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# dagop.py - graph ancestry and topology algorithm for revset
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#
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# Copyright 2010 Matt Mackall <mpm@selenic.com>
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#
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# This software may be used and distributed according to the terms of the
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# GNU General Public License version 2 or any later version.
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from __future__ import absolute_import
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import heapq
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from .thirdparty import (
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attr,
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)
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from . import (
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error,
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mdiff,
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node,
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patch,
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pycompat,
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smartset,
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)
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baseset = smartset.baseset
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generatorset = smartset.generatorset
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# possible maximum depth between null and wdir()
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_maxlogdepth = 0x80000000
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def _walkrevtree(pfunc, revs, startdepth, stopdepth, reverse):
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"""Walk DAG using 'pfunc' from the given 'revs' nodes
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'pfunc(rev)' should return the parent/child revisions of the given 'rev'
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if 'reverse' is True/False respectively.
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Scan ends at the stopdepth (exlusive) if specified. Revisions found
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earlier than the startdepth are omitted.
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"""
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if startdepth is None:
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startdepth = 0
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if stopdepth is None:
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stopdepth = _maxlogdepth
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if stopdepth == 0:
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return
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if stopdepth < 0:
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raise error.ProgrammingError('negative stopdepth')
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if reverse:
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heapsign = -1 # max heap
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else:
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heapsign = +1 # min heap
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# load input revs lazily to heap so earlier revisions can be yielded
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# without fully computing the input revs
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revs.sort(reverse)
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irevs = iter(revs)
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pendingheap = [] # [(heapsign * rev, depth), ...] (i.e. lower depth first)
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inputrev = next(irevs, None)
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if inputrev is not None:
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heapq.heappush(pendingheap, (heapsign * inputrev, 0))
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lastrev = None
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while pendingheap:
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currev, curdepth = heapq.heappop(pendingheap)
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currev = heapsign * currev
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if currev == inputrev:
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inputrev = next(irevs, None)
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if inputrev is not None:
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heapq.heappush(pendingheap, (heapsign * inputrev, 0))
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# rescan parents until curdepth >= startdepth because queued entries
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# of the same revision are iterated from the lowest depth
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foundnew = (currev != lastrev)
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if foundnew and curdepth >= startdepth:
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lastrev = currev
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yield currev
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pdepth = curdepth + 1
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if foundnew and pdepth < stopdepth:
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for prev in pfunc(currev):
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if prev != node.nullrev:
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heapq.heappush(pendingheap, (heapsign * prev, pdepth))
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def filectxancestors(fctxs, followfirst=False):
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"""Like filectx.ancestors(), but can walk from multiple files/revisions,
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and includes the given fctxs themselves
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Yields (rev, {fctx, ...}) pairs in descending order.
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"""
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visit = {}
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visitheap = []
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def addvisit(fctx):
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rev = fctx.rev()
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if rev not in visit:
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visit[rev] = set()
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heapq.heappush(visitheap, -rev) # max heap
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visit[rev].add(fctx)
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if followfirst:
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cut = 1
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else:
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cut = None
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for c in fctxs:
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addvisit(c)
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while visit:
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currev = -heapq.heappop(visitheap)
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curfctxs = visit.pop(currev)
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yield currev, curfctxs
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for c in curfctxs:
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for parent in c.parents()[:cut]:
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addvisit(parent)
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assert not visitheap
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def filerevancestors(fctxs, followfirst=False):
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"""Like filectx.ancestors(), but can walk from multiple files/revisions,
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and includes the given fctxs themselves
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Returns a smartset.
