dibbler/sqlalchemy/topological.py

# topological.py
# Copyright (C) 2005, 2006, 2007, 2008, 2009, 2010 Michael Bayer mike_mp@zzzcomputing.com
#
# This module is part of SQLAlchemy and is released under
# the MIT License: http://www.opensource.org/licenses/mit-license.php

"""Topological sorting algorithms.

The topological sort is an algorithm that receives this list of
dependencies as a *partial ordering*, that is a list of pairs which
might say, *X is dependent on Y*, *Q is dependent on Z*, but does not
necessarily tell you anything about Q being dependent on X. Therefore,
its not a straight sort where every element can be compared to
another... only some of the elements have any sorting preference, and
then only towards just some of the other elements.  For a particular
partial ordering, there can be many possible sorts that satisfy the
conditions.

"""

from sqlalchemy.exc import CircularDependencyError
from sqlalchemy import util

__all__ = ['sort', 'sort_with_cycles', 'sort_as_tree']

def sort(tuples, allitems):
    """sort the given list of items by dependency.
    
    'tuples' is a list of tuples representing a partial ordering.
    """
    
    return [n.item for n in _sort(tuples, allitems, allow_cycles=False, ignore_self_cycles=True)]

def sort_with_cycles(tuples, allitems):
    """sort the given list of items by dependency, cutting out cycles.
    
    returns results as an iterable of 2-tuples, containing the item,
    and a list containing items involved in a cycle with this item, if any.
    
    'tuples' is a list of tuples representing a partial ordering.
    """
    
    return [(n.item, [n.item for n in n.cycles or []]) for n in _sort(tuples, allitems, allow_cycles=True)]
    
def sort_as_tree(tuples, allitems, with_cycles=False):
    """sort the given list of items by dependency, and return results
    as a hierarchical tree structure.
    
    returns results as an iterable of 3-tuples, containing the item,
    a list containing items involved in a cycle with this item, if any,
    and a list of child tuples.  
    
    if with_cycles is False, the returned structure is of the same form
    but the second element of each tuple, i.e. the 'cycles', is an empty list.
    
    'tuples' is a list of tuples representing a partial ordering.
    """

    return _organize_as_tree(_sort(tuples, allitems, allow_cycles=with_cycles))


class _Node(object):
    """Represent each item in the sort."""

    def __init__(self, item):
        self.item = item
        self.dependencies = set()
        self.children = []
        self.cycles = None

    def __str__(self):
        return self.safestr()
    
    def safestr(self, indent=0):
        return (' ' * indent * 2) + \
            str(self.item) + \
            (self.cycles is not None and (" (cycles: " + repr([x for x in self.cycles]) + ")") or "") + \
            "\n" + \
            ''.join(str(n) for n in self.children)

    def __repr__(self):
        return str(self.item)

    def all_deps(self):
        """Return a set of dependencies for this node and all its cycles."""

        deps = set(self.dependencies)
        if self.cycles is not None:
            for c in self.cycles:
                deps.update(c.dependencies)
        return deps

class _EdgeCollection(object):
    """A collection of directed edges."""

    def __init__(self):
        self.parent_to_children = util.defaultdict(set)
        self.child_to_parents = util.defaultdict(set)

    def add(self, edge):
        """Add an edge to this collection."""

        parentnode, childnode = edge
        self.parent_to_children[parentnode].add(childnode)
        self.child_to_parents[childnode].add(parentnode)
        parentnode.dependencies.add(childnode)

    def remove(self, edge):
        """Remove an edge from this collection.

        Return the childnode if it has no other parents.
        """

        (parentnode, childnode) = edge
        self.parent_to_children[parentnode].remove(childnode)
        self.child_to_parents[childnode].remove(parentnode)
        if not self.child_to_parents[childnode]:
            return childnode
        else:
            return None

    def has_parents(self, node):
        return node in self.child_to_parents and bool(self.child_to_parents[node])

    def edges_by_parent(self, node):
        if node in self.parent_to_children:
            return [(node, child) for child in self.parent_to_children[node]]
        else:
            return []

    def get_parents(self):
        return self.parent_to_children.keys()

    def pop_node(self, node):
        """Remove all edges where the given node is a parent.

