gecko-dev/netwerk/cache2/CacheStorageService.cpp
2014-02-18 16:05:07 +01:00

1498 lines
41 KiB
C++

/* 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 "nsICacheStorageVisitor.h"
#include "nsIObserverService.h"
#include "CacheStorage.h"
#include "AppCacheStorage.h"
#include "CacheEntry.h"
#include "OldWrappers.h"
#include "nsCacheService.h"
#include "nsDeleteDir.h"
#include "nsIFile.h"
#include "nsIURI.h"
#include "nsCOMPtr.h"
#include "nsAutoPtr.h"
#include "nsNetCID.h"
#include "nsServiceManagerUtils.h"
#include "mozilla/TimeStamp.h"
#include "mozilla/DebugOnly.h"
#include "mozilla/VisualEventTracer.h"
#include "mozilla/Services.h"
namespace mozilla {
namespace net {
namespace {
void LoadContextInfoMappingKey(nsAutoCString &key, nsILoadContextInfo* aInfo)
{
/**
* This key is used to salt file hashes. When form of the key is changed
* cache entries will fail to find on disk.
*/
key.Append(aInfo->IsPrivate() ? 'P' : '-');
key.Append(aInfo->IsAnonymous() ? 'A' : '-');
key.Append(':');
if (aInfo->AppId() != nsILoadContextInfo::NO_APP_ID) {
key.AppendInt(aInfo->AppId());
}
if (aInfo->IsInBrowserElement()) {
key.Append('B');
}
}
void AppendMemoryStorageID(nsAutoCString &key)
{
key.Append('M');
}
}
// 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.
typedef nsClassHashtable<nsCStringHashKey, CacheEntryTable>
GlobalEntryTables;
/**
* 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|appId|inBrowser> which builds a mapping key.
*
* Thread-safe to access, protected by the service mutex.
*/
static GlobalEntryTables* sGlobalEntryTables;
CacheMemoryConsumer::CacheMemoryConsumer()
: mReportedMemoryConsumption(0)
{
}
void
CacheMemoryConsumer::DoMemoryReport(uint32_t aCurrentSize)
{
if (CacheStorageService::Self())
CacheStorageService::Self()->OnMemoryConsumptionChange(this, aCurrentSize);
}
NS_IMPL_ISUPPORTS1(CacheStorageService, nsICacheStorageService)
CacheStorageService* CacheStorageService::sSelf = nullptr;
CacheStorageService::CacheStorageService()
: mLock("CacheStorageService")
, mShutdown(false)
, mMemorySize(0)
, mPurging(false)
{
CacheFileIOManager::Init();
MOZ_ASSERT(!sSelf);
sSelf = this;
sGlobalEntryTables = new GlobalEntryTables();
}
CacheStorageService::~CacheStorageService()
{
LOG(("CacheStorageService::~CacheStorageService"));
sSelf = nullptr;
if (mMemorySize != 0)
NS_ERROR("Network cache reported memory consumption is not at 0, probably leaking?");
}
void CacheStorageService::Shutdown()
{
if (mShutdown)
return;
LOG(("CacheStorageService::Shutdown - start"));
mShutdown = true;
nsCOMPtr<nsIRunnable> event =
NS_NewRunnableMethod(this, &CacheStorageService::ShutdownBackground);
Dispatch(event);
mozilla::MutexAutoLock lock(mLock);
sGlobalEntryTables->Clear();
delete sGlobalEntryTables;
sGlobalEntryTables = nullptr;
LOG(("CacheStorageService::Shutdown - done"));
}
void CacheStorageService::ShutdownBackground()
{
MOZ_ASSERT(IsOnManagementThread());
mFrecencyArray.Clear();
mExpirationArray.Clear();
}
// Internal management methods
namespace { // anon
// EvictionRunnable
// Responsible for purgin and unregistring entries (loaded) in memory
class EvictionRunnable : public nsRunnable
{
public:
EvictionRunnable(nsCSubstring const & aContextKey, TCacheEntryTable* aEntries,
bool aUsingDisk,
nsICacheEntryDoomCallback* aCallback)
: mContextKey(aContextKey)
, mEntries(aEntries)
, mCallback(aCallback)
, mUsingDisk(aUsingDisk) { }
NS_IMETHOD Run()
{
LOG(("EvictionRunnable::Run [this=%p, disk=%d]", this, mUsingDisk));
if (CacheStorageService::IsOnManagementThread()) {
if (mUsingDisk) {
// TODO for non private entries:
// - rename/move all files to TRASH, block shutdown
// - start the TRASH removal process
// - may also be invoked from the main thread...
