# Copyright 2008 Matt Chaput. All rights reserved.
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"""
This module contains classes for scoring (and sorting) search results.
"""
from math import log, pi
# Base classes
[docs]class WeightingModel:
"""Abstract base class for scoring models. A WeightingModel object provides
a method, ``scorer``, which returns an instance of
:class:`whoosh.scoring.Scorer`.
Basically, WeightingModel objects store the configuration information for
the model (for example, the values of B and K1 in the BM25F model), and
then creates a scorer instance based on additional run-time information
(the searcher, the fieldname, and term text) to do the actual scoring.
"""
use_final = False
[docs] def idf(self, searcher, fieldname, text):
"""Returns the inverse document frequency of the given term."""
parent = searcher.get_parent()
n = parent.doc_frequency(fieldname, text)
dc = parent.doc_count_all()
return log(dc / (n + 1)) + 1
[docs] def scorer(self, searcher, fieldname, text, qf=1):
"""Returns an instance of :class:`whoosh.scoring.Scorer` configured
for the given searcher, fieldname, and term text.
"""
raise NotImplementedError(self.__class__.__name__)
[docs] def final(self, searcher, docnum, score):
"""Returns a final score for each document. You can use this method
in subclasses to apply document-level adjustments to the score, for
example using the value of stored field to influence the score
(although that would be slow).
WeightingModel sub-classes that use ``final()`` should have the
attribute ``use_final`` set to ``True``.
:param searcher: :class:`whoosh.searching.Searcher` for the index.
:param docnum: the doc number of the document being scored.
:param score: the document's accumulated term score.
:rtype: float
"""
return score
[docs]class BaseScorer:
"""Base class for "scorer" implementations. A scorer provides a method for
scoring a document, and sometimes methods for rating the "quality" of a
document and a matcher's current "block", to implement quality-based
optimizations.
Scorer objects are created by WeightingModel objects. Basically,
WeightingModel objects store the configuration information for the model
(for example, the values of B and K1 in the BM25F model), and then creates
a scorer instance.
"""
[docs] def supports_block_quality(self):
"""Returns True if this class supports quality optimizations."""
return False
[docs] def score(self, matcher):
"""Returns a score for the current document of the matcher."""
raise NotImplementedError(self.__class__.__name__)
[docs] def max_quality(self):
"""Returns the *maximum limit* on the possible score the matcher can
give. This can be an estimate and not necessarily the actual maximum
score possible, but it must never be less than the actual maximum
score.
"""
raise NotImplementedError(self.__class__.__name__)
[docs] def block_quality(self, matcher):
"""Returns the *maximum limit* on the possible score the matcher can
give **in its current "block"** (whatever concept of "block" the
backend might use). This can be an estimate and not necessarily the
actual maximum score possible, but it must never be less than the
actual maximum score.
If this score is less than the minimum score
required to make the "top N" results, then we can tell the matcher to
skip ahead to another block with better "quality".
"""
raise NotImplementedError(self.__class__.__name__)
# Scorer that just returns term weight
[docs]class WeightScorer(BaseScorer):
"""A scorer that simply returns the weight as the score. This is useful
for more complex weighting models to return when they are asked for a
scorer for fields that aren't scorable (don't store field lengths).
"""
def __init__(self, maxweight):
self._maxweight = maxweight
def supports_block_quality(self):
return True
def score(self, matcher):
return matcher.weight()
def max_quality(self):
return self._maxweight
def block_quality(self, matcher):
return matcher.block_max_weight()
@classmethod
def for_(cls, searcher, fieldname, text):
ti = searcher.term_info(fieldname, text)
return cls(ti.max_weight())
# Base scorer for models that only use weight and field length
[docs]class WeightLengthScorer(BaseScorer):
"""Base class for scorers where the only per-document variables are term
weight and field length.
Subclasses should override the ``_score(weight, length)`` method to return
the score for a document with the given weight and length, and call the
``setup()`` method at the end of the initializer to set up common
attributes.
"""
def setup(self, searcher, fieldname, text):
"""Initializes the scorer and then does the busy work of
adding the ``dfl()`` function and maximum quality attribute.
