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- Committer: Gary van der Merwe
- Date: 2007-09-22 20:32:05 UTC
- mto: (256.2.56 gtk)
- mto: This revision was merged to the branch mainline in revision 289.
- Revision ID: garyvdm@gmail.com-20070922203205-wggmp778irmwqo03
Use fixed-height-mode on treeview so that revisions data is only
read off the disk when it is scrolled into view.
read off the disk when it is scrolled into view.
- files added:
- tests/test_viz.py
- files removed:
- branchview
- preferences
- files renamed:
- icons/bzr-icon-64.png => bzr-icon-64.png
- revisionview.py => logview.py
- preferences/__init__.py => preferences.py
- branchview/graphcell.py => viz/graphcell.py
- branchview/linegraph.py => viz/linegraph.py
- branchview/treemodel.py => viz/treemodel.py
- files modified:
- AUTHORS
added
removed
viz/linegraph.py
1
# -*- coding: UTF-8 -*-
2
"""Directed graph production.
3
4
This module contains the code to produce an ordered directed graph of a
5
bzr branch, such as we display in the tree view at the top of the bzrk
6
window.
7
"""
8
9
__copyright__ = "Copyright © 2005 Canonical Ltd."
10
__author__ = "Scott James Remnant <scott@ubuntu.com>"
11
12
from bzrlib.revision import NULL_REVISION
13
from bzrlib.tsort import merge_sort
14
15
def linegraph(graph, start_revs, maxnum=None, broken_line_length=None,
16
graph_data=True, mainline_only=False):
17
"""Produce a directed graph of a bzr repository.
18
19
Returns a tuple of (line_graph, revid_index, columns_len) where
20
* line_graph is a list of tuples of (revid,
21
node,
22
lines,
23
parents,
24
children,
25
revno_sequence),
26
* revid_index is a dict of each revision with the key being the revid, and
27
the value the row index, and
28
* columns_len is the number of columns need to draw the line graph.
29
30
31
Node is a tuple of (column, colour) with column being a zero-indexed
32
column number of the graph that this revision represents and colour
33
being a zero-indexed colour (which doesn't specify any actual colour
34
in particular) to draw the node in.
35
36
Lines is a list of tuples which represent lines you should draw away
37
from the revision, if you also need to draw lines into the revision
38
you should use the lines list from the previous iteration. Each
39
typle in the list is in the form (start, end, colour) with start and
40
end being zero-indexed column numbers and colour as in node.
41
42
It's up to you how to actually draw the nodes and lines (straight,
43
curved, kinked, etc.) and to pick the actual colours for each index.
44
"""
45
46
graph_parents = {}
47
ghosts = set()
48
graph_children = {}
49
for (revid, parent_revids) in graph.iter_ancestry(start_revs):
50
if parent_revids is None:
51
ghosts.add(revid)
52
continue
53
if parent_revids == (NULL_REVISION,):
54
graph_parents[revid] = ()
55
else:
56
graph_parents[revid] = parent_revids
57
for parent in parent_revids:
58
graph_children.setdefault(parent, []).append(revid)
59
graph_children.setdefault(revid, [])
60
for ghost in ghosts:
61
for ghost_child in graph_children[ghost]:
62
graph_parents[ghost_child] = [p for p in graph_parents[ghost_child]
63
if p not in ghosts]
64
graph_parents["top:"] = start_revs
65
66
if len(graph_parents)>0:
67
merge_sorted_revisions = merge_sort(
68
graph_parents,
69
"top:",
70
generate_revno=True)
71
else:
72
merge_sorted_revisions = ()
73
74
if mainline_only:
75
merge_sorted_revisions = [elem for elem in merge_sorted_revisions \
76
if len(elem[3])==1 ]
77
78
assert merge_sorted_revisions[0][1] == "top:"
79
merge_sorted_revisions = merge_sorted_revisions[1:]
