upstream/mercurial-mirror Files · mercurial/wireprotov2peer.py

wireprotov2peer: stream decoded responses...

wireprotov2peer: stream decoded responses Previously, wire protocol version 2 would buffer all response data. Only once all data was received did we CBOR decode it and resolve the future associated with the command. This was obviously not desirable. In future commits that introduce large response payloads, this caused significant memory bloat and slowed down client operations due to waiting on the server. This commit refactors the response handling code so that response data can be streamed. Command response objects now contain a buffered CBOR decoder. As new data arrives, it is fed into the decoder. Decoded objects are made available to the generator as they are decoded. Because there is a separate thread processing incoming frames and feeding data into the response object, there is the potential for race conditions when mutating response objects. So a lock has been added to guard access to critical state variables. Because the generator emitting decoded objects needs to wait on those objects to become available, we've added an Event for the generator to wait on so it doesn't busy loop. This does mean there is the potential for deadlocks. And I'm pretty sure they can occur in some scenarios. We already have a handful of TODOs around this. But I've added some more. Fixing this will likely require moving the background thread receiving frames into clienthandler. We likely would have done this anyway when implementing the client bits for the SSH transport. Test output changes because the initial CBOR map holding the overall response state is now always handled internally by the response object. Differential Revision: https://phab.mercurial-scm.org/D4474

Gregory Szorc - - Load All Authors

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      # wireprotov2peer.py - client side code for wire protocol version 2

      #

      # Copyright 2018 Gregory Szorc <gregory.szorc@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.

      from __future__ import absolute_import

      import threading

      from .i18n import _

      from . import (

          encoding,

          error,

          wireprotoframing,

      )

      from .utils import (

          cborutil,

      )

      def formatrichmessage(atoms):

          """Format an encoded message from the framing protocol."""

          chunks = []

          for atom in atoms:

              msg = _(atom[b'msg'])

              if b'args' in atom:

                  msg = msg % tuple(atom[b'args'])

              chunks.append(msg)

          return b''.join(chunks)

      class commandresponse(object):

          """Represents the response to a command request.

          Instances track the state of the command and hold its results.

          An external entity is required to update the state of the object when

          events occur.

          """

          def __init__(self, requestid, command):

              self.requestid = requestid

              self.command = command

              # Whether all remote input related to this command has been

              # received.

              self._inputcomplete = False

              # We have a lock that is acquired when important object state is

              # mutated. This is to prevent race conditions between 1 thread

              # sending us new data and another consuming it.

              self._lock = threading.RLock()

              # An event is set when state of the object changes. This event

              # is waited on by the generator emitting objects.

              self._serviceable = threading.Event()

              self._pendingevents = []

              self._decoder = cborutil.bufferingdecoder()

              self._seeninitial = False

          def _oninputcomplete(self):

              with self._lock:

                  self._inputcomplete = True

                  self._serviceable.set()

          def _onresponsedata(self, data):

              available, readcount, wanted = self._decoder.decode(data)

              if not available:

                  return

              with self._lock:

                  for o in self._decoder.getavailable():

                      if not self._seeninitial:

                          self._handleinitial(o)

                          continue

                      self._pendingevents.append(o)

                  self._serviceable.set()

          def _handleinitial(self, o):

              self._seeninitial = True

              if o[b'status'] == 'ok':

                  return

              atoms = [{'msg': o[b'error'][b'message']}]

              if b'args' in o[b'error']:

                  atoms[0]['args'] = o[b'error'][b'args']

              raise error.RepoError(formatrichmessage(atoms))

          def objects(self):

              """Obtained decoded objects from this response.

              This is a generator of data structures that were decoded from the

              command response.

              Obtaining the next member of the generator may block due to waiting

              on external data to become available.

              If the server encountered an error in the middle of serving the data

              or if another error occurred, an exception may be raised when

              advancing the generator.

