##// END OF EJS Templates
Change revlog.heads to walk the revision graph using revision numbers...
Alexis S. L. Carvalho -
r2490:6ff82ec1 default
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@@ -1,1279 +1,1279 b''
1 """
1 """
2 revlog.py - storage back-end for mercurial
2 revlog.py - storage back-end for mercurial
3
3
4 This provides efficient delta storage with O(1) retrieve and append
4 This provides efficient delta storage with O(1) retrieve and append
5 and O(changes) merge between branches
5 and O(changes) merge between branches
6
6
7 Copyright 2005 Matt Mackall <mpm@selenic.com>
7 Copyright 2005 Matt Mackall <mpm@selenic.com>
8
8
9 This software may be used and distributed according to the terms
9 This software may be used and distributed according to the terms
10 of the GNU General Public License, incorporated herein by reference.
10 of the GNU General Public License, incorporated herein by reference.
11 """
11 """
12
12
13 from node import *
13 from node import *
14 from i18n import gettext as _
14 from i18n import gettext as _
15 from demandload import demandload
15 from demandload import demandload
16 demandload(globals(), "binascii changegroup errno heapq mdiff os")
16 demandload(globals(), "binascii changegroup errno heapq mdiff os")
17 demandload(globals(), "sha struct util zlib")
17 demandload(globals(), "sha struct util zlib")
18
18
19 # revlog version strings
19 # revlog version strings
20 REVLOGV0 = 0
20 REVLOGV0 = 0
21 REVLOGNG = 1
21 REVLOGNG = 1
22
22
23 # revlog flags
23 # revlog flags
24 REVLOGNGINLINEDATA = (1 << 16)
24 REVLOGNGINLINEDATA = (1 << 16)
25 REVLOG_DEFAULT_FLAGS = REVLOGNGINLINEDATA
25 REVLOG_DEFAULT_FLAGS = REVLOGNGINLINEDATA
26
26
27 REVLOG_DEFAULT_FORMAT = REVLOGNG
27 REVLOG_DEFAULT_FORMAT = REVLOGNG
28 REVLOG_DEFAULT_VERSION = REVLOG_DEFAULT_FORMAT | REVLOG_DEFAULT_FLAGS
28 REVLOG_DEFAULT_VERSION = REVLOG_DEFAULT_FORMAT | REVLOG_DEFAULT_FLAGS
29
29
30 def flagstr(flag):
30 def flagstr(flag):
31 if flag == "inline":
31 if flag == "inline":
32 return REVLOGNGINLINEDATA
32 return REVLOGNGINLINEDATA
33 raise RevlogError(_("unknown revlog flag %s" % flag))
33 raise RevlogError(_("unknown revlog flag %s" % flag))
34
34
35 def hash(text, p1, p2):
35 def hash(text, p1, p2):
36 """generate a hash from the given text and its parent hashes
36 """generate a hash from the given text and its parent hashes
37
37
38 This hash combines both the current file contents and its history
38 This hash combines both the current file contents and its history
39 in a manner that makes it easy to distinguish nodes with the same
39 in a manner that makes it easy to distinguish nodes with the same
40 content in the revision graph.
40 content in the revision graph.
41 """
41 """
42 l = [p1, p2]
42 l = [p1, p2]
43 l.sort()
43 l.sort()
44 s = sha.new(l[0])
44 s = sha.new(l[0])
45 s.update(l[1])
45 s.update(l[1])
46 s.update(text)
46 s.update(text)
47 return s.digest()
47 return s.digest()
48
48
49 def compress(text):
49 def compress(text):
50 """ generate a possibly-compressed representation of text """
50 """ generate a possibly-compressed representation of text """
51 if not text: return ("", text)
51 if not text: return ("", text)
52 if len(text) < 44:
52 if len(text) < 44:
53 if text[0] == '\0': return ("", text)
53 if text[0] == '\0': return ("", text)
54 return ('u', text)
54 return ('u', text)
55 bin = zlib.compress(text)
55 bin = zlib.compress(text)
56 if len(bin) > len(text):
56 if len(bin) > len(text):
57 if text[0] == '\0': return ("", text)
57 if text[0] == '\0': return ("", text)
58 return ('u', text)
58 return ('u', text)
59 return ("", bin)
59 return ("", bin)
60
60
61 def decompress(bin):
61 def decompress(bin):
62 """ decompress the given input """
62 """ decompress the given input """
63 if not bin: return bin
63 if not bin: return bin
64 t = bin[0]
64 t = bin[0]
65 if t == '\0': return bin
65 if t == '\0': return bin
66 if t == 'x': return zlib.decompress(bin)
66 if t == 'x': return zlib.decompress(bin)
67 if t == 'u': return bin[1:]
67 if t == 'u': return bin[1:]
68 raise RevlogError(_("unknown compression type %r") % t)
68 raise RevlogError(_("unknown compression type %r") % t)
69
69
70 indexformatv0 = ">4l20s20s20s"
70 indexformatv0 = ">4l20s20s20s"
71 v0shaoffset = 56
71 v0shaoffset = 56
72 # index ng:
72 # index ng:
73 # 6 bytes offset
73 # 6 bytes offset
74 # 2 bytes flags
74 # 2 bytes flags
75 # 4 bytes compressed length
75 # 4 bytes compressed length
76 # 4 bytes uncompressed length
76 # 4 bytes uncompressed length
77 # 4 bytes: base rev
77 # 4 bytes: base rev
78 # 4 bytes link rev
78 # 4 bytes link rev
79 # 4 bytes parent 1 rev
79 # 4 bytes parent 1 rev
80 # 4 bytes parent 2 rev
80 # 4 bytes parent 2 rev
81 # 32 bytes: nodeid
81 # 32 bytes: nodeid
82 indexformatng = ">Qiiiiii20s12x"
82 indexformatng = ">Qiiiiii20s12x"
83 ngshaoffset = 32
83 ngshaoffset = 32
84 versionformat = ">i"
84 versionformat = ">i"
85
85
86 class lazyparser(object):
86 class lazyparser(object):
87 """
87 """
88 this class avoids the need to parse the entirety of large indices
88 this class avoids the need to parse the entirety of large indices
89 """
89 """
90
90
91 # lazyparser is not safe to use on windows if win32 extensions not
91 # lazyparser is not safe to use on windows if win32 extensions not
92 # available. it keeps file handle open, which make it not possible
92 # available. it keeps file handle open, which make it not possible
93 # to break hardlinks on local cloned repos.
93 # to break hardlinks on local cloned repos.
94 safe_to_use = os.name != 'nt' or (not util.is_win_9x() and
94 safe_to_use = os.name != 'nt' or (not util.is_win_9x() and
95 hasattr(util, 'win32api'))
95 hasattr(util, 'win32api'))
96
96
97 def __init__(self, dataf, size, indexformat, shaoffset):
97 def __init__(self, dataf, size, indexformat, shaoffset):
98 self.dataf = dataf
98 self.dataf = dataf
99 self.format = indexformat
99 self.format = indexformat
100 self.s = struct.calcsize(indexformat)
100 self.s = struct.calcsize(indexformat)
101 self.indexformat = indexformat
101 self.indexformat = indexformat
102 self.datasize = size
102 self.datasize = size
103 self.l = size/self.s
103 self.l = size/self.s
104 self.index = [None] * self.l
104 self.index = [None] * self.l
105 self.map = {nullid: -1}
105 self.map = {nullid: -1}
106 self.allmap = 0
106 self.allmap = 0
107 self.all = 0
107 self.all = 0
108 self.mapfind_count = 0
108 self.mapfind_count = 0
109 self.shaoffset = shaoffset
109 self.shaoffset = shaoffset
110
110
111 def loadmap(self):
111 def loadmap(self):
112 """
112 """
113 during a commit, we need to make sure the rev being added is
113 during a commit, we need to make sure the rev being added is
114 not a duplicate. This requires loading the entire index,
114 not a duplicate. This requires loading the entire index,
115 which is fairly slow. loadmap can load up just the node map,
115 which is fairly slow. loadmap can load up just the node map,
116 which takes much less time.
116 which takes much less time.
117 """
117 """
118 if self.allmap: return
118 if self.allmap: return
119 start = 0
119 start = 0
120 end = self.datasize
120 end = self.datasize
121 self.allmap = 1
121 self.allmap = 1
122 cur = 0
122 cur = 0
123 count = 0
123 count = 0
124 blocksize = self.s * 256
124 blocksize = self.s * 256
125 self.dataf.seek(0)
125 self.dataf.seek(0)
126 while cur < end:
126 while cur < end:
127 data = self.dataf.read(blocksize)
127 data = self.dataf.read(blocksize)
128 off = 0
128 off = 0
129 for x in xrange(256):
129 for x in xrange(256):
130 n = data[off + self.shaoffset:off + self.shaoffset + 20]
130 n = data[off + self.shaoffset:off + self.shaoffset + 20]
131 self.map[n] = count
131 self.map[n] = count
132 count += 1
132 count += 1
133 if count >= self.l:
133 if count >= self.l:
134 break
134 break
135 off += self.s
135 off += self.s
136 cur += blocksize
136 cur += blocksize
137
137
138 def loadblock(self, blockstart, blocksize, data=None):
138 def loadblock(self, blockstart, blocksize, data=None):
139 if self.all: return
139 if self.all: return
140 if data is None:
140 if data is None:
141 self.dataf.seek(blockstart)
141 self.dataf.seek(blockstart)
142 data = self.dataf.read(blocksize)
142 data = self.dataf.read(blocksize)
143 lend = len(data) / self.s
143 lend = len(data) / self.s
144 i = blockstart / self.s
144 i = blockstart / self.s
145 off = 0
145 off = 0
146 for x in xrange(lend):
146 for x in xrange(lend):
147 if self.index[i + x] == None:
147 if self.index[i + x] == None:
148 b = data[off : off + self.s]
148 b = data[off : off + self.s]
149 self.index[i + x] = b
149 self.index[i + x] = b
150 n = b[self.shaoffset:self.shaoffset + 20]
150 n = b[self.shaoffset:self.shaoffset + 20]
151 self.map[n] = i + x
151 self.map[n] = i + x
152 off += self.s
152 off += self.s
153
153
154 def findnode(self, node):
154 def findnode(self, node):
155 """search backwards through the index file for a specific node"""
155 """search backwards through the index file for a specific node"""
156 if self.allmap: return None
156 if self.allmap: return None
157
157
158 # hg log will cause many many searches for the manifest
158 # hg log will cause many many searches for the manifest
159 # nodes. After we get called a few times, just load the whole
159 # nodes. After we get called a few times, just load the whole
160 # thing.
