// Copyright 2015 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/interpreter/interpreter-intrinsics.h"
#include "src/code-factory.h"
namespace v8 {
namespace internal {
namespace interpreter {
using compiler::Node;
#define __ assembler_->
IntrinsicsHelper::IntrinsicsHelper(InterpreterAssembler* assembler)
: isolate_(assembler->isolate()),
zone_(assembler->zone()),
assembler_(assembler) {}
// static
bool IntrinsicsHelper::IsSupported(Runtime::FunctionId function_id) {
switch (function_id) {
#define SUPPORTED(name, lower_case, count) case Runtime::kInline##name:
INTRINSICS_LIST(SUPPORTED)
return true;
#undef SUPPORTED
default:
return false;
}
}
// static
IntrinsicsHelper::IntrinsicId IntrinsicsHelper::FromRuntimeId(
Runtime::FunctionId function_id) {
switch (function_id) {
#define TO_RUNTIME_ID(name, lower_case, count) \
case Runtime::kInline##name: \
return IntrinsicId::k##name;
INTRINSICS_LIST(TO_RUNTIME_ID)
#undef TO_RUNTIME_ID
default:
UNREACHABLE();
return static_cast<IntrinsicsHelper::IntrinsicId>(-1);
}
}
// static
Runtime::FunctionId IntrinsicsHelper::ToRuntimeId(
IntrinsicsHelper::IntrinsicId intrinsic_id) {
switch (intrinsic_id) {
#define TO_INTRINSIC_ID(name, lower_case, count) \
case IntrinsicId::k##name: \
return Runtime::kInline##name;
INTRINSICS_LIST(TO_INTRINSIC_ID)
#undef TO_INTRINSIC_ID
default:
UNREACHABLE();
return static_cast<Runtime::FunctionId>(-1);
}
}
Node* IntrinsicsHelper::InvokeIntrinsic(Node* function_id, Node* context,
Node* first_arg_reg, Node* arg_count) {
InterpreterAssembler::Label abort(assembler_), end(assembler_);
InterpreterAssembler::Variable result(assembler_,
MachineRepresentation::kTagged);
#define MAKE_LABEL(name, lower_case, count) \
InterpreterAssembler::Label lower_case(assembler_);
INTRINSICS_LIST(MAKE_LABEL)
#undef MAKE_LABEL
#define LABEL_POINTER(name, lower_case, count) &lower_case,
InterpreterAssembler::Label* labels[] = {INTRINSICS_LIST(LABEL_POINTER)};
#undef LABEL_POINTER
#define CASE(name, lower_case, count) \
static_cast<int32_t>(IntrinsicId::k##name),
int32_t cases[] = {INTRINSICS_LIST(CASE)};
#undef CASE
__ Switch(function_id, &abort, cases, labels, arraysize(cases));
#define HANDLE_CASE(name, lower_case, expected_arg_count) \
__ Bind(&lower_case); \
if (FLAG_debug_code && expected_arg_count >= 0) { \
AbortIfArgCountMismatch(expected_arg_count, arg_count); \
} \
result.Bind(name(first_arg_reg, arg_count, context)); \
__ Goto(&end);
INTRINSICS_LIST(HANDLE_CASE)
#undef HANDLE_CASE
__ Bind(&abort);
{
__ Abort(BailoutReason::kUnexpectedFunctionIDForInvokeIntrinsic);
result.Bind(__ UndefinedConstant());
__ Goto(&end);
}
__ Bind(&end);
return result.value();
}
Node* IntrinsicsHelper::CompareInstanceType(Node* object, int type,
InstanceTypeCompareMode mode) {
InterpreterAssembler::Variable return_value(assembler_,
MachineRepresentation::kTagged);
Node* instance_type = __ LoadInstanceType(object);
InterpreterAssembler::Label if_true(assembler_), if_false(assembler_),
end(assembler_);
if (mode == kInstanceTypeEqual) {
return __ Word32Equal(instance_type, __ Int32Constant(type));
} else {
DCHECK(mode == kInstanceTypeGreaterThanOrEqual);
return __ Int32GreaterThanOrEqual(instance_type, __ Int32Constant(type));
}
}
Node* IntrinsicsHelper::IsInstanceType(Node* input, int type) {
InterpreterAssembler::Variable return_value(assembler_,
MachineRepresentation::kTagged);
InterpreterAssembler::Label if_not_smi(assembler_), return_true(assembler_),
return_false(assembler_), end(assembler_);
Node* arg = __ LoadRegister(input);
__ GotoIf(__ TaggedIsSmi(arg), &return_false);
Node* condition = CompareInstanceType(arg, type, kInstanceTypeEqual);
__ Branch(condition, &return_true, &return_false);
__ Bind(&return_true);
{
return_value.Bind(__ BooleanConstant(true));
__ Goto(&end);
}
__ Bind(&return_false);
{
return_value.Bind(__ BooleanConstant(false));
__ Goto(&end);
}
__ Bind(&end);
return return_value.value();
}
Node* IntrinsicsHelper::IsJSReceiver(Node* input, Node* arg_count,
