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1 // Copyright 2012 the V8 project authors. All rights reserved.
2 // Redistribution and use in source and binary forms, with or without
3 // modification, are permitted provided that the following conditions are
4 // met:
5 //
6 //     * Redistributions of source code must retain the above copyright
7 //       notice, this list of conditions and the following disclaimer.
8 //     * Redistributions in binary form must reproduce the above
9 //       copyright notice, this list of conditions and the following
10 //       disclaimer in the documentation and/or other materials provided
11 //       with the distribution.
12 //     * Neither the name of Google Inc. nor the names of its
13 //       contributors may be used to endorse or promote products derived
14 //       from this software without specific prior written permission.
15 //
16 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
17 // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
18 // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
19 // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
20 // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
21 // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
22 // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
23 // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
24 // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
25 // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
26 // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
27 
28 #ifndef V8_PARSER_H_
29 #define V8_PARSER_H_
30 
31 #include "allocation.h"
32 #include "ast.h"
33 #include "preparse-data-format.h"
34 #include "preparse-data.h"
35 #include "scopes.h"
36 #include "preparser.h"
37 
38 namespace v8 {
39 namespace internal {
40 
41 class CompilationInfo;
42 class FuncNameInferrer;
43 class ParserLog;
44 class PositionStack;
45 class Target;
46 
47 template <typename T> class ZoneListWrapper;
48 
49 
50 class ParserMessage : public Malloced {
51  public:
ParserMessage(Scanner::Location loc,const char * message,Vector<const char * > args)52   ParserMessage(Scanner::Location loc, const char* message,
53                 Vector<const char*> args)
54       : loc_(loc),
55         message_(message),
56         args_(args) { }
57   ~ParserMessage();
location()58   Scanner::Location location() { return loc_; }
message()59   const char* message() { return message_; }
args()60   Vector<const char*> args() { return args_; }
61  private:
62   Scanner::Location loc_;
63   const char* message_;
64   Vector<const char*> args_;
65 };
66 
67 
68 class FunctionEntry BASE_EMBEDDED {
69  public:
70   enum {
71     kStartPositionIndex,
72     kEndPositionIndex,
73     kLiteralCountIndex,
74     kPropertyCountIndex,
75     kLanguageModeIndex,
76     kSize
77   };
78 
FunctionEntry(Vector<unsigned> backing)79   explicit FunctionEntry(Vector<unsigned> backing)
80     : backing_(backing) { }
81 
FunctionEntry()82   FunctionEntry() : backing_() { }
83 
start_pos()84   int start_pos() { return backing_[kStartPositionIndex]; }
end_pos()85   int end_pos() { return backing_[kEndPositionIndex]; }
literal_count()86   int literal_count() { return backing_[kLiteralCountIndex]; }
property_count()87   int property_count() { return backing_[kPropertyCountIndex]; }
language_mode()88   LanguageMode language_mode() {
89     ASSERT(backing_[kLanguageModeIndex] == CLASSIC_MODE ||
90            backing_[kLanguageModeIndex] == STRICT_MODE ||
91            backing_[kLanguageModeIndex] == EXTENDED_MODE);
92     return static_cast<LanguageMode>(backing_[kLanguageModeIndex]);
93   }
94 
is_valid()95   bool is_valid() { return !backing_.is_empty(); }
96 
97  private:
98   Vector<unsigned> backing_;
99   bool owns_data_;
100 };
101 
102 
103 class ScriptDataImpl : public ScriptData {
104  public:
ScriptDataImpl(Vector<unsigned> store)105   explicit ScriptDataImpl(Vector<unsigned> store)
106       : store_(store),
107         owns_store_(true) { }
108 
109   // Create an empty ScriptDataImpl that is guaranteed to not satisfy
110   // a SanityCheck.