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"""
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gen = (rev for rev, _cs in filectxancestors(fctxs, followfirst))
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return generatorset(gen, iterasc=False)
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def _genrevancestors(repo, revs, followfirst, startdepth, stopdepth, cutfunc):
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if followfirst:
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cut = 1
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else:
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cut = None
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cl = repo.changelog
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def plainpfunc(rev):
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try:
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return cl.parentrevs(rev)[:cut]
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except error.WdirUnsupported:
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return (pctx.rev() for pctx in repo[rev].parents()[:cut])
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if cutfunc is None:
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pfunc = plainpfunc
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else:
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pfunc = lambda rev: [r for r in plainpfunc(rev) if not cutfunc(r)]
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revs = revs.filter(lambda rev: not cutfunc(rev))
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return _walkrevtree(pfunc, revs, startdepth, stopdepth, reverse=True)
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def revancestors(repo, revs, followfirst=False, startdepth=None,
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stopdepth=None, cutfunc=None):
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"""Like revlog.ancestors(), but supports additional options, includes
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the given revs themselves, and returns a smartset
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Scan ends at the stopdepth (exlusive) if specified. Revisions found
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earlier than the startdepth are omitted.
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If cutfunc is provided, it will be used to cut the traversal of the DAG.
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When cutfunc(X) returns True, the DAG traversal stops - revision X and
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X's ancestors in the traversal path will be skipped. This could be an
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optimization sometimes.
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Note: if Y is an ancestor of X, cutfunc(X) returning True does not
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necessarily mean Y will also be cut. Usually cutfunc(Y) also wants to
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return True in this case. For example,
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D # revancestors(repo, D, cutfunc=lambda rev: rev == B)
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|\ # will include "A", because the path D -> C -> A was not cut.
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B C # If "B" gets cut, "A" might want to be cut too.
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|/
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A
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"""
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gen = _genrevancestors(repo, revs, followfirst, startdepth, stopdepth,
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cutfunc)
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return generatorset(gen, iterasc=False)
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def _genrevdescendants(repo, revs, followfirst):
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if followfirst:
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cut = 1
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else:
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cut = None
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cl = repo.changelog
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first = revs.min()
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nullrev = node.nullrev
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if first == nullrev:
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# Are there nodes with a null first parent and a non-null
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# second one? Maybe. Do we care? Probably not.
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yield first
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for i in cl:
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yield i
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else:
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seen = set(revs)
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for i in cl.revs(first):
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if i in seen:
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yield i
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continue
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for x in cl.parentrevs(i)[:cut]:
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if x != nullrev and x in seen:
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seen.add(i)
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yield i
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break
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def _builddescendantsmap(repo, startrev, followfirst):
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"""Build map of 'rev -> child revs', offset from startrev"""
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cl = repo.changelog
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nullrev = node.nullrev
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descmap = [[] for _rev in xrange(startrev, len(cl))]
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for currev in cl.revs(startrev + 1):
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p1rev, p2rev = cl.parentrevs(currev)
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if p1rev >= startrev:
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descmap[p1rev - startrev].append(currev)
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if not followfirst and p2rev != nullrev and p2rev >= startrev:
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descmap[p2rev - startrev].append(currev)
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return descmap
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def _genrevdescendantsofdepth(repo, revs, followfirst, startdepth, stopdepth):
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startrev = revs.min()
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descmap = _builddescendantsmap(repo, startrev, followfirst)
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def pfunc(rev):
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return descmap[rev - startrev]
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return _walkrevtree(pfunc, revs, startdepth, stopdepth, reverse=False)
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def revdescendants(repo, revs, followfirst, startdepth=None, stopdepth=None):
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"""Like revlog.descendants() but supports additional options, includes
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the given revs themselves, and returns a smartset
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Scan ends at the stopdepth (exlusive) if specified. Revisions found
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earlier than the startdepth are omitted.
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"""
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if startdepth is None and stopdepth is None:
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gen = _genrevdescendants(repo, revs, followfirst)
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else:
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gen = _genrevdescendantsofdepth(repo, revs, followfirst,
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startdepth, stopdepth)
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return generatorset(gen, iterasc=True)
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def _reachablerootspure(repo, minroot, roots, heads, includepath):
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"""return (heads(::<roots> and ::<heads>))
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If includepath is True, return (<roots>::<heads>)."""
