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Merge pull request #6810 from minrk/system-wide-config add system-wide IPython config

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asyncresult.py
703 lines | 24.1 KiB | text/x-python | PythonLexer
"""AsyncResult objects for the client"""
# Copyright (c) IPython Development Team.
# Distributed under the terms of the Modified BSD License.
from __future__ import print_function
import sys
import time
from datetime import datetime
from zmq import MessageTracker
from IPython.core.display import clear_output, display, display_pretty
from IPython.external.decorator import decorator
from IPython.parallel import error
from IPython.utils.py3compat import string_types
def _raw_text(s):
display_pretty(s, raw=True)
# global empty tracker that's always done:
finished_tracker = MessageTracker()
@decorator
def check_ready(f, self, *args, **kwargs):
"""Call spin() to sync state prior to calling the method."""
self.wait(0)
if not self._ready:
raise error.TimeoutError("result not ready")
return f(self, *args, **kwargs)
class AsyncResult(object):
"""Class for representing results of non-blocking calls.
Provides the same interface as :py:class:`multiprocessing.pool.AsyncResult`.
"""
msg_ids = None
_targets = None
_tracker = None
_single_result = False
owner = False,
def __init__(self, client, msg_ids, fname='unknown', targets=None, tracker=None,
owner=False,
):
if isinstance(msg_ids, string_types):
# always a list
msg_ids = [msg_ids]
self._single_result = True
else:
self._single_result = False
if tracker is None:
# default to always done
tracker = finished_tracker
self._client = client
self.msg_ids = msg_ids
self._fname=fname
self._targets = targets
self._tracker = tracker
self.owner = owner
self._ready = False
self._outputs_ready = False
self._success = None
self._metadata = [self._client.metadata[id] for id in self.msg_ids]
def __repr__(self):
if self._ready:
return "<%s: finished>"%(self.__class__.__name__)
else:
return "<%s: %s>"%(self.__class__.__name__,self._fname)
def _reconstruct_result(self, res):
"""Reconstruct our result from actual result list (always a list)
Override me in subclasses for turning a list of results
into the expected form.
"""
if self._single_result:
return res[0]
else:
return res
def get(self, timeout=-1):
"""Return the result when it arrives.
If `timeout` is not ``None`` and the result does not arrive within
`timeout` seconds then ``TimeoutError`` is raised. If the
remote call raised an exception then that exception will be reraised
by get() inside a `RemoteError`.
"""
if not self.ready():
self.wait(timeout)
if self._ready:
if self._success:
return self._result
else:
raise self._exception
else:
raise error.TimeoutError("Result not ready.")
def _check_ready(self):
if not self.ready():
raise error.TimeoutError("Result not ready.")
def ready(self):
"""Return whether the call has completed."""
if not self._ready:
self.wait(0)
elif not self._outputs_ready:
self._wait_for_outputs(0)
return self._ready
def wait(self, timeout=-1):
"""Wait until the result is available or until `timeout` seconds pass.
This method always returns None.
"""
if self._ready:
self._wait_for_outputs(timeout)
return
self._ready = self._client.wait(self.msg_ids, timeout)
if self._ready:
try:
results = list(map(self._client.results.get, self.msg_ids))
self._result = results
if self._single_result:
r = results[0]
if isinstance(r, Exception):
raise r
else:
results = error.collect_exceptions(results, self._fname)
self._result = self._reconstruct_result(results)
except Exception as e:
self._exception = e
self._success = False
else:
self._success = True
finally:
if timeout is None or timeout < 0:
# cutoff infinite wait at 10s
timeout = 10
self._wait_for_outputs(timeout)
if self.owner:
self._metadata = [self._client.metadata.pop(mid) for mid in self.msg_ids]
[self._client.results.pop(mid) for mid in self.msg_ids]
def successful(self):
"""Return whether the call completed without raising an exception.
Will raise ``AssertionError`` if the result is not ready.
"""
assert self.ready()
return self._success
#----------------------------------------------------------------
# Extra methods not in mp.pool.AsyncResult
#----------------------------------------------------------------
def get_dict(self, timeout=-1):
"""Get the results as a dict, keyed by engine_id.
timeout behavior is described in `get()`.
