v8/test/cctest/heap/test-spaces.cc
mlippautz bf74d43de0 [heap] MinorMC: Evacuation for young generation
In the spirit of the full MC, we evacuate and update pointers in parallel for
the young generation.

The collectors are connected during incremental marking when mark bits are
transferred from the young generation bitmap to the old generation bitmap.

The evacuation phase cannot (yet) move pages and relies completely on copying
objects.

BUG=chromium:651354

Review-Url: https://codereview.chromium.org/2796233003
Cr-Commit-Position: refs/heads/master@{#45074}
2017-05-03 21:31:06 +00:00

762 lines
25 KiB
C++

// Copyright 2011 the V8 project authors. All rights reserved.
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
// * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
// * Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following
// disclaimer in the documentation and/or other materials provided
// with the distribution.
// * Neither the name of Google Inc. nor the names of its
// contributors may be used to endorse or promote products derived
// from this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#include <stdlib.h>
#include "src/base/platform/platform.h"
#include "src/heap/spaces-inl.h"
// FIXME(mstarzinger, marja): This is weird, but required because of the missing
// (disallowed) include: src/heap/incremental-marking.h -> src/objects-inl.h
#include "src/objects-inl.h"
#include "src/snapshot/snapshot.h"
#include "src/v8.h"
#include "test/cctest/cctest.h"
#include "test/cctest/heap/heap-tester.h"
#include "test/cctest/heap/heap-utils.h"
namespace v8 {
namespace internal {
#if 0
static void VerifyRegionMarking(Address page_start) {
#ifdef ENABLE_CARDMARKING_WRITE_BARRIER
Page* p = Page::FromAddress(page_start);
p->SetRegionMarks(Page::kAllRegionsCleanMarks);
for (Address addr = p->ObjectAreaStart();
addr < p->ObjectAreaEnd();
addr += kPointerSize) {
CHECK(!Page::FromAddress(addr)->IsRegionDirty(addr));
}
for (Address addr = p->ObjectAreaStart();
addr < p->ObjectAreaEnd();
addr += kPointerSize) {
Page::FromAddress(addr)->MarkRegionDirty(addr);
}
for (Address addr = p->ObjectAreaStart();
addr < p->ObjectAreaEnd();
addr += kPointerSize) {
CHECK(Page::FromAddress(addr)->IsRegionDirty(addr));
}
#endif
}
#endif
// TODO(gc) you can no longer allocate pages like this. Details are hidden.
#if 0
TEST(Page) {
byte* mem = NewArray<byte>(2*Page::kPageSize);
CHECK(mem != NULL);
Address start = reinterpret_cast<Address>(mem);
Address page_start = RoundUp(start, Page::kPageSize);
Page* p = Page::FromAddress(page_start);
// Initialized Page has heap pointer, normally set by memory_allocator.
p->heap_ = CcTest::heap();
CHECK(p->address() == page_start);
CHECK(p->is_valid());
p->opaque_header = 0;
p->SetIsLargeObjectPage(false);
CHECK(!p->next_page()->is_valid());
CHECK(p->ObjectAreaStart() == page_start + Page::kObjectStartOffset);
CHECK(p->ObjectAreaEnd() == page_start + Page::kPageSize);
CHECK(p->Offset(page_start + Page::kObjectStartOffset) ==
Page::kObjectStartOffset);
CHECK(p->Offset(page_start + Page::kPageSize) == Page::kPageSize);
CHECK(p->OffsetToAddress(Page::kObjectStartOffset) == p->ObjectAreaStart());
CHECK(p->OffsetToAddress(Page::kPageSize) == p->ObjectAreaEnd());
// test region marking
VerifyRegionMarking(page_start);
DeleteArray(mem);
}
#endif
// Temporarily sets a given allocator in an isolate.
class TestMemoryAllocatorScope {
public:
TestMemoryAllocatorScope(Isolate* isolate, MemoryAllocator* allocator)
: isolate_(isolate), old_allocator_(isolate->heap()->memory_allocator()) {
isolate->heap()->memory_allocator_ = allocator;
}
~TestMemoryAllocatorScope() {
isolate_->heap()->memory_allocator_ = old_allocator_;
}
private:
Isolate* isolate_;
MemoryAllocator* old_allocator_;
DISALLOW_COPY_AND_ASSIGN(TestMemoryAllocatorScope);
};
// Temporarily sets a given code range in an isolate.