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if not roots:
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return []
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parentrevs = repo.changelog.parentrevs
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roots = set(roots)
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visit = list(heads)
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reachable = set()
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seen = {}
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# prefetch all the things! (because python is slow)
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reached = reachable.add
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dovisit = visit.append
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nextvisit = visit.pop
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# open-code the post-order traversal due to the tiny size of
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# sys.getrecursionlimit()
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while visit:
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rev = nextvisit()
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if rev in roots:
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reached(rev)
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if not includepath:
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continue
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parents = parentrevs(rev)
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seen[rev] = parents
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for parent in parents:
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if parent >= minroot and parent not in seen:
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dovisit(parent)
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if not reachable:
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return baseset()
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if not includepath:
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return reachable
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for rev in sorted(seen):
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for parent in seen[rev]:
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if parent in reachable:
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reached(rev)
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return reachable
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def reachableroots(repo, roots, heads, includepath=False):
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"""return (heads(::<roots> and ::<heads>))
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If includepath is True, return (<roots>::<heads>)."""
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if not roots:
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return baseset()
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minroot = roots.min()
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roots = list(roots)
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heads = list(heads)
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try:
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revs = repo.changelog.reachableroots(minroot, heads, roots, includepath)
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except AttributeError:
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revs = _reachablerootspure(repo, minroot, roots, heads, includepath)
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revs = baseset(revs)
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revs.sort()
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return revs
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def _changesrange(fctx1, fctx2, linerange2, diffopts):
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"""Return `(diffinrange, linerange1)` where `diffinrange` is True
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if diff from fctx2 to fctx1 has changes in linerange2 and
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`linerange1` is the new line range for fctx1.
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"""
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blocks = mdiff.allblocks(fctx1.data(), fctx2.data(), diffopts)
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filteredblocks, linerange1 = mdiff.blocksinrange(blocks, linerange2)
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diffinrange = any(stype == '!' for _, stype in filteredblocks)
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return diffinrange, linerange1
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def blockancestors(fctx, fromline, toline, followfirst=False):
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"""Yield ancestors of `fctx` with respect to the block of lines within
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`fromline`-`toline` range.
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"""
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diffopts = patch.diffopts(fctx._repo.ui)
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fctx = fctx.introfilectx()
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visit = {(fctx.linkrev(), fctx.filenode()): (fctx, (fromline, toline))}
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while visit:
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c, linerange2 = visit.pop(max(visit))
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pl = c.parents()
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if followfirst:
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pl = pl[:1]
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if not pl:
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# The block originates from the initial revision.
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yield c, linerange2
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continue
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inrange = False
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for p in pl:
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inrangep, linerange1 = _changesrange(p, c, linerange2, diffopts)
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inrange = inrange or inrangep
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if linerange1[0] == linerange1[1]:
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# Parent's linerange is empty, meaning that the block got
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# introduced in this revision; no need to go futher in this
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# branch.
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continue
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# Set _descendantrev with 'c' (a known descendant) so that, when
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# _adjustlinkrev is called for 'p', it receives this descendant
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# (as srcrev) instead possibly topmost introrev.
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p._descendantrev = c.rev()
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visit[p.linkrev(), p.filenode()] = p, linerange1
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if inrange:
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yield c, linerange2
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def blockdescendants(fctx, fromline, toline):
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"""Yield descendants of `fctx` with respect to the block of lines within
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`fromline`-`toline` range.
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"""
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# First possibly yield 'fctx' if it has changes in range with respect to
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# its parents.
