| Index: src/builtins/builtins-number.cc
|
| diff --git a/src/builtins/builtins-number.cc b/src/builtins/builtins-number.cc
|
| index 17628445d116930c04e439314e097d91f84c8d93..6b894d3e47e3269220f09a48619f1d6e99cc10ab 100644
|
| --- a/src/builtins/builtins-number.cc
|
| +++ b/src/builtins/builtins-number.cc
|
| @@ -2,8 +2,9 @@
|
| // Use of this source code is governed by a BSD-style license that can be
|
| // found in the LICENSE file.
|
|
|
| -#include "src/builtins/builtins.h"
|
| #include "src/builtins/builtins-utils.h"
|
| +#include "src/builtins/builtins.h"
|
| +#include "src/code-factory.h"
|
|
|
| namespace v8 {
|
| namespace internal {
|
| @@ -369,5 +370,1235 @@ void Builtins::Generate_NumberPrototypeValueOf(CodeStubAssembler* assembler) {
|
| assembler->Return(result);
|
| }
|
|
|
| +// static
|
| +void Builtins::Generate_Add(CodeStubAssembler* assembler) {
|
| + typedef CodeStubAssembler::Label Label;
|
| + typedef compiler::Node Node;
|
| + typedef CodeStubAssembler::Variable Variable;
|
| +
|
| + Node* left = assembler->Parameter(0);
|
| + Node* right = assembler->Parameter(1);
|
| + Node* context = assembler->Parameter(2);
|
| +
|
| + // Shared entry for floating point addition.
|
| + Label do_fadd(assembler);
|
| + Variable var_fadd_lhs(assembler, MachineRepresentation::kFloat64),
|
| + var_fadd_rhs(assembler, MachineRepresentation::kFloat64);
|
| +
|
| + // We might need to loop several times due to ToPrimitive, ToString and/or
|
| + // ToNumber conversions.
|
| + Variable var_lhs(assembler, MachineRepresentation::kTagged),
|
| + var_rhs(assembler, MachineRepresentation::kTagged),
|
| + var_result(assembler, MachineRepresentation::kTagged);
|
| + Variable* loop_vars[2] = {&var_lhs, &var_rhs};
|
| + Label loop(assembler, 2, loop_vars), end(assembler),
|
| + string_add_convert_left(assembler, Label::kDeferred),
|
| + string_add_convert_right(assembler, Label::kDeferred);
|
| + var_lhs.Bind(left);
|
| + var_rhs.Bind(right);
|
| + assembler->Goto(&loop);
|
| + assembler->Bind(&loop);
|
| + {
|
| + // Load the current {lhs} and {rhs} values.
|
| + Node* lhs = var_lhs.value();
|
| + Node* rhs = var_rhs.value();
|
| +
|
| + // Check if the {lhs} is a Smi or a HeapObject.
|
| + Label if_lhsissmi(assembler), if_lhsisnotsmi(assembler);
|
| + assembler->Branch(assembler->WordIsSmi(lhs), &if_lhsissmi, &if_lhsisnotsmi);
|
| +
|
| + assembler->Bind(&if_lhsissmi);
|
| + {
|
| + // Check if the {rhs} is also a Smi.
|
| + Label if_rhsissmi(assembler), if_rhsisnotsmi(assembler);
|
| + assembler->Branch(assembler->WordIsSmi(rhs), &if_rhsissmi,
|
| + &if_rhsisnotsmi);
|
| +
|
| + assembler->Bind(&if_rhsissmi);
|
| + {
|
| + // Try fast Smi addition first.
|
| + Node* pair = assembler->SmiAddWithOverflow(lhs, rhs);
|
| + Node* overflow = assembler->Projection(1, pair);
|
| +
|
| + // Check if the Smi additon overflowed.
|
| + Label if_overflow(assembler), if_notoverflow(assembler);
|
| + assembler->Branch(overflow, &if_overflow, &if_notoverflow);
|
| +
|
| + assembler->Bind(&if_overflow);
|
| + {
|
| + var_fadd_lhs.Bind(assembler->SmiToFloat64(lhs));
|
| + var_fadd_rhs.Bind(assembler->SmiToFloat64(rhs));
|
| + assembler->Goto(&do_fadd);
|
| + }
|
| +
|
| + assembler->Bind(&if_notoverflow);
|
| + var_result.Bind(assembler->Projection(0, pair));
|
| + assembler->Goto(&end);
|
| + }
|
| +
|
| + assembler->Bind(&if_rhsisnotsmi);
|
| + {
|
| + // Load the map of {rhs}.
|
| + Node* rhs_map = assembler->LoadMap(rhs);
|
| +
|
| + // Check if the {rhs} is a HeapNumber.
|
| + Label if_rhsisnumber(assembler),
|
| + if_rhsisnotnumber(assembler, Label::kDeferred);
|
| + assembler->Branch(assembler->IsHeapNumberMap(rhs_map), &if_rhsisnumber,
|
| + &if_rhsisnotnumber);
|
| +
|
| + assembler->Bind(&if_rhsisnumber);
|
| + {
|
| + var_fadd_lhs.Bind(assembler->SmiToFloat64(lhs));
|
| + var_fadd_rhs.Bind(assembler->LoadHeapNumberValue(rhs));
|
| + assembler->Goto(&do_fadd);
|
| + }
|
| +
|
| + assembler->Bind(&if_rhsisnotnumber);
|
| + {
|
| + // Load the instance type of {rhs}.
|
| + Node* rhs_instance_type = assembler->LoadMapInstanceType(rhs_map);
|
| +
|
| + // Check if the {rhs} is a String.
|
| + Label if_rhsisstring(assembler, Label::kDeferred),
|
| + if_rhsisnotstring(assembler, Label::kDeferred);
|
| + assembler->Branch(assembler->IsStringInstanceType(rhs_instance_type),
|
| + &if_rhsisstring, &if_rhsisnotstring);
|
| +
|
| + assembler->Bind(&if_rhsisstring);
|
| + {
|
| + var_lhs.Bind(lhs);
|
| + var_rhs.Bind(rhs);
|
| + assembler->Goto(&string_add_convert_left);
|
| + }
|
| +
|
| + assembler->Bind(&if_rhsisnotstring);
|
| + {
|
| + // Check if {rhs} is a JSReceiver.
|
| + Label if_rhsisreceiver(assembler, Label::kDeferred),
|
| + if_rhsisnotreceiver(assembler, Label::kDeferred);
|
| + assembler->Branch(
|
| + assembler->IsJSReceiverInstanceType(rhs_instance_type),
|
| + &if_rhsisreceiver, &if_rhsisnotreceiver);
|
| +
|
| + assembler->Bind(&if_rhsisreceiver);
|
| + {
|
| + // Convert {rhs} to a primitive first passing no hint.
|
| + Callable callable =
|
| + CodeFactory::NonPrimitiveToPrimitive(assembler->isolate());
|
| + var_rhs.Bind(assembler->CallStub(callable, context, rhs));
|
| + assembler->Goto(&loop);
|
| + }
|
| +
|
| + assembler->Bind(&if_rhsisnotreceiver);
|
| + {
|
| + // Convert {rhs} to a Number first.
|
| + Callable callable =
|
| + CodeFactory::NonNumberToNumber(assembler->isolate());
|
| + var_rhs.Bind(assembler->CallStub(callable, context, rhs));
|
| + assembler->Goto(&loop);
|
| + }
|
| + }
|
| + }
|
| + }
|
| + }
|
| +
|
| + assembler->Bind(&if_lhsisnotsmi);
|
| + {
|
| + // Load the map and instance type of {lhs}.