ScriptDataImpl()111   ScriptDataImpl() : owns_store_(false) { }
112 
113   virtual ~ScriptDataImpl();
114   virtual int Length();
115   virtual const char* Data();
116   virtual bool HasError();
117 
118   void Initialize();
119   void ReadNextSymbolPosition();
120 
121   FunctionEntry GetFunctionEntry(int start);
122   int GetSymbolIdentifier();
123   bool SanityCheck();
124 
125   Scanner::Location MessageLocation();
126   const char* BuildMessage();
127   Vector<const char*> BuildArgs();
128 
symbol_count()129   int symbol_count() {
130     return (store_.length() > PreparseDataConstants::kHeaderSize)
131         ? store_[PreparseDataConstants::kSymbolCountOffset]
132         : 0;
133   }
134   // The following functions should only be called if SanityCheck has
135   // returned true.
has_error()136   bool has_error() { return store_[PreparseDataConstants::kHasErrorOffset]; }
magic()137   unsigned magic() { return store_[PreparseDataConstants::kMagicOffset]; }
version()138   unsigned version() { return store_[PreparseDataConstants::kVersionOffset]; }
139 
140  private:
141   Vector<unsigned> store_;
142   unsigned char* symbol_data_;
143   unsigned char* symbol_data_end_;
144   int function_index_;
145   bool owns_store_;
146 
147   unsigned Read(int position);
148   unsigned* ReadAddress(int position);
149   // Reads a number from the current symbols
150   int ReadNumber(byte** source);
151 
ScriptDataImpl(const char * backing_store,int length)152   ScriptDataImpl(const char* backing_store, int length)
153       : store_(reinterpret_cast<unsigned*>(const_cast<char*>(backing_store)),
154                length / static_cast<int>(sizeof(unsigned))),
155         owns_store_(false) {
156     ASSERT_EQ(0, static_cast<int>(
157         reinterpret_cast<intptr_t>(backing_store) % sizeof(unsigned)));
158   }
159 
160   // Read strings written by ParserRecorder::WriteString.
161   static const char* ReadString(unsigned* start, int* chars);
162 
163   friend class ScriptData;
164 };
165 
166 
167 class ParserApi {
168  public:
169   // Parses the source code represented by the compilation info and sets its
170   // function literal.  Returns false (and deallocates any allocated AST
171   // nodes) if parsing failed.
172   static bool Parse(CompilationInfo* info, int flags);
173 
174   // Generic preparser generating full preparse data.
175   static ScriptDataImpl* PreParse(Utf16CharacterStream* source,
176                                   v8::Extension* extension,
177                                   int flags);
178 
179   // Preparser that only does preprocessing that makes sense if only used
180   // immediately after.
181   static ScriptDataImpl* PartialPreParse(Handle<String> source,
182                                          v8::Extension* extension,
183                                          int flags);
184 };
185 
186 // ----------------------------------------------------------------------------
187 // REGEXP PARSING
188 
189 // A BufferedZoneList is an automatically growing list, just like (and backed
190 // by) a ZoneList, that is optimized for the case of adding and removing
191 // a single element. The last element added is stored outside the backing list,
192 // and if no more than one element is ever added, the ZoneList isn't even
193 // allocated.
194 // Elements must not be NULL pointers.
195 template <typename T, int initial_size>
196 class BufferedZoneList {
197  public:
BufferedZoneList()198   BufferedZoneList() : list_(NULL), last_(NULL) {}
199 
200   // Adds element at end of list. This element is buffered and can
201   // be read using last() or removed using RemoveLast until a new Add or until
202   // RemoveLast or GetList has been called.
Add(T * value)203   void Add(T* value) {
204     if (last_ != NULL) {
205       if (list_ == NULL) {
206         list_ = new ZoneList<T*>(initial_size);
207       }
208       list_->Add(last_);
209     }
210     last_ = value;
211   }
212 
last()213   T* last() {
214     ASSERT(last_ != NULL);
215     return last_;
216   }
217 
RemoveLast()218   T* RemoveLast() {
219     ASSERT(last_ != NULL);
220     T* result = last_;
221     if ((list_ != NULL) && (list_->length() > 0))
222       last_ = list_->RemoveLast();
223     else
224       last_ = NULL;
225     return result;
226   }
227 
Get(int i)228   T* Get(int i) {
229     ASSERT((0 <= i) && (i < length()));
230     if (list_ == NULL) {
231       ASSERT_EQ(0, i);
232       return last_;
233     } else {
234       if (i == list_->length()) {
235         ASSERT(last_ != NULL);
236         return last_;
237       } else {
238         return list_->at(i);
239       }
240     }
241   }
242 
Clear()243   void Clear() {
244     list_ = NULL;
245     last_ = NULL;
246   }
247 
length()248   int length() {
249     int length = (list_ == NULL) ? 0 : list_->length();
250     return length + ((last_ == NULL) ? 0 : 1);
251   }
252 
GetList()253   ZoneList<T*>* GetList() {
254     if (list_ == NULL) {
255       list_ = new ZoneList<T*>(initial_size);
256     }
257     if (last_ != NULL) {
258       list_->Add(last_);
259       last_ = NULL;
260     }
261     return list_;
262   }
263 
264  private:
265   ZoneList<T*>* list_;
266   T* last_;
267 };
268 
269 
270 // Accumulates RegExp atoms and assertions into lists of terms and alternatives.
