# Copyright (C) 2009, 2010 Canonical Ltd # # This program is free software; you can redistribute it and/or modify # it under the terms of the GNU General Public License as published by # the Free Software Foundation; either version 2 of the License, or # (at your option) any later version. # # This program is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the # GNU General Public License for more details. # # You should have received a copy of the GNU General Public License # along with this program; if not, write to the Free Software # Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA """Implementation of Graph algorithms when we have already loaded everything. """ from __future__ import absolute_import from collections import deque from bzrlib import ( errors, revision, ) class _KnownGraphNode(object): """Represents a single object in the known graph.""" __slots__ = ('key', 'parent_keys', 'child_keys', 'gdfo') def __init__(self, key, parent_keys): self.key = key self.parent_keys = parent_keys self.child_keys = [] # Greatest distance from origin self.gdfo = None def __repr__(self): return '%s(%s gdfo:%s par:%s child:%s)' % ( self.__class__.__name__, self.key, self.gdfo, self.parent_keys, self.child_keys) class _MergeSortNode(object): """Information about a specific node in the merge graph.""" __slots__ = ('key', 'merge_depth', 'revno', 'end_of_merge') def __init__(self, key, merge_depth, revno, end_of_merge): self.key = key self.merge_depth = merge_depth self.revno = revno self.end_of_merge = end_of_merge class KnownGraph(object): """This is a class which assumes we already know the full graph.""" def __init__(self, parent_map, do_cache=True): """Create a new KnownGraph instance. :param parent_map: A dictionary mapping key => parent_keys """ self._nodes = {} # Maps {frozenset(revision_id, revision_id): heads} self._known_heads = {} self.do_cache = do_cache self._initialize_nodes(parent_map) self._find_gdfo() def _initialize_nodes(self, parent_map): """Populate self._nodes. After this has finished: - self._nodes will have an entry for every entry in parent_map. - ghosts will have a parent_keys = None, - all nodes found will also have .child_keys populated with all known child_keys, """ nodes = self._nodes for key, parent_keys in parent_map.iteritems(): if key in nodes: node = nodes[key] node.parent_keys = parent_keys else: node = _KnownGraphNode(key, parent_keys) nodes[key] = node for parent_key in parent_keys: try: parent_node = nodes[parent_key] except KeyError: parent_node = _KnownGraphNode(parent_key, None) nodes[parent_key] = parent_node parent_node.child_keys.append(key) def _find_tails(self): return [node for node in self._nodes.itervalues() if not node.parent_keys] def _find_tips(self): return [node for node in self._nodes.itervalues() if not node.child_keys] def _find_gdfo(self): nodes = self._nodes known_parent_gdfos = {} pending = [] for node in self._find_tails(): node.gdfo = 1 pending.append(node) while pending: node = pending.pop() for child_key in node.child_keys: child = nodes[child_key] if child_key in known_parent_gdfos: known_gdfo = known_parent_gdfos[child_key] + 1 present = True else: known_gdfo = 1 present = False if child.gdfo is None or node.gdfo + 1 > child.gdfo: child.gdfo = node.gdfo + 1 if known_gdfo == len(child.parent_keys): # We are the last parent updating that node, we can # continue from there pending.append(child) if present: del known_parent_gdfos[child_key] else: # Update known_parent_gdfos for a key we couldn't process known_parent_gdfos[child_key] = known_gdfo def add_node(self, key, parent_keys): """Add a new node to the graph. If this fills in a ghost, then the gdfos of all children will be updated accordingly. :param key: The node being added. If this is a duplicate, this is a no-op. :param parent_keys: The parents of the given node. :return: None (should we return if this was a ghost, etc?) """ nodes = self._nodes if key in nodes: node = nodes[key] if node.parent_keys is None: node.parent_keys = parent_keys # A ghost is being added, we can no-longer trust the heads # cache, so clear it self._known_heads.clear() else: # Make sure we compare a list to a list, as tuple != list. parent_keys = list(parent_keys) existing_parent_keys = list(node.parent_keys) if parent_keys == existing_parent_keys: return # Identical content else: raise ValueError('Parent key mismatch, existing node %s' ' has parents of %s not %s' % (key, existing_parent_keys, parent_keys)) else: node = _KnownGraphNode(key, parent_keys) nodes[key] = node parent_gdfo = 0 for parent_key in parent_keys: try: parent_node = nodes[parent_key] except KeyError: parent_node = _KnownGraphNode(parent_key, None) # Ghosts and roots have gdfo 1 parent_node.gdfo = 1 nodes[parent_key] = parent_node if parent_gdfo < parent_node.gdfo: parent_gdfo = parent_node.gdfo parent_node.child_keys.append(key) node.gdfo = parent_gdfo + 1 # Now fill the gdfo to all children # Note that this loop is slightly inefficient, in that we may visit the # same child (and its decendents) more than once, however, it is # 'efficient' in that we only walk to nodes that would be updated, # rather than all nodes # We use a deque rather than a simple list stack, to go for BFD rather # than DFD. So that if a longer path is possible, we walk it before we # get to the final child pending = deque([node]) while