# diff_tree.py -- Utilities for diffing files and trees. # Copyright (C) 2010 Google, Inc. # # 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 # or (at your option) a later version of the License. # # 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. """Utilities for diffing files and trees.""" from collections import ( defaultdict, namedtuple, ) from io import BytesIO from itertools import chain, izip import stat from dulwich.objects import ( S_ISGITLINK, TreeEntry, ) # TreeChange type constants. CHANGE_ADD = 'add' CHANGE_MODIFY = 'modify' CHANGE_DELETE = 'delete' CHANGE_RENAME = 'rename' CHANGE_COPY = 'copy' CHANGE_UNCHANGED = 'unchanged' RENAME_CHANGE_TYPES = (CHANGE_RENAME, CHANGE_COPY) _NULL_ENTRY = TreeEntry(None, None, None) _MAX_SCORE = 100 RENAME_THRESHOLD = 60 MAX_FILES = 200 REWRITE_THRESHOLD = None class TreeChange(namedtuple('TreeChange', ['type', 'old', 'new'])): """Named tuple a single change between two trees.""" @classmethod def add(cls, new): return cls(CHANGE_ADD, _NULL_ENTRY, new) @classmethod def delete(cls, old): return cls(CHANGE_DELETE, old, _NULL_ENTRY) def _tree_entries(path, tree): result = [] if not tree: return result for entry in tree.iteritems(name_order=True): result.append(entry.in_path(path)) return result def _merge_entries(path, tree1, tree2): """Merge the entries of two trees. :param path: A path to prepend to all tree entry names. :param tree1: The first Tree object to iterate, or None. :param tree2: The second Tree object to iterate, or None. :return: A list of pairs of TreeEntry objects for each pair of entries in the trees. If an entry exists in one tree but not the other, the other entry will have all attributes set to None. If neither entry's path is None, they are guaranteed to match. """ entries1 = _tree_entries(path, tree1) entries2 = _tree_entries(path, tree2) i1 = i2 = 0 len1 = len(entries1) len2 = len(entries2) result = [] while i1 < len1 and i2 < len2: entry1 = entries1[i1] entry2 = entries2[i2] if entry1.path < entry2.path: result.append((entry1, _NULL_ENTRY)) i1 += 1 elif entry1.path > entry2.path: result.append((_NULL_ENTRY, entry2)) i2 += 1 else: result.append((entry1, entry2)) i1 += 1 i2 += 1 for i in xrange(i1, len1): result.append((entries1[i], _NULL_ENTRY)) for i in xrange(i2, len2): result.append((_NULL_ENTRY, entries2[i])) return result def _is_tree(entry): mode = entry.mode if mode is None: return False return stat.S_ISDIR(mode) def walk_trees(store, tree1_id, tree2_id, prune_identical=False): """Recursively walk all the entries of two trees. Iteration is depth-first pre-order, as in e.g. os.walk. :param store: An ObjectStore for looking up objects. :param tree1_id: The SHA of the first Tree object to iterate, or None. :param tree2_id: The SHA of the second Tree object to iterate, or None. :param prune_identical: If True, identical subtrees will not be walked. :return: Iterator over Pairs of TreeEntry objects for each pair of entries in the trees and their subtrees recursively. If an entry exists in one tree but not the other, the other entry will have all attributes set to None. If neither entry's path is None, they are guaranteed to match. """ # This could be fairly easily generalized to >2 trees if we find a use # case. mode1 = tree1_id and stat.S_IFDIR or None mode2 = tree2_id and stat.S_IFDIR or None todo = [(TreeEntry('', mode1, tree1_id), TreeEntry('', mode2, tree2_id))] while todo: entry1, entry2 = todo.pop() is_tree1 = _is_tree(entry1) is_tree2 = _is_tree(entry2) if prune_identical and is_tree1 and is_tree2 and entry1 == entry2: continue tree1 = is_tree1 and store[entry1.sha] or None tree2 = is_tree2 and store[entry2.sha] or None path = entry1.path or entry2.path todo.extend(reversed(_merge_entries(path, tree1, tree2))) yield entry1, entry2 def _skip_tree(entry): if entry.mode is None or stat.S_ISDIR(entry.mode): return _NULL_ENTRY return entry def tree_changes(store, tree1_id, tree2_id, want_unchanged=False, rename_detector=None): """Find the differences between the contents of two trees. :param store: An ObjectStore for looking up objects. :param tree1_id: The SHA of the source tree. :param tree2_id: The SHA of the target tree. :param want_unchanged: If True, include TreeChanges for unmodified entries as well. :param rename_detector: RenameDetector object for detecting renames. :return: Iterator over TreeChange instances for each