src/scanner.h - platform/external/chromium_org/v8 - Git at Google

 // Copyright 2011 the V8 project authors. All rights reserved.
 // Redistribution and use in source and binary forms, with or without
 // modification, are permitted provided that the following conditions are
 // met:
 //
 //     * Redistributions of source code must retain the above copyright
 //       notice, this list of conditions and the following disclaimer.
 //     * Redistributions in binary form must reproduce the above
 //       copyright notice, this list of conditions and the following
 //       disclaimer in the documentation and/or other materials provided
 //       with the distribution.
 //     * Neither the name of Google Inc. nor the names of its
 //       contributors may be used to endorse or promote products derived
 //       from this software without specific prior written permission.
 //
 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
 // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
 // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
 // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
 // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
 // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
 // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
 // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

 // Features shared by parsing and pre-parsing scanners.

 #ifndef V8_SCANNER_H_
 #define V8_SCANNER_H_

 #include "allocation.h"
 #include "char-predicates.h"
 #include "checks.h"
 #include "globals.h"
 #include "hashmap.h"
 #include "list.h"
 #include "token.h"
 #include "unicode-inl.h"
 #include "utils.h"

 namespace v8 {
 namespace internal {


 // Returns the value (0 .. 15) of a hexadecimal character c.
 // If c is not a legal hexadecimal character, returns a value < 0.
 inline int HexValue(uc32 c) {
   c -= '0';
   if (static_cast<unsigned>(c) <= 9) return c;
   c = (c | 0x20) - ('a' - '0');  // detect 0x11..0x16 and 0x31..0x36.
   if (static_cast<unsigned>(c) <= 5) return c + 10;
   return -1;
 }


 // ---------------------------------------------------------------------
 // Buffered stream of UTF-16 code units, using an internal UTF-16 buffer.
 // A code unit is a 16 bit value representing either a 16 bit code point
 // or one part of a surrogate pair that make a single 21 bit code point.

 class Utf16CharacterStream {
  public:
   Utf16CharacterStream() : pos_(0) { }
   virtual ~Utf16CharacterStream() { }

   // Returns and advances past the next UTF-16 code unit in the input
   // stream. If there are no more code units, it returns a negative
   // value.
   inline uc32 Advance() {
     if (buffer_cursor_ < buffer_end_ || ReadBlock()) {
       pos_++;
       return static_cast<uc32>(*(buffer_cursor_++));
     }
     // Note: currently the following increment is necessary to avoid a
     // parser problem! The scanner treats the final kEndOfInput as
     // a code unit with a position, and does math relative to that
     // position.
     pos_++;

     return kEndOfInput;
   }

   // Return the current position in the code unit stream.
   // Starts at zero.
   inline unsigned pos() const { return pos_; }

   // Skips forward past the next code_unit_count UTF-16 code units
   // in the input, or until the end of input if that comes sooner.
   // Returns the number of code units actually skipped. If less
   // than code_unit_count,
   inline unsigned SeekForward(unsigned code_unit_count) {
     unsigned buffered_chars =
         static_cast<unsigned>(buffer_end_ - buffer_cursor_);
     if (code_unit_count <= buffered_chars) {
       buffer_cursor_ += code_unit_count;
       pos_ += code_unit_count;
       return code_unit_count;
     }
     return SlowSeekForward(code_unit_count);
   }

   // Pushes back the most recently read UTF-16 code unit (or negative
   // value if at end of input), i.e., the value returned by the most recent
   // call to Advance.
   // Must not be used right after calling SeekForward.
   virtual void PushBack(int32_t code_unit) = 0;

  protected:
   static const uc32 kEndOfInput = -1;

   // Ensures that the buffer_cursor_ points to the code_unit at
   // position pos_ of the input, if possible. If the position
   // is at or after the end of the input, return false. If there
   // are more code_units available, return true.
   virtual bool ReadBlock() = 0;
   virtual unsigned SlowSeekForward(unsigned code_unit_count) = 0;

   const uc16* buffer_cursor_;
   const uc16* buffer_end_;
   unsigned pos_;
 };


 // ---------------------------------------------------------------------
 // Caching predicates used by scanners.

 class UnicodeCache {
  public:
   UnicodeCache() {}
   typedef unibrow::Utf8Decoder<512> Utf8Decoder;

   StaticResource<Utf8Decoder>* utf8_decoder() {
     return &utf8_decoder_;
   }

   bool IsIdentifierStart(unibrow::uchar c) { return kIsIdentifierStart.get(c); }
   bool IsIdentifierPart(unibrow::uchar c) { return kIsIdentifierPart.get(c); }
   bool IsLineTerminator(unibrow::uchar c) { return kIsLineTerminator.get(c); }
   bool IsWhiteSpace(unibrow::uchar c) { return kIsWhiteSpace.get(c); }

  private:
   unibrow::Predicate<IdentifierStart, 128> kIsIdentifierStart;
   unibrow::Predicate<IdentifierPart, 128> kIsIdentifierPart;
   unibrow::Predicate<unibrow::LineTerminator, 128> kIsLineTerminator;
   unibrow::Predicate<unibrow::WhiteSpace, 128> kIsWhiteSpace;
   StaticResource<Utf8Decoder> utf8_decoder_;

