'''Parse a Python file and retrieve classes and methods. Parse enough of a Python file to recognize class and method definitions and to find out the superclasses of a class. The interface consists of a single function: readmodule(module, path) module is the name of a Python module, 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 defined in the module (including classes that are defined via the from XXX import YYY construct). The values are class instances of the class Class defined here. A class is described by the class Class in this module. Instances of this class have the following instance variables: name -- the name of the class super -- a list of super classes (Class instances) methods -- a dictionary of methods file -- the file in which the class was defined lineno -- the line in the file on which the class statement occurred The dictionary of methods uses the method names as keys and the line numbers on which the method was defined as values. 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. BUGS Continuation lines are not dealt with at all and strings may confuse the hell out of the parser, but it usually works.''' import os import sys import imp import re import string id = '[A-Za-z_][A-Za-z0-9_]*' # match identifier blank_line = re.compile('^[ \t]*($|#)') is_class = re.compile('^class[ \t]+(?P'+id+')[ \t]*(?P\([^)]*\))?[ \t]*:') is_method = re.compile('^[ \t]+def[ \t]+(?P'+id+')[ \t]*\(') is_import = re.compile('^import[ \t]*(?P[^#]+)') is_from = re.compile('^from[ \t]+(?P'+id+'([ \t]*\\.[ \t]*'+id+')*)[ \t]+import[ \t]+(?P[^#]+)') dedent = re.compile('^[^ \t]') indent = re.compile('^[^ \t]*') _modules = {} # cache of modules we've seen # each Python class is represented by an instance of this class class Class: '''Class to represent a Python class.''' def __init__(self, module, name, super, file, lineno): self.module = module self.name = name if super is None: super = [] self.super = super self.methods = {} self.file = file self.lineno = lineno def _addmethod(self, name, lineno): self.methods[name] = lineno def readmodule(module, path=[], inpackage=0): '''Read a module file and return a dictionary of classes. Search for MODULE in PATH and sys.path, read and parse the module and return a dictionary with one entry for each class found in the module.''' i = string.rfind(module, '.') if i >= 0: # Dotted module name package = string.strip(module[:i]) submodule = string.strip(module[i+1:]) parent = readmodule(package, path, inpackage) child = readmodule(submodule, parent['__path__'], 1) return child if _modules.has_key(module): # we've seen this module before... return _modules[module] if module in sys.builtin_module_names: # this is a built-in module dict = {} _modules[module] = dict return dict # search the path for the module f = None if inpackage: try: f, file, (suff, mode, type) = \ imp.find_module(module, path) except ImportError: f = None if f is None: fullpath = path + sys.path f, file, (suff, mode, type) = imp.find_module(module, fullpath) if type == imp.PKG_DIRECTORY: dict = {'__path__': [file]} _modules[module] = dict # XXX Should we recursively look for submodules? return dict if type != imp.PY_SOURCE: # not Python source, can't do anything with this module f.close() dict = {} _modules[module] = dict return dict cur_class = None dict = {} _modules[module] = dict imports = [] lineno = 0 while 1: line = f.readline() if not line: break lineno = lineno + 1 # count lines line = line[:-1] # remove line feed if blank_line.match(line): # ignore blank (and comment only) lines continue ## res = indent.match(line) ## if res: ## indentation = len(string.expandtabs(res.group(0), 8)) res = is_import.match(line) if res: # import module for n in string.splitfields(res.group('imp'), ','): n = string.strip(n) try: # recursively read the # imported module d = readmodule(n, path, inpackage) except: print 'module',n,'not found' pass continue res = is_from.match(line) if res: # from module import stuff mod = res.group('module') names = string.splitfields(res.group('imp'), ',') try: # recursively read the imported module d = readmodule(mod, path, inpackage) except: print 'module',mod,'not found' continue # add any classes that were defined in the # imported module to our name space if they # were mentioned in the list for n in names: n = string.strip(n) if d.has_key(n): dict[n] = d[n] elif n == '*': # only add a name if not # already there (to mimic what # Python does internally) # also don't add names that # start with _ for n in d.keys(): if n[0] != '_' and \ not dict.has_key(n): dict[n] = d[n] continue res = is_class.match(line) if res: # we found a class definition class_name = res.group('id') inherit = res.group('sup') if inherit: # the class inherits from other classes inherit = string.strip(inherit[1:-1]) names = [] for n in string.splitfields(inherit, ','): n = string.strip(n) if dict.has_key(n): # we know this super class n = dict[n] else: c = string.splitfields(n, '.') if len(c) > 1: # super class # is of the # form module.class: # look in # module for class m = c[-2] c = c[-1] if _modules.has_key(m): d = _modules[m] if d.has_key(c): n = d[c] names.append(n) inherit = names # remember this class cur_class = Class(module, class_name, inherit, file, lineno) dict[class_name] = cur_class continue res = is_method.match(line) if res: # found a method definition if cur_class: # and we know the class it belongs to meth_name = res.group('id') cur_class._addmethod(meth_name, lineno) continue if dedent.match(line): # end of class definition cur_class = None f.close() return dict