// Copyright 2010 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. #include "v8.h" #include "ast.h" #include "handles.h" #include "scanner.h" #include "unicode-inl.h" namespace v8 { namespace internal { // ---------------------------------------------------------------------------- // BufferedUC16CharacterStreams BufferedUC16CharacterStream::BufferedUC16CharacterStream() : UC16CharacterStream(), pushback_limit_(NULL) { // Initialize buffer as being empty. First read will fill the buffer. buffer_cursor_ = buffer_; buffer_end_ = buffer_; } BufferedUC16CharacterStream::~BufferedUC16CharacterStream() { } void BufferedUC16CharacterStream::PushBack(uc32 character) { if (character == kEndOfInput) { pos_--; return; } if (pushback_limit_ == NULL && buffer_cursor_ > buffer_) { // buffer_ is writable, buffer_cursor_ is const pointer. buffer_[--buffer_cursor_ - buffer_] = static_cast(character); pos_--; return; } SlowPushBack(static_cast(character)); } void BufferedUC16CharacterStream::SlowPushBack(uc16 character) { // In pushback mode, the end of the buffer contains pushback, // and the start of the buffer (from buffer start to pushback_limit_) // contains valid data that comes just after the pushback. // We NULL the pushback_limit_ if pushing all the way back to the // start of the buffer. if (pushback_limit_ == NULL) { // Enter pushback mode. pushback_limit_ = buffer_end_; buffer_end_ = buffer_ + kBufferSize; buffer_cursor_ = buffer_end_; } ASSERT(pushback_limit_ > buffer_); ASSERT(pos_ > 0); buffer_[--buffer_cursor_ - buffer_] = character; if (buffer_cursor_ == buffer_) { pushback_limit_ = NULL; } else if (buffer_cursor_ < pushback_limit_) { pushback_limit_ = buffer_cursor_; } pos_--; } bool BufferedUC16CharacterStream::ReadBlock() { if (pushback_limit_ != NULL) { buffer_cursor_ = buffer_; buffer_end_ = pushback_limit_; pushback_limit_ = NULL; ASSERT(buffer_cursor_ != buffer_end_); return true; } unsigned length = FillBuffer(pos_, kBufferSize); buffer_cursor_ = buffer_; buffer_end_ = buffer_ + length; return length > 0; } unsigned BufferedUC16CharacterStream::SlowSeekForward(unsigned delta) { // Leave pushback mode (i.e., ignore that there might be valid data // in the buffer before the pushback_limit_ point). pushback_limit_ = NULL; return BufferSeekForward(delta); } // ---------------------------------------------------------------------------- // GenericStringUC16CharacterStream GenericStringUC16CharacterStream::GenericStringUC16CharacterStream( Handle data, unsigned start_position, unsigned end_position) : string_(data), length_(end_position) { ASSERT(end_position >= start_position); buffer_cursor_ = buffer_; buffer_end_ = buffer_; pos_ = start_position; } GenericStringUC16CharacterStream::~GenericStringUC16CharacterStream() { } unsigned GenericStringUC16CharacterStream::BufferSeekForward(unsigned delta) { unsigned old_pos = pos_; pos_ = Min(pos_ + delta, length_); ReadBlock(); return pos_ - old_pos; } unsigned GenericStringUC16CharacterStream::FillBuffer(unsigned from_pos, unsigned length) { if (from_pos >= length_) return 0; if (from_pos + length > length_) { length = length_ - from_pos; } String::WriteToFlat(*string_, buffer_, from_pos, from_pos + length); return length; } // ---------------------------------------------------------------------------- // Utf8ToUC16CharacterStream Utf8ToUC16CharacterStream::Utf8ToUC16CharacterStream(const byte* data, unsigned length) : BufferedUC16CharacterStream(), raw_data_(data), raw_data_length_(length), raw_data_pos_(0), raw_character_position_(0) { ReadBlock(); } Utf8ToUC16CharacterStream::~Utf8ToUC16CharacterStream() { } unsigned Utf8ToUC16CharacterStream::BufferSeekForward(unsigned delta) { unsigned old_pos = pos_; unsigned target_pos = pos_ + delta; SetRawPosition(target_pos); pos_ = raw_character_position_; ReadBlock(); return pos_ - old_pos; } unsigned Utf8ToUC16CharacterStream::FillBuffer(unsigned char_position, unsigned length) { static const unibrow::uchar kMaxUC16Character = 0xffff; SetRawPosition(char_position); if (raw_character_position_ != char_position) { // char_position was not a valid position in the stream (hit the end // while spooling to it). return 0u; } unsigned i = 0; while (i < length) { if (raw_data_pos_ == raw_data_length_) break; unibrow::uchar