   DISALLOW_COPY_AND_ASSIGN(UnicodeCache);
 };


 // ---------------------------------------------------------------------
 // DuplicateFinder discovers duplicate symbols.

 class DuplicateFinder {
  public:
   explicit DuplicateFinder(UnicodeCache* constants)
       : unicode_constants_(constants),
         backing_store_(16),
         map_(&Match) { }

   int AddAsciiSymbol(Vector<const char> key, int value);
   int AddUtf16Symbol(Vector<const uint16_t> key, int value);
   // Add a a number literal by converting it (if necessary)
   // to the string that ToString(ToNumber(literal)) would generate.
   // and then adding that string with AddAsciiSymbol.
   // This string is the actual value used as key in an object literal,
   // and the one that must be different from the other keys.
   int AddNumber(Vector<const char> key, int value);

  private:
   int AddSymbol(Vector<const byte> key, bool is_ascii, int value);
   // Backs up the key and its length in the backing store.
   // The backup is stored with a base 127 encoding of the
   // length (plus a bit saying whether the string is ASCII),
   // followed by the bytes of the key.
   byte* BackupKey(Vector<const byte> key, bool is_ascii);

   // Compare two encoded keys (both pointing into the backing store)
   // for having the same base-127 encoded lengths and ASCII-ness,
   // and then having the same 'length' bytes following.
   static bool Match(void* first, void* second);
   // Creates a hash from a sequence of bytes.
   static uint32_t Hash(Vector<const byte> key, bool is_ascii);
   // Checks whether a string containing a JS number is its canonical
   // form.
   static bool IsNumberCanonical(Vector<const char> key);

   // Size of buffer. Sufficient for using it to call DoubleToCString in
   // from conversions.h.
   static const int kBufferSize = 100;

   UnicodeCache* unicode_constants_;
   // Backing store used to store strings used as hashmap keys.
   SequenceCollector<unsigned char> backing_store_;
   HashMap map_;
   // Buffer used for string->number->canonical string conversions.
   char number_buffer_[kBufferSize];
 };


 // ----------------------------------------------------------------------------
 // LiteralBuffer -  Collector of chars of literals.

 class LiteralBuffer {
  public:
   LiteralBuffer() : is_ascii_(true), position_(0), backing_store_() { }

   ~LiteralBuffer() {
     if (backing_store_.length() > 0) {
       backing_store_.Dispose();
     }
   }

   INLINE(void AddChar(uint32_t code_unit)) {
     if (position_ >= backing_store_.length()) ExpandBuffer();
     if (is_ascii_) {
       if (code_unit <= unibrow::Latin1::kMaxChar) {
         backing_store_[position_] = static_cast<byte>(code_unit);
         position_ += kOneByteSize;
         return;
       }
       ConvertToUtf16();
     }
     ASSERT(code_unit < 0x10000u);
     *reinterpret_cast<uc16*>(&backing_store_[position_]) = code_unit;
     position_ += kUC16Size;
   }

   bool is_ascii() { return is_ascii_; }

   bool is_contextual_keyword(Vector<const char> keyword) {
     return is_ascii() && keyword.length() == position_ &&
         (memcmp(keyword.start(), backing_store_.start(), position_) == 0);
   }

   Vector<const uc16> utf16_literal() {
     ASSERT(!is_ascii_);
     ASSERT((position_ & 0x1) == 0);
     return Vector<const uc16>(
         reinterpret_cast<const uc16*>(backing_store_.start()),
         position_ >> 1);
   }

   Vector<const char> ascii_literal() {
     ASSERT(is_ascii_);
     return Vector<const char>(
         reinterpret_cast<const char*>(backing_store_.start()),
         position_);
   }

   int length() {
     return is_ascii_ ? position_ : (position_ >> 1);
   }

   void Reset() {
     position_ = 0;
     is_ascii_ = true;
   }

  private:
   static const int kInitialCapacity = 16;
   static const int kGrowthFactory = 4;
   static const int kMinConversionSlack = 256;
   static const int kMaxGrowth = 1 * MB;
   inline int NewCapacity(int min_capacity) {
     int capacity = Max(min_capacity, backing_store_.length());
     int new_capacity = Min(capacity * kGrowthFactory, capacity + kMaxGrowth);
     return new_capacity;
   }

   void ExpandBuffer() {
     Vector<byte> new_store = Vector<byte>::New(NewCapacity(kInitialCapacity));
     OS::MemCopy(new_store.start(), backing_store_.start(), position_);
     backing_store_.Dispose();
     backing_store_ = new_store;
   }

   void ConvertToUtf16() {
     ASSERT(is_ascii_);
     Vector<byte> new_store;
     int new_content_size = position_ * kUC16Size;
     if (new_content_size >= backing_store_.length()) {
       // Ensure room for all currently read code units as UC16 as well
       // as the code unit about to be stored.
       new_store = Vector<byte>::New(NewCapacity(new_content_size));
     } else {
       new_store = backing_store_;
     }
     uint8_t* src = backing_store_.start();
     uc16* dst = reinterpret_cast<uc16*>(new_store.start());
     for (int i = position_ - 1; i >= 0; i--) {
       dst[i] = src[i];
     }
     if (new_store.start() != backing_store_.start()) {
       backing_store_.Dispose();
       backing_store_ = new_store;
     }
     position_ = new_content_size;
     is_ascii_ = false;
   }

   bool is_ascii_;
   int position_;
   Vector<byte> backing_store_;

