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v8/test/cctest/test-code-stub-assembler.cc
ishell bcf3da279f [stubs] Fixed tests that prevented LoadICTF stubs from being enabled. 
PrimaryStubCache and SecondaryStubCache: resurrected outdated tests (and enabled stub cache counters in the new LoadIC).
TryProbeStubCache: decreased number of code objects created.

Review-Url: https://codereview.chromium.org/2040193002
Cr-Commit-Position: refs/heads/master@{#36794}
2016-06-07 15:04:49 +00:00

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// 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/base/utils/random-number-generator.h"
#include "src/ic/stub-cache.h"
#include "src/interface-descriptors.h"
#include "src/isolate.h"
#include "test/cctest/compiler/function-tester.h"
namespace v8 {
namespace internal {
using compiler::FunctionTester;
using compiler::Node;
class ZoneHolder {
public:
explicit ZoneHolder(Isolate* isolate) : zone_(isolate->allocator()) {}
Zone* zone() { return &zone_; }
private:
Zone zone_;
};
// Inherit from ZoneHolder in order to create a zone that can be passed to
// CodeStubAssembler base class constructor.
class CodeStubAssemblerTester : private ZoneHolder, public CodeStubAssembler {
public:
// Test generating code for a stub.
CodeStubAssemblerTester(Isolate* isolate,
const CallInterfaceDescriptor& descriptor)
: ZoneHolder(isolate),
CodeStubAssembler(isolate, ZoneHolder::zone(), descriptor,
Code::ComputeFlags(Code::STUB), "test"),
scope_(isolate) {}
// Test generating code for a JS function (e.g. builtins).
CodeStubAssemblerTester(Isolate* isolate, int parameter_count)
: ZoneHolder(isolate),
CodeStubAssembler(isolate, ZoneHolder::zone(), parameter_count,
Code::ComputeFlags(Code::FUNCTION), "test"),
scope_(isolate) {}
// This constructor is intended to be used for creating code objects with
// specific flags.
CodeStubAssemblerTester(Isolate* isolate, Code::Flags flags)
: ZoneHolder(isolate),
CodeStubAssembler(isolate, ZoneHolder::zone(), 0, flags, "test"),
scope_(isolate) {}
Handle<Code> GenerateCodeCloseAndEscape() {
return scope_.CloseAndEscape(GenerateCode());
}
private:
HandleScope scope_;
LocalContext context_;
};
TEST(SimpleSmiReturn) {
Isolate* isolate(CcTest::InitIsolateOnce());
VoidDescriptor descriptor(isolate);
CodeStubAssemblerTester m(isolate, descriptor);
m.Return(m.SmiTag(m.Int32Constant(37)));
Handle<Code> code = m.GenerateCode();
FunctionTester ft(descriptor, code);
MaybeHandle<Object> result = ft.Call();
CHECK_EQ(37, Handle<Smi>::cast(result.ToHandleChecked())->value());
}
TEST(SimpleIntPtrReturn) {
Isolate* isolate(CcTest::InitIsolateOnce());
VoidDescriptor descriptor(isolate);
CodeStubAssemblerTester m(isolate, descriptor);
int test;
m.Return(m.IntPtrConstant(reinterpret_cast<intptr_t>(&test)));
Handle<Code> code = m.GenerateCode();
FunctionTester ft(descriptor, code);
MaybeHandle<Object> result = ft.Call();
CHECK_EQ(reinterpret_cast<intptr_t>(&test),
reinterpret_cast<intptr_t>(*result.ToHandleChecked()));
}
TEST(SimpleDoubleReturn) {
Isolate* isolate(CcTest::InitIsolateOnce());
VoidDescriptor descriptor(isolate);
CodeStubAssemblerTester m(isolate, descriptor);
m.Return(m.NumberConstant(0.5));
Handle<Code> code = m.GenerateCode();
FunctionTester ft(descriptor, code);
MaybeHandle<Object> result = ft.Call();
CHECK_EQ(0.5, Handle<HeapNumber>::cast(result.ToHandleChecked())->value());
}
TEST(SimpleCallRuntime1Arg) {
Isolate* isolate(CcTest::InitIsolateOnce());
VoidDescriptor descriptor(isolate);
CodeStubAssemblerTester m(isolate, descriptor);
Node* context = m.HeapConstant(Handle<Context>(isolate->native_context()));
Node* b = m.SmiTag(m.Int32Constant(0));
m.Return(m.CallRuntime(Runtime::kNumberToSmi, context, b));
Handle<Code> code = m.GenerateCode();
FunctionTester ft(descriptor, code);
MaybeHandle<Object> result = ft.Call();
CHECK_EQ(0, Handle<Smi>::cast(result.ToHandleChecked())->value());
}
TEST(SimpleTailCallRuntime1Arg) {
Isolate* isolate(CcTest::InitIsolateOnce());
VoidDescriptor descriptor(isolate);
CodeStubAssemblerTester m(isolate, descriptor);
Node* context = m.HeapConstant(Handle<Context>(isolate->native_context()));
Node* b = m.SmiTag(m.Int32Constant(0));
m.TailCallRuntime(Runtime::kNumberToSmi, context, b);
Handle<Code> code = m.GenerateCode();
FunctionTester ft(descriptor, code);
MaybeHandle<Object> result = ft.Call();
CHECK_EQ(0, Handle<Smi>::cast(result.ToHandleChecked())->value());
}
TEST(SimpleCallRuntime2Arg) {
Isolate* isolate(CcTest::InitIsolateOnce());
VoidDescriptor descriptor(isolate);
CodeStubAssemblerTester m(isolate, descriptor);
Node* context = m.HeapConstant(Handle<Context>(isolate->native_context()));
Node* a = m.SmiTag(m.Int32Constant(2));
Node* b = m.SmiTag(m.Int32Constant(4));
m.Return(m.CallRuntime(Runtime::kMathPow, context, a, b));
Handle<Code> code = m.GenerateCode();
FunctionTester ft(descriptor, code);
MaybeHandle<Object> result = ft.Call();
CHECK_EQ(16, Handle<Smi>::cast(result.ToHandleChecked())->value());
}
TEST(SimpleTailCallRuntime2Arg) {
Isolate* isolate(CcTest::InitIsolateOnce());
VoidDescriptor descriptor(isolate);
CodeStubAssemblerTester m(isolate, descriptor);
Node* context = m.HeapConstant(Handle<Context>(isolate->native_context()));
Node* a = m.SmiTag(m.Int32Constant(2));
Node* b = m.SmiTag(m.Int32Constant(4));
m.TailCallRuntime(Runtime::kMathPow, context, a, b);
Handle<Code> code = m.GenerateCode();
FunctionTester ft(descriptor, code);
MaybeHandle<Object> result = ft.Call();
CHECK_EQ(16, Handle<Smi>::cast(result.ToHandleChecked())->value());
}
TEST(VariableMerge1) {
Isolate* isolate(CcTest::InitIsolateOnce());
VoidDescriptor descriptor(isolate);
CodeStubAssemblerTester m(isolate, descriptor);
