# Copyright 2010 Matt Chaput. All rights reserved. # # Redistribution and use in source and binary forms, with or without # modification, are permitted provided that the following conditions are met: # # 1. Redistributions of source code must retain the above copyright notice, # this list of conditions and the following disclaimer. # # 2. Redistributions in binary form must reproduce the above copyright # notice, this list of conditions and the following disclaimer in the # documentation and/or other materials provided with the distribution. # # THIS SOFTWARE IS PROVIDED BY MATT CHAPUT ``AS IS'' AND ANY EXPRESS OR # IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF # MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO # EVENT SHALL MATT CHAPUT OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, # INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT # LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, # OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF # LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING # NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, # EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. # # The views and conclusions contained in the software and documentation are # those of the authors and should not be interpreted as representing official # policies, either expressed or implied, of Matt Chaput. from __future__ import division from whoosh.compat import xrange from whoosh.matching import mcore class WrappingMatcher(mcore.Matcher): """Base class for matchers that wrap sub-matchers. """ def __init__(self, child, boost=1.0): self.child = child self.boost = boost def __repr__(self): return "%s(%r, boost=%s)" % (self.__class__.__name__, self.child, self.boost) def copy(self): kwargs = {} if hasattr(self, "boost"): kwargs["boost"] = self.boost return self.__class__(self.child.copy(), **kwargs) def depth(self): return 1 + self.child.depth() def _replacement(self, newchild): return self.__class__(newchild, boost=self.boost) def replace(self, minquality=0): # Replace the child matcher r = self.child.replace(minquality) if r is not self.child: # If the child changed, return a new wrapper on the new child return self._replacement(r) else: return self def id(self): return self.child.id() def all_ids(self): return self.child.all_ids() def is_active(self): return self.child.is_active() def reset(self): self.child.reset() def children(self): return [self.child] def supports(self, astype): return self.child.supports(astype) def value(self): return self.child.value() def value_as(self, astype): return self.child.value_as(astype) def spans(self): return self.child.spans() def skip_to(self, id): return self.child.skip_to(id) def next(self): self.child.next() def supports_block_quality(self): return self.child.supports_block_quality() def skip_to_quality(self, minquality): return self.child.skip_to_quality(minquality / self.boost) def max_quality(self): return self.child.max_quality() * self.boost def block_quality(self): return self.child.block_quality() * self.boost def weight(self): return self.child.weight() * self.boost def score(self): return self.child.score() * self.boost class MultiMatcher(mcore.Matcher): """Serializes the results of a list of sub-matchers. """ def __init__(self, matchers, idoffsets, scorer=None, current=0): """ :param matchers: a list of Matcher objects. :param idoffsets: a list of offsets corresponding to items in the ``matchers`` list. """ self.matchers = matchers self.offsets = idoffsets self.scorer = scorer self.current = current self._next_matcher() def __repr__(self): return "%s(%r, %r, current=%s)" % (self.__class__.__name__, self.matchers, self.offsets, self.current) def is_active(self): return self.current < len(self.matchers) def reset(self): for mr in self.matchers: mr.reset() self.current = 0 def children(self): return [self.matchers[self.current]] def _next_matcher(self): matchers = self.matchers while (self.current < len(matchers) and not matchers[self.current].is_active()): self.current += 1 def copy(self): return self.__class__([mr.copy() for mr in self.matchers], self.offsets, current=self.current) def depth(self): if self.is_active(): return 1 + max(mr.depth() for mr in self.matchers[self.current:]) else: return 0 def replace(self, minquality=0): m = self if minquality: # Skip sub-matchers that don't have a high enough max quality to # contribute while (m.is_active() and m.matchers[m.current].max_quality() < minquality): m = self.