src/unicode-inl.h - v8/v8 - Git at Google

 // Copyright 2007-2010 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_INL_H_
 #define V8_UNICODE_INL_H_

 #include "src/unicode.h"
 #include "src/base/logging.h"
 #include "src/utils.h"

 namespace unibrow {

 #ifndef V8_INTL_SUPPORT
 template <class T, int s> bool Predicate<T, s>::get(uchar code_point) {
   CacheEntry entry = entries_[code_point & kMask];
   if (entry.code_point() == code_point) return entry.value();
   return CalculateValue(code_point);
 }

 template <class T, int s> bool Predicate<T, s>::CalculateValue(
     uchar code_point) {
   bool result = T::Is(code_point);
   entries_[code_point & kMask] = CacheEntry(code_point, result);
   return result;
 }

 template <class T, int s> int Mapping<T, s>::get(uchar c, uchar n,
     uchar* result) {
   CacheEntry entry = entries_[c & kMask];
   if (entry.code_point_ == c) {
     if (entry.offset_ == 0) {
       return 0;
     } else {
       result[0] = c + entry.offset_;
       return 1;
     }
   } else {
     return CalculateValue(c, n, result);
   }
 }

 template <class T, int s> int Mapping<T, s>::CalculateValue(uchar c, uchar n,
     uchar* result) {
   bool allow_caching = true;
   int length = T::Convert(c, n, result, &allow_caching);
   if (allow_caching) {
     if (length == 1) {
       entries_[c & kMask] = CacheEntry(c, result[0] - c);
       return 1;
     } else {
       entries_[c & kMask] = CacheEntry(c, 0);
       return 0;
     }
   } else {
     return length;
   }
 }
 #endif  // !V8_INTL_SUPPORT

 // Decodes UTF-8 bytes incrementally, allowing the decoding of bytes as they
 // stream in. This **must** be followed by a call to ValueOfIncrementalFinish
 // when the stream is complete, to ensure incomplete sequences are handled.
 uchar Utf8::ValueOfIncremental(const byte** cursor, State* state,
                                Utf8IncrementalBuffer* buffer) {
   DCHECK_NOT_NULL(buffer);
   State old_state = *state;
   byte next = **cursor;
   *cursor += 1;

   if (V8_LIKELY(next <= kMaxOneByteChar && old_state == State::kAccept)) {
     DCHECK_EQ(0u, *buffer);
     return static_cast<uchar>(next);
   }

   // So we're at the lead byte of a 2/3/4 sequence, or we're at a continuation
   // char in that sequence.
   Utf8DfaDecoder::Decode(next, state, buffer);

   switch (*state) {
     case State::kAccept: {
       uchar t = *buffer;
       *buffer = 0;
       return t;
     }

     case State::kReject:
       *state = State::kAccept;
       *buffer = 0;

       // If we hit a bad byte, we need to determine if we were trying to start
       // a sequence or continue one. If we were trying to start a sequence,
       // that means it's just an invalid lead byte and we need to continue to
       // the next (which we already did above). If we were already in a
       // sequence, we need to reprocess this same byte after resetting to the
       // initial state.
       if (old_state != State::kAccept) {
         // We were trying to continue a sequence, so let's reprocess this byte
         // next time.
         *cursor -= 1;
       }
       return kBadChar;

     default:
       return kIncomplete;
   }
 }

 unsigned Utf8::EncodeOneByte(char* str, uint8_t c) {
   static const int kMask = ~(1 << 6);
   if (c <= kMaxOneByteChar) {
     str[0] = c;
     return 1;
   }
   str[0] = 0xC0 | (c >> 6);
   str[1] = 0x80 | (c & kMask);
   return 2;
 }

