# Copyright 2012 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. """ This module contains "collector" objects. Collectors provide a way to gather "raw" results from a :class:`whoosh.matching.Matcher` object, implement sorting, filtering, collation, etc., and produce a :class:`whoosh.searching.Results` object. The basic collectors are: TopCollector Returns the top N matching results sorted by score, using block-quality optimizations to skip blocks of documents that can't contribute to the top N. The :meth:`whoosh.searching.Searcher.search` method uses this type of collector by default or when you specify a ``limit``. UnlimitedCollector Returns all matching results sorted by score. The :meth:`whoosh.searching.Searcher.search` method uses this type of collector when you specify ``limit=None`` or you specify a limit equal to or greater than the number of documents in the searcher. SortingCollector Returns all matching results sorted by a :class:`whoosh.sorting.Facet` object. The :meth:`whoosh.searching.Searcher.search` method uses this type of collector when you use the ``sortedby`` parameter. Here's an example of a simple collector that instead of remembering the matched documents just counts up the number of matches:: class CountingCollector(Collector): def prepare(self, top_searcher, q, context): # Always call super method in prepare Collector.prepare(self, top_searcher, q, context) self.count = 0 def collect(self, sub_docnum): self.count += 1 c = CountingCollector() mysearcher.search_with_collector(myquery, c) print(c.count) There are also several wrapping collectors that extend or modify the functionality of other collectors. The meth:`whoosh.searching.Searcher.search` method uses many of these when you specify various parameters. NOTE: collectors are not designed to be reentrant or thread-safe. It is generally a good idea to create a new collector for each search. """ import os import threading from array import array from bisect import insort from collections import defaultdict from heapq import heapify, heappush, heapreplace from whoosh import sorting from whoosh.compat import abstractmethod, iteritems, itervalues, xrange from whoosh.searching import Results, TimeLimit from whoosh.util import now # Functions def ilen(iterator): total = 0 for _ in iterator: total += 1 return total # Base class class Collector(object): """Base class for collectors. """ def prepare(self, top_searcher, q, context): """This method is called before a search. Subclasses can override this to perform set-up work, but they should still call the superclass's method because it sets several necessary attributes on the collector object: self.top_searcher The top-level searcher. self.q The query object self.context ``context.needs_current`` controls whether a wrapping collector requires that this collector's matcher be in a valid state at every call to ``collect()``. If this is ``False``, the collector is free to use faster methods that don't necessarily keep the matcher updated, such as ``matcher.all_ids()``. :param top_searcher: the top-level :class:`whoosh.searching.Searcher` object. :param q: the :class:`whoosh.query.Query` object being searched for. :param context: a :class:`whoosh.searching.SearchContext` object containing information about the search. """ self.top_searcher = top_searcher self.q = q self.context = context self.starttime = now() self.runtime = None self.docset = set() def run(self): # Collect matches for each sub-searcher try: for subsearcher, offset in self.top_searcher.leaf_searchers(): self.set_subsearcher(subsearcher, offset) self.collect_matches() finally: self.finish() def set_subsearcher(self, subsearcher, offset): """This method is called each time the collector starts on a new sub-searcher. Subclasses can override this to perform set-up work, but they should still call the superclass's method because it sets several necessary attributes on the collector object: self.subsearcher The current sub-searcher. If the top-level searcher is atomic, this is the same as the top-level searcher. self.offset The document number offset of the current searcher. You must add this number to the document number passed to :meth:`Collector.collect` to get the top-level document number for use in results. self.matcher A :class:`whoosh.matching.Matcher` object representing the matches for the query in the current sub-searcher. """ self.subsearcher = subsearcher self.offset = offset self.matcher = self.q.matcher(subsearcher, self.context) def computes_count(self): """Returns True if the collector naturally computes the exact number of matching documents. Collectors that use block optimizations will return False since they might skip blocks containing matching