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// Copyright (c) 2013, the Dart project authors. Please see the AUTHORS file
// for details. All rights reserved. Use of this source code is governed by a
// BSD-style license that can be found in the LICENSE file.
#include "vm/globals.h" // Needed here to get TARGET_ARCH_ARM.
#if defined(TARGET_ARCH_ARM)
#include "vm/compiler/backend/flow_graph_compiler.h"
#include "vm/compiler/api/type_check_mode.h"
#include "vm/compiler/backend/il_printer.h"
#include "vm/compiler/backend/locations.h"
#include "vm/compiler/jit/compiler.h"
#include "vm/cpu.h"
#include "vm/dart_entry.h"
#include "vm/deopt_instructions.h"
#include "vm/dispatch_table.h"
#include "vm/instructions.h"
#include "vm/object_store.h"
#include "vm/parser.h"
#include "vm/stack_frame.h"
#include "vm/stub_code.h"
#include "vm/symbols.h"
namespace dart {
DEFINE_FLAG(bool, trap_on_deoptimization, false, "Trap on deoptimization.");
DEFINE_FLAG(bool, unbox_doubles, true, "Optimize double arithmetic.");
DECLARE_FLAG(bool, enable_simd_inline);
void FlowGraphCompiler::ArchSpecificInitialization() {
if (FLAG_precompiled_mode) {
auto object_store = isolate_group()->object_store();
const auto& stub =
Code::ZoneHandle(object_store->write_barrier_wrappers_stub());
if (CanPcRelativeCall(stub)) {
assembler_->generate_invoke_write_barrier_wrapper_ =
[&](Condition condition, Register reg) {
const intptr_t offset_into_target =
Thread::WriteBarrierWrappersOffsetForRegister(reg);
assembler_->GenerateUnRelocatedPcRelativeCall(condition,
offset_into_target);
AddPcRelativeCallStubTarget(stub);
};
}
const auto& array_stub =
Code::ZoneHandle(object_store->array_write_barrier_stub());
if (CanPcRelativeCall(stub)) {
assembler_->generate_invoke_array_write_barrier_ =
[&](Condition condition) {
assembler_->GenerateUnRelocatedPcRelativeCall(condition);
AddPcRelativeCallStubTarget(array_stub);
};
}
}
}
FlowGraphCompiler::~FlowGraphCompiler() {
// BlockInfos are zone-allocated, so their destructors are not called.
// Verify the labels explicitly here.
for (int i = 0; i < block_info_.length(); ++i) {
ASSERT(!block_info_[i]->jump_label()->IsLinked());
}
}
bool FlowGraphCompiler::SupportsUnboxedDoubles() {
return FLAG_unbox_doubles;
}
bool FlowGraphCompiler::SupportsUnboxedSimd128() {
return TargetCPUFeatures::neon_supported() && FLAG_enable_simd_inline;
}
bool FlowGraphCompiler::CanConvertInt64ToDouble() {
// ARM does not have a short instruction sequence for converting int64 to
// double.
return false;
}
void FlowGraphCompiler::EnterIntrinsicMode() {
ASSERT(!intrinsic_mode());
intrinsic_mode_ = true;
ASSERT(!assembler()->constant_pool_allowed());
}
void FlowGraphCompiler::ExitIntrinsicMode() {
ASSERT(intrinsic_mode());
intrinsic_mode_ = false;
}
TypedDataPtr CompilerDeoptInfo::CreateDeoptInfo(FlowGraphCompiler* compiler,
DeoptInfoBuilder* builder,
const Array& deopt_table) {
if (deopt_env_ == NULL) {
++builder->current_info_number_;
return TypedData::null();
}
intptr_t stack_height = compiler->StackSize();
AllocateIncomingParametersRecursive(deopt_env_, &stack_height);
intptr_t slot_ix = 0;
Environment* current = deopt_env_;
// Emit all kMaterializeObject instructions describing objects to be
// materialized on the deoptimization as a prefix to the deoptimization info.
EmitMaterializations(deopt_env_, builder);
// The real frame starts here.
builder->MarkFrameStart();
Zone* zone = compiler->zone();
builder->AddPp(current->function(), slot_ix++);
builder->AddPcMarker(Function::ZoneHandle(zone), slot_ix++);
builder->AddCallerFp(slot_ix++);
builder->AddReturnAddress(current->function(), deopt_id(), slot_ix++);
// Emit all values that are needed for materialization as a part of the
// expression stack for the bottom-most frame. This guarantees that GC
// will be able to find them during materialization.
slot_ix = builder->EmitMaterializationArguments(slot_ix);
// For the innermost environment, set outgoing arguments and the locals.
for (intptr_t i = current->Length() - 1;
i >= current->fixed_parameter_count(); i--) {
builder->AddCopy(current->ValueAt(i), current->LocationAt(i), slot_ix++);
}
Environment* previous = current;
current = current->outer();
while (current != NULL) {
builder->AddPp(current->function(), slot_ix++);
builder->AddPcMarker(previous->function(), slot_ix++);
builder->AddCallerFp(slot_ix++);
// For any outer environment the deopt id is that of the call instruction
// which is recorded in the outer environment.
builder->AddReturnAddress(current->function(),
DeoptId::ToDeoptAfter(current->GetDeoptId()),
slot_ix++);
// The values of outgoing arguments can be changed from the inlined call so
// we must read them from the previous environment.
for (intptr_t i = previous->fixed_parameter_count() - 1; i >= 0; i--) {
builder->AddCopy(previous->ValueAt(i), previous->LocationAt(i),
slot_ix++);
}
// Set the locals, note that outgoing arguments are not in the environment.
for (intptr_t i = current->Length() - 1;
i >= current->fixed_parameter_count(); i--) {
builder->AddCopy(current->ValueAt(i), current->LocationAt(i), slot_ix++);
}
// Iterate on the outer environment.
previous = current;
current = current->outer();
}
// The previous pointer is now the outermost environment.
ASSERT(previous != NULL);
// Set slots for the outermost environment.
builder->AddCallerPp(slot_ix++);
builder->AddPcMarker(previous->function(), slot_ix++);
builder->AddCallerFp(slot_ix++);
builder->AddCallerPc(slot_ix++);
// For the outermost environment, set the incoming arguments.
for (intptr_t i = previous->fixed_parameter_count() - 1; i >= 0; i--) {
builder->AddCopy(previous->ValueAt(i), previous->LocationAt(i), slot_ix++);
}
return builder->CreateDeoptInfo(deopt_table);
}
void CompilerDeoptInfoWithStub::GenerateCode(FlowGraphCompiler* compiler,
intptr_t stub_ix) {
// Calls do not need stubs, they share a deoptimization trampoline.
