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SickRage/tornado/process.py

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#!/usr/bin/env python
#
# Copyright 2011 Facebook
#
# Licensed under the Apache License, Version 2.0 (the "License"); you may
# not use this file except in compliance with the License. You may obtain
# a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
# WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
# License for the specific language governing permissions and limitations
# under the License.
"""Utilities for working with multiple processes, including both forking
the server into multiple processes and managing subprocesses.
"""
from __future__ import absolute_import, division, print_function, with_statement
import errno
import os
import signal
import subprocess
import sys
import time
from binascii import hexlify
from tornado import ioloop
from tornado.iostream import PipeIOStream
from tornado.log import gen_log
from tornado.platform.auto import set_close_exec
from tornado import stack_context
from tornado.util import errno_from_exception
try:
import multiprocessing
except ImportError:
# Multiprocessing is not available on Google App Engine.
multiprocessing = None
try:
long # py2
except NameError:
long = int # py3
def cpu_count():
"""Returns the number of processors on this machine."""
if multiprocessing is None:
return 1
try:
return multiprocessing.cpu_count()
except NotImplementedError:
pass
try:
return os.sysconf("SC_NPROCESSORS_CONF")
except ValueError:
pass
gen_log.error("Could not detect number of processors; assuming 1")
return 1
def _reseed_random():
if 'random' not in sys.modules:
return
import random
# If os.urandom is available, this method does the same thing as
# random.seed (at least as of python 2.6). If os.urandom is not
# available, we mix in the pid in addition to a timestamp.
try:
seed = long(hexlify(os.urandom(16)), 16)
except NotImplementedError:
seed = int(time.time() * 1000) ^ os.getpid()
random.seed(seed)
def _pipe_cloexec():
r, w = os.pipe()
set_close_exec(r)
set_close_exec(w)
return r, w
_task_id = None
def fork_processes(num_processes, max_restarts=100):
"""Starts multiple worker processes.
If ``num_processes`` is None or <= 0, we detect the number of cores
available on this machine and fork that number of child
processes. If ``num_processes`` is given and > 0, we fork that
specific number of sub-processes.
Since we use processes and not threads, there is no shared memory
between any server code.
Note that multiple processes are not compatible with the autoreload
module (or the ``autoreload=True`` option to `tornado.web.Application`
which defaults to True when ``debug=True``).
When using multiple processes, no IOLoops can be created or
referenced until after the call to ``fork_processes``.
In each child process, ``fork_processes`` returns its *task id*, a
number between 0 and ``num_processes``. Processes that exit
abnormally (due to a signal or non-zero exit status) are restarted
with the same id (up to ``max_restarts`` times). In the parent
process, ``fork_processes`` returns None if all child processes
have exited normally, but will otherwise only exit by throwing an
exception.
"""
global _task_id
assert _task_id is None
if num_processes is None or num_processes <= 0:
num_processes = cpu_count()
if ioloop.IOLoop.initialized():
raise RuntimeError("Cannot run in multiple processes: IOLoop instance "
"has already been initialized. You cannot call "
"IOLoop.instance() before calling start_processes()")
gen_log.info("Starting %d processes", num_processes)
children = {}
def start_child(i):
pid = os.fork()
if pid == 0:
# child process
_reseed_random()
global _task_id
_task_id = i
return i
else:
children[pid] = i
return None
for i in range(num_processes):
id = start_child(i)
if id is not None:
return id
num_restarts = 0
while children:
try:
pid, status = os.wait()
except OSError as e:
if errno_from_exception(e) == errno.EINTR:
continue
raise
if pid not in children:
continue
id = children.pop(pid)
if os.WIFSIGNALED(status):
gen_log.warning("child %d (pid %d) killed by signal %d, restarting",
id, pid, os.WTERMSIG(status))
elif os.WEXITSTATUS(status) != 0:
gen_log.warning("child %d (pid %d) exited with status %d, restarting",
id, pid, os.WEXITSTATUS(status))
else:
gen_log.info("child %d (pid %d) exited normally", id, pid)
continue
num_restarts += 1
if num_restarts > max_restarts:
raise RuntimeError("Too many child restarts, giving up")
new_id = start_child(id)
if new_id is not None:
return new_id
# All child processes exited cleanly, so exit the master process
# instead of just returning to right after the call to
# fork_processes (which will probably just start up another IOLoop
# unless the caller checks the return value).
sys.exit(0)
def task_id():
"""Returns the current task id, if any.
Returns None if this process was not created by `fork_processes`.
