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// Copyright 2012 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.
#if V8_TARGET_ARCH_X64
#include "src/base/bits.h"
#include "src/base/division-by-constant.h"
#include "src/base/utils/random-number-generator.h"
#include "src/bootstrapper.h"
#include "src/callable.h"
#include "src/code-factory.h"
#include "src/code-stubs.h"
#include "src/counters.h"
#include "src/debug/debug.h"
#include "src/external-reference-table.h"
#include "src/frames-inl.h"
#include "src/globals.h"
#include "src/heap/heap-inl.h"
#include "src/instruction-stream.h"
#include "src/objects-inl.h"
#include "src/register-configuration.h"
#include "src/snapshot/snapshot.h"
#include "src/x64/assembler-x64.h"
#include "src/x64/macro-assembler-x64.h" // Cannot be the first include.
namespace v8 {
namespace internal {
Operand StackArgumentsAccessor::GetArgumentOperand(int index) {
DCHECK_GE(index, 0);
int receiver = (receiver_mode_ == ARGUMENTS_CONTAIN_RECEIVER) ? 1 : 0;
int displacement_to_last_argument =
base_reg_ == rsp ? kPCOnStackSize : kFPOnStackSize + kPCOnStackSize;
displacement_to_last_argument += extra_displacement_to_last_argument_;
if (argument_count_reg_ == no_reg) {
// argument[0] is at base_reg_ + displacement_to_last_argument +
// (argument_count_immediate_ + receiver - 1) * kPointerSize.
DCHECK_GT(argument_count_immediate_ + receiver, 0);
return Operand(
base_reg_,
displacement_to_last_argument +
(argument_count_immediate_ + receiver - 1 - index) * kPointerSize);
} else {
// argument[0] is at base_reg_ + displacement_to_last_argument +
// argument_count_reg_ * times_pointer_size + (receiver - 1) * kPointerSize.
return Operand(
base_reg_, argument_count_reg_, times_pointer_size,
displacement_to_last_argument + (receiver - 1 - index) * kPointerSize);
}
}
StackArgumentsAccessor::StackArgumentsAccessor(
Register base_reg, const ParameterCount& parameter_count,
StackArgumentsAccessorReceiverMode receiver_mode,
int extra_displacement_to_last_argument)
: base_reg_(base_reg),
argument_count_reg_(parameter_count.is_reg() ? parameter_count.reg()
: no_reg),
argument_count_immediate_(
parameter_count.is_immediate() ? parameter_count.immediate() : 0),
receiver_mode_(receiver_mode),
extra_displacement_to_last_argument_(
extra_displacement_to_last_argument) {}
MacroAssembler::MacroAssembler(Isolate* isolate,
const AssemblerOptions& options, void* buffer,
int size, CodeObjectRequired create_code_object)
: TurboAssembler(isolate, options, buffer, size, create_code_object) {
if (create_code_object == CodeObjectRequired::kYes) {
// Unlike TurboAssembler, which can be used off the main thread and may not
// allocate, macro assembler creates its own copy of the self-reference
// marker in order to disambiguate between self-references during nested
// code generation (e.g.: codegen of the current object triggers stub
// compilation through CodeStub::GetCode()).
code_object_ = Handle<HeapObject>::New(
*isolate->factory()->NewSelfReferenceMarker(), isolate);
}
}
static const int64_t kInvalidRootRegisterDelta = -1;
int64_t TurboAssembler::RootRegisterDelta(ExternalReference other) {
if (predictable_code_size() &&
(other.address() < reinterpret_cast<Address>(isolate()) ||
other.address() >= reinterpret_cast<Address>(isolate() + 1))) {
return kInvalidRootRegisterDelta;
}
return RootRegisterOffsetForExternalReference(isolate(), other);
}
void MacroAssembler::Load(Register destination, ExternalReference source) {
if (root_array_available_ && options().enable_root_array_delta_access) {
int64_t delta = RootRegisterDelta(source);
if (delta != kInvalidRootRegisterDelta && is_int32(delta)) {
movp(destination, Operand(kRootRegister, static_cast<int32_t>(delta)));
return;
}
}
// Safe code.
if (FLAG_embedded_builtins) {
if (root_array_available_ && options().isolate_independent_code) {
IndirectLoadExternalReference(kScratchRegister, source);
movp(destination, Operand(kScratchRegister, 0));
return;
}
}
if (destination == rax) {
load_rax(source);
} else {
Move(kScratchRegister, source);
movp(destination, Operand(kScratchRegister, 0));
}
}
void MacroAssembler::Store(ExternalReference destination, Register source) {
if (root_array_available_ && options().enable_root_array_delta_access) {
int64_t delta = RootRegisterDelta(destination);
if (delta != kInvalidRootRegisterDelta && is_int32(delta)) {
movp(Operand(kRootRegister, static_cast<int32_t>(delta)), source);
return;
}
}
// Safe code.
if (source == rax) {
store_rax(destination);
} else {
Move(kScratchRegister, destination);
movp(Operand(kScratchRegister, 0), source);
}
}
void TurboAssembler::LoadFromConstantsTable(Register destination,
int constant_index) {
DCHECK(isolate()->heap()->RootCanBeTreatedAsConstant(
Heap::kBuiltinsConstantsTableRootIndex));
LoadRoot(destination, Heap::kBuiltinsConstantsTableRootIndex);
movp(destination,
FieldOperand(destination,
FixedArray::kHeaderSize + constant_index * kPointerSize));
}
void TurboAssembler::LoadRootRegisterOffset(Register destination,
intptr_t offset) {
DCHECK(is_int32(offset));
if (offset == 0) {
Move(destination, kRootRegister);
} else {
leap(destination, Operand(kRootRegister, static_cast<int32_t>(offset)));
}
}
void TurboAssembler::LoadRootRelative(Register destination, int32_t offset) {
movp(destination, Operand(kRootRegister, offset));
}
void TurboAssembler::LoadAddress(Register destination,
ExternalReference source) {
if (root_array_available_ && options().enable_root_array_delta_access) {
int64_t delta = RootRegisterDelta(source);
if (delta != kInvalidRootRegisterDelta && is_int32(delta)) {
leap(destination, Operand(kRootRegister, static_cast<int32_t>(delta)));
return;
}
}
// Safe code.
if (FLAG_embedded_builtins) {
if (root_array_available_ && options().isolate_independent_code) {
IndirectLoadExternalReference(destination, source);
return;
}
}
Move(destination, source);
}
Operand TurboAssembler::ExternalOperand(ExternalReference target,
Register scratch) {
if (root_array_available_ && options().enable_root_array_delta_access) {
int64_t delta = RootRegisterDelta(target);
if (delta != kInvalidRootRegisterDelta && is_int32(delta)) {
return Operand(kRootRegister, static_cast<int32_t>(delta));
}
}
Move(scratch, target);
return Operand(scratch, 0);
}
void MacroAssembler::PushAddress(ExternalReference source) {
LoadAddress(kScratchRegister, source);
Push(kScratchRegister);
}
void TurboAssembler::LoadRoot(Register destination, Heap::RootListIndex index) {
DCHECK(root_array_available_);
movp(destination, Operand(kRootRegister, RootRegisterOffset(index)));
}
void MacroAssembler::PushRoot(Heap::RootListIndex index) {
DCHECK(root_array_available_);
Push(Operand(kRootRegister, RootRegisterOffset(index)));
}
void TurboAssembler::CompareRoot(Register with, Heap::RootListIndex index) {
DCHECK(root_array_available_);
cmpp(with, Operand(kRootRegister, RootRegisterOffset(index)));
}
void TurboAssembler::CompareRoot(Operand with, Heap::RootListIndex index) {
DCHECK(root_array_available_);
DCHECK(!with.AddressUsesRegister(kScratchRegister));
LoadRoot(kScratchRegister, index);
cmpp(with, kScratchRegister);
}
void MacroAssembler::RecordWriteField(Register object, int offset,
Register value, Register dst,
SaveFPRegsMode save_fp,
RememberedSetAction remembered_set_action,
SmiCheck smi_check) {
// First, check if a write barrier is even needed. The tests below
// catch stores of Smis.
Label done;
// Skip barrier if writing a smi.
if (smi_check == INLINE_SMI_CHECK) {
JumpIfSmi(value, &done);
}
// Although the object register is tagged, the offset is relative to the start
// of the object, so so offset must be a multiple of kPointerSize.
DCHECK(IsAligned(offset, kPointerSize));
leap(dst, FieldOperand(object, offset));
if (emit_debug_code()) {
Label ok;
testb(dst, Immediate(kPointerSize - 1));
j(zero, &ok, Label::kNear);
int3();
bind(&ok);
}
RecordWrite(object, dst, value, save_fp, remembered_set_action,
OMIT_SMI_CHECK);
bind(&done);
// Clobber clobbered input registers when running with the debug-code flag
// turned on to provoke errors.
if (emit_debug_code()) {
Move(value, kZapValue, RelocInfo::NONE);
Move(dst, kZapValue, RelocInfo::NONE);
}
}
void TurboAssembler::SaveRegisters(RegList registers) {
DCHECK_GT(NumRegs(registers), 0);
for (int i = 0; i < Register::kNumRegisters; ++i) {
if ((registers >> i) & 1u) {
pushq(Register::from_code(i));
}
}
}
void TurboAssembler::RestoreRegisters(RegList registers) {
DCHECK_GT(NumRegs(registers), 0);
for (int i = Register::kNumRegisters - 1; i >= 0; --i) {
if ((registers >> i) & 1u) {
popq(Register::from_code(i));
}
}
}
void TurboAssembler::CallRecordWriteStub(
Register object, Register address,
RememberedSetAction remembered_set_action, SaveFPRegsMode fp_mode) {
Callable const callable =
Builtins::CallableFor(isolate(), Builtins::kRecordWrite);
RegList registers = callable.descriptor().allocatable_registers();
SaveRegisters(registers);
Register object_parameter(callable.descriptor().GetRegisterParameter(
RecordWriteDescriptor::kObject));
Register slot_parameter(
callable.descriptor().GetRegisterParameter(RecordWriteDescriptor::kSlot));
Register isolate_parameter(callable.descriptor().GetRegisterParameter(
RecordWriteDescriptor::kIsolate));
Register remembered_set_parameter(callable.descriptor().GetRegisterParameter(
RecordWriteDescriptor::kRememberedSet));
Register fp_mode_parameter(callable.descriptor().GetRegisterParameter(
RecordWriteDescriptor::kFPMode));
// Prepare argument registers for calling RecordWrite
// slot_parameter <= address
// object_parameter <= object
if (slot_parameter != object) {
// Normal case
Move(slot_parameter, address);
Move(object_parameter, object);
} else if (object_parameter != address) {
// Only slot_parameter and object are the same register
// object_parameter <= object
// slot_parameter <= address
Move(object_parameter, object);
Move(slot_parameter, address);
} else {
// slot_parameter \/ address
// object_parameter /\ object
xchgq(slot_parameter, object_parameter);
}
LoadAddress(isolate_parameter, ExternalReference::isolate_address(isolate()));
Smi* smi_rsa = Smi::FromEnum(remembered_set_action);
Smi* smi_fm = Smi::FromEnum(fp_mode);
Move(remembered_set_parameter, smi_rsa);
if (smi_rsa != smi_fm) {
Move(fp_mode_parameter, smi_fm);
} else {
movq(fp_mode_parameter, remembered_set_parameter);
}
Call(callable.code(), RelocInfo::CODE_TARGET);
RestoreRegisters(registers);
}
void MacroAssembler::RecordWrite(Register object, Register address,
Register value, SaveFPRegsMode fp_mode,
RememberedSetAction remembered_set_action,
SmiCheck smi_check) {
DCHECK(object != value);
DCHECK(object != address);
DCHECK(value != address);
AssertNotSmi(object);
if (remembered_set_action == OMIT_REMEMBERED_SET &&
!FLAG_incremental_marking) {
return;
}
if (emit_debug_code()) {
Label ok;
cmpp(value, Operand(address, 0));
j(equal, &ok, Label::kNear);
int3();
bind(&ok);
}
// First, check if a write barrier is even needed. The tests below
// catch stores of smis and stores into the young generation.
