// 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_AST_H_ #define V8_REGEXP_REGEXP_AST_H_ #include "src/objects.h" #include "src/utils.h" #include "src/zone/zone-containers.h" #include "src/zone/zone.h" namespace v8 { namespace internal { #define FOR_EACH_REG_EXP_TREE_TYPE(VISIT) \ VISIT(Disjunction) \ VISIT(Alternative) \ VISIT(Assertion) \ VISIT(CharacterClass) \ VISIT(Atom) \ VISIT(Quantifier) \ VISIT(Capture) \ VISIT(Group) \ VISIT(Lookaround) \ VISIT(BackReference) \ VISIT(Empty) \ VISIT(Text) #define FORWARD_DECLARE(Name) class RegExp##Name; FOR_EACH_REG_EXP_TREE_TYPE(FORWARD_DECLARE) #undef FORWARD_DECLARE class RegExpCompiler; class RegExpNode; class RegExpTree; class RegExpVisitor BASE_EMBEDDED { public: virtual ~RegExpVisitor() {} #define MAKE_CASE(Name) \ virtual void* Visit##Name(RegExp##Name*, void* data) = 0; FOR_EACH_REG_EXP_TREE_TYPE(MAKE_CASE) #undef MAKE_CASE }; // A simple closed interval. class Interval { public: Interval() : from_(kNone), to_(kNone) {} Interval(int from, int to) : from_(from), to_(to) {} Interval Union(Interval that) { if (that.from_ == kNone) return *this; else if (from_ == kNone) return that; else return Interval(Min(from_, that.from_), Max(to_, that.to_)); } bool Contains(int value) { return (from_ <= value) && (value <= to_); } bool is_empty() { return from_ == kNone; } int from() const { return from_; } int to() const { return to_; } static Interval Empty() { return Interval(); } static const int kNone = -1; private: int from_; int to_; }; // Represents code units in the range from from_ to to_, both ends are // inclusive. class CharacterRange { public: CharacterRange() : from_(0), to_(0) {} // For compatibility with the CHECK_OK macro CharacterRange(void* null) { DCHECK_NULL(null); } // NOLINT static void AddClassEscape(uc16 type, ZoneList<CharacterRange>* ranges, Zone* zone); static Vector<const int> GetWordBounds(); static inline CharacterRange Singleton(uc32 value) { return CharacterRange(value, value); } static inline CharacterRange Range(uc32 from, uc32 to) { DCHECK(0 <= from && to <= String::kMaxCodePoint); DCHECK(static_cast<uint32_t>(from) <= static_cast<uint32_t>(to)); return CharacterRange(from, to); } static inline CharacterRange Everything() { return CharacterRange(0, String::kMaxCodePoint); } static inline ZoneList<CharacterRange>* List(Zone* zone, CharacterRange range) { ZoneList<CharacterRange>* list = new (zone) ZoneList<CharacterRange>(1, zone); list->Add(range, zone); return list; } bool Contains(uc32 i) { return from_ <= i && i <= to_; } uc32 from() const { return from_; } void set_from(uc32 value) { from_ = value; } uc32 to() const { return to_; } void set_to(uc32 value) { to_ = value; } bool is_valid() { return from_ <= to_; } bool IsEverything(uc16 max) { return from_ == 0 && to_ >= max; } bool IsSingleton() { return (from_ == to_); } static void AddCaseEquivalents(Isolate* isolate, Zone* zone, ZoneList<CharacterRange>* ranges, bool is_one_byte); // Whether a range list is in canonical form: Ranges ordered by from value, // and ranges non-overlapping and non-adjacent. static bool IsCanonical(ZoneList<CharacterRange>* ranges); // Convert range list to canonical form. The characters covered by the ranges // will still be the same, but no character is in more than one range, and // adjacent ranges are merged. The resulting list may be shorter than the // original, but cannot be longer. static void Canonicalize(ZoneList<CharacterRange>* ranges); // Negate the contents of a character range in canonical form. static void Negate(ZoneList<CharacterRange>* src, ZoneList<CharacterRange>* dst, Zone* zone); static const int kStartMarker = (1 << 24); static const int kPayloadMask = (1 << 24) - 1; private: CharacterRange(uc32 from, uc32 to) : from_(from), to_(to) {} uc32 from_; uc32 to_; }; class CharacterSet final BASE_EMBEDDED { public: explicit CharacterSet(uc16 standard_set_type) : ranges_(NULL), standard_set_type_(standard_set_type) {} explicit CharacterSet(ZoneList<CharacterRange>* ranges) : ranges_(ranges), standard_set_type_(0) {} ZoneList<CharacterRange>* ranges(Zone* zone); uc16 standard_set_type() { return standard_set_type_; } void set_standard_set_type(uc16 special_set_type) { standard_set_type_ = special_set_type; } bool is_standard() { return standard_set_type_ != 0; } void Canonicalize(); private: ZoneList<CharacterRange>* ranges_; // If non-zero, the value represents a standard set (e.g., all whitespace // characters) without having to expand the ranges. uc16 standard_set_type_; }; class TextElement final BASE_EMBEDDED { public: enum TextType { ATOM, CHAR_CLASS }; static TextElement Atom(RegExpAtom* atom); static TextElement CharClass(RegExpCharacterClass* char_class); int cp_offset() const { return cp_offset_; } void set_cp_offset(int cp_offset) { cp_offset_ = cp_offset; } int length() const; TextType text_type() const { return text_type_; } RegExpTree* tree() const { return tree_; } RegExpAtom* atom() const { DCHECK(text_type() == ATOM); return reinterpret_cast<RegExpAtom*>(tree()); } RegExpCharacterClass* char_class() const { DCHECK(text_type() == CHAR_CLASS); return reinterpret_cast<RegExpCharacterClass*>(tree()); } private: TextElement(TextType text_type, RegExpTree* tree) : cp_offset_(-1), text_type_(text_type), tree_(tree) {} int cp_offset_; TextType text_type_; RegExpTree* tree_; }; class RegExpTree : public ZoneObject { public: static const int kInfinity = kMaxInt; virtual ~RegExpTree() {} virtual void* Accept(RegExpVisitor* visitor, void* data) = 0; virtual RegExpNode* ToNode(RegExpCompiler* compiler, RegExpNode* on_success) = 0; virtual bool IsTextElement() { return false; } virtual bool IsAnchoredAtStart() { return false; } virtual bool IsAnchoredAtEnd() { return false; } virtual int min_match() = 0; virtual int max_match() = 0; // Returns the interval of registers used for captures within this // expression. virtual Interval CaptureRegisters() { return Interval::Empty(); } virtual void AppendToText(RegExpText* text, Zone* zone); std::ostream& Print(std::ostream& os, Zone* zone); // NOLINT #define MAKE_ASTYPE(Name) \ virtual RegExp##Name* As##Name(); \ virtual bool Is##Name(); FOR_EACH_REG_EXP_TREE_TYPE(MAKE_ASTYPE) #undef MAKE_ASTYPE }; class RegExpDisjunction final : public RegExpTree { public: explicit RegExpDisjunction(ZoneList<RegExpTree*>* alternatives); void* Accept(RegExpVisitor* visitor, void* data) override; RegExpNode* ToNode(RegExpCompiler* compiler, RegExpNode* on_success) override; RegExpDisjunction* AsDisjunction() override; Interval CaptureRegisters() override; bool IsDisjunction() override; bool IsAnchoredAtStart() override; bool IsAnchoredAtEnd() override; int min_match() override { return min_match_; } int max_match() override { return max_match_; } ZoneList<RegExpTree*>* alternatives() { return alternatives_; } private: bool SortConsecutiveAtoms(RegExpCompiler* compiler); void RationalizeConsecutiveAtoms(RegExpCompiler* compiler); void FixSingleCharacterDisjunctions(RegExpCompiler* compiler); ZoneList<RegExpTree*>* alternatives_; int min_match_; int max_match_; }; class RegExpAlternative final : public RegExpTree { public: explicit RegExpAlternative(ZoneList<RegExpTree*>* nodes); void* Accept(RegExpVisitor* visitor, void* data) override; RegExpNode* ToNode(RegExpCompiler* compiler, RegExpNode* on_success) override; RegExpAlternative* AsAlternative() override; Interval CaptureRegisters() override; bool IsAlternative() override; bool IsAnchoredAtStart() override; bool IsAnchoredAtEnd() override; int min_match() override { return min_match_; } int max_match() override { return max_match_; } ZoneList<RegExpTree*>* nodes() { return nodes_; } private: ZoneList<RegExpTree*>* nodes_; int min_match_; int max_match_; }; class RegExpAssertion final : public RegExpTree { public: enum AssertionType { START_OF_LINE, START_OF_INPUT, END_OF_LINE, END_OF_INPUT, BOUNDARY, NON_BOUNDARY }; explicit RegExpAssertion(AssertionType type) : assertion_type_(type) {} void* Accept(RegExpVisitor* visitor, void* data) override; RegExpNode* ToNode(RegExpCompiler* compiler, RegExpNode* on_success) override; RegExpAssertion* AsAssertion() override; bool IsAssertion() override; bool IsAnchoredAtStart() override; bool IsAnchoredAtEnd() override; int min_match() override { return 0; } int max_match() override { return 0; } AssertionType assertion_type() { return assertion_type_; } private: AssertionType assertion_type_; }; class RegExpCharacterClass final : public RegExpTree { public: RegExpCharacterClass(ZoneList<CharacterRange>* ranges, bool is_negated) : set_(ranges), is_negated_(is_negated) {} explicit RegExpCharacterClass(uc16 