~bzr-pqm/bzr/bzr.dev

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# (C) 2005 Canonical

# 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., 59 Temple Place, Suite 330, Boston, MA  02111-1307  USA


import bzrlib.errors
from bzrlib.graph import farthest_nodes, node_distances, all_descendants

class RevisionReference(object):
    """
    Reference to a stored revision.

    Includes the revision_id and revision_sha1.
    """
    revision_id = None
    revision_sha1 = None
    def __init__(self, revision_id, revision_sha1=None):
        if revision_id == None \
           or isinstance(revision_id, basestring):
            self.revision_id = revision_id
        else:
            raise ValueError('bad revision_id %r' % revision_id)

        if revision_sha1 != None:
            if isinstance(revision_sha1, basestring) \
               and len(revision_sha1) == 40:
                self.revision_sha1 = revision_sha1
            else:
                raise ValueError('bad revision_sha1 %r' % revision_sha1)
                


class Revision(object):
    """Single revision on a branch.

    Revisions may know their revision_hash, but only once they've been
    written out.  This is not stored because you cannot write the hash
    into the file it describes.

    After bzr 0.0.5 revisions are allowed to have multiple parents.

    parents
        List of parent revisions, each is a RevisionReference.
    """
    inventory_id = None
    inventory_sha1 = None
    revision_id = None
    timestamp = None
    message = None
    timezone = None
    committer = None
    
    def __init__(self, **args):
        self.__dict__.update(args)
        self.parents = []


    def __repr__(self):
        return "<Revision id %s>" % self.revision_id

    def __eq__(self, other):
        if not isinstance(other, Revision):
            return False
        return (self.inventory_id == other.inventory_id
                and self.inventory_sha1 == other.inventory_sha1
                and self.revision_id == other.revision_id
                and self.timestamp == other.timestamp
                and self.message == other.message
                and self.timezone == other.timezone
                and self.committer == other.committer)

    def __ne__(self, other):
        return not self.__eq__(other)

        

REVISION_ID_RE = None

def validate_revision_id(rid):
    """Check rid is syntactically valid for a revision id."""
    global REVISION_ID_RE
    if not REVISION_ID_RE:
        import re
        REVISION_ID_RE = re.compile('[\w.-]+@[\w.-]+--?\d+--?[0-9a-f]+\Z')

    if not REVISION_ID_RE.match(rid):
        raise ValueError("malformed revision-id %r" % rid)

def is_ancestor(revision_id, candidate_id, revision_source):
    """Return true if candidate_id is an ancestor of revision_id.
    A false negative will be returned if any intermediate descendent of
    candidate_id is not present in any of the revision_sources.
    
    revisions_source is an object supporting a get_revision operation that
    behaves like Branch's.
    """

    for ancestor_id, distance in iter_ancestors(revision_id, revision_source):
        if ancestor_id == candidate_id:
            return True
    return False

def iter_ancestors(revision_id, revision_source, only_present=False):
    ancestors = (revision_id,)
    distance = 0
    while len(ancestors) > 0:
        new_ancestors = []
        for ancestor in ancestors:
            if not only_present:
                yield ancestor, distance
            try:
                revision = revision_source.get_revision(ancestor)
            except bzrlib.errors.NoSuchRevision, e:
                if e.revision == revision_id:
                    raise 
                else:
                    continue
            if only_present:
                yield ancestor, distance
            new_ancestors.extend([p.revision_id for p in revision.parents])
        ancestors = new_ancestors
        distance += 1


def find_present_ancestors(revision_id, revision_source):
    """Return the ancestors of a revision present in a branch.

    It's possible that a branch won't have the complete ancestry of
    one of its revisions.  

    """
    found_ancestors = {}
    anc_iter = enumerate(iter_ancestors(revision_id, revision_source,
                         only_present=True))
    for anc_order, (anc_id, anc_distance) in anc_iter:
        if not found_ancestors.has_key(anc_id):
            found_ancestors[anc_id] = (anc_order, anc_distance)
    return found_ancestors
    

def __get_closest(intersection):
    intersection.sort()
    matches = [] 
    for entry in intersection:
        if entry[0] == intersection[0][0]:
            matches.append(entry[2])
    return matches


def old_common_ancestor(revision_a, revision_b, revision_source):
    """Find the ancestor common to both revisions that is closest to both.
    """
    from bzrlib.trace import mutter
    a_ancestors = find_present_ancestors(revision_a, revision_source)
    b_ancestors = find_present_ancestors(revision_b, revision_source)
    a_intersection = []
    b_intersection = []
    # a_order is used as a tie-breaker when two equally-good bases are found
    for revision, (a_order, a_distance) in a_ancestors.iteritems():
        if b_ancestors.has_key(revision):
            a_intersection.append((a_distance, a_order, revision))
            b_intersection.append((b_ancestors[revision][1], a_order, revision))
    mutter("a intersection: %r" % a_intersection)
    mutter("b intersection: %r" % b_intersection)

