##// END OF EJS Templates
context: use new manifest.diff(clean=True) support...
context: use new manifest.diff(clean=True) support This further simplifies the status code. This simplification comes at a slight performance cost for `hg export`. Before, on mozilla-central: perfmanifest tip ! wall 0.265977 comb 0.260000 user 0.240000 sys 0.020000 (best of 38) perftags ! result: 162 ! wall 0.007172 comb 0.010000 user 0.000000 sys 0.010000 (best of 403) perfstatus ! wall 0.422302 comb 0.420000 user 0.260000 sys 0.160000 (best of 24) hgperf export tip ! wall 0.148706 comb 0.150000 user 0.150000 sys 0.000000 (best of 65) after, same repo: perfmanifest tip ! wall 0.267143 comb 0.270000 user 0.250000 sys 0.020000 (best of 37) perftags ! result: 162 ! wall 0.006943 comb 0.010000 user 0.000000 sys 0.010000 (best of 397) perfstatus ! wall 0.411198 comb 0.410000 user 0.260000 sys 0.150000 (best of 24) hgperf export tip ! wall 0.173229 comb 0.170000 user 0.170000 sys 0.000000 (best of 55) The next set of patches introduces a new manifest type implemented almost entirely in C, and more than makes up for the performance hit incurred in this change.

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copies.py
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# copies.py - copy detection for Mercurial
#
# Copyright 2008 Matt Mackall <mpm@selenic.com>
#
# This software may be used and distributed according to the terms of the
# GNU General Public License version 2 or any later version.
import util
import heapq
def _nonoverlap(d1, d2, d3):
"Return list of elements in d1 not in d2 or d3"
return sorted([d for d in d1 if d not in d3 and d not in d2])
def _dirname(f):
s = f.rfind("/")
if s == -1:
return ""
return f[:s]
def _findlimit(repo, a, b):
"""
Find the last revision that needs to be checked to ensure that a full
transitive closure for file copies can be properly calculated.
Generally, this means finding the earliest revision number that's an
ancestor of a or b but not both, except when a or b is a direct descendent
of the other, in which case we can return the minimum revnum of a and b.
None if no such revision exists.
"""
# basic idea:
# - mark a and b with different sides
# - if a parent's children are all on the same side, the parent is
# on that side, otherwise it is on no side
# - walk the graph in topological order with the help of a heap;
# - add unseen parents to side map
# - clear side of any parent that has children on different sides
# - track number of interesting revs that might still be on a side
# - track the lowest interesting rev seen
# - quit when interesting revs is zero
cl = repo.changelog
working = len(cl) # pseudo rev for the working directory
if a is None:
a = working
if b is None:
b = working
side = {a: -1, b: 1}
visit = [-a, -b]
heapq.heapify(visit)
interesting = len(visit)
hascommonancestor = False
limit = working
while interesting:
r = -heapq.heappop(visit)
if r == working:
parents = [cl.rev(p) for p in repo.dirstate.parents()]
else:
parents = cl.parentrevs(r)
for p in parents:
if p < 0:
continue
if p not in side:
# first time we see p; add it to visit
side[p] = side[r]
if side[p]:
interesting += 1
heapq.heappush(visit, -p)
elif side[p] and side[p] != side[r]:
# p was interesting but now we know better
side[p] = 0
interesting -= 1
hascommonancestor = True
if side[r]:
limit = r # lowest rev visited
interesting -= 1
if not hascommonancestor:
return None
# Consider the following flow (see test-commit-amend.t under issue4405):
# 1/ File 'a0' committed
# 2/ File renamed from 'a0' to 'a1' in a new commit (call it 'a1')
# 3/ Move back to first commit
# 4/ Create a new commit via revert to contents of 'a1' (call it 'a1-amend')
# 5/ Rename file from 'a1' to 'a2' and commit --amend 'a1-msg'
#
# During the amend in step five, we will be in this state:
#
# @ 3 temporary amend commit for a1-amend
# |
# o 2 a1-amend
# |
# | o 1 a1
# |/
# o 0 a0
#
# When _findlimit is called, a and b are revs 3 and 0, so limit will be 2,
# yet the filelog has the copy information in rev 1 and we will not look
# back far enough unless we also look at the a and b as candidates.
# This only occurs when a is a descendent of b or visa-versa.
return min(limit, a, b)
def _chain(src, dst, a, b):
'''chain two sets of copies a->b'''
t = a.copy()
for k, v in b.iteritems():
if v in t:
# found a chain
if t[v] != k:
# file wasn't renamed back to itself
t[k] = t[v]
if v not in dst:
# chain was a rename, not a copy
del t[v]
if v in src:
# file is a copy of an existing file
t[k] = v
# remove criss-crossed copies
for k, v in t.items():
if k in src and v in dst:
del t[k]
return t
def _tracefile(fctx, am, limit=-1):
'''return file context that is the ancestor of fctx present in ancestor
manifest am, stopping after the first ancestor lower than limit'''
for f in fctx.ancestors():
if am.get(f.path(), None) == f.filenode():
return f
if f.rev() < limit:
return None
def _dirstatecopies(d):
ds = d._repo.dirstate
c = ds.copies().copy()
for k in c.keys():
if ds[k] not in 'anm':
del c[k]
return c
def _forwardcopies(a, b):
'''find {dst@b: src@a} copy mapping where a is an ancestor of b'''
# check for working copy
w = None
if b.rev() is None:
w = b
b = w.p1()
if a == b:
# short-circuit to avoid issues with merge states
return _dirstatecopies(w)
# files might have to be traced back to the fctx parent of the last
# one-side-only changeset, but not further back than that
limit = _findlimit(a._repo, a.rev(), b.rev())
if limit is None:
limit = -1
am = a.manifest()
# find where new files came from
# we currently don't try to find where old files went, too expensive
# this means we can miss a case like 'hg rm b; hg cp a b'
cm = {}
missing = set(b.manifest().iterkeys())
missing.difference_update(a.manifest().iterkeys())
for f in missing:
ofctx = _tracefile(b[f], am, limit)
if ofctx:
cm[f] = ofctx.path()
# combine copies from dirstate if necessary
if w is not None:
cm = _chain(a, w, cm, _dirstatecopies(w))
return cm
def _backwardrenames(a, b):
# Even though we're not taking copies into account, 1:n rename situations
# can still exist (e.g. hg cp a b; hg mv a c). In those cases we
# arbitrarily pick one of the renames.
f = _forwardcopies(b, a)
r = {}
for k, v in sorted(f.iteritems()):
# remove copies
if v in a:
continue
r[v] = k
return r
def pathcopies(x, y):
'''find {dst@y: src@x} copy mapping for directed compare'''
if x == y or not x or not y:
return {}
a = y.ancestor(x)
if a == x:
return _forwardcopies(x, y)
if a == y:
return _backwardrenames(x, y)
return _chain(x, y, _backwardrenames(x, a), _forwardcopies(a, y))
def mergecopies(repo, c1, c2, ca):
"""
Find moves and copies between context c1 and c2 that are relevant
for merging.
Returns four dicts: "copy", "movewithdir", "diverge", and
"renamedelete".
"copy" is a mapping from destination name -> source name,
where source is in c1 and destination is in c2 or vice-versa.
"movewithdir" is a mapping from source name -> destination name,
where the file at source present in one context but not the other
needs to be moved to destination by the merge process, because the
other context moved the directory it is in.
"diverge" is a mapping of source name -> list of destination names
for divergent renames.
"renamedelete" is a mapping of source name -> list of destination
names for files deleted in c1 that were renamed in c2 or vice-versa.
"""
# avoid silly behavior for update from empty dir
if not c1 or not c2 or c1 == c2:
return {}, {}, {}, {}
# avoid silly behavior for parent -> working dir
if c2.node() is None and c1.node() == repo.dirstate.p1():
return repo.dirstate.copies(), {}, {}, {}
limit = _findlimit(repo, c1.rev(), c2.rev())
if limit is None:
# no common ancestor, no copies
return {}, {}, {}, {}
m1 = c1.manifest()
m2 = c2.manifest()
ma = ca.manifest()
def makectx(f, n):
if len(n) != 20: # in a working context?
if c1.rev() is None:
return c1.filectx(f)
return c2.filectx(f)
return repo.filectx(f, fileid=n)
ctx = util.lrucachefunc(makectx)
copy = {}
movewithdir = {}
fullcopy = {}
diverge = {}
repo.ui.debug(" searching for copies back to rev %d\n" % limit)
u1 = _nonoverlap(m1, m2, ma)
u2 = _nonoverlap(m2, m1, ma)
if u1:
repo.ui.debug(" unmatched files in local:\n %s\n"
% "\n ".join(u1))
if u2:
repo.ui.debug(" unmatched files in other:\n %s\n"
% "\n ".join(u2))
for f in u1:
checkcopies(ctx, f, m1, m2, ca, limit, diverge, copy, fullcopy)
for f in u2:
checkcopies(ctx, f, m2, m1, ca, limit, diverge, copy, fullcopy)
renamedelete = {}
renamedelete2 = set()
diverge2 = set()
for of, fl in diverge.items():
if len(fl) == 1 or of in c1 or of in c2:
del diverge[of] # not actually divergent, or not a rename
if of not in c1 and of not in c2:
# renamed on one side, deleted on the other side, but filter
# out files that have been renamed and then deleted
renamedelete[of] = [f for f in fl if f in c1 or f in c2]
renamedelete2.update(fl) # reverse map for below
else:
diverge2.update(fl) # reverse map for below
bothnew = sorted([d for d in m1 if d in m2 and d not in ma])
if bothnew:
repo.ui.debug(" unmatched files new in both:\n %s\n"
% "\n ".join(bothnew))
bothdiverge, _copy, _fullcopy = {}, {}, {}
for f in bothnew:
checkcopies(ctx, f, m1, m2, ca, limit, bothdiverge, _copy, _fullcopy)
checkcopies(ctx, f, m2, m1, ca, limit, bothdiverge, _copy, _fullcopy)
for of, fl in bothdiverge.items():
if len(fl) == 2 and fl[0] == fl[1]:
copy[fl[0]] = of # not actually divergent, just matching renames
if fullcopy and repo.ui.debugflag:
repo.ui.debug(" all copies found (* = to merge, ! = divergent, "
"% = renamed and deleted):\n")
for f in sorted(fullcopy):
note = ""
if f in copy:
note += "*"
if f in diverge2:
note += "!"
