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dagop.py
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# dagop.py - graph ancestry and topology algorithm for revset
#
# Copyright 2010 Olivia Mackall <olivia@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.
from __future__ import annotations
import heapq
import typing
from typing import (
List,
)
from .thirdparty import attr
# Force pytype to use the non-vendored package
if typing.TYPE_CHECKING:
# noinspection PyPackageRequirements
import attr
from .node import nullrev
from . import (
error,
mdiff,
patch,
pycompat,
scmutil,
smartset,
)
baseset = smartset.baseset
generatorset = smartset.generatorset
# possible maximum depth between null and wdir()
maxlogdepth = 0x80000000
def _walkrevtree(pfunc, revs, startdepth, stopdepth, reverse):
"""Walk DAG using 'pfunc' from the given 'revs' nodes
'pfunc(rev)' should return the parent/child revisions of the given 'rev'
if 'reverse' is True/False respectively.
Scan ends at the stopdepth (exlusive) if specified. Revisions found
earlier than the startdepth are omitted.
"""
if startdepth is None:
startdepth = 0
if stopdepth is None:
stopdepth = maxlogdepth
if stopdepth == 0:
return
if stopdepth < 0:
raise error.ProgrammingError(b'negative stopdepth')
if reverse:
heapsign = -1 # max heap
else:
heapsign = +1 # min heap
# load input revs lazily to heap so earlier revisions can be yielded
# without fully computing the input revs
revs.sort(reverse)
irevs = iter(revs)
pendingheap = [] # [(heapsign * rev, depth), ...] (i.e. lower depth first)
inputrev = next(irevs, None)
if inputrev is not None:
heapq.heappush(pendingheap, (heapsign * inputrev, 0))
lastrev = None
while pendingheap:
currev, curdepth = heapq.heappop(pendingheap)
currev = heapsign * currev
if currev == inputrev:
inputrev = next(irevs, None)
if inputrev is not None:
heapq.heappush(pendingheap, (heapsign * inputrev, 0))
# rescan parents until curdepth >= startdepth because queued entries
# of the same revision are iterated from the lowest depth
foundnew = currev != lastrev
if foundnew and curdepth >= startdepth:
lastrev = currev
yield currev
pdepth = curdepth + 1
if foundnew and pdepth < stopdepth:
for prev in pfunc(currev):
if prev != nullrev:
heapq.heappush(pendingheap, (heapsign * prev, pdepth))
def filectxancestors(fctxs, followfirst=False):
"""Like filectx.ancestors(), but can walk from multiple files/revisions,
and includes the given fctxs themselves
Yields (rev, {fctx, ...}) pairs in descending order.
"""
visit = {}
visitheap = []
def addvisit(fctx):
rev = scmutil.intrev(fctx)
if rev not in visit:
visit[rev] = set()
heapq.heappush(visitheap, -rev) # max heap
visit[rev].add(fctx)
if followfirst:
cut = 1
else:
cut = None
for c in fctxs:
addvisit(c)
while visit:
currev = -(heapq.heappop(visitheap))
curfctxs = visit.pop(currev)
yield currev, curfctxs
for c in curfctxs:
for parent in c.parents()[:cut]:
addvisit(parent)
assert not visitheap
def filerevancestors(fctxs, followfirst=False):
"""Like filectx.ancestors(), but can walk from multiple files/revisions,
and includes the given fctxs themselves
Returns a smartset.
"""
gen = (rev for rev, _cs in filectxancestors(fctxs, followfirst))
return generatorset(gen, iterasc=False)
def _genrevancestors(repo, revs, followfirst, startdepth, stopdepth, cutfunc):
if followfirst:
cut = 1
else:
cut = None
cl = repo.changelog
def plainpfunc(rev):
try:
return cl.parentrevs(rev)[:cut]
except error.WdirUnsupported:
return (pctx.rev() for pctx in repo[rev].parents()[:cut])
if cutfunc is None:
pfunc = plainpfunc
else:
pfunc = lambda rev: [r for r in plainpfunc(rev) if not cutfunc(r)]
revs = revs.filter(lambda rev: not cutfunc(rev))
return _walkrevtree(pfunc, revs, startdepth, stopdepth, reverse=True)
def revancestors(
repo, revs, followfirst=False, startdepth=None, stopdepth=None, cutfunc=None
):
r"""Like revlog.ancestors(), but supports additional options, includes
the given revs themselves, and returns a smartset
Scan ends at the stopdepth (exlusive) if specified. Revisions found
earlier than the startdepth are omitted.
