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v8/test/unittests/compiler/instruction-selector-unittest.cc
danno 5319b50c85 [turbofan] Support variable size argument removal in TF-generated functions 
This is preparation for using TF to create builtins that handle variable number of
arguments and have to remove these arguments dynamically from the stack upon
return.

The gist of the changes:
- Added a second argument to the Return node which specifies the number of stack
  slots to pop upon return in addition to those specified by the Linkage of the
  compiled function.
- Removed Tail -> Non-Tail fallback in the instruction selector. Since TF now should
  handles all tail-call cases except where the return value type differs, this fallback
  was not really useful and in fact caused unexpected behavior with variable
  sized argument popping, since it wasn't possible to materialize a Return node
  with the right pop count from the TailCall without additional context.
- Modified existing Return generation to pass a constant zero as the additional
  pop argument since the variable pop functionality

LOG=N

Review-Url: https://codereview.chromium.org/2446543002
Cr-Commit-Position: refs/heads/master@{#40678}
2016-10-31 16:54:24 +00:00

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// Copyright 2014 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 "test/unittests/compiler/instruction-selector-unittest.h"
#include "src/code-factory.h"
#include "src/compiler/graph.h"
#include "src/compiler/schedule.h"
#include "src/flags.h"
#include "test/unittests/compiler/compiler-test-utils.h"
namespace v8 {
namespace internal {
namespace compiler {
InstructionSelectorTest::InstructionSelectorTest() : rng_(FLAG_random_seed) {}
InstructionSelectorTest::~InstructionSelectorTest() {}
InstructionSelectorTest::Stream InstructionSelectorTest::StreamBuilder::Build(
InstructionSelector::Features features,
InstructionSelectorTest::StreamBuilderMode mode,
InstructionSelector::SourcePositionMode source_position_mode) {
Schedule* schedule = Export();
if (FLAG_trace_turbo) {
OFStream out(stdout);
out << "=== Schedule before instruction selection ===" << std::endl
<< *schedule;
}
size_t const node_count = graph()->NodeCount();
EXPECT_NE(0u, node_count);
Linkage linkage(call_descriptor());
InstructionBlocks* instruction_blocks =
InstructionSequence::InstructionBlocksFor(test_->zone(), schedule);
InstructionSequence sequence(test_->isolate(), test_->zone(),
instruction_blocks);
SourcePositionTable source_position_table(graph());
InstructionSelector selector(test_->zone(), node_count, &linkage, &sequence,
schedule, &source_position_table, nullptr,
source_position_mode, features,
InstructionSelector::kDisableScheduling);
selector.SelectInstructions();
if (FLAG_trace_turbo) {
OFStream out(stdout);
PrintableInstructionSequence printable = {RegisterConfiguration::Turbofan(),
&sequence};
out << "=== Code sequence after instruction selection ===" << std::endl
<< printable;
}
Stream s;
s.virtual_registers_ = selector.GetVirtualRegistersForTesting();
// Map virtual registers.
