# wireprotov1peer.py - Client-side functionality for wire protocol version 1. # # Copyright 2005-2010 Matt Mackall # # 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 hashlib import sys import weakref from .i18n import _ from .node import bin from .pycompat import ( getattr, setattr, ) from . import ( bundle2, changegroup as changegroupmod, encoding, error, pushkey as pushkeymod, pycompat, util, wireprototypes, ) from .interfaces import ( repository, util as interfaceutil, ) urlreq = util.urlreq def batchable(f): '''annotation for batchable methods Such methods must implement a coroutine as follows: @batchable def sample(self, one, two=None): # Build list of encoded arguments suitable for your wire protocol: encargs = [('one', encode(one),), ('two', encode(two),)] # Create future for injection of encoded result: encresref = future() # Return encoded arguments and future: yield encargs, encresref # Assuming the future to be filled with the result from the batched # request now. Decode it: yield decode(encresref.value) The decorator returns a function which wraps this coroutine as a plain method, but adds the original method as an attribute called "batchable", which is used by remotebatch to split the call into separate encoding and decoding phases. ''' def plain(*args, **opts): batchable = f(*args, **opts) encargsorres, encresref = next(batchable) if not encresref: return encargsorres # a local result in this case self = args[0] cmd = pycompat.bytesurl(f.__name__) # ensure cmd is ascii bytestr encresref.set(self._submitone(cmd, encargsorres)) return next(batchable) setattr(plain, 'batchable', f) setattr(plain, '__name__', f.__name__) return plain class future(object): '''placeholder for a value to be set later''' def set(self, value): if util.safehasattr(self, b'value'): raise error.RepoError(b"future is already set") self.value = value def encodebatchcmds(req): """Return a ``cmds`` argument value for the ``batch`` command.""" escapearg = wireprototypes.escapebatcharg cmds = [] for op, argsdict in req: # Old servers didn't properly unescape argument names. So prevent # the sending of argument names that may not be decoded properly by # servers. assert all(escapearg(k) == k for k in argsdict) args = b','.join( b'%s=%s' % (escapearg(k), escapearg(v)) for k, v in pycompat.iteritems(argsdict) ) cmds.append(b'%s %s' % (op, args)) return b';'.join(cmds) class unsentfuture(pycompat.futures.Future): """A Future variation to represent an unsent command. Because we buffer commands and don't submit them immediately, calling ``result()`` on an unsent future could deadlock. Futures for buffered commands are represented by this type, which wraps ``result()`` to call ``sendcommands()``. """ def result(self, timeout=None): if self.done(): return pycompat.futures.Future.result(self, timeout) self._peerexecutor.sendcommands() # This looks like it will infinitely recurse. However, # sendcommands() should modify __class__. This call serves as a check # on that. return self.result(timeout) @interfaceutil.implementer(repository.ipeercommandexecutor) class peerexecutor(object): def __init__(self, peer): self._peer = peer self._sent = False self._closed = False self._calls = [] self._futures = weakref.WeakSet() self._responseexecutor = None self._responsef = None def __enter__(self): return self def __exit__(self, exctype, excvalee, exctb): self.close() def callcommand(self, command, args): if self._sent: raise error.ProgrammingError( b'callcommand() cannot be used ' b'after commands are sent' ) if self._closed: raise error.ProgrammingError( b'callcommand() cannot be used ' b'after close()' ) # Commands are dispatched through methods on the peer. fn = getattr(self._peer, pycompat.sysstr(command), None) if not fn: raise error.ProgrammingError( b'cannot call command %s: method of same name not available ' b'on peer' % command ) # Commands are either batchable or they aren't. If a command # isn't batchable, we send it immediately because the executor # can no longer accept new commands after a non-batchable command. # If a command is batchable, we queue it for later. But we have # to account for the case of a non-batchable command arriving after # a batchable one and refuse to service it. def addcall(): f = pycompat.futures.Future() self._futures.add(f) self._calls.append((command, args, fn, f)) return f if getattr(fn, 'batchable', False): f = addcall() # But since we don't issue it immediately, we wrap its result() # to trigger sending so we avoid deadlocks. f.