Lib/pyclbr.py - platform/external/python/cpython3 - Gitiles

 """Parse a Python module and describe its classes and functions.

 Parse enough of a Python file to recognize imports and class and
 function definitions, and to find out the superclasses of a class.

 The interface consists of a single function:
     readmodule_ex(module, path=None)
 where module is the name of a Python module, and path is an optional
 list of directories where the module is to be searched.  If present,
 path is prepended to the system search path sys.path.  The return value
 is a dictionary.  The keys of the dictionary are the names of the
 classes and functions defined in the module (including classes that are
 defined via the from XXX import YYY construct).  The values are
 instances of classes Class and Function.  One special key/value pair is
 present for packages: the key '__path__' has a list as its value which
 contains the package search path.

 Classes and Functions have a common superclass: _Object.  Every instance
 has the following attributes:
     module  -- name of the module;
     name    -- name of the object;
     file    -- file in which the object is defined;
     lineno  -- line in the file where the object's definition starts;
     end_lineno -- line in the file where the object's definition ends;
     parent  -- parent of this object, if any;
     children -- nested objects contained in this object.
 The 'children' attribute is a dictionary mapping names to objects.

 Instances of Function describe functions with the attributes from _Object,
 plus the following:
     is_async -- if a function is defined with an 'async' prefix

 Instances of Class describe classes with the attributes from _Object,
 plus the following:
     super   -- list of super classes (Class instances if possible);
     methods -- mapping of method names to beginning line numbers.
 If the name of a super class is not recognized, the corresponding
 entry in the list of super classes is not a class instance but a
 string giving the name of the super class.  Since import statements
 are recognized and imported modules are scanned as well, this
 shouldn't happen often.
 """

 import ast
 import sys
 import importlib.util

 __all__ = ["readmodule", "readmodule_ex", "Class", "Function"]

 _modules = {}  # Initialize cache of modules we've seen.


 class _Object:
     "Information about Python class or function."
     def __init__(self, module, name, file, lineno, end_lineno, parent):
         self.module = module
         self.name = name
         self.file = file
         self.lineno = lineno
         self.end_lineno = end_lineno
         self.parent = parent
         self.children = {}
         if parent is not None:
             parent.children[name] = self


 # Odd Function and Class signatures are for back-compatibility.
 class Function(_Object):
     "Information about a Python function, including methods."
     def __init__(self, module, name, file, lineno,
                  parent=None, is_async=False, *, end_lineno=None):
         super().__init__(module, name, file, lineno, end_lineno, parent)
         self.is_async = is_async
         if isinstance(parent, Class):
             parent.methods[name] = lineno


 class Class(_Object):
     "Information about a Python class."
     def __init__(self, module, name, super_, file, lineno,
                  parent=None, *, end_lineno=None):
         super().__init__(module, name, file, lineno, end_lineno, parent)
         self.super = super_ or []
         self.methods = {}


 # These 2 functions are used in these tests
 # Lib/test/test_pyclbr, Lib/idlelib/idle_test/test_browser.py
 def _nest_function(ob, func_name, lineno, end_lineno, is_async=False):
     "Return a Function after nesting within ob."
     return Function(ob.module, func_name, ob.file, lineno,
                     parent=ob, is_async=is_async, end_lineno=end_lineno)

 def _nest_class(ob, class_name, lineno, end_lineno, super=None):
     "Return a Class after nesting within ob."
     return Class(ob.module, class_name, super, ob.file, lineno,
                  parent=ob, end_lineno=end_lineno)


 def readmodule(module, path=None):
     """Return Class objects for the top-level classes in module.

     This is the original interface, before Functions were added.
     """

     res = {}
     for key, value in _readmodule(module, path or []).items():
         if isinstance(value, Class):
             res[key] = value
     return res

 def readmodule_ex(module, path=None):
     """Return a dictionary with all functions and classes in module.