for (Instruction* const instr : sequence) {
if (instr->opcode() < 0) continue;
if (mode == kTargetInstructions) {
switch (instr->arch_opcode()) {
#define CASE(Name) \
case k##Name: \
break;
TARGET_ARCH_OPCODE_LIST(CASE)
#undef CASE
default:
continue;
}
}
if (mode == kAllExceptNopInstructions && instr->arch_opcode() == kArchNop) {
continue;
}
for (size_t i = 0; i < instr->OutputCount(); ++i) {
InstructionOperand* output = instr->OutputAt(i);
EXPECT_NE(InstructionOperand::IMMEDIATE, output->kind());
if (output->IsConstant()) {
int vreg = ConstantOperand::cast(output)->virtual_register();
s.constants_.insert(std::make_pair(vreg, sequence.GetConstant(vreg)));
}
}
for (size_t i = 0; i < instr->InputCount(); ++i) {
InstructionOperand* input = instr->InputAt(i);
EXPECT_NE(InstructionOperand::CONSTANT, input->kind());
if (input->IsImmediate()) {
auto imm = ImmediateOperand::cast(input);
if (imm->type() == ImmediateOperand::INDEXED) {
int index = imm->indexed_value();
s.immediates_.insert(
std::make_pair(index, sequence.GetImmediate(imm)));
}
}
}
s.instructions_.push_back(instr);
}
for (auto i : s.virtual_registers_) {
int const virtual_register = i.second;
if (sequence.IsFP(virtual_register)) {
EXPECT_FALSE(sequence.IsReference(virtual_register));
s.doubles_.insert(virtual_register);
}
if (sequence.IsReference(virtual_register)) {
EXPECT_FALSE(sequence.IsFP(virtual_register));
s.references_.insert(virtual_register);
}
}
for (int i = 0; i < sequence.GetDeoptimizationEntryCount(); i++) {
s.deoptimization_entries_.push_back(
sequence.GetDeoptimizationEntry(i).descriptor());
}
return s;
}
int InstructionSelectorTest::Stream::ToVreg(const Node* node) const {
VirtualRegisters::const_iterator i = virtual_registers_.find(node->id());
CHECK(i != virtual_registers_.end());
return i->second;
}
bool InstructionSelectorTest::Stream::IsFixed(const InstructionOperand* operand,
Register reg) const {
if (!operand->IsUnallocated()) return false;
const UnallocatedOperand* unallocated = UnallocatedOperand::cast(operand);
if (!unallocated->HasFixedRegisterPolicy()) return false;
return unallocated->fixed_register_index() == reg.code();
}
bool InstructionSelectorTest::Stream::IsSameAsFirst(
const InstructionOperand* operand) const {
if (!operand->IsUnallocated()) return false;
const UnallocatedOperand* unallocated = UnallocatedOperand::cast(operand);
return unallocated->HasSameAsInputPolicy();
}
bool InstructionSelectorTest::Stream::IsUsedAtStart(
const InstructionOperand* operand) const {
if (!operand->IsUnallocated()) return false;
const UnallocatedOperand* unallocated = UnallocatedOperand::cast(operand);
return unallocated->IsUsedAtStart();
}
const FrameStateFunctionInfo*
InstructionSelectorTest::StreamBuilder::GetFrameStateFunctionInfo(
int parameter_count, int local_count) {
return common()->CreateFrameStateFunctionInfo(
FrameStateType::kJavaScriptFunction, parameter_count, local_count,
Handle<SharedFunctionInfo>());
}
// -----------------------------------------------------------------------------
// Return.
TARGET_TEST_F(InstructionSelectorTest, ReturnFloat32Constant) {
const float kValue = 4.2f;
StreamBuilder m(this, MachineType::Float32());
m.Return(m.Float32Constant(kValue));
Stream s = m.Build(kAllInstructions);
ASSERT_EQ(3U, s.size());
EXPECT_EQ(kArchNop, s[0]->arch_opcode());
ASSERT_EQ(InstructionOperand::CONSTANT, s[0]->OutputAt(0)->kind());
EXPECT_FLOAT_EQ(kValue, s.ToFloat32(s[0]->OutputAt(0)));
EXPECT_EQ(kArchRet, s[1]->arch_opcode());
EXPECT_EQ(2U, s[1]->InputCount());
}
TARGET_TEST_F(InstructionSelectorTest, ReturnParameter) {
StreamBuilder m(this, MachineType::Int32(), MachineType::Int32());
m.Return(m.Parameter(0));
Stream s = m.Build(kAllInstructions);
ASSERT_EQ(3U, s.size());
EXPECT_EQ(kArchNop, s[0]->arch_opcode());
ASSERT_EQ(1U, s[0]->OutputCount());
EXPECT_EQ(kArchRet, s[1]->arch_opcode());
EXPECT_EQ(2U, s[1]->InputCount());
}
TARGET_TEST_F(InstructionSelectorTest, ReturnZero) {
StreamBuilder m(this, MachineType::Int32());
m.Return(m.Int32Constant(0));
Stream s = m.Build(kAllInstructions);
ASSERT_EQ(3U, s.size());
EXPECT_EQ(kArchNop, s[0]->arch_opcode());
ASSERT_EQ(1U, s[0]->OutputCount());
EXPECT_EQ(InstructionOperand::CONSTANT, s[0]->OutputAt(0)->kind());
EXPECT_EQ(0, s.ToInt32(s[0]->OutputAt(0)));
EXPECT_EQ(kArchRet, s[1]->arch_opcode());
EXPECT_EQ(2U, s[1]->InputCount());
}
// -----------------------------------------------------------------------------
// Conversions.
