ladybird/Libraries/LibRegex/RegexByteCode.h
Pavel Shliak cdb54fe504 LibRegex: Clean up #include directives
This change aims to improve the speed of incremental builds.
2024-11-21 14:08:33 +01:00

912 lines
34 KiB
C++

/*
* Copyright (c) 2020, Emanuel Sprung <emanuel.sprung@gmail.com>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#pragma once
#include "RegexBytecodeStreamOptimizer.h"
#include "RegexMatch.h"
#include <AK/Concepts.h>
#include <AK/DisjointChunks.h>
#include <AK/Forward.h>
#include <AK/OwnPtr.h>
#include <AK/TypeCasts.h>
#include <AK/Types.h>
#include <AK/Vector.h>
#include <LibUnicode/Forward.h>
namespace regex {
using ByteCodeValueType = u64;
#define ENUMERATE_OPCODES \
__ENUMERATE_OPCODE(Compare) \
__ENUMERATE_OPCODE(Jump) \
__ENUMERATE_OPCODE(JumpNonEmpty) \
__ENUMERATE_OPCODE(ForkJump) \
__ENUMERATE_OPCODE(ForkStay) \
__ENUMERATE_OPCODE(ForkReplaceJump) \
__ENUMERATE_OPCODE(ForkReplaceStay) \
__ENUMERATE_OPCODE(FailForks) \
__ENUMERATE_OPCODE(SaveLeftCaptureGroup) \
__ENUMERATE_OPCODE(SaveRightCaptureGroup) \
__ENUMERATE_OPCODE(SaveRightNamedCaptureGroup) \
__ENUMERATE_OPCODE(CheckBegin) \
__ENUMERATE_OPCODE(CheckEnd) \
__ENUMERATE_OPCODE(CheckBoundary) \
__ENUMERATE_OPCODE(Save) \
__ENUMERATE_OPCODE(Restore) \
__ENUMERATE_OPCODE(GoBack) \
__ENUMERATE_OPCODE(ClearCaptureGroup) \
__ENUMERATE_OPCODE(Repeat) \
__ENUMERATE_OPCODE(ResetRepeat) \
__ENUMERATE_OPCODE(Checkpoint) \
__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(Property) \
__ENUMERATE_CHARACTER_COMPARE_TYPE(GeneralCategory) \
__ENUMERATE_CHARACTER_COMPARE_TYPE(Script) \
__ENUMERATE_CHARACTER_COMPARE_TYPE(ScriptExtension) \
__ENUMERATE_CHARACTER_COMPARE_TYPE(RangeExpressionDummy) \
__ENUMERATE_CHARACTER_COMPARE_TYPE(LookupTable) \
__ENUMERATE_CHARACTER_COMPARE_TYPE(And) \
__ENUMERATE_CHARACTER_COMPARE_TYPE(Or) \
__ENUMERATE_CHARACTER_COMPARE_TYPE(EndAndOr)
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 {
u32 const from;
u32 const 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 DisjointChunks<ByteCodeValueType> {
using Base = DisjointChunks<ByteCodeValueType>;
public:
ByteCode()
{
ensure_opcodes_initialized();
}
ByteCode(ByteCode const&) = default;
ByteCode(ByteCode&&) = default;
virtual ~ByteCode() = default;
ByteCode& operator=(ByteCode const&) = default;
ByteCode& operator=(ByteCode&&) = default;
ByteCode& operator=(Base&& value)
{
static_cast<Base&>(*this) = move(value);
return *this;
}
template<typename... Args>
void empend(Args&&... args)
{
if (is_empty())
Base::append({});
Base::last_chunk().empend(forward<Args>(args)...);
}
template<typename T>
void append(T&& value)
{
if (is_empty())
Base::append({});
Base::last_chunk().append(forward<T>(value));
}
template<typename T>
void prepend(T&& value)
{
if (is_empty())
return append(forward<T>(value));
Base::first_chunk().prepend(forward<T>(value));
}
void append(Span<ByteCodeValueType const> value)
{
if (is_empty())
Base::append({});
auto& last = Base::last_chunk();
last.ensure_capacity(value.size());
for (auto v : value)
last.unchecked_append(v);
}
void ensure_capacity(size_t capacity)
{
if (is_empty())
Base::append({});
Base::last_chunk().ensure_capacity(capacity);
}
void last_chunk() const = delete;
void first_chunk() const = delete;
