Mercurial > hg
view mercurial/sshpeer.py @ 44763:94f4f2ec7dee stable
packaging: support building Inno installer with PyOxidizer
We want to start distributing Mercurial on Python 3 on
Windows. PyOxidizer will be our vehicle for achieving that.
This commit implements basic support for producing Inno
installers using PyOxidizer.
While it is an eventual goal of PyOxidizer to produce
installers, those features aren't yet implemented. So our
strategy for producing Mercurial installers is similar to
what we've been doing with py2exe: invoke a build system to
produce files then stage those files into a directory so they
can be turned into an installer.
We had to make significant alterations to the pyoxidizer.bzl
config file to get it to produce the files that we desire for
a Windows install. This meant differentiating the build targets
so we can target Windows specifically.
We've added a new module to hgpackaging to deal with interacting
with PyOxidizer. It is similar to pyexe: we invoke a build process
then copy files to a staging directory. Ideally these extra
files would be defined in pyoxidizer.bzl. But I don't think it
is worth doing at this time, as PyOxidizer's config files are
lacking some features to make this turnkey.
The rest of the change is introducing a variant of the
Inno installer code that invokes PyOxidizer instead of
py2exe.
Comparing the Python 2.7 based Inno installers with this
one, the following changes were observed:
* No lib/*.{pyd, dll} files
* No Microsoft.VC90.CRT.manifest
* No msvc{m,p,r}90.dll files
* python27.dll replaced with python37.dll
* Add vcruntime140.dll file
The disappearance of the .pyd and .dll files is acceptable, as
PyOxidizer has embedded these in hg.exe and loads them from
memory.
The disappearance of the *90* files is acceptable because those
provide the Visual C++ 9 runtime, as required by Python 2.7.
Similarly, the appearance of vcruntime140.dll is a requirement
of Python 3.7.
Differential Revision: https://phab.mercurial-scm.org/D8473
author | Gregory Szorc <gregory.szorc@gmail.com> |
---|---|
date | Thu, 23 Apr 2020 18:06:02 -0700 |
parents | d783f945a701 |
children | 5d77f571a563 |
line wrap: on
line source
# sshpeer.py - ssh repository proxy class for mercurial # # Copyright 2005, 2006 Matt Mackall <mpm@selenic.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 re import uuid from .i18n import _ from .pycompat import getattr from . import ( error, pycompat, util, wireprotoserver, wireprototypes, wireprotov1peer, wireprotov1server, ) from .utils import ( procutil, stringutil, ) def _serverquote(s): """quote a string for the remote shell ... which we assume is sh""" if not s: return s if re.match(b'[a-zA-Z0-9@%_+=:,./-]*$', s): return s return b"'%s'" % s.replace(b"'", b"'\\''") def _forwardoutput(ui, pipe): """display all data currently available on pipe as remote output. This is non blocking.""" if pipe: s = procutil.readpipe(pipe) if s: for l in s.splitlines(): ui.status(_(b"remote: "), l, b'\n') class doublepipe(object): """Operate a side-channel pipe in addition of a main one The side-channel pipe contains server output to be forwarded to the user input. The double pipe will behave as the "main" pipe, but will ensure the content of the "side" pipe is properly processed while we wait for blocking call on the "main" pipe. If large amounts of data are read from "main", the forward will cease after the first bytes start to appear. This simplifies the implementation without affecting actual output of sshpeer too much as we rarely issue large read for data not yet emitted by the server. The main pipe is expected to be a 'bufferedinputpipe' from the util module that handle all the os specific bits. This class lives in this module because it focus on behavior specific to the ssh protocol.""" def __init__(self, ui, main, side): self._ui = ui self._main = main self._side = side def _wait(self): """wait until some data are available on main or side return a pair of boolean (ismainready, issideready) (This will only wait for data if the setup is supported by `util.poll`) """ if ( isinstance(self._main, util.bufferedinputpipe) and self._main.hasbuffer ): # Main has data. Assume side is worth poking at. return True, True fds = [self._main.fileno(), self._side.fileno()] try: act = util.poll(fds) except NotImplementedError: # non supported yet case, assume all have data. act = fds return (self._main.fileno() in act, self._side.fileno() in act) def write(self, data): return self._call(b'write', data) def read(self, size): r = self._call(b'read', size) if size != 0 and not r: # We've observed a condition that indicates the # stdout closed unexpectedly. Check stderr one # more time and snag anything that's there before # letting anyone know the main part of the pipe # closed prematurely. _forwardoutput(self._ui, self._side) return r def unbufferedread(self, size): r = self._call(b'unbufferedread', size) if size != 0 and not r: # We've observed a condition that indicates the # stdout closed unexpectedly. Check stderr one # more time and snag anything that's there before # letting anyone know the main part of the pipe # closed prematurely. _forwardoutput(self._ui, self._side) return r def readline(self): return self._call(b'readline') def _call(self, methname, data=None): """call <methname> on "main", forward output of "side" while blocking """ # data can be '' or 0 if (data is not None and not data) or self._main.closed: _forwardoutput(self._ui, self._side) return b'' while True: mainready, sideready = self._wait() if sideready: _forwardoutput(self._ui, self._side) if mainready: meth = getattr(self._main, methname) if data is None: return meth() else: return meth(data) def close(self): return self._main.close() def flush(self): return self._main.flush() def _cleanuppipes(ui, pipei, pipeo, pipee): """Clean up pipes used by an SSH connection.""" if pipeo: pipeo.close() if pipei: pipei.close() if pipee: # Try to read from the err descriptor until EOF. try: for l in pipee: ui.status(_(b'remote: '), l) except (IOError, ValueError): pass pipee.close() def _makeconnection(ui, sshcmd, args, remotecmd, path, sshenv=None): """Create an SSH connection to a server. Returns a tuple of (process, stdin, stdout, stderr) for the spawned process. """ cmd = b'%s %s %s' % ( sshcmd, args, procutil.shellquote( b'%s -R %s serve --stdio' % (_serverquote(remotecmd), _serverquote(path)) ), ) ui.debug(b'running %s\n' % cmd) cmd = procutil.quotecommand(cmd) # no buffer allow the use of 'select' # feel free to remove buffering and select usage when we ultimately # move to threading. stdin, stdout, stderr, proc = procutil.popen4(cmd, bufsize=0, env=sshenv) return proc, stdin, stdout, stderr def _clientcapabilities(): """Return list of capabilities of this client. Returns a list of capabilities that are supported by this client. """ protoparams = {b'partial-pull'} comps = [ e.wireprotosupport().name for e in util.compengines.supportedwireengines(util.CLIENTROLE) ] protoparams.add(b'comp=%s' % b','.join(comps)) return protoparams def _performhandshake(ui, stdin, stdout, stderr): def badresponse(): # Flush any output on stderr. _forwardoutput(ui, stderr) msg = _(b'no suitable response from remote hg') hint = ui.config(b'ui', b'ssherrorhint') raise error.RepoError(msg, hint=hint) # The handshake consists of sending wire protocol commands in reverse # order of protocol implementation and then sniffing for a response # to one of them. # # Those commands (from oldest to newest) are: # # ``between`` # Asks for the set of revisions between a pair of revisions. Command # present in all Mercurial server implementations. # # ``hello`` # Instructs the server to advertise its capabilities. Introduced in # Mercurial 0.9.1. # # ``upgrade`` # Requests upgrade from default transport protocol version 1 to # a newer version. Introduced in Mercurial 4.6 as an experimental # feature. # # The ``between`` command is issued with a request for the null # range. If the remote is a Mercurial server, this request will # generate a specific response: ``1\n\n``. This represents the # wire protocol encoded value for ``\n``. We look for ``1\n\n`` # in the output stream and know this is the response to ``between`` # and we're at the end of our handshake reply. # # The response to the ``hello`` command will be a