Node* context) {
InterpreterAssembler::Variable return_value(assembler_,
MachineRepresentation::kTagged);
InterpreterAssembler::Label return_true(assembler_), return_false(assembler_),
end(assembler_);
Node* arg = __ LoadRegister(input);
__ GotoIf(__ TaggedIsSmi(arg), &return_false);
STATIC_ASSERT(LAST_TYPE == LAST_JS_RECEIVER_TYPE);
Node* condition = CompareInstanceType(arg, FIRST_JS_RECEIVER_TYPE,
kInstanceTypeGreaterThanOrEqual);
__ Branch(condition, &return_true, &return_false);
__ Bind(&return_true);
{
return_value.Bind(__ BooleanConstant(true));
__ Goto(&end);
}
__ Bind(&return_false);
{
return_value.Bind(__ BooleanConstant(false));
__ Goto(&end);
}
__ Bind(&end);
return return_value.value();
}
Node* IntrinsicsHelper::IsArray(Node* input, Node* arg_count, Node* context) {
return IsInstanceType(input, JS_ARRAY_TYPE);
}
Node* IntrinsicsHelper::IsJSProxy(Node* input, Node* arg_count, Node* context) {
return IsInstanceType(input, JS_PROXY_TYPE);
}
Node* IntrinsicsHelper::IsRegExp(Node* input, Node* arg_count, Node* context) {
return IsInstanceType(input, JS_REGEXP_TYPE);
}
Node* IntrinsicsHelper::IsTypedArray(Node* input, Node* arg_count,
Node* context) {
return IsInstanceType(input, JS_TYPED_ARRAY_TYPE);
}
Node* IntrinsicsHelper::IsSmi(Node* input, Node* arg_count, Node* context) {
InterpreterAssembler::Variable return_value(assembler_,
MachineRepresentation::kTagged);
InterpreterAssembler::Label if_smi(assembler_), if_not_smi(assembler_),
end(assembler_);
Node* arg = __ LoadRegister(input);
__ Branch(__ TaggedIsSmi(arg), &if_smi, &if_not_smi);
__ Bind(&if_smi);
{
return_value.Bind(__ BooleanConstant(true));
__ Goto(&end);
}
__ Bind(&if_not_smi);
{
return_value.Bind(__ BooleanConstant(false));
__ Goto(&end);
}
__ Bind(&end);
return return_value.value();
}
Node* IntrinsicsHelper::IntrinsicAsStubCall(Node* args_reg, Node* context,
Callable const& callable) {
int param_count = callable.descriptor().GetParameterCount();
Node** args = zone()->NewArray<Node*>(param_count + 1); // 1 for context
for (int i = 0; i < param_count; i++) {
args[i] = __ LoadRegister(args_reg);
args_reg = __ NextRegister(args_reg);
}
args[param_count] = context;
return __ CallStubN(callable, args);
}
Node* IntrinsicsHelper::HasProperty(Node* input, Node* arg_count,
Node* context) {
return IntrinsicAsStubCall(input, context,
CodeFactory::HasProperty(isolate()));
}
Node* IntrinsicsHelper::NewObject(Node* input, Node* arg_count, Node* context) {
return IntrinsicAsStubCall(input, context,
CodeFactory::FastNewObject(isolate()));
}
Node* IntrinsicsHelper::NumberToString(Node* input, Node* arg_count,
Node* context) {
return IntrinsicAsStubCall(input, context,
CodeFactory::NumberToString(isolate()));
}
Node* IntrinsicsHelper::RegExpExec(Node* input, Node* arg_count,
Node* context) {
return IntrinsicAsStubCall(input, context,
CodeFactory::RegExpExec(isolate()));
}
Node* IntrinsicsHelper::SubString(Node* input, Node* arg_count, Node* context) {
return IntrinsicAsStubCall(input, context, CodeFactory::SubString(isolate()));
}
Node* IntrinsicsHelper::ToString(Node* input, Node* arg_count, Node* context) {
return IntrinsicAsStubCall(input, context, CodeFactory::ToString(isolate()));
}
Node* IntrinsicsHelper::ToLength(Node* input, Node* arg_count, Node* context) {
return IntrinsicAsStubCall(input, context, CodeFactory::ToLength(isolate()));
}
Node* IntrinsicsHelper::ToInteger(Node* input, Node* arg_count, Node* context) {
return IntrinsicAsStubCall(input, context, CodeFactory::ToInteger(isolate()));
}
Node* IntrinsicsHelper::ToNumber(Node* input, Node* arg_count, Node* context) {
return IntrinsicAsStubCall(input, context, CodeFactory::ToNumber(isolate()));
}
Node* IntrinsicsHelper::ToObject(Node* input, Node* arg_count, Node* context) {
return IntrinsicAsStubCall(input, context, CodeFactory::ToObject(isolate()));
}
Node* IntrinsicsHelper::Call(Node* args_reg, Node* arg_count, Node* context) {
// First argument register contains the function target.
