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# 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
"""Functionality for doing annotations in the 'optimal' way"""
from __future__ import absolute_import
from bzrlib.lazy_import import lazy_import
lazy_import(globals(), """
from bzrlib import (
annotate, # Must be lazy to avoid circular importing
graph as _mod_graph,
patiencediff,
)
""")
from bzrlib import (
errors,
osutils,
ui,
)
class Annotator(object):
"""Class that drives performing annotations."""
def __init__(self, vf):
"""Create a new Annotator from a VersionedFile."""
self._vf = vf
self._parent_map = {}
self._text_cache = {}
# Map from key => number of nexts that will be built from this key
self._num_needed_children = {}
self._annotations_cache = {}
self._heads_provider = None
self._ann_tuple_cache = {}
def _update_needed_children(self, key, parent_keys):
for parent_key in parent_keys:
if parent_key in self._num_needed_children:
self._num_needed_children[parent_key] += 1
else:
self._num_needed_children[parent_key] = 1
def _get_needed_keys(self, key):
"""Determine the texts we need to get from the backing vf.
:return: (vf_keys_needed, ann_keys_needed)
vf_keys_needed These are keys that we need to get from the vf
ann_keys_needed Texts which we have in self._text_cache but we
don't have annotations for. We need to yield these
in the proper order so that we can get proper
annotations.
"""
parent_map = self._parent_map
# We need 1 extra copy of the node we will be looking at when we are
# done
self._num_needed_children[key] = 1
vf_keys_needed = set()
ann_keys_needed = set()
needed_keys = set([key])
while needed_keys:
parent_lookup = []
next_parent_map = {}
for key in needed_keys:
if key in self._parent_map:
# We don't need to lookup this key in the vf
if key not in self._text_cache:
# Extract this text from the vf
vf_keys_needed.add(key)
elif key not in self._annotations_cache:
# We do need to annotate
ann_keys_needed.add(key)
next_parent_map[key] = self._parent_map[key]
else:
parent_lookup.append(key)
vf_keys_needed.add(key)
needed_keys = set()
next_parent_map.update(self._vf.get_parent_map(parent_lookup))
for key, parent_keys in next_parent_map.iteritems():
if parent_keys is None: # No graph versionedfile
parent_keys = ()
next_parent_map[key] = ()
self._update_needed_children(key, parent_keys)
needed_keys.update([key for key in parent_keys
if key not in parent_map])
parent_map.update(next_parent_map)
# _heads_provider does some graph caching, so it is only valid while
# self._parent_map hasn't changed
self._heads_provider = None
return vf_keys_needed, ann_keys_needed
def _get_needed_texts(self, key, pb=None):
"""Get the texts we need to properly annotate key.
:param key: A Key that is present in self._vf
:return: Yield (this_key, text, num_lines)
'text' is an opaque object that just has to work with whatever
matcher object we are using. Currently it is always 'lines' but
future improvements may change this to a simple text string.
"""
keys, ann_keys = self._get_needed_keys(key)
if pb is not None:
pb.update('getting stream', 0, len(keys))
stream = self._vf.get_record_stream(keys, 'topological', True)
for idx, record in enumerate(stream):
if pb is not None:
pb.update('extracting', 0, len(keys))
if record.storage_kind == 'absent':
raise errors.RevisionNotPresent(record.key, self._vf)
this_key = record.key
lines = osutils.chunks_to_lines(record.get_bytes_as('chunked'))
num_lines = len(lines)
self._text_cache[this_key] = lines
yield this_key, lines, num_lines
for key in ann_keys:
lines = self._text_cache[key]
num_lines = len(lines)
yield key, lines, num_lines
def _get_parent_annotations_and_matches(self, key, text, parent_key):
"""Get the list of annotations for the parent, and the matching lines.
:param text: The opaque value given by _get_needed_texts
:param parent_key: The key for the parent text
:return: (parent_annotations, matching_blocks)
parent_annotations is a list as long as the number of lines in
parent
matching_blocks is a list of (parent_idx, text_idx, len) tuples
indicating which lines match between the two texts
"""
parent_lines = self._text_cache[parent_key]
parent_annotations = self._annotations_cache[parent_key]
# PatienceSequenceMatcher should probably be part of Policy
matcher = patiencediff.PatienceSequenceMatcher(None,
parent_lines, text)
matching_blocks = matcher.get_matching_blocks()
return parent_annotations, matching_blocks
def _update_from_first_parent(self, key, annotations, lines, parent_key):
"""Reannotate this text relative to its first parent."""
(parent_annotations,
matching_blocks) = self._get_parent_annotations_and_matches(
key, lines, parent_key)
for parent_idx, lines_idx, match_len in matching_blocks:
# For all matching regions we copy across the parent annotations
annotations[lines_idx:lines_idx + match_len] = \
parent_annotations[parent_idx:parent_idx + match_len]
def _update_from_other_parents(self, key, annotations, lines,
this_annotation, parent_key):
"""Reannotate this text relative to a second (or more) parent."""