160 # thing.
161 if self.mapfind_count > 8:
161 if self.mapfind_count > 8:
162 self.loadmap()
162 self.loadmap()
163 if node in self.map:
163 if node in self.map:
164 return node
164 return node
165 return None
165 return None
166 self.mapfind_count += 1
166 self.mapfind_count += 1
167 last = self.l - 1
167 last = self.l - 1
168 while self.index[last] != None:
168 while self.index[last] != None:
169 if last == 0:
169 if last == 0:
170 self.all = 1
170 self.all = 1
171 self.allmap = 1
171 self.allmap = 1
172 return None
172 return None
173 last -= 1
173 last -= 1
174 end = (last + 1) * self.s
174 end = (last + 1) * self.s
175 blocksize = self.s * 256
175 blocksize = self.s * 256
176 while end >= 0:
176 while end >= 0:
177 start = max(end - blocksize, 0)
177 start = max(end - blocksize, 0)
178 self.dataf.seek(start)
178 self.dataf.seek(start)
179 data = self.dataf.read(end - start)
179 data = self.dataf.read(end - start)
180 findend = end - start
180 findend = end - start
181 while True:
181 while True:
182 # we're searching backwards, so weh have to make sure
182 # we're searching backwards, so weh have to make sure
183 # we don't find a changeset where this node is a parent
183 # we don't find a changeset where this node is a parent
184 off = data.rfind(node, 0, findend)
184 off = data.rfind(node, 0, findend)
185 findend = off
185 findend = off
186 if off >= 0:
186 if off >= 0:
187 i = off / self.s
187 i = off / self.s
188 off = i * self.s
188 off = i * self.s
189 n = data[off + self.shaoffset:off + self.shaoffset + 20]
189 n = data[off + self.shaoffset:off + self.shaoffset + 20]
190 if n == node:
190 if n == node:
191 self.map[n] = i + start / self.s
191 self.map[n] = i + start / self.s
192 return node
192 return node
193 else:
193 else:
194 break
194 break
195 end -= blocksize
195 end -= blocksize
196 return None
196 return None
197
197
198 def loadindex(self, i=None, end=None):
198 def loadindex(self, i=None, end=None):
199 if self.all: return
199 if self.all: return
200 all = False
200 all = False
201 if i == None:
201 if i == None:
202 blockstart = 0
202 blockstart = 0
203 blocksize = (512 / self.s) * self.s
203 blocksize = (512 / self.s) * self.s
204 end = self.datasize
204 end = self.datasize
205 all = True
205 all = True
206 else:
206 else:
207 if end:
207 if end:
208 blockstart = i * self.s
208 blockstart = i * self.s
209 end = end * self.s
209 end = end * self.s
210 blocksize = end - blockstart
210 blocksize = end - blockstart
211 else:
211 else:
212 blockstart = (i & ~(32)) * self.s
212 blockstart = (i & ~(32)) * self.s
213 blocksize = self.s * 64
213 blocksize = self.s * 64
214 end = blockstart + blocksize
214 end = blockstart + blocksize
215 while blockstart < end:
215 while blockstart < end:
216 self.loadblock(blockstart, blocksize)
216 self.loadblock(blockstart, blocksize)
217 blockstart += blocksize
217 blockstart += blocksize
218 if all: self.all = True
218 if all: self.all = True
219
219
220 class lazyindex(object):
220 class lazyindex(object):
221 """a lazy version of the index array"""
221 """a lazy version of the index array"""
222 def __init__(self, parser):
222 def __init__(self, parser):
223 self.p = parser
223 self.p = parser
224 def __len__(self):
224 def __len__(self):
225 return len(self.p.index)
225 return len(self.p.index)
226 def load(self, pos):
226 def load(self, pos):
227 if pos < 0:
227 if pos < 0:
228 pos += len(self.p.index)
228 pos += len(self.p.index)
229 self.p.loadindex(pos)
229 self.p.loadindex(pos)
230 return self.p.index[pos]
230 return self.p.index[pos]
231 def __getitem__(self, pos):
231 def __getitem__(self, pos):
232 ret = self.p.index[pos] or self.load(pos)
232 ret = self.p.index[pos] or self.load(pos)
233 if isinstance(ret, str):
233 if isinstance(ret, str):
234 ret = struct.unpack(self.p.indexformat, ret)
234 ret = struct.unpack(self.p.indexformat, ret)
235 return ret
235 return ret
236 def __setitem__(self, pos, item):
236 def __setitem__(self, pos, item):
237 self.p.index[pos] = item
237 self.p.index[pos] = item
238 def __delitem__(self, pos):
238 def __delitem__(self, pos):
239 del self.p.index[pos]
239 del self.p.index[pos]
240 def append(self, e):
240 def append(self, e):
241 self.p.index.append(e)
241 self.p.index.append(e)
242
242
243 class lazymap(object):
243 class lazymap(object):
244 """a lazy version of the node map"""
244 """a lazy version of the node map"""
245 def __init__(self, parser):
245 def __init__(self, parser):
246 self.p = parser
246 self.p = parser
247 def load(self, key):
247 def load(self, key):
248 n = self.p.findnode(key)
248 n = self.p.findnode(key)
249 if n == None:
249 if n == None:
250 raise KeyError(key)
250 raise KeyError(key)
251 def __contains__(self, key):
251 def __contains__(self, key):
252 if key in self.p.map:
252 if key in self.p.map:
253 return True
253 return True
254 self.p.loadmap()
254 self.p.loadmap()
255 return key in self.p.map
255 return key in self.p.map
256 def __iter__(self):
256 def __iter__(self):
257 yield nullid
257 yield nullid
258 for i in xrange(self.p.l):
258 for i in xrange(self.p.l):
259 ret = self.p.index[i]
259 ret = self.p.index[i]
260 if not ret:
260 if not ret:
261 self.p.loadindex(i)
261 self.p.loadindex(i)
262 ret = self.p.index[i]
262 ret = self.p.index[i]
263 if isinstance(ret, str):
263 if isinstance(ret, str):
264 ret = struct.unpack(self.p.indexformat, ret)
264 ret = struct.unpack(self.p.indexformat, ret)
265 yield ret[-1]
265 yield ret[-1]
266 def __getitem__(self, key):
266 def __getitem__(self, key):
267 try:
267 try:
268 return self.p.map[key]
268 return self.p.map[key]
269 except KeyError:
269 except KeyError:
270 try:
270 try:
271 self.load(key)
271 self.load(key)
272 return self.p.map[key]
272 return self.p.map[key]
273 except KeyError:
273 except KeyError:
274 raise KeyError("node " + hex(key))
274 raise KeyError("node " + hex(key))
275 def __setitem__(self, key, val):
275 def __setitem__(self, key, val):
276 self.p.map[key] = val
276 self.p.map[key] = val
277 def __delitem__(self, key):
277 def __delitem__(self, key):
278 del self.p.map[key]
278 del self.p.map[key]
279
279
280 class RevlogError(Exception): pass
280 class RevlogError(Exception): pass
281
281
282 class revlog(object):
282 class revlog(object):
283 """
283 """
284 the underlying revision storage object
284 the underlying revision storage object
285
285
286 A revlog consists of two parts, an index and the revision data.
286 A revlog consists of two parts, an index and the revision data.
287
287
288 The index is a file with a fixed record size containing
288 The index is a file with a fixed record size containing
289 information on each revision, includings its nodeid (hash), the
289 information on each revision, includings its nodeid (hash), the
290 nodeids of its parents, the position and offset of its data within
290 nodeids of its parents, the position and offset of its data within
291 the data file, and the revision it's based on. Finally, each entry
291 the data file, and the revision it's based on. Finally, each entry
292 contains a linkrev entry that can serve as a pointer to external
292 contains a linkrev entry that can serve as a pointer to external
293 data.
293 data.
294
294
295 The revision data itself is a linear collection of data chunks.
295 The revision data itself is a linear collection of data chunks.
296 Each chunk represents a revision and is usually represented as a
296 Each chunk represents a revision and is usually represented as a
297 delta against the previous chunk. To bound lookup time, runs of
297 delta against the previous chunk. To bound lookup time, runs of
298 deltas are limited to about 2 times the length of the original
298 deltas are limited to about 2 times the length of the original
299 version data. This makes retrieval of a version proportional to
299 version data. This makes retrieval of a version proportional to
300 its size, or O(1) relative to the number of revisions.
300 its size, or O(1) relative to the number of revisions.
301
301
302 Both pieces of the revlog are written to in an append-only
302 Both pieces of the revlog are written to in an append-only
303 fashion, which means we never need to rewrite a file to insert or
303 fashion, which means we never need to rewrite a file to insert or
304 remove data, and can use some simple techniques to avoid the need
304 remove data, and can use some simple techniques to avoid the need
305 for locking while reading.
305 for locking while reading.
306 """
306 """
307 def __init__(self, opener, indexfile, datafile,
307 def __init__(self, opener, indexfile, datafile,
308 defversion=REVLOG_DEFAULT_VERSION):
308 defversion=REVLOG_DEFAULT_VERSION):
309 """
309 """
310 create a revlog object
310 create a revlog object
311
311
312 opener is a function that abstracts the file opening operation
312 opener is a function that abstracts the file opening operation
313 and can be used to implement COW semantics or the like.
313 and can be used to implement COW semantics or the like.
