""" Mercurial phases support code
---
Copyright 2011 Pierre-Yves David <pierre-yves.david@ens-lyon.org>
Logilab SA <contact@logilab.fr>
Augie Fackler <durin42@gmail.com>
This software may be used and distributed according to the terms
of the GNU General Public License version 2 or any later version.
---
This module implements most phase logic in mercurial.
Basic Concept
=============
A 'changeset phase' is an indicator that tells us how a changeset is
manipulated and communicated. The details of each phase is described
below, here we describe the properties they have in common.
Like bookmarks, phases are not stored in history and thus are not
permanent and leave no audit trail.
First, no changeset can be in two phases at once. Phases are ordered,
so they can be considered from lowest to highest. The default, lowest
phase is 'public' - this is the normal phase of existing changesets. A
child changeset can not be in a lower phase than its parents.
These phases share a hierarchy of traits:
immutable shared
public: X X
draft: X
secret:
Local commits are draft by default.
Phase Movement and Exchange
===========================
Phase data is exchanged by pushkey on pull and push. Some servers have
a publish option set, we call such a server a "publishing server".
Pushing a draft changeset to a publishing server changes the phase to
public.
A small list of fact/rules define the exchange of phase:
* old client never changes server states
* pull never changes server states
* publish and old server changesets are seen as public by client
* any secret changeset seen in another repository is lowered to at
least draft
Here is the final table summing up the 49 possible use cases of phase
exchange:
server
old publish non-publish
N X N D P N D P
old client
pull
N - X/X - X/D X/P - X/D X/P
X - X/X - X/D X/P - X/D X/P
push
X X/X X/X X/P X/P X/P X/D X/D X/P
new client
pull
N - P/X - P/D P/P - D/D P/P
D - P/X - P/D P/P - D/D P/P
P - P/X - P/D P/P - P/D P/P
push
D P/X P/X P/P P/P P/P D/D D/D P/P
P P/X P/X P/P P/P P/P P/P P/P P/P
Legend:
A/B = final state on client / state on server
* N = new/not present,
* P = public,
* D = draft,
* X = not tracked (i.e., the old client or server has no internal
way of recording the phase.)
passive = only pushes
A cell here can be read like this:
"When a new client pushes a draft changeset (D) to a publishing
server where it's not present (N), it's marked public on both
sides (P/P)."
Note: old client behave as a publishing server with draft only content
- other people see it as public
- content is pushed as draft
"""
import heapq
import struct
import typing
import weakref
from typing import (
Any,
Callable,
Dict,
Iterable,
List,
Optional,
Set,
Tuple,
)
from .i18n import _
from .node import (
bin,
hex,
nullrev,
short,
wdirrev,
)
from . import (
error,
pycompat,
requirements,
smartset,
txnutil,
util,
)
Phaseroots = Dict[int, Set[int]]
PhaseSets = Dict[int, Set[int]]
if typing.TYPE_CHECKING:
from . import (
localrepo,
ui as uimod,
)
# keeps pyflakes happy
assert [uimod]
Phasedefaults = List[
Callable[[localrepo.localrepository, Phaseroots], Phaseroots]
]
_fphasesentry = struct.Struct(b'>i20s')
# record phase index
public: int = 0
draft: int = 1
secret: int = 2
archived = 32 # non-continuous for compatibility
internal = 96 # non-continuous for compatibility
allphases = (public, draft, secret, archived, internal)
trackedphases = (draft, secret, archived, internal)
not_public_phases = trackedphases
# record phase names
cmdphasenames = [b'public', b'draft', b'secret'] # known to `hg phase` command
phasenames = dict(enumerate(cmdphasenames))
phasenames[archived] = b'archived'
phasenames[internal] = b'internal'
# map phase name to phase number
phasenumber = {name: phase for phase, name in phasenames.items()}
# like phasenumber, but also include maps for the numeric and binary
# phase number to the phase number
phasenumber2 = phasenumber.copy()
phasenumber2.update({phase: phase for phase in phasenames})
phasenumber2.update({b'%i' % phase: phase for phase in phasenames})
# record phase property
mutablephases = (draft, secret, archived, internal)
relevant_mutable_phases = (draft, secret) # could be obsolete or unstable
remotehiddenphases = (secret, archived, internal)
localhiddenphases = (internal, archived)
all_internal_phases = tuple(p for p in allphases if p & internal)
