/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- * vim: sw=2 ts=2 et lcs=trail\:.,tab\:>~ : * 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 #include "mozilla/Telemetry.h" #include "mozilla/Preferences.h" #include "sqlite3.h" #include "nsThreadUtils.h" #include "mozilla/dom/quota/PersistenceType.h" #include "mozilla/dom/quota/QuotaManager.h" #include "mozilla/dom/quota/QuotaObject.h" #include "mozilla/net/IOActivityMonitor.h" #include "mozilla/IOInterposer.h" #include "nsEscape.h" // The last VFS version for which this file has been updated. #define LAST_KNOWN_VFS_VERSION 3 // The last io_methods version for which this file has been updated. #define LAST_KNOWN_IOMETHODS_VERSION 3 /** * By default use the unix-excl VFS, for the following reasons: * 1. It improves compatibility with NFS shares, whose implementation * is incompatible with SQLite's locking requirements. * Bug 433129 attempted to automatically identify such file-systems, * but a reliable way was not found and the fallback locking is slower than * POSIX locking, so we do not want to do it by default. * 2. It allows wal mode to avoid the memory mapped -shm file, reducing the * likelihood of SIGBUS failures when disk space is exhausted. * 3. It provides some protection from third party database tampering while a * connection is open. * This preference allows to revert to the "unix" VFS, that is not exclusive, * thus it can be used by developers to query a database through the Sqlite * command line while it's already in use. */ #define PREF_MULTI_PROCESS_ACCESS "storage.multiProcessAccess.enabled" namespace { using namespace mozilla; using namespace mozilla::dom::quota; using namespace mozilla::net; struct Histograms { const char* name; const Telemetry::HistogramID readB; const Telemetry::HistogramID writeB; const Telemetry::HistogramID readMS; const Telemetry::HistogramID writeMS; const Telemetry::HistogramID syncMS; }; #define SQLITE_TELEMETRY(FILENAME, HGRAM) \ { \ FILENAME, Telemetry::MOZ_SQLITE_##HGRAM##_READ_B, \ Telemetry::MOZ_SQLITE_##HGRAM##_WRITE_B, \ Telemetry::MOZ_SQLITE_##HGRAM##_READ_MS, \ Telemetry::MOZ_SQLITE_##HGRAM##_WRITE_MS, \ Telemetry::MOZ_SQLITE_##HGRAM##_SYNC_MS \ } Histograms gHistograms[] = {SQLITE_TELEMETRY("places.sqlite", PLACES), SQLITE_TELEMETRY("cookies.sqlite", COOKIES), SQLITE_TELEMETRY("webappsstore.sqlite", WEBAPPS), SQLITE_TELEMETRY(nullptr, OTHER)}; #undef SQLITE_TELEMETRY /** RAII class for measuring how long io takes on/off main thread */ class IOThreadAutoTimer { public: /** * IOThreadAutoTimer measures time spent in IO. Additionally it * automatically determines whether IO is happening on the main * thread and picks an appropriate histogram. * * @param id takes a telemetry histogram id. The id+1 must be an * equivalent histogram for the main thread. Eg, MOZ_SQLITE_OPEN_MS * is followed by MOZ_SQLITE_OPEN_MAIN_THREAD_MS. * * @param aOp optionally takes an IO operation to report through the * IOInterposer. Filename will be reported as NULL, and reference will be * either "sqlite-mainthread" or "sqlite-otherthread". */ explicit IOThreadAutoTimer( Telemetry::HistogramID aId, IOInterposeObserver::Operation aOp = IOInterposeObserver::OpNone) : start(TimeStamp::Now()), id(aId) #if defined(MOZ_GECKO_PROFILER) && !defined(XP_WIN) , op(aOp) #endif { } /** * This constructor is for when we want to report an operation to * IOInterposer but do not require a telemetry probe. * * @param aOp IO Operation to report through the IOInterposer. */ explicit IOThreadAutoTimer(IOInterposeObserver::Operation aOp) : start(TimeStamp::Now()), id(Telemetry::HistogramCount) #if defined(MOZ_GECKO_PROFILER) && !defined(XP_WIN) , op(aOp) #endif { } ~IOThreadAutoTimer() { TimeStamp end(TimeStamp::Now()); uint32_t mainThread = NS_IsMainThread() ? 