Label done;
if (smi_check == INLINE_SMI_CHECK) {
// Skip barrier if writing a smi.
JumpIfSmi(value, &done);
}
CheckPageFlag(value,
value, // Used as scratch.
MemoryChunk::kPointersToHereAreInterestingMask, zero, &done,
Label::kNear);
CheckPageFlag(object,
value, // Used as scratch.
MemoryChunk::kPointersFromHereAreInterestingMask,
zero,
&done,
Label::kNear);
CallRecordWriteStub(object, address, remembered_set_action, fp_mode);
bind(&done);
// Count number of write barriers in generated code.
isolate()->counters()->write_barriers_static()->Increment();
IncrementCounter(isolate()->counters()->write_barriers_dynamic(), 1);
// Clobber clobbered registers when running with the debug-code flag
// turned on to provoke errors.
if (emit_debug_code()) {
Move(address, kZapValue, RelocInfo::NONE);
Move(value, kZapValue, RelocInfo::NONE);
}
}
void TurboAssembler::Assert(Condition cc, AbortReason reason) {
if (emit_debug_code()) Check(cc, reason);
}
void TurboAssembler::AssertUnreachable(AbortReason reason) {
if (emit_debug_code()) Abort(reason);
}
void TurboAssembler::Check(Condition cc, AbortReason reason) {
Label L;
j(cc, &L, Label::kNear);
Abort(reason);
// Control will not return here.
bind(&L);
}
void TurboAssembler::CheckStackAlignment() {
int frame_alignment = base::OS::ActivationFrameAlignment();
int frame_alignment_mask = frame_alignment - 1;
if (frame_alignment > kPointerSize) {
DCHECK(base::bits::IsPowerOfTwo(frame_alignment));
Label alignment_as_expected;
testp(rsp, Immediate(frame_alignment_mask));
j(zero, &alignment_as_expected, Label::kNear);
// Abort if stack is not aligned.
int3();
bind(&alignment_as_expected);
}
}
void TurboAssembler::Abort(AbortReason reason) {
#ifdef DEBUG
const char* msg = GetAbortReason(reason);
RecordComment("Abort message: ");
RecordComment(msg);
#endif
// Avoid emitting call to builtin if requested.
if (trap_on_abort()) {
int3();
return;
}
if (should_abort_hard()) {
// We don't care if we constructed a frame. Just pretend we did.
FrameScope assume_frame(this, StackFrame::NONE);
movl(arg_reg_1, Immediate(static_cast<int>(reason)));
PrepareCallCFunction(1);
LoadAddress(rax, ExternalReference::abort_with_reason());
call(rax);
return;
}
Move(rdx, Smi::FromInt(static_cast<int>(reason)));
if (!has_frame()) {
// We don't actually want to generate a pile of code for this, so just
// claim there is a stack frame, without generating one.
FrameScope scope(this, StackFrame::NONE);
Call(BUILTIN_CODE(isolate(), Abort), RelocInfo::CODE_TARGET);
} else {
Call(BUILTIN_CODE(isolate(), Abort), RelocInfo::CODE_TARGET);
}
// Control will not return here.
int3();
}
void TurboAssembler::CallStubDelayed(CodeStub* stub) {
DCHECK(AllowThisStubCall(stub)); // Calls are not allowed in some stubs
call(stub);
}
void MacroAssembler::CallStub(CodeStub* stub) {
DCHECK(AllowThisStubCall(stub)); // Calls are not allowed in some stubs
Call(stub->GetCode(), RelocInfo::CODE_TARGET);
}
void MacroAssembler::TailCallStub(CodeStub* stub) {
Jump(stub->GetCode(), RelocInfo::CODE_TARGET);
}
bool TurboAssembler::AllowThisStubCall(CodeStub* stub) {
return has_frame() || !stub->SometimesSetsUpAFrame();
}
void TurboAssembler::CallRuntimeWithCEntry(Runtime::FunctionId fid,
Register centry) {
const Runtime::Function* f = Runtime::FunctionForId(fid);
// TODO(1236192): Most runtime routines don't need the number of
// arguments passed in because it is constant. At some point we
// should remove this need and make the runtime routine entry code
// smarter.
Set(rax, f->nargs);
LoadAddress(rbx, ExternalReference::Create(f));
DCHECK(!AreAliased(centry, rax, rbx));
addp(rcx, Immediate(Code::kHeaderSize - kHeapObjectTag));
Call(centry);
}
void MacroAssembler::CallRuntime(const Runtime::Function* f,
int num_arguments,
SaveFPRegsMode save_doubles) {
// If the expected number of arguments of the runtime function is
// constant, we check that the actual number of arguments match the
// expectation.
CHECK(f->nargs < 0 || f->nargs == num_arguments);
// TODO(1236192): Most runtime routines don't need the number of
// arguments passed in because it is constant. At some point we
// should remove this need and make the runtime routine entry code
// smarter.
Set(rax, num_arguments);
LoadAddress(rbx, ExternalReference::Create(f));
Handle<Code> code =
CodeFactory::CEntry(isolate(), f->result_size, save_doubles);
Call(code, RelocInfo::CODE_TARGET);
}
void MacroAssembler::TailCallRuntime(Runtime::FunctionId fid) {
// ----------- S t a t e -------------
// -- rsp[0] : return address
// -- rsp[8] : argument num_arguments - 1
// ...
// -- rsp[8 * num_arguments] : argument 0 (receiver)
//
// For runtime functions with variable arguments:
// -- rax : number of arguments
// -----------------------------------
const Runtime::Function* function = Runtime::FunctionForId(fid);
DCHECK_EQ(1, function->result_size);
if (function->nargs >= 0) {
Set(rax, function->nargs);
}
JumpToExternalReference(ExternalReference::Create(fid));
}
void MacroAssembler::JumpToExternalReference(const ExternalReference& ext,
bool builtin_exit_frame) {
// Set the entry point and jump to the C entry runtime stub.
LoadAddress(rbx, ext);
Handle<Code> code = CodeFactory::CEntry(isolate(), 1, kDontSaveFPRegs,
kArgvOnStack, builtin_exit_frame);
Jump(code, RelocInfo::CODE_TARGET);
}
static constexpr Register saved_regs[] = {rax, rcx, rdx, rbx, rbp, rsi,
rdi, r8, r9, r10, r11};
static constexpr int kNumberOfSavedRegs = sizeof(saved_regs) / sizeof(Register);
int TurboAssembler::RequiredStackSizeForCallerSaved(SaveFPRegsMode fp_mode,
Register exclusion1,
Register exclusion2,
Register exclusion3) const {
int bytes = 0;
for (int i = 0; i < kNumberOfSavedRegs; i++) {
Register reg = saved_regs[i];
if (reg != exclusion1 && reg != exclusion2 && reg != exclusion3) {
bytes += kPointerSize;
}
}
// R12 to r15 are callee save on all platforms.
if (fp_mode == kSaveFPRegs) {
bytes += kDoubleSize * XMMRegister::kNumRegisters;
}
return bytes;
}
int TurboAssembler::PushCallerSaved(SaveFPRegsMode fp_mode, Register exclusion1,
Register exclusion2, Register exclusion3) {
// We don't allow a GC during a store buffer overflow so there is no need to
// store the registers in any particular way, but we do have to store and
// restore them.
int bytes = 0;
for (int i = 0; i < kNumberOfSavedRegs; i++) {
Register reg = saved_regs[i];
if (reg != exclusion1 && reg != exclusion2 && reg != exclusion3) {
pushq(reg);
bytes += kPointerSize;
}
}
// R12 to r15 are callee save on all platforms.