c = raw_data_[raw_data_pos_]; if (c <= unibrow::Utf8::kMaxOneByteChar) { raw_data_pos_++; } else { c = unibrow::Utf8::CalculateValue(raw_data_ + raw_data_pos_, raw_data_length_ - raw_data_pos_, &raw_data_pos_); // Don't allow characters outside of the BMP. if (c > kMaxUC16Character) { c = unibrow::Utf8::kBadChar; } } buffer_[i++] = static_cast(c); } raw_character_position_ = char_position + i; return i; } static const byte kUtf8MultiByteMask = 0xC0; static const byte kUtf8MultiByteCharStart = 0xC0; static const byte kUtf8MultiByteCharFollower = 0x80; #ifdef DEBUG static bool IsUtf8MultiCharacterStart(byte first_byte) { return (first_byte & kUtf8MultiByteMask) == kUtf8MultiByteCharStart; } #endif static bool IsUtf8MultiCharacterFollower(byte later_byte) { return (later_byte & kUtf8MultiByteMask) == kUtf8MultiByteCharFollower; } // Move the cursor back to point at the preceding UTF-8 character start // in the buffer. static inline void Utf8CharacterBack(const byte* buffer, unsigned* cursor) { byte character = buffer[--*cursor]; if (character > unibrow::Utf8::kMaxOneByteChar) { ASSERT(IsUtf8MultiCharacterFollower(character)); // Last byte of a multi-byte character encoding. Step backwards until // pointing to the first byte of the encoding, recognized by having the // top two bits set. while (IsUtf8MultiCharacterFollower(buffer[--*cursor])) { } ASSERT(IsUtf8MultiCharacterStart(buffer[*cursor])); } } // Move the cursor forward to point at the next following UTF-8 character start // in the buffer. static inline void Utf8CharacterForward(const byte* buffer, unsigned* cursor) { byte character = buffer[(*cursor)++]; if (character > unibrow::Utf8::kMaxOneByteChar) { // First character of a multi-byte character encoding. // The number of most-significant one-bits determines the length of the // encoding: // 110..... - (0xCx, 0xDx) one additional byte (minimum). // 1110.... - (0xEx) two additional bytes. // 11110... - (0xFx) three additional bytes (maximum). ASSERT(IsUtf8MultiCharacterStart(character)); // Additional bytes is: // 1 if value in range 0xC0 .. 0xDF. // 2 if value in range 0xE0 .. 0xEF. // 3 if value in range 0xF0 .. 0xF7. // Encode that in a single value. unsigned additional_bytes = ((0x3211u) >> (((character - 0xC0) >> 2) & 0xC)) & 0x03; *cursor += additional_bytes; ASSERT(!IsUtf8MultiCharacterFollower(buffer[1 + additional_bytes])); } } void Utf8ToUC16CharacterStream::SetRawPosition(unsigned target_position) { if (raw_character_position_ > target_position) { // Spool backwards in utf8 buffer. do { Utf8CharacterBack(raw_data_, &raw_data_pos_); raw_character_position_--; } while (raw_character_position_ > target_position); return; } // Spool forwards in the utf8 buffer. while (raw_character_position_ < target_position) { if (raw_data_pos_ == raw_data_length_) return; Utf8CharacterForward(raw_data_, &raw_data_pos_); raw_character_position_++; } } // ---------------------------------------------------------------------------- // ExternalTwoByteStringUC16CharacterStream ExternalTwoByteStringUC16CharacterStream:: ~ExternalTwoByteStringUC16CharacterStream() { } ExternalTwoByteStringUC16CharacterStream ::ExternalTwoByteStringUC16CharacterStream( Handle data, int start_position, int end_position) : UC16CharacterStream(), source_(data), raw_data_(data->GetTwoByteData(start_position)) { buffer_cursor_ = raw_data_, buffer_end_ = raw_data_ + (end_position - start_position); pos_ = start_position; } // ---------------------------------------------------------------------------- // Scanner::LiteralScope Scanner::LiteralScope::LiteralScope(Scanner* self) : scanner_(self), complete_(false) { self->StartLiteral(); } Scanner::LiteralScope::~LiteralScope() { if (!complete_) scanner_->DropLiteral(); } void Scanner::LiteralScope::Complete() { scanner_->TerminateLiteral(); complete_ = true; } // ---------------------------------------------------------------------------- // V8JavaScriptScanner V8JavaScriptScanner::V8JavaScriptScanner() : JavaScriptScanner() { } void V8JavaScriptScanner::Initialize(UC16CharacterStream* source) { source_ = source; // Need to capture identifiers in order to recognize "get" and "set" // in object literals. Init(); // Skip initial whitespace allowing HTML comment ends just