/* 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 "CacheFileIOManager.h" #include "../cache/nsCacheUtils.h" #include "CacheHashUtils.h" #include "CacheStorageService.h" #include "CacheIndex.h" #include "CacheFileUtils.h" #include "nsThreadUtils.h" #include "CacheFile.h" #include "CacheObserver.h" #include "nsIFile.h" #include "CacheFileContextEvictor.h" #include "nsITimer.h" #include "nsISimpleEnumerator.h" #include "nsIDirectoryEnumerator.h" #include "nsIObserverService.h" #include "nsICacheStorageVisitor.h" #include "nsISizeOf.h" #include "mozilla/Telemetry.h" #include "mozilla/DebugOnly.h" #include "mozilla/Services.h" #include "nsDirectoryServiceUtils.h" #include "nsAppDirectoryServiceDefs.h" #include "private/pprio.h" #include "mozilla/Preferences.h" #include "nsNetUtil.h" // include files for ftruncate (or equivalent) #if defined(XP_UNIX) #include #elif defined(XP_WIN) #include #undef CreateFile #undef CREATE_NEW #else // XXX add necessary include file for ftruncate (or equivalent) #endif namespace mozilla { namespace net { #define kOpenHandlesLimit 64 #define kMetadataWriteDelay 5000 #define kRemoveTrashStartDelay 60000 // in milliseconds #define kSmartSizeUpdateInterval 60000 // in milliseconds #ifdef ANDROID const uint32_t kMaxCacheSizeKB = 200*1024; // 200 MB #else const uint32_t kMaxCacheSizeKB = 350*1024; // 350 MB #endif bool CacheFileHandle::DispatchRelease() { if (CacheFileIOManager::IsOnIOThreadOrCeased()) { return false; } nsCOMPtr ioTarget = CacheFileIOManager::IOTarget(); if (!ioTarget) { return false; } RefPtr > event = NS_NewNonOwningRunnableMethod(this, &CacheFileHandle::Release); nsresult rv = ioTarget->Dispatch(event, nsIEventTarget::DISPATCH_NORMAL); if (NS_FAILED(rv)) { return false; } return true; } NS_IMPL_ADDREF(CacheFileHandle) NS_IMETHODIMP_(MozExternalRefCountType) CacheFileHandle::Release() { nsrefcnt count = mRefCnt - 1; if (DispatchRelease()) { // Redispatched to the IO thread. return count; } MOZ_ASSERT(CacheFileIOManager::IsOnIOThreadOrCeased()); LOG(("CacheFileHandle::Release() [this=%p, refcnt=%d]", this, mRefCnt.get())); NS_PRECONDITION(0 != mRefCnt, "dup release"); count = --mRefCnt; NS_LOG_RELEASE(this, count, "CacheFileHandle"); if (0 == count) { mRefCnt = 1; delete (this); return 0; } return count; } NS_INTERFACE_MAP_BEGIN(CacheFileHandle) NS_INTERFACE_MAP_ENTRY(nsISupports) NS_INTERFACE_MAP_END_THREADSAFE CacheFileHandle::CacheFileHandle(const SHA1Sum::Hash *aHash, bool aPriority, PinningStatus aPinning) : mHash(aHash) , mPriority(aPriority) , mClosed(false) , mSpecialFile(false) , mInvalid(false) , mFileExists(false) , mPinning(aPinning) , mDoomWhenFoundPinned(false) , mDoomWhenFoundNonPinned(false) , mFileSize(-1) , mFD(nullptr) { // If we initialize mDoomed in the initialization list, that initialization is // not guaranteeded to be atomic. Whereas this assignment here is guaranteed // to be atomic. TSan will see this (atomic) assignment and be satisfied // that cross-thread accesses to mIsDoomed are properly synchronized. mIsDoomed = false; LOG(("CacheFileHandle::CacheFileHandle() [this=%p, hash=%08x%08x%08x%08x%08x]" , this, LOGSHA1(aHash))); } CacheFileHandle::CacheFileHandle(const nsACString &aKey, bool aPriority, PinningStatus aPinning) : mHash(nullptr) , mPriority(aPriority) , mClosed(false) , mSpecialFile(true) , mInvalid(false) , mFileExists(false) , mPinning(aPinning) , mDoomWhenFoundPinned(false) , mDoomWhenFoundNonPinned(false) , mFileSize(-1) , mFD(nullptr) , mKey(aKey) { // See comment above about the initialization of mIsDoomed. mIsDoomed = false; LOG(("CacheFileHandle::CacheFileHandle() [this=%p, key=%s]", this, PromiseFlatCString(aKey).get())); } CacheFileHandle::~CacheFileHandle() { LOG(("CacheFileHandle::~CacheFileHandle() [this=%p]", this)); MOZ_ASSERT(CacheFileIOManager::IsOnIOThreadOrCeased()); RefPtr ioMan = CacheFileIOManager::gInstance; if (!IsClosed() && ioMan) { ioMan->CloseHandleInternal(this); } } void CacheFileHandle::Log() { nsAutoCString leafName; if (mFile) { mFile->GetNativeLeafName(leafName); } if (mSpecialFile) { LOG(("CacheFileHandle::Log() - special file [this=%p, isDoomed=%d, " "priority=%d, closed=%d, invalid=%d, fileExists=%d, fileSize=%lld, " "leafName=%s, key=%s]", this, int(mIsDoomed), mPriority, mClosed, mInvalid, mFileExists, mFileSize, leafName.get(), mKey.get())); } else { LOG(("CacheFileHandle::Log() - entry file [this=%p, hash=%08x%08x%08x%08x" "%08x, isDoomed=%d, priority=%d, closed=%d, invalid=%d, fileExists=%d," " fileSize=%lld, leafName=%s, key=%s]", this, LOGSHA1(mHash), int(mIsDoomed), mPriority, mClosed, mInvalid, mFileExists, mFileSize, leafName.get(), mKey.get())); } } uint32_t CacheFileHandle::FileSizeInK() const { MOZ_ASSERT(mFileSize != -1); uint64_t size64 = mFileSize; size64 += 0x3FF; size64 >>= 10; uint32_t size; if (size64 >> 32) { NS_WARNING("CacheFileHandle::FileSizeInK() - FileSize is too large, " "truncating to PR_UINT32_MAX"); size = PR_UINT32_MAX; } else { size = static_cast(size64); } return size; } bool CacheFileHandle::SetPinned(bool aPinned) { LOG(("CacheFileHandle::SetPinned [this=%p, pinned=%d]", this, aPinned)); MOZ_ASSERT(CacheFileIOManager::IsOnIOThreadOrCeased()); mPinning = aPinned ? PinningStatus::PINNED : PinningStatus::NON_PINNED; if ((MOZ_UNLIKELY(mDoomWhenFoundPinned) && aPinned) || (MOZ_UNLIKELY(mDoomWhenFoundNonPinned) && !aPinned)) { LOG((" dooming, when: pinned=%d, non-pinned=%d, found: pinned=%d", bool(mDoomWhenFoundPinned), bool(mDoomWhenFoundNonPinned), aPinned)); mDoomWhenFoundPinned = false; mDoomWhenFoundNonPinned = false; return false; } return true; } // Memory reporting size_t CacheFileHandle::SizeOfExcludingThis(mozilla::MallocSizeOf mallocSizeOf) const { size_t n = 0; nsCOMPtr sizeOf; sizeOf = do_QueryInterface(mFile); if (sizeOf) { n += sizeOf->SizeOfIncludingThis(mallocSizeOf); } n += mallocSizeOf(mFD); n += mKey.SizeOfExcludingThisIfUnshared(mallocSizeOf); return n; } size_t CacheFileHandle::SizeOfIncludingThis(mozilla::MallocSizeOf mallocSizeOf) const { return mallocSizeOf(this) + SizeOfExcludingThis(mallocSizeOf); } /****************************************************************************** * CacheFileHandles::HandleHashKey *****************************************************************************/ void CacheFileHandles::HandleHashKey::AddHandle(CacheFileHandle* aHandle) { MOZ_ASSERT(CacheFileIOManager::IsOnIOThreadOrCeased()); mHandles.InsertElementAt(0, aHandle); } void CacheFileHandles::HandleHashKey::RemoveHandle(CacheFileHandle* aHandle) { MOZ_ASSERT(CacheFileIOManager::IsOnIOThreadOrCeased()); DebugOnly found; found = mHandles.RemoveElement(aHandle); MOZ_ASSERT(found); } already_AddRefed CacheFileHandles::HandleHashKey::GetNewestHandle() { MOZ_ASSERT(CacheFileIOManager::IsOnIOThreadOrCeased()); RefPtr handle; if (mHandles.Length()) { handle = mHandles[0]; } return handle.forget(); } void CacheFileHandles::HandleHashKey::GetHandles(nsTArray > &aResult) { MOZ_ASSERT(CacheFileIOManager::IsOnIOThreadOrCeased()); for (uint32_t i = 0; i < mHandles.Length(); ++i) { CacheFileHandle* handle = mHandles[i]; aResult.AppendElement(handle); } } #ifdef DEBUG void CacheFileHandles::HandleHashKey::AssertHandlesState() { for (uint32_t i = 0; i < mHandles.Length(); ++i) { CacheFileHandle* handle = mHandles[i]; MOZ_ASSERT(handle->IsDoomed()); } } #endif size_t CacheFileHandles::HandleHashKey::SizeOfExcludingThis(mozilla::MallocSizeOf mallocSizeOf) const { MOZ_ASSERT(CacheFileIOManager::IsOnIOThread()); size_t n = 0; n += mallocSizeOf(mHash); for (uint32_t i = 0; i < mHandles.Length(); ++i) { n += mHandles[i]->SizeOfIncludingThis(mallocSizeOf); } return n; } /****************************************************************************** * CacheFileHandles *****************************************************************************/ CacheFileHandles::CacheFileHandles() { LOG(("CacheFileHandles::CacheFileHandles() [this=%p]", this)); MOZ_COUNT_CTOR(CacheFileHandles); } CacheFileHandles::~CacheFileHandles() { LOG(("CacheFileHandles::~CacheFileHandles() [this=%p]", this)); MOZ_COUNT_DTOR(CacheFileHandles); } nsresult CacheFileHandles::GetHandle(const SHA1Sum::Hash *aHash, CacheFileHandle **_retval) { MOZ_ASSERT(CacheFileIOManager::IsOnIOThreadOrCeased()); MOZ_ASSERT(aHash); #ifdef DEBUG_HANDLES LOG(("CacheFileHandles::GetHandle() [hash=%08x%08x%08x%08x%08x]", LOGSHA1(aHash))); #endif // find hash entry for key HandleHashKey *entry = mTable.GetEntry(*aHash); if (!entry) { LOG(("CacheFileHandles::GetHandle() hash=%08x%08x%08x%08x%08x " "no handle entries found", LOGSHA1(aHash))); return NS_ERROR_NOT_AVAILABLE; } #ifdef DEBUG_HANDLES Log(entry); #endif // Check if the entry is doomed RefPtr handle = entry->GetNewestHandle(); if (!handle) { LOG(("CacheFileHandles::GetHandle() hash=%08x%08x%08x%08x%08x " "no handle found %p, entry %p", LOGSHA1(aHash), handle.get(), entry)); return NS_ERROR_NOT_AVAILABLE; } if (handle->IsDoomed()) { LOG(("CacheFileHandles::GetHandle() hash=%08x%08x%08x%08x%08x " "found doomed handle %p, entry %p", LOGSHA1(aHash), handle.get(), entry)); return NS_ERROR_NOT_AVAILABLE; } LOG(("CacheFileHandles::GetHandle() hash=%08x%08x%08x%08x%08x " "found handle %p, entry %p", LOGSHA1(aHash), handle.get(), entry)); handle.forget(_retval); return NS_OK; } nsresult CacheFileHandles::NewHandle(const SHA1Sum::Hash *aHash, bool aPriority, CacheFileHandle::PinningStatus aPinning, CacheFileHandle **_retval) { MOZ_ASSERT(CacheFileIOManager::IsOnIOThreadOrCeased()); MOZ_ASSERT(aHash); #ifdef DEBUG_HANDLES LOG(("CacheFileHandles::NewHandle() [hash=%08x%08x%08x%08x%08x]", LOGSHA1(aHash))); #endif // find hash entry for key HandleHashKey *entry = mTable.PutEntry(*aHash); #ifdef DEBUG_HANDLES Log(entry); #endif #ifdef DEBUG entry->AssertHandlesState(); #endif RefPtr handle = new CacheFileHandle(entry->Hash(), aPriority, aPinning); entry->AddHandle(handle); LOG(("CacheFileHandles::NewHandle() hash=%08x%08x%08x%08x%08x " "created new handle %p, entry=%p", LOGSHA1(aHash), handle.get(), entry)); handle.forget(_retval); return NS_OK; } void CacheFileHandles::RemoveHandle(CacheFileHandle *aHandle) { MOZ_ASSERT(CacheFileIOManager::IsOnIOThreadOrCeased()); MOZ_ASSERT(aHandle); if (!aHandle) { return; } #ifdef DEBUG_HANDLES LOG(("CacheFileHandles::RemoveHandle() [handle=%p, hash=%08x%08x%08x%08x%08x]" , aHandle, LOGSHA1(aHandle->Hash()))); #endif // find hash entry for key HandleHashKey *entry = mTable.GetEntry(*aHandle->Hash()); if (!entry) { MOZ_ASSERT(CacheFileIOManager::IsShutdown(), "Should find entry when removing a handle before shutdown"); LOG(("CacheFileHandles::RemoveHandle() hash=%08x%08x%08x%08x%08x " "no entries found", LOGSHA1(aHandle->Hash()))); return; } #ifdef DEBUG_HANDLES Log(entry); #endif LOG(("CacheFileHandles::RemoveHandle() hash=%08x%08x%08x%08x%08x " "removing handle %p", LOGSHA1(entry->Hash()), aHandle)); entry->RemoveHandle(aHandle); if (entry->IsEmpty()) { LOG(("CacheFileHandles::RemoveHandle() hash=%08x%08x%08x%08x%08x " "list is empty, removing entry %p", LOGSHA1(entry->Hash()), entry)); mTable.RemoveEntry(*entry->Hash()); } } void CacheFileHandles::GetAllHandles(nsTArray > *_retval) { MOZ_ASSERT(CacheFileIOManager::IsOnIOThreadOrCeased()); for (auto iter = mTable.Iter(); !iter.Done(); iter.Next()) { iter.Get()->GetHandles(*_retval); } } void CacheFileHandles::GetActiveHandles( nsTArray > *_retval) { MOZ_ASSERT(CacheFileIOManager::IsOnIOThreadOrCeased()); for (auto iter = mTable.Iter(); !iter.Done(); iter.Next()) { RefPtr handle = iter.Get()->GetNewestHandle(); MOZ_ASSERT(handle); if (!handle->IsDoomed()) { _retval->AppendElement(handle); } } } void CacheFileHandles::ClearAll() { MOZ_ASSERT(CacheFileIOManager::IsOnIOThreadOrCeased()); mTable.Clear(); } uint32_t CacheFileHandles::HandleCount() { return mTable.Count(); } #ifdef DEBUG_HANDLES void CacheFileHandles::Log(CacheFileHandlesEntry *entry) { LOG(("CacheFileHandles::Log() BEGIN [entry=%p]", entry)); nsTArray > array; aEntry->GetHandles(array); for (uint32_t i = 0; i < array.Length(); ++i) { CacheFileHandle *handle = array[i]; handle->Log(); } LOG(("CacheFileHandles::Log() END [entry=%p]", entry)); } #endif // Memory reporting size_t CacheFileHandles::SizeOfExcludingThis(mozilla::MallocSizeOf mallocSizeOf) const { MOZ_ASSERT(CacheFileIOManager::IsOnIOThread()); return mTable.SizeOfExcludingThis(mallocSizeOf); } // Events class ShutdownEvent : public nsRunnable { public: ShutdownEvent(mozilla::Mutex *aLock, mozilla::CondVar *aCondVar) : mLock(aLock) , mCondVar(aCondVar) { MOZ_COUNT_CTOR(ShutdownEvent); } protected: ~ShutdownEvent() { MOZ_COUNT_DTOR(ShutdownEvent); } public: NS_IMETHOD Run() { MutexAutoLock lock(*mLock); CacheFileIOManager::gInstance->ShutdownInternal(); mCondVar->Notify(); return NS_OK; } protected: mozilla::Mutex *mLock; mozilla::CondVar *mCondVar; }; class OpenFileEvent : public nsRunnable { public: OpenFileEvent(const nsACString &aKey, uint32_t aFlags, CacheFileIOListener *aCallback) : mFlags(aFlags) , mCallback(aCallback) , mKey(aKey) { MOZ_COUNT_CTOR(OpenFileEvent); mIOMan = CacheFileIOManager::gInstance; } protected: ~OpenFileEvent() { MOZ_COUNT_DTOR(OpenFileEvent); } public: NS_IMETHOD Run() { nsresult rv = NS_OK; if (!(mFlags & CacheFileIOManager::SPECIAL_FILE)) { SHA1Sum sum; sum.update(mKey.BeginReading(), mKey.Length()); sum.finish(mHash); } if (!mIOMan) { rv = NS_ERROR_NOT_INITIALIZED; } else { if (mFlags & CacheFileIOManager::SPECIAL_FILE) { rv = mIOMan->OpenSpecialFileInternal(mKey, mFlags, getter_AddRefs(mHandle)); } else { rv = mIOMan->OpenFileInternal(&mHash, mKey, mFlags, getter_AddRefs(mHandle)); } mIOMan = nullptr; if (mHandle) { if (mHandle->Key().IsEmpty()) { mHandle->Key() = mKey; } } } mCallback->OnFileOpened(mHandle, rv); return NS_OK; } protected: SHA1Sum::Hash mHash; uint32_t mFlags; nsCOMPtr mCallback; RefPtr mIOMan; RefPtr mHandle; nsCString mKey; }; class ReadEvent : public nsRunnable { public: ReadEvent(CacheFileHandle *aHandle, int64_t aOffset, char *aBuf, int32_t aCount, CacheFileIOListener *aCallback) : mHandle(aHandle) , mOffset(aOffset) , mBuf(aBuf) , mCount(aCount) , mCallback(aCallback) { MOZ_COUNT_CTOR(ReadEvent); } protected: ~ReadEvent() { MOZ_COUNT_DTOR(ReadEvent); } public: NS_IMETHOD Run() { nsresult rv; if (mHandle->IsClosed()) { rv = NS_ERROR_NOT_INITIALIZED; } else { rv = CacheFileIOManager::gInstance->ReadInternal( mHandle, mOffset, mBuf, mCount); } mCallback->OnDataRead(mHandle, mBuf, rv); return NS_OK; } protected: RefPtr mHandle; int64_t mOffset; char *mBuf; int32_t mCount; nsCOMPtr mCallback; }; class WriteEvent : public nsRunnable { public: WriteEvent(CacheFileHandle *aHandle, int64_t aOffset, const char *aBuf, int32_t aCount, bool aValidate, bool aTruncate, CacheFileIOListener *aCallback) : mHandle(aHandle) , mOffset(aOffset) , mBuf(aBuf) , mCount(aCount) , mValidate(aValidate) , mTruncate(aTruncate) , mCallback(aCallback) { MOZ_COUNT_CTOR(WriteEvent); } protected: ~WriteEvent() { MOZ_COUNT_DTOR(WriteEvent); if (!mCallback && mBuf) { free(const_cast(mBuf)); } } public: NS_IMETHOD Run() { nsresult rv; if (mHandle->IsClosed()) { rv = NS_ERROR_NOT_INITIALIZED; } else { rv = CacheFileIOManager::gInstance->WriteInternal( mHandle, mOffset, mBuf, mCount, mValidate, mTruncate); if (NS_FAILED(rv) && !mCallback) { // No listener is going to handle the error, doom the file CacheFileIOManager::gInstance->DoomFileInternal(mHandle); } } if (mCallback) { mCallback->OnDataWritten(mHandle, mBuf, rv); } else { free(const_cast(mBuf)); mBuf = nullptr; } return NS_OK; } protected: RefPtr mHandle; int64_t mOffset; const char *mBuf; int32_t mCount; bool mValidate : 1; bool mTruncate : 1; nsCOMPtr mCallback; }; class DoomFileEvent : public nsRunnable { public: DoomFileEvent(CacheFileHandle *aHandle, CacheFileIOListener *aCallback) : mCallback(aCallback) , mHandle(aHandle) { MOZ_COUNT_CTOR(DoomFileEvent); } protected: ~DoomFileEvent() { MOZ_COUNT_DTOR(DoomFileEvent); } public: NS_IMETHOD Run() { nsresult rv; if (mHandle->IsClosed()) { rv = NS_ERROR_NOT_INITIALIZED; } else { rv = CacheFileIOManager::gInstance->DoomFileInternal(mHandle); } if (mCallback) { mCallback->OnFileDoomed(mHandle, rv); } return NS_OK; } protected: nsCOMPtr mCallback; nsCOMPtr mTarget; RefPtr mHandle; }; class DoomFileByKeyEvent : public nsRunnable { public: DoomFileByKeyEvent(const nsACString &aKey, CacheFileIOListener *aCallback) : mCallback(aCallback) { MOZ_COUNT_CTOR(DoomFileByKeyEvent); SHA1Sum sum; sum.update(aKey.BeginReading(), aKey.Length()); sum.finish(mHash); mIOMan = CacheFileIOManager::gInstance; } protected: ~DoomFileByKeyEvent() { MOZ_COUNT_DTOR(DoomFileByKeyEvent); } public: NS_IMETHOD Run() { nsresult rv; if (!mIOMan) { rv = NS_ERROR_NOT_INITIALIZED; } else { rv = mIOMan->DoomFileByKeyInternal(&mHash); mIOMan = nullptr; } if (mCallback) { mCallback->OnFileDoomed(nullptr, rv); } return NS_OK; } protected: SHA1Sum::Hash mHash; nsCOMPtr mCallback; RefPtr mIOMan; }; class ReleaseNSPRHandleEvent : public nsRunnable { public: explicit ReleaseNSPRHandleEvent(CacheFileHandle *aHandle) : mHandle(aHandle) { MOZ_COUNT_CTOR(ReleaseNSPRHandleEvent); } protected: ~ReleaseNSPRHandleEvent() { MOZ_COUNT_DTOR(ReleaseNSPRHandleEvent); } public: NS_IMETHOD Run() { if (mHandle->mFD && !mHandle->IsClosed()) { CacheFileIOManager::gInstance->ReleaseNSPRHandleInternal(mHandle); } return NS_OK; } protected: RefPtr mHandle; }; class TruncateSeekSetEOFEvent : public nsRunnable { public: TruncateSeekSetEOFEvent(CacheFileHandle *aHandle, int64_t aTruncatePos, int64_t aEOFPos, CacheFileIOListener *aCallback) : mHandle(aHandle) , mTruncatePos(aTruncatePos) , mEOFPos(aEOFPos) , mCallback(aCallback) { MOZ_COUNT_CTOR(TruncateSeekSetEOFEvent); } protected: ~TruncateSeekSetEOFEvent() { MOZ_COUNT_DTOR(TruncateSeekSetEOFEvent); } public: NS_IMETHOD Run() { nsresult rv; if (mHandle->IsClosed()) { rv = NS_ERROR_NOT_INITIALIZED; } else { rv = CacheFileIOManager::gInstance->TruncateSeekSetEOFInternal( mHandle, mTruncatePos, mEOFPos); } if (mCallback) { mCallback->OnEOFSet(mHandle, rv); } return NS_OK; } protected: RefPtr mHandle; int64_t mTruncatePos; int64_t mEOFPos; nsCOMPtr mCallback; }; class RenameFileEvent : public nsRunnable { public: RenameFileEvent(CacheFileHandle *aHandle, const nsACString &aNewName, CacheFileIOListener *aCallback) : mHandle(aHandle) , mNewName(aNewName) , mCallback(aCallback) { MOZ_COUNT_CTOR(RenameFileEvent); } protected: ~RenameFileEvent() { MOZ_COUNT_DTOR(RenameFileEvent); } public: NS_IMETHOD Run() { nsresult rv; if (mHandle->IsClosed()) { rv = NS_ERROR_NOT_INITIALIZED; } else { rv = CacheFileIOManager::gInstance->RenameFileInternal(mHandle, mNewName); } if (mCallback) { mCallback->OnFileRenamed(mHandle, rv); } return NS_OK; } protected: RefPtr mHandle; nsCString mNewName; nsCOMPtr mCallback; }; class InitIndexEntryEvent : public nsRunnable { public: InitIndexEntryEvent(CacheFileHandle *aHandle, uint32_t aAppId, bool aAnonymous, bool aInBrowser, bool aPinning) : mHandle(aHandle) , mAppId(aAppId) , mAnonymous(aAnonymous) , mInBrowser(aInBrowser) , mPinning(aPinning) { MOZ_COUNT_CTOR(InitIndexEntryEvent); } protected: ~InitIndexEntryEvent() { MOZ_COUNT_DTOR(InitIndexEntryEvent); } public: NS_IMETHOD Run() { if (mHandle->IsClosed() || mHandle->IsDoomed()) { return NS_OK; } CacheIndex::InitEntry(mHandle->Hash(), mAppId, mAnonymous, mInBrowser, mPinning); // We cannot set the filesize before we init the entry. If we're opening // an existing entry file, frecency and expiration time will be set after // parsing the entry file, but we must set the filesize here since nobody is // going to set it if there is no write to the file. uint32_t sizeInK = mHandle->FileSizeInK(); CacheIndex::UpdateEntry(mHandle->Hash(), nullptr, nullptr, &sizeInK); return NS_OK; } protected: RefPtr mHandle; uint32_t mAppId; bool mAnonymous; bool mInBrowser; bool mPinning; }; class UpdateIndexEntryEvent : public nsRunnable { public: UpdateIndexEntryEvent(CacheFileHandle *aHandle, const uint32_t *aFrecency, const uint32_t *aExpirationTime) : mHandle(aHandle) , mHasFrecency(false) , mHasExpirationTime(false) { MOZ_COUNT_CTOR(UpdateIndexEntryEvent); if (aFrecency) { mHasFrecency = true; mFrecency = *aFrecency; } if (aExpirationTime) { mHasExpirationTime = true; mExpirationTime = *aExpirationTime; } } protected: ~UpdateIndexEntryEvent() { MOZ_COUNT_DTOR(UpdateIndexEntryEvent); } public: NS_IMETHOD Run() { if (mHandle->IsClosed() || mHandle->IsDoomed()) { return NS_OK; } CacheIndex::UpdateEntry(mHandle->Hash(), mHasFrecency ? &mFrecency : nullptr, mHasExpirationTime ? &mExpirationTime : nullptr, nullptr); return NS_OK; } protected: RefPtr mHandle; bool mHasFrecency; bool mHasExpirationTime; uint32_t mFrecency; uint32_t mExpirationTime; }; class MetadataWriteScheduleEvent : public nsRunnable { public: enum EMode { SCHEDULE, UNSCHEDULE, SHUTDOWN } mMode; RefPtr mFile; RefPtr mIOMan; MetadataWriteScheduleEvent(CacheFileIOManager * aManager, CacheFile * aFile, EMode aMode) : mMode(aMode) , mFile(aFile) , mIOMan(aManager) { } virtual ~MetadataWriteScheduleEvent() { } NS_IMETHOD Run() { RefPtr ioMan = CacheFileIOManager::gInstance; if (!ioMan) { NS_WARNING("CacheFileIOManager already gone in MetadataWriteScheduleEvent::Run()"); return NS_OK; } switch (mMode) { case SCHEDULE: ioMan->ScheduleMetadataWriteInternal(mFile); break; case UNSCHEDULE: ioMan->UnscheduleMetadataWriteInternal(mFile); break; case SHUTDOWN: ioMan->ShutdownMetadataWriteSchedulingInternal(); break; } return NS_OK; } }; CacheFileIOManager * CacheFileIOManager::gInstance = nullptr; NS_IMPL_ISUPPORTS(CacheFileIOManager, nsITimerCallback) CacheFileIOManager::CacheFileIOManager() : mShuttingDown(false) , mTreeCreated(false) , mOverLimitEvicting(false) , mRemovingTrashDirs(false) { LOG(("CacheFileIOManager::CacheFileIOManager [this=%p]", this)); MOZ_COUNT_CTOR(CacheFileIOManager); MOZ_ASSERT(!gInstance, "multiple CacheFileIOManager instances!"); } CacheFileIOManager::~CacheFileIOManager() { LOG(("CacheFileIOManager::~CacheFileIOManager [this=%p]", this)); MOZ_COUNT_DTOR(CacheFileIOManager); } // static nsresult CacheFileIOManager::Init() { LOG(("CacheFileIOManager::Init()")); MOZ_ASSERT(NS_IsMainThread()); if (gInstance) { return NS_ERROR_ALREADY_INITIALIZED; } RefPtr ioMan = new CacheFileIOManager(); nsresult rv = ioMan->InitInternal(); NS_ENSURE_SUCCESS(rv, rv); ioMan.swap(gInstance); return NS_OK; } nsresult CacheFileIOManager::InitInternal() { nsresult rv; mIOThread = new CacheIOThread(); rv = mIOThread->Init(); MOZ_ASSERT(NS_SUCCEEDED(rv), "Can't create background thread"); NS_ENSURE_SUCCESS(rv, rv); mStartTime = TimeStamp::NowLoRes(); return NS_OK; } // static nsresult CacheFileIOManager::Shutdown() { LOG(("CacheFileIOManager::Shutdown() [gInstance=%p]", gInstance)); MOZ_ASSERT(NS_IsMainThread()); if (!gInstance) { return NS_ERROR_NOT_INITIALIZED; } Telemetry::AutoTimer