mirror of
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584 lines
21 KiB
C++
584 lines
21 KiB
C++
// Copyright (c) 2013 The Chromium Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style license that can be
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// found in the LICENSE file.
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#include "net/disk_cache/simple/simple_index.h"
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#include <algorithm>
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#include <limits>
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#include <string>
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#include <utility>
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#include "base/bind.h"
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#include "base/bind_helpers.h"
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#include "base/files/file_enumerator.h"
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#include "base/files/file_util.h"
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#include "base/logging.h"
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#include "base/metrics/field_trial.h"
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#include "base/numerics/safe_conversions.h"
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#include "base/pickle.h"
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#include "base/strings/string_number_conversions.h"
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#include "base/strings/string_tokenizer.h"
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#include "base/task_runner.h"
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#include "base/time/time.h"
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#include "base/trace_event/memory_usage_estimator.h"
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#include "net/base/net_errors.h"
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#include "net/disk_cache/backend_cleanup_tracker.h"
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#include "net/disk_cache/simple/simple_entry_format.h"
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#include "net/disk_cache/simple/simple_experiment.h"
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#include "net/disk_cache/simple/simple_histogram_macros.h"
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#include "net/disk_cache/simple/simple_index_delegate.h"
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#include "net/disk_cache/simple/simple_index_file.h"
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#include "net/disk_cache/simple/simple_synchronous_entry.h"
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#include "net/disk_cache/simple/simple_util.h"
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#if defined(OS_POSIX)
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#include <sys/stat.h>
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#include <sys/time.h>
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#endif
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namespace {
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// How many milliseconds we delay writing the index to disk since the last cache
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// operation has happened.
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const int kWriteToDiskDelayMSecs = 20000;
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const int kWriteToDiskOnBackgroundDelayMSecs = 100;
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// Divides the cache space into this amount of parts to evict when only one part
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// is left.
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const uint32_t kEvictionMarginDivisor = 20;
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const uint32_t kBytesInKb = 1024;
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// This is added to the size of each entry before using the size
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// to determine which entries to evict first. It's basically an
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// estimate of the filesystem overhead, but it also serves to flatten
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// the curve so that 1-byte entries and 2-byte entries are basically
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// treated the same.
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static const int kEstimatedEntryOverhead = 512;
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} // namespace
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namespace disk_cache {
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const base::Feature kSimpleCacheEvictionWithSize = {
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"SimpleCacheEvictionWithSize", base::FEATURE_ENABLED_BY_DEFAULT};
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EntryMetadata::EntryMetadata()
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: last_used_time_seconds_since_epoch_(0),
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entry_size_256b_chunks_(0),
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in_memory_data_(0) {}
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EntryMetadata::EntryMetadata(base::Time last_used_time,
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base::StrictNumeric<uint32_t> entry_size)
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: last_used_time_seconds_since_epoch_(0),
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entry_size_256b_chunks_(0),
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in_memory_data_(0) {
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SetEntrySize(entry_size); // to round/pack properly.
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SetLastUsedTime(last_used_time);
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}
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base::Time EntryMetadata::GetLastUsedTime() const {
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// Preserve nullity.
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if (last_used_time_seconds_since_epoch_ == 0)
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return base::Time();
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return base::Time::UnixEpoch() +
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base::TimeDelta::FromSeconds(last_used_time_seconds_since_epoch_);
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}
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void EntryMetadata::SetLastUsedTime(const base::Time& last_used_time) {
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// Preserve nullity.
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if (last_used_time.is_null()) {
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last_used_time_seconds_since_epoch_ = 0;
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return;
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}
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last_used_time_seconds_since_epoch_ = base::saturated_cast<uint32_t>(
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(last_used_time - base::Time::UnixEpoch()).InSeconds());
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// Avoid accidental nullity.
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if (last_used_time_seconds_since_epoch_ == 0)
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last_used_time_seconds_since_epoch_ = 1;
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}
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uint32_t EntryMetadata::GetEntrySize() const {
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return entry_size_256b_chunks_ << 8;
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}
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void EntryMetadata::SetEntrySize(base::StrictNumeric<uint32_t> entry_size) {
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// This should not overflow since we limit entries to 1/8th of the cache.
