goldendict-ng/winlibs/include/xapian/weight.h

1538 lines
52 KiB
C
Raw Normal View History

2022-10-05 09:50:44 +00:00
/** @file
* @brief Weighting scheme API.
*/
/* Copyright (C) 2004,2007,2008,2009,2010,2011,2012,2015,2016,2019 Olly Betts
* Copyright (C) 2009 Lemur Consulting Ltd
* Copyright (C) 2013,2014 Aarsh Shah
* Copyright (C) 2016 Vivek Pal
*
* 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 of the
* License, or (at your option) any later version.
*
* 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 St, Fifth Floor, Boston, MA 02110-1301 USA
*/
#ifndef XAPIAN_INCLUDED_WEIGHT_H
#define XAPIAN_INCLUDED_WEIGHT_H
#include <string>
#include <xapian/types.h>
#include <xapian/visibility.h>
namespace Xapian {
/** Abstract base class for weighting schemes. */
class XAPIAN_VISIBILITY_DEFAULT Weight {
protected:
/// Stats which the weighting scheme can use (see @a need_stat()).
typedef enum {
/// Number of documents in the collection.
COLLECTION_SIZE = 1,
/// Number of documents in the RSet.
RSET_SIZE = 2,
/// Average length of documents in the collection.
AVERAGE_LENGTH = 4,
/// How many documents the current term is in.
TERMFREQ = 8,
/// How many documents in the RSet the current term is in.
RELTERMFREQ = 16,
/// Sum of wqf for terms in the query.
QUERY_LENGTH = 32,
/// Within-query-frequency of the current term.
WQF = 64,
/// Within-document-frequency of the current term in the current document.
WDF = 128,
/// Length of the current document (sum wdf).
DOC_LENGTH = 256,
/// Lower bound on (non-zero) document lengths.
DOC_LENGTH_MIN = 512,
/// Upper bound on document lengths.
DOC_LENGTH_MAX = 1024,
/// Upper bound on wdf.
WDF_MAX = 2048,
/// Sum of wdf over the whole collection for the current term.
COLLECTION_FREQ = 4096,
/// Number of unique terms in the current document.
UNIQUE_TERMS = 8192,
/** Sum of lengths of all documents in the collection.
*
* This gives the total number of term occurrences.
*/
TOTAL_LENGTH = COLLECTION_SIZE | AVERAGE_LENGTH
} stat_flags;
/** Tell Xapian that your subclass will want a particular statistic.
*
* Some of the statistics can be costly to fetch or calculate, so
* Xapian needs to know which are actually going to be used. You
* should call need_stat() from your constructor for each such
* statistic.
*
* @param flag The stat_flags value for a required statistic.
*/
void need_stat(stat_flags flag) {
stats_needed = stat_flags(stats_needed | flag);
}
/** Allow the subclass to perform any initialisation it needs to.
*
* @param factor Any scaling factor (e.g. from OP_SCALE_WEIGHT).
* If the Weight object is for the term-independent
* weight supplied by get_sumextra()/get_maxextra(),
* then init(0.0) is called (starting from Xapian
* 1.2.11 and 1.3.1 - earlier versions failed to
* call init() for such Weight objects).
*/
virtual void init(double factor) = 0;
private:
/// Don't allow assignment.
void operator=(const Weight &);
/// A bitmask of the statistics this weighting scheme needs.
stat_flags stats_needed;
/// The number of documents in the collection.
Xapian::doccount collection_size_;
/// The number of documents marked as relevant.
Xapian::doccount rset_size_;
/// The average length of a document in the collection.
Xapian::doclength average_length_;
/// The number of documents which this term indexes.
Xapian::doccount termfreq_;
// The collection frequency of the term.
Xapian::termcount collectionfreq_;
/// The number of relevant documents which this term indexes.
Xapian::doccount reltermfreq_;
/// The length of the query.
Xapian::termcount query_length_;
/// The within-query-frequency of this term.
Xapian::termcount wqf_;
/// A lower bound on the minimum length of any document in the database.
Xapian::termcount doclength_lower_bound_;
/// An upper bound on the maximum length of any document in the database.
Xapian::termcount doclength_upper_bound_;
/// An upper bound on the wdf of this term.
Xapian::termcount wdf_upper_bound_;
public:
/// Default constructor, needed by subclass constructors.
Weight() : stats_needed() { }
/** Type of smoothing to use with the Language Model Weighting scheme.
*
* Default is TWO_STAGE_SMOOTHING.
*/
typedef enum {
TWO_STAGE_SMOOTHING = 1,
DIRICHLET_SMOOTHING = 2,
ABSOLUTE_DISCOUNT_SMOOTHING = 3,
JELINEK_MERCER_SMOOTHING = 4,
DIRICHLET_PLUS_SMOOTHING = 5
} type_smoothing;
class Internal;
/** Virtual destructor, because we have virtual methods. */
virtual ~Weight();
/** Clone this object.
*
* This method allocates and returns a copy of the object it is called on.
*
* If your subclass is called FooWeight and has parameters a and b, then
* you would implement FooWeight::clone() like so:
*
* FooWeight * FooWeight::clone() const { return new FooWeight(a, b); }
*
* Note that the returned object will be deallocated by Xapian after use
* with "delete". If you want to handle the deletion in a special way
* (for example when wrapping the Xapian API for use from another
* language) then you can define a static <code>operator delete</code>
* method in your subclass as shown here:
* https://trac.xapian.org/ticket/554#comment:1
*/
virtual Weight * clone() const = 0;
/** Return the name of this weighting scheme.
*
* This name is used by the remote backend. It is passed along with the
* serialised parameters to the remote server so that it knows which class
* to create.
*
* Return the full namespace-qualified name of your class here - if
* your class is called FooWeight, return "FooWeight" from this method
* (Xapian::BM25Weight returns "Xapian::BM25Weight" here).
*
* If you don't want to support the remote backend, you can use the
* default implementation which simply returns an empty string.
*/
virtual std::string name() const;
/** Return this object's parameters serialised as a single string.
*
* If you don't want to support the remote backend, you can use the
* default implementation which simply throws Xapian::UnimplementedError.
*/
virtual std::string serialise() const;
/** Unserialise parameters.