|
| + Node* lhs_instance_type = assembler->LoadInstanceType(lhs);
|
| +
|
| + // Check if {lhs} is a String.
|
| + Label if_lhsisstring(assembler), if_lhsisnotstring(assembler);
|
| + assembler->Branch(assembler->IsStringInstanceType(lhs_instance_type),
|
| + &if_lhsisstring, &if_lhsisnotstring);
|
| +
|
| + assembler->Bind(&if_lhsisstring);
|
| + {
|
| + var_lhs.Bind(lhs);
|
| + var_rhs.Bind(rhs);
|
| + assembler->Goto(&string_add_convert_right);
|
| + }
|
| +
|
| + assembler->Bind(&if_lhsisnotstring);
|
| + {
|
| + // Check if {rhs} is a Smi.
|
| + Label if_rhsissmi(assembler), if_rhsisnotsmi(assembler);
|
| + assembler->Branch(assembler->WordIsSmi(rhs), &if_rhsissmi,
|
| + &if_rhsisnotsmi);
|
| +
|
| + assembler->Bind(&if_rhsissmi);
|
| + {
|
| + // Check if {lhs} is a Number.
|
| + Label if_lhsisnumber(assembler),
|
| + if_lhsisnotnumber(assembler, Label::kDeferred);
|
| + assembler->Branch(assembler->Word32Equal(
|
| + lhs_instance_type,
|
| + assembler->Int32Constant(HEAP_NUMBER_TYPE)),
|
| + &if_lhsisnumber, &if_lhsisnotnumber);
|
| +
|
| + assembler->Bind(&if_lhsisnumber);
|
| + {
|
| + // The {lhs} is a HeapNumber, the {rhs} is a Smi, just add them.
|
| + var_fadd_lhs.Bind(assembler->LoadHeapNumberValue(lhs));
|
| + var_fadd_rhs.Bind(assembler->SmiToFloat64(rhs));
|
| + assembler->Goto(&do_fadd);
|
| + }
|
| +
|
| + assembler->Bind(&if_lhsisnotnumber);
|
| + {
|
| + // The {lhs} is neither a Number nor a String, and the {rhs} is a
|
| + // Smi.
|
| + Label if_lhsisreceiver(assembler, Label::kDeferred),
|
| + if_lhsisnotreceiver(assembler, Label::kDeferred);
|
| + assembler->Branch(
|
| + assembler->IsJSReceiverInstanceType(lhs_instance_type),
|
| + &if_lhsisreceiver, &if_lhsisnotreceiver);
|
| +
|
| + assembler->Bind(&if_lhsisreceiver);
|
| + {
|
| + // Convert {lhs} to a primitive first passing no hint.
|
| + Callable callable =
|
| + CodeFactory::NonPrimitiveToPrimitive(assembler->isolate());
|
| + var_lhs.Bind(assembler->CallStub(callable, context, lhs));
|
| + assembler->Goto(&loop);
|
| + }
|
| +
|
| + assembler->Bind(&if_lhsisnotreceiver);
|
| + {
|
| + // Convert {lhs} to a Number first.
|
| + Callable callable =
|
| + CodeFactory::NonNumberToNumber(assembler->isolate());
|
| + var_lhs.Bind(assembler->CallStub(callable, context, lhs));
|
| + assembler->Goto(&loop);
|
| + }
|
| + }
|
| + }
|
| +
|
| + assembler->Bind(&if_rhsisnotsmi);
|
| + {
|
| + // Load the instance type of {rhs}.
|
| + Node* rhs_instance_type = assembler->LoadInstanceType(rhs);
|
| +
|
| + // Check if {rhs} is a String.
|
| + Label if_rhsisstring(assembler), if_rhsisnotstring(assembler);
|
| + assembler->Branch(assembler->IsStringInstanceType(rhs_instance_type),
|
| + &if_rhsisstring, &if_rhsisnotstring);
|
| +
|
| + assembler->Bind(&if_rhsisstring);
|
| + {
|
| + var_lhs.Bind(lhs);
|
| + var_rhs.Bind(rhs);
|
| + assembler->Goto(&string_add_convert_left);
|
| + }
|
| +
|
| + assembler->Bind(&if_rhsisnotstring);
|
| + {
|
| + // Check if {lhs} is a HeapNumber.
|
| + Label if_lhsisnumber(assembler), if_lhsisnotnumber(assembler);
|
| + assembler->Branch(assembler->Word32Equal(
|
| + lhs_instance_type,
|
| + assembler->Int32Constant(HEAP_NUMBER_TYPE)),
|
| + &if_lhsisnumber, &if_lhsisnotnumber);
|
| +
|
| + assembler->Bind(&if_lhsisnumber);
|
| + {
|
| + // Check if {rhs} is also a HeapNumber.
|
| + Label if_rhsisnumber(assembler),
|
| + if_rhsisnotnumber(assembler, Label::kDeferred);
|
| + assembler->Branch(assembler->Word32Equal(
|
| + rhs_instance_type,
|
| + assembler->Int32Constant(HEAP_NUMBER_TYPE)),
|
| + &if_rhsisnumber, &if_rhsisnotnumber);
|
| +
|
| + assembler->Bind(&if_rhsisnumber);
|
| + {
|
| + // Perform a floating point addition.
|
| + var_fadd_lhs.Bind(assembler->LoadHeapNumberValue(lhs));
|
| + var_fadd_rhs.Bind(assembler->LoadHeapNumberValue(rhs));
|
| + assembler->Goto(&do_fadd);
|
| + }
|
| +
|
| + assembler->Bind(&if_rhsisnotnumber);
|
| + {
|
| + // Check if {rhs} is a JSReceiver.
|
| + Label if_rhsisreceiver(assembler, Label::kDeferred),
|
| + if_rhsisnotreceiver(assembler, Label::kDeferred);
|
| + assembler->Branch(
|
| + assembler->IsJSReceiverInstanceType(rhs_instance_type),
|
| + &if_rhsisreceiver, &if_rhsisnotreceiver);
|
| +
|
| + assembler->Bind(&if_rhsisreceiver);
|
| + {
|
| + // Convert {rhs} to a primitive first passing no hint.
|
| + Callable callable = CodeFactory::NonPrimitiveToPrimitive(
|
| + assembler->isolate());
|
| + var_rhs.Bind(assembler->CallStub(callable, context, rhs));
|
| + assembler->Goto(&loop);
|
| + }
|
| +
|
| + assembler->Bind(&if_rhsisnotreceiver);
|
| + {
|
| + // Convert {rhs} to a Number first.
|
| + Callable callable =
|
| + CodeFactory::NonNumberToNumber(assembler->isolate());
|
| + var_rhs.Bind(assembler->CallStub(callable, context, rhs));
|
| + assembler->Goto(&loop);
|
| + }
|
| + }
|
| + }
|
| +
|
| + assembler->Bind(&if_lhsisnotnumber);
|
| + {
|
| + // Check if {lhs} is a JSReceiver.
|
| + Label if_lhsisreceiver(assembler, Label::kDeferred),
|
| + if_lhsisnotreceiver(assembler);
|
| + assembler->Branch(
|
| + assembler->IsJSReceiverInstanceType(lhs_instance_type),
|
| + &if_lhsisreceiver, &if_lhsisnotreceiver);
|
| +
|
| + assembler->Bind(&if_lhsisreceiver);
|
| + {
|
| + // Convert {lhs} to a primitive first passing no hint.
