# -*- coding: utf-8 -*-
# Copyright (C) 2014 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/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 collections
import io
import itertools
import os
from taskflow.types import graph
from taskflow.utils import iter_utils
from taskflow.utils import misc
[docs]
class FrozenNode(Exception):
"""Exception raised when a frozen node is modified."""
def __init__(self):
super(FrozenNode, self).__init__("Frozen node(s) can't be modified")
class _DFSIter(object):
"""Depth first iterator (non-recursive) over the child nodes."""
def __init__(self, root, include_self=False, right_to_left=True):
self.root = root
self.right_to_left = bool(right_to_left)
self.include_self = bool(include_self)
def __iter__(self):
stack = []
if self.include_self:
stack.append(self.root)
else:
if self.right_to_left:
stack.extend(self.root.reverse_iter())
else:
# Traverse the left nodes first to the right nodes.
stack.extend(iter(self.root))
while stack:
# Visit the node.
node = stack.pop()
yield node
if self.right_to_left:
stack.extend(node.reverse_iter())
else:
# Traverse the left nodes first to the right nodes.
stack.extend(iter(node))
class _BFSIter(object):
"""Breadth first iterator (non-recursive) over the child nodes."""
def __init__(self, root, include_self=False, right_to_left=False):
self.root = root
self.right_to_left = bool(right_to_left)
self.include_self = bool(include_self)
def __iter__(self):
q = collections.deque()
if self.include_self:
q.append(self.root)
else:
if self.right_to_left:
q.extend(iter(self.root))
else:
# Traverse the left nodes first to the right nodes.
q.extend(self.root.reverse_iter())
while q:
# Visit the node.
node = q.popleft()
yield node
if self.right_to_left:
q.extend(iter(node))
else:
# Traverse the left nodes first to the right nodes.
q.extend(node.reverse_iter())
[docs]
class Node(object):
"""A n-ary node class that can be used to create tree structures."""
#: Default string prefix used in :py:meth:`.pformat`.
STARTING_PREFIX = ""
#: Default string used to create empty space used in :py:meth:`.pformat`.
EMPTY_SPACE_SEP = " "
HORIZONTAL_CONN = "__"
"""
Default string used to horizontally connect a node to its
parent (used in :py:meth:`.pformat`.).
"""
VERTICAL_CONN = "|"
"""
Default string used to vertically connect a node to its
parent (used in :py:meth:`.pformat`).
"""
#: Default line separator used in :py:meth:`.pformat`.
LINE_SEP = os.linesep
def __init__(self, item, **kwargs):
self.item = item
self.parent = None
self.metadata = dict(kwargs)
self.frozen = False
self._children = []
def freeze(self):
if not self.frozen:
# This will DFS until all children are frozen as well, only
# after that works do we freeze ourselves (this makes it so
# that we don't become frozen if a child node fails to perform
# the freeze operation).
for n in self:
n.freeze()
self.frozen = True
[docs]
@misc.disallow_when_frozen(FrozenNode)
def add(self, child):
"""Adds a child to this node (appends to left of existing children).
NOTE(harlowja): this will also set the childs parent to be this node.
"""
child.parent = self
self._children.append(child)
[docs]
def empty(self):
"""Returns if the node is a leaf node."""
return self.child_count() == 0
[docs]
def path_iter(self, include_self=True):
"""Yields back the path from this node to the root node."""
if include_self:
node = self
else:
node = self.parent
while node is not None:
yield node
node = node.parent
[docs]
def find_first_match(self, matcher, only_direct=False, include_self=True):
"""Finds the *first* node that matching callback returns true.
This will search not only this node but also any children nodes (in
depth first order, from right to left) and finally if nothing is
matched then ``None`` is returned instead of a node object.
:param matcher: callback that takes one positional argument (a node)
and returns true if it matches desired node or false
if not.
:param only_direct: only look at current node and its
direct children (implies that this does not
search using depth first).
:param include_self: include the current node during searching.
