runtime/vm/unicode.h - sdk.git - Git at Google

 // Copyright (c) 2012, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.

 #ifndef RUNTIME_VM_UNICODE_H_
 #define RUNTIME_VM_UNICODE_H_

 #include "vm/allocation.h"
 #include "vm/globals.h"

 namespace dart {

 class String;

 class Utf : AllStatic {
  public:
   static const int32_t kMaxCodePoint = 0x10FFFF;

   static bool IsLatin1(int32_t code_point) {
     return (code_point >= 0) && (code_point <= 0xFF);
   }

   static bool IsBmp(int32_t code_point) {
     return (code_point >= 0) && (code_point <= 0xFFFF);
   }

   static bool IsSupplementary(int32_t code_point) {
     return (code_point > 0xFFFF) && (code_point <= kMaxCodePoint);
   }

   // Returns true if the code point value is above Plane 17.
   static bool IsOutOfRange(intptr_t code_point) {
     return (code_point < 0) || (code_point > kMaxCodePoint);
   }
 };

 class Utf8 : AllStatic {
  public:
   enum Type {
     kLatin1 = 0,     // Latin-1 code point [U+0000, U+00FF].
     kBMP,            // Basic Multilingual Plane code point [U+0000, U+FFFF].
     kSupplementary,  // Supplementary code point [U+010000, U+10FFFF].
   };

   // Returns the most restricted coding form in which the sequence of utf8
   // characters in 'utf8_array' can be represented in, and the number of
   // code units needed in that form.
   static intptr_t CodeUnitCount(const uint8_t* utf8_array,
                                 intptr_t array_len,
                                 Type* type);

   // Returns true if 'utf8_array' is a valid UTF-8 string.
   static bool IsValid(const uint8_t* utf8_array, intptr_t array_len);

   static intptr_t Length(int32_t ch);
   static intptr_t Length(const String& str);

   static intptr_t Encode(int32_t ch, char* dst);
   static intptr_t Encode(const String& src, char* dst, intptr_t len);

   static intptr_t Decode(const uint8_t* utf8_array,
                          intptr_t array_len,
                          int32_t* ch);

   static bool DecodeToLatin1(const uint8_t* utf8_array,
                              intptr_t array_len,
                              uint8_t* dst,
                              intptr_t len);
   static bool DecodeToUTF16(const uint8_t* utf8_array,
                             intptr_t array_len,
                             uint16_t* dst,
                             intptr_t len);
   static bool DecodeToUTF32(const uint8_t* utf8_array,
                             intptr_t array_len,
                             int32_t* dst,
                             intptr_t len);
   static bool DecodeCStringToUTF32(const char* str, int32_t* dst, intptr_t len);

   static const int32_t kMaxOneByteChar = 0x7F;
   static const int32_t kMaxTwoByteChar = 0x7FF;
   static const int32_t kMaxThreeByteChar = 0xFFFF;
   static const int32_t kMaxFourByteChar = Utf::kMaxCodePoint;

  private:
   static bool IsTrailByte(uint8_t code_unit) {
     return (code_unit & 0xC0) == 0x80;
   }

   static bool IsNonShortestForm(uint32_t code_point, size_t num_code_units) {
     return code_point < kOverlongMinimum[num_code_units];
   }

   static bool IsLatin1SequenceStart(uint8_t code_unit) {
     // Check if utf8 sequence is the start of a codepoint <= U+00FF
     return (code_unit <= 0xC3);
   }

   static bool IsSupplementarySequenceStart(uint8_t code_unit) {
     // Check if utf8 sequence is the start of a codepoint >= U+10000.
     return (code_unit >= 0xF0);
   }

   static const int8_t kTrailBytes[];
   static const uint32_t kMagicBits[];
   static const uint32_t kOverlongMinimum[];
 };

 class Utf16 : AllStatic {
  public:
   // Returns the length of the code point in UTF-16 code units.
   static intptr_t Length(int32_t ch) {
     return (ch <= Utf16::kMaxCodeUnit) ? 1 : 2;
   }

