/* * 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 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 "CString.h" #include "CharacterNames.h" #include "FloatConversion.h" #include "StringBuffer.h" #include "StringHash.h" #include "TextBreakIterator.h" #include "TextEncoding.h" #include "ThreadGlobalData.h" #include #include #include #include #include using namespace WTF; using namespace Unicode; namespace WebCore { static const unsigned minLengthToShare = 20; static inline UChar* newUCharVector(unsigned n) { return static_cast(fastMalloc(sizeof(UChar) * n)); } static inline void deleteUCharVector(const UChar* p) { fastFree(const_cast(p)); } // Some of the factory methods create buffers using fastMalloc. // We must ensure that all allocations of StringImpl are allocated using // fastMalloc so that we don't have mis-matched frees. We accomplish // this by overriding the new and delete operators. void* StringImpl::operator new(size_t size, void* address) { if (address) return address; // Allocating using an internal buffer return fastMalloc(size); } void* StringImpl::operator new(size_t size) { return fastMalloc(size); } void StringImpl::operator delete(void* address) { fastFree(address); } // This constructor is used only to create the empty string. StringImpl::StringImpl() : m_data(0) , m_length(0) , m_hash(0) { // Ensure that the hash is computed so that AtomicStringHash can call existingHash() // with impunity. The empty string is special because it is never entered into // AtomicString's HashKey, but still needs to compare correctly. hash(); } inline StringImpl::StringImpl(const UChar* characters, unsigned length) : m_data(characters) , m_length(length) , m_hash(0) { ASSERT(characters); ASSERT(length); ASSERT(!bufferIsInternal()); } inline StringImpl::StringImpl(unsigned length) : m_data(reinterpret_cast(this + 1)) , m_length(length) , m_hash(0) { ASSERT(length); ASSERT(bufferIsInternal()); } StringImpl::~StringImpl() { if (inTable()) AtomicString::remove(this); if (!bufferIsInternal()) { SharedUChar* sharedBuffer = m_sharedBufferAndFlags.get(); if (sharedBuffer) sharedBuffer->deref(); else deleteUCharVector(m_data); } } StringImpl* StringImpl::empty() { return threadGlobalData().emptyString(); } 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. for (unsigned i = 0; i < m_length; i++) if (!isASCIISpace(m_data[i])) 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; } return create(m_data + start, length); } UChar32 StringImpl::characterStartingAt(unsigned i) { if (U16_IS_SINGLE(m_data[i])) return m_data[i]; if (i + 1 < m_length && U16_IS_LEAD(m_data[i]) && U16_IS_TRAIL(m_data[i + 1])) return U16_GET_SUPPLEMENTARY(m_data[i], m_data[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: UChar ored = 0; bool noUpper = true; const UChar *end = m_data + m_length; for (const UChar* chp = m_data; chp != end; chp++) { if (UNLIKELY(isASCIIUpper(*chp))) noUpper = false; ored |= *chp; } // Nothing to do if the string is all ASCII with no uppercase. if (noUpper && !(ored & ~0x7F)) return this; int32_t length = m_length; UChar* data; RefPtr newImpl = createUninitialized(m_length, data); if (!(ored & ~0x7F)) { // Do a faster loop for the case where all the characters are ASCII. for (int i = 0; i < length; i++) { UChar c = m_data[i]; data[i] = toASCIILower(c); } return newImpl; } // Do a slower implementation for cases that include non-ASCII characters. bool error; int32_t realLength = Unicode::toLower(data, length, m_data, m_length, &error); if (!error && realLength == length) return newImpl; newImpl = createUninitialized(realLength, data); Unicode::toLower(data, realLength, m_data, m_length, &error); if (error) return this; return newImpl; } 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. UChar* data; PassRefPtr newImpl = createUninitialized(m_length, data); int32_t length = m_length; // Do a faster loop for the case where all the characters are ASCII. UChar ored = 0; for (int i = 0; i < length; i++) { UChar c = m_data[i]; ored |= c; data[i] = toASCIIUpper(c); } if (!