blob: d909eaecb3939f8a187f9ef9b8a8bf48e3b207be [file] [log] [blame]
// Copyright (c) 2013 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "net/disk_cache/simple/simple_backend_impl.h"
#include <algorithm>
#include <cstdlib>
#include <functional>
#include <limits>
#if defined(OS_POSIX)
#include <sys/resource.h>
#endif
#include "base/bind.h"
#include "base/callback.h"
#include "base/files/file_util.h"
#include "base/lazy_instance.h"
#include "base/location.h"
#include "base/macros.h"
#include "base/metrics/field_trial.h"
#include "base/metrics/field_trial_params.h"
#include "base/metrics/histogram_functions.h"
#include "base/metrics/histogram_macros.h"
#include "base/single_thread_task_runner.h"
#include "base/sys_info.h"
#include "base/task/post_task.h"
#include "base/task/task_scheduler/task_scheduler.h"
#include "base/task_runner_util.h"
#include "base/threading/thread_task_runner_handle.h"
#include "base/time/time.h"
#include "base/trace_event/memory_usage_estimator.h"
#include "base/trace_event/process_memory_dump.h"
#include "build/build_config.h"
#include "net/base/net_errors.h"
#include "net/base/prioritized_task_runner.h"
#include "net/disk_cache/backend_cleanup_tracker.h"
#include "net/disk_cache/cache_util.h"
#include "net/disk_cache/simple/simple_entry_format.h"
#include "net/disk_cache/simple/simple_entry_impl.h"
#include "net/disk_cache/simple/simple_file_tracker.h"
#include "net/disk_cache/simple/simple_histogram_macros.h"
#include "net/disk_cache/simple/simple_index.h"
#include "net/disk_cache/simple/simple_index_file.h"
#include "net/disk_cache/simple/simple_synchronous_entry.h"
#include "net/disk_cache/simple/simple_util.h"
#include "net/disk_cache/simple/simple_version_upgrade.h"
#include "starboard/types.h"
using base::Callback;
using base::Closure;
using base::FilePath;
using base::Time;
using base::DirectoryExists;
using base::CreateDirectory;
namespace disk_cache {
namespace {
// Maximum fraction of the cache that one entry can consume.
const int kMaxFileRatio = 8;
// Overrides the above.
const int kMinFileSizeLimit = 5 * 1024 * 1024;
bool g_fd_limit_histogram_has_been_populated = false;
void MaybeHistogramFdLimit() {
if (g_fd_limit_histogram_has_been_populated)
return;
// Used in histograms; add new entries at end.
enum FdLimitStatus {
FD_LIMIT_STATUS_UNSUPPORTED = 0,
FD_LIMIT_STATUS_FAILED = 1,
FD_LIMIT_STATUS_SUCCEEDED = 2,
FD_LIMIT_STATUS_MAX = 3
};
FdLimitStatus fd_limit_status = FD_LIMIT_STATUS_UNSUPPORTED;
int soft_fd_limit = 0;
int hard_fd_limit = 0;
#if defined(OS_POSIX)
struct rlimit nofile;
if (!getrlimit(RLIMIT_NOFILE, &nofile)) {
soft_fd_limit = nofile.rlim_cur;
hard_fd_limit = nofile.rlim_max;
fd_limit_status = FD_LIMIT_STATUS_SUCCEEDED;
} else {
fd_limit_status = FD_LIMIT_STATUS_FAILED;
}
#endif
UMA_HISTOGRAM_ENUMERATION("SimpleCache.FileDescriptorLimitStatus",
fd_limit_status, FD_LIMIT_STATUS_MAX);
if (fd_limit_status == FD_LIMIT_STATUS_SUCCEEDED) {
base::UmaHistogramSparse("SimpleCache.FileDescriptorLimitSoft",
soft_fd_limit);
base::UmaHistogramSparse("SimpleCache.FileDescriptorLimitHard",
hard_fd_limit);
}
g_fd_limit_histogram_has_been_populated = true;
}
// Global context of all the files we have open --- this permits some to be
// closed on demand if too many FDs are being used, to avoid running out.
base::LazyInstance<SimpleFileTracker>::Leaky g_simple_file_tracker =
LAZY_INSTANCE_INITIALIZER;
// Detects if the files in the cache directory match the current disk cache
// backend type and version. If the directory contains no cache, occupies it
// with the fresh structure.