   DISALLOW_COPY_AND_ASSIGN(LiteralBuffer);
 };


 // ----------------------------------------------------------------------------
 // JavaScript Scanner.

 class Scanner {
  public:
   // Scoped helper for literal recording. Automatically drops the literal
   // if aborting the scanning before it's complete.
   class LiteralScope {
    public:
     explicit LiteralScope(Scanner* self)
         : scanner_(self), complete_(false) {
       scanner_->StartLiteral();
     }
      ~LiteralScope() {
        if (!complete_) scanner_->DropLiteral();
      }
     void Complete() {
       scanner_->TerminateLiteral();
       complete_ = true;
     }

    private:
     Scanner* scanner_;
     bool complete_;
   };

   // Representation of an interval of source positions.
   struct Location {
     Location(int b, int e) : beg_pos(b), end_pos(e) { }
     Location() : beg_pos(0), end_pos(0) { }

     bool IsValid() const {
       return beg_pos >= 0 && end_pos >= beg_pos;
     }

     static Location invalid() { return Location(-1, -1); }

     int beg_pos;
     int end_pos;
   };

   // -1 is outside of the range of any real source code.
   static const int kNoOctalLocation = -1;

   explicit Scanner(UnicodeCache* scanner_contants);

   void Initialize(Utf16CharacterStream* source);

   // Returns the next token and advances input.
   Token::Value Next();
   // Returns the current token again.
   Token::Value current_token() { return current_.token; }
   // Returns the location information for the current token
   // (the token last returned by Next()).
   Location location() const { return current_.location; }
   // Returns the literal string, if any, for the current token (the
   // token last returned by Next()). The string is 0-terminated.
   // Literal strings are collected for identifiers, strings, and
   // numbers.
   // These functions only give the correct result if the literal
   // was scanned between calls to StartLiteral() and TerminateLiteral().
   Vector<const char> literal_ascii_string() {
     ASSERT_NOT_NULL(current_.literal_chars);
     return current_.literal_chars->ascii_literal();
   }
   Vector<const uc16> literal_utf16_string() {
     ASSERT_NOT_NULL(current_.literal_chars);
     return current_.literal_chars->utf16_literal();
   }
   bool is_literal_ascii() {
     ASSERT_NOT_NULL(current_.literal_chars);
     return current_.literal_chars->is_ascii();
   }
   bool is_literal_contextual_keyword(Vector<const char> keyword) {
     ASSERT_NOT_NULL(current_.literal_chars);
     return current_.literal_chars->is_contextual_keyword(keyword);
   }
   int literal_length() const {
     ASSERT_NOT_NULL(current_.literal_chars);
     return current_.literal_chars->length();
   }

   bool literal_contains_escapes() const {
     Location location = current_.location;
     int source_length = (location.end_pos - location.beg_pos);
     if (current_.token == Token::STRING) {
       // Subtract delimiters.
       source_length -= 2;
     }
     return current_.literal_chars->length() != source_length;
   }

   // Similar functions for the upcoming token.

   // One token look-ahead (past the token returned by Next()).
   Token::Value peek() const { return next_.token; }

   Location peek_location() const { return next_.location; }

   // Returns the literal string for the next token (the token that
   // would be returned if Next() were called).
   Vector<const char> next_literal_ascii_string() {
     ASSERT_NOT_NULL(next_.literal_chars);
     return next_.literal_chars->ascii_literal();
   }
   Vector<const uc16> next_literal_utf16_string() {
     ASSERT_NOT_NULL(next_.literal_chars);
     return next_.literal_chars->utf16_literal();
   }
   bool is_next_literal_ascii() {
     ASSERT_NOT_NULL(next_.literal_chars);
     return next_.literal_chars->is_ascii();
   }
   bool is_next_contextual_keyword(Vector<const char> keyword) {
     ASSERT_NOT_NULL(next_.literal_chars);
     return next_.literal_chars->is_contextual_keyword(keyword);
   }
   int next_literal_length() const {
     ASSERT_NOT_NULL(next_.literal_chars);
     return next_.literal_chars->length();
   }

   UnicodeCache* unicode_cache() { return unicode_cache_; }

   static const int kCharacterLookaheadBufferSize = 1;

   // Scans octal escape sequence. Also accepts "\0" decimal escape sequence.
   uc32 ScanOctalEscape(uc32 c, int length);

   // Returns the location of the last seen octal literal.
   Location octal_position() const { return octal_pos_; }
   void clear_octal_position() { octal_pos_ = Location::invalid(); }

   // Seek forward to the given position.  This operation does not
   // work in general, for instance when there are pushed back
   // characters, but works for seeking forward until simple delimiter
   // tokens, which is what it is used for.
   void SeekForward(int pos);

   bool HarmonyScoping() const {
     return harmony_scoping_;
   }
   void SetHarmonyScoping(bool scoping) {
     harmony_scoping_ = scoping;
   }
   bool HarmonyModules() const {
     return harmony_modules_;
   }
   void SetHarmonyModules(bool modules) {
     harmony_modules_ = modules;
   }
   bool HarmonyNumericLiterals() const {
     return harmony_numeric_literals_;
   }
   void SetHarmonyNumericLiterals(bool numeric_literals) {
     harmony_numeric_literals_ = numeric_literals;
   }