314 """
314 """
315 self.indexfile = indexfile
315 self.indexfile = indexfile
316 self.datafile = datafile
316 self.datafile = datafile
317 self.opener = opener
317 self.opener = opener
318
318
319 self.indexstat = None
319 self.indexstat = None
320 self.cache = None
320 self.cache = None
321 self.chunkcache = None
321 self.chunkcache = None
322 self.defversion = defversion
322 self.defversion = defversion
323 self.load()
323 self.load()
324
324
325 def load(self):
325 def load(self):
326 v = self.defversion
326 v = self.defversion
327 try:
327 try:
328 f = self.opener(self.indexfile)
328 f = self.opener(self.indexfile)
329 i = f.read(4)
329 i = f.read(4)
330 f.seek(0)
330 f.seek(0)
331 except IOError, inst:
331 except IOError, inst:
332 if inst.errno != errno.ENOENT:
332 if inst.errno != errno.ENOENT:
333 raise
333 raise
334 i = ""
334 i = ""
335 else:
335 else:
336 try:
336 try:
337 st = util.fstat(f)
337 st = util.fstat(f)
338 except AttributeError, inst:
338 except AttributeError, inst:
339 st = None
339 st = None
340 else:
340 else:
341 oldst = self.indexstat
341 oldst = self.indexstat
342 if (oldst and st.st_dev == oldst.st_dev
342 if (oldst and st.st_dev == oldst.st_dev
343 and st.st_ino == oldst.st_ino
343 and st.st_ino == oldst.st_ino
344 and st.st_mtime == oldst.st_mtime
344 and st.st_mtime == oldst.st_mtime
345 and st.st_ctime == oldst.st_ctime):
345 and st.st_ctime == oldst.st_ctime):
346 return
346 return
347 self.indexstat = st
347 self.indexstat = st
348 if len(i) > 0:
348 if len(i) > 0:
349 v = struct.unpack(versionformat, i)[0]
349 v = struct.unpack(versionformat, i)[0]
350 flags = v & ~0xFFFF
350 flags = v & ~0xFFFF
351 fmt = v & 0xFFFF
351 fmt = v & 0xFFFF
352 if fmt == REVLOGV0:
352 if fmt == REVLOGV0:
353 if flags:
353 if flags:
354 raise RevlogError(_("index %s invalid flags %x for format v0" %
354 raise RevlogError(_("index %s invalid flags %x for format v0" %
355 (self.indexfile, flags)))
355 (self.indexfile, flags)))
356 elif fmt == REVLOGNG:
356 elif fmt == REVLOGNG:
357 if flags & ~REVLOGNGINLINEDATA:
357 if flags & ~REVLOGNGINLINEDATA:
358 raise RevlogError(_("index %s invalid flags %x for revlogng" %
358 raise RevlogError(_("index %s invalid flags %x for revlogng" %
359 (self.indexfile, flags)))
359 (self.indexfile, flags)))
360 else:
360 else:
361 raise RevlogError(_("index %s invalid format %d" %
361 raise RevlogError(_("index %s invalid format %d" %
362 (self.indexfile, fmt)))
362 (self.indexfile, fmt)))
363 self.version = v
363 self.version = v
364 if v == REVLOGV0:
364 if v == REVLOGV0:
365 self.indexformat = indexformatv0
365 self.indexformat = indexformatv0
366 shaoffset = v0shaoffset
366 shaoffset = v0shaoffset
367 else:
367 else:
368 self.indexformat = indexformatng
368 self.indexformat = indexformatng
369 shaoffset = ngshaoffset
369 shaoffset = ngshaoffset
370
370
371 if i:
371 if i:
372 if (lazyparser.safe_to_use and not self.inlinedata() and
372 if (lazyparser.safe_to_use and not self.inlinedata() and
373 st and st.st_size > 10000):
373 st and st.st_size > 10000):
374 # big index, let's parse it on demand
374 # big index, let's parse it on demand
375 parser = lazyparser(f, st.st_size, self.indexformat, shaoffset)
375 parser = lazyparser(f, st.st_size, self.indexformat, shaoffset)
376 self.index = lazyindex(parser)
376 self.index = lazyindex(parser)
377 self.nodemap = lazymap(parser)
377 self.nodemap = lazymap(parser)
378 else:
378 else:
379 self.parseindex(f, st)
379 self.parseindex(f, st)
380 if self.version != REVLOGV0:
380 if self.version != REVLOGV0:
381 e = list(self.index[0])
381 e = list(self.index[0])
382 type = self.ngtype(e[0])
382 type = self.ngtype(e[0])
383 e[0] = self.offset_type(0, type)
383 e[0] = self.offset_type(0, type)
384 self.index[0] = e
384 self.index[0] = e
385 else:
385 else:
386 self.nodemap = { nullid: -1}
386 self.nodemap = { nullid: -1}
387 self.index = []
387 self.index = []
388
388
389
389
390 def parseindex(self, fp, st):
390 def parseindex(self, fp, st):
391 s = struct.calcsize(self.indexformat)
391 s = struct.calcsize(self.indexformat)
392 self.index = []
392 self.index = []
393 self.nodemap = {nullid: -1}
393 self.nodemap = {nullid: -1}
394 inline = self.inlinedata()
394 inline = self.inlinedata()
395 n = 0
395 n = 0
396 leftover = None
396 leftover = None
397 while True:
397 while True:
398 if st:
398 if st:
399 data = fp.read(65536)
399 data = fp.read(65536)
400 else:
400 else:
401 # hack for httprangereader, it doesn't do partial reads well
401 # hack for httprangereader, it doesn't do partial reads well
402 data = fp.read()
402 data = fp.read()
403 if not data:
403 if not data:
404 break
404 break
405 if n == 0 and self.inlinedata():
405 if n == 0 and self.inlinedata():
406 # cache the first chunk
406 # cache the first chunk
407 self.chunkcache = (0, data)
407 self.chunkcache = (0, data)
408 if leftover:
408 if leftover:
409 data = leftover + data
409 data = leftover + data
410 leftover = None
410 leftover = None
411 off = 0
411 off = 0
412 l = len(data)
412 l = len(data)
413 while off < l:
413 while off < l:
414 if l - off < s:
414 if l - off < s:
415 leftover = data[off:]
415 leftover = data[off:]
416 break
416 break
417 cur = data[off:off + s]
417 cur = data[off:off + s]
418 off += s
418 off += s
419 e = struct.unpack(self.indexformat, cur)
419 e = struct.unpack(self.indexformat, cur)
420 self.index.append(e)
420 self.index.append(e)
421 self.nodemap[e[-1]] = n
421 self.nodemap[e[-1]] = n
422 n += 1
422 n += 1
423 if inline:
423 if inline:
424 off += e[1]
424 off += e[1]
425 if off > l:
425 if off > l:
426 # some things don't seek well, just read it
426 # some things don't seek well, just read it
427 fp.read(off - l)
427 fp.read(off - l)
428 if not st:
428 if not st:
429 break
429 break
430
430
431
431
432 def ngoffset(self, q):
432 def ngoffset(self, q):
433 if q & 0xFFFF:
433 if q & 0xFFFF:
434 raise RevlogError(_('%s: incompatible revision flag %x') %
434 raise RevlogError(_('%s: incompatible revision flag %x') %
435 (self.indexfile, q))
435 (self.indexfile, q))
436 return long(q >> 16)
436 return long(q >> 16)
437
437
438 def ngtype(self, q):
438 def ngtype(self, q):
439 return int(q & 0xFFFF)
439 return int(q & 0xFFFF)
440
440
441 def offset_type(self, offset, type):
441 def offset_type(self, offset, type):
442 return long(long(offset) << 16 | type)
442 return long(long(offset) << 16 | type)
443
443
444 def loadindex(self, start, end):
444 def loadindex(self, start, end):
445 """load a block of indexes all at once from the lazy parser"""
445 """load a block of indexes all at once from the lazy parser"""
446 if isinstance(self.index, lazyindex):
446 if isinstance(self.index, lazyindex):
447 self.index.p.loadindex(start, end)
447 self.index.p.loadindex(start, end)
448
448
449 def loadindexmap(self):
449 def loadindexmap(self):
450 """loads both the map and the index from the lazy parser"""
450 """loads both the map and the index from the lazy parser"""
451 if isinstance(self.index, lazyindex):
451 if isinstance(self.index, lazyindex):
452 p = self.index.p
452 p = self.index.p
453 p.loadindex()
453 p.loadindex()
454 self.nodemap = p.map
454 self.nodemap = p.map
455
455
456 def loadmap(self):
456 def loadmap(self):
457 """loads the map from the lazy parser"""
457 """loads the map from the lazy parser"""
458 if isinstance(self.nodemap, lazymap):
458 if isinstance(self.nodemap, lazymap):
459 self.nodemap.p.loadmap()
459 self.nodemap.p.loadmap()
460 self.nodemap = self.nodemap.p.map
460 self.nodemap = self.nodemap.p.map
461
461
462 def inlinedata(self): return self.version & REVLOGNGINLINEDATA
462 def inlinedata(self): return self.version & REVLOGNGINLINEDATA
463 def tip(self): return self.node(len(self.index) - 1)
463 def tip(self): return self.node(len(self.index) - 1)
464 def count(self): return len(self.index)
464 def count(self): return len(self.index)
465 def node(self, rev):
465 def node(self, rev):
466 return (rev < 0) and nullid or self.index[rev][-1]
466 return (rev < 0) and nullid or self.index[rev][-1]
467 def rev(self, node):
467 def rev(self, node):
468 try:
468 try:
469 return self.nodemap[node]
469 return self.nodemap[node]
470 except KeyError:
470 except KeyError:
471 raise RevlogError(_('%s: no node %s') % (self.indexfile, hex(node)))
471 raise RevlogError(_('%s: no node %s') % (self.indexfile, hex(node)))
472 def linkrev(self, node): return self.index[self.rev(node)][-4]
472 def linkrev(self, node): return self.index[self.rev(node)][-4]
473 def parents(self, node):
473 def parents(self, node):
474 if node == nullid: return (nullid, nullid)
474 if node == nullid: return (nullid, nullid)
475 r = self.rev(node)
475 r = self.rev(node)
476 d = self.index[r][-3:-1]
476 d = self.index[r][-3:-1]
477 if self.version == REVLOGV0:
477 if self.version == REVLOGV0:
478 return d
478 return d
479 return [ self.node(x) for x in d ]
479 return [ self.node(x) for x in d ]
480 def parentrevs(self, rev):
480 def parentrevs(self, rev):
481 if rev == -1:
481 if rev == -1:
482 return (-1, -1)
482 return (-1, -1)
483 d = self.index[rev][-3:-1]
483 d = self.index[rev][-3:-1]
484 if self.version == REVLOGV0:
484 if self.version == REVLOGV0:
485 return [ self.rev(x) for x in d ]
485 return [ self.rev(x) for x in d ]
486 return d
486 return d
487 def start(self, rev):
487 def start(self, rev):
488 if rev < 0:
488 if rev < 0:
489 return -1
489 return -1
490 if self.version != REVLOGV0:
490 if self.version != REVLOGV0:
491 return self.ngoffset(self.index[rev][0])
491 return self.ngoffset(self.index[rev][0])
492 return self.index[rev][0]
492 return self.index[rev][0]
493
493
494 def end(self, rev): return self.start(rev) + self.length(rev)
494 def end(self, rev): return self.start(rev) + self.length(rev)
495
495
496 def size(self, rev):
496 def size(self, rev):
497 """return the length of the uncompressed text for a given revision"""
497 """return the length of the uncompressed text for a given revision"""
498 l = -1
498 l = -1
499 if self.version != REVLOGV0:
499 if self.version != REVLOGV0:
500 l = self.index[rev][2]
500 l = self.index[rev][2]
501 if l >= 0:
501 if l >= 0:
502 return l
502 return l
503
503
504 t = self.revision(self.node(rev))
504 t = self.revision(self.node(rev))
505 return len(t)
505 return len(t)
506
506
507 # alternate implementation, The advantage to this code is it
507 # alternate implementation, The advantage to this code is it
508 # will be faster for a single revision. But, the results are not
508 # will be faster for a single revision. But, the results are not
509 # cached, so finding the size of every revision will be slower.
