# -*- coding: utf-8 -*- """ sphinx.versioning ~~~~~~~~~~~~~~~~~ Implements the low-level algorithms Sphinx uses for the versioning of doctrees. :copyright: Copyright 2007-2013 by the Sphinx team, see AUTHORS. :license: BSD, see LICENSE for details. """ from uuid import uuid4 from operator import itemgetter from sphinx.util.pycompat import product, zip_longest, all # anything below that ratio is considered equal/changed VERSIONING_RATIO = 65 def add_uids(doctree, condition): """Add a unique id to every node in the `doctree` which matches the condition and yield the nodes. :param doctree: A :class:`docutils.nodes.document` instance. :param condition: A callable which returns either ``True`` or ``False`` for a given node. """ for node in doctree.traverse(condition): node.uid = uuid4().hex yield node def merge_doctrees(old, new, condition): """Merge the `old` doctree with the `new` one while looking at nodes matching the `condition`. Each node which replaces another one or has been added to the `new` doctree will be yielded. :param condition: A callable which returns either ``True`` or ``False`` for a given node. """ old_iter = old.traverse(condition) new_iter = new.traverse(condition) old_nodes = [] new_nodes = [] ratios = {} seen = set() # compare the nodes each doctree in order for old_node, new_node in zip_longest(old_iter, new_iter): if old_node is None: new_nodes.append(new_node) continue if new_node is None: old_nodes.append(old_node) continue ratio = get_ratio(old_node.rawsource, new_node.rawsource) if ratio == 0: new_node.uid = old_node.uid seen.add(new_node) else: ratios[old_node, new_node] = ratio old_nodes.append(old_node) new_nodes.append(new_node) # calculate the ratios for each unequal pair of nodes, should we stumble # on a pair which is equal we set the uid and add it to the seen ones for old_node, new_node in product(old_nodes, new_nodes): if new_node in seen or (old_node, new_node) in ratios: continue ratio = get_ratio(old_node.rawsource, new_node.rawsource) if ratio == 0: new_node.uid = old_node.uid seen.add(new_node) else: ratios[old_node, new_node] = ratio # choose the old node with the best ratio for each new node and set the uid # as long as the ratio is under a certain value, in which case we consider # them not changed but different ratios = sorted(ratios.iteritems(), key=itemgetter(1)) for (old_node, new_node), ratio in ratios: if new_node in seen: continue else: seen.add(new_node) if ratio < VERSIONING_RATIO: new_node.uid = old_node.uid else: new_node.uid = uuid4().hex yield new_node # create new uuids for any new node we left out earlier, this happens # if one or more nodes are simply added. for new_node in set(new_nodes) - seen: new_node.uid = uuid4().hex yield new_node def get_ratio(old, new): """Return a "similiarity ratio" (in percent) representing the similarity between the two strings where 0 is equal and anything above less than equal. """ if not all([old, new]): return VERSIONING_RATIO return levenshtein_distance(old, new) / (len(old) / 100.0) def levenshtein_distance(a, b): """Return the Levenshtein edit distance between two strings *a* and *b*.""" if a == b: return 0 if len(a) < len(b): a, b = b, a if not a: return len(b) previous_row = xrange(len(b) + 1) for i, column1 in enumerate(a): current_row = [i + 1] for j, column2 in enumerate(b): insertions = previous_row[j + 1] + 1 deletions = current_row[j] + 1 substitutions = previous_row[j] + (column1 != column2) current_row.append(min(insertions, deletions, substitutions)) previous_row = current_row return previous_row[-1]