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// Copyright 2011 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.
// A simple interpreter for the Irregexp byte code.
#include "src/regexp/regexp-interpreter.h"
#include "src/base/small-vector.h"
#include "src/base/strings.h"
#include "src/execution/isolate.h"
#include "src/logging/counters.h"
#include "src/objects/js-regexp-inl.h"
#include "src/objects/string-inl.h"
#include "src/regexp/regexp-bytecodes.h"
#include "src/regexp/regexp-macro-assembler.h"
#include "src/regexp/regexp-stack.h" // For kMaximumStackSize.
#include "src/regexp/regexp.h"
#include "src/strings/unicode.h"
#include "src/utils/memcopy.h"
#include "src/utils/utils.h"
#ifdef V8_INTL_SUPPORT
#include "unicode/uchar.h"
#endif // V8_INTL_SUPPORT
// Use token threaded dispatch iff the compiler supports computed gotos and the
// build argument v8_enable_regexp_interpreter_threaded_dispatch was set.
#if V8_HAS_COMPUTED_GOTO && \
defined(V8_ENABLE_REGEXP_INTERPRETER_THREADED_DISPATCH)
#define V8_USE_COMPUTED_GOTO 1
#endif // V8_HAS_COMPUTED_GOTO
namespace v8 {
namespace internal {
namespace {
bool BackRefMatchesNoCase(Isolate* isolate, int from, int current, int len,
base::Vector<const base::uc16> subject,
bool unicode) {
Address offset_a =
reinterpret_cast<Address>(const_cast<base::uc16*>(&subject.at(from)));
Address offset_b =
reinterpret_cast<Address>(const_cast<base::uc16*>(&subject.at(current)));
size_t length = len * base::kUC16Size;
bool result = unicode
? RegExpMacroAssembler::CaseInsensitiveCompareUnicode(
offset_a, offset_b, length, isolate)
: RegExpMacroAssembler::CaseInsensitiveCompareNonUnicode(
offset_a, offset_b, length, isolate);
return result == 1;
}
bool BackRefMatchesNoCase(Isolate* isolate, int from, int current, int len,
base::Vector<const uint8_t> subject, bool unicode) {
// For Latin1 characters the unicode flag makes no difference.
for (int i = 0; i < len; i++) {
unsigned int old_char = subject[from++];
unsigned int new_char = subject[current++];
if (old_char == new_char) continue;
// Convert both characters to lower case.
old_char |= 0x20;
new_char |= 0x20;
if (old_char != new_char) return false;
// Not letters in the ASCII range and Latin-1 range.
if (!(old_char - 'a' <= 'z' - 'a') &&
!(old_char - 224 <= 254 - 224 && old_char != 247)) {
return false;
}
}
return true;
}
#ifdef DEBUG
void MaybeTraceInterpreter(const uint8_t* code_base, const uint8_t* pc,
int stack_depth, int current_position,
uint32_t current_char, int bytecode_length,
const char* bytecode_name) {
if (v8_flags.trace_regexp_bytecodes) {
const bool printable = std::isprint(current_char);
const char* format =
printable
? "pc = %02x, sp = %d, curpos = %d, curchar = %08x (%c), bc = "
: "pc = %02x, sp = %d, curpos = %d, curchar = %08x .%c., bc = ";
PrintF(format, pc - code_base, stack_depth, current_position, current_char,
printable ? current_char : '.');
RegExpBytecodeDisassembleSingle(code_base, pc);
}
}
#endif // DEBUG
int32_t Load32Aligned(const uint8_t* pc) {
DCHECK_EQ(0, reinterpret_cast<intptr_t>(pc) & 3);
return *reinterpret_cast<const int32_t*>(pc);
}
// TODO(jgruber): Rename to Load16AlignedUnsigned.
uint32_t Load16Aligned(const uint8_t* pc) {
DCHECK_EQ(0, reinterpret_cast<intptr_t>(pc) & 1);
return *reinterpret_cast<const uint16_t*>(pc);
}
int32_t Load16AlignedSigned(const uint8_t* pc) {
DCHECK_EQ(0, reinterpret_cast<intptr_t>(pc) & 1);
return *reinterpret_cast<const int16_t*>(pc);
}
// Helpers to access the packed argument. Takes the 32 bits containing the
// current bytecode, where the 8 LSB contain the bytecode and the rest contains
// a packed 24-bit argument.
// TODO(jgruber): Specify signed-ness in bytecode signature declarations, and
// police restrictions during bytecode generation.
int32_t LoadPacked24Signed(int32_t bytecode_and_packed_arg) {
return bytecode_and_packed_arg >> BYTECODE_SHIFT;
}
uint32_t LoadPacked24Unsigned(int32_t bytecode_and_packed_arg) {
return static_cast<uint32_t>(bytecode_and_packed_arg) >> BYTECODE_SHIFT;
}
// A simple abstraction over the backtracking stack used by the interpreter.
