runtime/gc/heap.cc

/*
 * Copyright (C) 2011 The Android Open Source Project
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 *      http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

#include "heap.h"

#include <limits>
#include <memory>
#include <unwind.h>  // For GC verification.
#include <vector>

#include "android-base/stringprintf.h"

#include "allocation_listener.h"
#include "art_field-inl.h"
#include "base/allocator.h"
#include "base/arena_allocator.h"
#include "base/dumpable.h"
#include "base/histogram-inl.h"
#include "base/stl_util.h"
#include "base/systrace.h"
#include "base/time_utils.h"
#include "common_throws.h"
#include "cutils/sched_policy.h"
#include "debugger.h"
#include "dex_file-inl.h"
#include "gc/accounting/atomic_stack.h"
#include "gc/accounting/card_table-inl.h"
#include "gc/accounting/heap_bitmap-inl.h"
#include "gc/accounting/mod_union_table-inl.h"
#include "gc/accounting/remembered_set.h"
#include "gc/accounting/space_bitmap-inl.h"
#include "gc/collector/concurrent_copying.h"
#include "gc/collector/mark_compact.h"
#include "gc/collector/mark_sweep.h"
#include "gc/collector/partial_mark_sweep.h"
#include "gc/collector/semi_space.h"
#include "gc/collector/sticky_mark_sweep.h"
#include "gc/reference_processor.h"
#include "gc/scoped_gc_critical_section.h"
#include "gc/space/bump_pointer_space.h"
#include "gc/space/dlmalloc_space-inl.h"
#include "gc/space/image_space.h"
#include "gc/space/large_object_space.h"
#include "gc/space/region_space.h"
#include "gc/space/rosalloc_space-inl.h"
#include "gc/space/space-inl.h"
#include "gc/space/zygote_space.h"
#include "gc/task_processor.h"
#include "entrypoints/quick/quick_alloc_entrypoints.h"
#include "gc_pause_listener.h"
#include "heap-inl.h"
#include "image.h"
#include "intern_table.h"
#include "jit/jit.h"
#include "jit/jit_code_cache.h"
#include "obj_ptr-inl.h"
#include "mirror/class-inl.h"
#include "mirror/object-inl.h"
#include "mirror/object_array-inl.h"
#include "mirror/reference-inl.h"
#include "os.h"
#include "reflection.h"
#include "runtime.h"
#include "ScopedLocalRef.h"
#include "scoped_thread_state_change-inl.h"
#include "handle_scope-inl.h"
#include "thread_list.h"
#include "well_known_classes.h"

namespace art {

namespace gc {

using android::base::StringPrintf;

static constexpr size_t kCollectorTransitionStressIterations = 0;
static constexpr size_t kCollectorTransitionStressWait = 10 * 1000;  // Microseconds
// Minimum amount of remaining bytes before a concurrent GC is triggered.
static constexpr size_t kMinConcurrentRemainingBytes = 128 * KB;
static constexpr size_t kMaxConcurrentRemainingBytes = 512 * KB;
// Sticky GC throughput adjustment, divided by 4. Increasing this causes sticky GC to occur more
// relative to partial/full GC. This may be desirable since sticky GCs interfere less with mutator
// threads (lower pauses, use less memory bandwidth).
static constexpr double kStickyGcThroughputAdjustment = 1.0;
// Whether or not we compact the zygote in PreZygoteFork.
static constexpr bool kCompactZygote = kMovingCollector;
// How many reserve entries are at the end of the allocation stack, these are only needed if the
// allocation stack overflows.
static constexpr size_t kAllocationStackReserveSize = 1024;
// Default mark stack size in bytes.
static const size_t kDefaultMarkStackSize = 64 * KB;
// Define space name.
static const char* kDlMallocSpaceName[2] = {"main dlmalloc space", "main dlmalloc space 1"};
static const char* kRosAllocSpaceName[2] = {"main rosalloc space", "main rosalloc space 1"};
static const char* kMemMapSpaceName[2] = {"main space", "main space 1"};
static const char* kNonMovingSpaceName = "non moving space";
static const char* kZygoteSpaceName = "zygote space";
static constexpr size_t kGSSBumpPointerSpaceCapacity = 32 * MB;
static constexpr bool kGCALotMode = false;
// GC alot mode uses a small allocation stack to stress test a lot of GC.
static constexpr size_t kGcAlotAllocationStackSize = 4 * KB /
    sizeof(mirror::HeapReference<mirror::Object>);
// Verify objet has a small allocation stack size since searching the allocation stack is slow.
static constexpr size_t kVerifyObjectAllocationStackSize = 16 * KB /
    sizeof(mirror::HeapReference<mirror::Object>);
static constexpr size_t kDefaultAllocationStackSize = 8 * MB /
    sizeof(mirror::HeapReference<mirror::Object>);
// System.runFinalization can deadlock with native allocations, to deal with this, we have a
// timeout on how long we wait for finalizers to run. b/21544853
static constexpr uint64_t kNativeAllocationFinalizeTimeout = MsToNs(250u);

// For deterministic compilation, we need the heap to be at a well-known address.
static constexpr uint32_t kAllocSpaceBeginForDeterministicAoT = 0x40000000;
// Dump the rosalloc stats on SIGQUIT.
static constexpr bool kDumpRosAllocStatsOnSigQuit = false;

static constexpr size_t kNativeAllocationHistogramBuckets = 16;

// Extra added to the heap growth multiplier. Used to adjust the GC ergonomics for the read barrier
// config.
static constexpr double kExtraHeapGrowthMultiplier = kUseReadBarrier ? 1.0 : 0.0;

static inline bool CareAboutPauseTimes() {
  return Runtime::Current()->InJankPerceptibleProcessState();
}

Heap::Heap(size_t initial_size,
           size_t growth_limit,
           size_t min_free,
           size_t max_free,
           double target_utilization,
           double foreground_heap_growth_multiplier,
           size_t capacity,
           size_t non_moving_space_capacity,
           const std::string& image_file_name,
           const InstructionSet image_instruction_set,
           CollectorType foreground_collector_type,
           CollectorType background_collector_type,
           space::LargeObjectSpaceType large_object_space_type,
           size_t large_object_threshold,
           size_t parallel_gc_threads,
           size_t conc_gc_threads,
           bool low_memory_mode,
           size_t long_pause_log_threshold,
           size_t long_gc_log_threshold,
           bool ignore_max_footprint,
           bool use_tlab,
           bool verify_pre_gc_heap,
           bool verify_pre_sweeping_heap,
           bool verify_post_gc_heap,
           bool verify_pre_gc_rosalloc,
           bool verify_pre_sweeping_rosalloc,
           bool verify_post_gc_rosalloc,
           bool gc_stress_mode,
           bool measure_gc_performance,
           bool use_homogeneous_space_compaction_for_oom,
           uint64_t min_interval_homogeneous_space_compaction_by_oom)
    : non_moving_space_(nullptr),
      rosalloc_space_(nullptr),
      dlmalloc_space_(nullptr),
      main_space_(nullptr),
      collector_type_(kCollectorTypeNone),
      foreground_collector_type_(foreground_collector_type),
      background_collector_type_(background_collector_type),
      desired_collector_type_(foreground_collector_type_),
      pending_task_lock_(nullptr),
      parallel_gc_threads_(parallel_gc_threads),
      conc_gc_threads_(conc_gc_threads),
      low_memory_mode_(low_memory_mode),
      long_pause_log_threshold_(long_pause_log_threshold),
      long_gc_log_threshold_(long_gc_log_threshold),
      ignore_max_footprint_(ignore_max_footprint),
      zygote_creation_lock_("zygote creation lock", kZygoteCreationLock),
      zygote_space_(nullptr),
      large_object_threshold_(large_object_threshold),
      disable_thread_flip_count_(0),
      thread_flip_running_(false),
      collector_type_running_(kCollectorTypeNone),
      last_gc_type_(collector::kGcTypeNone),
      next_gc_type_(collector::kGcTypePartial),
      capacity_(capacity),
      growth_limit_(growth_limit),
      max_allowed_footprint_(initial_size),
      native_footprint_gc_watermark_(initial_size),
      native_need_to_run_finalization_(false),
      concurrent_start_bytes_(std::numeric_limits<size_t>::max()),
      total_bytes_freed_ever_(0),
      total_objects_freed_ever_(0),
      num_bytes_allocated_(0),
      native_bytes_allocated_(0),
      native_histogram_lock_("Native allocation lock"),
      native_allocation_histogram_("Native allocation sizes",
                                   1U,
                                   kNativeAllocationHistogramBuckets),
      native_free_histogram_("Native free sizes", 1U, kNativeAllocationHistogramBuckets),
      num_bytes_freed_revoke_(0),
      verify_missing_card_marks_(false),
      verify_system_weaks_(false),
      verify_pre_gc_heap_(verify_pre_gc_heap),
      verify_pre_sweeping_heap_(verify_pre_sweeping_heap),
      verify_post_gc_heap_(verify_post_gc_heap),
      verify_mod_union_table_(false),
      verify_pre_gc_rosalloc_(verify_pre_gc_rosalloc),
      verify_pre_sweeping_rosalloc_(verify_pre_sweeping_rosalloc),
      verify_post_gc_rosalloc_(verify_post_gc_rosalloc),
      gc_stress_mode_(gc_stress_mode),
      /* For GC a lot mode, we limit the allocations stacks to be kGcAlotInterval allocations. This
       * causes a lot of GC since we do a GC for alloc whenever the stack is full. When heap
       * verification is enabled, we limit the size of allocation stacks to speed up their
       * searching.
       */
      max_allocation_stack_size_(kGCALotMode ? kGcAlotAllocationStackSize
          : (kVerifyObjectSupport > kVerifyObjectModeFast) ? kVerifyObjectAllocationStackSize :
          kDefaultAllocationStackSize),
      current_allocator_(kAllocatorTypeDlMalloc),
      current_non_moving_allocator_(kAllocatorTypeNonMoving),
      bump_pointer_space_(nullptr),
      temp_space_(nullptr),
      region_space_(nullptr),
      min_free_(min_free),
      max_free_(max_free),
      target_utilization_(target_utilization),
      foreground_heap_growth_multiplier_(
          foreground_heap_growth_multiplier + kExtraHeapGrowthMultiplier),
      total_wait_time_(0),
      verify_object_mode_(kVerifyObjectModeDisabled),
      disable_moving_gc_count_(0),
      semi_space_collector_(nullptr),
      mark_compact_collector_(nullptr),
      concurrent_copying_collector_(nullptr),
      is_running_on_memory_tool_(Runtime::Current()->IsRunningOnMemoryTool()),
      use_tlab_(use_tlab),
      main_space_backup_(nullptr),
      min_interval_homogeneous_space_compaction_by_oom_(
          min_interval_homogeneous_space_compaction_by_oom),
      last_time_homogeneous_space_compaction_by_oom_(NanoTime()),
      pending_collector_transition_(nullptr),
      pending_heap_trim_(nullptr),
      use_homogeneous_space_compaction_for_oom_(use_homogeneous_space_compaction_for_oom),
      running_collection_is_blocking_(false),
      blocking_gc_count_(0U),
      blocking_gc_time_(0U),
      last_update_time_gc_count_rate_histograms_(  // Round down by the window duration.
          (NanoTime() / kGcCountRateHistogramWindowDuration) * kGcCountRateHistogramWindowDuration),
      gc_count_last_window_(0U),
      blocking_gc_count_last_window_(0U),
      gc_count_rate_histogram_("gc count rate histogram", 1U, kGcCountRateMaxBucketCount),
      blocking_gc_count_rate_histogram_("blocking gc count rate histogram", 1U,
                                        kGcCountRateMaxBucketCount),
      alloc_tracking_enabled_(false),
      backtrace_lock_(nullptr),
      seen_backtrace_count_(0u),
      unique_backtrace_count_(0u),
      gc_disabled_for_shutdown_(false) {
  if (VLOG_IS_ON(heap) || VLOG_IS_ON(startup)) {
    LOG(INFO) << "Heap() entering";
  }
  if (kUseReadBarrier) {
    CHECK_EQ(foreground_collector_type_, kCollectorTypeCC);
    CHECK_EQ(background_collector_type_, kCollectorTypeCCBackground);
  }
  CHECK_GE(large_object_threshold, kMinLargeObjectThreshold);
  ScopedTrace trace(__FUNCTION__);
  Runtime* const runtime = Runtime::Current();
  // If we aren't the zygote, switch to the default non zygote allocator. This may update the
  // entrypoints.
  const bool is_zygote = runtime->IsZygote();
  if (!is_zygote) {
    // Background compaction is currently not supported for command line runs.
    if (background_collector_type_ != foreground_collector_type_) {
      VLOG(heap) << "Disabling background compaction for non zygote";
      background_collector_type_ = foreground_collector_type_;
    }
  }
  ChangeCollector(desired_collector_type_);
  live_bitmap_.reset(new accounting::HeapBitmap(this));
  mark_bitmap_.reset(new accounting::HeapBitmap(this));
  // Requested begin for the alloc space, to follow the mapped image and oat files
  uint8_t* requested_alloc_space_begin = nullptr;
  if (foreground_collector_type_ == kCollectorTypeCC) {
    // Need to use a low address so that we can allocate a contiguous
    // 2 * Xmx space when there's no image (dex2oat for target).
    CHECK_GE(300 * MB, non_moving_space_capacity);
    requested_alloc_space_begin = reinterpret_cast<uint8_t*>(300 * MB) - non_moving_space_capacity;
  }

  // Load image space(s).
  if (space::ImageSpace::LoadBootImage(image_file_name,
                                       image_instruction_set,
                                       &boot_image_spaces_,
                                       &requested_alloc_space_begin)) {
    for (auto space : boot_image_spaces_) {
      AddSpace(space);
    }
  }

  /*
  requested_alloc_space_begin ->     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-
                                     +-  nonmoving space (non_moving_space_capacity)+-
                                     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-
                                     +-????????????????????????????????????????????+-
                                     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-
                                     +-main alloc space / bump space 1 (capacity_) +-
                                     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-
                                     +-????????????????????????????????????????????+-
                                     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-
                                     +-main alloc space2 / bump space 2 (capacity_)+-
                                     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-
  */
  // We don't have hspace compaction enabled with GSS or CC.
  if (foreground_collector_type_ == kCollectorTypeGSS ||
      foreground_collector_type_ == kCollectorTypeCC) {
    use_homogeneous_space_compaction_for_oom_ = false;
  }
  bool support_homogeneous_space_compaction =
      background_collector_type_ == gc::kCollectorTypeHomogeneousSpaceCompact ||
      use_homogeneous_space_compaction_for_oom_;
  // We may use the same space the main space for the non moving space if we don't need to compact
  // from the main space.
  // This is not the case if we support homogeneous compaction or have a moving background
  // collector type.
  bool separate_non_moving_space = is_zygote ||
      support_homogeneous_space_compaction || IsMovingGc(foreground_collector_type_) ||
      IsMovingGc(background_collector_type_);
  if (foreground_collector_type_ == kCollectorTypeGSS) {
    separate_non_moving_space = false;
  }
  std::unique_ptr<MemMap> main_mem_map_1;
  std::unique_ptr<MemMap> main_mem_map_2;

  // Gross hack to make dex2oat deterministic.
  if (foreground_collector_type_ == kCollectorTypeMS &&
      requested_alloc_space_begin == nullptr &&
      Runtime::Current()->IsAotCompiler()) {
    // Currently only enabled for MS collector since that is what the deterministic dex2oat uses.
    // b/26849108
    requested_alloc_space_begin = reinterpret_cast<uint8_t*>(kAllocSpaceBeginForDeterministicAoT);
  }
  uint8_t* request_begin = requested_alloc_space_begin;
  if (request_begin != nullptr && separate_non_moving_space) {
    request_begin += non_moving_space_capacity;
  }
  std::string error_str;
  std::unique_ptr<MemMap> non_moving_space_mem_map;
  if (separate_non_moving_space) {
    ScopedTrace trace2("Create separate non moving space");
    // If we are the zygote, the non moving space becomes the zygote space when we run
    // PreZygoteFork the first time. In this case, call the map "zygote space" since we can't
    // rename the mem map later.
    const char* space_name = is_zygote ? kZygoteSpaceName: kNonMovingSpaceName;
    // Reserve the non moving mem map before the other two since it needs to be at a specific
    // address.
    non_moving_space_mem_map.reset(
        MemMap::MapAnonymous(space_name, requested_alloc_space_begin,
                             non_moving_space_capacity, PROT_READ | PROT_WRITE, true, false,
                             &error_str));
    CHECK(non_moving_space_mem_map != nullptr) << error_str;
    // Try to reserve virtual memory at a lower address if we have a separate non moving space.
    request_begin = reinterpret_cast<uint8_t*>(300 * MB);
  }
  // Attempt to create 2 mem maps at or after the requested begin.
  if (foreground_collector_type_ != kCollectorTypeCC) {
    ScopedTrace trace2("Create main mem map");
    if (separate_non_moving_space || !is_zygote) {
      main_mem_map_1.reset(MapAnonymousPreferredAddress(kMemMapSpaceName[0],
                                                        request_begin,
                                                        capacity_,
                                                        &error_str));
    } else {
      // If no separate non-moving space and we are the zygote, the main space must come right
      // after the image space to avoid a gap. This is required since we want the zygote space to
      // be adjacent to the image space.
      main_mem_map_1.reset(MemMap::MapAnonymous(kMemMapSpaceName[0], request_begin, capacity_,
                                                PROT_READ | PROT_WRITE, true, false,
                                                &error_str));
    }
    CHECK(main_mem_map_1.get() != nullptr) << error_str;
  }
  if (support_homogeneous_space_compaction ||
      background_collector_type_ == kCollectorTypeSS ||
      foreground_collector_type_ == kCollectorTypeSS) {
    ScopedTrace trace2("Create main mem map 2");
    main_mem_map_2.reset(MapAnonymousPreferredAddress(kMemMapSpaceName[1], main_mem_map_1->End(),
                                                      capacity_, &error_str));
    CHECK(main_mem_map_2.get() != nullptr) << error_str;
  }

  // Create the non moving space first so that bitmaps don't take up the address range.
  if (separate_non_moving_space) {
    ScopedTrace trace2("Add non moving space");
    // Non moving space is always dlmalloc since we currently don't have support for multiple
    // active rosalloc spaces.
    const size_t size = non_moving_space_mem_map->Size();
    non_moving_space_ = space::DlMallocSpace::CreateFromMemMap(
        non_moving_space_mem_map.release(), "zygote / non moving space", kDefaultStartingSize,
        initial_size, size, size, false);
    non_moving_space_->SetFootprintLimit(non_moving_space_->Capacity());
    CHECK(non_moving_space_ != nullptr) << "Failed creating non moving space "
        << requested_alloc_space_begin;
    AddSpace(non_moving_space_);
  }
  // Create other spaces based on whether or not we have a moving GC.
  if (foreground_collector_type_ == kCollectorTypeCC) {
    region_space_ = space::RegionSpace::Create("main space (region space)", capacity_ * 2, request_begin);
    AddSpace(region_space_);
  } else if (IsMovingGc(foreground_collector_type_) &&
      foreground_collector_type_ != kCollectorTypeGSS) {
    // Create bump pointer spaces.
    // We only to create the bump pointer if the foreground collector is a compacting GC.
    // TODO: Place bump-pointer spaces somewhere to minimize size of card table.
    bump_pointer_space_ = space::BumpPointerSpace::CreateFromMemMap("Bump pointer space 1",
                                                                    main_mem_map_1.release());
    CHECK(bump_pointer_space_ != nullptr) << "Failed to create bump pointer space";
    AddSpace(bump_pointer_space_);
    temp_space_ = space::BumpPointerSpace::CreateFromMemMap("Bump pointer space 2",
                                                            main_mem_map_2.release());
    CHECK(temp_space_ != nullptr) << "Failed to create bump pointer space";
    AddSpace(temp_space_);
    CHECK(separate_non_moving_space);
  } else {
    CreateMainMallocSpace(main_mem_map_1.release(), initial_size, growth_limit_, capacity_);
    CHECK(main_space_ != nullptr);
    AddSpace(main_space_);
    if (!separate_non_moving_space) {
      non_moving_space_ = main_space_;
      CHECK(!non_moving_space_->CanMoveObjects());
    }
    if (foreground_collector_type_ == kCollectorTypeGSS) {
      CHECK_EQ(foreground_collector_type_, background_collector_type_);
      // Create bump pointer spaces instead of a backup space.
      main_mem_map_2.release();
      bump_pointer_space_ = space::BumpPointerSpace::Create("Bump pointer space 1",
                                                            kGSSBumpPointerSpaceCapacity, nullptr);
      CHECK(bump_pointer_space_ != nullptr);
      AddSpace(bump_pointer_space_);
      temp_space_ = space::BumpPointerSpace::Create("Bump pointer space 2",
                                                    kGSSBumpPointerSpaceCapacity, nullptr);
      CHECK(temp_space_ != nullptr);
      AddSpace(temp_space_);
    } else if (main_mem_map_2.get() != nullptr) {
      const char* name = kUseRosAlloc ? kRosAllocSpaceName[1] : kDlMallocSpaceName[1];
      main_space_backup_.reset(CreateMallocSpaceFromMemMap(main_mem_map_2.release(), initial_size,
                                                           growth_limit_, capacity_, name, true));
      CHECK(main_space_backup_.get() != nullptr);
      // Add the space so its accounted for in the heap_begin and heap_end.
      AddSpace(main_space_backup_.get());
    }
  }
  CHECK(non_moving_space_ != nullptr);
  CHECK(!non_moving_space_->CanMoveObjects());
  // Allocate the large object space.
  if (large_object_space_type == space::LargeObjectSpaceType::kFreeList) {
    large_object_space_ = space::FreeListSpace::Create("free list large object space", nullptr,
                                                       capacity_);
    CHECK(large_object_space_ != nullptr) << "Failed to create large object space";
  } else if (large_object_space_type == space::LargeObjectSpaceType::kMap) {
    large_object_space_ = space::LargeObjectMapSpace::Create("mem map large object space");
    CHECK(large_object_space_ != nullptr) << "Failed to create large object space";
  } else {
    // Disable the large object space by making the cutoff excessively large.
    large_object_threshold_ = std::numeric_limits<size_t>::max();
    large_object_space_ = nullptr;
  }
  if (large_object_space_ != nullptr) {
    AddSpace(large_object_space_);
  }
  // Compute heap capacity. Continuous spaces are sorted in order of Begin().
  CHECK(!continuous_spaces_.empty());
  // Relies on the spaces being sorted.
  uint8_t* heap_begin = continuous_spaces_.front()->Begin();
  uint8_t* heap_end = continuous_spaces_.back()->Limit();
  size_t heap_capacity = heap_end - heap_begin;
  // Remove the main backup space since it slows down the GC to have unused extra spaces.
  // TODO: Avoid needing to do this.
  if (main_space_backup_.get() != nullptr) {
    RemoveSpace(main_space_backup_.get());
  }
  // Allocate the card table.
  // We currently don't support dynamically resizing the card table.
  // Since we don't know where in the low_4gb the app image will be located, make the card table
  // cover the whole low_4gb. TODO: Extend the card table in AddSpace.
  UNUSED(heap_capacity);
  // Start at 64 KB, we can be sure there are no spaces mapped this low since the address range is
  // reserved by the kernel.
  static constexpr size_t kMinHeapAddress = 4 * KB;
  card_table_.reset(accounting::CardTable::Create(reinterpret_cast<uint8_t*>(kMinHeapAddress),
                                                  4 * GB - kMinHeapAddress));
  CHECK(card_table_.get() != nullptr) << "Failed to create card table";
  if (foreground_collector_type_ == kCollectorTypeCC && kUseTableLookupReadBarrier) {
    rb_table_.reset(new accounting::ReadBarrierTable());
    DCHECK(rb_table_->IsAllCleared());
  }
  if (HasBootImageSpace()) {
    // Don't add the image mod union table if we are running without an image, this can crash if
    // we use the CardCache implementation.
    for (space::ImageSpace* image_space : GetBootImageSpaces()) {
      accounting::ModUnionTable* mod_union_table = new accounting::ModUnionTableToZygoteAllocspace(
          "Image mod-union table", this, image_space);
      CHECK(mod_union_table != nullptr) << "Failed to create image mod-union table";
      AddModUnionTable(mod_union_table);
    }
  }
  if (collector::SemiSpace::kUseRememberedSet && non_moving_space_ != main_space_) {
    accounting::RememberedSet* non_moving_space_rem_set =
        new accounting::RememberedSet("Non-moving space remembered set", this, non_moving_space_);
    CHECK(non_moving_space_rem_set != nullptr) << "Failed to create non-moving space remembered set";
    AddRememberedSet(non_moving_space_rem_set);
  }
  // TODO: Count objects in the image space here?
  num_bytes_allocated_.StoreRelaxed(0);
  mark_stack_.reset(accounting::ObjectStack::Create("mark stack", kDefaultMarkStackSize,
                                                    kDefaultMarkStackSize));
  const size_t alloc_stack_capacity = max_allocation_stack_size_ + kAllocationStackReserveSize;
  allocation_stack_.reset(accounting::ObjectStack::Create(
      "allocation stack", max_allocation_stack_size_, alloc_stack_capacity));
  live_stack_.reset(accounting::ObjectStack::Create(
      "live stack", max_allocation_stack_size_, alloc_stack_capacity));
  // It's still too early to take a lock because there are no threads yet, but we can create locks
  // now. We don't create it earlier to make it clear that you can't use locks during heap
  // initialization.
  gc_complete_lock_ = new Mutex("GC complete lock");
  gc_complete_cond_.reset(new ConditionVariable("GC complete condition variable",
                                                *gc_complete_lock_));
  thread_flip_lock_ = new Mutex("GC thread flip lock");
  thread_flip_cond_.reset(new ConditionVariable("GC thread flip condition variable",
                                                *thread_flip_lock_));
  task_processor_.reset(new TaskProcessor());
  reference_processor_.reset(new ReferenceProcessor());
  pending_task_lock_ = new Mutex("Pending task lock");
  if (ignore_max_footprint_) {
    SetIdealFootprint(std::numeric_limits<size_t>::max());
    concurrent_start_bytes_ = std::numeric_limits<size_t>::max();
  }
  CHECK_NE(max_allowed_footprint_, 0U);
  // Create our garbage collectors.
  for (size_t i = 0; i < 2; ++i) {
    const bool concurrent = i != 0;
    if ((MayUseCollector(kCollectorTypeCMS) && concurrent) ||
        (MayUseCollector(kCollectorTypeMS) && !concurrent)) {
      garbage_collectors_.push_back(new collector::MarkSweep(this, concurrent));
      garbage_collectors_.push_back(new collector::PartialMarkSweep(this, concurrent));
      garbage_collectors_.push_back(new collector::StickyMarkSweep(this, concurrent));
    }
  }
  if (kMovingCollector) {
    if (MayUseCollector(kCollectorTypeSS) || MayUseCollector(kCollectorTypeGSS) ||
        MayUseCollector(kCollectorTypeHomogeneousSpaceCompact) ||
        use_homogeneous_space_compaction_for_oom_) {
      // TODO: Clean this up.
      const bool generational = foreground_collector_type_ == kCollectorTypeGSS;
      semi_space_collector_ = new collector::SemiSpace(this, generational,
                                                       generational ? "generational" : "");
      garbage_collectors_.push_back(semi_space_collector_);
    }
    if (MayUseCollector(kCollectorTypeCC)) {
      concurrent_copying_collector_ = new collector::ConcurrentCopying(this,
                                                                       "",
                                                                       measure_gc_performance);
      DCHECK(region_space_ != nullptr);
      concurrent_copying_collector_->SetRegionSpace(region_space_);
      garbage_collectors_.push_back(concurrent_copying_collector_);
    }
    if (MayUseCollector(kCollectorTypeMC)) {
      mark_compact_collector_ = new collector::MarkCompact(this);
      garbage_collectors_.push_back(mark_compact_collector_);
    }
  }
  if (!GetBootImageSpaces().empty() && non_moving_space_ != nullptr &&
      (is_zygote || separate_non_moving_space || foreground_collector_type_ == kCollectorTypeGSS)) {
    // Check that there's no gap between the image space and the non moving space so that the
    // immune region won't break (eg. due to a large object allocated in the gap). This is only
    // required when we're the zygote or using GSS.
    // Space with smallest Begin().
    space::ImageSpace* first_space = nullptr;
    for (space::ImageSpace* space : boot_image_spaces_) {
      if (first_space == nullptr || space->Begin() < first_space->Begin()) {
        first_space = space;
      }
    }
    bool no_gap = MemMap::CheckNoGaps(first_space->GetMemMap(), non_moving_space_->GetMemMap());
    if (!no_gap) {
      PrintFileToLog("/proc/self/maps", LogSeverity::ERROR);
      MemMap::DumpMaps(LOG_STREAM(ERROR), true);
      LOG(FATAL) << "There's a gap between the image space and the non-moving space";
    }
  }
  instrumentation::Instrumentation* const instrumentation = runtime->GetInstrumentation();
  if (gc_stress_mode_) {
    backtrace_lock_ = new Mutex("GC complete lock");
  }
  if (is_running_on_memory_tool_ || gc_stress_mode_) {
    instrumentation->InstrumentQuickAllocEntryPoints();
  }
  if (VLOG_IS_ON(heap) || VLOG_IS_ON(startup)) {
    LOG(INFO) << "Heap() exiting";
  }
}