|
| + Callable callable =
|
| + CodeFactory::NonPrimitiveToPrimitive(assembler->isolate());
|
| + var_lhs.Bind(assembler->CallStub(callable, context, lhs));
|
| + assembler->Goto(&loop);
|
| + }
|
| +
|
| + assembler->Bind(&if_lhsisnotreceiver);
|
| + {
|
| + // Check if {rhs} is a JSReceiver.
|
| + Label if_rhsisreceiver(assembler, Label::kDeferred),
|
| + if_rhsisnotreceiver(assembler, Label::kDeferred);
|
| + assembler->Branch(
|
| + assembler->IsJSReceiverInstanceType(rhs_instance_type),
|
| + &if_rhsisreceiver, &if_rhsisnotreceiver);
|
| +
|
| + assembler->Bind(&if_rhsisreceiver);
|
| + {
|
| + // Convert {rhs} to a primitive first passing no hint.
|
| + Callable callable = CodeFactory::NonPrimitiveToPrimitive(
|
| + assembler->isolate());
|
| + var_rhs.Bind(assembler->CallStub(callable, context, rhs));
|
| + assembler->Goto(&loop);
|
| + }
|
| +
|
| + assembler->Bind(&if_rhsisnotreceiver);
|
| + {
|
| + // Convert {lhs} to a Number first.
|
| + Callable callable =
|
| + CodeFactory::NonNumberToNumber(assembler->isolate());
|
| + var_lhs.Bind(assembler->CallStub(callable, context, lhs));
|
| + assembler->Goto(&loop);
|
| + }
|
| + }
|
| + }
|
| + }
|
| + }
|
| + }
|
| + }
|
| + }
|
| + assembler->Bind(&string_add_convert_left);
|
| + {
|
| + // Convert {lhs}, which is a Smi, to a String and concatenate the
|
| + // resulting string with the String {rhs}.
|
| + Callable callable = CodeFactory::StringAdd(
|
| + assembler->isolate(), STRING_ADD_CONVERT_LEFT, NOT_TENURED);
|
| + var_result.Bind(assembler->CallStub(callable, context, var_lhs.value(),
|
| + var_rhs.value()));
|
| + assembler->Goto(&end);
|
| + }
|
| +
|
| + assembler->Bind(&string_add_convert_right);
|
| + {
|
| + // Convert {lhs}, which is a Smi, to a String and concatenate the
|
| + // resulting string with the String {rhs}.
|
| + Callable callable = CodeFactory::StringAdd(
|
| + assembler->isolate(), STRING_ADD_CONVERT_RIGHT, NOT_TENURED);
|
| + var_result.Bind(assembler->CallStub(callable, context, var_lhs.value(),
|
| + var_rhs.value()));
|
| + assembler->Goto(&end);
|
| + }
|
| +
|
| + assembler->Bind(&do_fadd);
|
| + {
|
| + Node* lhs_value = var_fadd_lhs.value();
|
| + Node* rhs_value = var_fadd_rhs.value();
|
| + Node* value = assembler->Float64Add(lhs_value, rhs_value);
|
| + Node* result = assembler->ChangeFloat64ToTagged(value);
|
| + var_result.Bind(result);
|
| + assembler->Goto(&end);
|
| + }
|
| + assembler->Bind(&end);
|
| + assembler->Return(var_result.value());
|
| +}
|
| +
|
| +void Builtins::Generate_Subtract(CodeStubAssembler* assembler) {
|
| + typedef CodeStubAssembler::Label Label;
|
| + typedef compiler::Node Node;
|
| + typedef CodeStubAssembler::Variable Variable;
|
| +
|
| + Node* left = assembler->Parameter(0);
|
| + Node* right = assembler->Parameter(1);
|
| + Node* context = assembler->Parameter(2);
|
| +
|
| + // Shared entry for floating point subtraction.
|
| + Label do_fsub(assembler), end(assembler);
|
| + Variable var_fsub_lhs(assembler, MachineRepresentation::kFloat64),
|
| + var_fsub_rhs(assembler, MachineRepresentation::kFloat64);
|
| +
|
| + // We might need to loop several times due to ToPrimitive and/or ToNumber
|
| + // conversions.
|
| + Variable var_lhs(assembler, MachineRepresentation::kTagged),
|
| + var_rhs(assembler, MachineRepresentation::kTagged),
|
| + var_result(assembler, MachineRepresentation::kTagged);
|
| + Variable* loop_vars[2] = {&var_lhs, &var_rhs};
|
| + Label loop(assembler, 2, loop_vars);
|
| + var_lhs.Bind(left);
|
| + var_rhs.Bind(right);
|
| + assembler->Goto(&loop);
|
| + assembler->Bind(&loop);
|
| + {
|
| + // Load the current {lhs} and {rhs} values.
|
| + Node* lhs = var_lhs.value();
|
| + Node* rhs = var_rhs.value();
|
| +
|
| + // Check if the {lhs} is a Smi or a HeapObject.
|
| + Label if_lhsissmi(assembler), if_lhsisnotsmi(assembler);
|
| + assembler->Branch(assembler->WordIsSmi(lhs), &if_lhsissmi, &if_lhsisnotsmi);
|
| +
|
| + assembler->Bind(&if_lhsissmi);
|
| + {
|
| + // Check if the {rhs} is also a Smi.
|
| + Label if_rhsissmi(assembler), if_rhsisnotsmi(assembler);
|
| + assembler->Branch(assembler->WordIsSmi(rhs), &if_rhsissmi,
|
| + &if_rhsisnotsmi);
|
| +
|
| + assembler->Bind(&if_rhsissmi);
|
| + {
|
| + // Try a fast Smi subtraction first.
|
| + Node* pair = assembler->SmiSubWithOverflow(lhs, rhs);
|
| + Node* overflow = assembler->Projection(1, pair);
|
| +
|
| + // Check if the Smi subtraction overflowed.
|
| + Label if_overflow(assembler), if_notoverflow(assembler);
|
| + assembler->Branch(overflow, &if_overflow, &if_notoverflow);
|
| +
|
| + assembler->Bind(&if_overflow);
|
| + {
|
| + // The result doesn't fit into Smi range.
|
| + var_fsub_lhs.Bind(assembler->SmiToFloat64(lhs));
|
| + var_fsub_rhs.Bind(assembler->SmiToFloat64(rhs));
|
| + assembler->Goto(&do_fsub);
|
| + }
|
| +
|
| + assembler->Bind(&if_notoverflow);
|
| + var_result.Bind(assembler->Projection(0, pair));
|
| + assembler->Goto(&end);
|
| + }
|
| +
|
| + assembler->Bind(&if_rhsisnotsmi);
|
| + {
|
| + // Load the map of the {rhs}.
|
| + Node* rhs_map = assembler->LoadMap(rhs);
|
| +
|
| + // Check if {rhs} is a HeapNumber.
|
| + Label if_rhsisnumber(assembler),
|
| + if_rhsisnotnumber(assembler, Label::kDeferred);
|
| + assembler->Branch(assembler->IsHeapNumberMap(rhs_map), &if_rhsisnumber,
|
| + &if_rhsisnotnumber);
|
| +
|
| + assembler->Bind(&if_rhsisnumber);
|
| + {
|
| + // Perform a floating point subtraction.
