#ifndef lint
static char rcsid[] = "@(#$Id: searchdata.cpp,v 1.31 2008-12-19 09:44:39 dockes Exp $ (C) 2006 J.F.Dockes";
#endif
/*
* 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.,
* 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
*/
// Handle translation from rcl's SearchData structures to Xapian Queries
#include <string>
#include <vector>
#include "xapian.h"
#include "rcldb.h"
#include "searchdata.h"
#include "debuglog.h"
#include "smallut.h"
#include "textsplit.h"
#include "unacpp.h"
#include "utf8iter.h"
#include "stoplist.h"
#include "rclconfig.h"
#ifndef NO_NAMESPACES
using namespace std;
namespace Rcl {
#endif
typedef vector<SearchDataClause *>::iterator qlist_it_t;
typedef vector<SearchDataClause *>::const_iterator qlist_cit_t;
static const int original_term_wqf_booster = 10;
bool SearchData::toNativeQuery(Rcl::Db &db, void *d)
{
Xapian::Query xq;
m_reason.erase();
if (m_query.size() < 1) {
m_reason = "empty query";
return false;
}
// It's not allowed to have a pure negative query and also it
// seems that Xapian doesn't like the first element to be AND_NOT
qlist_it_t itnotneg = m_query.end();
for (qlist_it_t it = m_query.begin(); it != m_query.end(); it++) {
if ((*it)->m_tp != SCLT_EXCL) {
itnotneg = it;
break;
}
}
if (itnotneg == m_query.end()) {
LOGERR(("SearchData::toNativeQuery: can't have all negative clauses"));
m_reason = "Can't have only negative clauses";
return false;
}
if ((*m_query.begin())->m_tp == SCLT_EXCL)
iter_swap(m_query.begin(), itnotneg);
// Walk the clause list translating each in turn and building the
// Xapian query tree
for (qlist_it_t it = m_query.begin(); it != m_query.end(); it++) {
Xapian::Query nq;
if (!(*it)->toNativeQuery(db, &nq, m_stemlang)) {
LOGERR(("SearchData::toNativeQuery: failed\n"));
m_reason = (*it)->getReason();
return false;
}
// If this structure is an AND list, must use AND_NOT for excl clauses.
// Else this is an OR list, and there can't be excl clauses (checked by
// addClause())
Xapian::Query::op op;
if (m_tp == SCLT_AND) {
op = (*it)->m_tp == SCLT_EXCL ?
Xapian::Query::OP_AND_NOT: Xapian::Query::OP_AND;
} else {
op = Xapian::Query::OP_OR;
}
xq = xq.empty() ? nq : Xapian::Query(op, xq, nq);
}
// Add the file type filtering clause if any
if (!m_filetypes.empty()) {
vector<string> exptps;
exptps.reserve(m_filetypes.size());
// Expand categories
RclConfig *cfg = RclConfig::getMainConfig();
for (vector<string>::iterator it = m_filetypes.begin();
it != m_filetypes.end(); it++) {
if (cfg && cfg->isMimeCategory(*it)) {
list<string>tps;
cfg->getMimeCatTypes(*it, tps);
exptps.insert(exptps.end(), tps.begin(), tps.end());
} else {
exptps.push_back(*it);
}
}
list<Xapian::Query> pqueries;
Xapian::Query tq;
for (vector<string>::iterator it = exptps.begin();
it != exptps.end(); it++) {
string term = "T" + *it;
LOGDEB(("Adding file type term: [%s]\n", term.c_str()));
tq = tq.empty() ? Xapian::Query(term) :
Xapian::Query(Xapian::Query::OP_OR, tq, Xapian::Query(term));
}
xq = xq.empty() ? tq : Xapian::Query(Xapian::Query::OP_FILTER, xq, tq);
}
*((Xapian::Query *)d) = xq;
return true;
}
// Add clause to current list. OR lists cant have EXCL clauses.
