// Copyright 2011 the V8 project authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #ifndef V8_UNICODE_H_ #define V8_UNICODE_H_ #include #include "src/globals.h" #include "src/utils.h" /** * \file * Definitions and convenience functions for working with unicode. */ namespace unibrow { typedef unsigned int uchar; typedef unsigned char byte; /** * The max length of the result of converting the case of a single * character. */ const int kMaxMappingSize = 4; template class Predicate { public: inline Predicate() { } inline bool get(uchar c); private: friend class Test; bool CalculateValue(uchar c); class CacheEntry { public: inline CacheEntry() : bit_field_(CodePointField::encode(0) | ValueField::encode(0)) {} inline CacheEntry(uchar code_point, bool value) : bit_field_(CodePointField::encode(code_point) | ValueField::encode(value)) {} uchar code_point() const { return CodePointField::decode(bit_field_); } bool value() const { return ValueField::decode(bit_field_); } private: class CodePointField : public v8::internal::BitField {}; class ValueField : public v8::internal::BitField {}; uint32_t bit_field_; }; static const int kSize = size; static const int kMask = kSize - 1; CacheEntry entries_[kSize]; }; // A cache used in case conversion. It caches the value for characters // that either have no mapping or map to a single character independent // of context. Characters that map to more than one character or that // map differently depending on context are always looked up. template class Mapping { public: inline Mapping() { } inline int get(uchar c, uchar n, uchar* result); private: friend class Test; int CalculateValue(uchar c, uchar n, uchar* result); struct CacheEntry { inline CacheEntry() : code_point_(kNoChar), offset_(0) { } inline CacheEntry(uchar code_point, signed offset) : code_point_(code_point), offset_(offset) { } uchar code_point_; signed offset_; static const int kNoChar = (1 << 21) - 1; }; static const int kSize = size; static const int kMask = kSize - 1; CacheEntry entries_[kSize]; }; class UnicodeData { private: friend class Test; static int GetByteCount(); static const uchar kMaxCodePoint; }; class Utf16 { public: static inline bool IsSurrogatePair(int lead, int trail) { return IsLeadSurrogate(lead) && IsTrailSurrogate(trail); } static inline bool IsLeadSurrogate(int code) { if (code == kNoPreviousCharacter) return false; return (code & 0xfc00) == 0xd800; } static inline bool IsTrailSurrogate(int code) { if (code == kNoPreviousCharacter) return false; return (code & 0xfc00) == 0xdc00; } static inline int CombineSurrogatePair(uchar lead, uchar trail) { return 0x10000 + ((lead & 0x3ff) << 10) + (trail & 0x3ff); } static const int kNoPreviousCharacter = -1; static const uchar kMaxNonSurrogateCharCode = 0xffff; // Encoding a single UTF-16 code unit will produce 1, 2 or 3 bytes // of UTF-8 data. The special case where the unit is a surrogate // trail produces 1 byte net, because the encoding of the pair is // 4 bytes and the 3 bytes that were used to encode the lead surrogate // can be reclaimed. static const int kMaxExtraUtf8BytesForOneUtf16CodeUnit = 3; // One UTF-16 surrogate is endoded (illegally) as 3 UTF-8 bytes. // The illegality stems from the surrogate not being part of a pair. static const int kUtf8BytesToCodeASurrogate = 3; static inline uint16_t LeadSurrogate(uint32_t char_code) { return 0xd800 + (((char_code - 0x10000) >> 10) & 0x3ff); } static inline uint16_t TrailSurrogate(uint32_t char_code) { return 0xdc00 + (char_code & 0x3ff); } }; class Utf8 { public: static inline uchar Length(uchar chr, int previous); static inline unsigned EncodeOneByte(char* out, uint8_t c); static inline unsigned Encode(char* out, uchar c, int previous, bool replace_invalid = false); static uchar CalculateValue(const byte* str, unsigned length, unsigned* cursor); // The unicode replacement character, used to signal invalid unicode // sequences (e.g. an orphan surrogate) when converting to a UTF-8 encoding. static const uchar kBadChar = 0xFFFD; static const unsigned kMaxEncodedSize = 4; static const unsigned kMaxOneByteChar = 0x7f; static const unsigned kMaxTwoByteChar = 0x7ff; static const unsigned kMaxThreeByteChar = 0xffff; static const unsigned kMaxFourByteChar = 0x1fffff; // A single surrogate is coded as a 3 byte UTF-8 sequence, but two together // that match are coded as a 4 byte UTF-8 sequence. static const unsigned kBytesSavedByCombiningSurrogates = 2; static const unsigned kSizeOfUnmatchedSurrogate = 3; // The maximum size a single UTF-16 code unit may take up when encoded as // UTF-8. static const unsigned kMax16BitCodeUnitSize = 3; static inline uchar ValueOf(const byte* str, unsigned length, unsigned* cursor); }; struct Uppercase { static bool Is(uchar c); }; struct Lowercase { static bool Is(uchar c); }; struct Letter { static bool Is(uchar c); }; struct ID_Start { static bool Is(uchar c); }; struct ID_Continue { static bool Is(uchar c); }; struct WhiteSpace { static bool Is(uchar c); }; struct LineTerminator { static bool Is(uchar c); }; struct ToLowercase { static const int kMaxWidth = 3; static const bool kIsToLower = true; static int Convert(uchar c, uchar n, uchar* result, bool* allow_caching_ptr); }; struct ToUppercase { static const int kMaxWidth = 3; static const bool kIsToLower = false; static int Convert(uchar c, uchar n, uchar* result, bool* allow_caching_ptr); }; struct Ecma262Canonicalize { static const int kMaxWidth = 1; static int Convert(uchar c, uchar n, uchar* result, bool* allow_caching_ptr); }; struct Ecma262UnCanonicalize { static const int kMaxWidth = 4; static int Convert(uchar c, uchar n, uchar* result, bool* allow_caching_ptr); }; struct CanonicalizationRange { static const int kMaxWidth = 1; static int Convert(uchar c, uchar n, uchar* result, bool* allow_caching_ptr); }; } // namespace unibrow #endif // V8_UNICODE_H_