gecko-dev/netwerk/cache2/CacheStorageService.cpp

2370 строки
72 KiB
C++

/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim: set ts=8 sts=2 et sw=2 tw=80: */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#include "CacheLog.h"
#include "CacheStorageService.h"
#include "CacheFileIOManager.h"
#include "CacheObserver.h"
#include "CacheIndex.h"
#include "CacheIndexIterator.h"
#include "CacheStorage.h"
#include "CacheEntry.h"
#include "CacheFileUtils.h"
#include "nsICacheStorageVisitor.h"
#include "nsIObserverService.h"
#include "nsIFile.h"
#include "nsIURI.h"
#include "nsINetworkPredictor.h"
#include "nsCOMPtr.h"
#include "nsContentUtils.h"
#include "nsNetCID.h"
#include "nsNetUtil.h"
#include "nsServiceManagerUtils.h"
#include "nsXULAppAPI.h"
#include "mozilla/AtomicBitfields.h"
#include "mozilla/TimeStamp.h"
#include "mozilla/DebugOnly.h"
#include "mozilla/Services.h"
#include "mozilla/StoragePrincipalHelper.h"
#include "mozilla/IntegerPrintfMacros.h"
#include "mozilla/Telemetry.h"
#include "mozilla/StaticPrefs_network.h"
namespace mozilla::net {
namespace {
void AppendMemoryStorageTag(nsAutoCString& key) {
// Using DEL as the very last ascii-7 character we can use in the list of
// attributes
key.Append('\x7f');
key.Append(',');
}
} // namespace
// Not defining as static or class member of CacheStorageService since
// it would otherwise need to include CacheEntry.h and that then would
// need to be exported to make nsNetModule.cpp compilable.
using GlobalEntryTables = nsClassHashtable<nsCStringHashKey, CacheEntryTable>;
/**
* Keeps tables of entries. There is one entries table for each distinct load
* context type. The distinction is based on following load context info
* states: <isPrivate|isAnon|inIsolatedMozBrowser> which builds a mapping
* key.
*
* Thread-safe to access, protected by the service mutex.
*/
static GlobalEntryTables* sGlobalEntryTables;
CacheMemoryConsumer::CacheMemoryConsumer(uint32_t aFlags) {
StoreFlags(aFlags);
}
void CacheMemoryConsumer::DoMemoryReport(uint32_t aCurrentSize) {
if (!(LoadFlags() & DONT_REPORT) && CacheStorageService::Self()) {
CacheStorageService::Self()->OnMemoryConsumptionChange(this, aCurrentSize);
}
}
CacheStorageService::MemoryPool::MemoryPool(EType aType) : mType(aType) {}
CacheStorageService::MemoryPool::~MemoryPool() {
if (mMemorySize != 0) {
NS_ERROR(
"Network cache reported memory consumption is not at 0, probably "
"leaking?");
}
}
uint32_t CacheStorageService::MemoryPool::Limit() const {
uint32_t limit = 0;
switch (mType) {
case DISK:
limit = CacheObserver::MetadataMemoryLimit();
break;
case MEMORY:
limit = CacheObserver::MemoryCacheCapacity();
break;
default:
MOZ_CRASH("Bad pool type");
}
static const uint32_t kMaxLimit = 0x3FFFFF;
if (limit > kMaxLimit) {
LOG((" a memory limit (%u) is unexpectedly high, clipping to %u", limit,
kMaxLimit));
limit = kMaxLimit;
}
return limit << 10;
}
NS_IMPL_ISUPPORTS(CacheStorageService, nsICacheStorageService,
nsIMemoryReporter, nsITimerCallback, nsICacheTesting,
nsINamed)
CacheStorageService* CacheStorageService::sSelf = nullptr;
CacheStorageService::CacheStorageService() {
CacheFileIOManager::Init();
MOZ_ASSERT(XRE_IsParentProcess());
MOZ_ASSERT(!sSelf);
sSelf = this;
sGlobalEntryTables = new GlobalEntryTables();
RegisterStrongMemoryReporter(this);
}
CacheStorageService::~CacheStorageService() {
LOG(("CacheStorageService::~CacheStorageService"));
sSelf = nullptr;
}
void CacheStorageService::Shutdown() {
mozilla::MutexAutoLock lock(mLock);
if (mShutdown) return;
LOG(("CacheStorageService::Shutdown - start"));
mShutdown = true;
nsCOMPtr<nsIRunnable> event =
NewRunnableMethod("net::CacheStorageService::ShutdownBackground", this,
&CacheStorageService::ShutdownBackground);
Dispatch(event);
#ifdef NS_FREE_PERMANENT_DATA
sGlobalEntryTables->Clear();
delete sGlobalEntryTables;
#endif
sGlobalEntryTables = nullptr;
LOG(("CacheStorageService::Shutdown - done"));
}
void CacheStorageService::ShutdownBackground() {
LOG(("CacheStorageService::ShutdownBackground - start"));
MOZ_ASSERT(IsOnManagementThread());
{
mozilla::MutexAutoLock lock(mLock);
// Cancel purge timer to avoid leaking.
if (mPurgeTimer) {
LOG((" freeing the timer"));
mPurgeTimer->Cancel();
}
}
#ifdef NS_FREE_PERMANENT_DATA
Pool(false).mFrecencyArray.Clear();
Pool(false).mExpirationArray.Clear();
Pool(true).mFrecencyArray.Clear();
Pool(true).mExpirationArray.Clear();
#endif
LOG(("CacheStorageService::ShutdownBackground - done"));
}
// Internal management methods
namespace {
// WalkCacheRunnable
// Base class for particular storage entries visiting
class WalkCacheRunnable : public Runnable,
public CacheStorageService::EntryInfoCallback {
protected:
WalkCacheRunnable(nsICacheStorageVisitor* aVisitor, bool aVisitEntries)
: Runnable("net::WalkCacheRunnable"),
mService(CacheStorageService::Self()),
mCallback(aVisitor) {
MOZ_ASSERT(NS_IsMainThread());
StoreNotifyStorage(true);
StoreVisitEntries(aVisitEntries);
}
virtual ~WalkCacheRunnable() {
if (mCallback) {
ProxyReleaseMainThread("WalkCacheRunnable::mCallback", mCallback);
}
}
RefPtr<CacheStorageService> mService;
nsCOMPtr<nsICacheStorageVisitor> mCallback;
uint64_t mSize{0};
// clang-format off
MOZ_ATOMIC_BITFIELDS(mAtomicBitfields, 8, (
(bool, NotifyStorage, 1),
(bool, VisitEntries, 1)
))
// clang-format on
Atomic<bool> mCancel{false};
};
// WalkMemoryCacheRunnable
// Responsible to visit memory storage and walk
// all entries on it asynchronously.
class WalkMemoryCacheRunnable : public WalkCacheRunnable {
public:
WalkMemoryCacheRunnable(nsILoadContextInfo* aLoadInfo, bool aVisitEntries,
nsICacheStorageVisitor* aVisitor)
: WalkCacheRunnable(aVisitor, aVisitEntries) {
CacheFileUtils::AppendKeyPrefix(aLoadInfo, mContextKey);
MOZ_ASSERT(NS_IsMainThread());
}
nsresult Walk() { return mService->Dispatch(this); }
private:
NS_IMETHOD Run() override {
if (CacheStorageService::IsOnManagementThread()) {
LOG(("WalkMemoryCacheRunnable::Run - collecting [this=%p]", this));
// First, walk, count and grab all entries from the storage
mozilla::MutexAutoLock lock(CacheStorageService::Self()->Lock());
if (!CacheStorageService::IsRunning()) return NS_ERROR_NOT_INITIALIZED;
for (const auto& entries : sGlobalEntryTables->Values()) {
if (entries->Type() != CacheEntryTable::MEMORY_ONLY) {
continue;
}
for (CacheEntry* entry : entries->Values()) {
MOZ_ASSERT(!entry->IsUsingDisk());
mSize += entry->GetMetadataMemoryConsumption();
int64_t size;
if (NS_SUCCEEDED(entry->GetDataSize(&size))) {
mSize += size;
}
mEntryArray.AppendElement(entry);
}
}
// Next, we dispatch to the main thread
} else if (NS_IsMainThread()) {
LOG(("WalkMemoryCacheRunnable::Run - notifying [this=%p]", this));
if (LoadNotifyStorage()) {
LOG((" storage"));
uint64_t capacity = CacheObserver::MemoryCacheCapacity();
capacity <<= 10; // kilobytes to bytes
// Second, notify overall storage info
mCallback->OnCacheStorageInfo(mEntryArray.Length(), mSize, capacity,
nullptr);
if (!LoadVisitEntries()) return NS_OK; // done
StoreNotifyStorage(false);
} else {
LOG((" entry [left=%zu, canceled=%d]", mEntryArray.Length(),
(bool)mCancel));
// Third, notify each entry until depleted or canceled
if (!mEntryArray.Length() || mCancel) {
mCallback->OnCacheEntryVisitCompleted();
return NS_OK; // done
}
// Grab the next entry
RefPtr<CacheEntry> entry = mEntryArray[0];
mEntryArray.RemoveElementAt(0);
// Invokes this->OnEntryInfo, that calls the callback with all
// information of the entry.