}
if (mEntries) {
// Process only a limited number of entries during a single loop to
// prevent block of the management thread.
mBatch = 50;
mEntries->Enumerate(&EvictionRunnable::EvictEntry, this);
}
// Anything left? Process in a separate invokation.
if (mEntries && mEntries->Count())
NS_DispatchToCurrentThread(this);
else if (mCallback)
NS_DispatchToMainThread(this); // TODO - we may want caller thread
}
else if (NS_IsMainThread()) {
mCallback->OnCacheEntryDoomed(NS_OK);
}
else {
MOZ_ASSERT(false, "Not main or cache management thread");
}
return NS_OK;
}
private:
virtual ~EvictionRunnable()
{
if (mCallback)
ProxyReleaseMainThread(mCallback);
}
static PLDHashOperator EvictEntry(const nsACString& aKey,
nsRefPtr<CacheEntry>& aEntry,
void* aClosure)
{
EvictionRunnable* evictor = static_cast<EvictionRunnable*>(aClosure);
LOG((" evicting entry=%p", aEntry.get()));
// HACK ...
// in-mem-only should only be Purge(WHOLE)'ed
// on-disk may use the same technique I think, disk eviction runs independently
if (!evictor->mUsingDisk) {
// When evicting memory-only entries we have to remove them from
// the master table as well. PurgeAndDoom() enters the service
// management lock.
aEntry->PurgeAndDoom();
}
else {
// Disk (+memory-only) entries are already removed from the master
// hash table, save locking here!
aEntry->DoomAlreadyRemoved();
}
if (!--evictor->mBatch)
return PLDHashOperator(PL_DHASH_REMOVE | PL_DHASH_STOP);
return PL_DHASH_REMOVE;
}
nsCString mContextKey;
nsAutoPtr<TCacheEntryTable> mEntries;
nsCOMPtr<nsICacheEntryDoomCallback> mCallback;
uint32_t mBatch;
bool mUsingDisk;
};
// WalkRunnable
// Responsible to visit the storage and walk all entries on it asynchronously
class WalkRunnable : public nsRunnable
{
public:
WalkRunnable(nsCSubstring const & aContextKey, bool aVisitEntries,
bool aUsingDisk,
nsICacheStorageVisitor* aVisitor)
: mContextKey(aContextKey)
, mCallback(aVisitor)
, mSize(0)
, mNotifyStorage(true)
, mVisitEntries(aVisitEntries)
, mUsingDisk(aUsingDisk)
{
MOZ_ASSERT(NS_IsMainThread());
}
private:
NS_IMETHODIMP Run()
{
if (CacheStorageService::IsOnManagementThread()) {
LOG(("WalkRunnable::Run - collecting [this=%p, disk=%d]", this, (bool)mUsingDisk));
// First, walk, count and grab all entries from the storage
// TODO
// - walk files on disk, when the storage is not private
// - should create representative entries only for the time
// of need
mozilla::MutexAutoLock lock(CacheStorageService::Self()->Lock());
if (!CacheStorageService::IsRunning())
return NS_ERROR_NOT_INITIALIZED;
CacheEntryTable* entries;
if (sGlobalEntryTables->Get(mContextKey, &entries))
entries->EnumerateRead(&WalkRunnable::WalkStorage, this);
// Next, we dispatch to the main thread
}
else if (NS_IsMainThread()) {
LOG(("WalkRunnable::Run - notifying [this=%p, disk=%d]", this, (bool)mUsingDisk));
if (mNotifyStorage) {
LOG((" storage"));
// Second, notify overall storage info
mCallback->OnCacheStorageInfo(mEntryArray.Length(), mSize);
if (!mVisitEntries)
return NS_OK; // done
mNotifyStorage = false;
}
else {
LOG((" entry [left=%d]", mEntryArray.Length()));
// Third, notify each entry until depleted.
if (!mEntryArray.Length()) {
mCallback->OnCacheEntryVisitCompleted();
return NS_OK; // done
}
mCallback->OnCacheEntryInfo(mEntryArray[0]);
mEntryArray.RemoveElementAt(0);
// Dispatch to the main thread again
}
}
else {
MOZ_ASSERT(false);
return NS_ERROR_FAILURE;
}
NS_DispatchToMainThread(this);
return NS_OK;
}
virtual ~WalkRunnable()
{
if (mCallback)
ProxyReleaseMainThread(mCallback);
}
static PLDHashOperator
WalkStorage(const nsACString& aKey,
CacheEntry* aEntry,
void* aClosure)
{
WalkRunnable* walker = static_cast<WalkRunnable*>(aClosure);
if (!walker->mUsingDisk && aEntry->UsingDisk())
return PL_DHASH_NEXT;
walker->mSize += aEntry->GetMetadataMemoryConsumption();
int64_t size;
if (NS_SUCCEEDED(aEntry->GetDataSize(&size)))
walker->mSize += size;
walker->mEntryArray.AppendElement(aEntry);
return PL_DHASH_NEXT;
}
nsCString mContextKey;
nsCOMPtr<nsICacheStorageVisitor> mCallback;
nsTArray<nsRefPtr<CacheEntry> > mEntryArray;
uint64_t mSize;
bool mNotifyStorage : 1;
bool mVisitEntries : 1;
bool mUsingDisk : 1;
};
PLDHashOperator CollectPrivateContexts(const nsACString& aKey,