//
// Despite the name 'backtracking' stack, it's actually used as a generic stack
// that stores both program counters (= offsets into the bytecode) and generic
// integer values.
class BacktrackStack {
public:
BacktrackStack() = default;
BacktrackStack(const BacktrackStack&) = delete;
BacktrackStack& operator=(const BacktrackStack&) = delete;
V8_WARN_UNUSED_RESULT bool push(int v) {
data_.emplace_back(v);
return (static_cast<int>(data_.size()) <= kMaxSize);
}
int peek() const {
DCHECK(!data_.empty());
return data_.back();
}
int pop() {
int v = peek();
data_.pop_back();
return v;
}
// The 'sp' is the index of the first empty element in the stack.
int sp() const { return static_cast<int>(data_.size()); }
void set_sp(int new_sp) {
DCHECK_LE(new_sp, sp());
data_.resize_no_init(new_sp);
}
private:
// Semi-arbitrary. Should be large enough for common cases to remain in the
// static stack-allocated backing store, but small enough not to waste space.
static constexpr int kStaticCapacity = 64;
using ValueT = int;
base::SmallVector<ValueT, kStaticCapacity> data_;
static constexpr int kMaxSize =
RegExpStack::kMaximumStackSize / sizeof(ValueT);
};
// Registers used during interpreter execution. These consist of output
// registers in indices [0, output_register_count[ which will contain matcher
// results as a {start,end} index tuple for each capture (where the whole match
// counts as implicit capture 0); and internal registers in indices
// [output_register_count, total_register_count[.
class InterpreterRegisters {
public:
using RegisterT = int;
InterpreterRegisters(int total_register_count, RegisterT* output_registers,
int output_register_count)
: registers_(total_register_count),
output_registers_(output_registers),
output_register_count_(output_register_count) {
// TODO(jgruber): Use int32_t consistently for registers. Currently, CSA
// uses int32_t while runtime uses int.
static_assert(sizeof(int) == sizeof(int32_t));
DCHECK_GE(output_register_count, 2); // At least 2 for the match itself.
DCHECK_GE(total_register_count, output_register_count);
DCHECK_LE(total_register_count, RegExpMacroAssembler::kMaxRegisterCount);
DCHECK_NOT_NULL(output_registers);
// Initialize the output register region to -1 signifying 'no match'.
std::memset(registers_.data(), -1,
output_register_count * sizeof(RegisterT));
}
const RegisterT& operator[](size_t index) const { return registers_[index]; }
RegisterT& operator[](size_t index) { return registers_[index]; }
void CopyToOutputRegisters() {
MemCopy(output_registers_, registers_.data(),
output_register_count_ * sizeof(RegisterT));
}
private:
static constexpr int kStaticCapacity = 64; // Arbitrary.
base::SmallVector<RegisterT, kStaticCapacity> registers_;
RegisterT* const output_registers_;
const int output_register_count_;
};
IrregexpInterpreter::Result ThrowStackOverflow(Isolate* isolate,
RegExp::CallOrigin call_origin) {
CHECK(call_origin == RegExp::CallOrigin::kFromRuntime);
// We abort interpreter execution after the stack overflow is thrown, and thus
// allow allocation here despite the outer DisallowGarbageCollectionScope.
AllowGarbageCollection yes_gc;
isolate->StackOverflow();
return IrregexpInterpreter::EXCEPTION;
}
// Only throws if called from the runtime, otherwise just returns the EXCEPTION
// status code.
IrregexpInterpreter::Result MaybeThrowStackOverflow(
Isolate* isolate, RegExp::CallOrigin call_origin) {
if (call_origin == RegExp::CallOrigin::kFromRuntime) {
return ThrowStackOverflow(isolate, call_origin);
} else {
return IrregexpInterpreter::EXCEPTION;
}
}
template <typename Char>
void UpdateCodeAndSubjectReferences(
Isolate* isolate, Handle<ByteArray> code_array,
Handle<String> subject_string, Tagged<ByteArray>* code_array_out,
const uint8_t** code_base_out, const uint8_t** pc_out,
Tagged<String>* subject_string_out,
base::Vector<const Char>* subject_string_vector_out) {
DisallowGarbageCollection no_gc;
if (*code_base_out != code_array->GetDataStartAddress()) {
*code_array_out = *code_array;
const intptr_t pc_offset = *pc_out - *code_base_out;
DCHECK_GT(pc_offset, 0);
*code_base_out = code_array->GetDataStartAddress();
*pc_out = *code_base_out + pc_offset;
}
DCHECK(subject_string->IsFlat());
*subject_string_out = *subject_string;
*subject_string_vector_out = subject_string->GetCharVector<Char>(no_gc);
}
// Runs all pending interrupts and updates unhandlified object references if
// necessary.
template <typename Char>
IrregexpInterpreter::Result HandleInterrupts(
Isolate* isolate, RegExp::CallOrigin call_origin,
Tagged<ByteArray>* code_array_out, Tagged<String>* subject_string_out,
const uint8_t** code_base_out,
base::Vector<const Char>* subject_string_vector_out,
const uint8_t** pc_out) {
DisallowGarbageCollection no_gc;
StackLimitCheck check(isolate);
bool js_has_overflowed = check.JsHasOverflowed();
if (call_origin == RegExp::CallOrigin::kFromJs) {
// Direct calls from JavaScript can be interrupted in two ways:
// 1. A real stack overflow, in which case we let the caller throw the
// exception.
// 2. The stack guard was used to interrupt execution for another purpose,
// forcing the call through the runtime system.
if (js_has_overflowed) {
return IrregexpInterpreter::EXCEPTION;
} else if (check.InterruptRequested()) {
return IrregexpInterpreter::RETRY;
}
} else {
DCHECK(call_origin == RegExp::CallOrigin::kFromRuntime);
// Prepare for possible GC.
