upstream/mercurial-mirror Files · mercurial/setdiscovery.py

wireprotov2: add phases to "changesetdata" command...

wireprotov2: add phases to "changesetdata" command This commit teaches the "changesetdata" wire protocol command to emit the phase state for each changeset. This is a different approach from existing phase transfer in a few ways. Previously, if there are no new revisions (or we're not using bundle2), we perform a "listkeys" request to retrieve phase heads. And when revision data is being transferred with bundle2, phases data is encoded in a standalone bundle2 part. In both cases, phases data is logically decoupled from the changeset data and is encountered/applied after changeset revision data is received. The new wire protocol purposefully tries to more tightly associate changeset metadata (phases, bookmarks, obsolescence markers, etc) with the changeset revision and index data itself, rather than have it live as a separate entity that must be fetched and processed separately. I reckon that one reason we didn't do this before was it was difficult to add new data types/fields without breaking existing consumers. By using CBOR maps to transfer changeset data and putting clients in control of what fields are requested / present in those maps, we can easily add additional changeset data while maintaining backwards compatibility. I believe this to be a superior approach to the problem. That being said, for performance reasons, we may need to resort to alternative mechanisms for transferring data like phases. But for now, I think giving the wire protocol the ability to transfer changeset metadata next to the changeset itself is a powerful feature because it is a raw, changeset-centric data API. And if you build simple APIs for accessing the fundamental units of repository data, you enable client-side experimentation (partial clone, etc). If it turns out that we need specialized APIs or mechanisms for transferring data like phases, we can build in those APIs later. For now, I'd like to see how far we can get on simple APIs. It's worth noting that when phase data is being requested, the server will also emit changeset records for nodes in the bases specified by the "noderange" argument. This is to ensure that phase-only updates for nodes the client has are available to the client, even if no new changesets will be transferred. Differential Revision: https://phab.mercurial-scm.org/D4483

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      # setdiscovery.py - improved discovery of common nodeset for mercurial

      #

      # Copyright 2010 Benoit Boissinot <bboissin@gmail.com>

      # and Peter Arrenbrecht <peter@arrenbrecht.ch>

      #

      # This software may be used and distributed according to the terms of the

      # GNU General Public License version 2 or any later version.

      """

      Algorithm works in the following way. You have two repository: local and

      remote. They both contains a DAG of changelists.

      The goal of the discovery protocol is to find one set of node *common*,

      the set of nodes shared by local and remote.

      One of the issue with the original protocol was latency, it could

      potentially require lots of roundtrips to discover that the local repo was a

      subset of remote (which is a very common case, you usually have few changes

      compared to upstream, while upstream probably had lots of development).

      The new protocol only requires one interface for the remote repo: `known()`,

      which given a set of changelists tells you if they are present in the DAG.

      The algorithm then works as follow:

       - We will be using three sets, `common`, `missing`, `unknown`. Originally

       all nodes are in `unknown`.

       - Take a sample from `unknown`, call `remote.known(sample)`

         - For each node that remote knows, move it and all its ancestors to `common`

         - For each node that remote doesn't know, move it and all its descendants

         to `missing`

       - Iterate until `unknown` is empty

      There are a couple optimizations, first is instead of starting with a random

      sample of missing, start by sending all heads, in the case where the local

      repo is a subset, you computed the answer in one round trip.

      Then you can do something similar to the bisecting strategy used when

      finding faulty changesets. Instead of random samples, you can try picking

      nodes that will maximize the number of nodes that will be

      classified with it (since all ancestors or descendants will be marked as well).

      """

      from __future__ import absolute_import

      import collections

      import random

      from .i18n import _

      from .node import (

          nullid,

          nullrev,

      )

      from . import (

          error,

          util,

      )

      def _updatesample(revs, heads, sample, parentfn, quicksamplesize=0):

          """update an existing sample to match the expected size

          The sample is updated with revs exponentially distant from each head of the

          <revs> set. (H~1, H~2, H~4, H~8, etc).

          If a target size is specified, the sampling will stop once this size is

          reached. Otherwise sampling will happen until roots of the <revs> set are

          reached.

