obsutil.py
553 lines
| 21.1 KiB
| text/x-python
|
PythonLexer
/ mercurial / obsutil.py
Boris Feld
|
r32879 | # obsutil.py - utility functions for obsolescence | ||
# | ||||
# Copyright 2017 Boris Feld <boris.feld@octobus.net> | ||||
# | ||||
# 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 absolute_import | ||||
r33249 | from . import ( | |||
phases, | ||||
Boris Feld
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r33697 | util | ||
r33249 | ) | |||
r33149 | class marker(object): | |||
"""Wrap obsolete marker raw data""" | ||||
def __init__(self, repo, data): | ||||
# the repo argument will be used to create changectx in later version | ||||
self._repo = repo | ||||
self._data = data | ||||
self._decodedmeta = None | ||||
def __hash__(self): | ||||
return hash(self._data) | ||||
def __eq__(self, other): | ||||
if type(other) != type(self): | ||||
return False | ||||
return self._data == other._data | ||||
def precnode(self): | ||||
Boris Feld
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r33697 | msg = ("'marker.precnode' is deprecated, " | ||
"use 'marker.precnode'") | ||||
util.nouideprecwarn(msg, '4.4') | ||||
return self.prednode() | ||||
def prednode(self): | ||||
"""Predecessor changeset node identifier""" | ||||
r33149 | return self._data[0] | |||
def succnodes(self): | ||||
"""List of successor changesets node identifiers""" | ||||
return self._data[1] | ||||
def parentnodes(self): | ||||
Boris Feld
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r33697 | """Parents of the predecessors (None if not recorded)""" | ||
r33149 | return self._data[5] | |||
def metadata(self): | ||||
"""Decoded metadata dictionary""" | ||||
return dict(self._data[3]) | ||||
def date(self): | ||||
"""Creation date as (unixtime, offset)""" | ||||
return self._data[4] | ||||
def flags(self): | ||||
"""The flags field of the marker""" | ||||
return self._data[2] | ||||
r33150 | def getmarkers(repo, nodes=None, exclusive=False): | |||
"""returns markers known in a repository | ||||
If <nodes> is specified, only markers "relevant" to those nodes are are | ||||
returned""" | ||||
if nodes is None: | ||||
rawmarkers = repo.obsstore | ||||
elif exclusive: | ||||
rawmarkers = exclusivemarkers(repo, nodes) | ||||
else: | ||||
rawmarkers = repo.obsstore.relevantmarkers(nodes) | ||||
for markerdata in rawmarkers: | ||||
yield marker(repo, markerdata) | ||||
Boris Feld
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r32879 | def closestpredecessors(repo, nodeid): | ||
"""yield the list of next predecessors pointing on visible changectx nodes | ||||
This function respect the repoview filtering, filtered revision will be | ||||
considered missing. | ||||
""" | ||||
Boris Feld
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r33699 | precursors = repo.obsstore.predecessors | ||
Boris Feld
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r32879 | stack = [nodeid] | ||
seen = set(stack) | ||||
while stack: | ||||
current = stack.pop() | ||||
currentpreccs = precursors.get(current, ()) | ||||
for prec in currentpreccs: | ||||
precnodeid = prec[0] | ||||
# Basic cycle protection | ||||
if precnodeid in seen: | ||||
continue | ||||
seen.add(precnodeid) | ||||
if precnodeid in repo: | ||||
yield precnodeid | ||||
else: | ||||
stack.append(precnodeid) | ||||
r33143 | ||||
Boris Feld
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r33701 | def allprecursors(*args, **kwargs): | ||
""" (DEPRECATED) | ||||
""" | ||||
msg = ("'obsutil.allprecursors' is deprecated, " | ||||
"use 'obsutil.allpredecessors'") | ||||
util.nouideprecwarn(msg, '4.4') | ||||
return allpredecessors(*args, **kwargs) | ||||
def allpredecessors(obsstore, nodes, ignoreflags=0): | ||||
r33145 | """Yield node for every precursors of <nodes>. | |||
Some precursors may be unknown locally. | ||||
This is a linear yield unsuited to detecting folded changesets. It includes | ||||
initial nodes too.""" | ||||
remaining = set(nodes) | ||||
seen = set(remaining) | ||||
while remaining: | ||||
current = remaining.pop() | ||||
yield current | ||||
Boris Feld
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r33699 | for mark in obsstore.predecessors.get(current, ()): | ||
r33145 | # ignore marker flagged with specified flag | |||
if mark[2] & ignoreflags: | ||||
continue | ||||
suc = mark[0] | ||||
if suc not in seen: | ||||
seen.add(suc) | ||||