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try:
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c, linerange1 = next(blockancestors(fctx, fromline, toline))
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except StopIteration:
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pass
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else:
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if c == fctx:
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yield c, linerange1
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diffopts = patch.diffopts(fctx._repo.ui)
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fl = fctx.filelog()
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seen = {fctx.filerev(): (fctx, (fromline, toline))}
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for i in fl.descendants([fctx.filerev()]):
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c = fctx.filectx(i)
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inrange = False
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for x in fl.parentrevs(i):
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try:
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p, linerange2 = seen[x]
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except KeyError:
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# nullrev or other branch
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continue
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inrangep, linerange1 = _changesrange(c, p, linerange2, diffopts)
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inrange = inrange or inrangep
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# If revision 'i' has been seen (it's a merge) and the line range
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# previously computed differs from the one we just got, we take the
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# surrounding interval. This is conservative but avoids loosing
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# information.
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if i in seen and seen[i][1] != linerange1:
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lbs, ubs = zip(linerange1, seen[i][1])
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linerange1 = min(lbs), max(ubs)
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seen[i] = c, linerange1
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if inrange:
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yield c, linerange1
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@attr.s(slots=True, frozen=True)
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class annotateline(object):
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fctx = attr.ib()
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lineno = attr.ib(default=False)
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# Whether this annotation was the result of a skip-annotate.
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skip = attr.ib(default=False)
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def _countlines(text):
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if text.endswith("\n"):
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return text.count("\n")
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return text.count("\n") + int(bool(text))
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def _annotatepair(parents, childfctx, child, skipchild, diffopts):
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r'''
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Given parent and child fctxes and annotate data for parents, for all lines
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in either parent that match the child, annotate the child with the parent's
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data.
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Additionally, if `skipchild` is True, replace all other lines with parent
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annotate data as well such that child is never blamed for any lines.
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See test-annotate.py for unit tests.
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'''
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pblocks = [(parent, mdiff.allblocks(parent[1], child[1], opts=diffopts))
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for parent in parents]
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if skipchild:
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# Need to iterate over the blocks twice -- make it a list
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pblocks = [(p, list(blocks)) for (p, blocks) in pblocks]
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# Mercurial currently prefers p2 over p1 for annotate.
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# TODO: change this?
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for parent, blocks in pblocks:
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for (a1, a2, b1, b2), t in blocks:
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# Changed blocks ('!') or blocks made only of blank lines ('~')
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# belong to the child.
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if t == '=':
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child[0][b1:b2] = parent[0][a1:a2]
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if skipchild:
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# Now try and match up anything that couldn't be matched,
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# Reversing pblocks maintains bias towards p2, matching above
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# behavior.
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pblocks.reverse()
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# The heuristics are:
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# * Work on blocks of changed lines (effectively diff hunks with -U0).
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# This could potentially be smarter but works well enough.
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# * For a non-matching section, do a best-effort fit. Match lines in
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# diff hunks 1:1, dropping lines as necessary.
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# * Repeat the last line as a last resort.
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# First, replace as much as possible without repeating the last line.
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remaining = [(parent, []) for parent, _blocks in pblocks]
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for idx, (parent, blocks) in enumerate(pblocks):
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for (a1, a2, b1, b2), _t in blocks:
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if a2 - a1 >= b2 - b1:
|
|
|
for bk in xrange(b1, b2):
|
|
|
if child[0][bk].fctx == childfctx:
|
|
|
ak = min(a1 + (bk - b1), a2 - 1)
|
|
|
child[0][bk] = attr.evolve(parent[0][ak], skip=True)
|
|
|
else:
|
|
|
remaining[idx][1].append((a1, a2, b1, b2))
|
|
|
|
|
|
# Then, look at anything left, which might involve repeating the last
|
|
|
# line.
|
|
|
for parent, blocks in remaining:
|
|
|
for a1, a2, b1, b2 in blocks:
|
|
|
for bk in xrange(b1, b2):
|
|
|
if child[0][bk].fctx == childfctx:
|
|
|
ak = min(a1 + (bk - b1), a2 - 1)
|
|
|
child[0][bk] = attr.evolve(parent[0][ak], skip=True)
|
|
|
return child
|
|
|
|
|
|
def annotate(base, parents, linenumber=False, skiprevs=None, diffopts=None):
|
|
|
"""Core algorithm for filectx.annotate()
|
|
|
|
|
|
`parents(fctx)` is a function returning a list of parent filectxs.
