rebase: store rebase state after each commit
Before this patch, we stored the rebase state early in the processing
of a node, before we updated the rebase state to indicate that the
node was processed. This meant that we could redo the working copy
merge and run into conflicts. However, this only happened in the
--collapse case if the rebase was interrupted while editing the final
commit message; in the case earlier interruptions, we would instead
detect the in-process revision by finding two dirstate parents.
This patch moves the writing of the rebase state to after we have
completed the revision completely, and, importantly, after we have
updated the rebase state to mark it done. This means we'll realize
that all nodes have been rebased in the case mentioned above of
editing the final commit message of a --collapse. See change to test
case.
I also moved the writing outside of the large if/elif block in
_rebasenode(). This shouldn't matter much, but seems cleaner. One
observable effect is if rebase was interrupted just after ignoring an
obsolete node ("not rebasing ####, already in destination"), we used
to come up with the same decision after --continue too, but after this
patch we'll instead say "already rebased ###". This seems more
consistent, since that's what we would do with obsolete nodes that had
been marked done earlier in the process (not only just before the
interruption).
Differential Revision: https://phab.mercurial-scm.org/D2913
# lock.py - simple advisory locking scheme for mercurial
#
# Copyright 2005, 2006 Matt Mackall <mpm@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 absolute_import
import contextlib
import errno
import os
import signal
import socket
import time
import warnings
from .i18n import _
from . import (
encoding,
error,
pycompat,
util,
)
def _getlockprefix():
"""Return a string which is used to differentiate pid namespaces
It's useful to detect "dead" processes and remove stale locks with
confidence. Typically it's just hostname. On modern linux, we include an
extra Linux-specific pid namespace identifier.
"""
result = encoding.strtolocal(socket.gethostname())
if pycompat.sysplatform.startswith('linux'):
try:
result += '/%x' % os.stat('/proc/self/ns/pid').st_ino
except OSError as ex:
if ex.errno not in (errno.ENOENT, errno.EACCES, errno.ENOTDIR):
raise
return result
@contextlib.contextmanager
def _delayedinterrupt():
"""Block signal interrupt while doing something critical
This makes sure that the code block wrapped by this context manager won't
be interrupted.
For Windows developers: It appears not possible to guard time.sleep()
from CTRL_C_EVENT, so please don't use time.sleep() to test if this is
working.
"""
assertedsigs = []
blocked = False
orighandlers = {}
def raiseinterrupt(num):
if (num == getattr(signal, 'SIGINT', None) or
num == getattr(signal, 'CTRL_C_EVENT', None)):
raise KeyboardInterrupt
else:
raise error.SignalInterrupt
def catchterm(num, frame):
if blocked:
assertedsigs.append(num)
else:
raiseinterrupt(num)
try:
# save handlers first so they can be restored even if a setup is
# interrupted between signal.signal() and orighandlers[] =.
for name in ['CTRL_C_EVENT', 'SIGINT', 'SIGBREAK', 'SIGHUP', 'SIGTERM']:
num = getattr(signal, name, None)
if num and num not in orighandlers:
orighandlers[num] = signal.getsignal(num)
try:
for num in orighandlers:
signal.signal(num, catchterm)
except ValueError:
pass # in a thread? no luck
blocked = True
yield
finally:
# no simple way to reliably restore all signal handlers because
# any loops, recursive function calls, except blocks, etc. can be
# interrupted. so instead, make catchterm() raise interrupt.
blocked = False
try:
for num, handler in orighandlers.items():
signal.signal(num, handler)
except ValueError:
pass # in a thread?
# re-raise interrupt exception if any, which may be shadowed by a new
# interrupt occurred while re-raising the first one
if assertedsigs:
raiseinterrupt(assertedsigs[0])
def trylock(ui, vfs, lockname, timeout, warntimeout, *args, **kwargs):
"""return an acquired lock or raise an a LockHeld exception
This function is responsible to issue warnings and or debug messages about
the held lock while trying to acquires it."""
def printwarning(printer, locker):
"""issue the usual "waiting on lock" message through any channel"""
# show more details for new-style locks
if ':' in locker:
host, pid = locker.split(":", 1)
msg = (_("waiting for lock on %s held by process %r on host %r\n")
% (pycompat.bytestr(l.desc), pycompat.bytestr(pid),
pycompat.bytestr(host)))
else:
msg = (_("waiting for lock on %s held by %r\n")
% (l.desc, pycompat.bytestr(locker)))
printer(msg)
l = lock(vfs, lockname, 0, *args, dolock=False, **kwargs)
debugidx = 0 if (warntimeout and timeout) else -1
warningidx = 0
if not timeout:
warningidx = -1
elif warntimeout:
warningidx = warntimeout
delay = 0
while True:
try:
l._trylock()
break
except error.LockHeld as inst:
if delay == debugidx:
printwarning(ui.debug, inst.locker)
if delay == warningidx:
printwarning(ui.warn, inst.locker)
if timeout <= delay:
raise error.LockHeld(errno.ETIMEDOUT, inst.filename,
l.desc, inst.locker)
time.sleep(1)
delay += 1
l.delay = delay
if l.delay:
if 0 <= warningidx <= l.delay:
ui.warn(_("got lock after %d seconds\n") % l.delay)
else:
ui.debug("got lock after %d seconds\n" % l.delay)
if l.acquirefn:
l.acquirefn()
return l
class lock(object):
'''An advisory lock held by one process to control access to a set
of files. Non-cooperating processes or incorrectly written scripts
can ignore Mercurial's locking scheme and stomp all over the
repository, so don't do that.