509 # cached, so finding the size of every revision will be slower.
510 """
510 """
511 if self.cache and self.cache[1] == rev:
511 if self.cache and self.cache[1] == rev:
512 return len(self.cache[2])
512 return len(self.cache[2])
513
513
514 base = self.base(rev)
514 base = self.base(rev)
515 if self.cache and self.cache[1] >= base and self.cache[1] < rev:
515 if self.cache and self.cache[1] >= base and self.cache[1] < rev:
516 base = self.cache[1]
516 base = self.cache[1]
517 text = self.cache[2]
517 text = self.cache[2]
518 else:
518 else:
519 text = self.revision(self.node(base))
519 text = self.revision(self.node(base))
520
520
521 l = len(text)
521 l = len(text)
522 for x in xrange(base + 1, rev + 1):
522 for x in xrange(base + 1, rev + 1):
523 l = mdiff.patchedsize(l, self.chunk(x))
523 l = mdiff.patchedsize(l, self.chunk(x))
524 return l
524 return l
525 """
525 """
526
526
527 def length(self, rev):
527 def length(self, rev):
528 if rev < 0:
528 if rev < 0:
529 return 0
529 return 0
530 else:
530 else:
531 return self.index[rev][1]
531 return self.index[rev][1]
532 def base(self, rev): return (rev < 0) and rev or self.index[rev][-5]
532 def base(self, rev): return (rev < 0) and rev or self.index[rev][-5]
533
533
534 def reachable(self, rev, stop=None):
534 def reachable(self, rev, stop=None):
535 reachable = {}
535 reachable = {}
536 visit = [rev]
536 visit = [rev]
537 reachable[rev] = 1
537 reachable[rev] = 1
538 if stop:
538 if stop:
539 stopn = self.rev(stop)
539 stopn = self.rev(stop)
540 else:
540 else:
541 stopn = 0
541 stopn = 0
542 while visit:
542 while visit:
543 n = visit.pop(0)
543 n = visit.pop(0)
544 if n == stop:
544 if n == stop:
545 continue
545 continue
546 if n == nullid:
546 if n == nullid:
547 continue
547 continue
548 for p in self.parents(n):
548 for p in self.parents(n):
549 if self.rev(p) < stopn:
549 if self.rev(p) < stopn:
550 continue
550 continue
551 if p not in reachable:
551 if p not in reachable:
552 reachable[p] = 1
552 reachable[p] = 1
553 visit.append(p)
553 visit.append(p)
554 return reachable
554 return reachable
555
555
556 def nodesbetween(self, roots=None, heads=None):
556 def nodesbetween(self, roots=None, heads=None):
557 """Return a tuple containing three elements. Elements 1 and 2 contain
557 """Return a tuple containing three elements. Elements 1 and 2 contain
558 a final list bases and heads after all the unreachable ones have been
558 a final list bases and heads after all the unreachable ones have been
559 pruned. Element 0 contains a topologically sorted list of all
559 pruned. Element 0 contains a topologically sorted list of all
560
560
561 nodes that satisfy these constraints:
561 nodes that satisfy these constraints:
562 1. All nodes must be descended from a node in roots (the nodes on
562 1. All nodes must be descended from a node in roots (the nodes on
563 roots are considered descended from themselves).
563 roots are considered descended from themselves).
564 2. All nodes must also be ancestors of a node in heads (the nodes in
564 2. All nodes must also be ancestors of a node in heads (the nodes in
565 heads are considered to be their own ancestors).
565 heads are considered to be their own ancestors).
566
566
567 If roots is unspecified, nullid is assumed as the only root.
567 If roots is unspecified, nullid is assumed as the only root.
568 If heads is unspecified, it is taken to be the output of the
568 If heads is unspecified, it is taken to be the output of the
569 heads method (i.e. a list of all nodes in the repository that
569 heads method (i.e. a list of all nodes in the repository that
570 have no children)."""
570 have no children)."""
571 nonodes = ([], [], [])
571 nonodes = ([], [], [])
572 if roots is not None:
572 if roots is not None:
573 roots = list(roots)
573 roots = list(roots)
574 if not roots:
574 if not roots:
575 return nonodes
575 return nonodes
576 lowestrev = min([self.rev(n) for n in roots])
576 lowestrev = min([self.rev(n) for n in roots])
577 else:
577 else:
578 roots = [nullid] # Everybody's a descendent of nullid
578 roots = [nullid] # Everybody's a descendent of nullid
579 lowestrev = -1
579 lowestrev = -1
580 if (lowestrev == -1) and (heads is None):
580 if (lowestrev == -1) and (heads is None):
581 # We want _all_ the nodes!
581 # We want _all_ the nodes!
582 return ([self.node(r) for r in xrange(0, self.count())],
582 return ([self.node(r) for r in xrange(0, self.count())],
583 [nullid], list(self.heads()))
583 [nullid], list(self.heads()))
584 if heads is None:
584 if heads is None:
585 # All nodes are ancestors, so the latest ancestor is the last
585 # All nodes are ancestors, so the latest ancestor is the last
586 # node.
586 # node.
587 highestrev = self.count() - 1
587 highestrev = self.count() - 1
588 # Set ancestors to None to signal that every node is an ancestor.
588 # Set ancestors to None to signal that every node is an ancestor.
589 ancestors = None
589 ancestors = None
590 # Set heads to an empty dictionary for later discovery of heads
590 # Set heads to an empty dictionary for later discovery of heads
591 heads = {}
591 heads = {}
592 else:
592 else:
593 heads = list(heads)
593 heads = list(heads)
594 if not heads:
594 if not heads:
595 return nonodes
595 return nonodes
596 ancestors = {}
596 ancestors = {}
597 # Start at the top and keep marking parents until we're done.
597 # Start at the top and keep marking parents until we're done.
598 nodestotag = heads[:]
598 nodestotag = heads[:]
599 # Turn heads into a dictionary so we can remove 'fake' heads.
599 # Turn heads into a dictionary so we can remove 'fake' heads.
600 # Also, later we will be using it to filter out the heads we can't
600 # Also, later we will be using it to filter out the heads we can't
601 # find from roots.
601 # find from roots.
602 heads = dict.fromkeys(heads, 0)
602 heads = dict.fromkeys(heads, 0)
603 # Remember where the top was so we can use it as a limit later.
603 # Remember where the top was so we can use it as a limit later.
604 highestrev = max([self.rev(n) for n in nodestotag])
604 highestrev = max([self.rev(n) for n in nodestotag])
605 while nodestotag:
605 while nodestotag:
606 # grab a node to tag
606 # grab a node to tag
607 n = nodestotag.pop()
607 n = nodestotag.pop()
608 # Never tag nullid
608 # Never tag nullid
609 if n == nullid:
609 if n == nullid:
610 continue
610 continue
611 # A node's revision number represents its place in a
611 # A node's revision number represents its place in a
612 # topologically sorted list of nodes.
612 # topologically sorted list of nodes.
613 r = self.rev(n)
613 r = self.rev(n)
614 if r >= lowestrev:
614 if r >= lowestrev:
615 if n not in ancestors:
615 if n not in ancestors:
616 # If we are possibly a descendent of one of the roots
616 # If we are possibly a descendent of one of the roots
617 # and we haven't already been marked as an ancestor
617 # and we haven't already been marked as an ancestor
618 ancestors[n] = 1 # Mark as ancestor
618 ancestors[n] = 1 # Mark as ancestor
619 # Add non-nullid parents to list of nodes to tag.
619 # Add non-nullid parents to list of nodes to tag.
620 nodestotag.extend([p for p in self.parents(n) if
620 nodestotag.extend([p for p in self.parents(n) if
621 p != nullid])
621 p != nullid])
622 elif n in heads: # We've seen it before, is it a fake head?
622 elif n in heads: # We've seen it before, is it a fake head?
623 # So it is, real heads should not be the ancestors of
623 # So it is, real heads should not be the ancestors of
624 # any other heads.
624 # any other heads.
625 heads.pop(n)
625 heads.pop(n)
626 if not ancestors:
626 if not ancestors:
627 return nonodes
627 return nonodes
628 # Now that we have our set of ancestors, we want to remove any
628 # Now that we have our set of ancestors, we want to remove any
629 # roots that are not ancestors.
629 # roots that are not ancestors.
630
630
631 # If one of the roots was nullid, everything is included anyway.
631 # If one of the roots was nullid, everything is included anyway.
632 if lowestrev > -1:
632 if lowestrev > -1:
633 # But, since we weren't, let's recompute the lowest rev to not
633 # But, since we weren't, let's recompute the lowest rev to not
634 # include roots that aren't ancestors.
634 # include roots that aren't ancestors.