type) : set_(type), is_negated_(false) {} void* Accept(RegExpVisitor* visitor, void* data) override; RegExpNode* ToNode(RegExpCompiler* compiler, RegExpNode* on_success) override; RegExpCharacterClass* AsCharacterClass() override; bool IsCharacterClass() override; bool IsTextElement() override { return true; } int min_match() override { return 1; } // The character class may match two code units for unicode regexps. // TODO(yangguo): we should split this class for usage in TextElement, and // make max_match() dependent on the character class content. int max_match() override { return 2; } void AppendToText(RegExpText* text, Zone* zone) override; CharacterSet character_set() { return set_; } // TODO(lrn): Remove need for complex version if is_standard that // recognizes a mangled standard set and just do { return set_.is_special(); } bool is_standard(Zone* zone); // Returns a value representing the standard character set if is_standard() // returns true. // Currently used values are: // s : unicode whitespace // S : unicode non-whitespace // w : ASCII word character (digit, letter, underscore) // W : non-ASCII word character // d : ASCII digit // D : non-ASCII digit // . : non-newline // * : All characters, for advancing unanchored regexp uc16 standard_type() { return set_.standard_set_type(); } ZoneList<CharacterRange>* ranges(Zone* zone) { return set_.ranges(zone); } bool is_negated() { return is_negated_; } private: CharacterSet set_; bool is_negated_; }; class RegExpAtom final : public RegExpTree { public: explicit RegExpAtom(Vector<const uc16> data) : data_(data) {} void* Accept(RegExpVisitor* visitor, void* data) override; RegExpNode* ToNode(RegExpCompiler* compiler, RegExpNode* on_success) override; RegExpAtom* AsAtom() override; bool IsAtom() override; bool IsTextElement() override { return true; } int min_match() override { return data_.length(); } int max_match() override { return data_.length(); } void AppendToText(RegExpText* text, Zone* zone) override; Vector<const uc16> data() { return data_; } int length() { return data_.length(); } private: Vector<const uc16> data_; }; class RegExpText final : public RegExpTree { public: explicit RegExpText(Zone* zone) : elements_(2, zone), length_(0) {} void* Accept(RegExpVisitor* visitor, void* data) override; RegExpNode* ToNode(RegExpCompiler* compiler, RegExpNode* on_success) override; RegExpText* AsText() override; bool IsText() override; bool IsTextElement() override { return true; } int min_match() override { return length_; } int max_match() override { return length_; } void AppendToText(RegExpText* text, Zone* zone) override; void AddElement(TextElement elm, Zone* zone) { elements_.Add(elm, zone); length_ += elm.length(); } ZoneList<TextElement>* elements() { return &elements_; } private: ZoneList<TextElement> elements_; int length_; }; class RegExpQuantifier final : public RegExpTree { public: enum QuantifierType { GREEDY, NON_GREEDY, POSSESSIVE }; RegExpQuantifier(int min, int max, QuantifierType type, RegExpTree* body) : body_(body), min_(min), max_(max), min_match_(min * body->min_match()), quantifier_type_(type) { if (max > 0 && body->max_match() > kInfinity / max) { max_match_ = kInfinity; } else { max_match_ = max * body->max_match(); } } void* Accept(RegExpVisitor* visitor, void* data) override; RegExpNode* ToNode(RegExpCompiler* compiler, RegExpNode* on_success) override; static RegExpNode* ToNode(int min, int max, bool is_greedy, RegExpTree* body, RegExpCompiler* compiler, RegExpNode* on_success, bool not_at_start = false); RegExpQuantifier* AsQuantifier() override; Interval CaptureRegisters() override; bool IsQuantifier() override; int min_match() override { return min_match_; } int max_match() override { return max_match_; } int min() { return min_; } int max() { return max_; } bool is_possessive() { return quantifier_type_ == POSSESSIVE; } bool is_non_greedy() { return quantifier_type_ == NON_GREEDY; } bool is_greedy() { return quantifier_type_ == GREEDY; } RegExpTree* body() { return body_; } private: RegExpTree* body_; int min_; int max_; int min_match_; int max_match_; QuantifierType quantifier_type_; }; class RegExpCapture final : public RegExpTree { public: explicit RegExpCapture(int index) : body_(NULL), index_(index), name_(nullptr) {} void* Accept(RegExpVisitor* visitor, void* data) override; RegExpNode* ToNode(RegExpCompiler* compiler, RegExpNode* on_success) override; static