| // 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_X64. |
| #if defined(TARGET_ARCH_X64) |
| |
| #include "vm/flow_graph_compiler.h" |
| |
| #include "vm/ast_printer.h" |
| #include "vm/compiler.h" |
| #include "vm/dart_entry.h" |
| #include "vm/deopt_instructions.h" |
| #include "vm/il_printer.h" |
| #include "vm/instructions.h" |
| #include "vm/locations.h" |
| #include "vm/object_store.h" |
| #include "vm/parser.h" |
| #include "vm/stack_frame.h" |
| #include "vm/stub_code.h" |
| #include "vm/symbols.h" |
| #include "vm/verified_memory.h" |
| |
| namespace dart { |
| |
| DEFINE_FLAG(bool, trap_on_deoptimization, false, "Trap on deoptimization."); |
| DEFINE_FLAG(bool, unbox_mints, true, "Optimize 64-bit integer arithmetic."); |
| DECLARE_FLAG(bool, enable_simd_inline); |
| DECLARE_FLAG(bool, use_megamorphic_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()); |
| ASSERT(!block_info_[i]->jump_label()->HasNear()); |
| } |
| } |
| |
| |
| bool FlowGraphCompiler::SupportsUnboxedDoubles() { |
| return true; |
| } |
| |
| |
| bool FlowGraphCompiler::SupportsUnboxedMints() { |
| return FLAG_unbox_mints; |
| } |
| |
| |
| bool FlowGraphCompiler::SupportsUnboxedSimd128() { |
| return FLAG_enable_simd_inline; |
| } |
| |
| |
| |
| bool FlowGraphCompiler::SupportsSinCos() { |
| return true; |
| } |
| |
| |
| bool FlowGraphCompiler::SupportsHardwareDivision() { |
| return true; |
| } |
| |
| |
| void FlowGraphCompiler::EnterIntrinsicMode() { |
| ASSERT(!intrinsic_mode()); |
| intrinsic_mode_ = true; |
| ASSERT(!assembler()->constant_pool_allowed()); |
| } |
| |
| |
| void FlowGraphCompiler::ExitIntrinsicMode() { |
| ASSERT(intrinsic_mode()); |
| intrinsic_mode_ = false; |
| } |
| |
| |
| RawTypedData* 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::Handle(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(), |
| Thread::ToDeoptAfter(current->deopt_id()), |
| 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); |
| Assembler* assem = compiler->assembler(); |
| #define __ assem-> |
| __ Comment("%s", Name()); |
| __ Bind(entry_label()); |
| if (FLAG_trap_on_deoptimization) { |
| __ int3(); |
| } |
| |
| ASSERT(deopt_env() != NULL); |
| |
| __ pushq(CODE_REG); |
| __ Call(*StubCode::Deoptimize_entry()); |
| set_pc_offset(assem->CodeSize()); |
| __ int3(); |
| #undef __ |
| } |
| |
| |
| #define __ assembler()-> |
| |
| |
| // Fall through if bool_register contains null. |
| void FlowGraphCompiler::GenerateBoolToJump(Register bool_register, |
| Label* is_true, |
| Label* is_false) { |
| Label fall_through; |
| __ CompareObject(bool_register, Object::null_object()); |
| __ j(EQUAL, &fall_through, Assembler::kNearJump); |
| __ CompareObject(bool_register, Bool::True()); |
| __ j(EQUAL, is_true); |
| __ jmp(is_false); |
| __ Bind(&fall_through); |
| } |
| |
| |
| // Clobbers RCX. |
| RawSubtypeTestCache* FlowGraphCompiler::GenerateCallSubtypeTestStub( |
| TypeTestStubKind test_kind, |
| Register instance_reg, |
| Register type_arguments_reg, |
| Register temp_reg, |
| Label* is_instance_lbl, |
| Label* is_not_instance_lbl) { |
| const SubtypeTestCache& type_test_cache = |
| SubtypeTestCache::ZoneHandle(zone(), SubtypeTestCache::New()); |
| __ LoadUniqueObject(temp_reg, type_test_cache); |
| __ pushq(temp_reg); // Subtype test cache. |
| __ pushq(instance_reg); // Instance. |
| if (test_kind == kTestTypeOneArg) { |
| ASSERT(type_arguments_reg == kNoRegister); |
| __ PushObject(Object::null_object()); |
| __ Call(*StubCode::Subtype1TestCache_entry()); |
| } else if (test_kind == kTestTypeTwoArgs) { |
| ASSERT(type_arguments_reg == kNoRegister); |
| __ PushObject(Object::null_object()); |
| __ Call(*StubCode::Subtype2TestCache_entry()); |
| } else if (test_kind == kTestTypeThreeArgs) { |
| __ pushq(type_arguments_reg); |
| __ Call(*StubCode::Subtype3TestCache_entry()); |
| } else { |
| UNREACHABLE(); |
| } |
| // Result is in RCX: null -> not found, otherwise Bool::True or Bool::False. |
| ASSERT(instance_reg != RCX); |
| ASSERT(temp_reg != RCX); |
| __ popq(instance_reg); // Discard. |
| __ popq(instance_reg); // Restore receiver. |
| __ popq(temp_reg); // Discard. |
| GenerateBoolToJump(RCX, is_instance_lbl, is_not_instance_lbl); |
| return type_test_cache.raw(); |
| } |
| |
| |
| // Jumps to labels 'is_instance' or 'is_not_instance' respectively, if |
| // type test is conclusive, otherwise fallthrough if a type test could not |
| // be completed. |
| // RAX: instance (must survive). |
| // Clobbers R10. |
| RawSubtypeTestCache* |
| FlowGraphCompiler::GenerateInstantiatedTypeWithArgumentsTest( |
| intptr_t token_pos, |
| const AbstractType& type, |
| Label* is_instance_lbl, |
| Label* is_not_instance_lbl) { |
| __ Comment("InstantiatedTypeWithArgumentsTest"); |
| ASSERT(type.IsInstantiated()); |
| const Class& type_class = Class::ZoneHandle(zone(), type.type_class()); |
| ASSERT((type_class.NumTypeArguments() > 0) || type_class.IsSignatureClass()); |
| const Register kInstanceReg = RAX; |
| Error& malformed_error = Error::Handle(zone()); |
| const Type& int_type = Type::Handle(zone(), Type::IntType()); |
| const bool smi_is_ok = |
| int_type.IsSubtypeOf(type, &malformed_error, Heap::kOld); |
| // Malformed type should have been handled at graph construction time. |
| ASSERT(smi_is_ok || malformed_error.IsNull()); |
| __ testq(kInstanceReg, Immediate(kSmiTagMask)); |
| if (smi_is_ok) { |
| __ j(ZERO, is_instance_lbl); |
| } else { |
| __ j(ZERO, is_not_instance_lbl); |
| } |
| const intptr_t num_type_args = type_class.NumTypeArguments(); |
| const intptr_t num_type_params = type_class.NumTypeParameters(); |
| const intptr_t from_index = num_type_args - num_type_params; |
| const TypeArguments& type_arguments = |
| TypeArguments::ZoneHandle(zone(), type.arguments()); |
| const bool is_raw_type = type_arguments.IsNull() || |
| type_arguments.IsRaw(from_index, num_type_params); |
| // Signature class is an instantiated parameterized type. |
| if (!type_class.IsSignatureClass()) { |
| if (is_raw_type) { |
| const Register kClassIdReg = R10; |
| // dynamic type argument, check only classes. |
| __ LoadClassId(kClassIdReg, kInstanceReg); |
| __ cmpl(kClassIdReg, Immediate(type_class.id())); |
| __ j(EQUAL, is_instance_lbl); |
| // List is a very common case. |
| if (IsListClass(type_class)) { |
| GenerateListTypeCheck(kClassIdReg, is_instance_lbl); |
| } |
| return GenerateSubtype1TestCacheLookup( |
| token_pos, type_class, is_instance_lbl, is_not_instance_lbl); |
| } |
| // If one type argument only, check if type argument is Object or dynamic. |
| if (type_arguments.Length() == 1) { |
| const AbstractType& tp_argument = AbstractType::ZoneHandle(zone(), |
| type_arguments.TypeAt(0)); |
| ASSERT(!tp_argument.IsMalformed()); |
| if (tp_argument.IsType()) { |
| ASSERT(tp_argument.HasResolvedTypeClass()); |
| // Check if type argument is dynamic or Object. |
| const Type& object_type = Type::Handle(zone(), Type::ObjectType()); |
| if (object_type.IsSubtypeOf(tp_argument, NULL, Heap::kOld)) { |
| // Instance class test only necessary. |
| return GenerateSubtype1TestCacheLookup( |
| token_pos, type_class, is_instance_lbl, is_not_instance_lbl); |
| } |
| } |
| } |
| } |
| // Regular subtype test cache involving instance's type arguments. |
