/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- * vim: set ts=8 sts=2 et sw=2 tw=80: * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ // Copyright 2020 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. #include "irregexp/imported/regexp-macro-assembler-arch.h" #include "irregexp/imported/regexp-stack.h" #include "irregexp/imported/special-case.h" #include "jit/Linker.h" #include "jit/PerfSpewer.h" #include "vm/MatchPairs.h" #include "vm/Realm.h" #ifdef MOZ_VTUNE # include "vtune/VTuneWrapper.h" #endif #include "jit/ABIFunctionList-inl.h" #include "jit/MacroAssembler-inl.h" namespace v8 { namespace internal { using js::MatchPairs; using js::jit::AbsoluteAddress; using js::jit::Address; using js::jit::AllocatableGeneralRegisterSet; using js::jit::Assembler; using js::jit::BaseIndex; using js::jit::CodeLocationLabel; using js::jit::GeneralRegisterBackwardIterator; using js::jit::GeneralRegisterForwardIterator; using js::jit::GeneralRegisterSet; using js::jit::Imm32; using js::jit::ImmPtr; using js::jit::ImmWord; using js::jit::JitCode; using js::jit::Linker; using js::jit::LiveGeneralRegisterSet; using js::jit::Register; using js::jit::Registers; using js::jit::StackMacroAssembler; SMRegExpMacroAssembler::SMRegExpMacroAssembler(JSContext* cx, StackMacroAssembler& masm, Zone* zone, Mode mode, uint32_t num_capture_registers) : NativeRegExpMacroAssembler(cx->isolate.ref(), zone), cx_(cx), masm_(masm), mode_(mode), num_registers_(num_capture_registers), num_capture_registers_(num_capture_registers) { // Each capture has a start and an end register MOZ_ASSERT(num_capture_registers_ % 2 == 0); AllocatableGeneralRegisterSet regs(GeneralRegisterSet::All()); input_end_pointer_ = regs.takeAny(); current_character_ = regs.takeAny(); current_position_ = regs.takeAny(); backtrack_stack_pointer_ = regs.takeAny(); temp0_ = regs.takeAny(); temp1_ = regs.takeAny(); if (!regs.empty()) { // Not enough registers on x86. temp2_ = regs.takeAny(); } savedRegisters_ = js::jit::SavedNonVolatileRegisters(regs); masm_.jump(&entry_label_); // We'll generate the entry code later masm_.bind(&start_label_); // and continue from here. } int SMRegExpMacroAssembler::stack_limit_slack() { return RegExpStack::kStackLimitSlack; } void SMRegExpMacroAssembler::AdvanceCurrentPosition(int by) { if (by != 0) { masm_.addPtr(Imm32(by * char_size()), current_position_); } } void SMRegExpMacroAssembler::AdvanceRegister(int reg, int by) { MOZ_ASSERT(reg >= 0 && reg < num_registers_); if (by != 0) { masm_.addPtr(Imm32(by), register_location(reg)); } } void SMRegExpMacroAssembler::Backtrack() { #ifdef DEBUG js::jit::Label bailOut; // Check for simulating interrupt masm_.branch32(Assembler::NotEqual, AbsoluteAddress(&cx_->isolate->shouldSimulateInterrupt_), Imm32(0), &bailOut); #endif // Check for an interrupt. We have to restart from the beginning if we // are interrupted, so we only check for urgent interrupts. js::jit::Label noInterrupt; masm_.branchTest32( Assembler::Zero, AbsoluteAddress(cx_->addressOfInterruptBits()), Imm32(uint32_t(js::InterruptReason::CallbackUrgent)), &noInterrupt); #ifdef DEBUG // bailing out if we have simulating interrupt flag set masm_.bind(&bailOut); #endif masm_.movePtr(ImmWord(js::RegExpRunStatus_Error), temp0_); masm_.jump(&exit_label_); masm_.bind(&noInterrupt); // Pop code location from backtrack stack and jump to location. Pop(temp0_); masm_.jump(temp0_); } void SMRegExpMacroAssembler::Bind(Label* label) { masm_.bind(label->inner()); if (label->patchOffset_.bound()) { AddLabelPatch(label->patchOffset_, label->pos()); } } // Check if current_position + cp_offset is the input start void SMRegExpMacroAssembler::CheckAtStartImpl(int cp_offset, Label* on_cond, Assembler::Condition cond) { Address addr(current_position_, cp_offset * char_size()); masm_.computeEffectiveAddress(addr, temp0_); masm_.branchPtr(cond, inputStart(), temp0_, LabelOrBacktrack(on_cond)); } void SMRegExpMacroAssembler::CheckAtStart(int cp_offset, Label* on_at_start) { CheckAtStartImpl(cp_offset, on_at_start, Assembler::Equal); } void SMRegExpMacroAssembler::CheckNotAtStart(int cp_offset, Label* on_not_at_start) { CheckAtStartImpl(cp_offset, on_not_at_start, Assembler::NotEqual); } void SMRegExpMacroAssembler::CheckCharacterImpl(Imm32 c, Label* on_cond, Assembler::Condition cond) { masm_.branch32(cond, current_character_, c, LabelOrBacktrack(on_cond)); } void SMRegExpMacroAssembler::CheckCharacter(uint32_t c, Label* on_equal) { CheckCharacterImpl(Imm32(c), on_equal, Assembler::Equal); } void SMRegExpMacroAssembler::CheckNotCharacter(uint32_t c, Label* on_not_equal) { CheckCharacterImpl(Imm32(c), on_not_equal, Assembler::NotEqual); } void SMRegExpMacroAssembler::CheckCharacterGT(base::uc16 limit, Label* on_greater) { CheckCharacterImpl(Imm32(limit), on_greater, Assembler::GreaterThan); } void SMRegExpMacroAssembler::CheckCharacterLT(base::uc16 limit, Label* on_less) { CheckCharacterImpl(Imm32(limit), on_less, Assembler::LessThan); } // Bitwise-and the current character with mask and then check for a // match with c. void SMRegExpMacroAssembler::CheckCharacterAfterAndImpl(uint32_t c, uint32_t mask, Label* on_cond, bool is_not) { if (c == 0) { Assembler::Condition cond = is_not ? Assembler::NonZero : Assembler::Zero; masm_.branchTest32(cond, current_character_, Imm32(mask), LabelOrBacktrack(on_cond)); } else { Assembler::Condition cond = is_not ? Assembler::NotEqual : Assembler::Equal; masm_.move32(Imm32(mask), temp0_); masm_.and32(current_character_, temp0_); masm_.branch32(cond, temp0_, Imm32(c), LabelOrBacktrack(on_cond)); } } void SMRegExpMacroAssembler::CheckCharacterAfterAnd(uint32_t