third_party/v8/test/unittests/heap/cppgc/minor-gc-unittest.cc - cobalt - Git at Google

 // Copyright 2020 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.

 #if defined(CPPGC_YOUNG_GENERATION)

 #include "include/cppgc/allocation.h"
 #include "include/cppgc/persistent.h"
 #include "src/heap/cppgc/heap-object-header.h"
 #include "src/heap/cppgc/heap.h"
 #include "test/unittests/heap/cppgc/tests.h"
 #include "testing/gtest/include/gtest/gtest.h"

 namespace cppgc {
 namespace internal {

 namespace {

 class SimpleGCedBase : public GarbageCollected<SimpleGCedBase> {
  public:
   static size_t destructed_objects;

   virtual ~SimpleGCedBase() { ++destructed_objects; }

   virtual void Trace(Visitor* v) const { v->Trace(next); }

   Member<SimpleGCedBase> next;
 };

 size_t SimpleGCedBase::destructed_objects;

 template <size_t Size>
 class SimpleGCed final : public SimpleGCedBase {
   char array[Size];
 };

 using Small = SimpleGCed<64>;
 using Large = SimpleGCed<kLargeObjectSizeThreshold * 2>;

 template <typename Type>
 struct OtherType;
 template <>
 struct OtherType<Small> {
   using Type = Large;
 };
 template <>
 struct OtherType<Large> {
   using Type = Small;
 };

 class MinorGCTest : public testing::TestWithHeap {
  public:
   MinorGCTest() {
     CollectMajor();
     SimpleGCedBase::destructed_objects = 0;
   }

   static size_t DestructedObjects() {
     return SimpleGCedBase::destructed_objects;
   }

   void CollectMinor() {
     Heap::From(GetHeap())->CollectGarbage(
         Heap::Config::MinorPreciseAtomicConfig());
   }
   void CollectMajor() {
     Heap::From(GetHeap())->CollectGarbage(Heap::Config::PreciseAtomicConfig());
   }
 };

 template <typename SmallOrLarge>
 class MinorGCTestForType : public MinorGCTest {
  public:
   using Type = SmallOrLarge;
 };

 }  // namespace

 using ObjectTypes = ::testing::Types<Small, Large>;
 TYPED_TEST_SUITE(MinorGCTestForType, ObjectTypes);

 TYPED_TEST(MinorGCTestForType, MinorCollection) {
   using Type = typename TestFixture::Type;

   MakeGarbageCollected<Type>(this->GetAllocationHandle());
   EXPECT_EQ(0u, TestFixture::DestructedObjects());
   MinorGCTest::CollectMinor();
   EXPECT_EQ(1u, TestFixture::DestructedObjects());

   {
     Heap::NoGCScope no_gc_scope_(*Heap::From(this->GetHeap()));

     Type* prev = nullptr;
     for (size_t i = 0; i < 64; ++i) {
       auto* ptr = MakeGarbageCollected<Type>(this->GetAllocationHandle());
       ptr->next = prev;
       prev = ptr;
     }
   }

   MinorGCTest::CollectMinor();
   EXPECT_EQ(65u, TestFixture::DestructedObjects());
 }

 TYPED_TEST(MinorGCTestForType, StickyBits) {
   using Type = typename TestFixture::Type;

   Persistent<Type> p1 = MakeGarbageCollected<Type>(this->GetAllocationHandle());
   TestFixture::CollectMinor();
   EXPECT_FALSE(HeapObjectHeader::FromPayload(p1.Get()).IsYoung());
   TestFixture::CollectMajor();
   EXPECT_FALSE(HeapObjectHeader::FromPayload(p1.Get()).IsYoung());
   EXPECT_EQ(0u, TestFixture::DestructedObjects());
 }

 TYPED_TEST(MinorGCTestForType, OldObjectIsNotVisited) {
   using Type = typename TestFixture::Type;

   Persistent<Type> p = MakeGarbageCollected<Type>(this->GetAllocationHandle());
   TestFixture::CollectMinor();
   EXPECT_EQ(0u, TestFixture::DestructedObjects());
   EXPECT_FALSE(HeapObjectHeader::FromPayload(p.Get()).IsYoung());