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entry_size_256b_chunks_ = (static_cast<uint32_t>(entry_size) + 255) >> 8;
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}
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void EntryMetadata::Serialize(base::Pickle* pickle) const {
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DCHECK(pickle);
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int64_t internal_last_used_time = GetLastUsedTime().ToInternalValue();
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// If you modify the size of the size of the pickle, be sure to update
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// kOnDiskSizeBytes.
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uint32_t packed_entry_info = (entry_size_256b_chunks_ << 8) | in_memory_data_;
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pickle->WriteInt64(internal_last_used_time);
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pickle->WriteUInt64(packed_entry_info);
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}
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bool EntryMetadata::Deserialize(base::PickleIterator* it,
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bool has_entry_in_memory_data) {
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DCHECK(it);
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int64_t tmp_last_used_time;
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uint64_t tmp_entry_size;
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if (!it->ReadInt64(&tmp_last_used_time) || !it->ReadUInt64(&tmp_entry_size) ||
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tmp_entry_size > std::numeric_limits<uint32_t>::max())
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return false;
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SetLastUsedTime(base::Time::FromInternalValue(tmp_last_used_time));
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if (has_entry_in_memory_data) {
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// tmp_entry_size actually packs entry_size_256b_chunks_ and
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// in_memory_data_.
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SetEntrySize(static_cast<uint32_t>(tmp_entry_size & 0xFFFFFF00));
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SetInMemoryData(static_cast<uint8_t>(tmp_entry_size & 0xFF));
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} else {
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SetEntrySize(static_cast<uint32_t>(tmp_entry_size));
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SetInMemoryData(0);
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}
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return true;
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}
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SimpleIndex::SimpleIndex(
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const scoped_refptr<base::SingleThreadTaskRunner>& io_thread,
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scoped_refptr<BackendCleanupTracker> cleanup_tracker,
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SimpleIndexDelegate* delegate,
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net::CacheType cache_type,
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std::unique_ptr<SimpleIndexFile> index_file)
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: cleanup_tracker_(std::move(cleanup_tracker)),
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delegate_(delegate),
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cache_type_(cache_type),
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cache_size_(0),
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max_size_(0),
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high_watermark_(0),
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low_watermark_(0),
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eviction_in_progress_(false),
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initialized_(false),
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init_method_(INITIALIZE_METHOD_MAX),
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index_file_(std::move(index_file)),
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io_thread_(io_thread),
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// Creating the callback once so it is reused every time
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// write_to_disk_timer_.Start() is called.
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write_to_disk_cb_(base::Bind(&SimpleIndex::WriteToDisk,
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AsWeakPtr(),
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INDEX_WRITE_REASON_IDLE)),
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app_on_background_(false) {}
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SimpleIndex::~SimpleIndex() {
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DCHECK(io_thread_checker_.CalledOnValidThread());
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// Fail all callbacks waiting for the index to come up.
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for (CallbackList::iterator it = to_run_when_initialized_.begin(),
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end = to_run_when_initialized_.end(); it != end; ++it) {
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it->Run(net::ERR_ABORTED);
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}
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}
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void SimpleIndex::Initialize(base::Time cache_mtime) {
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DCHECK(io_thread_checker_.CalledOnValidThread());
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#if defined(OS_ANDROID)
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if (base::android::IsVMInitialized()) {
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app_status_listener_.reset(new base::android::ApplicationStatusListener(
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base::Bind(&SimpleIndex::OnApplicationStateChange, AsWeakPtr())));
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}
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#endif
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SimpleIndexLoadResult* load_result = new SimpleIndexLoadResult();
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std::unique_ptr<SimpleIndexLoadResult> load_result_scoped(load_result);
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base::Closure reply = base::Bind(
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&SimpleIndex::MergeInitializingSet,
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AsWeakPtr(),
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base::Passed(&load_result_scoped));
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index_file_->LoadIndexEntries(cache_mtime, reply, load_result);
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}
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void SimpleIndex::SetMaxSize(uint64_t max_bytes) {
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// Zero size means use the default.