void insert_bytecode_compare_values(Vector<CompareTypeAndValuePair>&& pairs)
{
Optimizer::append_character_class(*this, move(pairs));
}
void insert_bytecode_check_boundary(BoundaryCheckType type)
{
ByteCode bytecode;
bytecode.empend((ByteCodeValueType)OpCodeId::CheckBoundary);
bytecode.empend((ByteCodeValueType)type);
extend(move(bytecode));
}
void insert_bytecode_clear_capture_group(size_t index)
{
empend(static_cast<ByteCodeValueType>(OpCodeId::ClearCaptureGroup));
empend(index);
}
void insert_bytecode_compare_string(StringView view)
{
empend(static_cast<ByteCodeValueType>(OpCodeId::Compare));
empend(static_cast<u64>(1)); // number of arguments
empend(2 + view.length()); // size of arguments
empend(static_cast<ByteCodeValueType>(CharacterCompareType::String));
insert_string(view);
}
void insert_bytecode_group_capture_left(size_t capture_groups_count)
{
empend(static_cast<ByteCodeValueType>(OpCodeId::SaveLeftCaptureGroup));
empend(capture_groups_count);
}
void insert_bytecode_group_capture_right(size_t capture_groups_count)
{
empend(static_cast<ByteCodeValueType>(OpCodeId::SaveRightCaptureGroup));
empend(capture_groups_count);
}
void insert_bytecode_group_capture_right(size_t capture_groups_count, StringView name)
{
empend(static_cast<ByteCodeValueType>(OpCodeId::SaveRightNamedCaptureGroup));
empend(reinterpret_cast<ByteCodeValueType>(name.characters_without_null_termination()));
empend(name.length());
empend(capture_groups_count);
}
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);
extend(move(lookaround_body));
empend((ByteCodeValueType)OpCodeId::Restore);
return;
}
case LookAroundType::NegatedLookAhead: {
// JUMP _A
// LABEL _L
// REGEXP BODY
// FAIL
// LABEL _A
// SAVE
// FORKJUMP _L
// RESTORE
auto body_length = lookaround_body.size();
empend((ByteCodeValueType)OpCodeId::Jump);
empend((ByteCodeValueType)body_length + 1); // JUMP to label _A
extend(move(lookaround_body));
empend((ByteCodeValueType)OpCodeId::FailForks);
empend((ByteCodeValueType)OpCodeId::Save);
empend((ByteCodeValueType)OpCodeId::ForkJump);
empend((ByteCodeValueType) - (body_length + 4)); // JUMP to label _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);
extend(move(lookaround_body));
empend((ByteCodeValueType)OpCodeId::Restore);
return;
case LookAroundType::NegatedLookBehind: {
// JUMP _A
// LABEL _L
// GOBACK match_length(BODY)
// REGEXP BODY
// FAIL
// LABEL _A
// SAVE
// FORKJUMP _L
// RESTORE
auto body_length = lookaround_body.size();
empend((ByteCodeValueType)OpCodeId::Jump);
empend((ByteCodeValueType)body_length + 3); // JUMP to label _A
empend((ByteCodeValueType)OpCodeId::GoBack);
empend((ByteCodeValueType)match_length);
extend(move(lookaround_body));
empend((ByteCodeValueType)OpCodeId::FailForks);
empend((ByteCodeValueType)OpCodeId::Save);
empend((ByteCodeValueType)OpCodeId::ForkJump);
empend((ByteCodeValueType) - (body_length + 6)); // JUMP to label _L
empend((ByteCodeValueType)OpCodeId::Restore);
return;
}
}
VERIFY_NOT_REACHED();
}
void insert_bytecode_alternation(ByteCode&& left, ByteCode&& right)
{
// FORKJUMP _ALT
// REGEXP ALT2
// JUMP _END
// LABEL _ALT
// REGEXP ALT1
// LABEL _END
// Optimisation: Eliminate extra work by unifying common pre-and-postfix exprs.
