// 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.
#ifdef V8_INTERPRETED_REGEXP
#include "src/regexp/interpreter-irregexp.h"
#include "src/ast/ast.h"
#include "src/objects-inl.h"
#include "src/regexp/bytecodes-irregexp.h"
#include "src/regexp/jsregexp.h"
#include "src/regexp/regexp-macro-assembler.h"
#include "src/unicode.h"
#include "src/utils.h"
#ifdef V8_I18N_SUPPORT
#include "unicode/uchar.h"
#endif // V8_I18N_SUPPORT
namespace v8 {
namespace internal {
typedef unibrow::Mapping<unibrow::Ecma262Canonicalize> Canonicalize;
static bool BackRefMatchesNoCase(Isolate* isolate, int from, int current,
int len, Vector<const uc16> subject,
bool unicode) {
Address offset_a =
reinterpret_cast<Address>(const_cast<uc16*>(&subject.at(from)));
Address offset_b =
reinterpret_cast<Address>(const_cast<uc16*>(&subject.at(current)));
size_t length = len * kUC16Size;
return RegExpMacroAssembler::CaseInsensitiveCompareUC16(
offset_a, offset_b, length, unicode ? nullptr : isolate) == 1;
}
static bool BackRefMatchesNoCase(Isolate* isolate, int from, int current,
int len, 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
static void TraceInterpreter(const byte* code_base,
const byte* pc,
int stack_depth,
int current_position,
uint32_t current_char,
int bytecode_length,
const char* bytecode_name) {
if (FLAG_trace_regexp_bytecodes) {
bool printable = (current_char < 127 && current_char >= 32);
const char* format =
printable ?
"pc = %02x, sp = %d, curpos = %d, curchar = %08x (%c), bc = %s" :
"pc = %02x, sp = %d, curpos = %d, curchar = %08x .%c., bc = %s";
PrintF(format,
pc - code_base,
stack_depth,
current_position,
current_char,
printable ? current_char : '.',
bytecode_name);
for (int i = 0; i < bytecode_length; i++) {
printf(", %02x", pc[i]);
}
printf(" ");
for (int i = 1; i < bytecode_length; i++) {
unsigned char b = pc[i];
if (b < 127 && b >= 32) {
printf("%c", b);
} else {
printf(".");
}
}
printf("\n");
}
}
#define BYTECODE(name) \
case BC_##name: \
TraceInterpreter(code_base, \
pc, \
static_cast<int>(backtrack_sp - backtrack_stack_base), \
current, \
current_char, \
BC_##name##_LENGTH, \
#name);
#else
#define BYTECODE(name) \
case BC_##name:
#endif
static int32_t Load32Aligned(const byte* pc) {
DCHECK((reinterpret_cast<intptr_t>(pc) & 3) == 0);
return *reinterpret_cast<const int32_t *>(pc);
}
static int32_t Load16Aligned(const byte* pc) {
DCHECK((reinterpret_cast<intptr_t>(pc) & 1) == 0);
return *reinterpret_cast<const uint16_t *>(pc);
}
// A simple abstraction over the backtracking stack used by the interpreter.
// This backtracking stack does not grow automatically, but it ensures that the
// the memory held by the stack is released or remembered in a cache if the
// matching terminates.
class BacktrackStack {
public:
BacktrackStack() { data_ = NewArray<int>(kBacktrackStackSize); }
~BacktrackStack() {
DeleteArray(data_);
}
int* data() const { return data_; }
int max_size() const { return kBacktrackStackSize; }
private:
static const int kBacktrackStackSize = 10000;
int* data_;
DISALLOW_COPY_AND_ASSIGN(BacktrackStack);
};
template <typename Char>
static RegExpImpl::IrregexpResult RawMatch(Isolate* isolate,
const byte* code_base,
Vector<const Char> subject,
int* registers,
int current,
uint32_t current_char) {
const byte* pc = code_base;
// BacktrackStack ensures that the memory allocated for the backtracking stack
// is returned to the system or cached if there is no stack being cached at
// the moment.
