/* * Copyright (C) 1999 Lars Knoll (knoll@kde.org) * (C) 1999 Antti Koivisto (koivisto@kde.org) * (C) 2001 Dirk Mueller ( mueller@kde.org ) * Copyright (C) 2003, 2004, 2005, 2006, 2007, 2008, 2009, 2013 Apple Inc. All rights reserved. * Copyright (C) 2006 Andrew Wellington (proton@wiretapped.net) * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library 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 * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public License * along with this library; see the file COPYING.LIB. If not, write to * the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, * Boston, MA 02110-1301, USA. * */ #include "config.h" #include "StringImpl.h" #include "AtomicString.h" #include "StringBuffer.h" #include "StringHash.h" #include #include #include #include #ifdef STRING_STATS #include #include #endif using namespace std; namespace WTF { using namespace Unicode; COMPILE_ASSERT(sizeof(StringImpl) == 2 * sizeof(int) + 3 * sizeof(void*), StringImpl_should_stay_small); #ifdef STRING_STATS StringStats StringImpl::m_stringStats; unsigned StringStats::s_stringRemovesTillPrintStats = StringStats::s_printStringStatsFrequency; void StringStats::removeString(StringImpl* string) { unsigned length = string->length(); bool isSubString = string->isSubString(); --m_totalNumberStrings; if (string->has16BitShadow()) { --m_numberUpconvertedStrings; if (!isSubString) m_totalUpconvertedData -= length; } if (string->is8Bit()) { --m_number8BitStrings; if (!isSubString) m_total8BitData -= length; } else { --m_number16BitStrings; if (!isSubString) m_total16BitData -= length; } if (!--s_stringRemovesTillPrintStats) { s_stringRemovesTillPrintStats = s_printStringStatsFrequency; printStats(); } } void StringStats::printStats() { dataLogF("String stats for process id %d:\n", getCurrentProcessID()); unsigned long long totalNumberCharacters = m_total8BitData + m_total16BitData; double percent8Bit = m_totalNumberStrings ? ((double)m_number8BitStrings * 100) / (double)m_totalNumberStrings : 0.0; double average8bitLength = m_number8BitStrings ? (double)m_total8BitData / (double)m_number8BitStrings : 0.0; dataLogF("%8u (%5.2f%%) 8 bit %12llu chars %12llu bytes avg length %6.1f\n", m_number8BitStrings, percent8Bit, m_total8BitData, m_total8BitData, average8bitLength); double percent16Bit = m_totalNumberStrings ? ((double)m_number16BitStrings * 100) / (double)m_totalNumberStrings : 0.0; double average16bitLength = m_number16BitStrings ? (double)m_total16BitData / (double)m_number16BitStrings : 0.0; dataLogF("%8u (%5.2f%%) 16 bit %12llu chars %12llu bytes avg length %6.1f\n", m_number16BitStrings, percent16Bit, m_total16BitData, m_total16BitData * 2, average16bitLength); double percentUpconverted = m_totalNumberStrings ? ((double)m_numberUpconvertedStrings * 100) / (double)m_number8BitStrings : 0.0; double averageUpconvertedLength = m_numberUpconvertedStrings ? (double)m_totalUpconvertedData / (double)m_numberUpconvertedStrings : 0.0; dataLogF("%8u (%5.2f%%) upconverted %12llu chars %12llu bytes avg length %6.1f\n", m_numberUpconvertedStrings, percentUpconverted, m_totalUpconvertedData, m_totalUpconvertedData * 2, averageUpconvertedLength); double averageLength = m_totalNumberStrings ? (double)totalNumberCharacters / (double)m_totalNumberStrings : 0.0; unsigned long long totalDataBytes = m_total8BitData + (m_total16BitData + m_totalUpconvertedData) * 2; dataLogF("%8u Total %12llu chars %12llu bytes avg length %6.1f\n", m_totalNumberStrings, totalNumberCharacters, totalDataBytes, averageLength); unsigned long long totalSavedBytes = m_total8BitData - m_totalUpconvertedData; double percentSavings = totalSavedBytes ? ((double)totalSavedBytes * 100) / (double)(totalDataBytes + totalSavedBytes) : 0.0; dataLogF(" Total savings %12llu bytes (%5.2f%%)\n", totalSavedBytes, percentSavings); } #endif StringImpl::~StringImpl() { ASSERT(!isStatic()); STRING_STATS_REMOVE_STRING(this); if (isAtomic()) AtomicString::remove(this); if (isIdentifier()) { if (!wtfThreadData().currentIdentifierTable()->remove(this)) CRASH(); } BufferOwnership ownership = bufferOwnership(); if (has16BitShadow()) { ASSERT(m_copyData16); fastFree(m_copyData16); } if (ownership == BufferInternal) return; if (ownership == BufferOwned) { // We use m_data8, but since it is a union with m_data16 this works either way. ASSERT(m_data8); fastFree(const_cast(m_data8)); return; } #if PLATFORM(QT) if (ownership == BufferAdoptedQString) { if (!m_qStringData->ref.deref()) QStringData::deallocate(m_qStringData); return; } #endif ASSERT(ownership == BufferSubstring); ASSERT(m_substringBuffer); m_substringBuffer->deref(); } void StringImpl::destroy(StringImpl* stringImpl) { stringImpl->~StringImpl(); fastFree(stringImpl); } PassRefPtr StringImpl::createFromLiteral(const char* characters, unsigned length) { ASSERT_WITH_MESSAGE(length, "Use StringImpl::empty() to create an empty string"); ASSERT(charactersAreAllASCII(reinterpret_cast(characters), length)); return adoptRef(new StringImpl(reinterpret_cast(characters), length, DoesHaveTerminatingNullCharacter, ConstructWithoutCopying)); } PassRefPtr StringImpl::createFromLiteral(const char* characters) { return createFromLiteral(characters, strlen(characters)); } PassRefPtr StringImpl::createWithoutCopying(const UChar* characters, unsigned length, HasTerminatingNullCharacter hasTerminatingNullCharacter) { if (!length) return empty(); return adoptRef(new StringImpl(characters, length, hasTerminatingNullCharacter, ConstructWithoutCopying)); } PassRefPtr StringImpl::createWithoutCopying(const LChar* characters, unsigned length, HasTerminatingNullCharacter hasTerminatingNullCharacter) { if (!length) return empty(); return adoptRef(new StringImpl(characters, length, hasTerminatingNullCharacter, ConstructWithoutCopying)); } template inline PassRefPtr StringImpl::createUninitializedInternal(unsigned length, CharType*& data) { if (!length) { data = 0; return empty(); } // Allocate a single buffer large enough to contain the StringImpl // struct as well as the data which it contains. This removes one // heap allocation from this call. if (length > ((std::numeric_limits::max() - sizeof(StringImpl)) / sizeof(CharType))) CRASH(); size_t size = sizeof(StringImpl) + length * sizeof(CharType); StringImpl* string = static_cast(fastMalloc(size)); data = reinterpret_cast(string + 1); return constructInternal(string, length); } PassRefPtr StringImpl::createUninitialized(unsigned length, LChar*& data) { return createUninitializedInternal(length, data); } PassRefPtr StringImpl::createUninitialized(unsigned length, UChar*& data) { return