CacheStorageService::GetCacheEntryInfo(entry, this);
}
} else {
MOZ_CRASH("Bad thread");
return NS_ERROR_FAILURE;
}
NS_DispatchToMainThread(this);
return NS_OK;
}
virtual ~WalkMemoryCacheRunnable() {
if (mCallback) {
ProxyReleaseMainThread("WalkMemoryCacheRunnable::mCallback", mCallback);
}
}
virtual void OnEntryInfo(const nsACString& aURISpec,
const nsACString& aIdEnhance, int64_t aDataSize,
int64_t aAltDataSize, uint32_t aFetchCount,
uint32_t aLastModifiedTime, uint32_t aExpirationTime,
bool aPinned, nsILoadContextInfo* aInfo) override {
nsresult rv;
nsCOMPtr<nsIURI> uri;
rv = NS_NewURI(getter_AddRefs(uri), aURISpec);
if (NS_FAILED(rv)) {
return;
}
rv = mCallback->OnCacheEntryInfo(uri, aIdEnhance, aDataSize, aAltDataSize,
aFetchCount, aLastModifiedTime,
aExpirationTime, aPinned, aInfo);
if (NS_FAILED(rv)) {
LOG((" callback failed, canceling the walk"));
mCancel = true;
}
}
private:
nsCString mContextKey;
nsTArray<RefPtr<CacheEntry>> mEntryArray;
};
// WalkDiskCacheRunnable
// Using the cache index information to get the list of files per context.
class WalkDiskCacheRunnable : public WalkCacheRunnable {
public:
WalkDiskCacheRunnable(nsILoadContextInfo* aLoadInfo, bool aVisitEntries,
nsICacheStorageVisitor* aVisitor)
: WalkCacheRunnable(aVisitor, aVisitEntries),
mLoadInfo(aLoadInfo),
mPass(COLLECT_STATS),
mCount(0) {}
nsresult Walk() {
// TODO, bug 998693
// Initial index build should be forced here so that about:cache soon
// after startup gives some meaningfull results.
// Dispatch to the INDEX level in hope that very recent cache entries
// information gets to the index list before we grab the index iterator
// for the first time. This tries to avoid miss of entries that has
// been created right before the visit is required.
RefPtr<CacheIOThread> thread = CacheFileIOManager::IOThread();
NS_ENSURE_TRUE(thread, NS_ERROR_NOT_INITIALIZED);
return thread->Dispatch(this, CacheIOThread::INDEX);
}
private:
// Invokes OnCacheEntryInfo callback for each single found entry.
// There is one instance of this class per one entry.
class OnCacheEntryInfoRunnable : public Runnable {
public:
explicit OnCacheEntryInfoRunnable(WalkDiskCacheRunnable* aWalker)
: Runnable("net::WalkDiskCacheRunnable::OnCacheEntryInfoRunnable"),
mWalker(aWalker) {}
NS_IMETHOD Run() override {
MOZ_ASSERT(NS_IsMainThread());
nsresult rv;
nsCOMPtr<nsIURI> uri;
rv = NS_NewURI(getter_AddRefs(uri), mURISpec);
if (NS_FAILED(rv)) {
return NS_OK;
}
rv = mWalker->mCallback->OnCacheEntryInfo(
uri, mIdEnhance, mDataSize, mAltDataSize, mFetchCount,
mLastModifiedTime, mExpirationTime, mPinned, mInfo);
if (NS_FAILED(rv)) {
mWalker->mCancel = true;
}
return NS_OK;
}
RefPtr<WalkDiskCacheRunnable> mWalker;
nsCString mURISpec;
nsCString mIdEnhance;
int64_t mDataSize{0};
int64_t mAltDataSize{0};
uint32_t mFetchCount{0};
uint32_t mLastModifiedTime{0};
uint32_t mExpirationTime{0};
bool mPinned{false};
nsCOMPtr<nsILoadContextInfo> mInfo;
};
NS_IMETHOD Run() override {
// The main loop
nsresult rv;
if (CacheStorageService::IsOnManagementThread()) {
switch (mPass) {
case COLLECT_STATS:
// Get quickly the cache stats.
uint32_t size;
rv = CacheIndex::GetCacheStats(mLoadInfo, &size, &mCount);
if (NS_FAILED(rv)) {
if (LoadVisitEntries()) {
// both onStorageInfo and onCompleted are expected
NS_DispatchToMainThread(this);
}
return NS_DispatchToMainThread(this);
}
mSize = static_cast<uint64_t>(size) << 10;
// Invoke onCacheStorageInfo with valid information.
NS_DispatchToMainThread(this);
if (!LoadVisitEntries()) {
return NS_OK; // done
}
mPass = ITERATE_METADATA;
[[fallthrough]];
case ITERATE_METADATA:
// Now grab the context iterator.
if (!mIter) {
rv =
CacheIndex::GetIterator(mLoadInfo, true, getter_AddRefs(mIter));
if (NS_FAILED(rv)) {
// Invoke onCacheEntryVisitCompleted now
return NS_DispatchToMainThread(this);
}
}
while (!mCancel && !CacheObserver::ShuttingDown()) {
if (CacheIOThread::YieldAndRerun()) return NS_OK;
SHA1Sum::Hash hash;
rv = mIter->GetNextHash(&hash);
if (NS_FAILED(rv)) break; // done (or error?)
// This synchronously invokes OnEntryInfo on this class where we
// redispatch to the main thread for the consumer callback.
CacheFileIOManager::GetEntryInfo(&hash, this);
}
// Invoke onCacheEntryVisitCompleted on the main thread
NS_DispatchToMainThread(this);
}
} else if (NS_IsMainThread()) {
if (LoadNotifyStorage()) {
nsCOMPtr<nsIFile> dir;
CacheFileIOManager::GetCacheDirectory(getter_AddRefs(dir));
uint64_t capacity = CacheObserver::DiskCacheCapacity();
capacity <<= 10; // kilobytes to bytes
mCallback->OnCacheStorageInfo(mCount, mSize, capacity, dir);
StoreNotifyStorage(false);
} else {
mCallback->OnCacheEntryVisitCompleted();
}
} else {
MOZ_CRASH("Bad thread");
return NS_ERROR_FAILURE;
}
return NS_OK;
}
virtual void OnEntryInfo(const nsACString& aURISpec,
const nsACString& aIdEnhance, int64_t aDataSize,
int64_t aAltDataSize, uint32_t aFetchCount,
uint32_t aLastModifiedTime, uint32_t aExpirationTime,
bool aPinned, nsILoadContextInfo* aInfo) override {
// Called directly from CacheFileIOManager::GetEntryInfo.
// Invoke onCacheEntryInfo on the main thread for this entry.
RefPtr<OnCacheEntryInfoRunnable> info = new OnCacheEntryInfoRunnable(this);
info->mURISpec = aURISpec;
info->mIdEnhance = aIdEnhance;
info->mDataSize = aDataSize;
info->mAltDataSize = aAltDataSize;
info->mFetchCount = aFetchCount;
info->mLastModifiedTime = aLastModifiedTime;
info->mExpirationTime = aExpirationTime;
info->mPinned = aPinned;
info->mInfo = aInfo;
NS_DispatchToMainThread(info);
}
RefPtr<nsILoadContextInfo> mLoadInfo;
enum {
// First, we collect stats for the load context.
COLLECT_STATS,
// Second, if demanded, we iterate over the entries gethered
// from the iterator and call CacheFileIOManager::GetEntryInfo
// for each found entry.
ITERATE_METADATA,
} mPass;
RefPtr<CacheIndexIterator> mIter;
uint32_t mCount;
};
} // namespace
void CacheStorageService::DropPrivateBrowsingEntries() {
mozilla::MutexAutoLock lock(mLock);
if (mShutdown) return;
nsTArray<nsCString> keys;
for (const nsACString& key : sGlobalEntryTables->Keys()) {
nsCOMPtr<nsILoadContextInfo> info = CacheFileUtils::ParseKey(key);
if (info && info->IsPrivate()) {
keys.AppendElement(key);
}
}
for (uint32_t i = 0; i < keys.Length(); ++i) {
DoomStorageEntries(keys[i], nullptr, true, false, nullptr);
}
}
// Helper methods
// static
bool CacheStorageService::IsOnManagementThread() {
RefPtr<CacheStorageService> service = Self();
if (!service) return false;
nsCOMPtr<nsIEventTarget> target = service->Thread();
if (!target) return false;
bool currentThread;
nsresult rv = target->IsOnCurrentThread(&currentThread);
return NS_SUCCEEDED(rv) && currentThread;
}
already_AddRefed<nsIEventTarget> CacheStorageService::Thread() const {
return CacheFileIOManager::IOTarget();
}
nsresult CacheStorageService::Dispatch(nsIRunnable* aEvent) {
RefPtr<CacheIOThread> cacheIOThread = CacheFileIOManager::IOThread();
if (!cacheIOThread) return NS_ERROR_NOT_AVAILABLE;
return cacheIOThread->Dispatch(aEvent, CacheIOThread::MANAGEMENT);
}
namespace CacheStorageEvictHelper {
nsresult ClearStorage(bool const aPrivate, bool const aAnonymous,
OriginAttributes& aOa) {
nsresult rv;
aOa.SyncAttributesWithPrivateBrowsing(aPrivate);
RefPtr<LoadContextInfo> info = GetLoadContextInfo(aAnonymous, aOa);
nsCOMPtr<nsICacheStorage> storage;
RefPtr<CacheStorageService> service = CacheStorageService::Self();
NS_ENSURE_TRUE(service, NS_ERROR_FAILURE);
// Clear disk storage
rv = service->DiskCacheStorage(info, getter_AddRefs(storage));
NS_ENSURE_SUCCESS(rv, rv);
rv = storage->AsyncEvictStorage(nullptr);
NS_ENSURE_SUCCESS(rv, rv);
// Clear memory storage
rv = service->MemoryCacheStorage(info, getter_AddRefs(storage));
NS_ENSURE_SUCCESS(rv, rv);
rv = storage->AsyncEvictStorage(nullptr);
NS_ENSURE_SUCCESS(rv, rv);
return NS_OK;
}
nsresult Run(OriginAttributes& aOa) {
nsresult rv;
// Clear all [private X anonymous] combinations
rv = ClearStorage(false, false, aOa);
NS_ENSURE_SUCCESS(rv, rv);
rv = ClearStorage(false, true, aOa);
NS_ENSURE_SUCCESS(rv, rv);
rv = ClearStorage(true, false, aOa);
NS_ENSURE_SUCCESS(rv, rv);
rv = ClearStorage(true, true, aOa);
NS_ENSURE_SUCCESS(rv, rv);
return NS_OK;
}
} // namespace CacheStorageEvictHelper
// nsICacheStorageService
NS_IMETHODIMP CacheStorageService::MemoryCacheStorage(
nsILoadContextInfo* aLoadContextInfo, nsICacheStorage** _retval) {
NS_ENSURE_ARG(_retval);
nsCOMPtr<nsICacheStorage> storage =
new CacheStorage(aLoadContextInfo, false, false, false);
storage.forget(_retval);
return NS_OK;
}
NS_IMETHODIMP CacheStorageService::DiskCacheStorage(
nsILoadContextInfo* aLoadContextInfo, nsICacheStorage** _retval) {
NS_ENSURE_ARG(_retval);
// TODO save some heap granularity - cache commonly used storages.
