/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */ /* * This file is part of the LibreOffice project. * * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. * * This file incorporates work covered by the following license notice: * * 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 . */ #include #include #include #include #include #include #include #include #include using namespace ::com::sun::star; MnemonicGenerator::MnemonicGenerator(sal_Unicode cMnemonic) : m_cMnemonic(cMnemonic) { memset( maMnemonics, 1, sizeof( maMnemonics ) ); } sal_uInt16 MnemonicGenerator::ImplGetMnemonicIndex( sal_Unicode c ) { static sal_uInt16 const aImplMnemonicRangeTab[MNEMONIC_RANGES*2] = { MNEMONIC_RANGE_1_START, MNEMONIC_RANGE_1_END, MNEMONIC_RANGE_2_START, MNEMONIC_RANGE_2_END, MNEMONIC_RANGE_3_START, MNEMONIC_RANGE_3_END, MNEMONIC_RANGE_4_START, MNEMONIC_RANGE_4_END }; sal_uInt16 nMnemonicIndex = 0; for ( sal_uInt16 i = 0; i < MNEMONIC_RANGES; i++ ) { if ( (c >= aImplMnemonicRangeTab[i*2]) && (c <= aImplMnemonicRangeTab[i*2+1]) ) return nMnemonicIndex+c-aImplMnemonicRangeTab[i*2]; nMnemonicIndex += aImplMnemonicRangeTab[i*2+1]-aImplMnemonicRangeTab[i*2]; } return MNEMONIC_INDEX_NOTFOUND; } sal_Unicode MnemonicGenerator::ImplFindMnemonic( const OUString& rKey ) { sal_Int32 nIndex = 0; while ( (nIndex = rKey.indexOf( m_cMnemonic, nIndex )) != -1 ) { sal_Unicode cMnemonic = rKey[ nIndex+1 ]; if ( cMnemonic != m_cMnemonic ) return cMnemonic; nIndex += 2; } return 0; } void MnemonicGenerator::RegisterMnemonic( const OUString& rKey ) { uno::Reference < i18n::XCharacterClassification > xCharClass = GetCharClass(); // Don't crash even when we don't have access to i18n service if ( !xCharClass.is() ) return; OUString aKey = xCharClass->toLower(rKey, 0, rKey.getLength(), css::lang::Locale()); // If we find a Mnemonic, set the flag. In other case count the // characters, because we need this to set most as possible // Mnemonics sal_Unicode cMnemonic = ImplFindMnemonic( aKey ); if ( cMnemonic ) { sal_uInt16 nMnemonicIndex = ImplGetMnemonicIndex( cMnemonic ); if ( nMnemonicIndex != MNEMONIC_INDEX_NOTFOUND ) maMnemonics[nMnemonicIndex] = 0; } else { sal_Int32 nIndex = 0; sal_Int32 nLen = aKey.getLength(); while ( nIndex < nLen ) { sal_Unicode c = aKey[ nIndex ]; sal_uInt16 nMnemonicIndex = ImplGetMnemonicIndex( c ); if ( nMnemonicIndex != MNEMONIC_INDEX_NOTFOUND ) { if ( maMnemonics[nMnemonicIndex] && (maMnemonics[nMnemonicIndex] < 0xFF) ) maMnemonics[nMnemonicIndex]++; } nIndex++; } } } OUString MnemonicGenerator::CreateMnemonic( const OUString& _rKey ) { if ( _rKey.isEmpty() || ImplFindMnemonic( _rKey ) ) return _rKey; uno::Reference < i18n::XCharacterClassification > xCharClass = GetCharClass(); // Don't crash even when we don't have access to i18n service if ( !xCharClass.is() ) return _rKey; OUString aKey = xCharClass->toLower(_rKey, 0, _rKey.getLength(), css::lang::Locale()); bool bChanged = false; sal_Int32 nLen = aKey.getLength(); bool bCJK = MsLangId::isCJK(Application::GetSettings().GetUILanguageTag().getLanguageType()); // #107889# in CJK versions ALL strings (even those that contain latin characters) // will get mnemonics in the form: xyz (M) // thus steps 1) and 2) are skipped for CJK locales // #110720#, avoid CJK-style mnemonics for latin-only strings that do not contain useful mnemonic chars if( bCJK ) { bool bLatinOnly = true; bool bMnemonicIndexFound = false; sal_Unicode c; sal_Int32 nIndex; for( nIndex=0; nIndex < nLen; nIndex++ ) { c = aKey[ nIndex ]; if ( ((c >= 0x3000) && (c <= 0xD7FF)) || // cjk ((c >= 0xFF61) && (c <= 0xFFDC)) ) // halfwidth forms { bLatinOnly = false; break; } if( ImplGetMnemonicIndex( c ) != MNEMONIC_INDEX_NOTFOUND ) bMnemonicIndexFound = true; } if( bLatinOnly && !bMnemonicIndexFound ) return _rKey; } OUString rKey(_rKey); int nCJK = 0; sal_uInt16 nMnemonicIndex; sal_Unicode c; sal_Int32 nIndex = 0; if( !bCJK ) { // 1) first try the first character of a word do { c = aKey[ nIndex ]; if ( nCJK != 2 ) { if ( ((c >= 0x3000) && (c <= 0xD7FF)) || // cjk ((c >= 0xFF61) && (c <= 0xFFDC)) ) // halfwidth forms nCJK = 1; else if ( ((c >= 0x0030) && (c <= 0x0039)) || // digits ((c >= 0x0041) && (c <= 0x005A)) || // latin capitals ((c >= 0x0061) && (c <= 0x007A)) || // latin small ((c >= 0x0370) && (c <= 0x037F)) || // greek numeral signs ((c >= 0x0400) && (c <= 0x04FF)) ) // cyrillic nCJK = 2; } nMnemonicIndex = ImplGetMnemonicIndex( c ); if ( nMnemonicIndex != MNEMONIC_INDEX_NOTFOUND ) { if ( maMnemonics[nMnemonicIndex] ) { maMnemonics[nMnemonicIndex] = 0; rKey = rKey.replaceAt( nIndex, 0, OUString(m_cMnemonic) ); bChanged = true; break; } } // Search for next word nIndex++; while ( nIndex < nLen ) { c = aKey[ nIndex ]; if ( c == ' ' ) break; nIndex++; } nIndex++; } while ( nIndex < nLen ); // 2) search for a unique/uncommon character if ( !bChanged ) { sal_uInt16 nBestCount = 0xFFFF; sal_uInt16 nBestMnemonicIndex = 0; sal_Int32 nBestIndex = 0; nIndex = 0; do { c = aKey[ nIndex ]; nMnemonicIndex = ImplGetMnemonicIndex( c ); if ( nMnemonicIndex != MNEMONIC_INDEX_NOTFOUND ) { if ( maMnemonics[nMnemonicIndex] ) { if ( maMnemonics[nMnemonicIndex] < nBestCount ) { nBestCount = maMnemonics[nMnemonicIndex]; nBestIndex = nIndex; nBestMnemonicIndex = nMnemonicIndex; if ( nBestCount == 2 ) break; } } } nIndex++; } while ( nIndex < nLen ); if ( nBestCount != 0xFFFF ) { maMnemonics[nBestMnemonicIndex] = 0; rKey = rKey.replaceAt( nBestIndex, 0, OUString(m_cMnemonic) ); bChanged = true; } } } else nCJK = 1; // 3) Add English Mnemonic for CJK Text if ( !bChanged && (nCJK == 1) && !rKey.isEmpty() ) { // Append Ascii Mnemonic for ( c = MNEMONIC_RANGE_2_START; c <= MNEMONIC_RANGE_2_END; c++ ) { nMnemonicIndex = ImplGetMnemonicIndex(c); if ( nMnemonicIndex != MNEMONIC_INDEX_NOTFOUND ) { if ( maMnemonics[nMnemonicIndex] ) { maMnemonics[nMnemonicIndex] = 0; OUString aStr = OUStringBuffer(). append('(').append(m_cMnemonic).append(sal_Unicode(rtl::toAsciiUpperCase(c))). append(')').makeStringAndClear(); nIndex = rKey.getLength(); if( nIndex >= 2 ) { if ( ( rKey[nIndex-2] == '>' && rKey[nIndex-1] == '>' ) || ( rKey[nIndex-2] == 0xFF1E && rKey[nIndex-1] == 0xFF1E ) ) nIndex -= 2; } if( nIndex >= 3 ) { if ( ( rKey[nIndex-3] == '.' && rKey[nIndex-2] == '.' && rKey[nIndex-1] == '.' ) || ( rKey[nIndex-3] == 0xFF0E && rKey[nIndex-2] == 0xFF0E && rKey[nIndex-1] == 0xFF0E ) ) nIndex -= 3; } if( nIndex >= 1) { sal_Unicode cLastChar = rKey[ nIndex-1 ]; if ( (cLastChar == ':') || (cLastChar == 0xFF1A) || (cLastChar == '.') || (cLastChar == 0xFF0E) || (cLastChar == '?') || (cLastChar == 0xFF1F) || (cLastChar == ' ') ) nIndex--; } rKey = rKey.replaceAt( nIndex, 0, aStr ); break; } } } } return rKey; } uno::Reference< i18n::XCharacterClassification > const & MnemonicGenerator::GetCharClass() { if ( !mxCharClass.is() ) mxCharClass = vcl::unohelper::CreateCharacterClassification(); return mxCharClass; } OUString MnemonicGenerator::EraseAllMnemonicChars( const OUString& rStr ) { OUString aStr = rStr; sal_Int32 nLen = aStr.getLength(); sal_Int32 i = 0; while ( i < nLen ) { if ( aStr[ i ] == '~' ) { // check for CJK-style mnemonic if( i > 0 && (i+2) < nLen ) { sal_Unicode c = sal_Unicode(rtl::toAsciiUpperCase(aStr[i+1])); if( aStr[ i-1 ] == '(' && aStr[ i+2 ] == ')' && c >= MNEMONIC_RANGE_2_START && c <= MNEMONIC_RANGE_2_END ) { aStr = aStr.replaceAt( i-1, 4, "" ); nLen -= 4; i--; continue; } } // remove standard mnemonics aStr = aStr.replaceAt( i, 1, "" ); nLen--; } else i++; } return aStr; } /* vim:set shiftwidth=4 softtabstop=4 expandtab: */