   // Returns true if ch is a lead or trail surrogate.
   static bool IsSurrogate(uint32_t ch) { return (ch & 0xFFFFF800) == 0xD800; }

   // Returns true if ch is a lead surrogate.
   static bool IsLeadSurrogate(uint32_t ch) {
     return (ch & 0xFFFFFC00) == 0xD800;
   }

   // Returns true if ch is a low surrogate.
   static bool IsTrailSurrogate(uint32_t ch) {
     return (ch & 0xFFFFFC00) == 0xDC00;
   }

   // Returns the character at i and advances i to the next character
   // boundary.
   static int32_t Next(const uint16_t* characters, intptr_t* i, intptr_t len) {
     int32_t ch = characters[*i];
     if (Utf16::IsLeadSurrogate(ch) && (*i < (len - 1))) {
       int32_t ch2 = characters[*i + 1];
       if (Utf16::IsTrailSurrogate(ch2)) {
         ch = Utf16::Decode(ch, ch2);
         *i += 1;
       }
     }
     *i += 1;
     return ch;
   }

   // Decodes a surrogate pair into a supplementary code point.
   static int32_t Decode(uint16_t lead, uint16_t trail) {
     return 0x10000 + ((lead & 0x000003FF) << 10) + (trail & 0x3FF);
   }

   // Encodes a single code point.
   static void Encode(int32_t codepoint, uint16_t* dst);

   static const int32_t kMaxCodeUnit = 0xFFFF;

  private:
   static const int32_t kLeadSurrogateOffset = (0xD800 - (0x10000 >> 10));

   static const int32_t kSurrogateOffset = (0x10000 - (0xD800 << 10) - 0xDC00);
 };

 class CaseMapping : AllStatic {
  public:
   // Maps a code point to uppercase.
   static int32_t ToUpper(int32_t code_point) {
     return Convert(code_point, kUppercase);
   }

   // Maps a code point to lowercase.
   static int32_t ToLower(int32_t code_point) {
     return Convert(code_point, kLowercase);
   }

  private:
   // Property is a delta to the uppercase mapping.
   static const int32_t kUppercase = 1;

   // Property is a delta to the uppercase mapping.
   static const int32_t kLowercase = 2;

   // Property is an index into the exception table.
   static const int32_t kException = 3;

   // Type bit-field parameters
   static const int32_t kTypeShift = 2;
   static const int32_t kTypeMask = 3;

   // The size of the stage 1 index.
   // TODO(cshapiro): improve indexing so this value is unnecessary.
   static const int kStage1Size = 261;

   // The size of a stage 2 block in bytes.
   static const int kBlockSizeLog2 = 8;
   static const int kBlockSize = 1 << kBlockSizeLog2;

   static int32_t Convert(int32_t ch, int32_t mapping) {
     if (Utf::IsLatin1(ch)) {
       int32_t info = stage2_[ch];
       if ((info & kTypeMask) == mapping) {
         ch += info >> kTypeShift;
       }
     } else if (ch <= (kStage1Size << kBlockSizeLog2)) {
       int16_t offset = stage1_[ch >> kBlockSizeLog2] << kBlockSizeLog2;
       int32_t info = stage2_[offset + (ch & (kBlockSize - 1))];
       int32_t type = info & kTypeMask;
       if (type == mapping) {
         ch += (info >> kTypeShift);
       } else if (type == kException) {
         ch += stage2_exception_[info >> kTypeShift][mapping - 1];
       }
     }
     return ch;
   }

   // Index into the data array.
   static const uint8_t stage1_[];

   // Data for small code points with one mapping
   static const int16_t stage2_[];

   // Data for large code points or code points with both mappings.
   static const int32_t stage2_exception_[][2];
 };

 }  // namespace dart

 #endif  // RUNTIME_VM_UNICODE_H_
	// Copyright (c) 2012, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.

