/* * Copyright (c) 2020, Emanuel Sprung * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, this * list of conditions and the following disclaimer. * * 2. 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. * * 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 HOLDER 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. */ #pragma once #include "RegexMatch.h" #include "RegexOptions.h" #include #include #include #include #include #include #include #include namespace regex { using ByteCodeValueType = u64; #define ENUMERATE_OPCODES \ __ENUMERATE_OPCODE(Compare) \ __ENUMERATE_OPCODE(Jump) \ __ENUMERATE_OPCODE(ForkJump) \ __ENUMERATE_OPCODE(ForkStay) \ __ENUMERATE_OPCODE(FailForks) \ __ENUMERATE_OPCODE(SaveLeftCaptureGroup) \ __ENUMERATE_OPCODE(SaveRightCaptureGroup) \ __ENUMERATE_OPCODE(SaveLeftNamedCaptureGroup) \ __ENUMERATE_OPCODE(SaveRightNamedCaptureGroup) \ __ENUMERATE_OPCODE(CheckBegin) \ __ENUMERATE_OPCODE(CheckEnd) \ __ENUMERATE_OPCODE(CheckBoundary) \ __ENUMERATE_OPCODE(Save) \ __ENUMERATE_OPCODE(Restore) \ __ENUMERATE_OPCODE(GoBack) \ __ENUMERATE_OPCODE(Exit) // clang-format off enum class OpCodeId : ByteCodeValueType { #define __ENUMERATE_OPCODE(x) x, ENUMERATE_OPCODES #undef __ENUMERATE_OPCODE First = Compare, Last = Exit, }; // clang-format on #define ENUMERATE_CHARACTER_COMPARE_TYPES \ __ENUMERATE_CHARACTER_COMPARE_TYPE(Undefined) \ __ENUMERATE_CHARACTER_COMPARE_TYPE(Inverse) \ __ENUMERATE_CHARACTER_COMPARE_TYPE(TemporaryInverse) \ __ENUMERATE_CHARACTER_COMPARE_TYPE(AnyChar) \ __ENUMERATE_CHARACTER_COMPARE_TYPE(Char) \ __ENUMERATE_CHARACTER_COMPARE_TYPE(String) \ __ENUMERATE_CHARACTER_COMPARE_TYPE(CharClass) \ __ENUMERATE_CHARACTER_COMPARE_TYPE(CharRange) \ __ENUMERATE_CHARACTER_COMPARE_TYPE(Reference) \ __ENUMERATE_CHARACTER_COMPARE_TYPE(NamedReference) \ __ENUMERATE_CHARACTER_COMPARE_TYPE(RangeExpressionDummy) enum class CharacterCompareType : ByteCodeValueType { #define __ENUMERATE_CHARACTER_COMPARE_TYPE(x) x, ENUMERATE_CHARACTER_COMPARE_TYPES #undef __ENUMERATE_CHARACTER_COMPARE_TYPE }; #define ENUMERATE_CHARACTER_CLASSES \ __ENUMERATE_CHARACTER_CLASS(Alnum) \ __ENUMERATE_CHARACTER_CLASS(Cntrl) \ __ENUMERATE_CHARACTER_CLASS(Lower) \ __ENUMERATE_CHARACTER_CLASS(Space) \ __ENUMERATE_CHARACTER_CLASS(Alpha) \ __ENUMERATE_CHARACTER_CLASS(Digit) \ __ENUMERATE_CHARACTER_CLASS(Print) \ __ENUMERATE_CHARACTER_CLASS(Upper) \ __ENUMERATE_CHARACTER_CLASS(Blank) \ __ENUMERATE_CHARACTER_CLASS(Graph) \ __ENUMERATE_CHARACTER_CLASS(Punct) \ __ENUMERATE_CHARACTER_CLASS(Word) \ __ENUMERATE_CHARACTER_CLASS(Xdigit) enum class CharClass : ByteCodeValueType { #define __ENUMERATE_CHARACTER_CLASS(x) x, ENUMERATE_CHARACTER_CLASSES #undef __ENUMERATE_CHARACTER_CLASS }; #define ENUMERATE_BOUNDARY_CHECK_TYPES \ __ENUMERATE_BOUNDARY_CHECK_TYPE(Word) \ __ENUMERATE_BOUNDARY_CHECK_TYPE(NonWord) enum class BoundaryCheckType : ByteCodeValueType { #define __ENUMERATE_BOUNDARY_CHECK_TYPE(x) x, ENUMERATE_BOUNDARY_CHECK_TYPES #undef __ENUMERATE_BOUNDARY_CHECK_TYPE }; struct CharRange { const u32 from; const u32 to; CharRange(u64 value) : from(value >> 32) , to(value & 0xffffffff) { } CharRange(u32 from, u32 to) : from(from) , to(to) { } operator ByteCodeValueType() const { return ((u64)from << 32) | to; } }; struct CompareTypeAndValuePair { CharacterCompareType type; ByteCodeValueType value; }; class OpCode; class ByteCode : public Vector { public: ByteCode() = default; virtual ~ByteCode() = default; void insert_bytecode_compare_values(Vector&& pairs) { ByteCode bytecode; bytecode.empend(static_cast(OpCodeId::Compare)); bytecode.empend(pairs.size()); // number of arguments ByteCode arguments; for (auto& value : pairs) { ASSERT(value.type != CharacterCompareType::RangeExpressionDummy); ASSERT(value.type != CharacterCompareType::Undefined); ASSERT(value.type != CharacterCompareType::String); ASSERT(value.type != CharacterCompareType::NamedReference); arguments.append((ByteCodeValueType)value.type); if (value.type != CharacterCompareType::Inverse && value.type != CharacterCompareType::AnyChar && value.type != CharacterCompareType::TemporaryInverse) arguments.append(move(value.value)); } bytecode.empend(arguments.size()); // size of arguments bytecode.append(move(arguments)); append(move(bytecode)); } void insert_bytecode_check_boundary(BoundaryCheckType type) { ByteCode bytecode; bytecode.empend((ByteCodeValueType)OpCodeId::CheckBoundary); bytecode.empend((ByteCodeValueType)type); append(move(bytecode)); } void insert_bytecode_compare_string(StringView view, size_t length) { ByteCode bytecode; bytecode.empend(static_cast(OpCodeId::Compare)); bytecode.empend(1); // number of arguments ByteCode arguments; arguments.empend(static_cast(CharacterCompareType::String)); arguments.empend(reinterpret_cast(view.characters_without_null_termination())); arguments.empend(length); bytecode.empend(arguments.size()); // size of arguments bytecode.append(move(arguments)); append(move(bytecode)); } void insert_bytecode_compare_named_reference(StringView name, size_t length) { ByteCode bytecode; bytecode.empend(static_cast(OpCodeId::Compare)); bytecode.empend(1); // number of arguments ByteCode arguments; arguments.empend(static_cast(CharacterCompareType::NamedReference)); arguments.empend(reinterpret_cast(name.characters_without_null_termination())); arguments.empend(length); bytecode.empend(arguments.size()); // size of arguments bytecode.append(move(arguments)); append(move(bytecode)); } void insert_bytecode_group_capture_left(size_t capture_groups_count) { empend(static_cast(OpCodeId::SaveLeftCaptureGroup)); empend(capture_groups_count); } void insert_bytecode_group_capture_left(const StringView& name) { empend(static_cast(OpCodeId::SaveLeftNamedCaptureGroup)); empend(reinterpret_cast(name.characters_without_null_termination())); empend(name.length()); } void insert_bytecode_group_capture_right(size_t capture_groups_count) { empend(static_cast(OpCodeId::SaveRightCaptureGroup)); empend(capture_groups_count); } void insert_bytecode_group_capture_right(const StringView& name) { empend(static_cast(OpCodeId::SaveRightNamedCaptureGroup)); empend(reinterpret_cast(name.characters_without_null_termination())); empend(name.length()); } enum class LookAroundType { LookAhead, LookBehind, NegatedLookAhead, NegatedLookBehind, }; void insert_bytecode_lookaround(ByteCode&& lookaround_body, LookAroundType type, size_t match_length = 0) { // FIXME: The save stack will grow infinitely with repeated failures // as we do not discard that on failure (we don't necessarily know how many to pop with the current architecture). switch (type) { case LookAroundType::LookAhead: { // SAVE // REGEXP BODY // RESTORE empend((ByteCodeValueType)OpCodeId::Save); append(move(lookaround_body)); empend((ByteCodeValueType)OpCodeId::Restore); return; } case LookAroundType::NegatedLookAhead: { // JUMP _A // LABEL _L // REGEXP BODY // FAIL 2 // LABEL _A // SAVE // FORKJUMP _L // RESTORE auto body_length = lookaround_body.size(); empend((ByteCodeValueType)OpCodeId::Jump); empend((ByteCodeValueType)body_length + 2); // JUMP to label _A append(move(lookaround_body)); empend((ByteCodeValueType)OpCodeId::FailForks); empend((ByteCodeValueType)2); // Fail two forks empend((ByteCodeValueType)OpCodeId::Save); empend((ByteCodeValueType)OpCodeId::ForkJump); empend((ByteCodeValueType) - (body_length + 5)); // JUMP to lavel _L empend((ByteCodeValueType)OpCodeId::Restore); return; } case LookAroundType::LookBehind: // SAVE // GOBACK match_length(BODY) // REGEXP BODY // RESTORE empend((ByteCodeValueType)OpCodeId::Save); empend((ByteCodeValueType)OpCodeId::GoBack); empend((ByteCodeValueType)match_length); append(move(lookaround_body)); empend((ByteCodeValueType)OpCodeId::Restore); return; case LookAroundType::NegatedLookBehind: { // JUMP _A // LABEL _L // GOBACK match_length(BODY) // REGEXP BODY // FAIL 2 // LABEL _A // SAVE // FORKJUMP _L // RESTORE auto body_length = lookaround_body.size(); empend((ByteCodeValueType)OpCodeId::Jump); empend((ByteCodeValueType)body_length + 4); // JUMP to label _A empend((ByteCodeValueType)OpCodeId::GoBack); empend((ByteCodeValueType)match_length); append(move(lookaround_body)); empend((ByteCodeValueType)OpCodeId::FailForks); empend((ByteCodeValueType)2); // Fail two forks empend((ByteCodeValueType)OpCodeId::Save); empend((ByteCodeValueType)OpCodeId::ForkJump); empend((ByteCodeValueType) - (body_length + 7)); // JUMP to lavel _L empend((ByteCodeValueType)OpCodeId::Restore); return; } } ASSERT_NOT_REACHED(); } void insert_bytecode_alternation(ByteCode&& left, ByteCode&& right) { // FORKJUMP _ALT // REGEXP ALT1 // JUMP _END // LABEL _ALT // REGEXP ALT2 // LABEL _END ByteCode byte_code; empend(static_cast(OpCodeId::ForkJump)); empend(left.size() + 2); // Jump to the _ALT label for (auto& op : left) append(move(op)); empend(static_cast(OpCodeId::Jump)); empend(right.size()); // Jump to the _END label // LABEL _ALT = bytecode.size() + 2 for (auto& op : right) append(move(op)); // LABEL _END = alterantive_bytecode.size } void insert_bytecode_repetition_min_max(ByteCode& bytecode_to_repeat, size_t minimum, Optional maximum) { ByteCode new_bytecode; new_bytecode.insert_bytecode_repetition_n(bytecode_to_repeat, minimum); if (maximum.has_value()) { if (maximum.value() > minimum) { auto diff = maximum.value() - minimum; new_bytecode.empend(static_cast(OpCodeId::ForkStay)); new_bytecode.empend(diff * (bytecode_to_repeat.size() + 2)); // Jump to the _END label for (size_t i = 0; i < diff; ++i) { new_bytecode.append(bytecode_to_repeat); new_bytecode.empend(static_cast(OpCodeId::ForkStay)); new_bytecode.empend((diff - i - 1) * (bytecode_to_repeat.size() + 2)); // Jump to the _END label } } } else { // no maximum value set, repeat finding if possible new_bytecode.empend(static_cast(OpCodeId::ForkJump)); new_bytecode.empend(-bytecode_to_repeat.size() - 2); // Jump to the last iteration } bytecode_to_repeat = move(new_bytecode); } void insert_bytecode_repetition_n(ByteCode& bytecode_to_repeat, size_t n) { for (size_t i = 0; i < n; ++i) append(bytecode_to_repeat); } void insert_bytecode_repetition_min_one(ByteCode& bytecode_to_repeat, bool greedy) { // LABEL _START = -bytecode_to_repeat.size() // REGEXP // FORKSTAY _START (FORKJUMP -> Greedy) if (greedy) bytecode_to_repeat.empend(static_cast(OpCodeId::ForkJump)); else bytecode_to_repeat.empend(static_cast(OpCodeId::ForkStay)); bytecode_to_repeat.empend(-(bytecode_to_repeat.size() + 1)); // Jump to the _START label } void insert_bytecode_repetition_any(ByteCode& bytecode_to_repeat, bool greedy) { // LABEL _START // FORKJUMP _END (FORKSTAY -> Greedy) // REGEXP // JUMP _START // LABEL _END // LABEL _START = m_bytes.size(); ByteCode bytecode; if (greedy) bytecode.empend(static_cast(OpCodeId::ForkStay)); else bytecode.empend(static_cast(OpCodeId::ForkJump)); bytecode.empend(bytecode_to_repeat.size() + 2); // Jump to the _END label for (auto& op : bytecode_to_repeat) bytecode.append(move(op)); bytecode.empend(static_cast(OpCodeId::Jump)); bytecode.empend(-bytecode.size() - 1); // Jump to the _START label // LABEL _END = bytecode.size() bytecode_to_repeat = move(bytecode); } void insert_bytecode_repetition_zero_or_one(ByteCode& bytecode_to_repeat, bool greedy) { // FORKJUMP _END (FORKSTAY -> Greedy) // REGEXP // LABEL _END ByteCode bytecode; if (greedy) bytecode.empend(static_cast(OpCodeId::ForkStay)); else bytecode.empend(static_cast(OpCodeId::ForkJump)); bytecode.empend(bytecode_to_repeat.size()); // Jump to the _END label for (auto& op : bytecode_to_repeat) bytecode.append(move(op)); // LABEL _END = bytecode.size() bytecode_to_repeat = move(bytecode); } OpCode* get_opcode(MatchState& state) const; private: ALWAYS_INLINE OpCode* get_opcode_by_id(OpCodeId id) const; static HashMap> s_opcodes; }; #define ENUMERATE_EXECUTION_RESULTS \ __ENUMERATE_EXECUTION_RESULT(Continue) \ __ENUMERATE_EXECUTION_RESULT(Fork_PrioHigh) \ __ENUMERATE_EXECUTION_RESULT(Fork_PrioLow) \ __ENUMERATE_EXECUTION_RESULT(Failed) \ __ENUMERATE_EXECUTION_RESULT(Failed_ExecuteLowPrioForks) \ __ENUMERATE_EXECUTION_RESULT(Succeeded) enum class ExecutionResult : u8 { #define __ENUMERATE_EXECUTION_RESULT(x) x, ENUMERATE_EXECUTION_RESULTS #undef __ENUMERATE_EXECUTION_RESULT }; const char* execution_result_name(ExecutionResult result); const char* opcode_id_name(OpCodeId opcode_id); const char* boundary_check_type_name(BoundaryCheckType); const char* character_compare_type_name(CharacterCompareType result); const char* execution_result_name(ExecutionResult result); class OpCode { public: OpCode(ByteCode& bytecode) : m_bytecode(&bytecode) { } virtual ~OpCode() = default; virtual OpCodeId opcode_id() const = 0; virtual size_t size() const = 0; virtual ExecutionResult execute(const MatchInput& input, MatchState& state, MatchOutput& output) const = 0; ALWAYS_INLINE ByteCodeValueType argument(size_t offset) const { ASSERT(state().instruction_position + offset <= m_bytecode->size()); return m_bytecode->at(state().instruction_position + 1 + offset); } ALWAYS_INLINE const char* name() const; static const char* name(const OpCodeId); ALWAYS_INLINE OpCode* set_state(MatchState& state) { m_state = &state; return this; } ALWAYS_INLINE OpCode* set_bytecode(ByteCode& bytecode) { m_bytecode = &bytecode; return this; } ALWAYS_INLINE void reset_state() { m_state.clear(); } ALWAYS_INLINE const MatchState& state() const { ASSERT(m_state.has_value()); return *m_state.value(); } const String to_string() const { return String::format("[0x%02X] %s", opcode_id(), name(opcode_id())); } virtual const String arguments_string() const = 0; ALWAYS_INLINE const ByteCode& bytecode() const { return *m_bytecode; } protected: ByteCode* m_bytecode; Optional m_state; }; class OpCode_Exit final : public OpCode { public: OpCode_Exit(ByteCode& bytecode) : OpCode(bytecode) { } ExecutionResult execute(const MatchInput& input, MatchState& state, MatchOutput& output) const override; ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::Exit; } ALWAYS_INLINE size_t size() const override { return 1; } const String arguments_string() const override { return ""; } }; class OpCode_FailForks final : public OpCode { public: OpCode_FailForks(ByteCode& bytecode) : OpCode(bytecode) { } ExecutionResult execute(const MatchInput& input, MatchState& state, MatchOutput& output) const override; ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::FailForks; } ALWAYS_INLINE size_t size() const override { return 2; } ALWAYS_INLINE size_t count() const { return argument(0); } const String arguments_string() const override { return String::formatted("count={}", count()); } }; class OpCode_Save final : public OpCode { public: OpCode_Save(ByteCode& bytecode) : OpCode(bytecode) { } ExecutionResult execute(const MatchInput& input, MatchState& state, MatchOutput& output) const override; ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::Save; } ALWAYS_INLINE size_t size() const override { return 1; } const String arguments_string() const override { return ""; } }; class OpCode_Restore final : public OpCode { public: OpCode_Restore(ByteCode& bytecode) : OpCode(bytecode) { } ExecutionResult execute(const MatchInput& input, MatchState& state, MatchOutput& output) const override; ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::Restore; } ALWAYS_INLINE size_t size() const override { return 1; } const String arguments_string() const override { return ""; } }; class OpCode_GoBack final : public OpCode { public: OpCode_GoBack(ByteCode& bytecode) : OpCode(bytecode) { } ExecutionResult execute(const MatchInput& input, MatchState& state, MatchOutput& output) const override; ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::GoBack; } ALWAYS_INLINE size_t size() const override { return 2; } ALWAYS_INLINE