80
81
revid_index = {}
82
revno_index = {}
83
84
# This will hold an item for each "branch". For a revisions, the revsion
85
# number less the least significant digit is the branch_id, and used as the
86
# key for the dict. Hence revision with the same revsion number less the
87
# least significant digit are considered to be in the same branch line.
88
# e.g.: for revisions 290.12.1 and 290.12.2, the branch_id would be 290.12,
89
# and these two revisions will be in the same branch line. Each value is
90
# a list of rev_indexes in the branch.
91
branch_lines = {}
92
93
linegraph = []
94
95
for (rev_index, (sequence_number,
96
revid,
97
merge_depth,
98
revno_sequence,
99
end_of_merge)) in enumerate(merge_sorted_revisions):
100
if maxnum and rev_index >= maxnum:
101
break
102
revid_index[revid] = rev_index
103
104
parents = graph_parents[revid]
105
linegraph.append([revid,
106
None,
107
[],
108
parents,
109
None,
110
revno_sequence])
111
112
if graph_data:
113
revno_index[revno_sequence] = rev_index
114
115
branch_id = revno_sequence[0:-1]
116
117
branch_line = None
118
if branch_id not in branch_lines:
119
branch_line = []
120
branch_lines[branch_id] = branch_line
121
else:
122
branch_line = branch_lines[branch_id]
123
124
branch_line.append(rev_index)
125
126
if graph_data:
127
branch_ids = branch_lines.keys()
128
129
def branch_id_cmp(x, y):
130
"""Compaire branch_id's first by the number of digits, then reversed
131
by their value"""
132
len_x = len(x)
133
len_y = len(y)
134
if len_x == len_y:
135
return -cmp(x, y)
136
return cmp(len_x, len_y)
137
138
branch_ids.sort(branch_id_cmp)
139
# This will hold a tuple of (child_index, parent_index, col_index) for each
140
# line that needs to be drawn. If col_index is not none, then the line is
141
# drawn along that column, else the the line can be drawn directly between
142
# the child and parent because either the child and parent are in the same
143
# branch line, or the child and parent are 1 row apart.
144
lines = []
145
empty_column = [False for i in range(len(graph_parents))]
146
# This will hold a bit map for each cell. If the cell is true, then the
147
# cell allready contains a node or line. This use when deciding what column
148
# to place a branch line or line in, without it overlaping something else.
149
columns = [list(empty_column)]
150
151
152
for branch_id in branch_ids:
153
branch_line = branch_lines[branch_id]
154
155
# Find the col_index for the direct parent branch. This will be the
156
# starting point when looking for a free column.
157
parent_col_index = 0
158
parent_index = None
159
if len(branch_id) > 1:
160
parent_revno = branch_id[0:-1]
161
if parent_revno in revno_index:
162
parent_index = revno_index[parent_revno]
163
parent_node = linegraph[parent_index][1]
164
if parent_node:
165
parent_col_index = parent_node[0]
166
167
168
col_search_order = _branch_line_col_search_order(columns,
169
parent_col_index)
170
color = reduce(lambda x, y: x+y, branch_id, 0)
171
cur_cont_line = []
172
173
line_range = []
174
last_rev_index = None
175
for rev_index in branch_line:
176
if last_rev_index:
177
if broken_line_length and \
178
rev_index - last_rev_index > broken_line_length:
179
line_range.append(last_rev_index+1)
180
line_range.append(rev_index-1)
181
else:
182
line_range.extend(range(last_rev_index+1, rev_index))
183
184
line_range.append(rev_index)
185
last_rev_index = rev_index
186
187
if parent_index:
188
if broken_line_length and \
189
parent_index - last_rev_index > broken_line_length:
190
line_range.append(last_rev_index+1)
191
else:
192
line_range.extend(range(last_rev_index+1, parent_index))
193
194
col_index = _find_free_column(columns,
195
empty_column,
196
col_search_order,
197
line_range)
198
node = (col_index, color)
199
for rev_index in branch_line:
200
linegraph[rev_index][1] = node
201
columns[col_index][rev_index] = True
202
203
for rev_index in branch_line:
204
(sequence_number,
205
revid,
206
merge_depth,
207
revno_sequence,
208
end_of_merge) = merge_sorted_revisions[rev_index]
209
210
linegraph[rev_index][4] = graph_children[revid]
211
col_index = linegraph[rev_index][1][0]
212
213
for parent_revid in graph_parents[revid]:
214
if parent_revid in revid_index:
215
216
parent_index = revid_index[parent_revid]
217
parent_node = linegraph[parent_index][1]
218
if parent_node:
219
parent_col_index = parent_node[0]
220
else:
221
parent_col_index = None
222
col_search_order = \
223
_line_col_search_order(columns,
224
parent_col_index,
225
col_index)