Optimizer::append_alternation(*this, move(left), move(right));
}
template<Integral T>
static void transform_bytecode_repetition_min_max(ByteCode& bytecode_to_repeat, T minimum, Optional<T> maximum, size_t min_repetition_mark_id, size_t max_repetition_mark_id, bool greedy = true)
{
if (!maximum.has_value()) {
if (minimum == 0)
return transform_bytecode_repetition_any(bytecode_to_repeat, greedy);
if (minimum == 1)
return transform_bytecode_repetition_min_one(bytecode_to_repeat, greedy);
}
ByteCode new_bytecode;
new_bytecode.insert_bytecode_repetition_n(bytecode_to_repeat, minimum, min_repetition_mark_id);
if (maximum.has_value()) {
// (REPEAT REGEXP MIN)
// LABEL _MAX_LOOP |
// FORK END |
// REGEXP |
// REPEAT _MAX_LOOP MAX-MIN | if max > min
// FORK END |
// REGEXP |
// LABEL END |
// RESET _MAX_LOOP |
auto jump_kind = static_cast<ByteCodeValueType>(greedy ? OpCodeId::ForkStay : OpCodeId::ForkJump);
if (maximum.value() > minimum) {
new_bytecode.empend(jump_kind);
new_bytecode.empend((ByteCodeValueType)0); // Placeholder for the jump target.
auto pre_loop_fork_jump_index = new_bytecode.size();
new_bytecode.extend(bytecode_to_repeat);
auto repetitions = maximum.value() - minimum;
auto fork_jump_address = new_bytecode.size();
if (repetitions > 1) {
new_bytecode.empend((ByteCodeValueType)OpCodeId::Repeat);
new_bytecode.empend(bytecode_to_repeat.size() + 2);
new_bytecode.empend(static_cast<ByteCodeValueType>(repetitions - 1));
new_bytecode.empend(max_repetition_mark_id);
new_bytecode.empend(jump_kind);
new_bytecode.empend((ByteCodeValueType)0); // Placeholder for the jump target.
auto post_loop_fork_jump_index = new_bytecode.size();
new_bytecode.extend(bytecode_to_repeat);
fork_jump_address = new_bytecode.size();
new_bytecode[post_loop_fork_jump_index - 1] = (ByteCodeValueType)(fork_jump_address - post_loop_fork_jump_index);
new_bytecode.empend((ByteCodeValueType)OpCodeId::ResetRepeat);
new_bytecode.empend((ByteCodeValueType)max_repetition_mark_id);
}
new_bytecode[pre_loop_fork_jump_index - 1] = (ByteCodeValueType)(fork_jump_address - pre_loop_fork_jump_index);
}
} else {
// no maximum value set, repeat finding if possible:
// (REPEAT REGEXP MIN)
// LABEL _START
// CHECKPOINT _C
// REGEXP
// JUMP_NONEMPTY _C _START FORK
// Note: This is only safe because REPEAT will leave one iteration outside (see repetition_n)
auto checkpoint = s_next_checkpoint_serial_id++;
new_bytecode.insert(new_bytecode.size() - bytecode_to_repeat.size(), (ByteCodeValueType)OpCodeId::Checkpoint);
new_bytecode.insert(new_bytecode.size() - bytecode_to_repeat.size(), (ByteCodeValueType)checkpoint);
auto jump_kind = static_cast<ByteCodeValueType>(greedy ? OpCodeId::ForkJump : OpCodeId::ForkStay);
new_bytecode.empend((ByteCodeValueType)OpCodeId::JumpNonEmpty);
new_bytecode.empend(-bytecode_to_repeat.size() - 4 - 2); // Jump to the last iteration
new_bytecode.empend(checkpoint); // if _C is not empty.
new_bytecode.empend(jump_kind);
}
bytecode_to_repeat = move(new_bytecode);
}
template<Integral T>
void insert_bytecode_repetition_n(ByteCode& bytecode_to_repeat, T n, size_t repetition_mark_id)
{
// LABEL _LOOP
// REGEXP
// REPEAT _LOOP N-1
// REGEXP
if (n == 0)
return;
// Note: this bytecode layout allows callers to repeat the last REGEXP instruction without the
// REPEAT instruction forcing another loop.