 // Encode encodes the UTF-16 code units c and previous into the given str
 // buffer, and combines surrogate code units into single code points. If
 // replace_invalid is set to true, orphan surrogate code units will be replaced
 // with kBadChar.
 unsigned Utf8::Encode(char* str,
                       uchar c,
                       int previous,
                       bool replace_invalid) {
   static const int kMask = ~(1 << 6);
   if (c <= kMaxOneByteChar) {
     str[0] = c;
     return 1;
   } else if (c <= kMaxTwoByteChar) {
     str[0] = 0xC0 | (c >> 6);
     str[1] = 0x80 | (c & kMask);
     return 2;
   } else if (c <= kMaxThreeByteChar) {
     DCHECK(!Utf16::IsLeadSurrogate(Utf16::kNoPreviousCharacter));
     if (Utf16::IsSurrogatePair(previous, c)) {
       const int kUnmatchedSize = kSizeOfUnmatchedSurrogate;
       return Encode(str - kUnmatchedSize,
                     Utf16::CombineSurrogatePair(previous, c),
                     Utf16::kNoPreviousCharacter,
                     replace_invalid) - kUnmatchedSize;
     } else if (replace_invalid &&
                (Utf16::IsLeadSurrogate(c) ||
                Utf16::IsTrailSurrogate(c))) {
       c = kBadChar;
     }
     str[0] = 0xE0 | (c >> 12);
     str[1] = 0x80 | ((c >> 6) & kMask);
     str[2] = 0x80 | (c & kMask);
     return 3;
   } else {
     str[0] = 0xF0 | (c >> 18);
     str[1] = 0x80 | ((c >> 12) & kMask);
     str[2] = 0x80 | ((c >> 6) & kMask);
     str[3] = 0x80 | (c & kMask);
     return 4;
   }
 }


 uchar Utf8::ValueOf(const byte* bytes, size_t length, size_t* cursor) {
   if (length <= 0) return kBadChar;
   byte first = bytes[0];
   // Characters between 0000 and 007F are encoded as a single character
   if (V8_LIKELY(first <= kMaxOneByteChar)) {
     *cursor += 1;
     return first;
   }
   return CalculateValue(bytes, length, cursor);
 }

 unsigned Utf8::Length(uchar c, int previous) {
   if (c <= kMaxOneByteChar) {
     return 1;
   } else if (c <= kMaxTwoByteChar) {
     return 2;
   } else if (c <= kMaxThreeByteChar) {
     DCHECK(!Utf16::IsLeadSurrogate(Utf16::kNoPreviousCharacter));
     if (Utf16::IsSurrogatePair(previous, c)) {
       return kSizeOfUnmatchedSurrogate - kBytesSavedByCombiningSurrogates;
     }
     return 3;
   } else {
     return 4;
   }
 }

 bool Utf8::IsValidCharacter(uchar c) {
   return c < 0xD800u || (c >= 0xE000u && c < 0xFDD0u) ||
          (c > 0xFDEFu && c <= 0x10FFFFu && (c & 0xFFFEu) != 0xFFFEu &&
           c != kBadChar);
 }

 }  // namespace unibrow

 #endif  // V8_UNICODE_INL_H_
	// Copyright 2007-2010 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_INL_H_
	#define V8_UNICODE_INL_H_

	#include "src/unicode.h"
	#include "src/base/logging.h"
	#include "src/utils.h"

	namespace unibrow {

	#ifndef V8_INTL_SUPPORT
	template <class T, int s> bool Predicate<T, s>::get(uchar code_point) {
	CacheEntry entry = entries_[code_point & kMask];
	if (entry.code_point() == code_point) return entry.value();
	return CalculateValue(code_point);
	}

	template <class T, int s> bool Predicate<T, s>::CalculateValue(
	uchar code_point) {
	bool result = T::Is(code_point);
	entries_[code_point & kMask] = CacheEntry(code_point, result);
	return result;
	}

	template <class T, int s> int Mapping<T, s>::get(uchar c, uchar n,
	uchar* result) {
	CacheEntry entry = entries_[c & kMask];
	if (entry.code_point_ == c) {
	if (entry.offset_ == 0) {
	return 0;
	} else {
	result[0] = c + entry.offset_;
	return 1;
	}
	} else {
	return CalculateValue(c, n, result);
	}
	}

	template <class T, int s> int Mapping<T, s>::CalculateValue(uchar c, uchar n,
	uchar* result) {
	bool allow_caching = true;
	int length = T::Convert(c, n, result, &allow_caching);
	if (allow_caching) {
	if (length == 1) {
	entries_[c & kMask] = CacheEntry(c, result[0] - c);
	return 1;
	} else {
	entries_[c & kMask] = CacheEntry(c, 0);
	return 0;
	}
	} else {
	return length;
	}
	}
	#endif // !V8_INTL_SUPPORT

	// Decodes UTF-8 bytes incrementally, allowing the decoding of bytes as they
	// stream in. This must be followed by a call to ValueOfIncrementalFinish
	// when the stream is complete, to ensure incomplete sequences are handled.
	uchar Utf8::ValueOfIncremental(const byte** cursor, State* state,
	Utf8IncrementalBuffer* buffer) {
	DCHECK_NOT_NULL(buffer);
	State old_state = *state;
	byte next = **cursor;
	*cursor += 1;

	if (V8_LIKELY(next <= kMaxOneByteChar && old_state == State::kAccept)) {
	DCHECK_EQ(0u, *buffer);
	return static_cast<uchar>(next);
	}

