# commandserver.py - communicate with Mercurial's API over a pipe # # Copyright 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 errno import gc import os import random import signal import socket import struct import traceback try: import selectors selectors.BaseSelector except ImportError: from .thirdparty import selectors2 as selectors from .i18n import _ from . import ( encoding, error, pycompat, util, ) from .utils import ( procutil, ) logfile = None def log(*args): if not logfile: return for a in args: logfile.write(str(a)) logfile.flush() class channeledoutput(object): """ Write data to out in the following format: data length (unsigned int), data """ def __init__(self, out, channel): self.out = out self.channel = channel @property def name(self): return '<%c-channel>' % self.channel def write(self, data): if not data: return # single write() to guarantee the same atomicity as the underlying file self.out.write(struct.pack('>cI', self.channel, len(data)) + data) self.out.flush() def __getattr__(self, attr): if attr in ('isatty', 'fileno', 'tell', 'seek'): raise AttributeError(attr) return getattr(self.out, attr) class channeledinput(object): """ Read data from in_. Requests for input are written to out in the following format: channel identifier - 'I' for plain input, 'L' line based (1 byte) how many bytes to send at most (unsigned int), The client replies with: data length (unsigned int), 0 meaning EOF data """ maxchunksize = 4 * 1024 def __init__(self, in_, out, channel): self.in_ = in_ self.out = out self.channel = channel @property def name(self): return '<%c-channel>' % self.channel def read(self, size=-1): if size < 0: # if we need to consume all the clients input, ask for 4k chunks # so the pipe doesn't fill up risking a deadlock size = self.maxchunksize s = self._read(size, self.channel) buf = s while s: s = self._read(size, self.channel) buf += s return buf else: return self._read(size, self.channel) def _read(self, size, channel): if not size: return '' assert size > 0 # tell the client we need at most size bytes self.out.write(struct.pack('>cI', channel, size)) self.out.flush() length = self.in_.read(4) length = struct.unpack('>I', length)[0] if not length: return '' else: return self.in_.read(length) def readline(self, size=-1): if size < 0: size = self.maxchunksize s = self._read(size, 'L') buf = s # keep asking for more until there's either no more or # we got a full line while s and s[-1] != '\n': s = self._read(size, 'L') buf += s return buf else: return self._read(size, 'L') def __iter__(self): return self def next(self): l = self.readline() if not l: raise StopIteration return l def __getattr__(self, attr): if attr in ('isatty', 'fileno', 'tell', 'seek'): raise AttributeError(attr) return getattr(self.in_, attr) class server(object): """ Listens for commands on fin, runs them and writes the output on a channel based stream to fout. """ def __init__(self, ui, repo, fin, fout): self.cwd = pycompat.getcwd() # developer config: cmdserver.log logpath = ui.config("cmdserver", "log") if logpath: global logfile if logpath == '-': # write log on a special 'd' (debug) channel logfile = channeledoutput(fout, 'd') else: logfile = open(logpath, 'a') if repo: # the ui here is really the repo ui so take its baseui so we don't # end up with its local configuration self.ui = repo.baseui self.repo = repo self.repoui = repo.ui else: self.ui = ui self.repo = self.repoui = None self.cerr = channeledoutput(fout, 'e') self.cout = channeledoutput(fout, 'o') self.cin = channeledinput(fin, fout, 'I') self.cresult = channeledoutput(fout, 'r') self.client = fin def cleanup(self): """release and restore resources taken during server session""" def _read(self, size): if not size: return '' data = self.client.read(size) # is the other end closed? if not data: raise EOFError return data def _readstr(self): """read a string from the channel format: data length (uint32), data """ length = struct.unpack('>I', self._read(4))[0] if not length: return '' return self._read(length) def _readlist(self): """read a list of NULL separated strings from the channel""" s = self._readstr() if s: return s.split('\0') else: return [] def runcommand(self): """ reads a list of \0 terminated arguments, executes and writes the return code to the result channel """ from . import dispatch # avoid cycle args = self._readlist() # copy the uis so changes (e.g. --config or --verbose) don't # persist between requests copiedui = self.ui.copy() uis = [copiedui] if self.repo: self.repo.baseui = copiedui # clone ui without using ui.copy because this is protected repoui = self.repoui.