CacheEntryTable* aTable,
void* aClosure)
{
if (aKey[0] == 'P') {
nsTArray<nsCString>* keys = static_cast<nsTArray<nsCString>*>(aClosure);
keys->AppendElement(aKey);
}
return PL_DHASH_NEXT;
}
PLDHashOperator CollectContexts(const nsACString& aKey,
CacheEntryTable* aTable,
void* aClosure)
{
nsTArray<nsCString>* keys = static_cast<nsTArray<nsCString>*>(aClosure);
keys->AppendElement(aKey);
return PL_DHASH_NEXT;
}
} // anon
void CacheStorageService::DropPrivateBrowsingEntries()
{
mozilla::MutexAutoLock lock(mLock);
if (mShutdown)
return;
nsTArray<nsCString> keys;
sGlobalEntryTables->EnumerateRead(&CollectPrivateContexts, &keys);
for (uint32_t i = 0; i < keys.Length(); ++i)
DoomStorageEntries(keys[i], true, nullptr);
}
// static
void CacheStorageService::WipeCacheDirectory(uint32_t aVersion)
{
nsCOMPtr<nsIFile> cacheDir;
switch (aVersion) {
case 0:
nsCacheService::GetDiskCacheDirectory(getter_AddRefs(cacheDir));
break;
case 1:
CacheFileIOManager::GetCacheDirectory(getter_AddRefs(cacheDir));
break;
}
if (!cacheDir)
return;
nsDeleteDir::DeleteDir(cacheDir, true, 30000);
}
// Helper methods
// static
bool CacheStorageService::IsOnManagementThread()
{
nsRefPtr<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)
{
nsRefPtr<CacheIOThread> cacheIOThread = CacheFileIOManager::IOThread();
if (!cacheIOThread)
return NS_ERROR_NOT_AVAILABLE;
return cacheIOThread->Dispatch(aEvent, CacheIOThread::MANAGEMENT);
}
// nsICacheStorageService
NS_IMETHODIMP CacheStorageService::MemoryCacheStorage(nsILoadContextInfo *aLoadContextInfo,
nsICacheStorage * *_retval)
{
NS_ENSURE_ARG(aLoadContextInfo);
NS_ENSURE_ARG(_retval);
nsCOMPtr<nsICacheStorage> storage;
if (CacheObserver::UseNewCache()) {
storage = new CacheStorage(aLoadContextInfo, false, false);
}
else {
storage = new _OldStorage(aLoadContextInfo, false, false, false, nullptr);
}
storage.forget(_retval);
return NS_OK;
}
NS_IMETHODIMP CacheStorageService::DiskCacheStorage(nsILoadContextInfo *aLoadContextInfo,
bool aLookupAppCache,
nsICacheStorage * *_retval)
{
NS_ENSURE_ARG(aLoadContextInfo);
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;
if (CacheObserver::UseNewCache()) {
storage = new CacheStorage(aLoadContextInfo, useDisk, aLookupAppCache);
}
else {
storage = new _OldStorage(aLoadContextInfo, useDisk, aLookupAppCache, false, nullptr);
}
storage.forget(_retval);
return NS_OK;
}
NS_IMETHODIMP CacheStorageService::AppCacheStorage(nsILoadContextInfo *aLoadContextInfo,
nsIApplicationCache *aApplicationCache,
nsICacheStorage * *_retval)
{
NS_ENSURE_ARG(aLoadContextInfo);
NS_ENSURE_ARG(_retval);
nsCOMPtr<nsICacheStorage> storage;
if (CacheObserver::UseNewCache()) {
// Using classification since cl believes we want to instantiate this method
// having the same name as the desired class...
storage = new mozilla::net::AppCacheStorage(aLoadContextInfo, aApplicationCache);
}
else {
storage = new _OldStorage(aLoadContextInfo, true, false, true, aApplicationCache);
}
storage.forget(_retval);
return NS_OK;
}
namespace { // anon
class CacheFilesDeletor : public nsRunnable
, public CacheEntriesEnumeratorCallback
{
public:
NS_DECL_ISUPPORTS_INHERITED
CacheFilesDeletor(nsICacheEntryDoomCallback* aCallback);
~CacheFilesDeletor();
nsresult DeleteAll();
nsresult DeleteOverLimit();
nsresult DeleteDoomed();
private:
nsresult Init(CacheFileIOManager::EEnumerateMode aMode);
NS_IMETHOD Run();
NS_IMETHOD Execute();
void Callback();
virtual void OnFile(CacheFile* aFile);
nsCOMPtr<nsICacheEntryDoomCallback> mCallback;
nsAutoPtr<CacheEntriesEnumerator> mEnumerator;
nsRefPtr<CacheIOThread> mIOThread;
uint32_t mRunning;
enum {
ALL,
OVERLIMIT,
DOOMED
} mMode;
nsresult mRv;
};
NS_IMPL_ISUPPORTS_INHERITED0(CacheFilesDeletor, nsRunnable);
CacheFilesDeletor::CacheFilesDeletor(nsICacheEntryDoomCallback* aCallback)
: mCallback(aCallback)
, mRunning(0)
, mRv(NS_OK)
{
MOZ_COUNT_CTOR(CacheFilesDeletor);
MOZ_EVENT_TRACER_WAIT(static_cast<nsRunnable*>(this), "net::cache::deletor");
}
CacheFilesDeletor::~CacheFilesDeletor()
{
MOZ_COUNT_DTOR(CacheFilesDeletor);
MOZ_EVENT_TRACER_DONE(static_cast<nsRunnable*>(this), "net::cache::deletor");
if (mMode == ALL) {
// Now delete the doomed entries if some left.