*
* This method unserialises parameters serialised by the @a serialise()
* method and allocates and returns a new object initialised with them.
*
* If you don't want to support the remote backend, you can use the
* default implementation which simply throws Xapian::UnimplementedError.
*
* Note that the returned object will be deallocated by Xapian after use
* with "delete". If you want to handle the deletion in a special way
* (for example when wrapping the Xapian API for use from another
* language) then you can define a static <code>operator delete</code>
* method in your subclass as shown here:
* https://trac.xapian.org/ticket/554#comment:1
*
* @param serialised A string containing the serialised parameters.
*/
virtual Weight * unserialise(const std::string & serialised) const;
/** Calculate the weight contribution for this object's term to a document.
*
* The parameters give information about the document which may be used
* in the calculations:
*
* @param wdf The within document frequency of the term in the document.
* @param doclen The document's length (unnormalised).
* @param uniqterms Number of unique terms in the document (used
* for absolute smoothing).
*/
virtual double get_sumpart(Xapian::termcount wdf,
Xapian::termcount doclen,
Xapian::termcount uniqterms) const = 0;
/** Return an upper bound on what get_sumpart() can return for any document.
*
* This information is used by the matcher to perform various
* optimisations, so strive to make the bound as tight as possible.
*/
virtual double get_maxpart() const = 0;
/** Calculate the term-independent weight component for a document.
*
* The parameter gives information about the document which may be used
* in the calculations:
*
* @param doclen The document's length (unnormalised).
* @param uniqterms The number of unique terms in the document.
*/
virtual double get_sumextra(Xapian::termcount doclen,
Xapian::termcount uniqterms) const = 0;
/** Return an upper bound on what get_sumextra() can return for any
* document.
*
* This information is used by the matcher to perform various
* optimisations, so strive to make the bound as tight as possible.
*/
virtual double get_maxextra() const = 0;
/** @private @internal Initialise this object to calculate weights for term
* @a term.
*
* Old version of method, as used by 1.4.18 and earlier. This
* should only be referenced from inside the library and 1.4.19 and
* later will call the new version instead. We continue to provide it
* mainly to avoid triggering ABI checking tools.
*
* @param stats Source of statistics.
* @param query_len_ Query length.
* @param term The term for the new object.
* @param wqf_ The within-query-frequency of @a term.
* @param factor Any scaling factor (e.g. from OP_SCALE_WEIGHT).
*/
void init_(const Internal & stats, Xapian::termcount query_len_,
const std::string & term, Xapian::termcount wqf_,
double factor);
/** @private @internal Initialise this object to calculate weights for term
* @a term.
*
* @param stats Source of statistics.
* @param query_len_ Query length.
* @param term The term for the new object.
* @param wqf_ The within-query-frequency of @a term.
* @param factor Any scaling factor (e.g. from OP_SCALE_WEIGHT).
* @param postlist Pointer to a LeafPostList for the term (cast to void*
* to avoid needing to forward declare class
* LeafPostList in public API headers) which can be used
* to get wdf upper bound
*/
void init_(const Internal & stats, Xapian::termcount query_len_,
const std::string & term, Xapian::termcount wqf_,
double factor, void* postlist);
/** @private @internal Initialise this object to calculate weights for a
* synonym.
*
* @param stats Source of statistics.
* @param query_len_ Query length.
* @param factor Any scaling factor (e.g. from OP_SCALE_WEIGHT).
* @param termfreq The termfreq to use.
* @param reltermfreq The reltermfreq to use.
* @param collection_freq The collection frequency to use.
*/
void init_(const Internal & stats, Xapian::termcount query_len_,
double factor, Xapian::doccount termfreq,
Xapian::doccount reltermfreq, Xapian::termcount collection_freq);
/** @private @internal Initialise this object to calculate the extra weight
* component.
*
* @param stats Source of statistics.
* @param query_len_ Query length.
*/
void init_(const Internal & stats, Xapian::termcount query_len_);
/** @private @internal Return true if the document length is needed.
*
* If this method returns true, then the document length will be fetched
* and passed to @a get_sumpart(). Otherwise 0 may be passed for the
* document length.
*/
bool get_sumpart_needs_doclength_() const {
return stats_needed & DOC_LENGTH;
}
/** @private @internal Return true if the WDF is needed.
*
* If this method returns true, then the WDF will be fetched and passed to
* @a get_sumpart(). Otherwise 0 may be passed for the wdf.
*/
bool get_sumpart_needs_wdf_() const {
return stats_needed & WDF;
}
/** @private @internal Return true if the number of unique terms is needed.
*
* If this method returns true, then the number of unique terms will be
* fetched and passed to @a get_sumpart(). Otherwise 0 may be passed for
* the number of unique terms.
*/
bool get_sumpart_needs_uniqueterms_() const {
return stats_needed & UNIQUE_TERMS;
}
/// @private @internal Test if this is a BoolWeight object.
bool is_bool_weight_() const {
// Checking the name isn't ideal, but (get_maxpart() == 0.0) isn't
// required to work without init() having been called. We can at
// least avoid the virtual method call in most non-BoolWeight cases
// as most other classes will need at least some stats.
return stats_needed == 0 && name() == "Xapian::BoolWeight";
}
protected:
/** Don't allow copying.
*
* This would ideally be private, but that causes a compilation error
* with GCC 4.1 (which appears to be a bug).
*/
Weight(const Weight &);
/// The number of documents in the collection.
Xapian::doccount get_collection_size() const { return collection_size_; }
/// The number of documents marked as relevant.
Xapian::doccount get_rset_size() const { return rset_size_; }
/// The average length of a document in the collection.
Xapian::doclength get_average_length() const { return average_length_; }
/// The number of documents which this term indexes.
Xapian::doccount get_termfreq() const { return termfreq_; }
/// The number of relevant documents which this term indexes.
Xapian::doccount get_reltermfreq() const { return reltermfreq_; }
/// The collection frequency of the term.
Xapian::termcount get_collection_freq() const { return collectionfreq_; }
/// The length of the query.
Xapian::termcount get_query_length() const { return query_length_; }
/// The within-query-frequency of this term.
Xapian::termcount get_wqf() const { return wqf_; }
/** An upper bound on the maximum length of any document in the database.