documents. Note that if this method returns False you can still call :meth:`count`, but it means that method might have to do more work to calculate the number of matching documents. """ return True def all_ids(self): """Returns a sequence of docnums matched in this collector. (Only valid after the collector is run.) The default implementation is based on the docset. If a collector does not maintain the docset, it will need to override this method. """ return self.docset def count(self): """Returns the total number of documents matched in this collector. (Only valid after the collector is run.) The default implementation is based on the docset. If a collector does not maintain the docset, it will need to override this method. """ return len(self.docset) def collect_matches(self): """This method calls :meth:`Collector.matches` and then for each matched document calls :meth:`Collector.collect`. Sub-classes that want to intervene between finding matches and adding them to the collection (for example, to filter out certain documents) can override this method. """ collect = self.collect for sub_docnum in self.matches(): collect(sub_docnum) @abstractmethod def collect(self, sub_docnum): """This method is called for every matched document. It should do the work of adding a matched document to the results, and it should return an object to use as a "sorting key" for the given document (such as the document's score, a key generated by a facet, or just None). Subclasses must implement this method. If you want the score for the current document, use ``self.matcher.score()``. Overriding methods should add the current document offset (``self.offset``) to the ``sub_docnum`` to get the top-level document number for the matching document to add to results. :param sub_docnum: the document number of the current match within the current sub-searcher. You must add ``self.offset`` to this number to get the document's top-level document number. """ raise NotImplementedError @abstractmethod def sort_key(self, sub_docnum): """Returns a sorting key for the current match. This should return the same value returned by :meth:`Collector.collect`, but without the side effect of adding the current document to the results. If the collector has been prepared with ``context.needs_current=True``, this method can use ``self.matcher`` to get information, for example the score. Otherwise, it should only use the provided ``sub_docnum``, since the matcher may be in an inconsistent state. Subclasses must implement this method. """ raise NotImplementedError def remove(self, global_docnum): """Removes a document from the collector. Not that this method uses the global document number as opposed to :meth:`Collector.collect` which takes a segment-relative docnum. """ items = self.items for i in xrange(len(items)): if items[i][1] == global_docnum: items.pop(i) return raise KeyError(global_docnum) def _step_through_matches(self): matcher = self.matcher while matcher.is_active(): yield matcher.id() matcher.next() def matches(self): """Yields a series of relative document numbers for matches in the current subsearcher. """ # We jump through a lot of hoops to avoid stepping through the matcher # "manually" if we can because all_ids() is MUCH faster if self.context.needs_current: return self._step_through_matches() else: return self.matcher.all_ids() def finish(self): """This method is called after a search. Subclasses can override this to perform set-up work, but they should still call the superclass's method because it sets several necessary attributes on the collector object: self.runtime The time (in seconds) the search took. """ self.runtime = now() - self.starttime def _results(self, items, **kwargs): # Fills in a Results object with the invariant information and the # given "items" (a list of (score, docnum) tuples) r = Results(self.top_searcher, self.q, items, **kwargs) r.runtime = self.runtime r.collector = self return r @abstractmethod def results(self): """Returns a :class:`~whoosh.searching.Results` object containing the results of the search. Subclasses must implement this method """ raise NotImplementedError # Scored collectors class ScoredCollector(Collector): """Base class for collectors that sort the results based on document score. """ def __init__(self, replace=10): """ :param replace: Number of matches between attempts to replace the matcher with a more efficient version. """ Collector.