TARGET_TEST_F(InstructionSelectorTest, TruncateFloat64ToWord32WithParameter) {
StreamBuilder m(this, MachineType::Int32(), MachineType::Float64());
m.Return(m.TruncateFloat64ToWord32(m.Parameter(0)));
Stream s = m.Build(kAllInstructions);
ASSERT_EQ(4U, s.size());
EXPECT_EQ(kArchNop, s[0]->arch_opcode());
EXPECT_EQ(kArchTruncateDoubleToI, s[1]->arch_opcode());
EXPECT_EQ(1U, s[1]->InputCount());
EXPECT_EQ(1U, s[1]->OutputCount());
EXPECT_EQ(kArchRet, s[2]->arch_opcode());
}
// -----------------------------------------------------------------------------
// Parameters.
TARGET_TEST_F(InstructionSelectorTest, DoubleParameter) {
StreamBuilder m(this, MachineType::Float64(), MachineType::Float64());
Node* param = m.Parameter(0);
m.Return(param);
Stream s = m.Build(kAllInstructions);
EXPECT_TRUE(s.IsDouble(param));
}
TARGET_TEST_F(InstructionSelectorTest, ReferenceParameter) {
StreamBuilder m(this, MachineType::AnyTagged(), MachineType::AnyTagged());
Node* param = m.Parameter(0);
m.Return(param);
Stream s = m.Build(kAllInstructions);
EXPECT_TRUE(s.IsReference(param));
}
// -----------------------------------------------------------------------------
// FinishRegion.
TARGET_TEST_F(InstructionSelectorTest, FinishRegion) {
StreamBuilder m(this, MachineType::AnyTagged(), MachineType::AnyTagged());
Node* param = m.Parameter(0);
Node* finish =
m.AddNode(m.common()->FinishRegion(), param, m.graph()->start());
m.Return(finish);
Stream s = m.Build(kAllInstructions);
ASSERT_EQ(3U, s.size());
EXPECT_EQ(kArchNop, s[0]->arch_opcode());
ASSERT_EQ(1U, s[0]->OutputCount());
ASSERT_TRUE(s[0]->Output()->IsUnallocated());
EXPECT_EQ(kArchRet, s[1]->arch_opcode());
EXPECT_EQ(s.ToVreg(param), s.ToVreg(s[0]->Output()));
EXPECT_EQ(s.ToVreg(param), s.ToVreg(s[1]->InputAt(1)));
EXPECT_TRUE(s.IsReference(finish));
}
// -----------------------------------------------------------------------------
// Phi.