              """

              while True:

                  # TODO this can infinite loop if self._inputcomplete is never

                  # set. We likely want to tie the lifetime of this object/state

                  # to that of the background thread receiving frames and updating

                  # our state.

                  self._serviceable.wait(1.0)

                  with self._lock:

                      self._serviceable.clear()

                      # Make copies because objects could be mutated during

                      # iteration.

                      stop = self._inputcomplete

                      pending = list(self._pendingevents)

                      self._pendingevents[:] = []

                  for o in pending:

                      yield o

                  if stop:

                      break

      class clienthandler(object):

          """Object to handle higher-level client activities.

          The ``clientreactor`` is used to hold low-level state about the frame-based

          protocol, such as which requests and streams are active. This type is used

          for higher-level operations, such as reading frames from a socket, exposing

          and managing a higher-level primitive for representing command responses,

          etc. This class is what peers should probably use to bridge wire activity

          with the higher-level peer API.

          """

          def __init__(self, ui, clientreactor):

              self._ui = ui

              self._reactor = clientreactor

              self._requests = {}

              self._futures = {}

              self._responses = {}

          def callcommand(self, command, args, f):

              """Register a request to call a command.

              Returns an iterable of frames that should be sent over the wire.

              """

              request, action, meta = self._reactor.callcommand(command, args)

              if action != 'noop':

                  raise error.ProgrammingError('%s not yet supported' % action)

              rid = request.requestid

              self._requests[rid] = request

              self._futures[rid] = f

              # TODO we need some kind of lifetime on response instances otherwise

              # objects() may deadlock.

              self._responses[rid] = commandresponse(rid, command)

              return iter(())

          def flushcommands(self):

              """Flush all queued commands.

              Returns an iterable of frames that should be sent over the wire.

              """

              action, meta = self._reactor.flushcommands()

              if action != 'sendframes':

                  raise error.ProgrammingError('%s not yet supported' % action)

              return meta['framegen']

          def readframe(self, fh):

              """Attempt to read and process a frame.

              Returns None if no frame was read. Presumably this means EOF.

              """

              frame = wireprotoframing.readframe(fh)

              if frame is None:

                  # TODO tell reactor?

                  return

              self._ui.note(_('received %r\n') % frame)

              self._processframe(frame)

              return True

          def _processframe(self, frame):

              """Process a single read frame."""

              action, meta = self._reactor.onframerecv(frame)

              if action == 'error':

                  e = error.RepoError(meta['message'])

                  if frame.requestid in self._responses:

                      self._responses[frame.requestid]._oninputcomplete()

                  if frame.requestid in self._futures:

                      self._futures[frame.requestid].set_exception(e)

                      del self._futures[frame.requestid]

                  else:

                      raise e

                  return

              if frame.requestid not in self._requests:

                  raise error.ProgrammingError(

                      'received frame for unknown request; this is either a bug in '

                      'the clientreactor not screening for this or this instance was '

                      'never told about this request: %r' % frame)

              response = self._responses[frame.requestid]

              if action == 'responsedata':

                  # Any failures processing this frame should bubble up to the

                  # future tracking the request.

                  try:

                      self._processresponsedata(frame, meta, response)

                  except BaseException as e:

                      self._futures[frame.requestid].set_exception(e)

                      del self._futures[frame.requestid]

                      response._oninputcomplete()

              else:

                  raise error.ProgrammingError(

                      'unhandled action from clientreactor: %s' % action)

          def _processresponsedata(self, frame, meta, response):

              # This can raise. The caller can handle it.

              response._onresponsedata(meta['data'])

              if meta['eos']:

                  response._oninputcomplete()

                  del self._requests[frame.requestid]

              # If the command has a decoder, we wait until all input has been

              # received before resolving the future. Otherwise we resolve the

              # future immediately.

              if frame.requestid not in self._futures:

                  return

              if response.command not in COMMAND_DECODERS:

                  self._futures[frame.requestid].set_result(response.objects())

                  del self._futures[frame.requestid]

              elif response._inputcomplete:

                  decoded = COMMAND_DECODERS[response.command](response.objects())

                  self._futures[frame.requestid].set_result(decoded)

                  del self._futures[frame.requestid]

      def decodebranchmap(objs):

          # Response should be a single CBOR map of branch name to array of nodes.

          bm = next(objs)

          return {encoding.tolocal(k): v for k, v in bm.items()}

      def decodeheads(objs):