(ored & ~0x7F)) return newImpl; // Do a slower implementation for cases that include non-ASCII characters. bool error; int32_t realLength = Unicode::toUpper(data, length, m_data, m_length, &error); if (!error && realLength == length) return newImpl; newImpl = createUninitialized(realLength, data); Unicode::toUpper(data, realLength, m_data, m_length, &error); if (error) return this; return newImpl; } PassRefPtr StringImpl::secure(UChar aChar) { UChar* data; PassRefPtr newImpl = createUninitialized(m_length, data); int32_t length = m_length; for (int i = 0; i < length; ++i) data[i] = aChar; return newImpl; } PassRefPtr StringImpl::foldCase() { UChar* data; PassRefPtr newImpl = createUninitialized(m_length, data); int32_t length = m_length; // Do a faster loop for the case where all the characters are ASCII. UChar ored = 0; for (int i = 0; i < length; i++) { UChar c = m_data[i]; ored |= c; data[i] = toASCIILower(c); } if (!(ored & ~0x7F)) return newImpl; // Do a slower implementation for cases that include non-ASCII characters. bool error; int32_t realLength = Unicode::foldCase(data, length, m_data, m_length, &error); if (!error && realLength == length) return newImpl; newImpl = createUninitialized(realLength, data); Unicode::foldCase(data, realLength, m_data, m_length, &error); if (error) return this; return newImpl; } PassRefPtr StringImpl::stripWhiteSpace() { if (!m_length) return empty(); unsigned start = 0; unsigned end = m_length - 1; // skip white space from start while (start <= end && isSpaceOrNewline(m_data[start])) start++; // only white space if (start > end) return empty(); // skip white space from end while (end && isSpaceOrNewline(m_data[end])) end--; if (!start && end == m_length - 1) return this; return create(m_data + start, end + 1 - start); } PassRefPtr StringImpl::removeCharacters(CharacterMatchFunctionPtr findMatch) { const UChar* from = m_data; const UChar* 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); UChar* to = data.characters(); unsigned outc = from - m_data; if (outc) memcpy(to, m_data, outc * sizeof(UChar)); 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::simplifyWhiteSpace() { StringBuffer data(m_length); const UChar* from = m_data; const UChar* fromend = from + m_length; int outc = 0; bool changedToSpace = false; UChar* to = data.characters(); while (true) { while (from != fromend && isSpaceOrNewline(*from)) { if (*from != ' ') changedToSpace = true; from++; } while (from != fromend && !isSpaceOrNewline(*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::capitalize(UChar previous) { StringBuffer stringWithPrevious(m_length + 1); stringWithPrevious[0] = previous == noBreakSpace ? ' ' : previous; for (unsigned i = 1; i < m_length + 1; i++) { // Replace with a real space since ICU no longer treats as a word separator. if (m_data[i - 1] == noBreakSpace) stringWithPrevious[i] = ' '; else stringWithPrevious[i] = m_data[i - 1]; } TextBreakIterator* boundary = wordBreakIterator(stringWithPrevious.characters(), m_length + 1); if (!boundary) return this; StringBuffer data(m_length); int32_t endOfWord; int32_t startOfWord = textBreakFirst(boundary); for (endOfWord = textBreakNext(boundary); endOfWord != TextBreakDone; startOfWord = endOfWord, endOfWord = textBreakNext(boundary)) { if (startOfWord != 0) // Ignore first char of previous string data[startOfWord - 1] = m_data[startOfWord - 1] == noBreakSpace ? noBreakSpace : toTitleCase(stringWithPrevious[startOfWord]); for (int i = startOfWord + 1; i < endOfWord; i++) data[i - 1] = m_data[i - 1]; } return adopt(data); } int StringImpl::toIntStrict(bool* ok, int base) { return charactersToIntStrict(m_data, m_length, ok, base); } unsigned StringImpl::toUIntStrict(bool* ok, int base) { return charactersToUIntStrict(m_data, m_length, ok, base); } int64_t StringImpl::toInt64Strict(bool* ok, int base) { return charactersToInt64Strict(m_data, m_length, ok, base); } uint64_t StringImpl::toUInt64Strict(bool* ok, int base) { return charactersToUInt64Strict(m_data, m_length, ok, base); } intptr_t StringImpl::toIntPtrStrict(bool* ok, int base) { return charactersToIntPtrStrict(m_data, m_length, ok, base); } int StringImpl::toInt(bool* ok) { return charactersToInt(m_data, m_length, ok); } unsigned StringImpl::toUInt(bool* ok) { return charactersToUInt(m_data, m_length, ok); } int64_t StringImpl::toInt64(bool* ok) { return charactersToInt64(m_data, m_length, ok); } uint64_t StringImpl::toUInt64(bool* ok) { return charactersToUInt64(m_data, m_length, ok); } intptr_t StringImpl::toIntPtr(bool* ok) { return charactersToIntPtr(m_data, m_length, ok); } double StringImpl::toDouble(bool* ok) { return charactersToDouble(m_data, m_length, ok); } float StringImpl::toFloat(bool* ok) { return charactersToFloat(m_data, m_length, ok); } static bool equal(const UChar* a, const char* b, int length) { ASSERT(length >= 0); while (length--) { unsigned char bc = *b++; if (*a++ != bc) return false; } return true; } bool equalIgnoringCase(const UChar* a, const char* b, unsigned length) { while (length--) { unsigned char bc = *b++; if (foldCase(*a++) != foldCase(bc)) return false; } return true; } static inline bool equalIgnoringCase(const UChar* a, const UChar* b, int length) { ASSERT(length >= 0); return umemcasecmp(a, b, length) == 0; } int StringImpl::find(const char* chs, int index, bool caseSensitive) { if (!chs || index < 0) return -1; int chsLength = strlen(chs); int n = m_length - index; if (n < 0) return -1; n -= chsLength - 1; if (n <= 0) return -1; const char* chsPlusOne = chs + 1; int chsLengthMinusOne = chsLength - 1; const UChar* ptr = m_data + index - 1; if (caseSensitive) { UChar c = *chs; do { if (*++ptr == c && equal(ptr + 1, chsPlusOne, chsLengthMinusOne)) return m_length - chsLength - n + 1; } while (--n); } else { UChar lc = Unicode::foldCase(*chs); do { if (Unicode::foldCase(*++ptr) == lc && equalIgnoringCase(ptr + 1, chsPlusOne, chsLengthMinusOne)) return m_length - chsLength - n + 1; } while (--n); } return -1; } int StringImpl::find(UChar c, int start) { return WebCore::find(m_data, m_length, c, start); } int StringImpl::find(CharacterMatchFunctionPtr matchFunction, int start) { return WebCore::find(m_data, m_length, matchFunction, start); } int StringImpl::find(StringImpl* str, int index, bool caseSensitive) { /* We use a simple trick for efficiency's sake. Instead of comparing strings, we compare the sum of str with that of a part of this string. Only if that matches, we call memcmp or ucstrnicmp. */ ASSERT(str); if (index < 0) index += m_length; int lstr = str->m_length; int lthis = m_length - index; if ((unsigned)lthis > m_length) return -1; int delta = lthis - lstr; if (delta < 0) return -1; const UChar* uthis = m_data + index; const UChar* ustr = str->m_data; unsigned hthis = 0; unsigned hstr = 0; if (caseSensitive) { for (int i = 0; i < lstr; i++) { hthis += uthis[i]; hstr += ustr[i]; } int i = 0; while (1) { if (hthis == hstr && memcmp(uthis + i, ustr, lstr * sizeof(UChar)) == 0) return index + i; if (i == delta) return -1; hthis += uthis[i + lstr]; hthis -= uthis[i]; i++; } } else { for (int i = 0; i < lstr; i++ ) { hthis += toASCIILower(uthis[i]); hstr += toASCIILower(ustr[i]); } int i = 0; while (1) { if (hthis == hstr && equalIgnoringCase(uthis + i, ustr, lstr)) return index + i; if (i == delta) return -1; hthis += toASCIILower(uthis[i + lstr]); hthis -= toASCIILower(uthis[i]); i++; } } } int StringImpl::reverseFind(UChar c, int index) { return WebCore::reverseFind(m_data, m_length, c, index); } int StringImpl::reverseFind(StringImpl* str, int index, bool caseSensitive) { /* See StringImpl::find() for explanations. */ ASSERT(str); int lthis = m_length; if (index < 0) index += lthis; int lstr = str->m_length; int delta = lthis - lstr; if ( index < 0 || index > lthis || delta < 0 ) return -1; if ( index > delta ) index = delta; const UChar *uthis = m_data; const UChar *ustr = str->m_data; unsigned hthis = 0; unsigned hstr = 0; int i; if (caseSensitive) { for ( i = 0; i < lstr; i++ ) { hthis += uthis[index + i]; hstr += ustr[i]; } i = index; while (1) { if (hthis == hstr && memcmp(uthis + i, ustr, lstr * sizeof(UChar)) == 0) return i; if (i == 0) return -1; i--; hthis -= uthis[i + lstr]; hthis += uthis[i]; } } else { for (i = 0; i < lstr; i++) { hthis += toASCIILower(uthis[index + i]); hstr += toASCIILower(ustr[i]); } i = index; while (1) { if (hthis == hstr && equalIgnoringCase(uthis + i, ustr, lstr) ) return i; if (i == 0) return -1; i--; hthis -= toASCIILower(uthis[i + lstr]); hthis += toASCIILower(uthis[i]); } } // Should never get here. return -1; } bool StringImpl::endsWith(StringImpl* m_data, bool caseSensitive) { ASSERT(m_data); int start = m_length - m_data->m_length; if (start >= 0) return (find(m_data, start, caseSensitive) == start); return false; } PassRefPtr StringImpl::replace(UChar oldC, UChar newC) { if (oldC == newC) return this; unsigned i; for (i = 0; i != m_length; ++i) if (m_data[i] == oldC) break; if (i == m_length) return this; UChar* data; PassRefPtr newImpl = createUninitialized(m_length, data); for (i = 0; i != m_length; ++i) { UChar ch = m_data[i]; if (ch == oldC) ch = newC; data[i] = ch; } return newImpl; } 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; UChar* data; PassRefPtr newImpl = createUninitialized(length() - lengthToReplace + lengthToInsert, data); memcpy(data, characters(), position * sizeof(UChar)); if (str) memcpy(data + position, str->characters(), lengthToInsert * sizeof(UChar)); memcpy(data + position + lengthToInsert, characters() + position + lengthToReplace, (length() - position - lengthToReplace) * sizeof(UChar)); return newImpl; } PassRefPtr StringImpl::replace(UChar pattern, StringImpl* replacement) { if (!replacement) return this; int repStrLength = replacement->length(); int srcSegmentStart = 0; int matchCount = 0; // Count the matches while ((srcSegmentStart = find(pattern, srcSegmentStart)) >= 0) { ++matchCount; ++srcSegmentStart; } // If we have 0 matches, we don't have to do any more work if (!matchCount) return this; UChar* data; PassRefPtr newImpl = createUninitialized(m_length - matchCount + (matchCount * repStrLength), data); // Construct the new data int srcSegmentEnd; int srcSegmentLength; srcSegmentStart = 0; int dstOffset = 0; while ((srcSegmentEnd = find(pattern, srcSegmentStart)) >= 0) { srcSegmentLength = srcSegmentEnd - srcSegmentStart; memcpy(data + dstOffset, m_data + srcSegmentStart, srcSegmentLength * sizeof(UChar)); dstOffset += srcSegmentLength; memcpy(data + dstOffset, replacement->m_data, repStrLength * sizeof(UChar)); dstOffset += repStrLength; srcSegmentStart = srcSegmentEnd + 1; } srcSegmentLength = m_length - srcSegmentStart; memcpy(data + dstOffset, m_data + srcSegmentStart, srcSegmentLength * sizeof(UChar)); ASSERT(dstOffset + srcSegmentLength == static_cast(newImpl->length())); return newImpl; } PassRefPtr StringImpl::replace(StringImpl* pattern, StringImpl* replacement) { if (!pattern || !replacement) return this; int patternLength = pattern->length(); if (!patternLength) return this; int repStrLength = replacement->length(); int srcSegmentStart = 0; int matchCount = 0; // Count the matches while ((srcSegmentStart = find(pattern, srcSegmentStart)) >= 0) { ++matchCount; srcSegmentStart += patternLength; } // If we have 0 matches, we don't have to do any more work if (!matchCount) return this; UChar* data; PassRefPtr newImpl = createUninitialized(m_length + matchCount * (repStrLength - patternLength), data); // Construct the new data int srcSegmentEnd; int srcSegmentLength; srcSegmentStart = 0; int dstOffset = 0; while ((srcSegmentEnd = find(pattern, srcSegmentStart)) >= 0) { srcSegmentLength = srcSegmentEnd - srcSegmentStart; memcpy(data + dstOffset, m_data + srcSegmentStart, srcSegmentLength * sizeof(UChar)); dstOffset += srcSegmentLength; memcpy(data + dstOffset, replacement->m_data, repStrLength * sizeof(UChar)); dstOffset += repStrLength; srcSegmentStart = srcSegmentEnd + patternLength; } srcSegmentLength = m_length - srcSegmentStart; memcpy(data + dstOffset, m_data + srcSegmentStart, srcSegmentLength * sizeof(UChar)); ASSERT(dstOffset + srcSegmentLength == static_cast(newImpl->length())); return newImpl; } bool equal(StringImpl* a, StringImpl* b) { return StringHash::equal(a, b); } bool equal(StringImpl* a, const char* b) { if (!a) return !b; if (!b) return !a; unsigned length = a->length(); const UChar* as = a->characters(); for (unsigned i = 0; i != length; ++i) { unsigned char bc = b[i]; if (!bc) return false; if (as[i] != bc) return false; } return !b[length]; } bool equalIgnoringCase(StringImpl* a, StringImpl* b) { return CaseFoldingHash::equal(a, b); } bool equalIgnoringCase(StringImpl* a, const char* b) { if (!a) return !b; if (!b) return !a; unsigned length = a->length(); const UChar* as = a->characters(); // Do a faster loop for the case where all the characters are ASCII. UChar ored = 0; bool equal = true; for (unsigned i = 0; i != length; ++i) { char 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) { unsigned char bc = b[i]; equal = equal && (foldCase(as[i]) == foldCase(bc)); } } return equal && !b[length]; } bool equalIgnoringNullity(StringImpl* a, StringImpl* b) { if (StringHash::equal(a, b)) return true; if (!a && b && !b->length()) return true; if (!b && a && !a->length()) return true; return false; } Vector StringImpl::ascii() { Vector buffer(m_length + 1); for (unsigned i = 0; i != m_length; ++i) { UChar c = m_data[i]; if ((c >= 0x20 && c < 0x7F) || c == 0x00) buffer[i] = c; else buffer[i] = '?'; } buffer[m_length] = '\0'; return buffer; } WTF::Unicode::Direction StringImpl::defaultWritingDirection() { for (unsigned i = 0; i < m_length; ++i) { WTF::Unicode::Direction charDirection = WTF::Unicode::direction(m_data[i]); if (charDirection == WTF::Unicode::LeftToRight) return WTF::Unicode::LeftToRight; if (charDirection == WTF::Unicode::RightToLeft || charDirection == WTF::Unicode::RightToLeftArabic) return WTF::Unicode::RightToLeft; } return WTF::Unicode::LeftToRight; } // This is a hot function because it's used when parsing HTML. PassRefPtr StringImpl::createStrippingNullCharactersSlowCase(const