    a_closest = __get_closest(a_intersection)
    if len(a_closest) == 0:
        return None
    b_closest = __get_closest(b_intersection)
    assert len(b_closest) != 0
    mutter ("a_closest %r" % a_closest)
    mutter ("b_closest %r" % b_closest)
    if a_closest[0] in b_closest:
        return a_closest[0]
    elif b_closest[0] in a_closest:
        return b_closest[0]
    else:
        raise bzrlib.errors.AmbiguousBase((a_closest[0], b_closest[0]))
    return a_closest[0]

def revision_graph(revision, revision_source):
    """Produce a graph of the ancestry of the specified revision.
    Return root, ancestors map, descendants map

    TODO: Produce graphs with the NULL revision as root, so that we can find
    a common even when trees are not branches don't represent a single line
    of descent.
    """
    ancestors = {}
    descendants = {}
    lines = [revision]
    root = None
    descendants[revision] = {}
    while len(lines) > 0:
        new_lines = set()
        for line in lines:
            try:
                rev = revision_source.get_revision(line)
                parents = [p.revision_id for p in rev.parents]
                if len(parents) == 0:
                    root = line
            except bzrlib.errors.NoSuchRevision:
                if line == revision:
                    raise
                parents = None
            if parents is not None:
                for parent in parents:
                    if parent not in ancestors:
                        new_lines.add(parent)
                    if parent not in descendants:
                        descendants[parent] = {}
                    descendants[parent][line] = 1
            if parents is not None:
                ancestors[line] = set(parents)
        lines = new_lines
    assert root not in descendants[root]
    assert root not in ancestors[root]
    return root, ancestors, descendants

def combined_graph(revision_a, revision_b, revision_source):
    """Produce a combined ancestry graph.
    Return graph root, ancestors map, descendants map, set of common nodes"""
    root, ancestors, descendants = revision_graph(revision_a, revision_source)
    root_b, ancestors_b, descendants_b = revision_graph(revision_b, 
                                                        revision_source)
    assert root == root_b
    common = set()
    for node, node_anc in ancestors_b.iteritems():
        if node in ancestors:
            common.add(node)
        else:
            ancestors[node] = set()
        ancestors[node].update(node_anc)
    for node, node_dec in descendants_b.iteritems():
        if node not in descendants:
            descendants[node] = set()
        descendants[node].update(node_dec)
    return root, ancestors, descendants, common

def common_ancestor(revision_a, revision_b, revision_source):
    root, ancestors, descendants, common = \
        combined_graph(revision_a, revision_b, revision_source)
    nodes = farthest_nodes(descendants, ancestors, root)
    for node in nodes:
        if node in common:
            return node

class MultipleRevisionSources(object):
    """Proxy that looks in multiple branches for revisions."""
    def __init__(self, *args):
        object.__init__(self)
        assert len(args) != 0
        self._revision_sources = args

    def get_revision(self, revision_id):
        for source in self._revision_sources:
            try:
                return source.get_revision(revision_id)
            except bzrlib.errors.NoSuchRevision, e:
                pass
        raise e

def get_intervening_revisions(ancestor_id, rev_id, rev_source, 
                              revision_history=None):
    """Find the longest line of descent from maybe_ancestor to revision.
    Revision history is followed where possible.

    If ancestor_id == rev_id, list will be empty.
    Otherwise, rev_id will be the last entry.  ancestor_id will never appear.
    If ancestor_id is not an ancestor, NotAncestor will be thrown
    """
    root, ancestors, descendants = revision_graph(rev_id, rev_source)
    if len(descendants) == 0:
        raise NoSuchRevision(rev_source, rev_id)
    if ancestor_id not in descendants:
        rev_source.get_revision(ancestor_id)
        raise bzrlib.errors.NotAncestor(rev_id, ancestor_id)
    root_descendants = all_descendants(descendants, ancestor_id)
    root_descendants.add(ancestor_id)
    if rev_id not in root_descendants:
        raise bzrlib.errors.NotAncestor(rev_id, ancestor_id)
    distances = node_distances(descendants, ancestors, ancestor_id,
                               root_descendants=root_descendants)

    def best_ancestor(rev_id):
        best = None
        for anc_id in ancestors[rev_id]:
            try:
                distance = distances[anc_id]
            except KeyError:
                continue
            if revision_history is not None and anc_id in revision_history:
                return anc_id
            elif best is None or distance > best[1]:
                best = (anc_id, distance)
        return best[0]

    next = rev_id
    path = []
    while next != ancestor_id:
        path.append(next)
        next = best_ancestor(next)
    path.reverse()
    return path