HandleScope handles(isolate);
Handle<ByteArray> code_handle(*code_array_out, isolate);
Handle<String> subject_handle(*subject_string_out, isolate);
if (js_has_overflowed) {
return ThrowStackOverflow(isolate, call_origin);
} else if (check.InterruptRequested()) {
const bool was_one_byte =
String::IsOneByteRepresentationUnderneath(*subject_string_out);
Tagged<Object> result;
{
AllowGarbageCollection yes_gc;
result = isolate->stack_guard()->HandleInterrupts();
}
if (IsException(result, isolate)) {
return IrregexpInterpreter::EXCEPTION;
}
// If we changed between a LATIN1 and a UC16 string, we need to
// restart regexp matching with the appropriate template instantiation of
// RawMatch.
if (String::IsOneByteRepresentationUnderneath(*subject_handle) !=
was_one_byte) {
return IrregexpInterpreter::RETRY;
}
UpdateCodeAndSubjectReferences(
isolate, code_handle, subject_handle, code_array_out, code_base_out,
pc_out, subject_string_out, subject_string_vector_out);
}
}
return IrregexpInterpreter::SUCCESS;
}
bool CheckBitInTable(const uint32_t current_char, const uint8_t* const table) {
int mask = RegExpMacroAssembler::kTableMask;
int b = table[(current_char & mask) >> kBitsPerByteLog2];
int bit = (current_char & (kBitsPerByte - 1));
return (b & (1 << bit)) != 0;
}
// Returns true iff 0 <= index < length.
bool IndexIsInBounds(int index, int length) {
DCHECK_GE(length, 0);
return static_cast<uintptr_t>(index) < static_cast<uintptr_t>(length);
}
// If computed gotos are supported by the compiler, we can get addresses to
// labels directly in C/C++. Every bytecode handler has its own label and we
// store the addresses in a dispatch table indexed by bytecode. To execute the
// next handler we simply jump (goto) directly to its address.
#if V8_USE_COMPUTED_GOTO
#define BC_LABEL(name) BC_##name:
#define DECODE() \
do { \
next_insn = Load32Aligned(next_pc); \
next_handler_addr = dispatch_table[next_insn & BYTECODE_MASK]; \
} while (false)
#define DISPATCH() \
pc = next_pc; \
insn = next_insn; \
goto* next_handler_addr
// Without computed goto support, we fall back to a simple switch-based
// dispatch (A large switch statement inside a loop with a case for every
// bytecode).
#else // V8_USE_COMPUTED_GOTO
#define BC_LABEL(name) case BC_##name:
#define DECODE() next_insn = Load32Aligned(next_pc)
#define DISPATCH() \
pc = next_pc; \
insn = next_insn; \
goto switch_dispatch_continuation
#endif // V8_USE_COMPUTED_GOTO
// ADVANCE/SET_PC_FROM_OFFSET are separated from DISPATCH, because ideally some
// instructions can be executed between ADVANCE/SET_PC_FROM_OFFSET and DISPATCH.
// We want those two macros as far apart as possible, because the goto in
// DISPATCH is dependent on a memory load in ADVANCE/SET_PC_FROM_OFFSET. If we
// don't hit the cache and have to fetch the next handler address from physical
// memory, instructions between ADVANCE/SET_PC_FROM_OFFSET and DISPATCH can
// potentially be executed unconditionally, reducing memory stall.
#define ADVANCE(name) \
next_pc = pc + RegExpBytecodeLength(BC_##name); \
DECODE()
#define SET_PC_FROM_OFFSET(offset) \
next_pc = code_base + offset; \
DECODE()
// Current position mutations.
#define SET_CURRENT_POSITION(value) \
do { \
current = (value); \
DCHECK(base::IsInRange(current, 0, subject.length())); \
} while (false)
#define ADVANCE_CURRENT_POSITION(by) SET_CURRENT_POSITION(current + (by))
#ifdef DEBUG
#define BYTECODE(name) \
BC_LABEL(name) \
MaybeTraceInterpreter(code_base, pc, backtrack_stack.sp(), current, \
current_char, RegExpBytecodeLength(BC_##name), #name);
#else
#define BYTECODE(name) BC_LABEL(name)
#endif // DEBUG
template <typename Char>
IrregexpInterpreter::Result RawMatch(
Isolate* isolate, Tagged<ByteArray> code_array,
Tagged<String> subject_string, base::Vector<const Char> subject,
int* output_registers, int output_register_count, int total_register_count,
int current, uint32_t current_char, RegExp::CallOrigin call_origin,
const uint32_t backtrack_limit) {
DisallowGarbageCollection no_gc;
#if V8_USE_COMPUTED_GOTO
// We have to make sure that no OOB access to the dispatch table is possible and
// all values are valid label addresses.
// Otherwise jumps to arbitrary addresses could potentially happen.
// This is ensured as follows:
// Every index to the dispatch table gets masked using BYTECODE_MASK in
// DECODE(). This way we can only get values between 0 (only the least
// significant byte of an integer is used) and kRegExpPaddedBytecodeCount - 1
// (BYTECODE_MASK is defined to be exactly this value).
// All entries from kRegExpBytecodeCount to kRegExpPaddedBytecodeCount have to
// be filled with BREAKs (invalid operation).
// Fill dispatch table from last defined bytecode up to the next power of two
// with BREAK (invalid operation).
// TODO(pthier): Find a way to fill up automatically (at compile time)
// 59 real bytecodes -> 5 fillers
#define BYTECODE_FILLER_ITERATOR(V) \
V(BREAK) /* 1 */ \
V(BREAK) /* 2 */ \
V(BREAK) /* 3 */ \
V(BREAK) /* 4 */ \
V(BREAK) /* 5 */
#define COUNT(...) +1
static constexpr int kRegExpBytecodeFillerCount =
BYTECODE_FILLER_ITERATOR(COUNT);
#undef COUNT
// Make sure kRegExpPaddedBytecodeCount is actually the closest possible power
// of two.