:returns: the node that matched (or ``None``)
"""
if only_direct:
if include_self:
it = itertools.chain([self], self.reverse_iter())
else:
it = self.reverse_iter()
else:
it = self.dfs_iter(include_self=include_self)
return iter_utils.find_first_match(it, matcher)
[docs]
def find(self, item, only_direct=False, include_self=True):
"""Returns the *first* node for an item if it exists in this node.
This will search not only this node but also any children nodes (in
depth first order, from right to left) and finally if nothing is
matched then ``None`` is returned instead of a node object.
:param item: item to look for.
:param only_direct: only look at current node and its
direct children (implies that this does not
search using depth first).
:param include_self: include the current node during searching.
:returns: the node that matched provided item (or ``None``)
"""
return self.find_first_match(lambda n: n.item == item,
only_direct=only_direct,
include_self=include_self)
[docs]
@misc.disallow_when_frozen(FrozenNode)
def disassociate(self):
"""Removes this node from its parent (if any).
:returns: occurrences of this node that were removed from its parent.
"""
occurrences = 0
if self.parent is not None:
p = self.parent
self.parent = None
# Remove all instances of this node from its parent.
while True:
try:
p._children.remove(self)
except ValueError:
break
else:
occurrences += 1
return occurrences
[docs]
@misc.disallow_when_frozen(FrozenNode)
def remove(self, item, only_direct=False, include_self=True):
"""Removes a item from this nodes children.
This will search not only this node but also any children nodes and
finally if nothing is found then a value error is raised instead of
the normally returned *removed* node object.
:param item: item to lookup.
:param only_direct: only look at current node and its
direct children (implies that this does not
search using depth first).
:param include_self: include the current node during searching.
"""
node = self.find(item, only_direct=only_direct,
include_self=include_self)
if node is None:
raise ValueError("Item '%s' not found to remove" % item)
else:
node.disassociate()
return node
def __contains__(self, item):
"""Returns whether item exists in this node or this nodes children.
:returns: if the item exists in this node or nodes children,
true if the item exists, false otherwise
:rtype: boolean
"""
return self.find(item) is not None
def __getitem__(self, index):
# NOTE(harlowja): 0 is the right most index, len - 1 is the left most
return self._children[index]
[docs]
def child_count(self, only_direct=True):
"""Returns how many children this node has.
This can be either only the direct children of this node or inclusive
of all children nodes of this node (children of children and so-on).
NOTE(harlowja): it does not account for the current node in this count.
"""
if not only_direct:
return iter_utils.count(self.dfs_iter())
return len(self._children)
def __iter__(self):
"""Iterates over the direct children of this node (right->left)."""
for c in self._children:
yield c
[docs]
def reverse_iter(self):
"""Iterates over the direct children of this node (left->right)."""
for c in reversed(self._children):
yield c
[docs]
def index(self, item):
"""Finds the child index of a given item, searches in added order."""
index_at = None
for (i, child) in enumerate(self._children):
if child.item == item:
index_at = i
break
if index_at is None:
raise ValueError("%s is not contained in any child" % (item))
return index_at
[docs]
def dfs_iter(self, include_self=False, right_to_left=True):
"""Depth first iteration (non-recursive) over the child nodes."""
return _DFSIter(self,
include_self=include_self,
right_to_left=right_to_left)
[docs]
def bfs_iter(self, include_self=False, right_to_left=False):
"""Breadth first iteration (non-recursive) over the child nodes."""
return _BFSIter(self,
include_self=include_self,
right_to_left=right_to_left)
[docs]
def to_digraph(self):
"""Converts this node + its children into a ordered directed graph.
The graph returned will have the same structure as the
this node and its children (and tree node metadata will be translated
into graph node metadata).
:returns: a directed graph
:rtype: :py:class:`taskflow.types.graph.OrderedDiGraph`
"""
g = graph.OrderedDiGraph()
for node in self.bfs_iter(include_self=True, right_to_left=True):
g.add_node(node.item, **node.metadata)
if node is not self:
g.add_edge(node.parent.item, node.item)
return g