__init__(self) self.replace = replace def prepare(self, top_searcher, q, context): # This collector requires a valid matcher at each step Collector.prepare(self, top_searcher, q, context) if top_searcher.weighting.use_final: self.final_fn = top_searcher.weighting.final else: self.final_fn = None # Heap containing top N (score, 0-docnum) pairs self.items = [] # Minimum score a document must have to make it into the top N. This is # used by the block-quality optimizations self.minscore = 0 # Number of times the matcher was replaced (for debugging) self.replaced_times = 0 # Number of blocks skipped by quality optimizations (for debugging) self.skipped_times = 0 def sort_key(self, sub_docnum): return 0 - self.matcher.score() def _collect(self, global_docnum, score): # Concrete subclasses should override this method to collect matching # documents raise NotImplementedError def _use_block_quality(self): # Concrete subclasses should override this method to return True if the # collector should use block quality optimizations return False def collect(self, sub_docnum): # Do common work to calculate score and top-level document number global_docnum = self.offset + sub_docnum score = self.matcher.score() if self.final_fn: score = self.final_fn(self.top_searcher, global_docnum, score) # Call specialized method on subclass return self._collect(global_docnum, score) def matches(self): minscore = self.minscore matcher = self.matcher usequality = self._use_block_quality() replace = self.replace replacecounter = 0 # A flag to indicate whether we should check block quality at the start # of the next loop checkquality = True while matcher.is_active(): # If the replacement counter has reached 0, try replacing the # matcher with a more efficient version if replace: if replacecounter == 0 or self.minscore != minscore: self.matcher = matcher = matcher.replace(minscore or 0) self.replaced_times += 1 if not matcher.is_active(): break usequality = self._use_block_quality() replacecounter = self.replace if self.minscore != minscore: checkquality = True minscore = self.minscore replacecounter -= 1 # If we're using block quality optimizations, and the checkquality # flag is true, try to skip ahead to the next block with the # minimum required quality if usequality and checkquality and minscore is not None: self.skipped_times += matcher.skip_to_quality(minscore) # Skipping ahead might have moved the matcher to the end of the # posting list if not matcher.is_active(): break yield matcher.id() # Move to the next document. This method returns True if the # matcher has entered a new block, so we should check block quality # again. checkquality = matcher.next() class TopCollector(ScoredCollector): """A collector that only returns the top "N" scored results. """ def __init__(self, limit=10, usequality=True, **kwargs): """ :param limit: the maximum number of results to return. :param usequality: whether to use block-quality optimizations. This may be useful for debugging. """ ScoredCollector.__init__(self, **kwargs) self.limit = limit self.usequality = usequality self.total = 0 def _use_block_quality(self): return (self.usequality and not self.top_searcher.weighting.use_final and self.matcher.supports_block_quality()) def computes_count(self): return not self._use_block_quality() def all_ids(self): # Since this collector can skip blocks, it doesn't track the total # number of matching documents, so if the user asks for all matched # docs we need to re-run the search using docs_for_query return self.top_searcher.docs_for_query(self.q) def count(self): if self.computes_count(): return self.total else: return ilen(self.all_ids()) # ScoredCollector.collect calls this def _collect(self, global_docnum, score): items = self.items self.total += 1 # Document numbers are negated before putting them in the heap so that # higher document numbers have lower "priority" in the queue. Lower # document numbers should always come before higher document numbers # with the same score to keep the order stable. if len(items) < self.limit: # The heap isn't full, so add this document heappush(items, (score, 0 - global_docnum)) # Negate score to act as sort key so higher scores appear first return 0 - score elif score > items[0][0]: # The heap is full, but if this document has a high enough # score to make the top N, add it to the heap heapreplace(items, (score, 0 - global_docnum)) self.minscore = items[0][0] # Negate score to act as sort key so higher scores appear first return 0 - score else: return 0 def remove(self, global_docnum): negated = 0 - global_docnum items = self.items # Remove the document if it's on the list (it may not be since # TopCollector forgets documents that don't make the top N list) for i in xrange(len(items)): if items[i][1] == negated: items.pop(i) # Restore the heap invariant heapify(items) self.minscore = items[0][0] if items else 0 return def results(self): # The items are stored (postive score, negative docnum) so the heap # keeps the highest scores and lowest docnums, in order from lowest to # highest. Since for the results we want the highest scores first, # sort the heap in reverse order items = self.items items.sort(reverse=True) # De-negate the docnums for presentation to the user items = [(score, 0 - docnum) for score, docnum in items] return self._results(items) class UnlimitedCollector(ScoredCollector): """A collector that returns **all** scored results. """ def __init__(self, reverse=False): ScoredCollector.