635
635
636 # Filter out roots that aren't ancestors of heads
636 # Filter out roots that aren't ancestors of heads
637 roots = [n for n in roots if n in ancestors]
637 roots = [n for n in roots if n in ancestors]
638 # Recompute the lowest revision
638 # Recompute the lowest revision
639 if roots:
639 if roots:
640 lowestrev = min([self.rev(n) for n in roots])
640 lowestrev = min([self.rev(n) for n in roots])
641 else:
641 else:
642 # No more roots? Return empty list
642 # No more roots? Return empty list
643 return nonodes
643 return nonodes
644 else:
644 else:
645 # We are descending from nullid, and don't need to care about
645 # We are descending from nullid, and don't need to care about
646 # any other roots.
646 # any other roots.
647 lowestrev = -1
647 lowestrev = -1
648 roots = [nullid]
648 roots = [nullid]
649 # Transform our roots list into a 'set' (i.e. a dictionary where the
649 # Transform our roots list into a 'set' (i.e. a dictionary where the
650 # values don't matter.
650 # values don't matter.
651 descendents = dict.fromkeys(roots, 1)
651 descendents = dict.fromkeys(roots, 1)
652 # Also, keep the original roots so we can filter out roots that aren't
652 # Also, keep the original roots so we can filter out roots that aren't
653 # 'real' roots (i.e. are descended from other roots).
653 # 'real' roots (i.e. are descended from other roots).
654 roots = descendents.copy()
654 roots = descendents.copy()
655 # Our topologically sorted list of output nodes.
655 # Our topologically sorted list of output nodes.
656 orderedout = []
656 orderedout = []
657 # Don't start at nullid since we don't want nullid in our output list,
657 # Don't start at nullid since we don't want nullid in our output list,
658 # and if nullid shows up in descedents, empty parents will look like
658 # and if nullid shows up in descedents, empty parents will look like
659 # they're descendents.
659 # they're descendents.
660 for r in xrange(max(lowestrev, 0), highestrev + 1):
660 for r in xrange(max(lowestrev, 0), highestrev + 1):
661 n = self.node(r)
661 n = self.node(r)
662 isdescendent = False
662 isdescendent = False
663 if lowestrev == -1: # Everybody is a descendent of nullid
663 if lowestrev == -1: # Everybody is a descendent of nullid
664 isdescendent = True
664 isdescendent = True
665 elif n in descendents:
665 elif n in descendents:
666 # n is already a descendent
666 # n is already a descendent
667 isdescendent = True
667 isdescendent = True
668 # This check only needs to be done here because all the roots
668 # This check only needs to be done here because all the roots
669 # will start being marked is descendents before the loop.
669 # will start being marked is descendents before the loop.
670 if n in roots:
670 if n in roots:
671 # If n was a root, check if it's a 'real' root.
671 # If n was a root, check if it's a 'real' root.
672 p = tuple(self.parents(n))
672 p = tuple(self.parents(n))
673 # If any of its parents are descendents, it's not a root.
673 # If any of its parents are descendents, it's not a root.
674 if (p[0] in descendents) or (p[1] in descendents):
674 if (p[0] in descendents) or (p[1] in descendents):
675 roots.pop(n)
675 roots.pop(n)
676 else:
676 else:
677 p = tuple(self.parents(n))
677 p = tuple(self.parents(n))
678 # A node is a descendent if either of its parents are
678 # A node is a descendent if either of its parents are
679 # descendents. (We seeded the dependents list with the roots
679 # descendents. (We seeded the dependents list with the roots
680 # up there, remember?)
680 # up there, remember?)
681 if (p[0] in descendents) or (p[1] in descendents):
681 if (p[0] in descendents) or (p[1] in descendents):
682 descendents[n] = 1
682 descendents[n] = 1
683 isdescendent = True
683 isdescendent = True
684 if isdescendent and ((ancestors is None) or (n in ancestors)):
684 if isdescendent and ((ancestors is None) or (n in ancestors)):
685 # Only include nodes that are both descendents and ancestors.
685 # Only include nodes that are both descendents and ancestors.
686 orderedout.append(n)
686 orderedout.append(n)
687 if (ancestors is not None) and (n in heads):
687 if (ancestors is not None) and (n in heads):
688 # We're trying to figure out which heads are reachable
688 # We're trying to figure out which heads are reachable
689 # from roots.
689 # from roots.
690 # Mark this head as having been reached
690 # Mark this head as having been reached
691 heads[n] = 1
691 heads[n] = 1
692 elif ancestors is None:
692 elif ancestors is None:
693 # Otherwise, we're trying to discover the heads.
693 # Otherwise, we're trying to discover the heads.
694 # Assume this is a head because if it isn't, the next step
694 # Assume this is a head because if it isn't, the next step
695 # will eventually remove it.
695 # will eventually remove it.
696 heads[n] = 1
696 heads[n] = 1
697 # But, obviously its parents aren't.
697 # But, obviously its parents aren't.
698 for p in self.parents(n):
698 for p in self.parents(n):
699 heads.pop(p, None)
699 heads.pop(p, None)
700 heads = [n for n in heads.iterkeys() if heads[n] != 0]
700 heads = [n for n in heads.iterkeys() if heads[n] != 0]
701 roots = roots.keys()
701 roots = roots.keys()
702 assert orderedout
702 assert orderedout
703 assert roots
703 assert roots
704 assert heads
704 assert heads
705 return (orderedout, roots, heads)
705 return (orderedout, roots, heads)
706
706
707 def heads(self, start=None):
707 def heads(self, start=None):
708 """return the list of all nodes that have no children
708 """return the list of all nodes that have no children
709
709
710 if start is specified, only heads that are descendants of
710 if start is specified, only heads that are descendants of
711 start will be returned
711 start will be returned
712
712
713 """
713 """
714 if start is None:
714 if start is None:
715 start = nullid
715 start = nullid
716 reachable = {start: 1}
717 heads = {start: 1}
718 startrev = self.rev(start)
716 startrev = self.rev(start)
717 reachable = {startrev: 1}
718 heads = {startrev: 1}
719
719
720 parentrevs = self.parentrevs
720 for r in xrange(startrev + 1, self.count()):
721 for r in xrange(startrev + 1, self.count()):
721 n = self.node(r)
722 for p in parentrevs(r):
722 for pn in self.parents(n):
723 if p in reachable:
723 if pn in reachable:
724 reachable[r] = 1
724 reachable[n] = 1
725 heads[r] = 1
725 heads[n] = 1
726 if p in heads:
726 if pn in heads:
727 del heads[p]
727 del heads[pn]
728 return [self.node(r) for r in heads]
728 return heads.keys()
729
729
730 def children(self, node):
730 def children(self, node):
731 """find the children of a given node"""
731 """find the children of a given node"""
732 c = []
732 c = []
733 p = self.rev(node)
733 p = self.rev(node)
734 for r in range(p + 1, self.count()):
734 for r in range(p + 1, self.count()):
735 n = self.node(r)
735 n = self.node(r)
736 for pn in self.parents(n):
736 for pn in self.parents(n):
737 if pn == node:
737 if pn == node:
738 c.append(n)
738 c.append(n)
739 continue
739 continue
740 elif pn == nullid:
740 elif pn == nullid:
741 continue
741 continue
742 return c
742 return c
743
743
744 def lookup(self, id):
744 def lookup(self, id):
745 """locate a node based on revision number or subset of hex nodeid"""
745 """locate a node based on revision number or subset of hex nodeid"""
746 try:
746 try:
747 rev = int(id)
747 rev = int(id)
748 if str(rev) != id: raise ValueError
748 if str(rev) != id: raise ValueError
749 if rev < 0: rev = self.count() + rev
749 if rev < 0: rev = self.count() + rev
750 if rev < 0 or rev >= self.count(): raise ValueError
750 if rev < 0 or rev >= self.count(): raise ValueError
751 return self.node(rev)
751 return self.node(rev)
752 except (ValueError, OverflowError):
752 except (ValueError, OverflowError):
753 c = []
753 c = []
754 for n in self.nodemap:
754 for n in self.nodemap:
755 if hex(n).startswith(id):
755 if hex(n).startswith(id):
756 c.append(n)
756 c.append(n)
757 if len(c) > 1: raise RevlogError(_("Ambiguous identifier"))
757 if len(c) > 1: raise RevlogError(_("Ambiguous identifier"))
758 if len(c) < 1: raise RevlogError(_("No match found"))
758 if len(c) < 1: raise RevlogError(_("No match found"))
759 return c[0]
759 return c[0]
760
760
761 return None
761 return None
762
762
763 def diff(self, a, b):
763 def diff(self, a, b):
764 """return a delta between two revisions"""
764 """return a delta between two revisions"""
765 return mdiff.textdiff(a, b)
765 return mdiff.textdiff(a, b)
766
766
767 def patches(self, t, pl):
767 def patches(self, t, pl):
768 """apply a list of patches to a string"""
768 """apply a list of patches to a string"""
769 return mdiff.patches(t, pl)
769 return mdiff.patches(t, pl)
770
770
771 def chunk(self, rev, df=None, cachelen=4096):
771 def chunk(self, rev, df=None, cachelen=4096):
772 start, length = self.start(rev), self.length(rev)
772 start, length = self.start(rev), self.length(rev)
773 inline = self.inlinedata()
773 inline = self.inlinedata()
774 if inline:
774 if inline:
775 start += (rev + 1) * struct.calcsize(self.indexformat)
775 start += (rev + 1) * struct.calcsize(self.indexformat)
776 end = start + length
776 end = start + length
777 def loadcache(df):
777 def loadcache(df):
778 cache_length = max(cachelen, length) # 4k
778 cache_length = max(cachelen, length) # 4k
779 if not df:
779 if not df:
780 if inline:
780 if inline:
781 df = self.opener(self.indexfile)
781 df = self.opener(self.indexfile)
782 else:
782 else:
783 df = self.opener(self.datafile)
783 df = self.opener(self.datafile)
784 df.seek(start)
784 df.seek(start)
785 self.chunkcache = (start, df.read(cache_length))
785 self.chunkcache = (start, df.read(cache_length))
786
786
787 if not self.chunkcache:
787 if not self.chunkcache:
788 loadcache(df)
788 loadcache(df)
789
789
790 cache_start = self.chunkcache[0]
790 cache_start = self.chunkcache[0]
791 cache_end = cache_start + len(self.chunkcache[1])
791 cache_end = cache_start + len(self.chunkcache[1])
792 if start >= cache_start and end <= cache_end:
792 if start >= cache_start and end <= cache_end:
793 # it is cached
793 # it is cached
794 offset = start - cache_start
794 offset = start - cache_start
795 else:
795 else:
796 loadcache(df)
796 loadcache(df)
797 offset = 0
797 offset = 0
798
798
799 #def checkchunk():
799 #def checkchunk():
800 # df = self.opener(self.datafile)
800 # df = self.opener(self.datafile)
801 # df.seek(start)
801 # df.seek(start)
802 # return df.read(length)
802 # return df.read(length)
803 #assert s == checkchunk()
803 #assert s == checkchunk()
804 return decompress(self.chunkcache[1][offset:offset + length])
804 return decompress(self.chunkcache[1][offset:offset + length])
805
805
806 def delta(self, node):
806 def delta(self, node):
807 """return or calculate a delta between a node and its predecessor"""
807 """return or calculate a delta between a node and its predecessor"""
808 r = self.rev(node)
808 r = self.rev(node)
809 return self.revdiff(r - 1, r)
809 return self.revdiff(r - 1, r)
810
810
811 def revdiff(self, rev1, rev2):
811 def revdiff(self, rev1, rev2):
812 """return or calculate a delta between two revisions"""
812 """return or calculate a delta between two revisions"""
813 b1 = self.base(rev1)
813 b1 = self.base(rev1)
814 b2 = self.base(rev2)
814 b2 = self.base(rev2)
815 if b1 == b2 and rev1 + 1 == rev2:
815 if b1 == b2 and rev1 + 1 == rev2:
816 return self.chunk(rev2)
816 return self.chunk(rev2)
817 else:
817 else:
818 return self.diff(self.revision(self.node(rev1)),
818 return self.diff(self.revision(self.node(rev1)),
819 self.revision(self.node(rev2)))
819 self.revision(self.node(rev2)))
820
820
821 def revision(self, node):
821 def revision(self, node):
822 """return an uncompressed revision of a given"""
822 """return an uncompressed revision of a given"""
823 if node == nullid: return ""
823 if node == nullid: return ""
824 if self.cache and self.cache[0] == node: return self.cache[2]
824 if self.cache and self.cache[0] == node: return self.cache[2]
825
825
826 # look up what we need to read
826 # look up what we need to read
827 text = None
827 text = None
828 rev = self.rev(node)
828 rev = self.rev(node)
829 base = self.base(rev)
829 base = self.base(rev)
830
830
831 if self.inlinedata():
831 if self.inlinedata():
832 # we probably have the whole chunk cached
832 # we probably have the whole chunk cached
833 df = None
833 df = None
834 else:
834 else:
835 df = self.opener(self.datafile)
835 df = self.opener(self.datafile)
836
836
837 # do we have useful data cached?