	#ifndef RUNTIME_VM_UNICODE_H_
	#define RUNTIME_VM_UNICODE_H_

	#include "vm/allocation.h"
	#include "vm/globals.h"

	namespace dart {

	class String;

	class Utf : AllStatic {
	public:
	static const int32_t kMaxCodePoint = 0x10FFFF;

	static bool IsLatin1(int32_t code_point) {
	return (code_point >= 0) && (code_point <= 0xFF);
	}

	static bool IsBmp(int32_t code_point) {
	return (code_point >= 0) && (code_point <= 0xFFFF);
	}

	static bool IsSupplementary(int32_t code_point) {
	return (code_point > 0xFFFF) && (code_point <= kMaxCodePoint);
	}

	// Returns true if the code point value is above Plane 17.
	static bool IsOutOfRange(intptr_t code_point) {
	return (code_point < 0) \|\| (code_point > kMaxCodePoint);
	}
	};

	class Utf8 : AllStatic {
	public:
	enum Type {
	kLatin1 = 0, // Latin-1 code point [U+0000, U+00FF].
	kBMP, // Basic Multilingual Plane code point [U+0000, U+FFFF].
	kSupplementary, // Supplementary code point [U+010000, U+10FFFF].
	};

	// Returns the most restricted coding form in which the sequence of utf8
	// characters in 'utf8_array' can be represented in, and the number of
	// code units needed in that form.
	static intptr_t CodeUnitCount(const uint8_t* utf8_array,
	intptr_t array_len,
	Type* type);

	// Returns true if 'utf8_array' is a valid UTF-8 string.
	static bool IsValid(const uint8_t* utf8_array, intptr_t array_len);

	static intptr_t Length(int32_t ch);
	static intptr_t Length(const String& str);

	static intptr_t Encode(int32_t ch, char* dst);
	static intptr_t Encode(const String& src, char* dst, intptr_t len);

	static intptr_t Decode(const uint8_t* utf8_array,
	intptr_t array_len,
	int32_t* ch);

	static bool DecodeToLatin1(const uint8_t* utf8_array,
	intptr_t array_len,
	uint8_t* dst,
	intptr_t len);
	static bool DecodeToUTF16(const uint8_t* utf8_array,
	intptr_t array_len,
	uint16_t* dst,
	intptr_t len);
	static bool DecodeToUTF32(const uint8_t* utf8_array,
	intptr_t array_len,
	int32_t* dst,
	intptr_t len);
	static bool DecodeCStringToUTF32(const char* str, int32_t* dst, intptr_t len);

	static const int32_t kMaxOneByteChar = 0x7F;
	static const int32_t kMaxTwoByteChar = 0x7FF;
	static const int32_t kMaxThreeByteChar = 0xFFFF;
	static const int32_t kMaxFourByteChar = Utf::kMaxCodePoint;

	private:
	static bool IsTrailByte(uint8_t code_unit) {
	return (code_unit & 0xC0) == 0x80;
	}

	static bool IsNonShortestForm(uint32_t code_point, size_t num_code_units) {
	return code_point < kOverlongMinimum[num_code_units];
	}

	static bool IsLatin1SequenceStart(uint8_t code_unit) {
	// Check if utf8 sequence is the start of a codepoint <= U+00FF
	return (code_unit <= 0xC3);
	}

	static bool IsSupplementarySequenceStart(uint8_t code_unit) {
	// Check if utf8 sequence is the start of a codepoint >= U+10000.
	return (code_unit >= 0xF0);
	}

	static const int8_t kTrailBytes[];
	static const uint32_t kMagicBits[];
	static const uint32_t kOverlongMinimum[];
	};

	class Utf16 : AllStatic {
	public:
	// Returns the length of the code point in UTF-16 code units.
	static intptr_t Length(int32_t ch) {
	return (ch <= Utf16::kMaxCodeUnit) ? 1 : 2;
	}