DCHECK_EQ(kRegExpPaddedBytecodeCount,
base::bits::RoundUpToPowerOfTwo32(kRegExpBytecodeCount));
// Make sure every bytecode we get by using BYTECODE_MASK is well defined.
static_assert(kRegExpBytecodeCount <= kRegExpPaddedBytecodeCount);
static_assert(kRegExpBytecodeCount + kRegExpBytecodeFillerCount ==
kRegExpPaddedBytecodeCount);
#define DECLARE_DISPATCH_TABLE_ENTRY(name, ...) &&BC_##name,
static const void* const dispatch_table[kRegExpPaddedBytecodeCount] = {
BYTECODE_ITERATOR(DECLARE_DISPATCH_TABLE_ENTRY)
BYTECODE_FILLER_ITERATOR(DECLARE_DISPATCH_TABLE_ENTRY)};
#undef DECLARE_DISPATCH_TABLE_ENTRY
#undef BYTECODE_FILLER_ITERATOR
#endif // V8_USE_COMPUTED_GOTO
const uint8_t* pc = code_array->GetDataStartAddress();
const uint8_t* code_base = pc;
InterpreterRegisters registers(total_register_count, output_registers,
output_register_count);
BacktrackStack backtrack_stack;
uint32_t backtrack_count = 0;
#ifdef DEBUG
if (v8_flags.trace_regexp_bytecodes) {
PrintF("\n\nStart bytecode interpreter\n\n");
}
#endif
while (true) {
const uint8_t* next_pc = pc;
int32_t insn;
int32_t next_insn;
#if V8_USE_COMPUTED_GOTO
const void* next_handler_addr;
DECODE();
DISPATCH();
#else
insn = Load32Aligned(pc);
switch (insn & BYTECODE_MASK) {
#endif // V8_USE_COMPUTED_GOTO
BYTECODE(BREAK) { UNREACHABLE(); }
BYTECODE(PUSH_CP) {
ADVANCE(PUSH_CP);
if (!backtrack_stack.push(current)) {
return MaybeThrowStackOverflow(isolate, call_origin);
}
DISPATCH();
}
BYTECODE(PUSH_BT) {
ADVANCE(PUSH_BT);
if (!backtrack_stack.push(Load32Aligned(pc + 4))) {
return MaybeThrowStackOverflow(isolate, call_origin);
}
DISPATCH();
}
BYTECODE(PUSH_REGISTER) {
ADVANCE(PUSH_REGISTER);
if (!backtrack_stack.push(registers[LoadPacked24Unsigned(insn)])) {
return MaybeThrowStackOverflow(isolate, call_origin);
}
DISPATCH();
}
BYTECODE(SET_REGISTER) {
ADVANCE(SET_REGISTER);
registers[LoadPacked24Unsigned(insn)] = Load32Aligned(pc + 4);
DISPATCH();
}
BYTECODE(ADVANCE_REGISTER) {
ADVANCE(ADVANCE_REGISTER);
registers[LoadPacked24Unsigned(insn)] += Load32Aligned(pc + 4);
DISPATCH();
}
BYTECODE(SET_REGISTER_TO_CP) {
ADVANCE(SET_REGISTER_TO_CP);
registers[LoadPacked24Unsigned(insn)] = current + Load32Aligned(pc + 4);
DISPATCH();
}
BYTECODE(SET_CP_TO_REGISTER) {
ADVANCE(SET_CP_TO_REGISTER);
SET_CURRENT_POSITION(registers[LoadPacked24Unsigned(insn)]);
DISPATCH();
}
BYTECODE(SET_REGISTER_TO_SP) {
ADVANCE(SET_REGISTER_TO_SP);
registers[LoadPacked24Unsigned(insn)] = backtrack_stack.sp();
DISPATCH();
}
BYTECODE(SET_SP_TO_REGISTER) {
ADVANCE(SET_SP_TO_REGISTER);
backtrack_stack.set_sp(registers[LoadPacked24Unsigned(insn)]);
DISPATCH();
}
BYTECODE(POP_CP) {
ADVANCE(POP_CP);
SET_CURRENT_POSITION(backtrack_stack.pop());
DISPATCH();
}
BYTECODE(POP_BT) {
static_assert(JSRegExp::kNoBacktrackLimit == 0);
if (++backtrack_count == backtrack_limit) {
int return_code = LoadPacked24Signed(insn);
return static_cast<IrregexpInterpreter::Result>(return_code);
}
IrregexpInterpreter::Result return_code =
HandleInterrupts(isolate, call_origin, &code_array, &subject_string,
&code_base, &subject, &pc);
if (return_code != IrregexpInterpreter::SUCCESS) return return_code;
SET_PC_FROM_OFFSET(backtrack_stack.pop());
DISPATCH();
}
BYTECODE(POP_REGISTER) {
ADVANCE(POP_REGISTER);
registers[LoadPacked24Unsigned(insn)] = backtrack_stack.pop();
DISPATCH();
}
BYTECODE(FAIL) {
isolate->counters()->regexp_backtracks()->AddSample(
static_cast<int>(backtrack_count));
return IrregexpInterpreter::FAILURE;
}
BYTECODE(SUCCEED) {
isolate->counters()->regexp_backtracks()->AddSample(
static_cast<int>(backtrack_count));
registers.CopyToOutputRegisters();
return IrregexpInterpreter::SUCCESS;
}
BYTECODE(ADVANCE_CP) {
ADVANCE(ADVANCE_CP);
ADVANCE_CURRENT_POSITION(LoadPacked24Signed(insn));
DISPATCH();
}
BYTECODE(GOTO) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 4));
DISPATCH();
}
BYTECODE(ADVANCE_CP_AND_GOTO) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 4));
ADVANCE_CURRENT_POSITION(LoadPacked24Signed(insn));
DISPATCH();
}
BYTECODE(CHECK_GREEDY) {
if (current == backtrack_stack.peek()) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 4));
backtrack_stack.pop();
} else {
ADVANCE(CHECK_GREEDY);
}
DISPATCH();
}
BYTECODE(LOAD_CURRENT_CHAR) {
int pos = current + LoadPacked24Signed(insn);