837 # do we have useful data cached?
838 if self.cache and self.cache[1] >= base and self.cache[1] < rev:
838 if self.cache and self.cache[1] >= base and self.cache[1] < rev:
839 base = self.cache[1]
839 base = self.cache[1]
840 text = self.cache[2]
840 text = self.cache[2]
841 self.loadindex(base, rev + 1)
841 self.loadindex(base, rev + 1)
842 else:
842 else:
843 self.loadindex(base, rev + 1)
843 self.loadindex(base, rev + 1)
844 text = self.chunk(base, df=df)
844 text = self.chunk(base, df=df)
845
845
846 bins = []
846 bins = []
847 for r in xrange(base + 1, rev + 1):
847 for r in xrange(base + 1, rev + 1):
848 bins.append(self.chunk(r, df=df))
848 bins.append(self.chunk(r, df=df))
849
849
850 text = self.patches(text, bins)
850 text = self.patches(text, bins)
851
851
852 p1, p2 = self.parents(node)
852 p1, p2 = self.parents(node)
853 if node != hash(text, p1, p2):
853 if node != hash(text, p1, p2):
854 raise RevlogError(_("integrity check failed on %s:%d")
854 raise RevlogError(_("integrity check failed on %s:%d")
855 % (self.datafile, rev))
855 % (self.datafile, rev))
856
856
857 self.cache = (node, rev, text)
857 self.cache = (node, rev, text)
858 return text
858 return text
859
859
860 def checkinlinesize(self, tr, fp=None):
860 def checkinlinesize(self, tr, fp=None):
861 if not self.inlinedata():
861 if not self.inlinedata():
862 return
862 return
863 if not fp:
863 if not fp:
864 fp = self.opener(self.indexfile, 'r')
864 fp = self.opener(self.indexfile, 'r')
865 fp.seek(0, 2)
865 fp.seek(0, 2)
866 size = fp.tell()
866 size = fp.tell()
867 if size < 131072:
867 if size < 131072:
868 return
868 return
869 trinfo = tr.find(self.indexfile)
869 trinfo = tr.find(self.indexfile)
870 if trinfo == None:
870 if trinfo == None:
871 raise RevlogError(_("%s not found in the transaction" %
871 raise RevlogError(_("%s not found in the transaction" %
872 self.indexfile))
872 self.indexfile))
873
873
874 trindex = trinfo[2]
874 trindex = trinfo[2]
875 dataoff = self.start(trindex)
875 dataoff = self.start(trindex)
876
876
877 tr.add(self.datafile, dataoff)
877 tr.add(self.datafile, dataoff)
878 df = self.opener(self.datafile, 'w')
878 df = self.opener(self.datafile, 'w')
879 calc = struct.calcsize(self.indexformat)
879 calc = struct.calcsize(self.indexformat)
880 for r in xrange(self.count()):
880 for r in xrange(self.count()):
881 start = self.start(r) + (r + 1) * calc
881 start = self.start(r) + (r + 1) * calc
882 length = self.length(r)
882 length = self.length(r)
883 fp.seek(start)
883 fp.seek(start)
884 d = fp.read(length)
884 d = fp.read(length)
885 df.write(d)
885 df.write(d)
886 fp.close()
886 fp.close()
887 df.close()
887 df.close()
888 fp = self.opener(self.indexfile, 'w', atomictemp=True)
888 fp = self.opener(self.indexfile, 'w', atomictemp=True)
889 self.version &= ~(REVLOGNGINLINEDATA)
889 self.version &= ~(REVLOGNGINLINEDATA)
890 if self.count():
890 if self.count():
891 x = self.index[0]
891 x = self.index[0]
892 e = struct.pack(self.indexformat, *x)[4:]
892 e = struct.pack(self.indexformat, *x)[4:]
893 l = struct.pack(versionformat, self.version)
893 l = struct.pack(versionformat, self.version)
894 fp.write(l)
894 fp.write(l)
895 fp.write(e)
895 fp.write(e)
896
896
897 for i in xrange(1, self.count()):
897 for i in xrange(1, self.count()):
898 x = self.index[i]
898 x = self.index[i]
899 e = struct.pack(self.indexformat, *x)
899 e = struct.pack(self.indexformat, *x)
900 fp.write(e)
900 fp.write(e)
901
901
902 # if we don't call rename, the temp file will never replace the
902 # if we don't call rename, the temp file will never replace the
903 # real index
903 # real index
904 fp.rename()
904 fp.rename()
905
905
906 tr.replace(self.indexfile, trindex * calc)
906 tr.replace(self.indexfile, trindex * calc)
907 self.chunkcache = None
907 self.chunkcache = None
908
908
909 def addrevision(self, text, transaction, link, p1=None, p2=None, d=None):
909 def addrevision(self, text, transaction, link, p1=None, p2=None, d=None):
910 """add a revision to the log
910 """add a revision to the log
911
911
912 text - the revision data to add
912 text - the revision data to add
913 transaction - the transaction object used for rollback
913 transaction - the transaction object used for rollback
914 link - the linkrev data to add
914 link - the linkrev data to add
915 p1, p2 - the parent nodeids of the revision
915 p1, p2 - the parent nodeids of the revision
916 d - an optional precomputed delta
916 d - an optional precomputed delta
917 """
917 """
918 if text is None: text = ""
918 if text is None: text = ""
919 if p1 is None: p1 = self.tip()
919 if p1 is None: p1 = self.tip()
920 if p2 is None: p2 = nullid
920 if p2 is None: p2 = nullid
921
921
922 node = hash(text, p1, p2)
922 node = hash(text, p1, p2)
923
923
924 if node in self.nodemap:
924 if node in self.nodemap:
925 return node
925 return node
926
926
927 n = self.count()
927 n = self.count()
928 t = n - 1
928 t = n - 1
929
929
930 if n:
930 if n:
931 base = self.base(t)
931 base = self.base(t)
932 start = self.start(base)
932 start = self.start(base)
933 end = self.end(t)
933 end = self.end(t)
934 if not d:
934 if not d:
935 prev = self.revision(self.tip())
935 prev = self.revision(self.tip())
936 d = self.diff(prev, str(text))
936 d = self.diff(prev, str(text))
937 data = compress(d)
937 data = compress(d)
938 l = len(data[1]) + len(data[0])
938 l = len(data[1]) + len(data[0])
939 dist = end - start + l
939 dist = end - start + l
940
940
941 # full versions are inserted when the needed deltas
941 # full versions are inserted when the needed deltas
942 # become comparable to the uncompressed text
942 # become comparable to the uncompressed text
943 if not n or dist > len(text) * 2:
943 if not n or dist > len(text) * 2:
944 data = compress(text)
944 data = compress(text)
945 l = len(data[1]) + len(data[0])
945 l = len(data[1]) + len(data[0])
946 base = n
946 base = n
947 else:
947 else:
948 base = self.base(t)
948 base = self.base(t)
949
949
950 offset = 0
950 offset = 0
951 if t >= 0:
951 if t >= 0:
952 offset = self.end(t)
952 offset = self.end(t)
953
953
954 if self.version == REVLOGV0:
954 if self.version == REVLOGV0:
955 e = (offset, l, base, link, p1, p2, node)
955 e = (offset, l, base, link, p1, p2, node)
956 else:
956 else:
957 e = (self.offset_type(offset, 0), l, len(text),
957 e = (self.offset_type(offset, 0), l, len(text),
958 base, link, self.rev(p1), self.rev(p2), node)
958 base, link, self.rev(p1), self.rev(p2), node)
959
959
960 self.index.append(e)
960 self.index.append(e)
961 self.nodemap[node] = n
961 self.nodemap[node] = n
962 entry = struct.pack(self.indexformat, *e)
962 entry = struct.pack(self.indexformat, *e)
963
963
964 if not self.inlinedata():
964 if not self.inlinedata():
965 transaction.add(self.datafile, offset)
965 transaction.add(self.datafile, offset)
966 transaction.add(self.indexfile, n * len(entry))
966 transaction.add(self.indexfile, n * len(entry))
967 f = self.opener(self.datafile, "a")
967 f = self.opener(self.datafile, "a")
968 if data[0]:
968 if data[0]:
969 f.write(data[0])
969 f.write(data[0])
970 f.write(data[1])
970 f.write(data[1])
971 f.close()
971 f.close()
972 f = self.opener(self.indexfile, "a")
972 f = self.opener(self.indexfile, "a")
973 else:
973 else:
974 f = self.opener(self.indexfile, "a+")