c, uint32_t mask, Label* on_equal) { CheckCharacterAfterAndImpl(c, mask, on_equal, /*is_not =*/false); } void SMRegExpMacroAssembler::CheckNotCharacterAfterAnd(uint32_t c, uint32_t mask, Label* on_not_equal) { CheckCharacterAfterAndImpl(c, mask, on_not_equal, /*is_not =*/true); } // Subtract minus from the current character, then bitwise-and the // result with mask, then check for a match with c. void SMRegExpMacroAssembler::CheckNotCharacterAfterMinusAnd( base::uc16 c, base::uc16 minus, base::uc16 mask, Label* on_not_equal) { masm_.computeEffectiveAddress(Address(current_character_, -minus), temp0_); if (c == 0) { masm_.branchTest32(Assembler::NonZero, temp0_, Imm32(mask), LabelOrBacktrack(on_not_equal)); } else { masm_.and32(Imm32(mask), temp0_); masm_.branch32(Assembler::NotEqual, temp0_, Imm32(c), LabelOrBacktrack(on_not_equal)); } } // If the current position matches the position stored on top of the backtrack // stack, pops the backtrack stack and branches to the given label. void SMRegExpMacroAssembler::CheckGreedyLoop(Label* on_equal) { js::jit::Label fallthrough; masm_.branchPtr(Assembler::NotEqual, Address(backtrack_stack_pointer_, 0), current_position_, &fallthrough); masm_.addPtr(Imm32(sizeof(void*)), backtrack_stack_pointer_); // Pop. JumpOrBacktrack(on_equal); masm_.bind(&fallthrough); } void SMRegExpMacroAssembler::CheckCharacterInRangeImpl( base::uc16 from, base::uc16 to, Label* on_cond, Assembler::Condition cond) { // x is in [from,to] if unsigned(x - from) <= to - from masm_.computeEffectiveAddress(Address(current_character_, -from), temp0_); masm_.branch32(cond, temp0_, Imm32(to - from), LabelOrBacktrack(on_cond)); } void SMRegExpMacroAssembler::CheckCharacterInRange(base::uc16 from, base::uc16 to, Label* on_in_range) { CheckCharacterInRangeImpl(from, to, on_in_range, Assembler::BelowOrEqual); } void SMRegExpMacroAssembler::CheckCharacterNotInRange(base::uc16 from, base::uc16 to, Label* on_not_in_range) { CheckCharacterInRangeImpl(from, to, on_not_in_range, Assembler::Above); } /* static */ bool SMRegExpMacroAssembler::IsCharacterInRangeArray(uint32_t c, ByteArrayData* ranges) { js::AutoUnsafeCallWithABI unsafe; MOZ_ASSERT(ranges->length % sizeof(uint16_t) == 0); uint32_t length = ranges->length / sizeof(uint16_t); MOZ_ASSERT(length > 0); // Fast paths. if (c < ranges->getTyped(0)) { // |c| is lower than the start of the first range. // It is not in the range array. return false; } if (c >= ranges->getTyped(length - 1)) { // |c| is higher than the last entry. If the table contains an odd // number of entries, the last range is open-ended, so |c| is in // the range array iff |length| is odd. return (length % 2) != 0; } // |ranges| is stored as an interval list: an ordered list of // starting points, where every even index marks the beginning of a // range of characters that are included, and every odd index marks // the beginning of a range of characters that are excluded. For // example, the set [1,2,3,7,8,9] would be represented as the // range array [1,4,7,10]. If |ranges| has an odd number of entries, // the last included range is open-ended (so the set containing // every character would be represented as [0]). // // Because of the symmetry between included and excluded ranges, we // can do a binary search for the index in |ranges| with the value // closest to but not exceeding |c|. If that index is even, |c| is // in an included range. If that index is odd, |c| is in an excluded // range. uint32_t lower = 0; uint32_t upper = length; uint32_t mid = 0; do { mid = lower + (upper - lower) / 2; const base::uc16 elem = ranges->getTyped(mid); if (c < elem) { upper = mid; } else if (c > elem) { lower = mid + 1; } else { break; } } while (lower < upper); uint32_t rangeIndex = c < ranges->getTyped(mid) ? mid - 1 : mid; // Included ranges start at even indices and end at odd indices. return rangeIndex % 2 == 0; } void SMRegExpMacroAssembler::CallIsCharacterInRangeArray( const ZoneList* ranges) { Handle rangeArray = GetOrAddRangeArray(ranges); masm_.movePtr(ImmPtr(rangeArray->inner()), temp0_); // Save volatile regs. Temp regs don't need to be saved. LiveGeneralRegisterSet volatileRegs(GeneralRegisterSet::Volatile()); volatileRegs.takeUnchecked(temp0_); volatileRegs.takeUnchecked(temp1_); if (temp2_ != js::jit::InvalidReg) { volatileRegs.takeUnchecked(temp2_); } masm_.PushRegsInMask(volatileRegs); using Fn = bool (*)(uint32_t, ByteArrayData*); masm_.setupUnalignedABICall(temp1_); masm_.passABIArg(current_character_); masm_.passABIArg(temp0_); masm_.callWithABI(); masm_.storeCallBoolResult(temp1_); masm_.PopRegsInMask(volatileRegs); // GetOrAddRangeArray caches previously seen range arrays to reduce // memory usage, so this may not be the first time we've seen this // range array. We only need to transfer ownership from the // HandleScope to the |tables_| vector once. PseudoHandle rawRangeArray = rangeArray->maybeTakeOwnership(isolate()); if (rawRangeArray) { AddTable(std::move(rawRangeArray)); } } bool SMRegExpMacroAssembler::CheckCharacterInRangeArray( const ZoneList* ranges, Label* on_in_range) { CallIsCharacterInRangeArray(ranges); masm_.branchTest32(Assembler::NonZero, temp1_, temp1_, LabelOrBacktrack(on_in_range)); return true; } bool SMRegExpMacroAssembler::CheckCharacterNotInRangeArray( const ZoneList* ranges, Label* on_not_in_range) { CallIsCharacterInRangeArray(ranges); masm_.branchTest32(Assembler::Zero, temp1_, temp1_, LabelOrBacktrack(on_not_in_range)); return true; } void SMRegExpMacroAssembler::CheckBitInTable(Handle table, Label* on_bit_set) { // Claim ownership of the ByteArray from the current