Mercurial > public > mercurial-scm > hg-stable
view mercurial/wireprotov2peer.py @ 37722:89a16704114c
wireprotov2: define response data as CBOR
Previously, response data was defined as a stream of bytes. We had
the option to declare it as CBOR using a frame flag.
We've converged all wire protocol commands exposed on version 2 to
CBOR. I think consistency is important. The overhead to encoding
things with CBOR is minimal. Even a very large bytestring can be
efficiently encoded using an indefinite length bytestring. Now,
there are limitations with consumers not being able to efficiently
stream large CBOR values. But these feel like solvable problems.
This commit removes the "is CBOR" frame flag from command response
frames and defines the frame as always consisting of a stream of
CBOR values.
The framing protocol media type has been bumped to reflect this
BC change.
Differential Revision: https://phab.mercurial-scm.org/D3382
| author | Gregory Szorc <gregory.szorc@gmail.com> |
|---|---|
| date | Sat, 14 Apr 2018 12:07:31 -0700 |
| parents | f7673845b167 |
| children | 3ea8323d6f95 |
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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 .thirdparty import ( cbor, ) from . import ( encoding, error, util, wireprotoframing, ) 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.""" size = self.b.tell() self.b.seek(0) decoder = cbor.CBORDecoder(self.b) while self.b.tell() < size: yield decoder.decode() 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 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': 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) result = decoder(response) if decoder else response self._futures[frame.requestid].set_result(result) del self._requests[frame.requestid] del self._futures[frame.requestid] else: raise error.ProgrammingError( 'unhandled action from clientreactor: %s' % action) def decodebranchmap(resp): # Response should be a single CBOR map of branch name to array of nodes. bm = next(resp.cborobjects()) return {encoding.tolocal(k): v for k, v in bm.items()} def decodeheads(resp): # Array of node bytestrings. return next(resp.cborobjects()) def decodeknown(resp): # Bytestring where each byte is a 0 or 1. raw = next(resp.cborobjects()) return [True if c == '1' else False for c in raw] def decodelistkeys(resp): # Map with bytestring keys and values. return next(resp.cborobjects()) def decodelookup(resp): return next(resp.cborobjects()) def decodepushkey(resp): return next(resp.cborobjects()) COMMAND_DECODERS = { 'branchmap': decodebranchmap, 'heads': decodeheads, 'known': decodeknown, 'listkeys': decodelistkeys, 'lookup': decodelookup, 'pushkey': decodepushkey, }