__class__(self.matchers, self.offsets, self.scorer, m.current + 1) m._next_matcher() if not m.is_active(): return mcore.NullMatcher() # TODO: Possible optimization: if the last matcher is current, replace # this with the last matcher, but wrap it with a matcher that adds the # offset. Have to check whether that's actually faster, though. return m def id(self): current = self.current return self.matchers[current].id() + self.offsets[current] def all_ids(self): offsets = self.offsets for i, mr in enumerate(self.matchers): for id in mr.all_ids(): yield id + offsets[i] def spans(self): return self.matchers[self.current].spans() def supports(self, astype): return self.matchers[self.current].supports(astype) def value(self): return self.matchers[self.current].value() def value_as(self, astype): return self.matchers[self.current].value_as(astype) def next(self): if not self.is_active(): raise mcore.ReadTooFar self.matchers[self.current].next() if not self.matchers[self.current].is_active(): self._next_matcher() def skip_to(self, id): if not self.is_active(): raise mcore.ReadTooFar if id <= self.id(): return matchers = self.matchers offsets = self.offsets r = False while self.current < len(matchers) and id > self.id(): mr = matchers[self.current] sr = mr.skip_to(id - offsets[self.current]) r = sr or r if mr.is_active(): break self._next_matcher() return r def supports_block_quality(self): return all(mr.supports_block_quality() for mr in self.matchers[self.current:]) def max_quality(self): return max(m.max_quality() for m in self.matchers[self.current:]) def block_quality(self): return self.matchers[self.current].block_quality() def weight(self): return self.matchers[self.current].weight() def score(self): return self.scorer.score(self) def ExcludeMatcher(child, excluded, boost=1.0): return FilterMatcher(child, excluded, exclude=True, boost=boost) class FilterMatcher(WrappingMatcher): """Filters the postings from the wrapped based on whether the IDs are present in or absent from a set. """ def __init__(self, child, ids, exclude=False, boost=1.0): """ :param child: the child matcher. :param ids: a set of IDs to filter by. :param exclude: by default, only IDs from the wrapped matcher that are **in** the set are used. If this argument is True, only IDs from the wrapped matcher that are **not in** the set are used. """ super(FilterMatcher, self).__init__(child) self._ids = ids self._exclude = exclude self.boost = boost self._find_next() def __repr__(self): return "%s(%r, %r, %r, boost=%s)" % (self.__class__.__name__, self.child, self._ids, self._exclude, self.boost) def reset(self): self.child.reset() self._find_next() def copy(self): return self.__class__(self.child.copy(), self._ids, self._exclude, boost=self.boost) def _replacement(self, newchild): return self.__class__(newchild, self._ids, exclude=self._exclude, boost=self.boost) def _find_next(self): child = self.child ids = self._ids r = False if self._exclude: while child.is_active() and child.id() in ids: r = child.next() or r else: while child.is_active() and child.id() not in ids: r = child.next() or r return r def next(self): self.child.next() self._find_next() def skip_to(self, id): self.child.skip_to(id) self._find_next() def all_ids(self): ids = self._ids if self._exclude: return (id for id in self.child.all_ids() if id not in ids) else: return (id for id in self.child.all_ids() if id in ids) def all_items(self): ids = self._ids if self._exclude: return (item for item in self.child.all_items() if item[0] not in ids) else: return (item for item in self.child.all_items() if item[0] in ids) class InverseMatcher(WrappingMatcher): """Synthetic matcher, generates postings that are NOT present in the wrapped matcher. """ def __init__(self, child, limit, missing=None, weight=1.0, id=0): super(InverseMatcher, self).__init__(child) self.limit = limit self._weight = weight self.missing = missing or (lambda id: False) self._id = id self._find_next() def copy(self): return self.__class__(self.child.copy(), self.limit, weight=self._weight, missing=self.missing, id=self._id) def _replacement(self, newchild): return self.