|
| + var_fsub_lhs.Bind(assembler->SmiToFloat64(lhs));
|
| + var_fsub_rhs.Bind(assembler->LoadHeapNumberValue(rhs));
|
| + assembler->Goto(&do_fsub);
|
| + }
|
| +
|
| + assembler->Bind(&if_rhsisnotnumber);
|
| + {
|
| + // Convert the {rhs} to a Number first.
|
| + Callable callable =
|
| + CodeFactory::NonNumberToNumber(assembler->isolate());
|
| + var_rhs.Bind(assembler->CallStub(callable, context, rhs));
|
| + assembler->Goto(&loop);
|
| + }
|
| + }
|
| + }
|
| +
|
| + assembler->Bind(&if_lhsisnotsmi);
|
| + {
|
| + // Load the map of the {lhs}.
|
| + Node* lhs_map = assembler->LoadMap(lhs);
|
| +
|
| + // Check if the {lhs} is a HeapNumber.
|
| + Label if_lhsisnumber(assembler),
|
| + if_lhsisnotnumber(assembler, Label::kDeferred);
|
| + Node* number_map = assembler->HeapNumberMapConstant();
|
| + assembler->Branch(assembler->WordEqual(lhs_map, number_map),
|
| + &if_lhsisnumber, &if_lhsisnotnumber);
|
| +
|
| + assembler->Bind(&if_lhsisnumber);
|
| + {
|
| + // Check if the {rhs} is a Smi.
|
| + Label if_rhsissmi(assembler), if_rhsisnotsmi(assembler);
|
| + assembler->Branch(assembler->WordIsSmi(rhs), &if_rhsissmi,
|
| + &if_rhsisnotsmi);
|
| +
|
| + assembler->Bind(&if_rhsissmi);
|
| + {
|
| + // Perform a floating point subtraction.
|
| + var_fsub_lhs.Bind(assembler->LoadHeapNumberValue(lhs));
|
| + var_fsub_rhs.Bind(assembler->SmiToFloat64(rhs));
|
| + assembler->Goto(&do_fsub);
|
| + }
|
| +
|
| + assembler->Bind(&if_rhsisnotsmi);
|
| + {
|
| + // Load the map of the {rhs}.
|
| + Node* rhs_map = assembler->LoadMap(rhs);
|
| +
|
| + // Check if the {rhs} is a HeapNumber.
|
| + Label if_rhsisnumber(assembler),
|
| + if_rhsisnotnumber(assembler, Label::kDeferred);
|
| + assembler->Branch(assembler->WordEqual(rhs_map, number_map),
|
| + &if_rhsisnumber, &if_rhsisnotnumber);
|
| +
|
| + assembler->Bind(&if_rhsisnumber);
|
| + {
|
| + // Perform a floating point subtraction.
|
| + var_fsub_lhs.Bind(assembler->LoadHeapNumberValue(lhs));
|
| + var_fsub_rhs.Bind(assembler->LoadHeapNumberValue(rhs));
|
| + assembler->Goto(&do_fsub);
|
| + }
|
| +
|
| + assembler->Bind(&if_rhsisnotnumber);
|
| + {
|
| + // Convert the {rhs} to a Number first.
|
| + Callable callable =
|
| + CodeFactory::NonNumberToNumber(assembler->isolate());
|
| + var_rhs.Bind(assembler->CallStub(callable, context, rhs));
|
| + assembler->Goto(&loop);
|
| + }
|
| + }
|
| + }
|
| +
|
| + assembler->Bind(&if_lhsisnotnumber);
|
| + {
|
| + // Convert the {lhs} to a Number first.
|
| + Callable callable =
|
| + CodeFactory::NonNumberToNumber(assembler->isolate());
|
| + var_lhs.Bind(assembler->CallStub(callable, context, lhs));
|
| + assembler->Goto(&loop);
|
| + }
|
| + }
|
| + }
|
| +
|
| + assembler->Bind(&do_fsub);
|
| + {
|
| + Node* lhs_value = var_fsub_lhs.value();
|
| + Node* rhs_value = var_fsub_rhs.value();
|
| + Node* value = assembler->Float64Sub(lhs_value, rhs_value);
|
| + var_result.Bind(assembler->ChangeFloat64ToTagged(value));
|
| + assembler->Goto(&end);
|
| + }
|
| + assembler->Bind(&end);
|
| + assembler->Return(var_result.value());
|
| +}
|
| +
|
| +void Builtins::Generate_Multiply(CodeStubAssembler* assembler) {
|
| + typedef CodeStubAssembler::Label Label;
|
| + typedef compiler::Node Node;
|
| + typedef CodeStubAssembler::Variable Variable;
|
| +
|
| + Node* left = assembler->Parameter(0);
|
| + Node* right = assembler->Parameter(1);
|
| + Node* context = assembler->Parameter(2);
|
| +
|
| + // Shared entry point for floating point multiplication.
|
| + Label do_fmul(assembler), return_result(assembler);
|
| + Variable var_lhs_float64(assembler, MachineRepresentation::kFloat64),
|
| + var_rhs_float64(assembler, MachineRepresentation::kFloat64);
|
| +
|
| + Node* number_map = assembler->HeapNumberMapConstant();
|
| +
|
| + // We might need to loop one or two times due to ToNumber conversions.
|
| + Variable var_lhs(assembler, MachineRepresentation::kTagged),
|
| + var_rhs(assembler, MachineRepresentation::kTagged),
|
| + var_result(assembler, MachineRepresentation::kTagged);
|
| + Variable* loop_variables[] = {&var_lhs, &var_rhs};
|
| + Label loop(assembler, 2, loop_variables);
|
| + var_lhs.Bind(left);
|
| + var_rhs.Bind(right);
|
| + assembler->Goto(&loop);
|
| + assembler->Bind(&loop);
|
| + {
|
| + Node* lhs = var_lhs.value();
|
| + Node* rhs = var_rhs.value();
|
| +
|
| + Label lhs_is_smi(assembler), lhs_is_not_smi(assembler);
|
| + assembler->Branch(assembler->WordIsSmi(lhs), &lhs_is_smi, &lhs_is_not_smi);
|
| +
|
| + assembler->Bind(&lhs_is_smi);
|
| + {
|
| + Label rhs_is_smi(assembler), rhs_is_not_smi(assembler);
|
| + assembler->Branch(assembler->WordIsSmi(rhs), &rhs_is_smi,
|
| + &rhs_is_not_smi);
|
| +
|
| + assembler->Bind(&rhs_is_smi);
|
| + {
|
| + // Both {lhs} and {rhs} are Smis. The result is not necessarily a smi,
|
| + // in case of overflow.
|
| + var_result.Bind(assembler->SmiMul(lhs, rhs));
|
| + assembler->Goto(&return_result);
|
| + }
|
| +
|
| + assembler->Bind(&rhs_is_not_smi);
|
| + {
|
| + Node* rhs_map = assembler->LoadMap(rhs);
|
| +
|
| + // Check if {rhs} is a HeapNumber.
|
| + Label rhs_is_number(assembler),
|
| + rhs_is_not_number(assembler, Label::kDeferred);
|
| + assembler->Branch(assembler->WordEqual(rhs_map, number_map),
|
| + &rhs_is_number, &rhs_is_not_number);
|
| +
|
| + assembler->Bind(&rhs_is_number);
|
| + {
|
| + // Convert {lhs} to a double and multiply it with the value of {rhs}.
|
| + var_lhs_float64.Bind(assembler->SmiToFloat64(lhs));
|
| + var_rhs_float64.Bind(assembler->LoadHeapNumberValue(rhs));
|
| + assembler->Goto(&do_fmul);
|
| + }
|
| +
|
| + assembler->Bind(&rhs_is_not_number);
|
| + {
|
| + // Multiplication is commutative, swap {lhs} with {rhs} and loop.