MemMap* Heap::MapAnonymousPreferredAddress(const char* name,
                                           uint8_t* request_begin,
                                           size_t capacity,
                                           std::string* out_error_str) {
  while (true) {
    MemMap* map = MemMap::MapAnonymous(name, request_begin, capacity,
                                       PROT_READ | PROT_WRITE, true, false, out_error_str);
    if (map != nullptr || request_begin == nullptr) {
      return map;
    }
    // Retry a  second time with no specified request begin.
    request_begin = nullptr;
  }
}

bool Heap::MayUseCollector(CollectorType type) const {
  return foreground_collector_type_ == type || background_collector_type_ == type;
}

space::MallocSpace* Heap::CreateMallocSpaceFromMemMap(MemMap* mem_map,
                                                      size_t initial_size,
                                                      size_t growth_limit,
                                                      size_t capacity,
                                                      const char* name,
                                                      bool can_move_objects) {
  space::MallocSpace* malloc_space = nullptr;
  if (kUseRosAlloc) {
    // Create rosalloc space.
    malloc_space = space::RosAllocSpace::CreateFromMemMap(mem_map, name, kDefaultStartingSize,
                                                          initial_size, growth_limit, capacity,
                                                          low_memory_mode_, can_move_objects);
  } else {
    malloc_space = space::DlMallocSpace::CreateFromMemMap(mem_map, name, kDefaultStartingSize,
                                                          initial_size, growth_limit, capacity,
                                                          can_move_objects);
  }
  if (collector::SemiSpace::kUseRememberedSet) {
    accounting::RememberedSet* rem_set  =
        new accounting::RememberedSet(std::string(name) + " remembered set", this, malloc_space);
    CHECK(rem_set != nullptr) << "Failed to create main space remembered set";
    AddRememberedSet(rem_set);
  }
  CHECK(malloc_space != nullptr) << "Failed to create " << name;
  malloc_space->SetFootprintLimit(malloc_space->Capacity());
  return malloc_space;
}

void Heap::CreateMainMallocSpace(MemMap* mem_map, size_t initial_size, size_t growth_limit,
                                 size_t capacity) {
  // Is background compaction is enabled?
  bool can_move_objects = IsMovingGc(background_collector_type_) !=
      IsMovingGc(foreground_collector_type_) || use_homogeneous_space_compaction_for_oom_;
  // If we are the zygote and don't yet have a zygote space, it means that the zygote fork will
  // happen in the future. If this happens and we have kCompactZygote enabled we wish to compact
  // from the main space to the zygote space. If background compaction is enabled, always pass in
  // that we can move objets.
  if (kCompactZygote && Runtime::Current()->IsZygote() && !can_move_objects) {
    // After the zygote we want this to be false if we don't have background compaction enabled so
    // that getting primitive array elements is faster.
    // We never have homogeneous compaction with GSS and don't need a space with movable objects.
    can_move_objects = !HasZygoteSpace() && foreground_collector_type_ != kCollectorTypeGSS;
  }
  if (collector::SemiSpace::kUseRememberedSet && main_space_ != nullptr) {
    RemoveRememberedSet(main_space_);
  }
  const char* name = kUseRosAlloc ? kRosAllocSpaceName[0] : kDlMallocSpaceName[0];
  main_space_ = CreateMallocSpaceFromMemMap(mem_map, initial_size, growth_limit, capacity, name,
                                            can_move_objects);
  SetSpaceAsDefault(main_space_);
  VLOG(heap) << "Created main space " << main_space_;
}

void Heap::ChangeAllocator(AllocatorType allocator) {
  if (current_allocator_ != allocator) {
    // These two allocators are only used internally and don't have any entrypoints.
    CHECK_NE(allocator, kAllocatorTypeLOS);
    CHECK_NE(allocator, kAllocatorTypeNonMoving);
    current_allocator_ = allocator;
    MutexLock mu(nullptr, *Locks::runtime_shutdown_lock_);
    SetQuickAllocEntryPointsAllocator(current_allocator_);
    Runtime::Current()->GetInstrumentation()->ResetQuickAllocEntryPoints();
  }
}

void Heap::DisableMovingGc() {
  CHECK(!kUseReadBarrier);
  if (IsMovingGc(foreground_collector_type_)) {
    foreground_collector_type_ = kCollectorTypeCMS;
  }
  if (IsMovingGc(background_collector_type_)) {
    background_collector_type_ = foreground_collector_type_;
  }
  TransitionCollector(foreground_collector_type_);
  Thread* const self = Thread::Current();
  ScopedThreadStateChange tsc(self, kSuspended);
  ScopedSuspendAll ssa(__FUNCTION__);
  // Something may have caused the transition to fail.
  if (!IsMovingGc(collector_type_) && non_moving_space_ != main_space_) {
    CHECK(main_space_ != nullptr);
    // The allocation stack may have non movable objects in it. We need to flush it since the GC
    // can't only handle marking allocation stack objects of one non moving space and one main
    // space.
    {
      WriterMutexLock mu(self, *Locks::heap_bitmap_lock_);
      FlushAllocStack();
    }
    main_space_->DisableMovingObjects();
    non_moving_space_ = main_space_;
    CHECK(!non_moving_space_->CanMoveObjects());
  }
}

bool Heap::IsCompilingBoot() const {
  if (!Runtime::Current()->IsAotCompiler()) {
    return false;
  }
  ScopedObjectAccess soa(Thread::Current());
  for (const auto& space : continuous_spaces_) {
    if (space->IsImageSpace() || space->IsZygoteSpace()) {
      return false;
    }
  }
  return true;
}

void Heap::IncrementDisableMovingGC(Thread* self) {
  // Need to do this holding the lock to prevent races where the GC is about to run / running when
  // we attempt to disable it.
  ScopedThreadStateChange tsc(self, kWaitingForGcToComplete);
  MutexLock mu(self, *gc_complete_lock_);
  ++disable_moving_gc_count_;
  if (IsMovingGc(collector_type_running_)) {
    WaitForGcToCompleteLocked(kGcCauseDisableMovingGc, self);
  }
}

void Heap::DecrementDisableMovingGC(Thread* self) {
  MutexLock mu(self, *gc_complete_lock_);
  CHECK_GT(disable_moving_gc_count_, 0U);
  --disable_moving_gc_count_;
}

void Heap::IncrementDisableThreadFlip(Thread* self) {
  // Supposed to be called by mutators. If thread_flip_running_ is true, block. Otherwise, go ahead.
  CHECK(kUseReadBarrier);
  bool is_nested = self->GetDisableThreadFlipCount() > 0;
  self->IncrementDisableThreadFlipCount();
  if (is_nested) {
    // If this is a nested JNI critical section enter, we don't need to wait or increment the global
    // counter. The global counter is incremented only once for a thread for the outermost enter.
    return;
  }
  ScopedThreadStateChange tsc(self, kWaitingForGcThreadFlip);
  MutexLock mu(self, *thread_flip_lock_);
  bool has_waited = false;
  uint64_t wait_start = NanoTime();
  if (thread_flip_running_) {
    ATRACE_BEGIN("IncrementDisableThreadFlip");
    while (thread_flip_running_) {
      has_waited = true;
      thread_flip_cond_->Wait(self);
    }
    ATRACE_END();
  }
  ++disable_thread_flip_count_;
  if (has_waited) {
    uint64_t wait_time = NanoTime() - wait_start;
    total_wait_time_ += wait_time;
    if (wait_time > long_pause_log_threshold_) {
      LOG(INFO) << __FUNCTION__ << " blocked for " << PrettyDuration(wait_time);
    }
  }
}

void Heap::DecrementDisableThreadFlip(Thread* self) {
  // Supposed to be called by mutators. Decrement disable_thread_flip_count_ and potentially wake up
  // the GC waiting before doing a thread flip.
  CHECK(kUseReadBarrier);
  self->DecrementDisableThreadFlipCount();
  bool is_outermost = self->GetDisableThreadFlipCount() == 0;
  if (!is_outermost) {
    // If this is not an outermost JNI critical exit, we don't need to decrement the global counter.
    // The global counter is decremented only once for a thread for the outermost exit.
    return;
  }
  MutexLock mu(self, *thread_flip_lock_);
  CHECK_GT(disable_thread_flip_count_, 0U);
  --disable_thread_flip_count_;
  if (disable_thread_flip_count_ == 0) {
    // Potentially notify the GC thread blocking to begin a thread flip.
    thread_flip_cond_->Broadcast(self);
  }
}

void Heap::ThreadFlipBegin(Thread* self) {
  // Supposed to be called by GC. Set thread_flip_running_ to be true. If disable_thread_flip_count_
  // > 0, block. Otherwise, go ahead.
  CHECK(kUseReadBarrier);
  ScopedThreadStateChange tsc(self, kWaitingForGcThreadFlip);
  MutexLock mu(self, *thread_flip_lock_);
  bool has_waited = false;
  uint64_t wait_start = NanoTime();
  CHECK(!thread_flip_running_);
  // Set this to true before waiting so that frequent JNI critical enter/exits won't starve
  // GC. This like a writer preference of a reader-writer lock.
  thread_flip_running_ = true;
  while (disable_thread_flip_count_ > 0) {
    has_waited = true;
    thread_flip_cond_->Wait(self);
  }
  if (has_waited) {
    uint64_t wait_time = NanoTime() - wait_start;
    total_wait_time_ += wait_time;
    if (wait_time > long_pause_log_threshold_) {
      LOG(INFO) << __FUNCTION__ << " blocked for " << PrettyDuration(wait_time);
    }
  }
}

void Heap::ThreadFlipEnd(Thread* self) {
  // Supposed to be called by GC. Set thread_flip_running_ to false and potentially wake up mutators
  // waiting before doing a JNI critical.
  CHECK(kUseReadBarrier);
  MutexLock mu(self, *thread_flip_lock_);
  CHECK(thread_flip_running_);
  thread_flip_running_ = false;
  // Potentially notify mutator threads blocking to enter a JNI critical section.
  thread_flip_cond_->Broadcast(self);
}

void Heap::UpdateProcessState(ProcessState old_process_state, ProcessState new_process_state) {
  if (old_process_state != new_process_state) {
    const bool jank_perceptible = new_process_state == kProcessStateJankPerceptible;
    for (size_t i = 1; i <= kCollectorTransitionStressIterations; ++i) {
      // Start at index 1 to avoid "is always false" warning.
      // Have iteration 1 always transition the collector.
      TransitionCollector((((i & 1) == 1) == jank_perceptible)
          ? foreground_collector_type_
          : background_collector_type_);
      usleep(kCollectorTransitionStressWait);
    }
    if (jank_perceptible) {
      // Transition back to foreground right away to prevent jank.
      RequestCollectorTransition(foreground_collector_type_, 0);
    } else {
      // Don't delay for debug builds since we may want to stress test the GC.
      // If background_collector_type_ is kCollectorTypeHomogeneousSpaceCompact then we have
      // special handling which does a homogenous space compaction once but then doesn't transition
      // the collector. Similarly, we invoke a full compaction for kCollectorTypeCC but don't
      // transition the collector.
      RequestCollectorTransition(background_collector_type_,
                                 kIsDebugBuild ? 0 : kCollectorTransitionWait);
    }
  }
}

void Heap::CreateThreadPool() {
  const size_t num_threads = std::max(parallel_gc_threads_, conc_gc_threads_);
  if (num_threads != 0) {
    thread_pool_.reset(new ThreadPool("Heap thread pool", num_threads));
  }
}

// Visit objects when threads aren't suspended. If concurrent moving
// GC, disable moving GC and suspend threads and then visit objects.
void Heap::VisitObjects(ObjectCallback callback, void* arg) {
  Thread* self = Thread::Current();
  Locks::mutator_lock_->AssertSharedHeld(self);
  DCHECK(!Locks::mutator_lock_->IsExclusiveHeld(self)) << "Call VisitObjectsPaused() instead";
  if (IsGcConcurrentAndMoving()) {
    // Concurrent moving GC. Just suspending threads isn't sufficient
    // because a collection isn't one big pause and we could suspend
    // threads in the middle (between phases) of a concurrent moving
    // collection where it's not easily known which objects are alive
    // (both the region space and the non-moving space) or which
    // copies of objects to visit, and the to-space invariant could be
    // easily broken. Visit objects while GC isn't running by using
    // IncrementDisableMovingGC() and threads are suspended.
    IncrementDisableMovingGC(self);
    {
      ScopedThreadSuspension sts(self, kWaitingForVisitObjects);
      ScopedSuspendAll ssa(__FUNCTION__);
      VisitObjectsInternalRegionSpace(callback, arg);
      VisitObjectsInternal(callback, arg);
    }
    DecrementDisableMovingGC(self);
  } else {
    // Since concurrent moving GC has thread suspension, also poison ObjPtr the normal case to
    // catch bugs.
    self->PoisonObjectPointers();
    // GCs can move objects, so don't allow this.
    ScopedAssertNoThreadSuspension ants("Visiting objects");
    DCHECK(region_space_ == nullptr);
    VisitObjectsInternal(callback, arg);
    self->PoisonObjectPointers();
  }
}

// Visit objects when threads are already suspended.
void Heap::VisitObjectsPaused(ObjectCallback callback, void* arg) {
  Thread* self = Thread::Current();
  Locks::mutator_lock_->AssertExclusiveHeld(self);
  VisitObjectsInternalRegionSpace(callback, arg);
  VisitObjectsInternal(callback, arg);
}

// Visit objects in the region spaces.
void Heap::VisitObjectsInternalRegionSpace(ObjectCallback callback, void* arg) {
  Thread* self = Thread::Current();
  Locks::mutator_lock_->AssertExclusiveHeld(self);
  if (region_space_ != nullptr) {
    DCHECK(IsGcConcurrentAndMoving());
    if (!zygote_creation_lock_.IsExclusiveHeld(self)) {
      // Exclude the pre-zygote fork time where the semi-space collector
      // calls VerifyHeapReferences() as part of the zygote compaction
      // which then would call here without the moving GC disabled,
      // which is fine.
      DCHECK(IsMovingGCDisabled(self));
    }
    region_space_->Walk(callback, arg);
  }
}

// Visit objects in the other spaces.
void Heap::VisitObjectsInternal(ObjectCallback callback, void* arg) {
  if (bump_pointer_space_ != nullptr) {
    // Visit objects in bump pointer space.
    bump_pointer_space_->Walk(callback, arg);
  }
  // TODO: Switch to standard begin and end to use ranged a based loop.
  for (auto* it = allocation_stack_->Begin(), *end = allocation_stack_->End(); it < end; ++it) {
    mirror::Object* const obj = it->AsMirrorPtr();
    if (obj != nullptr && obj->GetClass() != nullptr) {
      // Avoid the race condition caused by the object not yet being written into the allocation
      // stack or the class not yet being written in the object. Or, if
      // kUseThreadLocalAllocationStack, there can be nulls on the allocation stack.
      callback(obj, arg);
    }
  }
  {
    ReaderMutexLock mu(Thread::Current(), *Locks::heap_bitmap_lock_);
    GetLiveBitmap()->Walk(callback, arg);
  }
}

void Heap::MarkAllocStackAsLive(accounting::ObjectStack* stack) {
  space::ContinuousSpace* space1 = main_space_ != nullptr ? main_space_ : non_moving_space_;
  space::ContinuousSpace* space2 = non_moving_space_;
  // TODO: Generalize this to n bitmaps?
  CHECK(space1 != nullptr);
  CHECK(space2 != nullptr);
  MarkAllocStack(space1->GetLiveBitmap(), space2->GetLiveBitmap(),
                 (large_object_space_ != nullptr ? large_object_space_->GetLiveBitmap() : nullptr),
                 stack);
}

void Heap::DeleteThreadPool() {
  thread_pool_.reset(nullptr);
}

void Heap::AddSpace(space::Space* space) {
  CHECK(space != nullptr);
  WriterMutexLock mu(Thread::Current(), *Locks::heap_bitmap_lock_);
  if (space->IsContinuousSpace()) {
    DCHECK(!space->IsDiscontinuousSpace());
    space::ContinuousSpace* continuous_space = space->AsContinuousSpace();
    // Continuous spaces don't necessarily have bitmaps.
    accounting::ContinuousSpaceBitmap* live_bitmap = continuous_space->GetLiveBitmap();
    accounting::ContinuousSpaceBitmap* mark_bitmap = continuous_space->GetMarkBitmap();
    if (live_bitmap != nullptr) {
      CHECK(mark_bitmap != nullptr);
      live_bitmap_->AddContinuousSpaceBitmap(live_bitmap);
      mark_bitmap_->AddContinuousSpaceBitmap(mark_bitmap);
    }
    continuous_spaces_.push_back(continuous_space);
    // Ensure that spaces remain sorted in increasing order of start address.
    std::sort(continuous_spaces_.begin(), continuous_spaces_.end(),
              [](const space::ContinuousSpace* a, const space::ContinuousSpace* b) {
      return a->Begin() < b->Begin();
    });
  } else {
    CHECK(space->IsDiscontinuousSpace());
    space::DiscontinuousSpace* discontinuous_space = space->AsDiscontinuousSpace();
    live_bitmap_->AddLargeObjectBitmap(discontinuous_space->GetLiveBitmap());
    mark_bitmap_->AddLargeObjectBitmap(discontinuous_space->GetMarkBitmap());
    discontinuous_spaces_.push_back(discontinuous_space);
  }
  if (space->IsAllocSpace()) {
    alloc_spaces_.push_back(space->AsAllocSpace());
  }
}

void Heap::SetSpaceAsDefault(space::ContinuousSpace* continuous_space) {
  WriterMutexLock mu(Thread::Current(), *Locks::heap_bitmap_lock_);
  if (continuous_space->IsDlMallocSpace()) {
    dlmalloc_space_ = continuous_space->AsDlMallocSpace();
  } else if (continuous_space->IsRosAllocSpace()) {
    rosalloc_space_ = continuous_space->AsRosAllocSpace();
  }
}