typedef InstructionSelectorTestWithParam<MachineType>
InstructionSelectorPhiTest;
TARGET_TEST_P(InstructionSelectorPhiTest, Doubleness) {
const MachineType type = GetParam();
StreamBuilder m(this, type, type, type);
Node* param0 = m.Parameter(0);
Node* param1 = m.Parameter(1);
RawMachineLabel a, b, c;
m.Branch(m.Int32Constant(0), &a, &b);
m.Bind(&a);
m.Goto(&c);
m.Bind(&b);
m.Goto(&c);
m.Bind(&c);
Node* phi = m.Phi(type.representation(), param0, param1);
m.Return(phi);
Stream s = m.Build(kAllInstructions);
EXPECT_EQ(s.IsDouble(phi), s.IsDouble(param0));
EXPECT_EQ(s.IsDouble(phi), s.IsDouble(param1));
}
TARGET_TEST_P(InstructionSelectorPhiTest, Referenceness) {
const MachineType type = GetParam();
StreamBuilder m(this, type, type, type);
Node* param0 = m.Parameter(0);
Node* param1 = m.Parameter(1);
RawMachineLabel a, b, c;
m.Branch(m.Int32Constant(1), &a, &b);
m.Bind(&a);
m.Goto(&c);
m.Bind(&b);
m.Goto(&c);
m.Bind(&c);
Node* phi = m.Phi(type.representation(), param0, param1);
m.Return(phi);
Stream s = m.Build(kAllInstructions);
EXPECT_EQ(s.IsReference(phi), s.IsReference(param0));
EXPECT_EQ(s.IsReference(phi), s.IsReference(param1));
}
INSTANTIATE_TEST_CASE_P(
InstructionSelectorTest, InstructionSelectorPhiTest,
::testing::Values(MachineType::Float64(), MachineType::Int8(),
MachineType::Uint8(), MachineType::Int16(),
MachineType::Uint16(), MachineType::Int32(),
MachineType::Uint32(), MachineType::Int64(),
MachineType::Uint64(), MachineType::Pointer(),
MachineType::AnyTagged()));
// -----------------------------------------------------------------------------
// ValueEffect.
TARGET_TEST_F(InstructionSelectorTest, ValueEffect) {
StreamBuilder m1(this, MachineType::Int32(), MachineType::Pointer());
Node* p1 = m1.Parameter(0);
m1.Return(m1.Load(MachineType::Int32(), p1, m1.Int32Constant(0)));
Stream s1 = m1.Build(kAllInstructions);
StreamBuilder m2(this, MachineType::Int32(), MachineType::Pointer());
Node* p2 = m2.Parameter(0);
m2.Return(m2.AddNode(
m2.machine()->Load(MachineType::Int32()), p2, m2.Int32Constant(0),
m2.AddNode(m2.common()->BeginRegion(RegionObservability::kObservable),
m2.graph()->start())));
Stream s2 = m2.Build(kAllInstructions);
EXPECT_LE(3U, s1.size());
ASSERT_EQ(s1.size(), s2.size());
TRACED_FORRANGE(size_t, i, 0, s1.size() - 1) {
const Instruction* i1 = s1[i];
const Instruction* i2 = s2[i];
EXPECT_EQ(i1->arch_opcode(), i2->arch_opcode());
EXPECT_EQ(i1->InputCount(), i2->InputCount());
EXPECT_EQ(i1->OutputCount(), i2->OutputCount());
}
}
// -----------------------------------------------------------------------------
// Calls with deoptimization.
TARGET_TEST_F(InstructionSelectorTest, CallJSFunctionWithDeopt) {
StreamBuilder m(this, MachineType::AnyTagged(), MachineType::AnyTagged(),
MachineType::AnyTagged(), MachineType::AnyTagged());
BailoutId bailout_id(42);
Node* function_node = m.Parameter(0);
Node* receiver = m.Parameter(1);
Node* context = m.Parameter(2);
ZoneVector<MachineType> int32_type(1, MachineType::Int32(), zone());
ZoneVector<MachineType> empty_types(zone());
CallDescriptor* descriptor = Linkage::GetJSCallDescriptor(
zone(), false, 1, CallDescriptor::kNeedsFrameState);
// Build frame state for the state before the call.
Node* parameters =
m.AddNode(m.common()->TypedStateValues(&int32_type), m.Int32Constant(1));
Node* locals = m.AddNode(m.common()->TypedStateValues(&empty_types));
Node* stack = m.AddNode(m.common()->TypedStateValues(&empty_types));
Node* context_sentinel = m.Int32Constant(0);
Node* state_node = m.AddNode(
m.common()->FrameState(bailout_id, OutputFrameStateCombine::Push(),
m.GetFrameStateFunctionInfo(1, 0)),
parameters, locals, stack, context_sentinel, function_node,
m.UndefinedConstant());
// Build the call.