bool SearchData::addClause(SearchDataClause* cl)
{
if (m_tp == SCLT_OR && (cl->m_tp == SCLT_EXCL)) {
LOGERR(("SearchData::addClause: cant add EXCL to OR list\n"));
m_reason = "No Negative (AND_NOT) clauses allowed in OR queries";
return false;
}
cl->setParent(this);
m_haveWildCards = m_haveWildCards || cl->m_haveWildCards;
m_query.push_back(cl);
return true;
}
// Make me all new
void SearchData::erase() {
LOGDEB(("SearchData::erase\n"));
m_tp = SCLT_AND;
for (qlist_it_t it = m_query.begin(); it != m_query.end(); it++)
delete *it;
m_query.clear();
m_filetypes.clear();
m_topdir.erase();
m_description.erase();
m_reason.erase();
}
// Am I a file name only search ? This is to turn off term highlighting
bool SearchData::fileNameOnly()
{
for (qlist_it_t it = m_query.begin(); it != m_query.end(); it++)
if (!(*it)->isFileName())
return false;
return true;
}
// Extract all terms and term groups
bool SearchData::getTerms(vector<string>& terms,
vector<vector<string> >& groups,
vector<int>& gslks) const
{
for (qlist_cit_t it = m_query.begin(); it != m_query.end(); it++)
(*it)->getTerms(terms, groups, gslks);
return true;
}
// Splitter callback for breaking a user string into simple terms and
// phrases. This is for parts of the user entry which would appear as
// a single word because there is no white space inside, but are
// actually multiple terms to rcldb (ie term1,term2)
class wsQData : public TextSplitCB {
public:
wsQData(const StopList &_stops)
: stops(_stops), alltermcount(0)
{}
vector<string> terms;
bool takeword(const std::string &term, int , int, int) {
alltermcount++;
LOGDEB1(("wsQData::takeword: %s\n", term.c_str()));
if (stops.hasStops() && stops.isStop(term)) {
LOGDEB1(("wsQData::takeword [%s] in stop list\n", term.c_str()));
return true;
}
terms.push_back(term);
return true;
}
const StopList &stops;
// Count of terms including stopwords: this is for adjusting
// phrase/near slack
int alltermcount;
};
// A class used to translate a user compound string (*not* a query
// language string) as may be entered in any_terms/all_terms search
// entry fields, ex: [term1 "a phrase" term3] into a xapian query
// tree.
// The object keeps track of the query terms and term groups while
// translating.
class StringToXapianQ {
public:
StringToXapianQ(Db& db, const string& prefix,
const string &stmlng, bool boostUser)
: m_db(db), m_prefix(prefix), m_stemlang(stmlng),
m_doBoostUserTerms(boostUser)
{ }
bool processUserString(const string &iq,
string &ermsg,
list<Xapian::Query> &pqueries,
const StopList &stops,
int slack = 0, bool useNear = false);
// After processing the string: return search terms and term
// groups (ie: for highlighting)
bool getTerms(vector<string>& terms, vector<vector<string> >& groups)
{
terms.insert(terms.end(), m_terms.begin(), m_terms.end());
groups.insert(groups.end(), m_groups.begin(), m_groups.end());
return true;
}
private:
void expandTerm(bool dont, const string& term, list<string>& exp,
string& sterm);
// After splitting entry on whitespace: process non-phrase element
void processSimpleSpan(const string& span, list<Xapian::Query> &pqueries);
// Process phrase/near element
void processPhraseOrNear(wsQData *splitData,
list<Xapian::Query> &pqueries,
bool useNear, int slack);
Db& m_db;
const string& m_prefix;
const string& m_stemlang;
bool m_doBoostUserTerms;
// Single terms and phrases resulting from breaking up text;
vector<string> m_terms;
vector<vector<string> > m_groups;
};
/** Expand stem and wildcards
*
* @param nostemexp don't perform stem expansion. This is mainly used to
* prevent stem expansion inside phrases (because the user probably
* does not expect it). This does NOT prevent wild card expansion.
* Other factors than nostemexp can prevent stem expansion:
* a null stemlang, resulting from a global user preference, a
* capitalized term, or wildcard(s)
* @param term input single word
* @param exp output expansion list
* @param sterm output original input term if there were no wildcards
*/
void StringToXapianQ::expandTerm(bool nostemexp,
const string& term,
list<string>& exp,
string &sterm)
{
LOGDEB2(("expandTerm: term [%s] stemlang [%s] nostemexp %d\n",
term.c_str(), m_stemlang.c_str(), nostemexp));
sterm.erase();
exp.clear();
if (term.empty()) {
return;
}
bool haswild = term.find_first_of("*?[") != string::npos;
// No stemming if there are wildcards or prevented globally.