createUninitializedInternal(length, data); } template inline PassRefPtr StringImpl::reallocateInternal(PassRefPtr originalString, unsigned length, CharType*& data) { ASSERT(originalString->hasOneRef()); ASSERT(originalString->bufferOwnership() == BufferInternal); if (!length) { data = 0; return empty(); } // Same as createUninitialized() except here we use fastRealloc. if (length > ((std::numeric_limits::max() - sizeof(StringImpl)) / sizeof(CharType))) CRASH(); size_t size = sizeof(StringImpl) + length * sizeof(CharType); originalString->~StringImpl(); StringImpl* string = static_cast(fastRealloc(originalString.leakRef(), size)); data = reinterpret_cast(string + 1); return constructInternal(string, length); } PassRefPtr StringImpl::reallocate(PassRefPtr originalString, unsigned length, LChar*& data) { ASSERT(originalString->is8Bit()); return reallocateInternal(originalString, length, data); } PassRefPtr StringImpl::reallocate(PassRefPtr originalString, unsigned length, UChar*& data) { ASSERT(!originalString->is8Bit()); return reallocateInternal(originalString, length, data); } template inline PassRefPtr StringImpl::createInternal(const CharType* characters, unsigned length) { if (!characters || !length) return empty(); CharType* data; RefPtr string = createUninitialized(length, data); memcpy(data, characters, length * sizeof(CharType)); return string.release(); } PassRefPtr StringImpl::create(const UChar* characters, unsigned length) { return createInternal(characters, length); } PassRefPtr StringImpl::create(const LChar* characters, unsigned length) { return createInternal(characters, length); } PassRefPtr StringImpl::create8BitIfPossible(const UChar* characters, unsigned length) { if (!characters || !length) return empty(); LChar* data; RefPtr string = createUninitialized(length, data); for (size_t i = 0; i < length; ++i) { if (characters[i] & 0xff00) return create(characters, length); data[i] = static_cast(characters[i]); } return string.release(); } PassRefPtr StringImpl::create8BitIfPossible(const UChar* string) { return StringImpl::create8BitIfPossible(string, lengthOfNullTerminatedString(string)); } PassRefPtr StringImpl::create(const LChar* string) { if (!string) return empty(); size_t length = strlen(reinterpret_cast(string)); if (length > numeric_limits::max()) CRASH(); return create(string, length); } const UChar* StringImpl::getData16SlowCase() const { if (has16BitShadow()) return m_copyData16; if (bufferOwnership() == BufferSubstring) { // If this is a substring, return a pointer into the parent string. // TODO: Consider severing this string from the parent string unsigned offset = m_data8 - m_substringBuffer->characters8(); return m_substringBuffer->characters() + offset; } STRING_STATS_ADD_UPCONVERTED_STRING(m_length); unsigned len = length(); if (hasTerminatingNullCharacter()) ++len; m_copyData16 = static_cast(fastMalloc(len * sizeof(UChar))); m_hashAndFlags |= s_hashFlagHas16BitShadow; upconvertCharacters(0, len); return m_copyData16; } void StringImpl::upconvertCharacters(unsigned start, unsigned end) const { ASSERT(is8Bit()); ASSERT(has16BitShadow()); for (size_t i = start; i < end; ++i) m_copyData16[i] = m_data8[i]; } bool StringImpl::containsOnlyWhitespace() { // FIXME: The definition of whitespace here includes a number of characters // that are not whitespace from the point of view of RenderText; I wonder if // that's a problem in practice. if (is8Bit()) { for (unsigned i = 0; i < m_length; ++i) { UChar c = m_data8[i]; if (!isASCIISpace(c)) return false; } return true; } for (unsigned i = 0; i < m_length; ++i) { UChar c = m_data16[i]; if (!isASCIISpace(c)) return false; } return true; } PassRefPtr StringImpl::substring(unsigned start, unsigned length) { if (start >= m_length) return empty(); unsigned maxLength = m_length - start; if (length >= maxLength) { if (!start) return this; length = maxLength; } if (is8Bit()) return create(m_data8 + start, length); return create(m_data16 + start, length); } UChar32 StringImpl::characterStartingAt(unsigned i) { if (is8Bit()) return m_data8[i]; if (U16_IS_SINGLE(m_data16[i])) return m_data16[i]; if (i + 1 < m_length && U16_IS_LEAD(m_data16[i]) && U16_IS_TRAIL(m_data16[i + 1])) return U16_GET_SUPPLEMENTARY(m_data16[i], m_data16[i + 1]); return 0; } PassRefPtr StringImpl::lower() { // Note: This is a hot function in the Dromaeo benchmark, specifically the // no-op code path up through the first 'return' statement. // First scan the string for uppercase and non-ASCII characters: bool noUpper = true; if (is8Bit()) { unsigned failingIndex; for (unsigned i = 0; i < m_length; ++i) { LChar character = m_data8[i]; if (UNLIKELY((character & ~0x7F) || isASCIIUpper(character))) { failingIndex = i; goto SlowPath8bitLower; } } return this; SlowPath8bitLower: LChar* data8; RefPtr newImpl = createUninitialized(m_length, data8); for (unsigned i = 0; i < failingIndex; ++i) data8[i] = m_data8[i]; for (unsigned i = failingIndex; i < m_length; ++i) { LChar character = m_data8[i]; if (!(character & ~0x7F)) data8[i] = toASCIILower(character); else data8[i] = static_cast(Unicode::toLower(character)); } return newImpl.release(); } unsigned ored = 0; for (unsigned i = 0; i < m_length; ++i) { UChar character = m_data16[i]; if (UNLIKELY(isASCIIUpper(character))) noUpper = false; ored |= character; } // Nothing to do if the string is all ASCII with no uppercase. if (noUpper && !(ored & ~0x7F)) return this; if (!(ored & ~0x7F)) { UChar* data16; RefPtr newImpl = createUninitialized(m_length, data16); for (unsigned i = 0; i < m_length; ++i) { UChar c = m_data16[i]; data16[i] = toASCIILower(c); } return newImpl.release(); } if (m_length > static_cast(numeric_limits::max())) CRASH(); int32_t length = m_length; // Do a slower implementation for cases that include non-ASCII characters. UChar* data16; RefPtr newImpl = createUninitialized(m_length, data16); bool error; int32_t realLength = Unicode::toLower(data16, length, m_data16, m_length, &error); if (!error && realLength == length) return newImpl.release(); newImpl = createUninitialized(realLength, data16); Unicode::toLower(data16, realLength, m_data16, m_length, &error); if (error) return this; return newImpl.release(); } PassRefPtr StringImpl::upper() { // This function could be optimized for no-op cases the way lower() is, // but in empirical testing, few actual calls to upper() are no-ops, so // it wouldn't be worth the extra time for pre-scanning. if (m_length > static_cast(numeric_limits::max())) CRASH(); int32_t length = m_length; if (is8Bit()) { LChar* data8; RefPtr newImpl = createUninitialized(m_length, data8); // Do a faster loop for the case where all the characters are ASCII. unsigned ored = 0; for (int i = 0; i < length; ++i) { LChar c = m_data8[i]; ored |= c; #if CPU(X86) && defined(_MSC_VER) && _MSC_VER >=1700 // Workaround for an MSVC 2012 x86 optimizer bug. Remove once the bug is fixed. // See https://connect.microsoft.com/VisualStudio/feedback/details/780362/optimization-bug-of-range-comparison // for more details. data8[i] = c >= 'a' && c <= 'z' ? c & ~0x20 : c; #else data8[i] = toASCIIUpper(c); #endif } if (!