e96a2a174e
HeapTest.GrowAndShrinkNewSpace emulates a GC cycle for shrinking new space. Starting a new MinorMC cycle should first finalize sweeping from the previous GC cycle. Bug: v8:12612 Change-Id: Iea35b54ba0f7be3b7870c557c92042a8d9896045 Reviewed-on: https://chromium-review.googlesource.com/c/v8/v8/+/4055625 Commit-Queue: Michael Lippautz <mlippautz@chromium.org> Auto-Submit: Omer Katz <omerkatz@chromium.org> Reviewed-by: Michael Lippautz <mlippautz@chromium.org> Cr-Commit-Position: refs/heads/main@{#84475}
448 lines
15 KiB
C++
448 lines
15 KiB
C++
// Copyright 2014 the V8 project authors. All rights reserved.
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// Use of this source code is governed by a BSD-style license that can be
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// found in the LICENSE file.
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#include "src/heap/heap.h"
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#include <cmath>
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#include <iostream>
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#include <limits>
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#include "include/v8-isolate.h"
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#include "include/v8-object.h"
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#include "src/flags/flags.h"
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#include "src/handles/handles-inl.h"
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#include "src/heap/gc-tracer.h"
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#include "src/heap/marking-state-inl.h"
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#include "src/heap/memory-chunk.h"
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#include "src/heap/remembered-set.h"
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#include "src/heap/safepoint.h"
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#include "src/heap/spaces-inl.h"
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#include "src/objects/objects-inl.h"
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#include "test/unittests/heap/heap-utils.h"
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#include "test/unittests/test-utils.h"
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#include "testing/gtest/include/gtest/gtest.h"
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namespace v8 {
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namespace internal {
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using HeapTest = TestWithHeapInternalsAndContext;
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TEST(Heap, YoungGenerationSizeFromOldGenerationSize) {
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const size_t pm = i::Heap::kPointerMultiplier;
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const size_t hlm = i::Heap::kHeapLimitMultiplier;
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ASSERT_EQ(3 * 512u * pm * KB,
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i::Heap::YoungGenerationSizeFromOldGenerationSize(128u * hlm * MB));
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ASSERT_EQ(3 * 2048u * pm * KB,
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i::Heap::YoungGenerationSizeFromOldGenerationSize(256u * hlm * MB));
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ASSERT_EQ(3 * 4096u * pm * KB,
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i::Heap::YoungGenerationSizeFromOldGenerationSize(512u * hlm * MB));
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ASSERT_EQ(
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3 * 8192u * pm * KB,
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i::Heap::YoungGenerationSizeFromOldGenerationSize(1024u * hlm * MB));
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}
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TEST(Heap, GenerationSizesFromHeapSize) {
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const size_t pm = i::Heap::kPointerMultiplier;
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const size_t hlm = i::Heap::kHeapLimitMultiplier;
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size_t old, young;
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i::Heap::GenerationSizesFromHeapSize(1 * KB, &young, &old);
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ASSERT_EQ(0u, old);
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ASSERT_EQ(0u, young);
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i::Heap::GenerationSizesFromHeapSize(1 * KB + 3 * 512u * pm * KB, &young,
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&old);
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ASSERT_EQ(1u * KB, old);
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ASSERT_EQ(3 * 512u * pm * KB, young);
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i::Heap::GenerationSizesFromHeapSize(128 * hlm * MB + 3 * 512 * pm * KB,
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&young, &old);
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ASSERT_EQ(128u * hlm * MB, old);
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ASSERT_EQ(3 * 512u * pm * KB, young);
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i::Heap::GenerationSizesFromHeapSize(256u * hlm * MB + 3 * 2048 * pm * KB,
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&young, &old);
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ASSERT_EQ(256u * hlm * MB, old);
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ASSERT_EQ(3 * 2048u * pm * KB, young);
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i::Heap::GenerationSizesFromHeapSize(512u * hlm * MB + 3 * 4096 * pm * KB,
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&young, &old);
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ASSERT_EQ(512u * hlm * MB, old);
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ASSERT_EQ(3 * 4096u * pm * KB, young);
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i::Heap::GenerationSizesFromHeapSize(1024u * hlm * MB + 3 * 8192 * pm * KB,
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&young, &old);
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ASSERT_EQ(1024u * hlm * MB, old);
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ASSERT_EQ(3 * 8192u * pm * KB, young);
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}
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TEST(Heap, HeapSizeFromPhysicalMemory) {
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const size_t pm = i::Heap::kPointerMultiplier;
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const size_t hlm = i::Heap::kHeapLimitMultiplier;
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// The expected value is old_generation_size + 3 * semi_space_size.