*
* This should only be used by get_maxpart() and get_maxextra().
*/
Xapian::termcount get_doclength_upper_bound() const {
return doclength_upper_bound_;
}
/** A lower bound on the minimum length of any document in the database.
*
* This bound does not include any zero-length documents.
*
* This should only be used by get_maxpart() and get_maxextra().
*/
Xapian::termcount get_doclength_lower_bound() const {
return doclength_lower_bound_;
}
/** An upper bound on the wdf of this term.
*
* This should only be used by get_maxpart() and get_maxextra().
*/
Xapian::termcount get_wdf_upper_bound() const {
return wdf_upper_bound_;
}
/// Total length of all documents in the collection.
Xapian::totallength get_total_length() const {
return Xapian::totallength(average_length_ * collection_size_ + 0.5);
}
};
/** Class implementing a "boolean" weighting scheme.
*
* This weighting scheme gives all documents zero weight.
*/
class XAPIAN_VISIBILITY_DEFAULT BoolWeight : public Weight {
BoolWeight * clone() const;
void init(double factor);
public:
/** Construct a BoolWeight. */
BoolWeight() { }
std::string name() const;
std::string serialise() const;
BoolWeight * unserialise(const std::string & serialised) const;
double get_sumpart(Xapian::termcount wdf,
Xapian::termcount doclen,
Xapian::termcount uniqterms) const;
double get_maxpart() const;
double get_sumextra(Xapian::termcount doclen,
Xapian::termcount uniqterms) const;
double get_maxextra() const;
};
/// Xapian::Weight subclass implementing the tf-idf weighting scheme.
class XAPIAN_VISIBILITY_DEFAULT TfIdfWeight : public Weight {
/* Three character string indicating the normalizations for tf(wdf), idf and
tfidf weight. */
std::string normalizations;
/// The factor to multiply with the weight.
double factor;
TfIdfWeight * clone() const;
void init(double factor);
/* When additional normalizations are implemented in the future, the additional statistics for them
should be accessed by these functions. */
double get_wdfn(Xapian::termcount wdf, char c) const;
double get_idfn(Xapian::doccount termfreq, char c) const;
double get_wtn(double wt, char c) const;
public:
/** Construct a TfIdfWeight
*
* @param normalizations A three character string indicating the
* normalizations to be used for the tf(wdf), idf
* and document weight. (default: "ntn")
*
* The @a normalizations string works like so:
*
* @li The first character specifies the normalization for the wdf. The
* following normalizations are currently supported:
*
* @li 'n': None. wdfn=wdf
* @li 'b': Boolean wdfn=1 if term in document else wdfn=0
* @li 's': Square wdfn=wdf*wdf
* @li 'l': Logarithmic wdfn=1+log<sub>e</sub>(wdf)
* @li 'L': Log average wdfn=(1+log(wdf))/(1+log(doclen/unique_terms))
*
* The Max-wdf and Augmented Max wdf normalizations haven't yet been
* implemented.
*
* @li The second character indicates the normalization for the idf. The
* following normalizations are currently supported:
*
* @li 'n': None idfn=1
* @li 't': TfIdf idfn=log(N/Termfreq) where N is the number of
* documents in collection and Termfreq is the number of documents
* which are indexed by the term t.
* @li 'p': Prob idfn=log((N-Termfreq)/Termfreq)
* @li 'f': Freq idfn=1/Termfreq
* @li 's': Squared idfn=(log(N/Termfreq))²
*
* @li The third and the final character indicates the normalization for
* the document weight. The following normalizations are currently
* supported:
*
* @li 'n': None wtn=tfn*idfn
*
* Implementing support for more normalizations of each type would require
* extending the backend to track more statistics.
*/
explicit TfIdfWeight(const std::string &normalizations);
/** Construct a TfIdfWeight using the default normalizations ("ntn"). */
TfIdfWeight()
: normalizations("ntn")
{
need_stat(TERMFREQ);
need_stat(WDF);
need_stat(WDF_MAX);
need_stat(COLLECTION_SIZE);
}
std::string name() const;
std::string serialise() const;
TfIdfWeight * unserialise(const std::string & serialised) const;
double get_sumpart(Xapian::termcount wdf,
Xapian::termcount doclen,
Xapian::termcount uniqterm) const;
double get_maxpart() const;
double get_sumextra(Xapian::termcount doclen,
Xapian::termcount uniqterms) const;
double get_maxextra() const;
};
/// Xapian::Weight subclass implementing the BM25 probabilistic formula.
class XAPIAN_VISIBILITY_DEFAULT BM25Weight : public Weight {
/// Factor to multiply the document length by.
mutable Xapian::doclength len_factor;
/// Factor combining all the document independent factors.
mutable double termweight;
/// The BM25 parameters.
double param_k1, param_k2, param_k3, param_b;
/// The minimum normalised document length value.
Xapian::doclength param_min_normlen;
BM25Weight * clone() const;
void init(double factor);
public:
/** Construct a BM25Weight.
*
* @param k1 A non-negative parameter controlling how influential
* within-document-frequency (wdf) is. k1=0 means that
* wdf doesn't affect the weights. The larger k1 is, the more
* wdf influences the weights. (default 1)
*
* @param k2 A non-negative parameter which controls the strength of a
* correction factor which depends upon query length and
* normalised document length. k2=0 disable this factor; larger
* k2 makes it stronger. (default 0)
*
* @param k3 A non-negative parameter controlling how influential
* within-query-frequency (wqf) is. k3=0 means that wqf
* doesn't affect the weights. The larger k3 is, the more
* wqf influences the weights. (default 1)
*
* @param b A parameter between 0 and 1, controlling how strong the
* document length normalisation of wdf is. 0 means no
* normalisation; 1 means full normalisation. (default 0.5)
*
* @param min_normlen A parameter specifying a minimum value for
* normalised document length. Normalised document length
* values less than this will be clamped to this value, helping
* to prevent very short documents getting large weights.