If cutfunc is provided, it will be used to cut the traversal of the DAG.
When cutfunc(X) returns True, the DAG traversal stops - revision X and
X's ancestors in the traversal path will be skipped. This could be an
optimization sometimes.
Note: if Y is an ancestor of X, cutfunc(X) returning True does not
necessarily mean Y will also be cut. Usually cutfunc(Y) also wants to
return True in this case. For example,
D # revancestors(repo, D, cutfunc=lambda rev: rev == B)
|\ # will include "A", because the path D -> C -> A was not cut.
B C # If "B" gets cut, "A" might want to be cut too.
|/
A
"""
gen = _genrevancestors(
repo, revs, followfirst, startdepth, stopdepth, cutfunc
)
return generatorset(gen, iterasc=False)
def _genrevdescendants(repo, revs, followfirst):
if followfirst:
cut = 1
else:
cut = None
cl = repo.changelog
first = revs.min()
if first == nullrev:
# Are there nodes with a null first parent and a non-null
# second one? Maybe. Do we care? Probably not.
yield first
for i in cl:
yield i
else:
seen = set(revs)
for i in cl.revs(first):
if i in seen:
yield i
continue
for x in cl.parentrevs(i)[:cut]:
if x != nullrev and x in seen:
seen.add(i)
yield i
break
def _builddescendantsmap(repo, startrev, followfirst):
"""Build map of 'rev -> child revs', offset from startrev"""
cl = repo.changelog
descmap = [[] for _rev in range(startrev, len(cl))]
for currev in cl.revs(startrev + 1):
p1rev, p2rev = cl.parentrevs(currev)
if p1rev >= startrev:
descmap[p1rev - startrev].append(currev)
if not followfirst and p2rev != nullrev and p2rev >= startrev:
descmap[p2rev - startrev].append(currev)
return descmap
def _genrevdescendantsofdepth(repo, revs, followfirst, startdepth, stopdepth):
startrev = revs.min()
descmap = _builddescendantsmap(repo, startrev, followfirst)
def pfunc(rev):
return descmap[rev - startrev]
return _walkrevtree(pfunc, revs, startdepth, stopdepth, reverse=False)
def revdescendants(repo, revs, followfirst, startdepth=None, stopdepth=None):
"""Like revlog.descendants() but supports additional options, includes
the given revs themselves, and returns a smartset
Scan ends at the stopdepth (exlusive) if specified. Revisions found
earlier than the startdepth are omitted.
"""
if startdepth is None and (stopdepth is None or stopdepth >= maxlogdepth):
gen = _genrevdescendants(repo, revs, followfirst)
else:
gen = _genrevdescendantsofdepth(
repo, revs, followfirst, startdepth, stopdepth
)
return generatorset(gen, iterasc=True)
def descendantrevs(revs, revsfn, parentrevsfn):
"""Generate revision number descendants in revision order.
Yields revision numbers starting with a child of some rev in
``revs``. Results are ordered by revision number and are
therefore topological. Each revision is not considered a descendant
of itself.
``revsfn`` is a callable that with no argument iterates over all
revision numbers and with a ``start`` argument iterates over revision
numbers beginning with that value.
``parentrevsfn`` is a callable that receives a revision number and
returns an iterable of parent revision numbers, whose values may include
nullrev.
"""
first = min(revs)
if first == nullrev:
for rev in revsfn():
yield rev
return
seen = set(revs)
for rev in revsfn(start=first + 1):
for prev in parentrevsfn(rev):
if prev != nullrev and prev in seen:
seen.add(rev)
yield rev
break
class subsetparentswalker:
r"""Scan adjacent ancestors in the graph given by the subset
This computes parent-child relations in the sub graph filtered by
a revset. Primary use case is to draw a revisions graph.
In the following example, we consider that the node 'f' has edges to all
ancestor nodes, but redundant paths are eliminated. The edge 'f'->'b'
is eliminated because there is a path 'f'->'c'->'b' for example.
- d - e -
/ \
a - b - c - f
If the node 'c' is filtered out, the edge 'f'->'b' is activated.
- d - e -
/ \
a - b -(c)- f
Likewise, if 'd' and 'e' are filtered out, this edge is fully eliminated
since there is a path 'f'->'c'->'b'->'a' for 'f'->'a'.