   // Check that the old deleted object won't be visited during minor GC.
   Type* raw = p.Release();
   TestFixture::CollectMinor();
   EXPECT_EQ(0u, TestFixture::DestructedObjects());
   EXPECT_FALSE(HeapObjectHeader::FromPayload(raw).IsYoung());
   EXPECT_FALSE(HeapObjectHeader::FromPayload(raw).IsFree());

   // Check that the old deleted object will be revisited in major GC.
   TestFixture::CollectMajor();
   EXPECT_EQ(1u, TestFixture::DestructedObjects());
 }

 template <typename Type1, typename Type2>
 void InterGenerationalPointerTest(MinorGCTest* test, cppgc::Heap* heap) {
   Persistent<Type1> old =
       MakeGarbageCollected<Type1>(heap->GetAllocationHandle());
   test->CollectMinor();
   EXPECT_FALSE(HeapObjectHeader::FromPayload(old.Get()).IsYoung());

   Type2* young = nullptr;

   {
     Heap::NoGCScope no_gc_scope_(*Heap::From(heap));

     // Allocate young objects.
     for (size_t i = 0; i < 64; ++i) {
       auto* ptr = MakeGarbageCollected<Type2>(heap->GetAllocationHandle());
       ptr->next = young;
       young = ptr;
       EXPECT_TRUE(HeapObjectHeader::FromPayload(young).IsYoung());
     }
   }

   const auto& set = Heap::From(heap)->remembered_slots();
   auto set_size_before = set.size();

   // Issue generational barrier.
   old->next = young;

   EXPECT_EQ(set_size_before + 1u, set.size());

   // Check that the remembered set is visited.
   test->CollectMinor();

   EXPECT_EQ(0u, MinorGCTest::DestructedObjects());
   EXPECT_TRUE(set.empty());

   for (size_t i = 0; i < 64; ++i) {
     EXPECT_FALSE(HeapObjectHeader::FromPayload(young).IsFree());
     EXPECT_FALSE(HeapObjectHeader::FromPayload(young).IsYoung());
     young = static_cast<Type2*>(young->next.Get());
   }

   old.Release();
   test->CollectMajor();
   EXPECT_EQ(65u, MinorGCTest::DestructedObjects());
 }

 TYPED_TEST(MinorGCTestForType, InterGenerationalPointerForSamePageTypes) {
   using Type = typename TestFixture::Type;
   InterGenerationalPointerTest<Type, Type>(this, this->GetHeap());
 }

 TYPED_TEST(MinorGCTestForType, InterGenerationalPointerForDifferentPageTypes) {
   using Type = typename TestFixture::Type;
   InterGenerationalPointerTest<Type, typename OtherType<Type>::Type>(
       this, this->GetHeap());
 }

 TYPED_TEST(MinorGCTestForType, OmitGenerationalBarrierForOnStackObject) {
   using Type = typename TestFixture::Type;

   class StackAllocated : GarbageCollected<StackAllocated> {
     CPPGC_STACK_ALLOCATED();

    public:
     Type* ptr = nullptr;
   } stack_object;

   auto* new_object = MakeGarbageCollected<Type>(this->GetAllocationHandle());

   const auto& set = Heap::From(this->GetHeap())->remembered_slots();
   const size_t set_size_before_barrier = set.size();

   // Try issuing generational barrier for on-stack object.
   stack_object.ptr = new_object;
   WriteBarrier::MarkingBarrier(reinterpret_cast<void*>(&stack_object.ptr),
                                new_object);

   EXPECT_EQ(set_size_before_barrier, set.size());
 }

 TYPED_TEST(MinorGCTestForType, OmitGenerationalBarrierForSentinels) {
   using Type = typename TestFixture::Type;

   Persistent<Type> old =
       MakeGarbageCollected<Type>(this->GetAllocationHandle());

   TestFixture::CollectMinor();
   EXPECT_FALSE(HeapObjectHeader::FromPayload(old.Get()).IsYoung());

   const auto& set = Heap::From(this->GetHeap())->remembered_slots();
   const size_t set_size_before_barrier = set.size();

   // Try issuing generational barrier for nullptr.
   old->next = static_cast<Type*>(nullptr);
   EXPECT_EQ(set_size_before_barrier, set.size());

   // Try issuing generational barrier for sentinel.
   old->next = static_cast<Type*>(kSentinelPointer);
   EXPECT_EQ(set_size_before_barrier, set.size());
 }
 }  // namespace internal
 }  // namespace cppgc

 #endif
	// Copyright 2020 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.