// When disk cache is disabled, still provide a storage, but just keep stuff
// in memory.
bool useDisk = CacheObserver::UseDiskCache();
nsCOMPtr<nsICacheStorage> storage = new CacheStorage(
aLoadContextInfo, useDisk, false /* size limit */, false /* don't pin */);
storage.forget(_retval);
return NS_OK;
}
NS_IMETHODIMP CacheStorageService::PinningCacheStorage(
nsILoadContextInfo* aLoadContextInfo, nsICacheStorage** _retval) {
NS_ENSURE_ARG(aLoadContextInfo);
NS_ENSURE_ARG(_retval);
// When disk cache is disabled don't pretend we cache.
if (!CacheObserver::UseDiskCache()) {
return NS_ERROR_NOT_AVAILABLE;
}
nsCOMPtr<nsICacheStorage> storage =
new CacheStorage(aLoadContextInfo, true /* use disk */,
true /* ignore size checks */, true /* pin */);
storage.forget(_retval);
return NS_OK;
}
NS_IMETHODIMP CacheStorageService::Clear() {
nsresult rv;
// Tell the index to block notification to AsyncGetDiskConsumption.
// Will be allowed again from CacheFileContextEvictor::EvictEntries()
// when all the context have been removed from disk.
CacheIndex::OnAsyncEviction(true);
mozilla::MutexAutoLock lock(mLock);
{
mozilla::MutexAutoLock forcedValidEntriesLock(mForcedValidEntriesLock);
mForcedValidEntries.Clear();
}
NS_ENSURE_TRUE(!mShutdown, NS_ERROR_NOT_INITIALIZED);
const auto keys = ToTArray<nsTArray<nsCString>>(sGlobalEntryTables->Keys());
for (const auto& key : keys) {
DoomStorageEntries(key, nullptr, true, false, nullptr);
}
// Passing null as a load info means to evict all contexts.
// EvictByContext() respects the entry pinning. EvictAll() does not.
rv = CacheFileIOManager::EvictByContext(nullptr, false, u""_ns);
NS_ENSURE_SUCCESS(rv, rv);
return NS_OK;
}
NS_IMETHODIMP CacheStorageService::ClearOrigin(nsIPrincipal* aPrincipal) {
nsresult rv;
if (NS_WARN_IF(!aPrincipal)) {
return NS_ERROR_FAILURE;
}
nsAutoString origin;
rv = nsContentUtils::GetUTFOrigin(aPrincipal, origin);
NS_ENSURE_SUCCESS(rv, rv);
rv = ClearOriginInternal(origin, aPrincipal->OriginAttributesRef(), true);
NS_ENSURE_SUCCESS(rv, rv);
rv = ClearOriginInternal(origin, aPrincipal->OriginAttributesRef(), false);
NS_ENSURE_SUCCESS(rv, rv);
return NS_OK;
}
NS_IMETHODIMP CacheStorageService::ClearOriginAttributes(
const nsAString& aOriginAttributes) {
nsresult rv;
if (NS_WARN_IF(aOriginAttributes.IsEmpty())) {
return NS_ERROR_FAILURE;
}
OriginAttributes oa;
if (!oa.Init(aOriginAttributes)) {
NS_ERROR("Could not parse the argument for OriginAttributes");
return NS_ERROR_FAILURE;
}
rv = CacheStorageEvictHelper::Run(oa);
NS_ENSURE_SUCCESS(rv, rv);
return NS_OK;
}
static bool RemoveExactEntry(CacheEntryTable* aEntries, nsACString const& aKey,
CacheEntry* aEntry, bool aOverwrite) {
RefPtr<CacheEntry> existingEntry;
if (!aEntries->Get(aKey, getter_AddRefs(existingEntry))) {
LOG(("RemoveExactEntry [entry=%p already gone]", aEntry));
return false; // Already removed...
}
if (!aOverwrite && existingEntry != aEntry) {
LOG(("RemoveExactEntry [entry=%p already replaced]", aEntry));
return false; // Already replaced...
}
LOG(("RemoveExactEntry [entry=%p removed]", aEntry));
aEntries->Remove(aKey);
return true;
}
NS_IMETHODIMP CacheStorageService::ClearBaseDomain(
const nsAString& aBaseDomain) {
if (sGlobalEntryTables) {
mozilla::MutexAutoLock lock(mLock);
if (mShutdown) return NS_ERROR_NOT_AVAILABLE;
nsCString cBaseDomain = NS_ConvertUTF16toUTF8(aBaseDomain);
nsTArray<nsCString> keys;
for (const auto& globalEntry : *sGlobalEntryTables) {
// Match by partitionKey base domain. This should cover most cache entries
// because we statically partition the cache. Most first party cache
// entries will also have a partitionKey set where the partitionKey base
// domain will match the entry URI base domain.
const nsACString& key = globalEntry.GetKey();
nsCOMPtr<nsILoadContextInfo> info =
CacheFileUtils::ParseKey(globalEntry.GetKey());
if (info &&
StoragePrincipalHelper::PartitionKeyHasBaseDomain(
info->OriginAttributesPtr()->mPartitionKey, aBaseDomain)) {
keys.AppendElement(key);
continue;
}
// If we didn't get a partitionKey match, try to match by entry URI. This
// requires us to iterate over all entries.
CacheEntryTable* table = globalEntry.GetWeak();
MOZ_ASSERT(table);
nsTArray<RefPtr<CacheEntry>> entriesToDelete;
for (CacheEntry* entry : table->Values()) {
nsCOMPtr<nsIURI> uri;
nsresult rv = NS_NewURI(getter_AddRefs(uri), entry->GetURI());
if (NS_WARN_IF(NS_FAILED(rv))) {
continue;
}
nsAutoCString host;
rv = uri->GetHost(host);
// Some entries may not have valid hosts. We can skip them.
if (NS_FAILED(rv) || host.IsEmpty()) {
continue;
}
bool hasRootDomain = false;
rv = HasRootDomain(host, cBaseDomain, &hasRootDomain);
if (NS_WARN_IF(NS_FAILED(rv))) {
continue;
}
if (hasRootDomain) {
entriesToDelete.AppendElement(entry);
}
}
// Clear individual matched entries.
for (RefPtr<CacheEntry>& entry : entriesToDelete) {
nsAutoCString entryKey;
nsresult rv = entry->HashingKey(entryKey);
if (NS_FAILED(rv)) {
NS_ERROR("aEntry->HashingKey() failed?");
return rv;
}
RemoveExactEntry(table, entryKey, entry, false /* don't overwrite */);
}
}
// Clear matched keys.
for (uint32_t i = 0; i < keys.Length(); ++i) {
DoomStorageEntries(keys[i], nullptr, true, false, nullptr);
}
}
return CacheFileIOManager::EvictByContext(nullptr, false /* pinned */, u""_ns,
aBaseDomain);
}
nsresult CacheStorageService::ClearOriginInternal(
const nsAString& aOrigin, const OriginAttributes& aOriginAttributes,
bool aAnonymous) {
nsresult rv;
RefPtr<LoadContextInfo> info =
GetLoadContextInfo(aAnonymous, aOriginAttributes);
if (NS_WARN_IF(!info)) {
return NS_ERROR_FAILURE;
}
mozilla::MutexAutoLock lock(mLock);
if (sGlobalEntryTables) {
for (const auto& globalEntry : *sGlobalEntryTables) {
bool matches = false;
rv = CacheFileUtils::KeyMatchesLoadContextInfo(globalEntry.GetKey(), info,
&matches);
NS_ENSURE_SUCCESS(rv, rv);
if (!matches) {
continue;
}
CacheEntryTable* table = globalEntry.GetWeak();
MOZ_ASSERT(table);
nsTArray<RefPtr<CacheEntry>> entriesToDelete;
for (CacheEntry* entry : table->Values()) {
nsCOMPtr<nsIURI> uri;
rv = NS_NewURI(getter_AddRefs(uri), entry->GetURI());
NS_ENSURE_SUCCESS(rv, rv);
nsAutoString origin;
rv = nsContentUtils::GetUTFOrigin(uri, origin);
NS_ENSURE_SUCCESS(rv, rv);
if (origin != aOrigin) {
continue;
}
entriesToDelete.AppendElement(entry);
}
for (RefPtr<CacheEntry>& entry : entriesToDelete) {
nsAutoCString entryKey;
rv = entry->HashingKey(entryKey);
if (NS_FAILED(rv)) {
NS_ERROR("aEntry->HashingKey() failed?");
return rv;
}
RemoveExactEntry(table, entryKey, entry, false /* don't overwrite */);
}
}
}
rv = CacheFileIOManager::EvictByContext(info, false /* pinned */, aOrigin);
NS_ENSURE_SUCCESS(rv, rv);
return NS_OK;
}
NS_IMETHODIMP CacheStorageService::PurgeFromMemory(uint32_t aWhat) {
uint32_t what;
switch (aWhat) {
case PURGE_DISK_DATA_ONLY:
what = CacheEntry::PURGE_DATA_ONLY_DISK_BACKED;
break;
case PURGE_DISK_ALL:
what = CacheEntry::PURGE_WHOLE_ONLY_DISK_BACKED;
break;
case PURGE_EVERYTHING:
what = CacheEntry::PURGE_WHOLE;
break;
default:
return NS_ERROR_INVALID_ARG;
}
nsCOMPtr<nsIRunnable> event = new PurgeFromMemoryRunnable(this, what);
return Dispatch(event);
}
NS_IMETHODIMP CacheStorageService::PurgeFromMemoryRunnable::Run() {
if (NS_IsMainThread()) {
nsCOMPtr<nsIObserverService> observerService =
mozilla::services::GetObserverService();
if (observerService) {
observerService->NotifyObservers(
nullptr, "cacheservice:purge-memory-pools", nullptr);
}
return NS_OK;
}
if (mService) {
// TODO not all flags apply to both pools
mService->Pool(true).PurgeAll(mWhat);
mService->Pool(false).PurgeAll(mWhat);
mService = nullptr;
}
NS_DispatchToMainThread(this);
return NS_OK;
}
NS_IMETHODIMP CacheStorageService::AsyncGetDiskConsumption(
nsICacheStorageConsumptionObserver* aObserver) {
NS_ENSURE_ARG(aObserver);
nsresult rv;
rv = CacheIndex::AsyncGetDiskConsumption(aObserver);
NS_ENSURE_SUCCESS(rv, rv);
return NS_OK;
}
NS_IMETHODIMP CacheStorageService::GetIoTarget(nsIEventTarget** aEventTarget) {
NS_ENSURE_ARG(aEventTarget);
nsCOMPtr<nsIEventTarget> ioTarget = CacheFileIOManager::IOTarget();
ioTarget.forget(aEventTarget);
return NS_OK;
}
NS_IMETHODIMP CacheStorageService::AsyncVisitAllStorages(
nsICacheStorageVisitor* aVisitor, bool aVisitEntries) {
LOG(("CacheStorageService::AsyncVisitAllStorages [cb=%p]", aVisitor));
NS_ENSURE_FALSE(mShutdown, NS_ERROR_NOT_INITIALIZED);
// Walking the disk cache also walks the memory cache.
