/* * (C) 1999 Lars Knoll (knoll@kde.org) * Copyright (C) 2004, 2005, 2006, 2007, 2008, 2009, 2010 Apple Inc. All rights reserved. * * 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. * */ #ifndef WTFString_h #define WTFString_h // This file would be called String.h, but that conflicts with // on systems without case-sensitive file systems. #include "StringImpl.h" #ifdef __OBJC__ #include #endif #if USE(CF) typedef const struct __CFString * CFStringRef; #endif #if PLATFORM(QT) QT_BEGIN_NAMESPACE class QString; QT_END_NAMESPACE #include #endif #if PLATFORM(WX) class wxString; #endif #if PLATFORM(HAIKU) class BString; #endif #if PLATFORM(BREWMP) // AECHAR is defined in AEEStdDef.h, but don't include it here to avoid conflicts. #ifndef _AECHAR_DEFINED typedef uint16 AECHAR; #define _AECHAR_DEFINED #endif #endif namespace WTF { class CString; struct StringHash; // Declarations of string operations bool charactersAreAllASCII(const UChar*, size_t); bool charactersAreAllLatin1(const UChar*, size_t); int charactersToIntStrict(const UChar*, size_t, bool* ok = 0, int base = 10); unsigned charactersToUIntStrict(const UChar*, size_t, bool* ok = 0, int base = 10); int64_t charactersToInt64Strict(const UChar*, size_t, bool* ok = 0, int base = 10); uint64_t charactersToUInt64Strict(const UChar*, size_t, bool* ok = 0, int base = 10); intptr_t charactersToIntPtrStrict(const UChar*, size_t, bool* ok = 0, int base = 10); int charactersToInt(const UChar*, size_t, bool* ok = 0); // ignores trailing garbage unsigned charactersToUInt(const UChar*, size_t, bool* ok = 0); // ignores trailing garbage int64_t charactersToInt64(const UChar*, size_t, bool* ok = 0); // ignores trailing garbage uint64_t charactersToUInt64(const UChar*, size_t, bool* ok = 0); // ignores trailing garbage intptr_t charactersToIntPtr(const UChar*, size_t, bool* ok = 0); // ignores trailing garbage double charactersToDouble(const UChar*, size_t, bool* ok = 0, bool* didReadNumber = 0); float charactersToFloat(const UChar*, size_t, bool* ok = 0, bool* didReadNumber = 0); template bool isAllSpecialCharacters(const UChar*, size_t); class String { public: // Construct a null string, distinguishable from an empty string. String() { } // Construct a string with UTF-16 data. String(const UChar* characters, unsigned length); // Construct a string by copying the contents of a vector. To avoid // copying, consider using String::adopt instead. template explicit String(const Vector&); // Construct a string with UTF-16 data, from a null-terminated source. String(const UChar*); // Construct a string with latin1 data. String(const char* characters, unsigned length); // Construct a string with latin1 data, from a null-terminated source. String(const char* characters); // Construct a string referencing an existing StringImpl. String(StringImpl* impl) : m_impl(impl) { } String(PassRefPtr impl) : m_impl(impl) { } String(RefPtr impl) : m_impl(impl) { } // Inline the destructor. ALWAYS_INLINE ~String() { } void swap(String& o) { m_impl.swap(o.m_impl); } static String adopt(StringBuffer& buffer) { return StringImpl::adopt(buffer); } template static String adopt(Vector& vector) { return StringImpl::adopt(vector); } bool isNull() const { return !m_impl; } bool isEmpty() const { return !m_impl || !m_impl->length(); } StringImpl* impl() const { return m_impl.get(); } unsigned length() const { if (!m_impl) return 0; return m_impl->length(); } const UChar* characters() const { if (!m_impl) return 0; return m_impl->characters(); } CString ascii() const; CString latin1() const; CString utf8(bool strict = false) const; UChar operator[](unsigned index) const { if (!m_impl || index >= m_impl->length()) return 0; return m_impl->characters()[index]; } static String number(short); static String number(unsigned short); static String number(int); static String number(unsigned); static String number(long); static String number(unsigned long); static String number(long long); static String number(unsigned long long); static String number(double); // Find a single character or string, also with match function & latin1 forms. size_t find(UChar c, unsigned start = 0) const { return m_impl ? m_impl->find(c, start) : notFound; } size_t find(const String& str, unsigned start = 0) const { return m_impl ? m_impl->find(str.impl(), start) : notFound; } size_t