     Search for module in PATH + sys.path.
     If possible, include imported superclasses.
     Do this by reading source, without importing (and executing) it.
     """
     return _readmodule(module, path or [])


 def _readmodule(module, path, inpackage=None):
     """Do the hard work for readmodule[_ex].

     If inpackage is given, it must be the dotted name of the package in
     which we are searching for a submodule, and then PATH must be the
     package search path; otherwise, we are searching for a top-level
     module, and path is combined with sys.path.
     """
     # Compute the full module name (prepending inpackage if set).
     if inpackage is not None:
         fullmodule = "%s.%s" % (inpackage, module)
     else:
         fullmodule = module

     # Check in the cache.
     if fullmodule in _modules:
         return _modules[fullmodule]

     # Initialize the dict for this module's contents.
     tree = {}

     # Check if it is a built-in module; we don't do much for these.
     if module in sys.builtin_module_names and inpackage is None:
         _modules[module] = tree
         return tree

     # Check for a dotted module name.
     i = module.rfind('.')
     if i >= 0:
         package = module[:i]
         submodule = module[i+1:]
         parent = _readmodule(package, path, inpackage)
         if inpackage is not None:
             package = "%s.%s" % (inpackage, package)
         if not '__path__' in parent:
             raise ImportError('No package named {}'.format(package))
         return _readmodule(submodule, parent['__path__'], package)

     # Search the path for the module.
     f = None
     if inpackage is not None:
         search_path = path
     else:
         search_path = path + sys.path
     spec = importlib.util._find_spec_from_path(fullmodule, search_path)
     if spec is None:
         raise ModuleNotFoundError(f"no module named {fullmodule!r}", name=fullmodule)
     _modules[fullmodule] = tree
     # Is module a package?
     if spec.submodule_search_locations is not None:
         tree['__path__'] = spec.submodule_search_locations
     try:
         source = spec.loader.get_source(fullmodule)
     except (AttributeError, ImportError):
         # If module is not Python source, we cannot do anything.
         return tree
     else:
         if source is None:
             return tree

     fname = spec.loader.get_filename(fullmodule)
     return _create_tree(fullmodule, path, fname, source, tree, inpackage)


 class _ModuleBrowser(ast.NodeVisitor):
     def __init__(self, module, path, file, tree, inpackage):
         self.path = path
         self.tree = tree
         self.file = file
         self.module = module
         self.inpackage = inpackage
         self.stack = []

     def visit_ClassDef(self, node):
         bases = []
         for base in node.bases:
             name = ast.unparse(base)
             if name in self.tree:
                 # We know this super class.
                 bases.append(self.tree[name])
             elif len(names := name.split(".")) > 1:
                 # Super class form is module.class:
                 # look in module for class.
                 *_, module, class_ = names
                 if module in _modules:
                     bases.append(_modules[module].get(class_, name))
             else:
                 bases.append(name)

         parent = self.stack[-1] if self.stack else None
         class_ = Class(self.module, node.name, bases, self.file, node.lineno,
                        parent=parent, end_lineno=node.end_lineno)
         if parent is None:
             self.tree[node.name] = class_
         self.stack.append(class_)
         self.generic_visit(node)
         self.stack.pop()

     def visit_FunctionDef(self, node, *, is_async=False):
         parent = self.stack[-1] if self.stack else None
         function = Function(self.module, node.name, self.file, node.lineno,
                             parent, is_async, end_lineno=node.end_lineno)
         if parent is None:
             self.tree[node.name] = function
         self.stack.append(function)
         self.generic_visit(node)
         self.stack.pop()

     def visit_AsyncFunctionDef(self, node):
         self.visit_FunctionDef(node, is_async=True)

     def visit_Import(self, node):
         if node.col_offset != 0:
             return

         for module in node.names:
             try:
                 try:
                     _readmodule(module.name, self.path, self.inpackage)
                 except ImportError:
                     _readmodule(module.name, [])
             except (ImportError, SyntaxError):
                 # If we can't find or parse the imported module,
                 # too bad -- don't die here.
                 continue