RefPtr<WalkDiskCacheRunnable> event =
new WalkDiskCacheRunnable(nullptr, aVisitEntries, aVisitor);
return event->Walk();
}
// Methods used by CacheEntry for management of in-memory structures.
namespace {
class FrecencyComparator {
public:
bool Equals(CacheEntry* a, CacheEntry* b) const {
return a->GetFrecency() == b->GetFrecency();
}
bool LessThan(CacheEntry* a, CacheEntry* b) const {
// We deliberately want to keep the '0' frecency entries at the tail of the
// aray, because these are new entries and would just slow down purging of
// the pools based on frecency.
if (a->GetFrecency() == 0.0 && b->GetFrecency() > 0.0) {
return false;
}
if (a->GetFrecency() > 0.0 && b->GetFrecency() == 0.0) {
return true;
}
return a->GetFrecency() < b->GetFrecency();
}
};
class ExpirationComparator {
public:
bool Equals(CacheEntry* a, CacheEntry* b) const {
return a->GetExpirationTime() == b->GetExpirationTime();
}
bool LessThan(CacheEntry* a, CacheEntry* b) const {
return a->GetExpirationTime() < b->GetExpirationTime();
}
};
} // namespace
void CacheStorageService::RegisterEntry(CacheEntry* aEntry) {
MOZ_ASSERT(IsOnManagementThread());
if (mShutdown || !aEntry->CanRegister()) return;
TelemetryRecordEntryCreation(aEntry);
LOG(("CacheStorageService::RegisterEntry [entry=%p]", aEntry));
MemoryPool& pool = Pool(aEntry->IsUsingDisk());
pool.mFrecencyArray.AppendElement(aEntry);
pool.mExpirationArray.AppendElement(aEntry);
aEntry->SetRegistered(true);
}
void CacheStorageService::UnregisterEntry(CacheEntry* aEntry) {
MOZ_ASSERT(IsOnManagementThread());
if (!aEntry->IsRegistered()) return;
TelemetryRecordEntryRemoval(aEntry);
LOG(("CacheStorageService::UnregisterEntry [entry=%p]", aEntry));
MemoryPool& pool = Pool(aEntry->IsUsingDisk());
mozilla::DebugOnly<bool> removedFrecency =
pool.mFrecencyArray.RemoveElement(aEntry);
mozilla::DebugOnly<bool> removedExpiration =
pool.mExpirationArray.RemoveElement(aEntry);
MOZ_ASSERT(mShutdown || (removedFrecency && removedExpiration));
// Note: aEntry->CanRegister() since now returns false
aEntry->SetRegistered(false);
}
static bool AddExactEntry(CacheEntryTable* aEntries, nsACString const& aKey,
CacheEntry* aEntry, bool aOverwrite) {
RefPtr<CacheEntry> existingEntry;
if (!aOverwrite && aEntries->Get(aKey, getter_AddRefs(existingEntry))) {
bool equals = existingEntry == aEntry;
LOG(("AddExactEntry [entry=%p equals=%d]", aEntry, equals));
return equals; // Already there...
}
LOG(("AddExactEntry [entry=%p put]", aEntry));
aEntries->InsertOrUpdate(aKey, RefPtr{aEntry});
return true;
}
bool CacheStorageService::RemoveEntry(CacheEntry* aEntry,
bool aOnlyUnreferenced) {
LOG(("CacheStorageService::RemoveEntry [entry=%p]", aEntry));
nsAutoCString entryKey;
nsresult rv = aEntry->HashingKey(entryKey);
if (NS_FAILED(rv)) {
NS_ERROR("aEntry->HashingKey() failed?");
return false;
}
mozilla::MutexAutoLock lock(mLock);
if (mShutdown) {
LOG((" after shutdown"));
return false;
}
if (aOnlyUnreferenced) {
if (aEntry->IsReferenced()) {
LOG((" still referenced, not removing"));
return false;
}
if (!aEntry->IsUsingDisk() &&
IsForcedValidEntry(aEntry->GetStorageID(), entryKey)) {
LOG((" forced valid, not removing"));
return false;
}
}
CacheEntryTable* entries;
if (sGlobalEntryTables->Get(aEntry->GetStorageID(), &entries)) {
RemoveExactEntry(entries, entryKey, aEntry, false /* don't overwrite */);
}
nsAutoCString memoryStorageID(aEntry->GetStorageID());
AppendMemoryStorageTag(memoryStorageID);
if (sGlobalEntryTables->Get(memoryStorageID, &entries)) {
RemoveExactEntry(entries, entryKey, aEntry, false /* don't overwrite */);
}
return true;
}
void CacheStorageService::RecordMemoryOnlyEntry(CacheEntry* aEntry,
bool aOnlyInMemory,
bool aOverwrite) {
LOG(
("CacheStorageService::RecordMemoryOnlyEntry [entry=%p, memory=%d, "
"overwrite=%d]",
aEntry, aOnlyInMemory, aOverwrite));
// This method is responsible to put this entry to a special record hashtable
// that contains only entries that are stored in memory.
// Keep in mind that every entry, regardless of whether is in-memory-only or
// not is always recorded in the storage master hash table, the one identified
// by CacheEntry.StorageID().
mLock.AssertCurrentThreadOwns();
if (mShutdown) {
LOG((" after shutdown"));
return;
}
nsresult rv;
nsAutoCString entryKey;
rv = aEntry->HashingKey(entryKey);
if (NS_FAILED(rv)) {
NS_ERROR("aEntry->HashingKey() failed?");
return;
}
CacheEntryTable* entries = nullptr;
nsAutoCString memoryStorageID(aEntry->GetStorageID());
AppendMemoryStorageTag(memoryStorageID);
if (!sGlobalEntryTables->Get(memoryStorageID, &entries)) {
if (!aOnlyInMemory) {
LOG((" not recorded as memory only"));
return;
}
entries = sGlobalEntryTables
->InsertOrUpdate(
memoryStorageID,
MakeUnique<CacheEntryTable>(CacheEntryTable::MEMORY_ONLY))
.get();
LOG((" new memory-only storage table for %s", memoryStorageID.get()));
}
if (aOnlyInMemory) {
AddExactEntry(entries, entryKey, aEntry, aOverwrite);
} else {
RemoveExactEntry(entries, entryKey, aEntry, aOverwrite);
}
}
// Checks if a cache entry is forced valid (will be loaded directly from cache
// without further validation) - see nsICacheEntry.idl for further details
bool CacheStorageService::IsForcedValidEntry(nsACString const& aContextKey,
nsACString const& aEntryKey) {
return IsForcedValidEntry(aContextKey + aEntryKey);
}
bool CacheStorageService::IsForcedValidEntry(
nsACString const& aContextEntryKey) {
mozilla::MutexAutoLock lock(mForcedValidEntriesLock);
ForcedValidData data;
if (!mForcedValidEntries.Get(aContextEntryKey, &data)) {
return false;
}
if (data.validUntil.IsNull()) {
MOZ_ASSERT_UNREACHABLE("the timeStamp should never be null");
return false;
}
// Entry timeout not reached yet
if (TimeStamp::NowLoRes() <= data.validUntil) {
return true;
}
// Entry timeout has been reached
mForcedValidEntries.Remove(aContextEntryKey);
if (!data.viewed) {
Telemetry::AccumulateCategorical(
Telemetry::LABELS_PREDICTOR_PREFETCH_USE_STATUS::WaitedTooLong);
}
return false;
}
void CacheStorageService::MarkForcedValidEntryUse(nsACString const& aContextKey,
nsACString const& aEntryKey) {
mozilla::MutexAutoLock lock(mForcedValidEntriesLock);
ForcedValidData data;
if (!mForcedValidEntries.Get(aContextKey + aEntryKey, &data)) {
return;
}
data.viewed = true;
mForcedValidEntries.InsertOrUpdate(aContextKey + aEntryKey, data);
}
// Allows a cache entry to be loaded directly from cache without further
// validation - see nsICacheEntry.idl for further details
void CacheStorageService::ForceEntryValidFor(nsACString const& aContextKey,
nsACString const& aEntryKey,
uint32_t aSecondsToTheFuture) {
mozilla::MutexAutoLock lock(mForcedValidEntriesLock);
TimeStamp now = TimeStamp::NowLoRes();
ForcedValidEntriesPrune(now);
ForcedValidData data;
data.validUntil = now + TimeDuration::FromSeconds(aSecondsToTheFuture);
data.viewed = false;
mForcedValidEntries.InsertOrUpdate(aContextKey + aEntryKey, data);
}
void CacheStorageService::RemoveEntryForceValid(nsACString const& aContextKey,
nsACString const& aEntryKey) {
mozilla::MutexAutoLock lock(mForcedValidEntriesLock);
LOG(("CacheStorageService::RemoveEntryForceValid context='%s' entryKey=%s",
aContextKey.BeginReading(), aEntryKey.BeginReading()));
ForcedValidData data;
bool ok = mForcedValidEntries.Get(aContextKey + aEntryKey, &data);
if (ok && !data.viewed) {
Telemetry::AccumulateCategorical(
Telemetry::LABELS_PREDICTOR_PREFETCH_USE_STATUS::WaitedTooLong);
}
mForcedValidEntries.Remove(aContextKey + aEntryKey);
}
// Cleans out the old entries in mForcedValidEntries
void CacheStorageService::ForcedValidEntriesPrune(TimeStamp& now) {
static TimeDuration const oneMinute = TimeDuration::FromSeconds(60);
static TimeStamp dontPruneUntil = now + oneMinute;
if (now < dontPruneUntil) return;
for (auto iter = mForcedValidEntries.Iter(); !iter.Done(); iter.Next()) {
if (iter.Data().validUntil < now) {
if (!iter.Data().viewed) {
Telemetry::AccumulateCategorical(
Telemetry::LABELS_PREDICTOR_PREFETCH_USE_STATUS::WaitedTooLong);
}
iter.Remove();
}
}
dontPruneUntil = now + oneMinute;
}
void CacheStorageService::OnMemoryConsumptionChange(
CacheMemoryConsumer* aConsumer, uint32_t aCurrentMemoryConsumption) {
LOG(("CacheStorageService::OnMemoryConsumptionChange [consumer=%p, size=%u]",
aConsumer, aCurrentMemoryConsumption));
uint32_t savedMemorySize = aConsumer->LoadReportedMemoryConsumption();
if (savedMemorySize == aCurrentMemoryConsumption) return;
// Exchange saved size with current one.