          :revs:  set of revs we want to discover (if None, assume the whole dag)

          :heads: set of DAG head revs

          :sample: a sample to update

          :parentfn: a callable to resolve parents for a revision

          :quicksamplesize: optional target size of the sample"""

          dist = {}

          visit = collections.deque(heads)

          seen = set()

          factor = 1

          while visit:

              curr = visit.popleft()

              if curr in seen:

                  continue

              d = dist.setdefault(curr, 1)

              if d > factor:

                  factor *= 2

              if d == factor:

                  sample.add(curr)

                  if quicksamplesize and (len(sample) >= quicksamplesize):

                      return

              seen.add(curr)

              for p in parentfn(curr):

                  if p != nullrev and (not revs or p in revs):

                      dist.setdefault(p, d + 1)

                      visit.append(p)

      def _takequicksample(repo, headrevs, revs, size):

          """takes a quick sample of size <size>

          It is meant for initial sampling and focuses on querying heads and close

          ancestors of heads.

          :dag: a dag object

          :headrevs: set of head revisions in local DAG to consider

          :revs: set of revs to discover

          :size: the maximum size of the sample"""

          sample = set(repo.revs('heads(%ld)', revs))

          if len(sample) >= size:

              return _limitsample(sample, size)

          _updatesample(None, headrevs, sample, repo.changelog.parentrevs,

                        quicksamplesize=size)

          return sample

      def _takefullsample(repo, headrevs, revs, size):

          sample = set(repo.revs('heads(%ld)', revs))

          # update from heads

          revsheads = set(repo.revs('heads(%ld)', revs))

          _updatesample(revs, revsheads, sample, repo.changelog.parentrevs)

          # update from roots

          revsroots = set(repo.revs('roots(%ld)', revs))

          # _updatesample() essentially does interaction over revisions to look up

          # their children. This lookup is expensive and doing it in a loop is

          # quadratic. We precompute the children for all relevant revisions and

          # make the lookup in _updatesample() a simple dict lookup.

          #

          # Because this function can be called multiple times during discovery, we

          # may still perform redundant work and there is room to optimize this by

          # keeping a persistent cache of children across invocations.

          children = {}

          parentrevs = repo.changelog.parentrevs

          for rev in repo.changelog.revs(start=min(revsroots)):

              # Always ensure revision has an entry so we don't need to worry about

              # missing keys.

              children.setdefault(rev, [])

              for prev in parentrevs(rev):

                  if prev == nullrev:

                      continue

                  children.setdefault(prev, []).append(rev)

          _updatesample(revs, revsroots, sample, children.__getitem__)

          assert sample

          sample = _limitsample(sample, size)

          if len(sample) < size:

              more = size - len(sample)

              sample.update(random.sample(list(revs - sample), more))

          return sample

      def _limitsample(sample, desiredlen):

          """return a random subset of sample of at most desiredlen item"""

          if len(sample) > desiredlen:

              sample = set(random.sample(sample, desiredlen))

          return sample

      def findcommonheads(ui, local, remote,

                          initialsamplesize=100,

                          fullsamplesize=200,

                          abortwhenunrelated=True,

                          ancestorsof=None):

          '''Return a tuple (common, anyincoming, remoteheads) used to identify

          missing nodes from or in remote.

          '''

          start = util.timer()

          roundtrips = 0

          cl = local.changelog

          clnode = cl.node

          clrev = cl.rev

          if ancestorsof is not None:

              ownheads = [clrev(n) for n in ancestorsof]

          else:

              ownheads = [rev for rev in cl.headrevs() if rev != nullrev]

          # early exit if we know all the specified remote heads already

          ui.debug("query 1; heads\n")

          roundtrips += 1

          sample = _limitsample(ownheads, initialsamplesize)

          # indices between sample and externalized version must match

          sample = list(sample)

          with remote.commandexecutor() as e:

              fheads = e.callcommand('heads', {})

              fknown = e.callcommand('known', {

                  'nodes': [clnode(r) for r in sample],

              })

          srvheadhashes, yesno = fheads.result(), fknown.result()

          if cl.tip() == nullid:

              if srvheadhashes != [nullid]:

                  return [nullid], True, srvheadhashes

              return [nullid], False, []

          # start actual discovery (we note this before the next "if" for

          # compatibility reasons)

          ui.status(_("searching for changes\n"))

          srvheads = []

          for node in srvheadhashes:

              if node == nullid:

                  continue

              try:

                  srvheads.append(clrev(node))