271 class RegExpBuilder: public ZoneObject {
272  public:
273   RegExpBuilder();
274   void AddCharacter(uc16 character);
275   // "Adds" an empty expression. Does nothing except consume a
276   // following quantifier
277   void AddEmpty();
278   void AddAtom(RegExpTree* tree);
279   void AddAssertion(RegExpTree* tree);
280   void NewAlternative();  // '|'
281   void AddQuantifierToAtom(int min, int max, RegExpQuantifier::Type type);
282   RegExpTree* ToRegExp();
283 
284  private:
285   void FlushCharacters();
286   void FlushText();
287   void FlushTerms();
zone()288   Zone* zone() { return zone_; }
289 
290   Zone* zone_;
291   bool pending_empty_;
292   ZoneList<uc16>* characters_;
293   BufferedZoneList<RegExpTree, 2> terms_;
294   BufferedZoneList<RegExpTree, 2> text_;
295   BufferedZoneList<RegExpTree, 2> alternatives_;
296 #ifdef DEBUG
297   enum {ADD_NONE, ADD_CHAR, ADD_TERM, ADD_ASSERT, ADD_ATOM} last_added_;
298 #define LAST(x) last_added_ = x;
299 #else
300 #define LAST(x)
301 #endif
302 };
303 
304 
305 class RegExpParser {
306  public:
307   RegExpParser(FlatStringReader* in,
308                Handle<String>* error,
309                bool multiline_mode);
310 
311   static bool ParseRegExp(FlatStringReader* input,
312                           bool multiline,
313                           RegExpCompileData* result);
314 
315   RegExpTree* ParsePattern();
316   RegExpTree* ParseDisjunction();
317   RegExpTree* ParseGroup();
318   RegExpTree* ParseCharacterClass();
319 
320   // Parses a {...,...} quantifier and stores the range in the given
321   // out parameters.
322   bool ParseIntervalQuantifier(int* min_out, int* max_out);
323 
324   // Parses and returns a single escaped character.  The character
325   // must not be 'b' or 'B' since they are usually handle specially.
326   uc32 ParseClassCharacterEscape();
327 
328   // Checks whether the following is a length-digit hexadecimal number,
329   // and sets the value if it is.
330   bool ParseHexEscape(int length, uc32* value);
331 
332   uc32 ParseOctalLiteral();
333 
334   // Tries to parse the input as a back reference.  If successful it
335   // stores the result in the output parameter and returns true.  If
336   // it fails it will push back the characters read so the same characters
337   // can be reparsed.
338   bool ParseBackReferenceIndex(int* index_out);
339 
340   CharacterRange ParseClassAtom(uc16* char_class);
341   RegExpTree* ReportError(Vector<const char> message);
342   void Advance();
343   void Advance(int dist);
344   void Reset(int pos);
345 
346   // Reports whether the pattern might be used as a literal search string.
347   // Only use if the result of the parse is a single atom node.
348   bool simple();
contains_anchor()349   bool contains_anchor() { return contains_anchor_; }
set_contains_anchor()350   void set_contains_anchor() { contains_anchor_ = true; }
captures_started()351   int captures_started() { return captures_ == NULL ? 0 : captures_->length(); }
position()352   int position() { return next_pos_ - 1; }
failed()353   bool failed() { return failed_; }
354 
355   static const int kMaxCaptures = 1 << 16;
356   static const uc32 kEndMarker = (1 << 21);
357 
358  private:
359   enum SubexpressionType {
360     INITIAL,
361     CAPTURE,  // All positive values represent captures.
362     POSITIVE_LOOKAHEAD,
363     NEGATIVE_LOOKAHEAD,
364     GROUPING
365   };
366 
367   class RegExpParserState : public ZoneObject {
368    public:
RegExpParserState(RegExpParserState * previous_state,SubexpressionType group_type,int disjunction_capture_index)369     RegExpParserState(RegExpParserState* previous_state,
370                       SubexpressionType group_type,
371                       int disjunction_capture_index)
372         : previous_state_(previous_state),
373           builder_(new RegExpBuilder()),
374           group_type_(group_type),
375           disjunction_capture_index_(disjunction_capture_index) {}
376     // Parser state of containing expression, if any.
