runtime/vm/unicode.cc - 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.

 #include "platform/unicode.h"

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

 namespace dart {

 // A constant mask that can be 'and'ed with a word of data to determine if it
 // is all ASCII (with no Latin1 characters).
 #if defined(ARCH_IS_64_BIT)
 static const uintptr_t kAsciiWordMask = DART_UINT64_C(0x8080808080808080);
 #else
 static const uintptr_t kAsciiWordMask = 0x80808080u;
 #endif

 intptr_t Utf8::Length(const String& str) {
   if (str.IsOneByteString() || str.IsExternalOneByteString()) {
     // For 1-byte strings, all code points < 0x80 have single-byte UTF-8
     // encodings and all >= 0x80 have two-byte encodings.  To get the length,
     // start with the number of code points and add the number of high bits in
     // the bytes.
     uintptr_t char_length = str.Length();
     uintptr_t length = char_length;
     const uintptr_t* data;
     NoSafepointScope no_safepoint;
     if (str.IsOneByteString()) {
       data = reinterpret_cast<const uintptr_t*>(OneByteString::DataStart(str));
     } else {
       data = reinterpret_cast<const uintptr_t*>(
           ExternalOneByteString::DataStart(str));
     }
     uintptr_t i;
     for (i = sizeof(uintptr_t); i <= char_length; i += sizeof(uintptr_t)) {
       uintptr_t chunk = *data++;
       chunk &= kAsciiWordMask;
       if (chunk != 0) {
 // Shuffle the bits until we have a count of bits in the low nibble.
 #if defined(ARCH_IS_64_BIT)
         chunk += chunk >> 32;
 #endif
         chunk += chunk >> 16;
         chunk += chunk >> 8;
         length += (chunk >> 7) & 0xf;
       }
     }
     // Take care of the tail of the string, the last length % wordsize chars.
     i -= sizeof(uintptr_t);
     for (; i < char_length; i++) {
       if (str.CharAt(i) > kMaxOneByteChar) length++;
     }
     return length;
   }

   // Slow case for 2-byte strings that handles surrogate pairs and longer UTF-8
   // encodings.
   intptr_t length = 0;
   String::CodePointIterator it(str);
   while (it.Next()) {
     int32_t ch = it.Current();
     length += Utf8::Length(ch);
   }
   return length;
 }

 intptr_t Utf8::Encode(const String& src, char* dst, intptr_t len) {
   uintptr_t array_len = len;
   intptr_t pos = 0;
   ASSERT(static_cast<intptr_t>(array_len) >= Length(src));
   if (src.IsOneByteString() || src.IsExternalOneByteString()) {
     // For 1-byte strings, all code points < 0x80 have single-byte UTF-8
     // encodings and all >= 0x80 have two-byte encodings.
     const uintptr_t* data;
     NoSafepointScope scope;
     if (src.IsOneByteString()) {
       data = reinterpret_cast<const uintptr_t*>(OneByteString::DataStart(src));
     } else {
       data = reinterpret_cast<const uintptr_t*>(
           ExternalOneByteString::DataStart(src));
     }
     uintptr_t char_length = src.Length();
     uintptr_t pos = 0;
     ASSERT(kMaxOneByteChar + 1 == 0x80);
     for (uintptr_t i = 0; i < char_length; i += sizeof(uintptr_t)) {
       // Read the input one word at a time and just write it verbatim if it is
       // plain ASCII, as determined by the mask.
       if (i + sizeof(uintptr_t) <= char_length &&
           (*data & kAsciiWordMask) == 0 &&
           pos + sizeof(uintptr_t) <= array_len) {
         StoreUnaligned(reinterpret_cast<uintptr_t*>(dst + pos), *data);
         pos += sizeof(uintptr_t);
       } else {
         // Process up to one word of input that contains non-ASCII Latin1
         // characters.
         const uint8_t* p = reinterpret_cast<const uint8_t*>(data);
         const uint8_t* limit =
             Utils::Minimum(p + sizeof(uintptr_t), p + (char_length - i));
         for (; p < limit; p++) {
           uint8_t c = *p;
           // These calls to Length and Encode get inlined and the cases for 3
           // and 4 byte sequences are removed.
           intptr_t bytes = Length(c);
           if (pos + bytes > array_len) {
             return pos;
           }
           Encode(c, reinterpret_cast<char*>(dst) + pos);
           pos += bytes;
         }
       }
       data++;
     }
   } else {
     // For two-byte strings, which can contain 3 and 4-byte UTF-8 encodings,
     // which can result in surrogate pairs, use the more general code.
     String::CodePointIterator it(src);
     while (it.Next()) {
       int32_t ch = it.Current();
       ASSERT(!Utf::IsOutOfRange(ch));
       if (Utf16::IsSurrogate(ch)) {
         // Encode unpaired surrogates as replacement characters to ensure the
         // output is valid UTF-8. Encoded size is the same (3), so the computed
         // length is still valid.
         ch = Utf::kReplacementChar;
       }
       intptr_t num_bytes = Utf8::Length(ch);
       if (pos + num_bytes > len) {
         break;
       }
       Utf8::Encode(ch, &dst[pos]);
       pos += num_bytes;
     }
   }
   return pos;
 }

 }  // namespace dart
	// 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.