Node* function = __ LoadRegister(args_reg);
// Receiver is the second runtime call argument.
Node* receiver_reg = __ NextRegister(args_reg);
Node* receiver_arg = __ RegisterLocation(receiver_reg);
// Subtract function and receiver from arg count.
Node* function_and_receiver_count = __ Int32Constant(2);
Node* target_args_count = __ Int32Sub(arg_count, function_and_receiver_count);
if (FLAG_debug_code) {
InterpreterAssembler::Label arg_count_positive(assembler_);
Node* comparison = __ Int32LessThan(target_args_count, __ Int32Constant(0));
__ GotoUnless(comparison, &arg_count_positive);
__ Abort(kWrongArgumentCountForInvokeIntrinsic);
__ Goto(&arg_count_positive);
__ Bind(&arg_count_positive);
}
Node* result = __ CallJS(function, context, receiver_arg, target_args_count,
TailCallMode::kDisallow);
return result;
}
Node* IntrinsicsHelper::ValueOf(Node* args_reg, Node* arg_count,
Node* context) {
InterpreterAssembler::Variable return_value(assembler_,
MachineRepresentation::kTagged);
InterpreterAssembler::Label done(assembler_);
Node* object = __ LoadRegister(args_reg);
return_value.Bind(object);
// If the object is a smi return the object.
__ GotoIf(__ TaggedIsSmi(object), &done);
// If the object is not a value type, return the object.
Node* condition =
CompareInstanceType(object, JS_VALUE_TYPE, kInstanceTypeEqual);
__ GotoUnless(condition, &done);
// If the object is a value type, return the value field.
return_value.Bind(__ LoadObjectField(object, JSValue::kValueOffset));
__ Goto(&done);
__ Bind(&done);
return return_value.value();
}
Node* IntrinsicsHelper::ClassOf(Node* args_reg, Node* arg_count,
Node* context) {
InterpreterAssembler::Variable return_value(assembler_,
MachineRepresentation::kTagged);
InterpreterAssembler::Label done(assembler_), null(assembler_),
function(assembler_), non_function_constructor(assembler_);
Node* object = __ LoadRegister(args_reg);
// If the object is not a JSReceiver, we return null.
__ GotoIf(__ TaggedIsSmi(object), &null);
STATIC_ASSERT(LAST_JS_RECEIVER_TYPE == LAST_TYPE);
Node* is_js_receiver = CompareInstanceType(object, FIRST_JS_RECEIVER_TYPE,
kInstanceTypeGreaterThanOrEqual);
__ GotoUnless(is_js_receiver, &null);
// Return 'Function' for JSFunction and JSBoundFunction objects.
Node* is_function = CompareInstanceType(object, FIRST_FUNCTION_TYPE,
kInstanceTypeGreaterThanOrEqual);
STATIC_ASSERT(LAST_FUNCTION_TYPE == LAST_TYPE);
__ GotoIf(is_function, &function);
// Check if the constructor in the map is a JS function.
Node* constructor = __ LoadMapConstructor(__ LoadMap(object));
Node* constructor_is_js_function =
CompareInstanceType(constructor, JS_FUNCTION_TYPE, kInstanceTypeEqual);
__ GotoUnless(constructor_is_js_function, &non_function_constructor);
// Grab the instance class name from the constructor function.
Node* shared =
__ LoadObjectField(constructor, JSFunction::kSharedFunctionInfoOffset);
return_value.Bind(
__ LoadObjectField(shared, SharedFunctionInfo::kInstanceClassNameOffset));
__ Goto(&done);
// Non-JS objects have class null.
__ Bind(&null);
{
return_value.Bind(__ LoadRoot(Heap::kNullValueRootIndex));
__ Goto(&done);
}
// Functions have class 'Function'.
__ Bind(&function);
{
return_value.Bind(__ LoadRoot(Heap::kFunction_stringRootIndex));
__ Goto(&done);
}
// Objects with a non-function constructor have class 'Object'.
__ Bind(&non_function_constructor);
{
return_value.Bind(__ LoadRoot(Heap::kObject_stringRootIndex));
__ Goto(&done);
}
__ Bind(&done);
return return_value.value();
}
void IntrinsicsHelper::AbortIfArgCountMismatch(int expected, Node* actual) {
InterpreterAssembler::Label match(assembler_);
Node* comparison = __ Word32Equal(actual, __ Int32Constant(expected));
__ GotoIf(comparison, &match);
__ Abort(kWrongArgumentCountForInvokeIntrinsic);
__ Goto(&match);
__ Bind(&match);
}
} // namespace interpreter
} // namespace internal
} // namespace v8