          # Array of node bytestrings.

          return next(objs)

      def decodeknown(objs):

          # Bytestring where each byte is a 0 or 1.

          raw = next(objs)

          return [True if c == '1' else False for c in raw]

      def decodelistkeys(objs):

          # Map with bytestring keys and values.

          return next(objs)

      def decodelookup(objs):

          return next(objs)

      def decodepushkey(objs):

          return next(objs)

      COMMAND_DECODERS = {

          'branchmap': decodebranchmap,

          'heads': decodeheads,

          'known': decodeknown,

          'listkeys': decodelistkeys,

          'lookup': decodelookup,

          'pushkey': decodepushkey,

      }

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				# wireprotov2peer.py - client side code for wire protocol version 2
				#
				# Copyright 2018 Gregory Szorc <gregory.szorc@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.

				from __future__ import absolute_import

				import threading

				from .i18n import _
				from . import (
				encoding,
				error,
				wireprotoframing,
				)
				from .utils import (
				cborutil,
				)

				def formatrichmessage(atoms):
				"""Format an encoded message from the framing protocol."""

				chunks = []

				for atom in atoms:
				msg = _(atom[b'msg'])

				if b'args' in atom:
				msg = msg % tuple(atom[b'args'])

				chunks.append(msg)

				return b''.join(chunks)

				class commandresponse(object):
				"""Represents the response to a command request.

				Instances track the state of the command and hold its results.

				An external entity is required to update the state of the object when
				events occur.
				"""

				def __init__(self, requestid, command):
				self.requestid = requestid
				self.command = command

				# Whether all remote input related to this command has been
				# received.
				self._inputcomplete = False

				# We have a lock that is acquired when important object state is
				# mutated. This is to prevent race conditions between 1 thread
				# sending us new data and another consuming it.
				self._lock = threading.RLock()

				# An event is set when state of the object changes. This event
				# is waited on by the generator emitting objects.
				self._serviceable = threading.Event()

				self._pendingevents = []
				self._decoder = cborutil.bufferingdecoder()
				self._seeninitial = False

				def _oninputcomplete(self):
				with self._lock:
				self._inputcomplete = True
				self._serviceable.set()

				def _onresponsedata(self, data):
				available, readcount, wanted = self._decoder.decode(data)

				if not available:
				return

				with self._lock:
				for o in self._decoder.getavailable():
				if not self._seeninitial:
				self._handleinitial(o)
				continue

				self._pendingevents.append(o)

				self._serviceable.set()

				def _handleinitial(self, o):
				self._seeninitial = True
				if o[b'status'] == 'ok':
				return

				atoms = [{'msg': o[b'error'][b'message']}]
				if b'args' in o[b'error']:
				atoms[0]['args'] = o[b'error'][b'args']

				raise error.RepoError(formatrichmessage(atoms))

				def objects(self):
				"""Obtained decoded objects from this response.

				This is a generator of data structures that were decoded from the
				command response.

				Obtaining the next member of the generator may block due to waiting
				on external data to become available.

				If the server encountered an error in the middle of serving the data
				or if another error occurred, an exception may be raised when
				advancing the generator.
				"""
				while True:
				# TODO this can infinite loop if self._inputcomplete is never
				# set. We likely want to tie the lifetime of this object/state
				# to that of the background thread receiving frames and updating
				# our state.
				self._serviceable.wait(1.0)

				with self._lock:
				self._serviceable.clear()

				# Make copies because objects could be mutated during
				# iteration.
				stop = self._inputcomplete
				pending = list(self._pendingevents)
				self._pendingevents[:] = []

				for o in pending:
				yield o

				if stop:
				break

				class clienthandler(object):
				"""Object to handle higher-level client activities.

				The ``clientreactor`` is used to hold low-level state about the frame-based
				protocol, such as which requests and streams are active. This type is used
				for higher-level operations, such as reading frames from a socket, exposing
				and managing a higher-level primitive for representing command responses,
				etc. This class is what peers should probably use to bridge wire activity
				with the higher-level peer API.
				"""

				def __init__(self, ui, clientreactor):
				self._ui = ui
				self._reactor = clientreactor
				self._requests = {}
				self._futures = {}
				self._responses = {}

				def callcommand(self, command, args, f):
				"""Register a request to call a command.