     def visit_ImportFrom(self, node):
         if node.col_offset != 0:
             return
         try:
             module = "." * node.level
             if node.module:
                 module += node.module
             module = _readmodule(module, self.path, self.inpackage)
         except (ImportError, SyntaxError):
             return

         for name in node.names:
             if name.name in module:
                 self.tree[name.asname or name.name] = module[name.name]
             elif name.name == "*":
                 for import_name, import_value in module.items():
                     if import_name.startswith("_"):
                         continue
                     self.tree[import_name] = import_value


 def _create_tree(fullmodule, path, fname, source, tree, inpackage):
     mbrowser = _ModuleBrowser(fullmodule, path, fname, tree, inpackage)
     mbrowser.visit(ast.parse(source))
     return mbrowser.tree


 def _main():
     "Print module output (default this file) for quick visual check."
     import os
     try:
         mod = sys.argv[1]
     except:
         mod = __file__
     if os.path.exists(mod):
         path = [os.path.dirname(mod)]
         mod = os.path.basename(mod)
         if mod.lower().endswith(".py"):
             mod = mod[:-3]
     else:
         path = []
     tree = readmodule_ex(mod, path)
     lineno_key = lambda a: getattr(a, 'lineno', 0)
     objs = sorted(tree.values(), key=lineno_key, reverse=True)
     indent_level = 2
     while objs:
         obj = objs.pop()
         if isinstance(obj, list):
             # Value is a __path__ key.
             continue
         if not hasattr(obj, 'indent'):
             obj.indent = 0

         if isinstance(obj, _Object):
             new_objs = sorted(obj.children.values(),
                               key=lineno_key, reverse=True)
             for ob in new_objs:
                 ob.indent = obj.indent + indent_level
             objs.extend(new_objs)
         if isinstance(obj, Class):
             print("{}class {} {} {}"
                   .format(' ' * obj.indent, obj.name, obj.super, obj.lineno))
         elif isinstance(obj, Function):
             print("{}def {} {}".format(' ' * obj.indent, obj.name, obj.lineno))

 if __name__ == "__main__":
     _main()
	"""Parse a Python module and describe its classes and functions.

	Parse enough of a Python file to recognize imports and class and
	function definitions, and to find out the superclasses of a class.

	The interface consists of a single function:
	readmodule_ex(module, path=None)
	where module is the name of a Python module, and path is an optional
	list of directories where the module is to be searched. If present,
	path is prepended to the system search path sys.path. The return value
	is a dictionary. The keys of the dictionary are the names of the
	classes and functions defined in the module (including classes that are
	defined via the from XXX import YYY construct). The values are
	instances of classes Class and Function. One special key/value pair is
	present for packages: the key '__path__' has a list as its value which
	contains the package search path.

	Classes and Functions have a common superclass: _Object. Every instance
	has the following attributes:
	module -- name of the module;
	name -- name of the object;
	file -- file in which the object is defined;
	lineno -- line in the file where the object's definition starts;
	end_lineno -- line in the file where the object's definition ends;
	parent -- parent of this object, if any;
	children -- nested objects contained in this object.
	The 'children' attribute is a dictionary mapping names to objects.

	Instances of Function describe functions with the attributes from _Object,
	plus the following:
	is_async -- if a function is defined with an 'async' prefix

	Instances of Class describe classes with the attributes from _Object,
	plus the following:
	super -- list of super classes (Class instances if possible);
	methods -- mapping of method names to beginning line numbers.
	If the name of a super class is not recognized, the corresponding
	entry in the list of super classes is not a class instance but a
	string giving the name of the super class. Since import statements
	are recognized and imported modules are scanned as well, this
	shouldn't happen often.
	"""

	import ast
	import sys
	import importlib.util

	__all__ = ["readmodule", "readmodule_ex", "Class", "Function"]

	_modules = {} # Initialize cache of modules we've seen.