# We do not want any internal content to exit the repository, ever.
no_bundle_phases = all_internal_phases
def supportinternal(repo: "localrepo.localrepository") -> bool:
"""True if the internal phase can be used on a repository"""
return requirements.INTERNAL_PHASE_REQUIREMENT in repo.requirements
def supportarchived(repo: "localrepo.localrepository") -> bool:
"""True if the archived phase can be used on a repository"""
return requirements.ARCHIVED_PHASE_REQUIREMENT in repo.requirements
def _readroots(
repo: "localrepo.localrepository",
phasedefaults: Optional["Phasedefaults"] = None,
) -> Tuple[Phaseroots, bool]:
"""Read phase roots from disk
phasedefaults is a list of fn(repo, roots) callable, which are
executed if the phase roots file does not exist. When phases are
being initialized on an existing repository, this could be used to
set selected changesets phase to something else than public.
Return (roots, dirty) where dirty is true if roots differ from
what is being stored.
"""
repo = repo.unfiltered()
dirty = False
roots = {i: set() for i in allphases}
to_rev = repo.changelog.index.get_rev
unknown_msg = b'removing unknown node %s from %i-phase boundary\n'
try:
f, pending = txnutil.trypending(repo.root, repo.svfs, b'phaseroots')
try:
for line in f:
str_phase, hex_node = line.split()
phase = int(str_phase)
node = bin(hex_node)
rev = to_rev(node)
if rev is None:
repo.ui.debug(unknown_msg % (short(hex_node), phase))
dirty = True
else:
roots[phase].add(rev)
finally:
f.close()
except FileNotFoundError:
if phasedefaults:
for f in phasedefaults:
roots = f(repo, roots)
dirty = True
return roots, dirty
def binaryencode(phasemapping: Dict[int, List[bytes]]) -> bytes:
"""encode a 'phase -> nodes' mapping into a binary stream
The revision lists are encoded as (phase, root) pairs.
"""
binarydata = []
for phase, nodes in phasemapping.items():
for head in nodes:
binarydata.append(_fphasesentry.pack(phase, head))
return b''.join(binarydata)
def binarydecode(stream) -> Dict[int, List[bytes]]:
"""decode a binary stream into a 'phase -> nodes' mapping
The (phase, root) pairs are turned back into a dictionary with
the phase as index and the aggregated roots of that phase as value."""
headsbyphase = {i: [] for i in allphases}
entrysize = _fphasesentry.size
while True:
entry = stream.read(entrysize)
if len(entry) < entrysize:
if entry:
raise error.Abort(_(b'bad phase-heads stream'))
break
phase, node = _fphasesentry.unpack(entry)
headsbyphase[phase].append(node)
return headsbyphase
def _sortedrange_insert(data, idx, rev, t):
merge_before = False
if idx:
r1, t1 = data[idx - 1]
merge_before = r1[-1] + 1 == rev and t1 == t
merge_after = False
if idx < len(data):
r2, t2 = data[idx]
merge_after = r2[0] == rev + 1 and t2 == t
if merge_before and merge_after:
data[idx - 1] = (range(r1[0], r2[-1] + 1), t)
data.pop(idx)
elif merge_before:
data[idx - 1] = (range(r1[0], rev + 1), t)
elif merge_after:
data[idx] = (range(rev, r2[-1] + 1), t)
else:
data.insert(idx, (range(rev, rev + 1), t))
def _sortedrange_split(data, idx, rev, t):
r1, t1 = data[idx]
if t == t1:
return
t = (t1[0], t[1])
if len(r1) == 1:
data.pop(idx)
_sortedrange_insert(data, idx, rev, t)
elif r1[0] == rev:
data[idx] = (range(rev + 1, r1[-1] + 1), t1)
_sortedrange_insert(data, idx, rev, t)
elif r1[-1] == rev:
data[idx] = (range(r1[0], rev), t1)
_sortedrange_insert(data, idx + 1, rev, t)
else:
data[idx : idx + 1] = [
(range(r1[0], rev), t1),
(range(rev, rev + 1), t),
(range(rev + 1, r1[-1] + 1), t1),
]
def _trackphasechange(data, rev, old, new):
"""add a phase move to the <data> list of ranges
If data is None, nothing happens.