if (pos >= subject.length() || pos < 0) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 4));
} else {
ADVANCE(LOAD_CURRENT_CHAR);
current_char = subject[pos];
}
DISPATCH();
}
BYTECODE(LOAD_CURRENT_CHAR_UNCHECKED) {
ADVANCE(LOAD_CURRENT_CHAR_UNCHECKED);
int pos = current + LoadPacked24Signed(insn);
current_char = subject[pos];
DISPATCH();
}
BYTECODE(LOAD_2_CURRENT_CHARS) {
int pos = current + LoadPacked24Signed(insn);
if (pos + 2 > subject.length() || pos < 0) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 4));
} else {
ADVANCE(LOAD_2_CURRENT_CHARS);
Char next = subject[pos + 1];
current_char = (subject[pos] | (next << (kBitsPerByte * sizeof(Char))));
}
DISPATCH();
}
BYTECODE(LOAD_2_CURRENT_CHARS_UNCHECKED) {
ADVANCE(LOAD_2_CURRENT_CHARS_UNCHECKED);
int pos = current + LoadPacked24Signed(insn);
Char next = subject[pos + 1];
current_char = (subject[pos] | (next << (kBitsPerByte * sizeof(Char))));
DISPATCH();
}
BYTECODE(LOAD_4_CURRENT_CHARS) {
DCHECK_EQ(1, sizeof(Char));
int pos = current + LoadPacked24Signed(insn);
if (pos + 4 > subject.length() || pos < 0) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 4));
} else {
ADVANCE(LOAD_4_CURRENT_CHARS);
Char next1 = subject[pos + 1];
Char next2 = subject[pos + 2];
Char next3 = subject[pos + 3];
current_char =
(subject[pos] | (next1 << 8) | (next2 << 16) | (next3 << 24));
}
DISPATCH();
}
BYTECODE(LOAD_4_CURRENT_CHARS_UNCHECKED) {
ADVANCE(LOAD_4_CURRENT_CHARS_UNCHECKED);
DCHECK_EQ(1, sizeof(Char));
int pos = current + LoadPacked24Signed(insn);
Char next1 = subject[pos + 1];
Char next2 = subject[pos + 2];
Char next3 = subject[pos + 3];
current_char =
(subject[pos] | (next1 << 8) | (next2 << 16) | (next3 << 24));
DISPATCH();
}
BYTECODE(CHECK_4_CHARS) {
uint32_t c = Load32Aligned(pc + 4);
if (c == current_char) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 8));
} else {
ADVANCE(CHECK_4_CHARS);
}
DISPATCH();
}
BYTECODE(CHECK_CHAR) {
uint32_t c = LoadPacked24Unsigned(insn);
if (c == current_char) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 4));
} else {
ADVANCE(CHECK_CHAR);
}
DISPATCH();
}
BYTECODE(CHECK_NOT_4_CHARS) {
uint32_t c = Load32Aligned(pc + 4);
if (c != current_char) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 8));
} else {
ADVANCE(CHECK_NOT_4_CHARS);
}
DISPATCH();
}
BYTECODE(CHECK_NOT_CHAR) {
uint32_t c = LoadPacked24Unsigned(insn);
if (c != current_char) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 4));
} else {
ADVANCE(CHECK_NOT_CHAR);
}
DISPATCH();
}
BYTECODE(AND_CHECK_4_CHARS) {
uint32_t c = Load32Aligned(pc + 4);
if (c == (current_char & Load32Aligned(pc + 8))) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 12));
} else {
ADVANCE(AND_CHECK_4_CHARS);
}
DISPATCH();
}
BYTECODE(AND_CHECK_CHAR) {
uint32_t c = LoadPacked24Unsigned(insn);
if (c == (current_char & Load32Aligned(pc + 4))) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 8));
} else {
ADVANCE(AND_CHECK_CHAR);
}
DISPATCH();
}
BYTECODE(AND_CHECK_NOT_4_CHARS) {
uint32_t c = Load32Aligned(pc + 4);
if (c != (current_char & Load32Aligned(pc + 8))) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 12));
} else {
ADVANCE(AND_CHECK_NOT_4_CHARS);
}
DISPATCH();
}
BYTECODE(AND_CHECK_NOT_CHAR) {
uint32_t c = LoadPacked24Unsigned(insn);
if (c != (current_char & Load32Aligned(pc + 4))) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 8));
} else {
ADVANCE(AND_CHECK_NOT_CHAR);
}
DISPATCH();
}
BYTECODE(MINUS_AND_CHECK_NOT_CHAR) {
uint32_t c = LoadPacked24Unsigned(insn);
uint32_t minus = Load16Aligned(pc + 4);
uint32_t mask = Load16Aligned(pc + 6);
if (c != ((current_char - minus) & mask)) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 8));
} else {
ADVANCE(MINUS_AND_CHECK_NOT_CHAR);
}
DISPATCH();
}
BYTECODE(CHECK_CHAR_IN_RANGE) {
uint32_t from = Load16Aligned(pc + 4);
uint32_t to = Load16Aligned(pc + 6);
if (from <= current_char && current_char <= to) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 8));
} else {
ADVANCE(CHECK_CHAR_IN_RANGE);
}
DISPATCH();
}
BYTECODE(CHECK_CHAR_NOT_IN_RANGE) {
uint32_t from = Load16Aligned(pc + 4);
uint32_t to = Load16Aligned(pc + 6);
if (from > current_char || current_char > to) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 8));
} else {
ADVANCE(CHECK_CHAR_NOT_IN_RANGE);
}
DISPATCH();
}
BYTECODE(CHECK_BIT_IN_TABLE) {
