/* * Copyright (C) 2019 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #define LOG_TAG "IncrementalService" #include "IncrementalService.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include "IncrementalServiceValidation.h" #include "Metadata.pb.h" using namespace std::literals; constexpr const char* kLoaderUsageStats = "android.permission.LOADER_USAGE_STATS"; constexpr const char* kOpUsage = "android:loader_usage_stats"; constexpr const char* kInteractAcrossUsers = "android.permission.INTERACT_ACROSS_USERS"; namespace android::incremental { using content::pm::DataLoaderParamsParcel; using content::pm::FileSystemControlParcel; using content::pm::IDataLoader; namespace { using IncrementalFileSystemControlParcel = os::incremental::IncrementalFileSystemControlParcel; struct Constants { static constexpr auto backing = "backing_store"sv; static constexpr auto mount = "mount"sv; static constexpr auto mountKeyPrefix = "MT_"sv; static constexpr auto storagePrefix = "st"sv; static constexpr auto mountpointMdPrefix = ".mountpoint."sv; static constexpr auto infoMdName = ".info"sv; static constexpr auto readLogsDisabledMarkerName = ".readlogs_disabled"sv; static constexpr auto libDir = "lib"sv; static constexpr auto libSuffix = ".so"sv; static constexpr auto blockSize = 4096; static constexpr auto systemPackage = "android"sv; static constexpr auto userStatusDelay = 100ms; static constexpr auto progressUpdateInterval = 1000ms; static constexpr auto perUidTimeoutOffset = progressUpdateInterval * 2; static constexpr auto minPerUidTimeout = progressUpdateInterval * 3; // If DL was up and not crashing for 10mins, we consider it healthy and reset all delays. static constexpr auto healthyDataLoaderUptime = 10min; // For healthy DLs, we'll retry every ~5secs for ~10min static constexpr auto bindRetryInterval = 5s; static constexpr auto bindGracePeriod = 10min; static constexpr auto bindingTimeout = 1min; // 1s, 10s, 100s (~2min), 1000s (~15min), 10000s (~3hrs) static constexpr auto minBindDelay = 1s; static constexpr auto maxBindDelay = 10000s; static constexpr auto bindDelayMultiplier = 10; static constexpr auto bindDelayJitterDivider = 10; // Max interval after system invoked the DL when readlog collection can be enabled. static constexpr auto readLogsMaxInterval = 2h; // How long should we wait till dataLoader reports destroyed. static constexpr auto destroyTimeout = 10s; static constexpr auto anyStatus = INT_MIN; }; static const Constants& constants() { static constexpr Constants c; return c; } static bool isPageAligned(IncFsSize s) { return (s & (Constants::blockSize - 1)) == 0; } static bool getAlwaysEnableReadTimeoutsForSystemDataLoaders() { return android::base:: GetBoolProperty("debug.incremental.always_enable_read_timeouts_for_system_dataloaders", true); } static bool getEnableReadTimeoutsAfterInstall() { return android::base::GetBoolProperty("debug.incremental.enable_read_timeouts_after_install", true); } static bool getEnforceReadLogsMaxIntervalForSystemDataLoaders() { return android::base::GetBoolProperty("debug.incremental.enforce_readlogs_max_interval_for_" "system_dataloaders", false); } static Seconds getReadLogsMaxInterval() { constexpr int limit = duration_cast(Constants::readLogsMaxInterval).count(); int readlogs_max_interval_secs = std::min(limit, android::base::GetIntProperty< int>("debug.incremental.readlogs_max_interval_sec", limit)); return Seconds{readlogs_max_interval_secs}; } template bool mkdirOrLog(std::string_view name, int mode = 0770, bool allowExisting = true) { auto cstr = path::c_str(name); if (::mkdir(cstr, mode)) { if (!allowExisting || errno != EEXIST) { PLOG(level) << "Can't create directory '" << name << '\''; return false; } struct stat st; if (::stat(cstr, &st) || !S_ISDIR(st.st_mode)) { PLOG(level) << "Path exists but is not a directory: '" << name << '\''; return false; } } if (::chmod(cstr, mode)) { PLOG(level) << "Changing permission failed for '" << name << '\''; return false; } return true; } static std::string toMountKey(std::string_view path) { if (path.empty()) { return "@none"; } if (path == "/"sv) { return "@root"; } if (path::isAbsolute(path)) { path.remove_prefix(1); } if (path.size() > 16) { path = path.substr(0, 16); } std::string res(path); std::replace_if( res.begin(), res.end(), [](char c) { return c == '/' || c == '@'; }, '_'); return std::string(constants().mountKeyPrefix) += res; } static std::pair makeMountDir(std::string_view incrementalDir, std::string_view path) { auto mountKey = toMountKey(path); const auto prefixSize = mountKey.size(); for (int counter = 0; counter < 1000; mountKey.resize(prefixSize), base::StringAppendF(&mountKey, "%d", counter++)) { auto mountRoot = path::join(incrementalDir, mountKey); if (mkdirOrLog(mountRoot, 0777, false)) { return {mountKey, mountRoot}; } } return {}; } template typename Map::const_iterator findParentPath(const Map& map, std::string_view path) { const auto nextIt = map.upper_bound(path); if (nextIt == map.begin()) { return map.end(); } const auto suspectIt = std::prev(nextIt); if (!path::startsWith(path, suspectIt->first)) { return map.end(); } return suspectIt; } static base::unique_fd dup(base::borrowed_fd fd) { const auto res = fcntl(fd.get(), F_DUPFD_CLOEXEC, 0); return base::unique_fd(res); } template static ProtoMessage parseFromIncfs(const IncFsWrapper* incfs, const Control& control, std::string_view path) { auto md = incfs->getMetadata(control, path); ProtoMessage message; return message.ParseFromArray(md.data(), md.size()) ? message : ProtoMessage{}; } static bool isValidMountTarget(std::string_view path) { return path::isAbsolute(path) && path::isEmptyDir(path).value_or(true); } std::string makeUniqueName(std::string_view prefix) { static constexpr auto uuidStringSize = 36; uuid_t guid; uuid_generate(guid); std::string name; const auto prefixSize = prefix.size(); name.reserve(prefixSize + uuidStringSize); name = prefix; name.resize(prefixSize + uuidStringSize); uuid_unparse(guid, name.data() + prefixSize); return name; } std::string makeBindMdName() { return makeUniqueName(constants().mountpointMdPrefix); } static bool checkReadLogsDisabledMarker(std::string_view root) { const auto markerPath = path::c_str(path::join(root, constants().readLogsDisabledMarkerName)); struct stat st; return (::stat(markerPath, &st) == 0); } } // namespace IncrementalService::IncFsMount::~IncFsMount() { if (dataLoaderStub) { dataLoaderStub->cleanupResources(); dataLoaderStub = {}; } control.close(); LOG(INFO) << "Unmounting and cleaning up mount " << mountId << " with root '" << root << '\''; for (auto&& [target, _] : bindPoints) { LOG(INFO) << " bind: " << target; incrementalService.mVold->unmountIncFs(target); } LOG(INFO) << " root: " << root; incrementalService.mVold->unmountIncFs(path::join(root, constants().mount)); cleanupFilesystem(root); } auto IncrementalService::IncFsMount::makeStorage(StorageId id) -> StorageMap::iterator { std::string name; for (int no = nextStorageDirNo.fetch_add(1, std::memory_order_relaxed), i = 0; i < 1024 && no >= 0; no = nextStorageDirNo.fetch_add(1, std::memory_order_relaxed), ++i) { name.clear(); base::StringAppendF(&name, "%.*s_%d_%d", int(constants().storagePrefix.size()), constants().storagePrefix.data(), id, no); auto fullName = path::join(root, constants().mount, name); if (auto err = incrementalService.mIncFs->makeDir(control, fullName, 0755); !err) { std::lock_guard l(lock); return storages.insert_or_assign(id, Storage{std::move(fullName)}).first; } else if (err != EEXIST) { LOG(ERROR) << __func__ << "(): failed to create dir |" << fullName << "| " << err; break; } } nextStorageDirNo = 0; return storages.end(); } template static auto makeCleanup(Func&& f) requires(!std::is_lvalue_reference_v) { // ok to move a 'forwarding' reference here as lvalues are disabled anyway auto deleter = [f = std::move(f)](auto) { // NOLINT f(); }; // &f is a dangling pointer here, but we actually never use it as deleter moves it in. return std::unique_ptr(&f, std::move(deleter)); } static auto openDir(const char* dir) { struct DirCloser { void operator()(DIR* d) const noexcept { ::closedir(d); } }; return std::unique_ptr(::opendir(dir)); } static auto openDir(std::string_view dir) { return openDir(path::c_str(dir)); } static int rmDirContent(const char* path) { auto dir = openDir(path); if (!dir) { return -EINVAL; } while (auto entry = ::readdir(dir.get())) { if (entry->d_name == "."sv || entry->d_name == ".."sv) { continue; } auto fullPath = base::StringPrintf("%s/%s", path, entry->d_name); if (entry->d_type == DT_DIR) { if (const auto err = rmDirContent(fullPath.c_str()); err != 0) { PLOG(WARNING) << "Failed to delete " << fullPath << " content"; return err; } if (const auto err = ::rmdir(fullPath.c_str()); err != 0) { PLOG(WARNING) << "Failed to rmdir " << fullPath; return err; } } else { if (const auto err = ::unlink(fullPath.c_str()); err != 0) { PLOG(WARNING) << "Failed to delete " << fullPath; return err; } } } return 0; } void IncrementalService::IncFsMount::cleanupFilesystem(std::string_view root) { rmDirContent(path::join(root, constants().backing).c_str()); ::rmdir(path::join(root, constants().backing).c_str()); ::rmdir(path::join(root, constants().mount).c_str()); ::rmdir(path::c_str(root)); } void IncrementalService::IncFsMount::setFlag(StorageFlags flag, bool value) { if (value) { flags |= flag; } else { flags &= ~flag; } } IncrementalService::IncrementalService(ServiceManagerWrapper&& sm, std::string_view rootDir) : mVold(sm.getVoldService()), mDataLoaderManager(sm.getDataLoaderManager()), mIncFs(sm.getIncFs()), mAppOpsManager(sm.getAppOpsManager()), mJni(sm.getJni()), mLooper(sm.getLooper()), mTimedQueue(sm.getTimedQueue()), mProgressUpdateJobQueue(sm.getProgressUpdateJobQueue()), mFs(sm.getFs()), mClock(sm.getClock()), mIncrementalDir(rootDir) { CHECK(mVold) << "Vold service is unavailable"; CHECK(mDataLoaderManager) << "DataLoaderManagerService is unavailable"; CHECK(mAppOpsManager) << "AppOpsManager is unavailable"; CHECK(mJni) << "JNI is unavailable"; CHECK(mLooper) << "Looper is unavailable"; CHECK(mTimedQueue) << "TimedQueue is unavailable"; CHECK(mProgressUpdateJobQueue) << "mProgressUpdateJobQueue is unavailable"; CHECK(mFs) << "Fs is unavailable"; CHECK(mClock) << "Clock is unavailable"; mJobQueue.reserve(16); mJobProcessor = std::thread([this]() { mJni->initializeForCurrentThread(); runJobProcessing(); }); mCmdLooperThread = std::thread([this]() { mJni->initializeForCurrentThread(); runCmdLooper(); }); const auto mountedRootNames = adoptMountedInstances(); mountExistingImages(mountedRootNames); } IncrementalService::~IncrementalService() { { std::lock_guard lock(mJobMutex); mRunning = false; } mJobCondition.notify_all(); mJobProcessor.join(); mLooper->wake(); mCmdLooperThread.join(); mTimedQueue->stop(); mProgressUpdateJobQueue->stop(); // Ensure that mounts are destroyed while the service is still valid. mBindsByPath.clear(); mMounts.clear(); } static const char* toString(IncrementalService::BindKind kind) { switch (kind) { case IncrementalService::BindKind::Temporary: return "Temporary"; case IncrementalService::BindKind::Permanent: return "Permanent"; } } template static int64_t elapsedMcs(Duration start, Duration end) { return std::chrono::duration_cast(end - start).count(); } int64_t IncrementalService::elapsedUsSinceMonoTs(uint64_t monoTsUs) { const auto now = mClock->now(); const auto nowUs = static_cast( duration_cast(now.time_since_epoch()).count()); return nowUs - monoTsUs; } static const char* loadingStateToString(incfs::LoadingState state) { switch (state) { case (incfs::LoadingState::Full): return "Full"; case (incfs::LoadingState::MissingBlocks): return "MissingBlocks"; default: return "error obtaining loading state"; } } void IncrementalService::onDump(int fd) { dprintf(fd, "Incremental is %s\n", incfs::enabled() ? "ENABLED" : "DISABLED"); dprintf(fd, "IncFs features: 0x%x\n", int(mIncFs->features())); dprintf(fd, "Incremental dir: %s\n", mIncrementalDir.c_str()); std::unique_lock l(mLock); dprintf(fd, "Mounts (%d): {\n", int(mMounts.size())); for (auto&& [id, ifs] : mMounts) { std::unique_lock ll(ifs->lock); const IncFsMount& mnt = *ifs; dprintf(fd, " [%d]: {\n", id); if (id != mnt.mountId) { dprintf(fd, " reference to mountId: %d\n", mnt.mountId); } else { dprintf(fd, " mountId: %d\n", mnt.mountId); dprintf(fd, " root: %s\n", mnt.root.c_str()); const auto& metricsInstanceName = ifs->metricsKey; dprintf(fd, " metrics instance name: %s\n", path::c_str(metricsInstanceName).get()); dprintf(fd, " nextStorageDirNo: %d\n", mnt.nextStorageDirNo.load()); dprintf(fd, " flags: %d\n", int(mnt.flags)); if (mnt.startLoadingTs.time_since_epoch() == Clock::duration::zero()) { dprintf(fd, " not loading\n"); } else { dprintf(fd, " startLoading: %llds\n", (long long)(elapsedMcs(mnt.startLoadingTs, Clock::now()) / 1000000)); } if (mnt.dataLoaderStub) { mnt.dataLoaderStub->onDump(fd); } else { dprintf(fd, " dataLoader: null\n"); } dprintf(fd, " storages (%d): {\n", int(mnt.storages.size())); for (auto&& [storageId, storage] : mnt.storages) { auto&& ifs = getIfsLocked(storageId); dprintf(fd, " [%d] -> [%s] (%d %% loaded)(%s) \n", storageId, storage.name.c_str(), (int)(getLoadingProgressFromPath(mnt, storage.name.c_str()).getProgress() * 100), ifs ? loadingStateToString(mIncFs->isEverythingFullyLoaded(ifs->control)) : "error obtaining ifs"); } dprintf(fd, " }\n"); dprintf(fd, " bindPoints (%d): {\n", int(mnt.bindPoints.size())); for (auto&& [target, bind] : mnt.bindPoints) { dprintf(fd, " [%s]->[%d]:\n", target.c_str(), bind.storage); dprintf(fd, " savedFilename: %s\n", bind.savedFilename.c_str()); dprintf(fd, " sourceDir: %s\n", bind.sourceDir.c_str()); dprintf(fd, " kind: %s\n", toString(bind.kind)); } dprintf(fd, " }\n"); dprintf(fd, " incfsMetrics: {\n"); const auto incfsMetrics = mIncFs->getMetrics(metricsInstanceName); if (incfsMetrics) { dprintf(fd, " readsDelayedMin: %d\n", incfsMetrics.value().readsDelayedMin); dprintf(fd, " readsDelayedMinUs: %lld\n", (long long)incfsMetrics.value().readsDelayedMinUs); dprintf(fd, " readsDelayedPending: %d\n", incfsMetrics.value().readsDelayedPending); dprintf(fd, " readsDelayedPendingUs: %lld\n", (long long)incfsMetrics.value().readsDelayedPendingUs); dprintf(fd, " readsFailedHashVerification: %d\n", incfsMetrics.value().readsFailedHashVerification); dprintf(fd, " readsFailedOther: %d\n", incfsMetrics.value().readsFailedOther); dprintf(fd, " readsFailedTimedOut: %d\n", incfsMetrics.value().readsFailedTimedOut); } else { dprintf(fd, " Metrics not available. Errno: %d\n", errno); } dprintf(fd, " }\n"); const auto lastReadError = mIncFs->getLastReadError(ifs->control); const auto errorNo = errno; dprintf(fd, " lastReadError: {\n"); if (lastReadError) { if (lastReadError->timestampUs == 0) { dprintf(fd, " No read errors.\n"); } else { dprintf(fd, " fileId: %s\n", IncFsWrapper::toString(lastReadError->id).c_str()); dprintf(fd, " time: %llu microseconds ago\n", (unsigned long long)elapsedUsSinceMonoTs(lastReadError->timestampUs)); dprintf(fd, " blockIndex: %d\n", lastReadError->block); dprintf(fd, " errno: %d\n", lastReadError->errorNo); } } else { dprintf(fd, " Info not available. Errno: %d\n", errorNo); } dprintf(fd, " }\n"); } dprintf(fd, " }\n"); } dprintf(fd, "}\n"); dprintf(fd, "Sorted binds (%d): {\n", int(mBindsByPath.size())); for (auto&& [target, mountPairIt] : mBindsByPath) { const auto& bind = mountPairIt->second; dprintf(fd, " [%s]->[%d]:\n", target.c_str(), bind.storage); dprintf(fd, " savedFilename: %s\n", bind.savedFilename.c_str()); dprintf(fd, " sourceDir: %s\n", bind.sourceDir.c_str()); dprintf(fd, " kind: %s\n", toString(bind.kind)); } dprintf(fd, "}\n"); } bool IncrementalService::needStartDataLoaderLocked(IncFsMount& ifs) { if (!ifs.dataLoaderStub) { return false; } if (ifs.dataLoaderStub->isSystemDataLoader()) { return true; } return mIncFs->isEverythingFullyLoaded(ifs.control) == incfs::LoadingState::MissingBlocks; } void IncrementalService::onSystemReady() { if (mSystemReady.exchange(true)) { return; } std::vector mounts; { std::lock_guard l(mLock); mounts.reserve(mMounts.size()); for (auto&& [id, ifs] : mMounts) { std::unique_lock ll(ifs->lock); if (ifs->mountId != id) { continue; } if (needStartDataLoaderLocked(*ifs)) { mounts.push_back(ifs); } } } if (mounts.empty()) { return; } std::thread([this, mounts = std::move(mounts)]() { mJni->initializeForCurrentThread(); for (auto&& ifs : mounts) { std::unique_lock l(ifs->lock); if (ifs->dataLoaderStub) { ifs->dataLoaderStub->requestStart(); } } }).detach(); } auto IncrementalService::getStorageSlotLocked() -> MountMap::iterator { for (;;) { if (mNextId == kMaxStorageId) { mNextId = 0; } auto id = ++mNextId; auto [it, inserted] = mMounts.try_emplace(id, nullptr); if (inserted) { return it; } } } StorageId IncrementalService::createStorage(std::string_view mountPoint, content::pm::DataLoaderParamsParcel dataLoaderParams, CreateOptions options) { LOG(INFO) << "createStorage: " << mountPoint << " | " << int(options); if (!path::isAbsolute(mountPoint)) { LOG(ERROR) << "path is not absolute: " << mountPoint; return kInvalidStorageId; } auto mountNorm = path::normalize(mountPoint); { const auto id = findStorageId(mountNorm); if (id != kInvalidStorageId) { if (options & CreateOptions::OpenExisting) { LOG(INFO) << "Opened existing storage " << id; return id; } LOG(ERROR) << "Directory " << mountPoint << " is already mounted at storage " << id; return kInvalidStorageId; } } if (!(options & CreateOptions::CreateNew)) { LOG(ERROR) << "not requirested create new storage, and it doesn't exist: " << mountPoint; return kInvalidStorageId; } if (!path::isEmptyDir(mountNorm)) { LOG(ERROR) << "Mounting over existing non-empty directory is not supported: " << mountNorm; return kInvalidStorageId; } auto [mountKey, mountRoot] = makeMountDir(mIncrementalDir, mountNorm); if (mountRoot.empty()) { LOG(ERROR) << "Bad mount point"; return kInvalidStorageId; } // Make sure the code removes all crap it may create while still failing. auto firstCleanup = [](const std::string* ptr) { IncFsMount::cleanupFilesystem(*ptr); }; auto firstCleanupOnFailure = std::unique_ptr(&mountRoot, firstCleanup); auto mountTarget = path::join(mountRoot, constants().mount); const auto backing = path::join(mountRoot, constants().backing); if (!mkdirOrLog(backing, 0777) || !mkdirOrLog(mountTarget)) { return kInvalidStorageId; } std::string metricsKey; IncFsMount::Control control; { std::lock_guard l(mMountOperationLock); IncrementalFileSystemControlParcel controlParcel; if (auto err = rmDirContent(backing.c_str())) { LOG(ERROR) << "Coudn't clean the backing directory " << backing << ": " << err; return kInvalidStorageId; } if (!mkdirOrLog(path::join(backing, ".index"), 0777)) { return kInvalidStorageId; } if (!mkdirOrLog(path::join(backing, ".incomplete"), 0777)) { return kInvalidStorageId; } metricsKey = makeUniqueName(mountKey); auto status = mVold->mountIncFs(backing, mountTarget, 0, metricsKey, &controlParcel); if (!status.isOk()) { LOG(ERROR) << "Vold::mountIncFs() failed: " << status.toString8(); return kInvalidStorageId; } if (controlParcel.cmd.get() < 0 || controlParcel.pendingReads.get() < 0 || controlParcel.log.get() < 0) { LOG(ERROR) << "Vold::mountIncFs() returned invalid control parcel."; return kInvalidStorageId; } int cmd = controlParcel.cmd.release().release(); int pendingReads = controlParcel.pendingReads.release().release(); int logs = controlParcel.log.release().release(); int blocksWritten = controlParcel.blocksWritten ? controlParcel.blocksWritten->release().release() : -1; control = mIncFs->createControl(cmd, pendingReads, logs, blocksWritten); } std::unique_lock l(mLock); const auto mountIt = getStorageSlotLocked(); const auto mountId = mountIt->first; l.unlock(); auto ifs = std::make_shared(std::move(mountRoot), std::move(metricsKey), mountId, std::move(control), *this); // Now it's the |ifs|'s responsibility to clean up after itself, and the only cleanup we need // is the removal of the |ifs|. (void)firstCleanupOnFailure.release(); auto secondCleanup = [this, &l](auto itPtr) { if (!l.owns_lock()) { l.lock(); } mMounts.erase(*itPtr); }; auto secondCleanupOnFailure = std::unique_ptr(&mountIt, secondCleanup); const auto storageIt = ifs->makeStorage(ifs->mountId); if (storageIt == ifs->storages.end()) { LOG(ERROR) << "Can't create a default storage directory"; return kInvalidStorageId; } { metadata::Mount m; m.mutable_storage()->set_id(ifs->mountId); m.mutable_loader()->set_type((int)dataLoaderParams.type); m.mutable_loader()->set_package_name(std::move(dataLoaderParams.packageName)); m.mutable_loader()->set_class_name(std::move(dataLoaderParams.className)); m.mutable_loader()->set_arguments(std::move(dataLoaderParams.arguments)); const auto metadata = m.SerializeAsString(); if (auto err = mIncFs->makeFile(ifs->control, path::join(ifs->root, constants().mount, constants().infoMdName), 0777, idFromMetadata(metadata), {.metadata = {metadata.data(), (IncFsSize)metadata.size()}})) { LOG(ERROR) << "Saving mount metadata failed: " << -err; return kInvalidStorageId; } } const auto bk = (options & CreateOptions::PermanentBind) ? BindKind::Permanent : BindKind::Temporary; if (auto err = addBindMount(*ifs, storageIt->first, storageIt->second.name, std::string(storageIt->second.name), std::move(mountNorm), bk, l); err < 0) { LOG(ERROR) << "Adding bind mount failed: " << -err; return kInvalidStorageId; } // Done here as well, all data structures are in good state. (void)secondCleanupOnFailure.release(); mountIt->second = std::move(ifs); l.unlock(); LOG(INFO) << "created storage " << mountId; return mountId; } StorageId IncrementalService::createLinkedStorage(std::string_view mountPoint, StorageId linkedStorage, IncrementalService::CreateOptions options) { if (!isValidMountTarget(mountPoint)) { LOG(ERROR) << "Mount point is invalid or missing"; return kInvalidStorageId; } std::unique_lock l(mLock); auto ifs = getIfsLocked(linkedStorage); if (!ifs) { LOG(ERROR) << "Ifs unavailable"; return kInvalidStorageId; } const auto mountIt = getStorageSlotLocked(); const auto storageId = mountIt->first; const auto storageIt = ifs->makeStorage(storageId); if (storageIt == ifs->storages.end()) { LOG(ERROR) << "Can't create a new storage"; mMounts.erase(mountIt); return kInvalidStorageId; } l.unlock(); const auto bk = (options & CreateOptions::PermanentBind) ? BindKind::Permanent : BindKind::Temporary; if (auto err = addBindMount(*ifs, storageIt->first, storageIt->second.name, std::string(storageIt->second.name), path::normalize(mountPoint), bk, l); err < 0) { LOG(ERROR) << "bindMount failed with error: " << err; (void)mIncFs->unlink(ifs->control, storageIt->second.name); ifs->storages.erase(storageIt); return kInvalidStorageId; } mountIt->second = ifs; return storageId; } bool IncrementalService::startLoading(StorageId storageId, content::pm::DataLoaderParamsParcel dataLoaderParams, DataLoaderStatusListener statusListener, const StorageHealthCheckParams& healthCheckParams, StorageHealthListener healthListener, std::vector perUidReadTimeouts) { // Per Uid timeouts. if (!perUidReadTimeouts.empty()) { setUidReadTimeouts(storageId, std::move(perUidReadTimeouts)); } IfsMountPtr ifs; DataLoaderStubPtr dataLoaderStub; // Re-initialize DataLoader. { ifs = getIfs(storageId); if (!ifs) { return false; } std::unique_lock l(ifs->lock); dataLoaderStub = std::exchange(ifs->dataLoaderStub, nullptr); } if (dataLoaderStub) { dataLoaderStub->cleanupResources(); dataLoaderStub = {}; } { std::unique_lock l(ifs->lock); if (ifs->dataLoaderStub) { LOG(INFO) << "Skipped data loader stub creation because it already exists"; return false; } prepareDataLoaderLocked(*ifs, std::move(dataLoaderParams), std::move(statusListener), healthCheckParams, std::move(healthListener)); CHECK(ifs->dataLoaderStub); dataLoaderStub = ifs->dataLoaderStub; // Disable long read timeouts for non-system dataloaders. // To be re-enabled after installation is complete. ifs->setReadTimeoutsRequested(dataLoaderStub->isSystemDataLoader() && getAlwaysEnableReadTimeoutsForSystemDataLoaders()); applyStorageParamsLocked(*ifs); } if (dataLoaderStub->isSystemDataLoader() && !getEnforceReadLogsMaxIntervalForSystemDataLoaders()) { // Readlogs from system dataloader (adb) can always be collected. ifs->startLoadingTs = TimePoint::max(); } else { // Assign time when installation wants the DL to start