| const Register kTypeArgumentsReg = kNoRegister; |
| const Register kTempReg = R10; |
| return GenerateCallSubtypeTestStub(kTestTypeTwoArgs, |
| kInstanceReg, |
| kTypeArgumentsReg, |
| kTempReg, |
| is_instance_lbl, |
| is_not_instance_lbl); |
| } |
| |
| |
| void FlowGraphCompiler::CheckClassIds(Register class_id_reg, |
| const GrowableArray<intptr_t>& class_ids, |
| Label* is_equal_lbl, |
| Label* is_not_equal_lbl) { |
| for (intptr_t i = 0; i < class_ids.length(); i++) { |
| __ cmpl(class_id_reg, Immediate(class_ids[i])); |
| __ j(EQUAL, is_equal_lbl); |
| } |
| __ jmp(is_not_equal_lbl); |
| } |
| |
| |
| // Testing against an instantiated type with no arguments, without |
| // SubtypeTestCache. |
| // RAX: instance to test against (preserved). |
| // Clobbers R10, R13. |
| // Returns true if there is a fallthrough. |
| bool FlowGraphCompiler::GenerateInstantiatedTypeNoArgumentsTest( |
| intptr_t token_pos, |
| const AbstractType& type, |
| Label* is_instance_lbl, |
| Label* is_not_instance_lbl) { |
| __ Comment("InstantiatedTypeNoArgumentsTest"); |
| ASSERT(type.IsInstantiated()); |
| const Class& type_class = Class::Handle(zone(), type.type_class()); |
| ASSERT(type_class.NumTypeArguments() == 0); |
| |
| const Register kInstanceReg = RAX; |
| __ testq(kInstanceReg, Immediate(kSmiTagMask)); |
| // If instance is Smi, check directly. |
| const Class& smi_class = Class::Handle(zone(), Smi::Class()); |
| if (smi_class.IsSubtypeOf(TypeArguments::Handle(zone()), |
| type_class, |
| TypeArguments::Handle(zone()), |
| NULL, |
| Heap::kOld)) { |
| __ j(ZERO, is_instance_lbl); |
| } else { |
| __ j(ZERO, is_not_instance_lbl); |
| } |
| // Compare if the classes are equal. |
| const Register kClassIdReg = R10; |
| __ LoadClassId(kClassIdReg, kInstanceReg); |
| __ cmpl(kClassIdReg, Immediate(type_class.id())); |
| __ j(EQUAL, is_instance_lbl); |
| // See ClassFinalizer::ResolveSuperTypeAndInterfaces for list of restricted |
| // interfaces. |
| // Bool interface can be implemented only by core class Bool. |
| if (type.IsBoolType()) { |
| __ cmpl(kClassIdReg, Immediate(kBoolCid)); |
| __ j(EQUAL, is_instance_lbl); |
| __ jmp(is_not_instance_lbl); |
| return false; |
| } |
| if (type.IsFunctionType()) { |
| // Check if instance is a closure. |
| __ LoadClassById(R13, kClassIdReg); |
| __ movq(R13, FieldAddress(R13, Class::signature_function_offset())); |
| __ CompareObject(R13, Object::null_object()); |
| __ j(NOT_EQUAL, is_instance_lbl); |
| } |
| // Custom checking for numbers (Smi, Mint, Bigint and Double). |
| // Note that instance is not Smi (checked above). |
| if (type.IsSubtypeOf( |
| Type::Handle(zone(), Type::Number()), NULL, Heap::kOld)) { |
| GenerateNumberTypeCheck( |
| kClassIdReg, type, is_instance_lbl, is_not_instance_lbl); |
| return false; |
| } |
| if (type.IsStringType()) { |
| GenerateStringTypeCheck(kClassIdReg, is_instance_lbl, is_not_instance_lbl); |
| return false; |
| } |
| // Otherwise fallthrough. |
| return true; |
| } |
| |
| |
| // Uses SubtypeTestCache to store instance class and result. |
| // RAX: instance to test. |
| // Clobbers R10, R13. |
| // Immediate class test already done. |
| // TODO(srdjan): Implement a quicker subtype check, as type test |
| // arrays can grow too high, but they may be useful when optimizing |
| // code (type-feedback). |
| RawSubtypeTestCache* FlowGraphCompiler::GenerateSubtype1TestCacheLookup( |
| intptr_t token_pos, |
| const Class& type_class, |
| Label* is_instance_lbl, |
| Label* is_not_instance_lbl) { |
| __ Comment("Subtype1TestCacheLookup"); |
| const Register kInstanceReg = RAX; |
| __ LoadClass(R10, kInstanceReg); |
| // R10: instance class. |
| // Check immediate superclass equality. |
| __ movq(R13, FieldAddress(R10, Class::super_type_offset())); |
| __ movq(R13, FieldAddress(R13, Type::type_class_offset())); |
| __ CompareObject(R13, type_class); |
| __ j(EQUAL, is_instance_lbl); |
| |
| const Register kTypeArgumentsReg = kNoRegister; |
| const Register kTempReg = R10; |
| return GenerateCallSubtypeTestStub(kTestTypeOneArg, |
| kInstanceReg, |
| kTypeArgumentsReg, |
| kTempReg, |
| is_instance_lbl, |
| is_not_instance_lbl); |
| } |
| |
| |
| // Generates inlined check if 'type' is a type parameter or type itself |
| // RAX: instance (preserved). |
| // Clobbers RDI, RDX, R10. |
| RawSubtypeTestCache* FlowGraphCompiler::GenerateUninstantiatedTypeTest( |
| intptr_t token_pos, |
| const AbstractType& type, |
| Label* is_instance_lbl, |
| Label* is_not_instance_lbl) { |
| __ Comment("UninstantiatedTypeTest"); |
| ASSERT(!type.IsInstantiated()); |
| // Skip check if destination is a dynamic type. |
| if (type.IsTypeParameter()) { |
| const TypeParameter& type_param = TypeParameter::Cast(type); |
| // Load instantiator (or null) and instantiator type arguments on stack. |
| __ movq(RDX, Address(RSP, 0)); // Get instantiator type arguments. |
| // RDX: instantiator type arguments. |
| // Check if type arguments are null, i.e. equivalent to vector of dynamic. |
| __ CompareObject(RDX, Object::null_object()); |
| __ j(EQUAL, is_instance_lbl); |
| __ movq(RDI, |
| FieldAddress(RDX, TypeArguments::type_at_offset(type_param.index()))); |
| // RDI: Concrete type of type. |
| // Check if type argument is dynamic. |
| __ CompareObject(RDI, Type::ZoneHandle(zone(), Type::DynamicType())); |
| __ j(EQUAL, is_instance_lbl); |
| const Type& object_type = Type::ZoneHandle(zone(), Type::ObjectType()); |
| __ CompareObject(RDI, object_type); |
| __ j(EQUAL, is_instance_lbl); |
| |
| // For Smi check quickly against int and num interfaces. |
| Label not_smi; |
| __ testq(RAX, Immediate(kSmiTagMask)); // Value is Smi? |
| __ j(NOT_ZERO, ¬_smi, Assembler::kNearJump); |
| __ CompareObject(RDI, Type::ZoneHandle(zone(), Type::IntType())); |
| __ j(EQUAL, is_instance_lbl); |
| __ CompareObject(RDI, Type::ZoneHandle(zone(), Type::Number())); |
| __ j(EQUAL, is_instance_lbl); |
| // Smi must be handled in runtime. |
| Label fall_through; |
| __ jmp(&fall_through); |
| |
| __ Bind(¬_smi); |
| // RDX: instantiator type arguments. |
| // RAX: instance. |
| const Register kInstanceReg = RAX; |
| const Register kTypeArgumentsReg = RDX; |
| const Register kTempReg = R10; |
| const SubtypeTestCache& type_test_cache = |
| SubtypeTestCache::ZoneHandle(zone(), |
| GenerateCallSubtypeTestStub(kTestTypeThreeArgs, |
| kInstanceReg, |
| kTypeArgumentsReg, |
| kTempReg, |
| is_instance_lbl, |
| is_not_instance_lbl)); |
| __ Bind(&fall_through); |
| return type_test_cache.raw(); |
| } |
| if (type.IsType()) { |
| const Register kInstanceReg = RAX; |
| const Register kTypeArgumentsReg = RDX; |
| __ testq(kInstanceReg, Immediate(kSmiTagMask)); // Is instance Smi? |
| __ j(ZERO, is_not_instance_lbl); |
| __ movq(kTypeArgumentsReg, Address(RSP, 0)); // Instantiator type args. |
| // Uninstantiated type class is known at compile time, but the type |
| // arguments are determined at runtime by the instantiator. |
| const Register kTempReg = R10; |
| return GenerateCallSubtypeTestStub(kTestTypeThreeArgs, |
| kInstanceReg, |
| kTypeArgumentsReg, |
| kTempReg, |
| is_instance_lbl, |
| is_not_instance_lbl); |
| } |
| return SubtypeTestCache::null(); |
| } |
| |
| |
| // Inputs: |
| // - RAX: instance to test against (preserved). |