* (default 0.5)
*/
BM25Weight(double k1, double k2, double k3, double b, double min_normlen)
: param_k1(k1), param_k2(k2), param_k3(k3), param_b(b),
param_min_normlen(min_normlen)
{
if (param_k1 < 0) param_k1 = 0;
if (param_k2 < 0) param_k2 = 0;
if (param_k3 < 0) param_k3 = 0;
if (param_b < 0) {
param_b = 0;
} else if (param_b > 1) {
param_b = 1;
}
need_stat(COLLECTION_SIZE);
need_stat(RSET_SIZE);
need_stat(TERMFREQ);
need_stat(RELTERMFREQ);
need_stat(WDF);
need_stat(WDF_MAX);
if (param_k2 != 0 || (param_k1 != 0 && param_b != 0)) {
need_stat(DOC_LENGTH_MIN);
need_stat(AVERAGE_LENGTH);
}
if (param_k1 != 0 && param_b != 0) need_stat(DOC_LENGTH);
if (param_k2 != 0) need_stat(QUERY_LENGTH);
if (param_k3 != 0) need_stat(WQF);
}
BM25Weight()
: param_k1(1), param_k2(0), param_k3(1), param_b(0.5),
param_min_normlen(0.5)
{
need_stat(COLLECTION_SIZE);
need_stat(RSET_SIZE);
need_stat(TERMFREQ);
need_stat(RELTERMFREQ);
need_stat(WDF);
need_stat(WDF_MAX);
need_stat(DOC_LENGTH_MIN);
need_stat(AVERAGE_LENGTH);
need_stat(DOC_LENGTH);
need_stat(WQF);
}
std::string name() const;
std::string serialise() const;
BM25Weight * unserialise(const std::string & serialised) const;
double get_sumpart(Xapian::termcount wdf,
Xapian::termcount doclen,
Xapian::termcount uniqterm) const;
double get_maxpart() const;
double get_sumextra(Xapian::termcount doclen,
Xapian::termcount uniqterms) const;
double get_maxextra() const;
};
/// Xapian::Weight subclass implementing the BM25+ probabilistic formula.
class XAPIAN_VISIBILITY_DEFAULT BM25PlusWeight : public Weight {
/// Factor to multiply the document length by.
mutable Xapian::doclength len_factor;
/// Factor combining all the document independent factors.
mutable double termweight;
/// The BM25+ parameters.
double param_k1, param_k2, param_k3, param_b;
/// The minimum normalised document length value.
Xapian::doclength param_min_normlen;
/// Additional parameter delta in the BM25+ formula.
double param_delta;
BM25PlusWeight * clone() const;
void init(double factor);
public:
/** Construct a BM25PlusWeight.
*
* @param k1 A non-negative parameter controlling how influential
* within-document-frequency (wdf) is. k1=0 means that
* wdf doesn't affect the weights. The larger k1 is, the more
* wdf influences the weights. (default 1)
*
* @param k2 A non-negative parameter which controls the strength of a
* correction factor which depends upon query length and
* normalised document length. k2=0 disable this factor; larger
* k2 makes it stronger. The paper which describes BM25+
* ignores BM25's document-independent component (so implicitly
* k2=0), but we support non-zero k2 too. (default 0)
*
* @param k3 A non-negative parameter controlling how influential
* within-query-frequency (wqf) is. k3=0 means that wqf
* doesn't affect the weights. The larger k3 is, the more
* wqf influences the weights. (default 1)
*
* @param b A parameter between 0 and 1, controlling how strong the
* document length normalisation of wdf is. 0 means no
* normalisation; 1 means full normalisation. (default 0.5)
*
* @param min_normlen A parameter specifying a minimum value for
* normalised document length. Normalised document length
* values less than this will be clamped to this value, helping
* to prevent very short documents getting large weights.
* (default 0.5)
*
* @param delta A parameter for pseudo tf value to control the scale
* of the tf lower bound. Delta(δ) can be tuned for example
* from 0.0 to 1.5 but BM25+ can still work effectively
* across collections with a fixed δ = 1.0. (default 1.0)
*/
BM25PlusWeight(double k1, double k2, double k3, double b,
double min_normlen, double delta)
: param_k1(k1), param_k2(k2), param_k3(k3), param_b(b),
param_min_normlen(min_normlen), param_delta(delta)
{
if (param_k1 < 0) param_k1 = 0;
if (param_k2 < 0) param_k2 = 0;
if (param_k3 < 0) param_k3 = 0;
if (param_delta < 0) param_delta = 0;
if (param_b < 0) {
param_b = 0;
} else if (param_b > 1) {
param_b = 1;
}
need_stat(COLLECTION_SIZE);
need_stat(RSET_SIZE);
need_stat(TERMFREQ);
need_stat(RELTERMFREQ);
need_stat(WDF);
need_stat(WDF_MAX);
if (param_k2 != 0 || (param_k1 != 0 && param_b != 0)) {
need_stat(DOC_LENGTH_MIN);
need_stat(AVERAGE_LENGTH);
}
if (param_k1 != 0 && param_b != 0) need_stat(DOC_LENGTH);
if (param_k2 != 0) need_stat(QUERY_LENGTH);
if (param_k3 != 0) need_stat(WQF);
if (param_delta != 0) {
need_stat(AVERAGE_LENGTH);
need_stat(DOC_LENGTH);
need_stat(WQF);
}
}
BM25PlusWeight()
: param_k1(1), param_k2(0), param_k3(1), param_b(0.5),
param_min_normlen(0.5), param_delta(1)
{
need_stat(COLLECTION_SIZE);
need_stat(RSET_SIZE);
need_stat(TERMFREQ);
need_stat(RELTERMFREQ);
need_stat(WDF);
need_stat(WDF_MAX);
need_stat(DOC_LENGTH_MIN);
need_stat(AVERAGE_LENGTH);
need_stat(DOC_LENGTH);
need_stat(WQF);
}
std::string name() const;
std::string serialise() const;
BM25PlusWeight * unserialise(const std::string & serialised) const;
double get_sumpart(Xapian::termcount wdf,
Xapian::termcount doclen,
Xapian::termcount uniqterm) const;
double get_maxpart() const;
double get_sumextra(Xapian::termcount doclen,
Xapian::termcount uniqterms) const;
double get_maxextra() const;
};
/** Xapian::Weight subclass implementing the traditional probabilistic formula.
*
* This class implements the "traditional" Probabilistic Weighting scheme, as
* described by the early papers on Probabilistic Retrieval. BM25 generally
* gives better results.