__class__(newchild, self.limit, missing=self.missing, weight=self._weight, id=self._id) def is_active(self): return self._id < self.limit def reset(self): self.child.reset() self._id = 0 self._find_next() def supports_block_quality(self): return False def _find_next(self): child = self.child missing = self.missing # If the current docnum isn't missing and the child matcher is # exhausted (so we don't have to worry about skipping its matches), we # don't have to do anything if not child.is_active() and not missing(self._id): return # Skip missing documents while self._id < self.limit and missing(self._id): self._id += 1 # Catch the child matcher up to where this matcher is if child.is_active() and child.id() < self._id: child.skip_to(self._id) # While self._id is missing or is in the child matcher, increase it while child.is_active() and self._id < self.limit: if missing(self._id): self._id += 1 continue if self._id == child.id(): self._id += 1 child.next() continue break def id(self): return self._id def all_ids(self): return mcore.Matcher.all_ids(self) def next(self): if self._id >= self.limit: raise mcore.ReadTooFar self._id += 1 self._find_next() def skip_to(self, id): if self._id >= self.limit: raise mcore.ReadTooFar if id < self._id: return self._id = id self._find_next() def weight(self): return self._weight def score(self): return self._weight class RequireMatcher(WrappingMatcher): """Matches postings that are in both sub-matchers, but only uses scores from the first. """ def __init__(self, a, b): from whoosh.matching.binary import IntersectionMatcher self.a = a self.b = b WrappingMatcher.__init__(self, IntersectionMatcher(a, b)) def copy(self): return self.__class__(self.a.copy(), self.b.copy()) def supports_block_quality(self): return self.a.supports_block_quality() def replace(self, minquality=0): if not self.child.is_active(): # If one of the sub-matchers is inactive, go inactive return mcore.NullMatcher() elif minquality and self.a.max_quality() < minquality: # If the required matcher doesn't have a high enough max quality # to possibly contribute, return an inactive matcher return mcore.NullMatcher() new_a = self.a.replace(minquality) new_b = self.b.replace() if not new_a.is_active(): return mcore.NullMatcher() elif new_a is not self.a or new_b is not self.b: # If one of the sub-matchers changed, return a new Require return self.__class__(new_a, self.b) else: return self def max_quality(self): return self.a.max_quality() def block_quality(self): return self.a.block_quality() def skip_to_quality(self, minquality): skipped = self.a.skip_to_quality(minquality) self.child._find_next() return skipped def weight(self): return self.a.weight() def score(self): return self.a.score() def supports(self, astype): return self.a.supports(astype) def value(self): return self.a.value() def value_as(self, astype): return self.a.value_as(astype) class ConstantScoreWrapperMatcher(WrappingMatcher): def __init__(self, child, score=1.0): WrappingMatcher.__init__(self, child) self._score = score def copy(self): return self.__class__(self.child.copy(), score=self._score) def _replacement(self, newchild): return self.__class__(newchild, score=self._score) def max_quality(self): return self._score def block_quality(self): return self._score def score(self): return self._score class SingleTermMatcher(WrappingMatcher): """Makes a tree of matchers act as if they were a matcher for a single term for the purposes of "what terms are matching?" questions. """ def __init__(self, child, term): WrappingMatcher.__init__(self, child) self._term = term def term(self): return self._term def replace(self, minquality=0): return self class CoordMatcher(WrappingMatcher): """Modifies the computed score to penalize documents that don't match all terms in the matcher tree. Because this matcher modifies the score, it may give unexpected results when compared to another matcher returning the unmodified score. """ def __init__(self, child, scale=1.0): WrappingMatcher.__init__(self, child) self._termcount = len(list(child.term_matchers())) self._maxqual = child.max_quality() self._scale = scale def _replacement(self, newchild): return self.__class__(newchild, scale=self._scale) def _sqr(self, score, matching): # This is the "SQR" (Short Query Ranking) function used by Apple's old # V-twin search library, described in the paper "V-Twin: A Lightweight # Engine for Interactive Use". # # http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.56.1916 # score - document score using the current weighting function # matching - number of matching terms in the current document termcount = self._termcount # Number of terms in this tree scale = self._scale # Scaling factor sqr = ((score + ((matching - 1) / (termcount - scale) ** 2)) * ((termcount - 1) / termcount)) return sqr def max_quality(self): return self._sqr(self.child.max_quality(), self._termcount) def block_quality(self): return self._sqr(self.child.block_quality(), self._termcount) def score(self): child = self.child score = child.score() matching = 0 for _ in child.matching_terms(child.id()): matching += 1 return self._sqr(score, matching)