aConsumer->StoreReportedMemoryConsumption(aCurrentMemoryConsumption);
bool usingDisk = !(aConsumer->LoadFlags() & CacheMemoryConsumer::MEMORY_ONLY);
bool overLimit = Pool(usingDisk).OnMemoryConsumptionChange(
savedMemorySize, aCurrentMemoryConsumption);
if (!overLimit) return;
// It's likely the timer has already been set when we get here,
// check outside the lock to save resources.
#ifdef MOZ_TSAN
if (mPurgeTimerActive) {
#else
if (mPurgeTimer) {
#endif
return;
}
// We don't know if this is called under the service lock or not,
// hence rather dispatch.
RefPtr<nsIEventTarget> cacheIOTarget = Thread();
if (!cacheIOTarget) return;
// Dispatch as a priority task, we want to set the purge timer
// ASAP to prevent vain redispatch of this event.
nsCOMPtr<nsIRunnable> event = NewRunnableMethod(
"net::CacheStorageService::SchedulePurgeOverMemoryLimit", this,
&CacheStorageService::SchedulePurgeOverMemoryLimit);
cacheIOTarget->Dispatch(event, nsIEventTarget::DISPATCH_NORMAL);
}
bool CacheStorageService::MemoryPool::OnMemoryConsumptionChange(
uint32_t aSavedMemorySize, uint32_t aCurrentMemoryConsumption) {
mMemorySize -= aSavedMemorySize;
mMemorySize += aCurrentMemoryConsumption;
LOG((" mMemorySize=%u (+%u,-%u)", uint32_t(mMemorySize),
aCurrentMemoryConsumption, aSavedMemorySize));
// Bypass purging when memory has not grew up significantly
if (aCurrentMemoryConsumption <= aSavedMemorySize) return false;
return mMemorySize > Limit();
}
void CacheStorageService::SchedulePurgeOverMemoryLimit() {
LOG(("CacheStorageService::SchedulePurgeOverMemoryLimit"));
mozilla::MutexAutoLock lock(mLock);
if (mShutdown) {
LOG((" past shutdown"));
return;
}
if (mPurgeTimer) {
LOG((" timer already up"));
return;
}
mPurgeTimer = NS_NewTimer();
if (mPurgeTimer) {
#ifdef MOZ_TSAN
mPurgeTimerActive = true;
#endif
nsresult rv;
rv = mPurgeTimer->InitWithCallback(this, 1000, nsITimer::TYPE_ONE_SHOT);
LOG((" timer init rv=0x%08" PRIx32, static_cast<uint32_t>(rv)));
}
}
NS_IMETHODIMP
CacheStorageService::Notify(nsITimer* aTimer) {
LOG(("CacheStorageService::Notify"));
mozilla::MutexAutoLock lock(mLock);
if (aTimer == mPurgeTimer) {
#ifdef MOZ_TSAN
mPurgeTimerActive = false;
#endif
mPurgeTimer = nullptr;
nsCOMPtr<nsIRunnable> event =
NewRunnableMethod("net::CacheStorageService::PurgeOverMemoryLimit",
this, &CacheStorageService::PurgeOverMemoryLimit);
Dispatch(event);
}
return NS_OK;
}
NS_IMETHODIMP
CacheStorageService::GetName(nsACString& aName) {
aName.AssignLiteral("CacheStorageService");
return NS_OK;
}
void CacheStorageService::PurgeOverMemoryLimit() {
MOZ_ASSERT(IsOnManagementThread());
LOG(("CacheStorageService::PurgeOverMemoryLimit"));
static TimeDuration const kFourSeconds = TimeDuration::FromSeconds(4);
TimeStamp now = TimeStamp::NowLoRes();
if (!mLastPurgeTime.IsNull() && now - mLastPurgeTime < kFourSeconds) {
LOG((" bypassed, too soon"));
return;
}
mLastPurgeTime = now;
Pool(true).PurgeOverMemoryLimit();
Pool(false).PurgeOverMemoryLimit();
}
void CacheStorageService::MemoryPool::PurgeOverMemoryLimit() {
TimeStamp start(TimeStamp::Now());
uint32_t const memoryLimit = Limit();
if (mMemorySize > memoryLimit) {
LOG((" memory data consumption over the limit, abandon expired entries"));
PurgeExpired();
}
// No longer makes sense since:
// Memory entries are never purged partially, only as a whole when the memory
// cache limit is overreached.
// Disk entries throw the data away ASAP so that only metadata are kept.
// TODO when this concept of two separate pools is found working, the code
// should clean up.
#if 0
if (mMemorySize > memoryLimit) {
LOG((" memory data consumption over the limit, abandon disk backed data"));
PurgeByFrecency(CacheEntry::PURGE_DATA_ONLY_DISK_BACKED);
}
if (mMemorySize > memoryLimit) {
LOG((" metadata consumtion over the limit, abandon disk backed entries"));
PurgeByFrecency(CacheEntry::PURGE_WHOLE_ONLY_DISK_BACKED);
}
#endif
if (mMemorySize > memoryLimit) {
LOG((" memory data consumption over the limit, abandon any entry"));
PurgeByFrecency(CacheEntry::PURGE_WHOLE);
}
LOG((" purging took %1.2fms", (TimeStamp::Now() - start).ToMilliseconds()));
}
void CacheStorageService::MemoryPool::PurgeExpired() {
MOZ_ASSERT(IsOnManagementThread());
mExpirationArray.Sort(ExpirationComparator());
uint32_t now = NowInSeconds();
uint32_t const memoryLimit = Limit();
for (uint32_t i = 0;
mMemorySize > memoryLimit && i < mExpirationArray.Length();) {
if (CacheIOThread::YieldAndRerun()) return;
RefPtr<CacheEntry> entry = mExpirationArray[i];
uint32_t expirationTime = entry->GetExpirationTime();
if (expirationTime > 0 && expirationTime <= now &&
entry->Purge(CacheEntry::PURGE_WHOLE)) {
LOG((" purged expired, entry=%p, exptime=%u (now=%u)", entry.get(),
entry->GetExpirationTime(), now));
continue;
}
// not purged, move to the next one
++i;
}
}
void CacheStorageService::MemoryPool::PurgeByFrecency(uint32_t aWhat) {
MOZ_ASSERT(IsOnManagementThread());
// Pretend the limit is 10% lower so that we get rid of more entries at one
// shot and save the sorting below.
uint32_t const memoryLimit = Limit() * 0.9;
// Let's do our best and try to shorten the array to at least this size so
// that it doesn't overgrow. We will ignore higher priority events and keep
// looping to try to purge while the array is larget than this size.
static size_t const kFrecencyArrayLengthLimit = 2000;
LOG(("MemoryPool::PurgeByFrecency, len=%zu", mFrecencyArray.Length()));
mFrecencyArray.Sort(FrecencyComparator());
for (uint32_t i = 0;
mMemorySize > memoryLimit && i < mFrecencyArray.Length();) {
if (mFrecencyArray.Length() <= kFrecencyArrayLengthLimit &&
CacheIOThread::YieldAndRerun()) {
LOG(("MemoryPool::PurgeByFrecency interrupted"));
return;
}
RefPtr<CacheEntry> entry = mFrecencyArray[i];
if (entry->Purge(aWhat)) {
LOG((" abandoned (%d), entry=%p, frecency=%1.10f", aWhat, entry.get(),
entry->GetFrecency()));
continue;
}
// not purged, move to the next one
++i;
}
LOG(("MemoryPool::PurgeByFrecency done"));
}
void CacheStorageService::MemoryPool::PurgeAll(uint32_t aWhat) {
LOG(("CacheStorageService::MemoryPool::PurgeAll aWhat=%d", aWhat));
MOZ_ASSERT(IsOnManagementThread());
for (uint32_t i = 0; i < mFrecencyArray.Length();) {
if (CacheIOThread::YieldAndRerun()) return;
RefPtr<CacheEntry> entry = mFrecencyArray[i];
if (entry->Purge(aWhat)) {
LOG((" abandoned entry=%p", entry.get()));
continue;
}
// not purged, move to the next one
++i;
}
}
// Methods exposed to and used by CacheStorage.