|
| + var_lhs.Bind(rhs);
|
| + var_rhs.Bind(lhs);
|
| + assembler->Goto(&loop);
|
| + }
|
| + }
|
| + }
|
| +
|
| + assembler->Bind(&lhs_is_not_smi);
|
| + {
|
| + Node* lhs_map = assembler->LoadMap(lhs);
|
| +
|
| + // Check if {lhs} is a HeapNumber.
|
| + Label lhs_is_number(assembler),
|
| + lhs_is_not_number(assembler, Label::kDeferred);
|
| + assembler->Branch(assembler->WordEqual(lhs_map, number_map),
|
| + &lhs_is_number, &lhs_is_not_number);
|
| +
|
| + assembler->Bind(&lhs_is_number);
|
| + {
|
| + // Check if {rhs} is a Smi.
|
| + Label rhs_is_smi(assembler), rhs_is_not_smi(assembler);
|
| + assembler->Branch(assembler->WordIsSmi(rhs), &rhs_is_smi,
|
| + &rhs_is_not_smi);
|
| +
|
| + assembler->Bind(&rhs_is_smi);
|
| + {
|
| + // Convert {rhs} to a double and multiply it with the value of {lhs}.
|
| + var_lhs_float64.Bind(assembler->LoadHeapNumberValue(lhs));
|
| + var_rhs_float64.Bind(assembler->SmiToFloat64(rhs));
|
| + assembler->Goto(&do_fmul);
|
| + }
|
| +
|
| + assembler->Bind(&rhs_is_not_smi);
|
| + {
|
| + Node* rhs_map = assembler->LoadMap(rhs);
|
| +
|
| + // Check if {rhs} is a HeapNumber.
|
| + Label rhs_is_number(assembler),
|
| + rhs_is_not_number(assembler, Label::kDeferred);
|
| + assembler->Branch(assembler->WordEqual(rhs_map, number_map),
|
| + &rhs_is_number, &rhs_is_not_number);
|
| +
|
| + assembler->Bind(&rhs_is_number);
|
| + {
|
| + // Both {lhs} and {rhs} are HeapNumbers. Load their values and
|
| + // multiply them.
|
| + var_lhs_float64.Bind(assembler->LoadHeapNumberValue(lhs));
|
| + var_rhs_float64.Bind(assembler->LoadHeapNumberValue(rhs));
|
| + assembler->Goto(&do_fmul);
|
| + }
|
| +
|
| + assembler->Bind(&rhs_is_not_number);
|
| + {
|
| + // Multiplication is commutative, swap {lhs} with {rhs} and loop.
|
| + var_lhs.Bind(rhs);
|
| + var_rhs.Bind(lhs);
|
| + assembler->Goto(&loop);
|
| + }
|
| + }
|
| + }
|
| +
|
| + assembler->Bind(&lhs_is_not_number);
|
| + {
|
| + // Convert {lhs} to a Number and loop.
|
| + Callable callable =
|
| + CodeFactory::NonNumberToNumber(assembler->isolate());
|
| + var_lhs.Bind(assembler->CallStub(callable, context, lhs));
|
| + assembler->Goto(&loop);
|
| + }
|
| + }
|
| + }
|
| +
|
| + assembler->Bind(&do_fmul);
|
| + {
|
| + Node* value =
|
| + assembler->Float64Mul(var_lhs_float64.value(), var_rhs_float64.value());
|
| + Node* result = assembler->ChangeFloat64ToTagged(value);
|
| + var_result.Bind(result);
|
| + assembler->Goto(&return_result);
|
| + }
|
| +
|
| + assembler->Bind(&return_result);
|
| + assembler->Return(var_result.value());
|
| +}
|
| +
|
| +void Builtins::Generate_Divide(CodeStubAssembler* assembler) {
|
| + typedef CodeStubAssembler::Label Label;
|
| + typedef compiler::Node Node;
|
| + typedef CodeStubAssembler::Variable Variable;
|
| +
|
| + Node* left = assembler->Parameter(0);
|
| + Node* right = assembler->Parameter(1);
|
| + Node* context = assembler->Parameter(2);
|
| +
|
| + // Shared entry point for floating point division.
|
| + Label do_fdiv(assembler), end(assembler);
|
| + Variable var_dividend_float64(assembler, MachineRepresentation::kFloat64),
|
| + var_divisor_float64(assembler, MachineRepresentation::kFloat64);
|
| +
|
| + Node* number_map = assembler->HeapNumberMapConstant();
|
| +
|
| + // We might need to loop one or two times due to ToNumber conversions.
|
| + Variable var_dividend(assembler, MachineRepresentation::kTagged),
|
| + var_divisor(assembler, MachineRepresentation::kTagged),
|
| + var_result(assembler, MachineRepresentation::kTagged);
|
| + Variable* loop_variables[] = {&var_dividend, &var_divisor};
|
| + Label loop(assembler, 2, loop_variables);
|
| + var_dividend.Bind(left);
|
| + var_divisor.Bind(right);
|
| + assembler->Goto(&loop);
|
| + assembler->Bind(&loop);
|
| + {
|
| + Node* dividend = var_dividend.value();
|
| + Node* divisor = var_divisor.value();
|
| +
|
| + Label dividend_is_smi(assembler), dividend_is_not_smi(assembler);
|
| + assembler->Branch(assembler->WordIsSmi(dividend), ÷nd_is_smi,
|
| + ÷nd_is_not_smi);
|
| +
|
| + assembler->Bind(÷nd_is_smi);
|
| + {
|
| + Label divisor_is_smi(assembler), divisor_is_not_smi(assembler);
|
| + assembler->Branch(assembler->WordIsSmi(divisor), &divisor_is_smi,
|
| + &divisor_is_not_smi);
|
| +
|
| + assembler->Bind(&divisor_is_smi);
|
| + {
|
| + Label bailout(assembler);
|
| +
|
| + // Do floating point division if {divisor} is zero.
|
| + assembler->GotoIf(
|
| + assembler->WordEqual(divisor, assembler->IntPtrConstant(0)),
|
| + &bailout);
|
| +
|
| + // Do floating point division {dividend} is zero and {divisor} is
|
| + // negative.
|
| + Label dividend_is_zero(assembler), dividend_is_not_zero(assembler);
|
| + assembler->Branch(
|
| + assembler->WordEqual(dividend, assembler->IntPtrConstant(0)),
|
| + ÷nd_is_zero, ÷nd_is_not_zero);
|
| +
|
| + assembler->Bind(÷nd_is_zero);
|
| + {
|
| + assembler->GotoIf(
|
| + assembler->IntPtrLessThan(divisor, assembler->IntPtrConstant(0)),
|
| + &bailout);
|
| + assembler->Goto(÷nd_is_not_zero);
|
| + }
|
| + assembler->Bind(÷nd_is_not_zero);
|
| +
|
| + Node* untagged_divisor = assembler->SmiUntag(divisor);
|
| + Node* untagged_dividend = assembler->SmiUntag(dividend);
|
| +
|
| + // Do floating point division if {dividend} is kMinInt (or kMinInt - 1
|
| + // if the Smi size is 31) and {divisor} is -1.