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if (max_bytes) {
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max_size_ = max_bytes;
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high_watermark_ = max_size_ - max_size_ / kEvictionMarginDivisor;
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low_watermark_ = max_size_ - 2 * (max_size_ / kEvictionMarginDivisor);
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}
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}
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int SimpleIndex::ExecuteWhenReady(const net::CompletionCallback& task) {
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DCHECK(io_thread_checker_.CalledOnValidThread());
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if (initialized_)
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io_thread_->PostTask(FROM_HERE, base::Bind(task, net::OK));
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else
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to_run_when_initialized_.push_back(task);
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return net::ERR_IO_PENDING;
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}
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std::unique_ptr<SimpleIndex::HashList> SimpleIndex::GetEntriesBetween(
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base::Time initial_time,
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base::Time end_time) {
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DCHECK_EQ(true, initialized_);
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if (!initial_time.is_null())
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initial_time -= EntryMetadata::GetLowerEpsilonForTimeComparisons();
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if (end_time.is_null())
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end_time = base::Time::Max();
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else
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end_time += EntryMetadata::GetUpperEpsilonForTimeComparisons();
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DCHECK(end_time >= initial_time);
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std::unique_ptr<HashList> ret_hashes(new HashList());
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for (const auto& entry : entries_set_) {
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const EntryMetadata& metadata = entry.second;
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base::Time entry_time = metadata.GetLastUsedTime();
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if (initial_time <= entry_time && entry_time < end_time)
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ret_hashes->push_back(entry.first);
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}
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return ret_hashes;
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}
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std::unique_ptr<SimpleIndex::HashList> SimpleIndex::GetAllHashes() {
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return GetEntriesBetween(base::Time(), base::Time());
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}
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int32_t SimpleIndex::GetEntryCount() const {
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// TODO(pasko): return a meaningful initial estimate before initialized.
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return entries_set_.size();
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}
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uint64_t SimpleIndex::GetCacheSize() const {
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DCHECK(initialized_);
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return cache_size_;
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}
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uint64_t SimpleIndex::GetCacheSizeBetween(base::Time initial_time,
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base::Time end_time) const {
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DCHECK_EQ(true, initialized_);
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if (!initial_time.is_null())
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initial_time -= EntryMetadata::GetLowerEpsilonForTimeComparisons();
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if (end_time.is_null())
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end_time = base::Time::Max();
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else
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end_time += EntryMetadata::GetUpperEpsilonForTimeComparisons();
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DCHECK(end_time >= initial_time);
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uint64_t size = 0;
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for (const auto& entry : entries_set_) {
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const EntryMetadata& metadata = entry.second;
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base::Time entry_time = metadata.GetLastUsedTime();
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if (initial_time <= entry_time && entry_time < end_time)
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size += metadata.GetEntrySize();
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}
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return size;
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}
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size_t SimpleIndex::EstimateMemoryUsage() const {
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return base::trace_event::EstimateMemoryUsage(entries_set_) +
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base::trace_event::EstimateMemoryUsage(removed_entries_);
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}
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void SimpleIndex::SetLastUsedTimeForTest(uint64_t entry_hash,
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const base::Time last_used) {
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EntrySet::iterator it = entries_set_.find(entry_hash);
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DCHECK(it != entries_set_.end());
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it->second.SetLastUsedTime(last_used);
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}
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void SimpleIndex::Insert(uint64_t entry_hash) {
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DCHECK(io_thread_checker_.CalledOnValidThread());
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// Upon insert we don't know yet the size of the entry.
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// It will be updated later when the SimpleEntryImpl finishes opening or
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// creating the new entry, and then UpdateEntrySize will be called.
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InsertInEntrySet(entry_hash, EntryMetadata(base::Time::Now(), 0u),
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&entries_set_);
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if (!initialized_)
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removed_entries_.erase(entry_hash);
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PostponeWritingToDisk();
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}
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void SimpleIndex::Remove(uint64_t entry_hash) {
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DCHECK(io_thread_checker_.CalledOnValidThread());
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EntrySet::iterator it = entries_set_.find(entry_hash);
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if (it != entries_set_.end()) {
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UpdateEntryIteratorSize(&it, 0u);
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entries_set_.erase(it);
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}
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if (!initialized_)
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removed_entries_.insert(entry_hash);
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PostponeWritingToDisk();
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}
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bool SimpleIndex::Has(uint64_t hash) const {
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DCHECK(io_thread_checker_.CalledOnValidThread());
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// If not initialized, always return true, forcing it to go to the disk.