pending: node = pending.popleft() next_gdfo = node.gdfo + 1 for child_key in node.child_keys: child = nodes[child_key] if child.gdfo < next_gdfo: # This child is being updated, we need to check its # children child.gdfo = next_gdfo pending.append(child) def heads(self, keys): """Return the heads from amongst keys. This is done by searching the ancestries of each key. Any key that is reachable from another key is not returned; all the others are. This operation scales with the relative depth between any two keys. It uses gdfo to avoid walking all ancestry. :param keys: An iterable of keys. :return: A set of the heads. Note that as a set there is no ordering information. Callers will need to filter their input to create order if they need it. """ candidate_nodes = dict((key, self._nodes[key]) for key in keys) if revision.NULL_REVISION in candidate_nodes: # NULL_REVISION is only a head if it is the only entry candidate_nodes.pop(revision.NULL_REVISION) if not candidate_nodes: return frozenset([revision.NULL_REVISION]) if len(candidate_nodes) < 2: # No or only one candidate return frozenset(candidate_nodes) heads_key = frozenset(candidate_nodes) # Do we have a cached result ? try: heads = self._known_heads[heads_key] return heads except KeyError: pass # Let's compute the heads seen = set() pending = [] min_gdfo = None for node in candidate_nodes.values(): if node.parent_keys: pending.extend(node.parent_keys) if min_gdfo is None or node.gdfo < min_gdfo: min_gdfo = node.gdfo nodes = self._nodes while pending: node_key = pending.pop() if node_key in seen: # node already appears in some ancestry continue seen.add(node_key) node = nodes[node_key] if node.gdfo <= min_gdfo: continue if node.parent_keys: pending.extend(node.parent_keys) heads = heads_key.difference(seen) if self.do_cache: self._known_heads[heads_key] = heads return heads def topo_sort(self): """Return the nodes in topological order. All parents must occur before all children. """ for node in self._nodes.itervalues(): if node.gdfo is None: raise errors.GraphCycleError(self._nodes) pending = self._find_tails() pending_pop = pending.pop pending_append = pending.append topo_order = [] topo_order_append = topo_order.append num_seen_parents = dict.fromkeys(self._nodes, 0) while pending: node = pending_pop() if node.parent_keys is not None: # We don't include ghost parents topo_order_append(node.key) for child_key in node.child_keys: child_node = self._nodes[child_key] seen_parents = num_seen_parents[child_key] + 1 if seen_parents == len(child_node.parent_keys): # All parents have been processed, enqueue this child pending_append(child_node) # This has been queued up, stop tracking it del num_seen_parents[child_key] else: num_seen_parents[child_key] = seen_parents # We started from the parents, so we don't need to do anymore work return topo_order def gc_sort(self): """Return a reverse topological ordering which is 'stable'. There are a few constraints: 1) Reverse topological (all children before all parents) 2) Grouped by prefix 3) 'stable' sorting, so that we get the same result, independent of machine, or extra data. To do this, we use the same basic algorithm as topo_sort, but when we aren't sure what node to access next, we sort them lexicographically. """ tips = self._find_tips() # Split the tips based on prefix prefix_tips = {} for node in tips: if node.key.__class__ is str or len(node.key) == 1: prefix = '' else: prefix = node.key[0] prefix_tips.setdefault(prefix, []).append(node) num_seen_children = dict.fromkeys(self._nodes, 0) result = [] for prefix in sorted(prefix_tips): pending = sorted(prefix_tips[prefix], key=lambda n:n.key, reverse=True) while pending: node = pending.pop() if node.parent_keys is None: # Ghost node, skip it continue result.append(node.key) for parent_key in sorted(node.parent_keys, reverse=True): parent_node = self._nodes[parent_key] seen_children = num_seen_children[parent_key] + 1 if seen_children == len(parent_node.child_keys): # All children have been processed, enqueue this parent pending.append(parent_node) # This has been queued up, stop tracking it del num_seen_children[parent_key] else: num_seen_children[parent_key] = seen_children return result def merge_sort(self, tip_key): """Compute the merge sorted graph output.""" from bzrlib import tsort as_parent_map = dict((node.key, node.parent_keys) for node in self._nodes.itervalues() if node.parent_keys is not None) # We intentionally always generate revnos and never force the # mainline_revisions # Strip the sequence_number that merge_sort generates return [_MergeSortNode(key, merge_depth, revno, end_of_merge) for _, key, merge_depth, revno, end_of_merge in tsort.merge_sort(as_parent_map, tip_key, mainline_revisions=None, generate_revno=True)] def get_parent_keys(self, key): """Get the parents for a key Returns a list containg the parents keys. If the key is a ghost, None is returned. A KeyError will be raised if the key is not in the graph. :param keys: Key to check (eg revision_id) :return: A list of parents """ return self._nodes[key].parent_keys def get_child_keys(self, key): """Get the children for a key Returns a list containg the children keys. A KeyError will be raised if the key is not in the graph. :param keys: Key to check (eg revision_id) :return: A list of children """ return self._nodes[key].child_keys