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ASSERT_EQ(128 * hlm * MB + 3 * 512 * pm * KB,
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i::Heap::HeapSizeFromPhysicalMemory(0u));
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ASSERT_EQ(128 * hlm * MB + 3 * 512 * pm * KB,
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i::Heap::HeapSizeFromPhysicalMemory(512u * MB));
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ASSERT_EQ(256 * hlm * MB + 3 * 2048 * pm * KB,
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i::Heap::HeapSizeFromPhysicalMemory(1024u * MB));
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ASSERT_EQ(512 * hlm * MB + 3 * 4096 * pm * KB,
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i::Heap::HeapSizeFromPhysicalMemory(2048u * MB));
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ASSERT_EQ(
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1024 * hlm * MB + 3 * 8192 * pm * KB,
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i::Heap::HeapSizeFromPhysicalMemory(static_cast<uint64_t>(4096u) * MB));
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ASSERT_EQ(
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1024 * hlm * MB + 3 * 8192 * pm * KB,
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i::Heap::HeapSizeFromPhysicalMemory(static_cast<uint64_t>(8192u) * MB));
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}
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TEST_F(HeapTest, ASLR) {
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#if V8_TARGET_ARCH_X64
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#if V8_OS_DARWIN
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Heap* heap = i_isolate()->heap();
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std::set<void*> hints;
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for (int i = 0; i < 1000; i++) {
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hints.insert(heap->GetRandomMmapAddr());
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}
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if (hints.size() == 1) {
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EXPECT_TRUE((*hints.begin()) == nullptr);
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EXPECT_TRUE(i::GetRandomMmapAddr() == nullptr);
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} else {
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// It is unlikely that 1000 random samples will collide to less then 500
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// values.
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EXPECT_GT(hints.size(), 500u);
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const uintptr_t kRegionMask = 0xFFFFFFFFu;
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void* first = *hints.begin();
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for (void* hint : hints) {
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uintptr_t diff = reinterpret_cast<uintptr_t>(first) ^
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reinterpret_cast<uintptr_t>(hint);
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EXPECT_LE(diff, kRegionMask);
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}
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}
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#endif // V8_OS_DARWIN
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#endif // V8_TARGET_ARCH_X64
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}
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TEST_F(HeapTest, ExternalLimitDefault) {
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Heap* heap = i_isolate()->heap();
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EXPECT_EQ(kExternalAllocationSoftLimit, heap->external_memory_limit());
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}
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TEST_F(HeapTest, ExternalLimitStaysAboveDefaultForExplicitHandling) {
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v8_isolate()->AdjustAmountOfExternalAllocatedMemory(+10 * MB);
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v8_isolate()->AdjustAmountOfExternalAllocatedMemory(-10 * MB);
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Heap* heap = i_isolate()->heap();
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EXPECT_GE(heap->external_memory_limit(), kExternalAllocationSoftLimit);
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}
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#ifdef V8_COMPRESS_POINTERS
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TEST_F(HeapTest, HeapLayout) {
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// Produce some garbage.