size_t count() const { return argument(0); } const String arguments_string() const override { return String::formatted("count={}", count()); } }; class OpCode_Jump final : public OpCode { public: OpCode_Jump(ByteCode& bytecode) : OpCode(bytecode) { } ExecutionResult execute(const MatchInput& input, MatchState& state, MatchOutput& output) const override; ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::Jump; } ALWAYS_INLINE size_t size() const override { return 2; } ALWAYS_INLINE ssize_t offset() const { return argument(0); } const String arguments_string() const override { return String::format("offset=%i [&%lu]", offset(), state().instruction_position + size() + offset()); } }; class OpCode_ForkJump final : public OpCode { public: OpCode_ForkJump(ByteCode& bytecode) : OpCode(bytecode) { } ExecutionResult execute(const MatchInput& input, MatchState& state, MatchOutput& output) const override; ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::ForkJump; } ALWAYS_INLINE size_t size() const override { return 2; } ALWAYS_INLINE ssize_t offset() const { return argument(0); } const String arguments_string() const override { return String::format("offset=%i [&%lu], sp: %lu", offset(), state().instruction_position + size() + offset(), state().string_position); } }; class OpCode_ForkStay final : public OpCode { public: OpCode_ForkStay(ByteCode& bytecode) : OpCode(bytecode) { } ExecutionResult execute(const MatchInput& input, MatchState& state, MatchOutput& output) const override; ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::ForkStay; } ALWAYS_INLINE size_t size() const override { return 2; } ALWAYS_INLINE ssize_t offset() const { return argument(0); } const String arguments_string() const override { return String::format("offset=%i [&%lu], sp: %lu", offset(), state().instruction_position + size() + offset(), state().string_position); } }; class OpCode_CheckBegin final : public OpCode { public: OpCode_CheckBegin(ByteCode& bytecode) : OpCode(bytecode) { } ExecutionResult execute(const MatchInput& input, MatchState& state, MatchOutput& output) const override; ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::CheckBegin; } ALWAYS_INLINE size_t size() const override { return 1; } const String arguments_string() const override { return ""; } }; class OpCode_CheckEnd final : public OpCode { public: OpCode_CheckEnd(ByteCode& bytecode) : OpCode(bytecode) { } ExecutionResult execute(const MatchInput& input, MatchState& state, MatchOutput& output) const override; ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::CheckEnd; } ALWAYS_INLINE size_t size() const override { return 1; } const String arguments_string() const override { return ""; } }; class OpCode_CheckBoundary final : public OpCode { public: OpCode_CheckBoundary(ByteCode& bytecode) : OpCode(bytecode) { } ExecutionResult execute(const MatchInput& input, MatchState& state, MatchOutput& output) const override; ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::CheckBoundary; } ALWAYS_INLINE size_t size() const override { return 2; } ALWAYS_INLINE size_t arguments_count() const { return 1; } ALWAYS_INLINE BoundaryCheckType type() const { return static_cast(argument(0)); } const String arguments_string() const override { return String::format("kind=%lu (%s)", argument(0), boundary_check_type_name(type())); } }; class OpCode_SaveLeftCaptureGroup final : public OpCode { public: OpCode_SaveLeftCaptureGroup(ByteCode& bytecode) : OpCode(bytecode) { } ExecutionResult execute(const MatchInput& input, MatchState& state, MatchOutput& output) const override; ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::SaveLeftCaptureGroup; } ALWAYS_INLINE size_t size() const override { return 2; } ALWAYS_INLINE size_t id() const { return argument(0); } const String arguments_string() const override { return String::format("id=%lu", id()); } }; class OpCode_SaveRightCaptureGroup final : public OpCode { public: OpCode_SaveRightCaptureGroup(ByteCode& bytecode) : OpCode(bytecode) { } ExecutionResult execute(const MatchInput& input, MatchState& state, MatchOutput& output) const override; ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::SaveRightCaptureGroup; } ALWAYS_INLINE size_t size() const override { return 2; } ALWAYS_INLINE size_t id() const { return argument(0); } const String arguments_string() const override { return String::format("id=%lu", id()); } }; class OpCode_SaveLeftNamedCaptureGroup final : public OpCode { public: OpCode_SaveLeftNamedCaptureGroup(ByteCode& bytecode) : OpCode(bytecode) { } ExecutionResult execute(const MatchInput& input, MatchState& state, MatchOutput& output) const override; ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::SaveLeftNamedCaptureGroup; } ALWAYS_INLINE size_t size() const override { return 3; } ALWAYS_INLINE StringView name() const { return { reinterpret_cast(argument(0)), length() }; } ALWAYS_INLINE size_t length() const { return argument(1); } const String arguments_string() const override { return String::format("name=%s, length=%lu", name().to_string().characters(), length()); } }; class OpCode_SaveRightNamedCaptureGroup final : public OpCode { public: OpCode_SaveRightNamedCaptureGroup(ByteCode& bytecode) : OpCode(bytecode) { } ExecutionResult execute(const MatchInput& input, MatchState& state, MatchOutput& output) const override; ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::SaveRightNamedCaptureGroup; } ALWAYS_INLINE size_t size() const override { return 3; } ALWAYS_INLINE StringView name() const { return { reinterpret_cast(argument(0)), length() }; } ALWAYS_INLINE size_t length() const { return argument(1); } const String arguments_string() const override { return String::format("name=%s, length=%lu", name().to_string().characters(), length()); } }; class OpCode_Compare final : public OpCode { public: OpCode_Compare(ByteCode& bytecode) : OpCode(bytecode) { } ExecutionResult execute(const MatchInput& input, MatchState& state, MatchOutput& output) const override; ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::Compare; } ALWAYS_INLINE size_t size() const override { return arguments_size() + 3; } ALWAYS_INLINE size_t arguments_count() const { return argument(0); } ALWAYS_INLINE size_t arguments_size() const { return argument(1); } const String arguments_string() const override; const Vector variable_arguments_to_string(Optional input = {}) const; private: ALWAYS_INLINE static void compare_char(const MatchInput& input, MatchState& state, u32 ch1, bool inverse, bool& inverse_matched); ALWAYS_INLINE static bool compare_string(const MatchInput& input, MatchState& state, const char* str, size_t length); ALWAYS_INLINE static void compare_character_class(const MatchInput& input, MatchState& state, CharClass character_class, u32 ch, bool inverse, bool& inverse_matched); ALWAYS_INLINE static void compare_character_range(const MatchInput& input, MatchState& state, u32 from, u32 to, u32 ch, bool inverse, bool& inverse_matched); }; template bool is(const OpCode&); template ALWAYS_INLINE bool is(const OpCode&) { return false; } template ALWAYS_INLINE bool is(const OpCode* opcode) { return is(*opcode); } template<> ALWAYS_INLINE bool is(const OpCode& opcode) { return opcode.opcode_id() == OpCodeId::ForkStay; } template<> ALWAYS_INLINE bool is(const OpCode& opcode) { return opcode.opcode_id() == OpCodeId::Exit; } template<> ALWAYS_INLINE bool is(const OpCode& opcode) { return opcode.opcode_id() == OpCodeId::Compare; } template ALWAYS_INLINE const T& to(const OpCode& opcode) { ASSERT(is(opcode)); return static_cast(opcode); } template ALWAYS_INLINE T* to(OpCode* opcode) { ASSERT(is(opcode)); return static_cast(opcode); } template ALWAYS_INLINE const T* to(const OpCode* opcode) { ASSERT(is(opcode)); return static_cast(opcode); } template ALWAYS_INLINE T& to(OpCode& opcode) { ASSERT(is(opcode)); return static_cast(opcode); } }