              # Catches unknown and filtered nodes.

              except error.LookupError:

                  continue

          if len(srvheads) == len(srvheadhashes):

              ui.debug("all remote heads known locally\n")

              return srvheadhashes, False, srvheadhashes

          if len(sample) == len(ownheads) and all(yesno):

              ui.note(_("all local heads known remotely\n"))

              ownheadhashes = [clnode(r) for r in ownheads]

              return ownheadhashes, True, srvheadhashes

          # full blown discovery

          # own nodes I know we both know

          # treat remote heads (and maybe own heads) as a first implicit sample

          # response

          common = cl.incrementalmissingrevs(srvheads)

          commoninsample = set(n for i, n in enumerate(sample) if yesno[i])

          common.addbases(commoninsample)

          # own nodes where I don't know if remote knows them

          undecided = set(common.missingancestors(ownheads))

          # own nodes I know remote lacks

          missing = set()

          full = False

          progress = ui.makeprogress(_('searching'), unit=_('queries'))

          while undecided:

              if sample:

                  missinginsample = [n for i, n in enumerate(sample) if not yesno[i]]

                  if missing:

                      missing.update(local.revs('descendants(%ld) - descendants(%ld)',

                                                missinginsample, missing))

                  else:

                      missing.update(local.revs('descendants(%ld)', missinginsample))

                  undecided.difference_update(missing)

              if not undecided:

                  break

              if full or common.hasbases():

                  if full:

                      ui.note(_("sampling from both directions\n"))

                  else:

                      ui.debug("taking initial sample\n")

                  samplefunc = _takefullsample

                  targetsize = fullsamplesize

              else:

                  # use even cheaper initial sample

                  ui.debug("taking quick initial sample\n")

                  samplefunc = _takequicksample

                  targetsize = initialsamplesize

              if len(undecided) < targetsize:

                  sample = list(undecided)

              else:

                  sample = samplefunc(local, ownheads, undecided, targetsize)

              roundtrips += 1

              progress.update(roundtrips)

              ui.debug("query %i; still undecided: %i, sample size is: %i\n"

                       % (roundtrips, len(undecided), len(sample)))

              # indices between sample and externalized version must match

              sample = list(sample)

              with remote.commandexecutor() as e:

                  yesno = e.callcommand('known', {

                      'nodes': [clnode(r) for r in sample],

                  }).result()

              full = True

              if sample:

                  commoninsample = set(n for i, n in enumerate(sample) if yesno[i])

                  common.addbases(commoninsample)

                  common.removeancestorsfrom(undecided)

          # heads(common) == heads(common.bases) since common represents common.bases

          # and all its ancestors

          # The presence of nullrev will confuse heads(). So filter it out.

          result = set(local.revs('heads(%ld)', common.bases - {nullrev}))

          elapsed = util.timer() - start

          progress.complete()

          ui.debug("%d total queries in %.4fs\n" % (roundtrips, elapsed))

          msg = ('found %d common and %d unknown server heads,'

                 ' %d roundtrips in %.4fs\n')

          missing = set(result) - set(srvheads)

          ui.log('discovery', msg, len(result), len(missing), roundtrips,

                 elapsed)

          if not result and srvheadhashes != [nullid]:

              if abortwhenunrelated:

                  raise error.Abort(_("repository is unrelated"))

              else:

                  ui.warn(_("warning: repository is unrelated\n"))

              return ({nullid}, True, srvheadhashes,)

          anyincoming = (srvheadhashes != [nullid])

          result = {clnode(r) for r in result}

          return result, anyincoming, srvheadhashes

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				# setdiscovery.py - improved discovery of common nodeset for mercurial
				#
				# Copyright 2010 Benoit Boissinot <bboissin@gmail.com>
				# and Peter Arrenbrecht <peter@arrenbrecht.ch>
				#
				# This software may be used and distributed according to the terms of the
				# GNU General Public License version 2 or any later version.
				"""
				Algorithm works in the following way. You have two repository: local and
				remote. They both contains a DAG of changelists.

				The goal of the discovery protocol is to find one set of node common,
				the set of nodes shared by local and remote.

				One of the issue with the original protocol was latency, it could
				potentially require lots of roundtrips to discover that the local repo was a
				subset of remote (which is a very common case, you usually have few changes
				compared to upstream, while upstream probably had lots of development).

				The new protocol only requires one interface for the remote repo: `known()`,
				which given a set of changelists tells you if they are present in the DAG.

				The algorithm then works as follow:

				- We will be using three sets, `common`, `missing`, `unknown`. Originally
				all nodes are in `unknown`.
				- Take a sample from `unknown`, call `remote.known(sample)`
				- For each node that remote knows, move it and all its ancestors to `common`
				- For each node that remote doesn't know, move it and all its descendants
				to `missing`
				- Iterate until `unknown` is empty

				There are a couple optimizations, first is instead of starting with a random
				sample of missing, start by sending all heads, in the case where the local
				repo is a subset, you computed the answer in one round trip.