class TestCodeRangeScope {
public:
TestCodeRangeScope(Isolate* isolate, CodeRange* code_range)
: isolate_(isolate),
old_code_range_(isolate->heap()->memory_allocator()->code_range()) {
isolate->heap()->memory_allocator()->code_range_ = code_range;
}
~TestCodeRangeScope() {
isolate_->heap()->memory_allocator()->code_range_ = old_code_range_;
}
private:
Isolate* isolate_;
CodeRange* old_code_range_;
DISALLOW_COPY_AND_ASSIGN(TestCodeRangeScope);
};
static void VerifyMemoryChunk(Isolate* isolate,
Heap* heap,
CodeRange* code_range,
size_t reserve_area_size,
size_t commit_area_size,
size_t second_commit_area_size,
Executability executable) {
MemoryAllocator* memory_allocator = new MemoryAllocator(isolate);
CHECK(memory_allocator->SetUp(heap->MaxReserved(), 0));
{
TestMemoryAllocatorScope test_allocator_scope(isolate, memory_allocator);
TestCodeRangeScope test_code_range_scope(isolate, code_range);
size_t header_size = (executable == EXECUTABLE)
? MemoryAllocator::CodePageGuardStartOffset()
: MemoryChunk::kObjectStartOffset;
size_t guard_size =
(executable == EXECUTABLE) ? MemoryAllocator::CodePageGuardSize() : 0;
MemoryChunk* memory_chunk = memory_allocator->AllocateChunk(
reserve_area_size, commit_area_size, executable, NULL);
size_t alignment = code_range != NULL && code_range->valid()
? MemoryChunk::kAlignment
: base::OS::CommitPageSize();
size_t reserved_size =
((executable == EXECUTABLE))
? RoundUp(header_size + guard_size + reserve_area_size + guard_size,
alignment)
: RoundUp(header_size + reserve_area_size,
base::OS::CommitPageSize());
CHECK(memory_chunk->size() == reserved_size);
CHECK(memory_chunk->area_start() <
memory_chunk->address() + memory_chunk->size());
CHECK(memory_chunk->area_end() <=
memory_chunk->address() + memory_chunk->size());
CHECK(static_cast<size_t>(memory_chunk->area_size()) == commit_area_size);
Address area_start = memory_chunk->area_start();
memory_chunk->CommitArea(second_commit_area_size);
CHECK(area_start == memory_chunk->area_start());
CHECK(memory_chunk->area_start() <
memory_chunk->address() + memory_chunk->size());
CHECK(memory_chunk->area_end() <=
memory_chunk->address() + memory_chunk->size());
CHECK(static_cast<size_t>(memory_chunk->area_size()) ==
second_commit_area_size);
memory_allocator->Free<MemoryAllocator::kFull>(memory_chunk);
}
memory_allocator->TearDown();
delete memory_allocator;
}
TEST(Regress3540) {
Isolate* isolate = CcTest::i_isolate();
Heap* heap = isolate->heap();
MemoryAllocator* memory_allocator = new MemoryAllocator(isolate);
CHECK(memory_allocator->SetUp(heap->MaxReserved(), 0));
TestMemoryAllocatorScope test_allocator_scope(isolate, memory_allocator);
CodeRange* code_range = new CodeRange(isolate);
size_t code_range_size =
kMinimumCodeRangeSize > 0 ? kMinimumCodeRangeSize : 3 * Page::kPageSize;
if (!code_range->SetUp(code_range_size)) {
return;
}
Address address;
size_t size;
size_t request_size = code_range_size - Page::kPageSize;
address = code_range->AllocateRawMemory(
request_size, request_size - (2 * MemoryAllocator::CodePageGuardSize()),
&size);
CHECK_NOT_NULL(address);
Address null_address;
size_t null_size;
request_size = code_range_size - Page::kPageSize;
null_address = code_range->AllocateRawMemory(
request_size, request_size - (2 * MemoryAllocator::CodePageGuardSize()),
&null_size);
CHECK_NULL(null_address);
code_range->FreeRawMemory(address, size);
delete code_range;
memory_allocator->TearDown();
delete memory_allocator;
}
static unsigned int Pseudorandom() {
static uint32_t lo = 2345;
lo = 18273 * (lo & 0xFFFFF) + (lo >> 16);
return lo & 0xFFFFF;
}
TEST(MemoryChunk) {
Isolate* isolate = CcTest::i_isolate();
Heap* heap = isolate->heap();
size_t reserve_area_size = 1 * MB;
size_t initial_commit_area_size, second_commit_area_size;
for (int i = 0; i < 100; i++) {
initial_commit_area_size = Pseudorandom();
second_commit_area_size = Pseudorandom();
// With CodeRange.