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RunJS(
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"let ar = [];"
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"for (let i = 0; i < 100; i++) {"
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" ar.push(Array(i));"
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"}"
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"ar.push(Array(32 * 1024 * 1024));");
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Address cage_base = i_isolate()->cage_base();
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EXPECT_TRUE(IsAligned(cage_base, size_t{4} * GB));
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Address code_cage_base = i_isolate()->code_cage_base();
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if (V8_EXTERNAL_CODE_SPACE_BOOL) {
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EXPECT_TRUE(IsAligned(code_cage_base, kMinExpectedOSPageSize));
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} else {
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EXPECT_TRUE(IsAligned(code_cage_base, size_t{4} * GB));
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}
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#ifdef V8_COMPRESS_POINTERS_IN_ISOLATE_CAGE
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Address isolate_root = i_isolate()->isolate_root();
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EXPECT_EQ(cage_base, isolate_root);
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#endif
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// Check that all memory chunks belong this region.
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base::AddressRegion heap_reservation(cage_base, size_t{4} * GB);
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base::AddressRegion code_reservation(code_cage_base, size_t{4} * GB);
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IsolateSafepointScope scope(i_isolate()->heap());
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OldGenerationMemoryChunkIterator iter(i_isolate()->heap());
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for (;;) {
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MemoryChunk* chunk = iter.next();
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if (chunk == nullptr) break;
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Address address = chunk->address();
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size_t size = chunk->area_end() - address;
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AllocationSpace owner_id = chunk->owner_identity();
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if (V8_EXTERNAL_CODE_SPACE_BOOL &&
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(owner_id == CODE_SPACE || owner_id == CODE_LO_SPACE)) {
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EXPECT_TRUE(code_reservation.contains(address, size));
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} else {
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EXPECT_TRUE(heap_reservation.contains(address, size));
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}
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}
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}
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#endif // V8_COMPRESS_POINTERS
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namespace {
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void ShrinkNewSpace(NewSpace* new_space) {
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if (!v8_flags.minor_mc) {
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new_space->Shrink();
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return;
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}
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// MinorMC shrinks the space as part of sweeping.
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PagedNewSpace* paged_new_space = PagedNewSpace::From(new_space);
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Heap* heap = paged_new_space->heap();
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heap->EnsureSweepingCompleted(Heap::SweepingForcedFinalizationMode::kV8Only);
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GCTracer* tracer = heap->tracer();
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tracer->StartObservablePause();
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tracer->StartCycle(GarbageCollector::MARK_COMPACTOR,
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GarbageCollectionReason::kTesting, "heap unittest",
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GCTracer::MarkingType::kAtomic);
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tracer->StartAtomicPause();
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paged_new_space->StartShrinking();
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for (Page* page = paged_new_space->first_page();
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page != paged_new_space->last_page() &&
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(paged_new_space->ShouldReleasePage());) {
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Page* current_page = page;
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page = page->next_page();
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if (current_page->allocated_bytes() == 0) {
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paged_new_space->ReleasePage(current_page);
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}
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}
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paged_new_space->FinishShrinking();
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tracer->StopAtomicPause();
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tracer->StopObservablePause();
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tracer->NotifyFullSweepingCompleted();
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}
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} // namespace
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TEST_F(HeapTest, GrowAndShrinkNewSpace) {
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if (v8_flags.single_generation) return;
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{
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ManualGCScope manual_gc_scope(i_isolate());
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// Avoid shrinking new space in GC epilogue. This can happen if allocation
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// throughput samples have been taken while executing the benchmark.
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v8_flags.predictable = true;
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v8_flags.stress_concurrent_allocation = false; // For SimulateFullSpace.
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}
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NewSpace* new_space = heap()->new_space();
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if (heap()->MaxSemiSpaceSize() == heap()->InitialSemiSpaceSize()) {
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return;
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}
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// Make sure we're in a consistent state to start out.
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CollectAllGarbage();
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CollectAllGarbage();
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ShrinkNewSpace(new_space);
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// Explicitly growing should double the space capacity.
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size_t old_capacity, new_capacity;
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old_capacity = new_space->TotalCapacity();
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GrowNewSpace();
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new_capacity = new_space->TotalCapacity();
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CHECK_EQ(2 * old_capacity, new_capacity);
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old_capacity = new_space->TotalCapacity();
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{
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v8::HandleScope temporary_scope(reinterpret_cast<v8::Isolate*>(isolate()));
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SimulateFullSpace(new_space);
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}
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new_capacity = new_space->TotalCapacity();
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CHECK_EQ(old_capacity, new_capacity);
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// Explicitly shrinking should not affect space capacity.