nsresult CacheStorageService::AddStorageEntry(CacheStorage const* aStorage,
const nsACString& aURI,
const nsACString& aIdExtension,
uint32_t aFlags,
CacheEntryHandle** aResult) {
NS_ENSURE_FALSE(mShutdown, NS_ERROR_NOT_INITIALIZED);
NS_ENSURE_ARG(aStorage);
nsAutoCString contextKey;
CacheFileUtils::AppendKeyPrefix(aStorage->LoadInfo(), contextKey);
return AddStorageEntry(contextKey, aURI, aIdExtension,
aStorage->WriteToDisk(), aStorage->SkipSizeCheck(),
aStorage->Pinning(), aFlags, aResult);
}
nsresult CacheStorageService::AddStorageEntry(
const nsACString& aContextKey, const nsACString& aURI,
const nsACString& aIdExtension, bool aWriteToDisk, bool aSkipSizeCheck,
bool aPin, uint32_t aFlags, CacheEntryHandle** aResult) {
nsresult rv;
nsAutoCString entryKey;
rv = CacheEntry::HashingKey(""_ns, aIdExtension, aURI, entryKey);
NS_ENSURE_SUCCESS(rv, rv);
LOG(("CacheStorageService::AddStorageEntry [entryKey=%s, contextKey=%s]",
entryKey.get(), aContextKey.BeginReading()));
RefPtr<CacheEntry> entry;
RefPtr<CacheEntryHandle> handle;
{
mozilla::MutexAutoLock lock(mLock);
NS_ENSURE_FALSE(mShutdown, NS_ERROR_NOT_INITIALIZED);
// Ensure storage table
CacheEntryTable* const entries =
sGlobalEntryTables
->LookupOrInsertWith(
aContextKey,
[&aContextKey] {
LOG((" new storage entries table for context '%s'",
aContextKey.BeginReading()));
return MakeUnique<CacheEntryTable>(
CacheEntryTable::ALL_ENTRIES);
})
.get();
bool entryExists = entries->Get(entryKey, getter_AddRefs(entry));
if (!entryExists && (aFlags & nsICacheStorage::OPEN_READONLY) &&
(aFlags & nsICacheStorage::OPEN_SECRETLY) &&
StaticPrefs::network_cache_bug1708673()) {
return NS_ERROR_CACHE_KEY_NOT_FOUND;
}
bool replace = aFlags & nsICacheStorage::OPEN_TRUNCATE;
if (entryExists && !replace) {
// check whether we want to turn this entry to a memory-only.
if (MOZ_UNLIKELY(!aWriteToDisk) && MOZ_LIKELY(entry->IsUsingDisk())) {
LOG((" entry is persistent but we want mem-only, replacing it"));
replace = true;
}
}
// If truncate is demanded, delete and doom the current entry
if (entryExists && replace) {
entries->Remove(entryKey);
LOG((" dooming entry %p for %s because of OPEN_TRUNCATE", entry.get(),
entryKey.get()));
// On purpose called under the lock to prevent races of doom and open on
// I/O thread No need to remove from both memory-only and all-entries
// tables. The new entry will overwrite the shadow entry in its ctor.
entry->DoomAlreadyRemoved();
entry = nullptr;
entryExists = false;
// Would only lead to deleting force-valid timestamp again. We don't need
// the replace information anymore after this point anyway.
replace = false;
}
// Ensure entry for the particular URL
if (!entryExists) {
// When replacing with a new entry, always remove the current force-valid
// timestamp, this is the only place to do it.
if (replace) {
RemoveEntryForceValid(aContextKey, entryKey);
}
// Entry is not in the hashtable or has just been truncated...
entry = new CacheEntry(aContextKey, aURI, aIdExtension, aWriteToDisk,
aSkipSizeCheck, aPin);
entries->InsertOrUpdate(entryKey, RefPtr{entry});
LOG((" new entry %p for %s", entry.get(), entryKey.get()));
}
if (entry) {
// Here, if this entry was not for a long time referenced by any consumer,
// gets again first 'handles count' reference.
handle = entry->NewHandle();
}
}
handle.forget(aResult);
return NS_OK;
}
nsresult CacheStorageService::CheckStorageEntry(CacheStorage const* aStorage,
const nsACString& aURI,
const nsACString& aIdExtension,
bool* aResult) {
nsresult rv;
nsAutoCString contextKey;
CacheFileUtils::AppendKeyPrefix(aStorage->LoadInfo(), contextKey);
if (!aStorage->WriteToDisk()) {
AppendMemoryStorageTag(contextKey);
}
LOG(("CacheStorageService::CheckStorageEntry [uri=%s, eid=%s, contextKey=%s]",
aURI.BeginReading(), aIdExtension.BeginReading(), contextKey.get()));
{
mozilla::MutexAutoLock lock(mLock);
NS_ENSURE_FALSE(mShutdown, NS_ERROR_NOT_INITIALIZED);
nsAutoCString entryKey;
rv = CacheEntry::HashingKey(""_ns, aIdExtension, aURI, entryKey);
NS_ENSURE_SUCCESS(rv, rv);
CacheEntryTable* entries;
if ((*aResult = sGlobalEntryTables->Get(contextKey, &entries)) &&
entries->GetWeak(entryKey, aResult)) {
LOG((" found in hash tables"));
return NS_OK;
}
}
if (!aStorage->WriteToDisk()) {
// Memory entry, nothing more to do.
LOG((" not found in hash tables"));
return NS_OK;
}
// Disk entry, not found in the hashtable, check the index.
nsAutoCString fileKey;
rv = CacheEntry::HashingKey(contextKey, aIdExtension, aURI, fileKey);
CacheIndex::EntryStatus status;
rv = CacheIndex::HasEntry(fileKey, &status);
if (NS_FAILED(rv) || status == CacheIndex::DO_NOT_KNOW) {
LOG((" index doesn't know, rv=0x%08" PRIx32, static_cast<uint32_t>(rv)));
return NS_ERROR_NOT_AVAILABLE;
}
*aResult = status == CacheIndex::EXISTS;
LOG((" %sfound in index", *aResult ? "" : "not "));
return NS_OK;
}
nsresult CacheStorageService::GetCacheIndexEntryAttrs(
CacheStorage const* aStorage, const nsACString& aURI,
const nsACString& aIdExtension, bool* aHasAltData, uint32_t* aFileSizeKb) {
nsresult rv;
nsAutoCString contextKey;
CacheFileUtils::AppendKeyPrefix(aStorage->LoadInfo(), contextKey);
LOG(
("CacheStorageService::GetCacheIndexEntryAttrs [uri=%s, eid=%s, "
"contextKey=%s]",
aURI.BeginReading(), aIdExtension.BeginReading(), contextKey.get()));
nsAutoCString fileKey;
rv = CacheEntry::HashingKey(contextKey, aIdExtension, aURI, fileKey);
if (NS_FAILED(rv)) {
return rv;
}
*aHasAltData = false;
*aFileSizeKb = 0;
auto closure = [&aHasAltData, &aFileSizeKb](const CacheIndexEntry* entry) {
*aHasAltData = entry->GetHasAltData();
*aFileSizeKb = entry->GetFileSize();
};
CacheIndex::EntryStatus status;
rv = CacheIndex::HasEntry(fileKey, &status, closure);
if (NS_FAILED(rv)) {
return rv;
}
if (status != CacheIndex::EXISTS) {
return NS_ERROR_CACHE_KEY_NOT_FOUND;
}
return NS_OK;
}
namespace {
class CacheEntryDoomByKeyCallback : public CacheFileIOListener,
public nsIRunnable {
public:
NS_DECL_THREADSAFE_ISUPPORTS
NS_DECL_NSIRUNNABLE
explicit CacheEntryDoomByKeyCallback(nsICacheEntryDoomCallback* aCallback)
: mCallback(aCallback), mResult(NS_ERROR_NOT_INITIALIZED) {}
private:
virtual ~CacheEntryDoomByKeyCallback();
NS_IMETHOD OnFileOpened(CacheFileHandle* aHandle, nsresult aResult) override {
return NS_OK;
}
NS_IMETHOD OnDataWritten(CacheFileHandle* aHandle, const char* aBuf,
nsresult aResult) override {
return NS_OK;
}
NS_IMETHOD OnDataRead(CacheFileHandle* aHandle, char* aBuf,
nsresult aResult) override {
return NS_OK;
}
NS_IMETHOD OnFileDoomed(CacheFileHandle* aHandle, nsresult aResult) override;
NS_IMETHOD OnEOFSet(CacheFileHandle* aHandle, nsresult aResult) override {
return NS_OK;
}
NS_IMETHOD OnFileRenamed(CacheFileHandle* aHandle,
nsresult aResult) override {
return NS_OK;
}
nsCOMPtr<nsICacheEntryDoomCallback> mCallback;
nsresult mResult;
};
CacheEntryDoomByKeyCallback::~CacheEntryDoomByKeyCallback() {
if (mCallback) {
ProxyReleaseMainThread("CacheEntryDoomByKeyCallback::mCallback", mCallback);
}
}
NS_IMETHODIMP CacheEntryDoomByKeyCallback::OnFileDoomed(
CacheFileHandle* aHandle, nsresult aResult) {
if (!mCallback) return NS_OK;
mResult = aResult;
if (NS_IsMainThread()) {
Run();
} else {
NS_DispatchToMainThread(this);
}
return NS_OK;
}
NS_IMETHODIMP CacheEntryDoomByKeyCallback::Run() {
mCallback->OnCacheEntryDoomed(mResult);
return NS_OK;
}
NS_IMPL_ISUPPORTS(CacheEntryDoomByKeyCallback, CacheFileIOListener,
nsIRunnable);
} // namespace
nsresult CacheStorageService::DoomStorageEntry(
CacheStorage const* aStorage, const nsACString& aURI,
const nsACString& aIdExtension, nsICacheEntryDoomCallback* aCallback) {
LOG(("CacheStorageService::DoomStorageEntry"));
NS_ENSURE_ARG(aStorage);
nsAutoCString contextKey;
CacheFileUtils::AppendKeyPrefix(aStorage->LoadInfo(), contextKey);
nsAutoCString entryKey;
nsresult rv = CacheEntry::HashingKey(""_ns, aIdExtension, aURI, entryKey);
NS_ENSURE_SUCCESS(rv, rv);
RefPtr<CacheEntry> entry;
{
mozilla::MutexAutoLock lock(mLock);
NS_ENSURE_FALSE(mShutdown, NS_ERROR_NOT_INITIALIZED);
CacheEntryTable* entries;
if (sGlobalEntryTables->Get(contextKey, &entries)) {
if (entries->Get(entryKey, getter_AddRefs(entry))) {
if (aStorage->WriteToDisk() || !entry->IsUsingDisk()) {
// When evicting from disk storage, purge
// When evicting from memory storage and the entry is memory-only,
// purge
LOG(
(" purging entry %p for %s [storage use disk=%d, entry use "
"disk=%d]",