CodeRange* code_range = new CodeRange(isolate);
const size_t code_range_size = 32 * MB;
if (!code_range->SetUp(code_range_size)) return;
VerifyMemoryChunk(isolate,
heap,
code_range,
reserve_area_size,
initial_commit_area_size,
second_commit_area_size,
EXECUTABLE);
VerifyMemoryChunk(isolate,
heap,
code_range,
reserve_area_size,
initial_commit_area_size,
second_commit_area_size,
NOT_EXECUTABLE);
delete code_range;
// Without a valid CodeRange, i.e., omitting SetUp.
code_range = new CodeRange(isolate);
VerifyMemoryChunk(isolate,
heap,
code_range,
reserve_area_size,
initial_commit_area_size,
second_commit_area_size,
EXECUTABLE);
VerifyMemoryChunk(isolate,
heap,
code_range,
reserve_area_size,
initial_commit_area_size,
second_commit_area_size,
NOT_EXECUTABLE);
delete code_range;
}
}
TEST(MemoryAllocator) {
Isolate* isolate = CcTest::i_isolate();
Heap* heap = isolate->heap();
MemoryAllocator* memory_allocator = new MemoryAllocator(isolate);
CHECK(memory_allocator != nullptr);
CHECK(memory_allocator->SetUp(heap->MaxReserved(), 0));
TestMemoryAllocatorScope test_scope(isolate, memory_allocator);
{
int total_pages = 0;
OldSpace faked_space(heap, OLD_SPACE, NOT_EXECUTABLE);
Page* first_page = memory_allocator->AllocatePage(
faked_space.AreaSize(), static_cast<PagedSpace*>(&faked_space),
NOT_EXECUTABLE);
first_page->InsertAfter(faked_space.anchor()->prev_page());
CHECK(Page::IsValid(first_page));
CHECK(first_page->next_page() == faked_space.anchor());
total_pages++;
for (Page* p = first_page; p != faked_space.anchor(); p = p->next_page()) {
CHECK(p->owner() == &faked_space);
}
// Again, we should get n or n - 1 pages.
Page* other = memory_allocator->AllocatePage(
faked_space.AreaSize(), static_cast<PagedSpace*>(&faked_space),
NOT_EXECUTABLE);
CHECK(Page::IsValid(other));
total_pages++;
other->InsertAfter(first_page);
int page_count = 0;
for (Page* p = first_page; p != faked_space.anchor(); p = p->next_page()) {
CHECK(p->owner() == &faked_space);
page_count++;
}
CHECK(total_pages == page_count);
Page* second_page = first_page->next_page();
CHECK(Page::IsValid(second_page));
// OldSpace's destructor will tear down the space and free up all pages.
}
memory_allocator->TearDown();
delete memory_allocator;
}
TEST(NewSpace) {
Isolate* isolate = CcTest::i_isolate();
Heap* heap = isolate->heap();
MemoryAllocator* memory_allocator = new MemoryAllocator(isolate);
CHECK(memory_allocator->SetUp(heap->MaxReserved(), 0));
TestMemoryAllocatorScope test_scope(isolate, memory_allocator);
NewSpace new_space(heap);
CHECK(new_space.SetUp(CcTest::heap()->InitialSemiSpaceSize(),
CcTest::heap()->InitialSemiSpaceSize()));
CHECK(new_space.HasBeenSetUp());
while (new_space.Available() >= kMaxRegularHeapObjectSize) {
CHECK(new_space.Contains(
new_space.AllocateRawUnaligned(kMaxRegularHeapObjectSize)
.ToObjectChecked()));
}
new_space.TearDown();
memory_allocator->TearDown();
delete memory_allocator;
}
TEST(OldSpace) {
Isolate* isolate = CcTest::i_isolate();
Heap* heap = isolate->heap();
MemoryAllocator* memory_allocator = new MemoryAllocator(isolate);
CHECK(memory_allocator->SetUp(heap->MaxReserved(), 0));
TestMemoryAllocatorScope test_scope(isolate, memory_allocator);
OldSpace* s = new OldSpace(heap, OLD_SPACE, NOT_EXECUTABLE);
CHECK(s != NULL);
CHECK(s->SetUp());
while (s->Available() > 0) {
s->AllocateRawUnaligned(kMaxRegularHeapObjectSize).ToObjectChecked();
}
delete s;
memory_allocator->TearDown();
delete memory_allocator;
}
TEST(LargeObjectSpace) {
// This test does not initialize allocated objects, which confuses the
// incremental marker.