   // Returns true if there was a line terminator before the peek'ed token,
   // possibly inside a multi-line comment.
   bool HasAnyLineTerminatorBeforeNext() const {
     return has_line_terminator_before_next_ ||
            has_multiline_comment_before_next_;
   }

   // Scans the input as a regular expression pattern, previous
   // character(s) must be /(=). Returns true if a pattern is scanned.
   bool ScanRegExpPattern(bool seen_equal);
   // Returns true if regexp flags are scanned (always since flags can
   // be empty).
   bool ScanRegExpFlags();

  private:
   // The current and look-ahead token.
   struct TokenDesc {
     Token::Value token;
     Location location;
     LiteralBuffer* literal_chars;
   };

   // Call this after setting source_ to the input.
   void Init() {
     // Set c0_ (one character ahead)
     STATIC_ASSERT(kCharacterLookaheadBufferSize == 1);
     Advance();
     // Initialize current_ to not refer to a literal.
     current_.literal_chars = NULL;
   }

   // Literal buffer support
   inline void StartLiteral() {
     LiteralBuffer* free_buffer = (current_.literal_chars == &literal_buffer1_) ?
             &literal_buffer2_ : &literal_buffer1_;
     free_buffer->Reset();
     next_.literal_chars = free_buffer;
   }

   INLINE(void AddLiteralChar(uc32 c)) {
     ASSERT_NOT_NULL(next_.literal_chars);
     next_.literal_chars->AddChar(c);
   }

   // Complete scanning of a literal.
   inline void TerminateLiteral() {
     // Does nothing in the current implementation.
   }

   // Stops scanning of a literal and drop the collected characters,
   // e.g., due to an encountered error.
   inline void DropLiteral() {
     next_.literal_chars = NULL;
   }

   inline void AddLiteralCharAdvance() {
     AddLiteralChar(c0_);
     Advance();
   }

   // Low-level scanning support.
   void Advance() { c0_ = source_->Advance(); }
   void PushBack(uc32 ch) {
     source_->PushBack(c0_);
     c0_ = ch;
   }

   inline Token::Value Select(Token::Value tok) {
     Advance();
     return tok;
   }

   inline Token::Value Select(uc32 next, Token::Value then, Token::Value else_) {
     Advance();
     if (c0_ == next) {
       Advance();
       return then;
     } else {
       return else_;
     }
   }

   uc32 ScanHexNumber(int expected_length);

   // Scans a single JavaScript token.
   void Scan();

   bool SkipWhiteSpace();
   Token::Value SkipSingleLineComment();
   Token::Value SkipMultiLineComment();
   // Scans a possible HTML comment -- begins with '<!'.
   Token::Value ScanHtmlComment();

   void ScanDecimalDigits();
   Token::Value ScanNumber(bool seen_period);
   Token::Value ScanIdentifierOrKeyword();
   Token::Value ScanIdentifierSuffix(LiteralScope* literal);

   Token::Value ScanString();

   // Scans an escape-sequence which is part of a string and adds the
   // decoded character to the current literal. Returns true if a pattern
   // is scanned.
   bool ScanEscape();
   // Decodes a Unicode escape-sequence which is part of an identifier.
   // If the escape sequence cannot be decoded the result is kBadChar.
   uc32 ScanIdentifierUnicodeEscape();
   // Scans a Unicode escape-sequence and adds its characters,
   // uninterpreted, to the current literal. Used for parsing RegExp
   // flags.
   bool ScanLiteralUnicodeEscape();

   // Return the current source position.
   int source_pos() {
     return source_->pos() - kCharacterLookaheadBufferSize;
   }

   UnicodeCache* unicode_cache_;

   // Buffers collecting literal strings, numbers, etc.
   LiteralBuffer literal_buffer1_;
   LiteralBuffer literal_buffer2_;

   TokenDesc current_;  // desc for current token (as returned by Next())
   TokenDesc next_;     // desc for next token (one token look-ahead)

   // Input stream. Must be initialized to an Utf16CharacterStream.
   Utf16CharacterStream* source_;


   // Start position of the octal literal last scanned.
   Location octal_pos_;

   // One Unicode character look-ahead; c0_ < 0 at the end of the input.
   uc32 c0_;

   // Whether there is a line terminator whitespace character after
   // the current token, and  before the next. Does not count newlines
   // inside multiline comments.
   bool has_line_terminator_before_next_;
   // Whether there is a multi-line comment that contains a
   // line-terminator after the current token, and before the next.
   bool has_multiline_comment_before_next_;
   // Whether we scan 'let' as a keyword for harmony block-scoped let bindings.
   bool harmony_scoping_;
   // Whether we scan 'module', 'import', 'export' as keywords.
   bool harmony_modules_;
   // Whether we scan 0o777 and 0b111 as numbers.
   bool harmony_numeric_literals_;
 };

 } }  // namespace v8::internal

 #endif  // V8_SCANNER_H_
	// Copyright 2011 the V8 project authors. All rights reserved.
	// Redistribution and use in source and binary forms, with or without
	// modification, are permitted provided that the following conditions are
	// met:
	//
	// * Redistributions of source code must retain the above copyright
	// notice, this list of conditions and the following disclaimer.
	// * Redistributions in binary form must reproduce the above
	// copyright notice, this list of conditions and the following
	// disclaimer in the documentation and/or other materials provided
	// with the distribution.
	// * Neither the name of Google Inc. nor the names of its
	// contributors may be used to endorse or promote products derived
	// from this software without specific prior written permission.
	//
	// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
	// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
	// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

	// Features shared by parsing and pre-parsing scanners.