void Heap::RemoveSpace(space::Space* space) {
  DCHECK(space != nullptr);
  WriterMutexLock mu(Thread::Current(), *Locks::heap_bitmap_lock_);
  if (space->IsContinuousSpace()) {
    DCHECK(!space->IsDiscontinuousSpace());
    space::ContinuousSpace* continuous_space = space->AsContinuousSpace();
    // Continuous spaces don't necessarily have bitmaps.
    accounting::ContinuousSpaceBitmap* live_bitmap = continuous_space->GetLiveBitmap();
    accounting::ContinuousSpaceBitmap* mark_bitmap = continuous_space->GetMarkBitmap();
    if (live_bitmap != nullptr) {
      DCHECK(mark_bitmap != nullptr);
      live_bitmap_->RemoveContinuousSpaceBitmap(live_bitmap);
      mark_bitmap_->RemoveContinuousSpaceBitmap(mark_bitmap);
    }
    auto it = std::find(continuous_spaces_.begin(), continuous_spaces_.end(), continuous_space);
    DCHECK(it != continuous_spaces_.end());
    continuous_spaces_.erase(it);
  } else {
    DCHECK(space->IsDiscontinuousSpace());
    space::DiscontinuousSpace* discontinuous_space = space->AsDiscontinuousSpace();
    live_bitmap_->RemoveLargeObjectBitmap(discontinuous_space->GetLiveBitmap());
    mark_bitmap_->RemoveLargeObjectBitmap(discontinuous_space->GetMarkBitmap());
    auto it = std::find(discontinuous_spaces_.begin(), discontinuous_spaces_.end(),
                        discontinuous_space);
    DCHECK(it != discontinuous_spaces_.end());
    discontinuous_spaces_.erase(it);
  }
  if (space->IsAllocSpace()) {
    auto it = std::find(alloc_spaces_.begin(), alloc_spaces_.end(), space->AsAllocSpace());
    DCHECK(it != alloc_spaces_.end());
    alloc_spaces_.erase(it);
  }
}

void Heap::DumpGcPerformanceInfo(std::ostream& os) {
  // Dump cumulative timings.
  os << "Dumping cumulative Gc timings\n";
  uint64_t total_duration = 0;
  // Dump cumulative loggers for each GC type.
  uint64_t total_paused_time = 0;
  for (auto& collector : garbage_collectors_) {
    total_duration += collector->GetCumulativeTimings().GetTotalNs();
    total_paused_time += collector->GetTotalPausedTimeNs();
    collector->DumpPerformanceInfo(os);
  }
  if (total_duration != 0) {
    const double total_seconds = static_cast<double>(total_duration / 1000) / 1000000.0;
    os << "Total time spent in GC: " << PrettyDuration(total_duration) << "\n";
    os << "Mean GC size throughput: "
       << PrettySize(GetBytesFreedEver() / total_seconds) << "/s\n";
    os << "Mean GC object throughput: "
       << (GetObjectsFreedEver() / total_seconds) << " objects/s\n";
  }
  uint64_t total_objects_allocated = GetObjectsAllocatedEver();
  os << "Total number of allocations " << total_objects_allocated << "\n";
  os << "Total bytes allocated " << PrettySize(GetBytesAllocatedEver()) << "\n";
  os << "Total bytes freed " << PrettySize(GetBytesFreedEver()) << "\n";
  os << "Free memory " << PrettySize(GetFreeMemory()) << "\n";
  os << "Free memory until GC " << PrettySize(GetFreeMemoryUntilGC()) << "\n";
  os << "Free memory until OOME " << PrettySize(GetFreeMemoryUntilOOME()) << "\n";
  os << "Total memory " << PrettySize(GetTotalMemory()) << "\n";
  os << "Max memory " << PrettySize(GetMaxMemory()) << "\n";
  if (HasZygoteSpace()) {
    os << "Zygote space size " << PrettySize(zygote_space_->Size()) << "\n";
  }
  os << "Total mutator paused time: " << PrettyDuration(total_paused_time) << "\n";
  os << "Total time waiting for GC to complete: " << PrettyDuration(total_wait_time_) << "\n";
  os << "Total GC count: " << GetGcCount() << "\n";
  os << "Total GC time: " << PrettyDuration(GetGcTime()) << "\n";
  os << "Total blocking GC count: " << GetBlockingGcCount() << "\n";
  os << "Total blocking GC time: " << PrettyDuration(GetBlockingGcTime()) << "\n";

  {
    MutexLock mu(Thread::Current(), *gc_complete_lock_);
    if (gc_count_rate_histogram_.SampleSize() > 0U) {
      os << "Histogram of GC count per " << NsToMs(kGcCountRateHistogramWindowDuration) << " ms: ";
      gc_count_rate_histogram_.DumpBins(os);
      os << "\n";
    }
    if (blocking_gc_count_rate_histogram_.SampleSize() > 0U) {
      os << "Histogram of blocking GC count per "
         << NsToMs(kGcCountRateHistogramWindowDuration) << " ms: ";
      blocking_gc_count_rate_histogram_.DumpBins(os);
      os << "\n";
    }
  }

  if (kDumpRosAllocStatsOnSigQuit && rosalloc_space_ != nullptr) {
    rosalloc_space_->DumpStats(os);
  }

  {
    MutexLock mu(Thread::Current(), native_histogram_lock_);
    if (native_allocation_histogram_.SampleSize() > 0u) {
      os << "Histogram of native allocation ";
      native_allocation_histogram_.DumpBins(os);
      os << " bucket size " << native_allocation_histogram_.BucketWidth() << "\n";
    }
    if (native_free_histogram_.SampleSize() > 0u) {
      os << "Histogram of native free ";
      native_free_histogram_.DumpBins(os);
      os << " bucket size " << native_free_histogram_.BucketWidth() << "\n";
    }
  }

  BaseMutex::DumpAll(os);
}

void Heap::ResetGcPerformanceInfo() {
  for (auto& collector : garbage_collectors_) {
    collector->ResetMeasurements();
  }
  total_bytes_freed_ever_ = 0;
  total_objects_freed_ever_ = 0;
  total_wait_time_ = 0;
  blocking_gc_count_ = 0;
  blocking_gc_time_ = 0;
  gc_count_last_window_ = 0;
  blocking_gc_count_last_window_ = 0;
  last_update_time_gc_count_rate_histograms_ =  // Round down by the window duration.
      (NanoTime() / kGcCountRateHistogramWindowDuration) * kGcCountRateHistogramWindowDuration;
  {
    MutexLock mu(Thread::Current(), *gc_complete_lock_);
    gc_count_rate_histogram_.Reset();
    blocking_gc_count_rate_histogram_.Reset();
  }
}

uint64_t Heap::GetGcCount() const {
  uint64_t gc_count = 0U;
  for (auto& collector : garbage_collectors_) {
    gc_count += collector->GetCumulativeTimings().GetIterations();
  }
  return gc_count;
}

uint64_t Heap::GetGcTime() const {
  uint64_t gc_time = 0U;
  for (auto& collector : garbage_collectors_) {
    gc_time += collector->GetCumulativeTimings().GetTotalNs();
  }
  return gc_time;
}

uint64_t Heap::GetBlockingGcCount() const {
  return blocking_gc_count_;
}

uint64_t Heap::GetBlockingGcTime() const {
  return blocking_gc_time_;
}

void Heap::DumpGcCountRateHistogram(std::ostream& os) const {
  MutexLock mu(Thread::Current(), *gc_complete_lock_);
  if (gc_count_rate_histogram_.SampleSize() > 0U) {
    gc_count_rate_histogram_.DumpBins(os);
  }
}

void Heap::DumpBlockingGcCountRateHistogram(std::ostream& os) const {
  MutexLock mu(Thread::Current(), *gc_complete_lock_);
  if (blocking_gc_count_rate_histogram_.SampleSize() > 0U) {
    blocking_gc_count_rate_histogram_.DumpBins(os);
  }
}

ALWAYS_INLINE
static inline AllocationListener* GetAndOverwriteAllocationListener(
    Atomic<AllocationListener*>* storage, AllocationListener* new_value) {
  AllocationListener* old;
  do {
    old = storage->LoadSequentiallyConsistent();
  } while (!storage->CompareExchangeStrongSequentiallyConsistent(old, new_value));
  return old;
}

Heap::~Heap() {
  VLOG(heap) << "Starting ~Heap()";
  STLDeleteElements(&garbage_collectors_);
  // If we don't reset then the mark stack complains in its destructor.
  allocation_stack_->Reset();
  allocation_records_.reset();
  live_stack_->Reset();
  STLDeleteValues(&mod_union_tables_);
  STLDeleteValues(&remembered_sets_);
  STLDeleteElements(&continuous_spaces_);
  STLDeleteElements(&discontinuous_spaces_);
  delete gc_complete_lock_;
  delete thread_flip_lock_;
  delete pending_task_lock_;
  delete backtrace_lock_;
  if (unique_backtrace_count_.LoadRelaxed() != 0 || seen_backtrace_count_.LoadRelaxed() != 0) {
    LOG(INFO) << "gc stress unique=" << unique_backtrace_count_.LoadRelaxed()
        << " total=" << seen_backtrace_count_.LoadRelaxed() +
            unique_backtrace_count_.LoadRelaxed();
  }

  VLOG(heap) << "Finished ~Heap()";
}


space::ContinuousSpace* Heap::FindContinuousSpaceFromAddress(const mirror::Object* addr) const {
  for (const auto& space : continuous_spaces_) {
    if (space->Contains(addr)) {
      return space;
    }
  }
  return nullptr;
}

space::ContinuousSpace* Heap::FindContinuousSpaceFromObject(ObjPtr<mirror::Object> obj,
                                                            bool fail_ok) const {
  space::ContinuousSpace* space = FindContinuousSpaceFromAddress(obj.Ptr());
  if (space != nullptr) {
    return space;
  }
  if (!fail_ok) {
    LOG(FATAL) << "object " << obj << " not inside any spaces!";
  }
  return nullptr;
}

space::DiscontinuousSpace* Heap::FindDiscontinuousSpaceFromObject(ObjPtr<mirror::Object> obj,
                                                                  bool fail_ok) const {
  for (const auto& space : discontinuous_spaces_) {
    if (space->Contains(obj.Ptr())) {
      return space;
    }
  }
  if (!fail_ok) {
    LOG(FATAL) << "object " << obj << " not inside any spaces!";
  }
  return nullptr;
}

space::Space* Heap::FindSpaceFromObject(ObjPtr<mirror::Object> obj, bool fail_ok) const {
  space::Space* result = FindContinuousSpaceFromObject(obj, true);
  if (result != nullptr) {
    return result;
  }
  return FindDiscontinuousSpaceFromObject(obj, fail_ok);
}

space::Space* Heap::FindSpaceFromAddress(const void* addr) const {
  for (const auto& space : continuous_spaces_) {
    if (space->Contains(reinterpret_cast<const mirror::Object*>(addr))) {
      return space;
    }
  }
  for (const auto& space : discontinuous_spaces_) {
    if (space->Contains(reinterpret_cast<const mirror::Object*>(addr))) {
      return space;
    }
  }
  return nullptr;
}


void Heap::ThrowOutOfMemoryError(Thread* self, size_t byte_count, AllocatorType allocator_type) {
  // If we're in a stack overflow, do not create a new exception. It would require running the
  // constructor, which will of course still be in a stack overflow.
  if (self->IsHandlingStackOverflow()) {
    self->SetException(Runtime::Current()->GetPreAllocatedOutOfMemoryError());
    return;
  }

  std::ostringstream oss;
  size_t total_bytes_free = GetFreeMemory();
  oss << "Failed to allocate a " << byte_count << " byte allocation with " << total_bytes_free
      << " free bytes and " << PrettySize(GetFreeMemoryUntilOOME()) << " until OOM,"
      << " max allowed footprint " << max_allowed_footprint_ << ", growth limit "
      << growth_limit_;
  // If the allocation failed due to fragmentation, print out the largest continuous allocation.
  if (total_bytes_free >= byte_count) {
    space::AllocSpace* space = nullptr;
    if (allocator_type == kAllocatorTypeNonMoving) {
      space = non_moving_space_;
    } else if (allocator_type == kAllocatorTypeRosAlloc ||
               allocator_type == kAllocatorTypeDlMalloc) {
      space = main_space_;
    } else if (allocator_type == kAllocatorTypeBumpPointer ||
               allocator_type == kAllocatorTypeTLAB) {
      space = bump_pointer_space_;
    } else if (allocator_type == kAllocatorTypeRegion ||
               allocator_type == kAllocatorTypeRegionTLAB) {
      space = region_space_;
    }
    if (space != nullptr) {
      space->LogFragmentationAllocFailure(oss, byte_count);
    }
  }
  self->ThrowOutOfMemoryError(oss.str().c_str());
}

void Heap::DoPendingCollectorTransition() {
  CollectorType desired_collector_type = desired_collector_type_;
  // Launch homogeneous space compaction if it is desired.
  if (desired_collector_type == kCollectorTypeHomogeneousSpaceCompact) {
    if (!CareAboutPauseTimes()) {
      PerformHomogeneousSpaceCompact();
    } else {
      VLOG(gc) << "Homogeneous compaction ignored due to jank perceptible process state";
    }
  } else if (desired_collector_type == kCollectorTypeCCBackground) {
    DCHECK(kUseReadBarrier);
    if (!CareAboutPauseTimes()) {
      // Invoke CC full compaction.
      CollectGarbageInternal(collector::kGcTypeFull,
                             kGcCauseCollectorTransition,
                             /*clear_soft_references*/false);
    } else {
      VLOG(gc) << "CC background compaction ignored due to jank perceptible process state";
    }
  } else {
    TransitionCollector(desired_collector_type);
  }
}

void Heap::Trim(Thread* self) {
  Runtime* const runtime = Runtime::Current();
  if (!CareAboutPauseTimes()) {
    // Deflate the monitors, this can cause a pause but shouldn't matter since we don't care
    // about pauses.
    ScopedTrace trace("Deflating monitors");
    // Avoid race conditions on the lock word for CC.
    ScopedGCCriticalSection gcs(self, kGcCauseTrim, kCollectorTypeHeapTrim);
    ScopedSuspendAll ssa(__FUNCTION__);
    uint64_t start_time = NanoTime();
    size_t count = runtime->GetMonitorList()->DeflateMonitors();
    VLOG(heap) << "Deflating " << count << " monitors took "
        << PrettyDuration(NanoTime() - start_time);
  }
  TrimIndirectReferenceTables(self);
  TrimSpaces(self);
  // Trim arenas that may have been used by JIT or verifier.
  runtime->GetArenaPool()->TrimMaps();
}

class TrimIndirectReferenceTableClosure : public Closure {
 public:
  explicit TrimIndirectReferenceTableClosure(Barrier* barrier) : barrier_(barrier) {
  }
  virtual void Run(Thread* thread) OVERRIDE NO_THREAD_SAFETY_ANALYSIS {
    thread->GetJniEnv()->locals.Trim();
    // If thread is a running mutator, then act on behalf of the trim thread.
    // See the code in ThreadList::RunCheckpoint.
    barrier_->Pass(Thread::Current());
  }

 private:
  Barrier* const barrier_;
};

void Heap::TrimIndirectReferenceTables(Thread* self) {
  ScopedObjectAccess soa(self);
  ScopedTrace trace(__PRETTY_FUNCTION__);
  JavaVMExt* vm = soa.Vm();
  // Trim globals indirect reference table.
  vm->TrimGlobals();
  // Trim locals indirect reference tables.
  Barrier barrier(0);
  TrimIndirectReferenceTableClosure closure(&barrier);
  ScopedThreadStateChange tsc(self, kWaitingForCheckPointsToRun);
  size_t barrier_count = Runtime::Current()->GetThreadList()->RunCheckpoint(&closure);
  if (barrier_count != 0) {
    barrier.Increment(self, barrier_count);
  }
}

void Heap::StartGC(Thread* self, GcCause cause, CollectorType collector_type) {
  MutexLock mu(self, *gc_complete_lock_);
  // Ensure there is only one GC at a time.
  WaitForGcToCompleteLocked(cause, self);
  collector_type_running_ = collector_type;
}

void Heap::TrimSpaces(Thread* self) {
  {
    // Need to do this before acquiring the locks since we don't want to get suspended while
    // holding any locks.
    ScopedThreadStateChange tsc(self, kWaitingForGcToComplete);
    // Pretend we are doing a GC to prevent background compaction from deleting the space we are
    // trimming.
    StartGC(self, kGcCauseTrim, kCollectorTypeHeapTrim);
  }
  ScopedTrace trace(__PRETTY_FUNCTION__);
  const uint64_t start_ns = NanoTime();
  // Trim the managed spaces.
  uint64_t total_alloc_space_allocated = 0;
  uint64_t total_alloc_space_size = 0;
  uint64_t managed_reclaimed = 0;
  {
    ScopedObjectAccess soa(self);
    for (const auto& space : continuous_spaces_) {
      if (space->IsMallocSpace()) {
        gc::space::MallocSpace* malloc_space = space->AsMallocSpace();
        if (malloc_space->IsRosAllocSpace() || !CareAboutPauseTimes()) {
          // Don't trim dlmalloc spaces if we care about pauses since this can hold the space lock
          // for a long period of time.
          managed_reclaimed += malloc_space->Trim();
        }
        total_alloc_space_size += malloc_space->Size();
      }
    }
  }
  total_alloc_space_allocated = GetBytesAllocated();
  if (large_object_space_ != nullptr) {
    total_alloc_space_allocated -= large_object_space_->GetBytesAllocated();
  }
  if (bump_pointer_space_ != nullptr) {
    total_alloc_space_allocated -= bump_pointer_space_->Size();
  }
  if (region_space_ != nullptr) {
    total_alloc_space_allocated -= region_space_->GetBytesAllocated();
  }
  const float managed_utilization = static_cast<float>(total_alloc_space_allocated) /
      static_cast<float>(total_alloc_space_size);
  uint64_t gc_heap_end_ns = NanoTime();
  // We never move things in the native heap, so we can finish the GC at this point.
  FinishGC(self, collector::kGcTypeNone);

  VLOG(heap) << "Heap trim of managed (duration=" << PrettyDuration(gc_heap_end_ns - start_ns)
      << ", advised=" << PrettySize(managed_reclaimed) << ") heap. Managed heap utilization of "
      << static_cast<int>(100 * managed_utilization) << "%.";
}

bool Heap::IsValidObjectAddress(const void* addr) const {
  if (addr == nullptr) {
    return true;
  }
  return IsAligned<kObjectAlignment>(addr) && FindSpaceFromAddress(addr) != nullptr;
}

bool Heap::IsNonDiscontinuousSpaceHeapAddress(const void* addr) const {
  return FindContinuousSpaceFromAddress(reinterpret_cast<const mirror::Object*>(addr)) != nullptr;
}

bool Heap::IsLiveObjectLocked(ObjPtr<mirror::Object> obj,
                              bool search_allocation_stack,
                              bool search_live_stack,
                              bool sorted) {
  if (UNLIKELY(!IsAligned<kObjectAlignment>(obj.Ptr()))) {
    return false;
  }
  if (bump_pointer_space_ != nullptr && bump_pointer_space_->HasAddress(obj.Ptr())) {
    mirror::Class* klass = obj->GetClass<kVerifyNone>();
    if (obj == klass) {
      // This case happens for java.lang.Class.
      return true;
    }
    return VerifyClassClass(klass) && IsLiveObjectLocked(klass);
  } else if (temp_space_ != nullptr && temp_space_->HasAddress(obj.Ptr())) {
    // If we are in the allocated region of the temp space, then we are probably live (e.g. during
    // a GC). When a GC isn't running End() - Begin() is 0 which means no objects are contained.
    return temp_space_->Contains(obj.Ptr());
  }
  if (region_space_ != nullptr && region_space_->HasAddress(obj.Ptr())) {
    return true;
  }
  space::ContinuousSpace* c_space = FindContinuousSpaceFromObject(obj, true);
  space::DiscontinuousSpace* d_space = nullptr;
  if (c_space != nullptr) {
    if (c_space->GetLiveBitmap()->Test(obj.Ptr())) {
      return true;
    }
  } else {
    d_space = FindDiscontinuousSpaceFromObject(obj, true);
    if (d_space != nullptr) {
      if (d_space->GetLiveBitmap()->Test(obj.Ptr())) {
        return true;
      }
    }
  }
  // This is covering the allocation/live stack swapping that is done without mutators suspended.
  for (size_t i = 0; i < (sorted ? 1 : 5); ++i) {
    if (i > 0) {
      NanoSleep(MsToNs(10));
    }
    if (search_allocation_stack) {
      if (sorted) {
        if (allocation_stack_->ContainsSorted(obj.Ptr())) {
          return true;
        }
      } else if (allocation_stack_->Contains(obj.Ptr())) {
        return true;
      }
    }

    if (search_live_stack) {
      if (sorted) {
        if (live_stack_->ContainsSorted(obj.Ptr())) {
          return true;
        }
      } else if (live_stack_->Contains(obj.Ptr())) {
        return true;
      }
    }
  }
  // We need to check the bitmaps again since there is a race where we mark something as live and
  // then clear the stack containing it.
  if (c_space != nullptr) {
    if (c_space->GetLiveBitmap()->Test(obj.Ptr())) {
      return true;
    }
  } else {
    d_space = FindDiscontinuousSpaceFromObject(obj, true);
    if (d_space != nullptr && d_space->GetLiveBitmap()->Test(obj.Ptr())) {
      return true;
    }
  }
  return false;
}

std::string Heap::DumpSpaces() const {
  std::ostringstream oss;
  DumpSpaces(oss);
  return oss.str();
}

void Heap::DumpSpaces(std::ostream& stream) const {
  for (const auto& space : continuous_spaces_) {
    accounting::ContinuousSpaceBitmap* live_bitmap = space->GetLiveBitmap();
    accounting::ContinuousSpaceBitmap* mark_bitmap = space->GetMarkBitmap();
    stream << space << " " << *space << "\n";
    if (live_bitmap != nullptr) {
      stream << live_bitmap << " " << *live_bitmap << "\n";
    }
    if (mark_bitmap != nullptr) {
      stream << mark_bitmap << " " << *mark_bitmap << "\n";
    }
  }
  for (const auto& space : discontinuous_spaces_) {
    stream << space << " " << *space << "\n";
  }
}

void Heap::VerifyObjectBody(ObjPtr<mirror::Object> obj) {
  if (verify_object_mode_ == kVerifyObjectModeDisabled) {
    return;
  }