change between the source and target tree. """ if (rename_detector is not None and tree1_id is not None and tree2_id is not None): for change in rename_detector.changes_with_renames( tree1_id, tree2_id, want_unchanged=want_unchanged): yield change return entries = walk_trees(store, tree1_id, tree2_id, prune_identical=(not want_unchanged)) for entry1, entry2 in entries: if entry1 == entry2 and not want_unchanged: continue # Treat entries for trees as missing. entry1 = _skip_tree(entry1) entry2 = _skip_tree(entry2) if entry1 != _NULL_ENTRY and entry2 != _NULL_ENTRY: if stat.S_IFMT(entry1.mode) != stat.S_IFMT(entry2.mode): # File type changed: report as delete/add. yield TreeChange.delete(entry1) entry1 = _NULL_ENTRY change_type = CHANGE_ADD elif entry1 == entry2: change_type = CHANGE_UNCHANGED else: change_type = CHANGE_MODIFY elif entry1 != _NULL_ENTRY: change_type = CHANGE_DELETE elif entry2 != _NULL_ENTRY: change_type = CHANGE_ADD else: # Both were None because at least one was a tree. continue yield TreeChange(change_type, entry1, entry2) def _all_eq(seq, key, value): for e in seq: if key(e) != value: return False return True def _all_same(seq, key): return _all_eq(seq[1:], key, key(seq[0])) def tree_changes_for_merge(store, parent_tree_ids, tree_id, rename_detector=None): """Get the tree changes for a merge tree relative to all its parents. :param store: An ObjectStore for looking up objects. :param parent_tree_ids: An iterable of the SHAs of the parent trees. :param tree_id: The SHA of the merge tree. :param rename_detector: RenameDetector object for detecting renames. :return: Iterator over lists of TreeChange objects, one per conflicted path in the merge. Each list contains one element per parent, with the TreeChange for that path relative to that parent. An element may be None if it never existed in one parent and was deleted in two others. A path is only included in the output if it is a conflict, i.e. its SHA in the merge tree is not found in any of the parents, or in the case of deletes, if not all of the old SHAs match. """ all_parent_changes = [tree_changes(store, t, tree_id, rename_detector=rename_detector) for t in parent_tree_ids] num_parents = len(parent_tree_ids) changes_by_path = defaultdict(lambda: [None] * num_parents) # Organize by path. for i, parent_changes in enumerate(all_parent_changes): for change in parent_changes: if change.type == CHANGE_DELETE: path = change.old.path else: path = change.new.path changes_by_path[path][i] = change old_sha = lambda c: c.old.sha change_type = lambda c: c.type # Yield only conflicting changes. for _, changes in sorted(changes_by_path.iteritems()): assert len(changes) == num_parents have = [c for c in changes if c is not None] if _all_eq(have, change_type, CHANGE_DELETE): if not _all_same(have, old_sha): yield changes elif not _all_same(have, change_type): yield changes elif None not in changes: # If no change was found relative to one parent, that means the SHA # must have matched the SHA in that parent, so it is not a # conflict. yield changes _BLOCK_SIZE = 64 def _count_blocks(obj): """Count the blocks in an object. Splits the data into blocks either on lines or <=64-byte chunks of lines. :param obj: The object to count blocks for. :return: A dict of block hashcode -> total bytes occurring. """ block_counts = defaultdict(int) block = BytesIO() n = 0 # Cache attrs as locals to avoid expensive lookups in the inner loop. block_write = block.write block_seek = block.seek block_truncate = block.truncate block_getvalue = block.getvalue for c in chain(*obj.as_raw_chunks()): block_write(c) n += 1 if c == '\n' or n == _BLOCK_SIZE: value = block_getvalue() block_counts[hash(value)] += len(value) block_seek(0) block_truncate() n = 0 if n > 0: last_block = block_getvalue() block_counts[hash(last_block)] += len(last_block) return block_counts def _common_bytes(blocks1, blocks2): """Count the number of common bytes in two block count dicts. :param block1: The first dict of block hashcode -> total bytes. :param block2: The second dict of block hashcode -> total bytes. :return: The number of bytes in common between blocks1 and blocks2. This is only approximate due to possible hash collisions. """ # Iterate over the smaller of the two dicts, since this is symmetrical. if len(blocks1) > len(blocks2): blocks1, blocks2 = blocks2, blocks1 score = 0 for block, count1 in