v8/src/scanner.h
sgjesse@chromium.org fca7b2cefa Refactor the scanner interface
No need to create sub strings for lazy compiles. The scanner will start from the start position provided.

Moved the creating of character streams into the scanner where possible. This uses a input buffer in the scanner class instead of a stack allocated one.

Added a UTF16 buffer for reading external ascii strings (by templating the external two byte string one) as all the source for the builtins are exposed as external ascii strings.
Review URL: http://codereview.chromium.org/661367

git-svn-id: http://v8.googlecode.com/svn/branches/bleeding_edge@4007 ce2b1a6d-e550-0410-aec6-3dcde31c8c00
2010-03-03 13:16:10 +00:00

497 lines
15 KiB
C++

// Copyright 2006-2008 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.
#ifndef V8_SCANNER_H_
#define V8_SCANNER_H_
#include "token.h"
#include "char-predicates-inl.h"
namespace v8 {
namespace internal {
class UTF8Buffer {
public:
UTF8Buffer();
~UTF8Buffer();
void AddChar(uc32 c) {
ASSERT_NOT_NULL(data_);
if (cursor_ <= limit_ &&
static_cast<unsigned>(c) <= unibrow::Utf8::kMaxOneByteChar) {
*cursor_++ = static_cast<char>(c);
} else {
AddCharSlow(c);
}
}
void Reset() {
if (data_ == NULL) {
data_ = NewArray<char>(kInitialCapacity);
limit_ = ComputeLimit(data_, kInitialCapacity);
}
cursor_ = data_;
}
int pos() const {
ASSERT_NOT_NULL(data_);
return static_cast<int>(cursor_ - data_);
}
char* data() const { return data_; }
private:
static const int kInitialCapacity = 256;
char* data_;
char* cursor_;
char* limit_;
int Capacity() const {
ASSERT_NOT_NULL(data_);
return static_cast<int>(limit_ - data_) + unibrow::Utf8::kMaxEncodedSize;
}
static char* ComputeLimit(char* data, int capacity) {
return (data + capacity) - unibrow::Utf8::kMaxEncodedSize;
}
void AddCharSlow(uc32 c);
};
// Interface through which the scanner reads characters from the input source.
class UTF16Buffer {
public:
UTF16Buffer();
virtual ~UTF16Buffer() {}
virtual void PushBack(uc32 ch) = 0;
// Returns a value < 0 when the buffer end is reached.
virtual uc32 Advance() = 0;
virtual void SeekForward(int pos) = 0;
int pos() const { return pos_; }
protected:
int pos_; // Current position in the buffer.
int end_; // Position where scanning should stop (EOF).
};
// UTF16 buffer to read characters from a character stream.
class CharacterStreamUTF16Buffer: public UTF16Buffer {
public:
CharacterStreamUTF16Buffer();
virtual ~CharacterStreamUTF16Buffer() {}
void Initialize(Handle<String> data,
unibrow::CharacterStream* stream,
int start_position,
int end_position);
virtual void PushBack(uc32 ch);
virtual uc32 Advance();
virtual void SeekForward(int pos);
private:
List<uc32> pushback_buffer_;
uc32 last_;
unibrow::CharacterStream* stream_;
List<uc32>* pushback_buffer() { return &pushback_buffer_; }
};
// UTF16 buffer to read characters from an external string.
template <typename StringType, typename CharType>
class ExternalStringUTF16Buffer: public UTF16Buffer {
public:
ExternalStringUTF16Buffer();
virtual ~ExternalStringUTF16Buffer() {}
void Initialize(Handle<StringType> data,
int start_position,
int end_position);
virtual void PushBack(uc32 ch);
virtual uc32 Advance();
virtual void SeekForward(int pos);
private:
const CharType* raw_data_; // Pointer to the actual array of characters.
};
class KeywordMatcher {
// Incrementally recognize keywords.
//
// Recognized keywords:
// break case catch const* continue debugger* default delete do else
// finally false for function if in instanceof native* new null
// return switch this throw true try typeof var void while with
//
// *: Actually "future reserved keywords". These are the only ones we
// recognized, the remaining are allowed as identifiers.
public:
KeywordMatcher() : state_(INITIAL), token_(Token::IDENTIFIER) {}
Token::Value token() { return token_; }
inline void AddChar(uc32 input) {
if (state_ != UNMATCHABLE) {
Step(input);
}
}
void Fail() {
token_ = Token::IDENTIFIER;
state_ = UNMATCHABLE;
}
private:
enum State {
UNMATCHABLE,
INITIAL,
KEYWORD_PREFIX,
KEYWORD_MATCHED,
C,
CA,
CO,
CON,
D,
DE,
F,
I,
IN,
N,
T,
TH,
TR,
V,
W
};
struct FirstState {
const char* keyword;
State state;
Token::Value token;
};
// Range of possible first characters of a keyword.