226
227
# If this line is really long, break it.
228
if len(branch_id) > 0 and \
229
broken_line_length and \
230
parent_index - rev_index > broken_line_length:
231
child_line_col_index = \
232
_find_free_column(columns,
233
empty_column,
234
col_search_order,
235
(rev_index + 1,))
236
_mark_column_as_used(columns,
237
child_line_col_index,
238
(rev_index + 1,))
239
240
# Recall _line_col_search_order to reset it back to
241
# the beging.
242
col_search_order = \
243
_line_col_search_order(columns,
244
parent_col_index,
245
col_index)
246
parent_col_line_index = \
247
_find_free_column(columns,
248
empty_column,
249
col_search_order,
250
(parent_index - 1,))
251
_mark_column_as_used(columns,
252
parent_col_line_index,
253
(parent_index - 1,))
254
lines.append((rev_index,
255
parent_index,
256
(child_line_col_index,
257
parent_col_line_index)))
258
else :
259
line_col_index = col_index
260
if parent_index - rev_index >1:
261
line_range = range(rev_index + 1, parent_index)
262
line_col_index = \
263
_find_free_column(columns,
264
empty_column,
265
col_search_order,
266
line_range)
267
_mark_column_as_used(columns,
268
line_col_index,
269
line_range)
270
lines.append((rev_index,
271
parent_index,
272
(line_col_index,)))
273
274
for (child_index, parent_index, line_col_indexes) in lines:
275
(child_col_index, child_color) = linegraph[child_index][1]
276
(parent_col_index, parent_color) = linegraph[parent_index][1]
277
278
if len(line_col_indexes) == 1:
279
if parent_index - child_index == 1:
280
linegraph[child_index][2].append(
281
(child_col_index,
282
parent_col_index,
283
parent_color))
284
else:
285
# line from the child's column to the lines column
286
linegraph[child_index][2].append(
287
(child_col_index,
288
line_col_indexes[0],
289
parent_color))
290
# lines down the line's column
291
for line_part_index in range(child_index+1, parent_index-1):
292
linegraph[line_part_index][2].append(
293
(line_col_indexes[0],
294
line_col_indexes[0],
295
parent_color))
296
# line from the line's column to the parent's column
297
linegraph[parent_index-1][2].append(
298
(line_col_indexes[0],
299
parent_col_index,
300
parent_color))
301
else:
302
# Broken line
303
# line from the child's column to the lines column
304
linegraph[child_index][2].append(
305
(child_col_index,
306
line_col_indexes[0],
307
parent_color))
308
# Broken line end
309
linegraph[child_index+1][2].append(
310
(line_col_indexes[0],
311
None,
312
parent_color))
313
314
# Broken line end
315
linegraph[parent_index-2][2].append(
316
(None,
317
line_col_indexes[1],
318
parent_color))
319
# line from the line's column to the parent's column
320
linegraph[parent_index-1][2].append(
321
(line_col_indexes[1],
322
parent_col_index,
323
parent_color))
324
return (linegraph, revid_index, len(columns))
325
else:
326
return (linegraph, revid_index, 0)
327
328
329
def _branch_line_col_search_order(columns, parent_col_index):
330
for col_index in range(parent_col_index, len(columns)):
331
yield col_index
332
for col_index in range(parent_col_index-1, -1, -1):
333
yield col_index
334
335
def _line_col_search_order(columns, parent_col_index, child_col_index):
336
if parent_col_index is not None:
337
max_index = max(parent_col_index, child_col_index)
338
min_index = min(parent_col_index, child_col_index)
339
for col_index in range(max_index, min_index -1, -1):
340
yield col_index
341
else:
342
max_index = child_col_index
343
min_index = child_col_index
344
yield child_col_index
345
i = 1
346
while max_index + i < len(columns) or \
347
min_index - i > -1:
348
if max_index + i < len(columns):
349
yield max_index + i
350
if min_index - i > -1:
351
yield min_index - i
352
i += 1
353
354
def _find_free_column(columns, empty_column, col_search_order, line_range):
355
for col_index in col_search_order:
356
column = columns[col_index]
357
has_overlaping_line = False
358
for row_index in line_range:
359
if column[row_index]:
360
has_overlaping_line = True
361
break
362
if not has_overlaping_line:
363
break
364
else:
365
col_index = len(columns)
366
column = list(empty_column)
367
columns.append(column)
368
return col_index
369
370
def _mark_column_as_used(columns, col_index, line_range):
371
column = columns[col_index]
372
for row_index in line_range:
373
column[row_index] = True
374
375
def same_branch(a, b):
376
"""Return whether we think revisions a and b are on the same branch."""