CodeStubAssembler::Variable var1(&m, MachineRepresentation::kTagged);
CodeStubAssembler::Label l1(&m), l2(&m), merge(&m);
Node* temp = m.Int32Constant(0);
var1.Bind(temp);
m.Branch(m.Int32Constant(1), &l1, &l2);
m.Bind(&l1);
CHECK_EQ(var1.value(), temp);
m.Goto(&merge);
m.Bind(&l2);
CHECK_EQ(var1.value(), temp);
m.Goto(&merge);
m.Bind(&merge);
CHECK_EQ(var1.value(), temp);
}
TEST(VariableMerge2) {
Isolate* isolate(CcTest::InitIsolateOnce());
VoidDescriptor descriptor(isolate);
CodeStubAssemblerTester m(isolate, descriptor);
CodeStubAssembler::Variable var1(&m, MachineRepresentation::kTagged);
CodeStubAssembler::Label l1(&m), l2(&m), merge(&m);
Node* temp = m.Int32Constant(0);
var1.Bind(temp);
m.Branch(m.Int32Constant(1), &l1, &l2);
m.Bind(&l1);
CHECK_EQ(var1.value(), temp);
m.Goto(&merge);
m.Bind(&l2);
Node* temp2 = m.Int32Constant(2);
var1.Bind(temp2);
CHECK_EQ(var1.value(), temp2);
m.Goto(&merge);
m.Bind(&merge);
CHECK_NE(var1.value(), temp);
}
TEST(VariableMerge3) {
Isolate* isolate(CcTest::InitIsolateOnce());
VoidDescriptor descriptor(isolate);
CodeStubAssemblerTester m(isolate, descriptor);
CodeStubAssembler::Variable var1(&m, MachineRepresentation::kTagged);
CodeStubAssembler::Variable var2(&m, MachineRepresentation::kTagged);
CodeStubAssembler::Label l1(&m), l2(&m), merge(&m);
Node* temp = m.Int32Constant(0);
var1.Bind(temp);
var2.Bind(temp);
m.Branch(m.Int32Constant(1), &l1, &l2);
m.Bind(&l1);
CHECK_EQ(var1.value(), temp);
m.Goto(&merge);
m.Bind(&l2);
Node* temp2 = m.Int32Constant(2);
var1.Bind(temp2);
CHECK_EQ(var1.value(), temp2);
m.Goto(&merge);
m.Bind(&merge);
CHECK_NE(var1.value(), temp);
CHECK_NE(var1.value(), temp2);
CHECK_EQ(var2.value(), temp);
}
TEST(VariableMergeBindFirst) {
Isolate* isolate(CcTest::InitIsolateOnce());
VoidDescriptor descriptor(isolate);
CodeStubAssemblerTester m(isolate, descriptor);
CodeStubAssembler::Variable var1(&m, MachineRepresentation::kTagged);
CodeStubAssembler::Label l1(&m), l2(&m), merge(&m, &var1), end(&m);
Node* temp = m.Int32Constant(0);
var1.Bind(temp);
m.Branch(m.Int32Constant(1), &l1, &l2);
m.Bind(&l1);
CHECK_EQ(var1.value(), temp);
m.Goto(&merge);
m.Bind(&merge);
CHECK(var1.value() != temp);
CHECK(var1.value() != nullptr);
m.Goto(&end);
m.Bind(&l2);
Node* temp2 = m.Int32Constant(2);
var1.Bind(temp2);
CHECK_EQ(var1.value(), temp2);
m.Goto(&merge);
m.Bind(&end);
CHECK(var1.value() != temp);
CHECK(var1.value() != nullptr);
}
TEST(VariableMergeSwitch) {
Isolate* isolate(CcTest::InitIsolateOnce());
VoidDescriptor descriptor(isolate);
CodeStubAssemblerTester m(isolate, descriptor);
CodeStubAssembler::Variable var1(&m, MachineRepresentation::kTagged);
CodeStubAssembler::Label l1(&m), l2(&m), default_label(&m);
CodeStubAssembler::Label* labels[] = {&l1, &l2};
int32_t values[] = {1, 2};
Node* temp = m.Int32Constant(0);
var1.Bind(temp);
m.Switch(m.Int32Constant(2), &default_label, values, labels, 2);
m.Bind(&l1);
DCHECK_EQ(temp, var1.value());
m.Return(temp);
m.Bind(&l2);
DCHECK_EQ(temp, var1.value());
m.Return(temp);
m.Bind(&default_label);
DCHECK_EQ(temp, var1.value());
m.Return(temp);
}
TEST(FixedArrayAccessSmiIndex) {
Isolate* isolate(CcTest::InitIsolateOnce());
VoidDescriptor descriptor(isolate);
CodeStubAssemblerTester m(isolate, descriptor);
Handle<FixedArray> array = isolate->factory()->NewFixedArray(5);
array->set(4, Smi::FromInt(733));
m.Return(m.LoadFixedArrayElement(m.HeapConstant(array),
m.SmiTag(m.Int32Constant(4)), 0,
CodeStubAssembler::SMI_PARAMETERS));
Handle<Code> code = m.GenerateCode();
FunctionTester ft(descriptor, code);
MaybeHandle<Object> result = ft.Call();
CHECK_EQ(733, Handle<Smi>::cast(result.ToHandleChecked())->value());
}
TEST(LoadHeapNumberValue) {
Isolate* isolate(CcTest::InitIsolateOnce());
VoidDescriptor descriptor(isolate);
CodeStubAssemblerTester m(isolate, descriptor);
Handle<HeapNumber> number = isolate->factory()->NewHeapNumber(1234);
m.Return(m.SmiTag(
m.ChangeFloat64ToUint32(m.LoadHeapNumberValue(m.HeapConstant(number)))));
Handle<Code> code = m.GenerateCode();
FunctionTester ft(descriptor, code);
MaybeHandle<Object> result = ft.Call();
CHECK_EQ(1234, Handle<Smi>::cast(result.ToHandleChecked())->value());
}
TEST(LoadInstanceType) {
Isolate* isolate(CcTest::InitIsolateOnce());
VoidDescriptor descriptor(isolate);
CodeStubAssemblerTester m(isolate, descriptor);
Handle<HeapObject> undefined = isolate->factory()->undefined_value();
m.Return(m.SmiTag(m.LoadInstanceType(m.HeapConstant(undefined))));
Handle<Code> code = m.GenerateCode();
FunctionTester ft(descriptor, code);
MaybeHandle<Object> result = ft.Call();
CHECK_EQ(InstanceType::ODDBALL_TYPE,
Handle<Smi>::cast(result.ToHandleChecked())->value());
}
namespace {
class TestBitField : public BitField<unsigned, 3, 3> {};
} // namespace
TEST(BitFieldDecode) {
Isolate* isolate(CcTest::InitIsolateOnce());
VoidDescriptor descriptor(isolate);
CodeStubAssemblerTester m(isolate, descriptor);
m.Return(m.SmiTag(m.BitFieldDecode<TestBitField>(m.Int32Constant(0x2f))));
Handle<Code> code = m.GenerateCode();
FunctionTester ft(descriptor, code);
MaybeHandle<Object> result = ft.Call();
// value = 00101111
// mask = 00111000
// result = 101
CHECK_EQ(5, Handle<Smi>::cast(result.ToHandleChecked())->value());
}
namespace {
Handle<JSFunction> CreateFunctionFromCode(int parameter_count_with_receiver,
Handle<Code> code) {
Isolate* isolate = code->GetIsolate();
Handle<String> name = isolate->factory()->InternalizeUtf8String("test");
Handle<JSFunction> function =
isolate->factory()->NewFunctionWithoutPrototype(name, code);
function->shared()->set_internal_formal_parameter_count(
parameter_count_with_receiver - 1); // Implicit undefined receiver.