974 f = self.opener(self.indexfile, "a+")
975 f.seek(0, 2)
975 f.seek(0, 2)
976 transaction.add(self.indexfile, f.tell(), self.count() - 1)
976 transaction.add(self.indexfile, f.tell(), self.count() - 1)
977
977
978 if len(self.index) == 1 and self.version != REVLOGV0:
978 if len(self.index) == 1 and self.version != REVLOGV0:
979 l = struct.pack(versionformat, self.version)
979 l = struct.pack(versionformat, self.version)
980 f.write(l)
980 f.write(l)
981 entry = entry[4:]
981 entry = entry[4:]
982
982
983 f.write(entry)
983 f.write(entry)
984
984
985 if self.inlinedata():
985 if self.inlinedata():
986 f.write(data[0])
986 f.write(data[0])
987 f.write(data[1])
987 f.write(data[1])
988 self.checkinlinesize(transaction, f)
988 self.checkinlinesize(transaction, f)
989
989
990 self.cache = (node, n, text)
990 self.cache = (node, n, text)
991 return node
991 return node
992
992
993 def ancestor(self, a, b):
993 def ancestor(self, a, b):
994 """calculate the least common ancestor of nodes a and b"""
994 """calculate the least common ancestor of nodes a and b"""
995
995
996 # start with some short cuts for the linear cases
996 # start with some short cuts for the linear cases
997 if a == b:
997 if a == b:
998 return a
998 return a
999 ra = self.rev(a)
999 ra = self.rev(a)
1000 rb = self.rev(b)
1000 rb = self.rev(b)
1001 if ra < rb:
1001 if ra < rb:
1002 last = b
1002 last = b
1003 first = a
1003 first = a
1004 else:
1004 else:
1005 last = a
1005 last = a
1006 first = b
1006 first = b
1007
1007
1008 # reachable won't include stop in the list, so we have to use a parent
1008 # reachable won't include stop in the list, so we have to use a parent
1009 reachable = self.reachable(last, stop=self.parents(first)[0])
1009 reachable = self.reachable(last, stop=self.parents(first)[0])
1010 if first in reachable:
1010 if first in reachable:
1011 return first
1011 return first
1012
1012
1013 # calculate the distance of every node from root
1013 # calculate the distance of every node from root
1014 dist = {nullid: 0}
1014 dist = {nullid: 0}
1015 for i in xrange(self.count()):
1015 for i in xrange(self.count()):
1016 n = self.node(i)
1016 n = self.node(i)
1017 p1, p2 = self.parents(n)
1017 p1, p2 = self.parents(n)
1018 dist[n] = max(dist[p1], dist[p2]) + 1
1018 dist[n] = max(dist[p1], dist[p2]) + 1
1019
1019
1020 # traverse ancestors in order of decreasing distance from root
1020 # traverse ancestors in order of decreasing distance from root
1021 def ancestors(node):
1021 def ancestors(node):
1022 # we store negative distances because heap returns smallest member
1022 # we store negative distances because heap returns smallest member
1023 h = [(-dist[node], node)]
1023 h = [(-dist[node], node)]
1024 seen = {}
1024 seen = {}
1025 while h:
1025 while h:
1026 d, n = heapq.heappop(h)
1026 d, n = heapq.heappop(h)
1027 if n not in seen:
1027 if n not in seen:
1028 seen[n] = 1
1028 seen[n] = 1
1029 yield (-d, n)
1029 yield (-d, n)
1030 for p in self.parents(n):
1030 for p in self.parents(n):
1031 heapq.heappush(h, (-dist[p], p))
1031 heapq.heappush(h, (-dist[p], p))
1032
1032
1033 def generations(node):
1033 def generations(node):
1034 sg, s = None, {}
1034 sg, s = None, {}
1035 for g,n in ancestors(node):
1035 for g,n in ancestors(node):
1036 if g != sg:
1036 if g != sg:
1037 if sg:
1037 if sg:
1038 yield sg, s
1038 yield sg, s
1039 sg, s = g, {n:1}
1039 sg, s = g, {n:1}
1040 else:
1040 else:
1041 s[n] = 1
1041 s[n] = 1
1042 yield sg, s
1042 yield sg, s
1043
1043
1044 x = generations(a)
1044 x = generations(a)
1045 y = generations(b)
1045 y = generations(b)
1046 gx = x.next()
1046 gx = x.next()
1047 gy = y.next()
1047 gy = y.next()
1048
1048
1049 # increment each ancestor list until it is closer to root than
1049 # increment each ancestor list until it is closer to root than
1050 # the other, or they match
1050 # the other, or they match
1051 while 1:
1051 while 1:
1052 #print "ancestor gen %s %s" % (gx[0], gy[0])
1052 #print "ancestor gen %s %s" % (gx[0], gy[0])
1053 if gx[0] == gy[0]:
1053 if gx[0] == gy[0]:
1054 # find the intersection
1054 # find the intersection
1055 i = [ n for n in gx[1] if n in gy[1] ]
1055 i = [ n for n in gx[1] if n in gy[1] ]
1056 if i:
1056 if i:
1057 return i[0]
1057 return i[0]
1058 else:
1058 else:
1059 #print "next"
1059 #print "next"
1060 gy = y.next()
1060 gy = y.next()
1061 gx = x.next()
1061 gx = x.next()
1062 elif gx[0] < gy[0]:
1062 elif gx[0] < gy[0]:
1063 #print "next y"
1063 #print "next y"
1064 gy = y.next()
1064 gy = y.next()
1065 else:
1065 else:
1066 #print "next x"
1066 #print "next x"
1067 gx = x.next()
1067 gx = x.next()
1068
1068
1069 def group(self, nodelist, lookup, infocollect=None):
1069 def group(self, nodelist, lookup, infocollect=None):
1070 """calculate a delta group
1070 """calculate a delta group
1071
1071
1072 Given a list of changeset revs, return a set of deltas and
1072 Given a list of changeset revs, return a set of deltas and
1073 metadata corresponding to nodes. the first delta is
1073 metadata corresponding to nodes. the first delta is
1074 parent(nodes[0]) -> nodes[0] the receiver is guaranteed to
1074 parent(nodes[0]) -> nodes[0] the receiver is guaranteed to
1075 have this parent as it has all history before these
1075 have this parent as it has all history before these
1076 changesets. parent is parent[0]
1076 changesets. parent is parent[0]
1077 """
1077 """
1078 revs = [self.rev(n) for n in nodelist]
1078 revs = [self.rev(n) for n in nodelist]
1079
1079
1080 # if we don't have any revisions touched by these changesets, bail
1080 # if we don't have any revisions touched by these changesets, bail
1081 if not revs:
1081 if not revs:
1082 yield changegroup.closechunk()
1082 yield changegroup.closechunk()
1083 return
1083 return
1084
1084
1085 # add the parent of the first rev
1085 # add the parent of the first rev
1086 p = self.parents(self.node(revs[0]))[0]
1086 p = self.parents(self.node(revs[0]))[0]
1087 revs.insert(0, self.rev(p))
1087 revs.insert(0, self.rev(p))
1088
1088
1089 # build deltas
1089 # build deltas
1090 for d in xrange(0, len(revs) - 1):
1090 for d in xrange(0, len(revs) - 1):
1091 a, b = revs[d], revs[d + 1]
1091 a, b = revs[d], revs[d + 1]
1092 nb = self.node(b)
1092 nb = self.node(b)
1093
1093
1094 if infocollect is not None:
1094 if infocollect is not None:
1095 infocollect(nb)
1095 infocollect(nb)
1096
1096
1097 d = self.revdiff(a, b)
1097 d = self.revdiff(a, b)
1098 p = self.parents(nb)
1098 p = self.parents(nb)
1099 meta = nb + p[0] + p[1] + lookup(nb)
1099 meta = nb + p[0] + p[1] + lookup(nb)
1100 yield changegroup.genchunk("%s%s" % (meta, d))
1100 yield changegroup.genchunk("%s%s" % (meta, d))
1101
1101
1102 yield changegroup.closechunk()
1102 yield changegroup.closechunk()
1103
1103
1104 def addgroup(self, revs, linkmapper, transaction, unique=0):
1104 def addgroup(self, revs, linkmapper, transaction, unique=0):
1105 """
1105 """
1106 add a delta group
1106 add a delta group
1107
1107
1108 given a set of deltas, add them to the revision log. the
1108 given a set of deltas, add them to the revision log. the
1109 first delta is against its parent, which should be in our
1109 first delta is against its parent, which should be in our
1110 log, the rest are against the previous delta.
1110 log, the rest are against the previous delta.