remaining.add(suc) | ||||
r33146 | def allsuccessors(obsstore, nodes, ignoreflags=0): | |||
"""Yield node for every successor of <nodes>. | ||||
Some successors may be unknown locally. | ||||
This is a linear yield unsuited to detecting split changesets. It includes | ||||
initial nodes too.""" | ||||
remaining = set(nodes) | ||||
seen = set(remaining) | ||||
while remaining: | ||||
current = remaining.pop() | ||||
yield current | ||||
for mark in obsstore.successors.get(current, ()): | ||||
# ignore marker flagged with specified flag | ||||
if mark[2] & ignoreflags: | ||||
continue | ||||
for suc in mark[1]: | ||||
if suc not in seen: | ||||
seen.add(suc) | ||||
remaining.add(suc) | ||||
r33144 | def _filterprunes(markers): | |||
"""return a set with no prune markers""" | ||||
return set(m for m in markers if m[1]) | ||||
def exclusivemarkers(repo, nodes): | ||||
"""set of markers relevant to "nodes" but no other locally-known nodes | ||||
This function compute the set of markers "exclusive" to a locally-known | ||||
node. This means we walk the markers starting from <nodes> until we reach a | ||||
locally-known precursors outside of <nodes>. Element of <nodes> with | ||||
locally-known successors outside of <nodes> are ignored (since their | ||||
precursors markers are also relevant to these successors). | ||||
For example: | ||||
# (A0 rewritten as A1) | ||||
# | ||||
# A0 <-1- A1 # Marker "1" is exclusive to A1 | ||||
or | ||||
# (A0 rewritten as AX; AX rewritten as A1; AX is unkown locally) | ||||
# | ||||
# <-1- A0 <-2- AX <-3- A1 # Marker "2,3" are exclusive to A1 | ||||
or | ||||
# (A0 has unknown precursors, A0 rewritten as A1 and A2 (divergence)) | ||||
# | ||||
# <-2- A1 # Marker "2" is exclusive to A0,A1 | ||||
# / | ||||
# <-1- A0 | ||||
# \ | ||||
# <-3- A2 # Marker "3" is exclusive to A0,A2 | ||||
# | ||||
# in addition: | ||||
# | ||||
# Markers "2,3" are exclusive to A1,A2 | ||||
# Markers "1,2,3" are exclusive to A0,A1,A2 | ||||
See test/test-obsolete-bundle-strip.t for more examples. | ||||
An example usage is strip. When stripping a changeset, we also want to | ||||
strip the markers exclusive to this changeset. Otherwise we would have | ||||
"dangling"" obsolescence markers from its precursors: Obsolescence markers | ||||
marking a node as obsolete without any successors available locally. | ||||
As for relevant markers, the prune markers for children will be followed. | ||||
Of course, they will only be followed if the pruned children is | ||||
locally-known. Since the prune markers are relevant to the pruned node. | ||||
However, while prune markers are considered relevant to the parent of the | ||||
pruned changesets, prune markers for locally-known changeset (with no | ||||
successors) are considered exclusive to the pruned nodes. This allows | ||||
to strip the prune markers (with the rest of the exclusive chain) alongside | ||||
the pruned changesets. | ||||
""" | ||||
# running on a filtered repository would be dangerous as markers could be | ||||
# reported as exclusive when they are relevant for other filtered nodes. | ||||
unfi = repo.unfiltered() | ||||
# shortcut to various useful item | ||||
nm = unfi.changelog.nodemap | ||||
Boris Feld
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r33699 | precursorsmarkers = unfi.obsstore.predecessors | ||
r33144 | successormarkers = unfi.obsstore.successors | |||
childrenmarkers = unfi.obsstore.children | ||||
# exclusive markers (return of the function) | ||||
exclmarkers = set() | ||||
# we need fast membership testing | ||||
nodes = set(nodes) | ||||
# looking for head in the obshistory | ||||
# | ||||
# XXX we are ignoring all issues in regard with cycle for now. | ||||
stack = [n for n in nodes if not _filterprunes(successormarkers.get(n, ()))] | ||||
stack.sort() | ||||
# nodes already stacked | ||||
seennodes = set(stack) | ||||
while stack: | ||||
current = stack.pop() | ||||
# fetch precursors markers | ||||
markers = list(precursorsmarkers.get(current, ())) | ||||
# extend the list with prune markers | ||||
for mark in successormarkers.get(current, ()): | ||||
if not mark[1]: | ||||
markers.append(mark) | ||||
# and markers from children (looking for prune) | ||||
for mark in childrenmarkers.get(current, ()): | ||||
if not mark[1]: | ||||
markers.append(mark) | ||||
# traverse the markers | ||||
for mark in markers: | ||||