*
* TradWeight(k) is equivalent to BM25Weight(k, 0, 0, 1, 0), except that
* the latter returns weights (k+1) times larger.
*/
class XAPIAN_VISIBILITY_DEFAULT TradWeight : public Weight {
/// Factor to multiply the document length by.
mutable Xapian::doclength len_factor;
/// Factor combining all the document independent factors.
mutable double termweight;
/// The parameter in the formula.
double param_k;
TradWeight * clone() const;
void init(double factor);
public:
/** Construct a TradWeight.
*
* @param k A non-negative parameter controlling how influential
* within-document-frequency (wdf) and document length are.
* k=0 means that wdf and document length don't affect the
* weights. The larger k is, the more they do. (default 1)
*/
explicit TradWeight(double k = 1.0) : param_k(k) {
if (param_k < 0) param_k = 0;
if (param_k != 0.0) {
need_stat(AVERAGE_LENGTH);
need_stat(DOC_LENGTH);
}
need_stat(COLLECTION_SIZE);
need_stat(RSET_SIZE);
need_stat(TERMFREQ);
need_stat(RELTERMFREQ);
need_stat(DOC_LENGTH_MIN);
need_stat(WDF);
need_stat(WDF_MAX);
}
std::string name() const;
std::string serialise() const;
TradWeight * unserialise(const std::string & serialised) const;
double get_sumpart(Xapian::termcount wdf,
Xapian::termcount doclen,
Xapian::termcount uniqueterms) const;
double get_maxpart() const;
double get_sumextra(Xapian::termcount doclen,
Xapian::termcount uniqterms) const;
double get_maxextra() const;
};
/** This class implements the InL2 weighting scheme.
*
* InL2 is a representative scheme of the Divergence from Randomness Framework
* by Gianni Amati.
*
* This weighting scheme is useful for tasks that require early precision.
*
* It uses the Inverse document frequency model (In), the Laplace method to
* find the aftereffect of sampling (L) and the second wdf normalization
* proposed by Amati to normalize the wdf in the document to the length of the
* document (H2).
*
* For more information about the DFR Framework and the InL2 scheme, please
* refer to: Gianni Amati and Cornelis Joost Van Rijsbergen Probabilistic
* models of information retrieval based on measuring the divergence from
* randomness ACM Transactions on Information Systems (TOIS) 20, (4), 2002,
* pp. 357-389.
*/
class XAPIAN_VISIBILITY_DEFAULT InL2Weight : public Weight {
/// The wdf normalization parameter in the formula.
double param_c;
/// The upper bound on the weight a term can give to a document.
double upper_bound;
/// The constant values which are used on every call to get_sumpart().
double wqf_product_idf;
double c_product_avlen;
InL2Weight * clone() const;
void init(double factor);
public:
/** Construct an InL2Weight.
*
* @param c A strictly positive parameter controlling the extent
* of the normalization of the wdf to the document length. The
* default value of 1 is suitable for longer queries but it may
* need to be changed for shorter queries. For more information,
* please refer to Gianni Amati's PHD thesis.
*/
explicit InL2Weight(double c);
InL2Weight()
: param_c(1.0)
{
need_stat(AVERAGE_LENGTH);
need_stat(DOC_LENGTH);
need_stat(DOC_LENGTH_MIN);
need_stat(DOC_LENGTH_MAX);
need_stat(COLLECTION_SIZE);
need_stat(WDF);
need_stat(WDF_MAX);
need_stat(WQF);
need_stat(TERMFREQ);
}
std::string name() const;
std::string serialise() const;
InL2Weight * unserialise(const std::string & serialised) const;
double get_sumpart(Xapian::termcount wdf,
Xapian::termcount doclen,
Xapian::termcount uniqterms) const;
double get_maxpart() const;
double get_sumextra(Xapian::termcount doclen,
Xapian::termcount uniqterms) const;
double get_maxextra() const;
};
/** This class implements the IfB2 weighting scheme.
*
* IfB2 is a representative scheme of the Divergence from Randomness Framework
* by Gianni Amati.
*
* It uses the Inverse term frequency model (If), the Bernoulli method to find
* the aftereffect of sampling (B) and the second wdf normalization proposed
* by Amati to normalize the wdf in the document to the length of the document
* (H2).
*
* For more information about the DFR Framework and the IfB2 scheme, please
* refer to: Gianni Amati and Cornelis Joost Van Rijsbergen Probabilistic
* models of information retrieval based on measuring the divergence from
* randomness ACM Transactions on Information Systems (TOIS) 20, (4), 2002,
* pp. 357-389.
*/
class XAPIAN_VISIBILITY_DEFAULT IfB2Weight : public Weight {
/// The wdf normalization parameter in the formula.
double param_c;
/// The upper bound on the weight.
double upper_bound;
/// The constant values which are used for calculations in get_sumpart().
double wqf_product_idf;
double c_product_avlen;
double B_constant;
IfB2Weight * clone() const;
void init(double factor);
public:
/** Construct an IfB2Weight.
*
* @param c A strictly positive parameter controlling the extent
* of the normalization of the wdf to the document length. The
* default value of 1 is suitable for longer queries but it may
* need to be changed for shorter queries. For more information,
* please refer to Gianni Amati's PHD thesis titled
* Probabilistic Models for Information Retrieval based on
* Divergence from Randomness.
*/
explicit IfB2Weight(double c);
IfB2Weight() : param_c(1.0) {
need_stat(AVERAGE_LENGTH);
need_stat(DOC_LENGTH);
need_stat(DOC_LENGTH_MIN);
need_stat(DOC_LENGTH_MAX);
need_stat(COLLECTION_SIZE);
need_stat(COLLECTION_FREQ);
need_stat(WDF);
need_stat(WDF_MAX);
need_stat(WQF);
need_stat(TERMFREQ);
}
std::string name() const;
std::string serialise() const;
IfB2Weight * unserialise(const std::string & serialised) const;
double get_sumpart(Xapian::termcount wdf,
Xapian::termcount doclen,
Xapian::termcount uniqterm) const;
double get_maxpart() const;
double get_sumextra(Xapian::termcount doclen,
Xapian::termcount uniqterms) const;
double get_maxextra() const;
};
/** This class implements the IneB2 weighting scheme.