1111 """
1111 """
1112
1112
1113 #track the base of the current delta log
1113 #track the base of the current delta log
1114 r = self.count()
1114 r = self.count()
1115 t = r - 1
1115 t = r - 1
1116 node = None
1116 node = None
1117
1117
1118 base = prev = -1
1118 base = prev = -1
1119 start = end = textlen = 0
1119 start = end = textlen = 0
1120 if r:
1120 if r:
1121 end = self.end(t)
1121 end = self.end(t)
1122
1122
1123 ifh = self.opener(self.indexfile, "a+")
1123 ifh = self.opener(self.indexfile, "a+")
1124 ifh.seek(0, 2)
1124 ifh.seek(0, 2)
1125 transaction.add(self.indexfile, ifh.tell(), self.count())
1125 transaction.add(self.indexfile, ifh.tell(), self.count())
1126 if self.inlinedata():
1126 if self.inlinedata():
1127 dfh = None
1127 dfh = None
1128 else:
1128 else:
1129 transaction.add(self.datafile, end)
1129 transaction.add(self.datafile, end)
1130 dfh = self.opener(self.datafile, "a")
1130 dfh = self.opener(self.datafile, "a")
1131
1131
1132 # loop through our set of deltas
1132 # loop through our set of deltas
1133 chain = None
1133 chain = None
1134 for chunk in revs:
1134 for chunk in revs:
1135 node, p1, p2, cs = struct.unpack("20s20s20s20s", chunk[:80])
1135 node, p1, p2, cs = struct.unpack("20s20s20s20s", chunk[:80])
1136 link = linkmapper(cs)
1136 link = linkmapper(cs)
1137 if node in self.nodemap:
1137 if node in self.nodemap:
1138 # this can happen if two branches make the same change
1138 # this can happen if two branches make the same change
1139 # if unique:
1139 # if unique:
1140 # raise RevlogError(_("already have %s") % hex(node[:4]))
1140 # raise RevlogError(_("already have %s") % hex(node[:4]))
1141 chain = node
1141 chain = node
1142 continue
1142 continue
1143 delta = chunk[80:]
1143 delta = chunk[80:]
1144
1144
1145 for p in (p1, p2):
1145 for p in (p1, p2):
1146 if not p in self.nodemap:
1146 if not p in self.nodemap:
1147 raise RevlogError(_("unknown parent %s") % short(p))
1147 raise RevlogError(_("unknown parent %s") % short(p))
1148
1148
1149 if not chain:
1149 if not chain:
1150 # retrieve the parent revision of the delta chain
1150 # retrieve the parent revision of the delta chain
1151 chain = p1
1151 chain = p1
1152 if not chain in self.nodemap:
1152 if not chain in self.nodemap:
1153 raise RevlogError(_("unknown base %s") % short(chain[:4]))
1153 raise RevlogError(_("unknown base %s") % short(chain[:4]))
1154
1154
1155 # full versions are inserted when the needed deltas become
1155 # full versions are inserted when the needed deltas become
1156 # comparable to the uncompressed text or when the previous
1156 # comparable to the uncompressed text or when the previous
1157 # version is not the one we have a delta against. We use
1157 # version is not the one we have a delta against. We use
1158 # the size of the previous full rev as a proxy for the
1158 # the size of the previous full rev as a proxy for the
1159 # current size.
1159 # current size.
1160
1160
1161 if chain == prev:
1161 if chain == prev:
1162 tempd = compress(delta)
1162 tempd = compress(delta)
1163 cdelta = tempd[0] + tempd[1]
1163 cdelta = tempd[0] + tempd[1]
1164 textlen = mdiff.patchedsize(textlen, delta)
1164 textlen = mdiff.patchedsize(textlen, delta)
1165
1165
1166 if chain != prev or (end - start + len(cdelta)) > textlen * 2:
1166 if chain != prev or (end - start + len(cdelta)) > textlen * 2:
1167 # flush our writes here so we can read it in revision
1167 # flush our writes here so we can read it in revision
1168 if dfh:
1168 if dfh:
1169 dfh.flush()
1169 dfh.flush()
1170 ifh.flush()
1170 ifh.flush()
1171 text = self.revision(chain)
1171 text = self.revision(chain)
1172 text = self.patches(text, [delta])
1172 text = self.patches(text, [delta])
1173 chk = self.addrevision(text, transaction, link, p1, p2)
1173 chk = self.addrevision(text, transaction, link, p1, p2)
1174 if chk != node:
1174 if chk != node:
1175 raise RevlogError(_("consistency error adding group"))
1175 raise RevlogError(_("consistency error adding group"))
1176 textlen = len(text)
1176 textlen = len(text)
1177 else:
1177 else:
1178 if self.version == REVLOGV0:
1178 if self.version == REVLOGV0:
1179 e = (end, len(cdelta), base, link, p1, p2, node)
1179 e = (end, len(cdelta), base, link, p1, p2, node)
1180 else:
1180 else:
1181 e = (self.offset_type(end, 0), len(cdelta), textlen, base,
1181 e = (self.offset_type(end, 0), len(cdelta), textlen, base,
1182 link, self.rev(p1), self.rev(p2), node)
1182 link, self.rev(p1), self.rev(p2), node)
1183 self.index.append(e)
1183 self.index.append(e)
1184 self.nodemap[node] = r
1184 self.nodemap[node] = r
1185 if self.inlinedata():
1185 if self.inlinedata():
1186 ifh.write(struct.pack(self.indexformat, *e))
1186 ifh.write(struct.pack(self.indexformat, *e))
1187 ifh.write(cdelta)
1187 ifh.write(cdelta)
1188 self.checkinlinesize(transaction, ifh)
1188 self.checkinlinesize(transaction, ifh)
1189 if not self.inlinedata():
1189 if not self.inlinedata():
1190 dfh = self.opener(self.datafile, "a")
1190 dfh = self.opener(self.datafile, "a")
1191 ifh = self.opener(self.indexfile, "a")
1191 ifh = self.opener(self.indexfile, "a")
1192 else:
1192 else:
1193 if not dfh:
1193 if not dfh:
1194 # addrevision switched from inline to conventional
1194 # addrevision switched from inline to conventional
1195 # reopen the index
1195 # reopen the index
1196 dfh = self.opener(self.datafile, "a")
1196 dfh = self.opener(self.datafile, "a")
1197 ifh = self.opener(self.indexfile, "a")
1197 ifh = self.opener(self.indexfile, "a")
1198 dfh.write(cdelta)
1198 dfh.write(cdelta)
1199 ifh.write(struct.pack(self.indexformat, *e))
1199 ifh.write(struct.pack(self.indexformat, *e))
1200
1200
1201 t, r, chain, prev = r, r + 1, node, node
1201 t, r, chain, prev = r, r + 1, node, node
1202 base = self.base(t)
1202 base = self.base(t)
1203 start = self.start(base)
1203 start = self.start(base)
1204 end = self.end(t)
1204 end = self.end(t)
1205
1205
1206 return node
1206 return node
1207
1207
1208 def strip(self, rev, minlink):
1208 def strip(self, rev, minlink):
1209 if self.count() == 0 or rev >= self.count():
1209 if self.count() == 0 or rev >= self.count():
1210 return
1210 return
1211
1211
1212 if isinstance(self.index, lazyindex):
1212 if isinstance(self.index, lazyindex):
1213 self.loadindexmap()
1213 self.loadindexmap()
1214
1214
1215 # When stripping away a revision, we need to make sure it
1215 # When stripping away a revision, we need to make sure it
1216 # does not actually belong to an older changeset.
1216 # does not actually belong to an older changeset.
1217 # The minlink parameter defines the oldest revision
1217 # The minlink parameter defines the oldest revision
1218 # we're allowed to strip away.
1218 # we're allowed to strip away.
1219 while minlink > self.index[rev][-4]:
1219 while minlink > self.index[rev][-4]:
1220 rev += 1
1220 rev += 1
1221 if rev >= self.count():
1221 if rev >= self.count():
1222 return
1222 return
1223
1223
1224 # first truncate the files on disk
1224 # first truncate the files on disk
1225 end = self.start(rev)
1225 end = self.start(rev)
1226 if not self.inlinedata():
1226 if not self.inlinedata():
1227 df = self.opener(self.datafile, "a")
1227 df = self.opener(self.datafile, "a")
1228 df.truncate(end)
1228 df.truncate(end)
1229 end = rev * struct.calcsize(self.indexformat)
1229 end = rev * struct.calcsize(self.indexformat)
1230 else:
1230 else:
1231 end += rev * struct.calcsize(self.indexformat)
1231 end += rev * struct.calcsize(self.indexformat)
1232
1232
1233 indexf = self.opener(self.indexfile, "a")
1233 indexf = self.opener(self.indexfile, "a")
1234 indexf.truncate(end)
1234 indexf.truncate(end)
1235
1235
1236 # then reset internal state in memory to forget those revisions
1236 # then reset internal state in memory to forget those revisions
1237 self.cache = None
1237 self.cache = None
1238 self.chunkcache = None
1238 self.chunkcache = None
1239 for x in xrange(rev, self.count()):
1239 for x in xrange(rev, self.count()):
1240 del self.nodemap[self.node(x)]
1240 del self.nodemap[self.node(x)]
1241
1241
1242 del self.index[rev:]
1242 del self.index[rev:]
1243
1243
1244 def checksize(self):
1244 def checksize(self):
1245 expected = 0
1245 expected = 0
1246 if self.count():
1246 if self.count():
1247 expected = self.end(self.count() - 1)
1247 expected = self.end(self.count() - 1)
1248
1248
1249 try:
1249 try:
1250 f = self.opener(self.datafile)
1250 f = self.opener(self.datafile)
1251 f.seek(0, 2)
1251 f.seek(0, 2)
1252 actual = f.tell()
1252 actual = f.tell()
1253 dd = actual - expected
1253 dd = actual - expected
1254 except IOError, inst:
1254 except IOError, inst:
1255 if inst.errno != errno.ENOENT:
1255 if inst.errno != errno.ENOENT:
1256 raise
1256 raise
1257 dd = 0
1257 dd = 0
1258
1258
1259 try:
1259 try:
1260 f = self.opener(self.indexfile)
1260 f = self.opener(self.indexfile)
1261 f.seek(0, 2)
1261 f.seek(0, 2)
1262 actual = f.tell()
1262 actual = f.tell()
1263 s = struct.calcsize(self.indexformat)
1263 s = struct.calcsize(self.indexformat)
1264 i = actual / s
1264 i = actual / s
1265 di = actual - (i * s)
1265 di = actual - (i * s)
1266 if self.inlinedata():
1266 if self.inlinedata():
1267 databytes = 0
1267 databytes = 0
1268 for r in xrange(self.count()):
1268 for r in xrange(self.count()):
1269 databytes += self.length(r)
1269 databytes += self.length(r)
1270 dd = 0
1270 dd = 0
1271 di = actual - self.count() * s - databytes
1271 di = actual - self.count() * s - databytes
1272 except IOError, inst:
1272 except IOError, inst:
1273 if inst.errno != errno.ENOENT:
1273 if inst.errno != errno.ENOENT:
1274 raise
1274 raise
1275 di = 0
1275 di = 0
1276
1276
1277 return (dd, di)
1277 return (dd, di)
1278
1278
1279
1279
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