377
if len(a.parent_ids) == 1:
378
# Defacto same branch if only parent
379
return True
380
elif a.committer == b.committer:
381
# Same committer so may as well be
382
return True
383
else:
384
return False
1
# -*- coding: UTF-8 -*-
2
"""Directed graph production.
3
4
This module contains the code to produce an ordered directed graph of a
5
bzr branch, such as we display in the tree view at the top of the bzrk
6
window.
7
"""
8
9
__copyright__ = "Copyright © 2005 Canonical Ltd."
10
__author__ = "Scott James Remnant <scott@ubuntu.com>"
11
12
from bzrlib.tsort import merge_sort
13
14
def linegraph(branch, start, maxnum):
15
"""Produce a directed graph of a bzr branch.
16
17
Returns a tuple of (line_graph, revid_index, columns_len) where
18
* line_graph is a list of tuples of (revid,
19
node,
20
lines,
21
parents,
22
children,
23
revno_sequence),
24
* revid_index is a dict of each revision with the key being the revid, and
25
the value the row index, and
26
* columns_len is the number of columns need to draw the line graph.
27
28
29
Node is a tuple of (column, colour) with column being a zero-indexed
30
column number of the graph that this revision represents and colour
31
being a zero-indexed colour (which doesn't specify any actual colour
32
in particular) to draw the node in.
33
34
Lines is a list of tuples which represent lines you should draw away
35
from the revision, if you also need to draw lines into the revision
36
you should use the lines list from the previous iteration. Each
37
typle in the list is in the form (start, end, colour) with start and
38
end being zero-indexed column numbers and colour as in node.
39
40
It's up to you how to actually draw the nodes and lines (straight,
41
curved, kinked, etc.) and to pick the actual colours for each index.
42
"""
43
44
# We get the mainline so we can pass it to merge_sort to make merge_sort
45
# run faster.
46
mainline = branch.revision_history()
47
graph_parents = branch.repository.get_revision_graph(start)
48
graph_children = {}
49
for revid in graph_parents.iterkeys():
50
graph_children[revid] = []
51
52
merge_sorted_revisions = merge_sort(
53
graph_parents,
54
start,
55
mainline,
56
generate_revno=True)