(d) (e)
a - b - c - f
Implementation-wise, 'f' is passed down to 'a' as unresolved through the
'f'->'e'->'d'->'a' path, whereas we do also remember that 'f' has already
been resolved while walking down the 'f'->'c'->'b'->'a' path. When
processing the node 'a', the unresolved 'f'->'a' path is eliminated as
the 'f' end is marked as resolved.
Ancestors are searched from the tipmost revision in the subset so the
results can be cached. You should specify startrev to narrow the search
space to ':startrev'.
"""
def __init__(self, repo, subset, startrev=None):
if startrev is not None:
subset = repo.revs(b'%d:null', startrev) & subset
# equivalent to 'subset = subset.sorted(reverse=True)', but there's
# no such function.
fastdesc = subset.fastdesc
if fastdesc:
desciter = fastdesc()
else:
if not subset.isdescending() and not subset.istopo():
subset = smartset.baseset(subset)
subset.sort(reverse=True)
desciter = iter(subset)
self._repo = repo
self._changelog = repo.changelog
self._subset = subset
# scanning state (see _scanparents):
self._tovisit = []
self._pendingcnt = {}
self._pointers = {}
self._parents = {}
self._inputhead = nullrev # reassigned by self._advanceinput()
self._inputtail = desciter
self._bottomrev = nullrev
self._advanceinput()
def parentsset(self, rev):
"""Look up parents of the given revision in the subset, and returns
as a smartset"""
return smartset.baseset(self.parents(rev))
def parents(self, rev):
"""Look up parents of the given revision in the subset
The returned revisions are sorted by parent index (p1/p2).
"""
self._scanparents(rev)
return [r for _c, r in sorted(self._parents.get(rev, []))]
def _parentrevs(self, rev):
try:
revs = self._changelog.parentrevs(rev)
if revs[-1] == nullrev:
return revs[:-1]
return revs
except error.WdirUnsupported:
return tuple(pctx.rev() for pctx in self._repo[None].parents())
def _advanceinput(self):
"""Advance the input iterator and set the next revision to _inputhead"""
if self._inputhead < nullrev:
return
try:
self._inputhead = next(self._inputtail)
except StopIteration:
self._bottomrev = self._inputhead
self._inputhead = nullrev - 1
def _scanparents(self, stoprev):
"""Scan ancestors until the parents of the specified stoprev are
resolved"""
# 'tovisit' is the queue of the input revisions and their ancestors.
# It will be populated incrementally to minimize the initial cost
# of computing the given subset.
#
# For to-visit revisions, we keep track of
# - the number of the unresolved paths: pendingcnt[rev],
# - dict of the unresolved descendants and chains: pointers[rev][0],
# - set of the already resolved descendants: pointers[rev][1].
#
# When a revision is visited, 'pointers[rev]' should be popped and
# propagated to its parents accordingly.
#
# Once all pending paths have been resolved, 'pendingcnt[rev]' becomes
# 0 and 'parents[rev]' contains the unsorted list of parent revisions
# and p1/p2 chains (excluding linear paths.) The p1/p2 chains will be
# used as a sort key preferring p1. 'len(chain)' should be the number
# of merges between two revisions.
subset = self._subset
tovisit = self._tovisit # heap queue of [-rev]
pendingcnt = self._pendingcnt # {rev: count} for visited revisions
pointers = self._pointers # {rev: [{unresolved_rev: chain}, resolved]}
parents = self._parents # {rev: [(chain, rev)]}
while tovisit or self._inputhead >= nullrev:
if pendingcnt.get(stoprev) == 0:
return
# feed greater revisions from input set to queue
if not tovisit:
heapq.heappush(tovisit, -self._inputhead)
self._advanceinput()
while self._inputhead >= -tovisit[0]:
heapq.heappush(tovisit, -self._inputhead)
self._advanceinput()
rev = -heapq.heappop(tovisit)
if rev < self._bottomrev:
return
if rev in pendingcnt and rev not in pointers:
continue # already visited
curactive = rev in subset
pendingcnt.setdefault(rev, 0) # mark as visited
if curactive:
assert rev not in parents
parents[rev] = []
unresolved, resolved = pointers.pop(rev, ({}, set()))
if curactive:
# reached to active rev, resolve pending descendants' parents
for r, c in unresolved.items():
pendingcnt[r] -= 1
assert pendingcnt[r] >= 0
if r in resolved:
continue # eliminate redundant path
parents[r].append((c, rev))
# mark the descendant 'r' as resolved through this path if
# there are still pending pointers. the 'resolved' set may
# be concatenated later at a fork revision.
if pendingcnt[r] > 0:
resolved.add(r)
unresolved.clear()