HandleScope. // ByteArrays are allocated on the C++ heap and are (eventually) // owned by the RegExpShared. PseudoHandle rawTable = table->takeOwnership(isolate()); masm_.movePtr(ImmPtr(rawTable->data()), temp0_); masm_.move32(Imm32(kTableMask), temp1_); masm_.and32(current_character_, temp1_); masm_.load8ZeroExtend(BaseIndex(temp0_, temp1_, js::jit::TimesOne), temp0_); masm_.branchTest32(Assembler::NonZero, temp0_, temp0_, LabelOrBacktrack(on_bit_set)); // Transfer ownership of |rawTable| to the |tables_| vector. AddTable(std::move(rawTable)); } void SMRegExpMacroAssembler::CheckNotBackReferenceImpl(int start_reg, bool read_backward, bool unicode, Label* on_no_match, bool ignore_case) { js::jit::Label fallthrough; // Captures are stored as a sequential pair of registers. // Find the length of the back-referenced capture and load the // capture's start index into current_character_. masm_.loadPtr(register_location(start_reg), // index of start current_character_); masm_.loadPtr(register_location(start_reg + 1), temp0_); // index of end masm_.subPtr(current_character_, temp0_); // length of capture // Capture registers are either both set or both cleared. // If the capture length is zero, then the capture is either empty or cleared. // Fall through in both cases. masm_.branchPtr(Assembler::Equal, temp0_, ImmWord(0), &fallthrough); // Check that there are sufficient characters left in the input. if (read_backward) { // If start + len > current, there isn't enough room for a // lookbehind backreference. masm_.loadPtr(inputStart(), temp1_); masm_.addPtr(temp0_, temp1_); masm_.branchPtr(Assembler::GreaterThan, temp1_, current_position_, LabelOrBacktrack(on_no_match)); } else { // current_position_ is the negative offset from the end. // If current + len > 0, there isn't enough room for a backreference. masm_.movePtr(current_position_, temp1_); masm_.addPtr(temp0_, temp1_); masm_.branchPtr(Assembler::GreaterThan, temp1_, ImmWord(0), LabelOrBacktrack(on_no_match)); } if (mode_ == UC16 && ignore_case) { // We call a helper function for case-insensitive non-latin1 strings. // Save volatile regs. temp1_, temp2_, and current_character_ // don't need to be saved. current_position_ needs to be saved // even if it's non-volatile, because we modify it to use as an argument. LiveGeneralRegisterSet volatileRegs(GeneralRegisterSet::Volatile()); volatileRegs.addUnchecked(current_position_); volatileRegs.takeUnchecked(temp1_); if (temp2_ != js::jit::InvalidReg) { volatileRegs.takeUnchecked(temp2_); } volatileRegs.takeUnchecked(current_character_); masm_.PushRegsInMask(volatileRegs); // Parameters are // Address captured - Address of captured substring's start. // Address current - Address of current character position. // size_t byte_length - length of capture (in bytes) // Compute |captured| masm_.addPtr(input_end_pointer_, current_character_); // Compute |current| masm_.addPtr(input_end_pointer_, current_position_); if (read_backward) { // Offset by length when matching backwards. masm_.subPtr(temp0_, current_position_); } using Fn = uint32_t (*)(const char16_t*, const char16_t*, size_t); masm_.setupUnalignedABICall(temp1_); masm_.passABIArg(current_character_); masm_.passABIArg(current_position_); masm_.passABIArg(temp0_); if (unicode) { masm_.callWithABI(); } else { masm_.callWithABI(); } masm_.storeCallInt32Result(temp1_); masm_.PopRegsInMask(volatileRegs); masm_.branchTest32(Assembler::Zero, temp1_, temp1_, LabelOrBacktrack(on_no_match)); // On success, advance position by length of capture if (read_backward) { masm_.subPtr(temp0_, current_position_); } else { masm_.addPtr(temp0_, current_position_); } masm_.bind(&fallthrough); return; } // We will be modifying current_position_. Save it in case the match fails. masm_.push(current_position_); // Compute start of capture string masm_.addPtr(input_end_pointer_, current_character_); // Compute start of match string masm_.addPtr(input_end_pointer_, current_position_); if (read_backward) { // Offset by length when matching backwards. masm_.subPtr(temp0_, current_position_); } // Compute end of match string masm_.addPtr(current_position_, temp0_); Register nextCaptureChar = temp1_; Register nextMatchChar = temp2_; if (temp2_ == js::jit::InvalidReg) { masm_.push(backtrack_stack_pointer_); nextMatchChar = backtrack_stack_pointer_; } js::jit::Label success; js::jit::Label fail; js::jit::Label loop; masm_.bind(&loop); // Load next character from each string. if (mode_ == LATIN1) { masm_.load8ZeroExtend(Address(current_character_, 0), nextCaptureChar); masm_.load8ZeroExtend(Address(current_position_, 0), nextMatchChar); } else { masm_.load16ZeroExtend(Address(current_character_, 0), nextCaptureChar); masm_.load16ZeroExtend(Address(current_position_, 0), nextMatchChar); } if (ignore_case) { MOZ_ASSERT(mode_ == LATIN1); // Try exact match. js::jit::Label loop_increment; masm_.branch32(Assembler::Equal, nextCaptureChar, nextMatchChar, &loop_increment); // Mismatch. Try case-insensitive match. // Force the capture character to lower case (by setting bit 0x20) // then check to see if it is a letter. js::jit::Label convert_match; masm_.or32(Imm32(0x20), nextCaptureChar); // Check if it is in [a,z]. masm_.computeEffectiveAddress(Address(nextCaptureChar, -'a'), nextMatchChar); masm_.branch32(Assembler::BelowOrEqual, nextMatchChar, Imm32('z' - 'a'), &convert_match); // Check for values in range [224,254]. // Exclude 247 (U+00F7 DIVISION SIGN). masm_.sub32(Imm32(224 - 'a'), nextMatchChar); masm_.branch32(Assembler::Above, nextMatchChar, Imm32(254 - 224), &fail); masm_.branch32(Assembler::Equal, nextMatchChar, Imm32(247 - 224), &fail); // Capture character is lower case. Convert match character // to lower case and compare. masm_.bind(&convert_match); masm_.load8ZeroExtend(Address(current_position_, 0), nextMatchChar); masm_.or32(Imm32(0x20), nextMatchChar); masm_.branch32(Assembler::NotEqual, nextCaptureChar, nextMatchChar, &fail); masm_.bind(&loop_increment); } else { // Fail if characters do not match. masm_.branch32(Assembler::NotEqual, nextCaptureChar, nextMatchChar, &fail); } // Increment pointers into match and capture strings. masm_.addPtr(Imm32(char_size()), current_character_); masm_.addPtr(Imm32(char_size()), current_position_); // Loop if we have not reached the end of the match string. masm_.branchPtr(Assembler::Below, current_position_, temp0_, &loop); masm_.jump(&success); // If we fail, restore current_position_ and branch. masm_.bind(&fail); if (temp2_ == js::jit::InvalidReg) { // Restore backtrack_stack_pointer_ when it was used as a temp register. masm_.pop(backtrack_stack_pointer_); } masm_.pop(current_position_); JumpOrBacktrack(on_no_match); masm_.bind(&success); if (temp2_ == js::jit::InvalidReg) { // Restore backtrack_stack_pointer_ when it was used as a temp register. masm_.pop(backtrack_stack_pointer_); } // Drop saved value of current_position_ masm_.addToStackPtr(Imm32(sizeof(uintptr_t))); // current_position_ is a pointer. Convert it back to an offset. masm_.subPtr(input_end_pointer_, current_position_); if (read_backward) { // Subtract match length if we matched backward masm_.addPtr(register_location(start_reg), current_position_); masm_.subPtr(register_location(start_reg + 1), current_position_); } masm_.bind(&fallthrough); } // Branch if a back-reference does not match a previous capture. void SMRegExpMacroAssembler::CheckNotBackReference(int start_reg, bool read_backward, Label* on_no_match) { CheckNotBackReferenceImpl(start_reg, read_backward, /*unicode = */ false, on_no_match, /*ignore_case = */ false); } void SMRegExpMacroAssembler::CheckNotBackReferenceIgnoreCase( int start_reg, bool read_backward, bool unicode, Label* on_no_match) { CheckNotBackReferenceImpl(start_reg, read_backward, unicode, on_no_match, /*ignore_case = */ true); } // Checks whether the given offset from the current position is // inside the input string. void SMRegExpMacroAssembler::CheckPosition(int cp_offset, Label* on_outside_input) { // Note: current_position_ is a (negative) byte offset relative to // the end of the input string. if (cp_offset >= 0) { // end + current + offset >= end // <=> current + offset >= 0 // <=> current >= -offset masm_.branchPtr(Assembler::GreaterThanOrEqual, current_position_, ImmWord(-cp_offset * char_size()), LabelOrBacktrack(on_outside_input)); } else { // Compute offset position masm_.computeEffectiveAddress( Address(current_position_, cp_offset * char_size()), temp0_); // Compare to start of input. masm_.branchPtr(Assembler::GreaterThan, inputStart(), temp0_, LabelOrBacktrack(on_outside_input)); } } // This function attempts to generate special case code for character classes. // Returns true if a special case is generated. // Otherwise returns false and generates no code. bool SMRegExpMacroAssembler::CheckSpecialCharacterClass( StandardCharacterSet type, Label* on_no_match) { js::jit::Label* no_match = LabelOrBacktrack(on_no_match); // Note: throughout this function, range checks (c in [min, max]) // are implemented by an unsigned (c - min) <= (max - min) check. switch (type) { case StandardCharacterSet::kWhitespace: { // Match space-characters if (mode_ != LATIN1) { return false; } js::jit::Label success; // One byte space characters are ' ', '\t'..'\r', and '\u00a0' (NBSP). // Check ' ' masm_.branch32(Assembler::Equal, current_character_, Imm32(' '), &success); // Check '\t'..'\r' masm_.computeEffectiveAddress(Address(current_character_, -'\t'), temp0_); masm_.branch32(Assembler::BelowOrEqual, temp0_, Imm32('\r' - '\t'), &success); // Check \u00a0. masm_.branch32(Assembler::NotEqual, temp0_, Imm32(0x00a0 - '\t'), no_match); masm_.bind(&success); return true; } case StandardCharacterSet::kNotWhitespace: // The emitted code for generic character classes is good enough. return false; case StandardCharacterSet::kDigit: // Match latin1 digits ('0'-'9') masm_.computeEffectiveAddress(Address(current_character_, -'0'), temp0_); masm_.branch32(Assembler::Above, temp0_, Imm32('9' - '0'), no_match); return true; case StandardCharacterSet::kNotDigit: // Match anything except latin1 digits ('0'-'9') masm_.computeEffectiveAddress(Address(current_character_, -'0'), temp0_); masm_.branch32(Assembler::BelowOrEqual, temp0_, Imm32('9' - '0'), no_match); return true; case StandardCharacterSet::kNotLineTerminator: // Match non-newlines. This excludes '\n' (0x0a), '\r' (0x0d), // U+2028 LINE SEPARATOR, and U+2029 PARAGRAPH SEPARATOR. // See https://tc39.es/ecma262/#prod-LineTerminator // To test for 0x0a and 0x0d efficiently, we XOR the input with 1. // This converts 0x0a to 0x0b, and 0x0d to 0x0c, allowing us to // test for the contiguous range 0x0b..0x0c. masm_.move32(current_character_, temp0_); masm_.xor32(Imm32(0x01), temp0_); masm_.sub32(Imm32(0x0b), temp0_); masm_.branch32(Assembler::BelowOrEqual, temp0_, Imm32(0x0c - 0x0b), no_match); if (mode_ == UC16) { // Compare original value to 0x2028 and 0x2029, using the already // computed (current_char ^ 0x01 - 0x0b). I.e., check for // 0x201d (0x2028 - 0x0b) or 0x201e. masm_.sub32(Imm32(0x2028 - 0x0b), temp0_); masm_.branch32(Assembler::BelowOrEqual, temp0_, Imm32(0x2029 - 0x2028), no_match); } return true; case StandardCharacterSet::kWord: // \w matches the set of 63 characters