*
* IneB2 is a representative scheme of the Divergence from Randomness
* Framework by Gianni Amati.
*
* It uses the Inverse expected document frequency model (Ine), the Bernoulli
* method to find the aftereffect of sampling (B) and the second wdf
* normalization proposed by Amati to normalize the wdf in the document to the
* length of the document (H2).
*
* For more information about the DFR Framework and the IneB2 scheme, please
* refer to: Gianni Amati and Cornelis Joost Van Rijsbergen Probabilistic
* models of information retrieval based on measuring the divergence from
* randomness ACM Transactions on Information Systems (TOIS) 20, (4), 2002,
* pp. 357-389.
*/
class XAPIAN_VISIBILITY_DEFAULT IneB2Weight : public Weight {
/// The wdf normalization parameter in the formula.
double param_c;
/// The upper bound of the weight.
double upper_bound;
/// Constant values used in get_sumpart().
double wqf_product_idf;
double c_product_avlen;
double B_constant;
IneB2Weight * clone() const;
void init(double factor);
public:
/** Construct an IneB2Weight.
*
* @param c A strictly positive parameter controlling the extent
* of the normalization of the wdf to the document length. The
* default value of 1 is suitable for longer queries but it may
* need to be changed for shorter queries. For more information,
* please refer to Gianni Amati's PHD thesis.
*/
explicit IneB2Weight(double c);
IneB2Weight() : param_c(1.0) {
need_stat(AVERAGE_LENGTH);
need_stat(DOC_LENGTH);
need_stat(DOC_LENGTH_MIN);
need_stat(DOC_LENGTH_MAX);
need_stat(COLLECTION_SIZE);
need_stat(WDF);
need_stat(WDF_MAX);
need_stat(WQF);
need_stat(COLLECTION_FREQ);
need_stat(TERMFREQ);
}
std::string name() const;
std::string serialise() const;
IneB2Weight * unserialise(const std::string & serialised) const;
double get_sumpart(Xapian::termcount wdf,
Xapian::termcount doclen,
Xapian::termcount uniqterms) const;
double get_maxpart() const;
double get_sumextra(Xapian::termcount doclen,
Xapian::termcount uniqterms) const;
double get_maxextra() const;
};
/** This class implements the BB2 weighting scheme.
*
* BB2 is a representative scheme of the Divergence from Randomness Framework
* by Gianni Amati.
*
* It uses the Bose-Einstein probabilistic distribution (B) along with
* Stirling's power approximation, the Bernoulli method to find the
* aftereffect of sampling (B) and the second wdf normalization proposed by
* Amati to normalize the wdf in the document to the length of the document
* (H2).
*
* For more information about the DFR Framework and the BB2 scheme, please
* refer to : Gianni Amati and Cornelis Joost Van Rijsbergen Probabilistic
* models of information retrieval based on measuring the divergence from
* randomness ACM Transactions on Information Systems (TOIS) 20, (4), 2002,
* pp. 357-389.
*/
class XAPIAN_VISIBILITY_DEFAULT BB2Weight : public Weight {
/// The wdf normalization parameter in the formula.
double param_c;
/// The upper bound on the weight.
double upper_bound;
/// The constant values to be used in get_sumpart().
double c_product_avlen;
double B_constant;
double wt;
double stirling_constant_1;
double stirling_constant_2;
BB2Weight * clone() const;
void init(double factor);
public:
/** Construct a BB2Weight.
*
* @param c A strictly positive parameter controlling the extent
* of the normalization of the wdf to the document length. A
* default value of 1 is suitable for longer queries but it may
* need to be changed for shorter queries. For more information,
* please refer to Gianni Amati's PHD thesis titled
* Probabilistic Models for Information Retrieval based on
* Divergence from Randomness.
*/
explicit BB2Weight(double c);
BB2Weight() : param_c(1.0) {
need_stat(AVERAGE_LENGTH);
need_stat(DOC_LENGTH);
need_stat(DOC_LENGTH_MIN);
need_stat(DOC_LENGTH_MAX);
need_stat(COLLECTION_SIZE);
need_stat(COLLECTION_FREQ);
need_stat(WDF);
need_stat(WDF_MAX);
need_stat(WQF);
need_stat(TERMFREQ);
}
std::string name() const;
std::string serialise() const;
BB2Weight * unserialise(const std::string & serialised) const;
double get_sumpart(Xapian::termcount wdf,
Xapian::termcount doclen,
Xapian::termcount uniqterms) const;
double get_maxpart() const;
double get_sumextra(Xapian::termcount doclen,
Xapian::termcount uniqterms) const;
double get_maxextra() const;
};
/** This class implements the DLH weighting scheme, which is a representative
* scheme of the Divergence from Randomness Framework by Gianni Amati.
*
* This is a parameter free weighting scheme and it should be used with query
* expansion to obtain better results. It uses the HyperGeometric Probabilistic
* model and Laplace's normalization to calculate the risk gain.
*
* For more information about the DFR Framework and the DLH scheme, please
* refer to :
* a.) Gianni Amati and Cornelis Joost Van Rijsbergen Probabilistic
* models of information retrieval based on measuring the divergence from
* randomness ACM Transactions on Information Systems (TOIS) 20, (4), 2002, pp.
* 357-389.
* b.) FUB, IASI-CNR and University of Tor Vergata at TREC 2007 Blog Track.
* G. Amati and E. Ambrosi and M. Bianchi and C. Gaibisso and G. Gambosi.
* Proceedings of the 16th Text REtrieval Conference (TREC-2007), 2008.
*/
class XAPIAN_VISIBILITY_DEFAULT DLHWeight : public Weight {
/// Now unused but left in place in 1.4.x for ABI compatibility.
double lower_bound;
/// The upper bound on the weight.
double upper_bound;
/// The constant value to be used in get_sumpart().
double log_constant;
double wqf_product_factor;
DLHWeight * clone() const;
void init(double factor);
public:
DLHWeight() {
need_stat(DOC_LENGTH);
need_stat(COLLECTION_FREQ);
need_stat(WDF);
need_stat(WQF);
need_stat(WDF_MAX);
need_stat(DOC_LENGTH_MIN);
need_stat(DOC_LENGTH_MAX);
need_stat(TOTAL_LENGTH);
}
std::string name() const;
std::string serialise() const;
DLHWeight * unserialise(const std::string & serialised) const;
double get_sumpart(Xapian::termcount wdf,
Xapian::termcount doclen,
Xapian::termcount uniqterms) const;
double get_maxpart() const;
double get_sumextra(Xapian::termcount doclen,
Xapian::termcount uniqterms) const;
double get_maxextra() const;
};
/** This class implements the PL2 weighting scheme.