  // Ignore early dawn of the universe verifications.
  if (UNLIKELY(static_cast<size_t>(num_bytes_allocated_.LoadRelaxed()) < 10 * KB)) {
    return;
  }
  CHECK_ALIGNED(obj.Ptr(), kObjectAlignment) << "Object isn't aligned";
  mirror::Class* c = obj->GetFieldObject<mirror::Class, kVerifyNone>(mirror::Object::ClassOffset());
  CHECK(c != nullptr) << "Null class in object " << obj;
  CHECK_ALIGNED(c, kObjectAlignment) << "Class " << c << " not aligned in object " << obj;
  CHECK(VerifyClassClass(c));

  if (verify_object_mode_ > kVerifyObjectModeFast) {
    // Note: the bitmap tests below are racy since we don't hold the heap bitmap lock.
    CHECK(IsLiveObjectLocked(obj)) << "Object is dead " << obj << "\n" << DumpSpaces();
  }
}

void Heap::VerificationCallback(mirror::Object* obj, void* arg) {
  reinterpret_cast<Heap*>(arg)->VerifyObjectBody(obj);
}

void Heap::VerifyHeap() {
  ReaderMutexLock mu(Thread::Current(), *Locks::heap_bitmap_lock_);
  GetLiveBitmap()->Walk(Heap::VerificationCallback, this);
}

void Heap::RecordFree(uint64_t freed_objects, int64_t freed_bytes) {
  // Use signed comparison since freed bytes can be negative when background compaction foreground
  // transitions occurs. This is caused by the moving objects from a bump pointer space to a
  // free list backed space typically increasing memory footprint due to padding and binning.
  DCHECK_LE(freed_bytes, static_cast<int64_t>(num_bytes_allocated_.LoadRelaxed()));
  // Note: This relies on 2s complement for handling negative freed_bytes.
  num_bytes_allocated_.FetchAndSubSequentiallyConsistent(static_cast<ssize_t>(freed_bytes));
  if (Runtime::Current()->HasStatsEnabled()) {
    RuntimeStats* thread_stats = Thread::Current()->GetStats();
    thread_stats->freed_objects += freed_objects;
    thread_stats->freed_bytes += freed_bytes;
    // TODO: Do this concurrently.
    RuntimeStats* global_stats = Runtime::Current()->GetStats();
    global_stats->freed_objects += freed_objects;
    global_stats->freed_bytes += freed_bytes;
  }
}

void Heap::RecordFreeRevoke() {
  // Subtract num_bytes_freed_revoke_ from num_bytes_allocated_ to cancel out the
  // the ahead-of-time, bulk counting of bytes allocated in rosalloc thread-local buffers.
  // If there's a concurrent revoke, ok to not necessarily reset num_bytes_freed_revoke_
  // all the way to zero exactly as the remainder will be subtracted at the next GC.
  size_t bytes_freed = num_bytes_freed_revoke_.LoadSequentiallyConsistent();
  CHECK_GE(num_bytes_freed_revoke_.FetchAndSubSequentiallyConsistent(bytes_freed),
           bytes_freed) << "num_bytes_freed_revoke_ underflow";
  CHECK_GE(num_bytes_allocated_.FetchAndSubSequentiallyConsistent(bytes_freed),
           bytes_freed) << "num_bytes_allocated_ underflow";
  GetCurrentGcIteration()->SetFreedRevoke(bytes_freed);
}

space::RosAllocSpace* Heap::GetRosAllocSpace(gc::allocator::RosAlloc* rosalloc) const {
  if (rosalloc_space_ != nullptr && rosalloc_space_->GetRosAlloc() == rosalloc) {
    return rosalloc_space_;
  }
  for (const auto& space : continuous_spaces_) {
    if (space->AsContinuousSpace()->IsRosAllocSpace()) {
      if (space->AsContinuousSpace()->AsRosAllocSpace()->GetRosAlloc() == rosalloc) {
        return space->AsContinuousSpace()->AsRosAllocSpace();
      }
    }
  }
  return nullptr;
}

static inline bool EntrypointsInstrumented() REQUIRES_SHARED(Locks::mutator_lock_) {
  instrumentation::Instrumentation* const instrumentation =
      Runtime::Current()->GetInstrumentation();
  return instrumentation != nullptr && instrumentation->AllocEntrypointsInstrumented();
}

mirror::Object* Heap::AllocateInternalWithGc(Thread* self,
                                             AllocatorType allocator,
                                             bool instrumented,
                                             size_t alloc_size,
                                             size_t* bytes_allocated,
                                             size_t* usable_size,
                                             size_t* bytes_tl_bulk_allocated,
                                             ObjPtr<mirror::Class>* klass) {
  bool was_default_allocator = allocator == GetCurrentAllocator();
  // Make sure there is no pending exception since we may need to throw an OOME.
  self->AssertNoPendingException();
  DCHECK(klass != nullptr);
  StackHandleScope<1> hs(self);
  HandleWrapperObjPtr<mirror::Class> h(hs.NewHandleWrapper(klass));
  // The allocation failed. If the GC is running, block until it completes, and then retry the
  // allocation.
  collector::GcType last_gc = WaitForGcToComplete(kGcCauseForAlloc, self);
  // If we were the default allocator but the allocator changed while we were suspended,
  // abort the allocation.
  if ((was_default_allocator && allocator != GetCurrentAllocator()) ||
      (!instrumented && EntrypointsInstrumented())) {
    return nullptr;
  }
  if (last_gc != collector::kGcTypeNone) {
    // A GC was in progress and we blocked, retry allocation now that memory has been freed.
    mirror::Object* ptr = TryToAllocate<true, false>(self, allocator, alloc_size, bytes_allocated,
                                                     usable_size, bytes_tl_bulk_allocated);
    if (ptr != nullptr) {
      return ptr;
    }
  }

  collector::GcType tried_type = next_gc_type_;
  const bool gc_ran =
      CollectGarbageInternal(tried_type, kGcCauseForAlloc, false) != collector::kGcTypeNone;
  if ((was_default_allocator && allocator != GetCurrentAllocator()) ||
      (!instrumented && EntrypointsInstrumented())) {
    return nullptr;
  }
  if (gc_ran) {
    mirror::Object* ptr = TryToAllocate<true, false>(self, allocator, alloc_size, bytes_allocated,
                                                     usable_size, bytes_tl_bulk_allocated);
    if (ptr != nullptr) {
      return ptr;
    }
  }

  // Loop through our different Gc types and try to Gc until we get enough free memory.
  for (collector::GcType gc_type : gc_plan_) {
    if (gc_type == tried_type) {
      continue;
    }
    // Attempt to run the collector, if we succeed, re-try the allocation.
    const bool plan_gc_ran =
        CollectGarbageInternal(gc_type, kGcCauseForAlloc, false) != collector::kGcTypeNone;
    if ((was_default_allocator && allocator != GetCurrentAllocator()) ||
        (!instrumented && EntrypointsInstrumented())) {
      return nullptr;
    }
    if (plan_gc_ran) {
      // Did we free sufficient memory for the allocation to succeed?
      mirror::Object* ptr = TryToAllocate<true, false>(self, allocator, alloc_size, bytes_allocated,
                                                       usable_size, bytes_tl_bulk_allocated);
      if (ptr != nullptr) {
        return ptr;
      }
    }
  }
  // Allocations have failed after GCs;  this is an exceptional state.
  // Try harder, growing the heap if necessary.
  mirror::Object* ptr = TryToAllocate<true, true>(self, allocator, alloc_size, bytes_allocated,
                                                  usable_size, bytes_tl_bulk_allocated);
  if (ptr != nullptr) {
    return ptr;
  }
  // Most allocations should have succeeded by now, so the heap is really full, really fragmented,
  // or the requested size is really big. Do another GC, collecting SoftReferences this time. The
  // VM spec requires that all SoftReferences have been collected and cleared before throwing
  // OOME.
  VLOG(gc) << "Forcing collection of SoftReferences for " << PrettySize(alloc_size)
           << " allocation";
  // TODO: Run finalization, but this may cause more allocations to occur.
  // We don't need a WaitForGcToComplete here either.
  DCHECK(!gc_plan_.empty());
  CollectGarbageInternal(gc_plan_.back(), kGcCauseForAlloc, true);
  if ((was_default_allocator && allocator != GetCurrentAllocator()) ||
      (!instrumented && EntrypointsInstrumented())) {
    return nullptr;
  }
  ptr = TryToAllocate<true, true>(self, allocator, alloc_size, bytes_allocated, usable_size,
                                  bytes_tl_bulk_allocated);
  if (ptr == nullptr) {
    const uint64_t current_time = NanoTime();
    switch (allocator) {
      case kAllocatorTypeRosAlloc:
        // Fall-through.
      case kAllocatorTypeDlMalloc: {
        if (use_homogeneous_space_compaction_for_oom_ &&
            current_time - last_time_homogeneous_space_compaction_by_oom_ >
            min_interval_homogeneous_space_compaction_by_oom_) {
          last_time_homogeneous_space_compaction_by_oom_ = current_time;
          HomogeneousSpaceCompactResult result = PerformHomogeneousSpaceCompact();
          // Thread suspension could have occurred.
          if ((was_default_allocator && allocator != GetCurrentAllocator()) ||
              (!instrumented && EntrypointsInstrumented())) {
            return nullptr;
          }
          switch (result) {
            case HomogeneousSpaceCompactResult::kSuccess:
              // If the allocation succeeded, we delayed an oom.
              ptr = TryToAllocate<true, true>(self, allocator, alloc_size, bytes_allocated,
                                              usable_size, bytes_tl_bulk_allocated);
              if (ptr != nullptr) {
                count_delayed_oom_++;
              }
              break;
            case HomogeneousSpaceCompactResult::kErrorReject:
              // Reject due to disabled moving GC.
              break;
            case HomogeneousSpaceCompactResult::kErrorVMShuttingDown:
              // Throw OOM by default.
              break;
            default: {
              UNIMPLEMENTED(FATAL) << "homogeneous space compaction result: "
                  << static_cast<size_t>(result);
              UNREACHABLE();
            }
          }
          // Always print that we ran homogeneous space compation since this can cause jank.
          VLOG(heap) << "Ran heap homogeneous space compaction, "
                    << " requested defragmentation "
                    << count_requested_homogeneous_space_compaction_.LoadSequentiallyConsistent()
                    << " performed defragmentation "
                    << count_performed_homogeneous_space_compaction_.LoadSequentiallyConsistent()
                    << " ignored homogeneous space compaction "
                    << count_ignored_homogeneous_space_compaction_.LoadSequentiallyConsistent()
                    << " delayed count = "
                    << count_delayed_oom_.LoadSequentiallyConsistent();
        }
        break;
      }
      case kAllocatorTypeNonMoving: {
        if (kUseReadBarrier) {
          // DisableMovingGc() isn't compatible with CC.
          break;
        }
        // Try to transition the heap if the allocation failure was due to the space being full.
        if (!IsOutOfMemoryOnAllocation(allocator, alloc_size, /*grow*/ false)) {
          // If we aren't out of memory then the OOM was probably from the non moving space being
          // full. Attempt to disable compaction and turn the main space into a non moving space.
          DisableMovingGc();
          // Thread suspension could have occurred.
          if ((was_default_allocator && allocator != GetCurrentAllocator()) ||
              (!instrumented && EntrypointsInstrumented())) {
            return nullptr;
          }
          // If we are still a moving GC then something must have caused the transition to fail.
          if (IsMovingGc(collector_type_)) {
            MutexLock mu(self, *gc_complete_lock_);
            // If we couldn't disable moving GC, just throw OOME and return null.
            LOG(WARNING) << "Couldn't disable moving GC with disable GC count "
                         << disable_moving_gc_count_;
          } else {
            LOG(WARNING) << "Disabled moving GC due to the non moving space being full";
            ptr = TryToAllocate<true, true>(self, allocator, alloc_size, bytes_allocated,
                                            usable_size, bytes_tl_bulk_allocated);
          }
        }
        break;
      }
      default: {
        // Do nothing for others allocators.
      }
    }
  }
  // If the allocation hasn't succeeded by this point, throw an OOM error.
  if (ptr == nullptr) {
    ThrowOutOfMemoryError(self, alloc_size, allocator);
  }
  return ptr;
}

void Heap::SetTargetHeapUtilization(float target) {
  DCHECK_GT(target, 0.0f);  // asserted in Java code
  DCHECK_LT(target, 1.0f);
  target_utilization_ = target;
}

size_t Heap::GetObjectsAllocated() const {
  Thread* const self = Thread::Current();
  ScopedThreadStateChange tsc(self, kWaitingForGetObjectsAllocated);
  // Need SuspendAll here to prevent lock violation if RosAlloc does it during InspectAll.
  ScopedSuspendAll ssa(__FUNCTION__);
  ReaderMutexLock mu(self, *Locks::heap_bitmap_lock_);
  size_t total = 0;
  for (space::AllocSpace* space : alloc_spaces_) {
    total += space->GetObjectsAllocated();
  }
  return total;
}

uint64_t Heap::GetObjectsAllocatedEver() const {
  uint64_t total = GetObjectsFreedEver();
  // If we are detached, we can't use GetObjectsAllocated since we can't change thread states.
  if (Thread::Current() != nullptr) {
    total += GetObjectsAllocated();
  }
  return total;
}

uint64_t Heap::GetBytesAllocatedEver() const {
  return GetBytesFreedEver() + GetBytesAllocated();
}

class InstanceCounter {
 public:
  InstanceCounter(const std::vector<Handle<mirror::Class>>& classes,
                  bool use_is_assignable_from,
                  uint64_t* counts)
      REQUIRES_SHARED(Locks::mutator_lock_)
      : classes_(classes), use_is_assignable_from_(use_is_assignable_from), counts_(counts) {}

  static void Callback(mirror::Object* obj, void* arg)
      REQUIRES_SHARED(Locks::mutator_lock_, Locks::heap_bitmap_lock_) {
    InstanceCounter* instance_counter = reinterpret_cast<InstanceCounter*>(arg);
    mirror::Class* instance_class = obj->GetClass();
    CHECK(instance_class != nullptr);
    for (size_t i = 0; i < instance_counter->classes_.size(); ++i) {
      ObjPtr<mirror::Class> klass = instance_counter->classes_[i].Get();
      if (instance_counter->use_is_assignable_from_) {
        if (klass != nullptr && klass->IsAssignableFrom(instance_class)) {
          ++instance_counter->counts_[i];
        }
      } else if (instance_class == klass) {
        ++instance_counter->counts_[i];
      }
    }
  }

 private:
  const std::vector<Handle<mirror::Class>>& classes_;
  bool use_is_assignable_from_;
  uint64_t* const counts_;
  DISALLOW_COPY_AND_ASSIGN(InstanceCounter);
};

void Heap::CountInstances(const std::vector<Handle<mirror::Class>>& classes,
                          bool use_is_assignable_from,
                          uint64_t* counts) {
  InstanceCounter counter(classes, use_is_assignable_from, counts);
  VisitObjects(InstanceCounter::Callback, &counter);
}

class InstanceCollector {
 public:
  InstanceCollector(VariableSizedHandleScope& scope,
                    Handle<mirror::Class> c,
                    int32_t max_count,
                    std::vector<Handle<mirror::Object>>& instances)
      REQUIRES_SHARED(Locks::mutator_lock_)
      : scope_(scope),
        class_(c),
        max_count_(max_count),
        instances_(instances) {}

  static void Callback(mirror::Object* obj, void* arg)
      REQUIRES_SHARED(Locks::mutator_lock_, Locks::heap_bitmap_lock_) {
    DCHECK(arg != nullptr);
    InstanceCollector* instance_collector = reinterpret_cast<InstanceCollector*>(arg);
    if (obj->GetClass() == instance_collector->class_.Get()) {
      if (instance_collector->max_count_ == 0 ||
          instance_collector->instances_.size() < instance_collector->max_count_) {
        instance_collector->instances_.push_back(instance_collector->scope_.NewHandle(obj));
      }
    }
  }

 private:
  VariableSizedHandleScope& scope_;
  Handle<mirror::Class> const class_;
  const uint32_t max_count_;
  std::vector<Handle<mirror::Object>>& instances_;
  DISALLOW_COPY_AND_ASSIGN(InstanceCollector);
};

void Heap::GetInstances(VariableSizedHandleScope& scope,
                        Handle<mirror::Class> c,
                        int32_t max_count,
                        std::vector<Handle<mirror::Object>>& instances) {
  InstanceCollector collector(scope, c, max_count, instances);
  VisitObjects(&InstanceCollector::Callback, &collector);
}

class ReferringObjectsFinder {
 public:
  ReferringObjectsFinder(VariableSizedHandleScope& scope,
                         Handle<mirror::Object> object,
                         int32_t max_count,
                         std::vector<Handle<mirror::Object>>& referring_objects)
      REQUIRES_SHARED(Locks::mutator_lock_)
      : scope_(scope),
        object_(object),
        max_count_(max_count),
        referring_objects_(referring_objects) {}

  static void Callback(mirror::Object* obj, void* arg)
      REQUIRES_SHARED(Locks::mutator_lock_, Locks::heap_bitmap_lock_) {
    reinterpret_cast<ReferringObjectsFinder*>(arg)->operator()(obj);
  }

  // For bitmap Visit.
  // TODO: Fix lock analysis to not use NO_THREAD_SAFETY_ANALYSIS, requires support for
  // annotalysis on visitors.
  void operator()(ObjPtr<mirror::Object> o) const NO_THREAD_SAFETY_ANALYSIS {
    o->VisitReferences(*this, VoidFunctor());
  }

  // For Object::VisitReferences.
  void operator()(ObjPtr<mirror::Object> obj,
                  MemberOffset offset,
                  bool is_static ATTRIBUTE_UNUSED) const
      REQUIRES_SHARED(Locks::mutator_lock_) {
    mirror::Object* ref = obj->GetFieldObject<mirror::Object>(offset);
    if (ref == object_.Get() && (max_count_ == 0 || referring_objects_.size() < max_count_)) {
      referring_objects_.push_back(scope_.NewHandle(obj));
    }
  }

  void VisitRootIfNonNull(mirror::CompressedReference<mirror::Object>* root ATTRIBUTE_UNUSED)
      const {}
  void VisitRoot(mirror::CompressedReference<mirror::Object>* root ATTRIBUTE_UNUSED) const {}

 private:
  VariableSizedHandleScope& scope_;
  Handle<mirror::Object> const object_;
  const uint32_t max_count_;
  std::vector<Handle<mirror::Object>>& referring_objects_;
  DISALLOW_COPY_AND_ASSIGN(ReferringObjectsFinder);
};

void Heap::GetReferringObjects(VariableSizedHandleScope& scope,
                               Handle<mirror::Object> o,
                               int32_t max_count,
                               std::vector<Handle<mirror::Object>>& referring_objects) {
  ReferringObjectsFinder finder(scope, o, max_count, referring_objects);
  VisitObjects(&ReferringObjectsFinder::Callback, &finder);
}

void Heap::CollectGarbage(bool clear_soft_references) {
  // Even if we waited for a GC we still need to do another GC since weaks allocated during the
  // last GC will not have necessarily been cleared.
  CollectGarbageInternal(gc_plan_.back(), kGcCauseExplicit, clear_soft_references);
}

bool Heap::SupportHomogeneousSpaceCompactAndCollectorTransitions() const {
  return main_space_backup_.get() != nullptr && main_space_ != nullptr &&
      foreground_collector_type_ == kCollectorTypeCMS;
}

HomogeneousSpaceCompactResult Heap::PerformHomogeneousSpaceCompact() {
  Thread* self = Thread::Current();
  // Inc requested homogeneous space compaction.
  count_requested_homogeneous_space_compaction_++;
  // Store performed homogeneous space compaction at a new request arrival.
  ScopedThreadStateChange tsc(self, kWaitingPerformingGc);
  Locks::mutator_lock_->AssertNotHeld(self);
  {
    ScopedThreadStateChange tsc2(self, kWaitingForGcToComplete);
    MutexLock mu(self, *gc_complete_lock_);
    // Ensure there is only one GC at a time.
    WaitForGcToCompleteLocked(kGcCauseHomogeneousSpaceCompact, self);
    // Homogeneous space compaction is a copying transition, can't run it if the moving GC disable count
    // is non zero.
    // If the collector type changed to something which doesn't benefit from homogeneous space compaction,
    // exit.
    if (disable_moving_gc_count_ != 0 || IsMovingGc(collector_type_) ||
        !main_space_->CanMoveObjects()) {
      return kErrorReject;
    }
    if (!SupportHomogeneousSpaceCompactAndCollectorTransitions()) {
      return kErrorUnsupported;
    }
    collector_type_running_ = kCollectorTypeHomogeneousSpaceCompact;
  }
  if (Runtime::Current()->IsShuttingDown(self)) {
    // Don't allow heap transitions to happen if the runtime is shutting down since these can
    // cause objects to get finalized.
    FinishGC(self, collector::kGcTypeNone);
    return HomogeneousSpaceCompactResult::kErrorVMShuttingDown;
  }
  collector::GarbageCollector* collector;
  {
    ScopedSuspendAll ssa(__FUNCTION__);
    uint64_t start_time = NanoTime();
    // Launch compaction.
    space::MallocSpace* to_space = main_space_backup_.release();
    space::MallocSpace* from_space = main_space_;
    to_space->GetMemMap()->Protect(PROT_READ | PROT_WRITE);
    const uint64_t space_size_before_compaction = from_space->Size();
    AddSpace(to_space);
    // Make sure that we will have enough room to copy.
    CHECK_GE(to_space->GetFootprintLimit(), from_space->GetFootprintLimit());
    collector = Compact(to_space, from_space, kGcCauseHomogeneousSpaceCompact);
    const uint64_t space_size_after_compaction = to_space->Size();
    main_space_ = to_space;
    main_space_backup_.reset(from_space);
    RemoveSpace(from_space);
    SetSpaceAsDefault(main_space_);  // Set as default to reset the proper dlmalloc space.
    // Update performed homogeneous space compaction count.
    count_performed_homogeneous_space_compaction_++;
    // Print statics log and resume all threads.
    uint64_t duration = NanoTime() - start_time;
    VLOG(heap) << "Heap homogeneous space compaction took " << PrettyDuration(duration) << " size: "
               << PrettySize(space_size_before_compaction) << " -> "
               << PrettySize(space_size_after_compaction) << " compact-ratio: "
               << std::fixed << static_cast<double>(space_size_after_compaction) /
               static_cast<double>(space_size_before_compaction);
  }
  // Finish GC.
  reference_processor_->EnqueueClearedReferences(self);
  GrowForUtilization(semi_space_collector_);
  LogGC(kGcCauseHomogeneousSpaceCompact, collector);
  FinishGC(self, collector::kGcTypeFull);
  {
    ScopedObjectAccess soa(self);
    soa.Vm()->UnloadNativeLibraries();
  }
  return HomogeneousSpaceCompactResult::kSuccess;
}