if (CheckBitInTable(current_char, pc + 8)) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 4));
} else {
ADVANCE(CHECK_BIT_IN_TABLE);
}
DISPATCH();
}
BYTECODE(CHECK_LT) {
uint32_t limit = LoadPacked24Unsigned(insn);
if (current_char < limit) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 4));
} else {
ADVANCE(CHECK_LT);
}
DISPATCH();
}
BYTECODE(CHECK_GT) {
uint32_t limit = LoadPacked24Unsigned(insn);
if (current_char > limit) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 4));
} else {
ADVANCE(CHECK_GT);
}
DISPATCH();
}
BYTECODE(CHECK_REGISTER_LT) {
if (registers[LoadPacked24Unsigned(insn)] < Load32Aligned(pc + 4)) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 8));
} else {
ADVANCE(CHECK_REGISTER_LT);
}
DISPATCH();
}
BYTECODE(CHECK_REGISTER_GE) {
if (registers[LoadPacked24Unsigned(insn)] >= Load32Aligned(pc + 4)) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 8));
} else {
ADVANCE(CHECK_REGISTER_GE);
}
DISPATCH();
}
BYTECODE(CHECK_REGISTER_EQ_POS) {
if (registers[LoadPacked24Unsigned(insn)] == current) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 4));
} else {
ADVANCE(CHECK_REGISTER_EQ_POS);
}
DISPATCH();
}
BYTECODE(CHECK_NOT_REGS_EQUAL) {
if (registers[LoadPacked24Unsigned(insn)] ==
registers[Load32Aligned(pc + 4)]) {
ADVANCE(CHECK_NOT_REGS_EQUAL);
} else {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 8));
}
DISPATCH();
}
BYTECODE(CHECK_NOT_BACK_REF) {
int from = registers[LoadPacked24Unsigned(insn)];
int len = registers[LoadPacked24Unsigned(insn) + 1] - from;
if (from >= 0 && len > 0) {
if (current + len > subject.length() ||
!CompareCharsEqual(&subject[from], &subject[current], len)) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 4));
DISPATCH();
}
ADVANCE_CURRENT_POSITION(len);
}
ADVANCE(CHECK_NOT_BACK_REF);
DISPATCH();
}
BYTECODE(CHECK_NOT_BACK_REF_BACKWARD) {
int from = registers[LoadPacked24Unsigned(insn)];
int len = registers[LoadPacked24Unsigned(insn) + 1] - from;
if (from >= 0 && len > 0) {
if (current - len < 0 ||
!CompareCharsEqual(&subject[from], &subject[current - len], len)) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 4));
DISPATCH();
}
SET_CURRENT_POSITION(current - len);
}
ADVANCE(CHECK_NOT_BACK_REF_BACKWARD);
DISPATCH();
}
BYTECODE(CHECK_NOT_BACK_REF_NO_CASE_UNICODE) {
int from = registers[LoadPacked24Unsigned(insn)];
int len = registers[LoadPacked24Unsigned(insn) + 1] - from;
if (from >= 0 && len > 0) {
if (current + len > subject.length() ||
!BackRefMatchesNoCase(isolate, from, current, len, subject, true)) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 4));
DISPATCH();
}
ADVANCE_CURRENT_POSITION(len);
}
ADVANCE(CHECK_NOT_BACK_REF_NO_CASE_UNICODE);
DISPATCH();
}
BYTECODE(CHECK_NOT_BACK_REF_NO_CASE) {
int from = registers[LoadPacked24Unsigned(insn)];
int len = registers[LoadPacked24Unsigned(insn) + 1] - from;
if (from >= 0 && len > 0) {
if (current + len > subject.length() ||
!BackRefMatchesNoCase(isolate, from, current, len, subject,
false)) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 4));
DISPATCH();
}
ADVANCE_CURRENT_POSITION(len);
}
ADVANCE(CHECK_NOT_BACK_REF_NO_CASE);
DISPATCH();
}
BYTECODE(CHECK_NOT_BACK_REF_NO_CASE_UNICODE_BACKWARD) {
int from = registers[LoadPacked24Unsigned(insn)];
int len = registers[LoadPacked24Unsigned(insn) + 1] - from;
if (from >= 0 && len > 0) {
if (current - len < 0 ||
!BackRefMatchesNoCase(isolate, from, current - len, len, subject,
true)) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 4));
DISPATCH();
}
SET_CURRENT_POSITION(current - len);
}
ADVANCE(CHECK_NOT_BACK_REF_NO_CASE_UNICODE_BACKWARD);
DISPATCH();
}
BYTECODE(CHECK_NOT_BACK_REF_NO_CASE_BACKWARD) {
int from = registers[LoadPacked24Unsigned(insn)];
int len = registers[LoadPacked24Unsigned(insn) + 1] - from;
if (from >= 0 && len > 0) {
if (current - len < 0 ||
!BackRefMatchesNoCase(isolate, from, current - len, len, subject,
false)) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 4));
DISPATCH();
}
SET_CURRENT_POSITION(current - len);
}
ADVANCE(CHECK_NOT_BACK_REF_NO_CASE_BACKWARD);
DISPATCH();
}
BYTECODE(CHECK_AT_START) {
if (current + LoadPacked24Signed(insn) == 0) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 4));
} else {
ADVANCE(CHECK_AT_START);
}
DISPATCH();
}
BYTECODE(CHECK_NOT_AT_START) {