if f in renamedelete2:
note += "%"
repo.ui.debug(" src: '%s' -> dst: '%s' %s\n" % (fullcopy[f], f,
note))
del diverge2
if not fullcopy:
return copy, movewithdir, diverge, renamedelete
repo.ui.debug(" checking for directory renames\n")
# generate a directory move map
d1, d2 = c1.dirs(), c2.dirs()
d1.addpath('/')
d2.addpath('/')
invalid = set()
dirmove = {}
# examine each file copy for a potential directory move, which is
# when all the files in a directory are moved to a new directory
for dst, src in fullcopy.iteritems():
dsrc, ddst = _dirname(src), _dirname(dst)
if dsrc in invalid:
# already seen to be uninteresting
continue
elif dsrc in d1 and ddst in d1:
# directory wasn't entirely moved locally
invalid.add(dsrc)
elif dsrc in d2 and ddst in d2:
# directory wasn't entirely moved remotely
invalid.add(dsrc)
elif dsrc in dirmove and dirmove[dsrc] != ddst:
# files from the same directory moved to two different places
invalid.add(dsrc)
else:
# looks good so far
dirmove[dsrc + "/"] = ddst + "/"
for i in invalid:
if i in dirmove:
del dirmove[i]
del d1, d2, invalid
if not dirmove:
return copy, movewithdir, diverge, renamedelete
for d in dirmove:
repo.ui.debug(" discovered dir src: '%s' -> dst: '%s'\n" %
(d, dirmove[d]))
# check unaccounted nonoverlapping files against directory moves
for f in u1 + u2:
if f not in fullcopy:
for d in dirmove:
if f.startswith(d):
# new file added in a directory that was moved, move it
df = dirmove[d] + f[len(d):]
if df not in copy:
movewithdir[f] = df
repo.ui.debug((" pending file src: '%s' -> "
"dst: '%s'\n") % (f, df))
break
return copy, movewithdir, diverge, renamedelete
def checkcopies(ctx, f, m1, m2, ca, limit, diverge, copy, fullcopy):
"""
check possible copies of f from m1 to m2
ctx = function accepting (filename, node) that returns a filectx.
f = the filename to check
m1 = the source manifest
m2 = the destination manifest
ca = the changectx of the common ancestor
limit = the rev number to not search beyond
diverge = record all diverges in this dict
copy = record all non-divergent copies in this dict
fullcopy = record all copies in this dict
"""
ma = ca.manifest()
def _related(f1, f2, limit):
# Walk back to common ancestor to see if the two files originate
# from the same file. Since workingfilectx's rev() is None it messes
# up the integer comparison logic, hence the pre-step check for
# None (f1 and f2 can only be workingfilectx's initially).
if f1 == f2:
return f1 # a match
g1, g2 = f1.ancestors(), f2.ancestors()
try:
f1r, f2r = f1.rev(), f2.rev()
if f1r is None:
f1 = g1.next()
if f2r is None:
f2 = g2.next()
while True:
f1r, f2r = f1.rev(), f2.rev()
if f1r > f2r:
f1 = g1.next()
elif f2r > f1r:
f2 = g2.next()
elif f1 == f2:
return f1 # a match
elif f1r == f2r or f1r < limit or f2r < limit:
return False # copy no longer relevant
except StopIteration:
return False
of = None
seen = set([f])
for oc in ctx(f, m1[f]).ancestors():
ocr = oc.rev()
of = oc.path()
if of in seen:
# check limit late - grab last rename before
if ocr < limit:
break
continue
seen.add(of)
fullcopy[f] = of # remember for dir rename detection
if of not in m2:
continue # no match, keep looking
if m2[of] == ma.get(of):
break # no merge needed, quit early
c2 = ctx(of, m2[of])
cr = _related(oc, c2, ca.rev())
if cr and (of == f or of == c2.path()): # non-divergent
copy[f] = of
of = None
break
if of in ma:
diverge.setdefault(of, []).append(f)
def duplicatecopies(repo, rev, fromrev, skiprev=None):
'''reproduce copies from fromrev to rev in the dirstate
If skiprev is specified, it's a revision that should be used to
filter copy records. Any copies that occur between fromrev and
skiprev will not be duplicated, even if they appear in the set of
copies between fromrev and rev.
'''
exclude = {}
if skiprev is not None:
exclude = pathcopies(repo[fromrev], repo[skiprev])
for dst, src in pathcopies(repo[fromrev], repo[rev]).iteritems():
# copies.pathcopies returns backward renames, so dst might not
# actually be in the dirstate
if dst in exclude:
continue
if repo.dirstate[dst] in "nma":
repo.dirstate.copy(src, dst)