__init__(self) self.reverse = reverse # ScoredCollector.collect calls this def _collect(self, global_docnum, score): self.items.append((score, global_docnum)) self.docset.add(global_docnum) # Negate score to act as sort key so higher scores appear first return 0 - score def results(self): # Sort by negated scores so that higher scores go first, then by # document number to keep the order stable when documents have the # same score self.items.sort(key=lambda x: (0 - x[0], x[1]), reverse=self.reverse) return self._results(self.items, docset=self.docset) # Sorting collector class SortingCollector(Collector): """A collector that returns results sorted by a given :class:`whoosh.sorting.Facet` object. See :doc:`/facets` for more information. """ def __init__(self, sortedby, limit=10, reverse=False): """ :param sortedby: see :doc:`/facets`. :param reverse: If True, reverse the overall results. Note that you can reverse individual facets in a multi-facet sort key as well. """ Collector.__init__(self) self.sortfacet = sorting.MultiFacet.from_sortedby(sortedby) self.limit = limit self.reverse = reverse def prepare(self, top_searcher, q, context): self.categorizer = self.sortfacet.categorizer(top_searcher) # If the categorizer requires a valid matcher, then tell the child # collector that we need it rm = context.needs_current or self.categorizer.needs_current Collector.prepare(self, top_searcher, q, context.set(needs_current=rm)) # List of (sortkey, docnum) pairs self.items = [] def set_subsearcher(self, subsearcher, offset): Collector.set_subsearcher(self, subsearcher, offset) self.categorizer.set_searcher(subsearcher, offset) def sort_key(self, sub_docnum): return self.categorizer.key_for(self.matcher, sub_docnum) def collect(self, sub_docnum): global_docnum = self.offset + sub_docnum sortkey = self.sort_key(sub_docnum) self.items.append((sortkey, global_docnum)) self.docset.add(global_docnum) return sortkey def results(self): items = self.items items.sort(reverse=self.reverse) if self.limit: items = items[:self.limit] return self._results(items, docset=self.docset) class UnsortedCollector(Collector): def prepare(self, top_searcher, q, context): Collector.prepare(self, top_searcher, q, context.set(weighting=None)) self.items = [] def collect(self, sub_docnum): global_docnum = self.offset + sub_docnum self.items.append((None, global_docnum)) self.docset.add(global_docnum) def results(self): items = self.items return self._results(items, docset=self.docset) # Wrapping collectors class WrappingCollector(Collector): """Base class for collectors that wrap other collectors. """ def __init__(self, child): self.child = child @property def top_searcher(self): return self.child.top_searcher @property def context(self): return self.child.context def prepare(self, top_searcher, q, context): self.child.prepare(top_searcher, q, context) def set_subsearcher(self, subsearcher, offset): self.child.set_subsearcher(subsearcher, offset) self.subsearcher = subsearcher self.matcher = self.child.matcher self.offset = self.child.offset def all_ids(self): return self.child.all_ids() def count(self): return self.child.count() def collect_matches(self): for sub_docnum in self.matches(): self.collect(sub_docnum) def sort_key(self, sub_docnum): return self.child.sort_key(sub_docnum) def collect(self, sub_docnum): return self.child.collect(sub_docnum) def remove(self, global_docnum): return self.child.remove(global_docnum) def matches(self): return self.child.matches() def finish(self): self.child.finish() def results(self): return self.child.results() # Allow and disallow collector class FilterCollector(WrappingCollector): """A collector that lets you allow and/or restrict certain document numbers in the results:: uc = collectors.UnlimitedCollector() ins = query.Term("chapter", "rendering") outs = query.Term("status", "restricted") fc = FilterCollector(uc, allow=ins, restrict=outs) mysearcher.search_with_collector(myquery, fc) print(fc.results()) This collector discards a document if: * The allowed set is not None and a document number is not in the set, or * The restrict set is not None and a document number is in the set. (So, if the same document number is in both sets, that document will be discarded.) If you have a