BacktrackStack backtrack_stack;
int* backtrack_stack_base = backtrack_stack.data();
int* backtrack_sp = backtrack_stack_base;
int backtrack_stack_space = backtrack_stack.max_size();
#ifdef DEBUG
if (FLAG_trace_regexp_bytecodes) {
PrintF("\n\nStart bytecode interpreter\n\n");
}
#endif
while (true) {
int32_t insn = Load32Aligned(pc);
switch (insn & BYTECODE_MASK) {
BYTECODE(BREAK)
UNREACHABLE();
return RegExpImpl::RE_FAILURE;
BYTECODE(PUSH_CP)
if (--backtrack_stack_space < 0) {
return RegExpImpl::RE_EXCEPTION;
}
*backtrack_sp++ = current;
pc += BC_PUSH_CP_LENGTH;
break;
BYTECODE(PUSH_BT)
if (--backtrack_stack_space < 0) {
return RegExpImpl::RE_EXCEPTION;
}
*backtrack_sp++ = Load32Aligned(pc + 4);
pc += BC_PUSH_BT_LENGTH;
break;
BYTECODE(PUSH_REGISTER)
if (--backtrack_stack_space < 0) {
return RegExpImpl::RE_EXCEPTION;
}
*backtrack_sp++ = registers[insn >> BYTECODE_SHIFT];
pc += BC_PUSH_REGISTER_LENGTH;
break;
BYTECODE(SET_REGISTER)
registers[insn >> BYTECODE_SHIFT] = Load32Aligned(pc + 4);
pc += BC_SET_REGISTER_LENGTH;
break;
BYTECODE(ADVANCE_REGISTER)
registers[insn >> BYTECODE_SHIFT] += Load32Aligned(pc + 4);
pc += BC_ADVANCE_REGISTER_LENGTH;
break;
BYTECODE(SET_REGISTER_TO_CP)
registers[insn >> BYTECODE_SHIFT] = current + Load32Aligned(pc + 4);
pc += BC_SET_REGISTER_TO_CP_LENGTH;
break;
BYTECODE(SET_CP_TO_REGISTER)
current = registers[insn >> BYTECODE_SHIFT];
pc += BC_SET_CP_TO_REGISTER_LENGTH;
break;
BYTECODE(SET_REGISTER_TO_SP)
registers[insn >> BYTECODE_SHIFT] =
static_cast<int>(backtrack_sp - backtrack_stack_base);
pc += BC_SET_REGISTER_TO_SP_LENGTH;
break;
BYTECODE(SET_SP_TO_REGISTER)
backtrack_sp = backtrack_stack_base + registers[insn >> BYTECODE_SHIFT];
backtrack_stack_space = backtrack_stack.max_size() -
static_cast<int>(backtrack_sp - backtrack_stack_base);
pc += BC_SET_SP_TO_REGISTER_LENGTH;
break;
BYTECODE(POP_CP)
backtrack_stack_space++;
--backtrack_sp;
current = *backtrack_sp;
pc += BC_POP_CP_LENGTH;
break;
BYTECODE(POP_BT)
backtrack_stack_space++;
--backtrack_sp;
pc = code_base + *backtrack_sp;
break;
BYTECODE(POP_REGISTER)
backtrack_stack_space++;
--backtrack_sp;
registers[insn >> BYTECODE_SHIFT] = *backtrack_sp;
pc += BC_POP_REGISTER_LENGTH;
break;
BYTECODE(FAIL)
return RegExpImpl::RE_FAILURE;
BYTECODE(SUCCEED)
return RegExpImpl::RE_SUCCESS;
BYTECODE(ADVANCE_CP)
current += insn >> BYTECODE_SHIFT;
pc += BC_ADVANCE_CP_LENGTH;
break;
BYTECODE(GOTO)
pc = code_base + Load32Aligned(pc + 4);
break;
BYTECODE(ADVANCE_CP_AND_GOTO)
current += insn >> BYTECODE_SHIFT;
pc = code_base + Load32Aligned(pc + 4);
break;
BYTECODE(CHECK_GREEDY)
if (current == backtrack_sp[-1]) {
backtrack_sp--;
backtrack_stack_space++;
pc = code_base + Load32Aligned(pc + 4);
} else {
pc += BC_CHECK_GREEDY_LENGTH;
}
break;
BYTECODE(LOAD_CURRENT_CHAR) {
int pos = current + (insn >> BYTECODE_SHIFT);
if (pos >= subject.length() || pos < 0) {