__class__ = unsentfuture f._peerexecutor = self else: if self._calls: raise error.ProgrammingError( b'%s is not batchable and cannot be called on a command ' b'executor along with other commands' % command ) f = addcall() # Non-batchable commands can never coexist with another command # in this executor. So send the command immediately. self.sendcommands() return f def sendcommands(self): if self._sent: return if not self._calls: return self._sent = True # Unhack any future types so caller seens a clean type and to break # cycle between us and futures. for f in self._futures: if isinstance(f, unsentfuture): f.__class__ = pycompat.futures.Future f._peerexecutor = None calls = self._calls # Mainly to destroy references to futures. self._calls = None # Simple case of a single command. We call it synchronously. if len(calls) == 1: command, args, fn, f = calls[0] # Future was cancelled. Ignore it. if not f.set_running_or_notify_cancel(): return try: result = fn(**pycompat.strkwargs(args)) except Exception: pycompat.future_set_exception_info(f, sys.exc_info()[1:]) else: f.set_result(result) return # Batch commands are a bit harder. First, we have to deal with the # @batchable coroutine. That's a bit annoying. Furthermore, we also # need to preserve streaming. i.e. it should be possible for the # futures to resolve as data is coming in off the wire without having # to wait for the final byte of the final response. We do this by # spinning up a thread to read the responses. requests = [] states = [] for command, args, fn, f in calls: # Future was cancelled. Ignore it. if not f.set_running_or_notify_cancel(): continue try: batchable = fn.batchable( fn.__self__, **pycompat.strkwargs(args) ) except Exception: pycompat.future_set_exception_info(f, sys.exc_info()[1:]) return # Encoded arguments and future holding remote result. try: encargsorres, fremote = next(batchable) except Exception: pycompat.future_set_exception_info(f, sys.exc_info()[1:]) return if not fremote: f.set_result(encargsorres) else: requests.append((command, encargsorres)) states.append((command, f, batchable, fremote)) if not requests: return # This will emit responses in order they were executed. wireresults = self._peer._submitbatch(requests) # The use of a thread pool executor here is a bit weird for something # that only spins up a single thread. However, thread management is # hard and it is easy to encounter race conditions, deadlocks, etc. # concurrent.futures already solves these problems and its thread pool # executor has minimal overhead. So we use it. self._responseexecutor = pycompat.futures.ThreadPoolExecutor(1) self._responsef = self._responseexecutor.submit( self._readbatchresponse, states, wireresults ) def close(self): self.sendcommands() if self._closed: return self._closed = True if not self._responsef: return # We need to wait on our in-flight response and then shut down the # executor once we have a result. try: self._responsef.result() finally: self._responseexecutor.shutdown(wait=True) self._responsef = None self._responseexecutor = None # If any of our futures are still in progress, mark them as # errored. Otherwise a result() could wait indefinitely. for f in self._futures: if not f.done(): f.set_exception( error.ResponseError( _(b'unfulfilled batch command response') ) ) self._futures = None def _readbatchresponse(self, states, wireresults): # Executes in a thread to read data off the wire. for command, f, batchable, fremote in states: # Grab raw result off the wire and teach the internal future # about it. remoteresult = next(wireresults) fremote.set(remoteresult) # And ask the coroutine to decode that value. try: result = next(batchable) except Exception: pycompat.future_set_exception_info(f, sys.exc_info()[1:]) else: f.set_result(result) @interfaceutil.implementer( repository.ipeercommands, repository.ipeerlegacycommands ) class wirepeer(repository.peer): """Client-side interface for communicating with a peer