previous_state()377     RegExpParserState* previous_state() { return previous_state_; }
IsSubexpression()378     bool IsSubexpression() { return previous_state_ != NULL; }
379     // RegExpBuilder building this regexp's AST.
builder()380     RegExpBuilder* builder() { return builder_; }
381     // Type of regexp being parsed (parenthesized group or entire regexp).
group_type()382     SubexpressionType group_type() { return group_type_; }
383     // Index in captures array of first capture in this sub-expression, if any.
384     // Also the capture index of this sub-expression itself, if group_type
385     // is CAPTURE.
capture_index()386     int capture_index() { return disjunction_capture_index_; }
387 
388    private:
389     // Linked list implementation of stack of states.
390     RegExpParserState* previous_state_;
391     // Builder for the stored disjunction.
392     RegExpBuilder* builder_;
393     // Stored disjunction type (capture, look-ahead or grouping), if any.
394     SubexpressionType group_type_;
395     // Stored disjunction's capture index (if any).
396     int disjunction_capture_index_;
397   };
398 
isolate()399   Isolate* isolate() { return isolate_; }
zone()400   Zone* zone() { return isolate_->zone(); }
401 
current()402   uc32 current() { return current_; }
has_more()403   bool has_more() { return has_more_; }
has_next()404   bool has_next() { return next_pos_ < in()->length(); }
405   uc32 Next();
in()406   FlatStringReader* in() { return in_; }
407   void ScanForCaptures();
408 
409   Isolate* isolate_;
410   Handle<String>* error_;
411   ZoneList<RegExpCapture*>* captures_;
412   FlatStringReader* in_;
413   uc32 current_;
414   int next_pos_;
415   // The capture count is only valid after we have scanned for captures.
416   int capture_count_;
417   bool has_more_;
418   bool multiline_;
419   bool simple_;
420   bool contains_anchor_;
421   bool is_scanned_for_captures_;
422   bool failed_;
423 };
424 
425 // ----------------------------------------------------------------------------
426 // JAVASCRIPT PARSING
427 
428 // Forward declaration.
429 class SingletonLogger;
430 
431 class Parser {
432  public:
433   Parser(Handle<Script> script,
434          int parsing_flags,  // Combination of ParsingFlags
435          v8::Extension* extension,
436          ScriptDataImpl* pre_data);
~Parser()437   virtual ~Parser() {
438     delete reusable_preparser_;
439     reusable_preparser_ = NULL;
440   }
441 
442   // Returns NULL if parsing failed.
443   FunctionLiteral* ParseProgram(CompilationInfo* info);
444   FunctionLiteral* ParseLazy(CompilationInfo* info);
445 
446   void ReportMessageAt(Scanner::Location loc,
447                        const char* message,
448                        Vector<const char*> args);
449   void ReportMessageAt(Scanner::Location loc,
450                        const char* message,
451                        Vector<Handle<String> > args);
452 
453  private:
454   // Limit on number of function parameters is chosen arbitrarily.
455   // Code::Flags uses only the low 17 bits of num-parameters to
456   // construct a hashable id, so if more than 2^17 are allowed, this
457   // should be checked.
458   static const int kMaxNumFunctionParameters = 32766;
459   static const int kMaxNumFunctionLocals = 32767;
460 
461   enum Mode {
462     PARSE_LAZILY,
463     PARSE_EAGERLY
464   };
465 
466   enum VariableDeclarationContext {
467     kModuleElement,
468     kBlockElement,
469     kStatement,
470     kForStatement
471   };
472 
473   // If a list of variable declarations includes any initializers.