return function;
}
} // namespace
TEST(JSFunction) {
const int kNumParams = 3; // Receiver, left, right.
Isolate* isolate(CcTest::InitIsolateOnce());
CodeStubAssemblerTester m(isolate, kNumParams);
m.Return(m.SmiTag(m.Int32Add(m.SmiToWord32(m.Parameter(1)),
m.SmiToWord32(m.Parameter(2)))));
Handle<Code> code = m.GenerateCode();
Handle<JSFunction> function = CreateFunctionFromCode(kNumParams, code);
Handle<Object> args[] = {Handle<Smi>(Smi::FromInt(23), isolate),
Handle<Smi>(Smi::FromInt(34), isolate)};
MaybeHandle<Object> result =
Execution::Call(isolate, function, isolate->factory()->undefined_value(),
arraysize(args), args);
CHECK_EQ(57, Handle<Smi>::cast(result.ToHandleChecked())->value());
}
TEST(SplitEdgeBranchMerge) {
Isolate* isolate(CcTest::InitIsolateOnce());
VoidDescriptor descriptor(isolate);
CodeStubAssemblerTester m(isolate, descriptor);
CodeStubAssembler::Label l1(&m), merge(&m);
m.Branch(m.Int32Constant(1), &l1, &merge);
m.Bind(&l1);
m.Goto(&merge);
m.Bind(&merge);
USE(m.GenerateCode());
}
TEST(SplitEdgeSwitchMerge) {
Isolate* isolate(CcTest::InitIsolateOnce());
VoidDescriptor descriptor(isolate);
CodeStubAssemblerTester m(isolate, descriptor);
CodeStubAssembler::Label l1(&m), l2(&m), l3(&m), default_label(&m);
CodeStubAssembler::Label* labels[] = {&l1, &l2};
int32_t values[] = {1, 2};
m.Branch(m.Int32Constant(1), &l3, &l1);
m.Bind(&l3);
m.Switch(m.Int32Constant(2), &default_label, values, labels, 2);
m.Bind(&l1);
m.Goto(&l2);
m.Bind(&l2);
m.Goto(&default_label);
m.Bind(&default_label);
USE(m.GenerateCode());
}
TEST(TestToConstant) {
Isolate* isolate(CcTest::InitIsolateOnce());
VoidDescriptor descriptor(isolate);
CodeStubAssemblerTester m(isolate, descriptor);
int32_t value32;
int64_t value64;
Node* a = m.Int32Constant(5);
CHECK(m.ToInt32Constant(a, value32));
CHECK(m.ToInt64Constant(a, value64));
a = m.Int64Constant(static_cast<int64_t>(1) << 32);
CHECK(!m.ToInt32Constant(a, value32));
CHECK(m.ToInt64Constant(a, value64));
a = m.Int64Constant(13);
CHECK(m.ToInt32Constant(a, value32));
CHECK(m.ToInt64Constant(a, value64));
a = m.UndefinedConstant();
CHECK(!m.ToInt32Constant(a, value32));
CHECK(!m.ToInt64Constant(a, value64));
a = m.UndefinedConstant();
CHECK(!m.ToInt32Constant(a, value32));
CHECK(!m.ToInt64Constant(a, value64));
}
TEST(ComputeIntegerHash) {
Isolate* isolate(CcTest::InitIsolateOnce());
const int param_count = 2;
CodeStubAssemblerTester m(isolate, param_count);
m.Return(m.SmiFromWord32(m.ComputeIntegerHash(
m.SmiToWord32(m.Parameter(0)), m.SmiToWord32(m.Parameter(1)))));
Handle<Code> code = m.GenerateCode();
FunctionTester ft(code, param_count);
Handle<Smi> hash_seed = isolate->factory()->hash_seed();
base::RandomNumberGenerator rand_gen(FLAG_random_seed);
for (int i = 0; i < 1024; i++) {
int k = rand_gen.NextInt(Smi::kMaxValue);
Handle<Smi> key(Smi::FromInt(k), isolate);
Handle<Object> result = ft.Call(key, hash_seed).ToHandleChecked();
uint32_t hash = ComputeIntegerHash(k, hash_seed->value());
Smi* expected = Smi::FromInt(hash & Smi::kMaxValue);
CHECK_EQ(expected, Smi::cast(*result));
}
}
TEST(TryToName) {
typedef CodeStubAssembler::Label Label;
typedef CodeStubAssembler::Variable Variable;
Isolate* isolate(CcTest::InitIsolateOnce());
const int param_count = 3;
CodeStubAssemblerTester m(isolate, param_count);
enum Result { kKeyIsIndex, kKeyIsUnique, kBailout };
{
Node* key = m.Parameter(0);
Node* expected_result = m.Parameter(1);
Node* expected_arg = m.Parameter(2);
Label passed(&m), failed(&m);
Label if_keyisindex(&m), if_keyisunique(&m), if_bailout(&m);
Variable var_index(&m, MachineRepresentation::kWord32);
m.TryToName(key, &if_keyisindex, &var_index, &if_keyisunique, &if_bailout);
m.Bind(&if_keyisindex);
m.GotoUnless(
m.WordEqual(expected_result, m.SmiConstant(Smi::FromInt(kKeyIsIndex))),
&failed);
m.Branch(m.Word32Equal(m.SmiToWord32(expected_arg), var_index.value()),
&passed, &failed);
m.Bind(&if_keyisunique);
m.GotoUnless(
m.WordEqual(expected_result, m.SmiConstant(Smi::FromInt(kKeyIsUnique))),
&failed);
m.Branch(m.WordEqual(expected_arg, key), &passed, &failed);
m.Bind(&if_bailout);
m.Branch(
m.WordEqual(expected_result, m.SmiConstant(Smi::FromInt(kBailout))),
&passed, &failed);
m.Bind(&passed);
m.Return(m.BooleanConstant(true));
m.Bind(&failed);
m.Return(m.BooleanConstant(false));
}
Handle<Code> code = m.GenerateCode();
FunctionTester ft(code, param_count);
Handle<Object> expect_index(Smi::FromInt(kKeyIsIndex), isolate);
Handle<Object> expect_unique(Smi::FromInt(kKeyIsUnique), isolate);
Handle<Object> expect_bailout(Smi::FromInt(kBailout), isolate);
{
// TryToName(<zero smi>) => if_keyisindex: smi value.