find(CharacterMatchFunctionPtr matchFunction, unsigned start = 0) const { return m_impl ? m_impl->find(matchFunction, start) : notFound; } size_t find(const char* str, unsigned start = 0) const { return m_impl ? m_impl->find(str, start) : notFound; } // Find the last instance of a single character or string. size_t reverseFind(UChar c, unsigned start = UINT_MAX) const { return m_impl ? m_impl->reverseFind(c, start) : notFound; } size_t reverseFind(const String& str, unsigned start = UINT_MAX) const { return m_impl ? m_impl->reverseFind(str.impl(), start) : notFound; } // Case insensitive string matching. size_t findIgnoringCase(const char* str, unsigned start = 0) const { return m_impl ? m_impl->findIgnoringCase(str, start) : notFound; } size_t findIgnoringCase(const String& str, unsigned start = 0) const { return m_impl ? m_impl->findIgnoringCase(str.impl(), start) : notFound; } size_t reverseFindIgnoringCase(const String& str, unsigned start = UINT_MAX) const { return m_impl ? m_impl->reverseFindIgnoringCase(str.impl(), start) : notFound; } // Wrappers for find & reverseFind adding dynamic sensitivity check. size_t find(const char* str, unsigned start, bool caseSensitive) const { return caseSensitive ? find(str, start) : findIgnoringCase(str, start); } size_t find(const String& str, unsigned start, bool caseSensitive) const { return caseSensitive ? find(str, start) : findIgnoringCase(str, start); } size_t reverseFind(const String& str, unsigned start, bool caseSensitive) const { return caseSensitive ? reverseFind(str, start) : reverseFindIgnoringCase(str, start); } const UChar* charactersWithNullTermination(); UChar32 characterStartingAt(unsigned) const; // Ditto. bool contains(UChar c) const { return find(c) != notFound; } bool contains(const char* str, bool caseSensitive = true) const { return find(str, 0, caseSensitive) != notFound; } bool contains(const String& str, bool caseSensitive = true) const { return find(str, 0, caseSensitive) != notFound; } bool startsWith(const String& s, bool caseSensitive = true) const { return m_impl ? m_impl->startsWith(s.impl(), caseSensitive) : s.isEmpty(); } bool endsWith(const String& s, bool caseSensitive = true) const { return m_impl ? m_impl->endsWith(s.impl(), caseSensitive) : s.isEmpty(); } void append(const String&); void append(char); void append(UChar); void append(const UChar*, unsigned length); void insert(const String&, unsigned pos); void insert(const UChar*, unsigned length, unsigned pos); String& replace(UChar a, UChar b) { if (m_impl) m_impl = m_impl->replace(a, b); return *this; } String& replace(UChar a, const String& b) { if (m_impl) m_impl = m_impl->replace(a, b.impl()); return *this; } String& replace(const String& a, const String& b) { if (m_impl) m_impl = m_impl->replace(a.impl(), b.impl()); return *this; } String& replace(unsigned index, unsigned len, const String& b) { if (m_impl) m_impl = m_impl->replace(index, len, b.impl()); return *this; } void makeLower() { if (m_impl) m_impl = m_impl->lower(); } void makeUpper() { if (m_impl) m_impl = m_impl->upper(); } void makeSecure(UChar aChar) { if (m_impl) m_impl = m_impl->secure(aChar); } void truncate(unsigned len); void remove(unsigned pos, int len = 1); String substring(unsigned pos, unsigned len = UINT_MAX) const; String substringSharingImpl(unsigned pos, unsigned len = UINT_MAX) const; String left(unsigned len) const { return substring(0, len); } String right(unsigned len) const { return substring(length() - len, len); } // Returns a lowercase/uppercase version of the string String lower() const; String upper() const; String stripWhiteSpace() const; String simplifyWhiteSpace() const; String removeCharacters(CharacterMatchFunctionPtr) const; template bool isAllSpecialCharacters() const; // Return the string with case folded for case insensitive comparison. String foldCase() const; #if !PLATFORM(QT) static String format(const char *, ...) WTF_ATTRIBUTE_PRINTF(1, 2); #else static String format(const char *, ...); #endif // Returns an uninitialized string. The characters needs to be written // into the buffer returned in data before the returned string is used. // Failure to do this will have unpredictable results. static String createUninitialized(unsigned length, UChar*& data) { return StringImpl::createUninitialized(length, data); } void split(const