|
|
|
"""
|
|
|
|
|
|
if linenumber:
|
|
|
def decorate(text, rev):
|
|
|
return ([annotateline(fctx=rev, lineno=i)
|
|
|
for i in xrange(1, _countlines(text) + 1)], text)
|
|
|
else:
|
|
|
def decorate(text, rev):
|
|
|
return ([annotateline(fctx=rev)] * _countlines(text), text)
|
|
|
|
|
|
# This algorithm would prefer to be recursive, but Python is a
|
|
|
# bit recursion-hostile. Instead we do an iterative
|
|
|
# depth-first search.
|
|
|
|
|
|
# 1st DFS pre-calculates pcache and needed
|
|
|
visit = [base]
|
|
|
pcache = {}
|
|
|
needed = {base: 1}
|
|
|
while visit:
|
|
|
f = visit.pop()
|
|
|
if f in pcache:
|
|
|
continue
|
|
|
pl = parents(f)
|
|
|
pcache[f] = pl
|
|
|
for p in pl:
|
|
|
needed[p] = needed.get(p, 0) + 1
|
|
|
if p not in pcache:
|
|
|
visit.append(p)
|
|
|
|
|
|
# 2nd DFS does the actual annotate
|
|
|
visit[:] = [base]
|
|
|
hist = {}
|
|
|
while visit:
|
|
|
f = visit[-1]
|
|
|
if f in hist:
|
|
|
visit.pop()
|
|
|
continue
|
|
|
|
|
|
ready = True
|
|
|
pl = pcache[f]
|
|
|
for p in pl:
|
|
|
if p not in hist:
|
|
|
ready = False
|
|
|
visit.append(p)
|
|
|
if ready:
|
|
|
visit.pop()
|
|
|
curr = decorate(f.data(), f)
|
|
|
skipchild = False
|
|
|
if skiprevs is not None:
|
|
|
skipchild = f._changeid in skiprevs
|
|
|
curr = _annotatepair([hist[p] for p in pl], f, curr, skipchild,
|
|
|
diffopts)
|
|
|
for p in pl:
|
|
|
if needed[p] == 1:
|
|
|
del hist[p]
|
|
|
del needed[p]
|
|
|
else:
|
|
|
needed[p] -= 1
|
|
|
|
|
|
hist[f] = curr
|
|
|
del pcache[f]
|
|
|
|
|
|
lineattrs, text = hist[base]
|
|
|
return pycompat.ziplist(lineattrs, mdiff.splitnewlines(text))
|
|
|
|
|
|
def toposort(revs, parentsfunc, firstbranch=()):
|
|
|
"""Yield revisions from heads to roots one (topo) branch at a time.
|
|
|
|
|
|
This function aims to be used by a graph generator that wishes to minimize
|
|
|
the number of parallel branches and their interleaving.
|
|
|
|
|
|
Example iteration order (numbers show the "true" order in a changelog):
|
|
|
|
|
|
o 4
|
|
|
|
|
|
|
o 1
|
|
|
|
|
|
|
| o 3
|
|
|
| |
|
|
|
| o 2
|
|
|
|/
|
|
|
o 0
|
|
|
|
|
|
Note that the ancestors of merges are understood by the current
|
|
|
algorithm to be on the same branch. This means no reordering will
|
|
|
occur behind a merge.