Handle<Object> key(Smi::FromInt(0), isolate);
ft.CheckTrue(key, expect_index, key);
}
{
// TryToName(<positive smi>) => if_keyisindex: smi value.
Handle<Object> key(Smi::FromInt(153), isolate);
ft.CheckTrue(key, expect_index, key);
}
{
// TryToName(<negative smi>) => bailout.
Handle<Object> key(Smi::FromInt(-1), isolate);
ft.CheckTrue(key, expect_bailout);
}
{
// TryToName(<symbol>) => if_keyisunique: <symbol>.
Handle<Object> key = isolate->factory()->NewSymbol();
ft.CheckTrue(key, expect_unique, key);
}
{
// TryToName(<internalized string>) => if_keyisunique: <internalized string>
Handle<Object> key = isolate->factory()->InternalizeUtf8String("test");
ft.CheckTrue(key, expect_unique, key);
}
{
// TryToName(<internalized number string>) => if_keyisindex: number.
Handle<Object> key = isolate->factory()->InternalizeUtf8String("153");
Handle<Object> index(Smi::FromInt(153), isolate);
ft.CheckTrue(key, expect_index, index);
}
{
// TryToName(<non-internalized string>) => bailout.
Handle<Object> key = isolate->factory()->NewStringFromAsciiChecked("test");
ft.CheckTrue(key, expect_bailout);
}
}
namespace {
template <typename Dictionary>
void TestNameDictionaryLookup() {
typedef CodeStubAssembler::Label Label;
typedef CodeStubAssembler::Variable Variable;
Isolate* isolate(CcTest::InitIsolateOnce());
const int param_count = 4;
CodeStubAssemblerTester m(isolate, param_count);
enum Result { kFound, kNotFound };
{
Node* dictionary = m.Parameter(0);
Node* unique_name = m.Parameter(1);
Node* expected_result = m.Parameter(2);
Node* expected_arg = m.Parameter(3);
Label passed(&m), failed(&m);
Label if_found(&m), if_not_found(&m);
Variable var_entry(&m, MachineRepresentation::kWord32);
m.NameDictionaryLookup<Dictionary>(dictionary, unique_name, &if_found,
&var_entry, &if_not_found);
m.Bind(&if_found);
m.GotoUnless(
m.WordEqual(expected_result, m.SmiConstant(Smi::FromInt(kFound))),
&failed);
m.Branch(m.Word32Equal(m.SmiToWord32(expected_arg), var_entry.value()),
&passed, &failed);
m.Bind(&if_not_found);
m.Branch(
m.WordEqual(expected_result, m.SmiConstant(Smi::FromInt(kNotFound))),
&passed, &failed);
m.Bind(&passed);
m.Return(m.BooleanConstant(true));
m.Bind(&failed);
m.Return(m.BooleanConstant(false));
}
Handle<Code> code = m.GenerateCode();
FunctionTester ft(code, param_count);
Handle<Object> expect_found(Smi::FromInt(kFound), isolate);
Handle<Object> expect_not_found(Smi::FromInt(kNotFound), isolate);
Handle<Dictionary> dictionary = Dictionary::New(isolate, 40);
PropertyDetails fake_details = PropertyDetails::Empty();
Factory* factory = isolate->factory();
Handle<Name> keys[] = {
factory->InternalizeUtf8String("0"),
factory->InternalizeUtf8String("42"),
factory->InternalizeUtf8String("-153"),
factory->InternalizeUtf8String("0.0"),
factory->InternalizeUtf8String("4.2"),
factory->InternalizeUtf8String(""),
factory->InternalizeUtf8String("name"),
factory->NewSymbol(),
factory->NewPrivateSymbol(),
};
for (size_t i = 0; i < arraysize(keys); i++) {
Handle<Object> value = factory->NewPropertyCell();
dictionary = Dictionary::Add(dictionary, keys[i], value, fake_details);
}
for (size_t i = 0; i < arraysize(keys); i++) {
int entry = dictionary->FindEntry(keys[i]);
CHECK_NE(Dictionary::kNotFound, entry);
Handle<Object> expected_entry(Smi::FromInt(entry), isolate);
ft.CheckTrue(dictionary, keys[i], expect_found, expected_entry);
}
Handle<Name> non_existing_keys[] = {
factory->InternalizeUtf8String("1"),
factory->InternalizeUtf8String("-42"),
factory->InternalizeUtf8String("153"),
factory->InternalizeUtf8String("-1.0"),
factory->InternalizeUtf8String("1.3"),
factory->InternalizeUtf8String("a"),
factory->InternalizeUtf8String("boom"),
factory->NewSymbol(),
factory->NewPrivateSymbol(),
};
for (size_t i = 0; i < arraysize(non_existing_keys); i++) {
int entry = dictionary->FindEntry(non_existing_keys[i]);
CHECK_EQ(Dictionary::kNotFound, entry);
ft.CheckTrue(dictionary, non_existing_keys[i], expect_not_found);
}
}
} // namespace
TEST(NameDictionaryLookup) { TestNameDictionaryLookup<NameDictionary>(); }
TEST(GlobalDictionaryLookup) { TestNameDictionaryLookup<GlobalDictionary>(); }
namespace {
template <typename Dictionary>
void TestNumberDictionaryLookup() {
typedef CodeStubAssembler::Label Label;
typedef CodeStubAssembler::Variable Variable;
Isolate* isolate(CcTest::InitIsolateOnce());
const int param_count = 4;
CodeStubAssemblerTester m(isolate, param_count);
enum Result { kFound, kNotFound };
{
Node* dictionary = m.Parameter(0);
Node* key = m.SmiToWord32(m.Parameter(1));
Node* expected_result = m.Parameter(2);
Node* expected_arg = m.Parameter(3);
Label passed(&m), failed(&m);
Label if_found(&m), if_not_found(&m);
Variable var_entry(&m, MachineRepresentation::kWord32);
m.NumberDictionaryLookup<Dictionary>(dictionary, key, &if_found, &var_entry,
&if_not_found);
m.Bind(&if_found);
m.GotoUnless(
m.WordEqual(expected_result, m.SmiConstant(Smi::FromInt(kFound))),
&failed);
m.Branch(m.Word32Equal(m.SmiToWord32(expected_arg), var_entry.value()),
&passed, &failed);
m.Bind(&if_not_found);
m.Branch(
m.WordEqual(expected_result, m.SmiConstant(Smi::FromInt(kNotFound))),
&passed, &failed);
m.Bind(&passed);
m.Return(m.BooleanConstant(true));
m.Bind(&failed);
m.Return(m.BooleanConstant(false));
}
Handle<Code> code = m.GenerateCode();