This method assumes the initializers of WeightLengthScorer subclasses
always take ``searcher, offset, fieldname, text`` as the first three
arguments. Any additional arguments given to this method are passed
through to the initializer.
Note: this method calls ``self._score()``, so you should only call it
in the initializer after setting up whatever attributes ``_score()``
depends on::
class MyScorer(WeightLengthScorer):
def __init__(self, searcher, fieldname, text, parm=1.0):
self.parm = parm
self.setup(searcher, fieldname, text)
def _score(self, weight, length):
return (weight / (length + 1)) * self.parm
"""
ti = searcher.term_info(fieldname, text)
if not searcher.schema[fieldname].scorable:
return WeightScorer(ti.max_weight())
self.dfl = lambda docid: searcher.doc_field_length(docid, fieldname, 1)
self._maxquality = self._score(ti.max_weight(), ti.min_length())
def supports_block_quality(self):
return True
def score(self, matcher):
return self._score(matcher.weight(), self.dfl(matcher.id()))
def max_quality(self):
return self._maxquality
def block_quality(self, matcher):
return self._score(matcher.block_max_weight(), matcher.block_min_length())
def _score(self, weight, length):
# Override this method with the actual scoring function
raise NotImplementedError(self.__class__.__name__)
# WeightingModel implementations
# Debugging model
class DebugModel(WeightingModel):
def __init__(self):
self.log = []
def scorer(self, searcher, fieldname, text, qf=1):
return DebugScorer(searcher, fieldname, text, self.log)
class DebugScorer(BaseScorer):
def __init__(self, searcher, fieldname, text, log):
ti = searcher.term_info(fieldname, text)
self._maxweight = ti.max_weight()
self.searcher = searcher
self.fieldname = fieldname
self.text = text
self.log = log
def supports_block_quality(self):
return True
def score(self, matcher):
fieldname, text = self.fieldname, self.text
docid = matcher.id()
w = matcher.weight()
length = self.searcher.doc_field_length(docid, fieldname)
self.log.append((fieldname, text, docid, w, length))
return w
def max_quality(self):
return self._maxweight
def block_quality(self, matcher):
return matcher.block_max_weight()
# BM25F Model
def bm25(idf, tf, fl, avgfl, B, K1):
# idf - inverse document frequency
# tf - term frequency in the current document
# fl - field length in the current document
# avgfl - average field length across documents in collection
# B, K1 - free paramters
return idf * ((tf * (K1 + 1)) / (tf + K1 * ((1 - B) + B * fl / avgfl)))
[docs]class BM25F(WeightingModel):
"""Implements the BM25F scoring algorithm."""
def __init__(self, B=0.75, K1=1.2, **kwargs):
"""
>>> from whoosh import scoring
>>> # Set a custom B value for the "content" field
>>> w = scoring.BM25F(B=0.75, content_B=1.0, K1=1.5)
:param B: free parameter, see the BM25 literature. Keyword arguments of
the form ``fieldname_B`` (for example, ``body_B``) set field-
specific values for B.
:param K1: free parameter, see the BM25 literature.
"""
self.B = B
self.K1 = K1
self._field_B = {}
for k, v in kwargs.items():
if k.endswith("_B"):
fieldname = k[:-2]
self._field_B[fieldname] = v
def supports_block_quality(self):
return True
def scorer(self, searcher, fieldname, text, qf=1):
if not searcher.schema[fieldname].scorable:
return WeightScorer.for_(searcher, fieldname, text)
if fieldname in self._field_B:
B = self._field_B[fieldname]
else:
B = self.B
return BM25FScorer(searcher, fieldname, text, B, self.K1, qf=qf)
class BM25FScorer(WeightLengthScorer):
def __init__(self, searcher, fieldname, text, B, K1, qf=1):
# IDF and average field length are global statistics, so get them from
# the top-level searcher
parent = searcher.get_parent() # Returns self if no parent
self.idf = parent.idf(fieldname, text)
self.avgfl = parent.avg_field_length(fieldname) or 1
self.B = B
self.K1 = K1
self.qf = qf
self.setup(searcher, fieldname, text)
def _score(self, weight, length):
s = bm25(self.idf, weight, length, self.avgfl, self.B, self.K1)
return s
# DFree model
def dfree(tf, cf, qf, dl, fl):
# tf - term frequency in current document
# cf - term frequency in collection
# qf - term frequency in query
# dl - field length in current document
# fl - total field length across all documents in collection
prior = tf / dl
post = (tf + 1.0) / (dl + 1.0)
invpriorcol = fl / cf
norm = tf * log(post / prior)
return (
qf
* norm
* (
tf * (log(prior * invpriorcol))
+ (tf + 1.0) * (log(post * invpriorcol))
+ 0.5 * log(post / prior)
)
)
class DFree(WeightingModel):
"""Implements the DFree scoring model from Terrier.