"""
results = self.get(timeout)
if self._single_result:
results = [results]
engine_ids = [ md['engine_id'] for md in self._metadata ]
rdict = {}
for engine_id, result in zip(engine_ids, results):
if engine_id in rdict:
raise ValueError("Cannot build dict, %i jobs ran on engine #%i" % (
engine_ids.count(engine_id), engine_id)
)
else:
rdict[engine_id] = result
return rdict
@property
def result(self):
"""result property wrapper for `get(timeout=-1)`."""
return self.get()
# abbreviated alias:
r = result
@property
def metadata(self):
"""property for accessing execution metadata."""
if self._single_result:
return self._metadata[0]
else:
return self._metadata
@property
def result_dict(self):
"""result property as a dict."""
return self.get_dict()
def __dict__(self):
return self.get_dict(0)
def abort(self):
"""abort my tasks."""
assert not self.ready(), "Can't abort, I am already done!"
return self._client.abort(self.msg_ids, targets=self._targets, block=True)
@property
def sent(self):
"""check whether my messages have been sent."""
return self._tracker.done
def wait_for_send(self, timeout=-1):
"""wait for pyzmq send to complete.
This is necessary when sending arrays that you intend to edit in-place.
`timeout` is in seconds, and will raise TimeoutError if it is reached
before the send completes.
"""
return self._tracker.wait(timeout)
#-------------------------------------
# dict-access
#-------------------------------------
def __getitem__(self, key):
"""getitem returns result value(s) if keyed by int/slice, or metadata if key is str.
"""
if isinstance(key, int):
self._check_ready()
return error.collect_exceptions([self._result[key]], self._fname)[0]
elif isinstance(key, slice):
self._check_ready()
return error.collect_exceptions(self._result[key], self._fname)
elif isinstance(key, string_types):
# metadata proxy *does not* require that results are done
self.wait(0)
values = [ md[key] for md in self._metadata ]
if self._single_result:
return values[0]
else:
return values
else:
raise TypeError("Invalid key type %r, must be 'int','slice', or 'str'"%type(key))
def __getattr__(self, key):
"""getattr maps to getitem for convenient attr access to metadata."""
try:
return self.__getitem__(key)
except (error.TimeoutError, KeyError):
raise AttributeError("%r object has no attribute %r"%(
self.__class__.__name__, key))
# asynchronous iterator:
def __iter__(self):
if self._single_result:
raise TypeError("AsyncResults with a single result are not iterable.")
try:
rlist = self.get(0)
except error.TimeoutError:
# wait for each result individually
for msg_id in self.msg_ids:
ar = AsyncResult(self._client, msg_id, self._fname)
yield ar.get()
else:
# already done
for r in rlist:
yield r
def __len__(self):
return len(self.msg_ids)
#-------------------------------------
# Sugar methods and attributes
#-------------------------------------
def timedelta(self, start, end, start_key=min, end_key=max):
"""compute the difference between two sets of timestamps
The default behavior is to use the earliest of the first
and the latest of the second list, but this can be changed
by passing a different
Parameters
----------
start : one or more datetime objects (e.g. ar.submitted)
end : one or more datetime objects (e.g. ar.received)
start_key : callable
Function to call on `start` to extract the relevant
entry [defalt: min]
end_key : callable
Function to call on `end` to extract the relevant
entry [default: max]
Returns
-------
dt : float
The time elapsed (in seconds) between the two selected timestamps.
"""
if not isinstance(start, datetime):
# handle single_result AsyncResults, where ar.stamp is single object,
# not a list
start = start_key(start)
if not isinstance(end, datetime):
# handle single_result AsyncResults, where ar.stamp is single object,
# not a list
end = end_key(end)
return (end - start).total_seconds()
@property
def progress(self):
"""the number of tasks which have been completed at this point.
Fractional progress would be given by 1.0 * ar.progress / len(ar)
"""
self.wait(0)
return len(self) - len(set(self.msg_ids).intersection(self._client.outstanding))
@property
def elapsed(self):
"""elapsed time since initial submission"""
if self.ready():
return self.wall_time
now = submitted = datetime.now()
for msg_id in self.msg_ids:
if msg_id in self._client.metadata:
stamp = self._client.metadata[msg_id]['submitted']
if stamp and stamp < submitted:
submitted = stamp
return (now-submitted).total_seconds()
@property
@check_ready
def serial_time(self):
"""serial computation time of a parallel calculation
Computed as the sum of (completed-started) of each task
"""
t = 0
for md in self._metadata:
t += (md['completed'] - md['started']).total_seconds()
return t
@property
@check_ready
def wall_time(self):
"""actual computation time of a parallel calculation
Computed as the time between the latest `received` stamp
and the earliest `submitted`.