shutdownTimer; CacheIndex::PreShutdown(); ShutdownMetadataWriteScheduling(); { mozilla::Mutex lock("CacheFileIOManager::Shutdown() lock"); mozilla::CondVar condVar(lock, "CacheFileIOManager::Shutdown() condVar"); MutexAutoLock autoLock(lock); RefPtr ev = new ShutdownEvent(&lock, &condVar); DebugOnly rv; rv = gInstance->mIOThread->Dispatch(ev, CacheIOThread::CLOSE); MOZ_ASSERT(NS_SUCCEEDED(rv)); condVar.Wait(); } MOZ_ASSERT(gInstance->mHandles.HandleCount() == 0); MOZ_ASSERT(gInstance->mHandlesByLastUsed.Length() == 0); if (gInstance->mIOThread) { gInstance->mIOThread->Shutdown(); } CacheIndex::Shutdown(); if (CacheObserver::ClearCacheOnShutdown()) { Telemetry::AutoTimer totalTimer; gInstance->SyncRemoveAllCacheFiles(); } RefPtr ioMan; ioMan.swap(gInstance); return NS_OK; } nsresult CacheFileIOManager::ShutdownInternal() { LOG(("CacheFileIOManager::ShutdownInternal() [this=%p]", this)); MOZ_ASSERT(mIOThread->IsCurrentThread()); // No new handles can be created after this flag is set mShuttingDown = true; // close all handles and delete all associated files nsTArray > handles; mHandles.GetAllHandles(&handles); handles.AppendElements(mSpecialHandles); for (uint32_t i=0 ; imClosed = true; h->Log(); // Close file handle if (h->mFD) { ReleaseNSPRHandleInternal(h); } // Remove file if entry is doomed or invalid if (h->mFileExists && (h->mIsDoomed || h->mInvalid)) { LOG(("CacheFileIOManager::ShutdownInternal() - Removing file from disk")); h->mFile->Remove(false); } if (!h->IsSpecialFile() && !h->mIsDoomed && (h->mInvalid || !h->mFileExists)) { CacheIndex::RemoveEntry(h->Hash()); } // Remove the handle from mHandles/mSpecialHandles if (h->IsSpecialFile()) { mSpecialHandles.RemoveElement(h); } else { mHandles.RemoveHandle(h); } // Pointer to the hash is no longer valid once the last handle with the // given hash is released. Null out the pointer so that we crash if there // is a bug in this code and we dereference the pointer after this point. if (!h->IsSpecialFile()) { h->mHash = nullptr; } } // Assert the table is empty. When we are here, no new handles can be added // and handles will no longer remove them self from this table and we don't // want to keep invalid handles here. Also, there is no lookup after this // point to happen. MOZ_ASSERT(mHandles.HandleCount() == 0); // Release trash directory enumerator if (mTrashDirEnumerator) { mTrashDirEnumerator->Close(); mTrashDirEnumerator = nullptr; } return NS_OK; } // static nsresult CacheFileIOManager::OnProfile() { LOG(("CacheFileIOManager::OnProfile() [gInstance=%p]", gInstance)); RefPtr ioMan = gInstance; if (!ioMan) { // CacheFileIOManager::Init() failed, probably could not create the IO // thread, just go with it... return NS_ERROR_NOT_INITIALIZED; } nsresult rv; nsCOMPtr directory; CacheObserver::ParentDirOverride(getter_AddRefs(directory)); #if defined(MOZ_WIDGET_ANDROID) nsCOMPtr profilelessDirectory; char* cachePath = getenv("CACHE_DIRECTORY"); if (!directory && cachePath && *cachePath) { rv = NS_NewNativeLocalFile(nsDependentCString(cachePath), true, getter_AddRefs(directory)); if (NS_SUCCEEDED(rv)) { // Save this directory as the profileless path. rv = directory->Clone(getter_AddRefs(profilelessDirectory)); NS_ENSURE_SUCCESS(rv, rv); // Add profile leaf name to the directory name to distinguish // multiple profiles Fennec supports. nsCOMPtr profD; rv = NS_GetSpecialDirectory(NS_APP_USER_PROFILE_50_DIR, getter_AddRefs(profD)); nsAutoCString leafName; if (NS_SUCCEEDED(rv)) { rv = profD->GetNativeLeafName(leafName); } if (NS_SUCCEEDED(rv)) { rv = directory->AppendNative(leafName); } if (NS_FAILED(rv)) { directory = nullptr; } } } #endif if (!directory) { rv = NS_GetSpecialDirectory(NS_APP_CACHE_PARENT_DIR, getter_AddRefs(directory)); } if (!directory) { rv = NS_GetSpecialDirectory(NS_APP_USER_PROFILE_LOCAL_50_DIR, getter_AddRefs(directory)); } if (directory) { rv = directory->Append(NS_LITERAL_STRING("cache2")); NS_ENSURE_SUCCESS(rv, rv); } // All functions return a clone. ioMan->mCacheDirectory.swap(directory); #if defined(MOZ_WIDGET_ANDROID) if (profilelessDirectory) { rv = profilelessDirectory->Append(NS_LITERAL_STRING("cache2")); NS_ENSURE_SUCCESS(rv, rv); } ioMan->mCacheProfilelessDirectory.swap(profilelessDirectory); #endif if (ioMan->mCacheDirectory) { CacheIndex::Init(ioMan->mCacheDirectory); } return NS_OK; } // static already_AddRefed CacheFileIOManager::IOTarget() { nsCOMPtr target; if (gInstance && gInstance->mIOThread) { target = gInstance->mIOThread->Target(); } return target.forget(); } // static already_AddRefed CacheFileIOManager::IOThread() { RefPtr thread; if (gInstance) { thread = gInstance->mIOThread; } return thread.forget(); } // static bool CacheFileIOManager::IsOnIOThread() { RefPtr ioMan = gInstance; if (ioMan && ioMan->mIOThread) { return ioMan->mIOThread->IsCurrentThread(); } return false; } // static bool CacheFileIOManager::IsOnIOThreadOrCeased() { RefPtr ioMan = gInstance; if (ioMan && ioMan->mIOThread) { return ioMan->mIOThread->IsCurrentThread(); } // Ceased... return true; } // static bool CacheFileIOManager::IsShutdown() { if (!gInstance) { return true; } return gInstance->mShuttingDown; } // static nsresult CacheFileIOManager::ScheduleMetadataWrite(CacheFile * aFile) { RefPtr ioMan = gInstance; NS_ENSURE_TRUE(ioMan, NS_ERROR_NOT_INITIALIZED); NS_ENSURE_TRUE(!ioMan->mShuttingDown, NS_ERROR_NOT_INITIALIZED); RefPtr event = new MetadataWriteScheduleEvent( ioMan, aFile, MetadataWriteScheduleEvent::SCHEDULE); nsCOMPtr target = ioMan->IOTarget(); NS_ENSURE_TRUE(target, NS_ERROR_UNEXPECTED); return target->Dispatch(event, nsIEventTarget::DISPATCH_NORMAL); } nsresult CacheFileIOManager::ScheduleMetadataWriteInternal(CacheFile * aFile) { MOZ_ASSERT(IsOnIOThreadOrCeased()); nsresult rv; if (!mMetadataWritesTimer) { mMetadataWritesTimer = do_CreateInstance("@mozilla.org/timer;1", &rv); NS_ENSURE_SUCCESS(rv, rv); rv = mMetadataWritesTimer->InitWithCallback( this, kMetadataWriteDelay, nsITimer::TYPE_ONE_SHOT); NS_ENSURE_SUCCESS(rv, rv); } if (mScheduledMetadataWrites.IndexOf(aFile) != mScheduledMetadataWrites.NoIndex) { return NS_OK; } mScheduledMetadataWrites.AppendElement(aFile); return NS_OK; } // static nsresult CacheFileIOManager::UnscheduleMetadataWrite(CacheFile * aFile) { RefPtr ioMan = gInstance; NS_ENSURE_TRUE(ioMan, NS_ERROR_NOT_INITIALIZED); NS_ENSURE_TRUE(!ioMan->mShuttingDown, NS_ERROR_NOT_INITIALIZED); RefPtr event = new MetadataWriteScheduleEvent( ioMan, aFile, MetadataWriteScheduleEvent::UNSCHEDULE); nsCOMPtr target = ioMan->IOTarget(); NS_ENSURE_TRUE(target, NS_ERROR_UNEXPECTED); return target->Dispatch(event, nsIEventTarget::DISPATCH_NORMAL); } nsresult CacheFileIOManager::UnscheduleMetadataWriteInternal(CacheFile * aFile) { MOZ_ASSERT(IsOnIOThreadOrCeased()); mScheduledMetadataWrites.RemoveElement(aFile); if (mScheduledMetadataWrites.Length() == 0 && mMetadataWritesTimer) { mMetadataWritesTimer->Cancel(); mMetadataWritesTimer = nullptr; } return NS_OK; } // static nsresult CacheFileIOManager::ShutdownMetadataWriteScheduling() { RefPtr ioMan = gInstance; NS_ENSURE_TRUE(ioMan, NS_ERROR_NOT_INITIALIZED); RefPtr event = new MetadataWriteScheduleEvent( ioMan, nullptr, MetadataWriteScheduleEvent::SHUTDOWN); nsCOMPtr target = ioMan->IOTarget(); NS_ENSURE_TRUE(target, NS_ERROR_UNEXPECTED); return target->Dispatch(event, nsIEventTarget::DISPATCH_NORMAL); } nsresult CacheFileIOManager::ShutdownMetadataWriteSchedulingInternal() { MOZ_ASSERT(IsOnIOThreadOrCeased()); nsTArray > files; files.SwapElements(mScheduledMetadataWrites); for (uint32_t i = 0; i < files.Length(); ++i) { CacheFile * file = files[i]; file->WriteMetadataIfNeeded(); } if (mMetadataWritesTimer) { mMetadataWritesTimer->Cancel(); mMetadataWritesTimer = nullptr; } return NS_OK; } NS_IMETHODIMP CacheFileIOManager::Notify(nsITimer * aTimer) { MOZ_ASSERT(IsOnIOThreadOrCeased()); MOZ_ASSERT(mMetadataWritesTimer == aTimer); mMetadataWritesTimer = nullptr; nsTArray > files; files.SwapElements(mScheduledMetadataWrites); for (uint32_t i = 0; i < files.Length(); ++i) { CacheFile * file = files[i]; file->WriteMetadataIfNeeded(); } return NS_OK; } // static nsresult CacheFileIOManager::OpenFile(const nsACString &aKey, uint32_t aFlags, CacheFileIOListener *aCallback) { LOG(("CacheFileIOManager::OpenFile() [key=%s, flags=%d, listener=%p]", PromiseFlatCString(aKey).get(), aFlags, aCallback)); nsresult rv; RefPtr ioMan = gInstance; if (!ioMan) { return NS_ERROR_NOT_INITIALIZED; } bool priority = aFlags & CacheFileIOManager::PRIORITY; RefPtr ev = new OpenFileEvent(aKey, aFlags, aCallback); rv = ioMan->mIOThread->Dispatch(ev, priority ? CacheIOThread::OPEN_PRIORITY : CacheIOThread::OPEN); NS_ENSURE_SUCCESS(rv, rv); return NS_OK; } nsresult CacheFileIOManager::OpenFileInternal(const SHA1Sum::Hash *aHash, const nsACString &aKey, uint32_t aFlags, CacheFileHandle **_retval) { LOG(("CacheFileIOManager::OpenFileInternal() [hash=%08x%08x%08x%08x%08x, " "key=%s, flags=%d]", LOGSHA1(aHash), PromiseFlatCString(aKey).get(), aFlags)); MOZ_ASSERT(CacheFileIOManager::IsOnIOThread()); nsresult rv; if (mShuttingDown) { return NS_ERROR_NOT_INITIALIZED; } if (!mTreeCreated) { rv = CreateCacheTree(); if (NS_FAILED(rv)) return rv; } CacheFileHandle::PinningStatus pinning = aFlags & PINNED ? CacheFileHandle::PinningStatus::PINNED : CacheFileHandle::PinningStatus::NON_PINNED; nsCOMPtr file; rv = GetFile(aHash, getter_AddRefs(file)); NS_ENSURE_SUCCESS(rv, rv); RefPtr handle; mHandles.GetHandle(aHash, getter_AddRefs(handle)); if ((aFlags & (OPEN | CREATE | CREATE_NEW)) == CREATE_NEW) { if (handle) { rv = DoomFileInternal(handle); NS_ENSURE_SUCCESS(rv, rv); handle = nullptr; } rv = mHandles.NewHandle(aHash, aFlags & PRIORITY, pinning, getter_AddRefs(handle)); NS_ENSURE_SUCCESS(rv, rv); bool exists; rv = file->Exists(&exists); NS_ENSURE_SUCCESS(rv, rv); if (exists) { CacheIndex::RemoveEntry(aHash); LOG(("CacheFileIOManager::OpenFileInternal() - Removing old file from " "disk")); rv = file->Remove(false); if (NS_FAILED(rv)) { NS_WARNING("Cannot remove old entry from the disk"); LOG(("CacheFileIOManager::OpenFileInternal() - Removing old file failed" ". [rv=0x%08x]", rv)); } } CacheIndex::AddEntry(aHash); handle->mFile.swap(file); handle->mFileSize = 0; } if (handle) { handle.swap(*_retval); return NS_OK; } bool exists, evictedAsPinned = false, evictedAsNonPinned = false; rv = file->Exists(&exists); NS_ENSURE_SUCCESS(rv, rv); if (exists && mContextEvictor) { if (mContextEvictor->ContextsCount() == 0) { mContextEvictor = nullptr; } else { mContextEvictor->WasEvicted(aKey, file, &evictedAsPinned, &evictedAsNonPinned); } } if (!exists && (aFlags & (OPEN | CREATE | CREATE_NEW)) == OPEN) { return NS_ERROR_NOT_AVAILABLE; } if (exists) { // For existing files we determine the pinning status later, after the metadata gets parsed. pinning = CacheFileHandle::PinningStatus::UNKNOWN; } rv = mHandles.NewHandle(aHash, aFlags & PRIORITY, pinning, getter_AddRefs(handle)); NS_ENSURE_SUCCESS(rv, rv); if (exists) { // If this file has been found evicted through the context file evictor above for // any of pinned or non-pinned state, these calls ensure we doom the handle ASAP // we know the real pinning state after metadta has been parsed. DoomFileInternal // on the |handle| doesn't doom right now, since the pinning state is unknown // and we pass down a pinning restriction. if (evictedAsPinned) { rv = DoomFileInternal(handle, DOOM_WHEN_PINNED); MOZ_ASSERT(!handle->IsDoomed() && NS_SUCCEEDED(rv)); } if (evictedAsNonPinned) { rv = DoomFileInternal(handle, DOOM_WHEN_NON_PINNED); MOZ_ASSERT(!handle->IsDoomed() && NS_SUCCEEDED(rv)); } rv = file->GetFileSize(&handle->mFileSize); NS_ENSURE_SUCCESS(rv, rv); handle->mFileExists = true; CacheIndex::EnsureEntryExists(aHash); } else { handle->mFileSize = 0; CacheIndex::AddEntry(aHash); } handle->mFile.swap(file); handle.swap(*_retval); return NS_OK; } nsresult CacheFileIOManager::OpenSpecialFileInternal(const nsACString &aKey, uint32_t aFlags, CacheFileHandle **_retval) { LOG(("CacheFileIOManager::OpenSpecialFileInternal() [key=%s, flags=%d]", PromiseFlatCString(aKey).get(), aFlags)); MOZ_ASSERT(CacheFileIOManager::IsOnIOThread()); nsresult rv; if (mShuttingDown) { return NS_ERROR_NOT_INITIALIZED; } if (!mTreeCreated) { rv = CreateCacheTree(); if (NS_FAILED(rv)) return rv; } nsCOMPtr file; rv = GetSpecialFile(aKey, getter_AddRefs(file)); NS_ENSURE_SUCCESS(rv, rv); RefPtr handle; for (uint32_t i = 0 ; i < mSpecialHandles.Length() ; i++) { if (!mSpecialHandles[i]->IsDoomed() && mSpecialHandles[i]->Key() == aKey) { handle = mSpecialHandles[i]; break; } } if ((aFlags & (OPEN | CREATE | CREATE_NEW)) == CREATE_NEW) { if (handle) { rv = DoomFileInternal(handle); NS_ENSURE_SUCCESS(rv, rv); handle = nullptr; } handle = new CacheFileHandle(aKey, aFlags & PRIORITY, CacheFileHandle::PinningStatus::NON_PINNED); mSpecialHandles.AppendElement(handle); bool exists; rv = file->Exists(&exists); NS_ENSURE_SUCCESS(rv, rv); if (exists) { LOG(("CacheFileIOManager::OpenSpecialFileInternal() - Removing file from " "disk")); rv = file->Remove(false); if (NS_FAILED(rv)) { NS_WARNING("Cannot remove old entry from the disk"); LOG(("CacheFileIOManager::OpenSpecialFileInternal() - Removing file " "failed. [rv=0x%08x]", rv)); } } handle->mFile.swap(file); handle->mFileSize = 0; } if (handle) { handle.swap(*_retval); return NS_OK; } bool exists; rv = file->Exists(&exists); NS_ENSURE_SUCCESS(rv, rv); if (!exists && (aFlags & (OPEN | CREATE | CREATE_NEW)) == OPEN) { return NS_ERROR_NOT_AVAILABLE; } handle = new CacheFileHandle(aKey, aFlags & PRIORITY, CacheFileHandle::PinningStatus::NON_PINNED); mSpecialHandles.AppendElement(handle); if (exists) { rv = file->GetFileSize(&handle->mFileSize); NS_ENSURE_SUCCESS(rv, rv); handle->mFileExists = true; } else { handle->mFileSize = 0; } handle->mFile.swap(file); handle.swap(*_retval); return NS_OK; } nsresult CacheFileIOManager::CloseHandleInternal(CacheFileHandle *aHandle) { LOG(("CacheFileIOManager::CloseHandleInternal() [handle=%p]", aHandle)); MOZ_ASSERT(!aHandle->IsClosed()); aHandle->Log(); MOZ_ASSERT(CacheFileIOManager::IsOnIOThreadOrCeased()); // Close file handle if (aHandle->mFD) { ReleaseNSPRHandleInternal(aHandle); } // Delete the file if the entry was doomed or invalid if (aHandle->mIsDoomed || aHandle->mInvalid) { LOG(("CacheFileIOManager::CloseHandleInternal() - Removing file from " "disk")); aHandle->mFile->Remove(false); } if (!aHandle->IsSpecialFile() && !aHandle->mIsDoomed && (aHandle->mInvalid || !aHandle->mFileExists)) { CacheIndex::RemoveEntry(aHandle->Hash()); } // Don't remove handles after shutdown if (!mShuttingDown) { if (aHandle->IsSpecialFile()) { mSpecialHandles.RemoveElement(aHandle); } else { mHandles.RemoveHandle(aHandle); } } return NS_OK; } // static nsresult CacheFileIOManager::Read(CacheFileHandle *aHandle, int64_t aOffset, char *aBuf, int32_t aCount, CacheFileIOListener *aCallback) { LOG(("CacheFileIOManager::Read() [handle=%p, offset=%lld, count=%d, " "listener=%p]", aHandle, aOffset, aCount, aCallback)); nsresult rv; RefPtr ioMan = gInstance; if (aHandle->IsClosed() || !ioMan) { return NS_ERROR_NOT_INITIALIZED; } RefPtr ev = new ReadEvent(aHandle, aOffset, aBuf, aCount, aCallback); rv = ioMan->mIOThread->Dispatch(ev, aHandle->IsPriority() ? CacheIOThread::READ_PRIORITY : CacheIOThread::READ); NS_ENSURE_SUCCESS(rv, rv); return NS_OK; } nsresult CacheFileIOManager::ReadInternal(CacheFileHandle *aHandle, int64_t aOffset, char *aBuf, int32_t aCount) { LOG(("CacheFileIOManager::ReadInternal() [handle=%p, offset=%lld, count=%d]", aHandle, aOffset, aCount)); nsresult rv; if (!aHandle->mFileExists) { NS_WARNING("Trying to read from non-existent file"); return NS_ERROR_NOT_AVAILABLE; } if (!aHandle->mFD) { rv = OpenNSPRHandle(aHandle); NS_ENSURE_SUCCESS(rv, rv); } else { NSPRHandleUsed(aHandle); } // Check again, OpenNSPRHandle could figure out the file was gone. if (!aHandle->mFileExists) { NS_WARNING("Trying to read from non-existent file"); return NS_ERROR_NOT_AVAILABLE; } int64_t offset = PR_Seek64(aHandle->mFD, aOffset, PR_SEEK_SET); if (offset == -1) { return NS_ERROR_FAILURE; } int32_t bytesRead = PR_Read(aHandle->mFD, aBuf, aCount); if (bytesRead != aCount) { return NS_ERROR_FAILURE; } return NS_OK; } // static nsresult CacheFileIOManager::Write(CacheFileHandle *aHandle, int64_t aOffset, const char *aBuf, int32_t aCount, bool aValidate, bool aTruncate, CacheFileIOListener *aCallback) { LOG(("CacheFileIOManager::Write() [handle=%p, offset=%lld, count=%d, " "validate=%d, truncate=%d, listener=%p]", aHandle, aOffset, aCount, aValidate, aTruncate, aCallback)); nsresult rv; RefPtr ioMan = gInstance; if (aHandle->IsClosed() || !ioMan) { if (!aCallback) { // When no callback is provided, CacheFileIOManager is responsible for // releasing the buffer. We must release it even in case of failure. free(const_cast(aBuf)); } return NS_ERROR_NOT_INITIALIZED; } RefPtr ev = new WriteEvent(aHandle, aOffset, aBuf, aCount, aValidate, aTruncate, aCallback); rv = ioMan->mIOThread->Dispatch(ev, CacheIOThread::WRITE); NS_ENSURE_SUCCESS(rv, rv); return NS_OK; } static nsresult TruncFile(PRFileDesc *aFD, int64_t aEOF) { #if defined(XP_UNIX) if (ftruncate(PR_FileDesc2NativeHandle(aFD), aEOF) != 0) { NS_ERROR("ftruncate failed"); return NS_ERROR_FAILURE; } #elif defined(XP_WIN) int64_t cnt = PR_Seek64(aFD, aEOF, PR_SEEK_SET); if (cnt == -1) { return NS_ERROR_FAILURE; } if (!SetEndOfFile((HANDLE) PR_FileDesc2NativeHandle(aFD))) { NS_ERROR("SetEndOfFile failed"); return NS_ERROR_FAILURE; } #else MOZ_ASSERT(false, "Not implemented!"); return NS_ERROR_NOT_IMPLEMENTED; #endif return NS_OK; } nsresult CacheFileIOManager::WriteInternal(CacheFileHandle *aHandle, int64_t aOffset, const char *aBuf, int32_t aCount, bool aValidate, bool aTruncate) { LOG(("CacheFileIOManager::WriteInternal() [handle=%p, offset=%lld, count=%d, " "validate=%d, truncate=%d]", aHandle, aOffset, aCount, aValidate, aTruncate)); nsresult rv; if (!aHandle->mFileExists) { rv = CreateFile(aHandle); NS_ENSURE_SUCCESS(rv, rv); } if (!aHandle->mFD) { rv = OpenNSPRHandle(aHandle); NS_ENSURE_SUCCESS(rv, rv); } else { NSPRHandleUsed(aHandle); } // Check again, OpenNSPRHandle could figure out the file was gone. if (!aHandle->mFileExists) { return NS_ERROR_NOT_AVAILABLE; } // Check whether this write would cause critical low disk space. if (aHandle->mFileSize < aOffset + aCount) { int64_t freeSpace = -1; rv = mCacheDirectory->GetDiskSpaceAvailable(&freeSpace); if (NS_WARN_IF(NS_FAILED(rv))) { LOG(("CacheFileIOManager::WriteInternal() - GetDiskSpaceAvailable() " "failed! [rv=0x%08x]", rv)); } else { uint32_t limit = CacheObserver::DiskFreeSpaceHardLimit(); if (freeSpace - aOffset - aCount + aHandle->mFileSize < limit) { LOG(("CacheFileIOManager::WriteInternal() - Low free space, refusing " "to write! [freeSpace=%lld, limit=%u]", freeSpace, limit)); return NS_ERROR_FILE_DISK_FULL; } } } // Write invalidates the entry by default aHandle->mInvalid = true; int64_t offset = PR_Seek64(aHandle->mFD, aOffset, PR_SEEK_SET); if (offset == -1) { return NS_ERROR_FAILURE; } int32_t bytesWritten = PR_Write(aHandle->mFD, aBuf, aCount); if (bytesWritten != -1) { uint32_t oldSizeInK = aHandle->FileSizeInK(); int64_t writeEnd = aOffset + bytesWritten; if (aTruncate) { rv = TruncFile(aHandle->mFD, writeEnd); NS_ENSURE_SUCCESS(rv, rv); aHandle->mFileSize = writeEnd; } else { if (aHandle->mFileSize < writeEnd) { aHandle->mFileSize = writeEnd; } } uint32_t newSizeInK = aHandle->FileSizeInK(); if (oldSizeInK != newSizeInK && !aHandle->IsDoomed() && !aHandle->IsSpecialFile()) { CacheIndex::UpdateEntry(aHandle->Hash(), nullptr, nullptr, &newSizeInK); if (oldSizeInK < newSizeInK) { EvictIfOverLimitInternal(); } } } if (bytesWritten != aCount) { return NS_ERROR_FAILURE; } // Write was successful and this write validates the entry (i.e. metadata) if (aValidate) { aHandle->mInvalid = false; } return NS_OK; } // static nsresult CacheFileIOManager::DoomFile(CacheFileHandle *aHandle, CacheFileIOListener *aCallback) { LOG(("CacheFileIOManager::DoomFile() [handle=%p, listener=%p]", aHandle, aCallback)); nsresult rv; RefPtr ioMan = gInstance; if (aHandle->IsClosed() || !ioMan) { return NS_ERROR_NOT_INITIALIZED; } RefPtr ev = new DoomFileEvent(aHandle, aCallback); rv = ioMan->mIOThread->Dispatch(ev, aHandle->IsPriority() ? CacheIOThread::OPEN_PRIORITY : CacheIOThread::OPEN); NS_ENSURE_SUCCESS(rv, rv); return NS_OK; } nsresult CacheFileIOManager::DoomFileInternal(CacheFileHandle *aHandle, PinningDoomRestriction aPinningDoomRestriction) { LOG(("CacheFileIOManager::DoomFileInternal() [handle=%p]", aHandle)); aHandle->Log(); MOZ_ASSERT(CacheFileIOManager::IsOnIOThreadOrCeased()); nsresult rv; if (aHandle->IsDoomed()) { return NS_OK; } if (aPinningDoomRestriction > NO_RESTRICTION) { switch (aHandle->mPinning) { case CacheFileHandle::PinningStatus::NON_PINNED: if (MOZ_LIKELY(aPinningDoomRestriction != DOOM_WHEN_NON_PINNED)) { LOG((" not dooming, it's a non-pinned handle")); return NS_OK; } // Doom now break; case CacheFileHandle::PinningStatus::PINNED: if (MOZ_UNLIKELY(aPinningDoomRestriction != DOOM_WHEN_PINNED)) { LOG((" not dooming, it's a pinned handle")); return NS_OK; } // Doom now break; case CacheFileHandle::PinningStatus::UNKNOWN: if (MOZ_LIKELY(aPinningDoomRestriction == DOOM_WHEN_NON_PINNED)) { LOG((" doom when non-pinned set")); aHandle->mDoomWhenFoundNonPinned = true; } else if (MOZ_UNLIKELY(aPinningDoomRestriction == DOOM_WHEN_PINNED)) { LOG((" doom when pinned set")); aHandle->mDoomWhenFoundPinned = true; } LOG((" pinning status not known, deferring doom decision")); return NS_OK; } } if (aHandle->mFileExists) { // we need to move the current file to the doomed directory if (aHandle->mFD) { ReleaseNSPRHandleInternal(aHandle); } // find unused filename nsCOMPtr file; rv = GetDoomedFile(getter_AddRefs(file)); NS_ENSURE_SUCCESS(rv, rv); nsCOMPtr parentDir; rv = file->GetParent(getter_AddRefs(parentDir)); NS_ENSURE_SUCCESS(rv, rv); nsAutoCString leafName; rv = file->GetNativeLeafName(leafName); NS_ENSURE_SUCCESS(rv, rv); rv = aHandle->mFile->MoveToNative(parentDir, leafName); if (NS_ERROR_FILE_NOT_FOUND == rv || NS_ERROR_FILE_TARGET_DOES_NOT_EXIST == rv) { LOG((" file already removed under our hands")); aHandle->mFileExists = false; rv = NS_OK; } else { NS_ENSURE_SUCCESS(rv, rv); aHandle->mFile.swap(file); } } if (!aHandle->IsSpecialFile()) { CacheIndex::RemoveEntry(aHandle->Hash()); } aHandle->mIsDoomed = true; if (!aHandle->IsSpecialFile()) { RefPtr storageService = CacheStorageService::Self(); if (storageService) { nsAutoCString idExtension, url; nsCOMPtr info = CacheFileUtils::ParseKey(aHandle->Key(), &idExtension, &url); MOZ_ASSERT(info); if (info) { storageService->CacheFileDoomed(info, idExtension, url); } } } return