if (haswild || m_stemlang.empty())
nostemexp = true;
if (!nostemexp) {
// Check if the first letter is a majuscule in which
// case we do not want to do stem expansion. Note that
// the test is convoluted and possibly problematic
string noacterm, noaclowterm;
if (unacmaybefold(term, noacterm, "UTF-8", false) &&
unacmaybefold(noacterm, noaclowterm, "UTF-8", true)) {
Utf8Iter it1(noacterm);
Utf8Iter it2(noaclowterm);
if (*it1 != *it2)
nostemexp = true;
}
}
if (nostemexp && !haswild) {
// Neither stemming nor wildcard expansion: just the word
sterm = term;
exp.push_front(term);
exp.resize(1);
} else {
list<TermMatchEntry> l;
if (haswild) {
m_db.termMatch(Rcl::Db::ET_WILD, m_stemlang, term, l);
} else {
sterm = term;
m_db.termMatch(Rcl::Db::ET_STEM, m_stemlang, term, l);
}
for (list<TermMatchEntry>::const_iterator it = l.begin();
it != l.end(); it++) {
exp.push_back(it->term);
}
}
}
// Do distribution of string vectors: a,b c,d -> a,c a,d b,c b,d
void multiply_groups(vector<vector<string> >::const_iterator vvit,
vector<vector<string> >::const_iterator vvend,
vector<string>& comb,
vector<vector<string> >&allcombs)
{
// Remember my string vector and compute next, for recursive calls.
vector<vector<string> >::const_iterator myvit = vvit++;
// Walk the string vector I'm called upon and, for each string,
// add it to current result, an call myself recursively on the
// next string vector. The last call (last element of the vector of
// vectors), adds the elementary result to the output
// Walk my string vector
for (vector<string>::const_iterator strit = (*myvit).begin();
strit != (*myvit).end(); strit++) {
// Add my current value to the string vector we're building
comb.push_back(*strit);
if (vvit == vvend) {
// Last call: store current result
allcombs.push_back(comb);
} else {
// Call recursively on next string vector
multiply_groups(vvit, vvend, comb, allcombs);
}
// Pop the value I just added (make room for the next element in my
// vector)
comb.pop_back();
}
}
/** Add prefix to all strings in list */
static void addPrefix(list<string>& terms, const string& prefix)
{
if (prefix.empty())
return;
for (list<string>::iterator it = terms.begin(); it != terms.end(); it++)
it->insert(0, prefix);
}
void StringToXapianQ::processSimpleSpan(const string& span,
list<Xapian::Query> &pqueries)
{
list<string> exp;
string sterm; // dumb version of user term
expandTerm(false, span, exp, sterm);
m_terms.insert(m_terms.end(), exp.begin(), exp.end());
addPrefix(exp, m_prefix);
// Push either term or OR of stem-expanded set
Xapian::Query xq(Xapian::Query::OP_OR, exp.begin(), exp.end());
// If sterm (simplified original user term) is not null, give it a
// relevance boost. We do this even if no expansion occurred (else
// the non-expanded terms in a term list would end-up with even
// less wqf). This does not happen if there are wildcards anywhere
// in the search.
if (m_doBoostUserTerms && !sterm.empty()) {
xq = Xapian::Query(Xapian::Query::OP_OR,
xq,
Xapian::Query(m_prefix+sterm,
original_term_wqf_booster));
}
pqueries.push_back(xq);
}
// User entry element had several terms: transform into a PHRASE or
// NEAR xapian query, the elements of which can themselves be OR
// queries if the terms get expanded by stemming or wildcards (we
// don't do stemming for PHRASE though)
void StringToXapianQ::processPhraseOrNear(wsQData *splitData,
list<Xapian::Query> &pqueries,
bool useNear, int slack)
{
Xapian::Query::op op = useNear ? Xapian::Query::OP_NEAR :
Xapian::Query::OP_PHRASE;
list<Xapian::Query> orqueries;
bool hadmultiple = false;
vector<vector<string> >groups;
// Go through the list and perform stem/wildcard expansion for each element
for (vector<string>::iterator it = splitData->terms.begin();
it != splitData->terms.end(); it++) {
// Adjust when we do stem expansion. Not inside phrases, and
// some versions of xapian will accept only one OR clause
// inside NEAR, all others must be leafs.
bool nostemexp = (op == Xapian::Query::OP_PHRASE) || hadmultiple;
string sterm;
list<string>exp;
expandTerm(nostemexp, *it, exp, sterm);
groups.push_back(vector<string>(exp.begin(), exp.end()));
addPrefix(exp, m_prefix);
orqueries.push_back(Xapian::Query(Xapian::Query::OP_OR,
exp.begin(), exp.end()));
#ifdef XAPIAN_NEAR_EXPAND_SINGLE_BUF
if (exp.size() > 1)
hadmultiple = true;
#endif
}
// Generate an appropriate PHRASE/NEAR query with adjusted slack
// For phrases, give a relevance boost like we do for original terms
Xapian::Query xq(op, orqueries.begin(), orqueries.end(),
splitData->alltermcount + slack);
if (op == Xapian::Query::OP_PHRASE)
xq = Xapian::Query(Xapian::Query::OP_SCALE_WEIGHT, xq,
original_term_wqf_booster);
pqueries.push_back(xq);
// Add all combinations of NEAR/PHRASE groups to the highlighting data.