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return !initialized_ || entries_set_.count(hash) > 0;
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}
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uint8_t SimpleIndex::GetEntryInMemoryData(uint64_t entry_hash) const {
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DCHECK(io_thread_checker_.CalledOnValidThread());
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EntrySet::const_iterator it = entries_set_.find(entry_hash);
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if (it == entries_set_.end())
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return 0;
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return it->second.GetInMemoryData();
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}
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void SimpleIndex::SetEntryInMemoryData(uint64_t entry_hash, uint8_t value) {
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DCHECK(io_thread_checker_.CalledOnValidThread());
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EntrySet::iterator it = entries_set_.find(entry_hash);
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if (it == entries_set_.end())
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return;
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return it->second.SetInMemoryData(value);
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}
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bool SimpleIndex::UseIfExists(uint64_t entry_hash) {
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DCHECK(io_thread_checker_.CalledOnValidThread());
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// Always update the last used time, even if it is during initialization.
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// It will be merged later.
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EntrySet::iterator it = entries_set_.find(entry_hash);
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if (it == entries_set_.end())
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// If not initialized, always return true, forcing it to go to the disk.
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return !initialized_;
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it->second.SetLastUsedTime(base::Time::Now());
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PostponeWritingToDisk();
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return true;
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}
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void SimpleIndex::StartEvictionIfNeeded() {
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DCHECK(io_thread_checker_.CalledOnValidThread());
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if (eviction_in_progress_ || cache_size_ <= high_watermark_)
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return;
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// Take all live key hashes from the index and sort them by time.
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eviction_in_progress_ = true;
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eviction_start_time_ = base::TimeTicks::Now();
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SIMPLE_CACHE_UMA(
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MEMORY_KB, "Eviction.CacheSizeOnStart2", cache_type_,
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static_cast<base::HistogramBase::Sample>(cache_size_ / kBytesInKb));
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SIMPLE_CACHE_UMA(
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MEMORY_KB, "Eviction.MaxCacheSizeOnStart2", cache_type_,
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static_cast<base::HistogramBase::Sample>(max_size_ / kBytesInKb));
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// Flatten for sorting.
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std::vector<std::pair<uint64_t, const EntrySet::value_type*>> entries;
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entries.reserve(entries_set_.size());
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uint32_t now = (base::Time::Now() - base::Time::UnixEpoch()).InSeconds();
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bool use_size = base::FeatureList::IsEnabled(kSimpleCacheEvictionWithSize);
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for (EntrySet::const_iterator i = entries_set_.begin();
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i != entries_set_.end(); ++i) {
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uint64_t sort_value = now - i->second.RawTimeForSorting();
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if (use_size) {
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// Will not overflow since we're multiplying two 32-bit values and storing
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// them in a 64-bit variable.
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sort_value *= i->second.GetEntrySize() + kEstimatedEntryOverhead;
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}
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// Subtract so we don't need a custom comparator.
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entries.emplace_back(std::numeric_limits<uint64_t>::max() - sort_value,
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&*i);
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}
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uint64_t evicted_so_far_size = 0;
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const uint64_t amount_to_evict = cache_size_ - low_watermark_;
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std::vector<uint64_t> entry_hashes;
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std::sort(entries.begin(), entries.end());
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for (const auto& score_metadata_pair : entries) {
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if (evicted_so_far_size >= amount_to_evict)
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break;
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evicted_so_far_size += score_metadata_pair.second->second.GetEntrySize();
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entry_hashes.push_back(score_metadata_pair.second->first);
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}
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SIMPLE_CACHE_UMA(COUNTS_1M,
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"Eviction.EntryCount", cache_type_, entry_hashes.size());
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SIMPLE_CACHE_UMA(TIMES,
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"Eviction.TimeToSelectEntries", cache_type_,
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base::TimeTicks::Now() - eviction_start_time_);
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SIMPLE_CACHE_UMA(
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MEMORY_KB, "Eviction.SizeOfEvicted2", cache_type_,
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static_cast<base::HistogramBase::Sample>(
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evicted_so_far_size / kBytesInKb));
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delegate_->DoomEntries(&entry_hashes, base::Bind(&SimpleIndex::EvictionDone,
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AsWeakPtr()));
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}
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bool SimpleIndex::UpdateEntrySize(uint64_t entry_hash,
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base::StrictNumeric<uint32_t> entry_size) {
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DCHECK(io_thread_checker_.CalledOnValidThread());
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EntrySet::iterator it = entries_set_.find(entry_hash);
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if (it == entries_set_.end())
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return false;
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UpdateEntryIteratorSize(&it, entry_size);
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PostponeWritingToDisk();
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StartEvictionIfNeeded();
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return true;
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}
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void SimpleIndex::EvictionDone(int result) {
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DCHECK(io_thread_checker_.CalledOnValidThread());
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// Ignore the result of eviction. We did our best.