Node* args[] = {receiver, m.UndefinedConstant(), m.Int32Constant(1), context};
Node* call =
m.CallNWithFrameState(descriptor, function_node, args, state_node);
m.Return(call);
Stream s = m.Build(kAllExceptNopInstructions);
// Skip until kArchCallJSFunction.
size_t index = 0;
for (; index < s.size() && s[index]->arch_opcode() != kArchCallJSFunction;
index++) {
}
// Now we should have two instructions: call and return.
ASSERT_EQ(index + 2, s.size());
EXPECT_EQ(kArchCallJSFunction, s[index++]->arch_opcode());
EXPECT_EQ(kArchRet, s[index++]->arch_opcode());
// TODO(jarin) Check deoptimization table.
}
TARGET_TEST_F(InstructionSelectorTest, CallStubWithDeopt) {
StreamBuilder m(this, MachineType::AnyTagged(), MachineType::AnyTagged(),
MachineType::AnyTagged(), MachineType::AnyTagged());
BailoutId bailout_id_before(42);
// Some arguments for the call node.
Node* function_node = m.Parameter(0);
Node* receiver = m.Parameter(1);
Node* context = m.Int32Constant(1); // Context is ignored.
ZoneVector<MachineType> int32_type(1, MachineType::Int32(), zone());
ZoneVector<MachineType> float64_type(1, MachineType::Float64(), zone());
ZoneVector<MachineType> tagged_type(1, MachineType::AnyTagged(), zone());
Callable callable = CodeFactory::ToObject(isolate());
CallDescriptor* descriptor = Linkage::GetStubCallDescriptor(
isolate(), zone(), callable.descriptor(), 1,
CallDescriptor::kNeedsFrameState, Operator::kNoProperties);
// Build frame state for the state before the call.
Node* parameters =
m.AddNode(m.common()->TypedStateValues(&int32_type), m.Int32Constant(43));
Node* locals = m.AddNode(m.common()->TypedStateValues(&float64_type),
m.Float64Constant(0.5));
Node* stack = m.AddNode(m.common()->TypedStateValues(&tagged_type),
m.UndefinedConstant());
Node* context_sentinel = m.Int32Constant(0);
Node* state_node = m.AddNode(
m.common()->FrameState(bailout_id_before, OutputFrameStateCombine::Push(),
m.GetFrameStateFunctionInfo(1, 1)),
parameters, locals, stack, context_sentinel, function_node,
m.UndefinedConstant());
// Build the call.
Node* args[] = {function_node, receiver, context};
Node* stub_code = m.HeapConstant(callable.code());
Node* call = m.CallNWithFrameState(descriptor, stub_code, args, state_node);
m.Return(call);
Stream s = m.Build(kAllExceptNopInstructions);
// Skip until kArchCallJSFunction.
size_t index = 0;
for (; index < s.size() && s[index]->arch_opcode() != kArchCallCodeObject;
index++) {
}
// Now we should have two instructions: call, return.
ASSERT_EQ(index + 2, s.size());
// Check the call instruction
const Instruction* call_instr = s[index++];
EXPECT_EQ(kArchCallCodeObject, call_instr->arch_opcode());
size_t num_operands =
1 + // Code object.
1 +
5 + // Frame state deopt id + one input for each value in frame state.
1 + // Function.
1; // Context.
ASSERT_EQ(num_operands, call_instr->InputCount());
// Code object.
EXPECT_TRUE(call_instr->InputAt(0)->IsImmediate());
// Deoptimization id.
int32_t deopt_id_before = s.ToInt32(call_instr->InputAt(1));
FrameStateDescriptor* desc_before =
s.GetFrameStateDescriptor(deopt_id_before);
EXPECT_EQ(bailout_id_before, desc_before->bailout_id());
EXPECT_EQ(OutputFrameStateCombine::kPushOutput,
desc_before->state_combine().kind());
EXPECT_EQ(1u, desc_before->parameters_count());
EXPECT_EQ(1u, desc_before->locals_count());
EXPECT_EQ(1u, desc_before->stack_count());
EXPECT_EQ(43, s.ToInt32(call_instr->InputAt(3)));
EXPECT_EQ(0, s.ToInt32(call_instr->InputAt(4))); // This should be a context.