NS_OK; } // static nsresult CacheFileIOManager::DoomFileByKey(const nsACString &aKey, CacheFileIOListener *aCallback) { LOG(("CacheFileIOManager::DoomFileByKey() [key=%s, listener=%p]", PromiseFlatCString(aKey).get(), aCallback)); nsresult rv; RefPtr ioMan = gInstance; if (!ioMan) { return NS_ERROR_NOT_INITIALIZED; } RefPtr ev = new DoomFileByKeyEvent(aKey, aCallback); rv = ioMan->mIOThread->DispatchAfterPendingOpens(ev); NS_ENSURE_SUCCESS(rv, rv); return NS_OK; } nsresult CacheFileIOManager::DoomFileByKeyInternal(const SHA1Sum::Hash *aHash) { LOG(("CacheFileIOManager::DoomFileByKeyInternal() [hash=%08x%08x%08x%08x%08x]" , LOGSHA1(aHash))); MOZ_ASSERT(CacheFileIOManager::IsOnIOThreadOrCeased()); nsresult rv; if (mShuttingDown) { return NS_ERROR_NOT_INITIALIZED; } if (!mCacheDirectory) { return NS_ERROR_FILE_INVALID_PATH; } // Find active handle RefPtr handle; mHandles.GetHandle(aHash, getter_AddRefs(handle)); if (handle) { handle->Log(); return DoomFileInternal(handle); } // There is no handle for this file, delete the file if exists nsCOMPtr file; rv = GetFile(aHash, getter_AddRefs(file)); NS_ENSURE_SUCCESS(rv, rv); bool exists; rv = file->Exists(&exists); NS_ENSURE_SUCCESS(rv, rv); if (!exists) { return NS_ERROR_NOT_AVAILABLE; } LOG(("CacheFileIOManager::DoomFileByKeyInternal() - Removing file from " "disk")); rv = file->Remove(false); if (NS_FAILED(rv)) { NS_WARNING("Cannot remove old entry from the disk"); LOG(("CacheFileIOManager::DoomFileByKeyInternal() - Removing file failed. " "[rv=0x%08x]", rv)); } CacheIndex::RemoveEntry(aHash); return NS_OK; } // static nsresult CacheFileIOManager::ReleaseNSPRHandle(CacheFileHandle *aHandle) { LOG(("CacheFileIOManager::ReleaseNSPRHandle() [handle=%p]", aHandle)); nsresult rv; RefPtr ioMan = gInstance; if (aHandle->IsClosed() || !ioMan) { return NS_ERROR_NOT_INITIALIZED; } RefPtr ev = new ReleaseNSPRHandleEvent(aHandle); rv = ioMan->mIOThread->Dispatch(ev, CacheIOThread::CLOSE); NS_ENSURE_SUCCESS(rv, rv); return NS_OK; } nsresult CacheFileIOManager::ReleaseNSPRHandleInternal(CacheFileHandle *aHandle) { LOG(("CacheFileIOManager::ReleaseNSPRHandleInternal() [handle=%p]", aHandle)); MOZ_ASSERT(CacheFileIOManager::IsOnIOThreadOrCeased()); MOZ_ASSERT(aHandle->mFD); DebugOnly found; found = mHandlesByLastUsed.RemoveElement(aHandle); MOZ_ASSERT(found); PR_Close(aHandle->mFD); aHandle->mFD = nullptr; return NS_OK; } // static nsresult CacheFileIOManager::TruncateSeekSetEOF(CacheFileHandle *aHandle, int64_t aTruncatePos, int64_t aEOFPos, CacheFileIOListener *aCallback) { LOG(("CacheFileIOManager::TruncateSeekSetEOF() [handle=%p, truncatePos=%lld, " "EOFPos=%lld, listener=%p]", aHandle, aTruncatePos, aEOFPos, aCallback)); nsresult rv; RefPtr ioMan = gInstance; if (aHandle->IsClosed() || !ioMan) { return NS_ERROR_NOT_INITIALIZED; } RefPtr ev = new TruncateSeekSetEOFEvent( aHandle, aTruncatePos, aEOFPos, aCallback); rv = ioMan->mIOThread->Dispatch(ev, CacheIOThread::WRITE); NS_ENSURE_SUCCESS(rv, rv); return NS_OK; } // static void CacheFileIOManager::GetCacheDirectory(nsIFile** result) { *result = nullptr; RefPtr ioMan = gInstance; if (!ioMan) { return; } ioMan->mCacheDirectory->Clone(result); } #if defined(MOZ_WIDGET_ANDROID) // static void CacheFileIOManager::GetProfilelessCacheDirectory(nsIFile** result) { *result = nullptr; RefPtr ioMan = gInstance; if (!ioMan || !ioMan->mCacheProfilelessDirectory) { return; } ioMan->mCacheProfilelessDirectory->Clone(result); } #endif // static nsresult CacheFileIOManager::GetEntryInfo(const SHA1Sum::Hash *aHash, CacheStorageService::EntryInfoCallback *aCallback) { MOZ_ASSERT(CacheFileIOManager::IsOnIOThread()); nsresult rv; RefPtr ioMan = gInstance; if (!ioMan) { return NS_ERROR_NOT_INITIALIZED; } nsAutoCString enhanceId; nsAutoCString uriSpec; RefPtr handle; ioMan->mHandles.GetHandle(aHash, getter_AddRefs(handle)); if (handle) { RefPtr info = CacheFileUtils::ParseKey(handle->Key(), &enhanceId, &uriSpec); MOZ_ASSERT(info); if (!info) { return NS_OK; // ignore } RefPtr service = CacheStorageService::Self(); if (!service) { return NS_ERROR_NOT_INITIALIZED; } // Invokes OnCacheEntryInfo when an existing entry is found if (service->GetCacheEntryInfo(info, enhanceId, uriSpec, aCallback)) { return NS_OK; } // When we are here, there is no existing entry and we need // to synchrnously load metadata from a disk file. } // Locate the actual file nsCOMPtr file; ioMan->GetFile(aHash, getter_AddRefs(file)); // Read metadata from the file synchronously RefPtr metadata = new CacheFileMetadata(); rv = metadata->SyncReadMetadata(file); if (NS_FAILED(rv)) { return NS_OK; } // Now get the context + enhance id + URL from the key. nsAutoCString key; metadata->GetKey(key); RefPtr info = CacheFileUtils::ParseKey(key, &enhanceId, &uriSpec); MOZ_ASSERT(info); if (!info) { return NS_OK; } // Pick all data to pass to the callback. int64_t dataSize = metadata->Offset(); uint32_t fetchCount; if (NS_FAILED(metadata->GetFetchCount(&fetchCount))) { fetchCount = 0; } uint32_t expirationTime; if (NS_FAILED(metadata->GetExpirationTime(&expirationTime))) { expirationTime = 0; } uint32_t lastModified; if (NS_FAILED(metadata->GetLastModified(&lastModified))) { lastModified = 0; } // Call directly on the callback. aCallback->OnEntryInfo(uriSpec, enhanceId, dataSize, fetchCount, lastModified, expirationTime, metadata->Pinned()); return NS_OK; } nsresult CacheFileIOManager::TruncateSeekSetEOFInternal(CacheFileHandle *aHandle, int64_t aTruncatePos, int64_t aEOFPos) { LOG(("CacheFileIOManager::TruncateSeekSetEOFInternal() [handle=%p, " "truncatePos=%lld, EOFPos=%lld]", aHandle, aTruncatePos, aEOFPos)); nsresult rv; if (!aHandle->mFileExists) { rv = CreateFile(aHandle); NS_ENSURE_SUCCESS(rv, rv); } if (!aHandle->mFD) { rv = OpenNSPRHandle(aHandle); NS_ENSURE_SUCCESS(rv, rv); } else { NSPRHandleUsed(aHandle); } // Check again, OpenNSPRHandle could figure out the file was gone. if (!aHandle->mFileExists) { return NS_ERROR_NOT_AVAILABLE; } // Check whether this operation would cause critical low disk space. if (aHandle->mFileSize < aEOFPos) { int64_t freeSpace = -1; rv = mCacheDirectory->GetDiskSpaceAvailable(&freeSpace); if (NS_WARN_IF(NS_FAILED(rv))) { LOG(("CacheFileIOManager::TruncateSeekSetEOFInternal() - " "GetDiskSpaceAvailable() failed! [rv=0x%08x]", rv)); } else { uint32_t limit = CacheObserver::DiskFreeSpaceHardLimit(); if (freeSpace - aEOFPos + aHandle->mFileSize < limit) { LOG(("CacheFileIOManager::TruncateSeekSetEOFInternal() - Low free space" ", refusing to write! [freeSpace=%lld, limit=%u]", freeSpace, limit)); return NS_ERROR_FILE_DISK_FULL; } } } // This operation always invalidates the entry aHandle->mInvalid = true; rv = TruncFile(aHandle->mFD, aTruncatePos); NS_ENSURE_SUCCESS(rv, rv); if (aTruncatePos != aEOFPos) { rv = TruncFile(aHandle->mFD, aEOFPos); NS_ENSURE_SUCCESS(rv, rv); } uint32_t oldSizeInK = aHandle->FileSizeInK(); aHandle->mFileSize = aEOFPos; uint32_t newSizeInK = aHandle->FileSizeInK(); if (oldSizeInK != newSizeInK && !aHandle->IsDoomed() && !aHandle->IsSpecialFile()) { CacheIndex::UpdateEntry(aHandle->Hash(), nullptr, nullptr, &newSizeInK); if (oldSizeInK < newSizeInK) { EvictIfOverLimitInternal(); } } return NS_OK; } // static nsresult CacheFileIOManager::RenameFile(CacheFileHandle *aHandle, const nsACString &aNewName, CacheFileIOListener *aCallback) { LOG(("CacheFileIOManager::RenameFile() [handle=%p, newName=%s, listener=%p]", aHandle, PromiseFlatCString(aNewName).get(), aCallback)); nsresult rv; RefPtr ioMan = gInstance; if (aHandle->IsClosed() || !ioMan) { return NS_ERROR_NOT_INITIALIZED; } if (!aHandle->IsSpecialFile()) { return NS_ERROR_UNEXPECTED; } RefPtr ev = new RenameFileEvent(aHandle, aNewName, aCallback); rv = ioMan->mIOThread->Dispatch(ev, CacheIOThread::WRITE); NS_ENSURE_SUCCESS(rv, rv); return NS_OK; } nsresult CacheFileIOManager::RenameFileInternal(CacheFileHandle *aHandle, const nsACString &aNewName) { LOG(("CacheFileIOManager::RenameFileInternal() [handle=%p, newName=%s]", aHandle, PromiseFlatCString(aNewName).get())); nsresult rv; MOZ_ASSERT(aHandle->IsSpecialFile()); if (aHandle->IsDoomed()) { return NS_ERROR_NOT_AVAILABLE; } // Doom old handle if it exists and is not doomed for (uint32_t i = 0 ; i < mSpecialHandles.Length() ; i++) { if (!mSpecialHandles[i]->IsDoomed() && mSpecialHandles[i]->Key() == aNewName) { MOZ_ASSERT(aHandle != mSpecialHandles[i]); rv = DoomFileInternal(mSpecialHandles[i]); NS_ENSURE_SUCCESS(rv, rv); break; } } nsCOMPtr file; rv = GetSpecialFile(aNewName, getter_AddRefs(file)); NS_ENSURE_SUCCESS(rv, rv); bool exists; rv = file->Exists(&exists); NS_ENSURE_SUCCESS(rv, rv); if (exists) { LOG(("CacheFileIOManager::RenameFileInternal() - Removing old file from " "disk")); rv = file->Remove(false); if (NS_FAILED(rv)) { NS_WARNING("Cannot remove file from the disk"); LOG(("CacheFileIOManager::RenameFileInternal() - Removing old file failed" ". [rv=0x%08x]", rv)); } } if (!aHandle->FileExists()) { aHandle->mKey = aNewName; return NS_OK; } if (aHandle->mFD) { ReleaseNSPRHandleInternal(aHandle); } rv = aHandle->mFile->MoveToNative(nullptr, aNewName); NS_ENSURE_SUCCESS(rv, rv); aHandle->mKey = aNewName; return NS_OK; } // static nsresult CacheFileIOManager::EvictIfOverLimit() { LOG(("CacheFileIOManager::EvictIfOverLimit()")); nsresult rv; RefPtr ioMan = gInstance; if (!ioMan) { return NS_ERROR_NOT_INITIALIZED; } nsCOMPtr ev; ev = NS_NewRunnableMethod(ioMan, &CacheFileIOManager::EvictIfOverLimitInternal); rv = ioMan->mIOThread->Dispatch(ev, CacheIOThread::EVICT); NS_ENSURE_SUCCESS(rv, rv); return NS_OK; } nsresult CacheFileIOManager::EvictIfOverLimitInternal() { LOG(("CacheFileIOManager::EvictIfOverLimitInternal()")); nsresult rv; MOZ_ASSERT(mIOThread->IsCurrentThread()); if (mShuttingDown) { return NS_ERROR_NOT_INITIALIZED; } if (mOverLimitEvicting) { LOG(("CacheFileIOManager::EvictIfOverLimitInternal() - Eviction already " "running.")); return NS_OK; } int64_t freeSpace; rv = mCacheDirectory->GetDiskSpaceAvailable(&freeSpace); if (NS_WARN_IF(NS_FAILED(rv))) { freeSpace = -1; // Do not change smart size. LOG(("CacheFileIOManager::EvictIfOverLimitInternal() - " "GetDiskSpaceAvailable() failed! [rv=0x%08x]", rv)); } else { UpdateSmartCacheSize(freeSpace); } uint32_t cacheUsage; rv = CacheIndex::GetCacheSize(&cacheUsage); NS_ENSURE_SUCCESS(rv, rv); uint32_t cacheLimit = CacheObserver::DiskCacheCapacity() >> 10; uint32_t freeSpaceLimit = CacheObserver::DiskFreeSpaceSoftLimit(); if (cacheUsage <= cacheLimit && (freeSpace == -1 || freeSpace >= freeSpaceLimit)) { LOG(("CacheFileIOManager::EvictIfOverLimitInternal() - Cache size and free " "space in limits. [cacheSize=%ukB, cacheSizeLimit=%ukB, " "freeSpace=%lld, freeSpaceLimit=%u]", cacheUsage, cacheLimit, freeSpace, freeSpaceLimit)); return NS_OK; } LOG(("CacheFileIOManager::EvictIfOverLimitInternal() - Cache size exceeded " "limit. Starting overlimit eviction. [cacheSize=%u, limit=%u]", cacheUsage, cacheLimit)); nsCOMPtr ev; ev = NS_NewRunnableMethod(this, &CacheFileIOManager::OverLimitEvictionInternal); rv = mIOThread->Dispatch(ev, CacheIOThread::EVICT); NS_ENSURE_SUCCESS(rv, rv); mOverLimitEvicting = true; return NS_OK; } nsresult CacheFileIOManager::OverLimitEvictionInternal() { LOG(("CacheFileIOManager::OverLimitEvictionInternal()")); nsresult rv; MOZ_ASSERT(mIOThread->IsCurrentThread()); // mOverLimitEvicting is accessed only on IO thread, so we can set it to false // here