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Viewing changes to bzrlib/tests/test_graph.py

  • Committer: Martin Pool
  • Date: 2005-05-09 04:38:31 UTC
  • Revision ID: mbp@sourcefrog.net-20050509043831-d45f7832b7d4d5b0
- better message when refusing to add symlinks (from mpe)

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bzrlib/tests/test_graph.py
1
 
# Copyright (C) 2007 Canonical Ltd
2
 
#
3
 
# This program is free software; you can redistribute it and/or modify
4
 
# it under the terms of the GNU General Public License as published by
5
 
# the Free Software Foundation; either version 2 of the License, or
6
 
# (at your option) any later version.
7
 
#
8
 
# This program is distributed in the hope that it will be useful,
9
 
# but WITHOUT ANY WARRANTY; without even the implied warranty of
10
 
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
11
 
# GNU General Public License for more details.
12
 
#
13
 
# You should have received a copy of the GNU General Public License
14
 
# along with this program; if not, write to the Free Software
15
 
# Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307  USA
16
 
 
17
 
from bzrlib import (
18
 
    errors,
19
 
    graph as _mod_graph,
20
 
    )
21
 
from bzrlib.revision import NULL_REVISION
22
 
from bzrlib.tests import TestCaseWithMemoryTransport
23
 
 
24
 
 
25
 
# Ancestry 1:
26
 
#
27
 
#  NULL_REVISION
28
 
#       |
29
 
#     rev1
30
 
#      /\
31
 
#  rev2a rev2b
32
 
#     |    |
33
 
#   rev3  /
34
 
#     |  /
35
 
#   rev4
36
 
ancestry_1 = {'rev1': [NULL_REVISION], 'rev2a': ['rev1'], 'rev2b': ['rev1'],
37
 
              'rev3': ['rev2a'], 'rev4': ['rev3', 'rev2b']}
38
 
 
39
 
 
40
 
# Ancestry 2:
41
 
#
42
 
#  NULL_REVISION
43
 
#    /    \
44
 
# rev1a  rev1b
45
 
#   |
46
 
# rev2a
47
 
#   |
48
 
# rev3a
49
 
#   |
50
 
# rev4a
51
 
ancestry_2 = {'rev1a': [NULL_REVISION], 'rev2a': ['rev1a'],
52
 
              'rev1b': [NULL_REVISION], 'rev3a': ['rev2a'], 'rev4a': ['rev3a']}
53
 
 
54
 
 
55
 
# Criss cross ancestry
56
 
#
57
 
#     NULL_REVISION
58
 
#         |
59
 
#        rev1
60
 
#        /  \
61
 
#    rev2a  rev2b
62
 
#       |\  /|
63
 
#       |  X |
64
 
#       |/  \|
65
 
#    rev3a  rev3b
66
 
criss_cross = {'rev1': [NULL_REVISION], 'rev2a': ['rev1'], 'rev2b': ['rev1'],
67
 
               'rev3a': ['rev2a', 'rev2b'], 'rev3b': ['rev2b', 'rev2a']}
68
 
 
69
 
 
70
 
# Criss-cross 2
71
 
#
72
 
#  NULL_REVISION
73
 
#    /   \
74
 
# rev1a  rev1b
75
 
#   |\   /|
76
 
#   | \ / |
77
 
#   |  X  |
78
 
#   | / \ |
79
 
#   |/   \|
80
 
# rev2a  rev2b
81
 
criss_cross2 = {'rev1a': [NULL_REVISION], 'rev1b': [NULL_REVISION],
82
 
                'rev2a': ['rev1a', 'rev1b'], 'rev2b': ['rev1b', 'rev1a']}
83
 
 
84
 
 
85
 
# Mainline:
86
 
#
87
 
#  NULL_REVISION
88
 
#       |
89
 
#      rev1
90
 
#      /  \
91
 
#      | rev2b
92
 
#      |  /
93
 
#     rev2a
94
 
mainline = {'rev1': [NULL_REVISION], 'rev2a': ['rev1', 'rev2b'],
95
 
            'rev2b': ['rev1']}
96
 
 
97
 
 
98
 
# feature branch:
99
 
#
100
 
#  NULL_REVISION
101
 
#       |
102
 
#      rev1
103
 
#       |
104
 
#     rev2b
105
 
#       |
106
 
#     rev3b
107
 
feature_branch = {'rev1': [NULL_REVISION],
108
 
                  'rev2b': ['rev1'], 'rev3b': ['rev2b']}
109
 
 
110
 
 
111
 
# History shortcut
112
 
#  NULL_REVISION
113
 
#       |
114
 
#     rev1------
115
 