        Return the collection of all nodes which were children of the
        given node, and have no further parents.
        """

        children = self.parent_to_children.pop(node, None)
        if children is not None:
            for child in children:
                self.child_to_parents[child].remove(node)
                if not self.child_to_parents[child]:
                    yield child

    def __len__(self):
        return sum(len(x) for x in self.parent_to_children.values())

    def __iter__(self):
        for parent, children in self.parent_to_children.iteritems():
            for child in children:
                yield (parent, child)

    def __repr__(self):
        return repr(list(self))

def _sort(tuples, allitems, allow_cycles=False, ignore_self_cycles=False):
    nodes = {}
    edges = _EdgeCollection()

    for item in list(allitems) + [t[0] for t in tuples] + [t[1] for t in tuples]:
        item_id = id(item)
        if item_id not in nodes:
            nodes[item_id] = _Node(item)

    for t in tuples:
        id0, id1 = id(t[0]), id(t[1])
        if t[0] is t[1]:
            if allow_cycles:
                n = nodes[id0]
                n.cycles = set([n])
            elif not ignore_self_cycles:
                raise CircularDependencyError("Self-referential dependency detected: %r" % t)
            continue
        childnode = nodes[id1]
        parentnode = nodes[id0]
        edges.add((parentnode, childnode))

    queue = []
    for n in nodes.values():
        if not edges.has_parents(n):
            queue.append(n)

    output = []
    while nodes:
        if not queue:
            # edges remain but no edgeless nodes to remove; this indicates
            # a cycle
            if allow_cycles:
                for cycle in _find_cycles(edges):
                    lead = cycle[0][0]
                    lead.cycles = set()
                    for edge in cycle:
                        n = edges.remove(edge)
                        lead.cycles.add(edge[0])
                        lead.cycles.add(edge[1])
                        if n is not None:
                            queue.append(n)
                    for n in lead.cycles:
                        if n is not lead:
                            n._cyclical = True
                            for (n, k) in list(edges.edges_by_parent(n)):
                                edges.add((lead, k))
                                edges.remove((n, k))
                continue
            else:
                # long cycles not allowed
                raise CircularDependencyError("Circular dependency detected: %r %r " % (edges, queue))
        node = queue.pop()
        if not hasattr(node, '_cyclical'):
            output.append(node)
        del nodes[id(node.item)]
        for childnode in edges.pop_node(node):
            queue.append(childnode)
    return output

def _organize_as_tree(nodes):
    """Given a list of nodes from a topological sort, organize the
    nodes into a tree structure, with as many non-dependent nodes
    set as siblings to each other as possible.
    
    returns nodes as 3-tuples (item, cycles, children).
    """

    if not nodes:
        return None
    # a list of all currently independent subtrees as a tuple of
    # (root_node, set_of_all_tree_nodes, set_of_all_cycle_nodes_in_tree)
    # order of the list has no semantics for the algorithmic
    independents = []
    # in reverse topological order
    for node in reversed(nodes):
        # nodes subtree and cycles contain the node itself
        subtree = set([node])
        if node.cycles is not None:
            cycles = set(node.cycles)
        else:
            cycles = set()
        # get a set of dependent nodes of node and its cycles
        nodealldeps = node.all_deps()
        if nodealldeps:
            # iterate over independent node indexes in reverse order so we can efficiently remove them
            for index in xrange(len(independents) - 1, -1, -1):
                child, childsubtree, childcycles = independents[index]
                # if there is a dependency between this node and an independent node
                if (childsubtree.intersection(nodealldeps) or childcycles.intersection(node.dependencies)):
                    # prepend child to nodes children
                    # (append should be fine, but previous implemetation used prepend)
                    node.children[0:0] = [(child.item, [n.item for n in child.cycles or []], child.children)]
                    # merge childs subtree and cycles
                    subtree.update(childsubtree)
                    cycles.update(childcycles)
                    # remove the child from list of independent subtrees
                    independents[index:index+1] = []
        # add node as a new independent subtree
        independents.append((node, subtree, cycles))
    # choose an arbitrary node from list of all independent subtrees
    head = independents.pop()[0]
    # add all other independent subtrees as a child of the chosen root
    # used prepend [0:0] instead of extend to maintain exact behaviour of previous implementation
    head.children[0:0] = [(i[0].item, [n.item for n in i[0].cycles or []], i[0].children) for i in independents]
    return (head.item, [n.item for n in head.cycles or []], head.children)