if (fp_mode == kSaveFPRegs) {
int delta = kDoubleSize * XMMRegister::kNumRegisters;
subp(rsp, Immediate(delta));
for (int i = 0; i < XMMRegister::kNumRegisters; i++) {
XMMRegister reg = XMMRegister::from_code(i);
Movsd(Operand(rsp, i * kDoubleSize), reg);
}
bytes += delta;
}
return bytes;
}
int TurboAssembler::PopCallerSaved(SaveFPRegsMode fp_mode, Register exclusion1,
Register exclusion2, Register exclusion3) {
int bytes = 0;
if (fp_mode == kSaveFPRegs) {
for (int i = 0; i < XMMRegister::kNumRegisters; i++) {
XMMRegister reg = XMMRegister::from_code(i);
Movsd(reg, Operand(rsp, i * kDoubleSize));
}
int delta = kDoubleSize * XMMRegister::kNumRegisters;
addp(rsp, Immediate(kDoubleSize * XMMRegister::kNumRegisters));
bytes += delta;
}
for (int i = kNumberOfSavedRegs - 1; i >= 0; i--) {
Register reg = saved_regs[i];
if (reg != exclusion1 && reg != exclusion2 && reg != exclusion3) {
popq(reg);
bytes += kPointerSize;
}
}
return bytes;
}
void TurboAssembler::Cvtss2sd(XMMRegister dst, XMMRegister src) {
if (CpuFeatures::IsSupported(AVX)) {
CpuFeatureScope scope(this, AVX);
vcvtss2sd(dst, src, src);
} else {
cvtss2sd(dst, src);
}
}
void TurboAssembler::Cvtss2sd(XMMRegister dst, Operand src) {
if (CpuFeatures::IsSupported(AVX)) {
CpuFeatureScope scope(this, AVX);
vcvtss2sd(dst, dst, src);
} else {
cvtss2sd(dst, src);
}
}
void TurboAssembler::Cvtsd2ss(XMMRegister dst, XMMRegister src) {
if (CpuFeatures::IsSupported(AVX)) {
CpuFeatureScope scope(this, AVX);
vcvtsd2ss(dst, src, src);
} else {
cvtsd2ss(dst, src);
}
}
void TurboAssembler::Cvtsd2ss(XMMRegister dst, Operand src) {
if (CpuFeatures::IsSupported(AVX)) {
CpuFeatureScope scope(this, AVX);
vcvtsd2ss(dst, dst, src);
} else {
cvtsd2ss(dst, src);
}
}
void TurboAssembler::Cvtlsi2sd(XMMRegister dst, Register src) {
if (CpuFeatures::IsSupported(AVX)) {
CpuFeatureScope scope(this, AVX);
vxorpd(dst, dst, dst);
vcvtlsi2sd(dst, dst, src);
} else {
xorpd(dst, dst);
cvtlsi2sd(dst, src);
}
}
void TurboAssembler::Cvtlsi2sd(XMMRegister dst, Operand src) {
if (CpuFeatures::IsSupported(AVX)) {
CpuFeatureScope scope(this, AVX);
vxorpd(dst, dst, dst);
vcvtlsi2sd(dst, dst, src);
} else {
xorpd(dst, dst);
cvtlsi2sd(dst, src);
}
}
void TurboAssembler::Cvtlsi2ss(XMMRegister dst, Register src) {
if (CpuFeatures::IsSupported(AVX)) {
CpuFeatureScope scope(this, AVX);
vxorps(dst, dst, dst);
vcvtlsi2ss(dst, dst, src);
} else {
xorps(dst, dst);
cvtlsi2ss(dst, src);
}
}
void TurboAssembler::Cvtlsi2ss(XMMRegister dst, Operand src) {
if (CpuFeatures::IsSupported(AVX)) {
CpuFeatureScope scope(this, AVX);
vxorps(dst, dst, dst);
vcvtlsi2ss(dst, dst, src);
} else {
xorps(dst, dst);
cvtlsi2ss(dst, src);
}
}
void TurboAssembler::Cvtqsi2ss(XMMRegister dst, Register src) {
if (CpuFeatures::IsSupported(AVX)) {
CpuFeatureScope scope(this, AVX);
vxorps(dst, dst, dst);
vcvtqsi2ss(dst, dst, src);
} else {
xorps(dst, dst);
cvtqsi2ss(dst, src);
}
}
void TurboAssembler::Cvtqsi2ss(XMMRegister dst, Operand src) {
if (CpuFeatures::IsSupported(AVX)) {
CpuFeatureScope scope(this, AVX);
vxorps(dst, dst, dst);
vcvtqsi2ss(dst, dst, src);
} else {
xorps(dst, dst);
cvtqsi2ss(dst, src);
}
}
void TurboAssembler::Cvtqsi2sd(XMMRegister dst, Register src) {
if (CpuFeatures::IsSupported(AVX)) {
CpuFeatureScope scope(this, AVX);
vxorpd(dst, dst, dst);
vcvtqsi2sd(dst, dst, src);
} else {
xorpd(dst, dst);
cvtqsi2sd(dst, src);
}
}
void TurboAssembler::Cvtqsi2sd(XMMRegister dst, Operand src) {
if (CpuFeatures::IsSupported(AVX)) {
CpuFeatureScope scope(this, AVX);
vxorpd(dst, dst, dst);
vcvtqsi2sd(dst, dst, src);
} else {
xorpd(dst, dst);
cvtqsi2sd(dst, src);
}
}
void TurboAssembler::Cvtlui2ss(XMMRegister dst, Register src) {
// Zero-extend the 32 bit value to 64 bit.
movl(kScratchRegister, src);
Cvtqsi2ss(dst, kScratchRegister);
}
void TurboAssembler::Cvtlui2ss(XMMRegister dst, Operand src) {
// Zero-extend the 32 bit value to 64 bit.
movl(kScratchRegister, src);
Cvtqsi2ss(dst, kScratchRegister);
}
void TurboAssembler::Cvtlui2sd(XMMRegister dst, Register src) {
// Zero-extend the 32 bit value to 64 bit.
movl(kScratchRegister, src);
Cvtqsi2sd(dst, kScratchRegister);
}
void TurboAssembler::Cvtlui2sd(XMMRegister dst, Operand src) {
// Zero-extend the 32 bit value to 64 bit.
movl(kScratchRegister, src);
Cvtqsi2sd(dst, kScratchRegister);
}
void TurboAssembler::Cvtqui2ss(XMMRegister dst, Register src) {
Label done;
Cvtqsi2ss(dst, src);
testq(src, src);
j(positive, &done, Label::kNear);
// Compute {src/2 | (src&1)} (retain the LSB to avoid rounding errors).
if (src != kScratchRegister) movq(kScratchRegister, src);
shrq(kScratchRegister, Immediate(1));
// The LSB is shifted into CF. If it is set, set the LSB in {tmp}.
Label msb_not_set;
j(not_carry, &msb_not_set, Label::kNear);
orq(kScratchRegister, Immediate(1));
bind(&msb_not_set);
Cvtqsi2ss(dst, kScratchRegister);
addss(dst, dst);
bind(&done);
}
void TurboAssembler::Cvtqui2ss(XMMRegister dst, Operand src) {
movq(kScratchRegister, src);
Cvtqui2ss(dst, kScratchRegister);
}
void TurboAssembler::Cvtqui2sd(XMMRegister dst, Register src) {
Label done;
Cvtqsi2sd(dst, src);
testq(src, src);
j(positive, &done, Label::kNear);
// Compute {src/2 | (src&1)} (retain the LSB to avoid rounding errors).
if (src != kScratchRegister) movq(kScratchRegister, src);
shrq(kScratchRegister, Immediate(1));
// The LSB is shifted into CF. If it is set, set the LSB in {tmp}.
Label msb_not_set;
j(not_carry, &msb_not_set, Label::kNear);
orq(kScratchRegister, Immediate(1));
bind(&msb_not_set);
Cvtqsi2sd(dst, kScratchRegister);
addsd(dst, dst);
bind(&done);
}
void TurboAssembler::Cvtqui2sd(XMMRegister dst, Operand src) {
movq(kScratchRegister, src);
Cvtqui2sd(dst, kScratchRegister);
}
void TurboAssembler::Cvttss2si(Register dst, XMMRegister src) {
if (CpuFeatures::IsSupported(AVX)) {
CpuFeatureScope scope(this, AVX);
vcvttss2si(dst, src);
} else {
cvttss2si(dst, src);
}
}
void TurboAssembler::Cvttss2si(Register dst, Operand src) {
if (CpuFeatures::IsSupported(AVX)) {
CpuFeatureScope scope(this, AVX);
vcvttss2si(dst, src);
} else {
cvttss2si(dst, src);
}
}
void TurboAssembler::Cvttsd2si(Register dst, XMMRegister src) {
if (CpuFeatures::IsSupported(AVX)) {
CpuFeatureScope scope(this, AVX);
vcvttsd2si(dst, src);
} else {
cvttsd2si(dst, src);
}
}
void TurboAssembler::Cvttsd2si(Register dst, Operand src) {
if (CpuFeatures::IsSupported(AVX)) {
CpuFeatureScope scope(this, AVX);
vcvttsd2si(dst, src);
} else {
cvttsd2si(dst, src);
}
}
void TurboAssembler::Cvttss2siq(Register dst, XMMRegister src) {
if (CpuFeatures::IsSupported(AVX)) {
CpuFeatureScope scope(this, AVX);
vcvttss2siq(dst, src);
} else {
cvttss2siq(dst, src);
}
}
void TurboAssembler::Cvttss2siq(Register dst, Operand src) {
if (CpuFeatures::IsSupported(AVX)) {
CpuFeatureScope scope(this, AVX);
vcvttss2siq(dst, src);
} else {
cvttss2siq(dst, src);
}
}
void TurboAssembler::Cvttsd2siq(Register dst, XMMRegister src) {
if (CpuFeatures::IsSupported(AVX)) {
CpuFeatureScope scope(this, AVX);
vcvttsd2siq(dst, src);
} else {
cvttsd2siq(dst, src);
}
}
void TurboAssembler::Cvttsd2siq(Register dst, Operand src) {
if (CpuFeatures::IsSupported(AVX)) {
CpuFeatureScope scope(this, AVX);
vcvttsd2siq(dst, src);
} else {
cvttsd2siq(dst, src);
}
}
namespace {
template <typename OperandOrXMMRegister, bool is_double>
void ConvertFloatToUint64(TurboAssembler* tasm, Register dst,
OperandOrXMMRegister src, Label* fail) {
Label success;
// There does not exist a native float-to-uint instruction, so we have to use
// a float-to-int, and postprocess the result.
if (is_double) {
tasm->Cvttsd2siq(dst, src);
} else {
tasm->Cvttss2siq(dst, src);
}
// If the result of the conversion is positive, we are already done.
tasm->testq(dst, dst);
tasm->j(positive, &success);
// The result of the first conversion was negative, which means that the
// input value was not within the positive int64 range. We subtract 2^63
// and convert it again to see if it is within the uint64 range.
if (is_double) {
tasm->Move(kScratchDoubleReg, -9223372036854775808.0);
tasm->addsd(kScratchDoubleReg, src);
tasm->Cvttsd2siq(dst, kScratchDoubleReg);
} else {
tasm->Move(kScratchDoubleReg, -9223372036854775808.0f);
tasm->addss(kScratchDoubleReg, src);
tasm->Cvttss2siq(dst, kScratchDoubleReg);
}
tasm->testq(dst, dst);
// The only possible negative value here is 0x80000000000000000, which is
// used on x64 to indicate an integer overflow.
tasm->j(negative, fail ? fail : &success);
// The input value is within uint64 range and the second conversion worked
// successfully, but we still have to undo the subtraction we did
// earlier.