"""
if data is None:
return
# If data is empty, create a one-revision range and done
if not data:
data.insert(0, (range(rev, rev + 1), (old, new)))
return
low = 0
high = len(data)
t = (old, new)
while low < high:
mid = (low + high) // 2
revs = data[mid][0]
revs_low = revs[0]
revs_high = revs[-1]
if rev >= revs_low and rev <= revs_high:
_sortedrange_split(data, mid, rev, t)
return
if revs_low == rev + 1:
if mid and data[mid - 1][0][-1] == rev:
_sortedrange_split(data, mid - 1, rev, t)
else:
_sortedrange_insert(data, mid, rev, t)
return
if revs_high == rev - 1:
if mid + 1 < len(data) and data[mid + 1][0][0] == rev:
_sortedrange_split(data, mid + 1, rev, t)
else:
_sortedrange_insert(data, mid + 1, rev, t)
return
if revs_low > rev:
high = mid
else:
low = mid + 1
if low == len(data):
data.append((range(rev, rev + 1), t))
return
r1, t1 = data[low]
if r1[0] > rev:
data.insert(low, (range(rev, rev + 1), t))
else:
data.insert(low + 1, (range(rev, rev + 1), t))
# consider incrementaly updating the phase set the update set is not bigger
# than this size
#
# Be warned, this number is picked arbitrarily, without any benchmark. It
# should blindly pickup "small update"
INCREMENTAL_PHASE_SETS_UPDATE_MAX_UPDATE = 100
class phasecache:
def __init__(
self,
repo: "localrepo.localrepository",
phasedefaults: Optional["Phasedefaults"],
_load: bool = True,
):
if _load:
# Cheap trick to allow shallow-copy without copy module
loaded = _readroots(repo, phasedefaults)
self._phaseroots: Phaseroots = loaded[0]
self.dirty: bool = loaded[1]
self._loadedrevslen = 0
self._phasesets: PhaseSets = None
def hasnonpublicphases(self, repo: "localrepo.localrepository") -> bool:
"""detect if there are revisions with non-public phase"""
# XXX deprecate the unused repo argument
return any(
revs for phase, revs in self._phaseroots.items() if phase != public
)
def nonpublicphaseroots(
self, repo: "localrepo.localrepository"
) -> Set[int]:
"""returns the roots of all non-public phases
The roots are not minimized, so if the secret revisions are
descendants of draft revisions, their roots will still be present.
"""
repo = repo.unfiltered()
self._ensure_phase_sets(repo)
return set().union(
*[
revs
for phase, revs in self._phaseroots.items()
if phase != public
]
)
def getrevset(
self,
repo: "localrepo.localrepository",
phases: Iterable[int],
subset: Optional[Any] = None,
) -> Any:
# TODO: finish typing this
"""return a smartset for the given phases"""
self._ensure_phase_sets(repo.unfiltered())
phases = set(phases)
publicphase = public in phases
if publicphase:
# In this case, phases keeps all the *other* phases.
phases = set(allphases).difference(phases)
if not phases:
return smartset.fullreposet(repo)
# fast path: _phasesets contains the interesting sets,
# might only need a union and post-filtering.
revsneedscopy = False
if len(phases) == 1:
[p] = phases
revs = self._phasesets[p]
revsneedscopy = True # Don't modify _phasesets
else:
# revs has the revisions in all *other* phases.
revs = set.union(*[self._phasesets[p] for p in phases])
def _addwdir(wdirsubset, wdirrevs):
if wdirrev in wdirsubset and repo[None].phase() in phases:
if revsneedscopy:
wdirrevs = wdirrevs.copy()
# The working dir would never be in the # cache, but it was in
# the subset being filtered for its phase (or filtered out,
# depending on publicphase), so add it to the output to be
# included (or filtered out).
wdirrevs.add(wdirrev)
return wdirrevs
if not publicphase:
if repo.changelog.filteredrevs:
revs = revs - repo.changelog.filteredrevs
if subset is None:
return smartset.baseset(revs)
else:
revs = _addwdir(subset, revs)
return subset & smartset.baseset(revs)
else:
if subset is None:
subset = smartset.fullreposet(repo)
revs = _addwdir(subset, revs)
if not revs:
return subset
return subset.filter(lambda r: r not in revs)
def copy(self):