	class _Object:
	"Information about Python class or function."
	def __init__(self, module, name, file, lineno, end_lineno, parent):
	self.module = module
	self.name = name
	self.file = file
	self.lineno = lineno
	self.end_lineno = end_lineno
	self.parent = parent
	self.children = {}
	if parent is not None:
	parent.children[name] = self


	# Odd Function and Class signatures are for back-compatibility.
	class Function(_Object):
	"Information about a Python function, including methods."
	def __init__(self, module, name, file, lineno,
	parent=None, is_async=False, *, end_lineno=None):
	super().__init__(module, name, file, lineno, end_lineno, parent)
	self.is_async = is_async
	if isinstance(parent, Class):
	parent.methods[name] = lineno


	class Class(_Object):
	"Information about a Python class."
	def __init__(self, module, name, super_, file, lineno,
	parent=None, *, end_lineno=None):
	super().__init__(module, name, file, lineno, end_lineno, parent)
	self.super = super_ or []
	self.methods = {}


	# These 2 functions are used in these tests
	# Lib/test/test_pyclbr, Lib/idlelib/idle_test/test_browser.py
	def _nest_function(ob, func_name, lineno, end_lineno, is_async=False):
	"Return a Function after nesting within ob."
	return Function(ob.module, func_name, ob.file, lineno,
	parent=ob, is_async=is_async, end_lineno=end_lineno)

	def _nest_class(ob, class_name, lineno, end_lineno, super=None):
	"Return a Class after nesting within ob."
	return Class(ob.module, class_name, super, ob.file, lineno,
	parent=ob, end_lineno=end_lineno)


	def readmodule(module, path=None):
	"""Return Class objects for the top-level classes in module.

	This is the original interface, before Functions were added.
	"""

	res = {}
	for key, value in _readmodule(module, path or []).items():
	if isinstance(value, Class):
	res[key] = value
	return res

	def readmodule_ex(module, path=None):
	"""Return a dictionary with all functions and classes in module.

	Search for module in PATH + sys.path.
	If possible, include imported superclasses.
	Do this by reading source, without importing (and executing) it.
	"""
	return _readmodule(module, path or [])


	def _readmodule(module, path, inpackage=None):
	"""Do the hard work for readmodule[_ex].

	If inpackage is given, it must be the dotted name of the package in
	which we are searching for a submodule, and then PATH must be the
	package search path; otherwise, we are searching for a top-level
	module, and path is combined with sys.path.
	"""
	# Compute the full module name (prepending inpackage if set).
	if inpackage is not None:
	fullmodule = "%s.%s" % (inpackage, module)
	else:
	fullmodule = module

	# Check in the cache.
	if fullmodule in _modules:
	return _modules[fullmodule]

	# Initialize the dict for this module's contents.
	tree = {}

	# Check if it is a built-in module; we don't do much for these.
	if module in sys.builtin_module_names and inpackage is None:
	_modules[module] = tree
	return tree

	# Check for a dotted module name.
	i = module.rfind('.')
	if i >= 0:
	package = module[:i]
	submodule = module[i+1:]
	parent = _readmodule(package, path, inpackage)
	if inpackage is not None:
	package = "%s.%s" % (inpackage, package)
	if not '__path__' in parent:
	raise ImportError('No package named {}'.format(package))
	return _readmodule(submodule, parent['__path__'], package)

	# Search the path for the module.
	f = None
	if inpackage is not None:
	search_path = path
	else:
	search_path = path + sys.path
	spec = importlib.util._find_spec_from_path(fullmodule, search_path)
	if spec is None:
	raise ModuleNotFoundError(f"no module named {fullmodule!r}", name=fullmodule)
	_modules[fullmodule] = tree
	# Is module a package?
	if spec.submodule_search_locations is not None:
	tree['__path__'] = spec.submodule_search_locations
	try:
	source = spec.loader.get_source(fullmodule)
	except (AttributeError, ImportError):
	# If module is not Python source, we cannot do anything.
	return tree
	else:
	if source is None:
	return tree

	fname = spec.loader.get_filename(fullmodule)
	return _create_tree(fullmodule, path, fname, source, tree, inpackage)