if mark in exclmarkers: | ||||
# markers already selected | ||||
continue | ||||
# If the markers is about the current node, select it | ||||
# | ||||
# (this delay the addition of markers from children) | ||||
if mark[1] or mark[0] == current: | ||||
exclmarkers.add(mark) | ||||
# should we keep traversing through the precursors? | ||||
prec = mark[0] | ||||
# nodes in the stack or already processed | ||||
if prec in seennodes: | ||||
continue | ||||
# is this a locally known node ? | ||||
known = prec in nm | ||||
# if locally-known and not in the <nodes> set the traversal | ||||
# stop here. | ||||
if known and prec not in nodes: | ||||
continue | ||||
# do not keep going if there are unselected markers pointing to this | ||||
# nodes. If we end up traversing these unselected markers later the | ||||
# node will be taken care of at that point. | ||||
precmarkers = _filterprunes(successormarkers.get(prec)) | ||||
if precmarkers.issubset(exclmarkers): | ||||
seennodes.add(prec) | ||||
stack.append(prec) | ||||
return exclmarkers | ||||
r33147 | def foreground(repo, nodes): | |||
"""return all nodes in the "foreground" of other node | ||||
The foreground of a revision is anything reachable using parent -> children | ||||
or precursor -> successor relation. It is very similar to "descendant" but | ||||
augmented with obsolescence information. | ||||
Beware that possible obsolescence cycle may result if complex situation. | ||||
""" | ||||
repo = repo.unfiltered() | ||||
foreground = set(repo.set('%ln::', nodes)) | ||||
if repo.obsstore: | ||||
# We only need this complicated logic if there is obsolescence | ||||
# XXX will probably deserve an optimised revset. | ||||
nm = repo.changelog.nodemap | ||||
plen = -1 | ||||
# compute the whole set of successors or descendants | ||||
while len(foreground) != plen: | ||||
plen = len(foreground) | ||||
succs = set(c.node() for c in foreground) | ||||
mutable = [c.node() for c in foreground if c.mutable()] | ||||
succs.update(allsuccessors(repo.obsstore, mutable)) | ||||
known = (n for n in succs if n in nm) | ||||
foreground = set(repo.set('%ln::', known)) | ||||
return set(c.node() for c in foreground) | ||||
r33249 | def getobsoleted(repo, tr): | |||
"""return the set of pre-existing revisions obsoleted by a transaction""" | ||||
torev = repo.unfiltered().changelog.nodemap.get | ||||
phase = repo._phasecache.phase | ||||
succsmarkers = repo.obsstore.successors.get | ||||
public = phases.public | ||||
addedmarkers = tr.changes.get('obsmarkers') | ||||
addedrevs = tr.changes.get('revs') | ||||
seenrevs = set(addedrevs) | ||||
obsoleted = set() | ||||
for mark in addedmarkers: | ||||
node = mark[0] | ||||
rev = torev(node) | ||||
if rev is None or rev in seenrevs: | ||||
continue | ||||
seenrevs.add(rev) | ||||
if phase(repo, rev) == public: | ||||
continue | ||||
Augie Fackler
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r33679 | if set(succsmarkers(node) or []).issubset(addedmarkers): | ||
r33249 | obsoleted.add(rev) | |||
return obsoleted | ||||
Boris Feld
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r33274 | def successorssets(repo, initialnode, closest=False, cache=None): | ||
r33143 | """Return set of all latest successors of initial nodes | |||
The successors set of a changeset A are the group of revisions that succeed | ||||
A. It succeeds A as a consistent whole, each revision being only a partial | ||||
Boris Feld
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r33274 | replacement. By default, the successors set contains non-obsolete | ||
changesets only, walking the obsolescence graph until reaching a leaf. If | ||||
'closest' is set to True, closest successors-sets are return (the | ||||
obsolescence walk stops on known changesets). | ||||
r33143 | ||||
This function returns the full list of successor sets which is why it | ||||
returns a list of tuples and not just a single tuple. Each tuple is a valid | ||||
successors set. Note that (A,) may be a valid successors set for changeset A | ||||
(see below). | ||||
In most cases, a changeset A will have a single element (e.g. the changeset | ||||
A is replaced by A') in its successors set. Though, it is also common for a | ||||
changeset A to have no elements in its successor set (e.g. the changeset | ||||
has been pruned). Therefore, the returned list of successors sets will be | ||||