# Shallow copy meant to ensure isolation in
# advance/retractboundary(), nothing more.
ph = self.__class__(None, None, _load=False)
ph._phaseroots = self._phaseroots.copy()
ph.dirty = self.dirty
ph._loadedrevslen = self._loadedrevslen
if self._phasesets is None:
ph._phasesets = None
else:
ph._phasesets = self._phasesets.copy()
return ph
def replace(self, phcache):
"""replace all values in 'self' with content of phcache"""
for a in (
'_phaseroots',
'dirty',
'_loadedrevslen',
'_phasesets',
):
setattr(self, a, getattr(phcache, a))
def _getphaserevsnative(self, repo):
repo = repo.unfiltered()
return repo.changelog.computephases(self._phaseroots)
def _computephaserevspure(self, repo):
repo = repo.unfiltered()
cl = repo.changelog
self._phasesets = {phase: set() for phase in allphases}
lowerroots = set()
for phase in reversed(trackedphases):
roots = self._phaseroots[phase]
if roots:
ps = set(cl.descendants(roots))
for root in roots:
ps.add(root)
ps.difference_update(lowerroots)
lowerroots.update(ps)
self._phasesets[phase] = ps
self._loadedrevslen = len(cl)
def _ensure_phase_sets(self, repo: "localrepo.localrepository") -> None:
"""ensure phase information is loaded in the object"""
assert repo.filtername is None
update = -1
cl = repo.changelog
cl_size = len(cl)
if self._phasesets is None:
update = 0
else:
if cl_size > self._loadedrevslen:
# check if an incremental update is worth it.
# note we need a tradeoff here because the whole logic is not
# stored and implemented in native code nd datastructure.
# Otherwise the incremental update woul always be a win.
missing = cl_size - self._loadedrevslen
if missing <= INCREMENTAL_PHASE_SETS_UPDATE_MAX_UPDATE:
update = self._loadedrevslen
else:
update = 0
if update == 0:
try:
res = self._getphaserevsnative(repo)
self._loadedrevslen, self._phasesets = res
except AttributeError:
self._computephaserevspure(repo)
assert self._loadedrevslen == len(repo.changelog)
elif update > 0:
# good candidate for native code
assert update == self._loadedrevslen
if self.hasnonpublicphases(repo):
start = self._loadedrevslen
get_phase = self.phase
rev_phases = [0] * missing
parents = cl.parentrevs
sets = {phase: set() for phase in self._phasesets}
for phase, roots in self._phaseroots.items():
# XXX should really store the max somewhere
for r in roots:
if r >= start:
rev_phases[r - start] = phase
for rev in range(start, cl_size):
phase = rev_phases[rev - start]
p1, p2 = parents(rev)
if p1 == nullrev:
p1_phase = public
elif p1 >= start:
p1_phase = rev_phases[p1 - start]
else:
p1_phase = max(phase, get_phase(repo, p1))
if p2 == nullrev:
p2_phase = public
elif p2 >= start:
p2_phase = rev_phases[p2 - start]
else:
p2_phase = max(phase, get_phase(repo, p2))
phase = max(phase, p1_phase, p2_phase)
if phase > public:
rev_phases[rev - start] = phase
sets[phase].add(rev)
# Be careful to preserve shallow-copied values: do not update
# phaseroots values, replace them.
for phase, extra in sets.items():
if extra:
self._phasesets[phase] = self._phasesets[phase] | extra
self._loadedrevslen = cl_size
def invalidate(self):
self._loadedrevslen = 0
self._phasesets = None
def phase(self, repo: "localrepo.localrepository", rev: int) -> int:
# We need a repo argument here to be able to build _phasesets
# if necessary. The repository instance is not stored in
# phasecache to avoid reference cycles. The changelog instance
# is not stored because it is a filecache() property and can
# be replaced without us being notified.
if rev == nullrev:
return public
if rev < nullrev:
raise ValueError(_(b'cannot lookup negative revision'))