pc = code_base + Load32Aligned(pc + 4);
} else {
current_char = subject[pos];
pc += BC_LOAD_CURRENT_CHAR_LENGTH;
}
break;
}
BYTECODE(LOAD_CURRENT_CHAR_UNCHECKED) {
int pos = current + (insn >> BYTECODE_SHIFT);
current_char = subject[pos];
pc += BC_LOAD_CURRENT_CHAR_UNCHECKED_LENGTH;
break;
}
BYTECODE(LOAD_2_CURRENT_CHARS) {
int pos = current + (insn >> BYTECODE_SHIFT);
if (pos + 2 > subject.length() || pos < 0) {
pc = code_base + Load32Aligned(pc + 4);
} else {
Char next = subject[pos + 1];
current_char =
(subject[pos] | (next << (kBitsPerByte * sizeof(Char))));
pc += BC_LOAD_2_CURRENT_CHARS_LENGTH;
}
break;
}
BYTECODE(LOAD_2_CURRENT_CHARS_UNCHECKED) {
int pos = current + (insn >> BYTECODE_SHIFT);
Char next = subject[pos + 1];
current_char = (subject[pos] | (next << (kBitsPerByte * sizeof(Char))));
pc += BC_LOAD_2_CURRENT_CHARS_UNCHECKED_LENGTH;
break;
}
BYTECODE(LOAD_4_CURRENT_CHARS) {
DCHECK(sizeof(Char) == 1);
int pos = current + (insn >> BYTECODE_SHIFT);
if (pos + 4 > subject.length() || pos < 0) {
pc = code_base + Load32Aligned(pc + 4);
} else {
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));
pc += BC_LOAD_4_CURRENT_CHARS_LENGTH;
}
break;
}
BYTECODE(LOAD_4_CURRENT_CHARS_UNCHECKED) {
DCHECK(sizeof(Char) == 1);
int pos = current + (insn >> BYTECODE_SHIFT);
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));
pc += BC_LOAD_4_CURRENT_CHARS_UNCHECKED_LENGTH;
break;
}
BYTECODE(CHECK_4_CHARS) {
uint32_t c = Load32Aligned(pc + 4);
if (c == current_char) {
pc = code_base + Load32Aligned(pc + 8);
} else {
pc += BC_CHECK_4_CHARS_LENGTH;
}
break;
}
BYTECODE(CHECK_CHAR) {
uint32_t c = (insn >> BYTECODE_SHIFT);
if (c == current_char) {
pc = code_base + Load32Aligned(pc + 4);
} else {
pc += BC_CHECK_CHAR_LENGTH;
}
break;
}
BYTECODE(CHECK_NOT_4_CHARS) {
uint32_t c = Load32Aligned(pc + 4);
if (c != current_char) {
pc = code_base + Load32Aligned(pc + 8);
} else {
pc += BC_CHECK_NOT_4_CHARS_LENGTH;
}
break;
}
BYTECODE(CHECK_NOT_CHAR) {
uint32_t c = (insn >> BYTECODE_SHIFT);
if (c != current_char) {
pc = code_base + Load32Aligned(pc + 4);
} else {
pc += BC_CHECK_NOT_CHAR_LENGTH;
}
break;
}
BYTECODE(AND_CHECK_4_CHARS) {
uint32_t c = Load32Aligned(pc + 4);
if (c == (current_char & Load32Aligned(pc + 8))) {
pc = code_base + Load32Aligned(pc + 12);
} else {
pc += BC_AND_CHECK_4_CHARS_LENGTH;
}
break;
}
BYTECODE(AND_CHECK_CHAR) {
uint32_t c = (insn >> BYTECODE_SHIFT);
if (c == (current_char & Load32Aligned(pc + 4))) {
pc = code_base + Load32Aligned(pc + 8);
} else {
pc += BC_AND_CHECK_CHAR_LENGTH;
}
break;
}
BYTECODE(AND_CHECK_NOT_4_CHARS) {
uint32_t c = Load32Aligned(pc + 4);
if (c != (current_char & Load32Aligned(pc + 8))) {
pc = code_base + Load32Aligned(pc + 12);
} else {
pc += BC_AND_CHECK_NOT_4_CHARS_LENGTH;
}
break;
}
BYTECODE(AND_CHECK_NOT_CHAR) {
uint32_t c = (insn >> BYTECODE_SHIFT);