ASSERT(reason() != ICData::kDeoptAtCall);
compiler::Assembler* assembler = compiler->assembler();
#define __ assembler->
__ Comment("%s", Name());
__ Bind(entry_label());
if (FLAG_trap_on_deoptimization) {
__ bkpt(0);
}
ASSERT(deopt_env() != NULL);
__ Call(compiler::Address(
THR, compiler::target::Thread::deoptimize_entry_offset()));
set_pc_offset(assembler->CodeSize());
#undef __
}
#define __ assembler->
// Static methods of FlowGraphCompiler that take an assembler.
void FlowGraphCompiler::GenerateIndirectTTSCall(compiler::Assembler* assembler,
Register reg_to_call,
intptr_t sub_type_cache_index) {
__ LoadField(
TTSInternalRegs::kScratchReg,
compiler::FieldAddress(
reg_to_call,
compiler::target::AbstractType::type_test_stub_entry_point_offset()));
__ LoadWordFromPoolIndex(TypeTestABI::kSubtypeTestCacheReg,
sub_type_cache_index);
__ blx(TTSInternalRegs::kScratchReg);
}
#undef __
#define __ assembler()->
// Instance methods of FlowGraphCompiler.
// Fall through if bool_register contains null.
void FlowGraphCompiler::GenerateBoolToJump(Register bool_register,
compiler::Label* is_true,
compiler::Label* is_false) {
compiler::Label fall_through;
__ CompareObject(bool_register, Object::null_object());
__ b(&fall_through, EQ);
BranchLabels labels = {is_true, is_false, &fall_through};
Condition true_condition =
EmitBoolTest(bool_register, labels, /*invert=*/false);
ASSERT(true_condition != kInvalidCondition);
__ b(is_true, true_condition);
__ b(is_false);
__ Bind(&fall_through);
}
void FlowGraphCompiler::EmitInstructionEpilogue(Instruction* instr) {
if (is_optimizing()) {
return;
}
Definition* defn = instr->AsDefinition();
if ((defn != NULL) && defn->HasTemp()) {
const Location value = defn->locs()->out(0);
if (value.IsRegister()) {
__ PushRegister(value.reg());
} else if (value.IsFpuRegister()) {
ASSERT(instr->representation() == kUnboxedDouble);
// In unoptimized code at instruction epilogue the only
// live register is an output register.
instr->locs()->live_registers()->Clear();
__ MoveUnboxedDouble(BoxDoubleStubABI::kValueReg, value.fpu_reg());
GenerateNonLazyDeoptableStubCall(
InstructionSource(), // No token position.
StubCode::BoxDouble(), UntaggedPcDescriptors::kOther, instr->locs());
__ PushRegister(BoxDoubleStubABI::kResultReg);
} else {
UNREACHABLE();
}
}
}
void FlowGraphCompiler::GenerateMethodExtractorIntrinsic(
const Function& extracted_method,
intptr_t type_arguments_field_offset) {
// No frame has been setup here.
ASSERT(!__ constant_pool_allowed());
ASSERT(extracted_method.IsZoneHandle());
const Code& build_method_extractor =
Code::ZoneHandle(extracted_method.IsGeneric()
? isolate_group()
->object_store()
->build_generic_method_extractor_code()
: isolate_group()
->object_store()
->build_nongeneric_method_extractor_code());
const intptr_t stub_index =
__ object_pool_builder().FindObject(build_method_extractor);
const intptr_t function_index =
__ object_pool_builder().FindObject(extracted_method);
// We use a custom pool register to preserve caller PP.
Register kPoolReg = R0;
// R1 = extracted function
// R4 = offset of type argument vector (or 0 if class is not generic)
if (FLAG_precompiled_mode) {
kPoolReg = PP;
} else {
__ LoadFieldFromOffset(kPoolReg, CODE_REG,
compiler::target::Code::object_pool_offset());
}
__ LoadImmediate(R4, type_arguments_field_offset);
__ LoadFieldFromOffset(
R1, kPoolReg,
compiler::target::ObjectPool::element_offset(function_index));
__ LoadFieldFromOffset(
CODE_REG, kPoolReg,
compiler::target::ObjectPool::element_offset(stub_index));
__ Branch(compiler::FieldAddress(
CODE_REG,
compiler::target::Code::entry_point_offset(Code::EntryKind::kUnchecked)));
}
void FlowGraphCompiler::EmitFrameEntry() {
const Function& function = parsed_function().function();
if (CanOptimizeFunction() && function.IsOptimizable() &&
(!is_optimizing() || may_reoptimize())) {
__ Comment("Invocation Count Check");
const Register function_reg = R8;
__ ldr(function_reg, compiler::FieldAddress(
CODE_REG, compiler::target::Code::owner_offset()));
__ ldr(R3, compiler::FieldAddress(
function_reg,
compiler::target::Function::usage_counter_offset()));
// Reoptimization of an optimized function is triggered by counting in
// IC stubs, but not at the entry of the function.
if (!is_optimizing()) {
__ add(R3, R3, compiler::Operand(1));
__ str(R3, compiler::FieldAddress(
function_reg,
compiler::target::Function::usage_counter_offset()));
}
__ CompareImmediate(R3, GetOptimizationThreshold());
ASSERT(function_reg == R8);
__ Branch(compiler::Address(
THR, compiler::target::Thread::optimize_entry_offset()),
GE);
}
if (flow_graph().graph_entry()->NeedsFrame()) {
__ Comment("Enter frame");
if (flow_graph().IsCompiledForOsr()) {
const intptr_t extra_slots = ExtraStackSlotsOnOsrEntry();
ASSERT(extra_slots >= 0);
__ EnterOsrFrame(extra_slots * compiler::target::kWordSize);
} else {
ASSERT(StackSize() >= 0);
__ EnterDartFrame(StackSize() * compiler::target::kWordSize);
}
} else if (FLAG_precompiled_mode) {
assembler()->set_constant_pool_allowed(true);
}
}
const InstructionSource& PrologueSource() {
static InstructionSource prologue_source(TokenPosition::kDartCodePrologue,
/*inlining_id=*/0);
return prologue_source;
}
void FlowGraphCompiler::EmitPrologue() {
BeginCodeSourceRange(PrologueSource());
EmitFrameEntry();
ASSERT(assembler()->constant_pool_allowed());
// In unoptimized code, initialize (non-argument) stack allocated slots.