| // - RDX: optional instantiator type arguments (preserved). |
| // Clobbers R10, R13. |
| // Returns: |
| // - preserved instance in RAX and optional instantiator type arguments in RDX. |
| // Note that this inlined code must be followed by the runtime_call code, as it |
| // may fall through to it. Otherwise, this inline code will jump to the label |
| // is_instance or to the label is_not_instance. |
| RawSubtypeTestCache* FlowGraphCompiler::GenerateInlineInstanceof( |
| intptr_t token_pos, |
| const AbstractType& type, |
| Label* is_instance_lbl, |
| Label* is_not_instance_lbl) { |
| __ Comment("InlineInstanceof"); |
| if (type.IsVoidType()) { |
| // A non-null value is returned from a void function, which will result in a |
| // type error. A null value is handled prior to executing this inline code. |
| return SubtypeTestCache::null(); |
| } |
| if (type.IsInstantiated()) { |
| const Class& type_class = Class::ZoneHandle(zone(), type.type_class()); |
| // A class equality check is only applicable with a dst type of a |
| // non-parameterized class, non-signature class, or with a raw dst type of |
| // a parameterized class. |
| if (type_class.IsSignatureClass() || (type_class.NumTypeArguments() > 0)) { |
| return GenerateInstantiatedTypeWithArgumentsTest(token_pos, |
| type, |
| is_instance_lbl, |
| is_not_instance_lbl); |
| // Fall through to runtime call. |
| } |
| const bool has_fall_through = |
| GenerateInstantiatedTypeNoArgumentsTest(token_pos, |
| type, |
| is_instance_lbl, |
| is_not_instance_lbl); |
| if (has_fall_through) { |
| // If test non-conclusive so far, try the inlined type-test cache. |
| // 'type' is known at compile time. |
| return GenerateSubtype1TestCacheLookup( |
| token_pos, type_class, is_instance_lbl, is_not_instance_lbl); |
| } else { |
| return SubtypeTestCache::null(); |
| } |
| } |
| return GenerateUninstantiatedTypeTest(token_pos, |
| type, |
| is_instance_lbl, |
| is_not_instance_lbl); |
| } |
| |
| |
| // If instanceof type test cannot be performed successfully at compile time and |
| // therefore eliminated, optimize it by adding inlined tests for: |
| // - NULL -> return false. |
| // - Smi -> compile time subtype check (only if dst class is not parameterized). |
| // - Class equality (only if class is not parameterized). |
| // Inputs: |
| // - RAX: object. |
| // - RDX: instantiator type arguments or raw_null. |
| // - RCX: instantiator or raw_null. |
| // Clobbers RCX and RDX. |
| // Returns: |
| // - true or false in RAX. |
| void FlowGraphCompiler::GenerateInstanceOf(intptr_t token_pos, |
| intptr_t deopt_id, |
| const AbstractType& type, |
| bool negate_result, |
| LocationSummary* locs) { |
| ASSERT(type.IsFinalized() && !type.IsMalformedOrMalbounded()); |
| |
| Label is_instance, is_not_instance; |
| __ pushq(RCX); // Store instantiator on stack. |
| __ pushq(RDX); // Store instantiator type arguments. |
| // If type is instantiated and non-parameterized, we can inline code |
| // checking whether the tested instance is a Smi. |
| if (type.IsInstantiated()) { |
| // A null object is only an instance of Object and dynamic, which has |
| // already been checked above (if the type is instantiated). So we can |
| // return false here if the instance is null (and if the type is |
| // instantiated). |
| // We can only inline this null check if the type is instantiated at compile |
| // time, since an uninstantiated type at compile time could be Object or |
| // dynamic at run time. |
| __ CompareObject(RAX, Object::null_object()); |
| __ j(EQUAL, type.IsNullType() ? &is_instance : &is_not_instance); |
| } |
| |
| // Generate inline instanceof test. |
| SubtypeTestCache& test_cache = SubtypeTestCache::ZoneHandle(zone()); |
| test_cache = GenerateInlineInstanceof(token_pos, type, |
| &is_instance, &is_not_instance); |
| |
| // test_cache is null if there is no fall-through. |
| Label done; |
| if (!test_cache.IsNull()) { |
| // Generate runtime call. |
| __ movq(RDX, Address(RSP, 0)); // Get instantiator type arguments. |
| __ movq(RCX, Address(RSP, kWordSize)); // Get instantiator. |
| __ PushObject(Object::null_object()); // Make room for the result. |
| __ pushq(RAX); // Push the instance. |
| __ PushObject(type); // Push the type. |
| __ pushq(RCX); // TODO(srdjan): Pass instantiator instead of null. |
| __ pushq(RDX); // Instantiator type arguments. |
| __ LoadUniqueObject(RAX, test_cache); |
| __ pushq(RAX); |
| GenerateRuntimeCall(token_pos, |
| deopt_id, |
| kInstanceofRuntimeEntry, |
| 5, |
| locs); |
| // Pop the parameters supplied to the runtime entry. The result of the |
| // instanceof runtime call will be left as the result of the operation. |
| __ Drop(5); |
| if (negate_result) { |
| __ popq(RDX); |
| __ LoadObject(RAX, Bool::True()); |
| __ cmpq(RDX, RAX); |
| __ j(NOT_EQUAL, &done, Assembler::kNearJump); |
| __ LoadObject(RAX, Bool::False()); |
| } else { |
| __ popq(RAX); |
| } |
| __ jmp(&done, Assembler::kNearJump); |
| } |
| __ Bind(&is_not_instance); |
| __ LoadObject(RAX, Bool::Get(negate_result)); |
| __ jmp(&done, Assembler::kNearJump); |
| |
| __ Bind(&is_instance); |
| __ LoadObject(RAX, Bool::Get(!negate_result)); |
| __ Bind(&done); |
| __ popq(RDX); // Remove pushed instantiator type arguments. |
| __ popq(RCX); // Remove pushed instantiator. |
| } |
| |
| |
| // Optimize assignable type check by adding inlined tests for: |
| // - NULL -> return NULL. |
| // - Smi -> compile time subtype check (only if dst class is not parameterized). |
| // - Class equality (only if class is not parameterized). |
| // Inputs: |
| // - RAX: object. |
| // - RDX: instantiator type arguments or raw_null. |
| // - RCX: instantiator or raw_null. |
| // Returns: |
| // - object in RAX for successful assignable check (or throws TypeError). |
| // Performance notes: positive checks must be quick, negative checks can be slow |
| // as they throw an exception. |
| void FlowGraphCompiler::GenerateAssertAssignable(intptr_t token_pos, |
| intptr_t deopt_id, |
| const AbstractType& dst_type, |
| const String& dst_name, |
| LocationSummary* locs) { |
| ASSERT(token_pos >= 0); |
| ASSERT(!dst_type.IsNull()); |
| ASSERT(dst_type.IsFinalized()); |
| // Assignable check is skipped in FlowGraphBuilder, not here. |
| ASSERT(dst_type.IsMalformedOrMalbounded() || |
| (!dst_type.IsDynamicType() && !dst_type.IsObjectType())); |
| __ pushq(RCX); // Store instantiator. |
| __ pushq(RDX); // Store instantiator type arguments. |
| // A null object is always assignable and is returned as result. |
| Label is_assignable, runtime_call; |
| __ CompareObject(RAX, Object::null_object()); |
| __ j(EQUAL, &is_assignable); |
| |
| // Generate throw new TypeError() if the type is malformed or malbounded. |
| if (dst_type.IsMalformedOrMalbounded()) { |
| __ PushObject(Object::null_object()); // Make room for the result. |
| __ pushq(RAX); // Push the source object. |
| __ PushObject(dst_name); // Push the name of the destination. |
| __ PushObject(dst_type); // Push the type of the destination. |
| GenerateRuntimeCall(token_pos, |
| deopt_id, |
| kBadTypeErrorRuntimeEntry, |
| 3, |
| locs); |
| // We should never return here. |
| __ int3(); |
| |
| __ Bind(&is_assignable); // For a null object. |