blocks1.iteritems(): count2 = blocks2.get(block) if count2: score += min(count1, count2) return score def _similarity_score(obj1, obj2, block_cache=None): """Compute a similarity score for two objects. :param obj1: The first object to score. :param obj2: The second object to score. :param block_cache: An optional dict of SHA to block counts to cache results between calls. :return: The similarity score between the two objects, defined as the number of bytes in common between the two objects divided by the maximum size, scaled to the range 0-100. """ if block_cache is None: block_cache = {} if obj1.id not in block_cache: block_cache[obj1.id] = _count_blocks(obj1) if obj2.id not in block_cache: block_cache[obj2.id] = _count_blocks(obj2) common_bytes = _common_bytes(block_cache[obj1.id], block_cache[obj2.id]) max_size = max(obj1.raw_length(), obj2.raw_length()) if not max_size: return _MAX_SCORE return int(float(common_bytes) * _MAX_SCORE / max_size) def _tree_change_key(entry): # Sort by old path then new path. If only one exists, use it for both keys. path1 = entry.old.path path2 = entry.new.path if path1 is None: path1 = path2 if path2 is None: path2 = path1 return (path1, path2) class RenameDetector(object): """Object for handling rename detection between two trees.""" def __init__(self, store, rename_threshold=RENAME_THRESHOLD, max_files=MAX_FILES, rewrite_threshold=REWRITE_THRESHOLD, find_copies_harder=False): """Initialize the rename detector. :param store: An ObjectStore for looking up objects. :param rename_threshold: The threshold similarity score for considering an add/delete pair to be a rename/copy; see _similarity_score. :param max_files: The maximum number of adds and deletes to consider, or None for no limit. The detector is guaranteed to compare no more than max_files ** 2 add/delete pairs. This limit is provided because rename detection can be quadratic in the project size. If the limit is exceeded, no content rename detection is attempted. :param rewrite_threshold: The threshold similarity score below which a modify should be considered a delete/add, or None to not break modifies; see _similarity_score. :param find_copies_harder: If True, consider unmodified files when detecting copies. """ self._store = store self._rename_threshold = rename_threshold self._rewrite_threshold = rewrite_threshold self._max_files = max_files self._find_copies_harder = find_copies_harder self._want_unchanged = False def _reset(self): self._adds = [] self._deletes = [] self._changes = [] def _should_split(self, change): if (self._rewrite_threshold is None or change.type != CHANGE_MODIFY or change.old.sha == change.new.sha): return False old_obj = self._store[change.old.sha] new_obj = self._store[change.new.sha] return _similarity_score(old_obj, new_obj) < self._rewrite_threshold def _add_change(self, change): if change.type == CHANGE_ADD: self._adds.append(change) elif change.type == CHANGE_DELETE: self._deletes.append(change) elif self._should_split(change): self._deletes.append(TreeChange.delete(change.old)) self._adds.append(TreeChange.add(change.new)) elif ((self._find_copies_harder and change.type == CHANGE_UNCHANGED) or change.type == CHANGE_MODIFY): # Treat all modifies as potential deletes for rename detection, # but don't split them (to avoid spurious renames). Setting # find_copies_harder means we treat unchanged the same as # modified. self._deletes.append(change) else: self._changes.append(change) def _collect_changes(self, tree1_id, tree2_id): want_unchanged = self._find_copies_harder or self._want_unchanged for change in tree_changes(self._store, tree1_id, tree2_id, want_unchanged=want_unchanged): self._add_change(change) def _prune(self, add_paths, delete_paths): self._adds = [a for a in self._adds if a.new.path not in add_paths] self._deletes = [d for d in self._deletes if d.old.path not in delete_paths] def _find_exact_renames(self): add_map = defaultdict(list) for add in self._adds: add_map[add.new.sha].append(add.new) delete_map = defaultdict(list) for delete in self._deletes: # Keep track of whether the delete was actually marked as a delete. # If not, it needs to be marked as a copy. is_delete = delete.type == CHANGE_DELETE delete_map[delete.old.sha].append((delete.old, is_delete)) add_paths = set() delete_paths = set() for sha, sha_deletes in delete_map.iteritems(): sha_adds = add_map[sha] for (old, is_delete), new in izip(sha_deletes, sha_adds): if stat.S_IFMT(old.mode) != stat.S_IFMT(new.mode): continue if is_delete: delete_paths.add(old.path) add_paths.add(new.path) new_type = is_delete and CHANGE_RENAME or CHANGE_COPY self._changes.append(TreeChange(new_type, old, new)) num_extra_adds = len(sha_adds) - len(sha_deletes) # TODO(dborowitz): Less arbitrary way of dealing with extra copies. old = sha_deletes[0][0] if num_extra_adds > 0: for new in sha_adds[-num_extra_adds:]: add_paths.add(new.path) self._changes.append(TreeChange(CHANGE_COPY, old, new)) self._prune(add_paths, delete_paths) def _should_find_content_renames(self): return len(self._adds) * len(self._deletes) <= self._max_files ** 2 def _rename_type(self, check_paths, delete, add): if check_paths and delete.old.path == add.new.path: # If the paths match, this must be a split modify, so make sure it # comes out as a modify. return CHANGE_MODIFY elif delete.type != CHANGE_DELETE: # If it's in deletes but not marked as a delete, it must have been # added due to find_copies_harder, and needs to be marked as a # copy. return CHANGE_COPY return CHANGE_RENAME def _find_content_rename_candidates(self): candidates = self._candidates = [] # TODO: Optimizations: # - Compare object sizes before counting blocks. # - Skip if delete's S_IFMT differs from all adds. # - Skip if adds or deletes is empty. # Match C git's behavior of not attempting to find content renames if # the matrix size exceeds the threshold. if not self._should_find_content_renames(): return check_paths = self._rename_threshold is not None for delete in self._deletes: if S_ISGITLINK(delete.old.mode): continue # Git links don't exist in this repo. old_sha = delete.old.sha old_obj = self._store[old_sha] old_blocks = _count_blocks(old_obj) for add in self._adds: if stat.S_IFMT(delete.old.mode) != stat.S_IFMT(add.new.mode): continue new_obj = self._store[add.new.sha] score = _similarity_score(old_obj, new_obj, block_cache={old_sha: old_blocks}) if score > self._rename_threshold: new_type = self._rename_type(check_paths, delete, add) rename = TreeChange(new_type, delete.old, add.new) candidates.append((-score, rename)) def _choose_content_renames(self): # Sort scores from highest to lowest, but keep names in ascending # order. self._candidates.sort() delete_paths = set() add_paths = set() for _, change in self._candidates: new_path = change.new.path if new_path in add_paths: continue old_path = change.old.path orig_type = change.type if old_path in delete_paths: change = TreeChange(CHANGE_COPY, change.old, change.new) # If the candidate was originally a copy, that means it came from a # modified or unchanged path, so we don't want to prune it. if orig_type != CHANGE_COPY: delete_paths.add(old_path) add_paths.add(new_path) self._changes.append(change) self._prune(add_paths, delete_paths) def _join_modifies(self): if self._rewrite_threshold is None: return modifies = {} delete_map = dict((d.old.path, d) for d in self._deletes) for add in self._adds: path = add.new.path delete = delete_map.get(path) if (delete is not None and stat.S_IFMT(delete.old.mode) == stat.S_IFMT(add.new.mode)): modifies[path] = TreeChange(CHANGE_MODIFY, delete.old, add.new) self._adds = [a for a in self._adds if a.new.path not in modifies] self._deletes = [a for a in self._deletes if a.new.path not in modifies] self._changes += modifies.values() def _sorted_changes(self): result = [] result.extend(self._adds) result.extend(self._deletes) result.extend(self._changes) result.sort(key=_tree_change_key) return result def _prune_unchanged(self): if self._want_unchanged: return self._deletes = [d for d in self._deletes if d.type != CHANGE_UNCHANGED] def changes_with_renames(self, tree1_id, tree2_id, want_unchanged=False): """Iterate TreeChanges between two tree SHAs, with rename detection.""" self._reset() self._want_unchanged = want_unchanged self._collect_changes(tree1_id, tree2_id) self._find_exact_renames() self._find_content_rename_candidates() self._choose_content_renames() self._join_modifies() self._prune_unchanged() return self._sorted_changes() # Hold on to the pure-python implementations for testing. _is_tree_py = _is_tree _merge_entries_py = _merge_entries _count_blocks_py = _count_blocks try: # Try to import C versions from dulwich._diff_tree import _is_tree, _merge_entries, _count_blocks except ImportError: pass