nsRefPtr<CacheFilesDeletor> deletor = new CacheFilesDeletor(mCallback);
nsRefPtr<nsRunnableMethod<CacheFilesDeletor, nsresult> > event =
NS_NewRunnableMethod(deletor.get(), &CacheFilesDeletor::DeleteDoomed);
NS_DispatchToMainThread(event);
}
}
nsresult CacheFilesDeletor::DeleteAll()
{
mMode = ALL;
return Init(CacheFileIOManager::ENTRIES);
}
nsresult CacheFilesDeletor::DeleteOverLimit()
{
mMode = OVERLIMIT;
return Init(CacheFileIOManager::ENTRIES);
}
nsresult CacheFilesDeletor::DeleteDoomed()
{
mMode = DOOMED;
return Init(CacheFileIOManager::DOOMED);
}
nsresult CacheFilesDeletor::Init(CacheFileIOManager::EEnumerateMode aMode)
{
nsresult rv;
rv = CacheFileIOManager::EnumerateEntryFiles(
aMode, getter_Transfers(mEnumerator));
if (NS_ERROR_FILE_NOT_FOUND == rv || NS_ERROR_FILE_TARGET_DOES_NOT_EXIST == rv) {
rv = NS_OK;
}
NS_ENSURE_SUCCESS(rv, rv);
mIOThread = CacheFileIOManager::IOThread();
NS_ENSURE_TRUE(mIOThread, NS_ERROR_NOT_INITIALIZED);
rv = mIOThread->Dispatch(this, CacheIOThread::EVICT);
NS_ENSURE_SUCCESS(rv, rv);
return NS_OK;
}
void CacheFilesDeletor::Callback()
{
MOZ_ASSERT(NS_IsMainThread());
nsCOMPtr<nsIObserverService> obsSvc = mozilla::services::GetObserverService();
if (obsSvc) {
obsSvc->NotifyObservers(CacheStorageService::Self(),
"cacheservice:empty-cache",
nullptr);
}
if (!mCallback)
return;
nsCOMPtr<nsICacheEntryDoomCallback> callback;
callback.swap(mCallback);
callback->OnCacheEntryDoomed(mRv);
}
NS_IMETHODIMP CacheFilesDeletor::Run()
{
if (!mRunning) {
MOZ_EVENT_TRACER_EXEC(static_cast<nsRunnable*>(this), "net::cache::deletor");
}
MOZ_EVENT_TRACER_EXEC(static_cast<nsRunnable*>(this), "net::cache::deletor::exec");
nsresult rv = Execute();
if (NS_SUCCEEDED(mRv))
mRv = rv;
if (!mEnumerator || !mEnumerator->HasMore()) {
// No enumerator or no more elements means the job is done.
mEnumerator = nullptr;
if (mMode != ALL) {
nsRefPtr<nsRunnableMethod<CacheFilesDeletor> > event =
NS_NewRunnableMethod(this, &CacheFilesDeletor::Callback);
NS_DispatchToMainThread(event);
}
}
MOZ_EVENT_TRACER_DONE(static_cast<nsRunnable*>(this), "net::cache::deletor::exec");
return NS_OK;
}
nsresult CacheFilesDeletor::Execute()
{
LOG(("CacheFilesDeletor::Execute [this=%p]", this));
if (!mEnumerator) {
// No enumerator means the job is done.
return NS_OK;
}
nsresult rv;
TimeStamp start;
switch (mMode) {
case OVERLIMIT:
// Examine file by file and delete what is considered expired/unused.
while (mEnumerator->HasMore()) {
rv = mEnumerator->GetNextCacheFile(this);
if (NS_FAILED(rv))
return rv;
// Limit up to 5 concurrent file opens
if (mRunning >= 5)
break;
++mRunning;
}
break;
case ALL:
case DOOMED:
// Simply delete all files, don't doom then though the backend
start = TimeStamp::NowLoRes();
while (mEnumerator->HasMore()) {
nsCOMPtr<nsIFile> file;
rv = mEnumerator->GetNextFile(getter_AddRefs(file));
if (NS_FAILED(rv))
return rv;
#ifdef PR_LOG
nsAutoCString key;
file->GetNativeLeafName(key);
LOG((" deleting file with key=%s", key.get()));
#endif
rv = file->Remove(false);
if (NS_FAILED(rv)) {
LOG((" could not remove the file, probably doomed, rv=0x%08x", rv));
#if 0
// No need to open and doom the file manually since we doom all entries
// we currently have loaded in memory.