FunctionTester ft(code, param_count);
Handle<Object> expect_found(Smi::FromInt(kFound), isolate);
Handle<Object> expect_not_found(Smi::FromInt(kNotFound), isolate);
const int kKeysCount = 1000;
Handle<Dictionary> dictionary = Dictionary::New(isolate, kKeysCount);
uint32_t keys[kKeysCount];
Handle<Object> fake_value(Smi::FromInt(42), isolate);
PropertyDetails fake_details = PropertyDetails::Empty();
base::RandomNumberGenerator rand_gen(FLAG_random_seed);
for (int i = 0; i < kKeysCount; i++) {
int random_key = rand_gen.NextInt(Smi::kMaxValue);
keys[i] = static_cast<uint32_t>(random_key);
if (dictionary->FindEntry(keys[i]) != Dictionary::kNotFound) continue;
dictionary = Dictionary::Add(dictionary, keys[i], fake_value, fake_details);
}
// Now try querying existing keys.
for (int i = 0; i < kKeysCount; i++) {
int entry = dictionary->FindEntry(keys[i]);
CHECK_NE(Dictionary::kNotFound, entry);
Handle<Object> key(Smi::FromInt(keys[i]), isolate);
Handle<Object> expected_entry(Smi::FromInt(entry), isolate);
ft.CheckTrue(dictionary, key, expect_found, expected_entry);
}
// Now try querying random keys which do not exist in the dictionary.
for (int i = 0; i < kKeysCount;) {
int random_key = rand_gen.NextInt(Smi::kMaxValue);
int entry = dictionary->FindEntry(random_key);
if (entry != Dictionary::kNotFound) continue;
i++;
Handle<Object> key(Smi::FromInt(random_key), isolate);
ft.CheckTrue(dictionary, key, expect_not_found);
}
}
} // namespace
TEST(SeededNumberDictionaryLookup) {
TestNumberDictionaryLookup<SeededNumberDictionary>();
}
TEST(UnseededNumberDictionaryLookup) {
TestNumberDictionaryLookup<UnseededNumberDictionary>();
}
namespace {
void AddProperties(Handle<JSObject> object, Handle<Name> names[],
size_t count) {
Handle<Object> value(Smi::FromInt(42), object->GetIsolate());
for (size_t i = 0; i < count; i++) {
JSObject::AddProperty(object, names[i], value, NONE);
}
}
} // namespace
TEST(TryLookupProperty) {
typedef CodeStubAssembler::Label Label;
Isolate* isolate(CcTest::InitIsolateOnce());
const int param_count = 4;
CodeStubAssemblerTester m(isolate, param_count);
enum Result { kFound, kNotFound, kBailout };
{
Node* object = m.Parameter(0);
Node* unique_name = m.Parameter(1);
Node* expected_result = m.Parameter(2);
Label passed(&m), failed(&m);
Label if_found(&m), if_not_found(&m), if_bailout(&m);
Node* map = m.LoadMap(object);
Node* instance_type = m.LoadMapInstanceType(map);
m.TryLookupProperty(object, map, instance_type, unique_name, &if_found,
&if_not_found, &if_bailout);
m.Bind(&if_found);
m.Branch(m.WordEqual(expected_result, m.SmiConstant(Smi::FromInt(kFound))),
&passed, &failed);
m.Bind(&if_not_found);
m.Branch(
m.WordEqual(expected_result, m.SmiConstant(Smi::FromInt(kNotFound))),
&passed, &failed);
m.Bind(&if_bailout);
m.Branch(
m.WordEqual(expected_result, m.SmiConstant(Smi::FromInt(kBailout))),
&passed, &failed);
m.Bind(&passed);
m.Return(m.BooleanConstant(true));
m.Bind(&failed);
m.Return(m.BooleanConstant(false));
}
Handle<Code> code = m.GenerateCode();
FunctionTester ft(code, param_count);
Handle<Object> expect_found(Smi::FromInt(kFound), isolate);
Handle<Object> expect_not_found(Smi::FromInt(kNotFound), isolate);
Handle<Object> expect_bailout(Smi::FromInt(kBailout), isolate);
Factory* factory = isolate->factory();
Handle<Name> names[] = {
factory->InternalizeUtf8String("a"),
factory->InternalizeUtf8String("bb"),
factory->InternalizeUtf8String("ccc"),
factory->InternalizeUtf8String("dddd"),
factory->InternalizeUtf8String("eeeee"),
factory->InternalizeUtf8String(""),
factory->InternalizeUtf8String("name"),
factory->NewSymbol(),
factory->NewPrivateSymbol(),
};
std::vector<Handle<JSObject>> objects;
{
Handle<JSFunction> function = factory->NewFunction(factory->empty_string());
Handle<JSObject> object = factory->NewJSObject(function);
AddProperties(object, names, arraysize(names));
CHECK_EQ(JS_OBJECT_TYPE, object->map()->instance_type());
CHECK(!object->map()->is_dictionary_map());
objects.push_back(object);
}
{
Handle<JSFunction> function = factory->NewFunction(factory->empty_string());
Handle<JSObject> object = factory->NewJSObject(function);
AddProperties(object, names, arraysize(names));
JSObject::NormalizeProperties(object, CLEAR_INOBJECT_PROPERTIES, 0, "test");
CHECK_EQ(JS_OBJECT_TYPE, object->map()->instance_type());
CHECK(object->map()->is_dictionary_map());
objects.push_back(object);
}
{
Handle<JSFunction> function = factory->NewFunction(factory->empty_string());
JSFunction::EnsureHasInitialMap(function);
function->initial_map()->set_instance_type(JS_GLOBAL_OBJECT_TYPE);
function->initial_map()->set_is_prototype_map(true);
function->initial_map()->set_dictionary_map(true);
Handle<JSObject> object = factory->NewJSGlobalObject(function);
AddProperties(object, names, arraysize(names));
CHECK_EQ(JS_GLOBAL_OBJECT_TYPE, object->map()->instance_type());
CHECK(object->map()->is_dictionary_map());
objects.push_back(object);
}
{
for (Handle<JSObject> object : objects) {
for (size_t name_index = 0; name_index < arraysize(names); name_index++) {
Handle<Name> name = names[name_index];
CHECK(JSReceiver::HasProperty(object, name).FromJust());
ft.CheckTrue(object, name, expect_found);
}
}
}
{
Handle<Name> non_existing_names[] = {
factory->InternalizeUtf8String("ne_a"),
factory->InternalizeUtf8String("ne_bb"),