# occasionally clean resolved markers. otherwise the set
# would grow indefinitely.
resolved = {r for r in resolved if pendingcnt[r] > 0}
parentrevs = self._parentrevs(rev)
bothparentsactive = all(p in subset for p in parentrevs)
# set up or propagate tracking pointers if
# - one of the parents is not active,
# - or descendants' parents are unresolved.
if not bothparentsactive or unresolved or resolved:
if len(parentrevs) <= 1:
# can avoid copying the tracking pointer
parentpointers = [(unresolved, resolved)]
else:
parentpointers = [
(unresolved, resolved),
(unresolved.copy(), resolved.copy()),
]
# 'rev' is a merge revision. increment the pending count
# as the 'unresolved' dict will be duplicated, and append
# p1/p2 code to the existing chains.
for r in unresolved:
pendingcnt[r] += 1
parentpointers[0][0][r] += b'1'
parentpointers[1][0][r] += b'2'
for i, p in enumerate(parentrevs):
assert p < rev
heapq.heappush(tovisit, -p)
if p in pointers:
# 'p' is a fork revision. concatenate tracking pointers
# and decrement the pending count accordingly.
knownunresolved, knownresolved = pointers[p]
unresolved, resolved = parentpointers[i]
for r, c in unresolved.items():
if r in knownunresolved:
# unresolved at both paths
pendingcnt[r] -= 1
assert pendingcnt[r] > 0
# take shorter chain
knownunresolved[r] = min(c, knownunresolved[r])
else:
knownunresolved[r] = c
# simply propagate the 'resolved' set as deduplicating
# 'unresolved' here would be slightly complicated.
knownresolved.update(resolved)
else:
pointers[p] = parentpointers[i]
# then, populate the active parents directly and add the current
# 'rev' to the tracking pointers of the inactive parents.
# 'pointers[p]' may be optimized out if both parents are active.
chaincodes = [b''] if len(parentrevs) <= 1 else [b'1', b'2']
if curactive and bothparentsactive:
for i, p in enumerate(parentrevs):
c = chaincodes[i]
parents[rev].append((c, p))
# no need to mark 'rev' as resolved since the 'rev' should
# be fully resolved (i.e. pendingcnt[rev] == 0)
assert pendingcnt[rev] == 0
elif curactive:
for i, p in enumerate(parentrevs):
unresolved, resolved = pointers[p]
assert rev not in unresolved
c = chaincodes[i]
if p in subset:
parents[rev].append((c, p))
# mark 'rev' as resolved through this path
resolved.add(rev)
else:
pendingcnt[rev] += 1
unresolved[rev] = c
assert 0 < pendingcnt[rev] <= 2
def _reachablerootspure(pfunc, minroot, roots, heads, includepath):
"""See revlog.reachableroots"""
if not roots:
return []
roots = set(roots)
visit = list(heads)
reachable = set()
seen = {}
# prefetch all the things! (because python is slow)
reached = reachable.add
dovisit = visit.append
nextvisit = visit.pop
# open-code the post-order traversal due to the tiny size of
# sys.getrecursionlimit()
while visit:
rev = nextvisit()
if rev in roots:
reached(rev)
if not includepath:
continue
parents = pfunc(rev)
seen[rev] = parents
for parent in parents:
if parent >= minroot and parent not in seen:
dovisit(parent)
if not reachable:
return baseset()
if not includepath:
return reachable
for rev in sorted(seen):
for parent in seen[rev]:
if parent in reachable:
reached(rev)
return reachable
def reachableroots(repo, roots, heads, includepath=False):
"""See revlog.reachableroots"""
if not roots:
return baseset()
minroot = roots.min()
roots = list(roots)
heads = list(heads)
revs = repo.changelog.reachableroots(minroot, heads, roots, includepath)
revs = baseset(revs)
revs.sort()
return revs
def _changesrange(fctx1, fctx2, linerange2, diffopts):
"""Return `(diffinrange, linerange1)` where `diffinrange` is True
if diff from fctx2 to fctx1 has changes in linerange2 and
`linerange1` is the new line range for fctx1.
"""
blocks = mdiff.allblocks(fctx1.data(), fctx2.data(), diffopts)
filteredblocks, linerange1 = mdiff.blocksinrange(blocks, linerange2)
diffinrange = any(stype == b'!' for _, stype in filteredblocks)
return diffinrange, linerange1
def blockancestors(fctx, fromline, toline, followfirst=False):
"""Yield ancestors of `fctx` with respect to the block of lines within
`fromline`-`toline` range.
