Before this patch, refcount (managed in "needed") of parents of each
revisions in "visit" is increased, only when parent is not annotated
yet (examined by "p not in hist").
But this causes less refcount of the revision like "A" in the tree
below ("A" is assumed as the second parent of "C"):
A --- B --- C
\ /
\-----/
Steps of annotation for "C" in this case are shown below:
1. for "C"
1.1 increase refcount of "B"
1.2 increase refcount of "A" (=> 1)
1.3 defer annotation for "C"
2. for "A"
2.1 annotate for "A" (=> put result into "hist[A]")
2.2 clear "pcache[A]" ("pcache[A] = []")
3. for "B"
3.1 not increase refcount of "A", because "A not in hist" is False
3.2 annotate for "B"
3.3 decrease refcount of "A" (=> 0)
3.4 delete "hist[A]", even though "A" is still needed by "C"
3.5 clear "pcache[B]"
4. for "C", again
4.1 not increase refcount of "B", because "B not in hist" is False
4.2 increase refcount of "A" (=> 1)
4.3 defer annotation for "C"
5. for "A", again
5.1 annotate for "A" (=> put result into "hist[A]", again)
5.2 clear "pcache[A]"
6. for "C", once again
6.1 not increase refcount of "B", because "B not in hist" is False
6.2 not increase refcount of "A", because "A not in hist" is False
6.3 annotate for "C"
6.4 decrease refcount of "A", and delete "hist[A]"
6.5 decrease refcount of "B", and delete "hist[B]"
6.6 clear "pcache[C]"
At step (5.1), annotation for "A" mis-recognizes that all lines are
created at "A", because "pcache[A]" already cleared at step (2.2)
prevents from scanning ancestors of "A".
So, annotation for "C" or its descendants loses information about "A"
or its ancestors.
The root cause of this problem is that refcount of "A" is decreased at
step (3.3), even though it isn't increased at step (3.1).
To increase refcount correctly, this patch increases refcount of each
parents of each revisions:
- regardless of "p not in hist" or not, and
- only once for each revisions in "visit" (by "not pcached")
In fact, this problem should occur only on legacy repositories in
which a filelog includes the merging between the revision and its
ancestor (as the second parent), because:
- tree is scanned in depth-first
without such merging, revisions in "visit" refer different
revisions as parent each other
- recent Mercurial doesn't allow such merging
changelog and manifest can include such merging someway, but
filelogs can't, because "localrepository._filecommit()" converts
such merging request to linear history.
This patch tests merging cases below: these cases are from filelog of
"mercurial/commands.py" in the repository of Mercurial itself.
- both parents are same
10 --- 11 --- 12
\_/
filelogrev: changesetid:
10 526aca6bcb38
11 05098100ff44
12 2d4f4cfa81d6
- the second parent is also ancestor of the first one
37 --- 38 --- 39 --- 40
\________/
filelogrev: changesetid:
37 033dc4170fe6
38 5ff1a23ce38c
39 661a47367859
40 a2ba99fd026f
Before this patch, annotation is re-calculated even if it is already
calculated. This may cause unexpected annotation, because already
cleared "pcache" ("pcache[f] = []") prevents from scanning ancestors.
This patch reuses already calculated annotation if it is available.
In fact, "reusable" situation should be seen only on legacy
repositories in which a filelog include the merging between the
revision and its ancestor, because:
- tree is scanned in depth-first
without such merging, annotation result should be released soon
- recent Mercurial doesn't allow such merging
changelog and manifest can include such merging someway, but
filelogs can't, because "localrepository._filecommit()" converts
such merging request to linear history.
Instead of walking all the way to the root of the DAG, we generate
a set of candidate GCA revs, then figure out which ones will win
the race to the root (usually without needing to traverse all the
way to the root).
In the common case of nodes that are close to each other in both
revision number and topology, this is usually a big win: it makes
"hg --time debugancestors" up to 9 times faster than the more general
ancestor function when measured on heads of the linux-2.6 hg repo.
Victory is not assured, however. The older function can still win
by a large margin if one node is much closer to the root than the
other, or by a much smaller amount if one is an ancestor of the
other.
For now, we've also got a small paranoid harness function that calls
both ancestor functions on every input and ensures that they give
equivalent answers.
Even without the checker function, the old ancestor function needs
to stay alive for the time being, as its generality is used by
context.filectx.merge.
If exception is error.LookupError and running in i18n environment,
below condition is always true.
Because msg is translated and dosen't contain 'manifest'.
if util.safehasattr(err, 'name') and 'manifest' not in msg:
This patch creates a new exception class and uses it instead of
string match.
We can not use `len(repo,changelog)`, it may be a filtered revision. We now use
`repo,changelog.tip()` to fetch this information.
The `tip` command is also fixed and tested
Thanks goes to Idan Kamara for the initial report.
This pulls some of the logic for the cleanup that needs to happen
after a commit has been made otu of localrepo.commit and into
workingctx. This is part of a larger refactoring effort that will
eventually allow us to perform some types of merges in-memory.
Now that changelog filtering is in place, it's become evident that
naming the filters according to the set of revs _not_ included in the
filtered changelog is confusing. This is especially evident in the
collaborative branch cache scheme.