rv = mEnumerator->GetCacheFileFromFile(file, this);
if (NS_FAILED(rv))
return rv;
#endif
}
++mRunning;
if (!(mRunning % (1 << 5)) && mEnumerator->HasMore()) {
TimeStamp now(TimeStamp::NowLoRes());
#define DELETOR_LOOP_LIMIT_MS 200
static TimeDuration const kLimitms = TimeDuration::FromMilliseconds(DELETOR_LOOP_LIMIT_MS);
if ((now - start) > kLimitms) {
LOG((" deleted %u files, breaking %dms loop", mRunning, DELETOR_LOOP_LIMIT_MS));
rv = mIOThread->Dispatch(this, CacheIOThread::EVICT);
return rv;
}
}
}
break;
default:
MOZ_ASSERT(false);
}
return NS_OK;
}
void CacheFilesDeletor::OnFile(CacheFile* aFile)
{
LOG(("CacheFilesDeletor::OnFile [this=%p, file=%p]", this, aFile));
if (!aFile)
return;
MOZ_EVENT_TRACER_EXEC(static_cast<nsRunnable*>(this), "net::cache::deletor::file");
#ifdef PR_LOG
nsAutoCString key;
aFile->Key(key);
#endif
switch (mMode) {
case OVERLIMIT:
if (mEnumerator->HasMore())
mEnumerator->GetNextCacheFile(this);
// NO BREAK ..so far..
// mayhemer TODO - here we should decide based on frecency and exp time
// whether to delete the file or not. Then we have to check the consumption
// as well.
case ALL:
case DOOMED:
LOG((" dooming file with key=%s", key.get()));
// Uncompromisely delete the file!
aFile->Doom(nullptr);
break;
}
MOZ_EVENT_TRACER_DONE(static_cast<nsRunnable*>(this), "net::cache::deletor::file");
}
} // anon
NS_IMETHODIMP CacheStorageService::Clear()
{
nsresult rv;
if (CacheObserver::UseNewCache()) {
{
mozilla::MutexAutoLock lock(mLock);
NS_ENSURE_TRUE(!mShutdown, NS_ERROR_NOT_INITIALIZED);
nsTArray<nsCString> keys;
sGlobalEntryTables->EnumerateRead(&CollectContexts, &keys);
for (uint32_t i = 0; i < keys.Length(); ++i)
DoomStorageEntries(keys[i], true, nullptr);
}
// TODO - Callback can be provided!
nsRefPtr<CacheFilesDeletor> deletor = new CacheFilesDeletor(nullptr);
rv = deletor->DeleteAll();
NS_ENSURE_SUCCESS(rv, rv);
}
else {
nsCOMPtr<nsICacheService> serv =
do_GetService(NS_CACHESERVICE_CONTRACTID, &rv);
NS_ENSURE_SUCCESS(rv, rv);
rv = serv->EvictEntries(nsICache::STORE_ANYWHERE);
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::GetIoTarget(nsIEventTarget** aEventTarget)
{
NS_ENSURE_ARG(aEventTarget);
if (CacheObserver::UseNewCache()) {
nsCOMPtr<nsIEventTarget> ioTarget = CacheFileIOManager::IOTarget();
ioTarget.forget(aEventTarget);
}
else {
nsresult rv;
nsCOMPtr<nsICacheService> serv =
do_GetService(NS_CACHESERVICE_CONTRACTID, &rv);
NS_ENSURE_SUCCESS(rv, rv);
rv = serv->GetCacheIOTarget(aEventTarget);
NS_ENSURE_SUCCESS(rv, rv);
}
return NS_OK;
}
// Methods used by CacheEntry for management of in-memory structures.