	#ifndef V8_SCANNER_H_
	#define V8_SCANNER_H_

	#include "allocation.h"
	#include "char-predicates.h"
	#include "checks.h"
	#include "globals.h"
	#include "hashmap.h"
	#include "list.h"
	#include "token.h"
	#include "unicode-inl.h"
	#include "utils.h"

	namespace v8 {
	namespace internal {


	// Returns the value (0 .. 15) of a hexadecimal character c.
	// If c is not a legal hexadecimal character, returns a value < 0.
	inline int HexValue(uc32 c) {
	c -= '0';
	if (static_cast<unsigned>(c) <= 9) return c;
	c = (c \| 0x20) - ('a' - '0'); // detect 0x11..0x16 and 0x31..0x36.
	if (static_cast<unsigned>(c) <= 5) return c + 10;
	return -1;
	}


	// ---------------------------------------------------------------------
	// Buffered stream of UTF-16 code units, using an internal UTF-16 buffer.
	// A code unit is a 16 bit value representing either a 16 bit code point
	// or one part of a surrogate pair that make a single 21 bit code point.

	class Utf16CharacterStream {
	public:
	Utf16CharacterStream() : pos_(0) { }
	virtual ~Utf16CharacterStream() { }

	// Returns and advances past the next UTF-16 code unit in the input
	// stream. If there are no more code units, it returns a negative
	// value.
	inline uc32 Advance() {
	if (buffer_cursor_ < buffer_end_ \|\| ReadBlock()) {
	pos_++;
	return static_cast<uc32>(*(buffer_cursor_++));
	}
	// Note: currently the following increment is necessary to avoid a
	// parser problem! The scanner treats the final kEndOfInput as
	// a code unit with a position, and does math relative to that
	// position.
	pos_++;

	return kEndOfInput;
	}

	// Return the current position in the code unit stream.
	// Starts at zero.
	inline unsigned pos() const { return pos_; }

	// Skips forward past the next code_unit_count UTF-16 code units
	// in the input, or until the end of input if that comes sooner.
	// Returns the number of code units actually skipped. If less
	// than code_unit_count,
	inline unsigned SeekForward(unsigned code_unit_count) {
	unsigned buffered_chars =
	static_cast<unsigned>(buffer_end_ - buffer_cursor_);
	if (code_unit_count <= buffered_chars) {
	buffer_cursor_ += code_unit_count;
	pos_ += code_unit_count;
	return code_unit_count;
	}
	return SlowSeekForward(code_unit_count);
	}

	// Pushes back the most recently read UTF-16 code unit (or negative
	// value if at end of input), i.e., the value returned by the most recent
	// call to Advance.
	// Must not be used right after calling SeekForward.
	virtual void PushBack(int32_t code_unit) = 0;

	protected:
	static const uc32 kEndOfInput = -1;

	// Ensures that the buffer_cursor_ points to the code_unit at
	// position pos_ of the input, if possible. If the position
	// is at or after the end of the input, return false. If there
	// are more code_units available, return true.
	virtual bool ReadBlock() = 0;
	virtual unsigned SlowSeekForward(unsigned code_unit_count) = 0;

	const uc16* buffer_cursor_;
	const uc16* buffer_end_;
	unsigned pos_;
	};


	// ---------------------------------------------------------------------
	// Caching predicates used by scanners.

	class UnicodeCache {
	public:
	UnicodeCache() {}
	typedef unibrow::Utf8Decoder<512> Utf8Decoder;

	StaticResource<Utf8Decoder>* utf8_decoder() {
	return &utf8_decoder_;
	}

	bool IsIdentifierStart(unibrow::uchar c) { return kIsIdentifierStart.get(c); }
	bool IsIdentifierPart(unibrow::uchar c) { return kIsIdentifierPart.get(c); }
	bool IsLineTerminator(unibrow::uchar c) { return kIsLineTerminator.get(c); }
	bool IsWhiteSpace(unibrow::uchar c) { return kIsWhiteSpace.get(c); }

	private:
	unibrow::Predicate<IdentifierStart, 128> kIsIdentifierStart;
	unibrow::Predicate<IdentifierPart, 128> kIsIdentifierPart;
	unibrow::Predicate<unibrow::LineTerminator, 128> kIsLineTerminator;
	unibrow::Predicate<unibrow::WhiteSpace, 128> kIsWhiteSpace;
	StaticResource<Utf8Decoder> utf8_decoder_;