*
* PL2 is a representative scheme of the Divergence from Randomness Framework
* by Gianni Amati.
*
* This weighting scheme is useful for tasks that require early precision.
*
* It uses the Poisson approximation of the Binomial Probabilistic distribution
* (P) along with Stirling's approximation for the factorial value, the Laplace
* method to find the aftereffect of sampling (L) and the second wdf
* normalization proposed by Amati to normalize the wdf in the document to the
* length of the document (H2).
*
* For more information about the DFR Framework and the PL2 scheme, please
* refer to : Gianni Amati and Cornelis Joost Van Rijsbergen Probabilistic models
* of information retrieval based on measuring the divergence from randomness
* ACM Transactions on Information Systems (TOIS) 20, (4), 2002, pp. 357-389.
*/
class XAPIAN_VISIBILITY_DEFAULT PL2Weight : public Weight {
/// The wdf normalization parameter in the formula.
double param_c;
/** The factor to multiply weights by.
*
* The misleading name is due to this having been used to store a lower
* bound in 1.4.0. We no longer need to store that, and so this member
* has been repurposed in 1.4.1 and later (but the name left the same to
* ensure ABI compatibility with 1.4.0).
*/
double lower_bound;
/// The upper bound on the weight.
double upper_bound;
/// Constants for a given term in a given query.
double P1, P2;
/// Set by init() to (param_c * get_average_length())
double cl;
PL2Weight * clone() const;
void init(double factor);
public:
/** Construct a PL2Weight.
*
* @param c A strictly positive parameter controlling the extent
* of the normalization of the wdf to the document length. The
* default value of 1 is suitable for longer queries but it may
* need to be changed for shorter queries. For more information,
* please refer to Gianni Amati's PHD thesis titled
* Probabilistic Models for Information Retrieval based on
* Divergence from Randomness.
*/
explicit PL2Weight(double c);
PL2Weight() : param_c(1.0) {
need_stat(AVERAGE_LENGTH);
need_stat(DOC_LENGTH);
need_stat(DOC_LENGTH_MIN);
need_stat(DOC_LENGTH_MAX);
need_stat(COLLECTION_SIZE);
need_stat(COLLECTION_FREQ);
need_stat(WDF);
need_stat(WDF_MAX);
need_stat(WQF);
}
std::string name() const;
std::string serialise() const;
PL2Weight * unserialise(const std::string & serialised) const;
double get_sumpart(Xapian::termcount wdf,
Xapian::termcount doclen,
Xapian::termcount uniqterms) const;
double get_maxpart() const;
double get_sumextra(Xapian::termcount doclen,
Xapian::termcount uniqterms) const;
double get_maxextra() const;
};
/// Xapian::Weight subclass implementing the PL2+ probabilistic formula.
class XAPIAN_VISIBILITY_DEFAULT PL2PlusWeight : public Weight {
/// The factor to multiply weights by.
double factor;
/// The wdf normalization parameter in the formula.
double param_c;
/// Additional parameter delta in the PL2+ weighting formula.
double param_delta;
/// The upper bound on the weight.
double upper_bound;
/// Constants for a given term in a given query.
double P1, P2;
/// Set by init() to (param_c * get_average_length())
double cl;
/// Set by init() to get_collection_freq()) / get_collection_size()
double mean;
/// Weight contribution of delta term in the PL2+ function
double dw;
PL2PlusWeight * clone() const;
void init(double factor_);
public:
/** Construct a PL2PlusWeight.
*
* @param c A strictly positive parameter controlling the extent
* of the normalization of the wdf to the document length. The
* default value of 1 is suitable for longer queries but it may
* need to be changed for shorter queries. For more information,
* please refer to Gianni Amati's PHD thesis titled
* Probabilistic Models for Information Retrieval based on
* Divergence from Randomness.
*
* @param delta A parameter for pseudo tf value to control the scale
* of the tf lower bound. Delta(δ) should be a positive
* real number. It can be tuned for example from 0.1 to 1.5
* in increments of 0.1 or so. Experiments have shown that
* PL2+ works effectively across collections with a fixed δ = 0.8
* (default 0.8)
*/
PL2PlusWeight(double c, double delta);
PL2PlusWeight()
: param_c(1.0), param_delta(0.8) {
need_stat(AVERAGE_LENGTH);
need_stat(DOC_LENGTH);
need_stat(DOC_LENGTH_MIN);
need_stat(DOC_LENGTH_MAX);
need_stat(COLLECTION_SIZE);
need_stat(COLLECTION_FREQ);
need_stat(WDF);
need_stat(WDF_MAX);
need_stat(WQF);
}
std::string name() const;
std::string serialise() const;
PL2PlusWeight * unserialise(const std::string & serialised) const;
double get_sumpart(Xapian::termcount wdf,
Xapian::termcount doclen,
Xapian::termcount uniqterms) const;
double get_maxpart() const;
double get_sumextra(Xapian::termcount doclen,
Xapian::termcount uniqterms) const;
double get_maxextra() const;
};
/** This class implements the DPH weighting scheme.
*
* DPH is a representative scheme of the Divergence from Randomness Framework
* by Gianni Amati.
*
* This is a parameter free weighting scheme and it should be used with query
* expansion to obtain better results. It uses the HyperGeometric Probabilistic
* model and Popper's normalization to calculate the risk gain.
*
* For more information about the DFR Framework and the DPH scheme, please
* refer to :
* a.) Gianni Amati and Cornelis Joost Van Rijsbergen
* Probabilistic models of information retrieval based on measuring the
* divergence from randomness ACM Transactions on Information Systems (TOIS) 20,
* (4), 2002, pp. 357-389.