| __ popq(RDX); // Remove pushed instantiator type arguments. |
| __ popq(RCX); // Remove pushed instantiator. |
| return; |
| } |
| |
| // Generate inline type check, linking to runtime call if not assignable. |
| SubtypeTestCache& test_cache = SubtypeTestCache::ZoneHandle(zone()); |
| test_cache = GenerateInlineInstanceof(token_pos, dst_type, |
| &is_assignable, &runtime_call); |
| |
| __ Bind(&runtime_call); |
| __ movq(RDX, Address(RSP, 0)); // Get instantiator type arguments. |
| __ movq(RCX, Address(RSP, kWordSize)); // Get instantiator. |
| __ PushObject(Object::null_object()); // Make room for the result. |
| __ pushq(RAX); // Push the source object. |
| __ PushObject(dst_type); // Push the type of the destination. |
| __ pushq(RCX); // Instantiator. |
| __ pushq(RDX); // Instantiator type arguments. |
| __ PushObject(dst_name); // Push the name of the destination. |
| __ LoadUniqueObject(RAX, test_cache); |
| __ pushq(RAX); |
| GenerateRuntimeCall(token_pos, deopt_id, kTypeCheckRuntimeEntry, 6, locs); |
| // Pop the parameters supplied to the runtime entry. The result of the |
| // type check runtime call is the checked value. |
| __ Drop(6); |
| __ popq(RAX); |
| |
| __ Bind(&is_assignable); |
| __ popq(RDX); // Remove pushed instantiator type arguments. |
| __ popq(RCX); // Remove pushed instantiator. |
| } |
| |
| |
| void FlowGraphCompiler::EmitInstructionEpilogue(Instruction* instr) { |
| if (is_optimizing()) { |
| return; |
| } |
| Definition* defn = instr->AsDefinition(); |
| if ((defn != NULL) && defn->HasTemp()) { |
| Location value = defn->locs()->out(0); |
| if (value.IsRegister()) { |
| __ pushq(value.reg()); |
| } else if (value.IsConstant()) { |
| __ PushObject(value.constant()); |
| } else { |
| ASSERT(value.IsStackSlot()); |
| __ pushq(value.ToStackSlotAddress()); |
| } |
| } |
| } |
| |
| |
| void FlowGraphCompiler::CopyParameters() { |
| __ Comment("Copy parameters"); |
| const Function& function = parsed_function().function(); |
| LocalScope* scope = parsed_function().node_sequence()->scope(); |
| const int num_fixed_params = function.num_fixed_parameters(); |
| const int num_opt_pos_params = function.NumOptionalPositionalParameters(); |
| const int num_opt_named_params = function.NumOptionalNamedParameters(); |
| const int num_params = |
| num_fixed_params + num_opt_pos_params + num_opt_named_params; |
| ASSERT(function.NumParameters() == num_params); |
| ASSERT(parsed_function().first_parameter_index() == kFirstLocalSlotFromFp); |
| |
| // Check that min_num_pos_args <= num_pos_args <= max_num_pos_args, |
| // where num_pos_args is the number of positional arguments passed in. |
| const int min_num_pos_args = num_fixed_params; |
| const int max_num_pos_args = num_fixed_params + num_opt_pos_params; |
| |
| __ movq(RCX, |
| FieldAddress(R10, ArgumentsDescriptor::positional_count_offset())); |
| // Check that min_num_pos_args <= num_pos_args. |
| Label wrong_num_arguments; |
| __ CompareImmediate(RCX, Immediate(Smi::RawValue(min_num_pos_args))); |
| __ j(LESS, &wrong_num_arguments); |
| // Check that num_pos_args <= max_num_pos_args. |
| __ CompareImmediate(RCX, Immediate(Smi::RawValue(max_num_pos_args))); |
| __ j(GREATER, &wrong_num_arguments); |
| |
| // Copy positional arguments. |
| // Argument i passed at fp[kParamEndSlotFromFp + num_args - i] is copied |
| // to fp[kFirstLocalSlotFromFp - i]. |
| |
| __ movq(RBX, FieldAddress(R10, ArgumentsDescriptor::count_offset())); |
| // Since RBX and RCX are Smi, use TIMES_4 instead of TIMES_8. |
| // Let RBX point to the last passed positional argument, i.e. to |
| // fp[kParamEndSlotFromFp + num_args - (num_pos_args - 1)]. |
| __ subq(RBX, RCX); |
| __ leaq(RBX, Address(RBP, RBX, TIMES_4, |
| (kParamEndSlotFromFp + 1) * kWordSize)); |
| |
| // Let RDI point to the last copied positional argument, i.e. to |
| // fp[kFirstLocalSlotFromFp - (num_pos_args - 1)]. |
| __ SmiUntag(RCX); |
| __ movq(RAX, RCX); |
| __ negq(RAX); |
| // -num_pos_args is in RAX. |
| __ leaq(RDI, |
| Address(RBP, RAX, TIMES_8, (kFirstLocalSlotFromFp + 1) * kWordSize)); |
| Label loop, loop_condition; |
| __ jmp(&loop_condition, Assembler::kNearJump); |
| // We do not use the final allocation index of the variable here, i.e. |
| // scope->VariableAt(i)->index(), because captured variables still need |
| // to be copied to the context that is not yet allocated. |
| const Address argument_addr(RBX, RCX, TIMES_8, 0); |
| const Address copy_addr(RDI, RCX, TIMES_8, 0); |
| __ Bind(&loop); |
| __ movq(RAX, argument_addr); |
| __ movq(copy_addr, RAX); |
| __ Bind(&loop_condition); |
| __ decq(RCX); |
| __ j(POSITIVE, &loop, Assembler::kNearJump); |
| |
| // Copy or initialize optional named arguments. |
| Label all_arguments_processed; |
| #ifdef DEBUG |
| const bool check_correct_named_args = true; |
| #else |
| const bool check_correct_named_args = function.IsClosureFunction(); |
| #endif |
| if (num_opt_named_params > 0) { |
| // Start by alphabetically sorting the names of the optional parameters. |
| LocalVariable** opt_param = new LocalVariable*[num_opt_named_params]; |
| int* opt_param_position = new int[num_opt_named_params]; |
| for (int pos = num_fixed_params; pos < num_params; pos++) { |
| LocalVariable* parameter = scope->VariableAt(pos); |
| const String& opt_param_name = parameter->name(); |
| int i = pos - num_fixed_params; |
| while (--i >= 0) { |
| LocalVariable* param_i = opt_param[i]; |
| const intptr_t result = opt_param_name.CompareTo(param_i->name()); |
| ASSERT(result != 0); |
| if (result > 0) break; |
| opt_param[i + 1] = opt_param[i]; |
| opt_param_position[i + 1] = opt_param_position[i]; |
| } |
| opt_param[i + 1] = parameter; |
| opt_param_position[i + 1] = pos; |
| } |
| // Generate code handling each optional parameter in alphabetical order. |
| __ movq(RBX, FieldAddress(R10, ArgumentsDescriptor::count_offset())); |
| __ movq(RCX, |
| FieldAddress(R10, ArgumentsDescriptor::positional_count_offset())); |
| __ SmiUntag(RCX); |
| // Let RBX point to the first passed argument, i.e. to |
| // fp[kParamEndSlotFromFp + num_args]; num_args (RBX) is Smi. |
| __ leaq(RBX, |
| Address(RBP, RBX, TIMES_4, kParamEndSlotFromFp * kWordSize)); |
| // Let RDI point to the entry of the first named argument. |
| __ leaq(RDI, |
| FieldAddress(R10, ArgumentsDescriptor::first_named_entry_offset())); |
| for (int i = 0; i < num_opt_named_params; i++) { |
| Label load_default_value, assign_optional_parameter; |
| const int param_pos = opt_param_position[i]; |
| // Check if this named parameter was passed in. |
| // Load RAX with the name of the argument. |
| __ movq(RAX, Address(RDI, ArgumentsDescriptor::name_offset())); |
| ASSERT(opt_param[i]->name().IsSymbol()); |
| __ CompareObject(RAX, opt_param[i]->name()); |
| __ j(NOT_EQUAL, &load_default_value, Assembler::kNearJump); |
| // Load RAX with passed-in argument at provided arg_pos, i.e. at |
| // fp[kParamEndSlotFromFp + num_args - arg_pos]. |
| __ movq(RAX, Address(RDI, ArgumentsDescriptor::position_offset())); |
| // RAX is arg_pos as Smi. |
| // Point to next named entry. |
| __ AddImmediate( |
| RDI, Immediate(ArgumentsDescriptor::named_entry_size())); |
| __ negq(RAX); |
| Address argument_addr(RBX, RAX, TIMES_4, 0); // RAX is a negative Smi. |