streaming. const auto startLoadingTs = mClock->now(); ifs->startLoadingTs = startLoadingTs; // Setup a callback to disable the readlogs after max interval. addTimedJob(*mTimedQueue, storageId, getReadLogsMaxInterval(), [this, storageId, startLoadingTs]() { const auto ifs = getIfs(storageId); if (!ifs) { LOG(WARNING) << "Can't disable the readlogs, invalid storageId: " << storageId; return; } std::unique_lock l(ifs->lock); if (ifs->startLoadingTs != startLoadingTs) { LOG(INFO) << "Can't disable the readlogs, timestamp mismatch (new " "installation?): " << storageId; return; } disableReadLogsLocked(*ifs); }); } return dataLoaderStub->requestStart(); } void IncrementalService::onInstallationComplete(StorageId storage) { IfsMountPtr ifs = getIfs(storage); if (!ifs) { return; } // Always enable long read timeouts after installation is complete. std::unique_lock l(ifs->lock); ifs->setReadTimeoutsRequested(getEnableReadTimeoutsAfterInstall()); applyStorageParamsLocked(*ifs); } IncrementalService::BindPathMap::const_iterator IncrementalService::findStorageLocked( std::string_view path) const { return findParentPath(mBindsByPath, path); } StorageId IncrementalService::findStorageId(std::string_view path) const { std::lock_guard l(mLock); auto it = findStorageLocked(path); if (it == mBindsByPath.end()) { return kInvalidStorageId; } return it->second->second.storage; } void IncrementalService::disallowReadLogs(StorageId storageId) { const auto ifs = getIfs(storageId); if (!ifs) { LOG(ERROR) << "disallowReadLogs failed, invalid storageId: " << storageId; return; } std::unique_lock l(ifs->lock); if (!ifs->readLogsAllowed()) { return; } ifs->disallowReadLogs(); const auto metadata = constants().readLogsDisabledMarkerName; if (auto err = mIncFs->makeFile(ifs->control, path::join(ifs->root, constants().mount, constants().readLogsDisabledMarkerName), 0777, idFromMetadata(metadata), {})) { //{.metadata = {metadata.data(), (IncFsSize)metadata.size()}})) { LOG(ERROR) << "Failed to make marker file for storageId: " << storageId << " err: " << -err; return; } disableReadLogsLocked(*ifs); } int IncrementalService::setStorageParams(StorageId storageId, bool enableReadLogs) { const auto ifs = getIfs(storageId); if (!ifs) { LOG(ERROR) << "setStorageParams failed, invalid storageId: " << storageId; return -EINVAL; } std::string packageName; { std::unique_lock l(ifs->lock); if (!enableReadLogs) { return disableReadLogsLocked(*ifs); } if (!ifs->readLogsAllowed()) { LOG(ERROR) << "enableReadLogs failed, readlogs disallowed for storageId: " << storageId; return -EPERM; } if (!ifs->dataLoaderStub) { // This should never happen - only DL can call enableReadLogs. LOG(ERROR) << "enableReadLogs failed: invalid state"; return -EPERM; } // Check installation time. const auto now = mClock->now(); const auto startLoadingTs = ifs->startLoadingTs; if (startLoadingTs <= now && now - startLoadingTs > getReadLogsMaxInterval()) { LOG(ERROR) << "enableReadLogs failed, readlogs can't be enabled at this time, storageId: " << storageId; return -EPERM; } packageName = ifs->dataLoaderStub->params().packageName; ifs->setReadLogsRequested(true); } // Check loader usage stats permission and apop. if (auto status = mAppOpsManager->checkPermission(kLoaderUsageStats, kOpUsage, packageName.c_str()); !status.isOk()) { LOG(ERROR) << " Permission: " << kLoaderUsageStats << " check failed: " << status.toString8(); return fromBinderStatus(status); } // Check multiuser permission. if (auto status = mAppOpsManager->checkPermission(kInteractAcrossUsers, nullptr, packageName.c_str()); !status.isOk()) { LOG(ERROR) << " Permission: " << kInteractAcrossUsers << " check failed: " << status.toString8(); return fromBinderStatus(status); } { std::unique_lock l(ifs->lock); if (!ifs->readLogsRequested()) { return 0; } if (auto status = applyStorageParamsLocked(*ifs); status != 0) { return status; } } registerAppOpsCallback(packageName); return 0; } int IncrementalService::disableReadLogsLocked(IncFsMount& ifs) { ifs.setReadLogsRequested(false); return applyStorageParamsLocked(ifs); } int IncrementalService::applyStorageParamsLocked(IncFsMount& ifs) { os::incremental::IncrementalFileSystemControlParcel control; control.cmd.reset(dup(ifs.control.cmd())); control.pendingReads.reset(dup(ifs.control.pendingReads())); auto logsFd = ifs.control.logs(); if (logsFd >= 0) { control.log.reset(dup(logsFd)); } bool enableReadLogs = ifs.readLogsRequested(); bool enableReadTimeouts = ifs.readTimeoutsRequested(); std::lock_guard l(mMountOperationLock); auto status = mVold->setIncFsMountOptions(control, enableReadLogs, enableReadTimeouts, ifs.metricsKey); if (status.isOk()) { // Store states. ifs.setReadLogsEnabled(enableReadLogs); ifs.setReadTimeoutsEnabled(enableReadTimeouts); } else { LOG(ERROR) << "applyStorageParams failed: " << status.toString8(); } return status.isOk() ? 0 : fromBinderStatus(status); } void IncrementalService::deleteStorage(StorageId storageId) { const auto ifs = getIfs(storageId); if (!ifs) { return; } deleteStorage(*ifs); } void IncrementalService::deleteStorage(IncrementalService::IncFsMount& ifs) { std::unique_lock l(ifs.lock); deleteStorageLocked(ifs, std::move(l)); } void IncrementalService::deleteStorageLocked(IncrementalService::IncFsMount& ifs, std::unique_lock&& ifsLock) { const auto storages = std::move(ifs.storages); // Don't move the bind points out: Ifs's dtor will use them to unmount everything. const auto bindPoints = ifs.bindPoints; ifsLock.unlock(); std::lock_guard l(mLock); for (auto&& [id, _] : storages) { if (id != ifs.mountId) { mMounts.erase(id); } } for (auto&& [path, _] : bindPoints) { mBindsByPath.erase(path); } mMounts.erase(ifs.mountId); } StorageId IncrementalService::openStorage(std::string_view pathInMount) { if (!path::isAbsolute(pathInMount)) { return kInvalidStorageId; } return findStorageId(path::normalize(pathInMount)); } IncrementalService::IfsMountPtr IncrementalService::getIfs(StorageId storage) const { std::lock_guard l(mLock); return getIfsLocked(storage); } const IncrementalService::IfsMountPtr& IncrementalService::getIfsLocked(StorageId storage) const { auto it = mMounts.find(storage); if (it == mMounts.end()) { static const base::NoDestructor kEmpty{}; return *kEmpty; } return it->second; } int IncrementalService::bind(StorageId storage, std::string_view source, std::string_view target, BindKind kind) { if (!isValidMountTarget(target)) { LOG(ERROR) << __func__ << ": not a valid bind target " << target; return -EINVAL; } const auto ifs = getIfs(storage); if (!ifs) { LOG(ERROR) << __func__ << ": no ifs object for storage " << storage; return -EINVAL; } std::unique_lock l(ifs->lock); const auto storageInfo = ifs->storages.find(storage); if (storageInfo == ifs->storages.end()) { LOG(ERROR) << "no storage"; return -EINVAL; } std::string normSource = normalizePathToStorageLocked(*ifs, storageInfo, source); if (normSource.empty()) { LOG(ERROR) << "invalid source path"; return -EINVAL; } l.unlock(); std::unique_lock l2(mLock, std::defer_lock); return addBindMount(*ifs, storage, storageInfo->second.name, std::move(normSource), path::normalize(target), kind, l2); } int IncrementalService::unbind(StorageId storage, std::string_view target) { if (!path::isAbsolute(target)) { return -EINVAL; } LOG(INFO) << "Removing bind point " << target << " for storage " << storage; // Here we should only look up by the exact target, not by a subdirectory of any existing mount, // otherwise there's a chance to unmount something completely unrelated const auto norm = path::normalize(target); std::unique_lock l(mLock); const auto storageIt = mBindsByPath.find(norm); if (storageIt == mBindsByPath.end() || storageIt->second->second.storage != storage) { return -EINVAL; } const auto bindIt = storageIt->second; const auto storageId = bindIt->second.storage; const auto ifs = getIfsLocked(storageId); if (!ifs) { LOG(ERROR) << "Internal error: storageId " << storageId << " for bound path " << target << " is missing"; return -EFAULT; } mBindsByPath.erase(storageIt); l.unlock(); mVold->unmountIncFs(bindIt->first); std::unique_lock l2(ifs->lock); if (ifs->bindPoints.size() <= 1) { ifs->bindPoints.clear(); deleteStorageLocked(*ifs, std::move(l2)); } else { const std::string savedFile = std::move(bindIt->second.savedFilename); ifs->bindPoints.erase(bindIt); l2.unlock(); if (!savedFile.empty()) { mIncFs->unlink(ifs->control, path::join(ifs->root, constants().mount, savedFile)); } } return 0; } std::string IncrementalService::normalizePathToStorageLocked( const IncFsMount& incfs, IncFsMount::StorageMap::const_iterator storageIt, std::string_view path) const { if (!path::isAbsolute(path)) { return path::normalize(path::join(storageIt->second.name, path)); } auto normPath = path::normalize(path); if (path::startsWith(normPath, storageIt->second.name)) { return normPath; } // not that easy: need to find if any of the bind points match const auto bindIt = findParentPath(incfs.bindPoints, normPath); if (bindIt == incfs.bindPoints.end()) { return {}; } return path::join(bindIt->second.sourceDir, path::relativize(bindIt->first, normPath)); } std::string IncrementalService::normalizePathToStorage(const IncFsMount& ifs, StorageId storage, std::string_view path) const { std::unique_lock l(ifs.lock); const auto storageInfo = ifs.storages.find(storage); if (storageInfo == ifs.storages.end()) { return {}; } return normalizePathToStorageLocked(ifs, storageInfo, path); } int IncrementalService::makeFile(StorageId storage, std::string_view path, int mode, FileId id, incfs::NewFileParams params, std::span data) { const auto ifs = getIfs(storage); if (!ifs) { return -EINVAL; } if ((IncFsSize)data.size() > params.size) { LOG(ERROR) << "Bad data size - bigger than file size"; return -EINVAL; } if (!data.empty() && (IncFsSize)data.size() != params.size) { // Writing a page is an irreversible operation, and it can't be updated with additional // data later. Check that the last written page is complete, or we may break the file. if (!isPageAligned(data.size())) { LOG(ERROR) << "Bad data size - tried to write half a page?"; return -EINVAL; } } const std::string normPath = normalizePathToStorage(*ifs, storage, path); if (normPath.empty()) { LOG(ERROR) << "Internal error: storageId " << storage << " failed to normalize: " << path; return -EINVAL; } if (auto err = mIncFs->makeFile(ifs->control, normPath, mode, id, params); err) { LOG(ERROR) << "Internal error: storageId " << storage << " failed to makeFile [" << normPath << "]: " << err; return err; } if (params.size > 0) { if (auto err = mIncFs->reserveSpace(ifs->control, id, params.size)) { if (err != -EOPNOTSUPP) { LOG(ERROR) << "Failed to reserve space for a new file: " << err; (void)mIncFs->unlink(ifs->control, normPath); return err; } else { LOG(WARNING) << "Reserving space for backing file isn't supported, " "may run out of disk later"; } } if (!data.empty()) { if (auto err = setFileContent(ifs, id, path, data); err) { (void)mIncFs->unlink(ifs->control, normPath); return err; } } } return 0; } int IncrementalService::makeDir(StorageId storageId, std::string_view path, int mode) { if (auto ifs = getIfs(storageId)) { std::string normPath = normalizePathToStorage(*ifs, storageId, path); if (normPath.empty()) { return -EINVAL; } return mIncFs->makeDir(ifs->control, normPath, mode); } return -EINVAL; } int IncrementalService::makeDirs(StorageId storageId, std::string_view path, int mode) { const auto ifs = getIfs(storageId); if (!ifs) { return -EINVAL; } return makeDirs(*ifs, storageId, path, mode); } int IncrementalService::makeDirs(const IncFsMount& ifs, StorageId storageId, std::string_view path, int mode) { std::string normPath = normalizePathToStorage(ifs, storageId, path); if (normPath.empty()) { return -EINVAL; } return mIncFs->makeDirs(ifs.control, normPath, mode); } int IncrementalService::link(StorageId sourceStorageId, std::string_view oldPath, StorageId destStorageId, std::string_view newPath) { std::unique_lock l(mLock); auto ifsSrc = getIfsLocked(sourceStorageId); if (!ifsSrc) { return -EINVAL; } if (sourceStorageId != destStorageId && getIfsLocked(destStorageId) != ifsSrc) { return -EINVAL; } l.unlock(); std::string normOldPath = normalizePathToStorage(*ifsSrc, sourceStorageId, oldPath); std::string normNewPath = normalizePathToStorage(*ifsSrc, destStorageId, newPath); if (normOldPath.empty() || normNewPath.empty()) { LOG(ERROR) << "Invalid paths in link(): " << normOldPath << " | " << normNewPath; return -EINVAL; } if (auto err = mIncFs->link(ifsSrc->control, normOldPath, normNewPath); err < 0) { PLOG(ERROR) << "Failed to link " << oldPath << "[" << normOldPath << "]" << " to " << newPath << "[" << normNewPath << "]"; return err; } return 0; } int IncrementalService::unlink(StorageId storage, std::string_view path) { if (auto ifs = getIfs(storage)) { std::string normOldPath = normalizePathToStorage(*ifs, storage, path); return mIncFs->unlink(ifs->control, normOldPath); } return -EINVAL; } int IncrementalService::addBindMount(IncFsMount& ifs, StorageId storage, std::string_view storageRoot, std::string&& source, std::string&& target, BindKind kind, std::unique_lock& mainLock) { if (!isValidMountTarget(target)) { LOG(ERROR) << __func__ << ": invalid mount target " << target; return -EINVAL; } std::string mdFileName; std::string metadataFullPath; if (kind != BindKind::Temporary) { metadata::BindPoint bp; bp.set_storage_id(storage); bp.set_allocated_dest_path(&target); bp.set_allocated_source_subdir(&source); const auto metadata = bp.SerializeAsString(); static_cast(bp.release_dest_path()); static_cast(bp.release_source_subdir()); mdFileName = makeBindMdName(); metadataFullPath = path::join(ifs.root, constants().mount, mdFileName); auto node = mIncFs->makeFile(ifs.control, metadataFullPath, 0444, idFromMetadata(metadata), {.metadata = {metadata.data(), (IncFsSize)metadata.size()}}); if (node) { LOG(ERROR) << __func__ << ": couldn't create a mount node " << mdFileName; return int(node); } } const auto res = addBindMountWithMd(ifs, storage, std::move(mdFileName), std::move(source), std::move(target), kind, mainLock); if (res) { mIncFs->unlink(ifs.control, metadataFullPath); } return res; } int IncrementalService::addBindMountWithMd(IncrementalService::IncFsMount& ifs, StorageId storage, std::string&& metadataName, std::string&& source, std::string&& target, BindKind kind, std::unique_lock& mainLock) { { std::lock_guard l(mMountOperationLock); const auto status = mVold->bindMount(source, target); if (!status.isOk()) { LOG(ERROR) << "Calling Vold::bindMount() failed: " << status.toString8(); return status.exceptionCode() == binder::Status::EX_SERVICE_SPECIFIC ? status.serviceSpecificErrorCode() > 0 ? -status.serviceSpecificErrorCode() : status.serviceSpecificErrorCode() == 0 ? -EFAULT : status.serviceSpecificErrorCode() : -EIO; } } if (!mainLock.owns_lock()) { mainLock.lock(); } std::lock_guard l(ifs.lock); addBindMountRecordLocked(ifs, storage, std::move(metadataName), std::move(source), std::move(target), kind); return 0; } void IncrementalService::addBindMountRecordLocked(IncFsMount& ifs, StorageId storage, std::string&& metadataName, std::string&& source, std::string&& target, BindKind kind) { const auto [it, _] = ifs.bindPoints.insert_or_assign(target, IncFsMount::Bind{storage, std::move(metadataName), std::move(source), kind}); mBindsByPath[std::move(target)] = it; } RawMetadata IncrementalService::getMetadata(StorageId storage, std::string_view path) const { const auto ifs = getIfs(storage); if (!ifs) { return {}; } const auto normPath = normalizePathToStorage(*ifs, storage, path); if (normPath.empty()) { return {}; } return mIncFs->getMetadata(ifs->control, normPath); } RawMetadata IncrementalService::getMetadata(StorageId storage, FileId node) const { const auto ifs = getIfs(storage); if (!ifs) { return {}; } return mIncFs->getMetadata(ifs->control, node); } void IncrementalService::setUidReadTimeouts(StorageId storage, std::vector&& perUidReadTimeouts) { using microseconds = std::chrono::microseconds; using milliseconds = std::chrono::milliseconds; auto maxPendingTimeUs = microseconds(0); for (const auto& timeouts : perUidReadTimeouts) { maxPendingTimeUs = std::max(maxPendingTimeUs, microseconds(timeouts.maxPendingTimeUs)); } if (maxPendingTimeUs < Constants::minPerUidTimeout) { LOG(ERROR) << "Skip setting read timeouts (maxPendingTime < Constants::minPerUidTimeout): " << duration_cast(maxPendingTimeUs).count() << "ms < " << Constants::minPerUidTimeout.count() << "ms"; return; } const auto ifs = getIfs(storage); if (!ifs) { LOG(ERROR) << "Setting read timeouts failed: invalid storage id: " << storage; return; } if (auto err = mIncFs->setUidReadTimeouts(ifs->control, perUidReadTimeouts); err < 0) { LOG(ERROR) << "Setting read timeouts failed: " << -err; return; } const auto timeout = Clock::now() + maxPendingTimeUs - Constants::perUidTimeoutOffset; addIfsStateCallback(storage, [this, timeout](StorageId storageId, IfsState state) -> bool { if (checkUidReadTimeouts(storageId, state, timeout)) { return true; } clearUidReadTimeouts(storageId); return false; }); } void IncrementalService::clearUidReadTimeouts(StorageId storage) { const auto ifs = getIfs(storage); if (!ifs) { return; } mIncFs->setUidReadTimeouts(ifs->control, {}); } bool IncrementalService::checkUidReadTimeouts(StorageId storage, IfsState state, Clock::time_point timeLimit) { if (Clock::now() >= timeLimit) { // Reached maximum timeout. return false; } if (state.error) { // Something is wrong, abort. return false; } // Still loading? if (state.fullyLoaded && !state.readLogsEnabled) { return false; } const auto timeLeft = timeLimit - Clock::now(); if (timeLeft < Constants::progressUpdateInterval) { // Don't bother. return false; } return true; } std::unordered_set IncrementalService::adoptMountedInstances() { std::unordered_set mountedRootNames; mIncFs->listExistingMounts([this, &mountedRootNames](auto root, auto backingDir, auto binds) { LOG(INFO) << "Existing mount: " << backingDir << "->" << root; for (auto [source, target] : binds) { LOG(INFO) << " bind: '" << source << "'->'" << target << "'"; LOG(INFO) << " " << path::join(root, source); } // Ensure it's a kind of a mount that's managed by IncrementalService if (path::basename(root) != constants().mount || path::basename(backingDir) != constants().backing) { return; } const auto expectedRoot = path::dirname(root); if (path::dirname(backingDir) != expectedRoot) { return; } if (path::dirname(expectedRoot) != mIncrementalDir) { return; } if (!path::basename(expectedRoot).starts_with(constants().mountKeyPrefix)) { return; } LOG(INFO) << "Looks like an IncrementalService-owned: " << expectedRoot; // make sure we clean up the mount if it happens to be a bad one. // Note: unmounting needs to run first, so the cleanup object is created _last_. auto cleanupFiles = makeCleanup([&]() { LOG(INFO) << "Failed to adopt existing mount, deleting files: " << expectedRoot; IncFsMount::cleanupFilesystem(expectedRoot); }); auto cleanupMounts = makeCleanup([&]() { LOG(INFO) << "Failed to adopt existing mount, cleaning up: " << expectedRoot; for (auto&& [_, target] : binds) { mVold->unmountIncFs(std::string(target)); } mVold->unmountIncFs(std::string(root)); }); auto control = mIncFs->openMount(root); if (!control) { LOG(INFO) << "failed to open mount " << root; return; } auto mountRecord = parseFromIncfs(mIncFs.get(), control, path::join(root, constants().infoMdName)); if (!mountRecord.has_loader() || !mountRecord.has_storage()) { LOG(ERROR) << "Bad mount metadata in mount at " << expectedRoot; return; } auto mountId = mountRecord.storage().id(); mNextId = std::max(mNextId, mountId + 1); DataLoaderParamsParcel dataLoaderParams; { const auto& loader = mountRecord.loader(); dataLoaderParams.type = (content::pm::DataLoaderType)loader.type(); dataLoaderParams.packageName = loader.package_name(); dataLoaderParams.className = loader.class_name(); dataLoaderParams.arguments = loader.arguments(); } // Not way to obtain a real sysfs key at this point - metrics will stop working after "soft" // reboot. std::string metricsKey{}; auto ifs = std::make_shared(std::string(expectedRoot), std::move(metricsKey), mountId, std::move(control), *this); (void)cleanupFiles.release(); // ifs will take care of that now // Check if marker file present. if (checkReadLogsDisabledMarker(root)) { ifs->disallowReadLogs(); } std::vector> permanentBindPoints; auto d = openDir(root); while (auto e = ::readdir(d.get())) { if (e->d_type == DT_REG) { auto name = std::string_view(e->d_name); if (name.starts_with(constants().mountpointMdPrefix)) { permanentBindPoints .emplace_back(name, parseFromIncfs(mIncFs.get(), ifs->control, path::join(root, name))); if (permanentBindPoints.back().second.dest_path().empty() || permanentBindPoints.back().second.source_subdir().empty()) { permanentBindPoints.pop_back(); mIncFs->unlink(ifs->control, path::join(root, name)); } else { LOG(INFO) << "Permanent bind record: '" << permanentBindPoints.back().second.source_subdir() << "'->'" << permanentBindPoints.back().second.dest_path() << "'"; } } } else if (e->d_type == DT_DIR) { if (e->d_name == "."sv || e->d_name == ".."sv) { continue; } auto name = std::string_view(e->d_name); if (name.starts_with(constants().storagePrefix)) { int storageId; const auto res = std::from_chars(name.data() + constants().storagePrefix.size() + 1, name.data() + name.size(), storageId); if (res.ec != std::errc{} || *res.ptr != '_') { LOG(WARNING) << "Ignoring storage with invalid name '" << name << "' for mount " << expectedRoot; continue; } auto [_, inserted] = mMounts.try_emplace(storageId, ifs); if (!inserted) { LOG(WARNING) << "Ignoring storage with duplicate id " << storageId << " for mount " << expectedRoot; continue; } ifs->storages.insert_or_assign(storageId, IncFsMount::Storage{path::join(root, name)}); mNextId = std::max(mNextId, storageId + 1); } } } if (ifs->storages.empty()) { LOG(WARNING) << "No valid storages in mount " << root; return; } // now match the mounted directories with what we expect to have in the metadata { std::unique_lock l(mLock, std::defer_lock); for (auto&& [metadataFile, bindRecord] : permanentBindPoints) { auto mountedIt = std::find_if(binds.begin(), binds.end(), [&, bindRecord = bindRecord](auto&& bind) { return bind.second == bindRecord.dest_path() && path::join(root, bind.first) == bindRecord.source_subdir(); }); if (mountedIt != binds.end()) { LOG(INFO) << "Matched permanent bound " << bindRecord.source_subdir() << " to mount " << mountedIt->first; addBindMountRecordLocked(*ifs, bindRecord.storage_id(), std::move(metadataFile), std::move(*bindRecord.mutable_source_subdir()), std::move(*bindRecord.mutable_dest_path()), BindKind::Permanent); if (mountedIt != binds.end() - 1) { std::iter_swap(mountedIt, binds.end() - 1); } binds = binds.first(binds.size() - 1); } else { LOG(INFO) << "Didn't match permanent bound " << bindRecord.source_subdir() << ", mounting"; // doesn't exist - try mounting back if (addBindMountWithMd(*ifs, bindRecord.storage_id(), std::move(metadataFile), std::move(*bindRecord.mutable_source_subdir()), std::move(*bindRecord.mutable_dest_path()), BindKind::Permanent, l)) { mIncFs->unlink(ifs->control, metadataFile); } } } } // if anything stays in |binds| those are probably temporary binds; system restarted since // they were mounted - so let's unmount them all. for (auto&& [source, target] : binds) { if (source.empty()) { continue; } mVold->unmountIncFs(std::string(target)); } (void)cleanupMounts.release(); // ifs now manages everything if (ifs->bindPoints.empty()) { LOG(WARNING) << "No valid bind points for mount " << expectedRoot; deleteStorage(*ifs); return; } prepareDataLoaderLocked(*ifs, std::move(dataLoaderParams)); CHECK(ifs->dataLoaderStub); mountedRootNames.insert(path::basename(ifs->root)); // not locking here at all: we're still in the constructor, no other calls can happen mMounts[ifs->mountId] = std::move(ifs); }); return mountedRootNames; } void IncrementalService::mountExistingImages( const std::unordered_set& mountedRootNames) { auto dir = openDir(mIncrementalDir); if (!dir) { PLOG(WARNING) << "Couldn't open the root incremental dir " << mIncrementalDir; return; } while (auto entry = ::readdir(dir.get())) { if (entry->d_type != DT_DIR) { continue; } std::string_view name = entry->d_name; if (!name.starts_with(constants().mountKeyPrefix)) { continue; } if (mountedRootNames.find(name) != mountedRootNames.end()) { continue; } const auto root = path::join(mIncrementalDir, name); if (!mountExistingImage(root)) { IncFsMount::cleanupFilesystem(root); } } } bool IncrementalService::mountExistingImage(std::string_view root) { auto mountTarget = path::join(root, constants().mount); const auto backing = path::join(root, constants().backing); std::string mountKey(path::basename(path::dirname(mountTarget))); IncrementalFileSystemControlParcel controlParcel; auto metricsKey = makeUniqueName(mountKey); auto status = mVold->mountIncFs(backing, mountTarget, 0, metricsKey, &controlParcel); if (!status.isOk()) { LOG(ERROR) << "Vold::mountIncFs() failed: " << status.toString8(); return false; } int cmd = controlParcel.cmd.release().release(); int pendingReads = controlParcel.pendingReads.release().release(); int logs = controlParcel.log.release().release(); int blocksWritten = controlParcel.blocksWritten ? controlParcel.blocksWritten->release().release() : -1; IncFsMount::Control control = mIncFs->createControl(cmd, pendingReads, logs, blocksWritten); auto ifs = std::make_shared(std::string(root), std::move(metricsKey), -1, std::move(control), *this); auto mount = parseFromIncfs(mIncFs.get(), ifs->control, path::join(mountTarget, constants().infoMdName)); if (!mount.has_loader() || !mount.has_storage()) { LOG(ERROR) << "Bad mount metadata in mount at " << root; return false; } ifs->mountId = mount.storage().id(); mNextId = std::max(mNextId, ifs->mountId + 1); // Check if marker file present. if (checkReadLogsDisabledMarker(mountTarget)) { ifs->disallowReadLogs(); } // DataLoader params DataLoaderParamsParcel dataLoaderParams; { const auto& loader = mount.loader(); dataLoaderParams.type = (content::pm::DataLoaderType)loader.type(); dataLoaderParams.packageName = loader.package_name(); dataLoaderParams.className = loader.class_name(); dataLoaderParams.arguments = loader.arguments(); } prepareDataLoaderLocked(*ifs, std::move(dataLoaderParams)); CHECK(ifs->dataLoaderStub); std::vector> bindPoints; auto d = openDir(mountTarget); while (auto e = ::readdir(d.get())) { if (e->d_type == DT_REG) { auto name = std::string_view(e->d_name); if (name.starts_with(constants().mountpointMdPrefix)) { bindPoints.emplace_back(name, parseFromIncfs(mIncFs.get(), ifs->control, path::join(mountTarget, name))); if (bindPoints.back().second.dest_path().empty() || bindPoints.back().second.source_subdir().empty()) { bindPoints.pop_back(); mIncFs->unlink(ifs->control, path::join(ifs->root, constants().mount, name)); } } } else if (e->d_type == DT_DIR) { if (e->d_name == "."sv || e->d_name == ".."sv) { continue; } auto name = std::string_view(e->d_name); if (name.starts_with(constants().storagePrefix)) { int storageId; const auto res = std::from_chars(name.data() + constants().storagePrefix.size() + 1, name.data() + name.size(), storageId); if (res.ec != std::errc{} || *res.ptr != '_') { LOG(WARNING) << "Ignoring storage with invalid name '" << name << "' for mount " << root; continue; } auto [_, inserted] = mMounts.try_emplace(storageId, ifs); if (!inserted) { LOG(WARNING) << "Ignoring storage with duplicate id " << storageId << " for mount " << root; continue; } ifs->storages.insert_or_assign(storageId, IncFsMount::Storage{ path::join(root, constants().mount, name)}); mNextId = std::max(mNextId, storageId + 1); } } } if (ifs->storages.empty()) { LOG(WARNING) << "No valid storages in mount " << root; return false; } int bindCount = 0; { std::unique_lock l(mLock, std::defer_lock); for (auto&& bp : bindPoints) { bindCount += !addBindMountWithMd(*ifs, bp.second.storage_id(), std::move(bp.first), std::move(*bp.second.mutable_source_subdir()), std::move(*bp.second.mutable_dest_path()), BindKind::Permanent, l); } } if (bindCount == 0) { LOG(WARNING) << "No valid bind points for mount " << root; deleteStorage(*ifs); return false; } // not locking here at all: we're still in the constructor, no other calls can happen mMounts[ifs->mountId] = std::move(ifs); return true; } void IncrementalService::runCmdLooper() { constexpr auto kTimeoutMsecs = -1; while (mRunning.load(std::memory_order_relaxed)) { mLooper->pollAll(kTimeoutMsecs); } } void IncrementalService::trimReservedSpaceV1(const IncFsMount& ifs) { mIncFs->forEachFile(ifs.control, [this](auto&& control, auto&& fileId) { if (mIncFs->isFileFullyLoaded(control, fileId) == incfs::LoadingState::Full) { mIncFs->reserveSpace(control, fileId, -1); } return true; }); } void IncrementalService::prepareDataLoaderLocked(IncFsMount& ifs, DataLoaderParamsParcel&& params, DataLoaderStatusListener&& statusListener, const StorageHealthCheckParams& healthCheckParams, StorageHealthListener&& healthListener) { FileSystemControlParcel fsControlParcel; fsControlParcel.incremental = std::make_optional(); fsControlParcel.incremental->cmd.reset(dup(ifs.control.cmd())); fsControlParcel.incremental->pendingReads.reset(dup(ifs.control.pendingReads())); fsControlParcel.incremental->log.reset(dup(ifs.control.logs())); if (ifs.control.blocksWritten() >= 0) { fsControlParcel.incremental->blocksWritten.emplace(dup(ifs.control.blocksWritten())); } fsControlParcel.service = new IncrementalServiceConnector(*this, ifs.mountId); ifs.dataLoaderStub = new DataLoaderStub(*this, ifs.mountId, std::move(params), std::move(fsControlParcel), std::move(statusListener), healthCheckParams, std::move(healthListener), path::join(ifs.root, constants().mount)); // pre-v2 IncFS doesn't do automatic reserved space trimming - need to run it manually if (!(mIncFs->features() & incfs::Features::v2)) { addIfsStateCallback(ifs.mountId, [this](StorageId storageId, IfsState state) -> bool { if (!state.fullyLoaded) { return true; } const auto ifs = getIfs(storageId); if (!ifs) { return false; } trimReservedSpaceV1(*ifs); return false; }); } addIfsStateCallback(ifs.mountId, [this](StorageId storageId, IfsState state) -> bool { if (!state.fullyLoaded || state.readLogsEnabled) { return true; } DataLoaderStubPtr dataLoaderStub; { const auto ifs = getIfs(storageId); if (!ifs) { return false; } std::unique_lock l(ifs->lock); dataLoaderStub = std::exchange(ifs->dataLoaderStub, nullptr); } if (dataLoaderStub) { dataLoaderStub->cleanupResources(); } return false; }); } template static constexpr auto castToMs(Duration d) { return std::chrono::duration_cast(d); } // Extract lib files from zip, create new files in incfs and write data to them // Lib files should be placed next to the APK file in the following matter: // Example: // /path/to/base.apk // /path/to/lib/arm/first.so // /path/to/lib/arm/second.so bool IncrementalService::configureNativeBinaries(StorageId storage, std::string_view apkFullPath, std::string_view libDirRelativePath, std::string_view abi, bool extractNativeLibs) { auto start = Clock::now(); const auto ifs = getIfs(storage); if (!ifs) { LOG(ERROR) << "Invalid storage " << storage; return false; } const auto targetLibPathRelativeToStorage = path::join(path::dirname(normalizePathToStorage(*ifs, storage, apkFullPath)), libDirRelativePath); // First prepare target directories if they don't exist yet if (auto res = makeDirs(*ifs, storage, targetLibPathRelativeToStorage, 0755)) { LOG(ERROR) << "Failed to prepare target lib directory " << targetLibPathRelativeToStorage << " errno: " << res; return false; } auto mkDirsTs = Clock::now(); ZipArchiveHandle zipFileHandle; if (OpenArchive(path::c_str(apkFullPath), &zipFileHandle)) { LOG(ERROR) << "Failed to open zip file at " << apkFullPath; return false; } // Need a shared pointer: will be passing it into all unpacking jobs. std::shared_ptr zipFile(zipFileHandle, [](ZipArchiveHandle h) { CloseArchive(h); }); void* cookie = nullptr; const auto libFilePrefix = path::join(constants().libDir, abi) += "/"; if (StartIteration(zipFile.get(), &cookie, libFilePrefix, constants().libSuffix)) { LOG(ERROR) << "Failed to start zip iteration for " << apkFullPath; return false; } auto endIteration = [](void* cookie) { EndIteration(cookie); }; auto iterationCleaner = std::unique_ptr(cookie, endIteration); auto openZipTs = Clock::now(); auto mapFiles = (mIncFs->features() & incfs::Features::v2); incfs::FileId sourceId; if (mapFiles) { sourceId = mIncFs->getFileId(ifs->control, apkFullPath); if (!incfs::isValidFileId(sourceId)) { LOG(WARNING) << "Error getting IncFS file ID for apk path '" << apkFullPath << "', mapping disabled"; mapFiles = false; } } std::vector jobQueue; ZipEntry entry; std::string_view fileName; while (!Next(cookie, &entry, &fileName)) { if (fileName.empty()) { continue; } const auto entryUncompressed = entry.method == kCompressStored; const auto entryPageAligned = isPageAligned(entry.offset); if (!extractNativeLibs) { // ensure the file is properly aligned and unpacked if (!entryUncompressed) { LOG(WARNING) << "Library " << fileName << " must be uncompressed to mmap it"; return false; } if (!entryPageAligned) { LOG(WARNING) << "Library " << fileName << " must be page-aligned to mmap it, offset = 0x" << std::hex << entry.offset; return false; } continue; } auto startFileTs = Clock::now(); const auto libName = path::basename(fileName); auto targetLibPath = path::join(targetLibPathRelativeToStorage, libName); const auto targetLibPathAbsolute = normalizePathToStorage(*ifs, storage, targetLibPath); // If the extract file already exists, skip if (access(targetLibPathAbsolute.c_str(), F_OK) == 0) { if (perfLoggingEnabled()) { LOG(INFO) << "incfs: Native lib file already exists: " << targetLibPath << "; skipping extraction, spent " << elapsedMcs(startFileTs, Clock::now()) << "mcs"; } continue; } if (mapFiles && entryUncompressed && entryPageAligned && entry.uncompressed_length > 0) { incfs::NewMappedFileParams mappedFileParams = { .sourceId = sourceId, .sourceOffset = entry.offset, .size = entry.uncompressed_length, }; if (auto res = mIncFs->makeMappedFile(ifs->control, targetLibPathAbsolute, 0755, mappedFileParams); res == 0) { if (perfLoggingEnabled()) { auto doneTs = Clock::now(); LOG(INFO) << "incfs: Mapped " << libName << ": " << elapsedMcs(startFileTs, doneTs) << "mcs"; } continue; } else { LOG(WARNING) << "Failed to map file for: '" << targetLibPath << "' errno: " << res << "; falling back to full extraction"; } } // Create new lib file without signature info incfs::NewFileParams libFileParams = { .size = entry.uncompressed_length, .signature = {}, // Metadata of the new lib file is its relative path .metadata = {targetLibPath.c_str(), (IncFsSize)targetLibPath.size()}, }; incfs::FileId libFileId = idFromMetadata(targetLibPath); if (auto res = mIncFs->makeFile(ifs->control, targetLibPathAbsolute, 0755, libFileId, libFileParams)) { LOG(ERROR) << "Failed to make file for: " << targetLibPath << " errno: " << res; // If one lib file fails to be created, abort others as well return false; } auto makeFileTs = Clock::now(); // If it is a zero-byte file, skip data writing if (entry.uncompressed_length == 0) { if (perfLoggingEnabled()) { LOG(INFO) << "incfs: Extracted " << libName << "(0 bytes): " << elapsedMcs(startFileTs, makeFileTs) << "mcs"; } continue; } jobQueue.emplace_back([this, zipFile, entry, ifs = std::weak_ptr(ifs), libFileId, libPath = std::move(targetLibPath), makeFileTs]() mutable { extractZipFile(ifs.lock(), zipFile.get(), entry, libFileId, libPath, makeFileTs); }); if (perfLoggingEnabled()) { auto prepareJobTs = Clock::now(); LOG(INFO) << "incfs: Processed " << libName << ": " << elapsedMcs(startFileTs, prepareJobTs) << "mcs, make file: " << elapsedMcs(startFileTs, makeFileTs) << " prepare job: " << elapsedMcs(makeFileTs, prepareJobTs); } } auto processedTs = Clock::now(); if (!jobQueue.empty()) { { std::lock_guard lock(mJobMutex); if (mRunning) { auto& existingJobs = mJobQueue[ifs->mountId]; if (existingJobs.empty()) { existingJobs = std::move(jobQueue); } else { existingJobs.insert(existingJobs.end(), std::move_iterator(jobQueue.begin()), std::move_iterator(jobQueue.end())); } } } mJobCondition.notify_all(); } if (perfLoggingEnabled()) { auto end = Clock::now(); LOG(INFO) << "incfs: configureNativeBinaries complete in " << elapsedMcs(start, end) << "mcs, make dirs: " << elapsedMcs(start, mkDirsTs) << " open zip: " << elapsedMcs(mkDirsTs, openZipTs) << " make files: " << elapsedMcs(openZipTs, processedTs) << " schedule jobs: " << elapsedMcs(processedTs, end); } return true; } void IncrementalService::extractZipFile(const IfsMountPtr& ifs, ZipArchiveHandle zipFile, ZipEntry& entry, const incfs::FileId& libFileId, std::string_view debugLibPath, Clock::time_point scheduledTs) { if (!ifs) { LOG(INFO) << "Skipping zip file " << debugLibPath << " extraction for an expired mount"; return; } auto startedTs = Clock::now(); // Write extracted data to new file // NOTE: don't zero-initialize memory, it may take a while for nothing auto libData = std::unique_ptr(new uint8_t[entry.uncompressed_length]); if (ExtractToMemory(zipFile, &entry, libData.get(), entry.uncompressed_length)) { LOG(ERROR) << "Failed to extract native lib zip entry: " << path::basename(debugLibPath); return; } auto extractFileTs = Clock::now(); if (setFileContent(ifs, libFileId, debugLibPath, std::span(libData.get(), entry.uncompressed_length))) { return; } if (perfLoggingEnabled()) { auto endFileTs = Clock::now(); LOG(INFO) << "incfs: Extracted " << path::basename(debugLibPath) << "(" << entry.compressed_length << " -> " << entry.uncompressed_length << " bytes): " << elapsedMcs(startedTs, endFileTs) << "mcs, scheduling delay: " << elapsedMcs(scheduledTs, startedTs) << " extract: " << elapsedMcs(startedTs, extractFileTs) << " open/prepare/write: " << elapsedMcs(extractFileTs, endFileTs); } } bool IncrementalService::waitForNativeBinariesExtraction(StorageId storage) { struct WaitPrinter { const Clock::time_point startTs = Clock::now(); ~WaitPrinter() noexcept { if (perfLoggingEnabled()) { const auto endTs = Clock::now(); LOG(INFO) << "incfs: waitForNativeBinariesExtraction() complete in " << elapsedMcs(startTs, endTs) << "mcs"; } } } waitPrinter; MountId mount; { auto ifs = getIfs(storage); if (!ifs) { return true; } mount = ifs->mountId; } std::unique_lock lock(mJobMutex); mJobCondition.wait(lock, [this, mount] { return !mRunning || (mPendingJobsMount != mount && mJobQueue.find(mount) == mJobQueue.end()); }); return mRunning; } int IncrementalService::setFileContent(const IfsMountPtr& ifs, const incfs::FileId& fileId, std::string_view debugFilePath, std::span data) const { auto startTs = Clock::now(); const auto writeFd = mIncFs->openForSpecialOps(ifs->control, fileId); if (!writeFd.ok()) { LOG(ERROR) << "Failed to open write fd for: " << debugFilePath << " errno: " << writeFd.get(); return writeFd.get(); } const auto dataLength = data.size(); auto openFileTs = Clock::now(); const int numBlocks = (data.size() + constants().blockSize - 1) / constants().blockSize; std::vector instructions(numBlocks); for (int i = 0; i < numBlocks; i++) { const auto blockSize = std::min(constants().blockSize, data.size()); instructions[i] = IncFsDataBlock{ .fileFd = writeFd.get(), .pageIndex = static_cast(i), .compression = INCFS_COMPRESSION_KIND_NONE, .kind = INCFS_BLOCK_KIND_DATA, .dataSize = static_cast(blockSize), .data = reinterpret_cast(data.data()), }; data = data.subspan(blockSize); } auto prepareInstsTs = Clock::now(); size_t res = mIncFs->writeBlocks(instructions); if (res != instructions.size()) { LOG(ERROR) << "Failed to write data into: " << debugFilePath; return res; } if (perfLoggingEnabled()) { auto endTs = Clock::now(); LOG(INFO) << "incfs: Set file content " << debugFilePath << "(" << dataLength << " bytes): " << elapsedMcs(startTs, endTs) << "mcs, open: " << elapsedMcs(startTs, openFileTs) << " prepare: " << elapsedMcs(openFileTs, prepareInstsTs) << " write: " << elapsedMcs(prepareInstsTs, endTs); } return 0; } incfs::LoadingState IncrementalService::isFileFullyLoaded(StorageId storage, std::string_view filePath) const { std::unique_lock l(mLock); const auto ifs = getIfsLocked(storage); if (!ifs) { LOG(ERROR) << "isFileFullyLoaded failed, invalid storageId: " << storage; return incfs::LoadingState(-EINVAL); } const auto storageInfo = ifs->storages.find(storage); if (storageInfo == ifs->storages.end()) { LOG(ERROR) << "isFileFullyLoaded failed, no storage: " << storage; return incfs::LoadingState(-EINVAL); } l.unlock(); return mIncFs->isFileFullyLoaded(ifs->control, filePath); } incfs::LoadingState IncrementalService::isMountFullyLoaded(StorageId storage) const { const auto ifs = getIfs(storage); if (!ifs) { LOG(ERROR) << "isMountFullyLoaded failed, invalid storageId: " << storage; return incfs::LoadingState(-EINVAL); } return mIncFs->isEverythingFullyLoaded(ifs->control); } IncrementalService::LoadingProgress IncrementalService::getLoadingProgress( StorageId storage) const { std::unique_lock l(mLock); const auto ifs = getIfsLocked(storage); if (!ifs) { LOG(ERROR) << "getLoadingProgress failed, invalid storageId: " << storage; return {-EINVAL, -EINVAL}; } const auto storageInfo = ifs->storages.find(storage); if (storageInfo == ifs->storages.end()) { LOG(ERROR) << "getLoadingProgress failed, no storage: " << storage; return {-EINVAL, -EINVAL}; } l.unlock(); return getLoadingProgressFromPath(*ifs, storageInfo->second.name); } IncrementalService::LoadingProgress IncrementalService::getLoadingProgressFromPath( const IncFsMount& ifs, std::string_view storagePath) const { ssize_t totalBlocks = 0, filledBlocks = 0, error = 0; mFs->listFilesRecursive(storagePath, [&, this](auto filePath) { const auto [filledBlocksCount, totalBlocksCount] = mIncFs->countFilledBlocks(ifs.control, filePath); if (filledBlocksCount == -EOPNOTSUPP || filledBlocksCount == -ENOTSUP || filledBlocksCount == -ENOENT) { // a kind of a file that's not really being loaded, e.g. a mapped range // an older IncFS used to return ENOENT in this case, so handle it the same way return true; } if (filledBlocksCount < 0) { LOG(ERROR) << "getLoadingProgress failed to get filled blocks count for: " << filePath << ", errno: " << filledBlocksCount; error = filledBlocksCount; return false; } totalBlocks += totalBlocksCount; filledBlocks += filledBlocksCount; return true; }); return error ? LoadingProgress{error, error} : LoadingProgress{filledBlocks, totalBlocks}; } bool IncrementalService::updateLoadingProgress(StorageId storage, StorageLoadingProgressListener&& progressListener) { const auto progress = getLoadingProgress(storage); if (progress.isError()) { // Failed to get progress from incfs, abort. return false; } progressListener->onStorageLoadingProgressChanged(storage, progress.getProgress()); if (progress.fullyLoaded()) { // Stop updating progress once it is fully loaded return true; } addTimedJob(*mProgressUpdateJobQueue, storage, Constants::progressUpdateInterval /* repeat after 1s */, [storage, progressListener = std::move(progressListener), this]() mutable { updateLoadingProgress(storage, std::move(progressListener)); }); return true; } bool IncrementalService::registerLoadingProgressListener( StorageId storage, StorageLoadingProgressListener progressListener) { return updateLoadingProgress(storage, std::move(progressListener)); } bool IncrementalService::unregisterLoadingProgressListener(StorageId storage) { return removeTimedJobs(*mProgressUpdateJobQueue, storage); } bool IncrementalService::perfLoggingEnabled() { static const bool enabled = base::GetBoolProperty("incremental.perflogging", false); return enabled; } void IncrementalService::runJobProcessing() { for (;;) { std::unique_lock lock(mJobMutex); mJobCondition.wait(lock, [this]() { return !mRunning || !mJobQueue.empty(); }); if (!mRunning) { return; } auto it = mJobQueue.begin(); mPendingJobsMount = it->first; auto queue = std::move(it->second); mJobQueue.erase(it); lock.unlock(); for (auto&& job : queue) { job(); } lock.lock(); mPendingJobsMount = kInvalidStorageId; lock.unlock(); mJobCondition.notify_all(); } } void IncrementalService::registerAppOpsCallback(const std::string& packageName) { sp listener; { std::unique_lock lock{mCallbacksLock}; auto& cb = mCallbackRegistered[packageName]; if (cb) { return; } cb = new AppOpsListener(*this, packageName); listener = cb; } mAppOpsManager->startWatchingMode(AppOpsManager::OP_GET_USAGE_STATS, String16(packageName.c_str()), listener); } bool IncrementalService::unregisterAppOpsCallback(const std::string& packageName) { sp listener; { std::unique_lock lock{mCallbacksLock}; auto found = mCallbackRegistered.find(packageName); if (found == mCallbackRegistered.end()) { return false; } listener = found->second; mCallbackRegistered.erase(found); } mAppOpsManager->stopWatchingMode(listener); return true; } void IncrementalService::onAppOpChanged(const std::string& packageName) { if (!unregisterAppOpsCallback(packageName)) { return; } std::vector affected; { std::lock_guard l(mLock); affected.reserve(mMounts.size()); for (auto&& [id, ifs] : mMounts) { std::unique_lock ll(ifs->lock); if (ifs->mountId == id && ifs->dataLoaderStub && ifs->dataLoaderStub->params().packageName == packageName) { affected.push_back(ifs); } } } for (auto&& ifs : affected) { std::unique_lock ll(ifs->lock); disableReadLogsLocked(*ifs); } } bool IncrementalService::addTimedJob(TimedQueueWrapper& timedQueue, MountId id, Milliseconds after, Job what) { if (id == kInvalidStorageId) { return false; } timedQueue.addJob(id, after, std::move(what)); return true; } bool IncrementalService::removeTimedJobs(TimedQueueWrapper& timedQueue, MountId id) { if (id == kInvalidStorageId) { return false; } timedQueue.removeJobs(id); return true; } void IncrementalService::addIfsStateCallback(StorageId storageId, IfsStateCallback callback) { bool wasEmpty; { std::lock_guard l(mIfsStateCallbacksLock); wasEmpty = mIfsStateCallbacks.empty(); mIfsStateCallbacks[storageId].emplace_back(std::move(callback)); } if (wasEmpty) { addTimedJob(*mTimedQueue, kAllStoragesId, Constants::progressUpdateInterval, [this]() { processIfsStateCallbacks(); }); } } void IncrementalService::processIfsStateCallbacks() { StorageId storageId = kInvalidStorageId; std::vector local; while (true) { { std::lock_guard l(mIfsStateCallbacksLock); if (mIfsStateCallbacks.empty()) { return; } IfsStateCallbacks::iterator it; if (storageId == kInvalidStorageId) { // First entry, initialize the |it|. it = mIfsStateCallbacks.begin(); } else { // Subsequent entries, update the |storageId|, and shift to the new one (not that // it guarantees much about updated items, but at least the loop will finish). it = mIfsStateCallbacks.lower_bound(storageId); if (it == mIfsStateCallbacks.end()) { // Nothing else left, too bad. break; } if (it->first != storageId) { local.clear(); // Was removed during processing, forget the old callbacks. } else { // Put the 'surviving' callbacks back into the map and advance the position. auto& callbacks = it->second; if (callbacks.empty()) { std::swap(callbacks, local); } else { callbacks.insert(callbacks.end(), std::move_iterator(local.begin()), std::move_iterator(local.end())); local.clear(); } if (callbacks.empty()) { it = mIfsStateCallbacks.erase(it); if (mIfsStateCallbacks.empty()) { return; } } else { ++it; } } } if (it == mIfsStateCallbacks.end()) { break; } storageId = it->first; auto& callbacks = it->second; if (callbacks.empty()) { // Invalid case, one extra lookup should be ok. continue; } std::swap(callbacks, local); } processIfsStateCallbacks(storageId, local); } addTimedJob(*mTimedQueue, kAllStoragesId, Constants::progressUpdateInterval, [this]() { processIfsStateCallbacks(); }); } void IncrementalService::processIfsStateCallbacks(StorageId storageId, std::vector& callbacks) { const auto state = isMountFullyLoaded(storageId); IfsState storageState = {}; storageState.error = int(state) < 0; storageState.fullyLoaded = state == incfs::LoadingState::Full; if (storageState.fullyLoaded) { const auto ifs = getIfs(storageId); storageState.readLogsEnabled = ifs && ifs->readLogsEnabled(); } for (auto cur = callbacks.begin(); cur != callbacks.end();) { if ((*cur)(storageId, storageState)) { ++cur; } else { cur = callbacks.erase(cur); } } } void IncrementalService::removeIfsStateCallbacks(StorageId storageId) { std::lock_guard l(mIfsStateCallbacksLock); mIfsStateCallbacks.erase(storageId); } void IncrementalService::getMetrics(StorageId storageId, android::os::PersistableBundle* result) { const auto ifs = getIfs(storageId); if (!ifs) { LOG(ERROR) << "getMetrics failed, invalid storageId: " << storageId; return; } const