* b.) FUB, IASI-CNR and University of Tor Vergata at TREC 2007 Blog Track.
* G. Amati and E. Ambrosi and M. Bianchi and C. Gaibisso and G. Gambosi.
* Proceedings of the 16th Text Retrieval Conference (TREC-2007), 2008.
*/
class XAPIAN_VISIBILITY_DEFAULT DPHWeight : public Weight {
/// The upper bound on the weight.
double upper_bound;
/// Now unused but left in place in 1.4.x for ABI compatibility.
double lower_bound;
/// The constant value used in get_sumpart() .
double log_constant;
double wqf_product_factor;
DPHWeight * clone() const;
void init(double factor);
public:
/** Construct a DPHWeight. */
DPHWeight() {
need_stat(DOC_LENGTH);
need_stat(COLLECTION_FREQ);
need_stat(WDF);
need_stat(WQF);
need_stat(WDF_MAX);
need_stat(DOC_LENGTH_MIN);
need_stat(DOC_LENGTH_MAX);
need_stat(TOTAL_LENGTH);
}
std::string name() const;
std::string serialise() const;
DPHWeight * unserialise(const std::string & serialised) const;
double get_sumpart(Xapian::termcount wdf,
Xapian::termcount doclen,
Xapian::termcount uniqterms) const;
double get_maxpart() const;
double get_sumextra(Xapian::termcount doclen,
Xapian::termcount uniqterms) const;
double get_maxextra() const;
};
/** Xapian::Weight subclass implementing the Language Model formula.
*
* This class implements the "Language Model" Weighting scheme, as
* described by the early papers on LM by Bruce Croft.
*
* LM works by comparing the query to a Language Model of the document.
* The language model itself is parameter-free, though LMWeight takes
* parameters which specify the smoothing used.
*/
class XAPIAN_VISIBILITY_DEFAULT LMWeight : public Weight {
/** The type of smoothing to use. */
type_smoothing select_smoothing;
// Parameters for handling negative value of log, and for smoothing.
double param_log, param_smoothing1, param_smoothing2;
/** The factor to multiply weights by.
*
* The misleading name is due to this having been used to store some
* other value in 1.4.0. However, that value only takes one
* multiplication and one division to calculate, so for 1.4.x we can just
* recalculate it each time we need it, and so this member has been
* repurposed in 1.4.1 and later (but the name left the same to ensure ABI
* compatibility with 1.4.0).
*/
double weight_collection;
LMWeight * clone() const;
void init(double factor);
public:
/** Construct a LMWeight.
*
* @param param_log_ A non-negative parameter controlling how much
* to clamp negative values returned by the log.
* The log is calculated by multiplying the
* actual weight by param_log. If param_log is
* 0.0, then the document length upper bound will
* be used (default: document length upper bound)
*
* @param select_smoothing_ A parameter of type enum
* type_smoothing. This parameter
* controls which smoothing type to use.
* (default: TWO_STAGE_SMOOTHING)
*
* @param param_smoothing1_ A non-negative parameter for smoothing
* whose meaning depends on
* select_smoothing_. In
* JELINEK_MERCER_SMOOTHING, it plays the
* role of estimation and in
* DIRICHLET_SMOOTHING the role of query
* modelling. (default JELINEK_MERCER,
* ABSOLUTE, TWOSTAGE(0.7),
* DIRCHLET(2000))
*
* @param param_smoothing2_ A non-negative parameter which is used
* with TWO_STAGE_SMOOTHING as parameter for Dirichlet's
* smoothing (default: 2000) and as parameter delta to
* control the scale of the tf lower bound in the
* DIRICHLET_PLUS_SMOOTHING (default 0.05).
*
*/
// Unigram LM Constructor to specifically mention all parameters for handling negative log value and smoothing.
explicit LMWeight(double param_log_ = 0.0,
type_smoothing select_smoothing_ = TWO_STAGE_SMOOTHING,
double param_smoothing1_ = -1.0,
double param_smoothing2_ = -1.0)
: select_smoothing(select_smoothing_), param_log(param_log_), param_smoothing1(param_smoothing1_),
param_smoothing2(param_smoothing2_)
{
if (param_smoothing1 < 0) param_smoothing1 = 0.7;
if (param_smoothing2 < 0) {
if (select_smoothing == TWO_STAGE_SMOOTHING)
param_smoothing2 = 2000.0;
else
param_smoothing2 = 0.05;
}
need_stat(DOC_LENGTH);
need_stat(RSET_SIZE);
need_stat(TERMFREQ);
need_stat(RELTERMFREQ);
need_stat(DOC_LENGTH_MAX);
need_stat(WDF);
need_stat(WDF_MAX);
need_stat(COLLECTION_FREQ);
need_stat(TOTAL_LENGTH);
if (select_smoothing == ABSOLUTE_DISCOUNT_SMOOTHING)
need_stat(UNIQUE_TERMS);
if (select_smoothing == DIRICHLET_PLUS_SMOOTHING)
need_stat(DOC_LENGTH_MIN);
}
std::string name() const;
std::string serialise() const;
LMWeight * unserialise(const std::string & serialised) const;
double get_sumpart(Xapian::termcount wdf,
Xapian::termcount doclen,
Xapian::termcount uniqterm) const;
double get_maxpart() const;
double get_sumextra(Xapian::termcount doclen, Xapian::termcount) const;
double get_maxextra() const;
};
/** Xapian::Weight subclass implementing Coordinate Matching.
*
* Each matching term score one point. See Managing Gigabytes, Second Edition
* p181.
*/
class XAPIAN_VISIBILITY_DEFAULT CoordWeight : public Weight {
/// The factor to multiply weights by.
double factor;
public:
CoordWeight * clone() const;
void init(double factor_);
/** Construct a CoordWeight. */
CoordWeight() { }
std::string name() const;
std::string serialise() const;
CoordWeight * unserialise(const std::string & serialised) const;
double get_sumpart(Xapian::termcount wdf,
Xapian::termcount doclen,
Xapian::termcount uniqterm) const;
double get_maxpart() const;
double get_sumextra(Xapian::termcount, Xapian::termcount) const;
double get_maxextra() const;
};
}
#endif // XAPIAN_INCLUDED_WEIGHT_H