extend(bytecode_to_repeat);
if (n > 1) {
empend(static_cast<ByteCodeValueType>(OpCodeId::Repeat));
empend(bytecode_to_repeat.size());
empend(static_cast<ByteCodeValueType>(n - 1));
empend(repetition_mark_id);
extend(bytecode_to_repeat);
}
}
static void transform_bytecode_repetition_min_one(ByteCode& bytecode_to_repeat, bool greedy)
{
// LABEL _START = -bytecode_to_repeat.size()
// CHECKPOINT _C
// REGEXP
// JUMP_NONEMPTY _C _START FORKSTAY (FORKJUMP -> Greedy)
auto checkpoint = s_next_checkpoint_serial_id++;
bytecode_to_repeat.prepend((ByteCodeValueType)checkpoint);
bytecode_to_repeat.prepend((ByteCodeValueType)OpCodeId::Checkpoint);
bytecode_to_repeat.empend((ByteCodeValueType)OpCodeId::JumpNonEmpty);
bytecode_to_repeat.empend(-bytecode_to_repeat.size() - 3); // Jump to the _START label...
bytecode_to_repeat.empend(checkpoint); // ...if _C is not empty
if (greedy)
bytecode_to_repeat.empend(static_cast<ByteCodeValueType>(OpCodeId::ForkJump));
else
bytecode_to_repeat.empend(static_cast<ByteCodeValueType>(OpCodeId::ForkStay));
}
static void transform_bytecode_repetition_any(ByteCode& bytecode_to_repeat, bool greedy)
{
// LABEL _START
// FORKJUMP _END (FORKSTAY -> Greedy)
// CHECKPOINT _C
// REGEXP
// JUMP_NONEMPTY _C _START JUMP
// LABEL _END
// LABEL _START = m_bytes.size();
ByteCode bytecode;
if (greedy)
bytecode.empend(static_cast<ByteCodeValueType>(OpCodeId::ForkStay));
else
bytecode.empend(static_cast<ByteCodeValueType>(OpCodeId::ForkJump));
bytecode.empend(bytecode_to_repeat.size() + 2 + 4); // Jump to the _END label
auto checkpoint = s_next_checkpoint_serial_id++;
bytecode.empend(static_cast<ByteCodeValueType>(OpCodeId::Checkpoint));
bytecode.empend(static_cast<ByteCodeValueType>(checkpoint));
bytecode.extend(bytecode_to_repeat);
bytecode.empend(static_cast<ByteCodeValueType>(OpCodeId::JumpNonEmpty));
bytecode.empend(-bytecode.size() - 3); // Jump(...) to the _START label...
bytecode.empend(checkpoint); // ...only if _C passes.
bytecode.empend((ByteCodeValueType)OpCodeId::Jump);
// LABEL _END = bytecode.size()
bytecode_to_repeat = move(bytecode);
}
static void transform_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<ByteCodeValueType>(OpCodeId::ForkStay));
else
bytecode.empend(static_cast<ByteCodeValueType>(OpCodeId::ForkJump));
bytecode.empend(bytecode_to_repeat.size()); // Jump to the _END label
bytecode.extend(move(bytecode_to_repeat));
// LABEL _END = bytecode.size()
bytecode_to_repeat = move(bytecode);
}
OpCode& get_opcode(MatchState& state) const;
static void reset_checkpoint_serial_id() { s_next_checkpoint_serial_id = 0; }
private:
void insert_string(StringView view)
{
empend((ByteCodeValueType)view.length());
for (size_t i = 0; i < view.length(); ++i)
empend((ByteCodeValueType)view[i]);
}
void ensure_opcodes_initialized();
ALWAYS_INLINE OpCode& get_opcode_by_id(OpCodeId id) const;
static OwnPtr<OpCode> s_opcodes[(size_t)OpCodeId::Last + 1];
static bool s_opcodes_initialized;
static size_t s_next_checkpoint_serial_id;
};
#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
};
StringView execution_result_name(ExecutionResult result);
StringView opcode_id_name(OpCodeId opcode_id);
StringView boundary_check_type_name(BoundaryCheckType);
StringView character_compare_type_name(CharacterCompareType result);
StringView character_class_name(CharClass ch_class);
class OpCode {
public:
OpCode() = default;
virtual ~OpCode() = default;
virtual OpCodeId opcode_id() const = 0;
virtual size_t size() const = 0;
virtual ExecutionResult execute(MatchInput const& input, MatchState& state) const = 0;
ALWAYS_INLINE ByteCodeValueType argument(size_t offset) const
{
return m_bytecode->at(state().instruction_position + 1 + offset);
}
ALWAYS_INLINE StringView name() const;
static StringView name(OpCodeId);
ALWAYS_INLINE void set_state(MatchState& state) { m_state = &state; }
ALWAYS_INLINE void set_bytecode(ByteCode& bytecode) { m_bytecode = &bytecode; }
ALWAYS_INLINE MatchState const& state() const