	#if defined(CPPGC_YOUNG_GENERATION)

	#include "include/cppgc/allocation.h"
	#include "include/cppgc/persistent.h"
	#include "src/heap/cppgc/heap-object-header.h"
	#include "src/heap/cppgc/heap.h"
	#include "test/unittests/heap/cppgc/tests.h"
	#include "testing/gtest/include/gtest/gtest.h"

	namespace cppgc {
	namespace internal {

	namespace {

	class SimpleGCedBase : public GarbageCollected<SimpleGCedBase> {
	public:
	static size_t destructed_objects;

	virtual ~SimpleGCedBase() { ++destructed_objects; }

	virtual void Trace(Visitor* v) const { v->Trace(next); }

	Member<SimpleGCedBase> next;
	};

	size_t SimpleGCedBase::destructed_objects;

	template <size_t Size>
	class SimpleGCed final : public SimpleGCedBase {
	char array[Size];
	};

	using Small = SimpleGCed<64>;
	using Large = SimpleGCed<kLargeObjectSizeThreshold * 2>;

	template <typename Type>
	struct OtherType;
	template <>
	struct OtherType<Small> {
	using Type = Large;
	};
	template <>
	struct OtherType<Large> {
	using Type = Small;
	};

	class MinorGCTest : public testing::TestWithHeap {
	public:
	MinorGCTest() {
	CollectMajor();
	SimpleGCedBase::destructed_objects = 0;
	}

	static size_t DestructedObjects() {
	return SimpleGCedBase::destructed_objects;
	}

	void CollectMinor() {
	Heap::From(GetHeap())->CollectGarbage(
	Heap::Config::MinorPreciseAtomicConfig());
	}
	void CollectMajor() {
	Heap::From(GetHeap())->CollectGarbage(Heap::Config::PreciseAtomicConfig());
	}
	};

	template <typename SmallOrLarge>
	class MinorGCTestForType : public MinorGCTest {
	public:
	using Type = SmallOrLarge;
	};

	} // namespace

	using ObjectTypes = ::testing::Types<Small, Large>;
	TYPED_TEST_SUITE(MinorGCTestForType, ObjectTypes);

	TYPED_TEST(MinorGCTestForType, MinorCollection) {
	using Type = typename TestFixture::Type;

	MakeGarbageCollected<Type>(this->GetAllocationHandle());
	EXPECT_EQ(0u, TestFixture::DestructedObjects());
	MinorGCTest::CollectMinor();
	EXPECT_EQ(1u, TestFixture::DestructedObjects());

	{
	Heap::NoGCScope no_gc_scope_(*Heap::From(this->GetHeap()));

	Type* prev = nullptr;
	for (size_t i = 0; i < 64; ++i) {
	auto* ptr = MakeGarbageCollected<Type>(this->GetAllocationHandle());
	ptr->next = prev;
	prev = ptr;
	}
	}

	MinorGCTest::CollectMinor();
	EXPECT_EQ(65u, TestFixture::DestructedObjects());
	}

	TYPED_TEST(MinorGCTestForType, StickyBits) {
	using Type = typename TestFixture::Type;

	Persistent<Type> p1 = MakeGarbageCollected<Type>(this->GetAllocationHandle());
	TestFixture::CollectMinor();
	EXPECT_FALSE(HeapObjectHeader::FromPayload(p1.Get()).IsYoung());
	TestFixture::CollectMajor();
	EXPECT_FALSE(HeapObjectHeader::FromPayload(p1.Get()).IsYoung());
	EXPECT_EQ(0u, TestFixture::DestructedObjects());
	}

	TYPED_TEST(MinorGCTestForType, OldObjectIsNotVisited) {
	using Type = typename TestFixture::Type;

	Persistent<Type> p = MakeGarbageCollected<Type>(this->GetAllocationHandle());
	TestFixture::CollectMinor();
	EXPECT_EQ(0u, TestFixture::DestructedObjects());
	EXPECT_FALSE(HeapObjectHeader::FromPayload(p.Get()).IsYoung());