# double check self._loadedrevslen to avoid an extra method call as
# python is slow for that.
if rev >= self._loadedrevslen:
self._ensure_phase_sets(repo.unfiltered())
for phase in trackedphases:
if rev in self._phasesets[phase]:
return phase
return public
def write(self, repo):
if not self.dirty:
return
f = repo.svfs(b'phaseroots', b'w', atomictemp=True, checkambig=True)
try:
self._write(repo.unfiltered(), f)
finally:
f.close()
def _write(self, repo, fp):
assert repo.filtername is None
to_node = repo.changelog.node
for phase, roots in self._phaseroots.items():
for r in sorted(roots):
h = to_node(r)
fp.write(b'%i %s\n' % (phase, hex(h)))
self.dirty = False
def _updateroots(self, repo, phase, newroots, tr, invalidate=True):
self._phaseroots[phase] = newroots
self.dirty = True
if invalidate:
self.invalidate()
assert repo.filtername is None
wrepo = weakref.ref(repo)
def tr_write(fp):
repo = wrepo()
assert repo is not None
self._write(repo, fp)
tr.addfilegenerator(b'phase', (b'phaseroots',), tr_write)
tr.hookargs[b'phases_moved'] = b'1'
def registernew(self, repo, tr, targetphase, revs):
repo = repo.unfiltered()
self._retractboundary(repo, tr, targetphase, [], revs=revs)
if tr is not None and b'phases' in tr.changes:
phasetracking = tr.changes[b'phases']
phase = self.phase
for rev in sorted(revs):
revphase = phase(repo, rev)
_trackphasechange(phasetracking, rev, None, revphase)
repo.invalidatevolatilesets()
def advanceboundary(
self, repo, tr, targetphase, nodes=None, revs=None, dryrun=None
):
"""Set all 'nodes' to phase 'targetphase'
Nodes with a phase lower than 'targetphase' are not affected.
If dryrun is True, no actions will be performed
Returns a set of revs whose phase is changed or should be changed
"""
if targetphase == public and not self.hasnonpublicphases(repo):
return set()
repo = repo.unfiltered()
cl = repo.changelog
torev = cl.index.rev
# Be careful to preserve shallow-copied values: do not update
# phaseroots values, replace them.
new_revs = set()
if revs is not None:
new_revs.update(revs)
if nodes is not None:
new_revs.update(torev(node) for node in nodes)
if not new_revs: # bail out early to avoid the loadphaserevs call
return (
set()
) # note: why do people call advanceboundary with nothing?
if tr is None:
phasetracking = None
else:
phasetracking = tr.changes.get(b'phases')
affectable_phases = sorted(
p for p in allphases if p > targetphase and self._phaseroots[p]
)
# filter revision already in the right phases
candidates = new_revs
new_revs = set()
self._ensure_phase_sets(repo)
for phase in affectable_phases:
found = candidates & self._phasesets[phase]
new_revs |= found
candidates -= found
if not candidates:
break
if not new_revs:
return set()
# search for affected high phase changesets and roots
seen = set(new_revs)
push = heapq.heappush
pop = heapq.heappop
parents = cl.parentrevs
get_phase = self.phase
changed = {} # set of revisions to be changed
# set of root deleted by this path
delroots = set()
new_roots = {p: set() for p in affectable_phases}
new_target_roots = set()
# revision to walk down
revs = [-r for r in new_revs]
heapq.heapify(revs)
while revs:
current = -pop(revs)
current_phase = get_phase(repo, current)
changed[current] = current_phase
p1, p2 = parents(current)
if p1 == nullrev:
p1_phase = public
else:
p1_phase = get_phase(repo, p1)
if p2 == nullrev:
p2_phase = public
else:
p2_phase = get_phase(repo, p2)
# do we have a root ?
if current_phase != p1_phase and current_phase != p2_phase:
# do not record phase, because we could have "duplicated"
# roots, were one root is shadowed by the very same roots of an
# higher phases
delroots.add(current)
# schedule a walk down if needed
if p1_phase > targetphase and p1 not in seen:
seen.add(p1)
push(revs, -p1)
if p2_phase > targetphase and p2 not in seen:
seen.add(p2)
push(revs, -p2)
if p1_phase < targetphase and p2_phase < targetphase:
new_target_roots.add(current)
# the last iteration was done with the smallest value
min_current = current
# do we have unwalked children that might be new roots
if (min_current + len(changed)) < len(cl):
for r in range(min_current, len(cl)):
if r in changed:
continue
phase = get_phase(repo, r)
if phase <= targetphase:
continue
p1, p2 = parents(r)
if not (p1 in changed or p2 in changed):
continue # not affected
if p1 != nullrev and p1 not in changed:
p1_phase = get_phase(repo, p1)
if p1_phase == phase:
continue # not a root
if p2 != nullrev and p2 not in changed:
p2_phase = get_phase(repo, p2)
if p2_phase == phase:
continue # not a root
new_roots[phase].add(r)
# apply the changes
if not dryrun:
for r, p in changed.items():
_trackphasechange(phasetracking, r, p, targetphase)
if targetphase > public:
self._phasesets[targetphase].update(changed)
for phase in affectable_phases:
roots = self._phaseroots[phase]
removed = roots & delroots
if removed or new_roots[phase]:
self._phasesets[phase].difference_update(changed)