defined in Runtime Semantics: // WordCharacters. We use a static lookup table, which is defined in // regexp-macro-assembler.cc. // Note: if both Unicode and IgnoreCase are true, \w matches a // larger set of characters. That case is handled elsewhere. if (mode_ != LATIN1) { masm_.branch32(Assembler::Above, current_character_, Imm32('z'), no_match); } static_assert(arraysize(word_character_map) > unibrow::Latin1::kMaxChar); masm_.movePtr(ImmPtr(word_character_map), temp0_); masm_.load8ZeroExtend( BaseIndex(temp0_, current_character_, js::jit::TimesOne), temp0_); masm_.branchTest32(Assembler::Zero, temp0_, temp0_, no_match); return true; case StandardCharacterSet::kNotWord: { // See 'w' above. js::jit::Label done; if (mode_ != LATIN1) { masm_.branch32(Assembler::Above, current_character_, Imm32('z'), &done); } static_assert(arraysize(word_character_map) > unibrow::Latin1::kMaxChar); masm_.movePtr(ImmPtr(word_character_map), temp0_); masm_.load8ZeroExtend( BaseIndex(temp0_, current_character_, js::jit::TimesOne), temp0_); masm_.branchTest32(Assembler::NonZero, temp0_, temp0_, no_match); if (mode_ != LATIN1) { masm_.bind(&done); } return true; } //////////////////////////////////////////////////////////////////////// // Non-standard classes (with no syntactic shorthand) used internally // //////////////////////////////////////////////////////////////////////// case StandardCharacterSet::kEverything: // Match any character return true; case StandardCharacterSet::kLineTerminator: // Match newlines. The opposite of '.'. See '.' above. masm_.move32(current_character_, temp0_); masm_.xor32(Imm32(0x01), temp0_); masm_.sub32(Imm32(0x0b), temp0_); if (mode_ == LATIN1) { masm_.branch32(Assembler::Above, temp0_, Imm32(0x0c - 0x0b), no_match); } else { MOZ_ASSERT(mode_ == UC16); js::jit::Label done; masm_.branch32(Assembler::BelowOrEqual, temp0_, Imm32(0x0c - 0x0b), &done); // Compare original value to 0x2028 and 0x2029, using the already // computed (current_char ^ 0x01 - 0x0b). I.e., check for // 0x201d (0x2028 - 0x0b) or 0x201e. masm_.sub32(Imm32(0x2028 - 0x0b), temp0_); masm_.branch32(Assembler::Above, temp0_, Imm32(0x2029 - 0x2028), no_match); masm_.bind(&done); } return true; } return false; } void SMRegExpMacroAssembler::Fail() { masm_.movePtr(ImmWord(js::RegExpRunStatus_Success_NotFound), temp0_); masm_.jump(&exit_label_); } void SMRegExpMacroAssembler::GoTo(Label* to) { masm_.jump(LabelOrBacktrack(to)); } void SMRegExpMacroAssembler::IfRegisterGE(int reg, int comparand, Label* if_ge) { masm_.branchPtr(Assembler::GreaterThanOrEqual, register_location(reg), ImmWord(comparand), LabelOrBacktrack(if_ge)); } void SMRegExpMacroAssembler::IfRegisterLT(int reg, int comparand, Label* if_lt) { masm_.branchPtr(Assembler::LessThan, register_location(reg), ImmWord(comparand), LabelOrBacktrack(if_lt)); } void SMRegExpMacroAssembler::IfRegisterEqPos(int reg, Label* if_eq) { masm_.branchPtr(Assembler::Equal, register_location(reg), current_position_, LabelOrBacktrack(if_eq)); } // This is a word-for-word identical copy of the V8 code, which is // duplicated in at least nine different places in V8 (one per // supported architecture) with no differences outside of comments and // formatting. It should be hoisted into the superclass. Once that is // done upstream, this version can be deleted. void SMRegExpMacroAssembler::LoadCurrentCharacterImpl(int cp_offset, Label* on_end_of_input, bool check_bounds, int characters, int eats_at_least) { // It's possible to preload a small number of characters when each success // path requires a large number of characters, but not the reverse. MOZ_ASSERT(eats_at_least >= characters); MOZ_ASSERT(cp_offset < (1 << 30)); // Be sane! (And ensure negation works) if (check_bounds) { if (cp_offset >= 0) { CheckPosition(cp_offset + eats_at_least - 1, on_end_of_input); } else { CheckPosition(cp_offset, on_end_of_input); } } LoadCurrentCharacterUnchecked(cp_offset, characters); } // Load the character (or characters) at the specified offset from the // current position. Zero-extend to 32 bits. void SMRegExpMacroAssembler::LoadCurrentCharacterUnchecked(int cp_offset, int characters) { BaseIndex address(input_end_pointer_, current_position_, js::jit::TimesOne, cp_offset * char_size()); if (mode_ == LATIN1) { if (characters == 4) { masm_.load32(address, current_character_); } else if (characters == 2) { masm_.load16ZeroExtend(address, current_character_); } else { MOZ_ASSERT(characters == 1); masm_.load8ZeroExtend(address, current_character_); } } else { MOZ_ASSERT(mode_ == UC16); if (characters == 2) { masm_.load32(address, current_character_); } else { MOZ_ASSERT(characters == 1); masm_.load16ZeroExtend(address, current_character_); } } } void SMRegExpMacroAssembler::PopCurrentPosition() { Pop(current_position_); } void SMRegExpMacroAssembler::PopRegister(int register_index) { Pop(temp0_); masm_.storePtr(temp0_, register_location(register_index)); } void SMRegExpMacroAssembler::PushBacktrack(Label* label) { MOZ_ASSERT(!label->is_bound()); MOZ_ASSERT(!label->patchOffset_.bound()); label->patchOffset_ = masm_.movWithPatch(ImmPtr(nullptr), temp0_); MOZ_ASSERT(label->patchOffset_.bound()); Push(temp0_); CheckBacktrackStackLimit(); } void SMRegExpMacroAssembler::PushCurrentPosition() { Push(current_position_); } void SMRegExpMacroAssembler::PushRegister(int register_index, StackCheckFlag check_stack_limit) { masm_.loadPtr(register_location(register_index), temp0_); Push(temp0_); if (check_stack_limit) { CheckBacktrackStackLimit(); } } void SMRegExpMacroAssembler::ReadCurrentPositionFromRegister(int reg) { masm_.loadPtr(register_location(reg), current_position_); } void