1 : 0; if (id != Telemetry::HistogramCount) { Telemetry::AccumulateTimeDelta( static_cast(id + mainThread), start, end); } // We don't report SQLite I/O on Windows because we have a comprehensive // mechanism for intercepting I/O on that platform that captures a superset // of the data captured here. #if defined(MOZ_GECKO_PROFILER) && !defined(XP_WIN) if (IOInterposer::IsObservedOperation(op)) { const char* main_ref = "sqlite-mainthread"; const char* other_ref = "sqlite-otherthread"; // Create observation IOInterposeObserver::Observation ob(op, start, end, (mainThread ? main_ref : other_ref)); // Report observation IOInterposer::Report(ob); } #endif /* defined(MOZ_GECKO_PROFILER) && !defined(XP_WIN) */ } private: const TimeStamp start; const Telemetry::HistogramID id; #if defined(MOZ_GECKO_PROFILER) && !defined(XP_WIN) IOInterposeObserver::Operation op; #endif }; struct telemetry_file { // Base class. Must be first sqlite3_file base; // histograms pertaining to this file Histograms* histograms; // quota object for this file RefPtr quotaObject; // The chunk size for this file. See the documentation for // sqlite3_file_control() and FCNTL_CHUNK_SIZE. int fileChunkSize; // The filename char* location; // This contains the vfs that actually does work sqlite3_file pReal[1]; }; const char* DatabasePathFromWALPath(const char* zWALName) { /** * Do some sketchy pointer arithmetic to find the parameter key. The WAL * filename is in the middle of a big allocated block that contains: * * - Random Values * - Main Database Path * - \0 * - Multiple URI components consisting of: * - Key * - \0 * - Value * - \0 * - \0 * - Journal Path * - \0 * - WAL Path (zWALName) * - \0 * * Because the main database path is preceded by a random value we have to be * careful when trying to figure out when we should terminate this loop. */ MOZ_ASSERT(zWALName); nsDependentCSubstring dbPath(zWALName, strlen(zWALName)); // Chop off the "-wal" suffix. NS_NAMED_LITERAL_CSTRING(kWALSuffix, "-wal"); MOZ_ASSERT(StringEndsWith(dbPath, kWALSuffix)); dbPath.Rebind(zWALName, dbPath.Length() - kWALSuffix.Length()); MOZ_ASSERT(!dbPath.IsEmpty()); // We want to scan to the end of the key/value URI pairs. Skip the preceding // null and go to the last char of the journal path. const char* cursor = zWALName - 2; // Make sure we just skipped a null. MOZ_ASSERT(!*(cursor + 1)); // Walk backwards over the journal path. while (*cursor) { cursor--; } // There should be another null here. cursor--; MOZ_ASSERT(!*cursor); // Back up one more char to the last char of the previous string. It may be // the database path or it may be a key/value URI pair. cursor--; #ifdef DEBUG { // Verify that we just walked over the journal path. Account for the two // nulls we just skipped. const char* journalStart = cursor + 3; nsDependentCSubstring journalPath(journalStart, strlen(journalStart)); // Chop off the "-journal" suffix. NS_NAMED_LITERAL_CSTRING(kJournalSuffix, "-journal"); MOZ_ASSERT(StringEndsWith(journalPath, kJournalSuffix)); journalPath.Rebind(journalStart, journalPath.Length() - kJournalSuffix.Length()); MOZ_ASSERT(!journalPath.IsEmpty()); // Make