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eviction_in_progress_ = false;
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SIMPLE_CACHE_UMA(BOOLEAN, "Eviction.Result", cache_type_, result == net::OK);
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SIMPLE_CACHE_UMA(TIMES,
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"Eviction.TimeToDone", cache_type_,
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base::TimeTicks::Now() - eviction_start_time_);
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SIMPLE_CACHE_UMA(
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MEMORY_KB, "Eviction.SizeWhenDone2", cache_type_,
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static_cast<base::HistogramBase::Sample>(cache_size_ / kBytesInKb));
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}
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// static
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void SimpleIndex::InsertInEntrySet(
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uint64_t entry_hash,
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const disk_cache::EntryMetadata& entry_metadata,
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EntrySet* entry_set) {
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DCHECK(entry_set);
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entry_set->insert(std::make_pair(entry_hash, entry_metadata));
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}
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void SimpleIndex::InsertEntryForTesting(uint64_t entry_hash,
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const EntryMetadata& entry_metadata) {
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DCHECK(entries_set_.find(entry_hash) == entries_set_.end());
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InsertInEntrySet(entry_hash, entry_metadata, &entries_set_);
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cache_size_ += entry_metadata.GetEntrySize();
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}
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void SimpleIndex::PostponeWritingToDisk() {
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if (!initialized_)
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return;
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const int delay = app_on_background_ ? kWriteToDiskOnBackgroundDelayMSecs
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: kWriteToDiskDelayMSecs;
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// If the timer is already active, Start() will just Reset it, postponing it.
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write_to_disk_timer_.Start(
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FROM_HERE, base::TimeDelta::FromMilliseconds(delay), write_to_disk_cb_);
|
|
}
|
|
|
|
void SimpleIndex::UpdateEntryIteratorSize(
|
|
EntrySet::iterator* it,
|
|
base::StrictNumeric<uint32_t> entry_size) {
|
|
// Update the total cache size with the new entry size.
|
|
DCHECK(io_thread_checker_.CalledOnValidThread());
|
|
DCHECK_GE(cache_size_, (*it)->second.GetEntrySize());
|
|
cache_size_ -= (*it)->second.GetEntrySize();
|
|
(*it)->second.SetEntrySize(entry_size);
|
|
// We use GetEntrySize to get consistent rounding.
|
|
cache_size_ += (*it)->second.GetEntrySize();
|
|
}
|
|
|
|
void SimpleIndex::MergeInitializingSet(
|
|
std::unique_ptr<SimpleIndexLoadResult> load_result) {
|
|
DCHECK(io_thread_checker_.CalledOnValidThread());
|
|
|
|
EntrySet* index_file_entries = &load_result->entries;
|
|
|
|
for (std::unordered_set<uint64_t>::const_iterator it =
|
|
removed_entries_.begin();
|
|
it != removed_entries_.end(); ++it) {
|
|
index_file_entries->erase(*it);
|
|
}
|
|
removed_entries_.clear();
|
|
|
|
for (EntrySet::const_iterator it = entries_set_.begin();
|
|
it != entries_set_.end(); ++it) {
|
|
const uint64_t entry_hash = it->first;
|
|
std::pair<EntrySet::iterator, bool> insert_result =
|
|
index_file_entries->insert(EntrySet::value_type(entry_hash,
|
|
EntryMetadata()));
|
|
EntrySet::iterator& possibly_inserted_entry = insert_result.first;
|
|
possibly_inserted_entry->second = it->second;
|
|
}
|
|
|
|
uint64_t merged_cache_size = 0;
|
|
for (EntrySet::iterator it = index_file_entries->begin();
|
|
it != index_file_entries->end(); ++it) {
|
|
merged_cache_size += it->second.GetEntrySize();
|
|
}
|
|
|
|
entries_set_.swap(*index_file_entries);
|
|
cache_size_ = merged_cache_size;
|
|
initialized_ = true;
|
|
init_method_ = load_result->init_method;
|
|
|
|
// The actual IO is asynchronous, so calling WriteToDisk() shouldn't slow the
|
|
// merge down much.