"""
global _task_id
return _task_id
class Subprocess(object):
"""Wraps ``subprocess.Popen`` with IOStream support.
The constructor is the same as ``subprocess.Popen`` with the following
additions:
* ``stdin``, ``stdout``, and ``stderr`` may have the value
``tornado.process.Subprocess.STREAM``, which will make the corresponding
attribute of the resulting Subprocess a `.PipeIOStream`.
* A new keyword argument ``io_loop`` may be used to pass in an IOLoop.
"""
STREAM = object()
_initialized = False
_waiting = {}
def __init__(self, *args, **kwargs):
self.io_loop = kwargs.pop('io_loop', None) or ioloop.IOLoop.current()
# All FDs we create should be closed on error; those in to_close
# should be closed in the parent process on success.
pipe_fds = []
to_close = []
if kwargs.get('stdin') is Subprocess.STREAM:
in_r, in_w = _pipe_cloexec()
kwargs['stdin'] = in_r
pipe_fds.extend((in_r, in_w))
to_close.append(in_r)
self.stdin = PipeIOStream(in_w, io_loop=self.io_loop)
if kwargs.get('stdout') is Subprocess.STREAM:
out_r, out_w = _pipe_cloexec()
kwargs['stdout'] = out_w
pipe_fds.extend((out_r, out_w))
to_close.append(out_w)
self.stdout = PipeIOStream(out_r, io_loop=self.io_loop)
if kwargs.get('stderr') is Subprocess.STREAM:
err_r, err_w = _pipe_cloexec()
kwargs['stderr'] = err_w
pipe_fds.extend((err_r, err_w))
to_close.append(err_w)
self.stderr = PipeIOStream(err_r, io_loop=self.io_loop)
try:
self.proc = subprocess.Popen(*args, **kwargs)
except:
for fd in pipe_fds:
os.close(fd)
raise
for fd in to_close:
os.close(fd)
for attr in ['stdin', 'stdout', 'stderr', 'pid']:
if not hasattr(self, attr): # don't clobber streams set above
setattr(self, attr, getattr(self.proc, attr))
self._exit_callback = None
self.returncode = None
def set_exit_callback(self, callback):
"""Runs ``callback`` when this process exits.
The callback takes one argument, the return code of the process.
This method uses a ``SIGCHLD`` handler, which is a global setting
and may conflict if you have other libraries trying to handle the
same signal. If you are using more than one ``IOLoop`` it may
be necessary to call `Subprocess.initialize` first to designate
one ``IOLoop`` to run the signal handlers.
In many cases a close callback on the stdout or stderr streams
can be used as an alternative to an exit callback if the
signal handler is causing a problem.
"""
self._exit_callback = stack_context.wrap(callback)
Subprocess.initialize(self.io_loop)
Subprocess._waiting[self.pid] = self
Subprocess._try_cleanup_process(self.pid)
@classmethod
def initialize(cls, io_loop=None):
"""Initializes the ``SIGCHLD`` handler.
The signal handler is run on an `.IOLoop` to avoid locking issues.
Note that the `.IOLoop` used for signal handling need not be the
same one used by individual Subprocess objects (as long as the
``IOLoops`` are each running in separate threads).
"""
if cls._initialized:
return
if io_loop is None:
io_loop = ioloop.IOLoop.current()
cls._old_sigchld = signal.signal(
signal.SIGCHLD,
lambda sig, frame: io_loop.add_callback_from_signal(cls._cleanup))
cls._initialized = True
@classmethod
def uninitialize(cls):
"""Removes the ``SIGCHLD`` handler."""
if not cls._initialized:
return
signal.signal(signal.SIGCHLD, cls._old_sigchld)
cls._initialized = False
@classmethod
def _cleanup(cls):
for pid in list(cls._waiting.keys()): # make a copy
cls._try_cleanup_process(pid)
@classmethod
def _try_cleanup_process(cls, pid):
try:
ret_pid, status = os.waitpid(pid, os.WNOHANG)
except OSError as e:
if errno_from_exception(e) == errno.ECHILD:
return
if ret_pid == 0:
return
assert ret_pid == pid
subproc = cls._waiting.pop(pid)
subproc.io_loop.add_callback_from_signal(
subproc._set_returncode, status)
def _set_returncode(self, status):
if os.WIFSIGNALED(status):
self.returncode = -os.WTERMSIG(status)
else:
assert os.WIFEXITED(status)
self.returncode = os.WEXITSTATUS(status)
if self._exit_callback:
callback = self._exit_callback
self._exit_callback = None
callback(self.returncode)