				Returns an iterable of frames that should be sent over the wire.
				"""
				request, action, meta = self._reactor.callcommand(command, args)

				if action != 'noop':
				raise error.ProgrammingError('%s not yet supported' % action)

				rid = request.requestid
				self._requests[rid] = request
				self._futures[rid] = f
				# TODO we need some kind of lifetime on response instances otherwise
				# objects() may deadlock.
				self._responses[rid] = commandresponse(rid, command)

				return iter(())

				def flushcommands(self):
				"""Flush all queued commands.

				Returns an iterable of frames that should be sent over the wire.
				"""
				action, meta = self._reactor.flushcommands()

				if action != 'sendframes':
				raise error.ProgrammingError('%s not yet supported' % action)

				return meta['framegen']

				def readframe(self, fh):
				"""Attempt to read and process a frame.

				Returns None if no frame was read. Presumably this means EOF.
				"""
				frame = wireprotoframing.readframe(fh)
				if frame is None:
				# TODO tell reactor?
				return

				self._ui.note(_('received %r\n') % frame)
				self._processframe(frame)

				return True

				def _processframe(self, frame):
				"""Process a single read frame."""

				action, meta = self._reactor.onframerecv(frame)

				if action == 'error':
				e = error.RepoError(meta['message'])

				if frame.requestid in self._responses:
				self._responses[frame.requestid]._oninputcomplete()

				if frame.requestid in self._futures:
				self._futures[frame.requestid].set_exception(e)
				del self._futures[frame.requestid]
				else:
				raise e

				return

				if frame.requestid not in self._requests:
				raise error.ProgrammingError(
				'received frame for unknown request; this is either a bug in '
				'the clientreactor not screening for this or this instance was '
				'never told about this request: %r' % frame)

				response = self._responses[frame.requestid]

				if action == 'responsedata':
				# Any failures processing this frame should bubble up to the
				# future tracking the request.
				try:
				self._processresponsedata(frame, meta, response)
				except BaseException as e:
				self._futures[frame.requestid].set_exception(e)
				del self._futures[frame.requestid]
				response._oninputcomplete()
				else:
				raise error.ProgrammingError(
				'unhandled action from clientreactor: %s' % action)

				def _processresponsedata(self, frame, meta, response):
				# This can raise. The caller can handle it.
				response._onresponsedata(meta['data'])

				if meta['eos']:
				response._oninputcomplete()
				del self._requests[frame.requestid]

				# If the command has a decoder, we wait until all input has been
				# received before resolving the future. Otherwise we resolve the
				# future immediately.
				if frame.requestid not in self._futures:
				return

				if response.command not in COMMAND_DECODERS:
				self._futures[frame.requestid].set_result(response.objects())
				del self._futures[frame.requestid]
				elif response._inputcomplete:
				decoded = COMMAND_DECODERS[response.command](response.objects())
				self._futures[frame.requestid].set_result(decoded)
				del self._futures[frame.requestid]

				def decodebranchmap(objs):
				# Response should be a single CBOR map of branch name to array of nodes.
				bm = next(objs)

				return {encoding.tolocal(k): v for k, v in bm.items()}

				def decodeheads(objs):
				# Array of node bytestrings.
				return next(objs)

				def decodeknown(objs):
				# Bytestring where each byte is a 0 or 1.
				raw = next(objs)

				return [True if c == '1' else False for c in raw]

				def decodelistkeys(objs):
				# Map with bytestring keys and values.
				return next(objs)

				def decodelookup(objs):
				return next(objs)

				def decodepushkey(objs):
				return next(objs)

				COMMAND_DECODERS = {
				'branchmap': decodebranchmap,
				'heads': decodeheads,
				'known': decodeknown,
				'listkeys': decodelistkeys,
				'lookup': decodelookup,
				'pushkey': decodepushkey,
				}