src/third_party/v8/src/builtins/builtins-lazy-gen.cc - cobalt - Git at Google

 // Copyright 2018 the V8 project authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "src/builtins/builtins-lazy-gen.h"

 #include "src/builtins/builtins-utils-gen.h"
 #include "src/builtins/builtins.h"
 #include "src/common/globals.h"
 #include "src/objects/feedback-vector.h"
 #include "src/objects/shared-function-info.h"

 namespace v8 {
 namespace internal {

 void LazyBuiltinsAssembler::GenerateTailCallToJSCode(
     TNode<Code> code, TNode<JSFunction> function) {
   auto argc = UncheckedParameter<Int32T>(Descriptor::kActualArgumentsCount);
   auto context = Parameter<Context>(Descriptor::kContext);
   auto new_target = Parameter<Object>(Descriptor::kNewTarget);

   TailCallJSCode(code, context, function, new_target, argc);
 }

 void LazyBuiltinsAssembler::GenerateTailCallToReturnedCode(
     Runtime::FunctionId function_id, TNode<JSFunction> function) {
   auto context = Parameter<Context>(Descriptor::kContext);
   TNode<Code> code = CAST(CallRuntime(function_id, context, function));
   GenerateTailCallToJSCode(code, function);
 }

 void LazyBuiltinsAssembler::TailCallRuntimeIfMarkerEquals(
     TNode<Uint32T> marker, OptimizationMarker expected_marker,
     Runtime::FunctionId function_id, TNode<JSFunction> function) {
   Label no_match(this);
   GotoIfNot(Word32Equal(marker, Uint32Constant(expected_marker)), &no_match);
   GenerateTailCallToReturnedCode(function_id, function);
   BIND(&no_match);
 }

 void LazyBuiltinsAssembler::MaybeTailCallOptimizedCodeSlot(
     TNode<JSFunction> function, TNode<FeedbackVector> feedback_vector) {
   Label fallthrough(this), may_have_optimized_code(this);

   TNode<Uint32T> optimization_state =
       LoadObjectField<Uint32T>(feedback_vector, FeedbackVector::kFlagsOffset);

   // Fall through if no optimization trigger or optimized code.
   GotoIfNot(IsSetWord32(
                 optimization_state,
                 FeedbackVector::kHasOptimizedCodeOrCompileOptimizedMarkerMask),
             &fallthrough);

   GotoIfNot(IsSetWord32(
                 optimization_state,
                 FeedbackVector::kHasCompileOptimizedOrLogFirstExecutionMarker),
             &may_have_optimized_code);

   // TODO(ishell): introduce Runtime::kHandleOptimizationMarker and check
   // all these marker values there.
   TNode<Uint32T> marker =
       DecodeWord32<FeedbackVector::OptimizationMarkerBits>(optimization_state);
   TailCallRuntimeIfMarkerEquals(marker, OptimizationMarker::kLogFirstExecution,
                                 Runtime::kFunctionFirstExecution, function);
   TailCallRuntimeIfMarkerEquals(marker, OptimizationMarker::kCompileOptimized,
                                 Runtime::kCompileOptimized_NotConcurrent,
                                 function);
   TailCallRuntimeIfMarkerEquals(
       marker, OptimizationMarker::kCompileOptimizedConcurrent,
       Runtime::kCompileOptimized_Concurrent, function);

   Unreachable();
   BIND(&may_have_optimized_code);
   {
     Label heal_optimized_code_slot(this);
     TNode<MaybeObject> maybe_optimized_code_entry = LoadMaybeWeakObjectField(
         feedback_vector, FeedbackVector::kMaybeOptimizedCodeOffset);
     // Optimized code slot is a weak reference.
     TNode<Code> optimized_code = CAST(GetHeapObjectAssumeWeak(
         maybe_optimized_code_entry, &heal_optimized_code_slot));

     // Check if the optimized code is marked for deopt. If it is, call the
     // runtime to clear it.
     TNode<CodeDataContainer> code_data_container =
         CAST(LoadObjectField(optimized_code, Code::kCodeDataContainerOffset));

     TNode<Int32T> code_kind_specific_flags = LoadObjectField<Int32T>(
         code_data_container, CodeDataContainer::kKindSpecificFlagsOffset);
     GotoIf(IsSetWord32<Code::MarkedForDeoptimizationField>(
                code_kind_specific_flags),
            &heal_optimized_code_slot);

     // Optimized code is good, get it into the closure and link the closure into
     // the optimized functions list, then tail call the optimized code.
     StoreObjectField(function, JSFunction::kCodeOffset, optimized_code);
     GenerateTailCallToJSCode(optimized_code, function);

     // Optimized code slot contains deoptimized code or code is cleared and
     // optimized code marker isn't updated. Evict the code, update the marker
     // and re-enter the closure's code.
     BIND(&heal_optimized_code_slot);
     GenerateTailCallToReturnedCode(Runtime::kHealOptimizedCodeSlot, function);
   }