tasm->Set(kScratchRegister, 0x8000000000000000);
tasm->orq(dst, kScratchRegister);
tasm->bind(&success);
}
} // namespace
void TurboAssembler::Cvttsd2uiq(Register dst, Operand src, Label* success) {
ConvertFloatToUint64<Operand, true>(this, dst, src, success);
}
void TurboAssembler::Cvttsd2uiq(Register dst, XMMRegister src, Label* success) {
ConvertFloatToUint64<XMMRegister, true>(this, dst, src, success);
}
void TurboAssembler::Cvttss2uiq(Register dst, Operand src, Label* success) {
ConvertFloatToUint64<Operand, false>(this, dst, src, success);
}
void TurboAssembler::Cvttss2uiq(Register dst, XMMRegister src, Label* success) {
ConvertFloatToUint64<XMMRegister, false>(this, dst, src, success);
}
void MacroAssembler::Load(Register dst, Operand src, Representation r) {
DCHECK(!r.IsDouble());
if (r.IsInteger8()) {
movsxbq(dst, src);
} else if (r.IsUInteger8()) {
movzxbl(dst, src);
} else if (r.IsInteger16()) {
movsxwq(dst, src);
} else if (r.IsUInteger16()) {
movzxwl(dst, src);
} else if (r.IsInteger32()) {
movl(dst, src);
} else {
movp(dst, src);
}
}
void MacroAssembler::Store(Operand dst, Register src, Representation r) {
DCHECK(!r.IsDouble());
if (r.IsInteger8() || r.IsUInteger8()) {
movb(dst, src);
} else if (r.IsInteger16() || r.IsUInteger16()) {
movw(dst, src);
} else if (r.IsInteger32()) {
movl(dst, src);
} else {
if (r.IsHeapObject()) {
AssertNotSmi(src);
} else if (r.IsSmi()) {
AssertSmi(src);
}
movp(dst, src);
}
}
void TurboAssembler::Set(Register dst, int64_t x) {
if (x == 0) {
xorl(dst, dst);
} else if (is_uint32(x)) {
movl(dst, Immediate(static_cast<uint32_t>(x)));
} else if (is_int32(x)) {
movq(dst, Immediate(static_cast<int32_t>(x)));
} else {
movq(dst, x);
}
}
void TurboAssembler::Set(Operand dst, intptr_t x) {
if (kPointerSize == kInt64Size) {
if (is_int32(x)) {
movp(dst, Immediate(static_cast<int32_t>(x)));
} else {
Set(kScratchRegister, x);
movp(dst, kScratchRegister);
}
} else {
movp(dst, Immediate(static_cast<int32_t>(x)));
}
}
// ----------------------------------------------------------------------------
// Smi tagging, untagging and tag detection.
Register TurboAssembler::GetSmiConstant(Smi* source) {
STATIC_ASSERT(kSmiTag == 0);
int value = source->value();
if (value == 0) {
xorl(kScratchRegister, kScratchRegister);
return kScratchRegister;
}
Move(kScratchRegister, source);
return kScratchRegister;
}
void TurboAssembler::Move(Register dst, Smi* source) {
STATIC_ASSERT(kSmiTag == 0);
int value = source->value();
if (value == 0) {
xorl(dst, dst);
} else {
Move(dst, reinterpret_cast<Address>(source), RelocInfo::NONE);
}
}
void TurboAssembler::Move(Register dst, ExternalReference ext) {
if (FLAG_embedded_builtins) {
if (root_array_available_ && options().isolate_independent_code) {
IndirectLoadExternalReference(dst, ext);
return;
}
}
movp(dst, ext.address(), RelocInfo::EXTERNAL_REFERENCE);
}
void MacroAssembler::SmiTag(Register dst, Register src) {
STATIC_ASSERT(kSmiTag == 0);
if (dst != src) {
movp(dst, src);
}
DCHECK(SmiValuesAre32Bits() || SmiValuesAre31Bits());
shlp(dst, Immediate(kSmiShift));
}
void TurboAssembler::SmiUntag(Register dst, Register src) {
STATIC_ASSERT(kSmiTag == 0);
if (dst != src) {
movp(dst, src);
}
DCHECK(SmiValuesAre32Bits() || SmiValuesAre31Bits());
sarp(dst, Immediate(kSmiShift));
}
void TurboAssembler::SmiUntag(Register dst, Operand src) {
if (SmiValuesAre32Bits()) {
movl(dst, Operand(src, kSmiShift / kBitsPerByte));
// Sign extend to 64-bit.
movsxlq(dst, dst);
} else {
DCHECK(SmiValuesAre31Bits());
movp(dst, src);
sarp(dst, Immediate(kSmiShift));
}
}
void MacroAssembler::SmiCompare(Register smi1, Register smi2) {
AssertSmi(smi1);
AssertSmi(smi2);
cmpp(smi1, smi2);
}
void MacroAssembler::SmiCompare(Register dst, Smi* src) {
AssertSmi(dst);
Cmp(dst, src);
}
void MacroAssembler::Cmp(Register dst, Smi* src) {
DCHECK_NE(dst, kScratchRegister);
if (src->value() == 0) {
testp(dst, dst);
} else {
Register constant_reg = GetSmiConstant(src);
cmpp(dst, constant_reg);
}
}
void MacroAssembler::SmiCompare(Register dst, Operand src) {
AssertSmi(dst);
AssertSmi(src);
cmpp(dst, src);
}
void MacroAssembler::SmiCompare(Operand dst, Register src) {
AssertSmi(dst);
AssertSmi(src);
cmpp(dst, src);
}
void MacroAssembler::SmiCompare(Operand dst, Smi* src) {
AssertSmi(dst);
if (SmiValuesAre32Bits()) {
cmpl(Operand(dst, kSmiShift / kBitsPerByte), Immediate(src->value()));
} else {
DCHECK(SmiValuesAre31Bits());
cmpl(dst, Immediate(src));
}
}
void MacroAssembler::Cmp(Operand dst, Smi* src) {
// The Operand cannot use the smi register.
Register smi_reg = GetSmiConstant(src);
DCHECK(!dst.AddressUsesRegister(smi_reg));
cmpp(dst, smi_reg);
}
Condition TurboAssembler::CheckSmi(Register src) {
STATIC_ASSERT(kSmiTag == 0);
testb(src, Immediate(kSmiTagMask));
return zero;
}
Condition TurboAssembler::CheckSmi(Operand src) {
STATIC_ASSERT(kSmiTag == 0);
testb(src, Immediate(kSmiTagMask));
return zero;
}
void TurboAssembler::JumpIfSmi(Register src, Label* on_smi,
Label::Distance near_jump) {
Condition smi = CheckSmi(src);
j(smi, on_smi, near_jump);
}
void MacroAssembler::JumpIfNotSmi(Register src,
Label* on_not_smi,
Label::Distance near_jump) {
Condition smi = CheckSmi(src);
j(NegateCondition(smi), on_not_smi, near_jump);
}
void MacroAssembler::JumpIfNotSmi(Operand src, Label* on_not_smi,
Label::Distance near_jump) {
Condition smi = CheckSmi(src);
j(NegateCondition(smi), on_not_smi, near_jump);
}
void MacroAssembler::SmiAddConstant(Operand dst, Smi* constant) {
if (constant->value() != 0) {
if (SmiValuesAre32Bits()) {
addl(Operand(dst, kSmiShift / kBitsPerByte),
Immediate(constant->value()));
} else {
DCHECK(SmiValuesAre31Bits());
if (kPointerSize == kInt64Size) {
// Sign-extend value after addition
movl(kScratchRegister, dst);
addl(kScratchRegister, Immediate(constant));
movsxlq(kScratchRegister, kScratchRegister);
movq(dst, kScratchRegister);
} else {
DCHECK_EQ(kSmiShiftSize, 32);
addp(dst, Immediate(constant));
}
}
}
}
SmiIndex MacroAssembler::SmiToIndex(Register dst,
Register src,
int shift) {
if (SmiValuesAre32Bits()) {
DCHECK(is_uint6(shift));
// There is a possible optimization if shift is in the range 60-63, but that
// will (and must) never happen.
if (dst != src) {
movp(dst, src);
}
if (shift < kSmiShift) {
sarp(dst, Immediate(kSmiShift - shift));
} else {
shlp(dst, Immediate(shift - kSmiShift));
}
return SmiIndex(dst, times_1);
} else {
DCHECK(SmiValuesAre31Bits());
if (dst != src) {
movp(dst, src);
}
// We have to sign extend the index register to 64-bit as the SMI might
// be negative.
movsxlq(dst, dst);
if (shift < kSmiShift) {
sarq(dst, Immediate(kSmiShift - shift));
} else if (shift != kSmiShift) {
if (shift - kSmiShift <= static_cast<int>(times_8)) {
return SmiIndex(dst, static_cast<ScaleFactor>(shift - kSmiShift));
}
shlq(dst, Immediate(shift - kSmiShift));
}
return SmiIndex(dst, times_1);
}
}
void TurboAssembler::Push(Smi* source) {
intptr_t smi = reinterpret_cast<intptr_t>(source);
if (is_int32(smi)) {
Push(Immediate(static_cast<int32_t>(smi)));
return;
}
int first_byte_set = base::bits::CountTrailingZeros64(smi) / 8;
int last_byte_set = (63 - base::bits::CountLeadingZeros64(smi)) / 8;
if (first_byte_set == last_byte_set && kPointerSize == kInt64Size) {
// This sequence has only 7 bytes, compared to the 12 bytes below.