SimpleCacheConsistencyResult FileStructureConsistent(
const base::FilePath& path) {
if (!base::PathExists(path) && !base::CreateDirectory(path)) {
LOG(ERROR) << "Failed to create directory: " << path.LossyDisplayName();
return SimpleCacheConsistencyResult::kCreateDirectoryFailed;
}
return disk_cache::UpgradeSimpleCacheOnDisk(path);
}
// A context used by a BarrierCompletionCallback to track state.
struct BarrierContext {
explicit BarrierContext(net::CompletionOnceCallback final_callback,
int expected)
: final_callback_(std::move(final_callback)),
expected(expected),
count(0),
had_error(false) {}
net::CompletionOnceCallback final_callback_;
const int expected;
int count;
bool had_error;
};
void BarrierCompletionCallbackImpl(
BarrierContext* context,
int result) {
DCHECK_GT(context->expected, context->count);
if (context->had_error)
return;
if (result != net::OK) {
context->had_error = true;
std::move(context->final_callback_).Run(result);
return;
}
++context->count;
if (context->count == context->expected)
std::move(context->final_callback_).Run(net::OK);
}
// A barrier completion callback is a repeatable callback that waits for
// |count| successful results before invoking |final_callback|. In the case of
// an error, the first error is passed to |final_callback| and all others
// are ignored.
base::RepeatingCallback<void(int)> MakeBarrierCompletionCallback(
int count,
net::CompletionOnceCallback final_callback) {
BarrierContext* context =
new BarrierContext(std::move(final_callback), count);
return base::BindRepeating(&BarrierCompletionCallbackImpl,
base::Owned(context));
}
// A short bindable thunk that ensures a completion callback is always called
// after running an operation asynchronously.
void RunOperationAndCallback(
base::OnceCallback<net::Error(net::CompletionOnceCallback)> operation,
net::CompletionOnceCallback operation_callback) {
base::RepeatingCallback<void(int)> copyable_callback;
if (operation_callback)
copyable_callback =
base::AdaptCallbackForRepeating(std::move(operation_callback));
const int operation_result = std::move(operation).Run(copyable_callback);
if (operation_result != net::ERR_IO_PENDING && copyable_callback)
copyable_callback.Run(operation_result);
}
void RecordIndexLoad(net::CacheType cache_type,
base::TimeTicks constructed_since,
int result) {
const base::TimeDelta creation_to_index = base::TimeTicks::Now() -
constructed_since;
if (result == net::OK) {
SIMPLE_CACHE_UMA(TIMES, "CreationToIndex", cache_type, creation_to_index);
} else {
SIMPLE_CACHE_UMA(TIMES,
"CreationToIndexFail", cache_type, creation_to_index);
}
}
} // namespace
const base::Feature SimpleBackendImpl::kPrioritizedSimpleCacheTasks{
"PrioritizedSimpleCacheTasks", base::FEATURE_DISABLED_BY_DEFAULT};
// Static function which is called by base::trace_event::EstimateMemoryUsage()
// to estimate the memory of SimpleEntryImpl* type.
// This needs to be in disk_cache namespace.
size_t EstimateMemoryUsage(const SimpleEntryImpl* const& entry_impl) {
return sizeof(SimpleEntryImpl) + entry_impl->EstimateMemoryUsage();
}
class SimpleBackendImpl::ActiveEntryProxy
: public SimpleEntryImpl::ActiveEntryProxy {
public:
~ActiveEntryProxy() override {
if (backend_) {
DCHECK_EQ(1U, backend_->active_entries_.count(entry_hash_));
backend_->active_entries_.erase(entry_hash_);
}
}
static std::unique_ptr<SimpleEntryImpl::ActiveEntryProxy> Create(
int64_t entry_hash,
SimpleBackendImpl* backend) {
std::unique_ptr<SimpleEntryImpl::ActiveEntryProxy> proxy(
new ActiveEntryProxy(entry_hash, backend));
return proxy;
}
private:
ActiveEntryProxy(uint64_t entry_hash, SimpleBackendImpl* backend)
: entry_hash_(entry_hash), backend_(backend->AsWeakPtr()) {}
uint64_t entry_hash_;
base::WeakPtr<SimpleBackendImpl> backend_;
};
SimpleBackendImpl::SimpleBackendImpl(
const FilePath& path,
scoped_refptr<BackendCleanupTracker> cleanup_tracker,
SimpleFileTracker* file_tracker,
int64_t max_bytes,
net::CacheType cache_type,
net::NetLog* net_log)
: cleanup_tracker_(std::move(cleanup_tracker)),
file_tracker_(file_tracker ? file_tracker
: g_simple_file_tracker.Pointer()),
path_(path),
cache_type_(cache_type),
cache_runner_(base::CreateSequencedTaskRunnerWithTraits(
{base::MayBlock(), base::TaskPriority::USER_BLOCKING,
base::TaskShutdownBehavior::BLOCK_SHUTDOWN})),
orig_max_size_(max_bytes),
entry_operations_mode_((cache_type == net::DISK_CACHE ||
cache_type == net::GENERATED_CODE_CACHE)
? SimpleEntryImpl::OPTIMISTIC_OPERATIONS
: SimpleEntryImpl::NON_OPTIMISTIC_OPERATIONS),
net_log_(net_log) {
// Treat negative passed-in sizes same as SetMaxSize would here and in other
// backends, as default (if first call).