void Heap::TransitionCollector(CollectorType collector_type) {
  if (collector_type == collector_type_) {
    return;
  }
  // Collector transition must not happen with CC
  CHECK(!kUseReadBarrier);
  VLOG(heap) << "TransitionCollector: " << static_cast<int>(collector_type_)
             << " -> " << static_cast<int>(collector_type);
  uint64_t start_time = NanoTime();
  uint32_t before_allocated = num_bytes_allocated_.LoadSequentiallyConsistent();
  Runtime* const runtime = Runtime::Current();
  Thread* const self = Thread::Current();
  ScopedThreadStateChange tsc(self, kWaitingPerformingGc);
  Locks::mutator_lock_->AssertNotHeld(self);
  // Busy wait until we can GC (StartGC can fail if we have a non-zero
  // compacting_gc_disable_count_, this should rarely occurs).
  for (;;) {
    {
      ScopedThreadStateChange tsc2(self, kWaitingForGcToComplete);
      MutexLock mu(self, *gc_complete_lock_);
      // Ensure there is only one GC at a time.
      WaitForGcToCompleteLocked(kGcCauseCollectorTransition, self);
      // Currently we only need a heap transition if we switch from a moving collector to a
      // non-moving one, or visa versa.
      const bool copying_transition = IsMovingGc(collector_type_) != IsMovingGc(collector_type);
      // If someone else beat us to it and changed the collector before we could, exit.
      // This is safe to do before the suspend all since we set the collector_type_running_ before
      // we exit the loop. If another thread attempts to do the heap transition before we exit,
      // then it would get blocked on WaitForGcToCompleteLocked.
      if (collector_type == collector_type_) {
        return;
      }
      // GC can be disabled if someone has a used GetPrimitiveArrayCritical but not yet released.
      if (!copying_transition || disable_moving_gc_count_ == 0) {
        // TODO: Not hard code in semi-space collector?
        collector_type_running_ = copying_transition ? kCollectorTypeSS : collector_type;
        break;
      }
    }
    usleep(1000);
  }
  if (runtime->IsShuttingDown(self)) {
    // Don't allow heap transitions to happen if the runtime is shutting down since these can
    // cause objects to get finalized.
    FinishGC(self, collector::kGcTypeNone);
    return;
  }
  collector::GarbageCollector* collector = nullptr;
  {
    ScopedSuspendAll ssa(__FUNCTION__);
    switch (collector_type) {
      case kCollectorTypeSS: {
        if (!IsMovingGc(collector_type_)) {
          // Create the bump pointer space from the backup space.
          CHECK(main_space_backup_ != nullptr);
          std::unique_ptr<MemMap> mem_map(main_space_backup_->ReleaseMemMap());
          // We are transitioning from non moving GC -> moving GC, since we copied from the bump
          // pointer space last transition it will be protected.
          CHECK(mem_map != nullptr);
          mem_map->Protect(PROT_READ | PROT_WRITE);
          bump_pointer_space_ = space::BumpPointerSpace::CreateFromMemMap("Bump pointer space",
                                                                          mem_map.release());
          AddSpace(bump_pointer_space_);
          collector = Compact(bump_pointer_space_, main_space_, kGcCauseCollectorTransition);
          // Use the now empty main space mem map for the bump pointer temp space.
          mem_map.reset(main_space_->ReleaseMemMap());
          // Unset the pointers just in case.
          if (dlmalloc_space_ == main_space_) {
            dlmalloc_space_ = nullptr;
          } else if (rosalloc_space_ == main_space_) {
            rosalloc_space_ = nullptr;
          }
          // Remove the main space so that we don't try to trim it, this doens't work for debug
          // builds since RosAlloc attempts to read the magic number from a protected page.
          RemoveSpace(main_space_);
          RemoveRememberedSet(main_space_);
          delete main_space_;  // Delete the space since it has been removed.
          main_space_ = nullptr;
          RemoveRememberedSet(main_space_backup_.get());
          main_space_backup_.reset(nullptr);  // Deletes the space.
          temp_space_ = space::BumpPointerSpace::CreateFromMemMap("Bump pointer space 2",
                                                                  mem_map.release());
          AddSpace(temp_space_);
        }
        break;
      }
      case kCollectorTypeMS:
        // Fall through.
      case kCollectorTypeCMS: {
        if (IsMovingGc(collector_type_)) {
          CHECK(temp_space_ != nullptr);
          std::unique_ptr<MemMap> mem_map(temp_space_->ReleaseMemMap());
          RemoveSpace(temp_space_);
          temp_space_ = nullptr;
          mem_map->Protect(PROT_READ | PROT_WRITE);
          CreateMainMallocSpace(mem_map.get(),
                                kDefaultInitialSize,
                                std::min(mem_map->Size(), growth_limit_),
                                mem_map->Size());
          mem_map.release();
          // Compact to the main space from the bump pointer space, don't need to swap semispaces.
          AddSpace(main_space_);
          collector = Compact(main_space_, bump_pointer_space_, kGcCauseCollectorTransition);
          mem_map.reset(bump_pointer_space_->ReleaseMemMap());
          RemoveSpace(bump_pointer_space_);
          bump_pointer_space_ = nullptr;
          const char* name = kUseRosAlloc ? kRosAllocSpaceName[1] : kDlMallocSpaceName[1];
          // Temporarily unprotect the backup mem map so rosalloc can write the debug magic number.
          if (kIsDebugBuild && kUseRosAlloc) {
            mem_map->Protect(PROT_READ | PROT_WRITE);
          }
          main_space_backup_.reset(CreateMallocSpaceFromMemMap(
              mem_map.get(),
              kDefaultInitialSize,
              std::min(mem_map->Size(), growth_limit_),
              mem_map->Size(),
              name,
              true));
          if (kIsDebugBuild && kUseRosAlloc) {
            mem_map->Protect(PROT_NONE);
          }
          mem_map.release();
        }
        break;
      }
      default: {
        LOG(FATAL) << "Attempted to transition to invalid collector type "
                   << static_cast<size_t>(collector_type);
        break;
      }
    }
    ChangeCollector(collector_type);
  }
  // Can't call into java code with all threads suspended.
  reference_processor_->EnqueueClearedReferences(self);
  uint64_t duration = NanoTime() - start_time;
  GrowForUtilization(semi_space_collector_);
  DCHECK(collector != nullptr);
  LogGC(kGcCauseCollectorTransition, collector);
  FinishGC(self, collector::kGcTypeFull);
  {
    ScopedObjectAccess soa(self);
    soa.Vm()->UnloadNativeLibraries();
  }
  int32_t after_allocated = num_bytes_allocated_.LoadSequentiallyConsistent();
  int32_t delta_allocated = before_allocated - after_allocated;
  std::string saved_str;
  if (delta_allocated >= 0) {
    saved_str = " saved at least " + PrettySize(delta_allocated);
  } else {
    saved_str = " expanded " + PrettySize(-delta_allocated);
  }
  VLOG(heap) << "Collector transition to " << collector_type << " took "
             << PrettyDuration(duration) << saved_str;
}

void Heap::ChangeCollector(CollectorType collector_type) {
  // TODO: Only do this with all mutators suspended to avoid races.
  if (collector_type != collector_type_) {
    if (collector_type == kCollectorTypeMC) {
      // Don't allow mark compact unless support is compiled in.
      CHECK(kMarkCompactSupport);
    }
    collector_type_ = collector_type;
    gc_plan_.clear();
    switch (collector_type_) {
      case kCollectorTypeCC: {
        gc_plan_.push_back(collector::kGcTypeFull);
        if (use_tlab_) {
          ChangeAllocator(kAllocatorTypeRegionTLAB);
        } else {
          ChangeAllocator(kAllocatorTypeRegion);
        }
        break;
      }
      case kCollectorTypeMC:  // Fall-through.
      case kCollectorTypeSS:  // Fall-through.
      case kCollectorTypeGSS: {
        gc_plan_.push_back(collector::kGcTypeFull);
        if (use_tlab_) {
          ChangeAllocator(kAllocatorTypeTLAB);
        } else {
          ChangeAllocator(kAllocatorTypeBumpPointer);
        }
        break;
      }
      case kCollectorTypeMS: {
        gc_plan_.push_back(collector::kGcTypeSticky);
        gc_plan_.push_back(collector::kGcTypePartial);
        gc_plan_.push_back(collector::kGcTypeFull);
        ChangeAllocator(kUseRosAlloc ? kAllocatorTypeRosAlloc : kAllocatorTypeDlMalloc);
        break;
      }
      case kCollectorTypeCMS: {
        gc_plan_.push_back(collector::kGcTypeSticky);
        gc_plan_.push_back(collector::kGcTypePartial);
        gc_plan_.push_back(collector::kGcTypeFull);
        ChangeAllocator(kUseRosAlloc ? kAllocatorTypeRosAlloc : kAllocatorTypeDlMalloc);
        break;
      }
      default: {
        UNIMPLEMENTED(FATAL);
        UNREACHABLE();
      }
    }
    if (IsGcConcurrent()) {
      concurrent_start_bytes_ =
          std::max(max_allowed_footprint_, kMinConcurrentRemainingBytes) - kMinConcurrentRemainingBytes;
    } else {
      concurrent_start_bytes_ = std::numeric_limits<size_t>::max();
    }
  }
}

// Special compacting collector which uses sub-optimal bin packing to reduce zygote space size.
class ZygoteCompactingCollector FINAL : public collector::SemiSpace {
 public:
  ZygoteCompactingCollector(gc::Heap* heap, bool is_running_on_memory_tool)
      : SemiSpace(heap, false, "zygote collector"),
        bin_live_bitmap_(nullptr),
        bin_mark_bitmap_(nullptr),
        is_running_on_memory_tool_(is_running_on_memory_tool) {}

  void BuildBins(space::ContinuousSpace* space) {
    bin_live_bitmap_ = space->GetLiveBitmap();
    bin_mark_bitmap_ = space->GetMarkBitmap();
    BinContext context;
    context.prev_ = reinterpret_cast<uintptr_t>(space->Begin());
    context.collector_ = this;
    WriterMutexLock mu(Thread::Current(), *Locks::heap_bitmap_lock_);
    // Note: This requires traversing the space in increasing order of object addresses.
    bin_live_bitmap_->Walk(Callback, reinterpret_cast<void*>(&context));
    // Add the last bin which spans after the last object to the end of the space.
    AddBin(reinterpret_cast<uintptr_t>(space->End()) - context.prev_, context.prev_);
  }

 private:
  struct BinContext {
    uintptr_t prev_;  // The end of the previous object.
    ZygoteCompactingCollector* collector_;
  };
  // Maps from bin sizes to locations.
  std::multimap<size_t, uintptr_t> bins_;
  // Live bitmap of the space which contains the bins.
  accounting::ContinuousSpaceBitmap* bin_live_bitmap_;
  // Mark bitmap of the space which contains the bins.
  accounting::ContinuousSpaceBitmap* bin_mark_bitmap_;
  const bool is_running_on_memory_tool_;

  static void Callback(mirror::Object* obj, void* arg)
      REQUIRES_SHARED(Locks::mutator_lock_) {
    DCHECK(arg != nullptr);
    BinContext* context = reinterpret_cast<BinContext*>(arg);
    ZygoteCompactingCollector* collector = context->collector_;
    uintptr_t object_addr = reinterpret_cast<uintptr_t>(obj);
    size_t bin_size = object_addr - context->prev_;
    // Add the bin consisting of the end of the previous object to the start of the current object.
    collector->AddBin(bin_size, context->prev_);
    context->prev_ = object_addr + RoundUp(obj->SizeOf(), kObjectAlignment);
  }

  void AddBin(size_t size, uintptr_t position) {
    if (is_running_on_memory_tool_) {
      MEMORY_TOOL_MAKE_DEFINED(reinterpret_cast<void*>(position), size);
    }
    if (size != 0) {
      bins_.insert(std::make_pair(size, position));
    }
  }

  virtual bool ShouldSweepSpace(space::ContinuousSpace* space ATTRIBUTE_UNUSED) const {
    // Don't sweep any spaces since we probably blasted the internal accounting of the free list
    // allocator.
    return false;
  }

  virtual mirror::Object* MarkNonForwardedObject(mirror::Object* obj)
      REQUIRES(Locks::heap_bitmap_lock_, Locks::mutator_lock_) {
    size_t obj_size = obj->SizeOf();
    size_t alloc_size = RoundUp(obj_size, kObjectAlignment);
    mirror::Object* forward_address;
    // Find the smallest bin which we can move obj in.
    auto it = bins_.lower_bound(alloc_size);
    if (it == bins_.end()) {
      // No available space in the bins, place it in the target space instead (grows the zygote
      // space).
      size_t bytes_allocated, dummy;
      forward_address = to_space_->Alloc(self_, alloc_size, &bytes_allocated, nullptr, &dummy);
      if (to_space_live_bitmap_ != nullptr) {
        to_space_live_bitmap_->Set(forward_address);
      } else {
        GetHeap()->GetNonMovingSpace()->GetLiveBitmap()->Set(forward_address);
        GetHeap()->GetNonMovingSpace()->GetMarkBitmap()->Set(forward_address);
      }
    } else {
      size_t size = it->first;
      uintptr_t pos = it->second;
      bins_.erase(it);  // Erase the old bin which we replace with the new smaller bin.
      forward_address = reinterpret_cast<mirror::Object*>(pos);
      // Set the live and mark bits so that sweeping system weaks works properly.
      bin_live_bitmap_->Set(forward_address);
      bin_mark_bitmap_->Set(forward_address);
      DCHECK_GE(size, alloc_size);
      // Add a new bin with the remaining space.
      AddBin(size - alloc_size, pos + alloc_size);
    }
    // Copy the object over to its new location. Don't use alloc_size to avoid valgrind error.
    memcpy(reinterpret_cast<void*>(forward_address), obj, obj_size);
    if (kUseBakerReadBarrier) {
      obj->AssertReadBarrierState();
      forward_address->AssertReadBarrierState();
    }
    return forward_address;
  }
};

void Heap::UnBindBitmaps() {
  TimingLogger::ScopedTiming t("UnBindBitmaps", GetCurrentGcIteration()->GetTimings());
  for (const auto& space : GetContinuousSpaces()) {
    if (space->IsContinuousMemMapAllocSpace()) {
      space::ContinuousMemMapAllocSpace* alloc_space = space->AsContinuousMemMapAllocSpace();
      if (alloc_space->HasBoundBitmaps()) {
        alloc_space->UnBindBitmaps();
      }
    }
  }
}

void Heap::PreZygoteFork() {
  if (!HasZygoteSpace()) {
    // We still want to GC in case there is some unreachable non moving objects that could cause a
    // suboptimal bin packing when we compact the zygote space.
    CollectGarbageInternal(collector::kGcTypeFull, kGcCauseBackground, false);
    // Trim the pages at the end of the non moving space. Trim while not holding zygote lock since
    // the trim process may require locking the mutator lock.
    non_moving_space_->Trim();
  }
  Thread* self = Thread::Current();
  MutexLock mu(self, zygote_creation_lock_);
  // Try to see if we have any Zygote spaces.
  if (HasZygoteSpace()) {
    return;
  }
  Runtime::Current()->GetInternTable()->AddNewTable();
  Runtime::Current()->GetClassLinker()->MoveClassTableToPreZygote();
  VLOG(heap) << "Starting PreZygoteFork";
  // The end of the non-moving space may be protected, unprotect it so that we can copy the zygote
  // there.
  non_moving_space_->GetMemMap()->Protect(PROT_READ | PROT_WRITE);
  const bool same_space = non_moving_space_ == main_space_;
  if (kCompactZygote) {
    // Temporarily disable rosalloc verification because the zygote
    // compaction will mess up the rosalloc internal metadata.
    ScopedDisableRosAllocVerification disable_rosalloc_verif(this);
    ZygoteCompactingCollector zygote_collector(this, is_running_on_memory_tool_);
    zygote_collector.BuildBins(non_moving_space_);
    // Create a new bump pointer space which we will compact into.
    space::BumpPointerSpace target_space("zygote bump space", non_moving_space_->End(),
                                         non_moving_space_->Limit());
    // Compact the bump pointer space to a new zygote bump pointer space.
    bool reset_main_space = false;
    if (IsMovingGc(collector_type_)) {
      if (collector_type_ == kCollectorTypeCC) {
        zygote_collector.SetFromSpace(region_space_);
      } else {
        zygote_collector.SetFromSpace(bump_pointer_space_);
      }
    } else {
      CHECK(main_space_ != nullptr);
      CHECK_NE(main_space_, non_moving_space_)
          << "Does not make sense to compact within the same space";
      // Copy from the main space.
      zygote_collector.SetFromSpace(main_space_);
      reset_main_space = true;
    }
    zygote_collector.SetToSpace(&target_space);
    zygote_collector.SetSwapSemiSpaces(false);
    zygote_collector.Run(kGcCauseCollectorTransition, false);
    if (reset_main_space) {
      main_space_->GetMemMap()->Protect(PROT_READ | PROT_WRITE);
      madvise(main_space_->Begin(), main_space_->Capacity(), MADV_DONTNEED);
      MemMap* mem_map = main_space_->ReleaseMemMap();
      RemoveSpace(main_space_);
      space::Space* old_main_space = main_space_;
      CreateMainMallocSpace(mem_map, kDefaultInitialSize, std::min(mem_map->Size(), growth_limit_),
                            mem_map->Size());
      delete old_main_space;
      AddSpace(main_space_);
    } else {
      if (collector_type_ == kCollectorTypeCC) {
        region_space_->GetMemMap()->Protect(PROT_READ | PROT_WRITE);
        // Evacuated everything out of the region space, clear the mark bitmap.
        region_space_->GetMarkBitmap()->Clear();
      } else {
        bump_pointer_space_->GetMemMap()->Protect(PROT_READ | PROT_WRITE);
      }
    }
    if (temp_space_ != nullptr) {
      CHECK(temp_space_->IsEmpty());
    }
    total_objects_freed_ever_ += GetCurrentGcIteration()->GetFreedObjects();
    total_bytes_freed_ever_ += GetCurrentGcIteration()->GetFreedBytes();
    // Update the end and write out image.
    non_moving_space_->SetEnd(target_space.End());
    non_moving_space_->SetLimit(target_space.Limit());
    VLOG(heap) << "Create zygote space with size=" << non_moving_space_->Size() << " bytes";
  }
  // Change the collector to the post zygote one.
  ChangeCollector(foreground_collector_type_);
  // Save the old space so that we can remove it after we complete creating the zygote space.
  space::MallocSpace* old_alloc_space = non_moving_space_;
  // Turn the current alloc space into a zygote space and obtain the new alloc space composed of
  // the remaining available space.
  // Remove the old space before creating the zygote space since creating the zygote space sets
  // the old alloc space's bitmaps to null.
  RemoveSpace(old_alloc_space);
  if (collector::SemiSpace::kUseRememberedSet) {
    // Sanity bound check.
    FindRememberedSetFromSpace(old_alloc_space)->AssertAllDirtyCardsAreWithinSpace();
    // Remove the remembered set for the now zygote space (the old
    // non-moving space). Note now that we have compacted objects into
    // the zygote space, the data in the remembered set is no longer
    // needed. The zygote space will instead have a mod-union table
    // from this point on.
    RemoveRememberedSet(old_alloc_space);
  }
  // Remaining space becomes the new non moving space.
  zygote_space_ = old_alloc_space->CreateZygoteSpace(kNonMovingSpaceName, low_memory_mode_,
                                                     &non_moving_space_);
  CHECK(!non_moving_space_->CanMoveObjects());
  if (same_space) {
    main_space_ = non_moving_space_;
    SetSpaceAsDefault(main_space_);
  }
  delete old_alloc_space;
  CHECK(HasZygoteSpace()) << "Failed creating zygote space";
  AddSpace(zygote_space_);
  non_moving_space_->SetFootprintLimit(non_moving_space_->Capacity());
  AddSpace(non_moving_space_);
  if (kUseBakerReadBarrier && gc::collector::ConcurrentCopying::kGrayDirtyImmuneObjects) {
    // Treat all of the objects in the zygote as marked to avoid unnecessary dirty pages. This is
    // safe since we mark all of the objects that may reference non immune objects as gray.
    zygote_space_->GetLiveBitmap()->VisitMarkedRange(
        reinterpret_cast<uintptr_t>(zygote_space_->Begin()),
        reinterpret_cast<uintptr_t>(zygote_space_->Limit()),
        [](mirror::Object* obj) REQUIRES_SHARED(Locks::mutator_lock_) {
      CHECK(obj->AtomicSetMarkBit(0, 1));
    });
  }

  // Create the zygote space mod union table.
  accounting::ModUnionTable* mod_union_table =
      new accounting::ModUnionTableCardCache("zygote space mod-union table", this, zygote_space_);
  CHECK(mod_union_table != nullptr) << "Failed to create zygote space mod-union table";

  if (collector_type_ != kCollectorTypeCC) {
    // Set all the cards in the mod-union table since we don't know which objects contain references
    // to large objects.
    mod_union_table->SetCards();
  } else {
    // For CC we never collect zygote large objects. This means we do not need to set the cards for
    // the zygote mod-union table and we can also clear all of the existing image mod-union tables.
    // The existing mod-union tables are only for image spaces and may only reference zygote and
    // image objects.
    for (auto& pair : mod_union_tables_) {
      CHECK(pair.first->IsImageSpace());
      CHECK(!pair.first->AsImageSpace()->GetImageHeader().IsAppImage());
      accounting::ModUnionTable* table = pair.second;
      table->ClearTable();
    }
  }
  AddModUnionTable(mod_union_table);
  large_object_space_->SetAllLargeObjectsAsZygoteObjects(self);
  if (collector::SemiSpace::kUseRememberedSet) {
    // Add a new remembered set for the post-zygote non-moving space.
    accounting::RememberedSet* post_zygote_non_moving_space_rem_set =
        new accounting::RememberedSet("Post-zygote non-moving space remembered set", this,
                                      non_moving_space_);
    CHECK(post_zygote_non_moving_space_rem_set != nullptr)
        << "Failed to create post-zygote non-moving space remembered set";
    AddRememberedSet(post_zygote_non_moving_space_rem_set);
  }
}

void Heap::FlushAllocStack() {
  MarkAllocStackAsLive(allocation_stack_.get());
  allocation_stack_->Reset();
}

void Heap::MarkAllocStack(accounting::ContinuousSpaceBitmap* bitmap1,
                          accounting::ContinuousSpaceBitmap* bitmap2,
                          accounting::LargeObjectBitmap* large_objects,
                          accounting::ObjectStack* stack) {
  DCHECK(bitmap1 != nullptr);
  DCHECK(bitmap2 != nullptr);
  const auto* limit = stack->End();
  for (auto* it = stack->Begin(); it != limit; ++it) {
    const mirror::Object* obj = it->AsMirrorPtr();
    if (!kUseThreadLocalAllocationStack || obj != nullptr) {
      if (bitmap1->HasAddress(obj)) {
        bitmap1->Set(obj);
      } else if (bitmap2->HasAddress(obj)) {
        bitmap2->Set(obj);
      } else {
        DCHECK(large_objects != nullptr);
        large_objects->Set(obj);
      }
    }
  }
}

void Heap::SwapSemiSpaces() {
  CHECK(bump_pointer_space_ != nullptr);
  CHECK(temp_space_ != nullptr);
  std::swap(bump_pointer_space_, temp_space_);
}

collector::GarbageCollector* Heap::Compact(space::ContinuousMemMapAllocSpace* target_space,
                                           space::ContinuousMemMapAllocSpace* source_space,
                                           GcCause gc_cause) {
  CHECK(kMovingCollector);
  if (target_space != source_space) {
    // Don't swap spaces since this isn't a typical semi space collection.
    semi_space_collector_->SetSwapSemiSpaces(false);
    semi_space_collector_->SetFromSpace(source_space);
    semi_space_collector_->SetToSpace(target_space);
    semi_space_collector_->Run(gc_cause, false);
    return semi_space_collector_;
  } else {
    CHECK(target_space->IsBumpPointerSpace())
        << "In-place compaction is only supported for bump pointer spaces";
    mark_compact_collector_->SetSpace(target_space->AsBumpPointerSpace());
    mark_compact_collector_->Run(kGcCauseCollectorTransition, false);
    return mark_compact_collector_;
  }
}

collector::GcType Heap::CollectGarbageInternal(collector::GcType gc_type,
                                               GcCause gc_cause,
                                               bool clear_soft_references) {
  Thread* self = Thread::Current();
  Runtime* runtime = Runtime::Current();
  // If the heap can't run the GC, silently fail and return that no GC was run.
  switch (gc_type) {
    case collector::kGcTypePartial: {
      if (!HasZygoteSpace()) {
        return collector::kGcTypeNone;
      }
      break;
    }
    default: {
      // Other GC types don't have any special cases which makes them not runnable. The main case
      // here is full GC.
    }
  }
  ScopedThreadStateChange tsc(self, kWaitingPerformingGc);
  Locks::mutator_lock_->AssertNotHeld(self);
  if (self->IsHandlingStackOverflow()) {
    // If we are throwing a stack overflow error we probably don't have enough remaining stack
    // space to run the GC.
    return collector::kGcTypeNone;
  }
  bool compacting_gc;
  {
    gc_complete_lock_->AssertNotHeld(self);
    ScopedThreadStateChange tsc2(self, kWaitingForGcToComplete);
    MutexLock mu(self, *gc_complete_lock_);
    // Ensure there is only one GC at a time.
    WaitForGcToCompleteLocked(gc_cause, self);
    compacting_gc = IsMovingGc(collector_type_);
    // GC can be disabled if someone has a used GetPrimitiveArrayCritical.
    if (compacting_gc && disable_moving_gc_count_ != 0) {
      LOG(WARNING) << "Skipping GC due to disable moving GC count " << disable_moving_gc_count_;
      return collector::kGcTypeNone;
    }
    if (gc_disabled_for_shutdown_) {
      return collector::kGcTypeNone;
    }
    collector_type_running_ = collector_type_;
  }
  if (gc_cause == kGcCauseForAlloc && runtime->HasStatsEnabled()) {
    ++runtime->GetStats()->gc_for_alloc_count;
    ++self->GetStats()->gc_for_alloc_count;
  }
  const uint64_t bytes_allocated_before_gc = GetBytesAllocated();
  // Approximate heap size.
  ATRACE_INT("Heap size (KB)", bytes_allocated_before_gc / KB);