static const unsigned int kFirstCharRangeMin = 'b';
static const unsigned int kFirstCharRangeMax = 'w';
static const unsigned int kFirstCharRangeLength =
kFirstCharRangeMax - kFirstCharRangeMin + 1;
// State map for first keyword character range.
static FirstState first_states_[kFirstCharRangeLength];
// Current state.
State state_;
// Token for currently added characters.
Token::Value token_;
// Matching a specific keyword string (there is only one possible valid
// keyword with the current prefix).
const char* keyword_;
int counter_;
Token::Value keyword_token_;
// If input equals keyword's character at position, continue matching keyword
// from that position.
inline bool MatchKeywordStart(uc32 input,
const char* keyword,
int position,
Token::Value token_if_match) {
if (input == keyword[position]) {
state_ = KEYWORD_PREFIX;
this->keyword_ = keyword;
this->counter_ = position + 1;
this->keyword_token_ = token_if_match;
return true;
}
return false;
}
// If input equals match character, transition to new state and return true.
inline bool MatchState(uc32 input, char match, State new_state) {
if (input == match) {
state_ = new_state;
return true;
}
return false;
}
inline bool MatchKeyword(uc32 input,
char match,
State new_state,
Token::Value keyword_token) {
if (input == match) { // Matched "do".
state_ = new_state;
token_ = keyword_token;
return true;
}
return false;
}
void Step(uc32 input);
};
enum ParserMode { PARSE, PREPARSE };
enum ParserLanguage { JAVASCRIPT, JSON };
class Scanner {
public:
typedef unibrow::Utf8InputBuffer<1024> Utf8Decoder;
// Construction
explicit Scanner(ParserMode parse_mode);
// Initialize the Scanner to scan source.
void Initialize(Handle<String> source,
ParserLanguage language);
void Initialize(Handle<String> source,
unibrow::CharacterStream* stream,
ParserLanguage language);
void Initialize(Handle<String> source,
int start_position, int end_position,
ParserLanguage language);
// Returns the next token.
Token::Value Next();
// One token look-ahead (past the token returned by Next()).
Token::Value peek() const { return next_.token; }
// Returns true if there was a line terminator before the peek'ed token.
bool has_line_terminator_before_next() const {
return has_line_terminator_before_next_;
}
struct Location {
Location(int b, int e) : beg_pos(b), end_pos(e) { }
Location() : beg_pos(0), end_pos(0) { }
int beg_pos;
int end_pos;
};
// Returns the location information for the current token
// (the token returned by Next()).
Location location() const { return current_.location; }
Location peek_location() const { return next_.location; }
// Returns the literal string, if any, for the current token (the
// token returned by Next()). The string is 0-terminated and in
// UTF-8 format; they may contain 0-characters. 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().
const char* literal_string() const {
return current_.literal_buffer->data();
}
int literal_length() const {
// Excluding terminal '\0' added by TerminateLiteral().
return current_.literal_buffer->pos() - 1;
}
// Returns the literal string for the next token (the token that
// would be returned if Next() were called).
const char* next_literal_string() const {
return next_.literal_buffer->data();
}
// Returns the length of the next token (that would be returned if
// Next() were called).
int next_literal_length() const {
return next_.literal_buffer->pos() - 1;
}
Vector<const char> next_literal() const {
return Vector<const char>(next_literal_string(),
next_literal_length());
}
// 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();
// 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 stack_overflow() { return stack_overflow_; }
static StaticResource<Utf8Decoder>* utf8_decoder() { return &utf8_decoder_; }
// Tells whether the buffer contains an identifier (no escapes).
// Used for checking if a property name is an identifier.
static bool IsIdentifier(unibrow::CharacterStream* buffer);
static unibrow::Predicate<IdentifierStart, 128> kIsIdentifierStart;
static unibrow::Predicate<IdentifierPart, 128> kIsIdentifierPart;
static unibrow::Predicate<unibrow::LineTerminator, 128> kIsLineTerminator;
static unibrow::Predicate<unibrow::WhiteSpace, 128> kIsWhiteSpace;