#     /  \      \
116
 
#  rev2a rev2b rev2c
117
 
#    |  /   \   /
118
 
#  rev3a    reveb
119
 
history_shortcut = {'rev1': [NULL_REVISION], 'rev2a': ['rev1'],
120
 
                    'rev2b': ['rev1'], 'rev2c': ['rev1'],
121
 
                    'rev3a': ['rev2a', 'rev2b'], 'rev3b': ['rev2b', 'rev2c']}
122
 
 
123
 
#  NULL_REVISION
124
 
#       |
125
 
#       f
126
 
#       |
127
 
#       e
128
 
#      / \
129
 
#     b   d
130
 
#     | \ |
131
 
#     a   c
132
 
 
133
 
boundary = {'a': ['b'], 'c': ['b', 'd'], 'b':['e'], 'd':['e'], 'e': ['f'],
134
 
            'f':[NULL_REVISION]}
135
 
 
136
 
 
137
 
class InstrumentedParentsProvider(object):
138
 
 
139
 
    def __init__(self, parents_provider):
140
 
        self.calls = []
141
 
        self._real_parents_provider = parents_provider
142
 
 
143
 
    def get_parents(self, nodes):
144
 
        self.calls.extend(nodes)
145
 
        return self._real_parents_provider.get_parents(nodes)
146
 
 
147
 
 
148
 
class DictParentsProvider(object):
149
 
 
150
 
    def __init__(self, ancestry):
151
 
        self.ancestry = ancestry
152
 
 
153
 
    def __repr__(self):
154
 
        return 'DictParentsProvider(%r)' % self.ancestry
155
 
 
156
 
    def get_parents(self, revisions):
157
 
        return [self.ancestry.get(r, None) for r in revisions]
158
 
 
159
 
 
160
 
class TestGraph(TestCaseWithMemoryTransport):
161
 
 
162
 
    def make_graph(self, ancestors):
163
 
        tree = self.prepare_memory_tree('.')
164
 
        self.build_ancestry(tree, ancestors)
165
 
        tree.unlock()
166
 
        return tree.branch.repository.get_graph()
167
 
 
168
 
    def prepare_memory_tree(self, location):
169
 
        tree = self.make_branch_and_memory_tree(location)
170
 
        tree.lock_write()
171
 
        tree.add('.')
172
 
        return tree
173
 
 
174
 
    def build_ancestry(self, tree, ancestors):
175
 
        """Create an ancestry as specified by a graph dict
176
 
 
177
 
        :param tree: A tree to use
178
 
        :param ancestors: a dict of {node: [node_parent, ...]}
179
 
        """
180
 
        pending = [NULL_REVISION]
181
 
        descendants = {}
182
 
        for descendant, parents in ancestors.iteritems():
183
 
            for parent in parents:
184
 
                descendants.setdefault(parent, []).append(descendant)
185
 
        while len(pending) > 0:
186
 
            cur_node = pending.pop()
187
 
            for descendant in descendants.get(cur_node, []):
188
 
                if tree.branch.repository.has_revision(descendant):
189
 
                    continue
190
 
                parents = [p for p in ancestors[descendant] if p is not
191
 
                           NULL_REVISION]
192
 
                if len([p for p in parents if not
193
 
                    tree.branch.repository.has_revision(p)]) > 0:
194
 
                    continue
195
 
                tree.set_parent_ids(parents)
196
 
                if len(parents) > 0:
197
 
                    left_parent = parents[0]
198
 
                else:
199
 
                    left_parent = NULL_REVISION
200
 
                tree.branch.set_last_revision_info(
201
 
                    len(tree.branch._lefthand_history(left_parent)),
202
 
                    left_parent)
203
 
                tree.commit(descendant, rev_id=descendant)
204
 