{
VERIFY(m_state);
return *m_state;
}
ByteString to_byte_string() const
{
return ByteString::formatted("[{:#02X}] {}", (int)opcode_id(), name(opcode_id()));
}
virtual ByteString arguments_string() const = 0;
ALWAYS_INLINE ByteCode const& bytecode() const { return *m_bytecode; }
protected:
ByteCode* m_bytecode { nullptr };
MatchState* m_state { nullptr };
};
class OpCode_Exit final : public OpCode {
public:
ExecutionResult execute(MatchInput const& input, MatchState& state) const override;
ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::Exit; }
ALWAYS_INLINE size_t size() const override { return 1; }
ByteString arguments_string() const override { return ByteString::empty(); }
};
class OpCode_FailForks final : public OpCode {
public:
ExecutionResult execute(MatchInput const& input, MatchState& state) const override;
ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::FailForks; }
ALWAYS_INLINE size_t size() const override { return 1; }
ByteString arguments_string() const override { return ByteString::empty(); }
};
class OpCode_Save final : public OpCode {
public:
ExecutionResult execute(MatchInput const& input, MatchState& state) const override;
ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::Save; }
ALWAYS_INLINE size_t size() const override { return 1; }
ByteString arguments_string() const override { return ByteString::empty(); }
};
class OpCode_Restore final : public OpCode {
public:
ExecutionResult execute(MatchInput const& input, MatchState& state) const override;
ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::Restore; }
ALWAYS_INLINE size_t size() const override { return 1; }
ByteString arguments_string() const override { return ByteString::empty(); }
};
class OpCode_GoBack final : public OpCode {
public:
ExecutionResult execute(MatchInput const& input, MatchState& state) 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); }
ByteString arguments_string() const override { return ByteString::formatted("count={}", count()); }
};
class OpCode_Jump final : public OpCode {
public:
ExecutionResult execute(MatchInput const& input, MatchState& state) 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); }
ByteString arguments_string() const override
{
return ByteString::formatted("offset={} [&{}]", offset(), state().instruction_position + size() + offset());
}
};
class OpCode_ForkJump : public OpCode {
public:
ExecutionResult execute(MatchInput const& input, MatchState& state) 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); }
ByteString arguments_string() const override
{
return ByteString::formatted("offset={} [&{}], sp: {}", offset(), state().instruction_position + size() + offset(), state().string_position);
}
};
class OpCode_ForkReplaceJump final : public OpCode_ForkJump {
public:
ExecutionResult execute(MatchInput const& input, MatchState& state) const override;
ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::ForkReplaceJump; }
};
class OpCode_ForkStay : public OpCode {
public:
ExecutionResult execute(MatchInput const& input, MatchState& state) 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); }
ByteString arguments_string() const override
{
return ByteString::formatted("offset={} [&{}], sp: {}", offset(), state().instruction_position + size() + offset(), state().string_position);
}
};
class OpCode_ForkReplaceStay final : public OpCode_ForkStay {
public:
ExecutionResult execute(MatchInput const& input, MatchState& state) const override;
ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::ForkReplaceStay; }
};
class OpCode_CheckBegin final : public OpCode {
public:
ExecutionResult execute(MatchInput const& input, MatchState& state) const override;
ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::CheckBegin; }
ALWAYS_INLINE size_t size() const override { return 1; }
ByteString arguments_string() const override { return ByteString::empty(); }
};
class OpCode_CheckEnd final : public OpCode {
public:
ExecutionResult execute(MatchInput const& input, MatchState& state) const override;
ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::CheckEnd; }
ALWAYS_INLINE size_t size() const override { return 1; }
ByteString arguments_string() const override { return ByteString::empty(); }
};
class OpCode_CheckBoundary final : public OpCode {
public:
ExecutionResult execute(MatchInput const& input, MatchState& state) 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<BoundaryCheckType>(argument(0)); }
ByteString arguments_string() const override { return ByteString::formatted("kind={} ({})", (long unsigned int)argument(0), boundary_check_type_name(type())); }
};
class OpCode_ClearCaptureGroup final : public OpCode {
public:
ExecutionResult execute(MatchInput const& input, MatchState& state) const override;
ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::ClearCaptureGroup; }
ALWAYS_INLINE size_t size() const override { return 2; }
ALWAYS_INLINE size_t id() const { return argument(0); }
ByteString arguments_string() const override { return ByteString::formatted("id={}", id()); }
};
class OpCode_SaveLeftCaptureGroup final : public OpCode {
public:
ExecutionResult execute(MatchInput const& input, MatchState& state) 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); }
ByteString arguments_string() const override { return ByteString::formatted("id={}", id()); }
};
class OpCode_SaveRightCaptureGroup final : public OpCode {
public:
ExecutionResult execute(MatchInput const& input, MatchState& state) 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); }
ByteString arguments_string() const override { return ByteString::formatted("id={}", id()); }
};
class OpCode_SaveRightNamedCaptureGroup final : public OpCode {
public:
ExecutionResult execute(MatchInput const& input, MatchState& state) const override;
ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::SaveRightNamedCaptureGroup; }
ALWAYS_INLINE size_t size() const override { return 4; }
ALWAYS_INLINE StringView name() const { return { reinterpret_cast<char*>(argument(0)), length() }; }
ALWAYS_INLINE size_t length() const { return argument(1); }
ALWAYS_INLINE size_t id() const { return argument(2); }
ByteString arguments_string() const override
{
return ByteString::formatted("name={}, length={}", name(), length());
}
};
class OpCode_Compare final : public OpCode {
public:
ExecutionResult execute(MatchInput const& input, MatchState& state) 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); }
ByteString arguments_string() const override;
Vector<ByteString> variable_arguments_to_byte_string(Optional<MatchInput const&> input = {}) const;
Vector<CompareTypeAndValuePair> flat_compares() const;
static bool matches_character_class(CharClass, u32, bool insensitive);
private:
ALWAYS_INLINE static void compare_char(MatchInput const& input, MatchState& state, u32 ch1, bool inverse, bool& inverse_matched);
ALWAYS_INLINE static bool compare_string(MatchInput const& input, MatchState& state, RegexStringView str, bool& had_zero_length_match);
ALWAYS_INLINE static void compare_character_class(MatchInput const& input, MatchState& state, CharClass character_class, u32 ch, bool inverse, bool& inverse_matched);
ALWAYS_INLINE static void compare_character_range(MatchInput const& input, MatchState& state, u32 from, u32 to, u32 ch, bool inverse, bool& inverse_matched);
ALWAYS_INLINE static void compare_property(MatchInput const& input, MatchState& state, Unicode::Property property, bool inverse, bool& inverse_matched);
ALWAYS_INLINE static void compare_general_category(MatchInput const& input, MatchState& state, Unicode::GeneralCategory general_category, bool inverse, bool& inverse_matched);
ALWAYS_INLINE static void compare_script(MatchInput const& input, MatchState& state, Unicode::Script script, bool inverse, bool& inverse_matched);
ALWAYS_INLINE static void compare_script_extension(MatchInput const& input, MatchState& state, Unicode::Script script, bool inverse, bool& inverse_matched);