# Be careful to preserve shallow-copied values: do not
# update phaseroots values, replace them.
final_roots = roots - delroots | new_roots[phase]
self._updateroots(
repo, phase, final_roots, tr, invalidate=False
)
if new_target_roots:
# Thanks for previous filtering, we can't replace existing
# roots
new_target_roots |= self._phaseroots[targetphase]
self._updateroots(
repo, targetphase, new_target_roots, tr, invalidate=False
)
repo.invalidatevolatilesets()
return changed
def retractboundary(self, repo, tr, targetphase, nodes):
if tr is None:
phasetracking = None
else:
phasetracking = tr.changes.get(b'phases')
repo = repo.unfiltered()
retracted = self._retractboundary(repo, tr, targetphase, nodes)
if retracted and phasetracking is not None:
for r, old_phase in sorted(retracted.items()):
_trackphasechange(phasetracking, r, old_phase, targetphase)
repo.invalidatevolatilesets()
def _retractboundary(self, repo, tr, targetphase, nodes=None, revs=None):
if targetphase == public:
return {}
if (
targetphase == internal
and not supportinternal(repo)
or targetphase == archived
and not supportarchived(repo)
):
name = phasenames[targetphase]
msg = b'this repository does not support the %s phase' % name
raise error.ProgrammingError(msg)
assert repo.filtername is None
cl = repo.changelog
torev = cl.index.rev
new_revs = set()
if revs is not None:
new_revs.update(revs)
if nodes is not None:
new_revs.update(torev(node) for node in nodes)
if not new_revs: # bail out early to avoid the loadphaserevs call
return {} # note: why do people call retractboundary with nothing ?
if nullrev in new_revs:
raise error.Abort(_(b'cannot change null revision phase'))
# Filter revision that are already in the right phase
self._ensure_phase_sets(repo)
for phase, revs in self._phasesets.items():
if phase >= targetphase:
new_revs -= revs
if not new_revs: # all revisions already in the right phases
return {}
# Compute change in phase roots by walking the graph
#
# note: If we had a cheap parent → children mapping we could do
# something even cheaper/more-bounded
#
# The idea would be to walk from item in new_revs stopping at
# descendant with phases >= target_phase.
#
# 1) This detect new_revs that are not new_roots (either already >=
# target_phase or reachable though another new_revs
# 2) This detect replaced current_roots as we reach them
# 3) This can avoid walking to the tip if we retract over a small
# branch.
#
# So instead, we do a variation of this, we walk from the smaller new
# revision to the tip to avoid missing any potential children.
#
# The following code would be a good candidate for native code… if only
# we could knew the phase of a changeset efficiently in native code.
parents = cl.parentrevs
phase = self.phase
new_roots = set() # roots added by this phases
changed_revs = {} # revision affected by this call
replaced_roots = set() # older roots replaced by this call
currentroots = self._phaseroots[targetphase]
start = min(new_revs)
end = len(cl)
rev_phases = [None] * (end - start)
for r in range(start, end):
# gather information about the current_rev
r_phase = phase(repo, r)
p_phase = None # phase inherited from parents
p1, p2 = parents(r)
if p1 >= start:
p1_phase = rev_phases[p1 - start]
if p1_phase is not None:
p_phase = p1_phase
if p2 >= start:
p2_phase = rev_phases[p2 - start]
if p2_phase is not None:
if p_phase is not None:
p_phase = max(p_phase, p2_phase)
else:
p_phase = p2_phase
# assess the situation
if r in new_revs and r_phase < targetphase:
if p_phase is None or p_phase < targetphase:
new_roots.add(r)
rev_phases[r - start] = targetphase
changed_revs[r] = r_phase
elif p_phase is None:
rev_phases[r - start] = r_phase
else:
if p_phase > r_phase:
rev_phases[r - start] = p_phase
else:
rev_phases[r - start] = r_phase
if p_phase == targetphase:
if p_phase > r_phase:
changed_revs[r] = r_phase
elif r in currentroots:
replaced_roots.add(r)
sets = self._phasesets
sets[targetphase].update(changed_revs)
for r, old in changed_revs.items():
if old > public:
sets[old].discard(r)
if new_roots:
assert changed_revs
final_roots = new_roots | currentroots - replaced_roots
self._updateroots(
repo,
targetphase,
final_roots,
tr,
invalidate=False,
)
if targetphase > 1:
retracted = set(changed_revs)
for lower_phase in range(1, targetphase):
lower_roots = self._phaseroots.get(lower_phase)
if lower_roots is None:
continue
if lower_roots & retracted:
simpler_roots = lower_roots - retracted
self._updateroots(
repo,
lower_phase,
simpler_roots,
tr,
invalidate=False,
)
return changed_revs
else:
assert not changed_revs
assert not replaced_roots
return {}
def register_strip(
self,
repo,
tr,
strip_rev: int,
):
"""announce a strip to the phase cache
Any roots higher than the stripped revision should be dropped.