| __ movq(RAX, argument_addr); |
| __ jmp(&assign_optional_parameter, Assembler::kNearJump); |
| __ Bind(&load_default_value); |
| // Load RAX with default argument. |
| const Instance& value = parsed_function().DefaultParameterValueAt( |
| param_pos - num_fixed_params); |
| __ LoadObject(RAX, value); |
| __ Bind(&assign_optional_parameter); |
| // Assign RAX to fp[kFirstLocalSlotFromFp - param_pos]. |
| // We do not use the final allocation index of the variable here, i.e. |
| // scope->VariableAt(i)->index(), because captured variables still need |
| // to be copied to the context that is not yet allocated. |
| const intptr_t computed_param_pos = kFirstLocalSlotFromFp - param_pos; |
| const Address param_addr(RBP, computed_param_pos * kWordSize); |
| __ movq(param_addr, RAX); |
| } |
| delete[] opt_param; |
| delete[] opt_param_position; |
| if (check_correct_named_args) { |
| // Check that RDI now points to the null terminator in the arguments |
| // descriptor. |
| __ LoadObject(TMP, Object::null_object()); |
| __ cmpq(Address(RDI, 0), TMP); |
| __ j(EQUAL, &all_arguments_processed, Assembler::kNearJump); |
| } |
| } else { |
| ASSERT(num_opt_pos_params > 0); |
| __ movq(RCX, |
| FieldAddress(R10, ArgumentsDescriptor::positional_count_offset())); |
| __ SmiUntag(RCX); |
| for (int i = 0; i < num_opt_pos_params; i++) { |
| Label next_parameter; |
| // Handle this optional positional parameter only if k or fewer positional |
| // arguments have been passed, where k is param_pos, the position of this |
| // optional parameter in the formal parameter list. |
| const int param_pos = num_fixed_params + i; |
| __ CompareImmediate(RCX, Immediate(param_pos)); |
| __ j(GREATER, &next_parameter, Assembler::kNearJump); |
| // Load RAX with default argument. |
| const Object& value = parsed_function().DefaultParameterValueAt(i); |
| __ LoadObject(RAX, value); |
| // Assign RAX to fp[kFirstLocalSlotFromFp - param_pos]. |
| // We do not use the final allocation index of the variable here, i.e. |
| // scope->VariableAt(i)->index(), because captured variables still need |
| // to be copied to the context that is not yet allocated. |
| const intptr_t computed_param_pos = kFirstLocalSlotFromFp - param_pos; |
| const Address param_addr(RBP, computed_param_pos * kWordSize); |
| __ movq(param_addr, RAX); |
| __ Bind(&next_parameter); |
| } |
| if (check_correct_named_args) { |
| __ movq(RBX, FieldAddress(R10, ArgumentsDescriptor::count_offset())); |
| __ SmiUntag(RBX); |
| // Check that RCX equals RBX, i.e. no named arguments passed. |
| __ cmpq(RCX, RBX); |
| __ j(EQUAL, &all_arguments_processed, Assembler::kNearJump); |
| } |
| } |
| |
| __ Bind(&wrong_num_arguments); |
| if (function.IsClosureFunction()) { |
| __ LeaveDartFrame(kKeepCalleePP); // The arguments are still on the stack. |
| __ Jmp(*StubCode::CallClosureNoSuchMethod_entry()); |
| // The noSuchMethod call may return to the caller, but not here. |
| } else if (check_correct_named_args) { |
| __ Stop("Wrong arguments"); |
| } |
| |
| __ Bind(&all_arguments_processed); |
| // Nullify originally passed arguments only after they have been copied and |
| // checked, otherwise noSuchMethod would not see their original values. |
| // This step can be skipped in case we decide that formal parameters are |
| // implicitly final, since garbage collecting the unmodified value is not |
| // an issue anymore. |
| |
| // R10 : arguments descriptor array. |
| __ movq(RCX, FieldAddress(R10, ArgumentsDescriptor::count_offset())); |
| __ SmiUntag(RCX); |
| __ LoadObject(R12, Object::null_object()); |
| Label null_args_loop, null_args_loop_condition; |
| __ jmp(&null_args_loop_condition, Assembler::kNearJump); |
| const Address original_argument_addr( |
| RBP, RCX, TIMES_8, (kParamEndSlotFromFp + 1) * kWordSize); |
| __ Bind(&null_args_loop); |
| __ movq(original_argument_addr, R12); |
| __ Bind(&null_args_loop_condition); |
| __ decq(RCX); |
| __ j(POSITIVE, &null_args_loop, Assembler::kNearJump); |
| } |
| |
| |
| void FlowGraphCompiler::GenerateInlinedGetter(intptr_t offset) { |
| // TOS: return address. |
| // +1 : receiver. |
| // Sequence node has one return node, its input is load field node. |
| __ Comment("Inlined Getter"); |
| __ movq(RAX, Address(RSP, 1 * kWordSize)); |
| __ movq(RAX, FieldAddress(RAX, offset)); |
| __ ret(); |
| } |
| |
| |
| void FlowGraphCompiler::GenerateInlinedSetter(intptr_t offset) { |
| // TOS: return address. |
| // +1 : value |
| // +2 : receiver. |
| // Sequence node has one store node and one return NULL node. |
| __ Comment("Inlined Setter"); |
| __ movq(RAX, Address(RSP, 2 * kWordSize)); // Receiver. |
| __ movq(RBX, Address(RSP, 1 * kWordSize)); // Value. |
| __ StoreIntoObject(RAX, FieldAddress(RAX, offset), RBX); |
| __ LoadObject(RAX, Object::null_object()); |
| __ ret(); |
| } |
| |
| |
| // NOTE: If the entry code shape changes, ReturnAddressLocator in profiler.cc |
| // needs to be updated to match. |
| void FlowGraphCompiler::EmitFrameEntry() { |
| const Function& function = parsed_function().function(); |
| // Load pool pointer. |
| |
| if (flow_graph().IsCompiledForOsr()) { |
| intptr_t extra_slots = StackSize() |
| - flow_graph().num_stack_locals() |
| - flow_graph().num_copied_params(); |
| ASSERT(extra_slots >= 0); |
| __ EnterOsrFrame(extra_slots * kWordSize); |
| } else { |
| const Register new_pp = R13; |
| __ LoadPoolPointer(new_pp); |
| |
| if (CanOptimizeFunction() && |
| function.IsOptimizable() && |
| (!is_optimizing() || may_reoptimize())) { |
| const Register function_reg = RDI; |
| // Load function object using the callee's pool pointer. |
| __ LoadFunctionFromCalleePool(function_reg, function, new_pp); |
| |
| // Reoptimization of an optimized function is triggered by counting in |
| // IC stubs, but not at the entry of the function. |
| if (!is_optimizing()) { |
| __ incl(FieldAddress(function_reg, Function::usage_counter_offset())); |
| } |
| __ cmpl( |
| FieldAddress(function_reg, Function::usage_counter_offset()), |
| Immediate(GetOptimizationThreshold())); |
| ASSERT(function_reg == RDI); |
| __ J(GREATER_EQUAL, |
| *StubCode::OptimizeFunction_entry(), |
| new_pp); |
| } |
| ASSERT(StackSize() >= 0); |
| __ Comment("Enter frame"); |
| __ EnterDartFrame(StackSize() * kWordSize, new_pp); |
| } |
| } |
| |
| |
| void FlowGraphCompiler::CompileGraph() { |
| InitCompiler(); |
| |
| if (TryIntrinsify()) { |
| // Skip regular code generation. |
| return; |
| } |
| |
| EmitFrameEntry(); |
| ASSERT(assembler()->constant_pool_allowed()); |
| |
| const Function& function = parsed_function().function(); |
| |
| const int num_fixed_params = function.num_fixed_parameters(); |
| const int num_copied_params = parsed_function().num_copied_params(); |
| const int num_locals = parsed_function().num_stack_locals(); |
| |
| // We check the number of passed arguments when we have to copy them due to |
| // the presence of optional parameters. |
| // No such checking code is generated if only fixed parameters are declared, |
| // unless we are in debug mode or unless we are compiling a closure. |
| if (num_copied_params == 0) { |
| #ifdef DEBUG |
| ASSERT(!parsed_function().function().HasOptionalParameters()); |
| const bool check_arguments = !flow_graph().IsCompiledForOsr(); |