                pending.append(descendant)
205
 
 
206
 
    def test_lca(self):
207
 
        """Test finding least common ancestor.
208
 
 
209
 
        ancestry_1 should always have a single common ancestor
210
 
        """
211
 
        graph = self.make_graph(ancestry_1)
212
 
        self.assertRaises(errors.InvalidRevisionId, graph.find_lca, None)
213
 
        self.assertEqual(set([NULL_REVISION]),
214
 
                         graph.find_lca(NULL_REVISION, NULL_REVISION))
215
 
        self.assertEqual(set([NULL_REVISION]),
216
 
                         graph.find_lca(NULL_REVISION, 'rev1'))
217
 
        self.assertEqual(set(['rev1']), graph.find_lca('rev1', 'rev1'))
218
 
        self.assertEqual(set(['rev1']), graph.find_lca('rev2a', 'rev2b'))
219
 
 
220
 
    def test_no_unique_lca(self):
221
 
        """Test error when one revision is not in the graph"""
222
 
        graph = self.make_graph(ancestry_1)
223
 
        self.assertRaises(errors.NoCommonAncestor, graph.find_unique_lca,
224
 
                          'rev1', '1rev')
225
 
 
226
 
    def test_lca_criss_cross(self):
227
 
        """Test least-common-ancestor after a criss-cross merge."""
228
 
        graph = self.make_graph(criss_cross)
229
 
        self.assertEqual(set(['rev2a', 'rev2b']),
230
 
                         graph.find_lca('rev3a', 'rev3b'))
231
 
        self.assertEqual(set(['rev2b']),
232
 
                         graph.find_lca('rev3a', 'rev3b', 'rev2b'))
233
 
 
234
 
    def test_lca_shortcut(self):
235
 
        """Test least-common ancestor on this history shortcut"""
236
 
        graph = self.make_graph(history_shortcut)
237
 
        self.assertEqual(set(['rev2b']), graph.find_lca('rev3a', 'rev3b'))
238
 
 
239
 
    def test_recursive_unique_lca(self):
240
 
        """Test finding a unique least common ancestor.
241
 
 
242
 
        ancestry_1 should always have a single common ancestor
243
 
        """
244
 
        graph = self.make_graph(ancestry_1)
245
 
        self.assertEqual(NULL_REVISION,
246
 
                         graph.find_unique_lca(NULL_REVISION, NULL_REVISION))
247
 
        self.assertEqual(NULL_REVISION,
248
 
                         graph.find_unique_lca(NULL_REVISION, 'rev1'))
249
 
        self.assertEqual('rev1', graph.find_unique_lca('rev1', 'rev1'))
250
 
        self.assertEqual('rev1', graph.find_unique_lca('rev2a', 'rev2b'))
251
 
 
252
 
    def test_unique_lca_criss_cross(self):
253
 
        """Ensure we don't pick non-unique lcas in a criss-cross"""
254
 
        graph = self.make_graph(criss_cross)
255
 
        self.assertEqual('rev1', graph.find_unique_lca('rev3a', 'rev3b'))
256
 
 
257
 
    def test_unique_lca_null_revision(self):
258
 
        """Ensure we pick NULL_REVISION when necessary"""
259
 
        graph = self.make_graph(criss_cross2)
260
 
        self.assertEqual('rev1b', graph.find_unique_lca('rev2a', 'rev1b'))
261
 
        self.assertEqual(NULL_REVISION,
262
 
                         graph.find_unique_lca('rev2a', 'rev2b'))
263
 
 
264
 
    def test_unique_lca_null_revision2(self):
265
 
        """Ensure we pick NULL_REVISION when necessary"""
266
 
        graph = self.make_graph(ancestry_2)
267
 
        self.assertEqual(NULL_REVISION,
268
 
                         graph.find_unique_lca('rev4a', 'rev1b'))
269
 
 
270
 
    def test_common_ancestor_two_repos(self):
271
 