  DCHECK_LT(gc_type, collector::kGcTypeMax);
  DCHECK_NE(gc_type, collector::kGcTypeNone);

  collector::GarbageCollector* collector = nullptr;
  // TODO: Clean this up.
  if (compacting_gc) {
    DCHECK(current_allocator_ == kAllocatorTypeBumpPointer ||
           current_allocator_ == kAllocatorTypeTLAB ||
           current_allocator_ == kAllocatorTypeRegion ||
           current_allocator_ == kAllocatorTypeRegionTLAB);
    switch (collector_type_) {
      case kCollectorTypeSS:
        // Fall-through.
      case kCollectorTypeGSS:
        semi_space_collector_->SetFromSpace(bump_pointer_space_);
        semi_space_collector_->SetToSpace(temp_space_);
        semi_space_collector_->SetSwapSemiSpaces(true);
        collector = semi_space_collector_;
        break;
      case kCollectorTypeCC:
        collector = concurrent_copying_collector_;
        break;
      case kCollectorTypeMC:
        mark_compact_collector_->SetSpace(bump_pointer_space_);
        collector = mark_compact_collector_;
        break;
      default:
        LOG(FATAL) << "Invalid collector type " << static_cast<size_t>(collector_type_);
    }
    if (collector != mark_compact_collector_ && collector != concurrent_copying_collector_) {
      temp_space_->GetMemMap()->Protect(PROT_READ | PROT_WRITE);
      if (kIsDebugBuild) {
        // Try to read each page of the memory map in case mprotect didn't work properly b/19894268.
        temp_space_->GetMemMap()->TryReadable();
      }
      CHECK(temp_space_->IsEmpty());
    }
    gc_type = collector::kGcTypeFull;  // TODO: Not hard code this in.
  } else if (current_allocator_ == kAllocatorTypeRosAlloc ||
      current_allocator_ == kAllocatorTypeDlMalloc) {
    collector = FindCollectorByGcType(gc_type);
  } else {
    LOG(FATAL) << "Invalid current allocator " << current_allocator_;
  }
  if (IsGcConcurrent()) {
    // Disable concurrent GC check so that we don't have spammy JNI requests.
    // This gets recalculated in GrowForUtilization. It is important that it is disabled /
    // calculated in the same thread so that there aren't any races that can cause it to become
    // permanantly disabled. b/17942071
    concurrent_start_bytes_ = std::numeric_limits<size_t>::max();
  }

  CHECK(collector != nullptr)
      << "Could not find garbage collector with collector_type="
      << static_cast<size_t>(collector_type_) << " and gc_type=" << gc_type;
  collector->Run(gc_cause, clear_soft_references || runtime->IsZygote());
  total_objects_freed_ever_ += GetCurrentGcIteration()->GetFreedObjects();
  total_bytes_freed_ever_ += GetCurrentGcIteration()->GetFreedBytes();
  RequestTrim(self);
  // Enqueue cleared references.
  reference_processor_->EnqueueClearedReferences(self);
  // Grow the heap so that we know when to perform the next GC.
  GrowForUtilization(collector, bytes_allocated_before_gc);
  LogGC(gc_cause, collector);
  FinishGC(self, gc_type);
  // Inform DDMS that a GC completed.
  Dbg::GcDidFinish();
  // Unload native libraries for class unloading. We do this after calling FinishGC to prevent
  // deadlocks in case the JNI_OnUnload function does allocations.
  {
    ScopedObjectAccess soa(self);
    soa.Vm()->UnloadNativeLibraries();
  }
  return gc_type;
}

void Heap::LogGC(GcCause gc_cause, collector::GarbageCollector* collector) {
  const size_t duration = GetCurrentGcIteration()->GetDurationNs();
  const std::vector<uint64_t>& pause_times = GetCurrentGcIteration()->GetPauseTimes();
  // Print the GC if it is an explicit GC (e.g. Runtime.gc()) or a slow GC
  // (mutator time blocked >= long_pause_log_threshold_).
  bool log_gc = gc_cause == kGcCauseExplicit;
  if (!log_gc && CareAboutPauseTimes()) {
    // GC for alloc pauses the allocating thread, so consider it as a pause.
    log_gc = duration > long_gc_log_threshold_ ||
        (gc_cause == kGcCauseForAlloc && duration > long_pause_log_threshold_);
    for (uint64_t pause : pause_times) {
      log_gc = log_gc || pause >= long_pause_log_threshold_;
    }
  }
  if (log_gc) {
    const size_t percent_free = GetPercentFree();
    const size_t current_heap_size = GetBytesAllocated();
    const size_t total_memory = GetTotalMemory();
    std::ostringstream pause_string;
    for (size_t i = 0; i < pause_times.size(); ++i) {
      pause_string << PrettyDuration((pause_times[i] / 1000) * 1000)
                   << ((i != pause_times.size() - 1) ? "," : "");
    }
    LOG(INFO) << gc_cause << " " << collector->GetName()
              << " GC freed "  << current_gc_iteration_.GetFreedObjects() << "("
              << PrettySize(current_gc_iteration_.GetFreedBytes()) << ") AllocSpace objects, "
              << current_gc_iteration_.GetFreedLargeObjects() << "("
              << PrettySize(current_gc_iteration_.GetFreedLargeObjectBytes()) << ") LOS objects, "
              << percent_free << "% free, " << PrettySize(current_heap_size) << "/"
              << PrettySize(total_memory) << ", " << "paused " << pause_string.str()
              << " total " << PrettyDuration((duration / 1000) * 1000);
    VLOG(heap) << Dumpable<TimingLogger>(*current_gc_iteration_.GetTimings());
  }
}

void Heap::FinishGC(Thread* self, collector::GcType gc_type) {
  MutexLock mu(self, *gc_complete_lock_);
  collector_type_running_ = kCollectorTypeNone;
  if (gc_type != collector::kGcTypeNone) {
    last_gc_type_ = gc_type;

    // Update stats.
    ++gc_count_last_window_;
    if (running_collection_is_blocking_) {
      // If the currently running collection was a blocking one,
      // increment the counters and reset the flag.
      ++blocking_gc_count_;
      blocking_gc_time_ += GetCurrentGcIteration()->GetDurationNs();
      ++blocking_gc_count_last_window_;
    }
    // Update the gc count rate histograms if due.
    UpdateGcCountRateHistograms();
  }
  // Reset.
  running_collection_is_blocking_ = false;
  // Wake anyone who may have been waiting for the GC to complete.
  gc_complete_cond_->Broadcast(self);
}

void Heap::UpdateGcCountRateHistograms() {
  // Invariant: if the time since the last update includes more than
  // one windows, all the GC runs (if > 0) must have happened in first
  // window because otherwise the update must have already taken place
  // at an earlier GC run. So, we report the non-first windows with
  // zero counts to the histograms.
  DCHECK_EQ(last_update_time_gc_count_rate_histograms_ % kGcCountRateHistogramWindowDuration, 0U);
  uint64_t now = NanoTime();
  DCHECK_GE(now, last_update_time_gc_count_rate_histograms_);
  uint64_t time_since_last_update = now - last_update_time_gc_count_rate_histograms_;
  uint64_t num_of_windows = time_since_last_update / kGcCountRateHistogramWindowDuration;
  if (time_since_last_update >= kGcCountRateHistogramWindowDuration) {
    // Record the first window.
    gc_count_rate_histogram_.AddValue(gc_count_last_window_ - 1);  // Exclude the current run.
    blocking_gc_count_rate_histogram_.AddValue(running_collection_is_blocking_ ?
        blocking_gc_count_last_window_ - 1 : blocking_gc_count_last_window_);
    // Record the other windows (with zero counts).
    for (uint64_t i = 0; i < num_of_windows - 1; ++i) {
      gc_count_rate_histogram_.AddValue(0);
      blocking_gc_count_rate_histogram_.AddValue(0);
    }
    // Update the last update time and reset the counters.
    last_update_time_gc_count_rate_histograms_ =
        (now / kGcCountRateHistogramWindowDuration) * kGcCountRateHistogramWindowDuration;
    gc_count_last_window_ = 1;  // Include the current run.
    blocking_gc_count_last_window_ = running_collection_is_blocking_ ? 1 : 0;
  }
  DCHECK_EQ(last_update_time_gc_count_rate_histograms_ % kGcCountRateHistogramWindowDuration, 0U);
}

class RootMatchesObjectVisitor : public SingleRootVisitor {
 public:
  explicit RootMatchesObjectVisitor(const mirror::Object* obj) : obj_(obj) { }

  void VisitRoot(mirror::Object* root, const RootInfo& info)
      OVERRIDE REQUIRES_SHARED(Locks::mutator_lock_) {
    if (root == obj_) {
      LOG(INFO) << "Object " << obj_ << " is a root " << info.ToString();
    }
  }

 private:
  const mirror::Object* const obj_;
};


class ScanVisitor {
 public:
  void operator()(const mirror::Object* obj) const {
    LOG(ERROR) << "Would have rescanned object " << obj;
  }
};

// Verify a reference from an object.
class VerifyReferenceVisitor : public SingleRootVisitor {
 public:
  VerifyReferenceVisitor(Heap* heap, Atomic<size_t>* fail_count, bool verify_referent)
      REQUIRES_SHARED(Locks::mutator_lock_, Locks::heap_bitmap_lock_)
      : heap_(heap), fail_count_(fail_count), verify_referent_(verify_referent) {}

  size_t GetFailureCount() const {
    return fail_count_->LoadSequentiallyConsistent();
  }

  void operator()(ObjPtr<mirror::Class> klass ATTRIBUTE_UNUSED, ObjPtr<mirror::Reference> ref) const
      REQUIRES_SHARED(Locks::mutator_lock_) {
    if (verify_referent_) {
      VerifyReference(ref.Ptr(), ref->GetReferent(), mirror::Reference::ReferentOffset());
    }
  }

  void operator()(ObjPtr<mirror::Object> obj,
                  MemberOffset offset,
                  bool is_static ATTRIBUTE_UNUSED) const
      REQUIRES_SHARED(Locks::mutator_lock_) {
    VerifyReference(obj.Ptr(), obj->GetFieldObject<mirror::Object>(offset), offset);
  }

  bool IsLive(ObjPtr<mirror::Object> obj) const NO_THREAD_SAFETY_ANALYSIS {
    return heap_->IsLiveObjectLocked(obj, true, false, true);
  }

  void VisitRootIfNonNull(mirror::CompressedReference<mirror::Object>* root) const
      REQUIRES_SHARED(Locks::mutator_lock_) {
    if (!root->IsNull()) {
      VisitRoot(root);
    }
  }
  void VisitRoot(mirror::CompressedReference<mirror::Object>* root) const
      REQUIRES_SHARED(Locks::mutator_lock_) {
    const_cast<VerifyReferenceVisitor*>(this)->VisitRoot(
        root->AsMirrorPtr(), RootInfo(kRootVMInternal));
  }

  virtual void VisitRoot(mirror::Object* root, const RootInfo& root_info) OVERRIDE
      REQUIRES_SHARED(Locks::mutator_lock_) {
    if (root == nullptr) {
      LOG(ERROR) << "Root is null with info " << root_info.GetType();
    } else if (!VerifyReference(nullptr, root, MemberOffset(0))) {
      LOG(ERROR) << "Root " << root << " is dead with type " << mirror::Object::PrettyTypeOf(root)
          << " thread_id= " << root_info.GetThreadId() << " root_type= " << root_info.GetType();
    }
  }

 private:
  // TODO: Fix the no thread safety analysis.
  // Returns false on failure.
  bool VerifyReference(mirror::Object* obj, mirror::Object* ref, MemberOffset offset) const
      NO_THREAD_SAFETY_ANALYSIS {
    if (ref == nullptr || IsLive(ref)) {
      // Verify that the reference is live.
      return true;
    }
    if (fail_count_->FetchAndAddSequentiallyConsistent(1) == 0) {
      // Print message on only on first failure to prevent spam.
      LOG(ERROR) << "!!!!!!!!!!!!!!Heap corruption detected!!!!!!!!!!!!!!!!!!!";
    }
    if (obj != nullptr) {
      // Only do this part for non roots.
      accounting::CardTable* card_table = heap_->GetCardTable();
      accounting::ObjectStack* alloc_stack = heap_->allocation_stack_.get();
      accounting::ObjectStack* live_stack = heap_->live_stack_.get();
      uint8_t* card_addr = card_table->CardFromAddr(obj);
      LOG(ERROR) << "Object " << obj << " references dead object " << ref << " at offset "
                 << offset << "\n card value = " << static_cast<int>(*card_addr);
      if (heap_->IsValidObjectAddress(obj->GetClass())) {
        LOG(ERROR) << "Obj type " << obj->PrettyTypeOf();
      } else {
        LOG(ERROR) << "Object " << obj << " class(" << obj->GetClass() << ") not a heap address";
      }

      // Attempt to find the class inside of the recently freed objects.
      space::ContinuousSpace* ref_space = heap_->FindContinuousSpaceFromObject(ref, true);
      if (ref_space != nullptr && ref_space->IsMallocSpace()) {
        space::MallocSpace* space = ref_space->AsMallocSpace();
        mirror::Class* ref_class = space->FindRecentFreedObject(ref);
        if (ref_class != nullptr) {
          LOG(ERROR) << "Reference " << ref << " found as a recently freed object with class "
                     << ref_class->PrettyClass();
        } else {
          LOG(ERROR) << "Reference " << ref << " not found as a recently freed object";
        }
      }

      if (ref->GetClass() != nullptr && heap_->IsValidObjectAddress(ref->GetClass()) &&
          ref->GetClass()->IsClass()) {
        LOG(ERROR) << "Ref type " << ref->PrettyTypeOf();
      } else {
        LOG(ERROR) << "Ref " << ref << " class(" << ref->GetClass()
                   << ") is not a valid heap address";
      }

      card_table->CheckAddrIsInCardTable(reinterpret_cast<const uint8_t*>(obj));
      void* cover_begin = card_table->AddrFromCard(card_addr);
      void* cover_end = reinterpret_cast<void*>(reinterpret_cast<size_t>(cover_begin) +
          accounting::CardTable::kCardSize);
      LOG(ERROR) << "Card " << reinterpret_cast<void*>(card_addr) << " covers " << cover_begin
          << "-" << cover_end;
      accounting::ContinuousSpaceBitmap* bitmap =
          heap_->GetLiveBitmap()->GetContinuousSpaceBitmap(obj);

      if (bitmap == nullptr) {
        LOG(ERROR) << "Object " << obj << " has no bitmap";
        if (!VerifyClassClass(obj->GetClass())) {
          LOG(ERROR) << "Object " << obj << " failed class verification!";
        }
      } else {
        // Print out how the object is live.
        if (bitmap->Test(obj)) {
          LOG(ERROR) << "Object " << obj << " found in live bitmap";
        }
        if (alloc_stack->Contains(const_cast<mirror::Object*>(obj))) {
          LOG(ERROR) << "Object " << obj << " found in allocation stack";
        }
        if (live_stack->Contains(const_cast<mirror::Object*>(obj))) {
          LOG(ERROR) << "Object " << obj << " found in live stack";
        }
        if (alloc_stack->Contains(const_cast<mirror::Object*>(ref))) {
          LOG(ERROR) << "Ref " << ref << " found in allocation stack";
        }
        if (live_stack->Contains(const_cast<mirror::Object*>(ref))) {
          LOG(ERROR) << "Ref " << ref << " found in live stack";
        }
        // Attempt to see if the card table missed the reference.
        ScanVisitor scan_visitor;
        uint8_t* byte_cover_begin = reinterpret_cast<uint8_t*>(card_table->AddrFromCard(card_addr));
        card_table->Scan<false>(bitmap, byte_cover_begin,
                                byte_cover_begin + accounting::CardTable::kCardSize, scan_visitor);
      }

      // Search to see if any of the roots reference our object.
      RootMatchesObjectVisitor visitor1(obj);
      Runtime::Current()->VisitRoots(&visitor1);
      // Search to see if any of the roots reference our reference.
      RootMatchesObjectVisitor visitor2(ref);
      Runtime::Current()->VisitRoots(&visitor2);
    }
    return false;
  }

  Heap* const heap_;
  Atomic<size_t>* const fail_count_;
  const bool verify_referent_;
};

// Verify all references within an object, for use with HeapBitmap::Visit.
class VerifyObjectVisitor {
 public:
  VerifyObjectVisitor(Heap* heap, Atomic<size_t>* fail_count, bool verify_referent)
      : heap_(heap), fail_count_(fail_count), verify_referent_(verify_referent) {}

  void operator()(mirror::Object* obj)
      REQUIRES_SHARED(Locks::mutator_lock_, Locks::heap_bitmap_lock_) {
    // Note: we are verifying the references in obj but not obj itself, this is because obj must
    // be live or else how did we find it in the live bitmap?
    VerifyReferenceVisitor visitor(heap_, fail_count_, verify_referent_);
    // The class doesn't count as a reference but we should verify it anyways.
    obj->VisitReferences(visitor, visitor);
  }

  static void VisitCallback(mirror::Object* obj, void* arg)
      REQUIRES_SHARED(Locks::mutator_lock_, Locks::heap_bitmap_lock_) {
    VerifyObjectVisitor* visitor = reinterpret_cast<VerifyObjectVisitor*>(arg);
    visitor->operator()(obj);
  }

  void VerifyRoots() REQUIRES_SHARED(Locks::mutator_lock_) REQUIRES(!Locks::heap_bitmap_lock_) {
    ReaderMutexLock mu(Thread::Current(), *Locks::heap_bitmap_lock_);
    VerifyReferenceVisitor visitor(heap_, fail_count_, verify_referent_);
    Runtime::Current()->VisitRoots(&visitor);
  }

  size_t GetFailureCount() const {
    return fail_count_->LoadSequentiallyConsistent();
  }

 private:
  Heap* const heap_;
  Atomic<size_t>* const fail_count_;
  const bool verify_referent_;
};

void Heap::PushOnAllocationStackWithInternalGC(Thread* self, ObjPtr<mirror::Object>* obj) {
  // Slow path, the allocation stack push back must have already failed.
  DCHECK(!allocation_stack_->AtomicPushBack(obj->Ptr()));
  do {
    // TODO: Add handle VerifyObject.
    StackHandleScope<1> hs(self);
    HandleWrapperObjPtr<mirror::Object> wrapper(hs.NewHandleWrapper(obj));
    // Push our object into the reserve region of the allocaiton stack. This is only required due
    // to heap verification requiring that roots are live (either in the live bitmap or in the
    // allocation stack).
    CHECK(allocation_stack_->AtomicPushBackIgnoreGrowthLimit(obj->Ptr()));
    CollectGarbageInternal(collector::kGcTypeSticky, kGcCauseForAlloc, false);
  } while (!allocation_stack_->AtomicPushBack(obj->Ptr()));
}

void Heap::PushOnThreadLocalAllocationStackWithInternalGC(Thread* self,
                                                          ObjPtr<mirror::Object>* obj) {
  // Slow path, the allocation stack push back must have already failed.
  DCHECK(!self->PushOnThreadLocalAllocationStack(obj->Ptr()));
  StackReference<mirror::Object>* start_address;
  StackReference<mirror::Object>* end_address;
  while (!allocation_stack_->AtomicBumpBack(kThreadLocalAllocationStackSize, &start_address,
                                            &end_address)) {
    // TODO: Add handle VerifyObject.
    StackHandleScope<1> hs(self);
    HandleWrapperObjPtr<mirror::Object> wrapper(hs.NewHandleWrapper(obj));
    // Push our object into the reserve region of the allocaiton stack. This is only required due
    // to heap verification requiring that roots are live (either in the live bitmap or in the
    // allocation stack).
    CHECK(allocation_stack_->AtomicPushBackIgnoreGrowthLimit(obj->Ptr()));
    // Push into the reserve allocation stack.
    CollectGarbageInternal(collector::kGcTypeSticky, kGcCauseForAlloc, false);
  }
  self->SetThreadLocalAllocationStack(start_address, end_address);
  // Retry on the new thread-local allocation stack.
  CHECK(self->PushOnThreadLocalAllocationStack(obj->Ptr()));  // Must succeed.
}

// Must do this with mutators suspended since we are directly accessing the allocation stacks.
size_t Heap::VerifyHeapReferences(bool verify_referents) {
  Thread* self = Thread::Current();
  Locks::mutator_lock_->AssertExclusiveHeld(self);
  // Lets sort our allocation stacks so that we can efficiently binary search them.
  allocation_stack_->Sort();
  live_stack_->Sort();
  // Since we sorted the allocation stack content, need to revoke all
  // thread-local allocation stacks.
  RevokeAllThreadLocalAllocationStacks(self);
  Atomic<size_t> fail_count_(0);
  VerifyObjectVisitor visitor(this, &fail_count_, verify_referents);
  // Verify objects in the allocation stack since these will be objects which were:
  // 1. Allocated prior to the GC (pre GC verification).
  // 2. Allocated during the GC (pre sweep GC verification).
  // We don't want to verify the objects in the live stack since they themselves may be
  // pointing to dead objects if they are not reachable.
  VisitObjectsPaused(VerifyObjectVisitor::VisitCallback, &visitor);
  // Verify the roots:
  visitor.VerifyRoots();
  if (visitor.GetFailureCount() > 0) {
    // Dump mod-union tables.
    for (const auto& table_pair : mod_union_tables_) {
      accounting::ModUnionTable* mod_union_table = table_pair.second;
      mod_union_table->Dump(LOG_STREAM(ERROR) << mod_union_table->GetName() << ": ");
    }
    // Dump remembered sets.
    for (const auto& table_pair : remembered_sets_) {
      accounting::RememberedSet* remembered_set = table_pair.second;
      remembered_set->Dump(LOG_STREAM(ERROR) << remembered_set->GetName() << ": ");
    }
    DumpSpaces(LOG_STREAM(ERROR));
  }
  return visitor.GetFailureCount();
}

class VerifyReferenceCardVisitor {
 public:
  VerifyReferenceCardVisitor(Heap* heap, bool* failed)
      REQUIRES_SHARED(Locks::mutator_lock_,
                            Locks::heap_bitmap_lock_)
      : heap_(heap), failed_(failed) {
  }

  // There is no card marks for native roots on a class.
  void VisitRootIfNonNull(mirror::CompressedReference<mirror::Object>* root ATTRIBUTE_UNUSED)
      const {}
  void VisitRoot(mirror::CompressedReference<mirror::Object>* root ATTRIBUTE_UNUSED) const {}

  // TODO: Fix lock analysis to not use NO_THREAD_SAFETY_ANALYSIS, requires support for
  // annotalysis on visitors.
  void operator()(mirror::Object* obj, MemberOffset offset, bool is_static) const
      NO_THREAD_SAFETY_ANALYSIS {
    mirror::Object* ref = obj->GetFieldObject<mirror::Object>(offset);
    // Filter out class references since changing an object's class does not mark the card as dirty.
    // Also handles large objects, since the only reference they hold is a class reference.
    if (ref != nullptr && !ref->IsClass()) {
      accounting::CardTable* card_table = heap_->GetCardTable();
      // If the object is not dirty and it is referencing something in the live stack other than
      // class, then it must be on a dirty card.
      if (!card_table->AddrIsInCardTable(obj)) {
        LOG(ERROR) << "Object " << obj << " is not in the address range of the card table";
        *failed_ = true;
      } else if (!card_table->IsDirty(obj)) {
        // TODO: Check mod-union tables.
        // Card should be either kCardDirty if it got re-dirtied after we aged it, or
        // kCardDirty - 1 if it didnt get touched since we aged it.
        accounting::ObjectStack* live_stack = heap_->live_stack_.get();
        if (live_stack->ContainsSorted(ref)) {
          if (live_stack->ContainsSorted(obj)) {
            LOG(ERROR) << "Object " << obj << " found in live stack";
          }
          if (heap_->GetLiveBitmap()->Test(obj)) {
            LOG(ERROR) << "Object " << obj << " found in live bitmap";
          }
          LOG(ERROR) << "Object " << obj << " " << mirror::Object::PrettyTypeOf(obj)
                    << " references " << ref << " " << mirror::Object::PrettyTypeOf(ref)
                    << " in live stack";