line with the # length of the value returned by that command followed by that # value. If the server doesn't support ``hello`` (which should be # rare), that line will be ``0\n``. Otherwise, the value will contain # RFC 822 like lines. Of these, the ``capabilities:`` line contains # the capabilities of the server. # # The ``upgrade`` command isn't really a command in the traditional # sense of version 1 of the transport because it isn't using the # proper mechanism for formatting insteads: instead, it just encodes # arguments on the line, delimited by spaces. # # The ``upgrade`` line looks like ``upgrade <token> <capabilities>``. # If the server doesn't support protocol upgrades, it will reply to # this line with ``0\n``. Otherwise, it emits an # ``upgraded <token> <protocol>`` line to both stdout and stderr. # Content immediately following this line describes additional # protocol and server state. # # In addition to the responses to our command requests, the server # may emit "banner" output on stdout. SSH servers are allowed to # print messages to stdout on login. Issuing commands on connection # allows us to flush this banner output from the server by scanning # for output to our well-known ``between`` command. Of course, if # the banner contains ``1\n\n``, this will throw off our detection. requestlog = ui.configbool(b'devel', b'debug.peer-request') # Generate a random token to help identify responses to version 2 # upgrade request. token = pycompat.sysbytes(str(uuid.uuid4())) upgradecaps = [ (b'proto', wireprotoserver.SSHV2), ] upgradecaps = util.urlreq.urlencode(upgradecaps) try: pairsarg = b'%s-%s' % (b'0' * 40, b'0' * 40) handshake = [ b'hello\n', b'between\n', b'pairs %d\n' % len(pairsarg), pairsarg, ] # Request upgrade to version 2 if configured. if ui.configbool(b'experimental', b'sshpeer.advertise-v2'): ui.debug(b'sending upgrade request: %s %s\n' % (token, upgradecaps)) handshake.insert(0, b'upgrade %s %s\n' % (token, upgradecaps)) if requestlog: ui.debug(b'devel-peer-request: hello+between\n') ui.debug(b'devel-peer-request: pairs: %d bytes\n' % len(pairsarg)) ui.debug(b'sending hello command\n') ui.debug(b'sending between command\n') stdin.write(b''.join(handshake)) stdin.flush() except IOError: badresponse() # Assume version 1 of wire protocol by default. protoname = wireprototypes.SSHV1 reupgraded = re.compile(b'^upgraded %s (.*)$' % stringutil.reescape(token)) lines = [b'', b'dummy'] max_noise = 500 while lines[-1] and max_noise: try: l = stdout.readline() _forwardoutput(ui, stderr) # Look for reply to protocol upgrade request. It has a token # in it, so there should be no false positives. m = reupgraded.match(l) if m: protoname = m.group(1) ui.debug(b'protocol upgraded to %s\n' % protoname) # If an upgrade was handled, the ``hello`` and ``between`` # requests are ignored. The next output belongs to the # protocol, so stop scanning lines. break # Otherwise it could be a banner, ``0\n`` response if server # doesn't support upgrade. if lines[-1] == b'1\n' and l == b'\n': break if l: ui.debug(b'remote: ', l) lines.append(l) max_noise -= 1 except IOError: badresponse() else: badresponse() caps = set() # For version 1, we should see a ``capabilities`` line in response to the # ``hello`` command. if protoname == wireprototypes.SSHV1: for l in reversed(lines): # Look for response to ``hello`` command. Scan from the back so # we don't misinterpret banner output as the command reply. if l.startswith(b'capabilities:'): caps.update(l[:-1].split(b':')[1].split()) break elif protoname == wireprotoserver.SSHV2: # We see a line with number of bytes to follow and then a value # looking like ``capabilities: *``. line = stdout.readline() try: valuelen = int(line) except ValueError: badresponse() capsline = stdout.read(valuelen) if not capsline.startswith(b'capabilities: '): badresponse() ui.debug(b'remote: %s\n' % capsline) caps.update(capsline.split(b':')[1].split()) # Trailing newline. stdout.read(1) # Error if we couldn't find capabilities, this means: # # 1. Remote isn't a Mercurial server # 2. Remote is a <0.9.1 Mercurial server # 3. Remote is a future Mercurial server that dropped ``hello`` # and other attempted handshake mechanisms. if not caps: badresponse() # Flush any output on stderr before proceeding. _forwardoutput(ui, stderr) return protoname, caps class sshv1peer(wireprotov1peer.wirepeer): def __init__( self, ui, url, proc, stdin, stdout, stderr, caps, autoreadstderr=True ): """Create a peer from an existing SSH connection. ``proc`` is a handle on the underlying SSH process. ``stdin``, ``stdout``, and ``stderr`` are handles on the stdio pipes for that process. ``caps`` is a set of capabilities supported by the remote. ``autoreadstderr`` denotes whether to automatically read from stderr and to forward its output. """ self._url = url self.ui = ui # self._subprocess is unused. Keeping a handle on the process # holds a reference and prevents it from being garbage collected. self._subprocess = proc # And we hook up our "doublepipe" wrapper to allow querying # stderr any time we perform I/O. if autoreadstderr: stdout = doublepipe(ui, util.bufferedinputpipe(stdout), stderr) stdin = doublepipe(ui, stdin, stderr) self._pipeo = stdin self._pipei = stdout self._pipee = stderr self._caps = caps self._autoreadstderr = autoreadstderr # Commands that have a "framed" response where the first line of the # response contains the length of that response. _FRAMED_COMMANDS = { b'batch', } # Begin of ipeerconnection interface. def url(self): return self._url def local(self): return None def peer(self): return self def canpush(self): return True def close(self): pass # End of ipeerconnection interface. # Begin of ipeercommands interface. def capabilities(self): return self._caps # End of ipeercommands interface. def _readerr(self): _forwardoutput(self.ui, self._pipee) def _abort(self, exception): self._cleanup() raise exception def _cleanup(self): _cleanuppipes(self.ui, self._pipei, self._pipeo, self._pipee) __del__ = _cleanup def _sendrequest(self, cmd, args, framed=False): if self.ui.debugflag and self.ui.configbool( b'devel', b'debug.peer-request' ): dbg = self.ui.debug line = b'devel-peer-request: %s\n' dbg(line % cmd) for key, value in sorted(args.items()): if not isinstance(value, dict): dbg(line % b' %s: %d bytes' % (key, len(value))) else: for dk, dv in sorted(value.items()): dbg(line % b' %s-%s: %d' % (key, dk, len(dv))) self.ui.debug(b"sending %s command\n" % cmd) self._pipeo.write(b"%s\n" % cmd) _func, names = wireprotov1server.commands[cmd] keys = names.split() wireargs = {} for k in keys: if k == b'*': wireargs[b'*'] = args break else: wireargs[k] = args[k] del args[k] for k, v in sorted(pycompat.iteritems(wireargs)): self._pipeo.write(b"%s %d\n" % (k, len(v))) if isinstance(v, dict): for dk, dv in pycompat.iteritems(v): self._pipeo.write(b"%s %d\n" % (dk, len(dv))) self._pipeo.write(dv) else: self._pipeo.write(v) self._pipeo.flush() # We know exactly how many bytes are in the response. So return a proxy # around the raw output stream that allows reading exactly this many # bytes. Callers then can read() without fear of overrunning the # response. if framed: amount = self._getamount() return util.cappedreader(self._pipei, amount) return self._pipei def _callstream(self, cmd, **args): args = pycompat.byteskwargs(args) return self._sendrequest(cmd, args, framed=cmd in self._FRAMED_COMMANDS) def _callcompressable(self, cmd, **args): args = pycompat.byteskwargs(args) return self._sendrequest(cmd, args, framed=cmd in self._FRAMED_COMMANDS) def _call(self, cmd, **args): args = pycompat.byteskwargs(args) return self._sendrequest(cmd, args, framed=True).read() def _callpush(self, cmd, fp, **args): # The server responds with an empty frame if the client should # continue submitting the payload. r = self._call(cmd, **args) if r: return b'', r # The payload consists of frames with content followed by an empty # frame. for d in iter(lambda: fp.read(4096), b''): self._writeframed(d) self._writeframed(b"", flush=True) # In case of success, there is an empty frame and a frame containing # the integer result (as a string). # In case of error, there is a non-empty frame containing the error. r = self._readframed() if r: return b'', r return self._readframed(), b'' def _calltwowaystream(self, cmd, fp, **args): # The