474   enum VariableDeclarationProperties {
475     kHasInitializers,
476     kHasNoInitializers
477   };
478 
479   class BlockState;
480 
481   class FunctionState BASE_EMBEDDED {
482    public:
483     FunctionState(Parser* parser,
484                   Scope* scope,
485                   Isolate* isolate);
486     ~FunctionState();
487 
NextMaterializedLiteralIndex()488     int NextMaterializedLiteralIndex() {
489       return next_materialized_literal_index_++;
490     }
materialized_literal_count()491     int materialized_literal_count() {
492       return next_materialized_literal_index_ - JSFunction::kLiteralsPrefixSize;
493     }
494 
NextHandlerIndex()495     int NextHandlerIndex() { return next_handler_index_++; }
handler_count()496     int handler_count() { return next_handler_index_; }
497 
SetThisPropertyAssignmentInfo(bool only_simple_this_property_assignments,Handle<FixedArray> this_property_assignments)498     void SetThisPropertyAssignmentInfo(
499         bool only_simple_this_property_assignments,
500         Handle<FixedArray> this_property_assignments) {
501       only_simple_this_property_assignments_ =
502           only_simple_this_property_assignments;
503       this_property_assignments_ = this_property_assignments;
504     }
only_simple_this_property_assignments()505     bool only_simple_this_property_assignments() {
506       return only_simple_this_property_assignments_;
507     }
this_property_assignments()508     Handle<FixedArray> this_property_assignments() {
509       return this_property_assignments_;
510     }
511 
AddProperty()512     void AddProperty() { expected_property_count_++; }
expected_property_count()513     int expected_property_count() { return expected_property_count_; }
514 
factory()515     AstNodeFactory<AstConstructionVisitor>* factory() { return &factory_; }
516 
517    private:
518     // Used to assign an index to each literal that needs materialization in
519     // the function.  Includes regexp literals, and boilerplate for object and
520     // array literals.
521     int next_materialized_literal_index_;
522 
523     // Used to assign a per-function index to try and catch handlers.
524     int next_handler_index_;
525 
526     // Properties count estimation.
527     int expected_property_count_;
528 
529     // Keeps track of assignments to properties of this. Used for
530     // optimizing constructors.
531     bool only_simple_this_property_assignments_;
532     Handle<FixedArray> this_property_assignments_;
533 
534     Parser* parser_;
535     FunctionState* outer_function_state_;
536     Scope* outer_scope_;
537     int saved_ast_node_id_;
538     AstNodeFactory<AstConstructionVisitor> factory_;
539   };
540 
541 
542 
543 
544   FunctionLiteral* ParseLazy(CompilationInfo* info,
545                              Utf16CharacterStream* source,
546                              ZoneScope* zone_scope);
547 
isolate()548   Isolate* isolate() { return isolate_; }
zone()549   Zone* zone() { return isolate_->zone(); }
550 
551   // Called by ParseProgram after setting up the scanner.
552   FunctionLiteral* DoParseProgram(CompilationInfo* info,
553                                   Handle<String> source,
554                                   ZoneScope* zone_scope);
555 
556   // Report syntax error
557   void ReportUnexpectedToken(Token::Value token);
558   void ReportInvalidPreparseData(Handle<String> name, bool* ok);
559   void ReportMessage(const char* message, Vector<const char*> args);
560   void ReportMessage(const char* message, Vector<Handle<String> > args);
561 
inside_with()562   bool inside_with() const { return top_scope_->inside_with(); }
scanner()563   Scanner& scanner()  { return scanner_; }
mode()564   Mode mode() const { return mode_; }
pre_data()565   ScriptDataImpl* pre_data() const { return pre_data_; }
is_extended_mode()566   bool is_extended_mode() {
567     ASSERT(top_scope_ != NULL);
568     return top_scope_->is_extended_mode();
569   }
DeclarationScope(VariableMode mode)570   Scope* DeclarationScope(VariableMode mode) {
571     return (mode == LET || mode == CONST_HARMONY)
572         ? top_scope_ : top_scope_->DeclarationScope();
573   }
574 
575   // Check if the given string is 'eval' or 'arguments'.
576   bool IsEvalOrArguments(Handle<String> string);
577 
578   // All ParseXXX functions take as the last argument an *ok parameter
579   // which is set to false if parsing failed; it is unchanged otherwise.
580   // By making the 'exception handling' explicit, we are forced to check
581   // for failure at the call sites.