if (!is_optimizing()) {
const int num_locals = parsed_function().num_stack_locals();
intptr_t args_desc_slot = -1;
if (parsed_function().has_arg_desc_var()) {
args_desc_slot = compiler::target::frame_layout.FrameSlotForVariable(
parsed_function().arg_desc_var());
}
__ Comment("Initialize spill slots");
if (num_locals > 1 || (num_locals == 1 && args_desc_slot == -1)) {
__ LoadObject(R0, Object::null_object());
}
for (intptr_t i = 0; i < num_locals; ++i) {
const intptr_t slot_index =
compiler::target::frame_layout.FrameSlotForVariableIndex(-i);
Register value_reg = slot_index == args_desc_slot ? ARGS_DESC_REG : R0;
__ StoreToOffset(value_reg, FP, slot_index * compiler::target::kWordSize);
}
} else if (parsed_function().suspend_state_var() != nullptr &&
!flow_graph().IsCompiledForOsr()) {
// Initialize synthetic :suspend_state variable early
// as it may be accessed by GC and exception handling before
// InitSuspendableFunction stub is called.
const intptr_t slot_index =
compiler::target::frame_layout.FrameSlotForVariable(
parsed_function().suspend_state_var());
__ LoadObject(R0, Object::null_object());
__ StoreToOffset(R0, FP, slot_index * compiler::target::kWordSize);
}
EndCodeSourceRange(PrologueSource());
}
void FlowGraphCompiler::EmitCallToStub(const Code& stub) {
ASSERT(!stub.IsNull());
if (CanPcRelativeCall(stub)) {
__ GenerateUnRelocatedPcRelativeCall();
AddPcRelativeCallStubTarget(stub);
} else {
__ BranchLink(stub);
AddStubCallTarget(stub);
}
}
void FlowGraphCompiler::EmitJumpToStub(const Code& stub) {
ASSERT(!stub.IsNull());
if (CanPcRelativeCall(stub)) {
__ GenerateUnRelocatedPcRelativeTailCall();
AddPcRelativeTailCallStubTarget(stub);
} else {
__ LoadObject(CODE_REG, stub);
__ ldr(PC, compiler::FieldAddress(
CODE_REG, compiler::target::Code::entry_point_offset()));
AddStubCallTarget(stub);
}
}
void FlowGraphCompiler::EmitTailCallToStub(const Code& stub) {
ASSERT(!stub.IsNull());
if (CanPcRelativeCall(stub)) {
if (flow_graph().graph_entry()->NeedsFrame()) {
__ LeaveDartFrame();
}
__ GenerateUnRelocatedPcRelativeTailCall();
AddPcRelativeTailCallStubTarget(stub);
#if defined(DEBUG)
__ Breakpoint();
#endif
} else {
__ LoadObject(CODE_REG, stub);
if (flow_graph().graph_entry()->NeedsFrame()) {
__ LeaveDartFrame();
}
__ ldr(PC, compiler::FieldAddress(
CODE_REG, compiler::target::Code::entry_point_offset()));
AddStubCallTarget(stub);
}
}
void FlowGraphCompiler::GeneratePatchableCall(const InstructionSource& source,
const Code& stub,
UntaggedPcDescriptors::Kind kind,
LocationSummary* locs) {
__ BranchLinkPatchable(stub);
EmitCallsiteMetadata(source, DeoptId::kNone, kind, locs,
pending_deoptimization_env_);
}
void FlowGraphCompiler::GenerateDartCall(intptr_t deopt_id,
const InstructionSource& source,
const Code& stub,
UntaggedPcDescriptors::Kind kind,
LocationSummary* locs,
Code::EntryKind entry_kind) {
ASSERT(CanCallDart());
__ BranchLinkPatchable(stub, entry_kind);
EmitCallsiteMetadata(source, deopt_id, kind, locs,
pending_deoptimization_env_);
}
void FlowGraphCompiler::GenerateStaticDartCall(intptr_t deopt_id,
const InstructionSource& source,
UntaggedPcDescriptors::Kind kind,
LocationSummary* locs,
const Function& target,
Code::EntryKind entry_kind) {
ASSERT(CanCallDart());
if (CanPcRelativeCall(target)) {
__ GenerateUnRelocatedPcRelativeCall();
AddPcRelativeCallTarget(target, entry_kind);
EmitCallsiteMetadata(source, deopt_id, kind, locs,
pending_deoptimization_env_);
} else {
ASSERT(is_optimizing());
// Call sites to the same target can share object pool entries. These
// call sites are never patched for breakpoints: the function is deoptimized
// and the unoptimized code with IC calls for static calls is patched
// instead.
const auto& stub = StubCode::CallStaticFunction();
__ BranchLinkWithEquivalence(stub, target, entry_kind);
EmitCallsiteMetadata(source, deopt_id, kind, locs,
pending_deoptimization_env_);
AddStaticCallTarget(target, entry_kind);
}
}
void FlowGraphCompiler::EmitEdgeCounter(intptr_t edge_id) {
// We do not check for overflow when incrementing the edge counter. The
// function should normally be optimized long before the counter can
// overflow; and though we do not reset the counters when we optimize or
// deoptimize, there is a bound on the number of
// optimization/deoptimization cycles we will attempt.
ASSERT(!edge_counters_array_.IsNull());
ASSERT(assembler_->constant_pool_allowed());
__ Comment("Edge counter");
__ LoadObject(R0, edge_counters_array_);
#if defined(DEBUG)
bool old_use_far_branches = assembler_->use_far_branches();
assembler_->set_use_far_branches(true);
#endif // DEBUG
__ LoadFieldFromOffset(R1, R0,
compiler::target::Array::element_offset(edge_id));
__ add(R1, R1, compiler::Operand(Smi::RawValue(1)));
__ StoreIntoObjectNoBarrierOffset(
R0, compiler::target::Array::element_offset(edge_id), R1);
#if defined(DEBUG)
assembler_->set_use_far_branches(old_use_far_branches);
#endif // DEBUG
}
void FlowGraphCompiler::EmitOptimizedInstanceCall(
const Code& stub,
const ICData& ic_data,
intptr_t deopt_id,
const InstructionSource& source,
LocationSummary* locs,
Code::EntryKind entry_kind) {
ASSERT(CanCallDart());
ASSERT(Array::Handle(zone(), ic_data.arguments_descriptor()).Length() > 0);
// Each ICData propagated from unoptimized to optimized code contains the
// function that corresponds to the Dart function of that IC call. Due
// to inlining in optimized code, that function may not correspond to the
// top-level function (parsed_function().function()) which could be
// reoptimized and which counter needs to be incremented.