	#include "platform/unicode.h"

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

	namespace dart {

	// A constant mask that can be 'and'ed with a word of data to determine if it
	// is all ASCII (with no Latin1 characters).
	#if defined(ARCH_IS_64_BIT)
	static const uintptr_t kAsciiWordMask = DART_UINT64_C(0x8080808080808080);
	#else
	static const uintptr_t kAsciiWordMask = 0x80808080u;
	#endif

	intptr_t Utf8::Length(const String& str) {
	if (str.IsOneByteString() \|\| str.IsExternalOneByteString()) {
	// For 1-byte strings, all code points < 0x80 have single-byte UTF-8
	// encodings and all >= 0x80 have two-byte encodings. To get the length,
	// start with the number of code points and add the number of high bits in
	// the bytes.
	uintptr_t char_length = str.Length();
	uintptr_t length = char_length;
	const uintptr_t* data;
	NoSafepointScope no_safepoint;
	if (str.IsOneByteString()) {
	data = reinterpret_cast<const uintptr_t*>(OneByteString::DataStart(str));
	} else {
	data = reinterpret_cast<const uintptr_t*>(
	ExternalOneByteString::DataStart(str));
	}
	uintptr_t i;
	for (i = sizeof(uintptr_t); i <= char_length; i += sizeof(uintptr_t)) {
	uintptr_t chunk = *data++;
	chunk &= kAsciiWordMask;
	if (chunk != 0) {
	// Shuffle the bits until we have a count of bits in the low nibble.
	#if defined(ARCH_IS_64_BIT)
	chunk += chunk >> 32;
	#endif
	chunk += chunk >> 16;
	chunk += chunk >> 8;
	length += (chunk >> 7) & 0xf;
	}
	}
	// Take care of the tail of the string, the last length % wordsize chars.
	i -= sizeof(uintptr_t);
	for (; i < char_length; i++) {
	if (str.CharAt(i) > kMaxOneByteChar) length++;
	}
	return length;
	}

	// Slow case for 2-byte strings that handles surrogate pairs and longer UTF-8
	// encodings.
	intptr_t length = 0;
	String::CodePointIterator it(str);
	while (it.Next()) {
	int32_t ch = it.Current();
	length += Utf8::Length(ch);
	}
	return length;
	}

	intptr_t Utf8::Encode(const String& src, char* dst, intptr_t len) {
	uintptr_t array_len = len;
	intptr_t pos = 0;
	ASSERT(static_cast<intptr_t>(array_len) >= Length(src));
	if (src.IsOneByteString() \|\| src.IsExternalOneByteString()) {
	// For 1-byte strings, all code points < 0x80 have single-byte UTF-8
	// encodings and all >= 0x80 have two-byte encodings.
	const uintptr_t* data;
	NoSafepointScope scope;
	if (src.IsOneByteString()) {
	data = reinterpret_cast<const uintptr_t*>(OneByteString::DataStart(src));
	} else {
	data = reinterpret_cast<const uintptr_t*>(
	ExternalOneByteString::DataStart(src));
	}
	uintptr_t char_length = src.Length();
	uintptr_t pos = 0;
	ASSERT(kMaxOneByteChar + 1 == 0x80);
	for (uintptr_t i = 0; i < char_length; i += sizeof(uintptr_t)) {
	// Read the input one word at a time and just write it verbatim if it is
	// plain ASCII, as determined by the mask.
	if (i + sizeof(uintptr_t) <= char_length &&
	(*data & kAsciiWordMask) == 0 &&
	pos + sizeof(uintptr_t) <= array_len) {
	StoreUnaligned(reinterpret_cast<uintptr_t>(dst + pos), data);
	pos += sizeof(uintptr_t);
	} else {
	// Process up to one word of input that contains non-ASCII Latin1
	// characters.
	const uint8_t* p = reinterpret_cast<const uint8_t*>(data);
	const uint8_t* limit =
	Utils::Minimum(p + sizeof(uintptr_t), p + (char_length - i));
	for (; p < limit; p++) {
	uint8_t c = *p;
	// These calls to Length and Encode get inlined and the cases for 3
	// and 4 byte sequences are removed.
	intptr_t bytes = Length(c);
	if (pos + bytes > array_len) {
	return pos;
	}
	Encode(c, reinterpret_cast<char*>(dst) + pos);
	pos += bytes;
	}
	}
	data++;
	}
	} else {
	// For two-byte strings, which can contain 3 and 4-byte UTF-8 encodings,
	// which can result in surrogate pairs, use the more general code.
	String::CodePointIterator it(src);
	while (it.Next()) {
	int32_t ch = it.Current();
	ASSERT(!Utf::IsOutOfRange(ch));
	if (Utf16::IsSurrogate(ch)) {
	// Encode unpaired surrogates as replacement characters to ensure the
	// output is valid UTF-8. Encoded size is the same (3), so the computed
	// length is still valid.
	ch = Utf::kReplacementChar;
	}
	intptr_t num_bytes = Utf8::Length(ch);
	if (pos + num_bytes > len) {
	break;
	}
	Utf8::Encode(ch, &dst[pos]);
	pos += num_bytes;
	}
	}
	return pos;
	}

	} // namespace dart