sure that the database name is a substring of the journal name. MOZ_ASSERT(journalPath == dbPath); } #endif // Now we're either at the end of the key/value URI pairs or we're at the // end of the database path. Carefully walk backwards one character at a // time to do this safely without running past the beginning of the database // path. const char* const dbPathStart = dbPath.BeginReading(); const char* dbPathCursor = dbPath.EndReading() - 1; bool isDBPath = true; while (true) { MOZ_ASSERT(*dbPathCursor, "dbPathCursor should never see a null char!"); if (isDBPath) { isDBPath = dbPathStart <= dbPathCursor && *dbPathCursor == *cursor && *cursor; } if (!isDBPath) { // This isn't the database path so it must be a value. Scan past it and // the key also. for (size_t stringCount = 0; stringCount < 2; stringCount++) { // Scan past the string to the preceding null character. while (*cursor) { cursor--; } // Back up one more char to the last char of preceding string. cursor--; } // Reset and start again. dbPathCursor = dbPath.EndReading() - 1; isDBPath = true; continue; } MOZ_ASSERT(isDBPath); MOZ_ASSERT(*cursor); if (dbPathStart == dbPathCursor) { // Found the full database path, we're all done. MOZ_ASSERT(nsDependentCString(cursor) == dbPath); return cursor; } // Change the cursors and go through the loop again. cursor--; dbPathCursor--; } MOZ_CRASH("Should never get here!"); } already_AddRefed GetQuotaObjectFromNameAndParameters( const char* zName, const char* zURIParameterKey) { MOZ_ASSERT(zName); MOZ_ASSERT(zURIParameterKey); const char* directoryLockIdParam = sqlite3_uri_parameter(zURIParameterKey, "directoryLockId"); if (!directoryLockIdParam) { return nullptr; } nsresult rv; const int64_t directoryLockId = nsDependentCString(directoryLockIdParam).ToInteger64(&rv); MOZ_RELEASE_ASSERT(NS_SUCCEEDED(rv)); QuotaManager* quotaManager = QuotaManager::Get(); MOZ_ASSERT(quotaManager); return quotaManager->GetQuotaObject(directoryLockId, NS_ConvertUTF8toUTF16(zName)); } void MaybeEstablishQuotaControl(const char* zName, telemetry_file* pFile, int flags) { MOZ_ASSERT(pFile); MOZ_ASSERT(!pFile->quotaObject); if (!(flags & (SQLITE_OPEN_URI | SQLITE_OPEN_WAL))) { return; } MOZ_ASSERT(zName); const char* zURIParameterKey = (flags & SQLITE_OPEN_WAL) ? DatabasePathFromWALPath(zName) : zName; MOZ_ASSERT(zURIParameterKey); pFile->quotaObject = GetQuotaObjectFromNameAndParameters(zName, zURIParameterKey); } /* ** Close a telemetry_file. */ int xClose(sqlite3_file* pFile) { telemetry_file* p = (telemetry_file*)pFile; int rc; { // Scope for IOThreadAutoTimer IOThreadAutoTimer ioTimer(IOInterposeObserver::OpClose); rc = p->pReal->pMethods->xClose(p->pReal); } if (rc == SQLITE_OK) { delete p->base.pMethods; p->base.pMethods = nullptr; p->quotaObject = nullptr; delete[] p->location; #ifdef DEBUG p->fileChunkSize = 0; #endif } return rc; } /* ** Read data from a telemetry_file. */ int xRead(sqlite3_file* pFile, void* zBuf, int iAmt, sqlite_int64 iOfst) { telemetry_file* p = (telemetry_file*)pFile; IOThreadAutoTimer ioTimer(p->histograms->readMS, IOInterposeObserver::OpRead); int rc; rc = p->pReal->pMethods->xRead(p->pReal, zBuf, iAmt, iOfst); if (rc == SQLITE_OK && IOActivityMonitor::IsActive()) { IOActivityMonitor::Read(nsDependentCString(p->location), iAmt); } // sqlite likes to read from empty files, this is normal, ignore