(parent_annotations,
matching_blocks) = self._get_parent_annotations_and_matches(
key, lines, parent_key)
last_ann = None
last_parent = None
last_res = None
# TODO: consider making all annotations unique and then using 'is'
# everywhere. Current results claim that isn't any faster,
# because of the time spent deduping
# deduping also saves a bit of memory. For NEWS it saves ~1MB,
# but that is out of 200-300MB for extracting everything, so a
# fairly trivial amount
for parent_idx, lines_idx, match_len in matching_blocks:
# For lines which match this parent, we will now resolve whether
# this parent wins over the current annotation
ann_sub = annotations[lines_idx:lines_idx + match_len]
par_sub = parent_annotations[parent_idx:parent_idx + match_len]
if ann_sub == par_sub:
continue
for idx in xrange(match_len):
ann = ann_sub[idx]
par_ann = par_sub[idx]
ann_idx = lines_idx + idx
if ann == par_ann:
# Nothing to change
continue
if ann == this_annotation:
# Originally claimed 'this', but it was really in this
# parent
annotations[ann_idx] = par_ann
continue
# Resolve the fact that both sides have a different value for
# last modified
if ann == last_ann and par_ann == last_parent:
annotations[ann_idx] = last_res
else:
new_ann = set(ann)
new_ann.update(par_ann)
new_ann = tuple(sorted(new_ann))
annotations[ann_idx] = new_ann
last_ann = ann
last_parent = par_ann
last_res = new_ann
def _record_annotation(self, key, parent_keys, annotations):
self._annotations_cache[key] = annotations
for parent_key in parent_keys:
num = self._num_needed_children[parent_key]
num -= 1
if num == 0:
del self._text_cache[parent_key]
del self._annotations_cache[parent_key]
# Do we want to clean up _num_needed_children at this point as
# well?
self._num_needed_children[parent_key] = num
def _annotate_one(self, key, text, num_lines):
this_annotation = (key,)
# Note: annotations will be mutated by calls to _update_from*
annotations = [this_annotation] * num_lines
parent_keys = self._parent_map[key]
if parent_keys:
self._update_from_first_parent(key, annotations, text,
parent_keys[0])
for parent in parent_keys[1:]:
self._update_from_other_parents(key, annotations, text,
this_annotation, parent)
self._record_annotation(key, parent_keys, annotations)
def add_special_text(self, key, parent_keys, text):
"""Add a specific text to the graph.
This is used to add a text which is not otherwise present in the
versioned file. (eg. a WorkingTree injecting 'current:' into the
graph to annotate the edited content.)
:param key: The key to use to request this text be annotated
:param parent_keys: The parents of this text
:param text: A string containing the content of the text
"""
self._parent_map[key] = parent_keys
self._text_cache[key] = osutils.split_lines(text)
self._heads_provider = None
def annotate(self, key):
"""Return annotated fulltext for the given key.
:param key: A tuple defining the text to annotate
:return: ([annotations], [lines])
annotations is a list of tuples of keys, one for each line in lines
each key is a possible source for the given line.
lines the text of "key" as a list of lines
"""
pb = ui.ui_factory.nested_progress_bar()
try:
for text_key, text, num_lines in self._get_needed_texts(key, pb=pb):
self._annotate_one(text_key, text, num_lines)
finally:
pb.finished()
try:
annotations = self._annotations_cache[key]
except KeyError:
raise errors.RevisionNotPresent(key, self._vf)
return annotations, self._text_cache[key]
def _get_heads_provider(self):
if self._heads_provider is None:
self._heads_provider = _mod_graph.KnownGraph(self._parent_map)
return self._heads_provider
def _resolve_annotation_tie(self, the_heads, line, tiebreaker):
if tiebreaker is None:
head = sorted(the_heads)[0]
else:
# Backwards compatibility, break up the heads into pairs and
# resolve the result
next_head = iter(the_heads)
head = next_head.next()
for possible_head in next_head:
annotated_lines = ((head, line), (possible_head, line))
head = tiebreaker(annotated_lines)[0]
return head
def annotate_flat(self, key):
"""Determine the single-best-revision to source for each line.
This is meant as a compatibility thunk to how annotate() used to work.
:return: [(ann_key, line)]
A list of tuples with a single annotation key for each line.
"""
custom_tiebreaker = annotate._break_annotation_tie
annotations, lines = self.annotate(key)
out = []
heads = self._get_heads_provider().heads
append = out.append
for annotation, line in zip(annotations, lines):
if len(annotation) == 1:
head = annotation[0]
else:
the_heads = heads(annotation)
if len(the_heads) == 1:
for head in the_heads: break # get the item out of the set
else:
head = self._resolve_annotation_tie(the_heads, line,
custom_tiebreaker)
append((head, line))
return out
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