and set it to true again once we dispatch another event that will // continue with the eviction. The reason why we do so is that we can fail // early anywhere in this method and the variable will contain a correct // value. Otherwise we would need to set it to false on every failing place. mOverLimitEvicting = false; if (mShuttingDown) { return NS_ERROR_NOT_INITIALIZED; } while (true) { int64_t freeSpace = -1; rv = mCacheDirectory->GetDiskSpaceAvailable(&freeSpace); if (NS_WARN_IF(NS_FAILED(rv))) { // Do not change smart size. LOG(("CacheFileIOManager::EvictIfOverLimitInternal() - " "GetDiskSpaceAvailable() failed! [rv=0x%08x]", rv)); } else { UpdateSmartCacheSize(freeSpace); } uint32_t cacheUsage; rv = CacheIndex::GetCacheSize(&cacheUsage); NS_ENSURE_SUCCESS(rv, rv); uint32_t cacheLimit = CacheObserver::DiskCacheCapacity() >> 10; uint32_t freeSpaceLimit = CacheObserver::DiskFreeSpaceSoftLimit(); if (cacheUsage > cacheLimit) { LOG(("CacheFileIOManager::OverLimitEvictionInternal() - Cache size over " "limit. [cacheSize=%u, limit=%u]", cacheUsage, cacheLimit)); } else if (freeSpace != 1 && freeSpace < freeSpaceLimit) { LOG(("CacheFileIOManager::OverLimitEvictionInternal() - Free space under " "limit. [freeSpace=%lld, freeSpaceLimit=%u]", freeSpace, freeSpaceLimit)); } else { LOG(("CacheFileIOManager::OverLimitEvictionInternal() - Cache size and " "free space in limits. [cacheSize=%ukB, cacheSizeLimit=%ukB, " "freeSpace=%lld, freeSpaceLimit=%u]", cacheUsage, cacheLimit, freeSpace, freeSpaceLimit)); return NS_OK; } if (CacheIOThread::YieldAndRerun()) { LOG(("CacheFileIOManager::OverLimitEvictionInternal() - Breaking loop " "for higher level events.")); mOverLimitEvicting = true; return NS_OK; } SHA1Sum::Hash hash; uint32_t cnt; static uint32_t consecutiveFailures = 0; rv = CacheIndex::GetEntryForEviction(false, &hash, &cnt); NS_ENSURE_SUCCESS(rv, rv); rv = DoomFileByKeyInternal(&hash); if (NS_SUCCEEDED(rv)) { consecutiveFailures = 0; } else if (rv == NS_ERROR_NOT_AVAILABLE) { LOG(("CacheFileIOManager::OverLimitEvictionInternal() - " "DoomFileByKeyInternal() failed. [rv=0x%08x]", rv)); // TODO index is outdated, start update // Make sure index won't return the same entry again CacheIndex::RemoveEntry(&hash); consecutiveFailures = 0; } else { // This shouldn't normally happen, but the eviction must not fail // completely if we ever encounter this problem. NS_WARNING("CacheFileIOManager::OverLimitEvictionInternal() - Unexpected " "failure of DoomFileByKeyInternal()"); LOG(("CacheFileIOManager::OverLimitEvictionInternal() - " "DoomFileByKeyInternal() failed. [rv=0x%08x]", rv)); // Normally, CacheIndex::UpdateEntry() is called only to update newly // created/opened entries which are always fresh and UpdateEntry() expects // and checks this flag. The way we use UpdateEntry() here is a kind of // hack and we must make sure the flag is set by calling // EnsureEntryExists(). rv = CacheIndex::EnsureEntryExists(&hash); NS_ENSURE_SUCCESS(rv, rv); // Move the entry at the end of both lists to make sure we won't end up // failing on one entry forever. uint32_t frecency = 0; uint32_t expTime = nsICacheEntry::NO_EXPIRATION_TIME; rv = CacheIndex::UpdateEntry(&hash, &frecency, &expTime, nullptr); NS_ENSURE_SUCCESS(rv, rv); consecutiveFailures++; if (consecutiveFailures >= cnt) { // This doesn't necessarily mean that we've tried to doom every entry // but we've reached a sane number of tries. It is likely that another // eviction will start soon. And as said earlier, this normally doesn't // happen at all. return NS_OK; } } } NS_NOTREACHED("We should never get here"); return NS_OK; } // static nsresult CacheFileIOManager::EvictAll() { LOG(("CacheFileIOManager::EvictAll()")); nsresult rv; RefPtr ioMan = gInstance; if (!ioMan) { return NS_ERROR_NOT_INITIALIZED; } nsCOMPtr ev; ev = NS_NewRunnableMethod(ioMan, &CacheFileIOManager::EvictAllInternal); rv = ioMan->mIOThread->DispatchAfterPendingOpens(ev); if (NS_WARN_IF(NS_FAILED(rv))) { return rv; } return NS_OK; } namespace { class EvictionNotifierRunnable : public nsRunnable { public: NS_DECL_NSIRUNNABLE }; NS_IMETHODIMP EvictionNotifierRunnable::Run() { nsCOMPtr obsSvc = mozilla::services::GetObserverService(); if (obsSvc) { obsSvc->NotifyObservers(nullptr, "cacheservice:empty-cache", nullptr); } return NS_OK; } } // namespace nsresult CacheFileIOManager::EvictAllInternal() { LOG(("CacheFileIOManager::EvictAllInternal()")); nsresult rv; MOZ_ASSERT(mIOThread->IsCurrentThread()); RefPtr r = new EvictionNotifierRunnable(); if (!mCacheDirectory) { // This is a kind of hack. Somebody called EvictAll() without a profile. // This happens in xpcshell tests that use cache without profile. We need // to notify observers in this case since the tests are waiting for it. NS_DispatchToMainThread(r); return NS_ERROR_FILE_INVALID_PATH; } if (mShuttingDown) { return NS_ERROR_NOT_INITIALIZED; } if (!mTreeCreated) { rv = CreateCacheTree(); if (NS_FAILED(rv)) { return rv; } } // Doom all active handles nsTArray > handles; mHandles.GetActiveHandles(&handles); for (uint32_t i = 0; i < handles.Length(); ++i) { rv = DoomFileInternal(handles[i]); if (NS_WARN_IF(NS_FAILED(rv))) { LOG(("CacheFileIOManager::EvictAllInternal() - Cannot doom handle " "[handle=%p]", handles[i].get())); } } nsCOMPtr file; rv = mCacheDirectory->Clone(getter_AddRefs(file)); if (NS_WARN_IF(NS_FAILED(rv))) { return rv; } rv = file->AppendNative(NS_LITERAL_CSTRING(ENTRIES_DIR)); if (NS_WARN_IF(NS_FAILED(rv))) { return rv; } // Trash current entries directory rv = TrashDirectory(file); if (NS_WARN_IF(NS_FAILED(rv))) { return rv; } // Files are now inaccessible in entries directory, notify observers. NS_DispatchToMainThread(r); // Create a new empty entries directory rv = CheckAndCreateDir(mCacheDirectory, ENTRIES_DIR, false); if (NS_WARN_IF(NS_FAILED(rv))) { return rv; } CacheIndex::RemoveAll(); return NS_OK; } // static nsresult CacheFileIOManager::EvictByContext(nsILoadContextInfo *aLoadContextInfo, bool aPinned) { LOG(("CacheFileIOManager::EvictByContext() [loadContextInfo=%p]", aLoadContextInfo)); nsresult rv; RefPtr ioMan = gInstance; if (!ioMan) { return NS_ERROR_NOT_INITIALIZED; } nsCOMPtr ev; ev = NS_NewRunnableMethodWithArgs, bool> (ioMan, &CacheFileIOManager::EvictByContextInternal, aLoadContextInfo, aPinned); rv = ioMan->mIOThread->DispatchAfterPendingOpens(ev); if (NS_WARN_IF(NS_FAILED(rv))) { return rv; } return NS_OK; } nsresult CacheFileIOManager::EvictByContextInternal(nsILoadContextInfo *aLoadContextInfo, bool aPinned) { LOG(("CacheFileIOManager::EvictByContextInternal() [loadContextInfo=%p, pinned=%d]", aLoadContextInfo, aPinned)); nsresult rv; if (aLoadContextInfo) { nsAutoCString suffix; aLoadContextInfo->OriginAttributesPtr()->CreateSuffix(suffix); LOG((" anonymous=%u, suffix=%s]", aLoadContextInfo->IsAnonymous(), suffix.get())); MOZ_ASSERT(mIOThread->IsCurrentThread()); MOZ_ASSERT(!aLoadContextInfo->IsPrivate()); if (aLoadContextInfo->IsPrivate()) { return NS_ERROR_INVALID_ARG; } } if (!mCacheDirectory) { // This is a kind of hack. Somebody called EvictAll() without a profile. // This happens in xpcshell tests that use cache without profile. We need // to notify observers in this case since the tests are waiting for it. // Also notify for aPinned == true, those are interested as well. if (!aLoadContextInfo) { RefPtr r = new EvictionNotifierRunnable(); NS_DispatchToMainThread(r); } return NS_ERROR_FILE_INVALID_PATH; } if (mShuttingDown) { return NS_ERROR_NOT_INITIALIZED; } if (!mTreeCreated) { rv = CreateCacheTree(); if (NS_FAILED(rv)) { return rv; } } // Doom all active handles that matches the load context nsTArray > handles; mHandles.GetActiveHandles(&handles); for (uint32_t i = 0; i < handles.Length(); ++i) { CacheFileHandle* handle = handles[i]; if (aLoadContextInfo) { bool equals; rv = CacheFileUtils::KeyMatchesLoadContextInfo(handle->Key(), aLoadContextInfo, &equals); if (NS_FAILED(rv)) { LOG(("CacheFileIOManager::EvictByContextInternal() - Cannot parse key in " "handle! [handle=%p, key=%s]", handle, handle->Key().get())); MOZ_CRASH("Unexpected error!"); } if (!equals) { continue; } } // handle will be doomed only when pinning status is known and equal or // doom decision will be deferred until pinning status is determined. rv = DoomFileInternal(handle, aPinned ? CacheFileIOManager::DOOM_WHEN_PINNED : CacheFileIOManager::DOOM_WHEN_NON_PINNED); if (NS_WARN_IF(NS_FAILED(rv))) { LOG(("CacheFileIOManager::EvictByContextInternal() - Cannot doom handle" " [handle=%p]", handle)); } } if (!aLoadContextInfo) { RefPtr r = new EvictionNotifierRunnable(); NS_DispatchToMainThread(r); } if (!mContextEvictor) { mContextEvictor = new CacheFileContextEvictor(); mContextEvictor->Init(mCacheDirectory); } mContextEvictor->AddContext(aLoadContextInfo, aPinned); return NS_OK; } // static nsresult CacheFileIOManager::CacheIndexStateChanged() { LOG(("CacheFileIOManager::CacheIndexStateChanged()")); nsresult rv; // CacheFileIOManager lives longer than CacheIndex so gInstance must be // non-null here. MOZ_ASSERT(gInstance); // We have to re-distatch even if we are on IO thread to prevent reentering // the lock in CacheIndex nsCOMPtr ev; ev = NS_NewRunnableMethod( gInstance, &CacheFileIOManager::CacheIndexStateChangedInternal); nsCOMPtr ioTarget = IOTarget(); MOZ_ASSERT(ioTarget); rv = ioTarget->Dispatch(ev, nsIEventTarget::DISPATCH_NORMAL); if (NS_WARN_IF(NS_FAILED(rv))) { return rv; } return NS_OK; } nsresult CacheFileIOManager::CacheIndexStateChangedInternal() { if (mShuttingDown) { // ignore notification during shutdown return NS_OK; } if (!mContextEvictor) { return NS_OK; } mContextEvictor->CacheIndexStateChanged(); return NS_OK; } nsresult CacheFileIOManager::TrashDirectory(nsIFile *aFile) { nsAutoCString path; aFile->GetNativePath(path); LOG(("CacheFileIOManager::TrashDirectory() [file=%s]", path.get())); nsresult rv; MOZ_ASSERT(mIOThread->IsCurrentThread()); MOZ_ASSERT(mCacheDirectory); // When the directory is empty, it is cheaper to remove it directly instead of // using the trash mechanism. bool isEmpty; rv = IsEmptyDirectory(aFile, &isEmpty); NS_ENSURE_SUCCESS(rv, rv); if (isEmpty) { rv = aFile->Remove(false); LOG(("CacheFileIOManager::TrashDirectory() - Directory removed [rv=0x%08x]", rv)); return rv; } #ifdef DEBUG nsCOMPtr dirCheck; rv = aFile->GetParent(getter_AddRefs(dirCheck)); NS_ENSURE_SUCCESS(rv, rv); bool equals = false; rv = dirCheck->Equals(mCacheDirectory, &equals); NS_ENSURE_SUCCESS(rv, rv); MOZ_ASSERT(equals); #endif nsCOMPtr dir, trash; nsAutoCString leaf; rv = aFile->Clone(getter_AddRefs(dir)); NS_ENSURE_SUCCESS(rv, rv); rv = aFile->Clone(getter_AddRefs(trash)); NS_ENSURE_SUCCESS(rv, rv); srand(static_cast(PR_Now())); while (true) { leaf = TRASH_DIR; leaf.AppendInt(rand()); rv = trash->SetNativeLeafName(leaf); NS_ENSURE_SUCCESS(rv, rv); bool exists; if (NS_SUCCEEDED(trash->Exists(&exists)) && !exists) { break; } } LOG(("CacheFileIOManager::TrashDirectory() - Renaming directory [leaf=%s]", leaf.get())); rv = dir->MoveToNative(nullptr, leaf); NS_ENSURE_SUCCESS(rv, rv); StartRemovingTrash(); return NS_OK; } // static void CacheFileIOManager::OnTrashTimer(nsITimer *aTimer, void *aClosure) { LOG(("CacheFileIOManager::OnTrashTimer() [timer=%p, closure=%p]", aTimer, aClosure)); RefPtr ioMan = gInstance; if (!ioMan) { return; } ioMan->mTrashTimer = nullptr; ioMan->StartRemovingTrash(); } nsresult