// Copyright 2016 the V8 project authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #ifndef V8_REGEXP_REGEXP_PARSER_H_ #define V8_REGEXP_REGEXP_PARSER_H_ #include "src/objects.h" #include "src/regexp/regexp-ast.h" #include "src/zone.h" namespace v8 { namespace internal { struct RegExpCompileData; // A BufferedZoneList is an automatically growing list, just like (and backed // by) a ZoneList, that is optimized for the case of adding and removing // a single element. The last element added is stored outside the backing list, // and if no more than one element is ever added, the ZoneList isn't even // allocated. // Elements must not be NULL pointers. template class BufferedZoneList { public: BufferedZoneList() : list_(NULL), last_(NULL) {} // Adds element at end of list. This element is buffered and can // be read using last() or removed using RemoveLast until a new Add or until // RemoveLast or GetList has been called. void Add(T* value, Zone* zone) { if (last_ != NULL) { if (list_ == NULL) { list_ = new (zone) ZoneList(initial_size, zone); } list_->Add(last_, zone); } last_ = value; } T* last() { DCHECK(last_ != NULL); return last_; } T* RemoveLast() { DCHECK(last_ != NULL); T* result = last_; if ((list_ != NULL) && (list_->length() > 0)) last_ = list_->RemoveLast(); else last_ = NULL; return result; } T* Get(int i) { DCHECK((0 <= i) && (i < length())); if (list_ == NULL) { DCHECK_EQ(0, i); return last_; } else { if (i == list_->length()) { DCHECK(last_ != NULL); return last_; } else { return list_->at(i); } } } void Clear() { list_ = NULL; last_ = NULL; } int length() { int length = (list_ == NULL) ? 0 : list_->length(); return length + ((last_ == NULL) ? 0 : 1); } ZoneList* GetList(Zone* zone) { if (list_ == NULL) { list_ = new (zone) ZoneList(initial_size, zone); } if (last_ != NULL) { list_->Add(last_, zone); last_ = NULL; } return list_; } private: ZoneList* list_; T* last_; }; // Accumulates RegExp atoms and assertions into lists of terms and alternatives. class RegExpBuilder : public ZoneObject { public: explicit RegExpBuilder(Zone* zone); void AddCharacter(uc16 character); void AddUnicodeCharacter(uc32 character); // "Adds" an empty expression. Does nothing except consume a // following quantifier void AddEmpty(); void AddAtom(RegExpTree* tree); void AddAssertion(RegExpTree* tree); void NewAlternative(); // '|' void AddQuantifierToAtom(int min, int max, RegExpQuantifier::QuantifierType type); RegExpTree* ToRegExp(); private: void FlushCharacters(); void FlushText(); void FlushTerms(); Zone* zone() const { return zone_; } Zone* zone_; bool pending_empty_; ZoneList* characters_; BufferedZoneList terms_; BufferedZoneList text_; BufferedZoneList alternatives_; #ifdef DEBUG enum { ADD_NONE, ADD_CHAR, ADD_TERM, ADD_ASSERT, ADD_ATOM } last_added_; #define LAST(x) last_added_ = x; #else #define LAST(x) #endif }; class RegExpParser BASE_EMBEDDED { public: RegExpParser(FlatStringReader* in, Handle* error, bool multiline_mode, bool unicode, Isolate* isolate, Zone* zone); static bool ParseRegExp(Isolate* isolate, Zone* zone, FlatStringReader* input, bool multiline, bool unicode, RegExpCompileData* result); RegExpTree* ParsePattern(); RegExpTree* ParseDisjunction(); RegExpTree* ParseGroup(); RegExpTree* ParseCharacterClass(); // Parses a {...,...} quantifier and stores the range in the given // out parameters. bool ParseIntervalQuantifier(int* min_out, int* max_out); // Parses and returns a single escaped character. The character // must not be 'b' or 'B' since they are usually handle specially. uc32 ParseClassCharacterEscape(); // Checks whether the following is a length-digit hexadecimal number, // and sets the value if it is. bool ParseHexEscape(int length, uc32* value); bool ParseUnicodeEscape(uc32* value); bool ParseUnlimitedLengthHexNumber(int max_value, uc32* value); uc32 ParseOctalLiteral(); // Tries to parse the input as a back reference. If successful it // stores the result in the output parameter and returns true. If // it fails it will push back the characters read so the same characters // can be reparsed. bool ParseBackReferenceIndex(int* index_out); CharacterRange ParseClassAtom(uc16* char_class); RegExpTree* ReportError(Vector message); void Advance(); void Advance(int dist); void Reset(int pos); // Reports whether the pattern might be used as a literal search string. // Only use if the result of the parse is a single atom node. bool simple(); bool contains_anchor() { return contains_anchor_; } void set_contains_anchor() { contains_anchor_ = true; } int captures_started() { return captures_started_; } int position() { return next_pos_ - 1; } bool failed() { return failed_; } static bool IsSyntaxCharacter(uc32 c); static const int kMaxCaptures = 1 << 16; static const uc32 kEndMarker = (1 << 21); private: enum SubexpressionType { INITIAL, CAPTURE, // All positive values represent captures. POSITIVE_LOOKAROUND, NEGATIVE_LOOKAROUND, GROUPING }; class RegExpParserState : public ZoneObject { public: RegExpParserState(RegExpParserState* previous_state, SubexpressionType group_type, RegExpLookaround::Type lookaround_type, int disjunction_capture_index, Zone* zone) : previous_state_(previous_state), builder_(new (zone) RegExpBuilder(zone)), group_type_(group_type), lookaround_type_(lookaround_type), disjunction_capture_index_(disjunction_capture_index) {} // Parser state of containing expression, if any. RegExpParserState* previous_state() { return previous_state_; } bool IsSubexpression() { return previous_state_ != NULL; } // RegExpBuilder building this regexp's AST. RegExpBuilder* builder() { return builder_; } // Type of regexp being parsed (parenthesized group or entire regexp). SubexpressionType group_type() { return group_type_; } // Lookahead or Lookbehind. RegExpLookaround::Type lookaround_type() { return lookaround_type_; } // Index in captures array of first capture in this sub-expression, if any. // Also the capture index of this sub-expression itself, if group_type // is CAPTURE. int capture_index() { return disjunction_capture_index_; } // Check whether the parser is inside a capture group with the given index. bool IsInsideCaptureGroup(int index); private: // Linked list implementation of stack of states. RegExpParserState* previous_state_; // Builder for the stored disjunction. RegExpBuilder* builder_; // Stored disjunction type (capture, look-ahead or grouping), if any. SubexpressionType group_type_; // Stored read direction. RegExpLookaround::Type lookaround_type_; // Stored disjunction's capture index (if any). int disjunction_capture_index_; }; // Return the 1-indexed RegExpCapture object, allocate if necessary. RegExpCapture* GetCapture(int index); Isolate* isolate() { return isolate_; } Zone* zone() const { return zone_; } uc32 current() { return current_; } bool has_more() { return has_more_; } bool has_next() { return next_pos_ < in()->length(); } uc32 Next(); FlatStringReader* in() { return in_; } void ScanForCaptures(); Isolate* isolate_; Zone* zone_; Handle* error_; ZoneList* captures_; FlatStringReader* in_; uc32 current_; int next_pos_; int captures_started_; // The capture count is only valid after we have scanned for captures. int capture_count_; bool has_more_; bool multiline_; bool unicode_; bool simple_; bool contains_anchor_; bool is_scanned_for_captures_; bool failed_; }; } // namespace internal } // namespace v8 #endif // V8_REGEXP_REGEXP_PARSER_H_