RegExpNode* ToNode(RegExpTree* body, int index, RegExpCompiler* compiler, RegExpNode* on_success); RegExpCapture* AsCapture() override; bool IsAnchoredAtStart() override; bool IsAnchoredAtEnd() override; Interval CaptureRegisters() override; bool IsCapture() override; int min_match() override { return body_->min_match(); } int max_match() override { return body_->max_match(); } RegExpTree* body() { return body_; } void set_body(RegExpTree* body) { body_ = body; } int index() { return index_; } const ZoneVector<uc16>* name() const { return name_; } void set_name(const ZoneVector<uc16>* name) { name_ = name; } static int StartRegister(int index) { return index * 2; } static int EndRegister(int index) { return index * 2 + 1; } private: RegExpTree* body_; int index_; const ZoneVector<uc16>* name_; }; class RegExpGroup final : public RegExpTree { public: explicit RegExpGroup(RegExpTree* body) : body_(body) {} void* Accept(RegExpVisitor* visitor, void* data) override; RegExpNode* ToNode(RegExpCompiler* compiler, RegExpNode* on_success) override { return body_->ToNode(compiler, on_success); } RegExpGroup* AsGroup() override; bool IsAnchoredAtStart() override { return body_->IsAnchoredAtStart(); } bool IsAnchoredAtEnd() override { return body_->IsAnchoredAtEnd(); } bool IsGroup() override; int min_match() override { return body_->min_match(); } int max_match() override { return body_->max_match(); } Interval CaptureRegisters() override { return body_->CaptureRegisters(); } RegExpTree* body() { return body_; } private: RegExpTree* body_; }; class RegExpLookaround final : public RegExpTree { public: enum Type { LOOKAHEAD, LOOKBEHIND }; RegExpLookaround(RegExpTree* body, bool is_positive, int capture_count, int capture_from, Type type) : body_(body), is_positive_(is_positive), capture_count_(capture_count), capture_from_(capture_from), type_(type) {} void* Accept(RegExpVisitor* visitor, void* data) override; RegExpNode* ToNode(RegExpCompiler* compiler, RegExpNode* on_success) override; RegExpLookaround* AsLookaround() override; Interval CaptureRegisters() override; bool IsLookaround() override; bool IsAnchoredAtStart() override; int min_match() override { return 0; } int max_match() override { return 0; } RegExpTree* body() { return body_; } bool is_positive() { return is_positive_; } int capture_count() { return capture_count_; } int capture_from() { return capture_from_; } Type type() { return type_; } class Builder { public: Builder(bool is_positive, RegExpNode* on_success, int stack_pointer_register, int position_register, int capture_register_count = 0, int capture_register_start = 0); RegExpNode* on_match_success() { return on_match_success_; } RegExpNode* ForMatch(RegExpNode* match); private: bool is_positive_; RegExpNode* on_match_success_; RegExpNode* on_success_; int stack_pointer_register_; int position_register_; }; private: RegExpTree* body_; bool is_positive_; int capture_count_; int capture_from_; Type type_; }; class RegExpBackReference final : public RegExpTree { public: RegExpBackReference() : capture_(nullptr), name_(nullptr) {} explicit RegExpBackReference(RegExpCapture* capture) : capture_(capture), name_(nullptr) {} void* Accept(RegExpVisitor* visitor, void* data) override; RegExpNode* ToNode(RegExpCompiler* compiler, RegExpNode* on_success) override; RegExpBackReference* AsBackReference() override; bool IsBackReference() override; int min_match() override { return 0; } // The back reference may be recursive, e.g. /(\2)(\1)/. To avoid infinite // recursion, we give up. Ignorance is bliss. int max_match() override { return kInfinity; } int index() { return capture_->index(); } RegExpCapture* capture() { return capture_; } void set_capture(RegExpCapture* capture) { capture_ = capture; } const ZoneVector<uc16>* name() const { return name_; } void set_name(const ZoneVector<uc16>* name) { name_ = name; } private: RegExpCapture* capture_; const ZoneVector<uc16>* name_; }; class RegExpEmpty final : public RegExpTree { public: RegExpEmpty() {} void* Accept(RegExpVisitor* visitor, void* data) override; RegExpNode* ToNode(RegExpCompiler* compiler, RegExpNode* on_success) override; RegExpEmpty* AsEmpty() override; bool IsEmpty() override; int min_match() override { return 0; } int max_match() override { return 0; } }; } // namespace internal } // namespace v8 #endif // V8_REGEXP_REGEXP_AST_H_