entry.get(), entryKey.get(), aStorage->WriteToDisk(),
entry->IsUsingDisk()));
entries->Remove(entryKey);
} else {
// Otherwise, leave it
LOG(
(" leaving entry %p for %s [storage use disk=%d, entry use "
"disk=%d]",
entry.get(), entryKey.get(), aStorage->WriteToDisk(),
entry->IsUsingDisk()));
entry = nullptr;
}
}
}
if (!entry) {
RemoveEntryForceValid(contextKey, entryKey);
}
}
if (entry) {
LOG((" dooming entry %p for %s", entry.get(), entryKey.get()));
return entry->AsyncDoom(aCallback);
}
LOG((" no entry loaded for %s", entryKey.get()));
if (aStorage->WriteToDisk()) {
nsAutoCString contextKey;
CacheFileUtils::AppendKeyPrefix(aStorage->LoadInfo(), contextKey);
rv = CacheEntry::HashingKey(contextKey, aIdExtension, aURI, entryKey);
NS_ENSURE_SUCCESS(rv, rv);
LOG((" dooming file only for %s", entryKey.get()));
RefPtr<CacheEntryDoomByKeyCallback> callback(
new CacheEntryDoomByKeyCallback(aCallback));
rv = CacheFileIOManager::DoomFileByKey(entryKey, callback);
NS_ENSURE_SUCCESS(rv, rv);
return NS_OK;
}
class Callback : public Runnable {
public:
explicit Callback(nsICacheEntryDoomCallback* aCallback)
: mozilla::Runnable("Callback"), mCallback(aCallback) {}
NS_IMETHOD Run() override {
mCallback->OnCacheEntryDoomed(NS_ERROR_NOT_AVAILABLE);
return NS_OK;
}
nsCOMPtr<nsICacheEntryDoomCallback> mCallback;
};
if (aCallback) {
RefPtr<Runnable> callback = new Callback(aCallback);
return NS_DispatchToMainThread(callback);
}
return NS_OK;
}
nsresult CacheStorageService::DoomStorageEntries(
CacheStorage const* aStorage, nsICacheEntryDoomCallback* aCallback) {
LOG(("CacheStorageService::DoomStorageEntries"));
NS_ENSURE_FALSE(mShutdown, NS_ERROR_NOT_INITIALIZED);
NS_ENSURE_ARG(aStorage);
nsAutoCString contextKey;
CacheFileUtils::AppendKeyPrefix(aStorage->LoadInfo(), contextKey);
mozilla::MutexAutoLock lock(mLock);
return DoomStorageEntries(contextKey, aStorage->LoadInfo(),
aStorage->WriteToDisk(), aStorage->Pinning(),
aCallback);
}
nsresult CacheStorageService::DoomStorageEntries(
const nsACString& aContextKey, nsILoadContextInfo* aContext,
bool aDiskStorage, bool aPinned, nsICacheEntryDoomCallback* aCallback) {
LOG(("CacheStorageService::DoomStorageEntries [context=%s]",
aContextKey.BeginReading()));
mLock.AssertCurrentThreadOwns();
NS_ENSURE_TRUE(!mShutdown, NS_ERROR_NOT_INITIALIZED);
nsAutoCString memoryStorageID(aContextKey);
AppendMemoryStorageTag(memoryStorageID);
if (aDiskStorage) {
LOG((" dooming disk+memory storage of %s", aContextKey.BeginReading()));
// Walk one by one and remove entries according their pin status
CacheEntryTable *diskEntries, *memoryEntries;
if (sGlobalEntryTables->Get(aContextKey, &diskEntries)) {
sGlobalEntryTables->Get(memoryStorageID, &memoryEntries);
for (auto iter = diskEntries->Iter(); !iter.Done(); iter.Next()) {
auto entry = iter.Data();
if (entry->DeferOrBypassRemovalOnPinStatus(aPinned)) {
continue;
}
if (memoryEntries) {
RemoveExactEntry(memoryEntries, iter.Key(), entry, false);
}
iter.Remove();
}
}
if (aContext && !aContext->IsPrivate()) {
LOG((" dooming disk entries"));
CacheFileIOManager::EvictByContext(aContext, aPinned, u""_ns);
}
} else {
LOG((" dooming memory-only storage of %s", aContextKey.BeginReading()));
// Remove the memory entries table from the global tables.
// Since we store memory entries also in the disk entries table
// we need to remove the memory entries from the disk table one
// by one manually.
mozilla::UniquePtr<CacheEntryTable> memoryEntries;
sGlobalEntryTables->Remove(memoryStorageID, &memoryEntries);
CacheEntryTable* diskEntries;
if (memoryEntries && sGlobalEntryTables->Get(aContextKey, &diskEntries)) {
for (const auto& memoryEntry : *memoryEntries) {
const auto& entry = memoryEntry.GetData();
RemoveExactEntry(diskEntries, memoryEntry.GetKey(), entry, false);
}
}
}
{
mozilla::MutexAutoLock lock(mForcedValidEntriesLock);
if (aContext) {
for (auto iter = mForcedValidEntries.Iter(); !iter.Done(); iter.Next()) {
bool matches;
DebugOnly<nsresult> rv = CacheFileUtils::KeyMatchesLoadContextInfo(
iter.Key(), aContext, &matches);
MOZ_ASSERT(NS_SUCCEEDED(rv));
if (matches) {
iter.Remove();
}
}
} else {
mForcedValidEntries.Clear();
}
}
// An artificial callback. This is a candidate for removal tho. In the new
// cache any 'doom' or 'evict' function ensures that the entry or entries
// being doomed is/are not accessible after the function returns. So there is
// probably no need for a callback - has no meaning. But for compatibility
// with the old cache that is still in the tree we keep the API similar to be
// able to make tests as well as other consumers work for now.
class Callback : public Runnable {
public:
explicit Callback(nsICacheEntryDoomCallback* aCallback)
: mozilla::Runnable("Callback"), mCallback(aCallback) {}
NS_IMETHOD Run() override {
mCallback->OnCacheEntryDoomed(NS_OK);
return NS_OK;
}
nsCOMPtr<nsICacheEntryDoomCallback> mCallback;
};
if (aCallback) {
RefPtr<Runnable> callback = new Callback(aCallback);
return NS_DispatchToMainThread(callback);
}
return NS_OK;
}
nsresult CacheStorageService::WalkStorageEntries(
CacheStorage const* aStorage, bool aVisitEntries,
nsICacheStorageVisitor* aVisitor) {
LOG(("CacheStorageService::WalkStorageEntries [cb=%p, visitentries=%d]",
aVisitor, aVisitEntries));
NS_ENSURE_FALSE(mShutdown, NS_ERROR_NOT_INITIALIZED);
NS_ENSURE_ARG(aStorage);
if (aStorage->WriteToDisk()) {
RefPtr<WalkDiskCacheRunnable> event = new WalkDiskCacheRunnable(
aStorage->LoadInfo(), aVisitEntries, aVisitor);
return event->Walk();
}
RefPtr<WalkMemoryCacheRunnable> event = new WalkMemoryCacheRunnable(
aStorage->LoadInfo(), aVisitEntries, aVisitor);
return event->Walk();
}
void CacheStorageService::CacheFileDoomed(nsILoadContextInfo* aLoadContextInfo,
const nsACString& aIdExtension,
const nsACString& aURISpec) {
nsAutoCString contextKey;
CacheFileUtils::AppendKeyPrefix(aLoadContextInfo, contextKey);
nsAutoCString entryKey;
CacheEntry::HashingKey(""_ns, aIdExtension, aURISpec, entryKey);
mozilla::MutexAutoLock lock(mLock);
if (mShutdown) {
return;
}
CacheEntryTable* entries;
RefPtr<CacheEntry> entry;
if (sGlobalEntryTables->Get(contextKey, &entries) &&
entries->Get(entryKey, getter_AddRefs(entry))) {
if (entry->IsFileDoomed()) {
// Need to remove under the lock to avoid possible race leading
// to duplication of the entry per its key.
RemoveExactEntry(entries, entryKey, entry, false);
entry->DoomAlreadyRemoved();
}
// Entry found, but it's not the entry that has been found doomed
// by the lower eviction layer. Just leave everything unchanged.
return;
}
RemoveEntryForceValid(contextKey, entryKey);
}
bool CacheStorageService::GetCacheEntryInfo(
nsILoadContextInfo* aLoadContextInfo, const nsACString& aIdExtension,
const nsACString& aURISpec, EntryInfoCallback* aCallback) {
nsAutoCString contextKey;
CacheFileUtils::AppendKeyPrefix(aLoadContextInfo, contextKey);
nsAutoCString entryKey;
CacheEntry::HashingKey(""_ns, aIdExtension, aURISpec, entryKey);
RefPtr<CacheEntry> entry;
{
mozilla::MutexAutoLock lock(mLock);
if (mShutdown) {
return false;
}
CacheEntryTable* entries;
if (!sGlobalEntryTables->Get(contextKey, &entries)) {
return false;
}
if (!entries->Get(entryKey, getter_AddRefs(entry))) {
return false;
}
}
GetCacheEntryInfo(entry, aCallback);
return true;
}
// static
void CacheStorageService::GetCacheEntryInfo(CacheEntry* aEntry,
EntryInfoCallback* aCallback) {
nsCString const uriSpec = aEntry->GetURI();
nsCString const enhanceId = aEntry->GetEnhanceID();
nsAutoCString entryKey;
aEntry->HashingKeyWithStorage(entryKey);
nsCOMPtr<nsILoadContextInfo> info = CacheFileUtils::ParseKey(entryKey);
uint32_t dataSize;
if (NS_FAILED(aEntry->GetStorageDataSize(&dataSize))) {
dataSize = 0;
}
int64_t altDataSize;
if (NS_FAILED(aEntry->GetAltDataSize(&altDataSize))) {
altDataSize = 0;
}
uint32_t fetchCount;
if (NS_FAILED(aEntry->GetFetchCount(&fetchCount))) {
fetchCount = 0;
}
uint32_t lastModified;
if (NS_FAILED(aEntry->GetLastModified(&lastModified))) {
lastModified = 0;
}
uint32_t expirationTime;
if (NS_FAILED(aEntry->GetExpirationTime(&expirationTime))) {
expirationTime = 0;
}
aCallback->OnEntryInfo(uriSpec, enhanceId, dataSize, altDataSize, fetchCount,
lastModified, expirationTime, aEntry->IsPinned(),
info);
}
// static
uint32_t CacheStorageService::CacheQueueSize(bool highPriority) {
RefPtr<CacheIOThread> thread = CacheFileIOManager::IOThread();
// The thread will be null at shutdown.
