44f17d005f
This library no longer supports Python 2, thus usage of six can be removed. This also removes workaround about pickle library used in Python 2 only. ChangeId: I19d298cf0f402d65f0b142dea0bf35cf992332a9
373 lines
15 KiB
Python
373 lines
15 KiB
Python
# * coding: utf8 *




# Copyright (C) 2012 Yahoo! Inc. All Rights Reserved.


#


# 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/LICENSE2.0


#


# 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 collections


import functools




from taskflow import deciders as de


from taskflow import exceptions as exc


from taskflow import flow


from taskflow.types import graph as gr






def _unsatisfied_requires(node, graph, *additional_provided):


requires = set(node.requires)


if not requires:


return requires


for provided in additional_provided:


# This is using the difference() method vs the 


# operator since the latter doesn't work with frozen


# or regular sets (when used in combination with ordered


# sets).


#


# If this is not done the following happens...


#


# TypeError: unsupported operand type(s)


# for : 'set' and 'OrderedSet'


requires = requires.difference(provided)


if not requires:


return requires


for pred in graph.bfs_predecessors_iter(node):


requires = requires.difference(pred.provides)


if not requires:


return requires


return requires






class Flow(flow.Flow):


"""Graph flow pattern.




Contained *flows/tasks* will be executed according to their dependencies


which will be resolved by using the *flows/tasks* provides and requires


mappings or by following manually created dependency links.




From dependencies a `directed graph`_ is built. If it has edge ``A > B``,


this means ``B`` depends on ``A`` (and that the execution of ``B`` must


wait until ``A`` has finished executing, on reverting this means that the


reverting of ``A`` must wait until ``B`` has finished reverting).




Note: `cyclic`_ dependencies are not allowed.




.. _directed graph: https://en.wikipedia.org/wiki/Directed_graph


.. _cyclic: https://en.wikipedia.org/wiki/Cycle_graph


"""




def __init__(self, name, retry=None):


super(Flow, self).__init__(name, retry)


self._graph = gr.DiGraph(name=name)


self._graph.freeze()




#: Extracts the unsatisified symbol requirements of a single node.


_unsatisfied_requires = staticmethod(_unsatisfied_requires)




def link(self, u, v, decider=None, decider_depth=None):


"""Link existing node u as a runtime dependency of existing node v.




Note that if the addition of these edges creates a `cyclic`_ graph


then a :class:`~taskflow.exceptions.DependencyFailure` will be


raised and the provided changes will be discarded. If the nodes


that are being requested to link do not exist in this graph than a


:class:`ValueError` will be raised.




:param u: task or flow to create a link from (must exist already)


:param v: task or flow to create a link to (must exist already)


:param decider: A callback function that will be expected to decide


at runtime whether ``v`` should be allowed to


execute (or whether the execution of ``v`` should be


ignored, and therefore not executed). It is expected


to take as single keyword argument ``history`` which


will be the execution results of all ``u`` decidable


links that have ``v`` as a target. It is expected to


return a single boolean (``True`` to allow ``v``


execution or ``False`` to not).


:param decider_depth: One of the :py:class:`~taskflow.deciders.Depth`


enumerations (or a string version of) that will


be used to influence what atoms are ignored


when the decider provided results false. If


not provided (and a valid decider is provided


then this defaults to


:py:attr:`~taskflow.deciders.Depth.ALL`).




.. _cyclic: https://en.wikipedia.org/wiki/Cycle_graph


"""


if not self._graph.has_node(u):


raise ValueError("Node '%s' not found to link from" % (u))


if not self._graph.has_node(v):


raise ValueError("Node '%s' not found to link to" % (v))


if decider is not None:


if not callable(decider):


raise ValueError("Decider boolean callback must be callable")


self._swap(self._link(u, v, manual=True,


decider=decider, decider_depth=decider_depth))


return self




def _link(self, u, v, graph=None,


reason=None, manual=False, decider=None,


decider_depth=None):


mutable_graph = True


if graph is None:


graph = self._graph


mutable_graph = False


# NOTE(harlowja): Add an edge to a temporary copy and only if that


# copy is valid then do we swap with the underlying graph.


attrs = graph.get_edge_data(u, v)


if not attrs:


attrs = {}


if decider is not None:


attrs[flow.LINK_DECIDER] = decider


try:


# Remove existing decider depth, if one existed.


del attrs[flow.LINK_DECIDER_DEPTH]


except KeyError:


pass


if decider_depth is not None:


if decider is None:


raise ValueError("Decider depth requires a decider to be"


" provided along with it")


else:


decider_depth = de.Depth.translate(decider_depth)


attrs[flow.LINK_DECIDER_DEPTH] = decider_depth


if manual:


attrs[flow.LINK_MANUAL] = True


if reason is not None:


if flow.LINK_REASONS not in attrs:


attrs[flow.LINK_REASONS] = set()


attrs[flow.LINK_REASONS].add(reason)


if not mutable_graph:


graph = gr.DiGraph(graph)


graph.add_edge(u, v, **attrs)


return graph




def _swap(self, graph):


"""Validates the replacement graph and then swaps the underlying graph.




After swapping occurs the underlying graph will be frozen so that the


immutability invariant is maintained (we may be able to relax this


constraint in the future since our exposed public api does not allow


direct access to the underlying graph).


"""


if not graph.is_directed_acyclic():


raise exc.DependencyFailure("No path through the node(s) in the"


" graph produces an ordering that"


" will allow for logical"


" edge traversal")


self._graph = graph.freeze()




def add(self, *nodes, **kwargs):


"""Adds a given task/tasks/flow/flows to this flow.