String& separator, Vector& result) const; void split(const String& separator, bool allowEmptyEntries, Vector& result) const; void split(UChar separator, Vector& result) const; void split(UChar separator, bool allowEmptyEntries, Vector& result) const; int toIntStrict(bool* ok = 0, int base = 10) const; unsigned toUIntStrict(bool* ok = 0, int base = 10) const; int64_t toInt64Strict(bool* ok = 0, int base = 10) const; uint64_t toUInt64Strict(bool* ok = 0, int base = 10) const; intptr_t toIntPtrStrict(bool* ok = 0, int base = 10) const; int toInt(bool* ok = 0) const; unsigned toUInt(bool* ok = 0) const; int64_t toInt64(bool* ok = 0) const; uint64_t toUInt64(bool* ok = 0) const; intptr_t toIntPtr(bool* ok = 0) const; double toDouble(bool* ok = 0, bool* didReadNumber = 0) const; float toFloat(bool* ok = 0, bool* didReadNumber = 0) const; bool percentage(int& percentage) const; // Returns a StringImpl suitable for use on another thread. String crossThreadString() const; // Makes a deep copy. Helpful only if you need to use a String on another thread // (use crossThreadString if the method call doesn't need to be threadsafe). // Since the underlying StringImpl objects are immutable, there's no other reason // to ever prefer copy() over plain old assignment. String threadsafeCopy() const; // Prevent Strings from being implicitly convertable to bool as it will be ambiguous on any platform that // allows implicit conversion to another pointer type (e.g., Mac allows implicit conversion to NSString*). typedef struct ImplicitConversionFromWTFStringToBoolDisallowedA* (String::*UnspecifiedBoolTypeA); typedef struct ImplicitConversionFromWTFStringToBoolDisallowedB* (String::*UnspecifiedBoolTypeB); operator UnspecifiedBoolTypeA() const; operator UnspecifiedBoolTypeB() const; #if USE(CF) String(CFStringRef); CFStringRef createCFString() const; #endif #ifdef __OBJC__ String(NSString*); // This conversion maps NULL to "", which loses the meaning of NULL, but we // need this mapping because AppKit crashes when passed nil NSStrings. operator NSString*() const { if (!m_impl) return @""; return *m_impl; } #endif #if PLATFORM(QT) String(const QString&); String(const QStringRef&); operator QString() const; #endif #if PLATFORM(WX) String(const wxString&); operator wxString() const; #endif #if PLATFORM(HAIKU) String(const BString&); operator BString() const; #endif #if PLATFORM(BREWMP) String(const AECHAR*); #endif // String::fromUTF8 will return a null string if // the input data contains invalid UTF-8 sequences. static String fromUTF8(const char*, size_t); static String fromUTF8(const char*); // Tries to convert the passed in string to UTF-8, but will fall back to Latin-1 if the string is not valid UTF-8. static String fromUTF8WithLatin1Fallback(const char*, size_t); // Determines the writing direction using the Unicode Bidi Algorithm rules P2 and P3. WTF::Unicode::Direction defaultWritingDirection(bool* hasStrongDirectionality = 0) const { if (m_impl) return m_impl->defaultWritingDirection(hasStrongDirectionality); if (hasStrongDirectionality) *hasStrongDirectionality = false; return WTF::Unicode::LeftToRight; } bool containsOnlyASCII() const { return charactersAreAllASCII(characters(), length()); } bool containsOnlyLatin1() const { return charactersAreAllLatin1(characters(), length()); } // Hash table deleted values, which are only constructed and never copied or destroyed. String(WTF::HashTableDeletedValueType) : m_impl(WTF::HashTableDeletedValue) { } bool isHashTableDeletedValue() const { return m_impl.isHashTableDeletedValue(); } private: RefPtr m_impl; }; #if PLATFORM(QT) QDataStream& operator<<(QDataStream& stream, const String& str); QDataStream& operator>>(QDataStream& stream, String& str); #endif String operator+(const String&, const String&); String operator+(const String&, const char*); String operator+(const char*, const String&); inline String& operator+=(String& a, const String& b) { a.append(b); return a; } inline bool operator==(const String& a, const String& b) { return equal(a.impl(), b.impl()); } inline bool operator==(const String& a, const char* b) { return equal(a.impl(), b); } inline bool operator==(const char* a, const String& b) { return equal(a, b.impl()); } inline bool operator!=(const String& a, const String& b) { return !equal(a.impl(), b.impl()); } inline bool operator!