	// Returns true if ch is a lead or trail surrogate.
	static bool IsSurrogate(uint32_t ch) { return (ch & 0xFFFFF800) == 0xD800; }

	// Returns true if ch is a lead surrogate.
	static bool IsLeadSurrogate(uint32_t ch) {
	return (ch & 0xFFFFFC00) == 0xD800;
	}

	// Returns true if ch is a low surrogate.
	static bool IsTrailSurrogate(uint32_t ch) {
	return (ch & 0xFFFFFC00) == 0xDC00;
	}

	// Returns the character at i and advances i to the next character
	// boundary.
	static int32_t Next(const uint16_t* characters, intptr_t* i, intptr_t len) {
	int32_t ch = characters[*i];
	if (Utf16::IsLeadSurrogate(ch) && (*i < (len - 1))) {
	int32_t ch2 = characters[*i + 1];
	if (Utf16::IsTrailSurrogate(ch2)) {
	ch = Utf16::Decode(ch, ch2);
	*i += 1;
	}
	}
	*i += 1;
	return ch;
	}

	// Decodes a surrogate pair into a supplementary code point.
	static int32_t Decode(uint16_t lead, uint16_t trail) {
	return 0x10000 + ((lead & 0x000003FF) << 10) + (trail & 0x3FF);
	}

	// Encodes a single code point.
	static void Encode(int32_t codepoint, uint16_t* dst);

	static const int32_t kMaxCodeUnit = 0xFFFF;

	private:
	static const int32_t kLeadSurrogateOffset = (0xD800 - (0x10000 >> 10));

	static const int32_t kSurrogateOffset = (0x10000 - (0xD800 << 10) - 0xDC00);
	};

	class CaseMapping : AllStatic {
	public:
	// Maps a code point to uppercase.
	static int32_t ToUpper(int32_t code_point) {
	return Convert(code_point, kUppercase);
	}

	// Maps a code point to lowercase.
	static int32_t ToLower(int32_t code_point) {
	return Convert(code_point, kLowercase);
	}

	private:
	// Property is a delta to the uppercase mapping.
	static const int32_t kUppercase = 1;

	// Property is a delta to the uppercase mapping.
	static const int32_t kLowercase = 2;

	// Property is an index into the exception table.
	static const int32_t kException = 3;

	// Type bit-field parameters
	static const int32_t kTypeShift = 2;
	static const int32_t kTypeMask = 3;

	// The size of the stage 1 index.
	// TODO(cshapiro): improve indexing so this value is unnecessary.
	static const int kStage1Size = 261;

	// The size of a stage 2 block in bytes.
	static const int kBlockSizeLog2 = 8;
	static const int kBlockSize = 1 << kBlockSizeLog2;

	static int32_t Convert(int32_t ch, int32_t mapping) {
	if (Utf::IsLatin1(ch)) {
	int32_t info = stage2_[ch];
	if ((info & kTypeMask) == mapping) {
	ch += info >> kTypeShift;
	}
	} else if (ch <= (kStage1Size << kBlockSizeLog2)) {
	int16_t offset = stage1_[ch >> kBlockSizeLog2] << kBlockSizeLog2;
	int32_t info = stage2_[offset + (ch & (kBlockSize - 1))];
	int32_t type = info & kTypeMask;
	if (type == mapping) {
	ch += (info >> kTypeShift);
	} else if (type == kException) {
	ch += stage2_exception_[info >> kTypeShift][mapping - 1];
	}
	}
	return ch;
	}

	// Index into the data array.
	static const uint8_t stage1_[];

	// Data for small code points with one mapping
	static const int16_t stage2_[];

	// Data for large code points or code points with both mappings.
	static const int32_t stage2_exception_[][2];
	};

	} // namespace dart

	#endif // RUNTIME_VM_UNICODE_H_