(ored & ~0x7F)) return newImpl.release(); // Do a slower implementation for cases that include non-ASCII Latin-1 characters. int numberSharpSCharacters = 0; // There are two special cases. // 1. latin-1 characters when converted to upper case are 16 bit characters. // 2. Lower case sharp-S converts to "SS" (two characters) for (int32_t i = 0; i < length; ++i) { LChar c = m_data8[i]; if (UNLIKELY(c == smallLetterSharpS)) ++numberSharpSCharacters; UChar upper = Unicode::toUpper(c); if (UNLIKELY(upper > 0xff)) { // Since this upper-cased character does not fit in an 8-bit string, we need to take the 16-bit path. goto upconvert; } data8[i] = static_cast(upper); } if (!numberSharpSCharacters) return newImpl.release(); // We have numberSSCharacters sharp-s characters, but none of the other special characters. newImpl = createUninitialized(m_length + numberSharpSCharacters, data8); LChar* dest = data8; for (int32_t i = 0; i < length; ++i) { LChar c = m_data8[i]; if (c == smallLetterSharpS) { *dest++ = 'S'; *dest++ = 'S'; } else *dest++ = static_cast(Unicode::toUpper(c)); } return newImpl.release(); } upconvert: const UChar* source16 = characters(); UChar* data16; RefPtr newImpl = createUninitialized(m_length, data16); // Do a faster loop for the case where all the characters are ASCII. unsigned ored = 0; for (int i = 0; i < length; ++i) { UChar c = source16[i]; ored |= c; data16[i] = toASCIIUpper(c); } if (!(ored & ~0x7F)) return newImpl.release(); // Do a slower implementation for cases that include non-ASCII characters. bool error; newImpl = createUninitialized(m_length, data16); int32_t realLength = Unicode::toUpper(data16, length, source16, m_length, &error); if (!error && realLength == length) return newImpl; newImpl = createUninitialized(realLength, data16); Unicode::toUpper(data16, realLength, source16, m_length, &error); if (error) return this; return newImpl.release(); } PassRefPtr StringImpl::fill(UChar character) { if (!m_length) return this; if (!(character & ~0x7F)) { LChar* data; RefPtr newImpl = createUninitialized(m_length, data); for (unsigned i = 0; i < m_length; ++i) data[i] = character; return newImpl.release(); } UChar* data; RefPtr newImpl = createUninitialized(m_length, data); for (unsigned i = 0; i < m_length; ++i) data[i] = character; return newImpl.release(); } PassRefPtr StringImpl::foldCase() { if (m_length > static_cast(numeric_limits::max())) CRASH(); int32_t length = m_length; if (is8Bit()) { // Do a faster loop for the case where all the characters are ASCII. LChar* data; RefPtr newImpl = createUninitialized(m_length, data); LChar ored = 0; for (int32_t i = 0; i < length; ++i) { LChar c = m_data8[i]; data[i] = toASCIILower(c); ored |= c; } if (!(ored & ~0x7F)) return newImpl.release(); // Do a slower implementation for cases that include non-ASCII Latin-1 characters. for (int32_t i = 0; i < length; ++i) data[i] = static_cast(Unicode::toLower(m_data8[i])); return newImpl.release(); } // Do a faster loop for the case where all the characters are ASCII. UChar* data; RefPtr newImpl = createUninitialized(m_length, data); UChar ored = 0; for (int32_t i = 0; i < length; ++i) { UChar c = m_data16[i]; ored |= c; data[i] = toASCIILower(c); } if (!(ored & ~0x7F)) return newImpl.release(); // Do a slower implementation for cases that include non-ASCII characters. bool error; int32_t realLength = Unicode::foldCase(data, length, m_data16, m_length, &error); if (!error && realLength == length) return newImpl.release(); newImpl = createUninitialized(realLength, data); Unicode::foldCase(data, realLength, m_data16, m_length, &error); if (error) return this; return newImpl.release(); } template inline PassRefPtr StringImpl::stripMatchedCharacters(UCharPredicate predicate) { if (!m_length) return empty(); unsigned start = 0; unsigned end = m_length - 1; // skip white space from start while (start <= end && predicate(is8Bit() ? m_data8[start] : m_data16[start])) ++start; // only white space if (start > end) return empty(); // skip white space from end while (end && predicate(is8Bit() ? m_data8[end] : m_data16[end])) --end; if (!start && end == m_length - 1) return this; if (is8Bit()) return create(m_data8 + start, end + 1 - start); return create(m_data16 + start, end + 1 - start); } class UCharPredicate { public: inline UCharPredicate(CharacterMatchFunctionPtr function): m_function(function) { } inline bool operator()(UChar ch) const { return m_function(ch); } private: const CharacterMatchFunctionPtr m_function; }; class SpaceOrNewlinePredicate { public: inline bool operator()(UChar ch) const { return isSpaceOrNewline(ch); } }; PassRefPtr StringImpl::stripWhiteSpace() { return stripMatchedCharacters(SpaceOrNewlinePredicate()); } PassRefPtr StringImpl::stripWhiteSpace(IsWhiteSpaceFunctionPtr isWhiteSpace) { return stripMatchedCharacters(UCharPredicate(isWhiteSpace)); } template ALWAYS_INLINE PassRefPtr StringImpl::removeCharacters(const CharType* characters, CharacterMatchFunctionPtr findMatch) { const CharType* from = characters; const CharType* fromend = from + m_length; // Assume the common case will not remove any characters while (from != fromend && !findMatch(*from)) ++from; if (from == fromend) return this; StringBuffer data(m_length); CharType* to = data.characters(); unsigned outc = from - characters; if (outc) memcpy(to, characters, outc * sizeof(CharType)); while (true) { while (from != fromend && findMatch(*from)) ++from; while (from != fromend && !findMatch(*from)) to[outc++] = *from++; if (from == fromend) break; } data.shrink(outc); return adopt(data); } PassRefPtr StringImpl::removeCharacters(CharacterMatchFunctionPtr findMatch) { if (is8Bit()) return removeCharacters(characters8(), findMatch); return removeCharacters(characters16(), findMatch); } template inline PassRefPtr StringImpl::simplifyMatchedCharactersToSpace(UCharPredicate predicate) { StringBuffer data(m_length); const CharType* from = getCharacters(); const CharType* fromend = from + m_length; int outc = 0; bool changedToSpace = false; CharType* to = data.characters(); while (true) { while (from != fromend && predicate(*from)) { if (*from != ' ') changedToSpace = true; ++from; } while (from != fromend && !predicate(*from)) to[outc++] = *from++; if (from != fromend) to[outc++] = ' '; else break; } if (outc > 0 && to[outc - 1] == ' ') --outc; if (static_cast(outc) == m_length && !changedToSpace) return this; data.shrink(outc); return adopt(data); } PassRefPtr StringImpl::simplifyWhiteSpace() { if (is8Bit()) return StringImpl::simplifyMatchedCharactersToSpace(SpaceOrNewlinePredicate()); return StringImpl::simplifyMatchedCharactersToSpace(SpaceOrNewlinePredicate()); } PassRefPtr StringImpl::simplifyWhiteSpace(IsWhiteSpaceFunctionPtr isWhiteSpace) { if (is8Bit()) return StringImpl::simplifyMatchedCharactersToSpace(UCharPredicate(isWhiteSpace)); return StringImpl::simplifyMatchedCharactersToSpace(UCharPredicate(isWhiteSpace)); } int StringImpl::toIntStrict(bool* ok, int base) { if (is8Bit()) return charactersToIntStrict(characters8(), m_length, ok, base); return charactersToIntStrict(characters16(), m_length, ok, base); } unsigned StringImpl::toUIntStrict(bool* ok, int base) { if (is8Bit()) return charactersToUIntStrict(characters8(), m_length, ok, base); return charactersToUIntStrict(characters16(), m_length, ok, base); } int64_t StringImpl::toInt64Strict(bool* ok, int base) { if (is8Bit()) return charactersToInt64Strict(characters8(), m_length, ok, base); return charactersToInt64Strict(characters16(), m_length, ok, base); } uint64_t StringImpl::toUInt64Strict(bool* ok, int base) { if (is8Bit()) return charactersToUInt64Strict(characters8(), m_length, ok, base); return charactersToUInt64Strict(characters16(), m_length, ok, base); } intptr_t StringImpl::toIntPtrStrict(bool* ok, int base) { if (is8Bit()) return charactersToIntPtrStrict(characters8(), m_length, ok, base); return charactersToIntPtrStrict(characters16(), m_length, ok, base); } int StringImpl::toInt(bool* ok) { if (is8Bit()) return charactersToInt(characters8(), m_length, ok); return charactersToInt(characters16(), m_length, ok); } unsigned StringImpl::toUInt(bool* ok) { if (is8Bit()) return charactersToUInt(characters8(), m_length, ok); return charactersToUInt(characters16(), m_length, ok); } int64_t StringImpl::toInt64(bool* ok) { if (is8Bit()) return charactersToInt64(characters8(), m_length, ok); return charactersToInt64(characters16(), m_length, ok); } uint64_t StringImpl::toUInt64(bool* ok) { if (is8Bit()) return charactersToUInt64(characters8(), m_length, ok); return charactersToUInt64(characters16(), m_length, ok); } intptr_t StringImpl::toIntPtr(bool* ok) { if (is8Bit()) return charactersToIntPtr(characters8(), m_length, ok); return charactersToIntPtr(characters16(), m_length, ok); } double StringImpl::toDouble(bool* ok) { if (is8Bit()) return charactersToDouble(characters8(), m_length, ok); return charactersToDouble(characters16(), m_length, ok); } float StringImpl::toFloat(bool* ok) { if (is8Bit()) return charactersToFloat(characters8(), m_length, ok); return charactersToFloat(characters16(), m_length, ok); } bool equalIgnoringCase(const LChar* a, const LChar* b, unsigned length) { while (length--) { LChar bc = *b++; if (foldCase(*a++) != foldCase(bc)) return false; } return true; } bool equalIgnoringCase(const UChar* a, const LChar* b, unsigned length) { while (length--) { LChar bc = *b++; if (foldCase(*a++) != foldCase(bc)) return false; } return true; } size_t StringImpl::find(CharacterMatchFunctionPtr matchFunction, unsigned start) { if (is8Bit()) return WTF::find(characters8(), m_length, matchFunction, start); return WTF::find(characters16(), m_length, matchFunction, start); } size_t StringImpl::find(const LChar* matchString, unsigned index) { // Check for null or empty string to match against if (!matchString) return notFound; size_t matchStringLength = strlen(reinterpret_cast(matchString)); if (matchStringLength > numeric_limits::max()) CRASH(); unsigned matchLength = matchStringLength; if (!matchLength) return min(index, length()); // Optimization 1: fast case for strings of length 1. if (matchLength == 1) return WTF::find(characters16(), length(), *matchString, index); // Check index & matchLength are in range. if (index > length()) return notFound; unsigned searchLength = length() - index; if (matchLength > searchLength) return notFound; // delta is the number of additional times to test; delta == 0 means test only once. unsigned delta = searchLength - matchLength; const UChar* searchCharacters = characters() + index; // Optimization 2: keep a running hash of the strings, // only call equal if the hashes match. unsigned searchHash = 0; unsigned matchHash = 0; for (unsigned i = 0; i < matchLength; ++i) { searchHash += searchCharacters[i]; matchHash += matchString[i]; } unsigned i = 0; // keep looping until we match while (searchHash != matchHash || !equal(searchCharacters + i, matchString, matchLength)) { if (i == delta) return notFound; searchHash += searchCharacters[i + matchLength]; searchHash -= searchCharacters[i]; ++i; } return index + i; } size_t StringImpl::findIgnoringCase(const LChar* matchString, unsigned index) { // Check for null or empty string to match against if (!matchString) return notFound; size_t matchStringLength = strlen(reinterpret_cast(matchString)); if (matchStringLength > numeric_limits::max()) CRASH(); unsigned matchLength = matchStringLength; if (!matchLength) return min(index, length()); // Check index & matchLength are in range. if (index > length()) return notFound; unsigned searchLength = length() - index; if (matchLength > searchLength) return notFound; // delta is the number of additional times to test; delta == 0 means test only once. unsigned delta = searchLength - matchLength; const UChar* searchCharacters = characters() + index; unsigned i = 0; // keep looping until we match while (!equalIgnoringCase(searchCharacters + i, matchString, matchLength)) { if (i == delta) return notFound; ++i; } return index + i; } template ALWAYS_INLINE static size_t findInner(const SearchCharacterType* searchCharacters, const MatchCharacterType* matchCharacters, unsigned index, unsigned searchLength, unsigned matchLength) { // Optimization: keep a running hash of the strings, // only call equal() if the hashes match. // delta is the number of additional times to test; delta == 0 means test only once. unsigned delta = searchLength - matchLength; unsigned searchHash = 0; unsigned matchHash = 0; for (unsigned i = 0; i < matchLength; ++i) { searchHash += searchCharacters[i]; matchHash += matchCharacters[i]; } unsigned i = 0; // keep looping until we match while (searchHash != matchHash || !equal(searchCharacters + i, matchCharacters, matchLength)) { if (i == delta) return