namespace { // anon
class FrecencyComparator
{
public:
bool Equals(CacheEntry* a, CacheEntry* b) const {
return a->GetFrecency() == b->GetFrecency();
}
bool LessThan(CacheEntry* a, CacheEntry* b) const {
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();
}
};
} // anon
void
CacheStorageService::RegisterEntry(CacheEntry* aEntry)
{
MOZ_ASSERT(IsOnManagementThread());
if (mShutdown || !aEntry->CanRegister())
return;
LOG(("CacheStorageService::RegisterEntry [entry=%p]", aEntry));
mFrecencyArray.InsertElementSorted(aEntry, FrecencyComparator());
mExpirationArray.InsertElementSorted(aEntry, ExpirationComparator());
aEntry->SetRegistered(true);
}
void
CacheStorageService::UnregisterEntry(CacheEntry* aEntry)
{
MOZ_ASSERT(IsOnManagementThread());
if (!aEntry->IsRegistered())
return;
LOG(("CacheStorageService::UnregisterEntry [entry=%p]", aEntry));
mozilla::DebugOnly<bool> removedFrecency = mFrecencyArray.RemoveElement(aEntry);
mozilla::DebugOnly<bool> removedExpiration = mExpirationArray.RemoveElement(aEntry);
MOZ_ASSERT(mShutdown || (removedFrecency && removedExpiration));
// Note: aEntry->CanRegister() since now returns false
aEntry->SetRegistered(false);
}
static bool
AddExactEntry(CacheEntryTable* aEntries,
nsCString const& aKey,
CacheEntry* aEntry,
bool aOverwrite)
{
nsRefPtr<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->Put(aKey, aEntry);
return true;
}
static bool
RemoveExactEntry(CacheEntryTable* aEntries,
nsCString const& aKey,
CacheEntry* aEntry,
bool aOverwrite)
{
nsRefPtr<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;
}
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 && aEntry->IsReferenced()) {
LOG((" still referenced, not removing"));
return false;
}
CacheEntryTable* entries;
if (sGlobalEntryTables->Get(aEntry->GetStorageID(), &entries))
RemoveExactEntry(entries, entryKey, aEntry, false /* don't overwrite */);
nsAutoCString memoryStorageID(aEntry->GetStorageID());
AppendMemoryStorageID(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());
AppendMemoryStorageID(memoryStorageID);
if (!sGlobalEntryTables->Get(memoryStorageID, &entries)) {
if (!aOnlyInMemory) {
LOG((" not recorded as memory only"));
return;
}
entries = new CacheEntryTable();
sGlobalEntryTables->Put(memoryStorageID, entries);
LOG((" new memory-only storage table for %s", memoryStorageID.get()));
}
if (aOnlyInMemory) {
AddExactEntry(entries, entryKey, aEntry, aOverwrite);
}
else {
RemoveExactEntry(entries, entryKey, aEntry, aOverwrite);
}
}
void
CacheStorageService::OnMemoryConsumptionChange(CacheMemoryConsumer* aConsumer,
uint32_t aCurrentMemoryConsumption)
{
LOG(("CacheStorageService::OnMemoryConsumptionChange [consumer=%p, size=%u]",
aConsumer, aCurrentMemoryConsumption));
uint32_t savedMemorySize = aConsumer->mReportedMemoryConsumption;
if (savedMemorySize == aCurrentMemoryConsumption)
return;
// Exchange saved size with current one.
aConsumer->mReportedMemoryConsumption = aCurrentMemoryConsumption;
mMemorySize -= savedMemorySize;
mMemorySize += aCurrentMemoryConsumption;
LOG((" mMemorySize=%u (+%u,-%u)", uint32_t(mMemorySize), aCurrentMemoryConsumption, savedMemorySize));
// Bypass purging when memory has not grew up significantly
if (aCurrentMemoryConsumption <= savedMemorySize)
return;
if (mPurging) {
LOG((" already purging"));
return;
}
if (mMemorySize <= CacheObserver::MemoryLimit())
return;
// Throw the oldest data or whole entries away when over certain limits
mPurging = true;
// Must always dipatch, since this can be called under e.g. a CacheFile's lock.
nsCOMPtr<nsIRunnable> event =
NS_NewRunnableMethod(this, &CacheStorageService::PurgeOverMemoryLimit);
Dispatch(event);
}
void
CacheStorageService::PurgeOverMemoryLimit()
{
MOZ_ASSERT(IsOnManagementThread());
LOG(("CacheStorageService::PurgeOverMemoryLimit"));
#ifdef PR_LOG
TimeStamp start(TimeStamp::Now());
#endif
uint32_t const memoryLimit = CacheObserver::MemoryLimit();
if (mMemorySize > memoryLimit) {
LOG((" memory data consumption over the limit, abandon expired entries"));
PurgeExpired();
}
bool frecencyNeedsSort = true;
if (mMemorySize > memoryLimit) {
LOG((" memory data consumption over the limit, abandon disk backed data"));
PurgeByFrecency(frecencyNeedsSort, CacheEntry::PURGE_DATA_ONLY_DISK_BACKED);
}
if (mMemorySize > memoryLimit) {
LOG((" metadata consumtion over the limit, abandon disk backed entries"));
PurgeByFrecency(frecencyNeedsSort, CacheEntry::PURGE_WHOLE_ONLY_DISK_BACKED);
