(value)
paul@0	1260
paul@0	1261	# Module global names.
paul@0	1262
paul@0	1263	if self.is_global(name):
paul@0	1264	path = self.get_global_path(name)
paul@0	1265	self.set_object(path, init_value)
paul@0	1266
paul@0	1267	# Function local names.
paul@0	1268
paul@0	1269	elif self.in_function:
paul@0	1270	path = self.get_object_path(name)
paul@0	1271	self.set_function_local(name, init_value)
paul@0	1272
paul@0	1273	# Other namespaces (classes).
paul@0	1274
paul@0	1275	else:
paul@0	1276	path = self.get_object_path(name)
paul@0	1277	self.set_name(name, init_value)
paul@0	1278
paul@0	1279	def set_name(self, name, ref=None):
paul@0	1280
paul@0	1281	"Attach the 'name' with optional 'ref' to the current namespace."
paul@0	1282
paul@0	1283	self.set_object(self.get_object_path(name), ref)
paul@0	1284
paul@0	1285	def set_instance_attr(self, name, ref=None):
paul@0	1286
paul@0	1287	"""
paul@0	1288	Add an instance attribute of the given 'name' to the current class,
paul@0	1289	using the optional 'ref'.
paul@0	1290	"""
paul@0	1291
paul@251	1292	self._set_instance_attr(self.in_class, name, ref)
paul@251	1293
paul@251	1294	def _set_instance_attr(self, path, name, ref=None):
paul@251	1295
paul@251	1296	init_item(self.instance_attrs, path, set)
paul@251	1297	self.instance_attrs[path].add(name)
paul@0	1298
paul@0	1299	if ref:
paul@251	1300	init_item(self.instance_attr_constants, path, dict)
paul@251	1301	self.instance_attr_constants[path][name] = ref
paul@0	1302
paul@0	1303	def get_initialising_value(self, value):
paul@0	1304
paul@0	1305	"Return a suitable initialiser reference for 'value'."
paul@0	1306
paul@25	1307	# Includes LiteralSequenceRef, ResolvedNameRef...
paul@25	1308
paul@25	1309	if isinstance(value, (NameRef, AccessRef, InstanceRef)):
paul@0	1310	return value.reference()
paul@0	1311
paul@0	1312	# In general, invocations do not produce known results. However, the
paul@0	1313	# name initialisers are resolved once a module has been inspected.
paul@0	1314
paul@0	1315	elif isinstance(value, InvocationRef):
paul@27	1316	return value.reference()
paul@0	1317
paul@229	1318	# Variable references are unknown results.
paul@229	1319
paul@229	1320	elif isinstance(value, VariableRef):
paul@229	1321	return value.reference()
paul@229	1322
paul@0	1323	else:
paul@0	1324	return value
paul@0	1325
paul@0	1326	# Static, program-relative naming.
paul@0	1327
paul@0	1328	def find_name(self, name):
paul@0	1329
paul@0	1330	"""
paul@0	1331	Return the qualified name for the given 'name' used in the current
paul@0	1332	non-function namespace.
paul@0	1333	"""
paul@0	1334
paul@0	1335	path = self.get_namespace_path()
paul@0	1336	ref = None
paul@0	1337
paul@0	1338	if not self.in_function and name not in predefined_constants:
paul@0	1339	if self.in_class:
paul@152	1340	ref = self.get_object(self.get_object_path(name), False)
paul@0	1341	if not ref:
paul@0	1342	ref = self.get_global_or_builtin(name)
paul@0	1343
paul@0	1344	return ref
paul@0	1345
paul@0	1346	def get_class(self, node):
paul@0	1347
paul@0	1348	"""
paul@0	1349	Use the given 'node' to obtain the identity of a class. Return a
paul@0	1350	reference for the class. Unresolved dependencies are permitted and must
paul@0	1351	be resolved later.
paul@0	1352	"""
paul@0	1353
paul@0	1354	ref = self._get_class(node)
paul@0	1355	return ref.has_kind(["<class>", "<depends>"]) and ref or None
paul@0	1356
paul@0	1357	def _get_class(self, node):
paul@0	1358
paul@0	1359	"""
paul@0	1360	Use the given 'node' to find a class definition. Return a reference to
paul@0	1361	the class.
paul@0	1362	"""
paul@0	1363
paul@0	1364	if isinstance(node, compiler.ast.Getattr):
paul@0	1365
paul@0	1366	# Obtain the identity of the access target.
paul@0	1367
paul@0	1368	ref = self._get_class(node.expr)
paul@0	1369
paul@0	1370	# Where the target is a class or module, obtain the identity of the
paul@0	1371	# attribute.
paul@0	1372
paul@0	1373	if ref.has_kind(["<function>", "<var>"]):
paul@0	1374	return None
paul@0	1375	else:
paul@0	1376	attrname = "%s.%s" % (ref.get_origin(), node.attrname)
paul@0	1377	return self.get_object(attrname)
paul@0	1378
paul@0	1379	# Names can be module-level or built-in.
paul@0	1380
paul@0	1381	elif isinstance(node, compiler.ast.Name):
paul@0	1382
paul@0	1383	# Record usage of the name and attempt to identify it.
paul@0	1384
paul@0	1385	self.record_name(node.name)
paul@73	1386	return self.find_name(node.name)
paul@0	1387	else:
paul@0	1388	return None
paul@0	1389
paul@0	1390	def get_constant(self, name, value):
paul@0	1391
paul@0	1392	"Return a constant reference for the given type 'name' and 'value'."