|
| + Label divisor_is_minus_one(assembler),
|
| + divisor_is_not_minus_one(assembler);
|
| + assembler->Branch(assembler->Word32Equal(untagged_divisor,
|
| + assembler->Int32Constant(-1)),
|
| + &divisor_is_minus_one, &divisor_is_not_minus_one);
|
| +
|
| + assembler->Bind(&divisor_is_minus_one);
|
| + {
|
| + assembler->GotoIf(
|
| + assembler->Word32Equal(
|
| + untagged_dividend,
|
| + assembler->Int32Constant(
|
| + kSmiValueSize == 32 ? kMinInt : (kMinInt >> 1))),
|
| + &bailout);
|
| + assembler->Goto(&divisor_is_not_minus_one);
|
| + }
|
| + assembler->Bind(&divisor_is_not_minus_one);
|
| +
|
| + // TODO(epertoso): consider adding a machine instruction that returns
|
| + // both the result and the remainder.
|
| + Node* untagged_result =
|
| + assembler->Int32Div(untagged_dividend, untagged_divisor);
|
| + Node* truncated =
|
| + assembler->Int32Mul(untagged_result, untagged_divisor);
|
| + // Do floating point division if the remainder is not 0.
|
| + assembler->GotoIf(
|
| + assembler->Word32NotEqual(untagged_dividend, truncated), &bailout);
|
| + var_result.Bind(assembler->SmiTag(untagged_result));
|
| + assembler->Goto(&end);
|
| +
|
| + // Bailout: convert {dividend} and {divisor} to double and do double
|
| + // division.
|
| + assembler->Bind(&bailout);
|
| + {
|
| + var_dividend_float64.Bind(assembler->SmiToFloat64(dividend));
|
| + var_divisor_float64.Bind(assembler->SmiToFloat64(divisor));
|
| + assembler->Goto(&do_fdiv);
|
| + }
|
| + }
|
| +
|
| + assembler->Bind(&divisor_is_not_smi);
|
| + {
|
| + Node* divisor_map = assembler->LoadMap(divisor);
|
| +
|
| + // Check if {divisor} is a HeapNumber.
|
| + Label divisor_is_number(assembler),
|
| + divisor_is_not_number(assembler, Label::kDeferred);
|
| + assembler->Branch(assembler->WordEqual(divisor_map, number_map),
|
| + &divisor_is_number, &divisor_is_not_number);
|
| +
|
| + assembler->Bind(&divisor_is_number);
|
| + {
|
| + // Convert {dividend} to a double and divide it with the value of
|
| + // {divisor}.
|
| + var_dividend_float64.Bind(assembler->SmiToFloat64(dividend));
|
| + var_divisor_float64.Bind(assembler->LoadHeapNumberValue(divisor));
|
| + assembler->Goto(&do_fdiv);
|
| + }
|
| +
|
| + assembler->Bind(&divisor_is_not_number);
|
| + {
|
| + // Convert {divisor} to a number and loop.
|
| + Callable callable =
|
| + CodeFactory::NonNumberToNumber(assembler->isolate());
|
| + var_divisor.Bind(assembler->CallStub(callable, context, divisor));
|
| + assembler->Goto(&loop);
|
| + }
|
| + }
|
| + }
|
| +
|
| + assembler->Bind(÷nd_is_not_smi);
|
| + {
|
| + Node* dividend_map = assembler->LoadMap(dividend);
|
| +
|
| + // Check if {dividend} is a HeapNumber.
|
| + Label dividend_is_number(assembler),
|
| + dividend_is_not_number(assembler, Label::kDeferred);
|
| + assembler->Branch(assembler->WordEqual(dividend_map, number_map),
|
| + ÷nd_is_number, ÷nd_is_not_number);
|
| +
|
| + assembler->Bind(÷nd_is_number);
|
| + {
|
| + // Check if {divisor} is a Smi.
|
| + Label divisor_is_smi(assembler), divisor_is_not_smi(assembler);
|
| + assembler->Branch(assembler->WordIsSmi(divisor), &divisor_is_smi,
|
| + &divisor_is_not_smi);
|
| +
|
| + assembler->Bind(&divisor_is_smi);
|
| + {
|
| + // Convert {divisor} to a double and use it for a floating point
|
| + // division.
|
| + var_dividend_float64.Bind(assembler->LoadHeapNumberValue(dividend));
|
| + var_divisor_float64.Bind(assembler->SmiToFloat64(divisor));
|
| + assembler->Goto(&do_fdiv);
|
| + }
|
| +
|
| + assembler->Bind(&divisor_is_not_smi);
|
| + {
|
| + Node* divisor_map = assembler->LoadMap(divisor);
|
| +
|
| + // Check if {divisor} is a HeapNumber.
|
| + Label divisor_is_number(assembler),
|
| + divisor_is_not_number(assembler, Label::kDeferred);
|
| + assembler->Branch(assembler->WordEqual(divisor_map, number_map),
|
| + &divisor_is_number, &divisor_is_not_number);
|
| +
|
| + assembler->Bind(&divisor_is_number);
|
| + {
|
| + // Both {dividend} and {divisor} are HeapNumbers. Load their values
|
| + // and divide them.
|
| + var_dividend_float64.Bind(assembler->LoadHeapNumberValue(dividend));
|
| + var_divisor_float64.Bind(assembler->LoadHeapNumberValue(divisor));
|
| + assembler->Goto(&do_fdiv);
|
| + }
|
| +
|
| + assembler->Bind(&divisor_is_not_number);
|
| + {
|
| + // Convert {divisor} to a number and loop.
|
| + Callable callable =
|
| + CodeFactory::NonNumberToNumber(assembler->isolate());
|
| + var_divisor.Bind(assembler->CallStub(callable, context, divisor));
|
| + assembler->Goto(&loop);
|
| + }
|
| + }
|
| + }
|
| +
|
| + assembler->Bind(÷nd_is_not_number);
|
| + {
|
| + // Convert {dividend} to a Number and loop.
|
| + Callable callable =
|
| + CodeFactory::NonNumberToNumber(assembler->isolate());
|
| + var_dividend.Bind(assembler->CallStub(callable, context, dividend));
|
| + assembler->Goto(&loop);
|
| + }
|
| + }
|
| + }
|
| +
|
| + assembler->Bind(&do_fdiv);
|
| + {
|
| + Node* value = assembler->Float64Div(var_dividend_float64.value(),
|
| + var_divisor_float64.value());
|
| + var_result.Bind(assembler->ChangeFloat64ToTagged(value));
|
| + assembler->Goto(&end);
|
| + }
|
| + assembler->Bind(&end);
|
| + assembler->Return(var_result.value());
|
| +}
|
| +
|
| +void Builtins::Generate_Modulus(CodeStubAssembler* assembler) {
|
| + typedef CodeStubAssembler::Label Label;
|
| + typedef compiler::Node Node;
|
| + typedef CodeStubAssembler::Variable Variable;
|
| +
|
| + Node* left = assembler->Parameter(0);
|
| + Node* right = assembler->Parameter(1);
|
| + Node* context = assembler->Parameter(2);
|
| +
|
| + Variable var_result(assembler, MachineRepresentation::kTagged);
|
| + Label return_result(assembler, &var_result);
|
| +
|
| + // Shared entry point for floating point modulus.
|
| + Label do_fmod(assembler);
|
| + Variable var_dividend_float64(assembler, MachineRepresentation::kFloat64),
|
| + var_divisor_float64(assembler, MachineRepresentation::kFloat64);
|
| +
|
| + Node* number_map = assembler->HeapNumberMapConstant();
|
| +
|
| + // We might need to loop one or two times due to ToNumber conversions.