if (orig_max_size_ < 0)
orig_max_size_ = 0;
MaybeHistogramFdLimit();
}
SimpleBackendImpl::~SimpleBackendImpl() {
index_->WriteToDisk(SimpleIndex::INDEX_WRITE_REASON_SHUTDOWN);
}
void SimpleBackendImpl::SetWorkerPoolForTesting(
scoped_refptr<base::TaskRunner> task_runner) {
prioritized_task_runner_ =
base::MakeRefCounted<net::PrioritizedTaskRunner>(std::move(task_runner));
}
net::Error SimpleBackendImpl::Init(CompletionOnceCallback completion_callback) {
auto worker_pool = base::CreateTaskRunnerWithTraits(
{base::MayBlock(), base::WithBaseSyncPrimitives(),
base::TaskPriority::USER_BLOCKING,
base::TaskShutdownBehavior::CONTINUE_ON_SHUTDOWN});
prioritized_task_runner_ =
base::MakeRefCounted<net::PrioritizedTaskRunner>(worker_pool);
index_ = std::make_unique<SimpleIndex>(
base::ThreadTaskRunnerHandle::Get(), cleanup_tracker_.get(), this,
cache_type_,
std::make_unique<SimpleIndexFile>(cache_runner_, worker_pool.get(),
cache_type_, path_));
index_->ExecuteWhenReady(
base::BindOnce(&RecordIndexLoad, cache_type_, base::TimeTicks::Now()));
PostTaskAndReplyWithResult(
cache_runner_.get(), FROM_HERE,
base::BindOnce(&SimpleBackendImpl::InitCacheStructureOnDisk, path_,
orig_max_size_, cache_type_),
base::BindOnce(&SimpleBackendImpl::InitializeIndex, AsWeakPtr(),
std::move(completion_callback)));
return net::ERR_IO_PENDING;
}
bool SimpleBackendImpl::SetMaxSize(int64_t max_bytes) {
if (max_bytes < 0)
return false;
orig_max_size_ = max_bytes;
index_->SetMaxSize(max_bytes);
return true;
}
int SimpleBackendImpl::GetMaxFileSize() const {
return std::max(base::saturated_cast<int>(index_->max_size() / kMaxFileRatio),
kMinFileSizeLimit);
}
void SimpleBackendImpl::OnDoomStart(uint64_t entry_hash) {
DCHECK_EQ(0u, entries_pending_doom_.count(entry_hash));
entries_pending_doom_.insert(
std::make_pair(entry_hash, std::vector<PostDoomWaiter>()));
}
void SimpleBackendImpl::OnDoomComplete(uint64_t entry_hash) {
DCHECK_EQ(1u, entries_pending_doom_.count(entry_hash));
auto it = entries_pending_doom_.find(entry_hash);
std::vector<PostDoomWaiter> to_handle_waiters;
to_handle_waiters.swap(it->second);
entries_pending_doom_.erase(it);
SIMPLE_CACHE_UMA(COUNTS_1000, "NumOpsBlockedByPendingDoom", cache_type_,
to_handle_waiters.size());
for (PostDoomWaiter& post_doom : to_handle_waiters) {
SIMPLE_CACHE_UMA(TIMES, "QueueLatency.PendingDoom", cache_type_,
(base::TimeTicks::Now() - post_doom.time_queued));
std::move(post_doom.run_post_doom).Run();
}
}
void SimpleBackendImpl::DoomEntries(std::vector<uint64_t>* entry_hashes,
net::CompletionOnceCallback callback) {
std::unique_ptr<std::vector<uint64_t>> mass_doom_entry_hashes(
new std::vector<uint64_t>());
mass_doom_entry_hashes->swap(*entry_hashes);
std::vector<uint64_t> to_doom_individually_hashes;
// For each of the entry hashes, there are two cases:
// 1. There are corresponding entries in active set, pending doom, or both
// sets, and so the hash should be doomed individually to avoid flakes.