Push(Immediate(0));
movb(Operand(rsp, first_byte_set),
Immediate(static_cast<int8_t>(smi >> (8 * first_byte_set))));
return;
}
Register constant = GetSmiConstant(source);
Push(constant);
}
// ----------------------------------------------------------------------------
void TurboAssembler::Move(Register dst, Register src) {
if (dst != src) {
movp(dst, src);
}
}
void TurboAssembler::MoveNumber(Register dst, double value) {
int32_t smi;
if (DoubleToSmiInteger(value, &smi)) {
Move(dst, Smi::FromInt(smi));
} else {
movp_heap_number(dst, value);
}
}
void TurboAssembler::Move(XMMRegister dst, uint32_t src) {
if (src == 0) {
Xorps(dst, dst);
} else {
unsigned nlz = base::bits::CountLeadingZeros(src);
unsigned ntz = base::bits::CountTrailingZeros(src);
unsigned pop = base::bits::CountPopulation(src);
DCHECK_NE(0u, pop);
if (pop + ntz + nlz == 32) {
Pcmpeqd(dst, dst);
if (ntz) Pslld(dst, static_cast<byte>(ntz + nlz));
if (nlz) Psrld(dst, static_cast<byte>(nlz));
} else {
movl(kScratchRegister, Immediate(src));
Movd(dst, kScratchRegister);
}
}
}
void TurboAssembler::Move(XMMRegister dst, uint64_t src) {
if (src == 0) {
Xorpd(dst, dst);
} else {
unsigned nlz = base::bits::CountLeadingZeros(src);
unsigned ntz = base::bits::CountTrailingZeros(src);
unsigned pop = base::bits::CountPopulation(src);
DCHECK_NE(0u, pop);
if (pop + ntz + nlz == 64) {
Pcmpeqd(dst, dst);
if (ntz) Psllq(dst, static_cast<byte>(ntz + nlz));
if (nlz) Psrlq(dst, static_cast<byte>(nlz));
} else {
uint32_t lower = static_cast<uint32_t>(src);
uint32_t upper = static_cast<uint32_t>(src >> 32);
if (upper == 0) {
Move(dst, lower);
} else {
movq(kScratchRegister, src);
Movq(dst, kScratchRegister);
}
}
}
}
// ----------------------------------------------------------------------------
void MacroAssembler::Absps(XMMRegister dst) {
Andps(dst,
ExternalOperand(ExternalReference::address_of_float_abs_constant()));
}
void MacroAssembler::Negps(XMMRegister dst) {
Xorps(dst,
ExternalOperand(ExternalReference::address_of_float_neg_constant()));
}
void MacroAssembler::Abspd(XMMRegister dst) {
Andps(dst,
ExternalOperand(ExternalReference::address_of_double_abs_constant()));
}
void MacroAssembler::Negpd(XMMRegister dst) {
Xorps(dst,
ExternalOperand(ExternalReference::address_of_double_neg_constant()));
}
void MacroAssembler::Cmp(Register dst, Handle<Object> source) {
AllowDeferredHandleDereference smi_check;
if (source->IsSmi()) {
Cmp(dst, Smi::cast(*source));
} else {
Move(kScratchRegister, Handle<HeapObject>::cast(source));
cmpp(dst, kScratchRegister);
}
}
void MacroAssembler::Cmp(Operand dst, Handle<Object> source) {
AllowDeferredHandleDereference smi_check;
if (source->IsSmi()) {
Cmp(dst, Smi::cast(*source));
} else {
Move(kScratchRegister, Handle<HeapObject>::cast(source));
cmpp(dst, kScratchRegister);
}
}
void TurboAssembler::Push(Handle<HeapObject> source) {
Move(kScratchRegister, source);
Push(kScratchRegister);
}
void TurboAssembler::Move(Register result, Handle<HeapObject> object,
RelocInfo::Mode rmode) {
if (FLAG_embedded_builtins) {
if (root_array_available_ && options().isolate_independent_code) {
IndirectLoadConstant(result, object);
return;
}
}
movp(result, object.address(), rmode);
}
void TurboAssembler::Move(Operand dst, Handle<HeapObject> object,
RelocInfo::Mode rmode) {
Move(kScratchRegister, object, rmode);
movp(dst, kScratchRegister);
}
void MacroAssembler::Drop(int stack_elements) {
if (stack_elements > 0) {
addp(rsp, Immediate(stack_elements * kPointerSize));
}
}
void MacroAssembler::DropUnderReturnAddress(int stack_elements,
Register scratch) {
DCHECK_GT(stack_elements, 0);
if (kPointerSize == kInt64Size && stack_elements == 1) {
popq(MemOperand(rsp, 0));
return;
}
PopReturnAddressTo(scratch);
Drop(stack_elements);
PushReturnAddressFrom(scratch);
}
void TurboAssembler::Push(Register src) {
if (kPointerSize == kInt64Size) {
pushq(src);
} else {
// x32 uses 64-bit push for rbp in the prologue.
DCHECK(src.code() != rbp.code());
leal(rsp, Operand(rsp, -4));
movp(Operand(rsp, 0), src);
}
}
void TurboAssembler::Push(Operand src) {
if (kPointerSize == kInt64Size) {
pushq(src);
} else {
movp(kScratchRegister, src);
leal(rsp, Operand(rsp, -4));
movp(Operand(rsp, 0), kScratchRegister);
}
}
void MacroAssembler::PushQuad(Operand src) {
if (kPointerSize == kInt64Size) {
pushq(src);
} else {
movp(kScratchRegister, src);
pushq(kScratchRegister);
}
}
void TurboAssembler::Push(Immediate value) {
if (kPointerSize == kInt64Size) {
pushq(value);
} else {
leal(rsp, Operand(rsp, -4));
movp(Operand(rsp, 0), value);
}
}
void MacroAssembler::PushImm32(int32_t imm32) {
if (kPointerSize == kInt64Size) {
pushq_imm32(imm32);
} else {
leal(rsp, Operand(rsp, -4));
movp(Operand(rsp, 0), Immediate(imm32));
}
}
void MacroAssembler::Pop(Register dst) {
if (kPointerSize == kInt64Size) {
popq(dst);
} else {
// x32 uses 64-bit pop for rbp in the epilogue.
DCHECK(dst.code() != rbp.code());
movp(dst, Operand(rsp, 0));
leal(rsp, Operand(rsp, 4));
}
}
void MacroAssembler::Pop(Operand dst) {
if (kPointerSize == kInt64Size) {
popq(dst);
} else {
Register scratch = dst.AddressUsesRegister(kScratchRegister)
? kRootRegister : kScratchRegister;
movp(scratch, Operand(rsp, 0));
movp(dst, scratch);
leal(rsp, Operand(rsp, 4));
if (scratch == kRootRegister) {
// Restore kRootRegister.
InitializeRootRegister();
}
}
}
void MacroAssembler::PopQuad(Operand dst) {
if (kPointerSize == kInt64Size) {
popq(dst);
} else {
popq(kScratchRegister);
movp(dst, kScratchRegister);
}
}
void TurboAssembler::Jump(ExternalReference ext) {
LoadAddress(kScratchRegister, ext);
jmp(kScratchRegister);
}
void TurboAssembler::Jump(Operand op) {
if (kPointerSize == kInt64Size) {
jmp(op);
} else {
movp(kScratchRegister, op);
jmp(kScratchRegister);
}
}
void TurboAssembler::Jump(Address destination, RelocInfo::Mode rmode) {
Move(kScratchRegister, destination, rmode);
jmp(kScratchRegister);
}
void TurboAssembler::Jump(Handle<Code> code_object, RelocInfo::Mode rmode,
Condition cc) {
// TODO(X64): Inline this
if (FLAG_embedded_builtins) {
if (root_array_available_ && options().isolate_independent_code &&
!Builtins::IsIsolateIndependentBuiltin(*code_object)) {
// Calls to embedded targets are initially generated as standard
// pc-relative calls below. When creating the embedded blob, call offsets
// are patched up to point directly to the off-heap instruction start.
// Note: It is safe to dereference code_object above since code generation
// for builtins and code stubs happens on the main thread.
Label skip;
if (cc != always) {
if (cc == never) return;
j(NegateCondition(cc), &skip, Label::kNear);
}
IndirectLoadConstant(kScratchRegister, code_object);
leap(kScratchRegister, FieldOperand(kScratchRegister, Code::kHeaderSize));
jmp(kScratchRegister);
bind(&skip);
return;
} else if (options().inline_offheap_trampolines) {
int builtin_index = Builtins::kNoBuiltinId;
if (isolate()->builtins()->IsBuiltinHandle(code_object, &builtin_index) &&
Builtins::IsIsolateIndependent(builtin_index)) {
// Inline the trampoline.
RecordCommentForOffHeapTrampoline(builtin_index);
CHECK_NE(builtin_index, Builtins::kNoBuiltinId);
EmbeddedData d = EmbeddedData::FromBlob();
Address entry = d.InstructionStartOfBuiltin(builtin_index);
Move(kScratchRegister, entry, RelocInfo::OFF_HEAP_TARGET);
jmp(kScratchRegister);
return;
}
}
}
j(cc, code_object, rmode);
}
void MacroAssembler::JumpToInstructionStream(Address entry) {
Move(kOffHeapTrampolineRegister, entry, RelocInfo::OFF_HEAP_TARGET);
jmp(kOffHeapTrampolineRegister);
}
void TurboAssembler::Call(ExternalReference ext) {
LoadAddress(kScratchRegister, ext);
call(kScratchRegister);
}
void TurboAssembler::Call(Operand op) {
if (kPointerSize == kInt64Size && !CpuFeatures::IsSupported(ATOM)) {
call(op);
} else {
movp(kScratchRegister, op);
call(kScratchRegister);
}
}
void TurboAssembler::Call(Address destination, RelocInfo::Mode rmode) {
Move(kScratchRegister, destination, rmode);
call(kScratchRegister);
}
void TurboAssembler::Call(Handle<Code> code_object, RelocInfo::Mode rmode) {
if (FLAG_embedded_builtins) {
if (root_array_available_ && options().isolate_independent_code &&
!Builtins::IsIsolateIndependentBuiltin(*code_object)) {
// Calls to embedded targets are initially generated as standard
// pc-relative calls below. When creating the embedded blob, call offsets
// are patched up to point directly to the off-heap instruction start.
// Note: It is safe to dereference code_object above since code generation
// for builtins and code stubs happens on the main thread.
IndirectLoadConstant(kScratchRegister, code_object);
leap(kScratchRegister, FieldOperand(kScratchRegister, Code::kHeaderSize));
call(kScratchRegister);
return;
} else if (options().inline_offheap_trampolines) {
int builtin_index = Builtins::kNoBuiltinId;
if (isolate()->builtins()->IsBuiltinHandle(code_object, &builtin_index) &&
Builtins::IsIsolateIndependent(builtin_index)) {
// Inline the trampoline.
RecordCommentForOffHeapTrampoline(builtin_index);
CHECK_NE(builtin_index, Builtins::kNoBuiltinId);
EmbeddedData d = EmbeddedData::FromBlob();
Address entry = d.InstructionStartOfBuiltin(builtin_index);
Move(kScratchRegister, entry, RelocInfo::OFF_HEAP_TARGET);
call(kScratchRegister);
return;
}
}
}
DCHECK(RelocInfo::IsCodeTarget(rmode));
call(code_object, rmode);
}
void TurboAssembler::RetpolineCall(Register reg) {
Label setup_return, setup_target, inner_indirect_branch, capture_spec;
jmp(&setup_return); // Jump past the entire retpoline below.
bind(&inner_indirect_branch);
call(&setup_target);
bind(&capture_spec);
pause();
jmp(&capture_spec);
bind(&setup_target);
movq(Operand(rsp, 0), reg);
ret(0);
bind(&setup_return);
call(&inner_indirect_branch); // Callee will return after this instruction.