        """Ensure we do unique_lca using data from two repos"""
272
 
        mainline_tree = self.prepare_memory_tree('mainline')
273
 
        self.build_ancestry(mainline_tree, mainline)
274
 
        mainline_tree.unlock()
275
 
 
276
 
        # This is cheating, because the revisions in the graph are actually
277
 
        # different revisions, despite having the same revision-id.
278
 
        feature_tree = self.prepare_memory_tree('feature')
279
 
        self.build_ancestry(feature_tree, feature_branch)
280
 
        feature_tree.unlock()
281
 
        graph = mainline_tree.branch.repository.get_graph(
282
 
            feature_tree.branch.repository)
283
 
        self.assertEqual('rev2b', graph.find_unique_lca('rev2a', 'rev3b'))
284
 
 
285
 
    def test_graph_difference(self):
286
 
        graph = self.make_graph(ancestry_1)
287
 
        self.assertEqual((set(), set()), graph.find_difference('rev1', 'rev1'))
288
 
        self.assertEqual((set(), set(['rev1'])),
289
 
                         graph.find_difference(NULL_REVISION, 'rev1'))
290
 
        self.assertEqual((set(['rev1']), set()),
291
 
                         graph.find_difference('rev1', NULL_REVISION))
292
 
        self.assertEqual((set(['rev2a', 'rev3']), set(['rev2b'])),
293
 
                         graph.find_difference('rev3', 'rev2b'))
294
 
        self.assertEqual((set(['rev4', 'rev3', 'rev2a']), set()),
295
 
                         graph.find_difference('rev4', 'rev2b'))
296
 
 
297
 
    def test_graph_difference_criss_cross(self):
298
 
        graph = self.make_graph(criss_cross)
299
 
        self.assertEqual((set(['rev3a']), set(['rev3b'])),
300
 
                         graph.find_difference('rev3a', 'rev3b'))
301
 
        self.assertEqual((set([]), set(['rev3b', 'rev2b'])),
302
 
                         graph.find_difference('rev2a', 'rev3b'))
303
 
 
304
 
    def test_stacked_parents_provider(self):
305
 
 
306
 
        parents1 = DictParentsProvider({'rev2': ['rev3']})
307
 
        parents2 = DictParentsProvider({'rev1': ['rev4']})
308
 
        stacked = _mod_graph._StackedParentsProvider([parents1, parents2])
309
 
        self.assertEqual([['rev4',], ['rev3']],
310
 
                         stacked.get_parents(['rev1', 'rev2']))
311
 
        self.assertEqual([['rev3',], ['rev4']],
312
 
                         stacked.get_parents(['rev2', 'rev1']))
313
 
        self.assertEqual([['rev3',], ['rev3']],
314
 
                         stacked.get_parents(['rev2', 'rev2']))
315
 
        self.assertEqual([['rev4',], ['rev4']],
316
 
                         stacked.get_parents(['rev1', 'rev1']))
317
 
 
318
 
    def test_iter_topo_order(self):
319
 
        graph = self.make_graph(ancestry_1)
320
 
        args = ['rev2a', 'rev3', 'rev1']
321
 
        topo_args = list(graph.iter_topo_order(args))
322
 
        self.assertEqual(set(args), set(topo_args))
323
 
        self.assertTrue(topo_args.index('rev2a') > topo_args.index('rev1'))
324
 
        self.assertTrue(topo_args.index('rev2a') < topo_args.index('rev3'))
325
 
 
326
 
    def test_is_ancestor(self):
327
 
        graph = self.make_graph(ancestry_1)
328
 
        self.assertEqual(True, graph.is_ancestor('null:', 'null:'))
329
 
        self.assertEqual(True, graph.is_ancestor('null:', 'rev1'))
330
 
        self.assertEqual(False, graph.is_ancestor('rev1', 'null:'))
331
 