|
| + Variable var_dividend(assembler, MachineRepresentation::kTagged),
|
| + var_divisor(assembler, MachineRepresentation::kTagged);
|
| + Variable* loop_variables[] = {&var_dividend, &var_divisor};
|
| + Label loop(assembler, 2, loop_variables);
|
| + var_dividend.Bind(left);
|
| + var_divisor.Bind(right);
|
| + assembler->Goto(&loop);
|
| + assembler->Bind(&loop);
|
| + {
|
| + Node* dividend = var_dividend.value();
|
| + Node* divisor = var_divisor.value();
|
| +
|
| + Label dividend_is_smi(assembler), dividend_is_not_smi(assembler);
|
| + assembler->Branch(assembler->WordIsSmi(dividend), ÷nd_is_smi,
|
| + ÷nd_is_not_smi);
|
| +
|
| + assembler->Bind(÷nd_is_smi);
|
| + {
|
| + Label dividend_is_not_zero(assembler);
|
| + Label divisor_is_smi(assembler), divisor_is_not_smi(assembler);
|
| + assembler->Branch(assembler->WordIsSmi(divisor), &divisor_is_smi,
|
| + &divisor_is_not_smi);
|
| +
|
| + assembler->Bind(&divisor_is_smi);
|
| + {
|
| + // Compute the modulus of two Smis.
|
| + var_result.Bind(assembler->SmiMod(dividend, divisor));
|
| + assembler->Goto(&return_result);
|
| + }
|
| +
|
| + assembler->Bind(&divisor_is_not_smi);
|
| + {
|
| + Node* divisor_map = assembler->LoadMap(divisor);
|
| +
|
| + // Check if {divisor} is a HeapNumber.
|
| + Label divisor_is_number(assembler),
|
| + divisor_is_not_number(assembler, Label::kDeferred);
|
| + assembler->Branch(assembler->WordEqual(divisor_map, number_map),
|
| + &divisor_is_number, &divisor_is_not_number);
|
| +
|
| + assembler->Bind(&divisor_is_number);
|
| + {
|
| + // Convert {dividend} to a double and compute its modulus with the
|
| + // value of {dividend}.
|
| + var_dividend_float64.Bind(assembler->SmiToFloat64(dividend));
|
| + var_divisor_float64.Bind(assembler->LoadHeapNumberValue(divisor));
|
| + assembler->Goto(&do_fmod);
|
| + }
|
| +
|
| + assembler->Bind(&divisor_is_not_number);
|
| + {
|
| + // Convert {divisor} to a number and loop.
|
| + Callable callable =
|
| + CodeFactory::NonNumberToNumber(assembler->isolate());
|
| + var_divisor.Bind(assembler->CallStub(callable, context, divisor));
|
| + assembler->Goto(&loop);
|
| + }
|
| + }
|
| + }
|
| +
|
| + assembler->Bind(÷nd_is_not_smi);
|
| + {
|
| + Node* dividend_map = assembler->LoadMap(dividend);
|
| +
|
| + // Check if {dividend} is a HeapNumber.
|
| + Label dividend_is_number(assembler),
|
| + dividend_is_not_number(assembler, Label::kDeferred);
|
| + assembler->Branch(assembler->WordEqual(dividend_map, number_map),
|
| + ÷nd_is_number, ÷nd_is_not_number);
|
| +
|
| + assembler->Bind(÷nd_is_number);
|
| + {
|
| + // Check if {divisor} is a Smi.
|
| + Label divisor_is_smi(assembler), divisor_is_not_smi(assembler);
|
| + assembler->Branch(assembler->WordIsSmi(divisor), &divisor_is_smi,
|
| + &divisor_is_not_smi);
|
| +
|
| + assembler->Bind(&divisor_is_smi);
|
| + {
|
| + // Convert {divisor} to a double and compute {dividend}'s modulus with
|
| + // it.
|
| + var_dividend_float64.Bind(assembler->LoadHeapNumberValue(dividend));
|
| + var_divisor_float64.Bind(assembler->SmiToFloat64(divisor));
|
| + assembler->Goto(&do_fmod);
|
| + }
|
| +
|
| + assembler->Bind(&divisor_is_not_smi);
|
| + {
|
| + Node* divisor_map = assembler->LoadMap(divisor);
|
| +
|
| + // Check if {divisor} is a HeapNumber.
|
| + Label divisor_is_number(assembler),
|
| + divisor_is_not_number(assembler, Label::kDeferred);
|
| + assembler->Branch(assembler->WordEqual(divisor_map, number_map),
|
| + &divisor_is_number, &divisor_is_not_number);
|
| +
|
| + assembler->Bind(&divisor_is_number);
|
| + {
|
| + // Both {dividend} and {divisor} are HeapNumbers. Load their values
|
| + // and compute their modulus.
|
| + var_dividend_float64.Bind(assembler->LoadHeapNumberValue(dividend));
|
| + var_divisor_float64.Bind(assembler->LoadHeapNumberValue(divisor));
|
| + assembler->Goto(&do_fmod);
|
| + }
|
| +
|
| + assembler->Bind(&divisor_is_not_number);
|
| + {
|
| + // Convert {divisor} to a number and loop.
|
| + Callable callable =
|
| + CodeFactory::NonNumberToNumber(assembler->isolate());
|
| + var_divisor.Bind(assembler->CallStub(callable, context, divisor));
|
| + assembler->Goto(&loop);
|
| + }
|
| + }
|
| + }
|
| +
|
| + assembler->Bind(÷nd_is_not_number);
|
| + {
|
| + // Convert {dividend} to a Number and loop.