FLAG_incremental_marking = false;
v8::V8::Initialize();
LargeObjectSpace* lo = CcTest::heap()->lo_space();
CHECK(lo != NULL);
int lo_size = Page::kPageSize;
Object* obj = lo->AllocateRaw(lo_size, NOT_EXECUTABLE).ToObjectChecked();
CHECK(obj->IsHeapObject());
HeapObject* ho = HeapObject::cast(obj);
CHECK(lo->Contains(HeapObject::cast(obj)));
CHECK(lo->FindObject(ho->address()) == obj);
CHECK(lo->Contains(ho));
while (true) {
size_t available = lo->Available();
{ AllocationResult allocation = lo->AllocateRaw(lo_size, NOT_EXECUTABLE);
if (allocation.IsRetry()) break;
}
// The available value is conservative such that it may report
// zero prior to heap exhaustion.
CHECK(lo->Available() < available || available == 0);
}
CHECK(!lo->IsEmpty());
CHECK(lo->AllocateRaw(lo_size, NOT_EXECUTABLE).IsRetry());
}
TEST(SizeOfInitialHeap) {
if (i::FLAG_always_opt) return;
// Bootstrapping without a snapshot causes more allocations.
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
if (!isolate->snapshot_available()) return;
HandleScope scope(isolate);
v8::Local<v8::Context> context = CcTest::isolate()->GetCurrentContext();
// Skip this test on the custom snapshot builder.
if (!CcTest::global()
->Get(context, v8_str("assertEquals"))
.ToLocalChecked()
->IsUndefined()) {
return;
}
// Initial size of LO_SPACE
size_t initial_lo_space = isolate->heap()->lo_space()->Size();
// The limit for each space for an empty isolate containing just the
// snapshot.
// In PPC the page size is 64K, causing more internal fragmentation
// hence requiring a larger limit.
#if V8_OS_LINUX && V8_HOST_ARCH_PPC
const size_t kMaxInitialSizePerSpace = 3 * MB;
#else
const size_t kMaxInitialSizePerSpace = 2 * MB;
#endif
// Freshly initialized VM gets by with the snapshot size (which is below
// kMaxInitialSizePerSpace per space).
Heap* heap = isolate->heap();
int page_count[LAST_PAGED_SPACE + 1] = {0, 0, 0, 0};
for (int i = FIRST_PAGED_SPACE; i <= LAST_PAGED_SPACE; i++) {
// Debug code can be very large, so skip CODE_SPACE if we are generating it.
if (i == CODE_SPACE && i::FLAG_debug_code) continue;
page_count[i] = heap->paged_space(i)->CountTotalPages();
// Check that the initial heap is also below the limit.
CHECK_LE(heap->paged_space(i)->CommittedMemory(), kMaxInitialSizePerSpace);
}
// Executing the empty script gets by with the same number of pages, i.e.,
// requires no extra space.
CompileRun("/*empty*/");
for (int i = FIRST_PAGED_SPACE; i <= LAST_PAGED_SPACE; i++) {
// Skip CODE_SPACE, since we had to generate code even for an empty script.
if (i == CODE_SPACE) continue;
CHECK_EQ(page_count[i], isolate->heap()->paged_space(i)->CountTotalPages());
}
// No large objects required to perform the above steps.
CHECK_EQ(initial_lo_space,
static_cast<size_t>(isolate->heap()->lo_space()->Size()));
}
static HeapObject* AllocateUnaligned(NewSpace* space, int size) {
AllocationResult allocation = space->AllocateRawUnaligned(size);
CHECK(!allocation.IsRetry());
HeapObject* filler = NULL;
CHECK(allocation.To(&filler));
space->heap()->CreateFillerObjectAt(filler->address(), size,
ClearRecordedSlots::kNo);
return filler;
}
static HeapObject* AllocateUnaligned(PagedSpace* space, int size) {
AllocationResult allocation = space->AllocateRaw(size, kDoubleUnaligned);
CHECK(!allocation.IsRetry());
HeapObject* filler = NULL;
CHECK(allocation.To(&filler));
space->heap()->CreateFillerObjectAt(filler->address(), size,
ClearRecordedSlots::kNo);
return filler;
}
static HeapObject* AllocateUnaligned(LargeObjectSpace* space, int size) {
AllocationResult allocation = space->AllocateRaw(size, EXECUTABLE);
CHECK(!allocation.IsRetry());
HeapObject* filler = NULL;
CHECK(allocation.To(&filler));
return filler;
}
class Observer : public AllocationObserver {
public:
explicit Observer(intptr_t step_size)
: AllocationObserver(step_size), count_(0) {}
void Step(int bytes_allocated, Address, size_t) override { count_++; }
int count() const { return count_; }
private:
int count_;
};
template <typename T>
void testAllocationObserver(Isolate* i_isolate, T* space) {
Observer observer1(128);
space->AddAllocationObserver(&observer1);
// The observer should not get notified if we have only allocated less than
// 128 bytes.