Typically used via localrepository.lock() to lock the repository
store (.hg/store/) or localrepository.wlock() to lock everything
else under .hg/.'''
# lock is symlink on platforms that support it, file on others.
# symlink is used because create of directory entry and contents
# are atomic even over nfs.
# old-style lock: symlink to pid
# new-style lock: symlink to hostname:pid
_host = None
def __init__(self, vfs, file, timeout=-1, releasefn=None, acquirefn=None,
desc=None, inheritchecker=None, parentlock=None,
dolock=True):
self.vfs = vfs
self.f = file
self.held = 0
self.timeout = timeout
self.releasefn = releasefn
self.acquirefn = acquirefn
self.desc = desc
self._inheritchecker = inheritchecker
self.parentlock = parentlock
self._parentheld = False
self._inherited = False
self.postrelease = []
self.pid = self._getpid()
if dolock:
self.delay = self.lock()
if self.acquirefn:
self.acquirefn()
def __enter__(self):
return self
def __exit__(self, exc_type, exc_value, exc_tb):
self.release()
def __del__(self):
if self.held:
warnings.warn("use lock.release instead of del lock",
category=DeprecationWarning,
stacklevel=2)
# ensure the lock will be removed
# even if recursive locking did occur
self.held = 1
self.release()
def _getpid(self):
# wrapper around util.getpid() to make testing easier
return util.getpid()
def lock(self):
timeout = self.timeout
while True:
try:
self._trylock()
return self.timeout - timeout
except error.LockHeld as inst:
if timeout != 0:
time.sleep(1)
if timeout > 0:
timeout -= 1
continue
raise error.LockHeld(errno.ETIMEDOUT, inst.filename, self.desc,
inst.locker)
def _trylock(self):
if self.held:
self.held += 1
return
if lock._host is None:
lock._host = _getlockprefix()
lockname = '%s:%d' % (lock._host, self.pid)
retry = 5
while not self.held and retry:
retry -= 1
try:
with _delayedinterrupt():
self.vfs.makelock(lockname, self.f)
self.held = 1
except (OSError, IOError) as why:
if why.errno == errno.EEXIST:
locker = self._readlock()
if locker is None:
continue
# special case where a parent process holds the lock -- this
# is different from the pid being different because we do
# want the unlock and postrelease functions to be called,
# but the lockfile to not be removed.
if locker == self.parentlock:
self._parentheld = True
self.held = 1
return
locker = self._testlock(locker)
if locker is not None:
raise error.LockHeld(errno.EAGAIN,
self.vfs.join(self.f), self.desc,
locker)
else:
raise error.LockUnavailable(why.errno, why.strerror,
why.filename, self.desc)
if not self.held:
# use empty locker to mean "busy for frequent lock/unlock
# by many processes"
raise error.LockHeld(errno.EAGAIN,
self.vfs.join(self.f), self.desc, "")
def _readlock(self):
"""read lock and return its value
Returns None if no lock exists, pid for old-style locks, and host:pid
for new-style locks.
"""
try:
return self.vfs.readlock(self.f)
except (OSError, IOError) as why:
if why.errno == errno.ENOENT:
return None
raise
def _testlock(self, locker):
if locker is None:
return None
try:
host, pid = locker.split(":", 1)
except ValueError:
return locker
if host != lock._host:
return locker
try:
pid = int(pid)
except ValueError:
return locker
if util.testpid(pid):
return locker
# if locker dead, break lock. must do this with another lock
# held, or can race and break valid lock.
try:
l = lock(self.vfs, self.f + '.break', timeout=0)
self.vfs.unlink(self.f)
l.release()
except error.LockError:
return locker
def testlock(self):
"""return id of locker if lock is valid, else None.
If old-style lock, we cannot tell what machine locker is on.
with new-style lock, if locker is on this machine, we can
see if locker is alive. If locker is on this machine but
not alive, we can safely break lock.
The lock file is only deleted when None is returned.
"""
locker = self._readlock()
return self._testlock(locker)
@contextlib.contextmanager
def inherit(self):
"""context for the lock to be inherited by a Mercurial subprocess.
Yields a string that will be recognized by the lock in the subprocess.
Communicating this string to the subprocess needs to be done separately
-- typically by an environment variable.
"""
if not self.held:
raise error.LockInheritanceContractViolation(
'inherit can only be called while lock is held')
if self._inherited:
raise error.LockInheritanceContractViolation(
'inherit cannot be called while lock is already inherited')
if self._inheritchecker is not None:
self._inheritchecker()
if self.releasefn:
self.releasefn()
if self._parentheld:
lockname = self.parentlock
else:
lockname = '%s:%s' % (lock._host, self.pid)
self._inherited = True
try:
yield lockname
finally:
if self.acquirefn:
self.acquirefn()
self._inherited = False
def release(self):
"""release the lock and execute callback function if any
If the lock has been acquired multiple times, the actual release is
delayed to the last release call."""
if self.held > 1:
self.held -= 1
elif self.held == 1:
self.held = 0
if self._getpid() != self.pid:
# we forked, and are not the parent
return
try:
if self.releasefn:
self.releasefn()
finally:
if not self._parentheld:
try:
self.vfs.unlink(self.f)
except OSError:
pass
# The postrelease functions typically assume the lock is not held
# at all.
if not self._parentheld:
for callback in self.postrelease:
callback()
# Prevent double usage and help clear cycles.
self.postrelease = None
def release(*locks):
for lock in locks:
if lock is not None:
lock.release()