	DISALLOW_COPY_AND_ASSIGN(UnicodeCache);
	};


	// ---------------------------------------------------------------------
	// DuplicateFinder discovers duplicate symbols.

	class DuplicateFinder {
	public:
	explicit DuplicateFinder(UnicodeCache* constants)
	: unicode_constants_(constants),
	backing_store_(16),
	map_(&Match) { }

	int AddAsciiSymbol(Vector<const char> key, int value);
	int AddUtf16Symbol(Vector<const uint16_t> key, int value);
	// Add a a number literal by converting it (if necessary)
	// to the string that ToString(ToNumber(literal)) would generate.
	// and then adding that string with AddAsciiSymbol.
	// This string is the actual value used as key in an object literal,
	// and the one that must be different from the other keys.
	int AddNumber(Vector<const char> key, int value);

	private:
	int AddSymbol(Vector<const byte> key, bool is_ascii, int value);
	// Backs up the key and its length in the backing store.
	// The backup is stored with a base 127 encoding of the
	// length (plus a bit saying whether the string is ASCII),
	// followed by the bytes of the key.
	byte* BackupKey(Vector<const byte> key, bool is_ascii);

	// Compare two encoded keys (both pointing into the backing store)
	// for having the same base-127 encoded lengths and ASCII-ness,
	// and then having the same 'length' bytes following.
	static bool Match(void* first, void* second);
	// Creates a hash from a sequence of bytes.
	static uint32_t Hash(Vector<const byte> key, bool is_ascii);
	// Checks whether a string containing a JS number is its canonical
	// form.
	static bool IsNumberCanonical(Vector<const char> key);

	// Size of buffer. Sufficient for using it to call DoubleToCString in
	// from conversions.h.
	static const int kBufferSize = 100;

	UnicodeCache* unicode_constants_;
	// Backing store used to store strings used as hashmap keys.
	SequenceCollector<unsigned char> backing_store_;
	HashMap map_;
	// Buffer used for string->number->canonical string conversions.
	char number_buffer_[kBufferSize];
	};


	// ----------------------------------------------------------------------------
	// LiteralBuffer - Collector of chars of literals.

	class LiteralBuffer {
	public:
	LiteralBuffer() : is_ascii_(true), position_(0), backing_store_() { }

	~LiteralBuffer() {
	if (backing_store_.length() > 0) {
	backing_store_.Dispose();
	}
	}

	INLINE(void AddChar(uint32_t code_unit)) {
	if (position_ >= backing_store_.length()) ExpandBuffer();
	if (is_ascii_) {
	if (code_unit <= unibrow::Latin1::kMaxChar) {
	backing_store_[position_] = static_cast<byte>(code_unit);
	position_ += kOneByteSize;
	return;
	}
	ConvertToUtf16();
	}
	ASSERT(code_unit < 0x10000u);
	reinterpret_cast<uc16>(&backing_store_[position_]) = code_unit;
	position_ += kUC16Size;
	}

	bool is_ascii() { return is_ascii_; }

	bool is_contextual_keyword(Vector<const char> keyword) {
	return is_ascii() && keyword.length() == position_ &&
	(memcmp(keyword.start(), backing_store_.start(), position_) == 0);
	}

	Vector<const uc16> utf16_literal() {
	ASSERT(!is_ascii_);
	ASSERT((position_ & 0x1) == 0);
	return Vector<const uc16>(
	reinterpret_cast<const uc16*>(backing_store_.start()),
	position_ >> 1);
	}

	Vector<const char> ascii_literal() {
	ASSERT(is_ascii_);
	return Vector<const char>(
	reinterpret_cast<const char*>(backing_store_.start()),
	position_);
	}

	int length() {
	return is_ascii_ ? position_ : (position_ >> 1);
	}

	void Reset() {
	position_ = 0;
	is_ascii_ = true;
	}

	private:
	static const int kInitialCapacity = 16;
	static const int kGrowthFactory = 4;
	static const int kMinConversionSlack = 256;
	static const int kMaxGrowth = 1 * MB;
	inline int NewCapacity(int min_capacity) {
	int capacity = Max(min_capacity, backing_store_.length());
	int new_capacity = Min(capacity * kGrowthFactory, capacity + kMaxGrowth);
	return new_capacity;
	}

	void ExpandBuffer() {
	Vector<byte> new_store = Vector<byte>::New(NewCapacity(kInitialCapacity));
	OS::MemCopy(new_store.start(), backing_store_.start(), position_);
	backing_store_.Dispose();
	backing_store_ = new_store;
	}

	void ConvertToUtf16() {
	ASSERT(is_ascii_);
	Vector<byte> new_store;
	int new_content_size = position_ * kUC16Size;
	if (new_content_size >= backing_store_.length()) {
	// Ensure room for all currently read code units as UC16 as well
	// as the code unit about to be stored.
	new_store = Vector<byte>::New(NewCapacity(new_content_size));
	} else {
	new_store = backing_store_;
	}
	uint8_t* src = backing_store_.start();
	uc16* dst = reinterpret_cast<uc16*>(new_store.start());
	for (int i = position_ - 1; i >= 0; i--) {
	dst[i] = src[i];
	}
	if (new_store.start() != backing_store_.start()) {
	backing_store_.Dispose();
	backing_store_ = new_store;
	}
	position_ = new_content_size;
	is_ascii_ = false;
	}

	bool is_ascii_;
	int position_;
	Vector<byte> backing_store_;