it. if (rc != SQLITE_IOERR_SHORT_READ) Telemetry::Accumulate(p->histograms->readB, rc == SQLITE_OK ? iAmt : 0); return rc; } /* ** Return the current file-size of a telemetry_file. */ int xFileSize(sqlite3_file* pFile, sqlite_int64* pSize) { IOThreadAutoTimer ioTimer(IOInterposeObserver::OpStat); telemetry_file* p = (telemetry_file*)pFile; int rc; rc = p->pReal->pMethods->xFileSize(p->pReal, pSize); return rc; } /* ** Write data to a telemetry_file. */ int xWrite(sqlite3_file* pFile, const void* zBuf, int iAmt, sqlite_int64 iOfst) { telemetry_file* p = (telemetry_file*)pFile; IOThreadAutoTimer ioTimer(p->histograms->writeMS, IOInterposeObserver::OpWrite); int rc; if (p->quotaObject) { MOZ_ASSERT(INT64_MAX - iOfst >= iAmt); if (!p->quotaObject->MaybeUpdateSize(iOfst + iAmt, /* aTruncate */ false)) { return SQLITE_FULL; } } rc = p->pReal->pMethods->xWrite(p->pReal, zBuf, iAmt, iOfst); if (rc == SQLITE_OK && IOActivityMonitor::IsActive()) { IOActivityMonitor::Write(nsDependentCString(p->location), iAmt); } Telemetry::Accumulate(p->histograms->writeB, rc == SQLITE_OK ? iAmt : 0); if (p->quotaObject && rc != SQLITE_OK) { NS_WARNING( "xWrite failed on a quota-controlled file, attempting to " "update its current size..."); sqlite_int64 currentSize; if (xFileSize(pFile, ¤tSize) == SQLITE_OK) { p->quotaObject->MaybeUpdateSize(currentSize, /* aTruncate */ true); } } return rc; } /* ** Truncate a telemetry_file. */ int xTruncate(sqlite3_file* pFile, sqlite_int64 size) { IOThreadAutoTimer ioTimer(Telemetry::MOZ_SQLITE_TRUNCATE_MS); telemetry_file* p = (telemetry_file*)pFile; int rc; Telemetry::AutoTimer timer; if (p->quotaObject) { if (p->fileChunkSize > 0) { // Round up to the smallest multiple of the chunk size that will hold all // the data. size = ((size + p->fileChunkSize - 1) / p->fileChunkSize) * p->fileChunkSize; } if (!p->quotaObject->MaybeUpdateSize(size, /* aTruncate */ true)) { return SQLITE_FULL; } } rc = p->pReal->pMethods->xTruncate(p->pReal, size); if (p->quotaObject) { if (rc == SQLITE_OK) { #ifdef DEBUG // Make sure xTruncate set the size exactly as we calculated above. sqlite_int64 newSize; MOZ_ASSERT(xFileSize(pFile, &newSize) == SQLITE_OK); MOZ_ASSERT(newSize == size); #endif } else { NS_WARNING( "xTruncate failed on a quota-controlled file, attempting to " "update its current size..."); if (xFileSize(pFile, &size) == SQLITE_OK) { p->quotaObject->MaybeUpdateSize(size, /* aTruncate */ true); } } } return rc; } /* ** Sync a telemetry_file. */ int xSync(sqlite3_file* pFile, int flags) { telemetry_file* p = (telemetry_file*)pFile; IOThreadAutoTimer ioTimer(p->histograms->syncMS, IOInterposeObserver::OpFSync); return p->pReal->pMethods->xSync(p->pReal, flags); } /* ** Lock a telemetry_file. */ int xLock(sqlite3_file* pFile, int eLock) { telemetry_file* p = (telemetry_file*)pFile; int rc; rc = p->pReal->pMethods->xLock(p->pReal, eLock); return rc; } /* ** Unlock a telemetry_file. */ int xUnlock(sqlite3_file* pFile, int eLock) { telemetry_file* p = (telemetry_file*)pFile; int rc; rc = p->pReal->pMethods->xUnlock(p->pReal, eLock); return rc; } /* ** Check if another file-handle holds a RESERVED lock on a telemetry_file. */ int xCheckReservedLock(sqlite3_file* pFile, int* pResOut) { telemetry_file* p = (telemetry_file*)pFile; int rc = p->pReal->pMethods->xCheckReservedLock(p->pReal, pResOut); return rc; } /* ** File control method. For custom operations on a