SMRegExpMacroAssembler::WriteCurrentPositionToRegister(int reg, int cp_offset) { if (cp_offset == 0) { masm_.storePtr(current_position_, register_location(reg)); } else { Address addr(current_position_, cp_offset * char_size()); masm_.computeEffectiveAddress(addr, temp0_); masm_.storePtr(temp0_, register_location(reg)); } } // Note: The backtrack stack pointer is stored in a register as an // offset from the stack top, not as a bare pointer, so that it is not // corrupted if the backtrack stack grows (and therefore moves). void SMRegExpMacroAssembler::ReadStackPointerFromRegister(int reg) { masm_.loadPtr(register_location(reg), backtrack_stack_pointer_); masm_.addPtr(backtrackStackBase(), backtrack_stack_pointer_); } void SMRegExpMacroAssembler::WriteStackPointerToRegister(int reg) { masm_.movePtr(backtrack_stack_pointer_, temp0_); masm_.subPtr(backtrackStackBase(), temp0_); masm_.storePtr(temp0_, register_location(reg)); } // When matching a regexp that is anchored at the end, this operation // is used to try skipping the beginning of long strings. If the // maximum length of a match is less than the length of the string, we // can skip the initial len - max_len bytes. void SMRegExpMacroAssembler::SetCurrentPositionFromEnd(int by) { js::jit::Label after_position; masm_.branchPtr(Assembler::GreaterThanOrEqual, current_position_, ImmWord(-by * char_size()), &after_position); masm_.movePtr(ImmWord(-by * char_size()), current_position_); // On RegExp code entry (where this operation is used), the character before // the current position is expected to be already loaded. // We have advanced the position, so it's safe to read backwards. LoadCurrentCharacterUnchecked(-1, 1); masm_.bind(&after_position); } void SMRegExpMacroAssembler::SetRegister(int register_index, int to) { MOZ_ASSERT(register_index >= num_capture_registers_); masm_.storePtr(ImmWord(to), register_location(register_index)); } // Returns true if a regexp match can be restarted (aka the regexp is global). // The return value is not used anywhere, but we implement it to be safe. bool SMRegExpMacroAssembler::Succeed() { masm_.jump(&success_label_); return global(); } // Capture registers are initialized to input[-1] void SMRegExpMacroAssembler::ClearRegisters(int reg_from, int reg_to) { MOZ_ASSERT(reg_from <= reg_to); masm_.loadPtr(inputStart(), temp0_); masm_.subPtr(Imm32(char_size()), temp0_); for (int reg = reg_from; reg <= reg_to; reg++) { masm_.storePtr(temp0_, register_location(reg)); } } void SMRegExpMacroAssembler::Push(Register source) { MOZ_ASSERT(source != backtrack_stack_pointer_); masm_.subPtr(Imm32(sizeof(void*)), backtrack_stack_pointer_); masm_.storePtr(source, Address(backtrack_stack_pointer_, 0)); } void SMRegExpMacroAssembler::Pop(Register target) { MOZ_ASSERT(target != backtrack_stack_pointer_); masm_.loadPtr(Address(backtrack_stack_pointer_, 0), target); masm_.addPtr(Imm32(sizeof(void*)), backtrack_stack_pointer_); } void SMRegExpMacroAssembler::JumpOrBacktrack(Label* to) { if (to) { masm_.jump(to->inner()); } else { Backtrack(); } } // Generate a quick inline test for backtrack stack overflow. // If the test fails, call an OOL handler to try growing the stack. void SMRegExpMacroAssembler::CheckBacktrackStackLimit() { js::jit::Label no_stack_overflow; masm_.branchPtr( Assembler::BelowOrEqual, AbsoluteAddress(isolate()->regexp_stack()->limit_address_address()), backtrack_stack_pointer_, &no_stack_overflow); masm_.call(&stack_overflow_label_); // Exit with an exception if the call failed masm_.branchTest32(Assembler::Zero, temp0_, temp0_, &exit_with_exception_label_); masm_.bind(&no_stack_overflow); } // This is used to sneak an OOM through the V8 layer. static Handle DummyCode() { return Handle::fromHandleValue(JS::UndefinedHandleValue); } // Finalize code. This is called last, so that we know how many // registers we need. Handle SMRegExpMacroAssembler::GetCode(Handle source) { if (!cx_->realm()->ensureJitRealmExists(cx_)) { return DummyCode(); } masm_.bind(&entry_label_); createStackFrame(); initFrameAndRegs(); masm_.jump(&start_label_); successHandler(); exitHandler(); backtrackHandler(); stackOverflowHandler(); Linker linker(masm_); JitCode* code = linker.newCode(cx_, js::jit::CodeKind::RegExp); if (!code) { return DummyCode(); } for (LabelPatch& lp : labelPatches_) { Assembler::PatchDataWithValueCheck(CodeLocationLabel(code, lp.patchOffset_), ImmPtr(code->raw() + lp.labelOffset_), ImmPtr(nullptr)); } CollectPerfSpewerJitCodeProfile(code, "RegExp"); #ifdef MOZ_VTUNE js::vtune::MarkStub(code, "RegExp"); #endif return Handle(JS::PrivateGCThingValue(code), isolate()); } /* * The stack will have the following structure: * sp-> - FrameData * - inputStart * - backtrack stack base * - matches * - numMatches * - Registers * - Capture positions * - Scratch registers * --- frame alignment --- * - Saved register area * - Return address */ void SMRegExpMacroAssembler::createStackFrame() { #ifdef JS_CODEGEN_ARM64 // ARM64 communicates stack address via SP, but uses a pseudo-sp (PSP) for // addressing. The register we use for PSP may however also be used by // calling code, and it is nonvolatile, so save it. Do this as a special // case first because the generic save/restore code needs the PSP to be // initialized already. MOZ_ASSERT(js::jit::PseudoStackPointer64.Is(masm_.GetStackPointer64())); masm_.Str(js::jit::PseudoStackPointer64, vixl::MemOperand(js::jit::sp, -16, vixl::PreIndex)); // Initialize the PSP from the SP. masm_.initPseudoStackPtr(); #endif // Push non-volatile registers which might be modified by jitcode. size_t