notFound; searchHash += searchCharacters[i + matchLength]; searchHash -= searchCharacters[i]; ++i; } return index + i; } size_t StringImpl::find(StringImpl* matchString) { // Check for null string to match against if (UNLIKELY(!matchString)) return notFound; unsigned matchLength = matchString->length(); // Optimization 1: fast case for strings of length 1. if (matchLength == 1) { if (is8Bit()) { if (matchString->is8Bit()) return WTF::find(characters8(), length(), matchString->characters8()[0]); return WTF::find(characters8(), length(), matchString->characters16()[0]); } if (matchString->is8Bit()) return WTF::find(characters16(), length(), matchString->characters8()[0]); return WTF::find(characters16(), length(), matchString->characters16()[0]); } // Check matchLength is in range. if (matchLength > length()) return notFound; // Check for empty string to match against if (UNLIKELY(!matchLength)) return 0; if (is8Bit()) { if (matchString->is8Bit()) return findInner(characters8(), matchString->characters8(), 0, length(), matchLength); return findInner(characters8(), matchString->characters16(), 0, length(), matchLength); } if (matchString->is8Bit()) return findInner(characters16(), matchString->characters8(), 0, length(), matchLength); return findInner(characters16(), matchString->characters16(), 0, length(), matchLength); } size_t StringImpl::find(StringImpl* matchString, unsigned index) { // Check for null or empty string to match against if (UNLIKELY(!matchString)) return notFound; unsigned matchLength = matchString->length(); // Optimization 1: fast case for strings of length 1. if (matchLength == 1) { if (is8Bit()) return WTF::find(characters8(), length(), (*matchString)[0], index); return WTF::find(characters16(), length(), (*matchString)[0], index); } if (UNLIKELY(!matchLength)) return min(index, length()); // Check index & matchLength are in range. if (index > length()) return notFound; unsigned searchLength = length() - index; if (matchLength > searchLength) return notFound; if (is8Bit()) { if (matchString->is8Bit()) return findInner(characters8() + index, matchString->characters8(), index, searchLength, matchLength); return findInner(characters8() + index, matchString->characters16(), index, searchLength, matchLength); } if (matchString->is8Bit()) return findInner(characters16() + index, matchString->characters8(), index, searchLength, matchLength); return findInner(characters16() + index, matchString->characters16(), index, searchLength, matchLength); } template ALWAYS_INLINE static size_t findIgnoringCaseInner(const SearchCharacterType* searchCharacters, const MatchCharacterType* matchCharacters, unsigned index, unsigned searchLength, unsigned matchLength) { // delta is the number of additional times to test; delta == 0 means test only once. unsigned delta = searchLength - matchLength; unsigned i = 0; // keep looping until we match while (!equalIgnoringCase(searchCharacters + i, matchCharacters, matchLength)) { if (i == delta) return notFound; ++i; } return index + i; } size_t StringImpl::findIgnoringCase(StringImpl* matchString, unsigned index) { // Check for null or empty string to match against if (!matchString) return notFound; unsigned matchLength = matchString->length(); if (!matchLength) return min(index, length()); // Check index & matchLength are in range. if (index > length()) return notFound; unsigned searchLength = length() - index; if (matchLength > searchLength) return notFound; if (is8Bit()) { if (matchString->is8Bit()) return findIgnoringCaseInner(characters8() + index, matchString->characters8(), index, searchLength, matchLength); return findIgnoringCaseInner(characters8() + index, matchString->characters16(), index, searchLength, matchLength); } if (matchString->is8Bit()) return findIgnoringCaseInner(characters16() + index, matchString->characters8(), index, searchLength, matchLength); return findIgnoringCaseInner(characters16() + index, matchString->characters16(), index, searchLength, matchLength); } size_t StringImpl::findNextLineStart(unsigned index) { if (is8Bit()) return WTF::findNextLineStart(characters8(), m_length, index); return WTF::findNextLineStart(characters16(), m_length, index); } size_t StringImpl::reverseFind(UChar c, unsigned index) { if (is8Bit()) return WTF::reverseFind(characters8(), m_length, c, index); return WTF::reverseFind(characters16(), m_length, c, index); } template ALWAYS_INLINE static size_t reverseFindInner(const SearchCharacterType* searchCharacters, const MatchCharacterType* matchCharacters, unsigned index, unsigned length, unsigned matchLength) { // Optimization: keep a running hash of the strings, // only call equal if the hashes match. // delta is the number of additional times to test; delta == 0 means test only once. unsigned delta = min(index, length - matchLength); unsigned searchHash = 0; unsigned matchHash = 0; for (unsigned i = 0; i < matchLength; ++i) { searchHash += searchCharacters[delta + i]; matchHash += matchCharacters[i]; } // keep looping until we match while (searchHash != matchHash || !equal(searchCharacters + delta, matchCharacters, matchLength)) { if (!delta) return notFound; --delta; searchHash -= searchCharacters[delta + matchLength]; searchHash += searchCharacters[delta]; } return delta; } size_t StringImpl::reverseFind(StringImpl* matchString, unsigned index) { // Check for null or empty string to match against if (!matchString) return notFound; unsigned matchLength = matchString->length(); unsigned ourLength = length(); if (!matchLength) return min(index, ourLength); // Optimization 1: fast case for strings of length 1. if (matchLength == 1) { if (is8Bit()) return WTF::reverseFind(characters8(), ourLength, (*matchString)[0], index); return WTF::reverseFind(characters16(), ourLength, (*matchString)[0], index); } // Check index & matchLength are in range. if (matchLength > ourLength) return notFound; if (is8Bit()) { if (matchString->is8Bit()) return reverseFindInner(characters8(), matchString->characters8(), index, ourLength, matchLength); return reverseFindInner(characters8(), matchString->characters16(), index, ourLength, matchLength); } if (matchString->is8Bit()) return reverseFindInner(characters16(), matchString->characters8(), index, ourLength, matchLength); return reverseFindInner(characters16(), matchString->characters16(), index, ourLength, matchLength); } template ALWAYS_INLINE static size_t reverseFindIgnoringCaseInner(const SearchCharacterType* searchCharacters, const MatchCharacterType* matchCharacters, unsigned index, unsigned length, unsigned matchLength) { // delta is the number of additional times to