AllocateUnaligned(space, 64);
CHECK_EQ(observer1.count(), 0);
// The observer should get called when we have allocated exactly 128 bytes.
AllocateUnaligned(space, 64);
CHECK_EQ(observer1.count(), 1);
// Another >128 bytes should get another notification.
AllocateUnaligned(space, 136);
CHECK_EQ(observer1.count(), 2);
// Allocating a large object should get only one notification.
AllocateUnaligned(space, 1024);
CHECK_EQ(observer1.count(), 3);
// Allocating another 2048 bytes in small objects should get 16
// notifications.
for (int i = 0; i < 64; ++i) {
AllocateUnaligned(space, 32);
}
CHECK_EQ(observer1.count(), 19);
// Multiple observers should work.
Observer observer2(96);
space->AddAllocationObserver(&observer2);
AllocateUnaligned(space, 2048);
CHECK_EQ(observer1.count(), 20);
CHECK_EQ(observer2.count(), 1);
AllocateUnaligned(space, 104);
CHECK_EQ(observer1.count(), 20);
CHECK_EQ(observer2.count(), 2);
// Callback should stop getting called after an observer is removed.
space->RemoveAllocationObserver(&observer1);
AllocateUnaligned(space, 384);
CHECK_EQ(observer1.count(), 20); // no more notifications.
CHECK_EQ(observer2.count(), 3); // this one is still active.
// Ensure that PauseInlineAllocationObserversScope work correctly.
AllocateUnaligned(space, 48);
CHECK_EQ(observer2.count(), 3);
{
PauseAllocationObserversScope pause_observers(i_isolate->heap());
CHECK_EQ(observer2.count(), 3);
AllocateUnaligned(space, 384);
CHECK_EQ(observer2.count(), 3);
}
CHECK_EQ(observer2.count(), 3);
// Coupled with the 48 bytes allocated before the pause, another 48 bytes
// allocated here should trigger a notification.
AllocateUnaligned(space, 48);
CHECK_EQ(observer2.count(), 4);
space->RemoveAllocationObserver(&observer2);
AllocateUnaligned(space, 384);
CHECK_EQ(observer1.count(), 20);
CHECK_EQ(observer2.count(), 4);
}
UNINITIALIZED_TEST(AllocationObserver) {
v8::Isolate::CreateParams create_params;
create_params.array_buffer_allocator = CcTest::array_buffer_allocator();
v8::Isolate* isolate = v8::Isolate::New(create_params);
{
v8::Isolate::Scope isolate_scope(isolate);
v8::HandleScope handle_scope(isolate);
v8::Context::New(isolate)->Enter();
Isolate* i_isolate = reinterpret_cast<Isolate*>(isolate);
testAllocationObserver<NewSpace>(i_isolate, i_isolate->heap()->new_space());
// Old space is used but the code path is shared for all
// classes inheriting from PagedSpace.
testAllocationObserver<PagedSpace>(i_isolate,
i_isolate->heap()->old_space());
testAllocationObserver<LargeObjectSpace>(i_isolate,
i_isolate->heap()->lo_space());
}
isolate->Dispose();
}
UNINITIALIZED_TEST(InlineAllocationObserverCadence) {
v8::Isolate::CreateParams create_params;
create_params.array_buffer_allocator = CcTest::array_buffer_allocator();
v8::Isolate* isolate = v8::Isolate::New(create_params);
{
v8::Isolate::Scope isolate_scope(isolate);
v8::HandleScope handle_scope(isolate);
v8::Context::New(isolate)->Enter();
Isolate* i_isolate = reinterpret_cast<Isolate*>(isolate);
// Clear out any pre-existing garbage to make the test consistent
// across snapshot/no-snapshot builds.