paul@0	1393
paul@12	1394	ref = self.get_builtin_class(name)
paul@0	1395	return self.get_constant_reference(ref, value)
paul@0	1396
paul@405	1397	def get_literal_instance(self, n, name=None):
paul@0	1398
paul@405	1399	"""
paul@405	1400	For node 'n', return a reference to an instance of 'name', or if 'name'
paul@405	1401	is not specified, deduce the type from the value.
paul@405	1402	"""
paul@0	1403
paul@366	1404	# Handle stray None constants (Sliceobj seems to produce them).
paul@366	1405
paul@366	1406	if name == "NoneType":
paul@366	1407	return self.process_name_node(compiler.ast.Name("None"))
paul@366	1408
paul@0	1409	# Obtain the details of the literal itself.
paul@0	1410	# An alias to the type is generated for sequences.
paul@0	1411
paul@0	1412	if name in ("dict", "list", "tuple"):
paul@405	1413	ref = self.get_builtin_class(name)
paul@0	1414	self.set_special_literal(name, ref)
paul@0	1415	return self.process_literal_sequence_node(n, name, ref, LiteralSequenceRef)
paul@0	1416
paul@0	1417	# Constant values are independently recorded.
paul@0	1418
paul@0	1419	else:
paul@537	1420	value, typename, encoding = self.get_constant_value(n.value, n.literals)
paul@538	1421	ref = self.get_builtin_class(typename)
paul@406	1422	return self.get_constant_reference(ref, value, encoding)
paul@0	1423
paul@17	1424	# Special names.
paul@0	1425
paul@17	1426	def get_special(self, name):
paul@0	1427
paul@17	1428	"Return any stored value for the given special 'name'."
paul@0	1429
paul@423	1430	value = self.special.get(name)
paul@423	1431	if value:
paul@423	1432	ref, paths = value
paul@423	1433	else:
paul@423	1434	ref = None
paul@423	1435	return ref
paul@17	1436
paul@17	1437	def set_special(self, name, value):
paul@0	1438
paul@17	1439	"""
paul@17	1440	Set a special 'name' that merely tracks the use of an implicit object
paul@17	1441	'value'.
paul@17	1442	"""
paul@0	1443
paul@423	1444	if not self.special.has_key(name):
paul@423	1445	paths = set()
paul@423	1446	self.special[name] = value, paths
paul@423	1447	else:
paul@423	1448	_ref, paths = self.special[name]
paul@423	1449
paul@423	1450	paths.add(self.get_namespace_path())
paul@17	1451
paul@17	1452	def set_special_literal(self, name, ref):
paul@0	1453
paul@17	1454	"""
paul@17	1455	Set a special name for the literal type 'name' having type 'ref'. Such
paul@17	1456	special names provide a way of referring to literal object types.
paul@17	1457	"""
paul@0	1458
paul@17	1459	literal_name = "$L%s" % name
paul@17	1460	value = ResolvedNameRef(literal_name, ref)
paul@17	1461	self.set_special(literal_name, value)
paul@0	1462
paul@0	1463	# Functions and invocations.
paul@0	1464
paul@36	1465	def set_invocation_usage(self):
paul@36	1466
paul@36	1467	"""
paul@36	1468	Discard the current invocation storage figures, retaining the maximum
paul@36	1469	values.
paul@36	1470	"""
paul@36	1471
paul@36	1472	for path, (current, maximum) in self.function_targets.items():
paul@36	1473	self.importer.function_targets[path] = self.function_targets[path] = maximum
paul@36	1474
paul@36	1475	for path, (current, maximum) in self.function_arguments.items():
paul@36	1476	self.importer.function_arguments[path] = self.function_arguments[path] = maximum
paul@36	1477
paul@0	1478	def allocate_arguments(self, path, args):
paul@0	1479
paul@0	1480	"""
paul@0	1481	Allocate temporary argument storage using current and maximum
paul@0	1482	requirements for the given 'path' and 'args'.
paul@0	1483	"""
paul@0	1484
paul@192	1485	# Class and module initialisation is ultimately combined.
paul@192	1486
paul@192	1487	if not self.in_function:
paul@192	1488	path = self.name
paul@192	1489
paul@0	1490	init_item(self.function_targets, path, lambda: [0, 0])
paul@0	1491	t = self.function_targets[path]
paul@0	1492	t[0] += 1
paul@0	1493	t[1] = max(t[0], t[1])
paul@0	1494
paul@0	1495	init_item(self.function_arguments, path, lambda: [0, 0])
paul@0	1496	t = self.function_arguments[path]
paul@0	1497	t[0] += len(args) + 1
paul@0	1498	t[1] = max(t[0], t[1])
paul@0	1499
paul@0	1500	def deallocate_arguments(self, path, args):
paul@0	1501
paul@0	1502	"Deallocate temporary argument storage for the given 'path' and 'args'."
paul@0	1503
paul@192	1504	# Class and module initialisation is ultimately combined.
paul@192	1505
paul@192	1506	if not self.in_function:
paul@192	1507	path = self.name
paul@192	1508
paul@0	1509	self.function_targets[path][0] -= 1
paul@0	1510	self.function_arguments[path][0] -= len(args) + 1
paul@0	1511
paul@479	1512	# Exceptions.
paul@479	1513
paul@479	1514	def record_exception_handler(self):
paul@479	1515
paul@479	1516	"Record the current namespace as employing an exception handler."
paul@479	1517
paul@479	1518	self.exception_namespaces.add(self.get_namespace_path())
paul@479	1519
paul@0	1520	# vim: tabstop=4 expandtab shiftwidth=4