          // Print which field of the object is dead.
          if (!obj->IsObjectArray()) {
            mirror::Class* klass = is_static ? obj->AsClass() : obj->GetClass();
            CHECK(klass != nullptr);
            for (ArtField& field : (is_static ? klass->GetSFields() : klass->GetIFields())) {
              if (field.GetOffset().Int32Value() == offset.Int32Value()) {
                LOG(ERROR) << (is_static ? "Static " : "") << "field in the live stack is "
                           << field.PrettyField();
                break;
              }
            }
          } else {
            mirror::ObjectArray<mirror::Object>* object_array =
                obj->AsObjectArray<mirror::Object>();
            for (int32_t i = 0; i < object_array->GetLength(); ++i) {
              if (object_array->Get(i) == ref) {
                LOG(ERROR) << (is_static ? "Static " : "") << "obj[" << i << "] = ref";
              }
            }
          }

          *failed_ = true;
        }
      }
    }
  }

 private:
  Heap* const heap_;
  bool* const failed_;
};

class VerifyLiveStackReferences {
 public:
  explicit VerifyLiveStackReferences(Heap* heap)
      : heap_(heap),
        failed_(false) {}

  void operator()(mirror::Object* obj) const
      REQUIRES_SHARED(Locks::mutator_lock_, Locks::heap_bitmap_lock_) {
    VerifyReferenceCardVisitor visitor(heap_, const_cast<bool*>(&failed_));
    obj->VisitReferences(visitor, VoidFunctor());
  }

  bool Failed() const {
    return failed_;
  }

 private:
  Heap* const heap_;
  bool failed_;
};

bool Heap::VerifyMissingCardMarks() {
  Thread* self = Thread::Current();
  Locks::mutator_lock_->AssertExclusiveHeld(self);
  // We need to sort the live stack since we binary search it.
  live_stack_->Sort();
  // Since we sorted the allocation stack content, need to revoke all
  // thread-local allocation stacks.
  RevokeAllThreadLocalAllocationStacks(self);
  VerifyLiveStackReferences visitor(this);
  GetLiveBitmap()->Visit(visitor);
  // We can verify objects in the live stack since none of these should reference dead objects.
  for (auto* it = live_stack_->Begin(); it != live_stack_->End(); ++it) {
    if (!kUseThreadLocalAllocationStack || it->AsMirrorPtr() != nullptr) {
      visitor(it->AsMirrorPtr());
    }
  }
  return !visitor.Failed();
}

void Heap::SwapStacks() {
  if (kUseThreadLocalAllocationStack) {
    live_stack_->AssertAllZero();
  }
  allocation_stack_.swap(live_stack_);
}

void Heap::RevokeAllThreadLocalAllocationStacks(Thread* self) {
  // This must be called only during the pause.
  DCHECK(Locks::mutator_lock_->IsExclusiveHeld(self));
  MutexLock mu(self, *Locks::runtime_shutdown_lock_);
  MutexLock mu2(self, *Locks::thread_list_lock_);
  std::list<Thread*> thread_list = Runtime::Current()->GetThreadList()->GetList();
  for (Thread* t : thread_list) {
    t->RevokeThreadLocalAllocationStack();
  }
}

void Heap::AssertThreadLocalBuffersAreRevoked(Thread* thread) {
  if (kIsDebugBuild) {
    if (rosalloc_space_ != nullptr) {
      rosalloc_space_->AssertThreadLocalBuffersAreRevoked(thread);
    }
    if (bump_pointer_space_ != nullptr) {
      bump_pointer_space_->AssertThreadLocalBuffersAreRevoked(thread);
    }
  }
}

void Heap::AssertAllBumpPointerSpaceThreadLocalBuffersAreRevoked() {
  if (kIsDebugBuild) {
    if (bump_pointer_space_ != nullptr) {
      bump_pointer_space_->AssertAllThreadLocalBuffersAreRevoked();
    }
  }
}

accounting::ModUnionTable* Heap::FindModUnionTableFromSpace(space::Space* space) {
  auto it = mod_union_tables_.find(space);
  if (it == mod_union_tables_.end()) {
    return nullptr;
  }
  return it->second;
}

accounting::RememberedSet* Heap::FindRememberedSetFromSpace(space::Space* space) {
  auto it = remembered_sets_.find(space);
  if (it == remembered_sets_.end()) {
    return nullptr;
  }
  return it->second;
}

void Heap::ProcessCards(TimingLogger* timings,
                        bool use_rem_sets,
                        bool process_alloc_space_cards,
                        bool clear_alloc_space_cards) {
  TimingLogger::ScopedTiming t(__FUNCTION__, timings);
  // Clear cards and keep track of cards cleared in the mod-union table.
  for (const auto& space : continuous_spaces_) {
    accounting::ModUnionTable* table = FindModUnionTableFromSpace(space);
    accounting::RememberedSet* rem_set = FindRememberedSetFromSpace(space);
    if (table != nullptr) {
      const char* name = space->IsZygoteSpace() ? "ZygoteModUnionClearCards" :
          "ImageModUnionClearCards";
      TimingLogger::ScopedTiming t2(name, timings);
      table->ProcessCards();
    } else if (use_rem_sets && rem_set != nullptr) {
      DCHECK(collector::SemiSpace::kUseRememberedSet && collector_type_ == kCollectorTypeGSS)
          << static_cast<int>(collector_type_);
      TimingLogger::ScopedTiming t2("AllocSpaceRemSetClearCards", timings);
      rem_set->ClearCards();
    } else if (process_alloc_space_cards) {
      TimingLogger::ScopedTiming t2("AllocSpaceClearCards", timings);
      if (clear_alloc_space_cards) {
        uint8_t* end = space->End();
        if (space->IsImageSpace()) {
          // Image space end is the end of the mirror objects, it is not necessarily page or card
          // aligned. Align up so that the check in ClearCardRange does not fail.
          end = AlignUp(end, accounting::CardTable::kCardSize);
        }
        card_table_->ClearCardRange(space->Begin(), end);
      } else {
        // No mod union table for the AllocSpace. Age the cards so that the GC knows that these
        // cards were dirty before the GC started.
        // TODO: Need to use atomic for the case where aged(cleaning thread) -> dirty(other thread)
        // -> clean(cleaning thread).
        // The races are we either end up with: Aged card, unaged card. Since we have the
        // checkpoint roots and then we scan / update mod union tables after. We will always
        // scan either card. If we end up with the non aged card, we scan it it in the pause.
        card_table_->ModifyCardsAtomic(space->Begin(), space->End(), AgeCardVisitor(),
                                       VoidFunctor());
      }
    }
  }
}

struct IdentityMarkHeapReferenceVisitor : public MarkObjectVisitor {
  virtual mirror::Object* MarkObject(mirror::Object* obj) OVERRIDE {
    return obj;
  }
  virtual void MarkHeapReference(mirror::HeapReference<mirror::Object>*) OVERRIDE {
  }
};

void Heap::PreGcVerificationPaused(collector::GarbageCollector* gc) {
  Thread* const self = Thread::Current();
  TimingLogger* const timings = current_gc_iteration_.GetTimings();
  TimingLogger::ScopedTiming t(__FUNCTION__, timings);
  if (verify_pre_gc_heap_) {
    TimingLogger::ScopedTiming t2("(Paused)PreGcVerifyHeapReferences", timings);
    size_t failures = VerifyHeapReferences();
    if (failures > 0) {
      LOG(FATAL) << "Pre " << gc->GetName() << " heap verification failed with " << failures
          << " failures";
    }
  }
  // Check that all objects which reference things in the live stack are on dirty cards.
  if (verify_missing_card_marks_) {
    TimingLogger::ScopedTiming t2("(Paused)PreGcVerifyMissingCardMarks", timings);
    ReaderMutexLock mu(self, *Locks::heap_bitmap_lock_);
    SwapStacks();
    // Sort the live stack so that we can quickly binary search it later.
    CHECK(VerifyMissingCardMarks()) << "Pre " << gc->GetName()
                                    << " missing card mark verification failed\n" << DumpSpaces();
    SwapStacks();
  }
  if (verify_mod_union_table_) {
    TimingLogger::ScopedTiming t2("(Paused)PreGcVerifyModUnionTables", timings);
    ReaderMutexLock reader_lock(self, *Locks::heap_bitmap_lock_);
    for (const auto& table_pair : mod_union_tables_) {
      accounting::ModUnionTable* mod_union_table = table_pair.second;
      IdentityMarkHeapReferenceVisitor visitor;
      mod_union_table->UpdateAndMarkReferences(&visitor);
      mod_union_table->Verify();
    }
  }
}

void Heap::PreGcVerification(collector::GarbageCollector* gc) {
  if (verify_pre_gc_heap_ || verify_missing_card_marks_ || verify_mod_union_table_) {
    collector::GarbageCollector::ScopedPause pause(gc);
    PreGcVerificationPaused(gc);
  }
}

void Heap::PrePauseRosAllocVerification(collector::GarbageCollector* gc ATTRIBUTE_UNUSED) {
  // TODO: Add a new runtime option for this?
  if (verify_pre_gc_rosalloc_) {
    RosAllocVerification(current_gc_iteration_.GetTimings(), "PreGcRosAllocVerification");
  }
}

void Heap::PreSweepingGcVerification(collector::GarbageCollector* gc) {
  Thread* const self = Thread::Current();
  TimingLogger* const timings = current_gc_iteration_.GetTimings();
  TimingLogger::ScopedTiming t(__FUNCTION__, timings);
  // Called before sweeping occurs since we want to make sure we are not going so reclaim any
  // reachable objects.
  if (verify_pre_sweeping_heap_) {
    TimingLogger::ScopedTiming t2("(Paused)PostSweepingVerifyHeapReferences", timings);
    CHECK_NE(self->GetState(), kRunnable);
    {
      WriterMutexLock mu(self, *Locks::heap_bitmap_lock_);
      // Swapping bound bitmaps does nothing.
      gc->SwapBitmaps();
    }
    // Pass in false since concurrent reference processing can mean that the reference referents
    // may point to dead objects at the point which PreSweepingGcVerification is called.
    size_t failures = VerifyHeapReferences(false);
    if (failures > 0) {
      LOG(FATAL) << "Pre sweeping " << gc->GetName() << " GC verification failed with " << failures
          << " failures";
    }
    {
      WriterMutexLock mu(self, *Locks::heap_bitmap_lock_);
      gc->SwapBitmaps();
    }
  }
  if (verify_pre_sweeping_rosalloc_) {
    RosAllocVerification(timings, "PreSweepingRosAllocVerification");
  }
}

void Heap::PostGcVerificationPaused(collector::GarbageCollector* gc) {
  // Only pause if we have to do some verification.
  Thread* const self = Thread::Current();
  TimingLogger* const timings = GetCurrentGcIteration()->GetTimings();
  TimingLogger::ScopedTiming t(__FUNCTION__, timings);
  if (verify_system_weaks_) {
    ReaderMutexLock mu2(self, *Locks::heap_bitmap_lock_);
    collector::MarkSweep* mark_sweep = down_cast<collector::MarkSweep*>(gc);
    mark_sweep->VerifySystemWeaks();
  }
  if (verify_post_gc_rosalloc_) {
    RosAllocVerification(timings, "(Paused)PostGcRosAllocVerification");
  }
  if (verify_post_gc_heap_) {
    TimingLogger::ScopedTiming t2("(Paused)PostGcVerifyHeapReferences", timings);
    size_t failures = VerifyHeapReferences();
    if (failures > 0) {
      LOG(FATAL) << "Pre " << gc->GetName() << " heap verification failed with " << failures
          << " failures";
    }
  }
}

void Heap::PostGcVerification(collector::GarbageCollector* gc) {
  if (verify_system_weaks_ || verify_post_gc_rosalloc_ || verify_post_gc_heap_) {
    collector::GarbageCollector::ScopedPause pause(gc);
    PostGcVerificationPaused(gc);
  }
}

void Heap::RosAllocVerification(TimingLogger* timings, const char* name) {
  TimingLogger::ScopedTiming t(name, timings);
  for (const auto& space : continuous_spaces_) {
    if (space->IsRosAllocSpace()) {
      VLOG(heap) << name << " : " << space->GetName();
      space->AsRosAllocSpace()->Verify();
    }
  }
}

collector::GcType Heap::WaitForGcToComplete(GcCause cause, Thread* self) {
  ScopedThreadStateChange tsc(self, kWaitingForGcToComplete);
  MutexLock mu(self, *gc_complete_lock_);
  return WaitForGcToCompleteLocked(cause, self);
}

collector::GcType Heap::WaitForGcToCompleteLocked(GcCause cause, Thread* self) {
  collector::GcType last_gc_type = collector::kGcTypeNone;
  uint64_t wait_start = NanoTime();
  while (collector_type_running_ != kCollectorTypeNone) {
    if (self != task_processor_->GetRunningThread()) {
      // The current thread is about to wait for a currently running
      // collection to finish. If the waiting thread is not the heap
      // task daemon thread, the currently running collection is
      // considered as a blocking GC.
      running_collection_is_blocking_ = true;
      VLOG(gc) << "Waiting for a blocking GC " << cause;
    }
    ScopedTrace trace("GC: Wait For Completion");
    // We must wait, change thread state then sleep on gc_complete_cond_;
    gc_complete_cond_->Wait(self);
    last_gc_type = last_gc_type_;
  }
  uint64_t wait_time = NanoTime() - wait_start;
  total_wait_time_ += wait_time;
  if (wait_time > long_pause_log_threshold_) {
    LOG(INFO) << "WaitForGcToComplete blocked for " << PrettyDuration(wait_time)
        << " for cause " << cause;
  }
  if (self != task_processor_->GetRunningThread()) {
    // The current thread is about to run a collection. If the thread
    // is not the heap task daemon thread, it's considered as a
    // blocking GC (i.e., blocking itself).
    running_collection_is_blocking_ = true;
    VLOG(gc) << "Starting a blocking GC " << cause;
  }
  return last_gc_type;
}

void Heap::DumpForSigQuit(std::ostream& os) {
  os << "Heap: " << GetPercentFree() << "% free, " << PrettySize(GetBytesAllocated()) << "/"
     << PrettySize(GetTotalMemory()) << "; " << GetObjectsAllocated() << " objects\n";
  DumpGcPerformanceInfo(os);
}

size_t Heap::GetPercentFree() {
  return static_cast<size_t>(100.0f * static_cast<float>(GetFreeMemory()) / max_allowed_footprint_);
}

void Heap::SetIdealFootprint(size_t max_allowed_footprint) {
  if (max_allowed_footprint > GetMaxMemory()) {
    VLOG(gc) << "Clamp target GC heap from " << PrettySize(max_allowed_footprint) << " to "
             << PrettySize(GetMaxMemory());
    max_allowed_footprint = GetMaxMemory();
  }
  max_allowed_footprint_ = max_allowed_footprint;
}

bool Heap::IsMovableObject(ObjPtr<mirror::Object> obj) const {
  if (kMovingCollector) {
    space::Space* space = FindContinuousSpaceFromObject(obj.Ptr(), true);
    if (space != nullptr) {
      // TODO: Check large object?
      return space->CanMoveObjects();
    }
  }
  return false;
}

void Heap::UpdateMaxNativeFootprint() {
  size_t native_size = native_bytes_allocated_.LoadRelaxed();
  // TODO: Tune the native heap utilization to be a value other than the java heap utilization.
  size_t target_size = native_size / GetTargetHeapUtilization();
  if (target_size > native_size + max_free_) {
    target_size = native_size + max_free_;
  } else if (target_size < native_size + min_free_) {
    target_size = native_size + min_free_;
  }
  native_footprint_gc_watermark_ = std::min(growth_limit_, target_size);
}

collector::GarbageCollector* Heap::FindCollectorByGcType(collector::GcType gc_type) {
  for (const auto& collector : garbage_collectors_) {
    if (collector->GetCollectorType() == collector_type_ &&
        collector->GetGcType() == gc_type) {
      return collector;
    }
  }
  return nullptr;
}

double Heap::HeapGrowthMultiplier() const {
  // If we don't care about pause times we are background, so return 1.0.
  if (!CareAboutPauseTimes() || IsLowMemoryMode()) {
    return 1.0;
  }
  return foreground_heap_growth_multiplier_;
}

void Heap::GrowForUtilization(collector::GarbageCollector* collector_ran,
                              uint64_t bytes_allocated_before_gc) {
  // We know what our utilization is at this moment.
  // This doesn't actually resize any memory. It just lets the heap grow more when necessary.
  const uint64_t bytes_allocated = GetBytesAllocated();
  uint64_t target_size;
  collector::GcType gc_type = collector_ran->GetGcType();
  const double multiplier = HeapGrowthMultiplier();  // Use the multiplier to grow more for
  // foreground.
  const uint64_t adjusted_min_free = static_cast<uint64_t>(min_free_ * multiplier);
  const uint64_t adjusted_max_free = static_cast<uint64_t>(max_free_ * multiplier);
  if (gc_type != collector::kGcTypeSticky) {
    // Grow the heap for non sticky GC.
    ssize_t delta = bytes_allocated / GetTargetHeapUtilization() - bytes_allocated;
    CHECK_GE(delta, 0);
    target_size = bytes_allocated + delta * multiplier;
    target_size = std::min(target_size, bytes_allocated + adjusted_max_free);
    target_size = std::max(target_size, bytes_allocated + adjusted_min_free);
    native_need_to_run_finalization_ = true;
    next_gc_type_ = collector::kGcTypeSticky;
  } else {
    collector::GcType non_sticky_gc_type =
        HasZygoteSpace() ? collector::kGcTypePartial : collector::kGcTypeFull;
    // Find what the next non sticky collector will be.
    collector::GarbageCollector* non_sticky_collector = FindCollectorByGcType(non_sticky_gc_type);
    // If the throughput of the current sticky GC >= throughput of the non sticky collector, then
    // do another sticky collection next.
    // We also check that the bytes allocated aren't over the footprint limit in order to prevent a
    // pathological case where dead objects which aren't reclaimed by sticky could get accumulated
    // if the sticky GC throughput always remained >= the full/partial throughput.
    if (current_gc_iteration_.GetEstimatedThroughput() * kStickyGcThroughputAdjustment >=
        non_sticky_collector->GetEstimatedMeanThroughput() &&
        non_sticky_collector->NumberOfIterations() > 0 &&
        bytes_allocated <= max_allowed_footprint_) {
      next_gc_type_ = collector::kGcTypeSticky;
    } else {
      next_gc_type_ = non_sticky_gc_type;
    }
    // If we have freed enough memory, shrink the heap back down.
    if (bytes_allocated + adjusted_max_free < max_allowed_footprint_) {
      target_size = bytes_allocated + adjusted_max_free;
    } else {
      target_size = std::max(bytes_allocated, static_cast<uint64_t>(max_allowed_footprint_));
    }
  }
  if (!ignore_max_footprint_) {
    SetIdealFootprint(target_size);
    if (IsGcConcurrent()) {
      const uint64_t freed_bytes = current_gc_iteration_.GetFreedBytes() +
          current_gc_iteration_.GetFreedLargeObjectBytes() +
          current_gc_iteration_.GetFreedRevokeBytes();
      // Bytes allocated will shrink by freed_bytes after the GC runs, so if we want to figure out
      // how many bytes were allocated during the GC we need to add freed_bytes back on.
      CHECK_GE(bytes_allocated + freed_bytes, bytes_allocated_before_gc);
      const uint64_t bytes_allocated_during_gc = bytes_allocated + freed_bytes -
          bytes_allocated_before_gc;
      // Calculate when to perform the next ConcurrentGC.
      // Calculate the estimated GC duration.
      const double gc_duration_seconds = NsToMs(current_gc_iteration_.GetDurationNs()) / 1000.0;
      // Estimate how many remaining bytes we will have when we need to start the next GC.
      size_t remaining_bytes = bytes_allocated_during_gc * gc_duration_seconds;
      remaining_bytes = std::min(remaining_bytes, kMaxConcurrentRemainingBytes);
      remaining_bytes = std::max(remaining_bytes, kMinConcurrentRemainingBytes);
      if (UNLIKELY(remaining_bytes > max_allowed_footprint_)) {
        // A never going to happen situation that from the estimated allocation rate we will exceed
        // the applications entire footprint with the given estimated allocation rate. Schedule
        // another GC nearly straight away.
        remaining_bytes = kMinConcurrentRemainingBytes;
      }
      DCHECK_LE(remaining_bytes, max_allowed_footprint_);
      DCHECK_LE(max_allowed_footprint_, GetMaxMemory());
      // Start a concurrent GC when we get close to the estimated remaining bytes. When the
      // allocation rate is very high, remaining_bytes could tell us that we should start a GC
      // right away.
      concurrent_start_bytes_ = std::max(max_allowed_footprint_ - remaining_bytes,
                                         static_cast<size_t>(bytes_allocated));
    }
  }
}

void Heap::ClampGrowthLimit() {
  // Use heap bitmap lock to guard against races with BindLiveToMarkBitmap.
  ScopedObjectAccess soa(Thread::Current());
  WriterMutexLock mu(soa.Self(), *Locks::heap_bitmap_lock_);
  capacity_ = growth_limit_;
  for (const auto& space : continuous_spaces_) {
    if (space->IsMallocSpace()) {
      gc::space::MallocSpace* malloc_space = space->AsMallocSpace();
      malloc_space->ClampGrowthLimit();
    }
  }
  // This space isn't added for performance reasons.
  if (main_space_backup_.get() != nullptr) {
    main_space_backup_->ClampGrowthLimit();
  }
}

void Heap::ClearGrowthLimit() {
  growth_limit_ = capacity_;
  ScopedObjectAccess soa(Thread::Current());
  for (const auto& space : continuous_spaces_) {
    if (space->IsMallocSpace()) {
      gc::space::MallocSpace* malloc_space = space->AsMallocSpace();
      malloc_space->ClearGrowthLimit();
      malloc_space->SetFootprintLimit(malloc_space->Capacity());
    }
  }
  // This space isn't added for performance reasons.
  if (main_space_backup_.get() != nullptr) {
    main_space_backup_->ClearGrowthLimit();
    main_space_backup_->SetFootprintLimit(main_space_backup_->Capacity());
  }
}

void Heap::AddFinalizerReference(Thread* self, ObjPtr<mirror::Object>* object) {
  ScopedObjectAccess soa(self);
  ScopedLocalRef<jobject> arg(self->GetJniEnv(), soa.AddLocalReference<jobject>(*object));
  jvalue args[1];
  args[0].l = arg.get();
  InvokeWithJValues(soa, nullptr, WellKnownClasses::java_lang_ref_FinalizerReference_add, args);
  // Restore object in case it gets moved.
  *object = soa.Decode<mirror::Object>(arg.get());
}

void Heap::RequestConcurrentGCAndSaveObject(Thread* self,
                                            bool force_full,
                                            ObjPtr<mirror::Object>* obj) {
  StackHandleScope<1> hs(self);
  HandleWrapperObjPtr<mirror::Object> wrapper(hs.NewHandleWrapper(obj));
  RequestConcurrentGC(self, force_full);
}

class Heap::ConcurrentGCTask : public HeapTask {
 public:
  ConcurrentGCTask(uint64_t target_time, bool force_full)
      : HeapTask(target_time), force_full_(force_full) { }
  virtual void Run(Thread* self) OVERRIDE {
    gc::Heap* heap = Runtime::Current()->GetHeap();
    heap->ConcurrentGC(self, force_full_);
    heap->ClearConcurrentGCRequest();
  }