repository. Methods commonly call wire protocol commands of the same name. See also httppeer.py and sshpeer.py for protocol-specific implementations of this interface. """ def commandexecutor(self): return peerexecutor(self) # Begin of ipeercommands interface. def clonebundles(self): self.requirecap(b'clonebundles', _(b'clone bundles')) return self._call(b'clonebundles') @batchable def lookup(self, key): self.requirecap(b'lookup', _(b'look up remote revision')) f = future() yield {b'key': encoding.fromlocal(key)}, f d = f.value success, data = d[:-1].split(b" ", 1) if int(success): yield bin(data) else: self._abort(error.RepoError(data)) @batchable def heads(self): f = future() yield {}, f d = f.value try: yield wireprototypes.decodelist(d[:-1]) except ValueError: self._abort(error.ResponseError(_(b"unexpected response:"), d)) @batchable def known(self, nodes): f = future() yield {b'nodes': wireprototypes.encodelist(nodes)}, f d = f.value try: yield [bool(int(b)) for b in pycompat.iterbytestr(d)] except ValueError: self._abort(error.ResponseError(_(b"unexpected response:"), d)) @batchable def branchmap(self): f = future() yield {}, f d = f.value try: branchmap = {} for branchpart in d.splitlines(): branchname, branchheads = branchpart.split(b' ', 1) branchname = encoding.tolocal(urlreq.unquote(branchname)) branchheads = wireprototypes.decodelist(branchheads) branchmap[branchname] = branchheads yield branchmap except TypeError: self._abort(error.ResponseError(_(b"unexpected response:"), d)) @batchable def listkeys(self, namespace): if not self.capable(b'pushkey'): yield {}, None f = future() self.ui.debug(b'preparing listkeys for "%s"\n' % namespace) yield {b'namespace': encoding.fromlocal(namespace)}, f d = f.value self.ui.debug( b'received listkey for "%s": %i bytes\n' % (namespace, len(d)) ) yield pushkeymod.decodekeys(d) @batchable def pushkey(self, namespace, key, old, new): if not self.capable(b'pushkey'): yield False, None f = future() self.ui.debug(b'preparing pushkey for "%s:%s"\n' % (namespace, key)) yield { b'namespace': encoding.fromlocal(namespace), b'key': encoding.fromlocal(key), b'old': encoding.fromlocal(old), b'new': encoding.fromlocal(new), }, f d = f.value d, output = d.split(b'\n', 1) try: d = bool(int(d)) except ValueError: raise error.ResponseError( _(b'push failed (unexpected response):'), d ) for l in output.splitlines(True): self.ui.status(_(b'remote: '), l) yield d def stream_out(self): return self._callstream(b'stream_out') def getbundle(self, source, **kwargs): kwargs = pycompat.byteskwargs(kwargs) self.requirecap(b'getbundle', _(b'look up remote changes')) opts = {} bundlecaps = kwargs.get(b'bundlecaps') or set() for key, value in pycompat.iteritems(kwargs): if value is None: continue keytype = wireprototypes.GETBUNDLE_ARGUMENTS.get(key) if keytype is None: raise error.ProgrammingError( b'Unexpectedly None keytype for key %s' % key ) elif keytype == b'nodes': value = wireprototypes.encodelist(value) elif keytype == b'csv': value = b','.join(value) elif keytype == b'scsv': value = b','.join(sorted(value)) elif keytype == b'boolean': value = b'%i' % bool(value) elif keytype != b'plain': raise KeyError(b'unknown getbundle option type %s' % keytype) opts[key] = value f = self._callcompressable(b"getbundle", **pycompat.strkwargs(opts)) if any((cap.startswith(b'HG2') for cap in bundlecaps)): return bundle2.getunbundler(self.ui, f) else: return changegroupmod.cg1unpacker(f, b'UN') def unbundle(self, bundle, heads, url): '''Send cg (a readable file-like object representing the changegroup to push, typically a chunkbuffer object) to the remote server as a bundle. When pushing a bundle10 stream, return an integer indicating the result of the push (see changegroup.apply()). When pushing a bundle20 stream, return a bundle20 stream. `url` is the url the client thinks it's pushing to, which is visible to hooks. ''' if heads != [b'force'] and self.capable(b'unbundlehash'): heads = wireprototypes.encodelist( [b'hashed', hashlib.sha1(b''.join(sorted(heads))).digest()] ) else: heads = wireprototypes.encodelist(heads) if util.safehasattr(bundle, b'deltaheader'): # this a bundle10, do the old style call sequence ret, output = self._callpush(b"unbundle", bundle, heads=heads) if