This changes the names of the filters to reflect the revs that _are_
included:
hidden -> visible
unserved -> served
mutable -> immutable
impactable -> base
repoview.filteredrevs is renamed to filterrevs, so that callers read a
bit more sensibly, e.g.:
filterrevs('visible') # filter revs according to what's visible
Add sorted() in places found by testing with PYTHONHASHSEED=random and code
inspection.
An alternative to sprinkling sorted() all over would be to change substate to a
custom dict with sorted iterators...
On `filectx`, linkrev may point to any revision in the repository. When the
repository is filtered this may lead to `filectx` trying to build `changectx`
for filtered revision. In such case we fallback to creating `changectx` on the
unfiltered version of the reposition. This fallback should not be an issue
because `changectx` from `filectx` are not used in complex operation that
care about filtering. It is complicated to work around the issue in a
clearer way as code raising such `filectx` rarely have access to the
repository directly.
Linkrevs create a lot of issue with filtering. It is stored in revlog entry at
creation time and never changed. Nothing prevent the changeset revision pointed
to become filtered. Several bogus behavior emerge from such situation. Those
bugs are complex to solve and not part of the current effort to install
filtering. This changeset is simple hack that prevent plain crash in favor on
minor misbehavior without visible effect.
This "hack" is longly documented in to code itself to help people that would
look at it in the future.
Currently the code path of `changectx(filteredrepo, rev)` call
`filteredrepo.changelog.node(rev)`. When `rev` is filtered this raise an
unhandled `IndexError`. This case now raise a `RepoLookupError` as other
error case do.
The same we have `unstable` and `bumped`. Convenient method to access troubles
information in general may land later.
This get actual use and testing in the next changesets.
During changectx __init__ the dirstate's parents MAY be checked. If
the repo is filtered, this check will complain "working directory has
unknown parents" even if the parents are perfectly known.
This may happen when the repo is used for serving and the dirstate has
parents that are secret, as those secret changesets will be filtered.
The old name was not very good for two reasons:
- caller does not care about "cache",
- set of revision returned may not be obsolete at all.
The new name was suggested by Kevin Bullock.
This patch adds "descendant()", which uses "revlog.descendant()" for
descendant examination, to changectx.
This implementation is more efficient than "new in old.descendants()"
expression, because:
- "changectx.descendants()" creates temporary "changectx" objects,
but "revlog.descendant()" doesn't
"revlog.descendant()" checks only revision numbers of descendants.
- "revlog.descendant()" stops scanning, when scanning of all
revisions less than one of examination target is finished
this can avoid useless scanning in "not descendant" case.
This changeset introduces caches on the `obsstore` that keeps track of sets of
revisions meaningful for obsolescence related logics. For now they are:
- obsolete: changesets used as precursors (and not public),
- extinct: obsolete changesets with osbolete descendants only,
- unstable: non obsolete changesets with obsolete ancestors.
The cache is accessed using the `getobscache(repo, '<set-name>')` function which
builds the cache on demand. The `clearobscaches(repo)` function takes care of
clearing the caches if any.
Caches are cleared when one of these events happens:
- a new marker is added,
- a new changeset is added,
- some changesets are made public,
- some public changesets are demoted to draft or secret.
Declaration of more sets is made easy because we will have to handle at least
two other "troubles" (latecomer and conflicting).
Caches are now used by revset and changectx. It is usually not much more
expensive to compute the whole set than to check the property of a few elements.
The performance boost is welcome in case we apply obsolescence logic on a lot of
revisions. This makes the feature usable!
This set is always accessed through the repo for now. Having this set
carried by the changelog make it complicated to:
- initialize it, computing hidden set may involve revset call
- lazy compute it, (1) only the changelog can detect someone access it,
(2) only the repo have enought knowledge to compute it.
In later version I expect he changelog to apply filtering itself and the set to
be carried by changelog again.
`extinct` changesets are obsolete changesets with obsolete descendants only. They
are of no interest anymore and can be:
- exclude from exchange
- hidden to the user in most situation
- safely garbage collected
This changeset just allows mercurial to detect them.
The implementation is a bit naive, as for unstable changesets. We better use a
simple revset query and a cache, but simple version comes first.
An unstable changeset is a changeset *not* obsolete but with some obsolete
ancestors.
The current logic to decide if a changeset is unstable is naive and very
inefficient. A better solution is to compute the set of unstable changeset with
a simple revset and to cache the result. But this require cache invalidation
logic. Simpler version goes first.
An `obsolete` boolean property is added to changeset context. Function to get
obsolete marker object from a changeset context are added to the obsolete
module.
Accepting a variable number of arguments as the old API did is
deeply ugly, particularly as it means the API can't be extended
with new arguments. Partly as a result, we have at least three
different implementations of the same ancestors algorithm (!?).
Most callers were forced to call ancestors(*somelist), adding to
both inefficiency and ugliness.
The original motivation was changectx.phase() had special logic to
correctly lookup in repo._phaserev, including invalidating it when
necessary. And at other places, repo._phaserev was accessed directly.
This led to the discovery that phases state including _phaseroots,
_phaserev and _dirtyphase was manipulated in localrepository.py,
phases.py, repair.py, etc. phasecache helps encapsulating that.
This patch replaces all phase state in localrepo with phasecache and
adjust related code except for advance/retractboundary() in phases.
These still access to phasecache internals directly. This will be
addressed in a followup.