if (!thread) {
return 0;
}
return thread->QueueSize(highPriority);
}
// Telemetry collection
namespace {
bool TelemetryEntryKey(CacheEntry const* entry, nsAutoCString& key) {
nsAutoCString entryKey;
nsresult rv = entry->HashingKey(entryKey);
if (NS_FAILED(rv)) return false;
if (entry->GetStorageID().IsEmpty()) {
// Hopefully this will be const-copied, saves some memory
key = entryKey;
} else {
key.Assign(entry->GetStorageID());
key.Append(':');
key.Append(entryKey);
}
return true;
}
} // namespace
void CacheStorageService::TelemetryPrune(TimeStamp& now) {
static TimeDuration const oneMinute = TimeDuration::FromSeconds(60);
static TimeStamp dontPruneUntil = now + oneMinute;
if (now < dontPruneUntil) return;
static TimeDuration const fifteenMinutes = TimeDuration::FromSeconds(900);
for (auto iter = mPurgeTimeStamps.Iter(); !iter.Done(); iter.Next()) {
if (now - iter.Data() > fifteenMinutes) {
// We are not interested in resurrection of entries after 15 minutes
// of time. This is also the limit for the telemetry.
iter.Remove();
}
}
dontPruneUntil = now + oneMinute;
}
void CacheStorageService::TelemetryRecordEntryCreation(
CacheEntry const* entry) {
MOZ_ASSERT(CacheStorageService::IsOnManagementThread());
nsAutoCString key;
if (!TelemetryEntryKey(entry, key)) return;
TimeStamp now = TimeStamp::NowLoRes();
TelemetryPrune(now);
// When an entry is craeted (registered actually) we check if there is
// a timestamp marked when this very same cache entry has been removed
// (deregistered) because of over-memory-limit purging. If there is such
// a timestamp found accumulate telemetry on how long the entry was away.
TimeStamp timeStamp;
if (!mPurgeTimeStamps.Get(key, &timeStamp)) return;
mPurgeTimeStamps.Remove(key);
Telemetry::AccumulateTimeDelta(Telemetry::HTTP_CACHE_ENTRY_RELOAD_TIME,
timeStamp, TimeStamp::NowLoRes());
}
void CacheStorageService::TelemetryRecordEntryRemoval(CacheEntry* entry) {
MOZ_ASSERT(CacheStorageService::IsOnManagementThread());
// Doomed entries must not be considered, we are only interested in purged
// entries. Note that the mIsDoomed flag is always set before deregistration
// happens.
if (entry->IsDoomed()) return;
nsAutoCString key;
if (!TelemetryEntryKey(entry, key)) return;
// When an entry is removed (deregistered actually) we put a timestamp for
// this entry to the hashtable so that when the entry is created (registered)
// again we know how long it was away. Also accumulate number of AsyncOpen
// calls on the entry, this tells us how efficiently the pool actually works.
TimeStamp now = TimeStamp::NowLoRes();
TelemetryPrune(now);
mPurgeTimeStamps.InsertOrUpdate(key, now);
Telemetry::Accumulate(Telemetry::HTTP_CACHE_ENTRY_REUSE_COUNT,
entry->UseCount());
Telemetry::AccumulateTimeDelta(Telemetry::HTTP_CACHE_ENTRY_ALIVE_TIME,
entry->LoadStart(), TimeStamp::NowLoRes());
}
// nsIMemoryReporter
size_t CacheStorageService::SizeOfExcludingThis(
mozilla::MallocSizeOf mallocSizeOf) const {
CacheStorageService::Self()->Lock().AssertCurrentThreadOwns();
size_t n = 0;
// The elemets are referenced by sGlobalEntryTables and are reported from
// there
n += Pool(true).mFrecencyArray.ShallowSizeOfExcludingThis(mallocSizeOf);
n += Pool(true).mExpirationArray.ShallowSizeOfExcludingThis(mallocSizeOf);
n += Pool(false).mFrecencyArray.ShallowSizeOfExcludingThis(mallocSizeOf);
n += Pool(false).mExpirationArray.ShallowSizeOfExcludingThis(mallocSizeOf);
// Entries reported manually in CacheStorageService::CollectReports callback
if (sGlobalEntryTables) {
n += sGlobalEntryTables->ShallowSizeOfIncludingThis(mallocSizeOf);
}
n += mPurgeTimeStamps.SizeOfExcludingThis(mallocSizeOf);
return n;
}
size_t CacheStorageService::SizeOfIncludingThis(
mozilla::MallocSizeOf mallocSizeOf) const {
return mallocSizeOf(this) + SizeOfExcludingThis(mallocSizeOf);
}
NS_IMETHODIMP
CacheStorageService::CollectReports(nsIHandleReportCallback* aHandleReport,
nsISupports* aData, bool aAnonymize) {
MutexAutoLock lock(mLock);
MOZ_COLLECT_REPORT("explicit/network/cache2/io", KIND_HEAP, UNITS_BYTES,
CacheFileIOManager::SizeOfIncludingThis(MallocSizeOf),
"Memory used by the cache IO manager.");
MOZ_COLLECT_REPORT("explicit/network/cache2/index", KIND_HEAP, UNITS_BYTES,
CacheIndex::SizeOfIncludingThis(MallocSizeOf),
"Memory used by the cache index.");
// Report the service instance, this doesn't report entries, done lower
MOZ_COLLECT_REPORT("explicit/network/cache2/service", KIND_HEAP, UNITS_BYTES,
SizeOfIncludingThis(MallocSizeOf),
"Memory used by the cache storage service.");
// Report all entries, each storage separately (by the context key)
//
// References are:
// sGlobalEntryTables to N CacheEntryTable
// CacheEntryTable to N CacheEntry
// CacheEntry to 1 CacheFile
// CacheFile to
// N CacheFileChunk (keeping the actual data)
// 1 CacheFileMetadata (keeping http headers etc.)
// 1 CacheFileOutputStream
// N CacheFileInputStream
if (sGlobalEntryTables) {
for (const auto& globalEntry : *sGlobalEntryTables) {
CacheStorageService::Self()->Lock().AssertCurrentThreadOwns();
CacheEntryTable* table = globalEntry.GetWeak();
size_t size = 0;
mozilla::MallocSizeOf mallocSizeOf = CacheStorageService::MallocSizeOf;
size += table->ShallowSizeOfIncludingThis(mallocSizeOf);
for (const auto& tableEntry : *table) {
size += tableEntry.GetKey().SizeOfExcludingThisIfUnshared(mallocSizeOf);
// Bypass memory-only entries, those will be reported when iterating the
// memory only table. Memory-only entries are stored in both ALL_ENTRIES
// and MEMORY_ONLY hashtables.
RefPtr<mozilla::net::CacheEntry> const& entry = tableEntry.GetData();
if (table->Type() == CacheEntryTable::MEMORY_ONLY ||
entry->IsUsingDisk()) {
size += entry->SizeOfIncludingThis(mallocSizeOf);
}
}
aHandleReport->Callback(
""_ns,
nsPrintfCString(
"explicit/network/cache2/%s-storage(%s)",
table->Type() == CacheEntryTable::MEMORY_ONLY ? "memory" : "disk",
aAnonymize ? "<anonymized>"
: globalEntry.GetKey().BeginReading()),
nsIMemoryReporter::KIND_HEAP, nsIMemoryReporter::UNITS_BYTES, size,
"Memory used by the cache storage."_ns, aData);
}
}
return NS_OK;
}
// nsICacheTesting
NS_IMETHODIMP
CacheStorageService::IOThreadSuspender::Run() {
MonitorAutoLock mon(mMon);
while (!mSignaled) {
mon.Wait();
}
return NS_OK;
}
void CacheStorageService::IOThreadSuspender::Notify() {
MonitorAutoLock mon(mMon);
mSignaled = true;
mon.Notify();
}
NS_IMETHODIMP
CacheStorageService::SuspendCacheIOThread(uint32_t aLevel) {
RefPtr<CacheIOThread> thread = CacheFileIOManager::IOThread();
if (!thread) {
return NS_ERROR_NOT_AVAILABLE;
}
MOZ_ASSERT(!mActiveIOSuspender);
mActiveIOSuspender = new IOThreadSuspender();
return thread->Dispatch(mActiveIOSuspender, aLevel);
}
NS_IMETHODIMP
CacheStorageService::ResumeCacheIOThread() {
MOZ_ASSERT(mActiveIOSuspender);
RefPtr<IOThreadSuspender> suspender;
suspender.swap(mActiveIOSuspender);
suspender->Notify();
return NS_OK;
}
NS_IMETHODIMP
CacheStorageService::Flush(nsIObserver* aObserver) {
RefPtr<CacheIOThread> thread = CacheFileIOManager::IOThread();
if (!thread) {
return NS_ERROR_NOT_AVAILABLE;
}
nsCOMPtr<nsIObserverService> observerService =
mozilla::services::GetObserverService();
if (!observerService) {
return NS_ERROR_NOT_AVAILABLE;
}
// Adding as weak, the consumer is responsible to keep the reference
// until notified.
observerService->AddObserver(aObserver, "cacheservice:purge-memory-pools",
false);
// This runnable will do the purging and when done, notifies the above
// observer. We dispatch it to the CLOSE level, so all data writes scheduled
// up to this time will be done before this purging happens.
RefPtr<CacheStorageService::PurgeFromMemoryRunnable> r =
new CacheStorageService::PurgeFromMemoryRunnable(this,
CacheEntry::PURGE_WHOLE);
return thread->Dispatch(r, CacheIOThread::WRITE);
}
} // namespace mozilla::net