				Then you can do something similar to the bisecting strategy used when
				finding faulty changesets. Instead of random samples, you can try picking
				nodes that will maximize the number of nodes that will be
				classified with it (since all ancestors or descendants will be marked as well).
				"""

				from __future__ import absolute_import

				import collections
				import random

				from .i18n import _
				from .node import (
				nullid,
				nullrev,
				)
				from . import (
				error,
				util,
				)

				def _updatesample(revs, heads, sample, parentfn, quicksamplesize=0):
				"""update an existing sample to match the expected size

				The sample is updated with revs exponentially distant from each head of the
				<revs> set. (H~1, H~2, H~4, H~8, etc).

				If a target size is specified, the sampling will stop once this size is
				reached. Otherwise sampling will happen until roots of the <revs> set are
				reached.

				:revs: set of revs we want to discover (if None, assume the whole dag)
				:heads: set of DAG head revs
				:sample: a sample to update
				:parentfn: a callable to resolve parents for a revision
				:quicksamplesize: optional target size of the sample"""
				dist = {}
				visit = collections.deque(heads)
				seen = set()
				factor = 1
				while visit:
				curr = visit.popleft()
				if curr in seen:
				continue
				d = dist.setdefault(curr, 1)
				if d > factor:
				factor *= 2
				if d == factor:
				sample.add(curr)
				if quicksamplesize and (len(sample) >= quicksamplesize):
				return
				seen.add(curr)

				for p in parentfn(curr):
				if p != nullrev and (not revs or p in revs):
				dist.setdefault(p, d + 1)
				visit.append(p)

				def _takequicksample(repo, headrevs, revs, size):
				"""takes a quick sample of size <size>

				It is meant for initial sampling and focuses on querying heads and close
				ancestors of heads.

				:dag: a dag object
				:headrevs: set of head revisions in local DAG to consider
				:revs: set of revs to discover
				:size: the maximum size of the sample"""
				sample = set(repo.revs('heads(%ld)', revs))

				if len(sample) >= size:
				return _limitsample(sample, size)

				_updatesample(None, headrevs, sample, repo.changelog.parentrevs,
				quicksamplesize=size)
				return sample

				def _takefullsample(repo, headrevs, revs, size):
				sample = set(repo.revs('heads(%ld)', revs))

				# update from heads
				revsheads = set(repo.revs('heads(%ld)', revs))
				_updatesample(revs, revsheads, sample, repo.changelog.parentrevs)

				# update from roots
				revsroots = set(repo.revs('roots(%ld)', revs))

				# _updatesample() essentially does interaction over revisions to look up
				# their children. This lookup is expensive and doing it in a loop is
				# quadratic. We precompute the children for all relevant revisions and
				# make the lookup in _updatesample() a simple dict lookup.
				#
				# Because this function can be called multiple times during discovery, we
				# may still perform redundant work and there is room to optimize this by
				# keeping a persistent cache of children across invocations.
				children = {}

				parentrevs = repo.changelog.parentrevs
				for rev in repo.changelog.revs(start=min(revsroots)):
				# Always ensure revision has an entry so we don't need to worry about
				# missing keys.
				children.setdefault(rev, [])

				for prev in parentrevs(rev):
				if prev == nullrev:
				continue

				children.setdefault(prev, []).append(rev)

				_updatesample(revs, revsroots, sample, children.__getitem__)
				assert sample
				sample = _limitsample(sample, size)
				if len(sample) < size:
				more = size - len(sample)
				sample.update(random.sample(list(revs - sample), more))
				return sample

				def _limitsample(sample, desiredlen):
				"""return a random subset of sample of at most desiredlen item"""
				if len(sample) > desiredlen:
				sample = set(random.sample(sample, desiredlen))
				return sample

				def findcommonheads(ui, local, remote,
				initialsamplesize=100,
				fullsamplesize=200,
				abortwhenunrelated=True,
				ancestorsof=None):
				'''Return a tuple (common, anyincoming, remoteheads) used to identify
				missing nodes from or in remote.
				'''
				start = util.timer()

				roundtrips = 0
				cl = local.changelog
				clnode = cl.node
				clrev = cl.rev

				if ancestorsof is not None:
				ownheads = [clrev(n) for n in ancestorsof]
				else:
				ownheads = [rev for rev in cl.headrevs() if rev != nullrev]