	// So we're at the lead byte of a 2/3/4 sequence, or we're at a continuation
	// char in that sequence.
	Utf8DfaDecoder::Decode(next, state, buffer);

	switch (*state) {
	case State::kAccept: {
	uchar t = *buffer;
	*buffer = 0;
	return t;
	}

	case State::kReject:
	*state = State::kAccept;
	*buffer = 0;

	// If we hit a bad byte, we need to determine if we were trying to start
	// a sequence or continue one. If we were trying to start a sequence,
	// that means it's just an invalid lead byte and we need to continue to
	// the next (which we already did above). If we were already in a
	// sequence, we need to reprocess this same byte after resetting to the
	// initial state.
	if (old_state != State::kAccept) {
	// We were trying to continue a sequence, so let's reprocess this byte
	// next time.
	*cursor -= 1;
	}
	return kBadChar;

	default:
	return kIncomplete;
	}
	}

	unsigned Utf8::EncodeOneByte(char* str, uint8_t c) {
	static const int kMask = ~(1 << 6);
	if (c <= kMaxOneByteChar) {
	str[0] = c;
	return 1;
	}
	str[0] = 0xC0 \| (c >> 6);
	str[1] = 0x80 \| (c & kMask);
	return 2;
	}

	// Encode encodes the UTF-16 code units c and previous into the given str
	// buffer, and combines surrogate code units into single code points. If
	// replace_invalid is set to true, orphan surrogate code units will be replaced
	// with kBadChar.
	unsigned Utf8::Encode(char* str,
	uchar c,
	int previous,
	bool replace_invalid) {
	static const int kMask = ~(1 << 6);
	if (c <= kMaxOneByteChar) {
	str[0] = c;
	return 1;
	} else if (c <= kMaxTwoByteChar) {
	str[0] = 0xC0 \| (c >> 6);
	str[1] = 0x80 \| (c & kMask);
	return 2;
	} else if (c <= kMaxThreeByteChar) {
	DCHECK(!Utf16::IsLeadSurrogate(Utf16::kNoPreviousCharacter));
	if (Utf16::IsSurrogatePair(previous, c)) {
	const int kUnmatchedSize = kSizeOfUnmatchedSurrogate;
	return Encode(str - kUnmatchedSize,
	Utf16::CombineSurrogatePair(previous, c),
	Utf16::kNoPreviousCharacter,
	replace_invalid) - kUnmatchedSize;
	} else if (replace_invalid &&
	(Utf16::IsLeadSurrogate(c) \|\|
	Utf16::IsTrailSurrogate(c))) {
	c = kBadChar;
	}
	str[0] = 0xE0 \| (c >> 12);
	str[1] = 0x80 \| ((c >> 6) & kMask);
	str[2] = 0x80 \| (c & kMask);
	return 3;
	} else {
	str[0] = 0xF0 \| (c >> 18);
	str[1] = 0x80 \| ((c >> 12) & kMask);
	str[2] = 0x80 \| ((c >> 6) & kMask);
	str[3] = 0x80 \| (c & kMask);
	return 4;
	}
	}


	uchar Utf8::ValueOf(const byte* bytes, size_t length, size_t* cursor) {
	if (length <= 0) return kBadChar;
	byte first = bytes[0];
	// Characters between 0000 and 007F are encoded as a single character
	if (V8_LIKELY(first <= kMaxOneByteChar)) {
	*cursor += 1;
	return first;
	}
	return CalculateValue(bytes, length, cursor);
	}

	unsigned Utf8::Length(uchar c, int previous) {
	if (c <= kMaxOneByteChar) {
	return 1;
	} else if (c <= kMaxTwoByteChar) {
	return 2;
	} else if (c <= kMaxThreeByteChar) {
	DCHECK(!Utf16::IsLeadSurrogate(Utf16::kNoPreviousCharacter));
	if (Utf16::IsSurrogatePair(previous, c)) {
	return kSizeOfUnmatchedSurrogate - kBytesSavedByCombiningSurrogates;
	}
	return 3;
	} else {
	return 4;
	}
	}

	bool Utf8::IsValidCharacter(uchar c) {
	return c < 0xD800u \|\| (c >= 0xE000u && c < 0xFDD0u) \|\|
	(c > 0xFDEFu && c <= 0x10FFFFu && (c & 0xFFFEu) != 0xFFFEu &&
	c != kBadChar);
	}

	} // namespace unibrow

	#endif // V8_UNICODE_INL_H_