// 2. The hash is not in active use at all, so we can call
// SimpleSynchronousEntry::DeleteEntrySetFiles and delete the files en
// masse.
for (int i = mass_doom_entry_hashes->size() - 1; i >= 0; --i) {
const uint64_t entry_hash = (*mass_doom_entry_hashes)[i];
if (!active_entries_.count(entry_hash) &&
!entries_pending_doom_.count(entry_hash)) {
continue;
}
to_doom_individually_hashes.push_back(entry_hash);
(*mass_doom_entry_hashes)[i] = mass_doom_entry_hashes->back();
mass_doom_entry_hashes->resize(mass_doom_entry_hashes->size() - 1);
}
base::RepeatingCallback<void(int)> barrier_callback =
MakeBarrierCompletionCallback(to_doom_individually_hashes.size() + 1,
std::move(callback));
for (std::vector<uint64_t>::const_iterator
it = to_doom_individually_hashes.begin(),
end = to_doom_individually_hashes.end();
it != end; ++it) {
const int doom_result = DoomEntryFromHash(*it, barrier_callback);
DCHECK_EQ(net::ERR_IO_PENDING, doom_result);
index_->Remove(*it);
}
for (std::vector<uint64_t>::const_iterator
it = mass_doom_entry_hashes->begin(),
end = mass_doom_entry_hashes->end();
it != end; ++it) {
index_->Remove(*it);
OnDoomStart(*it);
}
// Taking this pointer here avoids undefined behaviour from calling
// base::Passed before mass_doom_entry_hashes.get().
std::vector<uint64_t>* mass_doom_entry_hashes_ptr =
mass_doom_entry_hashes.get();
PostTaskAndReplyWithResult(
prioritized_task_runner_->task_runner(), FROM_HERE,
base::BindOnce(&SimpleSynchronousEntry::DeleteEntrySetFiles,
mass_doom_entry_hashes_ptr, path_),
base::BindOnce(&SimpleBackendImpl::DoomEntriesComplete, AsWeakPtr(),
base::Passed(&mass_doom_entry_hashes), barrier_callback));
}
net::CacheType SimpleBackendImpl::GetCacheType() const {
return net::DISK_CACHE;
}
int32_t SimpleBackendImpl::GetEntryCount() const {
// TODO(pasko): Use directory file count when index is not ready.
return index_->GetEntryCount();
}
net::Error SimpleBackendImpl::OpenEntry(const std::string& key,
net::RequestPriority request_priority,
Entry** entry,
CompletionOnceCallback callback) {
const uint64_t entry_hash = simple_util::GetEntryHashKey(key);
std::vector<PostDoomWaiter>* post_doom = nullptr;
scoped_refptr<SimpleEntryImpl> simple_entry = CreateOrFindActiveOrDoomedEntry(
entry_hash, key, request_priority, &post_doom);
if (!simple_entry) {
if (post_doom->empty() &&
entry_operations_mode_ == SimpleEntryImpl::OPTIMISTIC_OPERATIONS) {
// The entry is doomed, and no other backend operations are queued for the
// entry, thus the open must fail and it's safe to return synchronously.
net::NetLogWithSource log_for_entry(net::NetLogWithSource::Make(
net_log_, net::NetLogSourceType::DISK_CACHE_ENTRY));
log_for_entry.AddEvent(
net::NetLogEventType::SIMPLE_CACHE_ENTRY_OPEN_CALL);
log_for_entry.AddEventWithNetErrorCode(
net::NetLogEventType::SIMPLE_CACHE_ENTRY_OPEN_END, net::ERR_FAILED);
return net::ERR_FAILED;
}
base::OnceCallback<net::Error(CompletionOnceCallback)> operation =
base::BindOnce(&SimpleBackendImpl::OpenEntry, base::Unretained(this),
key, request_priority, entry);
post_doom->emplace_back(base::BindOnce(
&RunOperationAndCallback, std::move(operation), std::move(callback)));
return net::ERR_IO_PENDING;
}
return simple_entry->OpenEntry(entry, std::move(callback));
}
net::Error SimpleBackendImpl::CreateEntry(const std::string& key,
net::RequestPriority request_priority,
Entry** entry,
CompletionOnceCallback callback) {
DCHECK_LT(0u, key.size());
const uint64_t entry_hash = simple_util::GetEntryHashKey(key);
std::vector<PostDoomWaiter>* post_doom = nullptr;
scoped_refptr<SimpleEntryImpl> simple_entry = CreateOrFindActiveOrDoomedEntry(
entry_hash, key, request_priority, &post_doom);
if (!simple_entry) {
// We would like to optimistically have create go ahead, for benefit of
// HTTP cache use. This can only be sanely done if we are the only op
// serialized after doom's completion.