|
|
if (load_result->flush_required)
|
|
WriteToDisk(INDEX_WRITE_REASON_STARTUP_MERGE);
|
|
|
|
SIMPLE_CACHE_UMA(CUSTOM_COUNTS,
|
|
"IndexInitializationWaiters", cache_type_,
|
|
to_run_when_initialized_.size(), 0, 100, 20);
|
|
SIMPLE_CACHE_UMA(CUSTOM_COUNTS, "IndexNumEntriesOnInit", cache_type_,
|
|
entries_set_.size(), 0, 100000, 50);
|
|
SIMPLE_CACHE_UMA(
|
|
MEMORY_KB, "CacheSizeOnInit", cache_type_,
|
|
static_cast<base::HistogramBase::Sample>(cache_size_ / kBytesInKb));
|
|
SIMPLE_CACHE_UMA(
|
|
MEMORY_KB, "MaxCacheSizeOnInit", cache_type_,
|
|
static_cast<base::HistogramBase::Sample>(max_size_ / kBytesInKb));
|
|
if (max_size_ > 0) {
|
|
SIMPLE_CACHE_UMA(PERCENTAGE, "PercentFullOnInit", cache_type_,
|
|
static_cast<base::HistogramBase::Sample>(
|
|
(cache_size_ * 100) / max_size_));
|
|
}
|
|
|
|
// Run all callbacks waiting for the index to come up.
|
|
for (CallbackList::iterator it = to_run_when_initialized_.begin(),
|
|
end = to_run_when_initialized_.end(); it != end; ++it) {
|
|
io_thread_->PostTask(FROM_HERE, base::Bind((*it), net::OK));
|
|
}
|
|
to_run_when_initialized_.clear();
|
|
}
|
|
|
|
#if defined(OS_ANDROID)
|
|
void SimpleIndex::OnApplicationStateChange(
|
|
base::android::ApplicationState state) {
|
|
DCHECK(io_thread_checker_.CalledOnValidThread());
|
|
// For more info about android activities, see:
|
|
// developer.android.com/training/basics/activity-lifecycle/pausing.html
|
|
if (state == base::android::APPLICATION_STATE_HAS_RUNNING_ACTIVITIES) {
|
|
app_on_background_ = false;
|
|
} else if (state ==
|
|
base::android::APPLICATION_STATE_HAS_STOPPED_ACTIVITIES) {
|
|
app_on_background_ = true;
|
|
WriteToDisk(INDEX_WRITE_REASON_ANDROID_STOPPED);
|
|
}
|
|
}
|
|
#endif
|
|
|
|
void SimpleIndex::WriteToDisk(IndexWriteToDiskReason reason) {
|
|
DCHECK(io_thread_checker_.CalledOnValidThread());
|
|
if (!initialized_)
|
|
return;
|
|
SIMPLE_CACHE_UMA(CUSTOM_COUNTS,
|
|
"IndexNumEntriesOnWrite", cache_type_,
|
|
entries_set_.size(), 0, 100000, 50);
|
|
const base::TimeTicks start = base::TimeTicks::Now();
|
|
if (!last_write_to_disk_.is_null()) {
|
|
if (app_on_background_) {
|
|
SIMPLE_CACHE_UMA(MEDIUM_TIMES,
|
|
"IndexWriteInterval.Background", cache_type_,
|
|
start - last_write_to_disk_);
|
|
} else {
|
|
SIMPLE_CACHE_UMA(MEDIUM_TIMES,
|
|
"IndexWriteInterval.Foreground", cache_type_,
|
|
start - last_write_to_disk_);
|
|
}
|
|
}
|
|
last_write_to_disk_ = start;
|
|
|
|
base::Closure after_write;
|
|
if (cleanup_tracker_) {
|
|
// Make anyone synchronizing with our cleanup wait for the index to be
|
|
// written back.
|
|
after_write = base::Bind(
|
|
base::DoNothing::Repeatedly<scoped_refptr<BackendCleanupTracker>>(),
|
|
cleanup_tracker_);
|
|
}
|
|
|
|
index_file_->WriteToDisk(reason, entries_set_, cache_size_, start,
|
|
app_on_background_, after_write);
|
|
}
|
|
|
|
} // namespace disk_cache
|