factory->InternalizeUtf8String("ne_ccc"),
factory->InternalizeUtf8String("ne_dddd"),
};
for (Handle<JSObject> object : objects) {
for (size_t key_index = 0; key_index < arraysize(non_existing_names);
key_index++) {
Handle<Name> key = non_existing_names[key_index];
CHECK(!JSReceiver::HasProperty(object, key).FromJust());
ft.CheckTrue(object, key, expect_not_found);
}
}
}
{
Handle<JSFunction> function = factory->NewFunction(factory->empty_string());
Handle<JSProxy> object = factory->NewJSProxy(function, objects[0]);
CHECK_EQ(JS_PROXY_TYPE, object->map()->instance_type());
ft.CheckTrue(object, names[0], expect_bailout);
}
{
Handle<JSObject> object = isolate->global_proxy();
CHECK_EQ(JS_GLOBAL_PROXY_TYPE, object->map()->instance_type());
ft.CheckTrue(object, names[0], expect_bailout);
}
}
namespace {
void AddElement(Handle<JSObject> object, uint32_t index, Handle<Object> value,
PropertyAttributes attributes = NONE) {
JSObject::AddDataElement(object, index, value, attributes).ToHandleChecked();
}
} // namespace
TEST(TryLookupElement) {
typedef CodeStubAssembler::Label Label;
Isolate* isolate(CcTest::InitIsolateOnce());
const int param_count = 4;
CodeStubAssemblerTester m(isolate, param_count);
enum Result { kFound, kNotFound, kBailout };
{
Node* object = m.Parameter(0);
Node* index = m.SmiToWord32(m.Parameter(1));
Node* expected_result = m.Parameter(2);
Label passed(&m), failed(&m);
Label if_found(&m), if_not_found(&m), if_bailout(&m);
Node* map = m.LoadMap(object);
Node* instance_type = m.LoadMapInstanceType(map);
m.TryLookupElement(object, map, instance_type, index, &if_found,
&if_not_found, &if_bailout);
m.Bind(&if_found);
m.Branch(m.WordEqual(expected_result, m.SmiConstant(Smi::FromInt(kFound))),
&passed, &failed);
m.Bind(&if_not_found);
m.Branch(
m.WordEqual(expected_result, m.SmiConstant(Smi::FromInt(kNotFound))),
&passed, &failed);
m.Bind(&if_bailout);
m.Branch(
m.WordEqual(expected_result, m.SmiConstant(Smi::FromInt(kBailout))),
&passed, &failed);
m.Bind(&passed);
m.Return(m.BooleanConstant(true));
m.Bind(&failed);
m.Return(m.BooleanConstant(false));
}
Handle<Code> code = m.GenerateCode();
FunctionTester ft(code, param_count);
Factory* factory = isolate->factory();
Handle<Object> smi0(Smi::FromInt(0), isolate);
Handle<Object> smi1(Smi::FromInt(1), isolate);
Handle<Object> smi7(Smi::FromInt(7), isolate);
Handle<Object> smi13(Smi::FromInt(13), isolate);
Handle<Object> smi42(Smi::FromInt(42), isolate);
Handle<Object> expect_found(Smi::FromInt(kFound), isolate);
Handle<Object> expect_not_found(Smi::FromInt(kNotFound), isolate);
Handle<Object> expect_bailout(Smi::FromInt(kBailout), isolate);
#define CHECK_FOUND(object, index) \
CHECK(JSReceiver::HasElement(object, index).FromJust()); \
ft.CheckTrue(object, smi##index, expect_found);
#define CHECK_NOT_FOUND(object, index) \
CHECK(!JSReceiver::HasElement(object, index).FromJust()); \
ft.CheckTrue(object, smi##index, expect_not_found);
{
Handle<JSArray> object = factory->NewJSArray(0, FAST_SMI_ELEMENTS);
AddElement(object, 0, smi0);
AddElement(object, 1, smi0);
CHECK_EQ(FAST_SMI_ELEMENTS, object->map()->elements_kind());
CHECK_FOUND(object, 0);
CHECK_FOUND(object, 1);
CHECK_NOT_FOUND(object, 7);
CHECK_NOT_FOUND(object, 13);
CHECK_NOT_FOUND(object, 42);
}
{
Handle<JSArray> object = factory->NewJSArray(0, FAST_HOLEY_SMI_ELEMENTS);
AddElement(object, 0, smi0);
AddElement(object, 13, smi0);
CHECK_EQ(FAST_HOLEY_SMI_ELEMENTS, object->map()->elements_kind());
CHECK_FOUND(object, 0);
CHECK_NOT_FOUND(object, 1);
CHECK_NOT_FOUND(object, 7);
CHECK_FOUND(object, 13);
CHECK_NOT_FOUND(object, 42);
}
{
Handle<JSArray> object = factory->NewJSArray(0, FAST_ELEMENTS);
AddElement(object, 0, smi0);
AddElement(object, 1, smi0);
CHECK_EQ(FAST_ELEMENTS, object->map()->elements_kind());
CHECK_FOUND(object, 0);
CHECK_FOUND(object, 1);
CHECK_NOT_FOUND(object, 7);
CHECK_NOT_FOUND(object, 13);
CHECK_NOT_FOUND(object, 42);
}
{
Handle<JSArray> object = factory->NewJSArray(0, FAST_HOLEY_ELEMENTS);
AddElement(object, 0, smi0);
AddElement(object, 13, smi0);
CHECK_EQ(FAST_HOLEY_ELEMENTS, object->map()->elements_kind());
CHECK_FOUND(object, 0);
CHECK_NOT_FOUND(object, 1);
CHECK_NOT_FOUND(object, 7);
CHECK_FOUND(object, 13);
CHECK_NOT_FOUND(object, 42);
}
{
Handle<JSFunction> constructor = isolate->string_function();
Handle<JSObject> object = factory->NewJSObject(constructor);
Handle<String> str = factory->InternalizeUtf8String("ab");
Handle<JSValue>::cast(object)->set_value(*str);
AddElement(object, 13, smi0);
CHECK_EQ(FAST_STRING_WRAPPER_ELEMENTS, object->map()->elements_kind());
CHECK_FOUND(object, 0);
CHECK_FOUND(object, 1);
CHECK_NOT_FOUND(object, 7);
CHECK_FOUND(object, 13);
CHECK_NOT_FOUND(object, 42);
}
{
Handle<JSFunction> constructor = isolate->string_function();
Handle<JSObject> object = factory->NewJSObject(constructor);
Handle<String> str = factory->InternalizeUtf8String("ab");
Handle<JSValue>::cast(object)->set_value(*str);
AddElement(object, 13, smi0);
JSObject::NormalizeElements(object);
CHECK_EQ(SLOW_STRING_WRAPPER_ELEMENTS, object->map()->elements_kind());
CHECK_FOUND(object, 0);
CHECK_FOUND(object, 1);
CHECK_NOT_FOUND(object, 7);
CHECK_FOUND(object, 13);
CHECK_NOT_FOUND(object, 42);
}
// TODO(ishell): uncomment once NO_ELEMENTS kind is supported.