57
58
revid_index = {}
59
revno_index = {}
60
61
# This will hold an item for each "branch". For a revisions, the revsion
62
# number less the least significant digit is the branch_id, and used as the
63
# key for the dict. Hence revision with the same revsion number less the
64
# least significant digit are considered to be in the same branch line.
65
# e.g.: for revisions 290.12.1 and 290.12.2, the branch_id would be 290.12,
66
# and these two revisions will be in the same branch line. Each value is
67
# a list of [rev_indexes, min_index, max_index, col_index].
68
branch_lines = {}
69
BL_REV_INDEXES = 0
70
BL_MIN_INDEX = 1
71
BL_MAX_INDEX = 2
72
BL_COL_INDEX = 3
73
74
linegraph = []
75
76
for (rev_index, (sequence_number,
77
revid,
78
merge_depth,
79
revno_sequence,
80
end_of_merge)) in enumerate(merge_sorted_revisions):
81
if maxnum and rev_index >= maxnum:
82
break
83
revid_index[revid] = rev_index
84
revno_index[revno_sequence] = rev_index
85
86
branch_id = revno_sequence[0:-1]
87
88
branch_line = None
89
if branch_id not in branch_lines:
90
branch_line = [[], # BL_REV_INDEXES
91
rev_index, # BL_MIN_INDEX
92
0, # BL_MAX_INDEX
93
None] # BL_COL_INDEX
94
branch_lines[branch_id] = branch_line
95
else:
96
branch_line = branch_lines[branch_id]
97
98
branch_line[BL_REV_INDEXES].append(rev_index)
99
if rev_index > branch_line[BL_MAX_INDEX]:
100
branch_line[BL_MAX_INDEX] = rev_index
101
102
parents = graph_parents[revid]
103
for parent_revid in parents:
104
graph_children[parent_revid].append(revid)
105
106
linegraph.append([revid,
107
None,
108
[],
109
parents,
110
None,
111
revno_sequence])
112
113
branch_ids = branch_lines.keys()
114
115
def branch_id_cmp(x, y):
116
"""Compaire branch_id's first by the number of digits, then reversed
117
by their value"""
118
len_x = len(x)
119
len_y = len(y)
120
if len_x == len_y:
121
return -cmp(x, y)
122
return cmp(len_x, len_y)
123
124
branch_ids.sort(branch_id_cmp)
125
# This will hold a tuple of (child_index, parent_index, col_index) for each
126
# line that needs to be drawn. If col_index is not none, then the line is
127
# drawn along that column, else the the line can be drawn directly between
128
# the child and parent because either the child and parent are in the same
129
# branch line, or the child and parent are 1 row apart.
130
lines = []
131
empty_column = [False for i in range(len(graph_parents))]
132
# This will hold a bit map for each cell. If the cell is true, then the
133
# cell allready contains a node or line. This use when deciding what column
134
# to place a branch line or line in, without it overlaping something else.
135
columns = [list(empty_column)]
136
137
138
for branch_id in branch_ids:
139
branch_line = branch_lines[branch_id]
140
141
# Find the col_index for the direct parent branch. This will be the
142
# starting point when looking for a free column.
143
parent_col_index = 0
144
if len(branch_id) > 1:
145
parent_branch_id = branch_id[0:-2]
146
parent_col_index = branch_lines[parent_branch_id][BL_COL_INDEX]
147
parent_revno = branch_id[0:-1]
148
if parent_revno in revno_index:
149
parent_index = revno_index[parent_revno]
150
branch_line[BL_MAX_INDEX] = parent_index - 1
151
152
col_search_order = _branch_line_col_search_order(columns,
153
parent_col_index)
154
branch_line[BL_COL_INDEX] = _append_line(columns,
155
(branch_line[BL_MIN_INDEX],
156
branch_line[BL_MAX_INDEX]),
157
empty_column,
158
col_search_order)
159
color = reduce(lambda x, y: x+y, branch_id, 0)
160
col_index = branch_line[BL_COL_INDEX]
161
node = (col_index, color)
162
163
for rev_index in branch_line[BL_REV_INDEXES]:
164
(sequence_number,
165
revid,
166
merge_depth,
167
revno_sequence,
168
end_of_merge) = merge_sorted_revisions[rev_index]
169
170
linegraph[rev_index][1] = node
171
linegraph[rev_index][4] = graph_children[revid]
172
173
for parent_revid in graph_parents[revid]:
174
if parent_revid in revid_index:
175
parent_index = revid_index[parent_revid]
176
parent_revno = merge_sorted_revisions[parent_index][3]
177
parent_branch_id = parent_revno[0:-1]
178
col_index = None
179
is_direct_parent_line = False
180
if len(branch_id) > 1:
181
if parent_revno == branch_id[0:-1]:
182
is_direct_parent_line = True
183
184
# A line only needs it's own column if it is going from
185
# one branch line to another, it's not the line to the
186
# direct parent, and if it is longer than one row.
187
if branch_id != parent_branch_id and \
188
parent_index - rev_index > 1 and \
189
not is_direct_parent_line:
190
parent_node = linegraph[parent_index][1]
191
if parent_node:
192
parent_col_index = parent_node[0]
193
else:
194
parent_col_index = None
195
col_search_order = \
196
_line_col_search_order(columns,
197
parent_col_index,
198
branch_line[BL_COL_INDEX])
199
col_index = _append_line(columns,
200
(rev_index+1, parent_index-1),
201
empty_column,
202
col_search_order)
203
lines.append((rev_index, parent_index, col_index))
204
205
for (child_index, parent_index, line_col_index) in lines:
206
child_col_index = linegraph[child_index][1][0]
207
208
parent_node = linegraph[parent_index][1]
209
parent_col_index = parent_node[0]
210
color = parent_node[1]
211
212
if line_col_index:
213
# line from the child's column to the lines column
214
linegraph[child_index][2].append(
215
(child_col_index,
216
line_col_index,
217
color))
218
# lines down the line's column
219
for line_part_index in range(child_index+1, parent_index-1):
220
linegraph[line_part_index][2].append(
221
(line_col_index,
222
line_col_index,
223
color))
224
# line from the line's column to the parent's column
225
linegraph[parent_index-1][2].append(
226
(line_col_index,
227
parent_col_index,
228
color))
229
else:
230
# lines down the child's column
231
for line_part_index in range(child_index, parent_index-1):
232
linegraph[line_part_index][2].append(
233
(child_col_index,
234
child_col_index,
235
color))
236
# line from the child's column to the parent's column
237
linegraph[parent_index-1][2].append(
238
(child_col_index,
239
parent_col_index,
240
color))
241
242
return (linegraph, revid_index, len(columns))
243
244
def _branch_line_col_search_order(columns, parent_col_index):
245
return range(parent_col_index, len(columns)) + \
246
range(parent_col_index-1, -1, -1)
247
248
def _line_col_search_order(columns, parent_col_index, child_col_index):
249
dest_col_indexes = []
250
if parent_col_index is not None:
251
dest_col_indexes.append(parent_col_index)
252
else:
253
dest_col_indexes.append(child_col_index)
254
dest_col_indexes.append(child_col_index)
255
dest_col_indexes.sort()
256
col_search_order = range(dest_col_indexes[1], dest_col_indexes[0] -1, -1)
257
i = 1
258
while dest_col_indexes[1] + i < len(columns) or \
259
dest_col_indexes[0] - i > -1:
260
if dest_col_indexes[1] + i < len(columns):
261
col_search_order.append(dest_col_indexes[1] + i)
262
if dest_col_indexes[0] - i > -1:
263
col_search_order.append(dest_col_indexes[0] - i)
264
i += 1
265
return col_search_order
266
267
def _append_line(columns, line, empty_column, col_search_order):
268
line_range = range(line[0], line[1]+1)
269
270
for col_index in col_search_order:
271
column = columns[col_index]
272
has_overlaping_line = False
273
for row_index in line_range:
274
if column[row_index]:
275
has_overlaping_line = True
276
break
277
if not has_overlaping_line:
278
break
279
else:
280
col_index = len(columns)
281
column = list(empty_column)
282
columns.append(column)
283
284
for row_index in line_range:
285
column[row_index] = True
286
return col_index
287
288
def same_branch(a, b):
289
"""Return whether we think revisions a and b are on the same branch."""
290
if len(a.parent_ids) == 1:
291
# Defacto same branch if only parent
292
return True
293
elif a.committer == b.committer:
294
# Same committer so may as well be
295
return True
296
else:
297
return False
Loggerhead is a web-based interface for Breezy
Version: 2.0.2.dev0