};
class OpCode_Repeat : public OpCode {
public:
ExecutionResult execute(MatchInput const& input, MatchState& state) const override;
ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::Repeat; }
ALWAYS_INLINE size_t size() const override { return 4; }
ALWAYS_INLINE size_t offset() const { return argument(0); }
ALWAYS_INLINE u64 count() const { return argument(1); }
ALWAYS_INLINE size_t id() const { return argument(2); }
ByteString arguments_string() const override
{
auto reps = id() < state().repetition_marks.size() ? state().repetition_marks.at(id()) : 0;
return ByteString::formatted("offset={} count={} id={} rep={}, sp: {}", offset(), count() + 1, id(), reps + 1, state().string_position);
}
};
class OpCode_ResetRepeat : public OpCode {
public:
ExecutionResult execute(MatchInput const& input, MatchState& state) const override;
ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::ResetRepeat; }
ALWAYS_INLINE size_t size() const override { return 2; }
ALWAYS_INLINE size_t id() const { return argument(0); }
ByteString arguments_string() const override
{
auto reps = id() < state().repetition_marks.size() ? state().repetition_marks.at(id()) : 0;
return ByteString::formatted("id={} rep={}", id(), reps + 1);
}
};
class OpCode_Checkpoint final : public OpCode {
public:
ExecutionResult execute(MatchInput const& input, MatchState& state) const override;
ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::Checkpoint; }
ALWAYS_INLINE size_t size() const override { return 2; }
ALWAYS_INLINE size_t id() const { return argument(0); }
ByteString arguments_string() const override { return ByteString::formatted("id={}", id()); }
};
class OpCode_JumpNonEmpty final : public OpCode {
public:
ExecutionResult execute(MatchInput const& input, MatchState& state) const override;
ALWAYS_INLINE OpCodeId opcode_id() const override { return OpCodeId::JumpNonEmpty; }
ALWAYS_INLINE size_t size() const override { return 4; }
ALWAYS_INLINE ssize_t offset() const { return argument(0); }
ALWAYS_INLINE ssize_t checkpoint() const { return argument(1); }
ALWAYS_INLINE OpCodeId form() const { return (OpCodeId)argument(2); }
ByteString arguments_string() const override
{
return ByteString::formatted("{} offset={} [&{}], cp={}",
opcode_id_name(form()),
offset(), state().instruction_position + size() + offset(),
checkpoint());
}
};
ALWAYS_INLINE OpCode& ByteCode::get_opcode(regex::MatchState& state) const
{
OpCodeId opcode_id;
if (auto opcode_ptr = static_cast<DisjointChunks<ByteCodeValueType> const&>(*this).find(state.instruction_position))
opcode_id = (OpCodeId)*opcode_ptr;
else
opcode_id = OpCodeId::Exit;
auto& opcode = get_opcode_by_id(opcode_id);
opcode.set_state(state);
return opcode;
}
ALWAYS_INLINE OpCode& ByteCode::get_opcode_by_id(OpCodeId id) const
{
VERIFY(id >= OpCodeId::First && id <= OpCodeId::Last);
auto& opcode = s_opcodes[(u32)id];
opcode->set_bytecode(*const_cast<ByteCode*>(this));
return *opcode;
}
template<typename T>
bool is(OpCode const&);
template<typename T>
ALWAYS_INLINE bool is(OpCode const&)
{
return false;
}
template<typename T>
ALWAYS_INLINE bool is(OpCode const* opcode)
{
return is<T>(*opcode);
}
template<>
ALWAYS_INLINE bool is<OpCode_ForkStay>(OpCode const& opcode)
{
return opcode.opcode_id() == OpCodeId::ForkStay;
}
template<>
ALWAYS_INLINE bool is<OpCode_Exit>(OpCode const& opcode)
{
return opcode.opcode_id() == OpCodeId::Exit;
}
template<>
ALWAYS_INLINE bool is<OpCode_Compare>(OpCode const& opcode)
{
return opcode.opcode_id() == OpCodeId::Compare;
}
template<typename T>
ALWAYS_INLINE T const& to(OpCode const& opcode)
{
return verify_cast<T>(opcode);
}
template<typename T>
ALWAYS_INLINE T* to(OpCode* opcode)
{
return verify_cast<T>(opcode);
}
template<typename T>
ALWAYS_INLINE T const* to(OpCode const* opcode)
{
return verify_cast<T>(opcode);
}
template<typename T>
ALWAYS_INLINE T& to(OpCode& opcode)
{
return verify_cast<T>(opcode);
}
}