// Pass the function explicitly, it is used in IC stub.
__ LoadObject(R8, parsed_function().function());
__ LoadFromOffset(R0, SP, (ic_data.SizeWithoutTypeArgs() - 1) * kWordSize);
__ LoadUniqueObject(IC_DATA_REG, ic_data);
GenerateDartCall(deopt_id, source, stub, UntaggedPcDescriptors::kIcCall, locs,
entry_kind);
__ Drop(ic_data.SizeWithTypeArgs());
}
void FlowGraphCompiler::EmitInstanceCallJIT(const Code& stub,
const ICData& ic_data,
intptr_t deopt_id,
const InstructionSource& source,
LocationSummary* locs,
Code::EntryKind entry_kind) {
ASSERT(CanCallDart());
ASSERT(entry_kind == Code::EntryKind::kNormal ||
entry_kind == Code::EntryKind::kUnchecked);
ASSERT(Array::Handle(zone(), ic_data.arguments_descriptor()).Length() > 0);
__ LoadFromOffset(R0, SP, (ic_data.SizeWithoutTypeArgs() - 1) * kWordSize);
__ LoadUniqueObject(IC_DATA_REG, ic_data);
__ LoadUniqueObject(CODE_REG, stub);
const intptr_t entry_point_offset =
entry_kind == Code::EntryKind::kNormal
? Code::entry_point_offset(Code::EntryKind::kMonomorphic)
: Code::entry_point_offset(Code::EntryKind::kMonomorphicUnchecked);
__ Call(compiler::FieldAddress(CODE_REG, entry_point_offset));
EmitCallsiteMetadata(source, deopt_id, UntaggedPcDescriptors::kIcCall, locs,
pending_deoptimization_env_);
__ Drop(ic_data.SizeWithTypeArgs());
}
void FlowGraphCompiler::EmitMegamorphicInstanceCall(
const String& name,
const Array& arguments_descriptor,
intptr_t deopt_id,
const InstructionSource& source,
LocationSummary* locs) {
ASSERT(CanCallDart());
ASSERT(!arguments_descriptor.IsNull() && (arguments_descriptor.Length() > 0));
const ArgumentsDescriptor args_desc(arguments_descriptor);
const MegamorphicCache& cache = MegamorphicCache::ZoneHandle(
zone(),
MegamorphicCacheTable::Lookup(thread(), name, arguments_descriptor));
__ Comment("MegamorphicCall");
// Load receiver into R0.
__ LoadFromOffset(R0, SP,
(args_desc.Count() - 1) * compiler::target::kWordSize);
// Use same code pattern as instance call so it can be parsed by code patcher.
if (FLAG_precompiled_mode) {
// The AOT runtime will replace the slot in the object pool with the
// entrypoint address - see app_snapshot.cc.
CLOBBERS_LR(__ LoadUniqueObject(LR, StubCode::MegamorphicCall()));
__ LoadUniqueObject(IC_DATA_REG, cache);
CLOBBERS_LR(__ blx(LR));
} else {
__ LoadUniqueObject(IC_DATA_REG, cache);
__ LoadUniqueObject(CODE_REG, StubCode::MegamorphicCall());
__ Call(compiler::FieldAddress(
CODE_REG, Code::entry_point_offset(Code::EntryKind::kMonomorphic)));
}
RecordSafepoint(locs);
AddCurrentDescriptor(UntaggedPcDescriptors::kOther, DeoptId::kNone, source);
if (!FLAG_precompiled_mode) {
const intptr_t deopt_id_after = DeoptId::ToDeoptAfter(deopt_id);
if (is_optimizing()) {
AddDeoptIndexAtCall(deopt_id_after, pending_deoptimization_env_);
} else {
// Add deoptimization continuation point after the call and before the
// arguments are removed.
AddCurrentDescriptor(UntaggedPcDescriptors::kDeopt, deopt_id_after,
source);
}
}
RecordCatchEntryMoves(pending_deoptimization_env_);
__ Drop(args_desc.SizeWithTypeArgs());
}
void FlowGraphCompiler::EmitInstanceCallAOT(const ICData& ic_data,
intptr_t deopt_id,
const InstructionSource& source,
LocationSummary* locs,
Code::EntryKind entry_kind,
bool receiver_can_be_smi) {
ASSERT(CanCallDart());
ASSERT(entry_kind == Code::EntryKind::kNormal ||
entry_kind == Code::EntryKind::kUnchecked);
ASSERT(ic_data.NumArgsTested() == 1);
const Code& initial_stub = StubCode::SwitchableCallMiss();
const char* switchable_call_mode = "smiable";
if (!receiver_can_be_smi) {
switchable_call_mode = "non-smi";
ic_data.set_receiver_cannot_be_smi(true);
}
const UnlinkedCall& data =
UnlinkedCall::ZoneHandle(zone(), ic_data.AsUnlinkedCall());
__ Comment("InstanceCallAOT (%s)", switchable_call_mode);
__ LoadFromOffset(
R0, SP,
(ic_data.SizeWithoutTypeArgs() - 1) * compiler::target::kWordSize);
if (FLAG_precompiled_mode) {
// The AOT runtime will replace the slot in the object pool with the
// entrypoint address - see app_snapshot.cc.