def _find_cycles(edges):
    cycles = {}

    def traverse(node, cycle, goal):
        for (n, key) in edges.edges_by_parent(node):
            if key in cycle:
                continue
            cycle.add(key)
            if key is goal:
                cycset = set(cycle)
                for x in cycle:
                    if x in cycles:
                        existing_set = cycles[x]
                        existing_set.update(cycset)
                        for y in existing_set:
                            cycles[y] = existing_set
                        cycset = existing_set
                    else:
                        cycles[x] = cycset
            else:
                traverse(key, cycle, goal)
            cycle.pop()

    for parent in edges.get_parents():
        traverse(parent, set(), parent)

    unique_cycles = set(tuple(s) for s in cycles.values())
    
    for cycle in unique_cycles:
        edgecollection = [edge for edge in edges
                          if edge[0] in cycle and edge[1] in cycle]
        yield edgecollection
morro 2010-05-07 19:33:49 +02:00			`# topological.py`
			`# Copyright (C) 2005, 2006, 2007, 2008, 2009, 2010 Michael Bayer mike_mp@zzzcomputing.com`
			`#`
			`# This module is part of SQLAlchemy and is released under`
			`# the MIT License: http://www.opensource.org/licenses/mit-license.php`

			`"""Topological sorting algorithms.`

			`The topological sort is an algorithm that receives this list of`
			`dependencies as a partial ordering, that is a list of pairs which`
			`might say, X is dependent on Y, Q is dependent on Z, but does not`
			`necessarily tell you anything about Q being dependent on X. Therefore,`
			`its not a straight sort where every element can be compared to`
			`another... only some of the elements have any sorting preference, and`
			`then only towards just some of the other elements. For a particular`
			`partial ordering, there can be many possible sorts that satisfy the`
			`conditions.`

			`"""`

			`from sqlalchemy.exc import CircularDependencyError`
			`from sqlalchemy import util`

			`__all__ = ['sort', 'sort_with_cycles', 'sort_as_tree']`

			`def sort(tuples, allitems):`
			`"""sort the given list of items by dependency.`

			`'tuples' is a list of tuples representing a partial ordering.`
			`"""`

			`return [n.item for n in _sort(tuples, allitems, allow_cycles=False, ignore_self_cycles=True)]`

			`def sort_with_cycles(tuples, allitems):`
			`"""sort the given list of items by dependency, cutting out cycles.`

			`returns results as an iterable of 2-tuples, containing the item,`
			`and a list containing items involved in a cycle with this item, if any.`

			`'tuples' is a list of tuples representing a partial ordering.`
			`"""`

			`return [(n.item, [n.item for n in n.cycles or []]) for n in _sort(tuples, allitems, allow_cycles=True)]`

			`def sort_as_tree(tuples, allitems, with_cycles=False):`
			`"""sort the given list of items by dependency, and return results`
			`as a hierarchical tree structure.`

			`returns results as an iterable of 3-tuples, containing the item,`
			`a list containing items involved in a cycle with this item, if any,`
			`and a list of child tuples.`

			`if with_cycles is False, the returned structure is of the same form`
			`but the second element of each tuple, i.e. the 'cycles', is an empty list.`

			`'tuples' is a list of tuples representing a partial ordering.`
			`"""`

			`return _organize_as_tree(_sort(tuples, allitems, allow_cycles=with_cycles))`


			`class _Node(object):`
			`"""Represent each item in the sort."""`

			`def __init__(self, item):`
			`self.item = item`
			`self.dependencies = set()`
			`self.children = []`
			`self.cycles = None`