like // after a newline and scan first token. has_line_terminator_before_next_ = true; SkipWhiteSpace(); Scan(); } // ---------------------------------------------------------------------------- // JsonScanner JsonScanner::JsonScanner() : Scanner() { } void JsonScanner::Initialize(UC16CharacterStream* source) { source_ = source; Init(); // Skip initial whitespace. SkipJsonWhiteSpace(); // Preload first token as look-ahead. ScanJson(); } Token::Value JsonScanner::Next() { // BUG 1215673: Find a thread safe way to set a stack limit in // pre-parse mode. Otherwise, we cannot safely pre-parse from other // threads. current_ = next_; // Check for stack-overflow before returning any tokens. ScanJson(); return current_.token; } bool JsonScanner::SkipJsonWhiteSpace() { int start_position = source_pos(); // JSON WhiteSpace is tab, carrige-return, newline and space. while (c0_ == ' ' || c0_ == '\n' || c0_ == '\r' || c0_ == '\t') { Advance(); } return source_pos() != start_position; } void JsonScanner::ScanJson() { next_.literal_chars = NULL; Token::Value token; do { // Remember the position of the next token next_.location.beg_pos = source_pos(); switch (c0_) { case '\t': case '\r': case '\n': case ' ': Advance(); token = Token::WHITESPACE; break; case '{': Advance(); token = Token::LBRACE; break; case '}': Advance(); token = Token::RBRACE; break; case '[': Advance(); token = Token::LBRACK; break; case ']': Advance(); token = Token::RBRACK; break; case ':': Advance(); token = Token::COLON; break; case ',': Advance(); token = Token::COMMA; break; case '"': token = ScanJsonString(); break; case '-': case '0': case '1': case '2': case '3': case '4': case '5': case '6': case '7': case '8': case '9': token = ScanJsonNumber(); break; case 't': token = ScanJsonIdentifier("true", Token::TRUE_LITERAL); break; case 'f': token = ScanJsonIdentifier("false", Token::FALSE_LITERAL); break; case 'n': token = ScanJsonIdentifier("null", Token::NULL_LITERAL); break; default: if (c0_ < 0) { Advance(); token = Token::EOS; } else { Advance(); token = Select(Token::ILLEGAL); } } } while (token == Token::WHITESPACE); next_.location.end_pos = source_pos(); next_.token = token; } Token::Value JsonScanner::ScanJsonString() { ASSERT_EQ('"', c0_); Advance(); LiteralScope literal(this); while (c0_ != '"') { // Check for control character (0x00-0x1f) or unterminated string (<0). if (c0_ < 0x20) return Token::ILLEGAL; if (c0_ != '\\') { AddLiteralCharAdvance(); } else { Advance(); switch (c0_) { case '"': case '\\': case '/': AddLiteralChar(c0_); break; case 'b': AddLiteralChar('\x08'); break; case 'f': AddLiteralChar('\x0c'); break; case 'n': AddLiteralChar('\x0a'); break; case 'r': AddLiteralChar('\x0d'); break; case 't': AddLiteralChar('\x09'); break; case 'u': { uc32 value = 0; for (int i = 0; i < 4; i++) { Advance(); int digit = HexValue(c0_); if (digit < 0) { return Token::ILLEGAL; } value = value * 16 + digit; } AddLiteralChar(value); break; } default: return Token::ILLEGAL; } Advance(); } } literal.Complete(); Advance(); return Token::STRING; } Token::Value JsonScanner::ScanJsonNumber() { LiteralScope literal(this); if (c0_ == '-') AddLiteralCharAdvance(); if (c0_ == '0') { AddLiteralCharAdvance(); // Prefix zero is only allowed if it's the only digit before // a decimal point or exponent. if ('0' <= c0_ && c0_ <= '9') return Token::ILLEGAL; } else { if (c0_ < '1' || c0_ > '9') return Token::ILLEGAL; do { AddLiteralCharAdvance(); } while (c0_ >= '0' && c0_ <= '9'); } if (c0_ == '.') { AddLiteralCharAdvance(); if (c0_ < '0' || c0_ > '9') return Token::ILLEGAL; do { AddLiteralCharAdvance(); } while (c0_ >= '0' && c0_ <= '9'); } if (AsciiAlphaToLower(c0_) == 'e') { AddLiteralCharAdvance(); if (c0_ == '-' || c0_ == '+') AddLiteralCharAdvance(); if (c0_ < '0' || c0_ > '9') return Token::ILLEGAL; do { AddLiteralCharAdvance(); } while (c0_ >= '0' && c0_ <= '9'); } literal.Complete(); return Token::NUMBER; } Token::Value JsonScanner::ScanJsonIdentifier(const char* text, Token::Value token) { LiteralScope literal(this); while (*text != '\0') { if (c0_ != *text) return Token::ILLEGAL; Advance(); text++; } if (ScannerConstants::kIsIdentifierPart.get(c0_)) return Token::ILLEGAL; literal.Complete(); return token; } } } // namespace v8::internal