if (current + LoadPacked24Signed(insn) == 0) {
ADVANCE(CHECK_NOT_AT_START);
} else {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 4));
}
DISPATCH();
}
BYTECODE(SET_CURRENT_POSITION_FROM_END) {
ADVANCE(SET_CURRENT_POSITION_FROM_END);
int by = LoadPacked24Unsigned(insn);
if (subject.length() - current > by) {
SET_CURRENT_POSITION(subject.length() - by);
current_char = subject[current - 1];
}
DISPATCH();
}
BYTECODE(CHECK_CURRENT_POSITION) {
int pos = current + LoadPacked24Signed(insn);
if (pos > subject.length() || pos < 0) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 4));
} else {
ADVANCE(CHECK_CURRENT_POSITION);
}
DISPATCH();
}
BYTECODE(SKIP_UNTIL_CHAR) {
int32_t load_offset = LoadPacked24Signed(insn);
int32_t advance = Load16AlignedSigned(pc + 4);
uint32_t c = Load16Aligned(pc + 6);
while (IndexIsInBounds(current + load_offset, subject.length())) {
current_char = subject[current + load_offset];
if (c == current_char) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 8));
DISPATCH();
}
ADVANCE_CURRENT_POSITION(advance);
}
SET_PC_FROM_OFFSET(Load32Aligned(pc + 12));
DISPATCH();
}
BYTECODE(SKIP_UNTIL_CHAR_AND) {
int32_t load_offset = LoadPacked24Signed(insn);
int32_t advance = Load16AlignedSigned(pc + 4);
uint16_t c = Load16Aligned(pc + 6);
uint32_t mask = Load32Aligned(pc + 8);
int32_t maximum_offset = Load32Aligned(pc + 12);
while (static_cast<uintptr_t>(current + maximum_offset) <=
static_cast<uintptr_t>(subject.length())) {
current_char = subject[current + load_offset];
if (c == (current_char & mask)) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 16));
DISPATCH();
}
ADVANCE_CURRENT_POSITION(advance);
}
SET_PC_FROM_OFFSET(Load32Aligned(pc + 20));
DISPATCH();
}
BYTECODE(SKIP_UNTIL_CHAR_POS_CHECKED) {
int32_t load_offset = LoadPacked24Signed(insn);
int32_t advance = Load16AlignedSigned(pc + 4);
uint16_t c = Load16Aligned(pc + 6);
int32_t maximum_offset = Load32Aligned(pc + 8);
while (static_cast<uintptr_t>(current + maximum_offset) <=
static_cast<uintptr_t>(subject.length())) {
current_char = subject[current + load_offset];
if (c == current_char) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 12));
DISPATCH();
}
ADVANCE_CURRENT_POSITION(advance);
}
SET_PC_FROM_OFFSET(Load32Aligned(pc + 16));
DISPATCH();
}
BYTECODE(SKIP_UNTIL_BIT_IN_TABLE) {
int32_t load_offset = LoadPacked24Signed(insn);
int32_t advance = Load16AlignedSigned(pc + 4);
const uint8_t* table = pc + 8;
while (IndexIsInBounds(current + load_offset, subject.length())) {
current_char = subject[current + load_offset];
if (CheckBitInTable(current_char, table)) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 24));
DISPATCH();
}
ADVANCE_CURRENT_POSITION(advance);
}
SET_PC_FROM_OFFSET(Load32Aligned(pc + 28));
DISPATCH();
}
BYTECODE(SKIP_UNTIL_GT_OR_NOT_BIT_IN_TABLE) {
int32_t load_offset = LoadPacked24Signed(insn);
int32_t advance = Load16AlignedSigned(pc + 4);
uint16_t limit = Load16Aligned(pc + 6);
const uint8_t* table = pc + 8;
while (IndexIsInBounds(current + load_offset, subject.length())) {
current_char = subject[current + load_offset];
if (current_char > limit) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 24));
DISPATCH();
}
if (!CheckBitInTable(current_char, table)) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 24));
DISPATCH();
}
ADVANCE_CURRENT_POSITION(advance);
}
SET_PC_FROM_OFFSET(Load32Aligned(pc + 28));
DISPATCH();
}
BYTECODE(SKIP_UNTIL_CHAR_OR_CHAR) {
int32_t load_offset = LoadPacked24Signed(insn);
int32_t advance = Load32Aligned(pc + 4);
uint16_t c = Load16Aligned(pc + 8);
uint16_t c2 = Load16Aligned(pc + 10);
while (IndexIsInBounds(current + load_offset, subject.length())) {
current_char = subject[current + load_offset];
// The two if-statements below are split up intentionally, as combining
// them seems to result in register allocation behaving quite
// differently and slowing down the resulting code.
if (c == current_char) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 12));
DISPATCH();
}
if (c2 == current_char) {
SET_PC_FROM_OFFSET(Load32Aligned(pc + 12));
DISPATCH();
}
ADVANCE_CURRENT_POSITION(advance);
}
SET_PC_FROM_OFFSET(Load32Aligned(pc + 16));
DISPATCH();
}
#if V8_USE_COMPUTED_GOTO
// Lint gets confused a lot if we just use !V8_USE_COMPUTED_GOTO or ifndef
// V8_USE_COMPUTED_GOTO here.
