/************************************************************** * * Licensed to the Apache Software Foundation (ASF) under one * or more contributor license agreements. See the NOTICE file * distributed with this work for additional information * regarding copyright ownership. The ASF licenses this file * to you under the Apache License, Version 2.0 (the * "License"); you may not use this file except in compliance * with the License. You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, * software distributed under the License is distributed on an * "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY * KIND, either express or implied. See the License for the * specific language governing permissions and limitations * under the License. * *************************************************************/ // MARKER(update_precomp.py): autogen include statement, do not remove #include "precompiled_i18npool.hxx" #include "textsearch.hxx" #include "levdis.hxx" #include #include #include #include #include #include #include #include #include #include #include #include #ifdef _MSC_VER // get rid of that dumb compiler warning // identifier was truncated to '255' characters in the debug information // for STL template usage, if .pdb files are to be created #pragma warning( disable: 4786 ) #endif #include using namespace ::com::sun::star::util; using namespace ::com::sun::star::uno; using namespace ::com::sun::star::lang; using namespace ::com::sun::star::i18n; using namespace ::rtl; static sal_Int32 COMPLEX_TRANS_MASK_TMP = TransliterationModules_ignoreBaFa_ja_JP | TransliterationModules_ignoreIterationMark_ja_JP | TransliterationModules_ignoreTiJi_ja_JP | TransliterationModules_ignoreHyuByu_ja_JP | TransliterationModules_ignoreSeZe_ja_JP | TransliterationModules_ignoreIandEfollowedByYa_ja_JP | TransliterationModules_ignoreKiKuFollowedBySa_ja_JP | TransliterationModules_ignoreProlongedSoundMark_ja_JP; static const sal_Int32 SIMPLE_TRANS_MASK = ~(COMPLEX_TRANS_MASK_TMP | TransliterationModules_IGNORE_WIDTH) | TransliterationModules_FULLWIDTH_HALFWIDTH; static const sal_Int32 COMPLEX_TRANS_MASK = COMPLEX_TRANS_MASK_TMP | TransliterationModules_IGNORE_KANA | TransliterationModules_FULLWIDTH_HALFWIDTH; // Above 2 transliteration is simple but need to take effect in // complex transliteration TextSearch::TextSearch(const Reference < XMultiServiceFactory > & rxMSF) : xMSF( rxMSF ) , pJumpTable( 0 ) , pJumpTable2( 0 ) , pRegexMatcher( NULL ) , pWLD( 0 ) { SearchOptions aOpt; aOpt.algorithmType = SearchAlgorithms_ABSOLUTE; aOpt.searchFlag = SearchFlags::ALL_IGNORE_CASE; //aOpt.Locale = ???; setOptions( aOpt ); } TextSearch::~TextSearch() { delete pRegexMatcher; delete pWLD; delete pJumpTable; delete pJumpTable2; } void TextSearch::setOptions( const SearchOptions& rOptions ) throw( RuntimeException ) { aSrchPara = rOptions; delete pRegexMatcher, pRegexMatcher = NULL; delete pWLD, pWLD = 0; delete pJumpTable, pJumpTable = 0; delete pJumpTable2, pJumpTable2 = 0; // Create Transliteration class if( aSrchPara.transliterateFlags & SIMPLE_TRANS_MASK ) { if( !xTranslit.is() ) { Reference < XInterface > xI = xMSF->createInstance( OUString::createFromAscii( "com.sun.star.i18n.Transliteration")); if ( xI.is() ) xI->queryInterface( ::getCppuType( (const Reference< XExtendedTransliteration >*)0)) >>= xTranslit; } // Load transliteration module if( xTranslit.is() ) xTranslit->loadModule( (TransliterationModules)( aSrchPara.transliterateFlags & SIMPLE_TRANS_MASK ), aSrchPara.Locale); } else if( xTranslit.is() ) xTranslit = 0; // Create Transliteration for 2<->1, 2<->2 transliteration if ( aSrchPara.transliterateFlags & COMPLEX_TRANS_MASK ) { if( !xTranslit2.is() ) { Reference < XInterface > xI = xMSF->createInstance( OUString::createFromAscii( "com.sun.star.i18n.Transliteration")); if ( xI.is() ) xI->queryInterface( ::getCppuType( (const Reference< XExtendedTransliteration >*)0)) >>= xTranslit2; } // Load transliteration module if( xTranslit2.is() ) xTranslit2->loadModule( (TransliterationModules)( aSrchPara.transliterateFlags & COMPLEX_TRANS_MASK ), aSrchPara.Locale); } if ( !xBreak.is() ) { Reference < XInterface > xI = xMSF->createInstance( OUString::createFromAscii( "com.sun.star.i18n.BreakIterator")); if( xI.is() ) xI->queryInterface( ::getCppuType( (const Reference< XBreakIterator >*)0)) >>= xBreak; } sSrchStr = aSrchPara.searchString; // use transliteration here if ( xTranslit.is() && aSrchPara.transliterateFlags & SIMPLE_TRANS_MASK ) sSrchStr = xTranslit->transliterateString2String( aSrchPara.searchString, 0, aSrchPara.searchString.getLength()); if ( xTranslit2.is() && aSrchPara.transliterateFlags & COMPLEX_TRANS_MASK ) sSrchStr2 = xTranslit2->transliterateString2String( aSrchPara.searchString, 0, aSrchPara.searchString.getLength()); // When start or end of search string is a complex script type, we need to // make sure the result boundary is not located in the middle of cell. checkCTLStart = (xBreak.is() && (xBreak->getScriptType(sSrchStr, 0) == ScriptType::COMPLEX)); checkCTLEnd = (xBreak.is() && (xBreak->getScriptType(sSrchStr, sSrchStr.getLength()-1) == ScriptType::COMPLEX)); switch( aSrchPara.algorithmType) { case SearchAlgorithms_REGEXP: fnForward = &TextSearch::RESrchFrwrd; fnBackward = &TextSearch::RESrchBkwrd; RESrchPrepare( aSrchPara); break; case SearchAlgorithms_APPROXIMATE: fnForward = &TextSearch::ApproxSrchFrwrd; fnBackward = &TextSearch::ApproxSrchBkwrd; pWLD = new WLevDistance( sSrchStr.getStr(), aSrchPara.changedChars, aSrchPara.insertedChars, aSrchPara.deletedChars, 0 != (SearchFlags::LEV_RELAXED & aSrchPara.searchFlag ) ); nLimit = pWLD->GetLimit(); break; default: fnForward = &TextSearch::NSrchFrwrd; fnBackward = &TextSearch::NSrchBkwrd; break; } } sal_Int32 FindPosInSeq_Impl( const Sequence & rOff, sal_Int32 nPos ) { sal_Int32 nRet = 0, nEnd = rOff.getLength(); while( nRet < nEnd && nPos > rOff[ nRet ] ) ++nRet; return nRet; } sal_Bool TextSearch::isCellStart(const OUString& searchStr, sal_Int32 nPos) throw( RuntimeException ) { sal_Int32 nDone; return nPos == xBreak->previousCharacters(searchStr, nPos+1, aSrchPara.Locale, CharacterIteratorMode::SKIPCELL, 1, nDone); } SearchResult TextSearch::searchForward( const OUString& searchStr, sal_Int32 startPos, sal_Int32 endPos ) throw( RuntimeException ) { SearchResult sres; OUString in_str(searchStr); sal_Int32 newStartPos = startPos; sal_Int32 newEndPos = endPos; bUsePrimarySrchStr = true; if ( xTranslit.is() ) { // apply normal transliteration (1<->1, 1<->0) com::sun::star::uno::Sequence offset( in_str.getLength()); in_str = xTranslit->transliterate( searchStr, 0, in_str.getLength(), offset ); // JP 20.6.2001: also the start and end positions must be corrected! if( startPos ) newStartPos = FindPosInSeq_Impl( offset, startPos ); if( endPos < searchStr.getLength() ) newEndPos = FindPosInSeq_Impl( offset, endPos ); else