static const int kCharacterLookaheadBufferSize = 1;
static const int kNoEndPosition = 1;
private:
void Init(Handle<String> source,
unibrow::CharacterStream* stream,
int start_position, int end_position,
ParserLanguage language);
// Different UTF16 buffers used to pull characters from. Based on input one of
// these will be initialized as the actual data source.
CharacterStreamUTF16Buffer char_stream_buffer_;
ExternalStringUTF16Buffer<ExternalTwoByteString, uint16_t>
two_byte_string_buffer_;
ExternalStringUTF16Buffer<ExternalAsciiString, char> ascii_string_buffer_;
// Source. Will point to one of the buffers declared above.
UTF16Buffer* source_;
// Used to convert the source string into a character stream when a stream
// is not passed to the scanner.
SafeStringInputBuffer safe_string_input_buffer_;
// Buffer to hold literal values (identifiers, strings, numbers)
// using 0-terminated UTF-8 encoding.
UTF8Buffer literal_buffer_1_;
UTF8Buffer literal_buffer_2_;
bool stack_overflow_;
static StaticResource<Utf8Decoder> utf8_decoder_;
// One Unicode character look-ahead; c0_ < 0 at the end of the input.
uc32 c0_;
// The current and look-ahead token.
struct TokenDesc {
Token::Value token;
Location location;
UTF8Buffer* literal_buffer;
};
TokenDesc current_; // desc for current token (as returned by Next())
TokenDesc next_; // desc for next token (one token look-ahead)
bool has_line_terminator_before_next_;
bool is_pre_parsing_;
bool is_parsing_json_;
// Literal buffer support
void StartLiteral();
void AddChar(uc32 ch);
void AddCharAdvance();
void TerminateLiteral();
// Low-level scanning support.
void Advance() { c0_ = source_->Advance(); }
void PushBack(uc32 ch) {
source_->PushBack(ch);
c0_ = ch;
}
bool SkipWhiteSpace() {
if (is_parsing_json_) {
return SkipJsonWhiteSpace();
} else {
return SkipJavaScriptWhiteSpace();
}
}
bool SkipJavaScriptWhiteSpace();
bool SkipJsonWhiteSpace();
Token::Value SkipSingleLineComment();
Token::Value SkipMultiLineComment();
inline Token::Value Select(Token::Value tok);
inline Token::Value Select(uc32 next, Token::Value then, Token::Value else_);
inline void Scan() {
if (is_parsing_json_) {
ScanJson();
} else {
ScanJavaScript();
}
}
// Scans a single JavaScript token.
void ScanJavaScript();
// Scan a single JSON token. The JSON lexical grammar is specified in the
// ECMAScript 5 standard, section 15.12.1.1.
// Recognizes all of the single-character tokens directly, or calls a function
// to scan a number, string or identifier literal.
// The only allowed whitespace characters between tokens are tab,
// carrige-return, newline and space.
void ScanJson();
// A JSON number (production JSONNumber) is a subset of the valid JavaScript
// decimal number literals.
// It includes an optional minus sign, must have at least one
// digit before and after a decimal point, may not have prefixed zeros (unless
// the integer part is zero), and may include an exponent part (e.g., "e-10").
// Hexadecimal and octal numbers are not allowed.
Token::Value ScanJsonNumber();
// A JSON string (production JSONString) is subset of valid JavaScript string
// literals. The string must only be double-quoted (not single-quoted), and
// the only allowed backslash-escapes are ", /, \, b, f, n, r, t and
// four-digit hex escapes (uXXXX). Any other use of backslashes is invalid.
Token::Value ScanJsonString();
// Used to recognizes one of the literals "true", "false", or "null". These
// are the only valid JSON identifiers (productions JSONBooleanLiteral,
// JSONNullLiteral).
Token::Value ScanJsonIdentifier(const char* text, Token::Value token);
void ScanDecimalDigits();
Token::Value ScanNumber(bool seen_period);
Token::Value ScanIdentifier();
uc32 ScanHexEscape(uc32 c, int length);
uc32 ScanOctalEscape(uc32 c, int length);
void ScanEscape();
Token::Value ScanString();
// Scans a possible HTML comment -- begins with '<!'.
Token::Value ScanHtmlComment();
// Return the current source position.
int source_pos() {
return source_->pos() - kCharacterLookaheadBufferSize;
}
// Decodes a unicode escape-sequence which is part of an identifier.
// If the escape sequence cannot be decoded the result is kBadRune.
uc32 ScanIdentifierUnicodeEscape();
};
} } // namespace v8::internal
#endif // V8_SCANNER_H_