// We inserted 0 here.
EXPECT_EQ(0.5, s.ToFloat64(call_instr->InputAt(5)));
EXPECT_TRUE(s.ToHeapObject(call_instr->InputAt(6))->IsUndefined(isolate()));
EXPECT_EQ(MachineType::AnyTagged(),
desc_before->GetType(0)); // function is always
// tagged/any.
EXPECT_EQ(MachineType::Int32(), desc_before->GetType(1));
EXPECT_EQ(MachineType::AnyTagged(),
desc_before->GetType(2)); // context is always
// tagged/any.
EXPECT_EQ(MachineType::Float64(), desc_before->GetType(3));
EXPECT_EQ(MachineType::AnyTagged(), desc_before->GetType(4));
// Function.
EXPECT_EQ(s.ToVreg(function_node), s.ToVreg(call_instr->InputAt(7)));
// Context.
EXPECT_EQ(s.ToVreg(context), s.ToVreg(call_instr->InputAt(8)));
EXPECT_EQ(kArchRet, s[index++]->arch_opcode());
EXPECT_EQ(index, s.size());
}
TARGET_TEST_F(InstructionSelectorTest, CallStubWithDeoptRecursiveFrameState) {
StreamBuilder m(this, MachineType::AnyTagged(), MachineType::AnyTagged(),
MachineType::AnyTagged(), MachineType::AnyTagged());
BailoutId bailout_id_before(42);
BailoutId bailout_id_parent(62);
// Some arguments for the call node.
Node* function_node = m.Parameter(0);
Node* receiver = m.Parameter(1);
Node* context = m.Int32Constant(66);
Node* context2 = m.Int32Constant(46);
ZoneVector<MachineType> int32_type(1, MachineType::Int32(), zone());
ZoneVector<MachineType> int32x2_type(2, MachineType::Int32(), zone());
ZoneVector<MachineType> float64_type(1, MachineType::Float64(), zone());
Callable callable = CodeFactory::ToObject(isolate());
CallDescriptor* descriptor = Linkage::GetStubCallDescriptor(
isolate(), zone(), callable.descriptor(), 1,
CallDescriptor::kNeedsFrameState, Operator::kNoProperties);
// Build frame state for the state before the call.
Node* parameters =
m.AddNode(m.common()->TypedStateValues(&int32_type), m.Int32Constant(63));
Node* locals =
m.AddNode(m.common()->TypedStateValues(&int32_type), m.Int32Constant(64));
Node* stack =
m.AddNode(m.common()->TypedStateValues(&int32_type), m.Int32Constant(65));
Node* frame_state_parent = m.AddNode(
m.common()->FrameState(bailout_id_parent,
OutputFrameStateCombine::Ignore(),
m.GetFrameStateFunctionInfo(1, 1)),
parameters, locals, stack, context, function_node, m.UndefinedConstant());
Node* parameters2 =
m.AddNode(m.common()->TypedStateValues(&int32_type), m.Int32Constant(43));
Node* locals2 = m.AddNode(m.common()->TypedStateValues(&float64_type),
m.Float64Constant(0.25));
Node* stack2 = m.AddNode(m.common()->TypedStateValues(&int32x2_type),
m.Int32Constant(44), m.Int32Constant(45));
Node* state_node = m.AddNode(
m.common()->FrameState(bailout_id_before, OutputFrameStateCombine::Push(),
m.GetFrameStateFunctionInfo(1, 1)),
parameters2, locals2, stack2, context2, function_node,
frame_state_parent);
// Build the call.