Only reliable if Client was spinning/waiting when the task finished, because
the `received` timestamp is created when a result is pulled off of the zmq queue,
which happens as a result of `client.spin()`.
For similar comparison of other timestamp pairs, check out AsyncResult.timedelta.
"""
return self.timedelta(self.submitted, self.received)
def wait_interactive(self, interval=1., timeout=-1):
"""interactive wait, printing progress at regular intervals"""
if timeout is None:
timeout = -1
N = len(self)
tic = time.time()
while not self.ready() and (timeout < 0 or time.time() - tic <= timeout):
self.wait(interval)
clear_output(wait=True)
print("%4i/%i tasks finished after %4i s" % (self.progress, N, self.elapsed), end="")
sys.stdout.flush()
print()
print("done")
def _republish_displaypub(self, content, eid):
"""republish individual displaypub content dicts"""
try:
ip = get_ipython()
except NameError:
# displaypub is meaningless outside IPython
return
md = content['metadata'] or {}
md['engine'] = eid
ip.display_pub.publish(data=content['data'], metadata=md)
def _display_stream(self, text, prefix='', file=None):
if not text:
# nothing to display
return
if file is None:
file = sys.stdout
end = '' if text.endswith('\n') else '\n'
multiline = text.count('\n') > int(text.endswith('\n'))
if prefix and multiline and not text.startswith('\n'):
prefix = prefix + '\n'
print("%s%s" % (prefix, text), file=file, end=end)
def _display_single_result(self):
self._display_stream(self.stdout)
self._display_stream(self.stderr, file=sys.stderr)
try:
get_ipython()
except NameError:
# displaypub is meaningless outside IPython
return
for output in self.outputs:
self._republish_displaypub(output, self.engine_id)
if self.execute_result is not None:
display(self.get())
def _wait_for_outputs(self, timeout=-1):
"""wait for the 'status=idle' message that indicates we have all outputs
"""
if self._outputs_ready or not self._success:
# don't wait on errors
return
# cast None to -1 for infinite timeout
if timeout is None:
timeout = -1
tic = time.time()
while True:
self._client._flush_iopub(self._client._iopub_socket)
self._outputs_ready = all(md['outputs_ready']
for md in self._metadata)
if self._outputs_ready or \
(timeout >= 0 and time.time() > tic + timeout):
break
time.sleep(0.01)
@check_ready
def display_outputs(self, groupby="type"):
"""republish the outputs of the computation
Parameters
----------
groupby : str [default: type]
if 'type':
Group outputs by type (show all stdout, then all stderr, etc.):
[stdout:1] foo
[stdout:2] foo
[stderr:1] bar
[stderr:2] bar
if 'engine':
Display outputs for each engine before moving on to the next:
[stdout:1] foo
[stderr:1] bar
[stdout:2] foo
[stderr:2] bar
if 'order':
Like 'type', but further collate individual displaypub
outputs. This is meant for cases of each command producing
several plots, and you would like to see all of the first
plots together, then all of the second plots, and so on.
"""
if self._single_result:
self._display_single_result()
return
stdouts = self.stdout
stderrs = self.stderr
execute_results = self.execute_result
output_lists = self.outputs
results = self.get()
targets = self.engine_id
if groupby == "engine":
for eid,stdout,stderr,outputs,r,execute_result in zip(
targets, stdouts, stderrs, output_lists, results, execute_results
):
self._display_stream(stdout, '[stdout:%i] ' % eid)
self._display_stream(stderr, '[stderr:%i] ' % eid, file=sys.stderr)
try:
get_ipython()
except NameError:
# displaypub is meaningless outside IPython
return
if outputs or execute_result is not None:
_raw_text('[output:%i]' % eid)
for output in outputs:
self._republish_displaypub(output, eid)
if execute_result is not None:
display(r)
elif groupby in ('type', 'order'):
# republish stdout:
for eid,stdout in zip(targets, stdouts):
self._display_stream(stdout, '[stdout:%i] ' % eid)
# republish stderr:
for eid,stderr in zip(targets, stderrs):
self._display_stream(stderr, '[stderr:%i] ' % eid, file=sys.stderr)
try:
get_ipython()
except NameError:
# displaypub is meaningless outside IPython
return
if groupby == 'order':
output_dict = dict((eid, outputs) for eid,outputs in zip(targets, output_lists))
N = max(len(outputs) for outputs in output_lists)
for i in range(N):
for eid in targets:
outputs = output_dict[eid]
if len(outputs) >= N:
_raw_text('[output:%i]' % eid)
self._republish_displaypub(outputs[i], eid)
else:
# republish displaypub output
for eid,outputs in zip(targets, output_lists):
if outputs:
_raw_text('[output:%i]' % eid)
for output in outputs:
self._republish_displaypub(output, eid)
# finally, add execute_result:
for eid,r,execute_result in zip(targets, results, execute_results):
if execute_result is not None:
display(r)
else:
raise ValueError("groupby must be one of 'type', 'engine', 'collate', not %r" % groupby)
class AsyncMapResult(AsyncResult):
"""Class for representing results of non-blocking gathers.