vector<vector<string> > allcombs;
vector<string> comb;
multiply_groups(groups.begin(), groups.end(), comb, allcombs);
m_groups.insert(m_groups.end(), allcombs.begin(), allcombs.end());
}
/**
* Turn user entry string (NOT query language) into a list of xapian queries.
* We just separate words and phrases, and do wildcard and stemp expansion,
*
* The final list contains one query for each term or phrase
* - Elements corresponding to a stem-expanded part are an OP_OR
* composition of the stem-expanded terms (or a single term query).
* - Elements corresponding to phrase/near are an OP_PHRASE/NEAR
* composition of the phrase terms (no stem expansion in this case)
* @return the subquery count (either or'd stem-expanded terms or phrase word
* count)
*/
bool StringToXapianQ::processUserString(const string &_iq,
string &ermsg,
list<Xapian::Query> &pqueries,
const StopList& stops,
int slack,
bool useNear
)
{
LOGDEB(("StringToXapianQ:: query string: [%s]\n", _iq.c_str()));
ermsg.erase();
m_terms.clear();
m_groups.clear();
// First unaccent/normalize the input: do it first so that it
// happens in the same order as when indexing: unac then split. As
// the character count can change during normalisation, this is
// specially important for cjk because the artificial cjk split is
// based on character counts
string iq;
dumb_string(_iq, iq);
// Simple whitespace-split input into user-level words and
// double-quoted phrases: word1 word2 "this is a phrase". The text
// splitter may further still decide that the resulting "words"
// are really phrases, this depends on separators: [paul@dom.net]
// would still be a word (span), but [about:me] will probably be
// handled as a phrase.
list<string> phrases;
TextSplit::stringToStrings(iq, phrases);
// Process each element: textsplit into terms, handle stem/wildcard
// expansion and transform into an appropriate Xapian::Query
try {
for (list<string>::iterator it = phrases.begin();
it != phrases.end(); it++) {
LOGDEB0(("strToXapianQ: phrase/word: [%s]\n", it->c_str()));
// If there are multiple spans in this element, including
// at least one composite, we have to increase the slack
// else a phrase query including a span would fail.
// Ex: "term0@term1 term2" is onlyspans-split as:
// 0 term0@term1 0 12
// 2 term2 13 18
// The position of term2 is 2, not 1, so a phrase search
// would fail.
// We used to do word split, searching for
// "term0 term1 term2" instead, which may have worse
// performance, but will succeed.
// We now adjust the phrase/near slack by the term count
// difference (this is mainly better for cjk where this is a very
// common occurrence because of the ngrams thing.
wsQData splitDataS(stops), splitDataW(stops);
TextSplit splitterS(&splitDataS,
TextSplit::Flags(TextSplit::TXTS_ONLYSPANS |
TextSplit::TXTS_KEEPWILD));
splitterS.text_to_words(*it);
TextSplit splitterW(&splitDataW,
TextSplit::Flags(TextSplit::TXTS_NOSPANS |
TextSplit::TXTS_KEEPWILD));
splitterW.text_to_words(*it);
wsQData *splitData = &splitDataS;
if (splitDataS.terms.size() > 1 &&
splitDataS.terms.size() != splitDataW.terms.size()) {
slack += splitDataW.terms.size() - splitDataS.terms.size();
// used to: splitData = &splitDataW;
}
LOGDEB0(("strToXapianQ: termcount: %d\n", splitData->terms.size()));
switch (splitData->terms.size()) {
case 0:
continue;// ??
case 1:
processSimpleSpan(splitData->terms.front(), pqueries);
break;
default:
processPhraseOrNear(splitData, pqueries, useNear, slack);
}
}
} catch (const Xapian::Error &e) {
ermsg = e.get_msg();
} catch (const string &s) {
ermsg = s;
} catch (const char *s) {
ermsg = s;
} catch (...) {
ermsg = "Caught unknown exception";
}
if (!ermsg.empty()) {
LOGERR(("stringToXapianQueries: %s\n", ermsg.c_str()));
return false;
}
return true;
}
static const string nullstemlang;
// Translate a simple OR, AND, or EXCL search clause.