newEndPos = in_str.getLength(); sres = (this->*fnForward)( in_str, newStartPos, newEndPos ); for ( int k = 0; k < sres.startOffset.getLength(); k++ ) { if (sres.startOffset[k]) sres.startOffset[k] = offset[sres.startOffset[k]]; // JP 20.6.2001: end is ever exclusive and then don't return // the position of the next character - return the // next position behind the last found character! // "a b c" find "b" must return 2,3 and not 2,4!!! if (sres.endOffset[k]) sres.endOffset[k] = offset[sres.endOffset[k]-1] + 1; } } else { sres = (this->*fnForward)( in_str, startPos, endPos ); } if ( xTranslit2.is() && aSrchPara.algorithmType != SearchAlgorithms_REGEXP) { SearchResult sres2; in_str = OUString(searchStr); com::sun::star::uno::Sequence offset( in_str.getLength()); in_str = xTranslit2->transliterate( searchStr, 0, in_str.getLength(), offset ); if( startPos ) startPos = FindPosInSeq_Impl( offset, startPos ); if( endPos < searchStr.getLength() ) endPos = FindPosInSeq_Impl( offset, endPos ); else endPos = in_str.getLength(); bUsePrimarySrchStr = false; sres2 = (this->*fnForward)( in_str, startPos, endPos ); for ( int k = 0; k < sres2.startOffset.getLength(); k++ ) { if (sres2.startOffset[k]) sres2.startOffset[k] = offset[sres2.startOffset[k]-1] + 1; if (sres2.endOffset[k]) sres2.endOffset[k] = offset[sres2.endOffset[k]-1] + 1; } // pick first and long one if ( sres.subRegExpressions == 0) return sres2; if ( sres2.subRegExpressions == 1) { if ( sres.startOffset[0] > sres2.startOffset[0]) return sres2; else if ( sres.startOffset[0] == sres2.startOffset[0] && sres.endOffset[0] < sres2.endOffset[0]) return sres2; } } return sres; } SearchResult TextSearch::searchBackward( const OUString& searchStr, sal_Int32 startPos, sal_Int32 endPos ) throw(RuntimeException) { SearchResult sres; OUString in_str(searchStr); sal_Int32 newStartPos = startPos; sal_Int32 newEndPos = endPos; bUsePrimarySrchStr = true; if ( xTranslit.is() ) { // apply only simple 1<->1 transliteration here com::sun::star::uno::Sequence offset( in_str.getLength()); in_str = xTranslit->transliterate( searchStr, 0, in_str.getLength(), offset ); // JP 20.6.2001: also the start and end positions must be corrected! if( startPos < searchStr.getLength() ) newStartPos = FindPosInSeq_Impl( offset, startPos ); else newStartPos = in_str.getLength(); if( endPos ) newEndPos = FindPosInSeq_Impl( offset, endPos ); sres = (this->*fnBackward)( in_str, newStartPos, newEndPos ); for ( int k = 0; k < sres.startOffset.getLength(); k++ ) { if (sres.startOffset[k]) sres.startOffset[k] = offset[sres.startOffset[k] - 1] + 1; // JP 20.6.2001: end is ever exclusive and then don't return // the position of the next character - return the // next position behind the last found character! // "a b c" find "b" must return 2,3 and not 2,4!!! if (sres.endOffset[k]) sres.endOffset[k] = offset[sres.endOffset[k]]; } } else { sres = (this->*fnBackward)( in_str, startPos, endPos ); } if ( xTranslit2.is() && aSrchPara.algorithmType != SearchAlgorithms_REGEXP ) { SearchResult sres2; in_str = OUString(searchStr); com::sun::star::uno::Sequence offset( in_str.getLength()); in_str = xTranslit2->transliterate(searchStr, 0, in_str.getLength(), offset); if( startPos < searchStr.getLength() ) startPos = FindPosInSeq_Impl( offset, startPos ); else startPos = in_str.getLength(); if( endPos ) endPos = FindPosInSeq_Impl( offset, endPos ); bUsePrimarySrchStr = false; sres2 = (this->*fnBackward)( in_str, startPos, endPos ); for( int k = 0; k < sres2.startOffset.getLength(); k++ ) { if (sres2.startOffset[k]) sres2.startOffset[k] = offset[sres2.startOffset[k]-1]+1; if (sres2.endOffset[k]) sres2.endOffset[k] = offset[sres2.endOffset[k]-1]+1; } // pick last and long one if ( sres.subRegExpressions == 0 ) return sres2; if ( sres2.subRegExpressions == 1 ) { if ( sres.startOffset[0] < sres2.startOffset[0] ) return sres2; if ( sres.startOffset[0] == sres2.startOffset[0] && sres.endOffset[0] > sres2.endOffset[0] ) return sres2; } } return sres; } //--------------------------------------------------------------------- bool TextSearch::IsDelimiter( const OUString& rStr, sal_Int32 nPos ) const { bool bRet = 1; if( '\x7f' != rStr[nPos]) { if ( !xCharClass.is() ) { Reference < XInterface > xI = xMSF->createInstance( OUString::createFromAscii( "com.sun.star.i18n.CharacterClassification")); if( xI.is() ) xI->queryInterface( ::getCppuType( (const Reference< XCharacterClassification >*)0)) >>= xCharClass; } if ( xCharClass.is() ) { sal_Int32 nCType = xCharClass->getCharacterType( rStr, nPos, aSrchPara.Locale ); if( 0 != (( KCharacterType::DIGIT | KCharacterType::ALPHA | KCharacterType::LETTER ) & nCType ) ) bRet = 0; } } return bRet; } // --------- helper methods for Boyer-Moore like text searching ---------- // TODO: use ICU's regex UREGEX_LITERAL mode instead when it becomes available void TextSearch::MakeForwardTab() { // create the jumptable for the search text if( pJumpTable ) { if( bIsForwardTab ) return ; // the jumpTable is ok delete pJumpTable; } bIsForwardTab = true; sal_Int32 n, nLen = sSrchStr.getLength(); pJumpTable = new TextSearchJumpTable; for( n = 0; n < nLen - 1; ++n ) { sal_Unicode cCh = sSrchStr[n]; sal_Int32 nDiff = nLen - n - 1; TextSearchJumpTable::value_type aEntry( cCh, nDiff ); ::std::pair< TextSearchJumpTable::iterator, bool > aPair = pJumpTable->insert( aEntry ); if ( !aPair.second ) (*(aPair.first)).second = nDiff; } } void TextSearch::MakeForwardTab2() { // create the jumptable for the search text if( pJumpTable2 ) { if( bIsForwardTab ) return ; // the jumpTable is ok delete pJumpTable2; } bIsForwardTab = true; sal_Int32 n, nLen = sSrchStr2.getLength(); pJumpTable2 = new TextSearchJumpTable; for( n = 0; n < nLen - 1; ++n ) { sal_Unicode cCh = sSrchStr2[n]; sal_Int32 nDiff = nLen - n - 1; TextSearchJumpTable::value_type aEntry( cCh, nDiff ); ::std::pair< TextSearchJumpTable::iterator, bool > aPair = pJumpTable2->insert( aEntry ); if ( !aPair.second ) (*(aPair.first)).second = nDiff; } } void TextSearch::MakeBackwardTab() { // create the jumptable for the search text if( pJumpTable ) { if( !bIsForwardTab ) return ; // the jumpTable is ok delete pJumpTable; } bIsForwardTab = false; sal_Int32 n, nLen = sSrchStr.getLength(); pJumpTable = new TextSearchJumpTable; for( n = nLen-1; n > 0; --n ) { sal_Unicode cCh = sSrchStr[n]; TextSearchJumpTable::value_type aEntry( cCh, n ); ::std::pair< TextSearchJumpTable::iterator, bool > aPair = pJumpTable->insert( aEntry ); if ( !aPair.second ) (*(aPair.first)).second = n; } } void TextSearch::MakeBackwardTab2() { // create the jumptable for the search text if( pJumpTable2 ) { if( !bIsForwardTab ) return ; // the jumpTable is ok delete pJumpTable2; } bIsForwardTab = false; sal_Int32 n, nLen = sSrchStr2.getLength(); pJumpTable2 = new TextSearchJumpTable; for( n = nLen-1; n > 0; --n ) { sal_Unicode cCh = sSrchStr2[n]; TextSearchJumpTable::value_type aEntry( cCh, n ); ::std::pair< TextSearchJumpTable::iterator, bool > aPair = pJumpTable2->insert( aEntry ); if ( !aPair.second ) (*(aPair.first)).second = n; } } sal_Int32 TextSearch::GetDiff( const sal_Unicode cChr ) const { TextSearchJumpTable *pJump; OUString sSearchKey; if ( bUsePrimarySrchStr ) { pJump = pJumpTable; sSearchKey = sSrchStr; } else { pJump = pJumpTable2; sSearchKey = sSrchStr2; } TextSearchJumpTable::const_iterator iLook = pJump->find( cChr ); if ( iLook == pJump->end() ) return sSearchKey.getLength(); return (*iLook).second; } // TextSearch::NSrchFrwrd is mis-optimized on unxsoli (#i105945#) SearchResult TextSearch::NSrchFrwrd( const OUString& searchStr, sal_Int32 startPos, sal_Int32 endPos ) throw(RuntimeException) { SearchResult aRet; aRet.subRegExpressions = 0; OUString sSearchKey = bUsePrimarySrchStr ? sSrchStr : sSrchStr2; OUString aStr( searchStr ); sal_Int32 nSuchIdx = aStr.getLength(); sal_Int32 nEnde = endPos; if( !nSuchIdx || !sSearchKey.getLength() || sSearchKey.getLength() > nSuchIdx ) return aRet; if( nEnde < sSearchKey.getLength() ) // position inside the search region ? return aRet; nEnde -= sSearchKey.getLength(); if (bUsePrimarySrchStr) MakeForwardTab(); // create the jumptable else MakeForwardTab2(); for (sal_Int32 nCmpIdx = startPos; // start position for the search nCmpIdx <= nEnde; nCmpIdx += GetDiff( aStr[nCmpIdx + sSearchKey.getLength()-1])) { // if the match would be the completed cells, skip it. if ( (checkCTLStart && !isCellStart( aStr, nCmpIdx )) || (checkCTLEnd && !isCellStart( aStr, nCmpIdx + sSearchKey.getLength())) ) continue; nSuchIdx = sSearchKey.getLength() - 1; while( nSuchIdx >= 0 && sSearchKey[nSuchIdx] == aStr[nCmpIdx + nSuchIdx]) { if( nSuchIdx == 0 ) { if( SearchFlags::NORM_WORD_ONLY & aSrchPara.searchFlag ) { sal_Int32 nFndEnd = nCmpIdx + sSearchKey.getLength(); bool bAtStart = !nCmpIdx; bool bAtEnd = nFndEnd == endPos; bool bDelimBefore = bAtStart || IsDelimiter( aStr, nCmpIdx-1 ); bool bDelimBehind = IsDelimiter( aStr, nFndEnd ); // * 1 -> only one word in the paragraph // * 2 -> at begin of paragraph // * 3 -> at end of paragraph // * 4 -> inside the paragraph if( !( ( bAtStart && bAtEnd ) || // 1 ( bAtStart && bDelimBehind ) || // 2 ( bAtEnd && bDelimBefore ) || // 3 ( bDelimBefore && bDelimBehind ))) // 4 break; } aRet.subRegExpressions = 1; aRet.startOffset.realloc( 1 ); aRet.startOffset[ 0 ] = nCmpIdx; aRet.endOffset.realloc( 1 ); aRet.endOffset[ 0 ] = nCmpIdx + sSearchKey.getLength(); return aRet; } else nSuchIdx--; } } return aRet; } SearchResult TextSearch::NSrchBkwrd( const OUString& searchStr, sal_Int32 startPos, sal_Int32 endPos ) throw(RuntimeException) { SearchResult aRet; aRet.subRegExpressions = 0; OUString sSearchKey = bUsePrimarySrchStr ? sSrchStr : sSrchStr2; OUString aStr( searchStr ); sal_Int32 nSuchIdx = aStr.getLength(); sal_Int32 nEnde = endPos; if( nSuchIdx == 0 || sSearchKey.getLength() == 0 || sSearchKey.getLength() > nSuchIdx) return aRet; if (bUsePrimarySrchStr) MakeBackwardTab(); // create the jumptable else MakeBackwardTab2(); if( nEnde == nSuchIdx ) // end position for the search nEnde = sSearchKey.getLength(); else nEnde += sSearchKey.getLength(); sal_Int32 nCmpIdx = startPos; // start position for the search while (nCmpIdx >= nEnde) { // if the match would be the completed cells, skip it. if ( (!checkCTLStart || isCellStart( aStr, nCmpIdx - sSearchKey.getLength() )) && (!checkCTLEnd || isCellStart( aStr, nCmpIdx))) { nSuchIdx = 0; while( nSuchIdx < sSearchKey.getLength() && sSearchKey[nSuchIdx] == aStr[nCmpIdx + nSuchIdx - sSearchKey.getLength()] ) nSuchIdx++; if( nSuchIdx >= sSearchKey.getLength() ) { if( SearchFlags::NORM_WORD_ONLY & aSrchPara.searchFlag ) { sal_Int32 nFndStt = nCmpIdx - sSearchKey.getLength(); bool bAtStart = !nFndStt; bool bAtEnd = nCmpIdx == startPos; bool bDelimBehind = IsDelimiter( aStr, nCmpIdx ); bool bDelimBefore = bAtStart || // begin of paragraph IsDelimiter( aStr, nFndStt-1 ); // * 1 -> only one word in the paragraph // * 2 -> at begin of paragraph // * 3 -> at end of paragraph // * 4 -> inside the paragraph if( ( bAtStart && bAtEnd ) || // 1 ( bAtStart && bDelimBehind ) || // 2 ( bAtEnd && bDelimBefore ) || // 3 ( bDelimBefore && bDelimBehind )) // 4 { aRet.subRegExpressions = 1; aRet.startOffset.realloc( 1 ); aRet.startOffset[ 0 ] = nCmpIdx; aRet.endOffset.realloc( 1 ); aRet.endOffset[ 0 ] = nCmpIdx - sSearchKey.getLength(); return aRet; } } else { aRet.subRegExpressions = 1; aRet.startOffset.realloc( 1 ); aRet.startOffset[ 0 ] = nCmpIdx; aRet.endOffset.realloc( 1 ); aRet.endOffset[ 0 ] = nCmpIdx - sSearchKey.getLength(); return aRet; } } } nSuchIdx = GetDiff( aStr[nCmpIdx - sSearchKey.getLength()] ); if( nCmpIdx < nSuchIdx ) return aRet; nCmpIdx -= nSuchIdx; } return aRet; } void TextSearch::RESrchPrepare( const ::com::sun::star::util::SearchOptions& rOptions) { // select the transliterated pattern string const OUString& rPatternStr = (rOptions.transliterateFlags & SIMPLE_TRANS_MASK) ? sSrchStr : ((rOptions.transliterateFlags & COMPLEX_TRANS_MASK) ? sSrchStr2 : rOptions.searchString); sal_uInt32 nIcuSearchFlags = UREGEX_UWORD; // request UAX#29 unicode capbility // map com::sun::star::util::SearchFlags to ICU uregex.h flags // TODO: REG_EXTENDED, REG_NOT_BEGINOFLINE, REG_NOT_ENDOFLINE // REG_NEWLINE is neither properly defined nor used anywhere => not implemented // REG_NOSUB is not used anywhere => not implemented // NORM_WORD_ONLY is only used for SearchAlgorithm==Absolute // LEV_RELAXED is only used for SearchAlgorithm==Approximate // why is even ALL_IGNORE_CASE deprecated in UNO? because of transliteration taking care of it??? if( (rOptions.searchFlag & com::sun::star::util::SearchFlags::ALL_IGNORE_CASE) != 0) nIcuSearchFlags |= UREGEX_CASE_INSENSITIVE; UErrorCode nIcuErr = U_ZERO_ERROR; // assumption: transliteration didn't mangle regexp control chars IcuUniString aIcuSearchPatStr( rPatternStr.getStr(), rPatternStr.getLength()); #if 1 // for conveniance specific syntax elements of the old regex engine are emulated // by using regular word boundary matching \b to replace \< and \> static const IcuUniString aChevronPattern( "\\<|\\>", -1, IcuUniString::kInvariant); static const IcuUniString aChevronReplace( "\\b", -1, IcuUniString::kInvariant); static RegexMatcher aChevronMatcher( aChevronPattern, 0, nIcuErr); aChevronMatcher.reset( aIcuSearchPatStr); aIcuSearchPatStr = aChevronMatcher.replaceAll( aChevronReplace, nIcuErr); aChevronMatcher.reset(); #endif pRegexMatcher = new RegexMatcher( aIcuSearchPatStr, nIcuSearchFlags, nIcuErr); if( nIcuErr) { delete pRegexMatcher; pRegexMatcher = NULL;} } //--------------------------------------------------------------------------- SearchResult TextSearch::RESrchFrwrd( const OUString& searchStr, sal_Int32 startPos, sal_Int32 endPos ) throw(RuntimeException) { SearchResult