=(const String& a, const char* b) { return !equal(a.impl(), b); } inline bool operator!=(const char* a, const String& b) { return !equal(a, b.impl()); } inline bool equalIgnoringCase(const String& a, const String& b) { return equalIgnoringCase(a.impl(), b.impl()); } inline bool equalIgnoringCase(const String& a, const char* b) { return equalIgnoringCase(a.impl(), b); } inline bool equalIgnoringCase(const char* a, const String& b) { return equalIgnoringCase(a, b.impl()); } inline bool equalPossiblyIgnoringCase(const String& a, const String& b, bool ignoreCase) { return ignoreCase ? equalIgnoringCase(a, b) : (a == b); } inline bool equalIgnoringNullity(const String& a, const String& b) { return equalIgnoringNullity(a.impl(), b.impl()); } template inline bool equalIgnoringNullity(const Vector& a, const String& b) { return equalIgnoringNullity(a, b.impl()); } inline bool operator!(const String& str) { return str.isNull(); } inline void swap(String& a, String& b) { a.swap(b); } // Definitions of string operations template String::String(const Vector& vector) : m_impl(vector.size() ? StringImpl::create(vector.data(), vector.size()) : 0) { } #ifdef __OBJC__ // This is for situations in WebKit where the long standing behavior has been // "nil if empty", so we try to maintain longstanding behavior for the sake of // entrenched clients inline NSString* nsStringNilIfEmpty(const String& str) { return str.isEmpty() ? nil : (NSString*)str; } #endif inline bool charactersAreAllASCII(const UChar* characters, size_t length) { UChar ored = 0; for (size_t i = 0; i < length; ++i) ored |= characters[i]; return !(ored & 0xFF80); } inline bool charactersAreAllLatin1(const UChar* characters, size_t length) { UChar ored = 0; for (size_t i = 0; i < length; ++i) ored |= characters[i]; return !(ored & 0xFF00); } int codePointCompare(const String&, const String&); inline size_t find(const UChar* characters, unsigned length, UChar matchCharacter, unsigned index = 0) { while (index < length) { if (characters[index] == matchCharacter) return index; ++index; } return notFound; } inline size_t find(const UChar* characters, unsigned length, CharacterMatchFunctionPtr matchFunction, unsigned index = 0) { while (index < length) { if (matchFunction(characters[index])) return index; ++index; } return notFound; } inline size_t reverseFind(const UChar* characters, unsigned length, UChar matchCharacter, unsigned index = UINT_MAX) { if (!length) return notFound; if (index >= length) index = length - 1; while (characters[index] != matchCharacter) { if (!index--) return notFound; } return index; } inline void append(Vector& vector, const String& string) { vector.append(string.characters(), string.length()); } inline void appendNumber(Vector& vector, unsigned char number) { int numberLength = number > 99 ? 3 : (number > 9 ? 2 : 1); size_t vectorSize = vector.size(); vector.grow(vectorSize + numberLength); switch (numberLength) { case 3: vector[vectorSize + 2] = number % 10 + '0'; number /= 10; case 2: vector[vectorSize + 1] = number % 10 + '0'; number /= 10; case 1: vector[vectorSize] = number % 10 + '0'; } } template inline bool isAllSpecialCharacters(const UChar* characters, size_t length) { for (size_t i = 0; i < length; ++i) { if (!isSpecialCharacter(characters[i])) return false; } return true; } template inline bool String::isAllSpecialCharacters() const { return WTF::isAllSpecialCharacters(characters(), length()); } // StringHash is the default hash for String template struct DefaultHash; template<> struct DefaultHash { typedef StringHash Hash; }; template <> struct VectorTraits : SimpleClassVectorTraits { }; } using WTF::CString; using WTF::String; using WTF::append; using WTF::appendNumber; using WTF::charactersAreAllASCII; using WTF::charactersAreAllLatin1; using WTF::charactersToIntStrict; using WTF::charactersToUIntStrict; using WTF::charactersToInt64Strict; using WTF::charactersToUInt64Strict; using WTF::charactersToIntPtrStrict; using WTF::charactersToInt; using WTF::charactersToUInt; using WTF::charactersToInt64; using WTF::charactersToUInt64; using WTF::charactersToIntPtr; using WTF::charactersToDouble; using WTF::charactersToFloat; using WTF::equal; using WTF::equalIgnoringCase; using WTF::find; using WTF::isAllSpecialCharacters; using WTF::isSpaceOrNewline; using WTF::reverseFind; #endif