Node* args[] = {function_node, receiver, context2};
Node* stub_code = m.HeapConstant(callable.code());
Node* call = m.CallNWithFrameState(descriptor, stub_code, args, state_node);
m.Return(call);
Stream s = m.Build(kAllExceptNopInstructions);
// Skip until kArchCallJSFunction.
size_t index = 0;
for (; index < s.size() && s[index]->arch_opcode() != kArchCallCodeObject;
index++) {
}
// Now we should have three instructions: call, return.
EXPECT_EQ(index + 2, s.size());
// Check the call instruction
const Instruction* call_instr = s[index++];
EXPECT_EQ(kArchCallCodeObject, call_instr->arch_opcode());
size_t num_operands =
1 + // Code object.
1 + // Frame state deopt id
6 + // One input for each value in frame state + context.
5 + // One input for each value in the parent frame state + context.
1 + // Function.
1; // Context.
EXPECT_EQ(num_operands, call_instr->InputCount());
// Code object.
EXPECT_TRUE(call_instr->InputAt(0)->IsImmediate());
// Deoptimization id.
int32_t deopt_id_before = s.ToInt32(call_instr->InputAt(1));
FrameStateDescriptor* desc_before =
s.GetFrameStateDescriptor(deopt_id_before);
FrameStateDescriptor* desc_before_outer = desc_before->outer_state();
EXPECT_EQ(bailout_id_before, desc_before->bailout_id());
EXPECT_EQ(1u, desc_before_outer->parameters_count());
EXPECT_EQ(1u, desc_before_outer->locals_count());
EXPECT_EQ(1u, desc_before_outer->stack_count());
// Values from parent environment.
EXPECT_EQ(MachineType::AnyTagged(), desc_before->GetType(0));
EXPECT_EQ(63, s.ToInt32(call_instr->InputAt(3)));
EXPECT_EQ(MachineType::Int32(), desc_before_outer->GetType(1));
// Context:
EXPECT_EQ(66, s.ToInt32(call_instr->InputAt(4)));
EXPECT_EQ(MachineType::AnyTagged(), desc_before_outer->GetType(2));
EXPECT_EQ(64, s.ToInt32(call_instr->InputAt(5)));
EXPECT_EQ(MachineType::Int32(), desc_before_outer->GetType(3));
EXPECT_EQ(65, s.ToInt32(call_instr->InputAt(6)));
EXPECT_EQ(MachineType::Int32(), desc_before_outer->GetType(4));
// Values from the nested frame.
EXPECT_EQ(1u, desc_before->parameters_count());
EXPECT_EQ(1u, desc_before->locals_count());
EXPECT_EQ(2u, desc_before->stack_count());
EXPECT_EQ(MachineType::AnyTagged(), desc_before->GetType(0));
EXPECT_EQ(43, s.ToInt32(call_instr->InputAt(8)));
EXPECT_EQ(MachineType::Int32(), desc_before->GetType(1));
EXPECT_EQ(46, s.ToInt32(call_instr->InputAt(9)));
EXPECT_EQ(MachineType::AnyTagged(), desc_before->GetType(2));
EXPECT_EQ(0.25, s.ToFloat64(call_instr->InputAt(10)));
EXPECT_EQ(MachineType::Float64(), desc_before->GetType(3));
EXPECT_EQ(44, s.ToInt32(call_instr->InputAt(11)));
EXPECT_EQ(MachineType::Int32(), desc_before->GetType(4));
EXPECT_EQ(45, s.ToInt32(call_instr->InputAt(12)));
EXPECT_EQ(MachineType::Int32(), desc_before->GetType(5));
// Function.
EXPECT_EQ(s.ToVreg(function_node), s.ToVreg(call_instr->InputAt(13)));
// Context.
EXPECT_EQ(s.ToVreg(context2), s.ToVreg(call_instr->InputAt(14)));
// Continuation.
EXPECT_EQ(kArchRet, s[index++]->arch_opcode());
EXPECT_EQ(index, s.size());
}
} // namespace compiler
} // namespace internal
} // namespace v8
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