[(A',)] or [], respectively. | ||||
When a changeset A is split into A' and B', however, it will result in a | ||||
successors set containing more than a single element, i.e. [(A',B')]. | ||||
Divergent changesets will result in multiple successors sets, i.e. [(A',), | ||||
(A'')]. | ||||
If a changeset A is not obsolete, then it will conceptually have no | ||||
successors set. To distinguish this from a pruned changeset, the successor | ||||
set will contain itself only, i.e. [(A,)]. | ||||
Boris Feld
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r33272 | Finally, final successors unknown locally are considered to be pruned | ||
(pruned: obsoleted without any successors). (Final: successors not affected | ||||
by markers). | ||||
r33143 | ||||
Boris Feld
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r33274 | The 'closest' mode respect the repoview filtering. For example, without | ||
filter it will stop at the first locally known changeset, with 'visible' | ||||
filter it will stop on visible changesets). | ||||
Boris Feld
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r33272 | The optional `cache` parameter is a dictionary that may contains | ||
precomputed successors sets. It is meant to reuse the computation of a | ||||
previous call to `successorssets` when multiple calls are made at the same | ||||
time. The cache dictionary is updated in place. The caller is responsible | ||||
for its life span. Code that makes multiple calls to `successorssets` | ||||
*should* use this cache mechanism or risk a performance hit. | ||||
Boris Feld
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r33274 | |||
Since results are different depending of the 'closest' most, the same cache | ||||
cannot be reused for both mode. | ||||
r33143 | """ | |||
succmarkers = repo.obsstore.successors | ||||
# Stack of nodes we search successors sets for | ||||
toproceed = [initialnode] | ||||
# set version of above list for fast loop detection | ||||
# element added to "toproceed" must be added here | ||||
stackedset = set(toproceed) | ||||
if cache is None: | ||||
cache = {} | ||||
# This while loop is the flattened version of a recursive search for | ||||
# successors sets | ||||
# | ||||
# def successorssets(x): | ||||
# successors = directsuccessors(x) | ||||
# ss = [[]] | ||||
# for succ in directsuccessors(x): | ||||
# # product as in itertools cartesian product | ||||
# ss = product(ss, successorssets(succ)) | ||||
# return ss | ||||
# | ||||
# But we can not use plain recursive calls here: | ||||
# - that would blow the python call stack | ||||
# - obsolescence markers may have cycles, we need to handle them. | ||||
# | ||||
# The `toproceed` list act as our call stack. Every node we search | ||||
# successors set for are stacked there. | ||||
# | ||||
# The `stackedset` is set version of this stack used to check if a node is | ||||
# already stacked. This check is used to detect cycles and prevent infinite | ||||
# loop. | ||||
# | ||||
# successors set of all nodes are stored in the `cache` dictionary. | ||||
# | ||||
# After this while loop ends we use the cache to return the successors sets | ||||
# for the node requested by the caller. | ||||
while toproceed: | ||||
# Every iteration tries to compute the successors sets of the topmost | ||||
# node of the stack: CURRENT. | ||||
# | ||||
# There are four possible outcomes: | ||||
# | ||||
# 1) We already know the successors sets of CURRENT: | ||||
# -> mission accomplished, pop it from the stack. | ||||
Boris Feld
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r33274 | # 2) Stop the walk: | ||
# default case: Node is not obsolete | ||||
# closest case: Node is known at this repo filter level | ||||
# -> the node is its own successors sets. Add it to the cache. | ||||
r33143 | # 3) We do not know successors set of direct successors of CURRENT: | |||
# -> We add those successors to the stack. | ||||
# 4) We know successors sets of all direct successors of CURRENT: | ||||
# -> We can compute CURRENT successors set and add it to the | ||||
# cache. | ||||
# | ||||
current = toproceed[-1] | ||||
Boris Feld
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r33274 | |||
# case 2 condition is a bit hairy because of closest, | ||||
# we compute it on its own | ||||
case2condition = ((current not in succmarkers) | ||||