telemetry_file. */ int xFileControl(sqlite3_file* pFile, int op, void* pArg) { telemetry_file* p = (telemetry_file*)pFile; int rc; // Hook SQLITE_FCNTL_SIZE_HINT for quota-controlled files and do the necessary // work before passing to the SQLite VFS. if (op == SQLITE_FCNTL_SIZE_HINT && p->quotaObject) { sqlite3_int64 hintSize = *static_cast(pArg); sqlite3_int64 currentSize; rc = xFileSize(pFile, ¤tSize); if (rc != SQLITE_OK) { return rc; } if (hintSize > currentSize) { rc = xTruncate(pFile, hintSize); if (rc != SQLITE_OK) { return rc; } } } rc = p->pReal->pMethods->xFileControl(p->pReal, op, pArg); // Grab the file chunk size after the SQLite VFS has approved. if (op == SQLITE_FCNTL_CHUNK_SIZE && rc == SQLITE_OK) { p->fileChunkSize = *static_cast(pArg); } #ifdef DEBUG if (op == SQLITE_FCNTL_SIZE_HINT && p->quotaObject && rc == SQLITE_OK) { sqlite3_int64 hintSize = *static_cast(pArg); if (p->fileChunkSize > 0) { hintSize = ((hintSize + p->fileChunkSize - 1) / p->fileChunkSize) * p->fileChunkSize; } sqlite3_int64 currentSize; MOZ_ASSERT(xFileSize(pFile, ¤tSize) == SQLITE_OK); MOZ_ASSERT(currentSize >= hintSize); } #endif return rc; } /* ** Return the sector-size in bytes for a telemetry_file. */ int xSectorSize(sqlite3_file* pFile) { telemetry_file* p = (telemetry_file*)pFile; int rc; rc = p->pReal->pMethods->xSectorSize(p->pReal); return rc; } /* ** Return the device characteristic flags supported by a telemetry_file. */ int xDeviceCharacteristics(sqlite3_file* pFile) { telemetry_file* p = (telemetry_file*)pFile; int rc; rc = p->pReal->pMethods->xDeviceCharacteristics(p->pReal); return rc; } /* ** Shared-memory operations. */ int xShmLock(sqlite3_file* pFile, int ofst, int n, int flags) { telemetry_file* p = (telemetry_file*)pFile; return p->pReal->pMethods->xShmLock(p->pReal, ofst, n, flags); } int xShmMap(sqlite3_file* pFile, int iRegion, int szRegion, int isWrite, void volatile** pp) { telemetry_file* p = (telemetry_file*)pFile; int rc; rc = p->pReal->pMethods->xShmMap(p->pReal, iRegion, szRegion, isWrite, pp); return rc; } void xShmBarrier(sqlite3_file* pFile) { telemetry_file* p = (telemetry_file*)pFile; p->pReal->pMethods->xShmBarrier(p->pReal); } int xShmUnmap(sqlite3_file* pFile, int delFlag) { telemetry_file* p = (telemetry_file*)pFile; int rc; rc = p->pReal->pMethods->xShmUnmap(p->pReal, delFlag); return rc; } int xFetch(sqlite3_file* pFile, sqlite3_int64 iOff, int iAmt, void** pp) { telemetry_file* p = (telemetry_file*)pFile; MOZ_ASSERT(p->pReal->pMethods->iVersion >= 3); return p->pReal->pMethods->xFetch(p->pReal, iOff, iAmt, pp); } int xUnfetch(sqlite3_file* pFile, sqlite3_int64 iOff, void* pResOut) { telemetry_file* p = (telemetry_file*)pFile; MOZ_ASSERT(p->pReal->pMethods->iVersion >= 3); return p->pReal->pMethods->xUnfetch(p->pReal, iOff, pResOut); } int xOpen(sqlite3_vfs* vfs, const char* zName, sqlite3_file* pFile, int flags, int* pOutFlags) { IOThreadAutoTimer ioTimer(Telemetry::MOZ_SQLITE_OPEN_MS, IOInterposeObserver::OpCreateOrOpen); Telemetry::AutoTimer timer; sqlite3_vfs* orig_vfs = static_cast(vfs->pAppData); int rc; telemetry_file* p = (telemetry_file*)pFile; Histograms* h = nullptr; // check if the filename is one we are probing for for (size_t i = 0; i < sizeof(gHistograms) / sizeof(gHistograms[0]); i++) { h = &gHistograms[i]; // last probe is the fallback probe if (!h->name) break; if (!zName) continue; const char* match = strstr(zName, h->name); if (!match) continue; char c = match[strlen(h->name)]; // include -wal/-journal too if (!c || c == '-') break; } p->histograms = h; MaybeEstablishQuotaControl(zName, p, flags); rc = orig_vfs->xOpen(orig_vfs, zName, p->pReal, flags, pOutFlags); if (rc != SQLITE_OK) return rc; if (zName) { p->location = new char[7 + strlen(zName) + 1]; strcpy(p->location, "file://"); strcpy(p->location + 7, zName); } else { p->location = new char[8]; strcpy(p->location, "file://"); } if (p->pReal->pMethods) { sqlite3_io_methods* pNew = new sqlite3_io_methods; const sqlite3_io_methods* pSub = p->pReal->pMethods; memset(pNew, 0, sizeof(*pNew)); // If the io_methods version is higher than the last known one, you should // update this VFS adding appropriate IO methods for any methods added in // the version change. pNew->iVersion = pSub->iVersion; MOZ_ASSERT(pNew->iVersion <= LAST_KNOWN_IOMETHODS_VERSION); pNew->xClose = xClose; pNew->xRead = xRead; pNew->xWrite = xWrite; pNew->xTruncate = xTruncate; pNew->xSync = xSync; pNew->xFileSize = xFileSize; pNew->xLock = xLock; pNew->xUnlock = xUnlock; pNew->xCheckReservedLock = xCheckReservedLock; pNew->xFileControl = xFileControl; pNew->xSectorSize = xSectorSize; pNew->xDeviceCharacteristics = xDeviceCharacteristics; if (pNew->iVersion >= 2) { // Methods added in version 2. pNew->xShmMap = pSub->xShmMap ? xShmMap : 0; pNew->xShmLock = pSub->xShmLock ? xShmLock : 0; pNew->xShmBarrier = pSub->xShmBarrier ? xShmBarrier : 0; pNew->xShmUnmap = pSub->xShmUnmap ? xShmUnmap : 0; } if (pNew->iVersion >= 3) { // Methods added in version 3. // SQLite 3.7.17 calls these methods without checking for nullptr first, // so we always define them. Verify that we're not going to call // nullptrs, though. MOZ_ASSERT(pSub->xFetch); pNew->xFetch = xFetch; MOZ_ASSERT(pSub->xUnfetch); pNew->xUnfetch = xUnfetch; } pFile->pMethods = pNew; } return rc; } int xDelete(sqlite3_vfs* vfs, const char* zName, int syncDir) { sqlite3_vfs* orig_vfs = static_cast(vfs->pAppData); int rc; RefPtr quotaObject; if (StringEndsWith(nsDependentCString(zName), NS_LITERAL_CSTRING("-wal"))) { const char* zURIParameterKey = DatabasePathFromWALPath(zName); MOZ_ASSERT(zURIParameterKey); quotaObject = GetQuotaObjectFromNameAndParameters(zName, zURIParameterKey); } rc = orig_vfs->xDelete(orig_vfs, zName, syncDir); if (rc == SQLITE_OK && quotaObject) { MOZ_ALWAYS_TRUE(quotaObject->MaybeUpdateSize(0, /* aTruncate */ true)); } return rc; } int xAccess(sqlite3_vfs* vfs, const char* zName, int flags, int* pResOut) { sqlite3_vfs* orig_vfs = static_cast(vfs->pAppData); return orig_vfs->xAccess(orig_vfs, zName, flags, pResOut); } int xFullPathname(sqlite3_vfs* vfs, const char* zName, int nOut, char* zOut) { sqlite3_vfs* orig_vfs = static_cast(vfs->pAppData); return orig_vfs->xFullPathname(orig_vfs, zName, nOut, zOut); } void* xDlOpen(sqlite3_vfs* vfs, const char* zFilename) { sqlite3_vfs* orig_vfs = static_cast(vfs->pAppData); return orig_vfs->xDlOpen(orig_vfs, zFilename); } void xDlError(sqlite3_vfs* vfs, int nByte, char* zErrMsg) { sqlite3_vfs* orig_vfs = static_cast(vfs->pAppData); orig_vfs->xDlError(orig_vfs, nByte, zErrMsg); } void (*xDlSym(sqlite3_vfs* vfs, void* pHdle, const char* zSym))(void) { sqlite3_vfs* orig_vfs = static_cast(vfs->pAppData); return orig_vfs->xDlSym(orig_vfs, pHdle, zSym); } void xDlClose(sqlite3_vfs* vfs, void* pHandle) { sqlite3_vfs* orig_vfs = static_cast(vfs->pAppData); orig_vfs->xDlClose(orig_vfs, pHandle); } int