	DISALLOW_COPY_AND_ASSIGN(LiteralBuffer);
	};


	// ----------------------------------------------------------------------------
	// JavaScript Scanner.

	class Scanner {
	public:
	// Scoped helper for literal recording. Automatically drops the literal
	// if aborting the scanning before it's complete.
	class LiteralScope {
	public:
	explicit LiteralScope(Scanner* self)
	: scanner_(self), complete_(false) {
	scanner_->StartLiteral();
	}
	~LiteralScope() {
	if (!complete_) scanner_->DropLiteral();
	}
	void Complete() {
	scanner_->TerminateLiteral();
	complete_ = true;
	}

	private:
	Scanner* scanner_;
	bool complete_;
	};

	// Representation of an interval of source positions.
	struct Location {
	Location(int b, int e) : beg_pos(b), end_pos(e) { }
	Location() : beg_pos(0), end_pos(0) { }

	bool IsValid() const {
	return beg_pos >= 0 && end_pos >= beg_pos;
	}

	static Location invalid() { return Location(-1, -1); }

	int beg_pos;
	int end_pos;
	};

	// -1 is outside of the range of any real source code.
	static const int kNoOctalLocation = -1;

	explicit Scanner(UnicodeCache* scanner_contants);

	void Initialize(Utf16CharacterStream* source);

	// Returns the next token and advances input.
	Token::Value Next();
	// Returns the current token again.
	Token::Value current_token() { return current_.token; }
	// Returns the location information for the current token
	// (the token last returned by Next()).
	Location location() const { return current_.location; }
	// Returns the literal string, if any, for the current token (the
	// token last returned by Next()). The string is 0-terminated.
	// Literal strings are collected for identifiers, strings, and
	// numbers.
	// These functions only give the correct result if the literal
	// was scanned between calls to StartLiteral() and TerminateLiteral().
	Vector<const char> literal_ascii_string() {
	ASSERT_NOT_NULL(current_.literal_chars);
	return current_.literal_chars->ascii_literal();
	}
	Vector<const uc16> literal_utf16_string() {
	ASSERT_NOT_NULL(current_.literal_chars);
	return current_.literal_chars->utf16_literal();
	}
	bool is_literal_ascii() {
	ASSERT_NOT_NULL(current_.literal_chars);
	return current_.literal_chars->is_ascii();
	}
	bool is_literal_contextual_keyword(Vector<const char> keyword) {
	ASSERT_NOT_NULL(current_.literal_chars);
	return current_.literal_chars->is_contextual_keyword(keyword);
	}
	int literal_length() const {
	ASSERT_NOT_NULL(current_.literal_chars);
	return current_.literal_chars->length();
	}

	bool literal_contains_escapes() const {
	Location location = current_.location;
	int source_length = (location.end_pos - location.beg_pos);
	if (current_.token == Token::STRING) {
	// Subtract delimiters.
	source_length -= 2;
	}
	return current_.literal_chars->length() != source_length;
	}

	// Similar functions for the upcoming token.

	// One token look-ahead (past the token returned by Next()).
	Token::Value peek() const { return next_.token; }

	Location peek_location() const { return next_.location; }

	// Returns the literal string for the next token (the token that
	// would be returned if Next() were called).
	Vector<const char> next_literal_ascii_string() {
	ASSERT_NOT_NULL(next_.literal_chars);
	return next_.literal_chars->ascii_literal();
	}
	Vector<const uc16> next_literal_utf16_string() {
	ASSERT_NOT_NULL(next_.literal_chars);
	return next_.literal_chars->utf16_literal();
	}
	bool is_next_literal_ascii() {
	ASSERT_NOT_NULL(next_.literal_chars);
	return next_.literal_chars->is_ascii();
	}
	bool is_next_contextual_keyword(Vector<const char> keyword) {
	ASSERT_NOT_NULL(next_.literal_chars);
	return next_.literal_chars->is_contextual_keyword(keyword);
	}
	int next_literal_length() const {
	ASSERT_NOT_NULL(next_.literal_chars);
	return next_.literal_chars->length();
	}

	UnicodeCache* unicode_cache() { return unicode_cache_; }

	static const int kCharacterLookaheadBufferSize = 1;

	// Scans octal escape sequence. Also accepts "\0" decimal escape sequence.
	uc32 ScanOctalEscape(uc32 c, int length);

	// Returns the location of the last seen octal literal.
	Location octal_position() const { return octal_pos_; }
	void clear_octal_position() { octal_pos_ = Location::invalid(); }

	// Seek forward to the given position. This operation does not
	// work in general, for instance when there are pushed back
	// characters, but works for seeking forward until simple delimiter
	// tokens, which is what it is used for.
	void SeekForward(int pos);

	bool HarmonyScoping() const {
	return harmony_scoping_;
	}
	void SetHarmonyScoping(bool scoping) {
	harmony_scoping_ = scoping;
	}
	bool HarmonyModules() const {
	return harmony_modules_;
	}
	void SetHarmonyModules(bool modules) {
	harmony_modules_ = modules;
	}
	bool HarmonyNumericLiterals() const {
	return harmony_numeric_literals_;
	}
	void SetHarmonyNumericLiterals(bool numeric_literals) {
	harmony_numeric_literals_ = numeric_literals;
	}