or (closest and current != initialnode | ||||
and current in repo)) | ||||
r33143 | if current in cache: | |||
# case (1): We already know the successors sets | ||||
stackedset.remove(toproceed.pop()) | ||||
Boris Feld
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r33274 | elif case2condition: | ||
# case (2): end of walk. | ||||
r33143 | if current in repo: | |||
Boris Feld
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r33274 | # We have a valid successors. | ||
r33143 | cache[current] = [(current,)] | |||
else: | ||||
# Final obsolete version is unknown locally. | ||||
# Do not count that as a valid successors | ||||
cache[current] = [] | ||||
else: | ||||
# cases (3) and (4) | ||||
# | ||||
# We proceed in two phases. Phase 1 aims to distinguish case (3) | ||||
# from case (4): | ||||
# | ||||
# For each direct successors of CURRENT, we check whether its | ||||
# successors sets are known. If they are not, we stack the | ||||
# unknown node and proceed to the next iteration of the while | ||||
# loop. (case 3) | ||||
# | ||||
# During this step, we may detect obsolescence cycles: a node | ||||
# with unknown successors sets but already in the call stack. | ||||
# In such a situation, we arbitrary set the successors sets of | ||||
# the node to nothing (node pruned) to break the cycle. | ||||
# | ||||
# If no break was encountered we proceed to phase 2. | ||||
# | ||||
# Phase 2 computes successors sets of CURRENT (case 4); see details | ||||
# in phase 2 itself. | ||||
# | ||||
# Note the two levels of iteration in each phase. | ||||
# - The first one handles obsolescence markers using CURRENT as | ||||
# precursor (successors markers of CURRENT). | ||||
# | ||||
# Having multiple entry here means divergence. | ||||
# | ||||
# - The second one handles successors defined in each marker. | ||||
# | ||||
# Having none means pruned node, multiple successors means split, | ||||
# single successors are standard replacement. | ||||
# | ||||
for mark in sorted(succmarkers[current]): | ||||
for suc in mark[1]: | ||||
if suc not in cache: | ||||
if suc in stackedset: | ||||
# cycle breaking | ||||
cache[suc] = [] | ||||
else: | ||||
# case (3) If we have not computed successors sets | ||||
# of one of those successors we add it to the | ||||
# `toproceed` stack and stop all work for this | ||||
# iteration. | ||||
toproceed.append(suc) | ||||
stackedset.add(suc) | ||||
break | ||||
else: | ||||
continue | ||||
break | ||||
else: | ||||
# case (4): we know all successors sets of all direct | ||||
# successors | ||||
# | ||||
# Successors set contributed by each marker depends on the | ||||
# successors sets of all its "successors" node. | ||||
# | ||||
# Each different marker is a divergence in the obsolescence | ||||
# history. It contributes successors sets distinct from other | ||||
# markers. | ||||
# | ||||
# Within a marker, a successor may have divergent successors | ||||
# sets. In such a case, the marker will contribute multiple | ||||
# divergent successors sets. If multiple successors have | ||||
# divergent successors sets, a Cartesian product is used. | ||||
# | ||||
# At the end we post-process successors sets to remove | ||||
# duplicated entry and successors set that are strict subset of | ||||
# another one. | ||||
succssets = [] | ||||
for mark in sorted(succmarkers[current]): | ||||
# successors sets contributed by this marker | ||||
markss = [[]] | ||||
for suc in mark[1]: | ||||
# cardinal product with previous successors | ||||
productresult = [] | ||||
for prefix in markss: | ||||
for suffix in cache[suc]: | ||||
newss = list(prefix) | ||||
for part in suffix: | ||||
# do not duplicated entry in successors set | ||||
# first entry wins. | ||||
if part not in newss: | ||||
newss.append(part) | ||||
productresult.append(newss) | ||||
markss = productresult | ||||
succssets.extend(markss) | ||||
# remove duplicated and subset | ||||
seen = [] | ||||
final = [] | ||||
candidate = sorted(((set(s), s) for s in succssets if s), | ||||
key=lambda x: len(x[1]), reverse=True) | ||||
for setversion, listversion in candidate: | ||||
for seenset in seen: | ||||
if setversion.issubset(seenset): | ||||
break | ||||
else: | ||||
final.append(listversion) | ||||
seen.append(setversion) | ||||
final.reverse() # put small successors set first | ||||
cache[current] = final | ||||
return cache[initialnode] | ||||