CLOBBERS_LR(__ LoadUniqueObject(LR, initial_stub));
} else {
__ LoadUniqueObject(CODE_REG, initial_stub);
const intptr_t entry_point_offset =
entry_kind == Code::EntryKind::kNormal
? compiler::target::Code::entry_point_offset(
Code::EntryKind::kMonomorphic)
: compiler::target::Code::entry_point_offset(
Code::EntryKind::kMonomorphicUnchecked);
CLOBBERS_LR(
__ ldr(LR, compiler::FieldAddress(CODE_REG, entry_point_offset)));
}
__ LoadUniqueObject(R9, data);
CLOBBERS_LR(__ blx(LR));
EmitCallsiteMetadata(source, DeoptId::kNone, UntaggedPcDescriptors::kOther,
locs, pending_deoptimization_env_);
__ Drop(ic_data.SizeWithTypeArgs());
}
void FlowGraphCompiler::EmitUnoptimizedStaticCall(
intptr_t size_with_type_args,
intptr_t deopt_id,
const InstructionSource& source,
LocationSummary* locs,
const ICData& ic_data,
Code::EntryKind entry_kind) {
ASSERT(CanCallDart());
const Code& stub =
StubCode::UnoptimizedStaticCallEntry(ic_data.NumArgsTested());
__ LoadObject(R9, ic_data);
GenerateDartCall(deopt_id, source, stub,
UntaggedPcDescriptors::kUnoptStaticCall, locs, entry_kind);
__ Drop(size_with_type_args);
}
void FlowGraphCompiler::EmitOptimizedStaticCall(
const Function& function,
const Array& arguments_descriptor,
intptr_t size_with_type_args,
intptr_t deopt_id,
const InstructionSource& source,
LocationSummary* locs,
Code::EntryKind entry_kind) {
ASSERT(CanCallDart());
ASSERT(!function.IsClosureFunction());
if (function.PrologueNeedsArgumentsDescriptor()) {
__ LoadObject(ARGS_DESC_REG, arguments_descriptor);
} else {
if (!FLAG_precompiled_mode) {
__ LoadImmediate(ARGS_DESC_REG, 0); // GC safe smi zero because of stub.
}
}
// Do not use the code from the function, but let the code be patched so that
// we can record the outgoing edges to other code.
GenerateStaticDartCall(deopt_id, source, UntaggedPcDescriptors::kOther, locs,
function, entry_kind);
__ Drop(size_with_type_args);
}
void FlowGraphCompiler::EmitDispatchTableCall(
int32_t selector_offset,
const Array& arguments_descriptor) {
const auto cid_reg = DispatchTableNullErrorABI::kClassIdReg;
ASSERT(CanCallDart());
ASSERT(cid_reg != ARGS_DESC_REG);
if (!arguments_descriptor.IsNull()) {
__ LoadObject(ARGS_DESC_REG, arguments_descriptor);
}
intptr_t offset = (selector_offset - DispatchTable::OriginElement()) *
compiler::target::kWordSize;
CLOBBERS_LR({
// Would like cid_reg to be available on entry to the target function
// for checking purposes.
ASSERT(cid_reg != LR);
if (offset == 0) {
__ ldr(LR, compiler::Address(DISPATCH_TABLE_REG, cid_reg, LSL,
compiler::target::kWordSizeLog2));
} else {
__ add(LR, DISPATCH_TABLE_REG,
compiler::Operand(cid_reg, LSL, compiler::target::kWordSizeLog2));
if (!Utils::MagnitudeIsUint(12, offset)) {
const intptr_t adjust = offset & -(1 << 12);
__ AddImmediate(LR, LR, adjust);
offset -= adjust;
}
__ ldr(LR, compiler::Address(LR, offset));
}
__ blx(LR);
});
}
Condition FlowGraphCompiler::EmitEqualityRegConstCompare(
Register reg,
const Object& obj,
bool needs_number_check,
const InstructionSource& source,
intptr_t deopt_id) {
if (needs_number_check) {
ASSERT(!obj.IsMint() && !obj.IsDouble());
__ Push(reg);
__ PushObject(obj);
if (is_optimizing()) {
// No breakpoints in optimized code.
__ BranchLink(StubCode::OptimizedIdenticalWithNumberCheck());
AddCurrentDescriptor(UntaggedPcDescriptors::kOther, deopt_id, source);
} else {
// Patchable to support breakpoints.
__ BranchLinkPatchable(StubCode::UnoptimizedIdenticalWithNumberCheck());
AddCurrentDescriptor(UntaggedPcDescriptors::kRuntimeCall, deopt_id,
source);
}
// Stub returns result in flags (result of a cmp, we need Z computed).
__ Drop(1); // Discard constant.
__ Pop(reg); // Restore 'reg'.
} else {
__ CompareObject(reg, obj);
}
return EQ;
}
Condition FlowGraphCompiler::EmitEqualityRegRegCompare(
Register left,
Register right,
bool needs_number_check,
const InstructionSource& source,
intptr_t deopt_id) {
if (needs_number_check) {
__ Push(left);
__ Push(right);
if (is_optimizing()) {
__ BranchLink(StubCode::OptimizedIdenticalWithNumberCheck());
} else {
__ BranchLinkPatchable(StubCode::UnoptimizedIdenticalWithNumberCheck());
}
AddCurrentDescriptor(UntaggedPcDescriptors::kRuntimeCall, deopt_id, source);
// Stub returns result in flags (result of a cmp, we need Z computed).
__ Pop(right);
__ Pop(left);
} else {
__ cmp(left, compiler::Operand(right));
}
return EQ;
}
Condition FlowGraphCompiler::EmitBoolTest(Register value,
BranchLabels labels,
bool invert) {
__ Comment("BoolTest");
__ tst(value,
compiler::Operand(compiler::target::ObjectAlignment::kBoolValueMask));
return invert ? NE : EQ;
}
// This function must be in sync with FlowGraphCompiler::RecordSafepoint and
// FlowGraphCompiler::SlowPathEnvironmentFor.
void FlowGraphCompiler::SaveLiveRegisters(LocationSummary* locs) {
#if defined(DEBUG)
locs->CheckWritableInputs();
ClobberDeadTempRegisters(locs);
#endif
// TODO(vegorov): consider saving only caller save (volatile) registers.
__ PushRegisters(*locs->live_registers());
}
void FlowGraphCompiler::RestoreLiveRegisters(LocationSummary* locs) {
__ PopRegisters(*locs->live_registers());
}
#if defined(DEBUG)
void FlowGraphCompiler::ClobberDeadTempRegisters(LocationSummary* locs) {
// Clobber temporaries that have not been manually preserved.
for (intptr_t i = 0; i < locs->temp_count(); ++i) {
Location tmp = locs->temp(i);
// TODO(zerny): clobber non-live temporary FPU registers.
if (tmp.IsRegister() &&
!locs->live_registers()->ContainsRegister(tmp.reg())) {
__ mov(tmp.reg(), compiler::Operand(0xf7));
}
}
}
#endif
Register FlowGraphCompiler::EmitTestCidRegister() {
return R2;
}
void FlowGraphCompiler::EmitTestAndCallLoadReceiver(
intptr_t count_without_type_args,
const Array& arguments_descriptor) {
__ Comment("EmitTestAndCall");
// Load receiver into R0.