}
if (mMemorySize > memoryLimit) {
LOG((" memory data consumption over the limit, abandon any entry"));
PurgeByFrecency(frecencyNeedsSort, CacheEntry::PURGE_WHOLE);
}
LOG((" purging took %1.2fms", (TimeStamp::Now() - start).ToMilliseconds()));
mPurging = false;
}
void
CacheStorageService::PurgeExpired()
{
MOZ_ASSERT(IsOnManagementThread());
mExpirationArray.Sort(ExpirationComparator());
uint32_t now = NowInSeconds();
uint32_t const memoryLimit = CacheObserver::MemoryLimit();
for (uint32_t i = 0; mMemorySize > memoryLimit && i < mExpirationArray.Length();) {
nsRefPtr<CacheEntry> entry = mExpirationArray[i];
uint32_t expirationTime = entry->GetExpirationTime();
if (expirationTime > 0 && expirationTime <= now) {
LOG((" dooming expired entry=%p, exptime=%u (now=%u)",
entry.get(), entry->GetExpirationTime(), now));
entry->PurgeAndDoom();
continue;
}
// not purged, move to the next one
++i;
}
}
void
CacheStorageService::PurgeByFrecency(bool &aFrecencyNeedsSort, uint32_t aWhat)
{
MOZ_ASSERT(IsOnManagementThread());
if (aFrecencyNeedsSort) {
mFrecencyArray.Sort(FrecencyComparator());
aFrecencyNeedsSort = false;
}
uint32_t const memoryLimit = CacheObserver::MemoryLimit();
for (uint32_t i = 0; mMemorySize > memoryLimit && i < mFrecencyArray.Length();) {
nsRefPtr<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;
}
}
void
CacheStorageService::PurgeAll(uint32_t aWhat)
{
LOG(("CacheStorageService::PurgeAll aWhat=%d", aWhat));
MOZ_ASSERT(IsOnManagementThread());
for (uint32_t i = 0; i < mFrecencyArray.Length();) {
nsRefPtr<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,
nsIURI* aURI,
const nsACString & aIdExtension,
bool aCreateIfNotExist,
bool aReplace,
CacheEntryHandle** aResult)
{
NS_ENSURE_FALSE(mShutdown, NS_ERROR_NOT_INITIALIZED);
NS_ENSURE_ARG(aStorage);
nsAutoCString contextKey;
LoadContextInfoMappingKey(contextKey, aStorage->LoadInfo());
return AddStorageEntry(contextKey, aURI, aIdExtension,
aStorage->WriteToDisk(), aCreateIfNotExist, aReplace,
aResult);
}
nsresult
CacheStorageService::AddStorageEntry(nsCSubstring const& aContextKey,
nsIURI* aURI,
const nsACString & aIdExtension,
bool aWriteToDisk,
bool aCreateIfNotExist,
bool aReplace,
CacheEntryHandle** aResult)
{
NS_ENSURE_ARG(aURI);
nsresult rv;
nsAutoCString entryKey;
rv = CacheEntry::HashingKey(EmptyCString(), aIdExtension, aURI, entryKey);
NS_ENSURE_SUCCESS(rv, rv);
LOG(("CacheStorageService::AddStorageEntry [entryKey=%s, contextKey=%s]",
entryKey.get(), aContextKey.BeginReading()));
nsRefPtr<CacheEntry> entry;
nsRefPtr<CacheEntryHandle> handle;
{
mozilla::MutexAutoLock lock(mLock);
NS_ENSURE_FALSE(mShutdown, NS_ERROR_NOT_INITIALIZED);
// Ensure storage table
CacheEntryTable* entries;
if (!sGlobalEntryTables->Get(aContextKey, &entries)) {
entries = new CacheEntryTable();
sGlobalEntryTables->Put(aContextKey, entries);
LOG((" new storage entries table for context %s", aContextKey.BeginReading()));
}
bool entryExists = entries->Get(entryKey, getter_AddRefs(entry));
// Check entry that is memory-only is also in related memory-only hashtable.
// If not, it has been evicted and we will truncate it ; doom is pending for it,
// this consumer just made it sooner then the entry has actually been removed
// from the master hash table.
// (This can be bypassed when entry is about to be replaced anyway.)
if (entryExists && !entry->UsingDisk() && !aReplace) {
nsAutoCString memoryStorageID(aContextKey);
AppendMemoryStorageID(memoryStorageID);
CacheEntryTable* memoryEntries;
aReplace = sGlobalEntryTables->Get(memoryStorageID, &memoryEntries) &&
memoryEntries->GetWeak(entryKey) != entry;
#ifdef MOZ_LOGGING
if (aReplace) {
LOG((" memory-only entry %p for %s already doomed, replacing", entry.get(), entryKey.get()));
}
#endif
}
// If truncate is demanded, delete and doom the current entry
if (entryExists && aReplace) {
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
entry->DoomAlreadyRemoved();
entry = nullptr;
entryExists = false;
}
if (entryExists && entry->SetUsingDisk(aWriteToDisk)) {
RecordMemoryOnlyEntry(entry, !aWriteToDisk, true /* overwrite */);
}
// Ensure entry for the particular URL, if not read/only
if (!entryExists && (aCreateIfNotExist || aReplace)) {
// Entry is not in the hashtable or has just been truncated...
entry = new CacheEntry(aContextKey, aURI, aIdExtension, aWriteToDisk);
entries->Put(entryKey, 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 'handlers count' reference.