			`def __str__(self):`
			`return self.safestr()`

			`def safestr(self, indent=0):`
			`return (' ' * indent * 2) + \`
			`str(self.item) + \`
			`(self.cycles is not None and (" (cycles: " + repr([x for x in self.cycles]) + ")") or "") + \`
			`"\n" + \`
			`''.join(str(n) for n in self.children)`

			`def __repr__(self):`
			`return str(self.item)`

			`def all_deps(self):`
			`"""Return a set of dependencies for this node and all its cycles."""`

			`deps = set(self.dependencies)`
			`if self.cycles is not None:`
			`for c in self.cycles:`
			`deps.update(c.dependencies)`
			`return deps`

			`class _EdgeCollection(object):`
			`"""A collection of directed edges."""`

			`def __init__(self):`
			`self.parent_to_children = util.defaultdict(set)`
			`self.child_to_parents = util.defaultdict(set)`

			`def add(self, edge):`
			`"""Add an edge to this collection."""`

			`parentnode, childnode = edge`
			`self.parent_to_children[parentnode].add(childnode)`
			`self.child_to_parents[childnode].add(parentnode)`
			`parentnode.dependencies.add(childnode)`

			`def remove(self, edge):`
			`"""Remove an edge from this collection.`

			`Return the childnode if it has no other parents.`
			`"""`

			`(parentnode, childnode) = edge`
			`self.parent_to_children[parentnode].remove(childnode)`
			`self.child_to_parents[childnode].remove(parentnode)`
			`if not self.child_to_parents[childnode]:`
			`return childnode`
			`else:`
			`return None`

			`def has_parents(self, node):`
			`return node in self.child_to_parents and bool(self.child_to_parents[node])`

			`def edges_by_parent(self, node):`
			`if node in self.parent_to_children:`
			`return [(node, child) for child in self.parent_to_children[node]]`
			`else:`
			`return []`

			`def get_parents(self):`
			`return self.parent_to_children.keys()`

			`def pop_node(self, node):`
			`"""Remove all edges where the given node is a parent.`

			`Return the collection of all nodes which were children of the`
			`given node, and have no further parents.`
			`"""`

			`children = self.parent_to_children.pop(node, None)`
			`if children is not None:`
			`for child in children:`
			`self.child_to_parents[child].remove(node)`
			`if not self.child_to_parents[child]:`
			`yield child`

			`def __len__(self):`
			`return sum(len(x) for x in self.parent_to_children.values())`

			`def __iter__(self):`
			`for parent, children in self.parent_to_children.iteritems():`
			`for child in children:`
			`yield (parent, child)`

			`def __repr__(self):`
			`return repr(list(self))`

			`def _sort(tuples, allitems, allow_cycles=False, ignore_self_cycles=False):`
			`nodes = {}`
			`edges = _EdgeCollection()`

			`for item in list(allitems) + [t[0] for t in tuples] + [t[1] for t in tuples]:`
			`item_id = id(item)`
			`if item_id not in nodes:`
			`nodes[item_id] = _Node(item)`

			`for t in tuples:`
			`id0, id1 = id(t[0]), id(t[1])`
			`if t[0] is t[1]:`
			`if allow_cycles:`
			`n = nodes[id0]`
			`n.cycles = set([n])`
			`elif not ignore_self_cycles:`
			`raise CircularDependencyError("Self-referential dependency detected: %r" % t)`
			`continue`
			`childnode = nodes[id1]`
			`parentnode = nodes[id0]`
			`edges.add((parentnode, childnode))`

			`queue = []`
			`for n in nodes.values():`
			`if not edges.has_parents(n):`
			`queue.append(n)`