if (post_doom->empty() &&
entry_operations_mode_ == SimpleEntryImpl::OPTIMISTIC_OPERATIONS) {
simple_entry = new SimpleEntryImpl(
cache_type_, path_, cleanup_tracker_.get(), entry_hash,
entry_operations_mode_, this, file_tracker_, net_log_,
GetNewEntryPriority(request_priority));
simple_entry->SetKey(key);
simple_entry->SetActiveEntryProxy(
ActiveEntryProxy::Create(entry_hash, this));
simple_entry->SetCreatePendingDoom();
std::pair<EntryMap::iterator, bool> insert_result =
active_entries_.insert(
EntryMap::value_type(entry_hash, simple_entry.get()));
post_doom->emplace_back(base::BindOnce(
&SimpleEntryImpl::NotifyDoomBeforeCreateComplete, simple_entry));
DCHECK(insert_result.second);
} else {
base::OnceCallback<net::Error(CompletionOnceCallback)> operation =
base::BindOnce(&SimpleBackendImpl::CreateEntry,
base::Unretained(this), key, request_priority, entry);
post_doom->emplace_back(base::BindOnce(
&RunOperationAndCallback, std::move(operation), std::move(callback)));
return net::ERR_IO_PENDING;
}
}
return simple_entry->CreateEntry(entry, std::move(callback));
}
net::Error SimpleBackendImpl::DoomEntry(const std::string& key,
net::RequestPriority priority,
CompletionOnceCallback callback) {
const uint64_t entry_hash = simple_util::GetEntryHashKey(key);
std::vector<PostDoomWaiter>* post_doom = nullptr;
scoped_refptr<SimpleEntryImpl> simple_entry =
CreateOrFindActiveOrDoomedEntry(entry_hash, key, priority, &post_doom);
if (!simple_entry) {
// At first glance, it appears exceedingly silly to queue up a doom
// when we get here because the files corresponding to our key are being
// deleted... but it's possible that one of the things in post_doom is a
// create for our key, in which case we still have work to do.
base::OnceCallback<net::Error(CompletionOnceCallback)> operation =
base::BindOnce(&SimpleBackendImpl::DoomEntry, base::Unretained(this),
key, priority);
post_doom->emplace_back(base::BindOnce(
&RunOperationAndCallback, std::move(operation), std::move(callback)));
return net::ERR_IO_PENDING;
}
return simple_entry->DoomEntry(std::move(callback));
}
net::Error SimpleBackendImpl::DoomAllEntries(CompletionOnceCallback callback) {
return DoomEntriesBetween(Time(), Time(), std::move(callback));
}
net::Error SimpleBackendImpl::DoomEntriesBetween(
const Time initial_time,
const Time end_time,
CompletionOnceCallback callback) {
return index_->ExecuteWhenReady(
base::BindOnce(&SimpleBackendImpl::IndexReadyForDoom, AsWeakPtr(),
initial_time, end_time, std::move(callback)));
}
net::Error SimpleBackendImpl::DoomEntriesSince(
const Time initial_time,
CompletionOnceCallback callback) {
return DoomEntriesBetween(initial_time, Time(), std::move(callback));
}
int64_t SimpleBackendImpl::CalculateSizeOfAllEntries(
Int64CompletionOnceCallback callback) {
return index_->ExecuteWhenReady(
base::BindOnce(&SimpleBackendImpl::IndexReadyForSizeCalculation,
AsWeakPtr(), std::move(callback)));
}
int64_t SimpleBackendImpl::CalculateSizeOfEntriesBetween(
base::Time initial_time,
base::Time end_time,
Int64CompletionOnceCallback callback) {
return index_->ExecuteWhenReady(
base::BindOnce(&SimpleBackendImpl::IndexReadyForSizeBetweenCalculation,
AsWeakPtr(), initial_time, end_time, std::move(callback)));
}
class SimpleBackendImpl::SimpleIterator final : public Iterator {
public:
explicit SimpleIterator(base::WeakPtr<SimpleBackendImpl> backend)
: backend_(backend),
weak_factory_(this) {
}
// From Backend::Iterator:
net::Error OpenNextEntry(Entry** next_entry,
CompletionOnceCallback callback) override {
CompletionOnceCallback open_next_entry_impl = base::BindOnce(