   // Fall-through if the optimized code cell is clear and there is no
   // optimization marker.
   BIND(&fallthrough);
 }

 void LazyBuiltinsAssembler::CompileLazy(TNode<JSFunction> function) {
   // First lookup code, maybe we don't need to compile!
   Label compile_function(this, Label::kDeferred);

   // Check the code object for the SFI. If SFI's code entry points to
   // CompileLazy, then we need to lazy compile regardless of the function or
   // feedback vector marker.
   TNode<SharedFunctionInfo> shared =
       CAST(LoadObjectField(function, JSFunction::kSharedFunctionInfoOffset));
   TNode<Code> sfi_code = GetSharedFunctionInfoCode(shared, &compile_function);

   TNode<HeapObject> feedback_cell_value = LoadFeedbackCellValue(function);

   // If feedback cell isn't initialized, compile function
   GotoIf(IsUndefined(feedback_cell_value), &compile_function);

   Label use_sfi_code(this);
   // If there is no feedback, don't check for optimized code.
   GotoIf(HasInstanceType(feedback_cell_value, CLOSURE_FEEDBACK_CELL_ARRAY_TYPE),
          &use_sfi_code);

   // If it isn't undefined or fixed array it must be a feedback vector.
   CSA_ASSERT(this, IsFeedbackVector(feedback_cell_value));

   // Is there an optimization marker or optimized code in the feedback vector?
   MaybeTailCallOptimizedCodeSlot(function, CAST(feedback_cell_value));
   Goto(&use_sfi_code);

   BIND(&use_sfi_code);
   // If not, install the SFI's code entry and jump to that.
   CSA_ASSERT(this, TaggedNotEqual(sfi_code, HeapConstant(BUILTIN_CODE(
                                                 isolate(), CompileLazy))));
   StoreObjectField(function, JSFunction::kCodeOffset, sfi_code);
   GenerateTailCallToJSCode(sfi_code, function);

   BIND(&compile_function);
   GenerateTailCallToReturnedCode(Runtime::kCompileLazy, function);
 }

 TF_BUILTIN(CompileLazy, LazyBuiltinsAssembler) {
   auto function = Parameter<JSFunction>(Descriptor::kTarget);

   CompileLazy(function);
 }

 TF_BUILTIN(CompileLazyDeoptimizedCode, LazyBuiltinsAssembler) {
   auto function = Parameter<JSFunction>(Descriptor::kTarget);

   // Set the code slot inside the JSFunction to CompileLazy.
   TNode<Code> code = HeapConstant(BUILTIN_CODE(isolate(), CompileLazy));
   StoreObjectField(function, JSFunction::kCodeOffset, code);
   GenerateTailCallToJSCode(code, function);
 }

 }  // namespace internal
 }  // namespace v8
	// Copyright 2018 the V8 project authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "src/builtins/builtins-lazy-gen.h"

	#include "src/builtins/builtins-utils-gen.h"
	#include "src/builtins/builtins.h"
	#include "src/common/globals.h"
	#include "src/objects/feedback-vector.h"
	#include "src/objects/shared-function-info.h"

	namespace v8 {
	namespace internal {

	void LazyBuiltinsAssembler::GenerateTailCallToJSCode(
	TNode<Code> code, TNode<JSFunction> function) {
	auto argc = UncheckedParameter<Int32T>(Descriptor::kActualArgumentsCount);
	auto context = Parameter<Context>(Descriptor::kContext);
	auto new_target = Parameter<Object>(Descriptor::kNewTarget);

	TailCallJSCode(code, context, function, new_target, argc);
	}

	void LazyBuiltinsAssembler::GenerateTailCallToReturnedCode(
	Runtime::FunctionId function_id, TNode<JSFunction> function) {
	auto context = Parameter<Context>(Descriptor::kContext);
	TNode<Code> code = CAST(CallRuntime(function_id, context, function));
	GenerateTailCallToJSCode(code, function);
	}

	void LazyBuiltinsAssembler::TailCallRuntimeIfMarkerEquals(
	TNode<Uint32T> marker, OptimizationMarker expected_marker,
	Runtime::FunctionId function_id, TNode<JSFunction> function) {
	Label no_match(this);
	GotoIfNot(Word32Equal(marker, Uint32Constant(expected_marker)), &no_match);
	GenerateTailCallToReturnedCode(function_id, function);
	BIND(&no_match);
	}

	void LazyBuiltinsAssembler::MaybeTailCallOptimizedCodeSlot(
	TNode<JSFunction> function, TNode<FeedbackVector> feedback_vector) {
	Label fallthrough(this), may_have_optimized_code(this);

	TNode<Uint32T> optimization_state =
	LoadObjectField<Uint32T>(feedback_vector, FeedbackVector::kFlagsOffset);

	// Fall through if no optimization trigger or optimized code.
	GotoIfNot(IsSetWord32(
	optimization_state,
	FeedbackVector::kHasOptimizedCodeOrCompileOptimizedMarkerMask),
	&fallthrough);

	GotoIfNot(IsSetWord32(
	optimization_state,
	FeedbackVector::kHasCompileOptimizedOrLogFirstExecutionMarker),
	&may_have_optimized_code);