| #else |
| const bool check_arguments = |
| function.IsClosureFunction() && !flow_graph().IsCompiledForOsr(); |
| #endif |
| if (check_arguments) { |
| __ Comment("Check argument count"); |
| // Check that exactly num_fixed arguments are passed in. |
| Label correct_num_arguments, wrong_num_arguments; |
| __ movq(RAX, FieldAddress(R10, ArgumentsDescriptor::count_offset())); |
| __ CompareImmediate(RAX, Immediate(Smi::RawValue(num_fixed_params))); |
| __ j(NOT_EQUAL, &wrong_num_arguments, Assembler::kNearJump); |
| __ cmpq(RAX, |
| FieldAddress(R10, |
| ArgumentsDescriptor::positional_count_offset())); |
| __ j(EQUAL, &correct_num_arguments, Assembler::kNearJump); |
| |
| __ Bind(&wrong_num_arguments); |
| if (function.IsClosureFunction()) { |
| __ LeaveDartFrame(kKeepCalleePP); // Leave arguments on the stack. |
| __ Jmp(*StubCode::CallClosureNoSuchMethod_entry()); |
| // The noSuchMethod call may return to the caller, but not here. |
| } else { |
| __ Stop("Wrong number of arguments"); |
| } |
| __ Bind(&correct_num_arguments); |
| } |
| } else if (!flow_graph().IsCompiledForOsr()) { |
| CopyParameters(); |
| } |
| |
| if (function.IsClosureFunction() && !flow_graph().IsCompiledForOsr()) { |
| // Load context from the closure object (first argument). |
| LocalScope* scope = parsed_function().node_sequence()->scope(); |
| LocalVariable* closure_parameter = scope->VariableAt(0); |
| __ movq(CTX, Address(RBP, closure_parameter->index() * kWordSize)); |
| __ movq(CTX, FieldAddress(CTX, Closure::context_offset())); |
| #ifdef DEBUG |
| Label ok; |
| __ LoadClassId(RAX, CTX); |
| __ cmpq(RAX, Immediate(kContextCid)); |
| __ j(EQUAL, &ok, Assembler::kNearJump); |
| __ Stop("Incorrect context at entry"); |
| __ Bind(&ok); |
| #endif |
| } |
| |
| // In unoptimized code, initialize (non-argument) stack allocated slots to |
| // null. |
| if (!is_optimizing()) { |
| ASSERT(num_locals > 0); // There is always at least context_var. |
| __ Comment("Initialize spill slots"); |
| const intptr_t slot_base = parsed_function().first_stack_local_index(); |
| const intptr_t context_index = |
| parsed_function().current_context_var()->index(); |
| if (num_locals > 1) { |
| __ LoadObject(RAX, Object::null_object()); |
| } |
| for (intptr_t i = 0; i < num_locals; ++i) { |
| // Subtract index i (locals lie at lower addresses than RBP). |
| if (((slot_base - i) == context_index)) { |
| if (function.IsClosureFunction()) { |
| __ movq(Address(RBP, (slot_base - i) * kWordSize), CTX); |
| } else { |
| const Context& empty_context = Context::ZoneHandle( |
| zone(), isolate()->object_store()->empty_context()); |
| __ StoreObject( |
| Address(RBP, (slot_base - i) * kWordSize), empty_context); |
| } |
| } else { |
| ASSERT(num_locals > 1); |
| __ movq(Address(RBP, (slot_base - i) * kWordSize), RAX); |
| } |
| } |
| } |
| |
| ASSERT(!block_order().is_empty()); |
| VisitBlocks(); |
| |
| __ int3(); |
| ASSERT(assembler()->constant_pool_allowed()); |
| GenerateDeferredCode(); |
| // Emit function patching code. This will be swapped with the first 13 bytes |
| // at entry point. |
| |
| if (is_optimizing() && Compiler::allow_recompilation()) { |
| // Leave enough space for patching in case of lazy deoptimization from |
| // deferred code. |
| __ nop(ShortCallPattern::pattern_length_in_bytes()); |
| lazy_deopt_pc_offset_ = assembler()->CodeSize(); |
| __ Jmp(*StubCode::DeoptimizeLazy_entry(), PP); |
| } |
| } |
| |
| |
| void FlowGraphCompiler::GenerateCall(intptr_t token_pos, |
| const StubEntry& stub_entry, |
| RawPcDescriptors::Kind kind, |
| LocationSummary* locs) { |
| __ Call(stub_entry); |
| AddCurrentDescriptor(kind, Thread::kNoDeoptId, token_pos); |
| RecordSafepoint(locs); |
| } |
| |
| |
| void FlowGraphCompiler::GenerateDartCall(intptr_t deopt_id, |
| intptr_t token_pos, |
| const StubEntry& stub_entry, |
| RawPcDescriptors::Kind kind, |
| LocationSummary* locs) { |
| __ CallPatchable(stub_entry); |
| AddCurrentDescriptor(kind, deopt_id, token_pos); |
| RecordSafepoint(locs); |
| // Marks either the continuation point in unoptimized code or the |
| // deoptimization point in optimized code, after call. |
| const intptr_t deopt_id_after = Thread::ToDeoptAfter(deopt_id); |
| if (is_optimizing()) { |
| AddDeoptIndexAtCall(deopt_id_after, token_pos); |
| } else { |
| // Add deoptimization continuation point after the call and before the |
| // arguments are removed. |
| AddCurrentDescriptor(RawPcDescriptors::kDeopt, deopt_id_after, token_pos); |
| } |
| } |
| |
| |
| void FlowGraphCompiler::GenerateRuntimeCall(intptr_t token_pos, |
| intptr_t deopt_id, |
| const RuntimeEntry& entry, |
| intptr_t argument_count, |
| LocationSummary* locs) { |
| __ CallRuntime(entry, argument_count); |
| AddCurrentDescriptor(RawPcDescriptors::kOther, deopt_id, token_pos); |
| RecordSafepoint(locs); |
| if (deopt_id != Thread::kNoDeoptId) { |
| // Marks either the continuation point in unoptimized code or the |
| // deoptimization point in optimized code, after call. |
| const intptr_t deopt_id_after = Thread::ToDeoptAfter(deopt_id); |
| if (is_optimizing()) { |
| AddDeoptIndexAtCall(deopt_id_after, token_pos); |
| } else { |
| // Add deoptimization continuation point after the call and before the |
| // arguments are removed. |
| AddCurrentDescriptor(RawPcDescriptors::kDeopt, deopt_id_after, token_pos); |
| } |
| } |
| } |
| |
| |
| void FlowGraphCompiler::EmitUnoptimizedStaticCall( |
| intptr_t argument_count, |
| intptr_t deopt_id, |
| intptr_t token_pos, |
| LocationSummary* locs, |
| const ICData& ic_data) { |
| const StubEntry* stub_entry = |
| StubCode::UnoptimizedStaticCallEntry(ic_data.NumArgsTested()); |
| __ LoadObject(RBX, ic_data); |
| GenerateDartCall(deopt_id, |
| token_pos, |
| *stub_entry, |
| RawPcDescriptors::kUnoptStaticCall, |
| locs); |
| __ Drop(argument_count, RCX); |
| } |
| |
| |
| 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(RAX, edge_counters_array_); |
| __ IncrementSmiField(FieldAddress(RAX, Array::element_offset(edge_id)), 1); |
| } |
| |
| |
| void FlowGraphCompiler::EmitOptimizedInstanceCall( |
| const StubEntry& stub_entry, |
| const ICData& ic_data, |
| intptr_t argument_count, |
| intptr_t deopt_id, |
| intptr_t token_pos, |
| LocationSummary* locs) { |
| 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(RDI, parsed_function().function()); |
| __ LoadUniqueObject(RBX, ic_data); |
| GenerateDartCall(deopt_id, |
| token_pos, |
| stub_entry, |
| RawPcDescriptors::kIcCall, |
| locs); |
| __ Drop(argument_count, RCX); |
| } |
| |
| |
| void FlowGraphCompiler::EmitInstanceCall(const StubEntry& stub_entry, |
| const ICData& ic_data, |
| intptr_t argument_count, |
| intptr_t deopt_id, |
| intptr_t token_pos, |
| LocationSummary* locs) { |
| ASSERT(Array::Handle(zone(), ic_data.arguments_descriptor()).Length() > 0); |
| __ LoadUniqueObject(RBX, ic_data); |
| GenerateDartCall(deopt_id, |
| token_pos, |
| stub_entry, |
| RawPcDescriptors::kIcCall, |
| locs); |
| __ Drop(argument_count, RCX); |
| } |
| |
| |
| void FlowGraphCompiler::EmitMegamorphicInstanceCall( |
| const ICData& ic_data, |
| intptr_t argument_count, |
| intptr_t deopt_id, |
| intptr_t token_pos, |
| LocationSummary* locs) { |
| const String& name = String::Handle(zone(), ic_data.target_name()); |