|
|
|
"""
|
|
|
|
|
|
### Quick summary of the algorithm
|
|
|
#
|
|
|
# This function is based around a "retention" principle. We keep revisions
|
|
|
# in memory until we are ready to emit a whole branch that immediately
|
|
|
# "merges" into an existing one. This reduces the number of parallel
|
|
|
# branches with interleaved revisions.
|
|
|
#
|
|
|
# During iteration revs are split into two groups:
|
|
|
# A) revision already emitted
|
|
|
# B) revision in "retention". They are stored as different subgroups.
|
|
|
#
|
|
|
# for each REV, we do the following logic:
|
|
|
#
|
|
|
# 1) if REV is a parent of (A), we will emit it. If there is a
|
|
|
# retention group ((B) above) that is blocked on REV being
|
|
|
# available, we emit all the revisions out of that retention
|
|
|
# group first.
|
|
|
#
|
|
|
# 2) else, we'll search for a subgroup in (B) awaiting for REV to be
|
|
|
# available, if such subgroup exist, we add REV to it and the subgroup is
|
|
|
# now awaiting for REV.parents() to be available.
|
|
|
#
|
|
|
# 3) finally if no such group existed in (B), we create a new subgroup.
|
|
|
#
|
|
|
#
|
|
|
# To bootstrap the algorithm, we emit the tipmost revision (which
|
|
|
# puts it in group (A) from above).
|
|
|
|
|
|
revs.sort(reverse=True)
|
|
|
|
|
|
# Set of parents of revision that have been emitted. They can be considered
|
|
|
# unblocked as the graph generator is already aware of them so there is no
|
|
|
# need to delay the revisions that reference them.
|
|
|
#
|
|
|
# If someone wants to prioritize a branch over the others, pre-filling this
|
|
|
# set will force all other branches to wait until this branch is ready to be
|
|
|
# emitted.
|
|
|
unblocked = set(firstbranch)
|
|
|
|
|
|
# list of groups waiting to be displayed, each group is defined by:
|
|
|
#
|
|
|
# (revs: lists of revs waiting to be displayed,
|
|
|
# blocked: set of that cannot be displayed before those in 'revs')
|
|
|
#
|
|
|
# The second value ('blocked') correspond to parents of any revision in the
|
|
|
# group ('revs') that is not itself contained in the group. The main idea
|
|
|
# of this algorithm is to delay as much as possible the emission of any
|
|
|
# revision. This means waiting for the moment we are about to display
|
|
|
# these parents to display the revs in a group.
|
|
|
#
|
|
|
# This first implementation is smart until it encounters a merge: it will
|
|
|
# emit revs as soon as any parent is about to be emitted and can grow an
|
|
|
# arbitrary number of revs in 'blocked'. In practice this mean we properly
|
|
|
# retains new branches but gives up on any special ordering for ancestors
|
|
|
# of merges. The implementation can be improved to handle this better.
|
|
|
#
|
|
|
# The first subgroup is special. It corresponds to all the revision that
|
|
|
# were already emitted. The 'revs' lists is expected to be empty and the
|
|
|
# 'blocked' set contains the parents revisions of already emitted revision.
|
|
|
#
|
|
|
# You could pre-seed the <parents> set of groups[0] to a specific
|
|
|
# changesets to select what the first emitted branch should be.
|
|
|
groups = [([], unblocked)]
|
|
|
pendingheap = []
|
|
|
pendingset = set()
|
|
|
|
|
|
heapq.heapify(pendingheap)
|
|
|
heappop = heapq.heappop
|
|
|
heappush = heapq.heappush
|
|
|
for currentrev in revs:
|
|
|
# Heap works with smallest element, we want highest so we invert
|
|
|
if currentrev not in pendingset:
|
|
|
heappush(pendingheap, -currentrev)
|
|
|
pendingset.add(currentrev)
|
|
|
# iterates on pending rev until after the current rev have been
|
|
|
# processed.
|
|
|
rev = None
|
|
|
while rev != currentrev:
|
|
|
rev = -heappop(pendingheap)
|
|
|
pendingset.remove(rev)
|
|
|
|
|
|
# Seek for a subgroup blocked, waiting for the current revision.
|
|
|
matching = [i for i, g in enumerate(groups) if rev in g[1]]
|
|
|
|
|
|
if matching:
|
|
|
# The main idea is to gather together all sets that are blocked
|
|
|
# on the same revision.
|
|
|
#
|
|
|
# Groups are merged when a common blocking ancestor is
|
|
|
# observed. For example, given two groups:
|
|
|
#
|
|
|
# revs [5, 4] waiting for 1
|
|
|
# revs [3, 2] waiting for 1
|
|
|
#
|
|
|
# These two groups will be merged when we process
|
|
|
# 1. In theory, we could have merged the groups when
|
|
|
# we added 2 to the group it is now in (we could have
|
|
|
# noticed the groups were both blocked on 1 then), but
|
|
|
# the way it works now makes the algorithm simpler.
|
|
|
#
|
|
|
# We also always keep the oldest subgroup first. We can
|
|
|
# probably improve the behavior by having the longest set
|
|
|
# first. That way, graph algorithms could minimise the length
|
|
|
# of parallel lines their drawing. This is currently not done.
|
|
|
targetidx = matching.pop(0)
|
|
|
trevs, tparents = groups[targetidx]
|
|
|
for i in matching:
|
|
|
gr = groups[i]
|
|
|
trevs.extend(gr[0])
|
|
|
tparents |= gr[1]
|
|
|
# delete all merged subgroups (except the one we kept)
|
|
|
# (starting from the last subgroup for performance and
|
|
|
# sanity reasons)
|
|
|
for i in reversed(matching):
|
|
|
del groups[i]
|
|
|
else:
|
|
|
# This is a new head. We create a new subgroup for it.
|
|
|
targetidx = len(groups)
|
|
|
groups.append(([], {rev}))
|
|
|
|
|
|
gr = groups[targetidx]
|
|
|
|
|
|
# We now add the current nodes to this subgroups. This is done
|
|
|
# after the subgroup merging because all elements from a subgroup
|
|
|
# that relied on this rev must precede it.
|
|
|
#
|
|
|
# we also update the <parents> set to include the parents of the
|
|
|
# new nodes.
|
|
|
if rev == currentrev: # only display stuff in rev
|
|
|
gr[0].append(rev)
|
|
|
gr[1].remove(rev)
|
|
|
parents = [p for p in parentsfunc(rev) if p > node.nullrev]
|
|
|
gr[1].update(parents)
|
|
|
for p in parents:
|
|
|
if p not in pendingset:
|
|
|
pendingset.add(p)
|
|
|
heappush(pendingheap, -p)
|
|
|
|
|
|
# Look for a subgroup to display
|
|
|
#
|
|
|
# When unblocked is empty (if clause), we were not waiting for any
|
|
|
# revisions during the first iteration (if no priority was given) or
|
|
|
# if we emitted a whole disconnected set of the graph (reached a
|
|
|
# root). In that case we arbitrarily take the oldest known
|
|
|
# subgroup. The heuristic could probably be better.
|
|
|
#
|
|
|
# Otherwise (elif clause) if the subgroup is blocked on
|
|
|
# a revision we just emitted, we can safely emit it as
|
|
|
# well.
|
|
|
if not unblocked:
|
|
|
if len(groups) > 1: # display other subset
|
|
|
targetidx = 1
|
|
|
gr = groups[1]
|
|
|
elif not gr[1] & unblocked:
|
|
|
gr = None
|
|
|
|
|
|
if gr is not None:
|
|
|
# update the set of awaited revisions with the one from the
|
|
|
# subgroup
|
|
|
unblocked |= gr[1]
|
|
|
# output all revisions in the subgroup
|
|
|
for r in gr[0]:
|
|
|
yield r
|
|
|
# delete the subgroup that you just output
|
|
|
# unless it is groups[0] in which case you just empty it.
|
|
|
if targetidx:
|
|
|
del groups[targetidx]
|
|
|
else:
|
|
|
gr[0][:] = []
|
|
|
# Check if we have some subgroup waiting for revisions we are not going to
|
|
|
# iterate over
|
|
|
for g in groups:
|
|
|
for r in g[0]:
|
|
|
yield r
|
|
|
|