582   void* ParseSourceElements(ZoneList<Statement*>* processor,
583                             int end_token, bool is_eval, bool* ok);
584   Statement* ParseModuleElement(ZoneStringList* labels, bool* ok);
585   Block* ParseModuleDeclaration(ZoneStringList* names, bool* ok);
586   Module* ParseModule(bool* ok);
587   Module* ParseModuleLiteral(bool* ok);
588   Module* ParseModulePath(bool* ok);
589   Module* ParseModuleVariable(bool* ok);
590   Module* ParseModuleUrl(bool* ok);
591   Module* ParseModuleSpecifier(bool* ok);
592   Block* ParseImportDeclaration(bool* ok);
593   Statement* ParseExportDeclaration(bool* ok);
594   Statement* ParseBlockElement(ZoneStringList* labels, bool* ok);
595   Statement* ParseStatement(ZoneStringList* labels, bool* ok);
596   Statement* ParseFunctionDeclaration(ZoneStringList* names, bool* ok);
597   Statement* ParseNativeDeclaration(bool* ok);
598   Block* ParseBlock(ZoneStringList* labels, bool* ok);
599   Block* ParseVariableStatement(VariableDeclarationContext var_context,
600                                 ZoneStringList* names,
601                                 bool* ok);
602   Block* ParseVariableDeclarations(VariableDeclarationContext var_context,
603                                    VariableDeclarationProperties* decl_props,
604                                    ZoneStringList* names,
605                                    Handle<String>* out,
606                                    bool* ok);
607   Statement* ParseExpressionOrLabelledStatement(ZoneStringList* labels,
608                                                 bool* ok);
609   IfStatement* ParseIfStatement(ZoneStringList* labels, bool* ok);
610   Statement* ParseContinueStatement(bool* ok);
611   Statement* ParseBreakStatement(ZoneStringList* labels, bool* ok);
612   Statement* ParseReturnStatement(bool* ok);
613   Statement* ParseWithStatement(ZoneStringList* labels, bool* ok);
614   CaseClause* ParseCaseClause(bool* default_seen_ptr, bool* ok);
615   SwitchStatement* ParseSwitchStatement(ZoneStringList* labels, bool* ok);
616   DoWhileStatement* ParseDoWhileStatement(ZoneStringList* labels, bool* ok);
617   WhileStatement* ParseWhileStatement(ZoneStringList* labels, bool* ok);
618   Statement* ParseForStatement(ZoneStringList* labels, bool* ok);
619   Statement* ParseThrowStatement(bool* ok);
620   Expression* MakeCatchContext(Handle<String> id, VariableProxy* value);
621   TryStatement* ParseTryStatement(bool* ok);
622   DebuggerStatement* ParseDebuggerStatement(bool* ok);
623 
624   // Support for hamony block scoped bindings.
625   Block* ParseScopedBlock(ZoneStringList* labels, bool* ok);
626 
627   Expression* ParseExpression(bool accept_IN, bool* ok);
628   Expression* ParseAssignmentExpression(bool accept_IN, bool* ok);
629   Expression* ParseConditionalExpression(bool accept_IN, bool* ok);
630   Expression* ParseBinaryExpression(int prec, bool accept_IN, bool* ok);
631   Expression* ParseUnaryExpression(bool* ok);
632   Expression* ParsePostfixExpression(bool* ok);
633   Expression* ParseLeftHandSideExpression(bool* ok);
634   Expression* ParseNewExpression(bool* ok);
635   Expression* ParseMemberExpression(bool* ok);
636   Expression* ParseNewPrefix(PositionStack* stack, bool* ok);
637   Expression* ParseMemberWithNewPrefixesExpression(PositionStack* stack,
638                                                    bool* ok);
639   Expression* ParsePrimaryExpression(bool* ok);
640   Expression* ParseArrayLiteral(bool* ok);
641   Expression* ParseObjectLiteral(bool* ok);
642   ObjectLiteral::Property* ParseObjectLiteralGetSet(bool is_getter, bool* ok);
643   Expression* ParseRegExpLiteral(bool seen_equal, bool* ok);
644 
645   // Populate the constant properties fixed array for a materialized object
646   // literal.
647   void BuildObjectLiteralConstantProperties(
648       ZoneList<ObjectLiteral::Property*>* properties,
649       Handle<FixedArray> constants,
650       bool* is_simple,
651       bool* fast_elements,
652       int* depth);
653 
654   // Populate the literals fixed array for a materialized array literal.