See http://terrier.org/
"""
def supports_block_quality(self):
return True
def scorer(self, searcher, fieldname, text, qf=1):
if not searcher.schema[fieldname].scorable:
return WeightScorer.for_(searcher, fieldname, text)
return DFreeScorer(searcher, fieldname, text, qf=qf)
class DFreeScorer(WeightLengthScorer):
def __init__(self, searcher, fieldname, text, qf=1):
# Total term weight and total field length are global statistics, so
# get them from the top-level searcher
parent = searcher.get_parent() # Returns self if no parent
self.cf = parent.weight(fieldname, text)
self.fl = parent.field_length(fieldname)
self.qf = qf
self.setup(searcher, fieldname, text)
def _score(self, weight, length):
return dfree(weight, self.cf, self.qf, length, self.fl)
# PL2 model
rec_log2_of_e = 1.0 / log(2)
def pl2(tf, cf, qf, dc, fl, avgfl, c):
# tf - term frequency in the current document
# cf - term frequency in the collection
# qf - term frequency in the query
# dc - doc count
# fl - field length in the current document
# avgfl - average field length across all documents
# c -free parameter
TF = tf * log(1.0 + (c * avgfl) / fl)
norm = 1.0 / (TF + 1.0)
f = cf / dc
return (
norm
* qf
* (
TF * log(1.0 / f)
+ f * rec_log2_of_e
+ 0.5 * log(2 * pi * TF)
+ TF * (log(TF) - rec_log2_of_e)
)
)
class PL2(WeightingModel):
"""Implements the PL2 scoring model from Terrier.
See http://terrier.org/
"""
def __init__(self, c=1.0):
self.c = c
def scorer(self, searcher, fieldname, text, qf=1):
if not searcher.schema[fieldname].scorable:
return WeightScorer.for_(searcher, fieldname, text)
return PL2Scorer(searcher, fieldname, text, self.c, qf=qf)
class PL2Scorer(WeightLengthScorer):
def __init__(self, searcher, fieldname, text, c, qf=1):
# Total term weight, document count, and average field length are
# global statistics, so get them from the top-level searcher
parent = searcher.get_parent() # Returns self if no parent
self.cf = parent.frequency(fieldname, text)
self.dc = parent.doc_count_all()
self.avgfl = parent.avg_field_length(fieldname) or 1
self.c = c
self.qf = qf
self.setup(searcher, fieldname, text)
def _score(self, weight, length):
return pl2(weight, self.cf, self.qf, self.dc, length, self.avgfl, self.c)
# Simple models
[docs]class Frequency(WeightingModel):
def scorer(self, searcher, fieldname, text, qf=1):
maxweight = searcher.term_info(fieldname, text).max_weight()
return WeightScorer(maxweight)
[docs]class TF_IDF(WeightingModel):
def scorer(self, searcher, fieldname, text, qf=1):
# IDF is a global statistic, so get it from the top-level searcher
parent = searcher.get_parent() # Returns self if no parent
idf = parent.idf(fieldname, text)
maxweight = searcher.term_info(fieldname, text).max_weight()
return TF_IDFScorer(maxweight, idf)
class TF_IDFScorer(BaseScorer):
def __init__(self, maxweight, idf):
self._maxquality = maxweight * idf
self.idf = idf
def supports_block_quality(self):
return True
def score(self, matcher):
return matcher.weight() * self.idf
def max_quality(self):
return self._maxquality
def block_quality(self, matcher):
return matcher.block_max_weight() * self.idf
# Utility models
class Weighting(WeightingModel):
"""This class provides backwards-compatibility with the old weighting
class architecture, so any existing custom scorers don't need to be
rewritten.
