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First version of cluster web service....
First version of cluster web service. This exposes ipcluster's over the web. The current implementation uses IPClusterLauncher to run ipcluster in a separate process. Here is the URL scheme we are using: GET /clusters => list available clusters GET /cluster/profile => list info for cluster with profile POST /cluster/profile/start => start a cluster POST /cluster/profile/stop => stop a cluster

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kernelmanager.py
312 lines | 10.7 KiB | text/x-python | PythonLexer
"""A kernel manager for multiple kernels.
Authors:
* Brian Granger
"""
#-----------------------------------------------------------------------------
# Copyright (C) 2008-2011 The IPython Development Team
#
# Distributed under the terms of the BSD License. The full license is in
# the file COPYING, distributed as part of this software.
#-----------------------------------------------------------------------------
#-----------------------------------------------------------------------------
# Imports
#-----------------------------------------------------------------------------
import os
import signal
import sys
import uuid
import zmq
from zmq.eventloop.zmqstream import ZMQStream
from tornado import web
from IPython.config.configurable import LoggingConfigurable
from IPython.zmq.ipkernel import launch_kernel
from IPython.zmq.kernelmanager import KernelManager
from IPython.utils.traitlets import Instance, Dict, List, Unicode, Float, Integer
#-----------------------------------------------------------------------------
# Classes
#-----------------------------------------------------------------------------
class DuplicateKernelError(Exception):
pass
class MultiKernelManager(LoggingConfigurable):
"""A class for managing multiple kernels."""
context = Instance('zmq.Context')
def _context_default(self):
return zmq.Context.instance()
connection_dir = Unicode('')
_kernels = Dict()
@property
def kernel_ids(self):
"""Return a list of the kernel ids of the active kernels."""
return self._kernels.keys()
def __len__(self):
"""Return the number of running kernels."""
return len(self.kernel_ids)
def __contains__(self, kernel_id):
if kernel_id in self.kernel_ids:
return True
else:
return False
def start_kernel(self, **kwargs):
"""Start a new kernel."""
kernel_id = unicode(uuid.uuid4())
# use base KernelManager for each Kernel
km = KernelManager(connection_file=os.path.join(
self.connection_dir, "kernel-%s.json" % kernel_id),
config=self.config,
)
km.start_kernel(**kwargs)
self._kernels[kernel_id] = km
return kernel_id
def kill_kernel(self, kernel_id):
"""Kill a kernel by its kernel uuid.
Parameters
==========
kernel_id : uuid
The id of the kernel to kill.
"""
self.get_kernel(kernel_id).kill_kernel()
del self._kernels[kernel_id]
def interrupt_kernel(self, kernel_id):
"""Interrupt (SIGINT) the kernel by its uuid.
Parameters
==========
kernel_id : uuid
The id of the kernel to interrupt.
"""
return self.get_kernel(kernel_id).interrupt_kernel()
def signal_kernel(self, kernel_id, signum):
""" Sends a signal to the kernel by its uuid.
Note that since only SIGTERM is supported on Windows, this function
is only useful on Unix systems.
Parameters
==========
kernel_id : uuid
The id of the kernel to signal.
"""
return self.get_kernel(kernel_id).signal_kernel(signum)
def get_kernel(self, kernel_id):
"""Get the single KernelManager object for a kernel by its uuid.
Parameters
==========
kernel_id : uuid
The id of the kernel.
"""
km = self._kernels.get(kernel_id)
if km is not None:
return km
else:
raise KeyError("Kernel with id not found: %s" % kernel_id)
def get_kernel_ports(self, kernel_id):
"""Return a dictionary of ports for a kernel.
Parameters
==========
kernel_id : uuid
The id of the kernel.
Returns
=======
port_dict : dict
A dict of key, value pairs where the keys are the names
(stdin_port,iopub_port,shell_port) and the values are the
integer port numbers for those channels.
"""
# this will raise a KeyError if not found:
km = self.get_kernel(kernel_id)
return dict(shell_port=km.shell_port,
iopub_port=km.iopub_port,
stdin_port=km.stdin_port,
hb_port=km.hb_port,
)
def get_kernel_ip(self, kernel_id):
"""Return ip address for a kernel.
Parameters
==========
kernel_id : uuid
The id of the kernel.
Returns
=======
ip : str
The ip address of the kernel.
"""
return self.get_kernel(kernel_id).ip
def create_connected_stream(self, ip, port, socket_type):
sock = self.context.socket(socket_type)
addr = "tcp://%s:%i" % (ip, port)
self.log.info("Connecting to: %s" % addr)
sock.connect(addr)
return ZMQStream(sock)
def create_iopub_stream(self, kernel_id):
ip = self.get_kernel_ip(kernel_id)
ports = self.get_kernel_ports(kernel_id)
iopub_stream = self.create_connected_stream(ip, ports['iopub_port'], zmq.SUB)
iopub_stream.socket.setsockopt(zmq.SUBSCRIBE, b'')
return iopub_stream
def create_shell_stream(self, kernel_id):
ip = self.get_kernel_ip(kernel_id)
ports = self.get_kernel_ports(kernel_id)
shell_stream = self.create_connected_stream(ip, ports['shell_port'], zmq.XREQ)
return shell_stream
def create_hb_stream(self, kernel_id):
ip = self.get_kernel_ip(kernel_id)
ports = self.get_kernel_ports(kernel_id)
hb_stream = self.create_connected_stream(ip, ports['hb_port'], zmq.REQ)
return hb_stream
class MappingKernelManager(MultiKernelManager):
"""A KernelManager that handles notebok mapping and HTTP error handling"""
kernel_argv = List(Unicode)
kernel_manager = Instance(KernelManager)
time_to_dead = Float(3.0, config=True, help="""Kernel heartbeat interval in seconds.""")