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old_capacity = new_space->TotalCapacity();
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ShrinkNewSpace(new_space);
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new_capacity = new_space->TotalCapacity();
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CHECK_EQ(old_capacity, new_capacity);
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// Let the scavenger empty the new space.
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CollectGarbage(NEW_SPACE);
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CHECK_LE(new_space->Size(), old_capacity);
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// Explicitly shrinking should halve the space capacity.
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old_capacity = new_space->TotalCapacity();
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ShrinkNewSpace(new_space);
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new_capacity = new_space->TotalCapacity();
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if (v8_flags.minor_mc) {
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// Shrinking may not be able to remove any pages if all contain live
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// objects.
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CHECK_GE(old_capacity, new_capacity);
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} else {
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CHECK_EQ(old_capacity, 2 * new_capacity);
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}
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// Consecutive shrinking should not affect space capacity.
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old_capacity = new_space->TotalCapacity();
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ShrinkNewSpace(new_space);
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ShrinkNewSpace(new_space);
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ShrinkNewSpace(new_space);
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new_capacity = new_space->TotalCapacity();
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CHECK_EQ(old_capacity, new_capacity);
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}
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TEST_F(HeapTest, CollectingAllAvailableGarbageShrinksNewSpace) {
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if (v8_flags.single_generation) return;
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v8_flags.stress_concurrent_allocation = false; // For SimulateFullSpace.
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if (heap()->MaxSemiSpaceSize() == heap()->InitialSemiSpaceSize()) {
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return;
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}
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v8::Isolate* iso = reinterpret_cast<v8::Isolate*>(isolate());
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v8::HandleScope scope(iso);
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NewSpace* new_space = heap()->new_space();
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size_t old_capacity, new_capacity;
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old_capacity = new_space->TotalCapacity();
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GrowNewSpace();
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new_capacity = new_space->TotalCapacity();
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CHECK_EQ(2 * old_capacity, new_capacity);
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{
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v8::HandleScope temporary_scope(iso);
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SimulateFullSpace(new_space);
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}
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CollectAllAvailableGarbage();
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new_capacity = new_space->TotalCapacity();
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CHECK_EQ(old_capacity, new_capacity);
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}
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// Test that HAllocateObject will always return an object in new-space.
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TEST_F(HeapTest, OptimizedAllocationAlwaysInNewSpace) {
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if (v8_flags.single_generation) return;
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v8_flags.allow_natives_syntax = true;
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v8_flags.stress_concurrent_allocation = false; // For SimulateFullSpace.
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if (!isolate()->use_optimizer() || v8_flags.always_turbofan) return;
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if (v8_flags.gc_global || v8_flags.stress_compaction ||
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v8_flags.stress_incremental_marking)
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return;
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v8::Isolate* iso = reinterpret_cast<v8::Isolate*>(isolate());
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v8::HandleScope scope(iso);
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v8::Local<v8::Context> ctx = iso->GetCurrentContext();
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SimulateFullSpace(heap()->new_space());
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AlwaysAllocateScopeForTesting always_allocate(heap());
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v8::Local<v8::Value> res = WithIsolateScopeMixin::RunJS(
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"function c(x) {"
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" this.x = x;"
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" for (var i = 0; i < 32; i++) {"
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" this['x' + i] = x;"
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" }"
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"}"
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"function f(x) { return new c(x); };"
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"%PrepareFunctionForOptimization(f);"
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"f(1); f(2); f(3);"
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"%OptimizeFunctionOnNextCall(f);"
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"f(4);");
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CHECK_EQ(4, res.As<v8::Object>()
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->GetRealNamedProperty(ctx, NewString("x"))
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.ToLocalChecked()
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->Int32Value(ctx)
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.FromJust());
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i::Handle<JSReceiver> o =
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v8::Utils::OpenHandle(*v8::Local<v8::Object>::Cast(res));
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CHECK(Heap::InYoungGeneration(*o));
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}
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namespace {
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template <RememberedSetType direction>
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static size_t GetRememberedSetSize(HeapObject obj) {
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size_t count = 0;
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auto chunk = MemoryChunk::FromHeapObject(obj);
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RememberedSet<direction>::Iterate(
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chunk,
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[&count](MaybeObjectSlot slot) {
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count++;
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return KEEP_SLOT;
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},
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SlotSet::KEEP_EMPTY_BUCKETS);
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return count;
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}
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} // namespace
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TEST_F(HeapTest, RememberedSet_InsertOnPromotingObjectToOld) {
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if (v8_flags.single_generation || v8_flags.stress_incremental_marking) return;
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v8_flags.stress_concurrent_allocation = false; // For SealCurrentObjects.