"""
def scorer(self, searcher, fieldname, text, qf=1):
return self.CompatibilityScorer(searcher, fieldname, text, self.score)
def score(self, searcher, fieldname, text, docnum, weight):
raise NotImplementedError
class CompatibilityScorer(BaseScorer):
def __init__(self, searcher, fieldname, text, scoremethod):
self.searcher = searcher
self.fieldname = fieldname
self.text = text
self.scoremethod = scoremethod
def score(self, matcher):
return self.scoremethod(
self.searcher, self.fieldname, self.text, matcher.id(), matcher.weight()
)
[docs]class FunctionWeighting(WeightingModel):
"""Uses a supplied function to do the scoring. For simple scoring functions
and experiments this may be simpler to use than writing a full weighting
model class and scorer class.
The function should accept the arguments
``searcher, fieldname, text, matcher``.
For example, the following function will score documents based on the
earliest position of the query term in the document::
def pos_score_fn(searcher, fieldname, text, matcher):
poses = matcher.value_as("positions")
return 1.0 / (poses[0] + 1)
pos_weighting = scoring.FunctionWeighting(pos_score_fn)
with myindex.searcher(weighting=pos_weighting) as s:
results = s.search(q)
Note that the searcher passed to the function may be a per-segment searcher
for performance reasons. If you want to get global statistics inside the
function, you should use ``searcher.get_parent()`` to get the top-level
searcher. (However, if you are using global statistics, you should probably
write a real model/scorer combo so you can cache them on the object.)
"""
def __init__(self, fn):
self.fn = fn
def scorer(self, searcher, fieldname, text, qf=1):
return self.FunctionScorer(self.fn, searcher, fieldname, text, qf=qf)
class FunctionScorer(BaseScorer):
def __init__(self, fn, searcher, fieldname, text, qf=1):
self.fn = fn
self.searcher = searcher
self.fieldname = fieldname
self.text = text
self.qf = qf
def score(self, matcher):
return self.fn(self.searcher, self.fieldname, self.text, matcher)
[docs]class MultiWeighting(WeightingModel):
"""Chooses from multiple scoring algorithms based on the field."""
def __init__(self, default, **weightings):
"""The only non-keyword argument specifies the default
:class:`Weighting` instance to use. Keyword arguments specify
Weighting instances for specific fields.
For example, to use ``BM25`` for most fields, but ``Frequency`` for
the ``id`` field and ``TF_IDF`` for the ``keys`` field::
mw = MultiWeighting(BM25(), id=Frequency(), keys=TF_IDF())
:param default: the Weighting instance to use for fields not
specified in the keyword arguments.
"""
self.default = default
# Store weighting functions by field name
self.weightings = weightings
def scorer(self, searcher, fieldname, text, qf=1):
w = self.weightings.get(fieldname, self.default)
return w.scorer(searcher, fieldname, text, qf=qf)
[docs]class ReverseWeighting(WeightingModel):
"""Wraps a weighting object and subtracts the wrapped model's scores from
0, essentially reversing the weighting model.
"""
def __init__(self, weighting):
self.weighting = weighting
def scorer(self, searcher, fieldname, text, qf=1):
subscorer = self.weighting.scorer(searcher, fieldname, text, qf=qf)
return ReverseWeighting.ReverseScorer(subscorer)
class ReverseScorer(BaseScorer):
def __init__(self, subscorer):
self.subscorer = subscorer
def supports_block_quality(self):
return self.subscorer.supports_block_quality()
def score(self, matcher):
return 0 - self.subscorer.score(matcher)
def max_quality(self):
return 0 - self.subscorer.max_quality()
def block_quality(self, matcher):
return 0 - self.subscorer.block_quality(matcher)
# class PositionWeighting(WeightingModel):
# def __init__(self, reversed=False):
# self.reversed = reversed
#
# def scorer(self, searcher, fieldname, text, qf=1):
# return PositionWeighting.PositionScorer()
#
# class PositionScorer(BaseScorer):
# def score(self, matcher):
# p = min(span.pos for span in matcher.spans())
# if self.reversed:
# return p
# else:
# return 0 - p