				# early exit if we know all the specified remote heads already
				ui.debug("query 1; heads\n")
				roundtrips += 1
				sample = _limitsample(ownheads, initialsamplesize)
				# indices between sample and externalized version must match
				sample = list(sample)

				with remote.commandexecutor() as e:
				fheads = e.callcommand('heads', {})
				fknown = e.callcommand('known', {
				'nodes': [clnode(r) for r in sample],
				})

				srvheadhashes, yesno = fheads.result(), fknown.result()

				if cl.tip() == nullid:
				if srvheadhashes != [nullid]:
				return [nullid], True, srvheadhashes
				return [nullid], False, []

				# start actual discovery (we note this before the next "if" for
				# compatibility reasons)
				ui.status(_("searching for changes\n"))

				srvheads = []
				for node in srvheadhashes:
				if node == nullid:
				continue

				try:
				srvheads.append(clrev(node))
				# Catches unknown and filtered nodes.
				except error.LookupError:
				continue

				if len(srvheads) == len(srvheadhashes):
				ui.debug("all remote heads known locally\n")
				return srvheadhashes, False, srvheadhashes

				if len(sample) == len(ownheads) and all(yesno):
				ui.note(_("all local heads known remotely\n"))
				ownheadhashes = [clnode(r) for r in ownheads]
				return ownheadhashes, True, srvheadhashes

				# full blown discovery

				# own nodes I know we both know
				# treat remote heads (and maybe own heads) as a first implicit sample
				# response
				common = cl.incrementalmissingrevs(srvheads)
				commoninsample = set(n for i, n in enumerate(sample) if yesno[i])
				common.addbases(commoninsample)
				# own nodes where I don't know if remote knows them
				undecided = set(common.missingancestors(ownheads))
				# own nodes I know remote lacks
				missing = set()

				full = False
				progress = ui.makeprogress(_('searching'), unit=_('queries'))
				while undecided:

				if sample:
				missinginsample = [n for i, n in enumerate(sample) if not yesno[i]]

				if missing:
				missing.update(local.revs('descendants(%ld) - descendants(%ld)',
				missinginsample, missing))
				else:
				missing.update(local.revs('descendants(%ld)', missinginsample))

				undecided.difference_update(missing)

				if not undecided:
				break

				if full or common.hasbases():
				if full:
				ui.note(_("sampling from both directions\n"))
				else:
				ui.debug("taking initial sample\n")
				samplefunc = _takefullsample
				targetsize = fullsamplesize
				else:
				# use even cheaper initial sample
				ui.debug("taking quick initial sample\n")
				samplefunc = _takequicksample
				targetsize = initialsamplesize
				if len(undecided) < targetsize:
				sample = list(undecided)
				else:
				sample = samplefunc(local, ownheads, undecided, targetsize)

				roundtrips += 1
				progress.update(roundtrips)
				ui.debug("query %i; still undecided: %i, sample size is: %i\n"
				% (roundtrips, len(undecided), len(sample)))
				# indices between sample and externalized version must match
				sample = list(sample)

				with remote.commandexecutor() as e:
				yesno = e.callcommand('known', {
				'nodes': [clnode(r) for r in sample],
				}).result()

				full = True

				if sample:
				commoninsample = set(n for i, n in enumerate(sample) if yesno[i])
				common.addbases(commoninsample)
				common.removeancestorsfrom(undecided)

				# heads(common) == heads(common.bases) since common represents common.bases
				# and all its ancestors
				# The presence of nullrev will confuse heads(). So filter it out.
				result = set(local.revs('heads(%ld)', common.bases - {nullrev}))
				elapsed = util.timer() - start
				progress.complete()
				ui.debug("%d total queries in %.4fs\n" % (roundtrips, elapsed))
				msg = ('found %d common and %d unknown server heads,'
				' %d roundtrips in %.4fs\n')
				missing = set(result) - set(srvheads)
				ui.log('discovery', msg, len(result), len(missing), roundtrips,
				elapsed)

				if not result and srvheadhashes != [nullid]:
				if abortwhenunrelated:
				raise error.Abort(_("repository is unrelated"))
				else:
				ui.warn(_("warning: repository is unrelated\n"))
				return ({nullid}, True, srvheadhashes,)

				anyincoming = (srvheadhashes != [nullid])
				result = {clnode(r) for r in result}
				return result, anyincoming, srvheadhashes