UChar* characters, unsigned length) { StringBuffer strippedCopy(length); unsigned strippedLength = 0; for (unsigned i = 0; i < length; i++) { if (int c = characters[i]) strippedCopy[strippedLength++] = c; } ASSERT(strippedLength < length); // Only take the slow case when stripping. strippedCopy.shrink(strippedLength); return adopt(strippedCopy); } PassRefPtr StringImpl::adopt(StringBuffer& buffer) { unsigned length = buffer.length(); if (length == 0) return empty(); return adoptRef(new StringImpl(buffer.release(), length)); } PassRefPtr StringImpl::adopt(Vector& vector) { size_t size = vector.size(); if (size == 0) return empty(); return adoptRef(new StringImpl(vector.releaseBuffer(), size)); } PassRefPtr StringImpl::createUninitialized(unsigned length, UChar*& 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. size_t size = sizeof(StringImpl) + length * sizeof(UChar); StringImpl* string = static_cast(fastMalloc(size)); data = reinterpret_cast(string + 1); string = new (string) StringImpl(length); return adoptRef(string); } PassRefPtr StringImpl::create(const UChar* characters, unsigned length) { if (!characters || !length) return empty(); UChar* data; PassRefPtr string = createUninitialized(length, data); memcpy(data, characters, length * sizeof(UChar)); return string; } PassRefPtr StringImpl::create(const char* characters, unsigned length) { if (!characters || !length) return empty(); UChar* data; PassRefPtr string = createUninitialized(length, data); for (unsigned i = 0; i != length; ++i) { unsigned char c = characters[i]; data[i] = c; } return string; } PassRefPtr StringImpl::create(const char* string) { if (!string) return empty(); return create(string, strlen(string)); } #if USE(JSC) PassRefPtr StringImpl::create(const JSC::UString& str) { SharedUChar* sharedBuffer = const_cast(&str)->rep()->sharedBuffer(); if (sharedBuffer) { PassRefPtr impl = adoptRef(new StringImpl(str.data(), str.size())); sharedBuffer->ref(); impl->m_sharedBufferAndFlags.set(sharedBuffer); return impl; } return StringImpl::create(str.data(), str.size()); } JSC::UString StringImpl::ustring() { SharedUChar* sharedBuffer = this->sharedBuffer(); if (sharedBuffer) return JSC::UString::Rep::create(sharedBuffer, const_cast(m_data), m_length); return JSC::UString(m_data, m_length); } #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 malloc block. UChar* data; int length = string.m_length; RefPtr terminatedString = createUninitialized(length + 1, data); memcpy(data, string.m_data, length * sizeof(UChar)); data[length] = 0; terminatedString->m_length--; terminatedString->m_hash = string.m_hash; terminatedString->m_sharedBufferAndFlags.setFlag(HasTerminatingNullCharacter); return terminatedString.release(); } PassRefPtr StringImpl::threadsafeCopy() const { // Special-case empty strings to make sure that per-thread empty string instance isn't returned. if (m_length == 0) return adoptRef(new StringImpl); return create(m_data, m_length); } PassRefPtr StringImpl::crossThreadString() { SharedUChar* shared = sharedBuffer(); if (shared) { RefPtr impl = adoptRef(new StringImpl(m_data, m_length)); impl->m_sharedBufferAndFlags.set(shared->crossThreadCopy().releaseRef()); return impl.release(); } // If no shared buffer is available, create a copy. return threadsafeCopy(); } StringImpl::SharedUChar* StringImpl::sharedBuffer() { if (m_length < minLengthToShare || bufferIsInternal()) return 0; if (!m_sharedBufferAndFlags.get()) m_sharedBufferAndFlags.set(SharedUChar::create(new OwnFastMallocPtr(const_cast(m_data))).releaseRef()); return m_sharedBufferAndFlags.get(); } } // namespace WebCore