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Factory* factory = isolate()->factory();
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Heap* heap = isolate()->heap();
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SealCurrentObjects();
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HandleScope scope(isolate());
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// Create a young object and age it one generation inside the new space.
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Handle<FixedArray> arr = factory->NewFixedArray(1);
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std::vector<Handle<FixedArray>> handles;
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if (v8_flags.minor_mc) {
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NewSpace* new_space = heap->new_space();
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CHECK(!new_space->IsAtMaximumCapacity());
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// Fill current pages to force MinorMC to promote them.
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SimulateFullSpace(new_space, &handles);
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IsolateSafepointScope scope(heap);
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// New empty pages should remain in new space.
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new_space->Grow();
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CHECK(new_space->EnsureCurrentCapacity());
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} else {
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CollectGarbage(i::NEW_SPACE);
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}
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CHECK(Heap::InYoungGeneration(*arr));
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// Add into 'arr' a reference to an object one generation younger.
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{
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HandleScope scope_inner(isolate());
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Handle<Object> number = factory->NewHeapNumber(42);
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arr->set(0, *number);
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}
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// Promote 'arr' into old, its element is still in new, the old to new
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// refs are inserted into the remembered sets during GC.
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CollectGarbage(i::NEW_SPACE);
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CHECK(heap->InOldSpace(*arr));
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CHECK(heap->InYoungGeneration(arr->get(0)));
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CHECK_EQ(1, GetRememberedSetSize<OLD_TO_NEW>(*arr));
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}
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TEST_F(HeapTest, Regress978156) {
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if (!v8_flags.incremental_marking) return;
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if (v8_flags.single_generation) return;
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ManualGCScope manual_gc_scope(isolate());
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HandleScope handle_scope(isolate());
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Heap* heap = isolate()->heap();
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// 1. Ensure that the new space is empty.
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GcAndSweep(OLD_SPACE);
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// 2. Fill the new space with FixedArrays.
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std::vector<Handle<FixedArray>> arrays;
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SimulateFullSpace(heap->new_space(), &arrays);
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// 3. Trim the last array by one word thus creating a one-word filler.
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Handle<FixedArray> last = arrays.back();
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CHECK_GT(last->length(), 0);
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heap->RightTrimFixedArray(*last, 1);
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// 4. Get the last filler on the page.
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HeapObject filler = HeapObject::FromAddress(
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MemoryChunk::FromHeapObject(*last)->area_end() - kTaggedSize);
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HeapObject::FromAddress(last->address() + last->Size());
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CHECK(filler.IsFiller());
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// 5. Start incremental marking.
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i::IncrementalMarking* marking = heap->incremental_marking();
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if (marking->IsStopped()) {
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IsolateSafepointScope scope(heap);
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heap->tracer()->StartCycle(
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GarbageCollector::MARK_COMPACTOR, GarbageCollectionReason::kTesting,
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"collector cctest", GCTracer::MarkingType::kIncremental);
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marking->Start(GarbageCollector::MARK_COMPACTOR,
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i::GarbageCollectionReason::kTesting);
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}
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MarkingState* marking_state = heap->marking_state();
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// 6. Mark the filler black to access its two markbits. This triggers
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// an out-of-bounds access of the marking bitmap in a bad case.
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marking_state->WhiteToGrey(filler);
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marking_state->GreyToBlack(filler);
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}
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} // namespace internal
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} // namespace v8
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