handle = entry->NewHandle();
}
}
handle.forget(aResult);
return NS_OK;
}
namespace { // anon
class CacheEntryDoomByKeyCallback : public CacheFileIOListener
{
public:
NS_DECL_THREADSAFE_ISUPPORTS
CacheEntryDoomByKeyCallback(nsICacheEntryDoomCallback* aCallback)
: mCallback(aCallback) { }
virtual ~CacheEntryDoomByKeyCallback();
private:
NS_IMETHOD OnFileOpened(CacheFileHandle *aHandle, nsresult aResult) { return NS_OK; }
NS_IMETHOD OnDataWritten(CacheFileHandle *aHandle, const char *aBuf, nsresult aResult) { return NS_OK; }
NS_IMETHOD OnDataRead(CacheFileHandle *aHandle, char *aBuf, nsresult aResult) { return NS_OK; }
NS_IMETHOD OnFileDoomed(CacheFileHandle *aHandle, nsresult aResult);
NS_IMETHOD OnEOFSet(CacheFileHandle *aHandle, nsresult aResult) { return NS_OK; }
NS_IMETHOD OnFileRenamed(CacheFileHandle *aHandle, nsresult aResult) { return NS_OK; }
nsCOMPtr<nsICacheEntryDoomCallback> mCallback;
};
CacheEntryDoomByKeyCallback::~CacheEntryDoomByKeyCallback()
{
if (mCallback)
ProxyReleaseMainThread(mCallback);
}
NS_IMETHODIMP CacheEntryDoomByKeyCallback::OnFileDoomed(CacheFileHandle *aHandle,
nsresult aResult)
{
if (!mCallback)
return NS_OK;
mCallback->OnCacheEntryDoomed(aResult);
return NS_OK;
}
NS_IMPL_ISUPPORTS1(CacheEntryDoomByKeyCallback, CacheFileIOListener);
} // anon
nsresult
CacheStorageService::DoomStorageEntry(CacheStorage const* aStorage,
nsIURI *aURI,
const nsACString & aIdExtension,
nsICacheEntryDoomCallback* aCallback)
{
LOG(("CacheStorageService::DoomStorageEntry"));
NS_ENSURE_ARG(aStorage);
NS_ENSURE_ARG(aURI);
nsAutoCString contextKey;
LoadContextInfoMappingKey(contextKey, aStorage->LoadInfo());
nsAutoCString entryKey;
nsresult rv = CacheEntry::HashingKey(EmptyCString(), aIdExtension, aURI, entryKey);
NS_ENSURE_SUCCESS(rv, rv);
nsRefPtr<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->UsingDisk()) {
// 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->UsingDisk()));
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->UsingDisk()));
entry = nullptr;
}
}
}
}
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;
LoadContextInfoMappingKey(contextKey, aStorage->LoadInfo());
rv = CacheEntry::HashingKey(contextKey, aIdExtension, aURI, entryKey);
NS_ENSURE_SUCCESS(rv, rv);
LOG((" dooming file only for %s", entryKey.get()));
nsRefPtr<CacheEntryDoomByKeyCallback> callback(
new CacheEntryDoomByKeyCallback(aCallback));
rv = CacheFileIOManager::DoomFileByKey(entryKey, callback);
NS_ENSURE_SUCCESS(rv, rv);
return NS_OK;
}
if (aCallback)
aCallback->OnCacheEntryDoomed(NS_ERROR_NOT_AVAILABLE);
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;
LoadContextInfoMappingKey(contextKey, aStorage->LoadInfo());
mozilla::MutexAutoLock lock(mLock);
return DoomStorageEntries(contextKey, aStorage->WriteToDisk(), aCallback);
}
nsresult
CacheStorageService::DoomStorageEntries(nsCSubstring const& aContextKey,
bool aDiskStorage,
nsICacheEntryDoomCallback* aCallback)
{
mLock.AssertCurrentThreadOwns();
NS_ENSURE_TRUE(!mShutdown, NS_ERROR_NOT_INITIALIZED);
nsAutoCString memoryStorageID(aContextKey);
AppendMemoryStorageID(memoryStorageID);
nsAutoPtr<CacheEntryTable> entries;
if (aDiskStorage) {
LOG((" dooming disk+memory storage of %s", aContextKey.BeginReading()));
// Grab all entries in this storage
sGlobalEntryTables->RemoveAndForget(aContextKey, entries);
// Just remove the memory-only records table
sGlobalEntryTables->Remove(memoryStorageID);
}
else {
LOG((" dooming memory-only storage of %s", aContextKey.BeginReading()));
// Grab the memory-only records table, EvictionRunnable will safely remove
// entries one by one from the master hashtable on the background management
// thread. Code at AddStorageEntry ensures a new entry will always replace
// memory only entries that EvictionRunnable yet didn't manage to remove.
sGlobalEntryTables->RemoveAndForget(memoryStorageID, entries);
}
nsRefPtr<EvictionRunnable> evict = new EvictionRunnable(
aContextKey, entries.forget(), aDiskStorage, aCallback);
return Dispatch(evict);
}
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);
nsAutoCString contextKey;
LoadContextInfoMappingKey(contextKey, aStorage->LoadInfo());
nsRefPtr<WalkRunnable> event = new WalkRunnable(
contextKey, aVisitEntries, aStorage->WriteToDisk(), aVisitor);
return Dispatch(event);
}
} // net
} // mozilla