}
void TurboAssembler::RetpolineCall(Address destination, RelocInfo::Mode rmode) {
Move(kScratchRegister, destination, rmode);
RetpolineCall(kScratchRegister);
}
void TurboAssembler::RetpolineJump(Register reg) {
Label setup_target, capture_spec;
call(&setup_target);
bind(&capture_spec);
pause();
jmp(&capture_spec);
bind(&setup_target);
movq(Operand(rsp, 0), reg);
ret(0);
}
void TurboAssembler::Pextrd(Register dst, XMMRegister src, int8_t imm8) {
if (imm8 == 0) {
Movd(dst, src);
return;
}
if (CpuFeatures::IsSupported(SSE4_1)) {
CpuFeatureScope sse_scope(this, SSE4_1);
pextrd(dst, src, imm8);
return;
}
DCHECK_EQ(1, imm8);
movq(dst, src);
shrq(dst, Immediate(32));
}
void TurboAssembler::Pinsrd(XMMRegister dst, Register src, int8_t imm8) {
if (CpuFeatures::IsSupported(SSE4_1)) {
CpuFeatureScope sse_scope(this, SSE4_1);
pinsrd(dst, src, imm8);
return;
}
Movd(kScratchDoubleReg, src);
if (imm8 == 1) {
punpckldq(dst, kScratchDoubleReg);
} else {
DCHECK_EQ(0, imm8);
Movss(dst, kScratchDoubleReg);
}
}
void TurboAssembler::Pinsrd(XMMRegister dst, Operand src, int8_t imm8) {
DCHECK(imm8 == 0 || imm8 == 1);
if (CpuFeatures::IsSupported(SSE4_1)) {
CpuFeatureScope sse_scope(this, SSE4_1);
pinsrd(dst, src, imm8);
return;
}
Movd(kScratchDoubleReg, src);
if (imm8 == 1) {
punpckldq(dst, kScratchDoubleReg);
} else {
DCHECK_EQ(0, imm8);
Movss(dst, kScratchDoubleReg);
}
}
void TurboAssembler::Lzcntl(Register dst, Register src) {
if (CpuFeatures::IsSupported(LZCNT)) {
CpuFeatureScope scope(this, LZCNT);
lzcntl(dst, src);
return;
}
Label not_zero_src;
bsrl(dst, src);
j(not_zero, &not_zero_src, Label::kNear);
Set(dst, 63); // 63^31 == 32
bind(&not_zero_src);
xorl(dst, Immediate(31)); // for x in [0..31], 31^x == 31 - x
}
void TurboAssembler::Lzcntl(Register dst, Operand src) {
if (CpuFeatures::IsSupported(LZCNT)) {
CpuFeatureScope scope(this, LZCNT);
lzcntl(dst, src);
return;
}
Label not_zero_src;
bsrl(dst, src);
j(not_zero, &not_zero_src, Label::kNear);
Set(dst, 63); // 63^31 == 32
bind(&not_zero_src);
xorl(dst, Immediate(31)); // for x in [0..31], 31^x == 31 - x
}
void TurboAssembler::Lzcntq(Register dst, Register src) {
if (CpuFeatures::IsSupported(LZCNT)) {
CpuFeatureScope scope(this, LZCNT);
lzcntq(dst, src);
return;
}
Label not_zero_src;
bsrq(dst, src);
j(not_zero, &not_zero_src, Label::kNear);
Set(dst, 127); // 127^63 == 64
bind(&not_zero_src);
xorl(dst, Immediate(63)); // for x in [0..63], 63^x == 63 - x
}
void TurboAssembler::Lzcntq(Register dst, Operand src) {
if (CpuFeatures::IsSupported(LZCNT)) {
CpuFeatureScope scope(this, LZCNT);
lzcntq(dst, src);
return;
}
Label not_zero_src;
bsrq(dst, src);
j(not_zero, &not_zero_src, Label::kNear);
Set(dst, 127); // 127^63 == 64
bind(&not_zero_src);
xorl(dst, Immediate(63)); // for x in [0..63], 63^x == 63 - x
}
void TurboAssembler::Tzcntq(Register dst, Register src) {
if (CpuFeatures::IsSupported(BMI1)) {
CpuFeatureScope scope(this, BMI1);
tzcntq(dst, src);
return;
}
Label not_zero_src;
bsfq(dst, src);
j(not_zero, &not_zero_src, Label::kNear);
// Define the result of tzcnt(0) separately, because bsf(0) is undefined.
Set(dst, 64);
bind(&not_zero_src);
}
void TurboAssembler::Tzcntq(Register dst, Operand src) {
if (CpuFeatures::IsSupported(BMI1)) {
CpuFeatureScope scope(this, BMI1);
tzcntq(dst, src);
return;
}
Label not_zero_src;
bsfq(dst, src);
j(not_zero, &not_zero_src, Label::kNear);
// Define the result of tzcnt(0) separately, because bsf(0) is undefined.
Set(dst, 64);
bind(&not_zero_src);
}
void TurboAssembler::Tzcntl(Register dst, Register src) {
if (CpuFeatures::IsSupported(BMI1)) {
CpuFeatureScope scope(this, BMI1);
tzcntl(dst, src);
return;
}
Label not_zero_src;
bsfl(dst, src);
j(not_zero, &not_zero_src, Label::kNear);
Set(dst, 32); // The result of tzcnt is 32 if src = 0.
bind(&not_zero_src);
}
void TurboAssembler::Tzcntl(Register dst, Operand src) {
if (CpuFeatures::IsSupported(BMI1)) {
CpuFeatureScope scope(this, BMI1);
tzcntl(dst, src);
return;
}
Label not_zero_src;
bsfl(dst, src);
j(not_zero, &not_zero_src, Label::kNear);
Set(dst, 32); // The result of tzcnt is 32 if src = 0.
bind(&not_zero_src);
}
void TurboAssembler::Popcntl(Register dst, Register src) {
if (CpuFeatures::IsSupported(POPCNT)) {
CpuFeatureScope scope(this, POPCNT);
popcntl(dst, src);
return;
}
UNREACHABLE();
}
void TurboAssembler::Popcntl(Register dst, Operand src) {
if (CpuFeatures::IsSupported(POPCNT)) {
CpuFeatureScope scope(this, POPCNT);
popcntl(dst, src);
return;
}
UNREACHABLE();
}
void TurboAssembler::Popcntq(Register dst, Register src) {
if (CpuFeatures::IsSupported(POPCNT)) {
CpuFeatureScope scope(this, POPCNT);
popcntq(dst, src);
return;
}
UNREACHABLE();
}
void TurboAssembler::Popcntq(Register dst, Operand src) {
if (CpuFeatures::IsSupported(POPCNT)) {
CpuFeatureScope scope(this, POPCNT);
popcntq(dst, src);
return;
}
UNREACHABLE();
}
void MacroAssembler::Pushad() {
Push(rax);
Push(rcx);
Push(rdx);
Push(rbx);
// Not pushing rsp or rbp.
Push(rsi);
Push(rdi);
Push(r8);
Push(r9);
// r10 is kScratchRegister.
Push(r11);
Push(r12);
// r13 is kRootRegister.
Push(r14);
Push(r15);
STATIC_ASSERT(12 == kNumSafepointSavedRegisters);
// Use lea for symmetry with Popad.
int sp_delta =
(kNumSafepointRegisters - kNumSafepointSavedRegisters) * kPointerSize;
leap(rsp, Operand(rsp, -sp_delta));
}
void MacroAssembler::Popad() {
// Popad must not change the flags, so use lea instead of addq.
int sp_delta =
(kNumSafepointRegisters - kNumSafepointSavedRegisters) * kPointerSize;
leap(rsp, Operand(rsp, sp_delta));
Pop(r15);
Pop(r14);
Pop(r12);
Pop(r11);
Pop(r9);
Pop(r8);
Pop(rdi);
Pop(rsi);
Pop(rbx);
Pop(rdx);
Pop(rcx);
Pop(rax);
}
// Order general registers are pushed by Pushad:
// rax, rcx, rdx, rbx, rsi, rdi, r8, r9, r11, r14, r15.
const int
MacroAssembler::kSafepointPushRegisterIndices[Register::kNumRegisters] = {
0,
1,
2,
3,
-1,
-1,
4,
5,
6,
7,
-1,
8,
9,
-1,
10,
11
};
void MacroAssembler::PushStackHandler() {
// Adjust this code if not the case.
STATIC_ASSERT(StackHandlerConstants::kSize == 2 * kPointerSize);
STATIC_ASSERT(StackHandlerConstants::kNextOffset == 0);
Push(Immediate(0)); // Padding.
// Link the current handler as the next handler.
ExternalReference handler_address =
ExternalReference::Create(IsolateAddressId::kHandlerAddress, isolate());
Push(ExternalOperand(handler_address));
// Set this new handler as the current one.
movp(ExternalOperand(handler_address), rsp);
}
void MacroAssembler::PopStackHandler() {
STATIC_ASSERT(StackHandlerConstants::kNextOffset == 0);
ExternalReference handler_address =
ExternalReference::Create(IsolateAddressId::kHandlerAddress, isolate());
Pop(ExternalOperand(handler_address));
addp(rsp, Immediate(StackHandlerConstants::kSize - kPointerSize));
}
void TurboAssembler::Ret() { ret(0); }
void TurboAssembler::Ret(int bytes_dropped, Register scratch) {
if (is_uint16(bytes_dropped)) {
ret(bytes_dropped);
} else {
PopReturnAddressTo(scratch);
addp(rsp, Immediate(bytes_dropped));
PushReturnAddressFrom(scratch);
ret(0);
}
}
void MacroAssembler::CmpObjectType(Register heap_object,
InstanceType type,
Register map) {
movp(map, FieldOperand(heap_object, HeapObject::kMapOffset));
CmpInstanceType(map, type);
}
void MacroAssembler::CmpInstanceType(Register map, InstanceType type) {
cmpw(FieldOperand(map, Map::kInstanceTypeOffset), Immediate(type));
}
void MacroAssembler::DoubleToI(Register result_reg, XMMRegister input_reg,
XMMRegister scratch, Label* lost_precision,
Label* is_nan, Label::Distance dst) {
Cvttsd2si(result_reg, input_reg);
Cvtlsi2sd(kScratchDoubleReg, result_reg);
Ucomisd(kScratchDoubleReg, input_reg);
j(not_equal, lost_precision, dst);
j(parity_even, is_nan, dst); // NaN.