// {
// Handle<Map> map = Map::Create(isolate, 0);
// map->set_elements_kind(NO_ELEMENTS);
// Handle<JSObject> object = factory->NewJSObjectFromMap(map);
// CHECK_EQ(NO_ELEMENTS, object->map()->elements_kind());
//
// CHECK_NOT_FOUND(object, 0);
// CHECK_NOT_FOUND(object, 1);
// CHECK_NOT_FOUND(object, 7);
// CHECK_NOT_FOUND(object, 13);
// CHECK_NOT_FOUND(object, 42);
// }
#undef CHECK_FOUND
#undef CHECK_NOT_FOUND
{
Handle<JSArray> handler = factory->NewJSArray(0);
Handle<JSFunction> function = factory->NewFunction(factory->empty_string());
Handle<JSProxy> object = factory->NewJSProxy(function, handler);
CHECK_EQ(JS_PROXY_TYPE, object->map()->instance_type());
ft.CheckTrue(object, smi0, expect_bailout);
}
{
Handle<JSObject> object = isolate->global_object();
CHECK_EQ(JS_GLOBAL_OBJECT_TYPE, object->map()->instance_type());
ft.CheckTrue(object, smi0, expect_bailout);
}
{
Handle<JSObject> object = isolate->global_proxy();
CHECK_EQ(JS_GLOBAL_PROXY_TYPE, object->map()->instance_type());
ft.CheckTrue(object, smi0, expect_bailout);
}
}
TEST(DeferredCodePhiHints) {
typedef compiler::Node Node;
typedef CodeStubAssembler::Label Label;
typedef CodeStubAssembler::Variable Variable;
Isolate* isolate(CcTest::InitIsolateOnce());
VoidDescriptor descriptor(isolate);
CodeStubAssemblerTester m(isolate, descriptor);
Label block1(&m, Label::kDeferred);
m.Goto(&block1);
m.Bind(&block1);
{
Variable var_object(&m, MachineRepresentation::kTagged);
Label loop(&m, &var_object);
var_object.Bind(m.IntPtrConstant(0));
m.Goto(&loop);
m.Bind(&loop);
{
Node* map = m.LoadMap(var_object.value());
var_object.Bind(map);
m.Goto(&loop);
}
}
CHECK(!m.GenerateCode().is_null());
}
TEST(TestOutOfScopeVariable) {
typedef CodeStubAssembler::Label Label;
typedef CodeStubAssembler::Variable Variable;
Isolate* isolate(CcTest::InitIsolateOnce());
VoidDescriptor descriptor(isolate);
CodeStubAssemblerTester m(isolate, descriptor);
Label block1(&m);
Label block2(&m);
Label block3(&m);
Label block4(&m);
m.Branch(m.WordEqual(m.Parameter(0), m.IntPtrConstant(0)), &block1, &block4);
m.Bind(&block4);
{
Variable var_object(&m, MachineRepresentation::kTagged);
m.Branch(m.WordEqual(m.Parameter(0), m.IntPtrConstant(0)), &block2,
&block3);
m.Bind(&block2);
var_object.Bind(m.IntPtrConstant(55));
m.Goto(&block1);
m.Bind(&block3);
var_object.Bind(m.IntPtrConstant(66));
m.Goto(&block1);
}
m.Bind(&block1);
CHECK(!m.GenerateCode().is_null());
}
namespace {
void TestStubCacheOffsetCalculation(StubCache::Table table,
Code::Kind handler_kind) {
Isolate* isolate(CcTest::InitIsolateOnce());
const int param_count = 2;
CodeStubAssemblerTester m(isolate, param_count);
Code::Flags code_flags =
Code::RemoveHolderFromFlags(Code::ComputeHandlerFlags(handler_kind));
{
Node* name = m.Parameter(0);
Node* map = m.Parameter(1);
Node* primary_offset = m.StubCachePrimaryOffset(name, code_flags, map);
Node* result;
if (table == StubCache::kPrimary) {
result = primary_offset;
} else {
CHECK_EQ(StubCache::kSecondary, table);
result = m.StubCacheSecondaryOffset(name, code_flags, primary_offset);
}
m.Return(m.SmiFromWord32(result));
}
Handle<Code> code = m.GenerateCode();
FunctionTester ft(code, param_count);
Factory* factory = isolate->factory();
Handle<Name> names[] = {
factory->NewSymbol(),
factory->InternalizeUtf8String("a"),
factory->InternalizeUtf8String("bb"),
factory->InternalizeUtf8String("ccc"),
factory->NewPrivateSymbol(),
factory->InternalizeUtf8String("dddd"),
factory->InternalizeUtf8String("eeeee"),
factory->InternalizeUtf8String("name"),
factory->NewSymbol(),
factory->NewPrivateSymbol(),
};
Handle<Map> maps[] = {
Handle<Map>(nullptr, isolate),
factory->cell_map(),
Map::Create(isolate, 0),
factory->meta_map(),
factory->code_map(),
Map::Create(isolate, 0),
factory->hash_table_map(),
factory->symbol_map(),
factory->string_map(),
Map::Create(isolate, 0),
factory->sloppy_arguments_elements_map(),
};
for (int name_index = 0; name_index < arraysize(names); name_index++) {
Handle<Name> name = names[name_index];
for (int map_index = 0; map_index < arraysize(maps); map_index++) {
Handle<Map> map = maps[map_index];
int expected_result;
{
int primary_offset =
StubCache::PrimaryOffsetForTesting(*name, code_flags, *map);
if (table == StubCache::kPrimary) {
expected_result = primary_offset;
} else {
expected_result = StubCache::SecondaryOffsetForTesting(
*name, code_flags, primary_offset);
}
}
Handle<Object> result = ft.Call(name, map).ToHandleChecked();
Smi* expected = Smi::FromInt(expected_result & Smi::kMaxValue);
CHECK_EQ(expected, Smi::cast(*result));
}
}
}
} // namespace
TEST(StubCachePrimaryOffsetLoadIC) {
TestStubCacheOffsetCalculation(StubCache::kPrimary, Code::LOAD_IC);
}
TEST(StubCachePrimaryOffsetStoreIC) {
TestStubCacheOffsetCalculation(StubCache::kPrimary, Code::STORE_IC);
}
TEST(StubCacheSecondaryOffsetLoadIC) {