	// Check that the old deleted object won't be visited during minor GC.
	Type* raw = p.Release();
	TestFixture::CollectMinor();
	EXPECT_EQ(0u, TestFixture::DestructedObjects());
	EXPECT_FALSE(HeapObjectHeader::FromPayload(raw).IsYoung());
	EXPECT_FALSE(HeapObjectHeader::FromPayload(raw).IsFree());

	// Check that the old deleted object will be revisited in major GC.
	TestFixture::CollectMajor();
	EXPECT_EQ(1u, TestFixture::DestructedObjects());
	}

	template <typename Type1, typename Type2>
	void InterGenerationalPointerTest(MinorGCTest* test, cppgc::Heap* heap) {
	Persistent<Type1> old =
	MakeGarbageCollected<Type1>(heap->GetAllocationHandle());
	test->CollectMinor();
	EXPECT_FALSE(HeapObjectHeader::FromPayload(old.Get()).IsYoung());

	Type2* young = nullptr;

	{
	Heap::NoGCScope no_gc_scope_(*Heap::From(heap));

	// Allocate young objects.
	for (size_t i = 0; i < 64; ++i) {
	auto* ptr = MakeGarbageCollected<Type2>(heap->GetAllocationHandle());
	ptr->next = young;
	young = ptr;
	EXPECT_TRUE(HeapObjectHeader::FromPayload(young).IsYoung());
	}
	}

	const auto& set = Heap::From(heap)->remembered_slots();
	auto set_size_before = set.size();

	// Issue generational barrier.
	old->next = young;

	EXPECT_EQ(set_size_before + 1u, set.size());

	// Check that the remembered set is visited.
	test->CollectMinor();

	EXPECT_EQ(0u, MinorGCTest::DestructedObjects());
	EXPECT_TRUE(set.empty());

	for (size_t i = 0; i < 64; ++i) {
	EXPECT_FALSE(HeapObjectHeader::FromPayload(young).IsFree());
	EXPECT_FALSE(HeapObjectHeader::FromPayload(young).IsYoung());
	young = static_cast<Type2*>(young->next.Get());
	}

	old.Release();
	test->CollectMajor();
	EXPECT_EQ(65u, MinorGCTest::DestructedObjects());
	}

	TYPED_TEST(MinorGCTestForType, InterGenerationalPointerForSamePageTypes) {
	using Type = typename TestFixture::Type;
	InterGenerationalPointerTest<Type, Type>(this, this->GetHeap());
	}

	TYPED_TEST(MinorGCTestForType, InterGenerationalPointerForDifferentPageTypes) {
	using Type = typename TestFixture::Type;
	InterGenerationalPointerTest<Type, typename OtherType<Type>::Type>(
	this, this->GetHeap());
	}

	TYPED_TEST(MinorGCTestForType, OmitGenerationalBarrierForOnStackObject) {
	using Type = typename TestFixture::Type;

	class StackAllocated : GarbageCollected<StackAllocated> {
	CPPGC_STACK_ALLOCATED();

	public:
	Type* ptr = nullptr;
	} stack_object;

	auto* new_object = MakeGarbageCollected<Type>(this->GetAllocationHandle());

	const auto& set = Heap::From(this->GetHeap())->remembered_slots();
	const size_t set_size_before_barrier = set.size();

	// Try issuing generational barrier for on-stack object.
	stack_object.ptr = new_object;
	WriteBarrier::MarkingBarrier(reinterpret_cast<void*>(&stack_object.ptr),
	new_object);

	EXPECT_EQ(set_size_before_barrier, set.size());
	}

	TYPED_TEST(MinorGCTestForType, OmitGenerationalBarrierForSentinels) {
	using Type = typename TestFixture::Type;

	Persistent<Type> old =
	MakeGarbageCollected<Type>(this->GetAllocationHandle());

	TestFixture::CollectMinor();
	EXPECT_FALSE(HeapObjectHeader::FromPayload(old.Get()).IsYoung());

	const auto& set = Heap::From(this->GetHeap())->remembered_slots();
	const size_t set_size_before_barrier = set.size();

	// Try issuing generational barrier for nullptr.
	old->next = static_cast<Type*>(nullptr);
	EXPECT_EQ(set_size_before_barrier, set.size());

	// Try issuing generational barrier for sentinel.
	old->next = static_cast<Type*>(kSentinelPointer);
	EXPECT_EQ(set_size_before_barrier, set.size());
	}
	} // namespace internal
	} // namespace cppgc

	#endif