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// 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 <sys/types.h>
#include "src/globals.h"
#include "src/third_party/utf8-decoder/utf8-decoder.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 T, int size = 256>
class Predicate {
public:
inline Predicate() = default;
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(CodePointField::kMask & code_point) |
ValueField::encode(value)) {
DCHECK_IMPLIES((CodePointField::kMask & code_point) != code_point,
code_point == static_cast<uchar>(-1));
}
uchar code_point() const { return CodePointField::decode(bit_field_); }
bool value() const { return ValueField::decode(bit_field_); }
private:
class CodePointField : public v8::internal::BitField<uchar, 0, 21> {};
class ValueField : public v8::internal::BitField<bool, 21, 1> {};
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 T, int size = 256>
class Mapping {
public:
inline Mapping() = default;
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 const int kNoPreviousCharacter = -1;
static inline bool IsSurrogatePair(int lead, int trail) {
return IsLeadSurrogate(lead) && IsTrailSurrogate(trail);
}
static inline bool IsLeadSurrogate(int code) {
return (code & 0xfc00) == 0xd800;
}
static inline bool IsTrailSurrogate(int code) {
return (code & 0xfc00) == 0xdc00;
}
static inline int CombineSurrogatePair(uchar lead, uchar trail) {
return 0x10000 + ((lead & 0x3ff) << 10) + (trail & 0x3ff);
}
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 V8_EXPORT_PRIVATE Utf8 {
public:
using State = Utf8DfaDecoder::State;
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, size_t length, size_t* 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 uchar kBufferEmpty = 0x0;
static const uchar kIncomplete = 0xFFFFFFFC; // any non-valid code point.
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, size_t length, size_t* cursor);
typedef uint32_t Utf8IncrementalBuffer;
static inline uchar ValueOfIncremental(const byte** cursor, State* state,
Utf8IncrementalBuffer* buffer);
static uchar ValueOfIncrementalFinish(State* state);
// Excludes non-characters from the set of valid code points.
static inline bool IsValidCharacter(uchar c);
// Validate if the input has a valid utf-8 encoding. Unlike JS source code
// this validation function will accept any unicode code point, including
// kBadChar and BOMs.
//
// This method checks for:
// - valid utf-8 endcoding (e.g. no over-long encodings),
// - absence of surrogates,
// - valid code point range.
static bool ValidateEncoding(const byte* str, size_t length);
};
struct Uppercase {
static bool Is(uchar c);
};
struct Letter {
static bool Is(uchar c);
};
#ifndef V8_INTL_SUPPORT
struct V8_EXPORT_PRIVATE ID_Start {
static bool Is(uchar c);
};
struct V8_EXPORT_PRIVATE ID_Continue {
static bool Is(uchar c);
};
struct V8_EXPORT_PRIVATE WhiteSpace {
static bool Is(uchar c);
};
#endif // !V8_INTL_SUPPORT
// LineTerminator: 'JS_Line_Terminator' in point.properties
// ES#sec-line-terminators lists exactly 4 code points:
// LF (U+000A), CR (U+000D), LS(U+2028), PS(U+2029)
V8_INLINE bool IsLineTerminator(uchar c) {
return c == 0x000A || c == 0x000D || c == 0x2028 || c == 0x2029;
}
V8_INLINE bool IsStringLiteralLineTerminator(uchar c) {
return c == 0x000A || c == 0x000D;
}
#ifndef V8_INTL_SUPPORT
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);
};
#endif
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_
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