TestStubCacheOffsetCalculation(StubCache::kSecondary, Code::LOAD_IC);
}
TEST(StubCacheSecondaryOffsetStoreIC) {
TestStubCacheOffsetCalculation(StubCache::kSecondary, Code::STORE_IC);
}
namespace {
Handle<Code> CreateCodeWithFlags(Code::Flags flags) {
Isolate* isolate(CcTest::InitIsolateOnce());
CodeStubAssemblerTester m(isolate, flags);
m.Return(m.UndefinedConstant());
return m.GenerateCodeCloseAndEscape();
}
} // namespace
TEST(TryProbeStubCache) {
typedef CodeStubAssembler::Label Label;
typedef CodeStubAssembler::Variable Variable;
Isolate* isolate(CcTest::InitIsolateOnce());
const int param_count = 3;
CodeStubAssemblerTester m(isolate, param_count);
Code::Flags flags_to_query =
Code::RemoveHolderFromFlags(Code::ComputeHandlerFlags(Code::LOAD_IC));
StubCache stub_cache(isolate);
stub_cache.Clear();
{
Node* receiver = m.Parameter(0);
Node* name = m.Parameter(1);
Node* expected_handler = m.Parameter(2);
Label passed(&m), failed(&m);
Variable var_handler(&m, MachineRepresentation::kTagged);
Label if_handler(&m), if_miss(&m);
m.TryProbeStubCache(&stub_cache, flags_to_query, receiver, name,
&if_handler, &var_handler, &if_miss);
m.Bind(&if_handler);
m.BranchIfWordEqual(expected_handler, var_handler.value(), &passed,
&failed);
m.Bind(&if_miss);
m.BranchIfWordEqual(expected_handler, m.IntPtrConstant(0), &passed,
&failed);
m.Bind(&passed);
m.Return(m.BooleanConstant(true));
m.Bind(&failed);
m.Return(m.BooleanConstant(false));
}
Handle<Code> code = m.GenerateCode();
FunctionTester ft(code, param_count);
std::vector<Handle<Name>> names;
std::vector<Handle<JSObject>> receivers;
std::vector<Handle<Code>> handlers;
base::RandomNumberGenerator rand_gen(FLAG_random_seed);
Factory* factory = isolate->factory();
// Generate some number of names.
for (int i = 0; i < StubCache::kPrimaryTableSize / 7; i++) {
Handle<Name> name;
switch (rand_gen.NextInt(3)) {
case 0: {
// Generate string.
std::stringstream ss;
ss << "s" << std::hex
<< (rand_gen.NextInt(Smi::kMaxValue) % StubCache::kPrimaryTableSize);
name = factory->InternalizeUtf8String(ss.str().c_str());
break;
}
case 1: {
// Generate number string.
std::stringstream ss;
ss << (rand_gen.NextInt(Smi::kMaxValue) % StubCache::kPrimaryTableSize);
name = factory->InternalizeUtf8String(ss.str().c_str());
break;
}
case 2: {
// Generate symbol.
name = factory->NewSymbol();
break;
}
default:
UNREACHABLE();
}
names.push_back(name);
}
// Generate some number of receiver maps and receivers.
for (int i = 0; i < StubCache::kSecondaryTableSize / 2; i++) {
Handle<Map> map = Map::Create(isolate, 0);
receivers.push_back(factory->NewJSObjectFromMap(map));
}
// Generate some number of handlers.
for (int i = 0; i < 30; i++) {
Code::Kind code_kind;
switch (rand_gen.NextInt(4)) {
case 0:
code_kind = Code::LOAD_IC;
break;
case 1:
code_kind = Code::KEYED_LOAD_IC;
break;
case 2:
code_kind = Code::STORE_IC;
break;
case 3:
code_kind = Code::KEYED_STORE_IC;
break;
default:
UNREACHABLE();
}
Code::Flags flags =
Code::RemoveHolderFromFlags(Code::ComputeHandlerFlags(code_kind));
handlers.push_back(CreateCodeWithFlags(flags));
}
// Ensure that GC does happen because from now on we are going to fill our
// own stub cache instance with raw values.
DisallowHeapAllocation no_gc;
// Populate {stub_cache}.
const int N = StubCache::kPrimaryTableSize + StubCache::kSecondaryTableSize;
for (int i = 0; i < N; i++) {
int index = rand_gen.NextInt();
Handle<Name> name = names[index % names.size()];
Handle<JSObject> receiver = receivers[index % receivers.size()];
Handle<Code> handler = handlers[index % handlers.size()];
stub_cache.Set(*name, receiver->map(), *handler);
}
// Perform some queries.
bool queried_existing = false;
bool queried_non_existing = false;
for (int i = 0; i < N; i++) {
int index = rand_gen.NextInt();
Handle<Name> name = names[index % names.size()];
Handle<JSObject> receiver = receivers[index % receivers.size()];
Code* handler = stub_cache.Get(*name, receiver->map(), flags_to_query);
if (handler == nullptr) {
queried_non_existing = true;
} else {
queried_existing = true;
}
Handle<Code> expected_handler(handler, isolate);
ft.CheckTrue(receiver, name, expected_handler);
}
for (int i = 0; i < N; i++) {
int index1 = rand_gen.NextInt();
int index2 = rand_gen.NextInt();
Handle<Name> name = names[index1 % names.size()];
Handle<JSObject> receiver = receivers[index2 % receivers.size()];
Code* handler = stub_cache.Get(*name, receiver->map(), flags_to_query);
if (handler == nullptr) {
queried_non_existing = true;
} else {
queried_existing = true;
}
Handle<Code> expected_handler(handler, isolate);
ft.CheckTrue(receiver, name, expected_handler);
}
// Ensure we performed both kind of queries.
CHECK(queried_existing && queried_non_existing);
}
} // namespace internal
} // namespace v8
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