&SimpleIterator::OpenNextEntryImpl, weak_factory_.GetWeakPtr(),
next_entry, std::move(callback));
return backend_->index_->ExecuteWhenReady(std::move(open_next_entry_impl));
}
void OpenNextEntryImpl(Entry** next_entry,
CompletionOnceCallback callback,
int index_initialization_error_code) {
if (!backend_) {
std::move(callback).Run(net::ERR_FAILED);
return;
}
if (index_initialization_error_code != net::OK) {
std::move(callback).Run(index_initialization_error_code);
return;
}
if (!hashes_to_enumerate_)
hashes_to_enumerate_ = backend_->index()->GetAllHashes();
auto copyable_callback =
base::AdaptCallbackForRepeating(std::move(callback));
while (!hashes_to_enumerate_->empty()) {
uint64_t entry_hash = hashes_to_enumerate_->back();
hashes_to_enumerate_->pop_back();
if (backend_->index()->Has(entry_hash)) {
*next_entry = NULL;
CompletionOnceCallback continue_iteration = base::BindOnce(
&SimpleIterator::CheckIterationReturnValue,
weak_factory_.GetWeakPtr(), next_entry, copyable_callback);
int error_code_open = backend_->OpenEntryFromHash(
entry_hash, next_entry, std::move(continue_iteration));
if (error_code_open == net::ERR_IO_PENDING)
return;
if (error_code_open != net::ERR_FAILED) {
copyable_callback.Run(error_code_open);
return;
}
}
}
copyable_callback.Run(net::ERR_FAILED);
}
void CheckIterationReturnValue(Entry** entry,
CompletionOnceCallback callback,
int error_code) {
if (error_code == net::ERR_FAILED) {
OpenNextEntry(entry, std::move(callback));
return;
}
std::move(callback).Run(error_code);
}
private:
base::WeakPtr<SimpleBackendImpl> backend_;
std::unique_ptr<std::vector<uint64_t>> hashes_to_enumerate_;
base::WeakPtrFactory<SimpleIterator> weak_factory_;
};
std::unique_ptr<Backend::Iterator> SimpleBackendImpl::CreateIterator() {
return std::unique_ptr<Iterator>(new SimpleIterator(AsWeakPtr()));
}
void SimpleBackendImpl::GetStats(base::StringPairs* stats) {
std::pair<std::string, std::string> item;
item.first = "Cache type";
item.second = "Simple Cache";
stats->push_back(item);
}
void SimpleBackendImpl::OnExternalCacheHit(const std::string& key) {
index_->UseIfExists(simple_util::GetEntryHashKey(key));
}
size_t SimpleBackendImpl::DumpMemoryStats(
base::trace_event::ProcessMemoryDump* pmd,
const std::string& parent_absolute_name) const {
base::trace_event::MemoryAllocatorDump* dump =
pmd->CreateAllocatorDump(parent_absolute_name + "/simple_backend");
size_t size = base::trace_event::EstimateMemoryUsage(index_) +
base::trace_event::EstimateMemoryUsage(active_entries_);
// TODO(xunjieli): crbug.com/669108. Track |entries_pending_doom_| once
// base::Closure is suppported in memory_usage_estimator.h.
dump->AddScalar(base::trace_event::MemoryAllocatorDump::kNameSize,
base::trace_event::MemoryAllocatorDump::kUnitsBytes, size);
return size;
}
uint8_t SimpleBackendImpl::GetEntryInMemoryData(const std::string& key) {
const uint64_t entry_hash = simple_util::GetEntryHashKey(key);
return index_->GetEntryInMemoryData(entry_hash);
}
void SimpleBackendImpl::SetEntryInMemoryData(const std::string& key,
uint8_t data) {
const uint64_t entry_hash = simple_util::GetEntryHashKey(key);
index_->SetEntryInMemoryData(entry_hash, data);
}
SimpleBackendImpl::PostDoomWaiter::PostDoomWaiter() {}
SimpleBackendImpl::PostDoomWaiter::PostDoomWaiter(
base::OnceClosure to_run_post_doom)
: time_queued(base::TimeTicks::Now()),
run_post_doom(std::move(to_run_post_doom)) {}
SimpleBackendImpl::PostDoomWaiter::PostDoomWaiter(PostDoomWaiter&& other)
: time_queued(other.time_queued),
run_post_doom(std::move(other.run_post_doom)) {}