reference to the collector, you can use ``FilterCollector.filtered_count`` to get the number of matching documents filtered out of the results by the collector. """ def __init__(self, child, allow=None, restrict=None): """ :param child: the collector to wrap. :param allow: a query, Results object, or set-like object containing docnument numbers that are allowed in the results, or None (meaning everything is allowed). :param restrict: a query, Results object, or set-like object containing document numbers to disallow from the results, or None (meaning nothing is disallowed). """ self.child = child self.allow = allow self.restrict = restrict def prepare(self, top_searcher, q, context): self.child.prepare(top_searcher, q, context) allow = self.allow restrict = self.restrict ftc = top_searcher._filter_to_comb self._allow = ftc(allow) if allow else None self._restrict = ftc(restrict) if restrict else None self.filtered_count = 0 def all_ids(self): child = self.child _allow = self._allow _restrict = self._restrict for global_docnum in child.all_ids(): if ( (_allow and global_docnum not in _allow) or (_restrict and global_docnum in _restrict) ): continue yield global_docnum def count(self): child = self.child if child.computes_count(): return child.count() else: return ilen(self.all_ids()) def collect_matches(self): child = self.child _allow = self._allow _restrict = self._restrict if _allow is not None or _restrict is not None: filtered_count = self.filtered_count for sub_docnum in child.matches(): global_docnum = self.offset + sub_docnum if ((_allow is not None and global_docnum not in _allow) or (_restrict is not None and global_docnum in _restrict)): filtered_count += 1 continue child.collect(sub_docnum) self.filtered_count = filtered_count else: # If there was no allow or restrict set, don't do anything special, # just forward the call to the child collector child.collect_matches() def results(self): r = self.child.results() r.collector = self r.filtered_count = self.filtered_count r.allowed = self.allow r.restricted = self.restrict return r # Facet grouping collector class FacetCollector(WrappingCollector): """A collector that creates groups of documents based on :class:`whoosh.sorting.Facet` objects. See :doc:`/facets` for more information. This collector is used if you specify a ``groupedby`` parameter in the :meth:`whoosh.searching.Searcher.search` method. You can use the :meth:`whoosh.searching.Results.groups` method to access the facet groups. If you have a reference to the collector can also use ``FacetedCollector.facetmaps`` to access the groups directly:: uc = collectors.UnlimitedCollector() fc = FacetedCollector(uc, sorting.FieldFacet("category")) mysearcher.search_with_collector(myquery, fc) print(fc.facetmaps) """ def __init__(self, child, groupedby, maptype=None): """ :param groupedby: see :doc:`/facets`. :param maptype: a :class:`whoosh.sorting.FacetMap` type to use for any facets that don't specify their own. """ self.child = child self.facets = sorting.Facets.from_groupedby(groupedby) self.maptype = maptype def prepare(self, top_searcher, q, context): facets = self.facets # For each facet we're grouping by: # - Create a facetmap (to hold the groups) # - Create a categorizer (to generate document keys) self.facetmaps = {} self.categorizers = {} # Set needs_current to True if any of the categorizers require the # current document to work needs_current = context.needs_current for facetname, facet in facets.items(): self.facetmaps[facetname] = facet.map(self.maptype) ctr = facet.categorizer(top_searcher) self.categorizers[facetname] = ctr needs_current = needs_current or ctr.needs_current context = context.set(needs_current=needs_current) self.child.prepare(top_searcher, q, context) def set_subsearcher(self, subsearcher, offset): WrappingCollector.set_subsearcher(self, subsearcher, offset) # Tell each categorizer about the new subsearcher and offset for categorizer in itervalues(self.categorizers): categorizer.set_searcher(self.child.subsearcher, self.child.offset) def collect(self, sub_docnum): matcher = self.child.matcher global_docnum = sub_docnum + self.child.offset # We want the sort key for the document so we can (by default) sort # the facet groups sortkey = self.child.collect(sub_docnum) # For each facet we're grouping by for name, categorizer in iteritems(self.categorizers): add = self.facetmaps[name].add # We have to do more work if the facet allows overlapping groups if categorizer.allow_overlap: for key in categorizer.keys_for(matcher, sub_docnum): add(categorizer.key_to_name(key), global_docnum, sortkey) else: key = categorizer.key_for(matcher, sub_docnum) key = categorizer.key_to_name(key) add(key, global_docnum, sortkey) return