pushedNonVolatileRegisters = 0; for (GeneralRegisterForwardIterator iter(savedRegisters_); iter.more(); ++iter) { masm_.Push(*iter); pushedNonVolatileRegisters++; } // The pointer to InputOutputData is passed as the first argument. // On x86 we have to load it off the stack into temp0_. // On other platforms it is already in a register. #ifdef JS_CODEGEN_X86 Address ioDataAddr(masm_.getStackPointer(), (pushedNonVolatileRegisters + 1) * sizeof(void*)); masm_.loadPtr(ioDataAddr, temp0_); #else (void)pushedNonVolatileRegisters; if (js::jit::IntArgReg0 != temp0_) { masm_.movePtr(js::jit::IntArgReg0, temp0_); } #endif // Start a new stack frame. size_t frameBytes = sizeof(FrameData) + num_registers_ * sizeof(void*); frameSize_ = js::jit::StackDecrementForCall(js::jit::ABIStackAlignment, masm_.framePushed(), frameBytes); masm_.reserveStack(frameSize_); masm_.checkStackAlignment(); // Check if we have space on the stack. Use the *NoInterrupt stack limit to // avoid failing repeatedly when the regex code is called from Ion JIT code. // (See bug 1208819) js::jit::Label stack_ok; AbsoluteAddress limit_addr(cx_->addressOfJitStackLimitNoInterrupt()); masm_.branchStackPtrRhs(Assembler::Below, limit_addr, &stack_ok); // There is not enough space on the stack. Exit with an exception. masm_.movePtr(ImmWord(js::RegExpRunStatus_Error), temp0_); masm_.jump(&exit_label_); masm_.bind(&stack_ok); } void SMRegExpMacroAssembler::initFrameAndRegs() { // At this point, an uninitialized stack frame has been created, // and the address of the InputOutputData is in temp0_. Register ioDataReg = temp0_; Register matchesReg = temp1_; masm_.loadPtr(Address(ioDataReg, offsetof(InputOutputData, matches)), matchesReg); // Initialize output registers // Use |backtrack_stack_pointer_| as an additional temp register. This is safe // because we haven't yet written any data to |backtrack_stack_pointer_|. Register extraTemp = backtrack_stack_pointer_; masm_.loadPtr(Address(matchesReg, MatchPairs::offsetOfPairs()), extraTemp); masm_.storePtr(extraTemp, matches()); masm_.load32(Address(matchesReg, MatchPairs::offsetOfPairCount()), extraTemp); masm_.store32(extraTemp, numMatches()); #ifdef DEBUG // Bounds-check numMatches. js::jit::Label enoughRegisters; masm_.branchPtr(Assembler::GreaterThanOrEqual, extraTemp, ImmWord(num_capture_registers_ / 2), &enoughRegisters); masm_.assumeUnreachable("Not enough output pairs for RegExp"); masm_.bind(&enoughRegisters); #endif // Load input start pointer. masm_.loadPtr(Address(ioDataReg, offsetof(InputOutputData, inputStart)), current_position_); // Load input end pointer masm_.loadPtr(Address(ioDataReg, offsetof(InputOutputData, inputEnd)), input_end_pointer_); // Set up input position to be negative offset from string end. masm_.subPtr(input_end_pointer_, current_position_); // Store inputStart masm_.storePtr(current_position_, inputStart()); // Load start index Register startIndexReg = temp1_; masm_.loadPtr(Address(ioDataReg, offsetof(InputOutputData, startIndex)), startIndexReg); masm_.computeEffectiveAddress( BaseIndex(current_position_, startIndexReg, factor()), current_position_); // Initialize current_character_. // Load newline if index is at start, or previous character otherwise. js::jit::Label start_regexp; js::jit::Label load_previous_character; masm_.branchPtr(Assembler::NotEqual, startIndexReg, ImmWord(0), &load_previous_character); masm_.movePtr(ImmWord('\n'), current_character_); masm_.jump(&start_regexp); masm_.bind(&load_previous_character); LoadCurrentCharacterUnchecked(-1, 1); masm_.bind(&start_regexp); // Initialize captured registers with inputStart - 1 MOZ_ASSERT(num_capture_registers_ > 0); Register inputStartMinusOneReg = temp0_; masm_.loadPtr(inputStart(), inputStartMinusOneReg); masm_.subPtr(Imm32(char_size()), inputStartMinusOneReg); if (num_capture_registers_ > 8) { masm_.movePtr(ImmWord(register_offset(0)), temp1_); js::jit::Label init_loop; masm_.bind(&init_loop); masm_.storePtr(inputStartMinusOneReg, BaseIndex(masm_.getStackPointer(), temp1_, js::jit::TimesOne)); masm_.addPtr(ImmWord(sizeof(void*)), temp1_); masm_.branchPtr(Assembler::LessThan, temp1_, ImmWord(register_offset(num_capture_registers_)), &init_loop); } else { // Unroll the loop for (int i = 0; i < num_capture_registers_; i++) { masm_.storePtr(inputStartMinusOneReg, register_location(i)); } } // Initialize backtrack stack pointer masm_.loadPtr(AbsoluteAddress(ExternalReference::TopOfRegexpStack(isolate())), backtrack_stack_pointer_); masm_.storePtr(backtrack_stack_pointer_, backtrackStackBase()); } // Called when we find a match. May not be generated if we can // determine ahead of time that a regexp cannot match: for example, // when compiling /\u1e9e/ for latin-1 inputs. void SMRegExpMacroAssembler::successHandler() { if (!success_label_.used()) { return; } masm_.bind(&success_label_); // Copy captures to the MatchPairs pointed to by the InputOutputData. // Captures are stored as positions, which are negative byte offsets // from the end of the string. We must convert them to actual // indices. // // Index: [ 0 ][ 1 ][ 2 ][ 3 ][ 4 ][ 5 ][END] // Pos (1-byte): [-6 ][-5 ][-4 ][-3 ][-2 ][-1 ][ 0 ] // IS = -6 // Pos (2-byte): [-12][-10][-8 ][-6 ][-4 ][-2 ][ 0 ] // IS = -12 // // To convert a position to an index, we subtract InputStart, and // divide the result by char_size. Register matchesReg = temp1_; masm_.loadPtr(matches(), matchesReg); // Use |backtrack_stack_pointer_| as an additional temp register. This is safe // because we don't read from |backtrack_stack_pointer_| after this point. Register extraTemp = backtrack_stack_pointer_; Register inputStartReg = extraTemp; masm_.loadPtr(inputStart(), inputStartReg); for (int i = 0; i < num_capture_registers_; i++) { masm_.loadPtr(register_location(i), temp0_); masm_.subPtr(inputStartReg, temp0_); if (mode_ == UC16) { masm_.rshiftPtrArithmetic(Imm32(1), temp0_); } masm_.store32(temp0_, Address(matchesReg, i * sizeof(int32_t))); } masm_.movePtr(ImmWord(js::RegExpRunStatus_Success), temp0_); // This falls through to the exit handler. } void SMRegExpMacroAssembler::exitHandler() { masm_.bind(&exit_label_); if (temp0_ != js::jit::ReturnReg) { masm_.movePtr(temp0_, js::jit::ReturnReg); } masm_.freeStack(frameSize_); // Restore registers which were saved on entry for (GeneralRegisterBackwardIterator iter(savedRegisters_); iter.more(); ++iter) { masm_.Pop(*iter); } #ifdef JS_CODEGEN_ARM64 // Now restore the value that was in the PSP register on entry, and return. // Obtain the correct SP from the PSP. masm_.Mov(js::jit::sp, js::jit::PseudoStackPointer64); // Restore the saved value of the PSP register, this value is whatever the // caller had saved in it, not any actual SP value, and it must not be // overwritten subsequently. masm_.Ldr(js::jit::PseudoStackPointer64, vixl::MemOperand(js::jit::sp, 16, vixl::PostIndex)); // Perform a plain Ret(), as abiret() will move SP <- PSP and that is wrong. masm_.Ret(vixl::lr); #else masm_.abiret(); #endif if (exit_with_exception_label_.used()) { masm_.bind(&exit_with_exception_label_); // Exit with an error result to signal thrown exception masm_.movePtr(ImmWord(js::RegExpRunStatus_Error), temp0_); masm_.jump(&exit_label_); } } void SMRegExpMacroAssembler::backtrackHandler() { if (!backtrack_label_.used()) { return; } masm_.bind(&backtrack_label_); Backtrack(); } void SMRegExpMacroAssembler::stackOverflowHandler() { if (!stack_overflow_label_.used()) { return; } js::jit::AutoCreatedBy acb(masm_, "SMRegExpMacroAssembler::stackOverflowHandler"); // Called if the backtrack-stack limit has been hit. masm_.bind(&stack_overflow_label_); // Load argument masm_.movePtr(ImmPtr(isolate()->regexp_stack()), temp1_); // Save registers before calling C function LiveGeneralRegisterSet volatileRegs(GeneralRegisterSet::Volatile()); #ifdef JS_USE_LINK_REGISTER masm_.pushReturnAddress(); #endif // Adjust for the return address on the stack. size_t frameOffset = sizeof(void*); volatileRegs.takeUnchecked(temp0_); volatileRegs.takeUnchecked(temp1_); masm_.PushRegsInMask(volatileRegs); using Fn = bool (*)(RegExpStack * regexp_stack); masm_.setupUnalignedABICall(temp0_); masm_.passABIArg(temp1_); masm_.callWithABI(); masm_.storeCallBoolResult(temp0_); masm_.PopRegsInMask(volatileRegs); // If GrowBacktrackStack returned false, we have failed to grow the // stack, and must exit with a stack-overflow exception. Do this in // the caller so that the stack is adjusted by our return instruction. js::jit::Label overflow_return; masm_.branchTest32(Assembler::Zero, temp0_, temp0_, &overflow_return); // Otherwise, store the new backtrack stack base and recompute the new // top of the stack. Address bsbAddress(masm_.getStackPointer(), offsetof(FrameData, backtrackStackBase) + frameOffset); masm_.subPtr(bsbAddress, backtrack_stack_pointer_); masm_.loadPtr(AbsoluteAddress(ExternalReference::TopOfRegexpStack(isolate())), temp1_); masm_.storePtr(temp1_, bsbAddress); masm_.addPtr(temp1_, backtrack_stack_pointer_); // Resume execution in calling code. masm_.bind(&overflow_return); masm_.ret(); } // This is only used by tracing code. // The return value doesn't matter. RegExpMacroAssembler::IrregexpImplementation SMRegExpMacroAssembler::Implementation() { return kBytecodeImplementation; } // Compare two strings in `/i` mode (ignoreCase, but not unicode). /*static */ uint32_t SMRegExpMacroAssembler::CaseInsensitiveCompareNonUnicode( const char16_t* substring1, const char16_t* substring2, size_t byteLength) { js::AutoUnsafeCallWithABI unsafe; MOZ_ASSERT(byteLength % sizeof(char16_t) == 0); size_t length = byteLength / sizeof(char16_t); for (size_t i = 0; i < length; i++) { char16_t c1 = substring1[i]; char16_t c2 = substring2[i]; if (c1 != c2) { #ifdef JS_HAS_INTL_API // Non-unicode regexps have weird case-folding rules. c1 = RegExpCaseFolding::Canonicalize(c1); c2 = RegExpCaseFolding::Canonicalize(c2); #else // If we aren't building with ICU, fall back to `/iu` mode. The only // differences are in corner cases. c1 = js::unicode::FoldCase(c1); c2 = js::unicode::FoldCase(c2); #endif if (c1 != c2) { return 0; } } } return 1; } // Compare two strings in `/iu` mode (ignoreCase and unicode). /*static */ uint32_t SMRegExpMacroAssembler::CaseInsensitiveCompareUnicode( const char16_t* substring1, const char16_t* substring2, size_t byteLength) { js::AutoUnsafeCallWithABI unsafe; MOZ_ASSERT(byteLength % sizeof(char16_t) == 0); size_t length = byteLength / sizeof(char16_t); for (size_t i = 0; i < length; i++) { char16_t c1 = substring1[i]; char16_t c2 = substring2[i]; if (c1 != c2) { // Unicode regexps use the common and simple case-folding // mappings of the Unicode Character Database. c1 = js::unicode::FoldCase(c1); c2 = js::unicode::FoldCase(c2); if (c1 != c2) { return 0; } } } return 1; } /* static */ bool SMRegExpMacroAssembler::GrowBacktrackStack(RegExpStack* regexp_stack) { js::AutoUnsafeCallWithABI unsafe; size_t size = regexp_stack->memory_size(); return !!regexp_stack->EnsureCapacity(size * 2); } bool SMRegExpMacroAssembler::CanReadUnaligned() const { #if defined(JS_CODEGEN_ARM) return !js::jit::HasAlignmentFault(); #elif defined(JS_CODEGEN_MIPS32) || defined(JS_CODEGEN_MIPS64) return false; #else return true; #endif } } // namespace internal } // namespace v8