__class__(self.repoui) repoui.copy = copiedui.copy # redo copy protection uis.append(repoui) self.repo.ui = self.repo.dirstate._ui = repoui self.repo.invalidateall() for ui in uis: ui.resetstate() # any kind of interaction must use server channels, but chg may # replace channels by fully functional tty files. so nontty is # enforced only if cin is a channel. if not util.safehasattr(self.cin, 'fileno'): ui.setconfig('ui', 'nontty', 'true', 'commandserver') req = dispatch.request(args[:], copiedui, self.repo, self.cin, self.cout, self.cerr) try: ret = dispatch.dispatch(req) & 255 self.cresult.write(struct.pack('>i', int(ret))) finally: # restore old cwd if '--cwd' in args: os.chdir(self.cwd) def getencoding(self): """ writes the current encoding to the result channel """ self.cresult.write(encoding.encoding) def serveone(self): cmd = self.client.readline()[:-1] if cmd: handler = self.capabilities.get(cmd) if handler: handler(self) else: # clients are expected to check what commands are supported by # looking at the servers capabilities raise error.Abort(_('unknown command %s') % cmd) return cmd != '' capabilities = {'runcommand': runcommand, 'getencoding': getencoding} def serve(self): hellomsg = 'capabilities: ' + ' '.join(sorted(self.capabilities)) hellomsg += '\n' hellomsg += 'encoding: ' + encoding.encoding hellomsg += '\n' hellomsg += 'pid: %d' % procutil.getpid() if util.safehasattr(os, 'getpgid'): hellomsg += '\n' hellomsg += 'pgid: %d' % os.getpgid(0) # write the hello msg in -one- chunk self.cout.write(hellomsg) try: while self.serveone(): pass except EOFError: # we'll get here if the client disconnected while we were reading # its request return 1 return 0 class pipeservice(object): def __init__(self, ui, repo, opts): self.ui = ui self.repo = repo def init(self): pass def run(self): ui = self.ui # redirect stdio to null device so that broken extensions or in-process # hooks will never cause corruption of channel protocol. with procutil.protectedstdio(ui.fin, ui.fout) as (fin, fout): try: sv = server(ui, self.repo, fin, fout) return sv.serve() finally: sv.cleanup() def _initworkerprocess(): # use a different process group from the master process, in order to: # 1. make the current process group no longer "orphaned" (because the # parent of this process is in a different process group while # remains in a same session) # according to POSIX 2.2.2.52, orphaned process group will ignore # terminal-generated stop signals like SIGTSTP (Ctrl+Z), which will # cause trouble for things like ncurses. # 2. the client can use kill(-pgid, sig) to simulate terminal-generated # SIGINT (Ctrl+C) and process-exit-generated SIGHUP. our child # processes like ssh will be killed properly, without affecting # unrelated processes. os.setpgid(0, 0) # change random state otherwise forked request handlers would have a # same state inherited from parent. random.seed() def _serverequest(ui, repo, conn, createcmdserver): fin = conn.makefile('rb') fout = conn.makefile('wb') sv = None try: sv = createcmdserver(repo, conn, fin, fout) try: sv.serve() # handle exceptions that may be raised by command server. most of # known exceptions are caught by dispatch. except error.Abort as inst: ui.warn(_('abort: %s\n') % inst) except IOError as inst: if inst.errno != errno.EPIPE: raise except KeyboardInterrupt: pass finally: sv.cleanup() except: # re-raises # also write traceback to error channel. otherwise client cannot # see it because it is written to server's stderr by default. if sv: cerr = sv.cerr else: cerr = channeledoutput(fout, 'e') traceback.print_exc(file=cerr) raise finally: fin.close() try: fout.close() # implicit flush() may cause another