|
| + Callable callable =
|
| + CodeFactory::NonNumberToNumber(assembler->isolate());
|
| + var_dividend.Bind(assembler->CallStub(callable, context, dividend));
|
| + assembler->Goto(&loop);
|
| + }
|
| + }
|
| + }
|
| +
|
| + assembler->Bind(&do_fmod);
|
| + {
|
| + Node* value = assembler->Float64Mod(var_dividend_float64.value(),
|
| + var_divisor_float64.value());
|
| + var_result.Bind(assembler->ChangeFloat64ToTagged(value));
|
| + assembler->Goto(&return_result);
|
| + }
|
| +
|
| + assembler->Bind(&return_result);
|
| + assembler->Return(var_result.value());
|
| +}
|
| +
|
| +void Builtins::Generate_ShiftLeft(CodeStubAssembler* assembler) {
|
| + compiler::Node* left = assembler->Parameter(0);
|
| + compiler::Node* right = assembler->Parameter(1);
|
| + compiler::Node* context = assembler->Parameter(2);
|
| +
|
| + using compiler::Node;
|
| +
|
| + Node* lhs_value = assembler->TruncateTaggedToWord32(context, left);
|
| + Node* rhs_value = assembler->TruncateTaggedToWord32(context, right);
|
| + Node* shift_count =
|
| + assembler->Word32And(rhs_value, assembler->Int32Constant(0x1f));
|
| + Node* value = assembler->Word32Shl(lhs_value, shift_count);
|
| + Node* result = assembler->ChangeInt32ToTagged(value);
|
| + assembler->Return(result);
|
| +}
|
| +
|
| +void Builtins::Generate_ShiftRight(CodeStubAssembler* assembler) {
|
| + compiler::Node* left = assembler->Parameter(0);
|
| + compiler::Node* right = assembler->Parameter(1);
|
| + compiler::Node* context = assembler->Parameter(2);
|
| +
|
| + using compiler::Node;
|
| +
|
| + Node* lhs_value = assembler->TruncateTaggedToWord32(context, left);
|
| + Node* rhs_value = assembler->TruncateTaggedToWord32(context, right);
|
| + Node* shift_count =
|
| + assembler->Word32And(rhs_value, assembler->Int32Constant(0x1f));
|
| + Node* value = assembler->Word32Sar(lhs_value, shift_count);
|
| + Node* result = assembler->ChangeInt32ToTagged(value);
|
| + assembler->Return(result);
|
| +}
|
| +
|
| +void Builtins::Generate_ShiftRightLogical(CodeStubAssembler* assembler) {
|
| + compiler::Node* left = assembler->Parameter(0);
|
| + compiler::Node* right = assembler->Parameter(1);
|
| + compiler::Node* context = assembler->Parameter(2);
|
| +
|
| + using compiler::Node;
|
| +
|
| + Node* lhs_value = assembler->TruncateTaggedToWord32(context, left);
|
| + Node* rhs_value = assembler->TruncateTaggedToWord32(context, right);
|
| + Node* shift_count =
|
| + assembler->Word32And(rhs_value, assembler->Int32Constant(0x1f));
|
| + Node* value = assembler->Word32Shr(lhs_value, shift_count);
|
| + Node* result = assembler->ChangeUint32ToTagged(value);
|
| + assembler->Return(result);
|
| +}
|
| +
|
| +void Builtins::Generate_BitwiseAnd(CodeStubAssembler* assembler) {
|
| + compiler::Node* left = assembler->Parameter(0);
|
| + compiler::Node* right = assembler->Parameter(1);
|
| + compiler::Node* context = assembler->Parameter(2);
|
| +
|
| + using compiler::Node;
|
| +
|
| + Node* lhs_value = assembler->TruncateTaggedToWord32(context, left);
|
| + Node* rhs_value = assembler->TruncateTaggedToWord32(context, right);
|
| + Node* value = assembler->Word32And(lhs_value, rhs_value);
|
| + Node* result = assembler->ChangeInt32ToTagged(value);
|
| + assembler->Return(result);
|
| +}
|
| +
|
| +void Builtins::Generate_BitwiseOr(CodeStubAssembler* assembler) {
|
| + compiler::Node* left = assembler->Parameter(0);
|
| + compiler::Node* right = assembler->Parameter(1);
|
| + compiler::Node* context = assembler->Parameter(2);
|
| +
|
| + using compiler::Node;
|
| +
|
| + Node* lhs_value = assembler->TruncateTaggedToWord32(context, left);
|
| + Node* rhs_value = assembler->TruncateTaggedToWord32(context, right);
|
| + Node* value = assembler->Word32Or(lhs_value, rhs_value);
|
| + Node* result = assembler->ChangeInt32ToTagged(value);
|
| + assembler->Return(result);
|
| +}
|
| +
|
| +void Builtins::Generate_BitwiseXor(CodeStubAssembler* assembler) {
|
| + compiler::Node* left = assembler->Parameter(0);
|
| + compiler::Node* right = assembler->Parameter(1);
|
| + compiler::Node* context = assembler->Parameter(2);
|
| +
|
| + using compiler::Node;
|
| +
|
| + Node* lhs_value = assembler->TruncateTaggedToWord32(context, left);
|
| + Node* rhs_value = assembler->TruncateTaggedToWord32(context, right);
|
| + Node* value = assembler->Word32Xor(lhs_value, rhs_value);
|
| + Node* result = assembler->ChangeInt32ToTagged(value);
|
| + assembler->Return(result);
|
| +}
|
| +
|
| +void Builtins::Generate_LessThan(CodeStubAssembler* assembler) {
|
| + compiler::Node* lhs = assembler->Parameter(0);
|
| + compiler::Node* rhs = assembler->Parameter(1);
|
| + compiler::Node* context = assembler->Parameter(2);
|
| +
|
| + assembler->Return(assembler->RelationalComparison(
|
| + CodeStubAssembler::kLessThan, lhs, rhs, context));
|
| +}
|
| +
|
| +void Builtins::Generate_LessThanOrEqual(CodeStubAssembler* assembler) {
|
| + compiler::Node* lhs = assembler->Parameter(0);
|
| + compiler::Node* rhs = assembler->Parameter(1);
|
| + compiler::Node* context = assembler->Parameter(2);
|
| +
|
| + assembler->Return(assembler->RelationalComparison(
|
| + CodeStubAssembler::kLessThanOrEqual, lhs, rhs, context));
|
| +}
|
| +
|
| +void Builtins::Generate_GreaterThan(CodeStubAssembler* assembler) {
|
| + compiler::Node* lhs = assembler->Parameter(0);
|
| + compiler::Node* rhs = assembler->Parameter(1);
|
| + compiler::Node* context = assembler->Parameter(2);
|
| +
|
| + assembler->Return(assembler->RelationalComparison(
|
| + CodeStubAssembler::kGreaterThan, lhs, rhs, context));
|
| +}
|
| +
|
| +void Builtins::Generate_GreaterThanOrEqual(CodeStubAssembler* assembler) {
|
| + compiler::Node* lhs = assembler->Parameter(0);
|
| + compiler::Node* rhs = assembler->Parameter(1);
|
| + compiler::Node* context = assembler->Parameter(2);
|
| +
|
| + assembler->Return(assembler->RelationalComparison(
|
| + CodeStubAssembler::kGreaterThanOrEqual, lhs, rhs, context));
|
| +}
|
| +
|
| +void Builtins::Generate_Equal(CodeStubAssembler* assembler) {
|
| + compiler::Node* lhs = assembler->Parameter(0);
|
| + compiler::Node* rhs = assembler->Parameter(1);
|
| + compiler::Node* context = assembler->Parameter(2);
|
| +
|
| + assembler->Return(assembler->Equal(CodeStubAssembler::kDontNegateResult, lhs,
|
| + rhs, context));
|
| +}
|
| +
|
| +void Builtins::Generate_NotEqual(CodeStubAssembler* assembler) {
|
| + compiler::Node* lhs = assembler->Parameter(0);
|
| + compiler::Node* rhs = assembler->Parameter(1);
|
| + compiler::Node* context = assembler->Parameter(2);
|
| +
|
| + assembler->Return(
|
| + assembler->Equal(CodeStubAssembler::kNegateResult, lhs, rhs, context));
|
| +}
|
| +
|
| +void Builtins::Generate_StrictEqual(CodeStubAssembler* assembler) {
|
| + compiler::Node* lhs = assembler->Parameter(0);
|
| + compiler::Node* rhs = assembler->Parameter(1);
|
| + compiler::Node* context = assembler->Parameter(2);
|
| +
|
| + assembler->Return(assembler->StrictEqual(CodeStubAssembler::kDontNegateResult,
|
| + lhs, rhs, context));
|
| +}
|
| +
|
| +void Builtins::Generate_StrictNotEqual(CodeStubAssembler* assembler) {
|
| + compiler::Node* lhs = assembler->Parameter(0);
|
| + compiler::Node* rhs = assembler->Parameter(1);
|
| + compiler::Node* context = assembler->Parameter(2);
|
| +
|
| + assembler->Return(assembler->StrictEqual(CodeStubAssembler::kNegateResult,
|
| + lhs, rhs, context));
|
| +}
|
| +
|
| } // namespace internal
|
| } // namespace v8
|
|
|
Chromium Code Reviews
Issue 2372113004:
[turbofan] JSGenericLowering mostly uses builtins instead of code stubs now (Closed)