	// Returns true if there was a line terminator before the peek'ed token,
	// possibly inside a multi-line comment.
	bool HasAnyLineTerminatorBeforeNext() const {
	return has_line_terminator_before_next_ \|\|
	has_multiline_comment_before_next_;
	}

	// Scans the input as a regular expression pattern, previous
	// character(s) must be /(=). Returns true if a pattern is scanned.
	bool ScanRegExpPattern(bool seen_equal);
	// Returns true if regexp flags are scanned (always since flags can
	// be empty).
	bool ScanRegExpFlags();

	private:
	// The current and look-ahead token.
	struct TokenDesc {
	Token::Value token;
	Location location;
	LiteralBuffer* literal_chars;
	};

	// Call this after setting source_ to the input.
	void Init() {
	// Set c0_ (one character ahead)
	STATIC_ASSERT(kCharacterLookaheadBufferSize == 1);
	Advance();
	// Initialize current_ to not refer to a literal.
	current_.literal_chars = NULL;
	}

	// Literal buffer support
	inline void StartLiteral() {
	LiteralBuffer* free_buffer = (current_.literal_chars == &literal_buffer1_) ?
	&literal_buffer2_ : &literal_buffer1_;
	free_buffer->Reset();
	next_.literal_chars = free_buffer;
	}

	INLINE(void AddLiteralChar(uc32 c)) {
	ASSERT_NOT_NULL(next_.literal_chars);
	next_.literal_chars->AddChar(c);
	}

	// Complete scanning of a literal.
	inline void TerminateLiteral() {
	// Does nothing in the current implementation.
	}

	// Stops scanning of a literal and drop the collected characters,
	// e.g., due to an encountered error.
	inline void DropLiteral() {
	next_.literal_chars = NULL;
	}

	inline void AddLiteralCharAdvance() {
	AddLiteralChar(c0_);
	Advance();
	}

	// Low-level scanning support.
	void Advance() { c0_ = source_->Advance(); }
	void PushBack(uc32 ch) {
	source_->PushBack(c0_);
	c0_ = ch;
	}

	inline Token::Value Select(Token::Value tok) {
	Advance();
	return tok;
	}

	inline Token::Value Select(uc32 next, Token::Value then, Token::Value else_) {
	Advance();
	if (c0_ == next) {
	Advance();
	return then;
	} else {
	return else_;
	}
	}

	uc32 ScanHexNumber(int expected_length);

	// Scans a single JavaScript token.
	void Scan();

	bool SkipWhiteSpace();
	Token::Value SkipSingleLineComment();
	Token::Value SkipMultiLineComment();
	// Scans a possible HTML comment -- begins with '<!'.
	Token::Value ScanHtmlComment();

	void ScanDecimalDigits();
	Token::Value ScanNumber(bool seen_period);
	Token::Value ScanIdentifierOrKeyword();
	Token::Value ScanIdentifierSuffix(LiteralScope* literal);

	Token::Value ScanString();

	// Scans an escape-sequence which is part of a string and adds the
	// decoded character to the current literal. Returns true if a pattern
	// is scanned.
	bool ScanEscape();
	// Decodes a Unicode escape-sequence which is part of an identifier.
	// If the escape sequence cannot be decoded the result is kBadChar.
	uc32 ScanIdentifierUnicodeEscape();
	// Scans a Unicode escape-sequence and adds its characters,
	// uninterpreted, to the current literal. Used for parsing RegExp
	// flags.
	bool ScanLiteralUnicodeEscape();

	// Return the current source position.
	int source_pos() {
	return source_->pos() - kCharacterLookaheadBufferSize;
	}

	UnicodeCache* unicode_cache_;

	// Buffers collecting literal strings, numbers, etc.
	LiteralBuffer literal_buffer1_;
	LiteralBuffer literal_buffer2_;

	TokenDesc current_; // desc for current token (as returned by Next())
	TokenDesc next_; // desc for next token (one token look-ahead)

	// Input stream. Must be initialized to an Utf16CharacterStream.
	Utf16CharacterStream* source_;


	// Start position of the octal literal last scanned.
	Location octal_pos_;

	// One Unicode character look-ahead; c0_ < 0 at the end of the input.
	uc32 c0_;

	// Whether there is a line terminator whitespace character after
	// the current token, and before the next. Does not count newlines
	// inside multiline comments.
	bool has_line_terminator_before_next_;
	// Whether there is a multi-line comment that contains a
	// line-terminator after the current token, and before the next.
	bool has_multiline_comment_before_next_;
	// Whether we scan 'let' as a keyword for harmony block-scoped let bindings.
	bool harmony_scoping_;
	// Whether we scan 'module', 'import', 'export' as keywords.
	bool harmony_modules_;
	// Whether we scan 0o777 and 0b111 as numbers.
	bool harmony_numeric_literals_;
	};

	} } // namespace v8::internal

	#endif // V8_SCANNER_H_