"""
for targetphase, roots in list(self._phaseroots.items()):
filtered = {r for r in roots if r >= strip_rev}
if filtered:
self._updateroots(repo, targetphase, roots - filtered, tr)
self.invalidate()
def advanceboundary(repo, tr, targetphase, nodes, revs=None, dryrun=None):
"""Add nodes to a phase changing other nodes phases if necessary.
This function move boundary *forward* this means that all nodes
are set in the target phase or kept in a *lower* phase.
Simplify boundary to contains phase roots only.
If dryrun is True, no actions will be performed
Returns a set of revs whose phase is changed or should be changed
"""
if revs is None:
revs = []
phcache = repo._phasecache.copy()
changes = phcache.advanceboundary(
repo, tr, targetphase, nodes, revs=revs, dryrun=dryrun
)
if not dryrun:
repo._phasecache.replace(phcache)
return changes
def retractboundary(repo, tr, targetphase, nodes):
"""Set nodes back to a phase changing other nodes phases if
necessary.
This function move boundary *backward* this means that all nodes
are set in the target phase or kept in a *higher* phase.
Simplify boundary to contains phase roots only."""
phcache = repo._phasecache.copy()
phcache.retractboundary(repo, tr, targetphase, nodes)
repo._phasecache.replace(phcache)
def registernew(repo, tr, targetphase, revs):
"""register a new revision and its phase
Code adding revisions to the repository should use this function to
set new changeset in their target phase (or higher).
"""
phcache = repo._phasecache.copy()
phcache.registernew(repo, tr, targetphase, revs)
repo._phasecache.replace(phcache)
def listphases(repo: "localrepo.localrepository") -> Dict[bytes, bytes]:
"""List phases root for serialization over pushkey"""
# Use ordered dictionary so behavior is deterministic.
keys = util.sortdict()
value = b'%i' % draft
cl = repo.unfiltered().changelog
to_node = cl.node
for root in repo._phasecache._phaseroots[draft]:
if repo._phasecache.phase(repo, root) <= draft:
keys[hex(to_node(root))] = value
if repo.publishing():
# Add an extra data to let remote know we are a publishing
# repo. Publishing repo can't just pretend they are old repo.
# When pushing to a publishing repo, the client still need to
# push phase boundary
#
# Push do not only push changeset. It also push phase data.
# New phase data may apply to common changeset which won't be
# push (as they are common). Here is a very simple example:
#
# 1) repo A push changeset X as draft to repo B
# 2) repo B make changeset X public
# 3) repo B push to repo A. X is not pushed but the data that
# X as now public should
#
# The server can't handle it on it's own as it has no idea of
# client phase data.
keys[b'publishing'] = b'True'
return keys
def pushphase(
repo: "localrepo.localrepository",
nhex: bytes,
oldphasestr: bytes,
newphasestr: bytes,
) -> bool:
"""List phases root for serialization over pushkey"""
repo = repo.unfiltered()
with repo.lock():
currentphase = repo[nhex].phase()
newphase = abs(int(newphasestr)) # let's avoid negative index surprise
oldphase = abs(int(oldphasestr)) # let's avoid negative index surprise
if currentphase == oldphase and newphase < oldphase:
with repo.transaction(b'pushkey-phase') as tr:
advanceboundary(repo, tr, newphase, [bin(nhex)])
return True
elif currentphase == newphase:
# raced, but got correct result
return True
else:
return False
def subsetphaseheads(repo, subset):
"""Finds the phase heads for a subset of a history
Returns a list indexed by phase number where each item is a list of phase
head nodes.