xRandomness(sqlite3_vfs* vfs, int nByte, char* zOut) { sqlite3_vfs* orig_vfs = static_cast(vfs->pAppData); return orig_vfs->xRandomness(orig_vfs, nByte, zOut); } int xSleep(sqlite3_vfs* vfs, int microseconds) { sqlite3_vfs* orig_vfs = static_cast(vfs->pAppData); return orig_vfs->xSleep(orig_vfs, microseconds); } int xCurrentTime(sqlite3_vfs* vfs, double* prNow) { sqlite3_vfs* orig_vfs = static_cast(vfs->pAppData); return orig_vfs->xCurrentTime(orig_vfs, prNow); } int xGetLastError(sqlite3_vfs* vfs, int nBuf, char* zBuf) { sqlite3_vfs* orig_vfs = static_cast(vfs->pAppData); return orig_vfs->xGetLastError(orig_vfs, nBuf, zBuf); } int xCurrentTimeInt64(sqlite3_vfs* vfs, sqlite3_int64* piNow) { sqlite3_vfs* orig_vfs = static_cast(vfs->pAppData); return orig_vfs->xCurrentTimeInt64(orig_vfs, piNow); } static int xSetSystemCall(sqlite3_vfs* vfs, const char* zName, sqlite3_syscall_ptr pFunc) { sqlite3_vfs* orig_vfs = static_cast(vfs->pAppData); return orig_vfs->xSetSystemCall(orig_vfs, zName, pFunc); } static sqlite3_syscall_ptr xGetSystemCall(sqlite3_vfs* vfs, const char* zName) { sqlite3_vfs* orig_vfs = static_cast(vfs->pAppData); return orig_vfs->xGetSystemCall(orig_vfs, zName); } static const char* xNextSystemCall(sqlite3_vfs* vfs, const char* zName) { sqlite3_vfs* orig_vfs = static_cast(vfs->pAppData); return orig_vfs->xNextSystemCall(orig_vfs, zName); } } // namespace namespace mozilla { namespace storage { const char* GetVFSName() { return "telemetry-vfs"; } sqlite3_vfs* ConstructTelemetryVFS() { #if defined(XP_WIN) # define EXPECTED_VFS "win32" # define EXPECTED_VFS_EXCL "win32" #else # define EXPECTED_VFS "unix" # define EXPECTED_VFS_EXCL "unix-excl" #endif bool expected_vfs; sqlite3_vfs* vfs; if (Preferences::GetBool(PREF_MULTI_PROCESS_ACCESS, false)) { // Use the non-exclusive VFS. vfs = sqlite3_vfs_find(nullptr); expected_vfs = vfs->zName && !strcmp(vfs->zName, EXPECTED_VFS); } else { vfs = sqlite3_vfs_find(EXPECTED_VFS_EXCL); expected_vfs = (vfs != nullptr); } if (!expected_vfs) { return nullptr; } sqlite3_vfs* tvfs = new ::sqlite3_vfs; memset(tvfs, 0, sizeof(::sqlite3_vfs)); // If the VFS version is higher than the last known one, you should update // this VFS adding appropriate methods for any methods added in the version // change. tvfs->iVersion = vfs->iVersion; MOZ_ASSERT(vfs->iVersion <= LAST_KNOWN_VFS_VERSION); tvfs->szOsFile = sizeof(telemetry_file) - sizeof(sqlite3_file) + vfs->szOsFile; tvfs->mxPathname = vfs->mxPathname; tvfs->zName = GetVFSName(); tvfs->pAppData = vfs; tvfs->xOpen = xOpen; tvfs->xDelete = xDelete; tvfs->xAccess = xAccess; tvfs->xFullPathname = xFullPathname; tvfs->xDlOpen = xDlOpen; tvfs->xDlError = xDlError; tvfs->xDlSym = xDlSym; tvfs->xDlClose = xDlClose; tvfs->xRandomness = xRandomness; tvfs->xSleep = xSleep; tvfs->xCurrentTime = xCurrentTime; tvfs->xGetLastError = xGetLastError; if (tvfs->iVersion >= 2) { // Methods added in version 2. tvfs->xCurrentTimeInt64 = xCurrentTimeInt64; } if (tvfs->iVersion >= 3) { // Methods added in version 3. tvfs->xSetSystemCall = xSetSystemCall; tvfs->xGetSystemCall = xGetSystemCall; tvfs->xNextSystemCall = xNextSystemCall; } return tvfs; } already_AddRefed GetQuotaObjectForFile(sqlite3_file* pFile) { MOZ_ASSERT(pFile); telemetry_file* p = (telemetry_file*)pFile; RefPtr result = p->quotaObject; return result.forget(); } } // namespace storage } // namespace mozilla