first_beat = Float(5.0, config=True, help="Delay (in seconds) before sending first heartbeat.")
max_msg_size = Integer(65536, config=True, help="""
The max raw message size accepted from the browser
over a WebSocket connection.
""")
_notebook_mapping = Dict()
#-------------------------------------------------------------------------
# Methods for managing kernels and sessions
#-------------------------------------------------------------------------
def kernel_for_notebook(self, notebook_id):
"""Return the kernel_id for a notebook_id or None."""
return self._notebook_mapping.get(notebook_id)
def set_kernel_for_notebook(self, notebook_id, kernel_id):
"""Associate a notebook with a kernel."""
if notebook_id is not None:
self._notebook_mapping[notebook_id] = kernel_id
def notebook_for_kernel(self, kernel_id):
"""Return the notebook_id for a kernel_id or None."""
notebook_ids = [k for k, v in self._notebook_mapping.iteritems() if v == kernel_id]
if len(notebook_ids) == 1:
return notebook_ids[0]
else:
return None
def delete_mapping_for_kernel(self, kernel_id):
"""Remove the kernel/notebook mapping for kernel_id."""
notebook_id = self.notebook_for_kernel(kernel_id)
if notebook_id is not None:
del self._notebook_mapping[notebook_id]
def start_kernel(self, notebook_id=None):
"""Start a kernel for a notebok an return its kernel_id.
Parameters
----------
notebook_id : uuid
The uuid of the notebook to associate the new kernel with. If this
is not None, this kernel will be persistent whenever the notebook
requests a kernel.
"""
kernel_id = self.kernel_for_notebook(notebook_id)
if kernel_id is None:
kwargs = dict()
kwargs['extra_arguments'] = self.kernel_argv
kernel_id = super(MappingKernelManager, self).start_kernel(**kwargs)
self.set_kernel_for_notebook(notebook_id, kernel_id)
self.log.info("Kernel started: %s" % kernel_id)
self.log.debug("Kernel args: %r" % kwargs)
else:
self.log.info("Using existing kernel: %s" % kernel_id)
return kernel_id
def kill_kernel(self, kernel_id):
"""Kill a kernel and remove its notebook association."""
self._check_kernel_id(kernel_id)
super(MappingKernelManager, self).kill_kernel(kernel_id)
self.delete_mapping_for_kernel(kernel_id)
self.log.info("Kernel killed: %s" % kernel_id)
def interrupt_kernel(self, kernel_id):
"""Interrupt a kernel."""
self._check_kernel_id(kernel_id)
super(MappingKernelManager, self).interrupt_kernel(kernel_id)
self.log.info("Kernel interrupted: %s" % kernel_id)
def restart_kernel(self, kernel_id):
"""Restart a kernel while keeping clients connected."""
self._check_kernel_id(kernel_id)
km = self.get_kernel(kernel_id)
km.restart_kernel(now=True)
self.log.info("Kernel restarted: %s" % kernel_id)
return kernel_id
# the following remains, in case the KM restart machinery is
# somehow unacceptable
# Get the notebook_id to preserve the kernel/notebook association.
notebook_id = self.notebook_for_kernel(kernel_id)
# Create the new kernel first so we can move the clients over.
new_kernel_id = self.start_kernel()
# Now kill the old kernel.
self.kill_kernel(kernel_id)
# Now save the new kernel/notebook association. We have to save it
# after the old kernel is killed as that will delete the mapping.
self.set_kernel_for_notebook(notebook_id, new_kernel_id)
self.log.info("Kernel restarted: %s" % new_kernel_id)
return new_kernel_id
def create_iopub_stream(self, kernel_id):
"""Create a new iopub stream."""
self._check_kernel_id(kernel_id)
return super(MappingKernelManager, self).create_iopub_stream(kernel_id)
def create_shell_stream(self, kernel_id):
"""Create a new shell stream."""
self._check_kernel_id(kernel_id)
return super(MappingKernelManager, self).create_shell_stream(kernel_id)
def create_hb_stream(self, kernel_id):
"""Create a new hb stream."""
self._check_kernel_id(kernel_id)
return super(MappingKernelManager, self).create_hb_stream(kernel_id)
def _check_kernel_id(self, kernel_id):
"""Check a that a kernel_id exists and raise 404 if not."""
if kernel_id not in self:
raise web.HTTPError(404, u'Kernel does not exist: %s' % kernel_id)