        self.assertEqual(True, graph.is_ancestor('null:', 'rev4'))
332
 
        self.assertEqual(False, graph.is_ancestor('rev4', 'null:'))
333
 
        self.assertEqual(False, graph.is_ancestor('rev4', 'rev2b'))
334
 
        self.assertEqual(True, graph.is_ancestor('rev2b', 'rev4'))
335
 
        self.assertEqual(False, graph.is_ancestor('rev2b', 'rev3'))
336
 
        self.assertEqual(False, graph.is_ancestor('rev3', 'rev2b'))
337
 
        instrumented_provider = InstrumentedParentsProvider(graph)
338
 
        instrumented_graph = _mod_graph.Graph(instrumented_provider)
339
 
        instrumented_graph.is_ancestor('rev2a', 'rev2b')
340
 
        self.assertTrue('null:' not in instrumented_provider.calls)
341
 
 
342
 
    def test_is_ancestor_boundary(self):
343
 
        """Ensure that we avoid searching the whole graph.
344
 
        
345
 
        This requires searching through b as a common ancestor, so we
346
 
        can identify that e is common.
347
 
        """
348
 
        graph = self.make_graph(boundary)
349
 
        instrumented_provider = InstrumentedParentsProvider(graph)
350
 
        graph = _mod_graph.Graph(instrumented_provider)
351
 
        self.assertFalse(graph.is_ancestor('a', 'c'))
352
 
        self.assertTrue('null:' not in instrumented_provider.calls)
353
 
 
354
 
    def test_filter_candidate_lca(self):
355
 
        """Test filter_candidate_lca for a corner case
356
 
 
357
 
        This tests the case where we encounter the end of iteration for 'e'
358
 
        in the same pass as we discover that 'd' is an ancestor of 'e', and
359
 
        therefore 'e' can't be an lca.
360
 
 
361
 
        To compensate for different dict orderings on other Python
362
 
        implementations, we mirror 'd' and 'e' with 'b' and 'a'.
363
 
        """
364
 
        # This test is sensitive to the iteration order of dicts.  It will
365
 
        # pass incorrectly if 'e' and 'a' sort before 'c'
366
 
        #
367
 
        # NULL_REVISION
368
 
        #     / \
369
 
        #    a   e
370
 
        #    |   |
371
 
        #    b   d
372
 
        #     \ /
373
 
        #      c
374
 
        graph = self.make_graph({'c': ['b', 'd'], 'd': ['e'], 'b': ['a'],
375
 
                                 'a': [NULL_REVISION], 'e': [NULL_REVISION]})
376
 
        self.assertEqual(set(['c']), graph.heads(['a', 'c', 'e']))
377
 
 
378
 
    def test_heads_null(self):
379
 
        graph = self.make_graph(ancestry_1)
380
 
        self.assertEqual(set(['null:']), graph.heads(['null:']))
381
 
        self.assertEqual(set(['rev1']), graph.heads(['null:', 'rev1']))
382
 
        self.assertEqual(set(['rev1']), graph.heads(['rev1', 'null:']))
383
 
        self.assertEqual(set(['rev1']), graph.heads(set(['rev1', 'null:'])))
384
 
        self.assertEqual(set(['rev1']), graph.heads(('rev1', 'null:')))
385
 
 
386
 
    def test_heads_one(self):
387
 
        # A single node will alwaya be a head
388
 
        graph = self.make_graph(ancestry_1)
389
 
        self.assertEqual(set(['null:']), graph.heads(['null:']))
390
 
        self.assertEqual(set(['rev1']), graph.heads(['rev1']))
391
 
        self.assertEqual(set(['rev2a']), graph.heads(['rev2a']))
392
 
        self.assertEqual(set(['rev2b']), graph.heads(['rev2b']))
393
 
        self.assertEqual(set(['rev3']), graph.heads(['rev3']))
394
 
        self.assertEqual(set(['rev4']), graph.heads(['rev4']))