test; delta == 0 means test only once. unsigned delta = min(index, length - matchLength); // keep looping until we match while (!equalIgnoringCase(searchCharacters + delta, matchCharacters, matchLength)) { if (!delta) return notFound; --delta; } return delta; } size_t StringImpl::reverseFindIgnoringCase(StringImpl* matchString, unsigned index) { // Check for null or empty string to match against if (!matchString) return notFound; unsigned matchLength = matchString->length(); unsigned ourLength = length(); if (!matchLength) return min(index, ourLength); // Check index & matchLength are in range. if (matchLength > ourLength) return notFound; if (is8Bit()) { if (matchString->is8Bit()) return reverseFindIgnoringCaseInner(characters8(), matchString->characters8(), index, ourLength, matchLength); return reverseFindIgnoringCaseInner(characters8(), matchString->characters16(), index, ourLength, matchLength); } if (matchString->is8Bit()) return reverseFindIgnoringCaseInner(characters16(), matchString->characters8(), index, ourLength, matchLength); return reverseFindIgnoringCaseInner(characters16(), matchString->characters16(), index, ourLength, matchLength); } ALWAYS_INLINE static bool equalInner(const StringImpl* stringImpl, unsigned startOffset, const char* matchString, unsigned matchLength, bool caseSensitive) { ASSERT(stringImpl); ASSERT(matchLength <= stringImpl->length()); ASSERT(startOffset + matchLength <= stringImpl->length()); if (caseSensitive) { if (stringImpl->is8Bit()) return equal(stringImpl->characters8() + startOffset, reinterpret_cast(matchString), matchLength); return equal(stringImpl->characters16() + startOffset, reinterpret_cast(matchString), matchLength); } if (stringImpl->is8Bit()) return equalIgnoringCase(stringImpl->characters8() + startOffset, reinterpret_cast(matchString), matchLength); return equalIgnoringCase(stringImpl->characters16() + startOffset, reinterpret_cast(matchString), matchLength); } bool StringImpl::startsWith(const StringImpl* str) const { if (!str) return false; if (str->length() > length()) return false; if (is8Bit()) { if (str->is8Bit()) return equal(characters8(), str->characters8(), str->length()); return equal(characters8(), str->characters16(), str->length()); } if (str->is8Bit()) return equal(characters16(), str->characters8(), str->length()); return equal(characters16(), str->characters16(), str->length()); } bool StringImpl::startsWith(UChar character) const { return m_length && (*this)[0] == character; } bool StringImpl::startsWith(const char* matchString, unsigned matchLength, bool caseSensitive) const { ASSERT(matchLength); if (matchLength > length()) return false; return equalInner(this, 0, matchString, matchLength, caseSensitive); } bool StringImpl::endsWith(StringImpl* matchString, bool caseSensitive) { ASSERT(matchString); if (m_length >= matchString->m_length) { unsigned start = m_length - matchString->m_length; return (caseSensitive ? find(matchString, start) : findIgnoringCase(matchString, start)) == start; } return false; } bool StringImpl::endsWith(UChar character) const { return m_length && (*this)[m_length - 1] == character; } bool StringImpl::endsWith(const char* matchString, unsigned matchLength, bool caseSensitive) const { ASSERT(matchLength); if (matchLength > length()) return false; unsigned startOffset = length() - matchLength; return equalInner(this, startOffset, matchString, matchLength, caseSensitive); } PassRefPtr StringImpl::replace(UChar oldC, UChar newC) { if (oldC == newC) return this; unsigned i; for (i = 0; i != m_length; ++i) { UChar c = is8Bit() ? m_data8[i] : m_data16[i]; if (c == oldC) break; } if (i == m_length) return this; if (is8Bit()) { if (oldC > 0xff) // Looking for a 16 bit char in an 8 bit string, we're done. return this; if (newC <= 0xff) { LChar* data; LChar oldChar = static_cast(oldC); LChar newChar = static_cast(newC); RefPtr newImpl = createUninitialized(m_length, data); for (i = 0; i != m_length; ++i) { LChar ch = m_data8[i]; if (ch == oldChar) ch = newChar; data[i] = ch; } return newImpl.release(); } // There is the possibility we need to up convert from 8 to 16 bit, // create a 16 bit string for the result. UChar* data; RefPtr newImpl = createUninitialized(m_length, data); for (i = 0; i != m_length; ++i) { UChar ch = m_data8[i]; if (ch == oldC) ch = newC; data[i] = ch; } return newImpl.release(); } UChar* data; RefPtr newImpl = createUninitialized(m_length, data); for (i = 0; i != m_length; ++i) { UChar ch = m_data16[i]; if (ch == oldC) ch = newC; data[i] = ch; } return newImpl.release(); } PassRefPtr StringImpl::replace(unsigned position, unsigned lengthToReplace, StringImpl* str) { position = min(position, length()); lengthToReplace = min(lengthToReplace, length() - position); unsigned lengthToInsert = str ? str->length() : 0; if (!lengthToReplace && !lengthToInsert) return this; if ((length() - lengthToReplace) >= (numeric_limits::max() - lengthToInsert)) CRASH(); if (is8Bit() && (!str || str->is8Bit())) { LChar* data; RefPtr newImpl = createUninitialized(length() - lengthToReplace + lengthToInsert, data); memcpy(data, m_data8, position * sizeof(LChar)); if (str) memcpy(data + position, str->m_data8, lengthToInsert * sizeof(LChar)); memcpy(data + position + lengthToInsert, m_data8 + position + lengthToReplace, (length() - position - lengthToReplace) * sizeof(LChar)); return newImpl.release(); } UChar* data; RefPtr newImpl = createUninitialized(length() - lengthToReplace + lengthToInsert, data); if (is8Bit()) for (unsigned i = 0; i < position; ++i) data[i] = m_data8[i]; else memcpy(data, m_data16, position * sizeof(UChar)); if (str) { if (str->is8Bit()) for (unsigned i = 0; i < lengthToInsert; ++i) data[i + position] = str->m_data8[i]; else memcpy(data + position, str->m_data16, lengthToInsert * sizeof(UChar)); } if (is8Bit()) { for (unsigned i = 0; i < length() - position - lengthToReplace; ++i) data[i + position + lengthToInsert] = m_data8[i + position + lengthToReplace]; } else { memcpy(data + position + lengthToInsert, characters() + position + lengthToReplace, (length() - position - lengthToReplace) * sizeof(UChar)); } return newImpl.release(); } PassRefPtr StringImpl::replace(UChar pattern, StringImpl* replacement) { if (!replacement) return this; if (replacement->is8Bit()) return replace(pattern, replacement->m_data8, replacement->length()); return replace(pattern, replacement->m_data16, replacement->length()); } PassRefPtr StringImpl::replace(UChar pattern, const LChar* replacement, unsigned repStrLength) { ASSERT(replacement); size_t srcSegmentStart = 0; unsigned matchCount = 0; // Count the matches. while ((srcSegmentStart = find(pattern, srcSegmentStart)) != notFound) { ++matchCount; ++srcSegmentStart; } // If we have 0 matches then we don't have to do any more work. if (!matchCount) return this; if (repStrLength && matchCount > numeric_limits::max() / repStrLength) CRASH(); unsigned replaceSize = matchCount * repStrLength; unsigned newSize = m_length - matchCount; if (newSize >= (numeric_limits::max() - replaceSize)) CRASH(); newSize += replaceSize; // Construct the new data. size_t srcSegmentEnd; unsigned srcSegmentLength; srcSegmentStart = 0; unsigned dstOffset = 0; if (is8Bit()) { LChar* data; RefPtr newImpl = createUninitialized(newSize, data); while ((srcSegmentEnd = find(pattern, srcSegmentStart)) != notFound) { srcSegmentLength = srcSegmentEnd - srcSegmentStart; memcpy(data + dstOffset, m_data8 + srcSegmentStart, srcSegmentLength * sizeof(LChar)); dstOffset += srcSegmentLength; memcpy(data + dstOffset, replacement, repStrLength * sizeof(LChar)); dstOffset += repStrLength; srcSegmentStart = srcSegmentEnd + 1; } srcSegmentLength = m_length - srcSegmentStart; memcpy(data + dstOffset, m_data8 + srcSegmentStart, srcSegmentLength * sizeof(LChar)); ASSERT(dstOffset + srcSegmentLength == newImpl->length()); return newImpl.release(); } UChar* data; RefPtr newImpl = createUninitialized(newSize, data); while ((srcSegmentEnd = find(pattern, srcSegmentStart)) != notFound) { srcSegmentLength = srcSegmentEnd - srcSegmentStart; memcpy(data + dstOffset, m_data16 + srcSegmentStart, srcSegmentLength * sizeof(UChar)); dstOffset += srcSegmentLength; for (unsigned i = 0; i < repStrLength; ++i) data[i + dstOffset] = replacement[i]; dstOffset += repStrLength; srcSegmentStart = srcSegmentEnd + 1; } srcSegmentLength = m_length - srcSegmentStart; memcpy(data + dstOffset, m_data16 + srcSegmentStart, srcSegmentLength * sizeof(UChar)); ASSERT(dstOffset + srcSegmentLength == newImpl->length()); return newImpl.release(); } PassRefPtr StringImpl::replace(UChar pattern, const UChar* replacement, unsigned repStrLength) { ASSERT(replacement); size_t srcSegmentStart = 0; unsigned matchCount = 0; // Count the matches. while ((srcSegmentStart = find(pattern, srcSegmentStart)) != notFound) { ++matchCount; ++srcSegmentStart; } // If we have 0 matches then we don't have to do any more work. if (!matchCount) return this; if (repStrLength && matchCount > numeric_limits::max() / repStrLength) CRASH(); unsigned replaceSize = matchCount * repStrLength; unsigned newSize = m_length - matchCount; if (newSize >= (numeric_limits::max() - replaceSize)) CRASH(); newSize += replaceSize; // Construct the new data. size_t srcSegmentEnd; unsigned srcSegmentLength; srcSegmentStart = 0; unsigned dstOffset = 0; if (is8Bit()) { UChar* data; RefPtr newImpl = createUninitialized(newSize, data); while ((srcSegmentEnd = find(pattern, srcSegmentStart)) != notFound) { srcSegmentLength = srcSegmentEnd - srcSegmentStart; for (unsigned i = 0; i < srcSegmentLength; ++i) data[i + dstOffset] = m_data8[i + srcSegmentStart]; dstOffset += srcSegmentLength; memcpy(data + dstOffset, replacement, repStrLength * sizeof(UChar)); dstOffset += repStrLength; srcSegmentStart = srcSegmentEnd + 1; } srcSegmentLength = m_length - srcSegmentStart; for (unsigned i = 0; i < srcSegmentLength; ++i) data[i + dstOffset] = m_data8[i + srcSegmentStart]; ASSERT(dstOffset + srcSegmentLength == newImpl->length()); return newImpl.release(); } UChar* data; RefPtr newImpl = createUninitialized(newSize, data); while ((srcSegmentEnd = find(pattern, srcSegmentStart)) != notFound) { srcSegmentLength = srcSegmentEnd - srcSegmentStart; memcpy(data + dstOffset, m_data16 + srcSegmentStart, srcSegmentLength * sizeof(UChar)); dstOffset += srcSegmentLength; memcpy(data + dstOffset, replacement, repStrLength * sizeof(UChar)); dstOffset += repStrLength; srcSegmentStart = srcSegmentEnd + 1; } srcSegmentLength = m_length - srcSegmentStart; memcpy(data + dstOffset, m_data16 + srcSegmentStart, srcSegmentLength * sizeof(UChar)); ASSERT(dstOffset + srcSegmentLength == newImpl->length()); return newImpl.release(); } PassRefPtr StringImpl::replace(StringImpl* pattern, StringImpl* replacement) { if (!pattern || !replacement) return this; unsigned patternLength = pattern->length(); if (!patternLength) return this; unsigned repStrLength = replacement->length(); size_t srcSegmentStart = 0; unsigned matchCount = 0; // Count the matches. while ((srcSegmentStart = find(pattern, srcSegmentStart)) != notFound) { ++matchCount; srcSegmentStart += patternLength; } // If we have 0 matches, we don't have to do any more work if (!matchCount) return this; unsigned newSize = m_length - matchCount * patternLength; if (repStrLength && matchCount > numeric_limits::max() / repStrLength) CRASH(); if (newSize > (numeric_limits::max() - matchCount * repStrLength)) CRASH(); newSize += matchCount * repStrLength; // Construct the new data size_t srcSegmentEnd; unsigned srcSegmentLength; srcSegmentStart = 0; unsigned dstOffset = 0; bool srcIs8Bit = is8Bit(); bool replacementIs8Bit = replacement->is8Bit(); // There are 4 cases: // 1. This and replacement are both 8 bit. // 2. This and replacement are both 16 bit. // 3. This is 8 bit and replacement is 16 bit. // 4. This is 16 bit and replacement is 8 bit. if (srcIs8Bit && replacementIs8Bit) { // Case 1 LChar* data; RefPtr newImpl = createUninitialized(newSize, data); while ((srcSegmentEnd = find(pattern, srcSegmentStart)) != notFound) { srcSegmentLength = srcSegmentEnd - srcSegmentStart; memcpy(data + dstOffset, m_data8 + srcSegmentStart, srcSegmentLength * sizeof(LChar)); dstOffset += srcSegmentLength; memcpy(data + dstOffset, replacement->m_data8, repStrLength * sizeof(LChar)); dstOffset += repStrLength; srcSegmentStart = srcSegmentEnd + patternLength; } srcSegmentLength = m_length - srcSegmentStart; memcpy(data + dstOffset, m_data8 + srcSegmentStart, srcSegmentLength * sizeof(LChar)); ASSERT(dstOffset + srcSegmentLength == newImpl->length()); return newImpl.release(); } UChar* data; RefPtr newImpl = createUninitialized(newSize, data); while ((srcSegmentEnd = find(pattern, srcSegmentStart)) != notFound) { srcSegmentLength = srcSegmentEnd - srcSegmentStart; if (srcIs8Bit) { // Case 3. for (unsigned i = 0; i < srcSegmentLength; ++i) data[i + dstOffset] = m_data8[i + srcSegmentStart]; } else { // Case 2 & 4. memcpy(data + dstOffset, m_data16 + srcSegmentStart, srcSegmentLength * sizeof(UChar)); } dstOffset += srcSegmentLength; if (replacementIs8Bit) { // Cases 2 & 3. for (unsigned i = 0; i < repStrLength; ++i) data[i + dstOffset] = replacement->m_data8[i]; } else { // Case 4 memcpy(data + dstOffset, replacement->m_data16, repStrLength * sizeof(UChar)); } dstOffset += repStrLength; srcSegmentStart = srcSegmentEnd + patternLength; } srcSegmentLength = m_length - srcSegmentStart; if (srcIs8Bit) { // Case 3. for (unsigned i = 0; i < srcSegmentLength; ++i) data[i + dstOffset] = m_data8[i + srcSegmentStart]; } else { // Cases 2 & 4. memcpy(data + dstOffset, m_data16 + srcSegmentStart, srcSegmentLength * sizeof(UChar)); } ASSERT(dstOffset + srcSegmentLength == newImpl->length()); return newImpl.release(); } static inline bool stringImplContentEqual(const StringImpl* a, const StringImpl* b) { unsigned aLength = a->length(); unsigned bLength = b->length(); if (aLength != bLength) return false; if (a->is8Bit()) { if (b->is8Bit()) return equal(a->characters8(), b->characters8(), aLength); return equal(a->characters8(), b->characters16(), aLength); } if (b->is8Bit()) return equal(a->characters16(), b->characters8(), aLength); return equal(a->characters16(), b->characters16(), aLength); } bool equal(const StringImpl* a, const StringImpl* b) { if (a == b) return true; if (!a || !b) return false; return stringImplContentEqual(a, b); } template inline bool equalInternal(const StringImpl* a, const CharType* b, unsigned length) { if (!a) return !b; if (!b) return false; if (a->length() != length) return false; if (a->is8Bit()) return equal(a->characters8(), b, length); return equal(a->characters16(), b, length); } bool equal(const StringImpl* a, const LChar* b, unsigned length) { return equalInternal(a, b, length); } bool equal(const StringImpl* a, const UChar* b, unsigned length) { return equalInternal(a, b, length); } bool equal(const StringImpl* a, const LChar* b) { if (!a) return !b; if (!b) return !a; unsigned length = a->length(); if (a->is8Bit()) { const LChar* aPtr = a->characters8(); for (unsigned i = 0; i != length; ++i) { LChar bc = b[i]; LChar ac = aPtr[i]; if (!bc) return false; if (ac != bc) return false; } return !b[length]; } const UChar* aPtr = a->characters16(); for (unsigned i = 0; i != length; ++i) { LChar bc = b[i]; if (!bc) return false; if (aPtr[i] != bc) return false; } return !b[length]; } bool equalNonNull(const StringImpl* a, const StringImpl* b) { ASSERT(a && b); if (a == b) return true; return stringImplContentEqual(a, b); } bool equalIgnoringCase(const StringImpl* a, const StringImpl* b) { if (a == b) return true; if (!a || !b) return false; return CaseFoldingHash::equal(a, b); } bool equalIgnoringCase(const StringImpl* a, const LChar* b) { if (!a) return !b; if (!b) return !a; unsigned length = a->length(); // Do a faster loop for the case where all the characters are ASCII. UChar ored = 0; bool equal = true; if (a->is8Bit()) { const LChar* as = a->characters8(); for (unsigned i = 0; i != length; ++i) { LChar bc = b[i]; if (!bc) return false; UChar ac = as[i]; ored |= ac; equal = equal && (toASCIILower(ac) == toASCIILower(bc)); } // Do a slower implementation for cases that include non-ASCII characters. if (ored & ~0x7F) { equal = true; for (unsigned i = 0; i != length; ++i) equal = equal && (foldCase(as[i]) == foldCase(b[i])); } return equal && !b[length]; } const UChar* as = a->characters16(); for (unsigned i = 0; i != length; ++i) { LChar bc = b[i]; if (!bc) return false; UChar ac = as[i]; ored |= ac; equal = equal && (toASCIILower(ac) == toASCIILower(bc)); } // Do a slower implementation for cases that include non-ASCII characters. if (ored & ~0x7F) { equal = true; for (unsigned i = 0; i != length; ++i) { equal = equal && (foldCase(as[i]) == foldCase(b[i])); } } return equal && !b[length]; } bool equalIgnoringCaseNonNull(const StringImpl* a, const StringImpl* b) { ASSERT(a && b); if (a == b) return true; unsigned length = a->length(); if (length != b->length()) return false; if (a->is8Bit()) { if (b->is8Bit()) return equalIgnoringCase(a->characters8(), b->characters8(), length); return equalIgnoringCase(b->characters16(), a->characters8(), length); } if (b->is8Bit()) return equalIgnoringCase(a->characters16(), b->characters8(), length); return equalIgnoringCase(a->characters16(), b->characters16(), length); } bool equalIgnoringNullity(StringImpl* a, StringImpl* b) { if (!a && b && !b->length()) return true; if (!b && a && !a->length()) return true; return equal(a, b); } WTF::Unicode::Direction StringImpl::defaultWritingDirection(bool* hasStrongDirectionality) { for (unsigned i = 0; i < m_length; ++i) { WTF::Unicode::Direction charDirection = WTF::Unicode::direction(is8Bit() ? m_data8[i] : m_data16[i]); if (charDirection == WTF::Unicode::LeftToRight) { if (hasStrongDirectionality) *hasStrongDirectionality = true; return WTF::Unicode::LeftToRight; } if (charDirection == WTF::Unicode::RightToLeft || charDirection == WTF::Unicode::RightToLeftArabic) { if (hasStrongDirectionality) *hasStrongDirectionality = true; return WTF::Unicode::RightToLeft; } } if (hasStrongDirectionality) *hasStrongDirectionality = false; return WTF::Unicode::LeftToRight; } PassRefPtr StringImpl::adopt(StringBuffer& buffer) { unsigned length = buffer.length(); if (!length) return empty(); return adoptRef(new StringImpl(buffer.release(), length)); } PassRefPtr StringImpl::adopt(StringBuffer& buffer) { unsigned length = buffer.length(); if (!length) return empty(); return adoptRef(new StringImpl(buffer.release(), length)); } #if PLATFORM(QT) PassRefPtr StringImpl::adopt(QStringData* qStringData) { ASSERT(qStringData); if (!qStringData->size) return empty(); return adoptRef(new StringImpl(qStringData, ConstructAdoptedQString)); } #endif PassRefPtr StringImpl::createWithTerminatingNullCharacter(const StringImpl& string) { // Use createUninitialized instead of 'new StringImpl' so that the string and its buffer // get allocated in a single memory block. unsigned length = string.m_length; if (length >= numeric_limits::max()) CRASH(); RefPtr terminatedString; if (string.is8Bit()) { LChar* data; terminatedString = createUninitialized(length + 1, data); memcpy(data, string.m_data8, length * sizeof(LChar)); data[length] = 0; } else { UChar* data; terminatedString = createUninitialized(length + 1, data); memcpy(data, string.m_data16, length * sizeof(UChar)); data[length] = 0; } --(terminatedString->m_length); terminatedString->m_hashAndFlags = (string.m_hashAndFlags & (~s_flagMask | s_hashFlag8BitBuffer)) | s_hashFlagHasTerminatingNullCharacter; return terminatedString.release(); } size_t StringImpl::sizeInBytes() const { // FIXME: support substrings size_t size = length(); if (is8Bit()) { if (has16BitShadow()) { size += 2 * size; if (hasTerminatingNullCharacter()) size += 2; } } else size *= 2; return size + sizeof(*this); } } // namespace WTF