655   void BuildArrayLiteralBoilerplateLiterals(ZoneList<Expression*>* properties,
656                                             Handle<FixedArray> constants,
657                                             bool* is_simple,
658                                             int* depth);
659 
660   // Decide if a property should be in the object boilerplate.
661   bool IsBoilerplateProperty(ObjectLiteral::Property* property);
662   // If the expression is a literal, return the literal value;
663   // if the expression is a materialized literal and is simple return a
664   // compile time value as encoded by CompileTimeValue::GetValue().
665   // Otherwise, return undefined literal as the placeholder
666   // in the object literal boilerplate.
667   Handle<Object> GetBoilerplateValue(Expression* expression);
668 
669   ZoneList<Expression*>* ParseArguments(bool* ok);
670   FunctionLiteral* ParseFunctionLiteral(Handle<String> var_name,
671                                         bool name_is_reserved,
672                                         int function_token_position,
673                                         FunctionLiteral::Type type,
674                                         bool* ok);
675 
676 
677   // Magical syntax support.
678   Expression* ParseV8Intrinsic(bool* ok);
679 
INLINE(Token::Value peek ())680   INLINE(Token::Value peek()) {
681     if (stack_overflow_) return Token::ILLEGAL;
682     return scanner().peek();
683   }
684 
INLINE(Token::Value Next ())685   INLINE(Token::Value Next()) {
686     // BUG 1215673: Find a thread safe way to set a stack limit in
687     // pre-parse mode. Otherwise, we cannot safely pre-parse from other
688     // threads.
689     if (stack_overflow_) {
690       return Token::ILLEGAL;
691     }
692     if (StackLimitCheck(isolate()).HasOverflowed()) {
693       // Any further calls to Next or peek will return the illegal token.
694       // The current call must return the next token, which might already
695       // have been peek'ed.
696       stack_overflow_ = true;
697     }
698     return scanner().Next();
699   }
700 
701   bool peek_any_identifier();
702 
703   INLINE(void Consume(Token::Value token));
704   void Expect(Token::Value token, bool* ok);
705   bool Check(Token::Value token);
706   void ExpectSemicolon(bool* ok);
707   void ExpectContextualKeyword(const char* keyword, bool* ok);
708 
LiteralString(PretenureFlag tenured)709   Handle<String> LiteralString(PretenureFlag tenured) {
710     if (scanner().is_literal_ascii()) {
711       return isolate_->factory()->NewStringFromAscii(
712           scanner().literal_ascii_string(), tenured);
713     } else {
714       return isolate_->factory()->NewStringFromTwoByte(
715             scanner().literal_utf16_string(), tenured);
716     }
717   }
718 
NextLiteralString(PretenureFlag tenured)719   Handle<String> NextLiteralString(PretenureFlag tenured) {
720     if (scanner().is_next_literal_ascii()) {
721       return isolate_->factory()->NewStringFromAscii(
722           scanner().next_literal_ascii_string(), tenured);
723     } else {
724       return isolate_->factory()->NewStringFromTwoByte(
725           scanner().next_literal_utf16_string(), tenured);
726     }
727   }
728 
729   Handle<String> GetSymbol(bool* ok);
730 
731   // Get odd-ball literals.
732   Literal* GetLiteralUndefined();
733   Literal* GetLiteralTheHole();
734 
735   Handle<String> ParseIdentifier(bool* ok);
736   Handle<String> ParseIdentifierOrStrictReservedWord(
737       bool* is_strict_reserved, bool* ok);
738   Handle<String> ParseIdentifierName(bool* ok);
739   Handle<String> ParseIdentifierNameOrGetOrSet(bool* is_get,
740                                                bool* is_set,
741                                                bool* ok);
742 
743   // Determine if the expression is a variable proxy and mark it as being used
744   // in an assignment or with a increment/decrement operator. This is currently
745   // used on for the statically checking assignments to harmony const bindings.
746   void MarkAsLValue(Expression* expression);
747 
748   // Strict mode validation of LValue expressions
749   void CheckStrictModeLValue(Expression* expression,
750                              const char* error,
751                              bool* ok);
752 
753   // Strict mode octal literal validation.
754   void CheckOctalLiteral(int beg_pos, int end_pos, bool* ok);
755 
756   // For harmony block scoping mode: Check if the scope has conflicting var/let
757   // declarations from different scopes. It covers for example
758   //
759   // function f() { { { var x; } let x; } }
760   // function g() { { var x; let x; } }
761   //
762   // The var declarations are hoisted to the function scope, but originate from
763   // a scope where the name has also been let bound or the var declaration is
764   // hoisted over such a scope.