SimpleBackendImpl::PostDoomWaiter& SimpleBackendImpl::PostDoomWaiter::operator=(
PostDoomWaiter&& other) {
time_queued = other.time_queued;
run_post_doom = std::move(other.run_post_doom);
return *this;
}
SimpleBackendImpl::PostDoomWaiter::~PostDoomWaiter() {}
void SimpleBackendImpl::InitializeIndex(CompletionOnceCallback callback,
const DiskStatResult& result) {
if (result.net_error == net::OK) {
index_->SetMaxSize(result.max_size);
#if defined(OS_ANDROID)
if (app_status_listener_)
index_->set_app_status_listener(app_status_listener_);
#endif
index_->Initialize(result.cache_dir_mtime);
}
std::move(callback).Run(result.net_error);
}
void SimpleBackendImpl::IndexReadyForDoom(Time initial_time,
Time end_time,
CompletionOnceCallback callback,
int result) {
if (result != net::OK) {
std::move(callback).Run(result);
return;
}
std::unique_ptr<std::vector<uint64_t>> removed_key_hashes(
index_->GetEntriesBetween(initial_time, end_time).release());
DoomEntries(removed_key_hashes.get(), std::move(callback));
}
void SimpleBackendImpl::IndexReadyForSizeCalculation(
Int64CompletionOnceCallback callback,
int result) {
int64_t rv = result == net::OK ? index_->GetCacheSize() : result;
std::move(callback).Run(rv);
}
void SimpleBackendImpl::IndexReadyForSizeBetweenCalculation(
base::Time initial_time,
base::Time end_time,
Int64CompletionOnceCallback callback,
int result) {
int64_t rv = result == net::OK
? index_->GetCacheSizeBetween(initial_time, end_time)
: result;
std::move(callback).Run(rv);
}
// static
SimpleBackendImpl::DiskStatResult SimpleBackendImpl::InitCacheStructureOnDisk(
const base::FilePath& path,
uint64_t suggested_max_size,
net::CacheType cache_type) {
DiskStatResult result;
result.max_size = suggested_max_size;
result.net_error = net::OK;
SimpleCacheConsistencyResult consistency = FileStructureConsistent(path);
SIMPLE_CACHE_UMA(ENUMERATION, "ConsistencyResult", cache_type, consistency);
if (consistency != SimpleCacheConsistencyResult::kOK) {
LOG(ERROR) << "Simple Cache Backend: wrong file structure on disk: "
<< static_cast<int>(consistency)
<< " path: " << path.LossyDisplayName();
result.net_error = net::ERR_FAILED;
} else {
bool mtime_result =
disk_cache::simple_util::GetMTime(path, &result.cache_dir_mtime);
DCHECK(mtime_result);
if (!result.max_size) {
int64_t available = base::SysInfo::AmountOfFreeDiskSpace(path);
result.max_size = disk_cache::PreferredCacheSize(available);
}
DCHECK(result.max_size);
}
return result;
}
scoped_refptr<SimpleEntryImpl>
SimpleBackendImpl::CreateOrFindActiveOrDoomedEntry(
const uint64_t entry_hash,
const std::string& key,
net::RequestPriority request_priority,
std::vector<PostDoomWaiter>** post_doom) {
DCHECK_EQ(entry_hash, simple_util::GetEntryHashKey(key));
// If there is a doom pending, we would want to serialize after it.
auto doom_it = entries_pending_doom_.find(entry_hash);
if (doom_it != entries_pending_doom_.end()) {
*post_doom = &doom_it->second;
return nullptr;
}
std::pair<EntryMap::iterator, bool> insert_result =
active_entries_.insert(EntryMap::value_type(entry_hash, NULL));
EntryMap::iterator& it = insert_result.first;
const bool did_insert = insert_result.second;
if (did_insert) {
SimpleEntryImpl* entry = it->second = new SimpleEntryImpl(
cache_type_, path_, cleanup_tracker_.get(), entry_hash,
entry_operations_mode_, this, file_tracker_, net_log_,
GetNewEntryPriority(request_priority));
entry->SetKey(key);
entry->SetActiveEntryProxy(ActiveEntryProxy::Create(entry_hash, this));
}
// TODO(jkarlin): In case of recycling a half-closed entry, we might want to
// update its priority.