"""
cl = repo.changelog
headsbyphase = {i: [] for i in allphases}
for phase in allphases:
revset = b"heads(%%ln & _phase(%d))" % phase
headsbyphase[phase] = [cl.node(r) for r in repo.revs(revset, subset)]
return headsbyphase
def updatephases(repo, trgetter, headsbyphase):
"""Updates the repo with the given phase heads"""
# Now advance phase boundaries of all phases
#
# run the update (and fetch transaction) only if there are actually things
# to update. This avoid creating empty transaction during no-op operation.
for phase in allphases:
revset = b'%ln - _phase(%s)'
heads = [c.node() for c in repo.set(revset, headsbyphase[phase], phase)]
if heads:
advanceboundary(repo, trgetter(), phase, heads)
def analyzeremotephases(repo, subset, roots):
"""Compute phases heads and root in a subset of node from root dict
* subset is heads of the subset
* roots is {<nodeid> => phase} mapping. key and value are string.
Accept unknown element input
"""
repo = repo.unfiltered()
# build list from dictionary
draftroots = []
has_node = repo.changelog.index.has_node # to filter unknown nodes
for nhex, phase in roots.items():
if nhex == b'publishing': # ignore data related to publish option
continue
node = bin(nhex)
phase = int(phase)
if phase == public:
if node != repo.nullid:
repo.ui.warn(
_(
b'ignoring inconsistent public root'
b' from remote: %s\n'
)
% nhex
)
elif phase == draft:
if has_node(node):
draftroots.append(node)
else:
repo.ui.warn(
_(b'ignoring unexpected root from remote: %i %s\n')
% (phase, nhex)
)
# compute heads
publicheads = newheads(repo, subset, draftroots)
return publicheads, draftroots
class remotephasessummary:
"""summarize phase information on the remote side
:publishing: True is the remote is publishing
:publicheads: list of remote public phase heads (nodes)
:draftheads: list of remote draft phase heads (nodes)
:draftroots: list of remote draft phase root (nodes)
"""
def __init__(self, repo, remotesubset, remoteroots):
unfi = repo.unfiltered()
self._allremoteroots = remoteroots
self.publishing = remoteroots.get(b'publishing', False)
ana = analyzeremotephases(repo, remotesubset, remoteroots)
self.publicheads, self.draftroots = ana
# Get the list of all "heads" revs draft on remote
dheads = unfi.set(b'heads(%ln::%ln)', self.draftroots, remotesubset)
self.draftheads = [c.node() for c in dheads]
def newheads(repo, heads, roots):
"""compute new head of a subset minus another
* `heads`: define the first subset
* `roots`: define the second we subtract from the first"""
# prevent an import cycle
# phases > dagop > patch > copies > scmutil > obsolete > obsutil > phases
from . import dagop
repo = repo.unfiltered()
cl = repo.changelog
rev = cl.index.get_rev
if not roots:
return heads
if not heads or heads == [repo.nullid]:
return []
# The logic operated on revisions, convert arguments early for convenience
new_heads = {rev(n) for n in heads if n != repo.nullid}
roots = [rev(n) for n in roots]
# compute the area we need to remove
affected_zone = repo.revs(b"(%ld::%ld)", roots, new_heads)
# heads in the area are no longer heads
new_heads.difference_update(affected_zone)
# revisions in the area have children outside of it,
# They might be new heads
candidates = repo.revs(
b"parents(%ld + (%ld and merge())) and not null", roots, affected_zone
)
candidates -= affected_zone
if new_heads or candidates:
# remove candidate that are ancestors of other heads
new_heads.update(candidates)
prunestart = repo.revs(b"parents(%ld) and not null", new_heads)
pruned = dagop.reachableroots(repo, candidates, prunestart)
new_heads.difference_update(pruned)
return pycompat.maplist(cl.node, sorted(new_heads))
def newcommitphase(ui: "uimod.ui") -> int:
"""helper to get the target phase of new commit
Handle all possible values for the phases.new-commit options.
"""
v = ui.config(b'phases', b'new-commit')
try:
return phasenumber2[v]
except KeyError:
raise error.ConfigError(
_(b"phases.new-commit: not a valid phase name ('%s')") % v
)
def hassecret(repo: "localrepo.localrepository") -> bool:
"""utility function that check if a repo have any secret changeset."""
return bool(repo._phasecache._phaseroots[secret])
def preparehookargs(
node: bytes,
old: Optional[int],
new: Optional[int],
) -> Dict[bytes, bytes]:
if old is None:
old = b''
else:
old = phasenames[old]
return {b'node': node, b'oldphase': old, b'phase': phasenames[new]}