if (c != (current_char & Load32Aligned(pc + 4))) {
pc = code_base + Load32Aligned(pc + 8);
} else {
pc += BC_AND_CHECK_NOT_CHAR_LENGTH;
}
break;
}
BYTECODE(MINUS_AND_CHECK_NOT_CHAR) {
uint32_t c = (insn >> BYTECODE_SHIFT);
uint32_t minus = Load16Aligned(pc + 4);
uint32_t mask = Load16Aligned(pc + 6);
if (c != ((current_char - minus) & mask)) {
pc = code_base + Load32Aligned(pc + 8);
} else {
pc += BC_MINUS_AND_CHECK_NOT_CHAR_LENGTH;
}
break;
}
BYTECODE(CHECK_CHAR_IN_RANGE) {
uint32_t from = Load16Aligned(pc + 4);
uint32_t to = Load16Aligned(pc + 6);
if (from <= current_char && current_char <= to) {
pc = code_base + Load32Aligned(pc + 8);
} else {
pc += BC_CHECK_CHAR_IN_RANGE_LENGTH;
}
break;
}
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) {
pc = code_base + Load32Aligned(pc + 8);
} else {
pc += BC_CHECK_CHAR_NOT_IN_RANGE_LENGTH;
}
break;
}
BYTECODE(CHECK_BIT_IN_TABLE) {
int mask = RegExpMacroAssembler::kTableMask;
byte b = pc[8 + ((current_char & mask) >> kBitsPerByteLog2)];
int bit = (current_char & (kBitsPerByte - 1));
if ((b & (1 << bit)) != 0) {
pc = code_base + Load32Aligned(pc + 4);
} else {
pc += BC_CHECK_BIT_IN_TABLE_LENGTH;
}
break;
}
BYTECODE(CHECK_LT) {
uint32_t limit = (insn >> BYTECODE_SHIFT);
if (current_char < limit) {
pc = code_base + Load32Aligned(pc + 4);
} else {
pc += BC_CHECK_LT_LENGTH;
}
break;
}
BYTECODE(CHECK_GT) {
uint32_t limit = (insn >> BYTECODE_SHIFT);
if (current_char > limit) {
pc = code_base + Load32Aligned(pc + 4);
} else {
pc += BC_CHECK_GT_LENGTH;
}
break;
}
BYTECODE(CHECK_REGISTER_LT)
if (registers[insn >> BYTECODE_SHIFT] < Load32Aligned(pc + 4)) {
pc = code_base + Load32Aligned(pc + 8);
} else {
pc += BC_CHECK_REGISTER_LT_LENGTH;
}
break;
BYTECODE(CHECK_REGISTER_GE)
if (registers[insn >> BYTECODE_SHIFT] >= Load32Aligned(pc + 4)) {
pc = code_base + Load32Aligned(pc + 8);
} else {
pc += BC_CHECK_REGISTER_GE_LENGTH;
}
break;
BYTECODE(CHECK_REGISTER_EQ_POS)
if (registers[insn >> BYTECODE_SHIFT] == current) {
pc = code_base + Load32Aligned(pc + 4);
} else {
pc += BC_CHECK_REGISTER_EQ_POS_LENGTH;
}
break;
BYTECODE(CHECK_NOT_REGS_EQUAL)
if (registers[insn >> BYTECODE_SHIFT] ==
registers[Load32Aligned(pc + 4)]) {
pc += BC_CHECK_NOT_REGS_EQUAL_LENGTH;
} else {
pc = code_base + Load32Aligned(pc + 8);
}
break;
BYTECODE(CHECK_NOT_BACK_REF) {
int from = registers[insn >> BYTECODE_SHIFT];
int len = registers[(insn >> BYTECODE_SHIFT) + 1] - from;
if (from >= 0 && len > 0) {
if (current + len > subject.length() ||
CompareChars(&subject[from], &subject[current], len) != 0) {
pc = code_base + Load32Aligned(pc + 4);
break;
}
current += len;
}
pc += BC_CHECK_NOT_BACK_REF_LENGTH;
break;
}
BYTECODE(CHECK_NOT_BACK_REF_BACKWARD) {
int from = registers[insn >> BYTECODE_SHIFT];
int len = registers[(insn >> BYTECODE_SHIFT) + 1] - from;
if (from >= 0 && len > 0) {
if (current - len < 0 ||