	// TODO(ishell): introduce Runtime::kHandleOptimizationMarker and check
	// all these marker values there.
	TNode<Uint32T> marker =
	DecodeWord32<FeedbackVector::OptimizationMarkerBits>(optimization_state);
	TailCallRuntimeIfMarkerEquals(marker, OptimizationMarker::kLogFirstExecution,
	Runtime::kFunctionFirstExecution, function);
	TailCallRuntimeIfMarkerEquals(marker, OptimizationMarker::kCompileOptimized,
	Runtime::kCompileOptimized_NotConcurrent,
	function);
	TailCallRuntimeIfMarkerEquals(
	marker, OptimizationMarker::kCompileOptimizedConcurrent,
	Runtime::kCompileOptimized_Concurrent, function);

	Unreachable();
	BIND(&may_have_optimized_code);
	{
	Label heal_optimized_code_slot(this);
	TNode<MaybeObject> maybe_optimized_code_entry = LoadMaybeWeakObjectField(
	feedback_vector, FeedbackVector::kMaybeOptimizedCodeOffset);
	// Optimized code slot is a weak reference.
	TNode<Code> optimized_code = CAST(GetHeapObjectAssumeWeak(
	maybe_optimized_code_entry, &heal_optimized_code_slot));

	// Check if the optimized code is marked for deopt. If it is, call the
	// runtime to clear it.
	TNode<CodeDataContainer> code_data_container =
	CAST(LoadObjectField(optimized_code, Code::kCodeDataContainerOffset));

	TNode<Int32T> code_kind_specific_flags = LoadObjectField<Int32T>(
	code_data_container, CodeDataContainer::kKindSpecificFlagsOffset);
	GotoIf(IsSetWord32<Code::MarkedForDeoptimizationField>(
	code_kind_specific_flags),
	&heal_optimized_code_slot);

	// Optimized code is good, get it into the closure and link the closure into
	// the optimized functions list, then tail call the optimized code.
	StoreObjectField(function, JSFunction::kCodeOffset, optimized_code);
	GenerateTailCallToJSCode(optimized_code, function);

	// Optimized code slot contains deoptimized code or code is cleared and
	// optimized code marker isn't updated. Evict the code, update the marker
	// and re-enter the closure's code.
	BIND(&heal_optimized_code_slot);
	GenerateTailCallToReturnedCode(Runtime::kHealOptimizedCodeSlot, function);
	}

	// Fall-through if the optimized code cell is clear and there is no
	// optimization marker.
	BIND(&fallthrough);
	}

	void LazyBuiltinsAssembler::CompileLazy(TNode<JSFunction> function) {
	// First lookup code, maybe we don't need to compile!
	Label compile_function(this, Label::kDeferred);

	// Check the code object for the SFI. If SFI's code entry points to
	// CompileLazy, then we need to lazy compile regardless of the function or
	// feedback vector marker.
	TNode<SharedFunctionInfo> shared =
	CAST(LoadObjectField(function, JSFunction::kSharedFunctionInfoOffset));
	TNode<Code> sfi_code = GetSharedFunctionInfoCode(shared, &compile_function);

	TNode<HeapObject> feedback_cell_value = LoadFeedbackCellValue(function);

	// If feedback cell isn't initialized, compile function
	GotoIf(IsUndefined(feedback_cell_value), &compile_function);

	Label use_sfi_code(this);
	// If there is no feedback, don't check for optimized code.
	GotoIf(HasInstanceType(feedback_cell_value, CLOSURE_FEEDBACK_CELL_ARRAY_TYPE),
	&use_sfi_code);

	// If it isn't undefined or fixed array it must be a feedback vector.
	CSA_ASSERT(this, IsFeedbackVector(feedback_cell_value));

	// Is there an optimization marker or optimized code in the feedback vector?
	MaybeTailCallOptimizedCodeSlot(function, CAST(feedback_cell_value));
	Goto(&use_sfi_code);

	BIND(&use_sfi_code);
	// If not, install the SFI's code entry and jump to that.
	CSA_ASSERT(this, TaggedNotEqual(sfi_code, HeapConstant(BUILTIN_CODE(
	isolate(), CompileLazy))));
	StoreObjectField(function, JSFunction::kCodeOffset, sfi_code);
	GenerateTailCallToJSCode(sfi_code, function);

	BIND(&compile_function);
	GenerateTailCallToReturnedCode(Runtime::kCompileLazy, function);
	}

	TF_BUILTIN(CompileLazy, LazyBuiltinsAssembler) {
	auto function = Parameter<JSFunction>(Descriptor::kTarget);

	CompileLazy(function);
	}

	TF_BUILTIN(CompileLazyDeoptimizedCode, LazyBuiltinsAssembler) {
	auto function = Parameter<JSFunction>(Descriptor::kTarget);

	// Set the code slot inside the JSFunction to CompileLazy.
	TNode<Code> code = HeapConstant(BUILTIN_CODE(isolate(), CompileLazy));
	StoreObjectField(function, JSFunction::kCodeOffset, code);
	GenerateTailCallToJSCode(code, function);
	}

	} // namespace internal
	} // namespace v8