Note that if the addition of these nodes (and any edges) creates


a `cyclic`_ graph then


a :class:`~taskflow.exceptions.DependencyFailure` will be


raised and the applied changes will be discarded.




:param nodes: node(s) to add to the flow


:param kwargs: keyword arguments, the two keyword arguments


currently processed are:




* ``resolve_requires`` a boolean that when true (the


default) implies that when node(s) are added their


symbol requirements will be matched to existing


node(s) and links will be automatically made to those


providers. If multiple possible providers exist


then a


:class:`~taskflow.exceptions.AmbiguousDependency`


exception will be raised and the provided additions


will be discarded.


* ``resolve_existing``, a boolean that when true (the


default) implies that on addition of a new node that


existing node(s) will have their requirements scanned


for symbols that this newly added node can provide.


If a match is found a link is automatically created


from the newly added node to the requiree.




.. _cyclic: https://en.wikipedia.org/wiki/Cycle_graph


"""




# Let's try to avoid doing any work if we can; since the below code


# after this filter can create more temporary graphs that aren't needed


# if the nodes already exist...


nodes = [i for i in nodes if not self._graph.has_node(i)]


if not nodes:


return self




# This syntax will *hopefully* be better in future versions of python.


#


# See: http://legacy.python.org/dev/peps/pep3102/ (python 3.0+)


resolve_requires = bool(kwargs.get('resolve_requires', True))


resolve_existing = bool(kwargs.get('resolve_existing', True))




# Figure out what the existing nodes *still* require and what they


# provide so we can do this lookup later when inferring.


required = collections.defaultdict(list)


provided = collections.defaultdict(list)




retry_provides = set()


if self._retry is not None:


for value in self._retry.requires:


required[value].append(self._retry)


for value in self._retry.provides:


retry_provides.add(value)


provided[value].append(self._retry)




for node in self._graph.nodes:


for value in self._unsatisfied_requires(node, self._graph,


retry_provides):


required[value].append(node)


for value in node.provides:


provided[value].append(node)




# NOTE(harlowja): Add node(s) and edge(s) to a temporary copy of the


# underlying graph and only if that is successful added to do we then


# swap with the underlying graph.


tmp_graph = gr.DiGraph(self._graph)


for node in nodes:


tmp_graph.add_node(node)




# Try to find a valid provider.


if resolve_requires:


for value in self._unsatisfied_requires(node, tmp_graph,


retry_provides):


if value in provided:


providers = provided[value]


if len(providers) > 1:


provider_names = [n.name for n in providers]


raise exc.AmbiguousDependency(


"Resolution error detected when"


" adding '%(node)s', multiple"


" providers %(providers)s found for"


" required symbol '%(value)s'"


% dict(node=node.name,


providers=sorted(provider_names),


value=value))


else:


self._link(providers[0], node,


graph=tmp_graph, reason=value)


else:


required[value].append(node)




for value in node.provides:


provided[value].append(node)




# See if what we provide fulfills any existing requiree.


if resolve_existing:


for value in node.provides:


if value in required:


for requiree in list(required[value]):


if requiree is not node:


self._link(node, requiree,


graph=tmp_graph, reason=value)


required[value].remove(requiree)




self._swap(tmp_graph)


return self




def _get_subgraph(self):


"""Get the active subgraph of _graph.




Descendants may override this to make only part of self._graph


visible.


"""


return self._graph




def __len__(self):


return self._get_subgraph().number_of_nodes()




def __iter__(self):


for n, _n_data in self.iter_nodes():


yield n




def iter_links(self):


return self._get_subgraph().edges(data=True)




def iter_nodes(self):


g = self._get_subgraph()


for n in g.topological_sort():


yield n, g.nodes[n]




@property


def requires(self):


requires = set()


retry_provides = set()


if self._retry is not None:


requires.update(self._retry.requires)


retry_provides.update(self._retry.provides)


g = self._get_subgraph()


for node in g.nodes:


requires.update(self._unsatisfied_requires(node, g,


retry_provides))


return frozenset(requires)






def _reset_cached_subgraph(func):


"""Resets cached subgraph after execution, in case it was affected."""




@functools.wraps(func)


def wrapper(self, *args, **kwargs):


result = func(self, *args, **kwargs)


self._subgraph = None


return result




return wrapper






class TargetedFlow(Flow):


"""Graph flow with a target.




Adds possibility to execute a flow up to certain graph node


(task or subflow).


"""




def __init__(self, *args, **kwargs):


super(TargetedFlow, self).__init__(*args, **kwargs)


self._subgraph = None


self._target = None




def set_target(self, target_node):


"""Set target for the flow.




Any node(s) (tasks or subflows) not needed for the target


node will not be executed.


"""


if not self._graph.has_node(target_node):


raise ValueError("Node '%s' not found" % target_node)


self._target = target_node


self._subgraph = None




def reset_target(self):


"""Reset target for the flow.




All node(s) of the flow will be executed.


"""


self._target = None


self._subgraph = None




add = _reset_cached_subgraph(Flow.add)




link = _reset_cached_subgraph(Flow.link)




def _get_subgraph(self):


if self._subgraph is not None:


return self._subgraph


if self._target is None:


return self._graph


nodes = [self._target]


nodes.extend(self._graph.bfs_predecessors_iter(self._target))


self._subgraph = gr.DiGraph(


incoming_graph_data=self._graph.subgraph(nodes))


self._subgraph.freeze()


return self._subgraph