765   void CheckConflictingVarDeclarations(Scope* scope, bool* ok);
766 
767   // Parser support
768   VariableProxy* NewUnresolved(Handle<String> name,
769                                VariableMode mode,
770                                Interface* interface = Interface::NewValue());
771   void Declare(Declaration* declaration, bool resolve, bool* ok);
772 
773   bool TargetStackContainsLabel(Handle<String> label);
774   BreakableStatement* LookupBreakTarget(Handle<String> label, bool* ok);
775   IterationStatement* LookupContinueTarget(Handle<String> label, bool* ok);
776 
777   void RegisterTargetUse(Label* target, Target* stop);
778 
779   // Factory methods.
780 
781   Scope* NewScope(Scope* parent, ScopeType type);
782 
783   Handle<String> LookupSymbol(int symbol_id);
784 
785   Handle<String> LookupCachedSymbol(int symbol_id);
786 
787   // Generate AST node that throw a ReferenceError with the given type.
788   Expression* NewThrowReferenceError(Handle<String> type);
789 
790   // Generate AST node that throw a SyntaxError with the given
791   // type. The first argument may be null (in the handle sense) in
792   // which case no arguments are passed to the constructor.
793   Expression* NewThrowSyntaxError(Handle<String> type, Handle<Object> first);
794 
795   // Generate AST node that throw a TypeError with the given
796   // type. Both arguments must be non-null (in the handle sense).
797   Expression* NewThrowTypeError(Handle<String> type,
798                                 Handle<Object> first,
799                                 Handle<Object> second);
800 
801   // Generic AST generator for throwing errors from compiled code.
802   Expression* NewThrowError(Handle<String> constructor,
803                             Handle<String> type,
804                             Vector< Handle<Object> > arguments);
805 
806   preparser::PreParser::PreParseResult LazyParseFunctionLiteral(
807        SingletonLogger* logger);
808 
factory()809   AstNodeFactory<AstConstructionVisitor>* factory() {
810     return current_function_state_->factory();
811   }
812 
813   Isolate* isolate_;
814   ZoneList<Handle<String> > symbol_cache_;
815 
816   Handle<Script> script_;
817   Scanner scanner_;
818   preparser::PreParser* reusable_preparser_;
819   Scope* top_scope_;
820   FunctionState* current_function_state_;
821   Target* target_stack_;  // for break, continue statements
822   v8::Extension* extension_;
823   ScriptDataImpl* pre_data_;
824   FuncNameInferrer* fni_;
825 
826   Mode mode_;
827   bool allow_natives_syntax_;
828   bool allow_lazy_;
829   bool allow_modules_;
830   bool stack_overflow_;
831   // If true, the next (and immediately following) function literal is
832   // preceded by a parenthesis.
833   // Heuristically that means that the function will be called immediately,
834   // so never lazily compile it.
835   bool parenthesized_function_;
836 
837   friend class BlockState;
838   friend class FunctionState;
839 };
840 
841 
842 // Support for handling complex values (array and object literals) that
843 // can be fully handled at compile time.
844 class CompileTimeValue: public AllStatic {
845  public:
846   enum Type {
847     OBJECT_LITERAL_FAST_ELEMENTS,
848     OBJECT_LITERAL_SLOW_ELEMENTS,
849     ARRAY_LITERAL
850   };
851 
852   static bool IsCompileTimeValue(Expression* expression);
853 
854   static bool ArrayLiteralElementNeedsInitialization(Expression* value);
855 
856   // Get the value as a compile time value.
857   static Handle<FixedArray> GetValue(Expression* expression);
858 
859   // Get the type of a compile time value returned by GetValue().
860   static Type GetType(Handle<FixedArray> value);
861 
862   // Get the elements array of a compile time value returned by GetValue().
863   static Handle<FixedArray> GetElements(Handle<FixedArray> value);
864 
865  private:
866   static const int kTypeSlot = 0;
867   static const int kElementsSlot = 1;
868 
869   DISALLOW_IMPLICIT_CONSTRUCTORS(CompileTimeValue);
870 };
871 
872 } }  // namespace v8::internal
873 
874 #endif  // V8_PARSER_H_
875