}
void MacroAssembler::AssertNotSmi(Register object) {
if (emit_debug_code()) {
Condition is_smi = CheckSmi(object);
Check(NegateCondition(is_smi), AbortReason::kOperandIsASmi);
}
}
void MacroAssembler::AssertSmi(Register object) {
if (emit_debug_code()) {
Condition is_smi = CheckSmi(object);
Check(is_smi, AbortReason::kOperandIsNotASmi);
}
}
void MacroAssembler::AssertSmi(Operand object) {
if (emit_debug_code()) {
Condition is_smi = CheckSmi(object);
Check(is_smi, AbortReason::kOperandIsNotASmi);
}
}
void TurboAssembler::AssertZeroExtended(Register int32_register) {
if (emit_debug_code()) {
DCHECK_NE(int32_register, kScratchRegister);
movq(kScratchRegister, int64_t{0x0000000100000000});
cmpq(kScratchRegister, int32_register);
Check(above_equal, AbortReason::k32BitValueInRegisterIsNotZeroExtended);
}
}
void MacroAssembler::AssertConstructor(Register object) {
if (emit_debug_code()) {
testb(object, Immediate(kSmiTagMask));
Check(not_equal, AbortReason::kOperandIsASmiAndNotAConstructor);
Push(object);
movq(object, FieldOperand(object, HeapObject::kMapOffset));
testb(FieldOperand(object, Map::kBitFieldOffset),
Immediate(Map::IsConstructorBit::kMask));
Pop(object);
Check(not_zero, AbortReason::kOperandIsNotAConstructor);
}
}
void MacroAssembler::AssertFunction(Register object) {
if (emit_debug_code()) {
testb(object, Immediate(kSmiTagMask));
Check(not_equal, AbortReason::kOperandIsASmiAndNotAFunction);
Push(object);
CmpObjectType(object, JS_FUNCTION_TYPE, object);
Pop(object);
Check(equal, AbortReason::kOperandIsNotAFunction);
}
}
void MacroAssembler::AssertBoundFunction(Register object) {
if (emit_debug_code()) {
testb(object, Immediate(kSmiTagMask));
Check(not_equal, AbortReason::kOperandIsASmiAndNotABoundFunction);
Push(object);
CmpObjectType(object, JS_BOUND_FUNCTION_TYPE, object);
Pop(object);
Check(equal, AbortReason::kOperandIsNotABoundFunction);
}
}
void MacroAssembler::AssertGeneratorObject(Register object) {
if (!emit_debug_code()) return;
testb(object, Immediate(kSmiTagMask));
Check(not_equal, AbortReason::kOperandIsASmiAndNotAGeneratorObject);
// Load map
Register map = object;
Push(object);
movp(map, FieldOperand(object, HeapObject::kMapOffset));
Label do_check;
// Check if JSGeneratorObject
CmpInstanceType(map, JS_GENERATOR_OBJECT_TYPE);
j(equal, &do_check);
// Check if JSAsyncGeneratorObject
CmpInstanceType(map, JS_ASYNC_GENERATOR_OBJECT_TYPE);
bind(&do_check);
// Restore generator object to register and perform assertion
Pop(object);
Check(equal, AbortReason::kOperandIsNotAGeneratorObject);
}
void MacroAssembler::AssertUndefinedOrAllocationSite(Register object) {
if (emit_debug_code()) {
Label done_checking;
AssertNotSmi(object);
Cmp(object, isolate()->factory()->undefined_value());
j(equal, &done_checking);
Cmp(FieldOperand(object, 0), isolate()->factory()->allocation_site_map());
Assert(equal, AbortReason::kExpectedUndefinedOrCell);
bind(&done_checking);
}
}
void MacroAssembler::LoadWeakValue(Register in_out, Label* target_if_cleared) {
cmpp(in_out, Immediate(kClearedWeakHeapObject));
j(equal, target_if_cleared);
andp(in_out, Immediate(~kWeakHeapObjectMask));
}
void MacroAssembler::IncrementCounter(StatsCounter* counter, int value) {
DCHECK_GT(value, 0);
if (FLAG_native_code_counters && counter->Enabled()) {
Operand counter_operand =
ExternalOperand(ExternalReference::Create(counter));
if (value == 1) {
incl(counter_operand);
} else {
addl(counter_operand, Immediate(value));
}
}
}
void MacroAssembler::DecrementCounter(StatsCounter* counter, int value) {
DCHECK_GT(value, 0);
if (FLAG_native_code_counters && counter->Enabled()) {
Operand counter_operand =
ExternalOperand(ExternalReference::Create(counter));
if (value == 1) {
decl(counter_operand);
} else {
subl(counter_operand, Immediate(value));
}
}
}
void MacroAssembler::MaybeDropFrames() {
// Check whether we need to drop frames to restart a function on the stack.
ExternalReference restart_fp =
ExternalReference::debug_restart_fp_address(isolate());
Load(rbx, restart_fp);
testp(rbx, rbx);
Label dont_drop;
j(zero, &dont_drop, Label::kNear);
Jump(BUILTIN_CODE(isolate(), FrameDropperTrampoline), RelocInfo::CODE_TARGET);
bind(&dont_drop);
}
void TurboAssembler::PrepareForTailCall(const ParameterCount& callee_args_count,
Register caller_args_count_reg,
Register scratch0, Register scratch1) {
#if DEBUG
if (callee_args_count.is_reg()) {
DCHECK(!AreAliased(callee_args_count.reg(), caller_args_count_reg, scratch0,
scratch1));
} else {
DCHECK(!AreAliased(caller_args_count_reg, scratch0, scratch1));
}
#endif
// Calculate the destination address where we will put the return address
// after we drop current frame.
Register new_sp_reg = scratch0;
if (callee_args_count.is_reg()) {
subp(caller_args_count_reg, callee_args_count.reg());
leap(new_sp_reg, Operand(rbp, caller_args_count_reg, times_pointer_size,
StandardFrameConstants::kCallerPCOffset));
} else {
leap(new_sp_reg, Operand(rbp, caller_args_count_reg, times_pointer_size,
StandardFrameConstants::kCallerPCOffset -
callee_args_count.immediate() * kPointerSize));
}
if (FLAG_debug_code) {
cmpp(rsp, new_sp_reg);
Check(below, AbortReason::kStackAccessBelowStackPointer);
}
// Copy return address from caller's frame to current frame's return address
// to avoid its trashing and let the following loop copy it to the right
// place.
Register tmp_reg = scratch1;
movp(tmp_reg, Operand(rbp, StandardFrameConstants::kCallerPCOffset));
movp(Operand(rsp, 0), tmp_reg);
// Restore caller's frame pointer now as it could be overwritten by
// the copying loop.
movp(rbp, Operand(rbp, StandardFrameConstants::kCallerFPOffset));
// +2 here is to copy both receiver and return address.
Register count_reg = caller_args_count_reg;
if (callee_args_count.is_reg()) {
leap(count_reg, Operand(callee_args_count.reg(), 2));
} else {
movp(count_reg, Immediate(callee_args_count.immediate() + 2));
// TODO(ishell): Unroll copying loop for small immediate values.
}
// Now copy callee arguments to the caller frame going backwards to avoid
// callee arguments corruption (source and destination areas could overlap).
Label loop, entry;
jmp(&entry, Label::kNear);
bind(&loop);
decp(count_reg);
movp(tmp_reg, Operand(rsp, count_reg, times_pointer_size, 0));
movp(Operand(new_sp_reg, count_reg, times_pointer_size, 0), tmp_reg);
bind(&entry);
cmpp(count_reg, Immediate(0));
j(not_equal, &loop, Label::kNear);
// Leave current frame.
movp(rsp, new_sp_reg);
}
void MacroAssembler::InvokeFunction(Register function, Register new_target,
const ParameterCount& actual,
InvokeFlag flag) {
movp(rbx, FieldOperand(function, JSFunction::kSharedFunctionInfoOffset));
movzxwq(rbx,
FieldOperand(rbx, SharedFunctionInfo::kFormalParameterCountOffset));
ParameterCount expected(rbx);
InvokeFunction(function, new_target, expected, actual, flag);
}
void MacroAssembler::InvokeFunction(Register function, Register new_target,
const ParameterCount& expected,
const ParameterCount& actual,
InvokeFlag flag) {
DCHECK(function == rdi);
movp(rsi, FieldOperand(function, JSFunction::kContextOffset));
InvokeFunctionCode(rdi, new_target, expected, actual, flag);
}
void MacroAssembler::InvokeFunctionCode(Register function, Register new_target,
const ParameterCount& expected,
const ParameterCount& actual,
InvokeFlag flag) {
// You can't call a function without a valid frame.
DCHECK(flag == JUMP_FUNCTION || has_frame());
DCHECK(function == rdi);
DCHECK_IMPLIES(new_target.is_valid(), new_target == rdx);
// On function call, call into the debugger if necessary.
CheckDebugHook(function, new_target, expected, actual);
// Clear the new.target register if not given.
if (!new_target.is_valid()) {
LoadRoot(rdx, Heap::kUndefinedValueRootIndex);
}
Label done;
bool definitely_mismatches = false;
InvokePrologue(expected, actual, &done, &definitely_mismatches, flag,
Label::kNear);
if (!definitely_mismatches) {
// We call indirectly through the code field in the function to
// allow recompilation to take effect without changing any of the
// call sites.
static_assert(kJavaScriptCallCodeStartRegister == rcx, "ABI mismatch");
movp(rcx, FieldOperand(function, JSFunction::kCodeOffset));
addp(rcx, Immediate(Code::kHeaderSize - kHeapObjectTag));
if (flag == CALL_FUNCTION) {
call(rcx);
} else {
DCHECK(flag == JUMP_FUNCTION);
jmp(rcx);
}
bind(&done);
}
}
void MacroAssembler::InvokePrologue(const ParameterCount& expected,
const ParameterCount& actual, Label* done,
bool* definitely_mismatches,
InvokeFlag flag,
Label::Distance near_jump) {
bool definitely_matches = false;
*definitely_mismatches = false;
Label invoke;
if (expected.is_immediate()) {
DCHECK(actual.is_immediate());
Set(rax, actual.immediate());
if (expected.immediate() == actual.immediate()) {
definitely_matches = true;
} else {
if (expected.immediate() ==
SharedFunctionInfo::kDontAdaptArgumentsSentinel) {
// Don't worry about adapting arguments for built-ins that
// don't want that done. Skip adaption code by making it look
// like we have a match between expected and actual number of
// arguments.
definitely_matches = true;
} else {
*definitely_mismatches = true;
Set(rbx, expected.immediate());
}
}
} else {
if (actual.is_immediate()) {
// Expected is in register, actual is immediate. This is the
// case when we invoke function values without going through the
// IC mechanism.
Set(rax, actual.immediate());
cmpp(expected.reg(), Immediate(actual.immediate()));
j(equal, &invoke, Label::kNear);
DCHECK(expected.reg() == rbx);
} else if (expected.reg() != actual.reg()) {
// Both expected and actual are in (different) registers. This
// is the case when we invoke functions using call and apply.
cmpp(expected.reg(), actual.reg());
j(equal, &invoke, Label::kNear);
DCHECK(actual.reg() == rax);
DCHECK(expected.reg() == rbx);
} else {
definitely_matches = true;
Move(rax, actual.reg());
}
}
if (!definitely_matches) {
Handle<Code> adaptor = BUILTIN_CODE(isolate(), ArgumentsAdaptorTrampoline);
if (flag == CALL_FUNCTION) {
Call(adaptor, RelocInfo::CODE_TARGET);
if (!*definitely_mismatches) {
jmp(done, near_jump);
}
} else {
Jump(adaptor, RelocInfo::CODE_TARGET);
}
bind(&invoke);
}
}
void MacroAssembler::CheckDebugHook(Register fun, Register new_target,
const ParameterCount& expected,
const ParameterCount& actual) {
Label skip_hook;
ExternalReference debug_hook_active =
ExternalReference::debug_hook_on_function_call_address(isolate());
Operand debug_hook_active_operand = ExternalOperand(debug_hook_active);
cmpb(debug_hook_active_operand, Immediate(0));
j(equal, &skip_hook);
{
FrameScope frame(this,
has_frame() ? StackFrame::NONE : StackFrame::INTERNAL);
if (expected.is_reg()) {
SmiTag(expected.reg(), expected.reg());
Push(expected.reg());
}
if (actual.is_reg()) {
SmiTag(actual.reg(), actual.reg());
Push(actual.reg());
SmiUntag(actual.reg(), actual.reg());
}
if (new_target.is_valid()) {
Push(new_target);
}
Push(fun);
Push(fun);
Push(StackArgumentsAccessor(rbp, actual).GetReceiverOperand());
CallRuntime(Runtime::kDebugOnFunctionCall);
Pop(fun);
if (new_target.is_valid()) {
Pop(new_target);
}
if (actual.is_reg()) {
Pop(actual.reg());
SmiUntag(actual.reg(), actual.reg());
}
if (expected.is_reg()) {
Pop(expected.reg());
SmiUntag(expected.reg(), expected.reg());
}
}
bind(&skip_hook);
}
void TurboAssembler::StubPrologue(StackFrame::Type type) {
pushq(rbp); // Caller's frame pointer.
movp(rbp, rsp);
Push(Immediate(StackFrame::TypeToMarker(type)));
}
void TurboAssembler::Prologue() {
pushq(rbp); // Caller's frame pointer.
movp(rbp, rsp);
Push(rsi); // Callee's context.