auto& kMetricsReadLogsEnabled = os::incremental::BnIncrementalService::METRICS_READ_LOGS_ENABLED(); result->putBoolean(String16(kMetricsReadLogsEnabled.c_str()), ifs->readLogsEnabled() != 0); const auto incfsMetrics = mIncFs->getMetrics(ifs->metricsKey); if (incfsMetrics) { const auto& kMetricsTotalDelayedReads = os::incremental::BnIncrementalService::METRICS_TOTAL_DELAYED_READS(); const auto totalDelayedReads = incfsMetrics->readsDelayedMin + incfsMetrics->readsDelayedPending; result->putInt(String16(kMetricsTotalDelayedReads.c_str()), totalDelayedReads); const auto& kMetricsTotalFailedReads = os::incremental::BnIncrementalService::METRICS_TOTAL_FAILED_READS(); const auto totalFailedReads = incfsMetrics->readsFailedTimedOut + incfsMetrics->readsFailedHashVerification + incfsMetrics->readsFailedOther; result->putInt(String16(kMetricsTotalFailedReads.c_str()), totalFailedReads); const auto& kMetricsTotalDelayedReadsMillis = os::incremental::BnIncrementalService::METRICS_TOTAL_DELAYED_READS_MILLIS(); const int64_t totalDelayedReadsMillis = (incfsMetrics->readsDelayedMinUs + incfsMetrics->readsDelayedPendingUs) / 1000; result->putLong(String16(kMetricsTotalDelayedReadsMillis.c_str()), totalDelayedReadsMillis); } const auto lastReadError = mIncFs->getLastReadError(ifs->control); if (lastReadError && lastReadError->timestampUs != 0) { const auto& kMetricsMillisSinceLastReadError = os::incremental::BnIncrementalService::METRICS_MILLIS_SINCE_LAST_READ_ERROR(); result->putLong(String16(kMetricsMillisSinceLastReadError.c_str()), (int64_t)elapsedUsSinceMonoTs(lastReadError->timestampUs) / 1000); const auto& kMetricsLastReadErrorNo = os::incremental::BnIncrementalService::METRICS_LAST_READ_ERROR_NUMBER(); result->putInt(String16(kMetricsLastReadErrorNo.c_str()), lastReadError->errorNo); const auto& kMetricsLastReadUid = os::incremental::BnIncrementalService::METRICS_LAST_READ_ERROR_UID(); result->putInt(String16(kMetricsLastReadUid.c_str()), lastReadError->uid); } std::unique_lock l(ifs->lock); if (!ifs->dataLoaderStub) { return; } ifs->dataLoaderStub->getMetrics(result); } IncrementalService::DataLoaderStub::DataLoaderStub( IncrementalService& service, MountId id, DataLoaderParamsParcel&& params, FileSystemControlParcel&& control, DataLoaderStatusListener&& statusListener, const StorageHealthCheckParams& healthCheckParams, StorageHealthListener&& healthListener, std::string&& healthPath) : mService(service), mId(id), mParams(std::move(params)), mControl(std::move(control)), mStatusListener(std::move(statusListener)), mHealthListener(std::move(healthListener)), mHealthPath(std::move(healthPath)), mHealthCheckParams(healthCheckParams) { if (mHealthListener && !isHealthParamsValid()) { mHealthListener = {}; } if (!mHealthListener) { // Disable advanced health check statuses. mHealthCheckParams.blockedTimeoutMs = -1; } updateHealthStatus(); } IncrementalService::DataLoaderStub::~DataLoaderStub() { if (isValid()) { cleanupResources(); } } void IncrementalService::DataLoaderStub::cleanupResources() { auto now = Clock::now(); { std::unique_lock lock(mMutex); mHealthPath.clear(); unregisterFromPendingReads(); resetHealthControl(); mService.removeTimedJobs(*mService.mTimedQueue, mId); } mService.removeIfsStateCallbacks(mId); requestDestroy(); { std::unique_lock lock(mMutex); mParams = {}; mControl = {}; mHealthControl = {}; mHealthListener = {}; mStatusCondition.wait_until(lock, now + Constants::destroyTimeout, [this] { return mCurrentStatus == IDataLoaderStatusListener::DATA_LOADER_DESTROYED; }); mStatusListener = {}; mId = kInvalidStorageId; } } sp IncrementalService::DataLoaderStub::getDataLoader() { sp dataloader; auto status = mService.mDataLoaderManager->getDataLoader(id(), &dataloader); if (!status.isOk()) { LOG(ERROR) << "Failed to get dataloader: " << status.toString8(); return {}; } if (!dataloader) { LOG(ERROR) << "DataLoader is null: " << status.toString8(); return {}; } return dataloader; } bool IncrementalService::DataLoaderStub::isSystemDataLoader() const { return (params().packageName == Constants::systemPackage); } bool IncrementalService::DataLoaderStub::requestCreate() { return setTargetStatus(IDataLoaderStatusListener::DATA_LOADER_CREATED); } bool IncrementalService::DataLoaderStub::requestStart() { return setTargetStatus(IDataLoaderStatusListener::DATA_LOADER_STARTED); } bool IncrementalService::DataLoaderStub::requestDestroy() { return setTargetStatus(IDataLoaderStatusListener::DATA_LOADER_DESTROYED); } bool IncrementalService::DataLoaderStub::setTargetStatus(int newStatus) { { std::unique_lock lock(mMutex); setTargetStatusLocked(newStatus); } return fsmStep(); } void IncrementalService::DataLoaderStub::setTargetStatusLocked(int status) { auto oldStatus = mTargetStatus; mTargetStatus = status; mTargetStatusTs = Clock::now(); LOG(DEBUG) << "Target status update for DataLoader " << id() << ": " << oldStatus << " -> " << status << " (current " << mCurrentStatus << ")"; } std::optional IncrementalService::DataLoaderStub::needToBind() { std::unique_lock lock(mMutex); const auto now = mService.mClock->now(); const bool healthy = (mPreviousBindDelay == 0ms); if (mCurrentStatus == IDataLoaderStatusListener::DATA_LOADER_BINDING && now - mCurrentStatusTs <= Constants::bindingTimeout) { LOG(INFO) << "Binding still in progress. " << (healthy ? "The DL is healthy/freshly bound, ok to retry for a few times." : "Already unhealthy, don't do anything.") << " for storage " << mId; // Binding still in progress. if (!healthy) { // Already unhealthy, don't do anything. return {}; } // The DL is healthy/freshly bound, ok to retry for a few times. if (now - mPreviousBindTs <= Constants::bindGracePeriod) { // Still within grace period. if (now - mCurrentStatusTs >= Constants::bindRetryInterval) { // Retry interval passed, retrying. mCurrentStatusTs = now; mPreviousBindDelay = 0ms; return 0ms; } return {}; } // fallthrough, mark as unhealthy, and retry with delay } const auto previousBindTs = mPreviousBindTs; mPreviousBindTs = now; const auto nonCrashingInterval = std::max(castToMs(now - previousBindTs - mPreviousBindDelay), 100ms); if (previousBindTs.time_since_epoch() == Clock::duration::zero() || nonCrashingInterval > Constants::healthyDataLoaderUptime) { mPreviousBindDelay = 0ms; return 0ms; } constexpr auto minBindDelayMs = castToMs(Constants::minBindDelay); constexpr auto maxBindDelayMs = castToMs(Constants::maxBindDelay); const auto bindDelayMs = std::min(std::max(mPreviousBindDelay * Constants::bindDelayMultiplier, minBindDelayMs), maxBindDelayMs) .count(); const auto bindDelayJitterRangeMs = bindDelayMs / Constants::bindDelayJitterDivider; // rand() is enough, not worth maintaining a full-blown object for delay jitter const auto bindDelayJitterMs = rand() % (bindDelayJitterRangeMs * 2) - // NOLINT bindDelayJitterRangeMs; mPreviousBindDelay = std::chrono::milliseconds(bindDelayMs + bindDelayJitterMs); return mPreviousBindDelay; } bool IncrementalService::DataLoaderStub::bind() { const auto maybeBindDelay = needToBind(); if (!maybeBindDelay) { LOG(DEBUG) << "Skipping bind to " << mParams.packageName << " because of pending bind."; return true; } const auto bindDelay = *maybeBindDelay; if (bindDelay > 1s) { LOG(INFO) << "Delaying bind to " << mParams.packageName << " by " << bindDelay.count() / 1000 << "s" << " for storage " << mId; } bool result = false; auto status = mService.mDataLoaderManager->bindToDataLoader(id(), mParams, bindDelay.count(), this, &result); if (!status.isOk() || !result) { const bool healthy = (bindDelay == 0ms); LOG(ERROR) << "Failed to bind a data loader for mount " << id() << (healthy ? ", retrying." : ""); // Internal error, retry for healthy/new DLs. // Let needToBind migrate it to unhealthy after too many retries. if (healthy) { if (mService.addTimedJob(*mService.mTimedQueue, id(), Constants::bindRetryInterval, [this]() { fsmStep(); })) { // Mark as binding so that we know it's not the DL's fault. setCurrentStatus(IDataLoaderStatusListener::DATA_LOADER_BINDING); return true; } } return false; } return true; } bool IncrementalService::DataLoaderStub::create() { auto dataloader = getDataLoader(); if (!dataloader) { return false; } auto status = dataloader->create(id(), mParams, mControl, this); if (!status.isOk()) { LOG(ERROR) << "Failed to create DataLoader: " << status.toString8(); return false; } return true; } bool IncrementalService::DataLoaderStub::start() { auto dataloader = getDataLoader(); if (!dataloader) { return false; } auto status = dataloader->start(id()); if (!status.isOk()) { LOG(ERROR) << "Failed to start DataLoader: " << status.toString8(); return false; } return true; } bool IncrementalService::DataLoaderStub::destroy() { return mService.mDataLoaderManager->unbindFromDataLoader(id()).isOk(); } bool IncrementalService::DataLoaderStub::fsmStep() { if (!isValid()) { return false; } int currentStatus; int targetStatus; { std::unique_lock lock(mMutex); currentStatus = mCurrentStatus; targetStatus = mTargetStatus; } LOG(DEBUG) << "fsmStep: " << id() << ": " << currentStatus << " -> " << targetStatus; if (currentStatus == targetStatus) { return true; } switch (targetStatus) { case IDataLoaderStatusListener::DATA_LOADER_DESTROYED: { switch (currentStatus) { case IDataLoaderStatusListener::DATA_LOADER_UNAVAILABLE: case IDataLoaderStatusListener::DATA_LOADER_UNRECOVERABLE: destroy(); // DataLoader is broken, just assume it's destroyed. compareAndSetCurrentStatus(currentStatus, IDataLoaderStatusListener::DATA_LOADER_DESTROYED); return true; case IDataLoaderStatusListener::DATA_LOADER_BINDING: compareAndSetCurrentStatus(currentStatus, IDataLoaderStatusListener::DATA_LOADER_DESTROYED); return true; default: return destroy(); } break; } case IDataLoaderStatusListener::DATA_LOADER_STARTED: { switch (currentStatus) { case IDataLoaderStatusListener::DATA_LOADER_CREATED: case IDataLoaderStatusListener::DATA_LOADER_STOPPED: return start(); } [[fallthrough]]; } case IDataLoaderStatusListener::DATA_LOADER_CREATED: switch (currentStatus) { case IDataLoaderStatusListener::DATA_LOADER_UNAVAILABLE: case IDataLoaderStatusListener::DATA_LOADER_UNRECOVERABLE: // Before binding need to make sure we are unbound. // Otherwise we'll get stuck binding. destroy(); // DataLoader is broken, just assume it's destroyed. compareAndSetCurrentStatus(currentStatus, IDataLoaderStatusListener::DATA_LOADER_DESTROYED); return true; case IDataLoaderStatusListener::DATA_LOADER_DESTROYED: case IDataLoaderStatusListener::DATA_LOADER_BINDING: return bind(); case IDataLoaderStatusListener::DATA_LOADER_BOUND: return create(); } break; default: LOG(ERROR) << "Invalid target status: " << targetStatus << ", current status: " << currentStatus; break; } return false; } binder::Status IncrementalService::DataLoaderStub::onStatusChanged(MountId mountId, int newStatus) { if (!isValid()) { if (newStatus == IDataLoaderStatusListener::DATA_LOADER_BOUND) { // Async "bound" came to already destroyed stub. // Unbind immediately to avoid invalid stub sitting around in DataLoaderManagerService. mService.mDataLoaderManager->unbindFromDataLoader(mountId); return binder::Status::ok(); } return binder::Status:: fromServiceSpecificError(-EINVAL, "onStatusChange came to invalid DataLoaderStub"); } if (id() != mountId) { LOG(ERROR) << "onStatusChanged: mount ID mismatch: expected " << id() << ", but got: " << mountId; return binder::Status::fromServiceSpecificError(-EPERM, "Mount ID mismatch."); } if (newStatus == IDataLoaderStatusListener::DATA_LOADER_UNAVAILABLE || newStatus == IDataLoaderStatusListener::DATA_LOADER_UNRECOVERABLE) { // User-provided status, let's postpone the handling to avoid possible deadlocks. mService.addTimedJob(*mService.mTimedQueue, id(), Constants::userStatusDelay, [this, newStatus]() { setCurrentStatus(newStatus); }); return binder::Status::ok(); } setCurrentStatus(newStatus); return binder::Status::ok(); } void IncrementalService::DataLoaderStub::setCurrentStatus(int newStatus) { compareAndSetCurrentStatus(Constants::anyStatus, newStatus); } void IncrementalService::DataLoaderStub::compareAndSetCurrentStatus(int expectedStatus, int newStatus) { int oldStatus, oldTargetStatus, newTargetStatus; DataLoaderStatusListener listener; { std::unique_lock