aRet; aRet.subRegExpressions = 0; if( !pRegexMatcher) return aRet; if( endPos > searchStr.getLength()) endPos = searchStr.getLength(); // use the ICU RegexMatcher to find the matches UErrorCode nIcuErr = U_ZERO_ERROR; const IcuUniString aSearchTargetStr( searchStr.getStr(), endPos); pRegexMatcher->reset( aSearchTargetStr); if( !pRegexMatcher->find( startPos, nIcuErr)) return aRet; const int nGroupCount = pRegexMatcher->groupCount(); aRet.subRegExpressions = nGroupCount + 1; aRet.startOffset.realloc( aRet.subRegExpressions); aRet.endOffset.realloc( aRet.subRegExpressions); aRet.startOffset[0] = pRegexMatcher->start( nIcuErr); aRet.endOffset[0] = pRegexMatcher->end( nIcuErr); for( int i = 1; i <= nGroupCount; ++i) { aRet.startOffset[i] = pRegexMatcher->start( i, nIcuErr); aRet.endOffset[i] = pRegexMatcher->end( i, nIcuErr); } return aRet; } SearchResult TextSearch::RESrchBkwrd( const OUString& searchStr, sal_Int32 startPos, sal_Int32 endPos ) throw(RuntimeException) { // NOTE: for backwards search callers provide startPos/endPos inverted! SearchResult aRet; aRet.subRegExpressions = 0; if( !pRegexMatcher) return aRet; if( startPos > searchStr.getLength()) startPos = searchStr.getLength(); // use the ICU RegexMatcher to find the matches // TODO: use ICU's backward searching once it becomes available // as its replacement using forward search is not as good as the real thing UErrorCode nIcuErr = U_ZERO_ERROR; const IcuUniString aSearchTargetStr( searchStr.getStr(), startPos); pRegexMatcher->reset( aSearchTargetStr); if( !pRegexMatcher->find( endPos, nIcuErr)) return aRet; // find the last match int nLastPos = 0; do { nLastPos = pRegexMatcher->start( nIcuErr); } while( pRegexMatcher->find( nLastPos + 1, nIcuErr)); // find last match again to get its details pRegexMatcher->find( nLastPos, nIcuErr); // fill in the details of the last match const int nGroupCount = pRegexMatcher->groupCount(); aRet.subRegExpressions = nGroupCount + 1; aRet.startOffset.realloc( aRet.subRegExpressions); aRet.endOffset.realloc( aRet.subRegExpressions); // NOTE: existing users of backward search seem to expect startOfs/endOfs being inverted! aRet.startOffset[0] = pRegexMatcher->end( nIcuErr); aRet.endOffset[0] = pRegexMatcher->start( nIcuErr); for( int i = 1; i <= nGroupCount; ++i) { aRet.startOffset[i] = pRegexMatcher->end( i, nIcuErr); aRet.endOffset[i] = pRegexMatcher->start( i, nIcuErr); } return aRet; } //--------------------------------------------------------------------------- // search for words phonetically SearchResult TextSearch::ApproxSrchFrwrd( const OUString& searchStr, sal_Int32 startPos, sal_Int32 endPos ) throw(RuntimeException) { SearchResult aRet; aRet.subRegExpressions = 0; if( !xBreak.is() ) return aRet; OUString aWTemp( searchStr ); register sal_Int32 nStt, nEnd; Boundary aWBnd = xBreak->getWordBoundary( aWTemp, startPos, aSrchPara.Locale, WordType::ANYWORD_IGNOREWHITESPACES, sal_True ); do { if( aWBnd.startPos >= endPos ) break; nStt = aWBnd.startPos < startPos ? startPos : aWBnd.startPos; nEnd = aWBnd.endPos > endPos ? endPos : aWBnd.endPos; if( nStt < nEnd && pWLD->WLD( aWTemp.getStr() + nStt, nEnd - nStt ) <= nLimit ) { aRet.subRegExpressions = 1; aRet.startOffset.realloc( 1 ); aRet.startOffset[ 0 ] = nStt; aRet.endOffset.realloc( 1 ); aRet.endOffset[ 0 ] = nEnd; break; } nStt = nEnd - 1; aWBnd = xBreak->nextWord( aWTemp, nStt, aSrchPara.Locale, WordType::ANYWORD_IGNOREWHITESPACES); } while( aWBnd.startPos != aWBnd.endPos || (aWBnd.endPos != aWTemp.getLength() && aWBnd.endPos != nEnd) ); // #i50244# aWBnd.endPos != nEnd : in case there is _no_ word (only // whitespace) in searchStr, getWordBoundary() returned startPos,startPos // and nextWord() does also => don't loop forever. return aRet; } SearchResult TextSearch::ApproxSrchBkwrd( const OUString& searchStr, sal_Int32 startPos, sal_Int32 endPos ) throw(RuntimeException) { SearchResult aRet; aRet.subRegExpressions = 0; if( !xBreak.is() ) return aRet; OUString aWTemp( searchStr ); register sal_Int32 nStt, nEnd; Boundary aWBnd = xBreak->getWordBoundary( aWTemp, startPos, aSrchPara.Locale, WordType::ANYWORD_IGNOREWHITESPACES, sal_True ); do { if( aWBnd.endPos <= endPos ) break; nStt = aWBnd.startPos < endPos ? endPos : aWBnd.startPos; nEnd = aWBnd.endPos > startPos ? startPos : aWBnd.endPos; if( nStt < nEnd && pWLD->WLD( aWTemp.getStr() + nStt, nEnd - nStt ) <= nLimit ) { aRet.subRegExpressions = 1; aRet.startOffset.realloc( 1 ); aRet.startOffset[ 0 ] = nEnd; aRet.endOffset.realloc( 1 ); aRet.endOffset[ 0 ] = nStt; break; } if( !nStt ) break; aWBnd = xBreak->previousWord( aWTemp, nStt, aSrchPara.Locale, WordType::ANYWORD_IGNOREWHITESPACES); } while( aWBnd.startPos != aWBnd.endPos || aWBnd.endPos != aWTemp.getLength() ); return aRet; } static const sal_Char cSearchName[] = "com.sun.star.util.TextSearch"; static const sal_Char cSearchImpl[] = "com.sun.star.util.TextSearch_i18n"; static OUString getServiceName_Static() { return OUString::createFromAscii( cSearchName ); } static OUString getImplementationName_Static() { return OUString::createFromAscii( cSearchImpl ); } OUString SAL_CALL TextSearch::getImplementationName() throw( RuntimeException ) { return getImplementationName_Static(); } sal_Bool SAL_CALL TextSearch::supportsService(const OUString& rServiceName) throw( RuntimeException ) { return !rServiceName.compareToAscii( cSearchName ); } Sequence< OUString > SAL_CALL TextSearch::getSupportedServiceNames(void) throw( RuntimeException ) { Sequence< OUString > aRet(1); aRet[0] = getServiceName_Static(); return aRet; } ::com::sun::star::uno::Reference< ::com::sun::star::uno::XInterface > SAL_CALL TextSearch_CreateInstance( const ::com::sun::star::uno::Reference< ::com::sun::star::lang::XMultiServiceFactory >& rxMSF ) { return ::com::sun::star::uno::Reference< ::com::sun::star::uno::XInterface >( (::cppu::OWeakObject*) new TextSearch( rxMSF ) ); } extern "C" { void SAL_CALL component_getImplementationEnvironment( const sal_Char** ppEnvTypeName, uno_Environment** /*ppEnv*/ ) { *ppEnvTypeName = CPPU_CURRENT_LANGUAGE_BINDING_NAME; } void* SAL_CALL component_getFactory( const sal_Char* sImplementationName, void* _pServiceManager, void* /*_pRegistryKey*/ ) { void* pRet = NULL; ::com::sun::star::lang::XMultiServiceFactory* pServiceManager = reinterpret_cast< ::com::sun::star::lang::XMultiServiceFactory* > ( _pServiceManager ); ::com::sun::star::uno::Reference< ::com::sun::star::lang::XSingleServiceFactory > xFactory; if ( 0 == rtl_str_compare( sImplementationName, cSearchImpl) ) { ::com::sun::star::uno::Sequence< ::rtl::OUString > aServiceNames(1); aServiceNames[0] = getServiceName_Static(); xFactory = ::cppu::createSingleFactory( pServiceManager, getImplementationName_Static(), &TextSearch_CreateInstance, aServiceNames ); } if ( xFactory.is() ) { xFactory->acquire(); pRet = xFactory.get(); } return pRet; } } // extern "C"