"""
diffopts = patch.diffopts(fctx._repo.ui)
fctx = fctx.introfilectx()
visit = {(fctx.linkrev(), fctx.filenode()): (fctx, (fromline, toline))}
while visit:
c, linerange2 = visit.pop(max(visit))
pl = c.parents()
if followfirst:
pl = pl[:1]
if not pl:
# The block originates from the initial revision.
yield c, linerange2
continue
inrange = False
for p in pl:
inrangep, linerange1 = _changesrange(p, c, linerange2, diffopts)
inrange = inrange or inrangep
if linerange1[0] == linerange1[1]:
# Parent's linerange is empty, meaning that the block got
# introduced in this revision; no need to go futher in this
# branch.
continue
# Set _descendantrev with 'c' (a known descendant) so that, when
# _adjustlinkrev is called for 'p', it receives this descendant
# (as srcrev) instead possibly topmost introrev.
p._descendantrev = c.rev()
visit[p.linkrev(), p.filenode()] = p, linerange1
if inrange:
yield c, linerange2
def blockdescendants(fctx, fromline, toline):
"""Yield descendants of `fctx` with respect to the block of lines within
`fromline`-`toline` range.
"""
# First possibly yield 'fctx' if it has changes in range with respect to
# its parents.
try:
c, linerange1 = next(blockancestors(fctx, fromline, toline))
except StopIteration:
pass
else:
if c == fctx:
yield c, linerange1
diffopts = patch.diffopts(fctx._repo.ui)
fl = fctx.filelog()
seen = {fctx.filerev(): (fctx, (fromline, toline))}
for i in fl.descendants([fctx.filerev()]):
c = fctx.filectx(i)
inrange = False
for x in fl.parentrevs(i):
try:
p, linerange2 = seen[x]
except KeyError:
# nullrev or other branch
continue
inrangep, linerange1 = _changesrange(c, p, linerange2, diffopts)
inrange = inrange or inrangep
# If revision 'i' has been seen (it's a merge) and the line range
# previously computed differs from the one we just got, we take the
# surrounding interval. This is conservative but avoids loosing
# information.
if i in seen and seen[i][1] != linerange1:
lbs, ubs = zip(linerange1, seen[i][1])
linerange1 = min(lbs), max(ubs)
seen[i] = c, linerange1
if inrange:
yield c, linerange1
@attr.s(slots=True, frozen=True)
class annotateline:
fctx = attr.ib()
lineno = attr.ib()
# Whether this annotation was the result of a skip-annotate.
skip = attr.ib(default=False)
text = attr.ib(default=None)
@attr.s(slots=True, frozen=True)
class _annotatedfile:
# list indexed by lineno - 1
fctxs = attr.ib()
linenos = attr.ib()
skips = attr.ib()
# full file content
text = attr.ib()
def _countlines(text):
if text.endswith(b"\n"):
return text.count(b"\n")
return text.count(b"\n") + int(bool(text))
def _decoratelines(text, fctx):
n = _countlines(text)
linenos = pycompat.rangelist(1, n + 1)
return _annotatedfile([fctx] * n, linenos, [False] * n, text)
def _annotatepair(parents, childfctx, child, skipchild, diffopts):
r"""
Given parent and child fctxes and annotate data for parents, for all lines
in either parent that match the child, annotate the child with the parent's
data.
Additionally, if `skipchild` is True, replace all other lines with parent
annotate data as well such that child is never blamed for any lines.
See test-annotate.py for unit tests.
"""
pblocks = [
(parent, mdiff.allblocks(parent.text, child.text, opts=diffopts))
for parent in parents
]
if skipchild:
# Need to iterate over the blocks twice -- make it a list
pblocks = [(p, list(blocks)) for (p, blocks) in pblocks]
# Mercurial currently prefers p2 over p1 for annotate.
# TODO: change this?
for parent, blocks in pblocks:
for (a1, a2, b1, b2), t in blocks:
# Changed blocks ('!') or blocks made only of blank lines ('~')
# belong to the child.
if t == b'=':
child.fctxs[b1:b2] = parent.fctxs[a1:a2]
child.linenos[b1:b2] = parent.linenos[a1:a2]
child.skips[b1:b2] = parent.skips[a1:a2]
if skipchild:
# Now try and match up anything that couldn't be matched,
# Reversing pblocks maintains bias towards p2, matching above
# behavior.
pblocks.reverse()