i_isolate->heap()->CollectAllGarbage(
i::Heap::kFinalizeIncrementalMarkingMask,
i::GarbageCollectionReason::kTesting);
NewSpace* new_space = i_isolate->heap()->new_space();
Observer observer1(512);
new_space->AddAllocationObserver(&observer1);
Observer observer2(576);
new_space->AddAllocationObserver(&observer2);
for (int i = 0; i < 512; ++i) {
AllocateUnaligned(new_space, 32);
}
new_space->RemoveAllocationObserver(&observer1);
new_space->RemoveAllocationObserver(&observer2);
CHECK_EQ(observer1.count(), 32);
CHECK_EQ(observer2.count(), 28);
}
isolate->Dispose();
}
TEST(ShrinkPageToHighWaterMarkFreeSpaceEnd) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
heap::SealCurrentObjects(CcTest::heap());
// Prepare page that only contains a single object and a trailing FreeSpace
// filler.
Handle<FixedArray> array = isolate->factory()->NewFixedArray(128, TENURED);
Page* page = Page::FromAddress(array->address());
// Reset space so high water mark is consistent.
CcTest::heap()->old_space()->ResetFreeList();
CcTest::heap()->old_space()->EmptyAllocationInfo();
HeapObject* filler =
HeapObject::FromAddress(array->address() + array->Size());
CHECK(filler->IsFreeSpace());
size_t shrinked = page->ShrinkToHighWaterMark();
size_t should_have_shrinked =
RoundDown(static_cast<size_t>(Page::kAllocatableMemory - array->Size()),
base::OS::CommitPageSize());
CHECK_EQ(should_have_shrinked, shrinked);
}
TEST(ShrinkPageToHighWaterMarkNoFiller) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
heap::SealCurrentObjects(CcTest::heap());
const int kFillerSize = 0;
std::vector<Handle<FixedArray>> arrays =
heap::FillOldSpacePageWithFixedArrays(CcTest::heap(), kFillerSize);
Handle<FixedArray> array = arrays.back();
Page* page = Page::FromAddress(array->address());
CHECK_EQ(page->area_end(), array->address() + array->Size() + kFillerSize);
// Reset space so high water mark and fillers are consistent.
CcTest::heap()->old_space()->ResetFreeList();
CcTest::heap()->old_space()->EmptyAllocationInfo();
const size_t shrinked = page->ShrinkToHighWaterMark();
CHECK_EQ(0u, shrinked);
}
TEST(ShrinkPageToHighWaterMarkOneWordFiller) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
heap::SealCurrentObjects(CcTest::heap());
const int kFillerSize = kPointerSize;
std::vector<Handle<FixedArray>> arrays =
heap::FillOldSpacePageWithFixedArrays(CcTest::heap(), kFillerSize);
Handle<FixedArray> array = arrays.back();
Page* page = Page::FromAddress(array->address());
CHECK_EQ(page->area_end(), array->address() + array->Size() + kFillerSize);
// Reset space so high water mark and fillers are consistent.
CcTest::heap()->old_space()->ResetFreeList();
CcTest::heap()->old_space()->EmptyAllocationInfo();
HeapObject* filler =
HeapObject::FromAddress(array->address() + array->Size());
CHECK_EQ(filler->map(), CcTest::heap()->one_pointer_filler_map());
const size_t shrinked = page->ShrinkToHighWaterMark();
CHECK_EQ(0u, shrinked);
}
TEST(ShrinkPageToHighWaterMarkTwoWordFiller) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
heap::SealCurrentObjects(CcTest::heap());
const int kFillerSize = 2 * kPointerSize;
std::vector<Handle<FixedArray>> arrays =
heap::FillOldSpacePageWithFixedArrays(CcTest::heap(), kFillerSize);
Handle<FixedArray> array = arrays.back();
Page* page = Page::FromAddress(array->address());
CHECK_EQ(page->area_end(), array->address() + array->Size() + kFillerSize);
// Reset space so high water mark and fillers are consistent.
CcTest::heap()->old_space()->ResetFreeList();
CcTest::heap()->old_space()->EmptyAllocationInfo();
HeapObject* filler =
HeapObject::FromAddress(array->address() + array->Size());
CHECK_EQ(filler->map(), CcTest::heap()->two_pointer_filler_map());
const size_t shrinked = page->ShrinkToHighWaterMark();
CHECK_EQ(0u, shrinked);
}
} // namespace internal
} // namespace v8