lock(mMutex); if (mCurrentStatus == newStatus) { return; } if (expectedStatus != Constants::anyStatus && expectedStatus != mCurrentStatus) { return; } oldStatus = mCurrentStatus; oldTargetStatus = mTargetStatus; listener = mStatusListener; // Change the status. mCurrentStatus = newStatus; mCurrentStatusTs = mService.mClock->now(); switch (mCurrentStatus) { case IDataLoaderStatusListener::DATA_LOADER_UNAVAILABLE: // Unavailable, retry. setTargetStatusLocked(IDataLoaderStatusListener::DATA_LOADER_STARTED); break; case IDataLoaderStatusListener::DATA_LOADER_UNRECOVERABLE: // Unrecoverable, just unbind. setTargetStatusLocked(IDataLoaderStatusListener::DATA_LOADER_DESTROYED); break; default: break; } newTargetStatus = mTargetStatus; } LOG(DEBUG) << "Current status update for DataLoader " << id() << ": " << oldStatus << " -> " << newStatus << " (target " << oldTargetStatus << " -> " << newTargetStatus << ")"; if (listener) { listener->onStatusChanged(id(), newStatus); } fsmStep(); mStatusCondition.notify_all(); } bool IncrementalService::DataLoaderStub::isHealthParamsValid() const { return mHealthCheckParams.blockedTimeoutMs > 0 && mHealthCheckParams.blockedTimeoutMs < mHealthCheckParams.unhealthyTimeoutMs; } void IncrementalService::DataLoaderStub::onHealthStatus(const StorageHealthListener& healthListener, int healthStatus) { LOG(DEBUG) << id() << ": healthStatus: " << healthStatus; if (healthListener) { healthListener->onHealthStatus(id(), healthStatus); } mHealthStatus = healthStatus; } void IncrementalService::DataLoaderStub::updateHealthStatus(bool baseline) { LOG(DEBUG) << id() << ": updateHealthStatus" << (baseline ? " (baseline)" : ""); int healthStatusToReport = -1; StorageHealthListener healthListener; { std::unique_lock lock(mMutex); unregisterFromPendingReads(); healthListener = mHealthListener; // Healthcheck depends on timestamp of the oldest pending read. // To get it, we need to re-open a pendingReads FD to get a full list of reads. // Additionally we need to re-register for epoll with fresh FDs in case there are no // reads. const auto now = Clock::now(); const auto kernelTsUs = getOldestPendingReadTs(); if (baseline) { // Updating baseline only on looper/epoll callback, i.e. on new set of pending // reads. mHealthBase = {now, kernelTsUs}; } if (kernelTsUs == kMaxBootClockTsUs || mHealthBase.kernelTsUs == kMaxBootClockTsUs || mHealthBase.userTs > now) { LOG(DEBUG) << id() << ": No pending reads or invalid base, report Ok and wait."; registerForPendingReads(); healthStatusToReport = IStorageHealthListener::HEALTH_STATUS_OK; lock.unlock(); onHealthStatus(healthListener, healthStatusToReport); return; } resetHealthControl(); // Always make sure the data loader is started. setTargetStatusLocked(IDataLoaderStatusListener::DATA_LOADER_STARTED); // Skip any further processing if health check params are invalid. if (!isHealthParamsValid()) { LOG(DEBUG) << id() << ": Skip any further processing if health check params are invalid."; healthStatusToReport = IStorageHealthListener::HEALTH_STATUS_READS_PENDING; lock.unlock(); onHealthStatus(healthListener, healthStatusToReport); // Triggering data loader start. This is a one-time action. fsmStep(); return; } // Don't schedule timer job less than 500ms in advance. static constexpr auto kTolerance = 500ms; const auto blockedTimeout = std::chrono::milliseconds(mHealthCheckParams.blockedTimeoutMs); const auto unhealthyTimeout = std::chrono::milliseconds(mHealthCheckParams.unhealthyTimeoutMs); const auto unhealthyMonitoring = std::max(1000ms, std::chrono::milliseconds(mHealthCheckParams.unhealthyMonitoringMs)); const auto delta = elapsedMsSinceKernelTs(now, kernelTsUs); Milliseconds checkBackAfter; if (delta + kTolerance < blockedTimeout) { LOG(DEBUG) << id() << ": Report reads pending and wait for blocked status."; checkBackAfter = blockedTimeout - delta; healthStatusToReport = IStorageHealthListener::HEALTH_STATUS_READS_PENDING; } else if (delta + kTolerance < unhealthyTimeout) { LOG(DEBUG) << id() << ": Report blocked and wait for unhealthy."; checkBackAfter = unhealthyTimeout - delta; healthStatusToReport = IStorageHealthListener::HEALTH_STATUS_BLOCKED; } else { LOG(DEBUG) << id() << ": Report unhealthy and continue monitoring."; checkBackAfter = unhealthyMonitoring; healthStatusToReport = IStorageHealthListener::HEALTH_STATUS_UNHEALTHY; } LOG(DEBUG) << id() << ": updateHealthStatus in " << double(checkBackAfter.count()) / 1000.0 << "secs"; mService.addTimedJob(*mService.mTimedQueue, id(), checkBackAfter, [this]() { updateHealthStatus(); }); } // With kTolerance we are expecting these to execute before the next update. if (healthStatusToReport != -1) { onHealthStatus(healthListener, healthStatusToReport); } fsmStep(); } Milliseconds IncrementalService::DataLoaderStub::elapsedMsSinceKernelTs(TimePoint now, BootClockTsUs kernelTsUs) { const auto kernelDeltaUs = kernelTsUs - mHealthBase.kernelTsUs; const auto userTs = mHealthBase.userTs + std::chrono::microseconds(kernelDeltaUs); return std::chrono::duration_cast(now - userTs); } const incfs::UniqueControl& IncrementalService::DataLoaderStub::initializeHealthControl() { if (mHealthPath.empty()) { resetHealthControl(); return mHealthControl; } if (mHealthControl.pendingReads() < 0) { mHealthControl = mService.mIncFs->openMount(mHealthPath); } if (mHealthControl.pendingReads() < 0) { LOG(ERROR) << "Failed to open health control for: " << id() << ", path: " << mHealthPath << "(" << mHealthControl.cmd() << ":" << mHealthControl.pendingReads() << ":" << mHealthControl.logs() << ")"; } return mHealthControl; } void IncrementalService::DataLoaderStub::resetHealthControl() { mHealthControl = {}; } BootClockTsUs IncrementalService::DataLoaderStub::getOldestPendingReadTs() { auto result = kMaxBootClockTsUs; const auto& control = initializeHealthControl(); if (control.pendingReads() < 0) { return result; } if (mService.mIncFs->waitForPendingReads(control, 0ms, &mLastPendingReads) != android::incfs::WaitResult::HaveData || mLastPendingReads.empty()) { // Clear previous pending reads mLastPendingReads.clear(); return result; } LOG(DEBUG) << id() << ": pendingReads: fd(" << control.pendingReads() << "), count(" << mLastPendingReads.size() << "), block: " << mLastPendingReads.front().block << ", time: " << mLastPendingReads.front().bootClockTsUs << ", uid: " << mLastPendingReads.front().uid; return getOldestTsFromLastPendingReads(); } void IncrementalService::DataLoaderStub::registerForPendingReads() { const auto pendingReadsFd = mHealthControl.pendingReads(); if (pendingReadsFd < 0) { return; } LOG(DEBUG) << id() << ": addFd(pendingReadsFd): " << pendingReadsFd; mService.mLooper->addFd( pendingReadsFd, android::Looper::POLL_CALLBACK, android::Looper::EVENT_INPUT, [](int, int, void* data) -> int { auto self = (DataLoaderStub*)data; self->updateHealthStatus(/*baseline=*/true); return 0; }, this); mService.mLooper->wake(); } BootClockTsUs IncrementalService::DataLoaderStub::getOldestTsFromLastPendingReads() { auto result = kMaxBootClockTsUs; for (auto&& pendingRead : mLastPendingReads) { result = std::min(result, pendingRead.bootClockTsUs); } return result; } void IncrementalService::DataLoaderStub::getMetrics(android::os::PersistableBundle* result) { const auto duration = elapsedMsSinceOldestPendingRead(); if (duration >= 0) { const auto& kMetricsMillisSinceOldestPendingRead = os::incremental::BnIncrementalService::METRICS_MILLIS_SINCE_OLDEST_PENDING_READ(); result->putLong(String16(kMetricsMillisSinceOldestPendingRead.c_str()), duration); } const auto& kMetricsStorageHealthStatusCode = os::incremental::BnIncrementalService::METRICS_STORAGE_HEALTH_STATUS_CODE(); result->putInt(String16(kMetricsStorageHealthStatusCode.c_str()), mHealthStatus); const auto& kMetricsDataLoaderStatusCode = os::incremental::BnIncrementalService::METRICS_DATA_LOADER_STATUS_CODE(); result->putInt(String16(kMetricsDataLoaderStatusCode.c_str()), mCurrentStatus); const auto& kMetricsMillisSinceLastDataLoaderBind = os::incremental::BnIncrementalService::METRICS_MILLIS_SINCE_LAST_DATA_LOADER_BIND(); result->putLong(String16(kMetricsMillisSinceLastDataLoaderBind.c_str()), elapsedMcs(mPreviousBindTs, mService.mClock->now()) / 1000); const auto& kMetricsDataLoaderBindDelayMillis = os::incremental::BnIncrementalService::METRICS_DATA_LOADER_BIND_DELAY_MILLIS(); result->putLong(String16(kMetricsDataLoaderBindDelayMillis.c_str()), mPreviousBindDelay.count()); } long IncrementalService::DataLoaderStub::elapsedMsSinceOldestPendingRead() { const auto oldestPendingReadKernelTs = getOldestTsFromLastPendingReads(); if (oldestPendingReadKernelTs == kMaxBootClockTsUs) { return 0; } return elapsedMsSinceKernelTs(Clock::now(), oldestPendingReadKernelTs).count(); } void IncrementalService::DataLoaderStub::unregisterFromPendingReads() { const auto pendingReadsFd = mHealthControl.pendingReads(); if (pendingReadsFd < 0) { return; } LOG(DEBUG) << id() << ": removeFd(pendingReadsFd): " << pendingReadsFd; mService.mLooper->removeFd(pendingReadsFd); mService.mLooper->wake(); } void IncrementalService::DataLoaderStub::setHealthListener( const StorageHealthCheckParams& healthCheckParams, StorageHealthListener&& healthListener) { std::lock_guard lock(mMutex); mHealthCheckParams = healthCheckParams; mHealthListener = std::move(healthListener); if (!mHealthListener) { mHealthCheckParams.blockedTimeoutMs = -1; } } static std::string toHexString(const RawMetadata& metadata) { int n = metadata.size(); std::string res(n * 2, '\0'); // Same as incfs::toString(fileId) static constexpr char kHexChar[] = "0123456789abcdef"; for (int i = 0; i < n; ++i) { res[i * 2] = kHexChar[(metadata[i] & 0xf0) >> 4]; res[i * 2 + 1] = kHexChar[(metadata[i] & 0x0f)]; } return res; } void IncrementalService::DataLoaderStub::onDump(int fd) { dprintf(fd, " dataLoader: {\n"); dprintf(fd, " currentStatus: %d\n", mCurrentStatus); dprintf(fd, " currentStatusTs: %lldmcs\n", (long long)(elapsedMcs(mCurrentStatusTs, Clock::now()))); dprintf(fd, " targetStatus: %d\n", mTargetStatus); dprintf(fd, " targetStatusTs: %lldmcs\n", (long long)(elapsedMcs(mTargetStatusTs, Clock::now()))); dprintf(fd, " health: {\n"); dprintf(fd, " path: %s\n", mHealthPath.c_str()); dprintf(fd, " base: %lldmcs (%lld)\n", (long long)(elapsedMcs(mHealthBase.userTs, Clock::now())), (long long)mHealthBase.kernelTsUs); dprintf(fd, " blockedTimeoutMs: %d\n", int(mHealthCheckParams.blockedTimeoutMs)); dprintf(fd, " unhealthyTimeoutMs: %d\n", int(mHealthCheckParams.unhealthyTimeoutMs)); dprintf(fd, " unhealthyMonitoringMs: %d\n", int(mHealthCheckParams.unhealthyMonitoringMs)); dprintf(fd, " lastPendingReads: \n"); const auto control = mService.mIncFs->openMount(mHealthPath); for (auto&& pendingRead : mLastPendingReads) { dprintf(fd, " fileId: %s\n", IncFsWrapper::toString(pendingRead.id).c_str()); const auto metadata = mService.mIncFs->getMetadata(control, pendingRead.id); dprintf(fd, " metadataHex: %s\n", toHexString(metadata).c_str()); dprintf(fd, " blockIndex: %d\n", pendingRead.block); dprintf(fd, " bootClockTsUs: %lld\n", (long long)pendingRead.bootClockTsUs); } dprintf(fd, " bind: %llds ago (delay: %llds)\n", (long long)(elapsedMcs(mPreviousBindTs, mService.mClock->now()) / 1000000), (long long)(mPreviousBindDelay.count() / 1000)); dprintf(fd, " }\n"); const auto& params = mParams; dprintf(fd, " dataLoaderParams: {\n"); dprintf(fd, " type: %s\n", toString(params.type).c_str()); dprintf(fd, " packageName: %s\n", params.packageName.c_str()); dprintf(fd, " className: %s\n", params.className.c_str()); dprintf(fd, " arguments: %s\n", params.arguments.c_str()); dprintf(fd, " }\n"); dprintf(fd, " }\n"); } void IncrementalService::AppOpsListener::opChanged(int32_t, const String16&) { incrementalService.onAppOpChanged(packageName); } binder::Status IncrementalService::IncrementalServiceConnector::setStorageParams( bool enableReadLogs, int32_t* _aidl_return) { *_aidl_return = incrementalService.setStorageParams(storage, enableReadLogs); return binder::Status::ok(); } FileId IncrementalService::idFromMetadata(std::span metadata) { return IncFs_FileIdFromMetadata({(const char*)metadata.data(), (IncFsSize)metadata.size()}); } } // namespace android::incremental