	class _ModuleBrowser(ast.NodeVisitor):
	def __init__(self, module, path, file, tree, inpackage):
	self.path = path
	self.tree = tree
	self.file = file
	self.module = module
	self.inpackage = inpackage
	self.stack = []

	def visit_ClassDef(self, node):
	bases = []
	for base in node.bases:
	name = ast.unparse(base)
	if name in self.tree:
	# We know this super class.
	bases.append(self.tree[name])
	elif len(names := name.split(".")) > 1:
	# Super class form is module.class:
	# look in module for class.
	*_, module, class_ = names
	if module in _modules:
	bases.append(_modules[module].get(class_, name))
	else:
	bases.append(name)

	parent = self.stack[-1] if self.stack else None
	class_ = Class(self.module, node.name, bases, self.file, node.lineno,
	parent=parent, end_lineno=node.end_lineno)
	if parent is None:
	self.tree[node.name] = class_
	self.stack.append(class_)
	self.generic_visit(node)
	self.stack.pop()

	def visit_FunctionDef(self, node, *, is_async=False):
	parent = self.stack[-1] if self.stack else None
	function = Function(self.module, node.name, self.file, node.lineno,
	parent, is_async, end_lineno=node.end_lineno)
	if parent is None:
	self.tree[node.name] = function
	self.stack.append(function)
	self.generic_visit(node)
	self.stack.pop()

	def visit_AsyncFunctionDef(self, node):
	self.visit_FunctionDef(node, is_async=True)

	def visit_Import(self, node):
	if node.col_offset != 0:
	return

	for module in node.names:
	try:
	try:
	_readmodule(module.name, self.path, self.inpackage)
	except ImportError:
	_readmodule(module.name, [])
	except (ImportError, SyntaxError):
	# If we can't find or parse the imported module,
	# too bad -- don't die here.
	continue

	def visit_ImportFrom(self, node):
	if node.col_offset != 0:
	return
	try:
	module = "." * node.level
	if node.module:
	module += node.module
	module = _readmodule(module, self.path, self.inpackage)
	except (ImportError, SyntaxError):
	return

	for name in node.names:
	if name.name in module:
	self.tree[name.asname or name.name] = module[name.name]
	elif name.name == "*":
	for import_name, import_value in module.items():
	if import_name.startswith("_"):
	continue
	self.tree[import_name] = import_value


	def _create_tree(fullmodule, path, fname, source, tree, inpackage):
	mbrowser = _ModuleBrowser(fullmodule, path, fname, tree, inpackage)
	mbrowser.visit(ast.parse(source))
	return mbrowser.tree


	def _main():
	"Print module output (default this file) for quick visual check."
	import os
	try:
	mod = sys.argv[1]
	except:
	mod = __file__
	if os.path.exists(mod):
	path = [os.path.dirname(mod)]
	mod = os.path.basename(mod)
	if mod.lower().endswith(".py"):
	mod = mod[:-3]
	else:
	path = []
	tree = readmodule_ex(mod, path)
	lineno_key = lambda a: getattr(a, 'lineno', 0)
	objs = sorted(tree.values(), key=lineno_key, reverse=True)
	indent_level = 2
	while objs:
	obj = objs.pop()
	if isinstance(obj, list):
	# Value is a __path__ key.
	continue
	if not hasattr(obj, 'indent'):
	obj.indent = 0

	if isinstance(obj, _Object):
	new_objs = sorted(obj.children.values(),
	key=lineno_key, reverse=True)
	for ob in new_objs:
	ob.indent = obj.indent + indent_level
	objs.extend(new_objs)
	if isinstance(obj, Class):
	print("{}class {} {} {}"
	.format(' ' * obj.indent, obj.name, obj.super, obj.lineno))
	elif isinstance(obj, Function):
	print("{}def {} {}".format(' ' * obj.indent, obj.name, obj.lineno))

	if __name__ == "__main__":
	_main()