bool SearchDataClauseSimple::toNativeQuery(Rcl::Db &db, void *p,
const string& stemlang)
{
const string& l_stemlang = (m_modifiers&SDCM_NOSTEMMING)? nullstemlang:
stemlang;
m_terms.clear();
m_groups.clear();
Xapian::Query *qp = (Xapian::Query *)p;
*qp = Xapian::Query();
Xapian::Query::op op;
switch (m_tp) {
case SCLT_AND: op = Xapian::Query::OP_AND; break;
// EXCL will be set with AND_NOT in the list. So it's an OR list here
case SCLT_OR:
case SCLT_EXCL: op = Xapian::Query::OP_OR; break;
default:
LOGERR(("SearchDataClauseSimple: bad m_tp %d\n", m_tp));
return false;
}
string prefix;
if (!m_field.empty())
db.fieldToPrefix(m_field, prefix);
list<Xapian::Query> pqueries;
// We normally boost the original term in the stem expansion list. Don't
// do it if there are wildcards anywhere, this would skew the results.
bool doBoostUserTerm =
(m_parentSearch && !m_parentSearch->haveWildCards()) ||
(m_parentSearch == 0 && !m_haveWildCards);
StringToXapianQ tr(db, prefix, l_stemlang, doBoostUserTerm);
if (!tr.processUserString(m_text, m_reason, pqueries,
db.getStopList()))
return false;
if (pqueries.empty()) {
LOGERR(("SearchDataClauseSimple: resolved to null query\n"));
return false;
}
tr.getTerms(m_terms, m_groups);
*qp = Xapian::Query(op, pqueries.begin(), pqueries.end());
return true;
}
// Translate a FILENAME search clause.
bool SearchDataClauseFilename::toNativeQuery(Rcl::Db &db, void *p,
const string&)
{
Xapian::Query *qp = (Xapian::Query *)p;
*qp = Xapian::Query();
list<string> patterns;
TextSplit::stringToStrings(m_text, patterns);
list<string> names;
for (list<string>::iterator it = patterns.begin();
it != patterns.end(); it++) {
list<string> more;
db.filenameWildExp(*it, more);
names.splice(names.end(), more);
}
// Build a query out of the matching file name terms.
*qp = Xapian::Query(Xapian::Query::OP_OR, names.begin(), names.end());
return true;
}
// Translate NEAR or PHRASE clause.
bool SearchDataClauseDist::toNativeQuery(Rcl::Db &db, void *p,
const string& stemlang)
{
const string& l_stemlang = (m_modifiers&SDCM_NOSTEMMING)? nullstemlang:
stemlang;
LOGDEB(("SearchDataClauseDist::toNativeQuery\n"));
m_terms.clear();
m_groups.clear();
Xapian::Query *qp = (Xapian::Query *)p;
*qp = Xapian::Query();
list<Xapian::Query> pqueries;
Xapian::Query nq;
string prefix;
if (!m_field.empty())
db.fieldToPrefix(m_field, prefix);
// We normally boost the original term in the stem expansion list. Don't
// do it if there are wildcards anywhere, this would skew the results.
bool doBoostUserTerm =
(m_parentSearch && !m_parentSearch->haveWildCards()) ||
(m_parentSearch == 0 && !m_haveWildCards);
// We produce a single phrase out of the user entry (there should be
// no dquotes in there), then use stringToXapianQueries() to
// lowercase and simplify the phrase terms etc. This will result
// into a single (complex) Xapian::Query.
if (m_text.find_first_of("\"") != string::npos) {
LOGDEB(("Double quotes inside phrase/near field\n"));
return false;
}
string s = string("\"") + m_text + string("\"");
bool useNear = (m_tp == SCLT_NEAR);
StringToXapianQ tr(db, prefix, l_stemlang, doBoostUserTerm);
if (!tr.processUserString(s, m_reason, pqueries, db.getStopList(),
m_slack, useNear))
return false;
if (pqueries.empty()) {
LOGERR(("SearchDataClauseDist: resolved to null query\n"));
return true;
}
tr.getTerms(m_terms, m_groups);
*qp = *pqueries.begin();
return true;
}
// Translate subquery
bool SearchDataClauseSub::toNativeQuery(Rcl::Db &db, void *p, const string&)
{
return m_sub->toNativeQuery(db, p);
}
bool SearchDataClauseSub::getTerms(vector<string>& terms,
vector<vector<string> >& groups,
vector<int>& gslks) const
{
return m_sub.getconstptr()->getTerms(terms, groups, gslks);
}
} // Namespace Rcl