CompareChars(&subject[from], &subject[current - len], len) != 0) {
pc = code_base + Load32Aligned(pc + 4);
break;
}
current -= len;
}
pc += BC_CHECK_NOT_BACK_REF_BACKWARD_LENGTH;
break;
}
BYTECODE(CHECK_NOT_BACK_REF_NO_CASE_UNICODE)
BYTECODE(CHECK_NOT_BACK_REF_NO_CASE) {
bool unicode =
(insn & BYTECODE_MASK) == BC_CHECK_NOT_BACK_REF_NO_CASE_UNICODE;
int from = registers[insn >> BYTECODE_SHIFT];
int len = registers[(insn >> BYTECODE_SHIFT) + 1] - from;
if (from >= 0 && len > 0) {
if (current + len > subject.length() ||
!BackRefMatchesNoCase(isolate, from, current, len, subject,
unicode)) {
pc = code_base + Load32Aligned(pc + 4);
break;
}
current += len;
}
pc += BC_CHECK_NOT_BACK_REF_NO_CASE_LENGTH;
break;
}
BYTECODE(CHECK_NOT_BACK_REF_NO_CASE_UNICODE_BACKWARD)
BYTECODE(CHECK_NOT_BACK_REF_NO_CASE_BACKWARD) {
bool unicode = (insn & BYTECODE_MASK) ==
BC_CHECK_NOT_BACK_REF_NO_CASE_UNICODE_BACKWARD;
int from = registers[insn >> BYTECODE_SHIFT];
int len = registers[(insn >> BYTECODE_SHIFT) + 1] - from;
if (from >= 0 && len > 0) {
if (current - len < 0 ||
!BackRefMatchesNoCase(isolate, from, current - len, len, subject,
unicode)) {
pc = code_base + Load32Aligned(pc + 4);
break;
}
current -= len;
}
pc += BC_CHECK_NOT_BACK_REF_NO_CASE_BACKWARD_LENGTH;
break;
}
BYTECODE(CHECK_AT_START)
if (current == 0) {
pc = code_base + Load32Aligned(pc + 4);
} else {
pc += BC_CHECK_AT_START_LENGTH;
}
break;
BYTECODE(CHECK_NOT_AT_START)
if (current + (insn >> BYTECODE_SHIFT) == 0) {
pc += BC_CHECK_NOT_AT_START_LENGTH;
} else {
pc = code_base + Load32Aligned(pc + 4);
}
break;
BYTECODE(SET_CURRENT_POSITION_FROM_END) {
int by = static_cast<uint32_t>(insn) >> BYTECODE_SHIFT;
if (subject.length() - current > by) {
current = subject.length() - by;
current_char = subject[current - 1];
}
pc += BC_SET_CURRENT_POSITION_FROM_END_LENGTH;
break;
}
default:
UNREACHABLE();
break;
}
}
}
RegExpImpl::IrregexpResult IrregexpInterpreter::Match(
Isolate* isolate,
Handle<ByteArray> code_array,
Handle<String> subject,
int* registers,
int start_position) {
DCHECK(subject->IsFlat());
DisallowHeapAllocation no_gc;
const byte* code_base = code_array->GetDataStartAddress();
uc16 previous_char = '\n';
String::FlatContent subject_content = subject->GetFlatContent();
if (subject_content.IsOneByte()) {
Vector<const uint8_t> subject_vector = subject_content.ToOneByteVector();
if (start_position != 0) previous_char = subject_vector[start_position - 1];
return RawMatch(isolate,
code_base,
subject_vector,
registers,
start_position,
previous_char);
} else {
DCHECK(subject_content.IsTwoByte());
Vector<const uc16> subject_vector = subject_content.ToUC16Vector();
if (start_position != 0) previous_char = subject_vector[start_position - 1];
return RawMatch(isolate,
code_base,
subject_vector,
registers,
start_position,
previous_char);
}
}
} // namespace internal
} // namespace v8
#endif // V8_INTERPRETED_REGEXP