__ LoadFromOffset(
R0, SP, (count_without_type_args - 1) * compiler::target::kWordSize);
__ LoadObject(ARGS_DESC_REG, arguments_descriptor);
}
void FlowGraphCompiler::EmitTestAndCallSmiBranch(compiler::Label* label,
bool if_smi) {
__ tst(R0, compiler::Operand(kSmiTagMask));
// Jump if receiver is not Smi.
__ b(label, if_smi ? EQ : NE);
}
void FlowGraphCompiler::EmitTestAndCallLoadCid(Register class_id_reg) {
ASSERT(class_id_reg != R0);
__ LoadClassId(class_id_reg, R0);
}
void FlowGraphCompiler::EmitMove(Location destination,
Location source,
TemporaryRegisterAllocator* allocator) {
if (destination.Equals(source)) return;
if (source.IsRegister()) {
if (destination.IsRegister()) {
__ mov(destination.reg(), compiler::Operand(source.reg()));
} else {
ASSERT(destination.IsStackSlot());
const intptr_t dest_offset = destination.ToStackSlotOffset();
__ StoreToOffset(source.reg(), destination.base_reg(), dest_offset);
}
} else if (source.IsStackSlot()) {
if (destination.IsRegister()) {
const intptr_t source_offset = source.ToStackSlotOffset();
__ LoadFromOffset(destination.reg(), source.base_reg(), source_offset);
} else {
ASSERT(destination.IsStackSlot());
const intptr_t source_offset = source.ToStackSlotOffset();
const intptr_t dest_offset = destination.ToStackSlotOffset();
CLOBBERS_LR({
// LR not used by register allocator.
COMPILE_ASSERT(((1 << LR) & kDartAvailableCpuRegs) == 0);
// StoreToOffset uses TMP in the case where dest_offset is too large or
// small in order to calculate a new base. We fall back to using LR as a
// temporary as we know we're in a ParallelMove.
const Register temp_reg = LR;
__ LoadFromOffset(temp_reg, source.base_reg(), source_offset);
__ StoreToOffset(temp_reg, destination.base_reg(), dest_offset);
});
}
} else if (source.IsFpuRegister()) {
if (destination.IsFpuRegister()) {
if (TargetCPUFeatures::neon_supported()) {
__ vmovq(destination.fpu_reg(), source.fpu_reg());
} else {
// If we're not inlining simd values, then only the even numbered D
// register will have anything in them.
__ vmovd(EvenDRegisterOf(destination.fpu_reg()),
EvenDRegisterOf(source.fpu_reg()));
}
} else if (destination.IsStackSlot()) {
// 32-bit float
const intptr_t dest_offset = destination.ToStackSlotOffset();
const SRegister src = EvenSRegisterOf(EvenDRegisterOf(source.fpu_reg()));
__ StoreSToOffset(src, destination.base_reg(), dest_offset);
} else if (destination.IsDoubleStackSlot()) {
const intptr_t dest_offset = destination.ToStackSlotOffset();
DRegister src = EvenDRegisterOf(source.fpu_reg());
__ StoreDToOffset(src, destination.base_reg(), dest_offset);
} else {
ASSERT(destination.IsQuadStackSlot());
const intptr_t dest_offset = destination.ToStackSlotOffset();
const DRegister dsrc0 = EvenDRegisterOf(source.fpu_reg());
__ StoreMultipleDToOffset(dsrc0, 2, destination.base_reg(), dest_offset);
}
} else if (source.IsDoubleStackSlot()) {
if (destination.IsFpuRegister()) {
const intptr_t source_offset = source.ToStackSlotOffset();
const DRegister dst = EvenDRegisterOf(destination.fpu_reg());
__ LoadDFromOffset(dst, source.base_reg(), source_offset);
} else if (destination.IsStackSlot()) {
// 32-bit float
const intptr_t source_offset = source.ToStackSlotOffset();
const intptr_t dest_offset = destination.ToStackSlotOffset();
__ LoadSFromOffset(STMP, source.base_reg(), source_offset);
__ StoreSToOffset(STMP, destination.base_reg(), dest_offset);
} else {
ASSERT(destination.IsDoubleStackSlot());
const intptr_t source_offset = source.ToStackSlotOffset();
const intptr_t dest_offset = destination.ToStackSlotOffset();
__ LoadDFromOffset(DTMP, source.base_reg(), source_offset);
__ StoreDToOffset(DTMP, destination.base_reg(), dest_offset);
}
} else if (source.IsQuadStackSlot()) {
if (destination.IsFpuRegister()) {
const intptr_t source_offset = source.ToStackSlotOffset();
const DRegister dst0 = EvenDRegisterOf(destination.fpu_reg());
__ LoadMultipleDFromOffset(dst0, 2, source.base_reg(), source_offset);
} else {
ASSERT(destination.IsQuadStackSlot());
const intptr_t source_offset = source.ToStackSlotOffset();
const intptr_t dest_offset = destination.ToStackSlotOffset();
const DRegister dtmp0 = DTMP;
__ LoadMultipleDFromOffset(dtmp0, 2, source.base_reg(), source_offset);
__ StoreMultipleDToOffset(dtmp0, 2, destination.base_reg(), dest_offset);
}
} else if (source.IsPairLocation()) {
ASSERT(destination.IsPairLocation());
for (intptr_t i : {0, 1}) {
EmitMove(destination.Component(i), source.Component(i), allocator);
}
} else {
ASSERT(source.IsConstant());
if (destination.IsFpuRegister() || destination.IsDoubleStackSlot() ||
destination.IsStackSlot()) {
Register tmp = allocator->AllocateTemporary();
source.constant_instruction()->EmitMoveToLocation(this, destination, tmp,
source.pair_index());
allocator->ReleaseTemporary();
} else {
source.constant_instruction()->EmitMoveToLocation(
this, destination, kNoRegister, source.pair_index());
}
}
}
static compiler::OperandSize BytesToOperandSize(intptr_t bytes) {
switch (bytes) {
case 4:
return compiler::OperandSize::kFourBytes;
case 2:
return compiler::OperandSize::kTwoBytes;
case 1:
return compiler::OperandSize::kByte;
default:
UNIMPLEMENTED();
}
}
void FlowGraphCompiler::EmitNativeMoveArchitecture(
const compiler::ffi::NativeLocation& destination,
const compiler::ffi::NativeLocation& source) {
const auto& src_payload_type = source.payload_type();
const auto& dst_payload_type = destination.payload_type();
const auto& src_container_type = source.container_type();
const auto& dst_container_type = destination.container_type();
ASSERT(src_container_type.IsFloat() == dst_container_type.IsFloat());
ASSERT(src_container_type.IsInt() == dst_container_type.IsInt());
ASSERT(src_payload_type.IsSigned() == dst_payload_type.IsSigned());
ASSERT(src_payload_type.IsPrimitive());
ASSERT(dst_payload_type.IsPrimitive());
const intptr_t src_size = src_payload_type.SizeInBytes();
const intptr_t dst_size = dst_payload_type.SizeInBytes();
const bool sign_or_zero_extend = dst_size > src_size;
if (source.IsRegisters()) {
const auto& src = source.AsRegisters();
ASSERT(src.num_regs() == 1);
ASSERT(src_size <= 4);
const auto src_reg = src.reg_at(0);
if (destination.IsRegisters()) {
const auto& dst = destination.AsRegisters();
ASSERT(dst.num_regs() == 1);
const auto dst_reg = dst.reg_at(0);
if (!sign_or_zero_extend) {
ASSERT(dst_size == 4);
__ mov(dst_reg, compiler::Operand(src_reg));
} else {
ASSERT(sign_or_zero_extend);
// Arm has no sign- or zero-extension instructions, so use shifts.