CacheFileIOManager::StartRemovingTrash() { LOG(("CacheFileIOManager::StartRemovingTrash()")); nsresult rv; MOZ_ASSERT(mIOThread->IsCurrentThread()); if (mShuttingDown) { return NS_ERROR_NOT_INITIALIZED; } if (!mCacheDirectory) { return NS_ERROR_FILE_INVALID_PATH; } if (mTrashTimer) { LOG(("CacheFileIOManager::StartRemovingTrash() - Trash timer exists.")); return NS_OK; } if (mRemovingTrashDirs) { LOG(("CacheFileIOManager::StartRemovingTrash() - Trash removing in " "progress.")); return NS_OK; } uint32_t elapsed = (TimeStamp::NowLoRes() - mStartTime).ToMilliseconds(); if (elapsed < kRemoveTrashStartDelay) { nsCOMPtr timer = do_CreateInstance("@mozilla.org/timer;1", &rv); NS_ENSURE_SUCCESS(rv, rv); nsCOMPtr ioTarget = IOTarget(); MOZ_ASSERT(ioTarget); rv = timer->SetTarget(ioTarget); NS_ENSURE_SUCCESS(rv, rv); rv = timer->InitWithFuncCallback(CacheFileIOManager::OnTrashTimer, nullptr, kRemoveTrashStartDelay - elapsed, nsITimer::TYPE_ONE_SHOT); NS_ENSURE_SUCCESS(rv, rv); mTrashTimer.swap(timer); return NS_OK; } nsCOMPtr ev; ev = NS_NewRunnableMethod(this, &CacheFileIOManager::RemoveTrashInternal); rv = mIOThread->Dispatch(ev, CacheIOThread::EVICT); NS_ENSURE_SUCCESS(rv, rv); mRemovingTrashDirs = true; return NS_OK; } nsresult CacheFileIOManager::RemoveTrashInternal() { LOG(("CacheFileIOManager::RemoveTrashInternal()")); nsresult rv; MOZ_ASSERT(mIOThread->IsCurrentThread()); if (mShuttingDown) { return NS_ERROR_NOT_INITIALIZED; } MOZ_ASSERT(!mTrashTimer); MOZ_ASSERT(mRemovingTrashDirs); if (!mTreeCreated) { rv = CreateCacheTree(); if (NS_FAILED(rv)) { return rv; } } // mRemovingTrashDirs is accessed only on IO thread, so we can drop the flag // here and set it again once we dispatch a continuation event. By doing so, // we don't have to drop the flag on any possible early return. mRemovingTrashDirs = false; while (true) { if (CacheIOThread::YieldAndRerun()) { LOG(("CacheFileIOManager::RemoveTrashInternal() - Breaking loop for " "higher level events.")); mRemovingTrashDirs = true; return NS_OK; } // Find some trash directory if (!mTrashDir) { MOZ_ASSERT(!mTrashDirEnumerator); rv = FindTrashDirToRemove(); if (rv == NS_ERROR_NOT_AVAILABLE) { LOG(("CacheFileIOManager::RemoveTrashInternal() - No trash directory " "found.")); return NS_OK; } NS_ENSURE_SUCCESS(rv, rv); nsCOMPtr enumerator; rv = mTrashDir->GetDirectoryEntries(getter_AddRefs(enumerator)); if (NS_SUCCEEDED(rv)) { mTrashDirEnumerator = do_QueryInterface(enumerator, &rv); NS_ENSURE_SUCCESS(rv, rv); } continue; // check elapsed time } // We null out mTrashDirEnumerator once we remove all files in the // directory, so remove the trash directory if we don't have enumerator. if (!mTrashDirEnumerator) { rv = mTrashDir->Remove(false); if (NS_FAILED(rv)) { // There is no reason why removing an empty directory should fail, but // if it does, we should continue and try to remove all other trash // directories. nsAutoCString leafName; mTrashDir->GetNativeLeafName(leafName); mFailedTrashDirs.AppendElement(leafName); LOG(("CacheFileIOManager::RemoveTrashInternal() - Cannot remove " "trashdir. [name=%s]", leafName.get())); } mTrashDir = nullptr; continue; // check elapsed time } nsCOMPtr file; rv = mTrashDirEnumerator->GetNextFile(getter_AddRefs(file)); if (!file) { mTrashDirEnumerator->Close(); mTrashDirEnumerator = nullptr; continue; // check elapsed time } else { bool isDir = false; file->IsDirectory(&isDir); if (isDir) { NS_WARNING("Found a directory in a trash directory! It will be removed " "recursively, but this can block IO thread for a while!"); if (LOG_ENABLED()) { nsAutoCString path; file->GetNativePath(path); LOG(("CacheFileIOManager::RemoveTrashInternal() - Found a directory in a trash " "directory! It will be removed recursively, but this can block IO " "thread for a while! [file=%s]", path.get())); } } file->Remove(isDir); } } NS_NOTREACHED("We should never get here"); return NS_OK; } nsresult CacheFileIOManager::FindTrashDirToRemove() { LOG(("CacheFileIOManager::FindTrashDirToRemove()")); nsresult rv; // We call this method on the main thread during shutdown when user wants to // remove all cache files. MOZ_ASSERT(mIOThread->IsCurrentThread() || mShuttingDown); nsCOMPtr iter; rv = mCacheDirectory->GetDirectoryEntries(getter_AddRefs(iter)); NS_ENSURE_SUCCESS(rv, rv); bool more; nsCOMPtr elem; while (NS_SUCCEEDED(iter->HasMoreElements(&more)) && more) { rv = iter->GetNext(getter_AddRefs(elem)); if (NS_FAILED(rv)) { continue; } nsCOMPtr file = do_QueryInterface(elem); if (!file) { continue; } bool isDir = false; file->IsDirectory(&isDir); if (!isDir) { continue; } nsAutoCString leafName; rv = file->GetNativeLeafName(leafName); if (NS_FAILED(rv)) { continue; } if (leafName.Length() < strlen(TRASH_DIR)) { continue; } if (!StringBeginsWith(leafName, NS_LITERAL_CSTRING(TRASH_DIR))) { continue; } if (mFailedTrashDirs.Contains(leafName)) { continue; } LOG(("CacheFileIOManager::FindTrashDirToRemove() - Returning directory %s", leafName.get())); mTrashDir = file; return NS_OK; } // When we're here we've tried to delete all trash directories. Clear // mFailedTrashDirs so we will try to delete them again when we start removing // trash directories next time. mFailedTrashDirs.Clear(); return NS_ERROR_NOT_AVAILABLE; } // static nsresult CacheFileIOManager::InitIndexEntry(CacheFileHandle *aHandle, uint32_t aAppId, bool aAnonymous, bool aInBrowser, bool aPinning) { LOG(("CacheFileIOManager::InitIndexEntry() [handle=%p, appId=%u, anonymous=%d" ", inBrowser=%d, pinned=%d]", aHandle, aAppId, aAnonymous, aInBrowser, aPinning)); nsresult rv; RefPtr ioMan = gInstance; if (aHandle->IsClosed() || !ioMan) { return NS_ERROR_NOT_INITIALIZED; } if (aHandle->IsSpecialFile()) { return NS_ERROR_UNEXPECTED; } RefPtr ev = new InitIndexEntryEvent(aHandle, aAppId, aAnonymous, aInBrowser, aPinning); rv = ioMan->mIOThread->Dispatch(ev, CacheIOThread::WRITE); NS_ENSURE_SUCCESS(rv, rv); return NS_OK; } // static nsresult CacheFileIOManager::UpdateIndexEntry(CacheFileHandle *aHandle, const uint32_t *aFrecency, const uint32_t *aExpirationTime) { LOG(("CacheFileIOManager::UpdateIndexEntry() [handle=%p, frecency=%s, " "expirationTime=%s]", aHandle, aFrecency ? nsPrintfCString("%u", *aFrecency).get() : "", aExpirationTime ? nsPrintfCString("%u", *aExpirationTime).get() : "")); nsresult rv; RefPtr ioMan = gInstance; if (aHandle->IsClosed() || !ioMan) { return NS_ERROR_NOT_INITIALIZED; } if (aHandle->IsSpecialFile()) { return NS_ERROR_UNEXPECTED; } RefPtr ev = new UpdateIndexEntryEvent(aHandle, aFrecency, aExpirationTime); rv = ioMan->mIOThread->Dispatch(ev, CacheIOThread::WRITE); NS_ENSURE_SUCCESS(rv, rv); return NS_OK; } nsresult CacheFileIOManager::CreateFile(CacheFileHandle *aHandle) { MOZ_ASSERT(!aHandle->mFD); MOZ_ASSERT(aHandle->mFile); nsresult rv; if (aHandle->IsDoomed()) { nsCOMPtr file; rv = GetDoomedFile(getter_AddRefs(file)); NS_ENSURE_SUCCESS(rv, rv); aHandle->mFile.swap(file); } else { bool exists; if (NS_SUCCEEDED(aHandle->mFile->Exists(&exists)) && exists) { NS_WARNING("Found a file that should not exist!"); } } rv = OpenNSPRHandle(aHandle, true); NS_ENSURE_SUCCESS(rv, rv); aHandle->mFileSize = 0; return NS_OK; } // static void CacheFileIOManager::HashToStr(const SHA1Sum::Hash *aHash, nsACString &_retval) { _retval.Truncate(); const char hexChars[] = {'0', '1', '2', '3', '4', '5', '6', '7', '8', '9', 'A', 'B', 'C', 'D', 'E', 'F'}; for (uint32_t i=0 ; i> 4]); _retval.Append(hexChars[(*aHash)[i] & 0xF]); } } // static nsresult CacheFileIOManager::StrToHash(const nsACString &aHash, SHA1Sum::Hash *_retval) { if (aHash.Length() != 2*sizeof(SHA1Sum::Hash)) { return NS_ERROR_INVALID_ARG; } for (uint32_t i=0 ; i= '0' && aHash[i] <= '9') { value = aHash[i] - '0'; } else if (aHash[i] >= 'A' && aHash[i] <= 'F') { value = aHash[i] - 'A' + 10; } else if (aHash[i] >= 'a' && aHash[i] <= 'f') { value = aHash[i] - 'a' + 10; } else { return NS_ERROR_INVALID_ARG; } if (i%2 == 0) { (reinterpret_cast(_retval))[i/2] = value << 4; } else { (reinterpret_cast(_retval))[i/2] += value; } } return NS_OK; } nsresult CacheFileIOManager::GetFile(const SHA1Sum::Hash *aHash, nsIFile **_retval) { nsresult rv; nsCOMPtr file; rv = mCacheDirectory->Clone(getter_AddRefs(file)); NS_ENSURE_SUCCESS(rv, rv); rv = file->AppendNative(NS_LITERAL_CSTRING(ENTRIES_DIR)); NS_ENSURE_SUCCESS(rv, rv); nsAutoCString leafName; HashToStr(aHash, leafName); rv = file->AppendNative(leafName); NS_ENSURE_SUCCESS(rv, rv); file.swap(*_retval); return NS_OK; } nsresult CacheFileIOManager::GetSpecialFile(const nsACString &aKey, nsIFile **_retval) { nsresult rv; nsCOMPtr file; rv = mCacheDirectory->Clone(getter_AddRefs(file)); NS_ENSURE_SUCCESS(rv, rv); rv = file->AppendNative(aKey); NS_ENSURE_SUCCESS(rv, rv); file.swap(*_retval); return NS_OK; } nsresult CacheFileIOManager::GetDoomedFile(nsIFile **_retval) { nsresult rv; nsCOMPtr file; rv = mCacheDirectory->Clone(getter_AddRefs(file)); NS_ENSURE_SUCCESS(rv, rv); rv = file->AppendNative(NS_LITERAL_CSTRING(DOOMED_DIR)); NS_ENSURE_SUCCESS(rv, rv); rv = file->AppendNative(NS_LITERAL_CSTRING("dummyleaf")); NS_ENSURE_SUCCESS(rv, rv); srand(static_cast(PR_Now())); nsAutoCString leafName; uint32_t iter=0; while (true) { iter++; leafName.AppendInt(rand()); rv = file->SetNativeLeafName(leafName); NS_ENSURE_SUCCESS(rv, rv); bool exists; if (NS_SUCCEEDED(file->Exists(&exists)) && !exists) { break; } leafName.Truncate(); } // Telemetry::Accumulate(Telemetry::DISK_CACHE_GETDOOMEDFILE_ITERATIONS, iter); file.swap(*_retval); return NS_OK; } nsresult CacheFileIOManager::IsEmptyDirectory(nsIFile *aFile, bool *_retval) { MOZ_ASSERT(mIOThread->IsCurrentThread()); nsresult rv; nsCOMPtr enumerator; rv = aFile->GetDirectoryEntries(getter_AddRefs(enumerator)); NS_ENSURE_SUCCESS(rv, rv); bool hasMoreElements = false; rv = enumerator->HasMoreElements(&hasMoreElements); NS_ENSURE_SUCCESS(rv, rv); *_retval = !hasMoreElements; return NS_OK; } nsresult CacheFileIOManager::CheckAndCreateDir(nsIFile *aFile, const char *aDir, bool aEnsureEmptyDir) { nsresult rv; nsCOMPtr file; if (!aDir) { file = aFile; } else { nsAutoCString dir(aDir); rv = aFile->Clone(getter_AddRefs(file)); NS_ENSURE_SUCCESS(rv, rv); rv = file->AppendNative(dir); NS_ENSURE_SUCCESS(rv, rv); } bool exists = false; rv = file->Exists(&exists); if (NS_SUCCEEDED(rv) && exists) { bool isDirectory = false; rv = file->IsDirectory(&isDirectory); if (NS_FAILED(rv) || !isDirectory) { // Try to remove the file rv = file->Remove(false); if (NS_SUCCEEDED(rv)) { exists = false; } } NS_ENSURE_SUCCESS(rv, rv); } if (aEnsureEmptyDir && NS_SUCCEEDED(rv) && exists) { bool isEmpty; rv = IsEmptyDirectory(file, &isEmpty); NS_ENSURE_SUCCESS(rv, rv); if (!isEmpty) { rv = TrashDirectory(file); NS_ENSURE_SUCCESS(rv, rv); exists = false; } } if (NS_SUCCEEDED(rv) && !exists) { rv = file->Create(nsIFile::DIRECTORY_TYPE, 0700); } if (NS_FAILED(rv)) { NS_WARNING("Cannot create directory"); return NS_ERROR_FAILURE; } return NS_OK; } nsresult CacheFileIOManager::CreateCacheTree() { MOZ_ASSERT(mIOThread->IsCurrentThread()); MOZ_ASSERT(!mTreeCreated); if (!mCacheDirectory) { return NS_ERROR_FILE_INVALID_PATH; } nsresult rv; // ensure parent directory exists nsCOMPtr parentDir; rv = mCacheDirectory->GetParent(getter_AddRefs(parentDir)); NS_ENSURE_SUCCESS(rv, rv); rv = CheckAndCreateDir(parentDir, nullptr, false); NS_ENSURE_SUCCESS(rv, rv); // ensure cache directory exists rv = CheckAndCreateDir(mCacheDirectory, nullptr, false); NS_ENSURE_SUCCESS(rv, rv); // ensure entries directory exists rv = CheckAndCreateDir(mCacheDirectory, ENTRIES_DIR, false); NS_ENSURE_SUCCESS(rv, rv); // ensure doomed directory exists rv = CheckAndCreateDir(mCacheDirectory, DOOMED_DIR, true); NS_ENSURE_SUCCESS(rv, rv); mTreeCreated = true; if (!mContextEvictor) { RefPtr contextEvictor; contextEvictor = new CacheFileContextEvictor(); // Init() method will try to load unfinished contexts from the disk. Store // the evictor as a member only when there is some unfinished job. contextEvictor->Init(mCacheDirectory); if (contextEvictor->ContextsCount()) { contextEvictor.swap(mContextEvictor); } } StartRemovingTrash(); if (!CacheObserver::CacheFSReported()) { uint32_t fsType = 4; // Other OS #ifdef XP_WIN nsAutoString target; nsresult rv = mCacheDirectory->GetTarget(target); if (NS_FAILED(rv)) { return NS_OK; } wchar_t volume_path[MAX_PATH + 1] = { 0 }; if (!::GetVolumePathNameW(target.get(), volume_path, mozilla::ArrayLength(volume_path))) { return NS_OK; } wchar_t fsName[6] = { 0 }; if (!::GetVolumeInformationW(volume_path, nullptr, 0, nullptr, nullptr, nullptr, fsName, mozilla::ArrayLength(fsName))) { return NS_OK; } if (wcscmp(fsName, L"NTFS") == 0) { fsType = 0; } else if (wcscmp(fsName, L"FAT32") == 0) { fsType = 1; } else if (wcscmp(fsName, L"FAT") == 0) { fsType = 2; } else { fsType = 3; } #endif Telemetry::Accumulate(Telemetry::NETWORK_CACHE_FS_TYPE, fsType); CacheObserver::SetCacheFSReported(); } return NS_OK; } nsresult CacheFileIOManager::OpenNSPRHandle(CacheFileHandle *aHandle, bool aCreate) { MOZ_ASSERT(CacheFileIOManager::IsOnIOThreadOrCeased()); MOZ_ASSERT(!aHandle->mFD); MOZ_ASSERT(mHandlesByLastUsed.IndexOf(aHandle) == mHandlesByLastUsed.NoIndex); MOZ_ASSERT(mHandlesByLastUsed.Length() <= kOpenHandlesLimit); MOZ_ASSERT((aCreate && !aHandle->mFileExists) || (!aCreate && aHandle->mFileExists)); nsresult rv; if (mHandlesByLastUsed.Length() == kOpenHandlesLimit) { // close handle that hasn't been used for the longest time rv = ReleaseNSPRHandleInternal(mHandlesByLastUsed[0]); NS_ENSURE_SUCCESS(rv, rv); } if (aCreate) { rv = aHandle->mFile->OpenNSPRFileDesc( PR_RDWR | PR_CREATE_FILE | PR_TRUNCATE, 0600, &aHandle->mFD); if (rv == NS_ERROR_FILE_ALREADY_EXISTS || // error from nsLocalFileWin rv == NS_ERROR_FILE_NO_DEVICE_SPACE) { // error from nsLocalFileUnix LOG(("CacheFileIOManager::OpenNSPRHandle() - Cannot create a new file, we" " might reached a limit on FAT32. Will evict a single entry and try " "again. [hash=%08x%08x%08x%08x%08x]", LOGSHA1(aHandle->Hash()))); SHA1Sum::Hash hash; uint32_t cnt; rv = CacheIndex::GetEntryForEviction(true, &hash, &cnt); if (NS_SUCCEEDED(rv)) { rv = DoomFileByKeyInternal(&hash); } if (NS_SUCCEEDED(rv)) { rv = aHandle->mFile->OpenNSPRFileDesc( PR_RDWR | PR_CREATE_FILE | PR_TRUNCATE, 0600, &aHandle->mFD); LOG(("CacheFileIOManager::OpenNSPRHandle() - Successfully evicted entry" " with hash %08x%08x%08x%08x%08x. %s to create the new file.", LOGSHA1(&hash), NS_SUCCEEDED(rv) ? "Succeeded" : "Failed")); // Report the full size only once per session static bool sSizeReported = false; if (!sSizeReported) { uint32_t cacheUsage; if (NS_SUCCEEDED(CacheIndex::GetCacheSize(&cacheUsage))) { cacheUsage >>= 10; Telemetry::Accumulate(Telemetry::NETWORK_CACHE_SIZE_FULL_FAT, cacheUsage); sSizeReported = true; } } } else { LOG(("CacheFileIOManager::OpenNSPRHandle() - Couldn't evict an existing" " entry.")); rv = NS_ERROR_FILE_NO_DEVICE_SPACE; } } NS_ENSURE_SUCCESS(rv, rv); aHandle->mFileExists = true; } else { rv = aHandle->mFile->OpenNSPRFileDesc(PR_RDWR, 0600, &aHandle->mFD); if (NS_ERROR_FILE_NOT_FOUND == rv) { LOG((" file doesn't exists")); aHandle->mFileExists = false; return DoomFileInternal(aHandle); } NS_ENSURE_SUCCESS(rv, rv); } mHandlesByLastUsed.AppendElement(aHandle); return NS_OK; } void CacheFileIOManager::NSPRHandleUsed(CacheFileHandle *aHandle) { MOZ_ASSERT(CacheFileIOManager::IsOnIOThreadOrCeased()); MOZ_ASSERT(aHandle->mFD); DebugOnly found; found = mHandlesByLastUsed.RemoveElement(aHandle); MOZ_ASSERT(found); mHandlesByLastUsed.AppendElement(aHandle); } nsresult CacheFileIOManager::SyncRemoveDir(nsIFile *aFile, const char *aDir) { nsresult rv; nsCOMPtr file; if (!aDir) { file = aFile; } else { rv = aFile->Clone(getter_AddRefs(file)); if (NS_WARN_IF(NS_FAILED(rv))) { return rv; } rv = file->AppendNative(nsDependentCString(aDir)); if (NS_WARN_IF(NS_FAILED(rv))) { return rv; } } if (LOG_ENABLED()) { nsAutoCString path; file->GetNativePath(path); LOG(("CacheFileIOManager::SyncRemoveDir() - Removing directory %s", path.get())); } rv = file->Remove(true); if (NS_WARN_IF(NS_FAILED(rv))) { LOG(("CacheFileIOManager::SyncRemoveDir() - Removing failed! [rv=0x%08x]", rv)); } return rv; } void CacheFileIOManager::SyncRemoveAllCacheFiles() { LOG(("CacheFileIOManager::SyncRemoveAllCacheFiles()")); nsresult rv; SyncRemoveDir(mCacheDirectory, ENTRIES_DIR); SyncRemoveDir(mCacheDirectory, DOOMED_DIR); // Clear any intermediate state of trash dir enumeration. mFailedTrashDirs.Clear(); mTrashDir = nullptr; while (true) { // FindTrashDirToRemove() fills mTrashDir if there is any trash directory. rv = FindTrashDirToRemove(); if (rv == NS_ERROR_NOT_AVAILABLE) { LOG(("CacheFileIOManager::SyncRemoveAllCacheFiles() - No trash directory " "found.")); break; } if (NS_WARN_IF(NS_FAILED(rv))) { LOG(("CacheFileIOManager::SyncRemoveAllCacheFiles() - " "FindTrashDirToRemove() returned an unexpected error. [rv=0x%08x]", rv)); break; } rv = SyncRemoveDir(mTrashDir, nullptr); if (NS_FAILED(rv)) { nsAutoCString leafName; mTrashDir->GetNativeLeafName(leafName); mFailedTrashDirs.AppendElement(leafName); } } } // Returns default ("smart") size (in KB) of cache, given available disk space // (also in KB) static uint32_t SmartCacheSize(const uint32_t availKB) { uint32_t maxSize = kMaxCacheSizeKB; if (availKB > 100 * 1024 * 1024) { return maxSize; // skip computing if we're over 100 GB } // Grow/shrink in 10 MB units, deliberately, so that in the common case we // don't shrink cache and evict items every time we startup (it's important // that we don't slow down startup benchmarks). uint32_t sz10MBs = 0; uint32_t avail10MBs = availKB / (1024*10); // .5% of space above 25 GB if (avail10MBs > 2500) { sz10MBs += static_cast((avail10MBs - 2500)*.005); avail10MBs = 2500; } // 1% of space between 7GB -> 25 GB if (avail10MBs > 700) { sz10MBs += static_cast((avail10MBs - 700)*.01); avail10MBs = 700; } // 5% of space between 500 MB -> 7 GB if (avail10MBs > 50) { sz10MBs += static_cast((avail10MBs - 50)*.05); avail10MBs = 50; } #ifdef ANDROID // On Android, smaller/older devices may have very little storage and // device owners may be sensitive to storage footprint: Use a smaller // percentage of available space and a smaller minimum. // 20% of space up to 500 MB (10 MB min) sz10MBs += std::max(1, static_cast(avail10MBs * .2)); #else // 40% of space up to 500 MB (50 MB min) sz10MBs += std::max(5, static_cast(avail10MBs * .4)); #endif return std::min(maxSize, sz10MBs * 10 * 1024); } nsresult CacheFileIOManager::UpdateSmartCacheSize(int64_t aFreeSpace) { MOZ_ASSERT(mIOThread->IsCurrentThread()); nsresult rv; if (!CacheObserver::UseNewCache()) { return NS_ERROR_NOT_AVAILABLE; } if (!CacheObserver::SmartCacheSizeEnabled()) { return NS_ERROR_NOT_AVAILABLE; } // Wait at least kSmartSizeUpdateInterval before recomputing smart size. static const TimeDuration kUpdateLimit = TimeDuration::FromMilliseconds(kSmartSizeUpdateInterval); if (!mLastSmartSizeTime.IsNull() && (TimeStamp::NowLoRes() - mLastSmartSizeTime) < kUpdateLimit) { return NS_OK; } // Do not compute smart size when cache size is not reliable. bool isUpToDate = false; CacheIndex::IsUpToDate(&isUpToDate); if (!isUpToDate) { return NS_ERROR_NOT_AVAILABLE; } uint32_t cacheUsage; rv = CacheIndex::GetCacheSize(&cacheUsage); if (NS_WARN_IF(NS_FAILED(rv))) { LOG(("CacheFileIOManager::UpdateSmartCacheSize() - Cannot get cacheUsage! " "[rv=0x%08x]", rv)); return rv; } mLastSmartSizeTime = TimeStamp::NowLoRes(); uint32_t smartSize = SmartCacheSize(static_cast(aFreeSpace / 1024) + cacheUsage); if (smartSize == (CacheObserver::DiskCacheCapacity() >> 10)) { // Smart size has not changed. return NS_OK; } CacheObserver::SetDiskCacheCapacity(smartSize << 10); return NS_OK; } // Memory reporting namespace { // A helper class that dispatches and waits for an event that gets result of // CacheFileIOManager->mHandles.SizeOfExcludingThis() on the I/O thread // to safely get handles memory report. // We must do this, since the handle list is only accessed and managed w/o // locking on the I/O thread. That is by design. class SizeOfHandlesRunnable : public nsRunnable { public: SizeOfHandlesRunnable(mozilla::MallocSizeOf mallocSizeOf, CacheFileHandles const &handles, nsTArray const &specialHandles) : mMonitor("SizeOfHandlesRunnable.mMonitor") , mMallocSizeOf(mallocSizeOf) , mHandles(handles) , mSpecialHandles(specialHandles) { } size_t Get(CacheIOThread* thread) { nsCOMPtr target = thread->Target(); if (!target) { NS_ERROR("If we have the I/O thread we also must have the I/O target"); return 0; } mozilla::MonitorAutoLock mon(mMonitor); nsresult rv = target->Dispatch(this, nsIEventTarget::DISPATCH_NORMAL); if (NS_FAILED(rv)) { NS_ERROR("Dispatch failed, cannot do memory report of CacheFileHandles"); return 0; } mon.Wait(); return mSize; } NS_IMETHOD Run() { mozilla::MonitorAutoLock mon(mMonitor); // Excluding this since the object itself is a member of CacheFileIOManager // reported in CacheFileIOManager::SizeOfIncludingThis as part of |this|. mSize = mHandles.SizeOfExcludingThis(mMallocSizeOf); for (uint32_t i = 0; i < mSpecialHandles.Length(); ++i) { mSize += mSpecialHandles[i]->SizeOfIncludingThis(mMallocSizeOf); } mon.Notify(); return NS_OK; } private: mozilla::Monitor mMonitor; mozilla::MallocSizeOf mMallocSizeOf; CacheFileHandles const &mHandles; nsTArray const &mSpecialHandles; size_t mSize; }; } // namespace size_t CacheFileIOManager::SizeOfExcludingThisInternal(mozilla::MallocSizeOf mallocSizeOf) const { size_t n = 0; nsCOMPtr sizeOf; if (mIOThread) { n += mIOThread->SizeOfIncludingThis(mallocSizeOf); // mHandles and mSpecialHandles must be accessed only on the I/O thread, // must sync dispatch. RefPtr sizeOfHandlesRunnable = new SizeOfHandlesRunnable(mallocSizeOf, mHandles, mSpecialHandles); n += sizeOfHandlesRunnable->Get(mIOThread); } // mHandlesByLastUsed just refers handles reported by mHandles. sizeOf = do_QueryInterface(mCacheDirectory); if (sizeOf) n += sizeOf->SizeOfIncludingThis(mallocSizeOf); sizeOf = do_QueryInterface(mMetadataWritesTimer); if (sizeOf) n += sizeOf->SizeOfIncludingThis(mallocSizeOf); sizeOf = do_QueryInterface(mTrashTimer); if (sizeOf) n += sizeOf->SizeOfIncludingThis(mallocSizeOf); sizeOf = do_QueryInterface(mTrashDir); if (sizeOf) n += sizeOf->SizeOfIncludingThis(mallocSizeOf); for (uint32_t i = 0; i < mFailedTrashDirs.Length(); ++i) { n += mFailedTrashDirs[i].SizeOfExcludingThisIfUnshared(mallocSizeOf); } return n; } // static size_t CacheFileIOManager::SizeOfExcludingThis(mozilla::MallocSizeOf mallocSizeOf) { if (!gInstance) return 0; return gInstance->SizeOfExcludingThisInternal(mallocSizeOf); } // static size_t CacheFileIOManager::SizeOfIncludingThis(mozilla::MallocSizeOf mallocSizeOf) { return mallocSizeOf(gInstance) + SizeOfExcludingThis(mallocSizeOf); } } // namespace net } // namespace mozilla