# vim: tabstop=4 shiftwidth=4 softtabstop=4 # Copyright 2013 Red Hat, Inc. # # 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. import eventlet import eventlet.event import eventlet.queue import eventlet.timeout from neutron.agent.linux import utils from neutron.openstack.common import log as logging LOG = logging.getLogger(__name__) class AsyncProcessException(Exception): pass class AsyncProcess(object): """Manages an asynchronous process. This class spawns a new process via subprocess and uses greenthreads to read stderr and stdout asynchronously into queues that can be read via repeatedly calling iter_stdout() and iter_stderr(). If respawn_interval is non-zero, any error in communicating with the managed process will result in the process and greenthreads being cleaned up and the process restarted after the specified interval. Example usage: >>> import time >>> proc = AsyncProcess(['ping']) >>> proc.start() >>> time.sleep(5) >>> proc.stop() >>> for line in proc.iter_stdout(): ... print line """ def __init__(self, cmd, root_helper=None, respawn_interval=None): """Constructor. :param cmd: The list of command arguments to invoke. :param root_helper: Optional, utility to use when running shell cmds. :param respawn_interval: Optional, the interval in seconds to wait to respawn after unexpected process death. Respawn will only be attempted if a value of 0 or greater is provided. """ self.cmd = cmd self.root_helper = root_helper if respawn_interval is not None and respawn_interval < 0: raise ValueError(_('respawn_interval must be >= 0 if provided.')) self.respawn_interval = respawn_interval self._process = None self._kill_event = None self._reset_queues() self._watchers = [] def _reset_queues(self): self._stdout_lines = eventlet.queue.LightQueue() self._stderr_lines = eventlet.queue.LightQueue() def start(self): """Launch a process and monitor it asynchronously.""" if self._kill_event: raise AsyncProcessException(_('Process is already started')) else: LOG.debug(_('Launching async process [%s].'), self.cmd) self._spawn() def stop(self): """Halt the process and watcher threads.""" if self._kill_event: LOG.debug(_('Halting async process [%s].'), self.cmd) self._kill() else: raise AsyncProcessException(_('Process is not running.')) def _spawn(self): """Spawn a process and its watchers.""" self._kill_event = eventlet.event.Event() self._process, cmd = utils.create_process(self.cmd, root_helper=self.root_helper) self._watchers = [] for reader in (self._read_stdout, self._read_stderr): # Pass the stop event directly to the greenthread to # ensure that assignment of a new event to the instance # attribute does not prevent the greenthread from using # the original event. watcher = eventlet.spawn(self._watch_process, reader, self._kill_event) self._watchers.append(watcher) def _kill(self, respawning=False): """Kill the process and the associated watcher greenthreads. :param respawning: Optional, whether respawn will be subsequently attempted. """ # Halt the greenthreads self._kill_event.send() pid = self._get_pid_to_kill() if pid: self._kill_process(pid) if not respawning: # Clear the kill event to ensure the process can be # explicitly started again. self._kill_event = None def _get_pid_to_kill(self): pid = self._process.pid # If root helper was used, two or more processes will be created: # # - a root helper process (e.g. sudo myscript) # - possibly a rootwrap script (e.g. neutron-rootwrap) # - a child process (e.g. myscript) # # Killing the root helper process will leave the child process # running, re-parented to init, so the only way to ensure that both # die is to target the child process directly. if self.root_helper: try: pid = utils.find_child_pids(pid)[0] except IndexError: # Process is already dead return None while True: try: # We shouldn't have more than one child per process # so keep getting the children of the first one pid = utils.find_child_pids(pid)[0] except IndexError: # Last process in the tree, return it break return pid def _kill_process(self, pid): try: # A process started by a root helper will be running as # root and need to be killed via the same helper. utils.execute(['kill', '-9', pid], root_helper=self.root_helper) except Exception as ex: stale_pid = (isinstance(ex, RuntimeError) and 'No such process' in str(ex)) if not stale_pid: LOG.exception(_('An error occurred while killing [%s].'), self.cmd) return False return True def _handle_process_error(self): """Kill the async process and respawn if necessary.""" LOG.debug(_('Halting async process [%s] in response to an error.'), self.cmd) respawning = self.respawn_interval >= 0 self._kill(respawning=respawning) if respawning: eventlet.sleep(self.respawn_interval) LOG.debug(_('Respawning async process [%s].'), self.cmd) self._spawn() def _watch_process(self, callback, kill_event): while not kill_event.ready(): try: if not callback(): break except Exception: LOG.exception(_('An error occurred while communicating ' 'with async process [%s].'), self.cmd) break # Ensure that watching a process with lots of output does # not block execution of other greenthreads. eventlet.sleep() # The kill event not being ready indicates that the loop was # broken out of due to an error in the watched process rather # than the loop condition being satisfied. if not kill_event.ready(): self._handle_process_error() def _read(self, stream, queue): data = stream.readline() if data: data = data.strip() queue.put(data) return data def _read_stdout(self): return self._read(self._process.stdout, self._stdout_lines) def _read_stderr(self): return self._read(self._process.stderr, self._stderr_lines) def _iter_queue(self, queue): while True: try: yield queue.get_nowait() except eventlet.queue.Empty: break def iter_stdout(self): return self._iter_queue(self._stdout_lines) def iter_stderr(self): return self._iter_queue(self._stderr_lines)