sortkey def results(self): r = self.child.results() r._facetmaps = self.facetmaps return r # Collapsing collector class CollapseCollector(WrappingCollector): """A collector that collapses results based on a facet. That is, it eliminates all but the top N results that share the same facet key. Documents with an empty key for the facet are never eliminated. The "top" results within each group is determined by the result ordering (e.g. highest score in a scored search) or an optional second "ordering" facet. If you have a reference to the collector you can use ``CollapseCollector.collapsed_counts`` to access the number of documents eliminated based on each key:: tc = TopCollector(limit=20) cc = CollapseCollector(tc, "group", limit=3) mysearcher.search_with_collector(myquery, cc) print(cc.collapsed_counts) See :ref:`collapsing` for more information. """ def __init__(self, child, keyfacet, limit=1, order=None): """ :param child: the collector to wrap. :param keyfacet: a :class:`whoosh.sorting.Facet` to use for collapsing. All but the top N documents that share a key will be eliminated from the results. :param limit: the maximum number of documents to keep for each key. :param order: an optional :class:`whoosh.sorting.Facet` to use to determine the "top" document(s) to keep when collapsing. The default (``orderfaceet=None``) uses the results order (e.g. the highest score in a scored search). """ self.child = child self.keyfacet = sorting.MultiFacet.from_sortedby(keyfacet) self.limit = limit if order: self.orderfacet = sorting.MultiFacet.from_sortedby(order) else: self.orderfacet = None def prepare(self, top_searcher, q, context): # Categorizer for getting the collapse key of a document self.keyer = self.keyfacet.categorizer(top_searcher) # Categorizer for getting the collapse order of a document self.orderer = None if self.orderfacet: self.orderer = self.orderfacet.categorizer(top_searcher) # Dictionary mapping keys to lists of (sortkey, global_docnum) pairs # representing the best docs for that key self.lists = defaultdict(list) # Dictionary mapping keys to the number of documents that have been # filtered out with that key self.collapsed_counts = defaultdict(int) # Total number of documents filtered out by collapsing self.collapsed_total = 0 # If the keyer or orderer require a valid matcher, tell the child # collector we need it needs_current = (context.needs_current or self.keyer.needs_current or (self.orderer and self.orderer.needs_current)) self.child.prepare(top_searcher, q, context.set(needs_current=needs_current)) def set_subsearcher(self, subsearcher, offset): WrappingCollector.set_subsearcher(self, subsearcher, offset) # Tell the keyer and (optional) orderer about the new subsearcher self.keyer.set_searcher(subsearcher, offset) if self.orderer: self.orderer.set_searcher(subsearcher, offset) def all_ids(self): child = self.child limit = self.limit counters = defaultdict(int) for subsearcher, offset in child.subsearchers(): self.set_subsearcher(subsearcher, offset) matcher = child.matcher keyer = self.keyer for sub_docnum in child.matches(): ckey = keyer.key_for(matcher, sub_docnum) if ckey is not None: if ckey in counters and counters[ckey] >= limit: continue else: counters[ckey] += 1 yield offset + sub_docnum def count(self): if self.child.computes_count(): return self.child.count() - self.collapsed_total else: return ilen(self.all_ids()) def collect_matches(self): lists = self.lists limit = self.limit keyer = self.keyer orderer = self.orderer collapsed_counts = self.collapsed_counts child = self.child matcher = child.matcher offset = child.offset for sub_docnum in child.matches(): # Collapsing category key ckey = keyer.key_to_name(keyer.key_for(matcher, sub_docnum)) if not ckey: # If the document isn't in a collapsing category, just add it child.collect(sub_docnum) else: global_docnum = offset + sub_docnum if orderer: # If user specified a collapse order, use it sortkey = orderer.key_for(child.matcher, sub_docnum) else: # Otherwise, use the results order sortkey = child.sort_key(sub_docnum) # Current list of best docs for this collapse key best = lists[ckey] add = False if len(best) < limit: # If the heap is not full yet, just add this document add = True elif sortkey < best[-1][0]: # If the heap is full but this document has a lower sort # key than the highest key currently on the heap, replace # the "least-best" document # Tell the child collector to remove the document child.remove(best.pop()[1]) add = True if add: insort(best, (sortkey, global_docnum)) child.collect(sub_docnum) else: # Remember that a document was filtered collapsed_counts[ckey] += 1 self.collapsed_total += 1 def results(self): r = self.child.results() r.collapsed_counts = self.collapsed_counts return r # Time limit collector class TimeLimitCollector(WrappingCollector): """A collector that raises a :class:`TimeLimit` exception if the search does not complete within a certain number of seconds:: uc = collectors.UnlimitedCollector() tlc = TimeLimitedCollector(uc, timelimit=5.8) try: mysearcher.search_with_collector(myquery, tlc) except collectors.TimeLimit: print("The search ran out of time!") # We can still get partial results from the collector print(tlc.results()) IMPORTANT: On Unix systems (systems where signal.SIGALRM is defined), the code uses signals to stop searching immediately when the time limit is reached. On Windows, the OS does not support this functionality, so the search only checks the time between each found document, so if a matcher is slow the search could exceed the time limit. """ def __init__(self, child, timelimit, greedy=False, use_alarm=True): """ :param child: the collector to wrap. :param timelimit: the maximum amount of time (in seconds) to allow for searching. If the search takes longer than this, it will raise a ``TimeLimit`` exception. :param greedy: if ``True``, the collector will finish adding the most recent hit before raising the ``TimeLimit`` exception. :param use_alarm: if ``True`` (the default), the collector will try to use signal.SIGALRM (on UNIX). """ self.child = child self.timelimit = timelimit self.greedy = greedy if use_alarm: import signal self.use_alarm = use_alarm and hasattr(signal, "SIGALRM") else: self.use_alarm = False self.timer = None self.timedout = False def prepare(self, top_searcher, q, context): self.child.prepare(top_searcher, q, context) self.timedout = False if self.use_alarm: import signal signal.signal(signal.SIGALRM, self._was_signaled) # Start a timer thread. If the timer fires, it will call this object's # _timestop() method self.timer = threading.Timer(self.timelimit, self._timestop) self.timer.start() def _timestop(self): # Called when the timer expires self.timer = None # Set an attribute that will be noticed in the collect_matches() loop self.timedout = True if self.use_alarm: import signal os.kill(os.getpid(), signal.SIGALRM) def _was_signaled(self, signum, frame): raise TimeLimit def collect_matches(self): child = self.child greedy = self.greedy for sub_docnum in child.matches(): # If the timer fired since the last loop and we're not greedy, # raise the exception if self.timedout and not greedy: raise TimeLimit child.collect(sub_docnum) # If the timer fired since we entered the loop or it fired earlier # but we were greedy, raise now if self.timedout: raise TimeLimit def finish(self): if self.timer: self.timer.cancel() self.timer = None self.child.finish() # Matched terms collector class TermsCollector(WrappingCollector): """A collector that remembers which terms appeared in which terms appeared in each matched document. This collector is used if you specify ``terms=True`` in the :meth:`whoosh.searching.Searcher.search` method. If you have a reference to the collector can also use ``TermsCollector.termslist`` to access the term lists directly:: uc = collectors.UnlimitedCollector() tc = TermsCollector(uc) mysearcher.search_with_collector(myquery, tc) # tc.termdocs is a dictionary mapping (fieldname, text) tuples to # sets of document numbers print(tc.termdocs) # tc.docterms is a dictionary mapping docnums to lists of # (fieldname, text) tuples print(tc.docterms) """ def __init__(self, child, settype=set): self.child = child self.settype = settype def prepare(self, top_searcher, q, context): # This collector requires a valid matcher at each step self.child.prepare(top_searcher, q, context.set(needs_current=True)) # A dictionary mapping (fieldname, text) pairs to arrays of docnums self.termdocs = defaultdict(lambda: array("I")) # A dictionary mapping docnums to lists of (fieldname, text) pairs self.docterms = defaultdict(list) def set_subsearcher(self, subsearcher, offset): WrappingCollector.set_subsearcher(self, subsearcher, offset) # Store a list of all the term matchers in the matcher tree self.termmatchers = list(self.child.matcher.term_matchers()) def collect(self, sub_docnum): child = self.child termdocs = self.termdocs docterms = self.docterms child.collect(sub_docnum) global_docnum = child.offset + sub_docnum # For each term matcher... for tm in self.termmatchers: # If the term matcher is matching the current document... if tm.is_active() and tm.id() == sub_docnum: # Add it to the list of matching documents for the term term = tm.term() termdocs[term].append(global_docnum) docterms[global_docnum].append(term) def results(self): r = self.child.results() r.termdocs = dict(self.termdocs) r.docterms = dict(self.docterms) return r