This will properly reconstruct the gather.
This class is iterable at any time, and will wait on results as they come.
If ordered=False, then the first results to arrive will come first, otherwise
results will be yielded in the order they were submitted.
"""
def __init__(self, client, msg_ids, mapObject, fname='', ordered=True):
AsyncResult.__init__(self, client, msg_ids, fname=fname)
self._mapObject = mapObject
self._single_result = False
self.ordered = ordered
def _reconstruct_result(self, res):
"""Perform the gather on the actual results."""
return self._mapObject.joinPartitions(res)
# asynchronous iterator:
def __iter__(self):
it = self._ordered_iter if self.ordered else self._unordered_iter
for r in it():
yield r
# asynchronous ordered iterator:
def _ordered_iter(self):
"""iterator for results *as they arrive*, preserving submission order."""
try:
rlist = self.get(0)
except error.TimeoutError:
# wait for each result individually
for msg_id in self.msg_ids:
ar = AsyncResult(self._client, msg_id, self._fname)
rlist = ar.get()
try:
for r in rlist:
yield r
except TypeError:
# flattened, not a list
# this could get broken by flattened data that returns iterables
# but most calls to map do not expose the `flatten` argument
yield rlist
else:
# already done
for r in rlist:
yield r
# asynchronous unordered iterator:
def _unordered_iter(self):
"""iterator for results *as they arrive*, on FCFS basis, ignoring submission order."""
try:
rlist = self.get(0)
except error.TimeoutError:
pending = set(self.msg_ids)
while pending:
try:
self._client.wait(pending, 1e-3)
except error.TimeoutError:
# ignore timeout error, because that only means
# *some* jobs are outstanding
pass
# update ready set with those no longer outstanding:
ready = pending.difference(self._client.outstanding)
# update pending to exclude those that are finished
pending = pending.difference(ready)
while ready:
msg_id = ready.pop()
ar = AsyncResult(self._client, msg_id, self._fname)
rlist = ar.get()
try:
for r in rlist:
yield r
except TypeError:
# flattened, not a list
# this could get broken by flattened data that returns iterables
# but most calls to map do not expose the `flatten` argument
yield rlist
else:
# already done
for r in rlist:
yield r
class AsyncHubResult(AsyncResult):
"""Class to wrap pending results that must be requested from the Hub.
Note that waiting/polling on these objects requires polling the Hubover the network,
so use `AsyncHubResult.wait()` sparingly.
"""
def _wait_for_outputs(self, timeout=-1):
"""no-op, because HubResults are never incomplete"""
self._outputs_ready = True
def wait(self, timeout=-1):
"""wait for result to complete."""
start = time.time()
if self._ready:
return
local_ids = [m for m in self.msg_ids if m in self._client.outstanding]
local_ready = self._client.wait(local_ids, timeout)
if local_ready:
remote_ids = [m for m in self.msg_ids if m not in self._client.results]
if not remote_ids:
self._ready = True
else:
rdict = self._client.result_status(remote_ids, status_only=False)
pending = rdict['pending']
while pending and (timeout < 0 or time.time() < start+timeout):
rdict = self._client.result_status(remote_ids, status_only=False)
pending = rdict['pending']
if pending:
time.sleep(0.1)
if not pending:
self._ready = True
if self._ready:
try:
results = list(map(self._client.results.get, self.msg_ids))
self._result = results
if self._single_result:
r = results[0]
if isinstance(r, Exception):
raise r
else:
results = error.collect_exceptions(results, self._fname)
self._result = self._reconstruct_result(results)
except Exception as e:
self._exception = e
self._success = False
else:
self._success = True
finally:
self._metadata = [self._client.metadata[mid] for mid in self.msg_ids]
if self.owner:
[self._client.metadata.pop(mid) for mid in self.msg_ids]
[self._client.results.pop(mid) for mid in self.msg_ids]
__all__ = ['AsyncResult', 'AsyncMapResult', 'AsyncHubResult']