ret == b"": raise error.ResponseError(_(b'push failed:'), output) try: ret = int(ret) except ValueError: raise error.ResponseError( _(b'push failed (unexpected response):'), ret ) for l in output.splitlines(True): self.ui.status(_(b'remote: '), l) else: # bundle2 push. Send a stream, fetch a stream. stream = self._calltwowaystream(b'unbundle', bundle, heads=heads) ret = bundle2.getunbundler(self.ui, stream) return ret # End of ipeercommands interface. # Begin of ipeerlegacycommands interface. def branches(self, nodes): n = wireprototypes.encodelist(nodes) d = self._call(b"branches", nodes=n) try: br = [tuple(wireprototypes.decodelist(b)) for b in d.splitlines()] return br except ValueError: self._abort(error.ResponseError(_(b"unexpected response:"), d)) def between(self, pairs): batch = 8 # avoid giant requests r = [] for i in pycompat.xrange(0, len(pairs), batch): n = b" ".join( [ wireprototypes.encodelist(p, b'-') for p in pairs[i : i + batch] ] ) d = self._call(b"between", pairs=n) try: r.extend( l and wireprototypes.decodelist(l) or [] for l in d.splitlines() ) except ValueError: self._abort(error.ResponseError(_(b"unexpected response:"), d)) return r def changegroup(self, nodes, source): n = wireprototypes.encodelist(nodes) f = self._callcompressable(b"changegroup", roots=n) return changegroupmod.cg1unpacker(f, b'UN') def changegroupsubset(self, bases, heads, source): self.requirecap(b'changegroupsubset', _(b'look up remote changes')) bases = wireprototypes.encodelist(bases) heads = wireprototypes.encodelist(heads) f = self._callcompressable( b"changegroupsubset", bases=bases, heads=heads ) return changegroupmod.cg1unpacker(f, b'UN') # End of ipeerlegacycommands interface. def _submitbatch(self, req): """run batch request on the server Returns an iterator of the raw responses from the server. """ ui = self.ui if ui.debugflag and ui.configbool(b'devel', b'debug.peer-request'): ui.debug(b'devel-peer-request: batched-content\n') for op, args in req: msg = b'devel-peer-request: - %s (%d arguments)\n' ui.debug(msg % (op, len(args))) unescapearg = wireprototypes.unescapebatcharg rsp = self._callstream(b"batch", cmds=encodebatchcmds(req)) chunk = rsp.read(1024) work = [chunk] while chunk: while b';' not in chunk and chunk: chunk = rsp.read(1024) work.append(chunk) merged = b''.join(work) while b';' in merged: one, merged = merged.split(b';', 1) yield unescapearg(one) chunk = rsp.read(1024) work = [merged, chunk] yield unescapearg(b''.join(work)) def _submitone(self, op, args): return self._call(op, **pycompat.strkwargs(args)) def debugwireargs(self, one, two, three=None, four=None, five=None): # don't pass optional arguments left at their default value opts = {} if three is not None: opts[r'three'] = three if four is not None: opts[r'four'] = four return self._call(b'debugwireargs', one=one, two=two, **opts) def _call(self, cmd, **args): """execute on the server The command is expected to return a simple string. returns the server reply as a string.""" raise NotImplementedError() def _callstream(self, cmd, **args): """execute on the server The command is expected to return a stream. Note that if the command doesn't return a stream, _callstream behaves differently for ssh and http peers. returns the server reply as a file like object. """ raise NotImplementedError() def _callcompressable(self, cmd, **args): """execute on the server The command is expected to return a stream. The stream may have been compressed in some implementations. This function takes care of the decompression. This is the only difference with _callstream. returns the server reply as a file like object. """ raise NotImplementedError() def _callpush(self, cmd, fp, **args): """execute a on server The command is expected to be related to a push. Push has a special return method. returns the server reply as a (ret, output) tuple. ret is either empty (error) or a stringified int. """ raise NotImplementedError() def _calltwowaystream(self, cmd, fp, **args): """execute on server The command will send a stream to the server and get a stream in reply. """ raise NotImplementedError() def _abort(self, exception): """clearly abort the wire protocol connection and raise the exception """ raise NotImplementedError()