Push(rdi); // Callee's JS function.
}
void TurboAssembler::EnterFrame(StackFrame::Type type) {
pushq(rbp);
movp(rbp, rsp);
Push(Immediate(StackFrame::TypeToMarker(type)));
}
void TurboAssembler::LeaveFrame(StackFrame::Type type) {
if (emit_debug_code()) {
cmpp(Operand(rbp, CommonFrameConstants::kContextOrFrameTypeOffset),
Immediate(StackFrame::TypeToMarker(type)));
Check(equal, AbortReason::kStackFrameTypesMustMatch);
}
movp(rsp, rbp);
popq(rbp);
}
void MacroAssembler::EnterBuiltinFrame(Register context, Register target,
Register argc) {
Push(rbp);
Move(rbp, rsp);
Push(context);
Push(target);
Push(argc);
}
void MacroAssembler::LeaveBuiltinFrame(Register context, Register target,
Register argc) {
Pop(argc);
Pop(target);
Pop(context);
leave();
}
void MacroAssembler::EnterExitFramePrologue(bool save_rax,
StackFrame::Type frame_type) {
DCHECK(frame_type == StackFrame::EXIT ||
frame_type == StackFrame::BUILTIN_EXIT);
// Set up the frame structure on the stack.
// All constants are relative to the frame pointer of the exit frame.
DCHECK_EQ(kFPOnStackSize + kPCOnStackSize,
ExitFrameConstants::kCallerSPDisplacement);
DCHECK_EQ(kFPOnStackSize, ExitFrameConstants::kCallerPCOffset);
DCHECK_EQ(0 * kPointerSize, ExitFrameConstants::kCallerFPOffset);
pushq(rbp);
movp(rbp, rsp);
// Reserve room for entry stack pointer and push the code object.
Push(Immediate(StackFrame::TypeToMarker(frame_type)));
DCHECK_EQ(-2 * kPointerSize, ExitFrameConstants::kSPOffset);
Push(Immediate(0)); // Saved entry sp, patched before call.
Move(kScratchRegister, CodeObject(), RelocInfo::EMBEDDED_OBJECT);
Push(kScratchRegister); // Accessed from ExitFrame::code_slot.
// Save the frame pointer and the context in top.
if (save_rax) {
movp(r14, rax); // Backup rax in callee-save register.
}
Store(
ExternalReference::Create(IsolateAddressId::kCEntryFPAddress, isolate()),
rbp);
Store(ExternalReference::Create(IsolateAddressId::kContextAddress, isolate()),
rsi);
Store(
ExternalReference::Create(IsolateAddressId::kCFunctionAddress, isolate()),
rbx);
}
void MacroAssembler::EnterExitFrameEpilogue(int arg_stack_space,
bool save_doubles) {
#ifdef _WIN64
const int kShadowSpace = 4;
arg_stack_space += kShadowSpace;
#endif
// Optionally save all XMM registers.
if (save_doubles) {
int space = XMMRegister::kNumRegisters * kDoubleSize +
arg_stack_space * kRegisterSize;
subp(rsp, Immediate(space));
int offset = -ExitFrameConstants::kFixedFrameSizeFromFp;
const RegisterConfiguration* config = RegisterConfiguration::Default();
for (int i = 0; i < config->num_allocatable_double_registers(); ++i) {
DoubleRegister reg =
DoubleRegister::from_code(config->GetAllocatableDoubleCode(i));
Movsd(Operand(rbp, offset - ((i + 1) * kDoubleSize)), reg);
}
} else if (arg_stack_space > 0) {
subp(rsp, Immediate(arg_stack_space * kRegisterSize));
}
// Get the required frame alignment for the OS.
const int kFrameAlignment = base::OS::ActivationFrameAlignment();
if (kFrameAlignment > 0) {
DCHECK(base::bits::IsPowerOfTwo(kFrameAlignment));
DCHECK(is_int8(kFrameAlignment));
andp(rsp, Immediate(-kFrameAlignment));
}
// Patch the saved entry sp.
movp(Operand(rbp, ExitFrameConstants::kSPOffset), rsp);
}
void MacroAssembler::EnterExitFrame(int arg_stack_space, bool save_doubles,
StackFrame::Type frame_type) {
EnterExitFramePrologue(true, frame_type);
// Set up argv in callee-saved register r15. It is reused in LeaveExitFrame,
// so it must be retained across the C-call.
int offset = StandardFrameConstants::kCallerSPOffset - kPointerSize;
leap(r15, Operand(rbp, r14, times_pointer_size, offset));
EnterExitFrameEpilogue(arg_stack_space, save_doubles);
}
void MacroAssembler::EnterApiExitFrame(int arg_stack_space) {
EnterExitFramePrologue(false, StackFrame::EXIT);
EnterExitFrameEpilogue(arg_stack_space, false);
}
void MacroAssembler::LeaveExitFrame(bool save_doubles, bool pop_arguments) {
// Registers:
// r15 : argv
if (save_doubles) {
int offset = -ExitFrameConstants::kFixedFrameSizeFromFp;
const RegisterConfiguration* config = RegisterConfiguration::Default();
for (int i = 0; i < config->num_allocatable_double_registers(); ++i) {
DoubleRegister reg =
DoubleRegister::from_code(config->GetAllocatableDoubleCode(i));
Movsd(reg, Operand(rbp, offset - ((i + 1) * kDoubleSize)));
}
}
if (pop_arguments) {
// Get the return address from the stack and restore the frame pointer.
movp(rcx, Operand(rbp, kFPOnStackSize));
movp(rbp, Operand(rbp, 0 * kPointerSize));
// Drop everything up to and including the arguments and the receiver
// from the caller stack.
leap(rsp, Operand(r15, 1 * kPointerSize));
PushReturnAddressFrom(rcx);
} else {
// Otherwise just leave the exit frame.
leave();
}
LeaveExitFrameEpilogue();
}
void MacroAssembler::LeaveApiExitFrame() {
movp(rsp, rbp);
popq(rbp);
LeaveExitFrameEpilogue();
}
void MacroAssembler::LeaveExitFrameEpilogue() {
// Restore current context from top and clear it in debug mode.
ExternalReference context_address =
ExternalReference::Create(IsolateAddressId::kContextAddress, isolate());
Operand context_operand = ExternalOperand(context_address);
movp(rsi, context_operand);
#ifdef DEBUG
movp(context_operand, Immediate(Context::kInvalidContext));
#endif
// Clear the top frame.
ExternalReference c_entry_fp_address =
ExternalReference::Create(IsolateAddressId::kCEntryFPAddress, isolate());
Operand c_entry_fp_operand = ExternalOperand(c_entry_fp_address);
movp(c_entry_fp_operand, Immediate(0));
}
#ifdef _WIN64
static const int kRegisterPassedArguments = 4;
#else
static const int kRegisterPassedArguments = 6;
#endif
void MacroAssembler::LoadNativeContextSlot(int index, Register dst) {
movp(dst, NativeContextOperand());
movp(dst, ContextOperand(dst, index));
}
int TurboAssembler::ArgumentStackSlotsForCFunctionCall(int num_arguments) {
// On Windows 64 stack slots are reserved by the caller for all arguments
// including the ones passed in registers, and space is always allocated for
// the four register arguments even if the function takes fewer than four
// arguments.
// On AMD64 ABI (Linux/Mac) the first six arguments are passed in registers
// and the caller does not reserve stack slots for them.
DCHECK_GE(num_arguments, 0);
#ifdef _WIN64
const int kMinimumStackSlots = kRegisterPassedArguments;
if (num_arguments < kMinimumStackSlots) return kMinimumStackSlots;
return num_arguments;
#else
if (num_arguments < kRegisterPassedArguments) return 0;
return num_arguments - kRegisterPassedArguments;
#endif
}
void TurboAssembler::PrepareCallCFunction(int num_arguments) {
int frame_alignment = base::OS::ActivationFrameAlignment();
DCHECK_NE(frame_alignment, 0);
DCHECK_GE(num_arguments, 0);
// Make stack end at alignment and allocate space for arguments and old rsp.
movp(kScratchRegister, rsp);
DCHECK(base::bits::IsPowerOfTwo(frame_alignment));
int argument_slots_on_stack =
ArgumentStackSlotsForCFunctionCall(num_arguments);
subp(rsp, Immediate((argument_slots_on_stack + 1) * kRegisterSize));
andp(rsp, Immediate(-frame_alignment));
movp(Operand(rsp, argument_slots_on_stack * kRegisterSize), kScratchRegister);
}
void TurboAssembler::CallCFunction(ExternalReference function,
int num_arguments) {
LoadAddress(rax, function);
CallCFunction(rax, num_arguments);
}
void TurboAssembler::CallCFunction(Register function, int num_arguments) {
DCHECK_LE(num_arguments, kMaxCParameters);
DCHECK(has_frame());
// Check stack alignment.
if (emit_debug_code()) {
CheckStackAlignment();
}
call(function);
DCHECK_NE(base::OS::ActivationFrameAlignment(), 0);
DCHECK_GE(num_arguments, 0);
int argument_slots_on_stack =
ArgumentStackSlotsForCFunctionCall(num_arguments);
movp(rsp, Operand(rsp, argument_slots_on_stack * kRegisterSize));
}
void TurboAssembler::CheckPageFlag(Register object, Register scratch, int mask,
Condition cc, Label* condition_met,
Label::Distance condition_met_distance) {
DCHECK(cc == zero || cc == not