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view mercurial/wireprotov2peer.py @ 39559:07b58266bce3
wireprotov2: implement commands as a generator of objects
Previously, wire protocol version 2 inherited version 1's model of
having separate types to represent the results of different wire
protocol commands.
As I implemented more powerful commands in future commits, I found
I was using a common pattern of returning a special type to hold a
generator. This meant the command function required a closure to
do most of the work. That made logic flow more difficult to follow.
I also noticed that many commands were effectively a sequence of
objects to be CBOR encoded.
I think it makes sense to define version 2 commands as generators.
This way, commands can simply emit the data structures they wish to
send to the client. This eliminates the need for a closure in
command functions and removes encoding from the bodies of commands.
As part of this commit, the handling of response objects has been
moved into the serverreactor class. This puts the reactor in the
driver's seat with regards to CBOR encoding and error handling.
Having error handling in the function that emits frames is
particularly important because exceptions in that function can lead
to things getting in a bad state: I'm fairly certain that uncaught
exceptions in the frame generator were causing deadlocks.
I also introduced a dedicated error type for explicit error reporting
in command handlers. This will be used in subsequent commits.
There's still a bit of work to be done here, especially around
formalizing the error handling "protocol." I've added yet another
TODO to track this so we don't forget.
Test output changed because we're using generators and no longer know
we are at the end of the data until we hit the end of the generator.
This means we can't emit the end-of-stream flag until we've exhausted
the generator. Hence the introduction of 0-sized end-of-stream frames.
Differential Revision: https://phab.mercurial-scm.org/D4472
| author | Gregory Szorc <gregory.szorc@gmail.com> |
|---|---|
| date | Wed, 05 Sep 2018 09:06:40 -0700 |
| parents | 43d92d68ac88 |
| children | d06834e0f48e |
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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 from .i18n import _ from . import ( encoding, error, util, 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.""" def __init__(self, requestid, command): self.requestid = requestid self.command = command self.b = util.bytesio() def cborobjects(self): """Obtain decoded CBOR objects from this response.""" self.b.seek(0) for v in cborutil.decodeall(self.b.getvalue()): yield v 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 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._futures: self._futures[frame.requestid].set_exception(e) 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) else: raise error.ProgrammingError( 'unhandled action from clientreactor: %s' % action) def _processresponsedata(self, frame, meta, response): # This buffers all data until end of stream is received. This # is bad for performance. # TODO make response data streamable response.b.write(meta['data']) if meta['eos']: # If the command has a decoder, resolve the future to the # decoded value. Otherwise resolve to the rich response object. decoder = COMMAND_DECODERS.get(response.command) # TODO consider always resolving the overall status map. if decoder: objs = response.cborobjects() overall = next(objs) if overall['status'] == 'ok': self._futures[frame.requestid].set_result(decoder(objs)) else: atoms = [{'msg': overall['error']['message']}] if 'args' in overall['error']: atoms[0]['args'] = overall['error']['args'] e = error.RepoError(formatrichmessage(atoms)) self._futures[frame.requestid].set_exception(e) else: self._futures[frame.requestid].set_result(response) del self._requests[frame.requestid] 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, }