server responds with an empty frame if the client should # continue submitting the payload. r = self._call(cmd, **args) if r: # XXX needs to be made better raise error.Abort(_(b'unexpected remote reply: %s') % r) # The payload consists of frames with content followed by an empty # frame. for d in iter(lambda: fp.read(4096), b''): self._writeframed(d) self._writeframed(b"", flush=True) return self._pipei def _getamount(self): l = self._pipei.readline() if l == b'\n': if self._autoreadstderr: self._readerr() msg = _(b'check previous remote output') self._abort(error.OutOfBandError(hint=msg)) if self._autoreadstderr: self._readerr() try: return int(l) except ValueError: self._abort(error.ResponseError(_(b"unexpected response:"), l)) def _readframed(self): size = self._getamount() if not size: return b'' return self._pipei.read(size) def _writeframed(self, data, flush=False): self._pipeo.write(b"%d\n" % len(data)) if data: self._pipeo.write(data) if flush: self._pipeo.flush() if self._autoreadstderr: self._readerr() class sshv2peer(sshv1peer): """A peer that speakers version 2 of the transport protocol.""" # Currently version 2 is identical to version 1 post handshake. # And handshake is performed before the peer is instantiated. So # we need no custom code. def makepeer(ui, path, proc, stdin, stdout, stderr, autoreadstderr=True): """Make a peer instance from existing pipes. ``path`` and ``proc`` are stored on the eventual peer instance and may not be used for anything meaningful. ``stdin``, ``stdout``, and ``stderr`` are the pipes connected to the SSH server's stdio handles. This function is factored out to allow creating peers that don't actually spawn a new process. It is useful for starting SSH protocol servers and clients via non-standard means, which can be useful for testing. """ try: protoname, caps = _performhandshake(ui, stdin, stdout, stderr) except Exception: _cleanuppipes(ui, stdout, stdin, stderr) raise if protoname == wireprototypes.SSHV1: return sshv1peer( ui, path, proc, stdin, stdout, stderr, caps, autoreadstderr=autoreadstderr, ) elif protoname == wireprototypes.SSHV2: return sshv2peer( ui, path, proc, stdin, stdout, stderr, caps, autoreadstderr=autoreadstderr, ) else: _cleanuppipes(ui, stdout, stdin, stderr) raise error.RepoError( _(b'unknown version of SSH protocol: %s') % protoname ) def instance(ui, path, create, intents=None, createopts=None): """Create an SSH peer. The returned object conforms to the ``wireprotov1peer.wirepeer`` interface. """ u = util.url(path, parsequery=False, parsefragment=False) if u.scheme != b'ssh' or not u.host or u.path is None: raise error.RepoError(_(b"couldn't parse location %s") % path) util.checksafessh(path) if u.passwd is not None: raise error.RepoError(_(b'password in URL not supported')) sshcmd = ui.config(b'ui', b'ssh') remotecmd = ui.config(b'ui', b'remotecmd') sshaddenv = dict(ui.configitems(b'sshenv')) sshenv = procutil.shellenviron(sshaddenv) remotepath = u.path or b'.' args = procutil.sshargs(sshcmd, u.host, u.user, u.port) if create: # We /could/ do this, but only if the remote init command knows how to # handle them. We don't yet make any assumptions about that. And without # querying the remote, there's no way of knowing if the remote even # supports said requested feature. if createopts: raise error.RepoError( _( b'cannot create remote SSH repositories ' b'with extra options' ) ) cmd = b'%s %s %s' % ( sshcmd, args, procutil.shellquote( b'%s init %s' % (_serverquote(remotecmd), _serverquote(remotepath)) ), ) ui.debug(b'running %s\n' % cmd) res = ui.system(cmd, blockedtag=b'sshpeer', environ=sshenv) if res != 0: raise error.RepoError(_(b'could not create remote repo')) proc, stdin, stdout, stderr = _makeconnection( ui, sshcmd, args, remotecmd, remotepath, sshenv ) peer = makepeer(ui, path, proc, stdin, stdout, stderr) # Finally, if supported by the server, notify it about our own # capabilities. if b'protocaps' in peer.capabilities(): try: peer._call( b"protocaps", caps=b' '.join(sorted(_clientcapabilities())) ) except IOError: peer._cleanup() raise error.RepoError(_(b'capability exchange failed')) return peer