1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
|
"""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_ex(module [, path[, inpackage]])
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. (inpackage is used
internally to search for a submodule of a package.)
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.
XXX describe the Function class.
BUGS
- Nested classes and functions can confuse it.
PACKAGE RELATED BUGS
- If you have a package and a module inside that or another package
with the same name, module caching doesn't work properly since the
key is the base name of the module/package.
- The only entry that is returned when you readmodule a package is a
__path__ whose value is a list which confuses certain class browsers.
- When code does:
from package import subpackage
class MyClass(subpackage.SuperClass):
...
It can't locate the parent. It probably needs to have the same
hairy logic that the import locator already does. (This logic
exists coded in Python in the freeze package.)
"""
import sys
import imp
import tokenize # Python tokenizer
from token import NAME
__all__ = ["readmodule"]
_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
class Function(Class):
'''Class to represent a top-level Python function'''
def __init__(self, module, name, file, lineno):
Class.__init__(self, module, name, None, file, lineno)
def _addmethod(self, name, lineno):
assert 0, "Function._addmethod() shouldn't be called"
def readmodule(module, path=[], inpackage=False):
'''Backwards compatible interface.
Like readmodule_ex() but strips Function objects from the
resulting dictionary.'''
dict = readmodule_ex(module, path, inpackage)
res = {}
for key, value in dict.items():
if not isinstance(value, Function):
res[key] = value
return res
def readmodule_ex(module, path=[], inpackage=False):
'''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.'''
dict = {}
i = module.rfind('.')
if i >= 0:
# Dotted module name
package = module[:i].strip()
submodule = module[i+1:].strip()
parent = readmodule_ex(package, path, inpackage)
child = readmodule_ex(submodule, parent['__path__'], True)
return child
if module in _modules:
# we've seen this module before...
return _modules[module]
if module in sys.builtin_module_names:
# this is a built-in module
_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 = list(path) + sys.path
f, file, (suff, mode, type) = imp.find_module(module, fullpath)
if type == imp.PKG_DIRECTORY:
dict['__path__'] = [file]
_modules[module] = dict
path = [file] + path
f, file, (suff, mode, type) = \
imp.find_module('__init__', [file])
if type != imp.PY_SOURCE:
# not Python source, can't do anything with this module
f.close()
_modules[module] = dict
return dict
_modules[module] = dict
classstack = [] # stack of (class, indent) pairs
g = tokenize.generate_tokens(f.readline)
try:
for tokentype, token, start, end, line in g:
if token == 'def':
lineno, thisindent = start
tokentype, meth_name, start, end, line = g.next()
if tokentype != NAME:
continue # Syntax error
# close all classes indented at least as much
while classstack and \
classstack[-1][1] >= thisindent:
del classstack[-1]
if classstack:
# it's a class method
cur_class = classstack[-1][0]
cur_class._addmethod(meth_name, lineno)
else:
# it's a function
dict[meth_name] = Function(module, meth_name, file, lineno)
elif token == 'class':
lineno, thisindent = start
tokentype, class_name, start, end, line = g.next()
if tokentype != NAME:
continue # Syntax error
# close all classes indented at least as much
while classstack and \
classstack[-1][1] >= thisindent:
del classstack[-1]
# parse what follows the class name
tokentype, token, start, end, line = g.next()
inherit = None
if token == '(':
names = [] # List of superclasses
# there's a list of superclasses
level = 1
super = [] # Tokens making up current superclass
while True:
tokentype, token, start, end, line = g.next()
if token in (')', ',') and level == 1:
n = "".join(super)
if n in dict:
# we know this super class
n = dict[n]
else:
c = n.split('.')
if len(c) > 1:
# super class is of the form
# module.class: look in module for
# class
m = c[-2]
c = c[-1]
if m in _modules:
d = _modules[m]
if c in d:
n = d[c]
names.append(n)
if token == '(':
level += 1
elif token == ')':
level -= 1
if level == 0:
break
elif token == ',' and level == 1:
pass
else:
super.append(token)
inherit = names
cur_class = Class(module, class_name, inherit, file, lineno)
dict[class_name] = cur_class
classstack.append((cur_class, thisindent))
elif token == 'import' and start[1] == 0:
modules = _getnamelist(g)
for mod, mod2 in modules:
readmodule_ex(mod, path, inpackage)
elif token == 'from' and start[1] == 0:
mod, token = _getname(g)
if not mod or token != "import":
continue
names = _getnamelist(g)
try:
# recursively read the imported module
d = readmodule_ex(mod, path, inpackage)
except:
continue
# add any classes that were defined in the imported module
# to our name space if they were mentioned in the list
for n, n2 in names:
if n in d:
dict[n2 or 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:
if n[0] != '_' and not n in dict:
dict[n] = d[n]
except StopIteration:
pass
f.close()
return dict
def _getnamelist(g):
# Helper to get a comma-separated list of dotted names plus 'as'
# clauses. Return a list of pairs (name, name2) where name2 is
# the 'as' name, or None if there is no 'as' clause.
names = []
while True:
name, token = _getname(g)
if not name:
break
if token == 'as':
name2, token = _getname(g)
else:
name2 = None
names.append((name, name2))
while token != "," and "\n" not in token:
tokentype, token, start, end, line = g.next()
if token != ",":
break
return names
def _getname(g):
# Helper to get a dotted name, return a pair (name, token) where
# name is the dotted name, or None if there was no dotted name,
# and token is the next input token.
parts = []
tokentype, token, start, end, line = g.next()
if tokentype != NAME and token != '*':
return (None, token)
parts.append(token)
while True:
tokentype, token, start, end, line = g.next()
if token != '.':
break
tokentype, token, start, end, line = g.next()
if tokentype != NAME:
break
parts.append(token)
return (".".join(parts), token)
|