EPIPE except IOError as inst: if inst.errno != errno.EPIPE: raise class unixservicehandler(object): """Set of pluggable operations for unix-mode services Almost all methods except for createcmdserver() are called in the main process. You can't pass mutable resource back from createcmdserver(). """ pollinterval = None def __init__(self, ui): self.ui = ui def bindsocket(self, sock, address): util.bindunixsocket(sock, address) sock.listen(socket.SOMAXCONN) self.ui.status(_('listening at %s\n') % address) self.ui.flush() # avoid buffering of status message def unlinksocket(self, address): os.unlink(address) def shouldexit(self): """True if server should shut down; checked per pollinterval""" return False def newconnection(self): """Called when main process notices new connection""" def createcmdserver(self, repo, conn, fin, fout): """Create new command server instance; called in the process that serves for the current connection""" return server(self.ui, repo, fin, fout) class unixforkingservice(object): """ Listens on unix domain socket and forks server per connection """ def __init__(self, ui, repo, opts, handler=None): self.ui = ui self.repo = repo self.address = opts['address'] if not util.safehasattr(socket, 'AF_UNIX'): raise error.Abort(_('unsupported platform')) if not self.address: raise error.Abort(_('no socket path specified with --address')) self._servicehandler = handler or unixservicehandler(ui) self._sock = None self._oldsigchldhandler = None self._workerpids = set() # updated by signal handler; do not iterate self._socketunlinked = None def init(self): self._sock = socket.socket(socket.AF_UNIX) self._servicehandler.bindsocket(self._sock, self.address) if util.safehasattr(procutil, 'unblocksignal'): procutil.unblocksignal(signal.SIGCHLD) o = signal.signal(signal.SIGCHLD, self._sigchldhandler) self._oldsigchldhandler = o self._socketunlinked = False def _unlinksocket(self): if not self._socketunlinked: self._servicehandler.unlinksocket(self.address) self._socketunlinked = True def _cleanup(self): signal.signal(signal.SIGCHLD, self._oldsigchldhandler) self._sock.close() self._unlinksocket() # don't kill child processes as they have active clients, just wait self._reapworkers(0) def run(self): try: self._mainloop() finally: self._cleanup() def _mainloop(self): exiting = False h = self._servicehandler selector = selectors.DefaultSelector() selector.register(self._sock, selectors.EVENT_READ) while True: if not exiting and h.shouldexit(): # clients can no longer connect() to the domain socket, so # we stop queuing new requests. # for requests that are queued (connect()-ed, but haven't been # accept()-ed), handle them before exit. otherwise, clients # waiting for recv() will receive ECONNRESET. self._unlinksocket() exiting = True ready = selector.select(timeout=h.pollinterval) if not ready: # only exit if we completed all queued requests if exiting: break continue try: conn, _addr = self._sock.accept() except socket.error as inst: if inst.args[0] == errno.EINTR: continue raise pid = os.fork() if pid: try: self.ui.debug('forked worker process (pid=%d)\n' % pid) self._workerpids.add(pid) h.newconnection() finally: conn.close() # release handle in parent process else: try: self._runworker(conn) conn.close() os._exit(0) except: # never return, hence no re-raises try: self.ui.traceback(force=True) finally: os._exit(255) selector.close() def _sigchldhandler(self, signal, frame): self._reapworkers(os.WNOHANG) def _reapworkers(self, options): while self._workerpids: try: pid, _status = os.waitpid(-1, options) except OSError as inst: if inst.errno == errno.EINTR: continue if inst.errno != errno.ECHILD: raise # no child processes at all (reaped by other waitpid()?) self._workerpids.clear() return if pid == 0: # no waitable child processes return self.ui.debug('worker process exited (pid=%d)\n' % pid) self._workerpids.discard(pid) def _runworker(self, conn): signal.signal(signal.SIGCHLD, self._oldsigchldhandler) _initworkerprocess() h = self._servicehandler try: _serverequest(self.ui, self.repo, conn, h.createcmdserver) finally: gc.collect() # trigger __del__ since worker process uses os._exit