| const Array& arguments_descriptor = |
| Array::ZoneHandle(zone(), ic_data.arguments_descriptor()); |
| ASSERT(!arguments_descriptor.IsNull() && (arguments_descriptor.Length() > 0)); |
| const MegamorphicCache& cache = MegamorphicCache::ZoneHandle(zone(), |
| MegamorphicCacheTable::Lookup(isolate(), name, arguments_descriptor)); |
| const Register receiverR = RDI; |
| const Register cacheR = RBX; |
| const Register targetR = RCX; |
| __ movq(receiverR, Address(RSP, (argument_count - 1) * kWordSize)); |
| __ LoadObject(cacheR, cache); |
| |
| if (FLAG_use_megamorphic_stub) { |
| __ Call(*StubCode::MegamorphicLookup_entry()); |
| } else { |
| StubCode::EmitMegamorphicLookup(assembler(), receiverR, cacheR, targetR); |
| } |
| __ LoadObject(RBX, ic_data); |
| __ LoadObject(R10, arguments_descriptor); |
| __ call(targetR); |
| AddCurrentDescriptor(RawPcDescriptors::kOther, |
| Thread::kNoDeoptId, token_pos); |
| RecordSafepoint(locs); |
| const intptr_t deopt_id_after = Thread::ToDeoptAfter(deopt_id); |
| if (is_optimizing()) { |
| AddDeoptIndexAtCall(deopt_id_after, token_pos); |
| } else { |
| // Add deoptimization continuation point after the call and before the |
| // arguments are removed. |
| AddCurrentDescriptor(RawPcDescriptors::kDeopt, deopt_id_after, token_pos); |
| } |
| __ Drop(argument_count, RCX); |
| } |
| |
| |
| void FlowGraphCompiler::EmitOptimizedStaticCall( |
| const Function& function, |
| const Array& arguments_descriptor, |
| intptr_t argument_count, |
| intptr_t deopt_id, |
| intptr_t token_pos, |
| LocationSummary* locs) { |
| __ LoadObject(R10, arguments_descriptor); |
| // 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. |
| GenerateDartCall(deopt_id, |
| token_pos, |
| *StubCode::CallStaticFunction_entry(), |
| RawPcDescriptors::kOther, |
| locs); |
| AddStaticCallTarget(function); |
| __ Drop(argument_count, RCX); |
| } |
| |
| |
| Condition FlowGraphCompiler::EmitEqualityRegConstCompare( |
| Register reg, |
| const Object& obj, |
| bool needs_number_check, |
| intptr_t token_pos) { |
| ASSERT(!needs_number_check || |
| (!obj.IsMint() && !obj.IsDouble() && !obj.IsBigint())); |
| |
| if (obj.IsSmi() && (Smi::Cast(obj).Value() == 0)) { |
| ASSERT(!needs_number_check); |
| __ testq(reg, reg); |
| return EQUAL; |
| } |
| |
| if (needs_number_check) { |
| __ pushq(reg); |
| __ PushObject(obj); |
| if (is_optimizing()) { |
| __ CallPatchable(*StubCode::OptimizedIdenticalWithNumberCheck_entry()); |
| } else { |
| __ CallPatchable(*StubCode::UnoptimizedIdenticalWithNumberCheck_entry()); |
| } |
| if (token_pos != Scanner::kNoSourcePos) { |
| AddCurrentDescriptor(RawPcDescriptors::kRuntimeCall, |
| Thread::kNoDeoptId, |
| token_pos); |
| } |
| // Stub returns result in flags (result of a cmpq, we need ZF computed). |
| __ popq(reg); // Discard constant. |
| __ popq(reg); // Restore 'reg'. |
| } else { |
| __ CompareObject(reg, obj); |
| } |
| return EQUAL; |
| } |
| |
| |
| Condition FlowGraphCompiler::EmitEqualityRegRegCompare(Register left, |
| Register right, |
| bool needs_number_check, |
| intptr_t token_pos) { |
| if (needs_number_check) { |
| __ pushq(left); |
| __ pushq(right); |
| if (is_optimizing()) { |
| __ CallPatchable(*StubCode::OptimizedIdenticalWithNumberCheck_entry()); |
| } else { |
| __ CallPatchable(*StubCode::UnoptimizedIdenticalWithNumberCheck_entry()); |
| } |
| if (token_pos != Scanner::kNoSourcePos) { |
| AddCurrentDescriptor(RawPcDescriptors::kRuntimeCall, |
| Thread::kNoDeoptId, |
| token_pos); |
| } |
| // Stub returns result in flags (result of a cmpq, we need ZF computed). |
| __ popq(right); |
| __ popq(left); |
| } else { |
| __ cmpl(left, right); |
| } |
| return EQUAL; |
| } |
| |
| |
| // 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): avoid saving non-volatile registers. |
| __ PushRegisters(locs->live_registers()->cpu_registers(), |
| locs->live_registers()->fpu_registers()); |
| } |
| |
| |
| void FlowGraphCompiler::RestoreLiveRegisters(LocationSummary* locs) { |
| __ PopRegisters(locs->live_registers()->cpu_registers(), |
| locs->live_registers()->fpu_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())) { |
| __ movq(tmp.reg(), Immediate(0xf7)); |
| } |
| } |
| } |
| #endif |
| |
| |
| void FlowGraphCompiler::EmitTestAndCall(const ICData& ic_data, |
| intptr_t argument_count, |
| const Array& argument_names, |
| Label* failed, |
| Label* match_found, |
| intptr_t deopt_id, |
| intptr_t token_index, |
| LocationSummary* locs) { |
| ASSERT(is_optimizing()); |
| |
| __ Comment("EmitTestAndCall"); |
| const Array& arguments_descriptor = |
| Array::ZoneHandle(zone(), ArgumentsDescriptor::New(argument_count, |
| argument_names)); |
| // Load receiver into RAX. |
| __ movq(RAX, |
| Address(RSP, (argument_count - 1) * kWordSize)); |
| __ LoadObject(R10, arguments_descriptor); |
| |
| const bool kFirstCheckIsSmi = ic_data.GetReceiverClassIdAt(0) == kSmiCid; |
| const intptr_t kNumChecks = ic_data.NumberOfChecks(); |
| |
| ASSERT(!ic_data.IsNull() && (kNumChecks > 0)); |
| |
| Label after_smi_test; |
| __ testq(RAX, Immediate(kSmiTagMask)); |
| if (kFirstCheckIsSmi) { |
| // Jump if receiver is not Smi. |
| if (kNumChecks == 1) { |
| __ j(NOT_ZERO, failed); |
| } else { |
| __ j(NOT_ZERO, &after_smi_test); |
| } |
| // 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. |
| GenerateDartCall(deopt_id, |
| token_index, |
| *StubCode::CallStaticFunction_entry(), |
| RawPcDescriptors::kOther, |
| locs); |
| const Function& function = Function::ZoneHandle( |
| zone(), ic_data.GetTargetAt(0)); |
| AddStaticCallTarget(function); |
| __ Drop(argument_count, RCX); |
| if (kNumChecks > 1) { |
| __ jmp(match_found); |
| } |
| } else { |
| // Receiver is Smi, but Smi is not a valid class therefore fail. |
| // (Smi class must be first in the list). |
| __ j(ZERO, failed); |
| } |
| __ Bind(&after_smi_test); |
| |
| ASSERT(!ic_data.IsNull() && (kNumChecks > 0)); |
| GrowableArray<CidTarget> sorted(kNumChecks); |
| SortICDataByCount(ic_data, &sorted, /* drop_smi = */ true); |
| |
| const intptr_t kSortedLen = sorted.length(); |
| // If kSortedLen is 0 then only a Smi check was needed; the Smi check above |
| // will fail if there was only one check and receiver is not Smi. |
| if (kSortedLen == 0) return; |
| |
| // Value is not Smi, |
| __ LoadClassId(RDI, RAX); |
| for (intptr_t i = 0; i < kSortedLen; i++) { |
| const bool kIsLastCheck = (i == (kSortedLen - 1)); |
| ASSERT(sorted[i].cid != kSmiCid); |
| Label next_test; |
| __ cmpl(RDI, Immediate(sorted[i].cid)); |
| if (kIsLastCheck) { |
| __ j(NOT_EQUAL, failed); |
| } else { |
| __ j(NOT_EQUAL, &next_test); |
| } |
| // 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. |
| GenerateDartCall(deopt_id, |
| token_index, |
| *StubCode::CallStaticFunction_entry(), |
| RawPcDescriptors::kOther, |
| locs); |
| const Function& function = *sorted[i].target; |
| AddStaticCallTarget(function); |
| __ Drop(argument_count, RCX); |
| if (!kIsLastCheck) { |
| __ jmp(match_found); |
| } |
| __ Bind(&next_test); |
| } |
| } |
| |
| |
| #undef __ |
| #define __ compiler_->assembler()-> |
| |
| |
| void ParallelMoveResolver::EmitMove(int index) { |
| MoveOperands* move = moves_[index]; |
| const Location source = move->src(); |