 private:
  const bool force_full_;  // If true, force full (or partial) collection.
};

static bool CanAddHeapTask(Thread* self) REQUIRES(!Locks::runtime_shutdown_lock_) {
  Runtime* runtime = Runtime::Current();
  return runtime != nullptr && runtime->IsFinishedStarting() && !runtime->IsShuttingDown(self) &&
      !self->IsHandlingStackOverflow();
}

void Heap::ClearConcurrentGCRequest() {
  concurrent_gc_pending_.StoreRelaxed(false);
}

void Heap::RequestConcurrentGC(Thread* self, bool force_full) {
  if (CanAddHeapTask(self) &&
      concurrent_gc_pending_.CompareExchangeStrongSequentiallyConsistent(false, true)) {
    task_processor_->AddTask(self, new ConcurrentGCTask(NanoTime(),  // Start straight away.
                                                        force_full));
  }
}

void Heap::ConcurrentGC(Thread* self, bool force_full) {
  if (!Runtime::Current()->IsShuttingDown(self)) {
    // Wait for any GCs currently running to finish.
    if (WaitForGcToComplete(kGcCauseBackground, self) == collector::kGcTypeNone) {
      // If the we can't run the GC type we wanted to run, find the next appropriate one and try that
      // instead. E.g. can't do partial, so do full instead.
      collector::GcType next_gc_type = next_gc_type_;
      // If forcing full and next gc type is sticky, override with a non-sticky type.
      if (force_full && next_gc_type == collector::kGcTypeSticky) {
        next_gc_type = HasZygoteSpace() ? collector::kGcTypePartial : collector::kGcTypeFull;
      }
      if (CollectGarbageInternal(next_gc_type, kGcCauseBackground, false) ==
          collector::kGcTypeNone) {
        for (collector::GcType gc_type : gc_plan_) {
          // Attempt to run the collector, if we succeed, we are done.
          if (gc_type > next_gc_type &&
              CollectGarbageInternal(gc_type, kGcCauseBackground, false) !=
                  collector::kGcTypeNone) {
            break;
          }
        }
      }
    }
  }
}

class Heap::CollectorTransitionTask : public HeapTask {
 public:
  explicit CollectorTransitionTask(uint64_t target_time) : HeapTask(target_time) {}

  virtual void Run(Thread* self) OVERRIDE {
    gc::Heap* heap = Runtime::Current()->GetHeap();
    heap->DoPendingCollectorTransition();
    heap->ClearPendingCollectorTransition(self);
  }
};

void Heap::ClearPendingCollectorTransition(Thread* self) {
  MutexLock mu(self, *pending_task_lock_);
  pending_collector_transition_ = nullptr;
}

void Heap::RequestCollectorTransition(CollectorType desired_collector_type, uint64_t delta_time) {
  Thread* self = Thread::Current();
  desired_collector_type_ = desired_collector_type;
  if (desired_collector_type_ == collector_type_ || !CanAddHeapTask(self)) {
    return;
  }
  if (collector_type_ == kCollectorTypeCC) {
    // For CC, we invoke a full compaction when going to the background, but the collector type
    // doesn't change.
    DCHECK_EQ(desired_collector_type_, kCollectorTypeCCBackground);
  }
  DCHECK_NE(collector_type_, kCollectorTypeCCBackground);
  CollectorTransitionTask* added_task = nullptr;
  const uint64_t target_time = NanoTime() + delta_time;
  {
    MutexLock mu(self, *pending_task_lock_);
    // If we have an existing collector transition, update the targe time to be the new target.
    if (pending_collector_transition_ != nullptr) {
      task_processor_->UpdateTargetRunTime(self, pending_collector_transition_, target_time);
      return;
    }
    added_task = new CollectorTransitionTask(target_time);
    pending_collector_transition_ = added_task;
  }
  task_processor_->AddTask(self, added_task);
}

class Heap::HeapTrimTask : public HeapTask {
 public:
  explicit HeapTrimTask(uint64_t delta_time) : HeapTask(NanoTime() + delta_time) { }
  virtual void Run(Thread* self) OVERRIDE {
    gc::Heap* heap = Runtime::Current()->GetHeap();
    heap->Trim(self);
    heap->ClearPendingTrim(self);
  }
};

void Heap::ClearPendingTrim(Thread* self) {
  MutexLock mu(self, *pending_task_lock_);
  pending_heap_trim_ = nullptr;
}

void Heap::RequestTrim(Thread* self) {
  if (!CanAddHeapTask(self)) {
    return;
  }
  // GC completed and now we must decide whether to request a heap trim (advising pages back to the
  // kernel) or not. Issuing a request will also cause trimming of the libc heap. As a trim scans
  // a space it will hold its lock and can become a cause of jank.
  // Note, the large object space self trims and the Zygote space was trimmed and unchanging since
  // forking.

  // We don't have a good measure of how worthwhile a trim might be. We can't use the live bitmap
  // because that only marks object heads, so a large array looks like lots of empty space. We
  // don't just call dlmalloc all the time, because the cost of an _attempted_ trim is proportional
  // to utilization (which is probably inversely proportional to how much benefit we can expect).
  // We could try mincore(2) but that's only a measure of how many pages we haven't given away,
  // not how much use we're making of those pages.
  HeapTrimTask* added_task = nullptr;
  {
    MutexLock mu(self, *pending_task_lock_);
    if (pending_heap_trim_ != nullptr) {
      // Already have a heap trim request in task processor, ignore this request.
      return;
    }
    added_task = new HeapTrimTask(kHeapTrimWait);
    pending_heap_trim_ = added_task;
  }
  task_processor_->AddTask(self, added_task);
}

void Heap::RevokeThreadLocalBuffers(Thread* thread) {
  if (rosalloc_space_ != nullptr) {
    size_t freed_bytes_revoke = rosalloc_space_->RevokeThreadLocalBuffers(thread);
    if (freed_bytes_revoke > 0U) {
      num_bytes_freed_revoke_.FetchAndAddSequentiallyConsistent(freed_bytes_revoke);
      CHECK_GE(num_bytes_allocated_.LoadRelaxed(), num_bytes_freed_revoke_.LoadRelaxed());
    }
  }
  if (bump_pointer_space_ != nullptr) {
    CHECK_EQ(bump_pointer_space_->RevokeThreadLocalBuffers(thread), 0U);
  }
  if (region_space_ != nullptr) {
    CHECK_EQ(region_space_->RevokeThreadLocalBuffers(thread), 0U);
  }
}

void Heap::RevokeRosAllocThreadLocalBuffers(Thread* thread) {
  if (rosalloc_space_ != nullptr) {
    size_t freed_bytes_revoke = rosalloc_space_->RevokeThreadLocalBuffers(thread);
    if (freed_bytes_revoke > 0U) {
      num_bytes_freed_revoke_.FetchAndAddSequentiallyConsistent(freed_bytes_revoke);
      CHECK_GE(num_bytes_allocated_.LoadRelaxed(), num_bytes_freed_revoke_.LoadRelaxed());
    }
  }
}

void Heap::RevokeAllThreadLocalBuffers() {
  if (rosalloc_space_ != nullptr) {
    size_t freed_bytes_revoke = rosalloc_space_->RevokeAllThreadLocalBuffers();
    if (freed_bytes_revoke > 0U) {
      num_bytes_freed_revoke_.FetchAndAddSequentiallyConsistent(freed_bytes_revoke);
      CHECK_GE(num_bytes_allocated_.LoadRelaxed(), num_bytes_freed_revoke_.LoadRelaxed());
    }
  }
  if (bump_pointer_space_ != nullptr) {
    CHECK_EQ(bump_pointer_space_->RevokeAllThreadLocalBuffers(), 0U);
  }
  if (region_space_ != nullptr) {
    CHECK_EQ(region_space_->RevokeAllThreadLocalBuffers(), 0U);
  }
}

bool Heap::IsGCRequestPending() const {
  return concurrent_gc_pending_.LoadRelaxed();
}

void Heap::RunFinalization(JNIEnv* env, uint64_t timeout) {
  env->CallStaticVoidMethod(WellKnownClasses::dalvik_system_VMRuntime,
                            WellKnownClasses::dalvik_system_VMRuntime_runFinalization,
                            static_cast<jlong>(timeout));
}

void Heap::RegisterNativeAllocation(JNIEnv* env, size_t bytes) {
  Thread* self = ThreadForEnv(env);
  {
    MutexLock mu(self, native_histogram_lock_);
    native_allocation_histogram_.AddValue(bytes);
  }
  if (native_need_to_run_finalization_) {
    RunFinalization(env, kNativeAllocationFinalizeTimeout);
    UpdateMaxNativeFootprint();
    native_need_to_run_finalization_ = false;
  }
  // Total number of native bytes allocated.
  size_t new_native_bytes_allocated = native_bytes_allocated_.FetchAndAddSequentiallyConsistent(bytes);
  new_native_bytes_allocated += bytes;
  if (new_native_bytes_allocated > native_footprint_gc_watermark_) {
    collector::GcType gc_type = HasZygoteSpace() ? collector::kGcTypePartial :
        collector::kGcTypeFull;

    // The second watermark is higher than the gc watermark. If you hit this it means you are
    // allocating native objects faster than the GC can keep up with.
    if (new_native_bytes_allocated > growth_limit_) {
      if (WaitForGcToComplete(kGcCauseForNativeAlloc, self) != collector::kGcTypeNone) {
        // Just finished a GC, attempt to run finalizers.
        RunFinalization(env, kNativeAllocationFinalizeTimeout);
        CHECK(!env->ExceptionCheck());
        // Native bytes allocated may be updated by finalization, refresh it.
        new_native_bytes_allocated = native_bytes_allocated_.LoadRelaxed();
      }
      // If we still are over the watermark, attempt a GC for alloc and run finalizers.
      if (new_native_bytes_allocated > growth_limit_) {
        CollectGarbageInternal(gc_type, kGcCauseForNativeAlloc, false);
        RunFinalization(env, kNativeAllocationFinalizeTimeout);
        native_need_to_run_finalization_ = false;
        CHECK(!env->ExceptionCheck());
      }
      // We have just run finalizers, update the native watermark since it is very likely that
      // finalizers released native managed allocations.
      UpdateMaxNativeFootprint();
    } else if (!IsGCRequestPending()) {
      if (IsGcConcurrent()) {
        RequestConcurrentGC(self, true);  // Request non-sticky type.
      } else {
        CollectGarbageInternal(gc_type, kGcCauseForNativeAlloc, false);
      }
    }
  }
}

void Heap::RegisterNativeFree(JNIEnv* env, size_t bytes) {
  size_t expected_size;
  {
    MutexLock mu(Thread::Current(), native_histogram_lock_);
    native_free_histogram_.AddValue(bytes);
  }
  do {
    expected_size = native_bytes_allocated_.LoadRelaxed();
    if (UNLIKELY(bytes > expected_size)) {
      ScopedObjectAccess soa(env);
      env->ThrowNew(WellKnownClasses::java_lang_RuntimeException,
                    StringPrintf("Attempted to free %zd native bytes with only %zd native bytes "
                    "registered as allocated", bytes, expected_size).c_str());
      break;
    }
  } while (!native_bytes_allocated_.CompareExchangeWeakRelaxed(expected_size,
                                                               expected_size - bytes));
}

size_t Heap::GetTotalMemory() const {
  return std::max(max_allowed_footprint_, GetBytesAllocated());
}

void Heap::AddModUnionTable(accounting::ModUnionTable* mod_union_table) {
  DCHECK(mod_union_table != nullptr);
  mod_union_tables_.Put(mod_union_table->GetSpace(), mod_union_table);
}

void Heap::CheckPreconditionsForAllocObject(ObjPtr<mirror::Class> c, size_t byte_count) {
  CHECK(c == nullptr || (c->IsClassClass() && byte_count >= sizeof(mirror::Class)) ||
        (c->IsVariableSize() || c->GetObjectSize() == byte_count)) << c->GetClassFlags();
  CHECK_GE(byte_count, sizeof(mirror::Object));
}

void Heap::AddRememberedSet(accounting::RememberedSet* remembered_set) {
  CHECK(remembered_set != nullptr);
  space::Space* space = remembered_set->GetSpace();
  CHECK(space != nullptr);
  CHECK(remembered_sets_.find(space) == remembered_sets_.end()) << space;
  remembered_sets_.Put(space, remembered_set);
  CHECK(remembered_sets_.find(space) != remembered_sets_.end()) << space;
}

void Heap::RemoveRememberedSet(space::Space* space) {
  CHECK(space != nullptr);
  auto it = remembered_sets_.find(space);
  CHECK(it != remembered_sets_.end());
  delete it->second;
  remembered_sets_.erase(it);
  CHECK(remembered_sets_.find(space) == remembered_sets_.end());
}

void Heap::ClearMarkedObjects() {
  // Clear all of the spaces' mark bitmaps.
  for (const auto& space : GetContinuousSpaces()) {
    accounting::ContinuousSpaceBitmap* mark_bitmap = space->GetMarkBitmap();
    if (space->GetLiveBitmap() != mark_bitmap) {
      mark_bitmap->Clear();
    }
  }
  // Clear the marked objects in the discontinous space object sets.
  for (const auto& space : GetDiscontinuousSpaces()) {
    space->GetMarkBitmap()->Clear();
  }
}

void Heap::SetAllocationRecords(AllocRecordObjectMap* records) {
  allocation_records_.reset(records);
}

void Heap::VisitAllocationRecords(RootVisitor* visitor) const {
  if (IsAllocTrackingEnabled()) {
    MutexLock mu(Thread::Current(), *Locks::alloc_tracker_lock_);
    if (IsAllocTrackingEnabled()) {
      GetAllocationRecords()->VisitRoots(visitor);
    }
  }
}

void Heap::SweepAllocationRecords(IsMarkedVisitor* visitor) const {
  if (IsAllocTrackingEnabled()) {
    MutexLock mu(Thread::Current(), *Locks::alloc_tracker_lock_);
    if (IsAllocTrackingEnabled()) {
      GetAllocationRecords()->SweepAllocationRecords(visitor);
    }
  }
}

void Heap::AllowNewAllocationRecords() const {
  CHECK(!kUseReadBarrier);
  MutexLock mu(Thread::Current(), *Locks::alloc_tracker_lock_);
  AllocRecordObjectMap* allocation_records = GetAllocationRecords();
  if (allocation_records != nullptr) {
    allocation_records->AllowNewAllocationRecords();
  }
}

void Heap::DisallowNewAllocationRecords() const {
  CHECK(!kUseReadBarrier);
  MutexLock mu(Thread::Current(), *Locks::alloc_tracker_lock_);
  AllocRecordObjectMap* allocation_records = GetAllocationRecords();
  if (allocation_records != nullptr) {
    allocation_records->DisallowNewAllocationRecords();
  }
}

void Heap::BroadcastForNewAllocationRecords() const {
  // Always broadcast without checking IsAllocTrackingEnabled() because IsAllocTrackingEnabled() may
  // be set to false while some threads are waiting for system weak access in
  // AllocRecordObjectMap::RecordAllocation() and we may fail to wake them up. b/27467554.
  MutexLock mu(Thread::Current(), *Locks::alloc_tracker_lock_);
  AllocRecordObjectMap* allocation_records = GetAllocationRecords();
  if (allocation_records != nullptr) {
    allocation_records->BroadcastForNewAllocationRecords();
  }
}

// Based on debug malloc logic from libc/bionic/debug_stacktrace.cpp.
class StackCrawlState {
 public:
  StackCrawlState(uintptr_t* frames, size_t max_depth, size_t skip_count)
      : frames_(frames), frame_count_(0), max_depth_(max_depth), skip_count_(skip_count) {
  }
  size_t GetFrameCount() const {
    return frame_count_;
  }
  static _Unwind_Reason_Code Callback(_Unwind_Context* context, void* arg) {
    auto* const state = reinterpret_cast<StackCrawlState*>(arg);
    const uintptr_t ip = _Unwind_GetIP(context);
    // The first stack frame is get_backtrace itself. Skip it.
    if (ip != 0 && state->skip_count_ > 0) {
      --state->skip_count_;
      return _URC_NO_REASON;
    }
    // ip may be off for ARM but it shouldn't matter since we only use it for hashing.
    state->frames_[state->frame_count_] = ip;
    state->frame_count_++;
    return state->frame_count_ >= state->max_depth_ ? _URC_END_OF_STACK : _URC_NO_REASON;
  }

 private:
  uintptr_t* const frames_;
  size_t frame_count_;
  const size_t max_depth_;
  size_t skip_count_;
};

static size_t get_backtrace(uintptr_t* frames, size_t max_depth) {
  StackCrawlState state(frames, max_depth, 0u);
  _Unwind_Backtrace(&StackCrawlState::Callback, &state);
  return state.GetFrameCount();
}

void Heap::CheckGcStressMode(Thread* self, ObjPtr<mirror::Object>* obj) {
  auto* const runtime = Runtime::Current();
  if (gc_stress_mode_ && runtime->GetClassLinker()->IsInitialized() &&
      !runtime->IsActiveTransaction() && mirror::Class::HasJavaLangClass()) {
    // Check if we should GC.
    bool new_backtrace = false;
    {
      static constexpr size_t kMaxFrames = 16u;
      uintptr_t backtrace[kMaxFrames];
      const size_t frames = get_backtrace(backtrace, kMaxFrames);
      uint64_t hash = 0;
      for (size_t i = 0; i < frames; ++i) {
        hash = hash * 2654435761 + backtrace[i];
        hash += (hash >> 13) ^ (hash << 6);
      }
      MutexLock mu(self, *backtrace_lock_);
      new_backtrace = seen_backtraces_.find(hash) == seen_backtraces_.end();
      if (new_backtrace) {
        seen_backtraces_.insert(hash);
      }
    }
    if (new_backtrace) {
      StackHandleScope<1> hs(self);
      auto h = hs.NewHandleWrapper(obj);
      CollectGarbage(false);
      unique_backtrace_count_.FetchAndAddSequentiallyConsistent(1);
    } else {
      seen_backtrace_count_.FetchAndAddSequentiallyConsistent(1);
    }
  }
}

void Heap::DisableGCForShutdown() {
  Thread* const self = Thread::Current();
  CHECK(Runtime::Current()->IsShuttingDown(self));
  MutexLock mu(self, *gc_complete_lock_);
  gc_disabled_for_shutdown_ = true;
}

bool Heap::ObjectIsInBootImageSpace(ObjPtr<mirror::Object> obj) const {
  for (gc::space::ImageSpace* space : boot_image_spaces_) {
    if (space->HasAddress(obj.Ptr())) {
      return true;
    }
  }
  return false;
}

bool Heap::IsInBootImageOatFile(const void* p) const {
  for (gc::space::ImageSpace* space : boot_image_spaces_) {
    if (space->GetOatFile()->Contains(p)) {
      return true;
    }
  }
  return false;
}

void Heap::GetBootImagesSize(uint32_t* boot_image_begin,
                             uint32_t* boot_image_end,
                             uint32_t* boot_oat_begin,
                             uint32_t* boot_oat_end) {
  DCHECK(boot_image_begin != nullptr);
  DCHECK(boot_image_end != nullptr);
  DCHECK(boot_oat_begin != nullptr);
  DCHECK(boot_oat_end != nullptr);
  *boot_image_begin = 0u;
  *boot_image_end = 0u;
  *boot_oat_begin = 0u;
  *boot_oat_end = 0u;
  for (gc::space::ImageSpace* space_ : GetBootImageSpaces()) {
    const uint32_t image_begin = PointerToLowMemUInt32(space_->Begin());
    const uint32_t image_size = space_->GetImageHeader().GetImageSize();
    if (*boot_image_begin == 0 || image_begin < *boot_image_begin) {
      *boot_image_begin = image_begin;
    }
    *boot_image_end = std::max(*boot_image_end, image_begin + image_size);
    const OatFile* boot_oat_file = space_->GetOatFile();
    const uint32_t oat_begin = PointerToLowMemUInt32(boot_oat_file->Begin());
    const uint32_t oat_size = boot_oat_file->Size();
    if (*boot_oat_begin == 0 || oat_begin < *boot_oat_begin) {
      *boot_oat_begin = oat_begin;
    }
    *boot_oat_end = std::max(*boot_oat_end, oat_begin + oat_size);
  }
}

void Heap::SetAllocationListener(AllocationListener* l) {
  AllocationListener* old = GetAndOverwriteAllocationListener(&alloc_listener_, l);

  if (old == nullptr) {
    Runtime::Current()->GetInstrumentation()->InstrumentQuickAllocEntryPoints();
  }
}

void Heap::RemoveAllocationListener() {
  AllocationListener* old = GetAndOverwriteAllocationListener(&alloc_listener_, nullptr);

  if (old != nullptr) {
    Runtime::Current()->GetInstrumentation()->UninstrumentQuickAllocEntryPoints();
  }
}

void Heap::SetGcPauseListener(GcPauseListener* l) {
  gc_pause_listener_.StoreRelaxed(l);
}

void Heap::RemoveGcPauseListener() {
  gc_pause_listener_.StoreRelaxed(nullptr);
}

mirror::Object* Heap::AllocWithNewTLAB(Thread* self,
                                       size_t alloc_size,
                                       bool grow,
                                       size_t* bytes_allocated,
                                       size_t* usable_size,
                                       size_t* bytes_tl_bulk_allocated) {
  const AllocatorType allocator_type = GetCurrentAllocator();
  if (allocator_type == kAllocatorTypeTLAB) {
    DCHECK(bump_pointer_space_ != nullptr);
    const size_t new_tlab_size = alloc_size + kDefaultTLABSize;
    if (UNLIKELY(IsOutOfMemoryOnAllocation(allocator_type, new_tlab_size, grow))) {
      return nullptr;
    }
    // Try allocating a new thread local buffer, if the allocation fails the space must be
    // full so return null.
    if (!bump_pointer_space_->AllocNewTlab(self, new_tlab_size)) {
      return nullptr;
    }
    *bytes_tl_bulk_allocated = new_tlab_size;
  } else {
    DCHECK(allocator_type == kAllocatorTypeRegionTLAB);
    DCHECK(region_space_ != nullptr);
    if (space::RegionSpace::kRegionSize >= alloc_size) {
      // Non-large. Check OOME for a tlab.
      if (LIKELY(!IsOutOfMemoryOnAllocation(allocator_type,
                                            space::RegionSpace::kRegionSize,
                                            grow))) {
        // Try to allocate a tlab.
        if (!region_space_->AllocNewTlab(self)) {
          // Failed to allocate a tlab. Try non-tlab.
          return region_space_->AllocNonvirtual<false>(alloc_size,
                                                       bytes_allocated,
                                                       usable_size,
                                                       bytes_tl_bulk_allocated);
        }
        *bytes_tl_bulk_allocated = space::RegionSpace::kRegionSize;
        // Fall-through to using the TLAB below.
      } else {
        // Check OOME for a non-tlab allocation.
        if (!IsOutOfMemoryOnAllocation(allocator_type, alloc_size, grow)) {
          return region_space_->AllocNonvirtual<false>(alloc_size,
                                                       bytes_allocated,
                                                       usable_size,
                                                       bytes_tl_bulk_allocated);
        }
        // Neither tlab or non-tlab works. Give up.
        return nullptr;
      }
    } else {
      // Large. Check OOME.
      if (LIKELY(!IsOutOfMemoryOnAllocation(allocator_type, alloc_size, grow))) {
        return region_space_->AllocNonvirtual<false>(alloc_size,
                                                     bytes_allocated,
                                                     usable_size,
                                                     bytes_tl_bulk_allocated);
      }
      return nullptr;
    }
  }
  // Refilled TLAB, return.
  mirror::Object* ret = self->AllocTlab(alloc_size);
  DCHECK(ret != nullptr);
  *bytes_allocated = alloc_size;
  *usable_size = alloc_size;
  return ret;
}

}  // namespace gc
}  // namespace art