DCHECK(it->second);
// It's possible, but unlikely, that we have an entry hash collision with a
// currently active entry.
if (key != it->second->key()) {
it->second->Doom();
DCHECK_EQ(0U, active_entries_.count(entry_hash));
DCHECK_EQ(1U, entries_pending_doom_.count(entry_hash));
// Re-run ourselves to handle the now-pending doom.
return CreateOrFindActiveOrDoomedEntry(entry_hash, key, request_priority,
post_doom);
}
return base::WrapRefCounted(it->second);
}
net::Error SimpleBackendImpl::OpenEntryFromHash(
uint64_t entry_hash,
Entry** entry,
CompletionOnceCallback callback) {
auto it = entries_pending_doom_.find(entry_hash);
if (it != entries_pending_doom_.end()) {
base::OnceCallback<net::Error(CompletionOnceCallback)> operation =
base::BindOnce(&SimpleBackendImpl::OpenEntryFromHash,
base::Unretained(this), entry_hash, entry);
it->second.emplace_back(base::BindOnce(
&RunOperationAndCallback, std::move(operation), std::move(callback)));
return net::ERR_IO_PENDING;
}
auto has_active = active_entries_.find(entry_hash);
if (has_active != active_entries_.end()) {
return OpenEntry(has_active->second->key(), net::HIGHEST, entry,
std::move(callback));
}
scoped_refptr<SimpleEntryImpl> simple_entry = new SimpleEntryImpl(
cache_type_, path_, cleanup_tracker_.get(), entry_hash,
entry_operations_mode_, this, file_tracker_, net_log_,
GetNewEntryPriority(net::HIGHEST));
CompletionOnceCallback backend_callback =
base::BindOnce(&SimpleBackendImpl::OnEntryOpenedFromHash, AsWeakPtr(),
entry_hash, entry, simple_entry, std::move(callback));
return simple_entry->OpenEntry(entry, std::move(backend_callback));
}
net::Error SimpleBackendImpl::DoomEntryFromHash(
uint64_t entry_hash,
CompletionOnceCallback callback) {
Entry** entry = new Entry*();
std::unique_ptr<Entry*> scoped_entry(entry);
auto pending_it = entries_pending_doom_.find(entry_hash);
if (pending_it != entries_pending_doom_.end()) {
base::OnceCallback<net::Error(CompletionOnceCallback)> operation =
base::BindOnce(&SimpleBackendImpl::DoomEntryFromHash,
base::Unretained(this), entry_hash);
pending_it->second.emplace_back(base::BindOnce(
&RunOperationAndCallback, std::move(operation), std::move(callback)));
return net::ERR_IO_PENDING;
}
auto active_it = active_entries_.find(entry_hash);
if (active_it != active_entries_.end())
return active_it->second->DoomEntry(std::move(callback));
// There's no pending dooms, nor any open entry. We can make a trivial
// call to DoomEntries() to delete this entry.
std::vector<uint64_t> entry_hash_vector;
entry_hash_vector.push_back(entry_hash);
DoomEntries(&entry_hash_vector, std::move(callback));
return net::ERR_IO_PENDING;
}
void SimpleBackendImpl::OnEntryOpenedFromHash(
uint64_t hash,
Entry** entry,
const scoped_refptr<SimpleEntryImpl>& simple_entry,
CompletionOnceCallback callback,
int error_code) {
if (error_code != net::OK) {
std::move(callback).Run(error_code);
return;
}
DCHECK(*entry);
std::pair<EntryMap::iterator, bool> insert_result =
active_entries_.insert(EntryMap::value_type(hash, simple_entry.get()));
EntryMap::iterator& it = insert_result.first;
const bool did_insert = insert_result.second;
if (did_insert) {
// There was no active entry corresponding to this hash. We've already put
// the entry opened from hash in the |active_entries_|. We now provide the
// proxy object to the entry.
it->second->SetActiveEntryProxy(ActiveEntryProxy::Create(hash, this));
std::move(callback).Run(net::OK);
} else {
// The entry was made active while we waiting for the open from hash to
// finish. The entry created from hash needs to be closed, and the one
// in |active_entries_| can be returned to the caller.
simple_entry->Close();
it->second->OpenEntry(entry, std::move(callback));
}
}
void SimpleBackendImpl::DoomEntriesComplete(
std::unique_ptr<std::vector<uint64_t>> entry_hashes,
CompletionOnceCallback callback,
int result) {
for (const uint64_t& entry_hash : *entry_hashes)
OnDoomComplete(entry_hash);
std::move(callback).Run(result);
}
// static
void SimpleBackendImpl::FlushWorkerPoolForTesting() {
// TODO(morlovich): Remove this, move everything over to disk_cache:: use.
base::TaskScheduler::GetInstance()->FlushForTesting();
}
uint32_t SimpleBackendImpl::GetNewEntryPriority(
net::RequestPriority request_priority) {
if (base::FeatureList::IsEnabled(kPrioritizedSimpleCacheTasks)) {
// Lower priority is better, so give high network priority the least bump.
return ((net::RequestPriority::MAXIMUM_PRIORITY - request_priority) *
10000) +
entry_count_++;
}
return 0;
}
} // namespace disk_cache