			`output = []`
			`while nodes:`
			`if not queue:`
			`# edges remain but no edgeless nodes to remove; this indicates`
			`# a cycle`
			`if allow_cycles:`
			`for cycle in _find_cycles(edges):`
			`lead = cycle[0][0]`
			`lead.cycles = set()`
			`for edge in cycle:`
			`n = edges.remove(edge)`
			`lead.cycles.add(edge[0])`
			`lead.cycles.add(edge[1])`
			`if n is not None:`
			`queue.append(n)`
			`for n in lead.cycles:`
			`if n is not lead:`
			`n._cyclical = True`
			`for (n, k) in list(edges.edges_by_parent(n)):`
			`edges.add((lead, k))`
			`edges.remove((n, k))`
			`continue`
			`else:`
			`# long cycles not allowed`
			`raise CircularDependencyError("Circular dependency detected: %r %r " % (edges, queue))`
			`node = queue.pop()`
			`if not hasattr(node, '_cyclical'):`
			`output.append(node)`
			`del nodes[id(node.item)]`
			`for childnode in edges.pop_node(node):`
			`queue.append(childnode)`
			`return output`

			`def _organize_as_tree(nodes):`
			`"""Given a list of nodes from a topological sort, organize the`
			`nodes into a tree structure, with as many non-dependent nodes`
			`set as siblings to each other as possible.`

			`returns nodes as 3-tuples (item, cycles, children).`
			`"""`

			`if not nodes:`
			`return None`
			`# a list of all currently independent subtrees as a tuple of`
			`# (root_node, set_of_all_tree_nodes, set_of_all_cycle_nodes_in_tree)`
			`# order of the list has no semantics for the algorithmic`
			`independents = []`
			`# in reverse topological order`
			`for node in reversed(nodes):`
			`# nodes subtree and cycles contain the node itself`
			`subtree = set([node])`
			`if node.cycles is not None:`
			`cycles = set(node.cycles)`
			`else:`
			`cycles = set()`
			`# get a set of dependent nodes of node and its cycles`
			`nodealldeps = node.all_deps()`
			`if nodealldeps:`
			`# iterate over independent node indexes in reverse order so we can efficiently remove them`
			`for index in xrange(len(independents) - 1, -1, -1):`
			`child, childsubtree, childcycles = independents[index]`
			`# if there is a dependency between this node and an independent node`
			`if (childsubtree.intersection(nodealldeps) or childcycles.intersection(node.dependencies)):`
			`# prepend child to nodes children`
			`# (append should be fine, but previous implemetation used prepend)`
			`node.children[0:0] = [(child.item, [n.item for n in child.cycles or []], child.children)]`
			`# merge childs subtree and cycles`
			`subtree.update(childsubtree)`
			`cycles.update(childcycles)`
			`# remove the child from list of independent subtrees`
			`independents[index:index+1] = []`
			`# add node as a new independent subtree`
			`independents.append((node, subtree, cycles))`
			`# choose an arbitrary node from list of all independent subtrees`
			`head = independents.pop()[0]`
			`# add all other independent subtrees as a child of the chosen root`
			`# used prepend [0:0] instead of extend to maintain exact behaviour of previous implementation`
			`head.children[0:0] = [(i[0].item, [n.item for n in i[0].cycles or []], i[0].children) for i in independents]`
			`return (head.item, [n.item for n in head.cycles or []], head.children)`

			`def _find_cycles(edges):`
			`cycles = {}`

			`def traverse(node, cycle, goal):`
			`for (n, key) in edges.edges_by_parent(node):`
			`if key in cycle:`
			`continue`
			`cycle.add(key)`
			`if key is goal:`
			`cycset = set(cycle)`
			`for x in cycle:`
			`if x in cycles:`
			`existing_set = cycles[x]`
			`existing_set.update(cycset)`
			`for y in existing_set:`
			`cycles[y] = existing_set`
			`cycset = existing_set`
			`else:`
			`cycles[x] = cycset`
			`else:`
			`traverse(key, cycle, goal)`
			`cycle.pop()`

			`for parent in edges.get_parents():`
			`traverse(parent, set(), parent)`

			`unique_cycles = set(tuple(s) for s in cycles.values())`

			`for cycle in unique_cycles:`
			`edgecollection = [edge for edge in edges`
			`if edge[0] in cycle and edge[1] in cycle]`
			`yield edgecollection`