| const Location destination = move->dest(); |
| |
| if (source.IsRegister()) { |
| if (destination.IsRegister()) { |
| __ movq(destination.reg(), source.reg()); |
| } else { |
| ASSERT(destination.IsStackSlot()); |
| __ movq(destination.ToStackSlotAddress(), source.reg()); |
| } |
| } else if (source.IsStackSlot()) { |
| if (destination.IsRegister()) { |
| __ movq(destination.reg(), source.ToStackSlotAddress()); |
| } else { |
| ASSERT(destination.IsStackSlot()); |
| MoveMemoryToMemory(destination.ToStackSlotAddress(), |
| source.ToStackSlotAddress()); |
| } |
| } else if (source.IsFpuRegister()) { |
| if (destination.IsFpuRegister()) { |
| // Optimization manual recommends using MOVAPS for register |
| // to register moves. |
| __ movaps(destination.fpu_reg(), source.fpu_reg()); |
| } else { |
| if (destination.IsDoubleStackSlot()) { |
| __ movsd(destination.ToStackSlotAddress(), source.fpu_reg()); |
| } else { |
| ASSERT(destination.IsQuadStackSlot()); |
| __ movups(destination.ToStackSlotAddress(), source.fpu_reg()); |
| } |
| } |
| } else if (source.IsDoubleStackSlot()) { |
| if (destination.IsFpuRegister()) { |
| __ movsd(destination.fpu_reg(), source.ToStackSlotAddress()); |
| } else { |
| ASSERT(destination.IsDoubleStackSlot()); |
| __ movsd(XMM0, source.ToStackSlotAddress()); |
| __ movsd(destination.ToStackSlotAddress(), XMM0); |
| } |
| } else if (source.IsQuadStackSlot()) { |
| if (destination.IsFpuRegister()) { |
| __ movups(destination.fpu_reg(), source.ToStackSlotAddress()); |
| } else { |
| ASSERT(destination.IsQuadStackSlot()); |
| __ movups(XMM0, source.ToStackSlotAddress()); |
| __ movups(destination.ToStackSlotAddress(), XMM0); |
| } |
| } else { |
| ASSERT(source.IsConstant()); |
| const Object& constant = source.constant(); |
| if (destination.IsRegister()) { |
| if (constant.IsSmi() && (Smi::Cast(constant).Value() == 0)) { |
| __ xorq(destination.reg(), destination.reg()); |
| } else if (constant.IsSmi() && |
| (source.constant_instruction()->representation() == kUnboxedInt32)) { |
| __ movl(destination.reg(), Immediate(Smi::Cast(constant).Value())); |
| } else { |
| __ LoadObject(destination.reg(), constant); |
| } |
| } else if (destination.IsFpuRegister()) { |
| if (Utils::DoublesBitEqual(Double::Cast(constant).value(), 0.0)) { |
| __ xorps(destination.fpu_reg(), destination.fpu_reg()); |
| } else { |
| __ LoadObject(TMP, constant); |
| __ movsd(destination.fpu_reg(), |
| FieldAddress(TMP, Double::value_offset())); |
| } |
| } else if (destination.IsDoubleStackSlot()) { |
| if (Utils::DoublesBitEqual(Double::Cast(constant).value(), 0.0)) { |
| __ xorps(XMM0, XMM0); |
| } else { |
| __ LoadObject(TMP, constant); |
| __ movsd(XMM0, FieldAddress(TMP, Double::value_offset())); |
| } |
| __ movsd(destination.ToStackSlotAddress(), XMM0); |
| } else { |
| ASSERT(destination.IsStackSlot()); |
| if (constant.IsSmi() && |
| (source.constant_instruction()->representation() == kUnboxedInt32)) { |
| __ movl(destination.ToStackSlotAddress(), |
| Immediate(Smi::Cast(constant).Value())); |
| } else { |
| StoreObject(destination.ToStackSlotAddress(), constant); |
| } |
| } |
| } |
| |
| move->Eliminate(); |
| } |
| |
| |
| void ParallelMoveResolver::EmitSwap(int index) { |
| MoveOperands* move = moves_[index]; |
| const Location source = move->src(); |
| const Location destination = move->dest(); |
| |
| if (source.IsRegister() && destination.IsRegister()) { |
| __ xchgq(destination.reg(), source.reg()); |
| } else if (source.IsRegister() && destination.IsStackSlot()) { |
| Exchange(source.reg(), destination.ToStackSlotAddress()); |
| } else if (source.IsStackSlot() && destination.IsRegister()) { |
| Exchange(destination.reg(), source.ToStackSlotAddress()); |
| } else if (source.IsStackSlot() && destination.IsStackSlot()) { |
| Exchange(destination.ToStackSlotAddress(), source.ToStackSlotAddress()); |
| } else if (source.IsFpuRegister() && destination.IsFpuRegister()) { |
| __ movaps(XMM0, source.fpu_reg()); |
| __ movaps(source.fpu_reg(), destination.fpu_reg()); |
| __ movaps(destination.fpu_reg(), XMM0); |
| } else if (source.IsFpuRegister() || destination.IsFpuRegister()) { |
| ASSERT(destination.IsDoubleStackSlot() || |
| destination.IsQuadStackSlot() || |
| source.IsDoubleStackSlot() || |
| source.IsQuadStackSlot()); |
| bool double_width = destination.IsDoubleStackSlot() || |
| source.IsDoubleStackSlot(); |
| XmmRegister reg = source.IsFpuRegister() ? source.fpu_reg() |
| : destination.fpu_reg(); |
| Address slot_address = source.IsFpuRegister() |
| ? destination.ToStackSlotAddress() |
| : source.ToStackSlotAddress(); |
| |
| if (double_width) { |
| __ movsd(XMM0, slot_address); |
| __ movsd(slot_address, reg); |
| } else { |
| __ movups(XMM0, slot_address); |
| __ movups(slot_address, reg); |
| } |
| __ movaps(reg, XMM0); |
| } else if (source.IsDoubleStackSlot() && destination.IsDoubleStackSlot()) { |
| const Address& source_slot_address = source.ToStackSlotAddress(); |
| const Address& destination_slot_address = destination.ToStackSlotAddress(); |
| |
| ScratchFpuRegisterScope ensure_scratch(this, XMM0); |
| __ movsd(XMM0, source_slot_address); |
| __ movsd(ensure_scratch.reg(), destination_slot_address); |
| __ movsd(destination_slot_address, XMM0); |
| __ movsd(source_slot_address, ensure_scratch.reg()); |
| } else if (source.IsQuadStackSlot() && destination.IsQuadStackSlot()) { |
| const Address& source_slot_address = source.ToStackSlotAddress(); |
| const Address& destination_slot_address = destination.ToStackSlotAddress(); |
| |
| ScratchFpuRegisterScope ensure_scratch(this, XMM0); |
| __ movups(XMM0, source_slot_address); |
| __ movups(ensure_scratch.reg(), destination_slot_address); |
| __ movups(destination_slot_address, XMM0); |
| __ movups(source_slot_address, ensure_scratch.reg()); |
| } 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 Address& dst, |
| const Address& src) { |
| __ MoveMemoryToMemory(dst, src); |
| } |
| |
| |
| void ParallelMoveResolver::StoreObject(const Address& dst, const Object& obj) { |
| __ StoreObject(dst, obj); |
| } |
| |
| |
| void ParallelMoveResolver::Exchange(Register reg, const Address& mem) { |
| __ Exchange(reg, mem); |
| } |
| |
| |
| void ParallelMoveResolver::Exchange(const Address& mem1, const Address& mem2) { |
| __ Exchange(mem1, mem2); |
| } |
| |
| |
| void ParallelMoveResolver::Exchange(Register reg, |
| Register base_reg, |
| intptr_t stack_offset) { |
| UNREACHABLE(); |
| } |
| |
| |
| void ParallelMoveResolver::Exchange(Register base_reg1, |
| intptr_t stack_offset1, |
| Register base_reg2, |
| intptr_t stack_offset2) { |
| UNREACHABLE(); |
| } |
| |
| |
| void ParallelMoveResolver::SpillScratch(Register reg) { |
| __ pushq(reg); |
| } |
| |
| |
| void ParallelMoveResolver::RestoreScratch(Register reg) { |
| __ popq(reg); |
| } |
| |
| |
| void ParallelMoveResolver::SpillFpuScratch(FpuRegister reg) { |
| __ AddImmediate(RSP, Immediate(-kFpuRegisterSize)); |
| __ movups(Address(RSP, 0), reg); |
| } |
| |
| |
| void ParallelMoveResolver::RestoreFpuScratch(FpuRegister reg) { |
| __ movups(reg, Address(RSP, 0)); |
| __ AddImmediate(RSP, Immediate(kFpuRegisterSize)); |
| } |
| |
| |
| #undef __ |
| |
| } // namespace dart |
| |
| #endif // defined TARGET_ARCH_X64 |