#else
default:
UNREACHABLE();
}
// Label we jump to in DISPATCH(). There must be no instructions between the
// end of the switch, this label and the end of the loop.
switch_dispatch_continuation : {}
#endif // V8_USE_COMPUTED_GOTO
}
}
#undef BYTECODE
#undef ADVANCE_CURRENT_POSITION
#undef SET_CURRENT_POSITION
#undef DISPATCH
#undef DECODE
#undef SET_PC_FROM_OFFSET
#undef ADVANCE
#undef BC_LABEL
#undef V8_USE_COMPUTED_GOTO
} // namespace
// static
IrregexpInterpreter::Result IrregexpInterpreter::Match(
Isolate* isolate, Tagged<JSRegExp> regexp, Tagged<String> subject_string,
int* output_registers, int output_register_count, int start_position,
RegExp::CallOrigin call_origin) {
if (v8_flags.regexp_tier_up) regexp->TierUpTick();
bool is_one_byte = String::IsOneByteRepresentationUnderneath(subject_string);
Tagged<ByteArray> code_array = ByteArray::cast(regexp->bytecode(is_one_byte));
int total_register_count = regexp->max_register_count();
return MatchInternal(isolate, code_array, subject_string, output_registers,
output_register_count, total_register_count,
start_position, call_origin, regexp->backtrack_limit());
}
IrregexpInterpreter::Result IrregexpInterpreter::MatchInternal(
Isolate* isolate, Tagged<ByteArray> code_array,
Tagged<String> subject_string, int* output_registers,
int output_register_count, int total_register_count, int start_position,
RegExp::CallOrigin call_origin, uint32_t backtrack_limit) {
DCHECK(subject_string->IsFlat());
// TODO(chromium:1262676): Remove this CHECK once fixed.
CHECK(IsByteArray(code_array));
// Note: Heap allocation *is* allowed in two situations if calling from
// Runtime:
// 1. When creating & throwing a stack overflow exception. The interpreter
// aborts afterwards, and thus possible-moved objects are never used.
// 2. When handling interrupts. We manually relocate unhandlified references
// after interrupts have run.
DisallowGarbageCollection no_gc;
base::uc16 previous_char = '\n';
String::FlatContent subject_content = subject_string->GetFlatContent(no_gc);
// Because interrupts can result in GC and string content relocation, the
// checksum verification in FlatContent may fail even though this code is
// safe. See (2) above.
subject_content.UnsafeDisableChecksumVerification();
if (subject_content.IsOneByte()) {
base::Vector<const uint8_t> subject_vector =
subject_content.ToOneByteVector();
if (start_position != 0) previous_char = subject_vector[start_position - 1];
return RawMatch(isolate, code_array, subject_string, subject_vector,
output_registers, output_register_count,
total_register_count, start_position, previous_char,
call_origin, backtrack_limit);
} else {
DCHECK(subject_content.IsTwoByte());
base::Vector<const base::uc16> subject_vector =
subject_content.ToUC16Vector();
if (start_position != 0) previous_char = subject_vector[start_position - 1];
return RawMatch(isolate, code_array, subject_string, subject_vector,
output_registers, output_register_count,
total_register_count, start_position, previous_char,
call_origin, backtrack_limit);
}
}
#ifndef COMPILING_IRREGEXP_FOR_EXTERNAL_EMBEDDER
// This method is called through an external reference from RegExpExecInternal
// builtin.
IrregexpInterpreter::Result IrregexpInterpreter::MatchForCallFromJs(
Address subject, int32_t start_position, Address, Address,
int* output_registers, int32_t output_register_count,
RegExp::CallOrigin call_origin, Isolate* isolate, Address regexp) {
DCHECK_NOT_NULL(isolate);
DCHECK_NOT_NULL(output_registers);
DCHECK(call_origin == RegExp::CallOrigin::kFromJs);
DisallowGarbageCollection no_gc;
DisallowJavascriptExecution no_js(isolate);
DisallowHandleAllocation no_handles;
DisallowHandleDereference no_deref;
Tagged<String> subject_string = String::cast(Tagged<Object>(subject));
Tagged<JSRegExp> regexp_obj = JSRegExp::cast(Tagged<Object>(regexp));
if (regexp_obj->MarkedForTierUp()) {
// Returning RETRY will re-enter through runtime, where actual recompilation
// for tier-up takes place.
return IrregexpInterpreter::RETRY;
}
return Match(isolate, regexp_obj, subject_string, output_registers,
output_register_count, start_position, call_origin);
}
#endif // !COMPILING_IRREGEXP_FOR_EXTERNAL_EMBEDDER
IrregexpInterpreter::Result IrregexpInterpreter::MatchForCallFromRuntime(
Isolate* isolate, Handle<JSRegExp> regexp, Handle<String> subject_string,
int* output_registers, int output_register_count, int start_position) {
return Match(isolate, *regexp, *subject_string, output_registers,
output_register_count, start_position,
RegExp::CallOrigin::kFromRuntime);
}
} // namespace internal
} // namespace v8
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