const intptr_t shift_length =
(compiler::target::kWordSize - src_size) * kBitsPerByte;
__ Lsl(dst_reg, src_reg, compiler::Operand(shift_length));
if (src_payload_type.IsSigned()) {
__ Asr(dst_reg, dst_reg, compiler::Operand(shift_length));
} else {
__ Lsr(dst_reg, dst_reg, compiler::Operand(shift_length));
}
}
} else if (destination.IsFpuRegisters()) {
// Fpu Registers should only contain doubles and registers only ints.
// The bit casts are done with a BitCastInstr.
// TODO(dartbug.com/40371): Remove BitCastInstr and implement here.
UNIMPLEMENTED();
} else {
ASSERT(destination.IsStack());
const auto& dst = destination.AsStack();
ASSERT(!sign_or_zero_extend);
ASSERT(dst_size <= 4);
auto const op_size = BytesToOperandSize(dst_size);
__ StoreToOffset(src.reg_at(0), dst.base_register(),
dst.offset_in_bytes(), op_size);
}
} else if (source.IsFpuRegisters()) {
const auto& src = source.AsFpuRegisters();
// We have not implemented conversions here, use IL convert instructions.
ASSERT(src_payload_type.Equals(dst_payload_type));
if (destination.IsRegisters()) {
// Fpu Registers should only contain doubles and registers only ints.
// The bit casts are done with a BitCastInstr.
// TODO(dartbug.com/40371): Remove BitCastInstr and implement here.
UNIMPLEMENTED();
} else if (destination.IsFpuRegisters()) {
const auto& dst = destination.AsFpuRegisters();
switch (dst_size) {
case 16:
__ vmovq(dst.fpu_reg(), src.fpu_reg());
return;
case 8:
__ vmovd(dst.fpu_as_d_reg(), src.fpu_as_d_reg());
return;
case 4:
__ vmovs(dst.fpu_as_s_reg(), src.fpu_as_s_reg());
return;
default:
UNREACHABLE();
}
} else {
ASSERT(destination.IsStack());
ASSERT(src_payload_type.IsFloat());
const auto& dst = destination.AsStack();
switch (dst_size) {
case 8:
__ StoreDToOffset(src.fpu_as_d_reg(), dst.base_register(),
dst.offset_in_bytes());
return;
case 4:
__ StoreSToOffset(src.fpu_as_s_reg(), dst.base_register(),
dst.offset_in_bytes());
return;
default:
// TODO(dartbug.com/37470): Case 16 for simd packed data.
UNREACHABLE();
}
}
} else {
ASSERT(source.IsStack());
const auto& src = source.AsStack();
if (destination.IsRegisters()) {
const auto& dst = destination.AsRegisters();
ASSERT(dst.num_regs() == 1);
const auto dst_reg = dst.reg_at(0);
ASSERT(!sign_or_zero_extend);
ASSERT(dst_size <= 4);
auto const op_size = BytesToOperandSize(dst_size);
__ LoadFromOffset(dst_reg, src.base_register(), src.offset_in_bytes(),
op_size);
} else if (destination.IsFpuRegisters()) {
ASSERT(src_payload_type.Equals(dst_payload_type));
ASSERT(src_payload_type.IsFloat());
const auto& dst = destination.AsFpuRegisters();
switch (src_size) {
case 8:
__ LoadDFromOffset(dst.fpu_as_d_reg(), src.base_register(),
src.offset_in_bytes());
return;
case 4:
__ LoadSFromOffset(dst.fpu_as_s_reg(), src.base_register(),
src.offset_in_bytes());
return;
default:
UNIMPLEMENTED();
}
} else {
ASSERT(destination.IsStack());
UNREACHABLE();
}
}
}
void FlowGraphCompiler::LoadBSSEntry(BSS::Relocation relocation,
Register dst,
Register tmp) {
compiler::Label skip_reloc;
__ b(&skip_reloc);
InsertBSSRelocation(relocation);
__ Bind(&skip_reloc);
// For historical reasons, the PC on ARM points 8 bytes (two instructions)
// past the current instruction.
__ sub(tmp, PC,
compiler::Operand(Instr::kPCReadOffset + compiler::target::kWordSize));
// tmp holds the address of the relocation.
__ ldr(dst, compiler::Address(tmp));
// dst holds the relocation itself: tmp - bss_start.
// tmp = tmp + (bss_start - tmp) = bss_start
__ add(tmp, tmp, compiler::Operand(dst));
// tmp holds the start of the BSS section.
// Load the "get-thread" routine: *bss_start.