# The heuristics are:
# * Work on blocks of changed lines (effectively diff hunks with -U0).
# This could potentially be smarter but works well enough.
# * For a non-matching section, do a best-effort fit. Match lines in
# diff hunks 1:1, dropping lines as necessary.
# * Repeat the last line as a last resort.
# First, replace as much as possible without repeating the last line.
remaining = [(parent, []) for parent, _blocks in pblocks]
for idx, (parent, blocks) in enumerate(pblocks):
for (a1, a2, b1, b2), _t in blocks:
if a2 - a1 >= b2 - b1:
for bk in range(b1, b2):
if child.fctxs[bk] == childfctx:
ak = min(a1 + (bk - b1), a2 - 1)
child.fctxs[bk] = parent.fctxs[ak]
child.linenos[bk] = parent.linenos[ak]
child.skips[bk] = 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 range(b1, b2):
if child.fctxs[bk] == childfctx:
ak = min(a1 + (bk - b1), a2 - 1)
child.fctxs[bk] = parent.fctxs[ak]
child.linenos[bk] = parent.linenos[ak]
child.skips[bk] = True
return child
def annotate(base, parents, skiprevs=None, diffopts=None) -> List[annotateline]:
"""Core algorithm for filectx.annotate()
`parents(fctx)` is a function returning a list of parent filectxs.
"""
# 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 = _decoratelines(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]
a = hist[base]
return [
annotateline(*r)
for r in zip(a.fctxs, a.linenos, a.skips, mdiff.splitnewlines(a.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 > 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
def headrevs(revs, parentsfn):
"""Resolve the set of heads from a set of revisions.
Receives an iterable of revision numbers and a callbable that receives a
revision number and returns an iterable of parent revision numbers, possibly
including nullrev.
Returns a set of revision numbers that are DAG heads within the passed
subset.
``nullrev`` is never included in the returned set, even if it is provided in
the input set.
"""
headrevs = set(revs)
parents = {nullrev}
up = parents.update
for rev in revs:
up(parentsfn(rev))
headrevs.difference_update(parents)
return headrevs
def headrevsdiff(parentsfn, start, stop):
"""Compute how the set of heads changed between
revisions `start-1` and `stop-1`.
"""
parents = set()
heads_added = set()
heads_removed = set()
for rev in range(stop - 1, start - 1, -1):
if rev in parents:
parents.remove(rev)
else:
heads_added.add(rev)
for p in parentsfn(rev):
parents.add(p)
# now `parents` is the collection of candidate removed heads
rev = start - 1
while parents:
if rev in parents:
heads_removed.add(rev)
parents.remove(rev)
for p in parentsfn(rev):
parents.discard(p)
rev = rev - 1
return (heads_removed, heads_added)
def headrevssubset(revsfn, parentrevsfn, startrev=None, stoprevs=None):
"""Returns the set of all revs that have no children with control.
``revsfn`` is a callable that with no arguments returns an iterator over
all revision numbers in topological order. With a ``start`` argument, it
returns revision numbers starting at that number.
``parentrevsfn`` is a callable receiving a revision number and returns an
iterable of parent revision numbers, where values can include nullrev.
``startrev`` is a revision number at which to start the search.
``stoprevs`` is an iterable of revision numbers that, when encountered,
will stop DAG traversal beyond them. Parents of revisions in this
collection will be heads.
"""
if startrev is None:
startrev = nullrev
stoprevs = set(stoprevs or [])
reachable = {startrev}
heads = {startrev}
for rev in revsfn(start=startrev + 1):
for prev in parentrevsfn(rev):
if prev in reachable:
if rev not in stoprevs:
reachable.add(rev)
heads.add(rev)
if prev in heads and prev not in stoprevs:
heads.remove(prev)
return heads
def linearize(revs, parentsfn):
"""Linearize and topologically sort a list of revisions.
The linearization process tries to create long runs of revs where a child
rev comes immediately after its first parent. This is done by visiting the
heads of the revs in inverse topological order, and for each visited rev,
visiting its second parent, then its first parent, then adding the rev
itself to the output list.
Returns a list of revision numbers.
"""
visit = list(sorted(headrevs(revs, parentsfn), reverse=True))
finished = set()
result = []
while visit:
rev = visit.pop()
if rev < 0:
rev = -rev - 1
if rev not in finished:
result.append(rev)
finished.add(rev)
else:
visit.append(-rev - 1)
for prev in parentsfn(rev):
if prev == nullrev or prev not in revs or prev in finished:
continue
visit.append(prev)
assert len(result) == len(revs)
return result