395
 
 
396
 
    def test_heads_single(self):
397
 
        graph = self.make_graph(ancestry_1)
398
 
        self.assertEqual(set(['rev4']), graph.heads(['null:', 'rev4']))
399
 
        self.assertEqual(set(['rev2a']), graph.heads(['rev1', 'rev2a']))
400
 
        self.assertEqual(set(['rev2b']), graph.heads(['rev1', 'rev2b']))
401
 
        self.assertEqual(set(['rev3']), graph.heads(['rev1', 'rev3']))
402
 
        self.assertEqual(set(['rev4']), graph.heads(['rev1', 'rev4']))
403
 
        self.assertEqual(set(['rev4']), graph.heads(['rev2a', 'rev4']))
404
 
        self.assertEqual(set(['rev4']), graph.heads(['rev2b', 'rev4']))
405
 
        self.assertEqual(set(['rev4']), graph.heads(['rev3', 'rev4']))
406
 
 
407
 
    def test_heads_two_heads(self):
408
 
        graph = self.make_graph(ancestry_1)
409
 
        self.assertEqual(set(['rev2a', 'rev2b']),
410
 
                         graph.heads(['rev2a', 'rev2b']))
411
 
        self.assertEqual(set(['rev3', 'rev2b']),
412
 
                         graph.heads(['rev3', 'rev2b']))
413
 
 
414
 
    def test_heads_criss_cross(self):
415
 
        graph = self.make_graph(criss_cross)
416
 
        self.assertEqual(set(['rev2a']),
417
 
                         graph.heads(['rev2a', 'rev1']))
418
 
        self.assertEqual(set(['rev2b']),
419
 
                         graph.heads(['rev2b', 'rev1']))
420
 
        self.assertEqual(set(['rev3a']),
421
 
                         graph.heads(['rev3a', 'rev1']))
422
 
        self.assertEqual(set(['rev3b']),
423
 
                         graph.heads(['rev3b', 'rev1']))
424
 
        self.assertEqual(set(['rev2a', 'rev2b']),
425
 
                         graph.heads(['rev2a', 'rev2b']))
426
 
        self.assertEqual(set(['rev3a']),
427
 
                         graph.heads(['rev3a', 'rev2a']))
428
 
        self.assertEqual(set(['rev3a']),
429
 
                         graph.heads(['rev3a', 'rev2b']))
430
 
        self.assertEqual(set(['rev3a']),
431
 
                         graph.heads(['rev3a', 'rev2a', 'rev2b']))
432
 
        self.assertEqual(set(['rev3b']),
433
 
                         graph.heads(['rev3b', 'rev2a']))
434
 
        self.assertEqual(set(['rev3b']),
435
 
                         graph.heads(['rev3b', 'rev2b']))
436
 
        self.assertEqual(set(['rev3b']),
437
 
                         graph.heads(['rev3b', 'rev2a', 'rev2b']))
438
 
        self.assertEqual(set(['rev3a', 'rev3b']),
439
 
                         graph.heads(['rev3a', 'rev3b']))
440
 
        self.assertEqual(set(['rev3a', 'rev3b']),
441
 
                         graph.heads(['rev3a', 'rev3b', 'rev2a', 'rev2b']))
442
 
 
443
 
    def test_heads_shortcut(self):
444
 
        graph = self.make_graph(history_shortcut)
445
 
 
446
 
        self.assertEqual(set(['rev2a', 'rev2b', 'rev2c']),
447
 
                         graph.heads(['rev2a', 'rev2b', 'rev2c']))
448
 
        self.assertEqual(set(['rev3a', 'rev3b']),
449
 
                         graph.heads(['rev3a', 'rev3b']))
450
 
        self.assertEqual(set(['rev3a', 'rev3b']),
451
 
                         graph.heads(['rev2a', 'rev3a', 'rev3b']))
452
 
        self.assertEqual(set(['rev2a', 'rev3b']),
453
 
                         graph.heads(['rev2a', 'rev3b']))
454
 
        self.assertEqual(set(['rev2c', 'rev3a']),
455
 
                         graph.heads(['rev2c', 'rev3a']))