__ ldr(dst, compiler::Address(tmp));
}
#undef __
#define __ compiler_->assembler()->
void ParallelMoveResolver::EmitSwap(int index) {
MoveOperands* move = moves_[index];
const Location source = move->src();
const Location destination = move->dest();
if (source.IsRegister() && destination.IsRegister()) {
ASSERT(source.reg() != IP);
ASSERT(destination.reg() != IP);
__ mov(IP, compiler::Operand(source.reg()));
__ mov(source.reg(), compiler::Operand(destination.reg()));
__ mov(destination.reg(), compiler::Operand(IP));
} else if (source.IsRegister() && destination.IsStackSlot()) {
Exchange(source.reg(), destination.base_reg(),
destination.ToStackSlotOffset());
} else if (source.IsStackSlot() && destination.IsRegister()) {
Exchange(destination.reg(), source.base_reg(), source.ToStackSlotOffset());
} else if (source.IsStackSlot() && destination.IsStackSlot()) {
Exchange(source.base_reg(), source.ToStackSlotOffset(),
destination.base_reg(), destination.ToStackSlotOffset());
} else if (source.IsFpuRegister() && destination.IsFpuRegister()) {
if (TargetCPUFeatures::neon_supported()) {
const QRegister dst = destination.fpu_reg();
const QRegister src = source.fpu_reg();
ASSERT(dst != QTMP && src != QTMP);
__ vmovq(QTMP, src);
__ vmovq(src, dst);
__ vmovq(dst, QTMP);
} else {
const DRegister dst = EvenDRegisterOf(destination.fpu_reg());
const DRegister src = EvenDRegisterOf(source.fpu_reg());
ASSERT(dst != DTMP && src != DTMP);
__ vmovd(DTMP, src);
__ vmovd(src, dst);
__ vmovd(dst, DTMP);
}
} else if (source.IsFpuRegister() || destination.IsFpuRegister()) {
ASSERT(destination.IsDoubleStackSlot() || destination.IsQuadStackSlot() ||
source.IsDoubleStackSlot() || source.IsQuadStackSlot());
bool double_width =
destination.IsDoubleStackSlot() || source.IsDoubleStackSlot();
QRegister qreg =
source.IsFpuRegister() ? source.fpu_reg() : destination.fpu_reg();
DRegister reg = EvenDRegisterOf(qreg);
Register base_reg =
source.IsFpuRegister() ? destination.base_reg() : source.base_reg();
const intptr_t slot_offset = source.IsFpuRegister()
? destination.ToStackSlotOffset()
: source.ToStackSlotOffset();
if (double_width) {
__ LoadDFromOffset(DTMP, base_reg, slot_offset);
__ StoreDToOffset(reg, base_reg, slot_offset);
__ vmovd(reg, DTMP);
} else {
__ LoadMultipleDFromOffset(DTMP, 2, base_reg, slot_offset);
__ StoreMultipleDToOffset(reg, 2, base_reg, slot_offset);
__ vmovq(qreg, QTMP);
}
} else if (source.IsDoubleStackSlot() && destination.IsDoubleStackSlot()) {
const intptr_t source_offset = source.ToStackSlotOffset();
const intptr_t dest_offset = destination.ToStackSlotOffset();
ScratchFpuRegisterScope ensure_scratch(this, kNoQRegister);
DRegister scratch = EvenDRegisterOf(ensure_scratch.reg());
__ LoadDFromOffset(DTMP, source.base_reg(), source_offset);
__ LoadDFromOffset(scratch, destination.base_reg(), dest_offset);
__ StoreDToOffset(DTMP, destination.base_reg(), dest_offset);
__ StoreDToOffset(scratch, destination.base_reg(), source_offset);
} else if (source.IsQuadStackSlot() && destination.IsQuadStackSlot()) {
const intptr_t source_offset = source.ToStackSlotOffset();
const intptr_t dest_offset = destination.ToStackSlotOffset();
ScratchFpuRegisterScope ensure_scratch(this, kNoQRegister);
DRegister scratch = EvenDRegisterOf(ensure_scratch.reg());
__ LoadMultipleDFromOffset(DTMP, 2, source.base_reg(), source_offset);
__ LoadMultipleDFromOffset(scratch, 2, destination.base_reg(), dest_offset);
__ StoreMultipleDToOffset(DTMP, 2, destination.base_reg(), dest_offset);
__ StoreMultipleDToOffset(scratch, 2, destination.base_reg(),
source_offset);
} else {
UNREACHABLE();
}
// The swap of source and destination has executed a move from source to
// destination.
move->Eliminate();
// Any unperformed (including pending) move with a source of either
// this move's source or destination needs to have their source
// changed to reflect the state of affairs after the swap.
for (int i = 0; i < moves_.length(); ++i) {
const MoveOperands& other_move = *moves_[i];
if (other_move.Blocks(source)) {
moves_[i]->set_src(destination);
} else if (other_move.Blocks(destination)) {
moves_[i]->set_src(source);
}
}
}
void ParallelMoveResolver::MoveMemoryToMemory(const compiler::Address& dst,
const compiler::Address& src) {
UNREACHABLE();
}
// Do not call or implement this function. Instead, use the form below that
// uses an offset from the frame pointer instead of an Address.
void ParallelMoveResolver::Exchange(Register reg,
const compiler::Address& mem) {
UNREACHABLE();
}
// Do not call or implement this function. Instead, use the form below that
// uses offsets from the frame pointer instead of Addresses.
void ParallelMoveResolver::Exchange(const compiler::Address& mem1,
const compiler::Address& mem2) {
UNREACHABLE();
}
void ParallelMoveResolver::Exchange(Register reg,
Register base_reg,
intptr_t stack_offset) {
ScratchRegisterScope tmp(this, reg);
__ mov(tmp.reg(), compiler::Operand(reg));
__ LoadFromOffset(reg, base_reg, stack_offset);
__ StoreToOffset(tmp.reg(), base_reg, stack_offset);
}
void ParallelMoveResolver::Exchange(Register base_reg1,
intptr_t stack_offset1,
Register base_reg2,
intptr_t stack_offset2) {
ScratchRegisterScope tmp1(this, kNoRegister);
ScratchRegisterScope tmp2(this, tmp1.reg());
__ LoadFromOffset(tmp1.reg(), base_reg1, stack_offset1);
__ LoadFromOffset(tmp2.reg(), base_reg2, stack_offset2);
__ StoreToOffset(tmp1.reg(), base_reg2, stack_offset2);
__ StoreToOffset(tmp2.reg(), base_reg1, stack_offset1);
}
void ParallelMoveResolver::SpillScratch(Register reg) {
__ Push(reg);
}
void ParallelMoveResolver::RestoreScratch(Register reg) {
__ Pop(reg);
}
void ParallelMoveResolver::SpillFpuScratch(FpuRegister reg) {
__ PushQuad(reg);
}
void ParallelMoveResolver::RestoreFpuScratch(FpuRegister reg) {
__ PopQuad(reg);
}
#undef __
} // namespace dart
#endif // defined(TARGET_ARCH_ARM)