/* * Copyright (C) 2015 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. */ #include "PublicVolume.h" #include "AppFuseUtil.h" #include "Utils.h" #include "VolumeManager.h" #include "fs/Exfat.h" #include "fs/Vfat.h" #include #include #include #include #include #include #include #include #include #include #include #include #include using android::base::GetBoolProperty; using android::base::StringPrintf; namespace android { namespace vold { static const char* kSdcardFsPath = "/system/bin/sdcard"; static const char* kAsecPath = "/mnt/secure/asec"; PublicVolume::PublicVolume(dev_t device) : VolumeBase(Type::kPublic), mDevice(device) { setId(StringPrintf("public:%u,%u", major(device), minor(device))); mDevPath = StringPrintf("/dev/block/vold/%s", getId().c_str()); mFuseMounted = false; mUseSdcardFs = IsSdcardfsUsed(); } PublicVolume::~PublicVolume() {} status_t PublicVolume::readMetadata() { status_t res = ReadMetadataUntrusted(mDevPath, &mFsType, &mFsUuid, &mFsLabel); auto listener = getListener(); if (listener) listener->onVolumeMetadataChanged(getId(), mFsType, mFsUuid, mFsLabel); return res; } status_t PublicVolume::initAsecStage() { std::string legacyPath(mRawPath + "/android_secure"); std::string securePath(mRawPath + "/.android_secure"); // Recover legacy secure path if (!access(legacyPath.c_str(), R_OK | X_OK) && access(securePath.c_str(), R_OK | X_OK)) { if (rename(legacyPath.c_str(), securePath.c_str())) { PLOG(WARNING) << getId() << " failed to rename legacy ASEC dir"; } } if (TEMP_FAILURE_RETRY(mkdir(securePath.c_str(), 0700))) { if (errno != EEXIST) { PLOG(WARNING) << getId() << " creating ASEC stage failed"; return -errno; } } BindMount(securePath, kAsecPath); return OK; } status_t PublicVolume::doCreate() { return CreateDeviceNode(mDevPath, mDevice); } status_t PublicVolume::doDestroy() { return DestroyDeviceNode(mDevPath); } status_t PublicVolume::doMount() { bool isVisible = isVisibleForWrite(); readMetadata(); if (mFsType == "vfat" && vfat::IsSupported()) { if (vfat::Check(mDevPath)) { LOG(ERROR) << getId() << " failed filesystem check"; return -EIO; } } else if (mFsType == "exfat" && exfat::IsSupported()) { if (exfat::Check(mDevPath)) { LOG(ERROR) << getId() << " failed filesystem check"; return -EIO; } } else { LOG(ERROR) << getId() << " unsupported filesystem " << mFsType; return -EIO; } // Use UUID as stable name, if available std::string stableName = getId(); if (!mFsUuid.empty()) { stableName = mFsUuid; } mRawPath = StringPrintf("/mnt/media_rw/%s", stableName.c_str()); mSdcardFsDefault = StringPrintf("/mnt/runtime/default/%s", stableName.c_str()); mSdcardFsRead = StringPrintf("/mnt/runtime/read/%s", stableName.c_str()); mSdcardFsWrite = StringPrintf("/mnt/runtime/write/%s", stableName.c_str()); mSdcardFsFull = StringPrintf("/mnt/runtime/full/%s", stableName.c_str()); setInternalPath(mRawPath); if (isVisible) { setPath(StringPrintf("/storage/%s", stableName.c_str())); } else { setPath(mRawPath); } if (fs_prepare_dir(mRawPath.c_str(), 0700, AID_ROOT, AID_ROOT)) { PLOG(ERROR) << getId() << " failed to create mount points"; return -errno; } if (mFsType == "vfat") { if (vfat::Mount(mDevPath, mRawPath, false, false, false, AID_ROOT, (isVisible ? AID_MEDIA_RW : AID_EXTERNAL_STORAGE), 0007, true)) { PLOG(ERROR) << getId() << " failed to mount " << mDevPath; return -EIO; } } else if (mFsType == "exfat") { if (exfat::Mount(mDevPath, mRawPath, AID_ROOT, (isVisible ? AID_MEDIA_RW : AID_EXTERNAL_STORAGE), 0007)) { PLOG(ERROR) << getId() << " failed to mount " << mDevPath; return -EIO; } } if (getMountFlags() & MountFlags::kPrimary) { initAsecStage(); } if (!isVisible) { // Not visible to apps, so no need to spin up sdcardfs or FUSE return OK; } if (mUseSdcardFs) { if (fs_prepare_dir(mSdcardFsDefault.c_str(), 0700, AID_ROOT, AID_ROOT) || fs_prepare_dir(mSdcardFsRead.c_str(), 0700, AID_ROOT, AID_ROOT) || fs_prepare_dir(mSdcardFsWrite.c_str(), 0700, AID_ROOT, AID_ROOT) || fs_prepare_dir(mSdcardFsFull.c_str(), 0700, AID_ROOT, AID_ROOT)) { PLOG(ERROR) << getId() << " failed to create sdcardfs mount points"; return -errno; } dev_t before = GetDevice(mSdcardFsFull); int sdcardFsPid; if (!(sdcardFsPid = fork())) { if (getMountFlags() & MountFlags::kPrimary) { // clang-format off if (execl(kSdcardFsPath, kSdcardFsPath, "-u", "1023", // AID_MEDIA_RW "-g", "1023", // AID_MEDIA_RW "-U", std::to_string(getMountUserId()).c_str(), "-w", mRawPath.c_str(), stableName.c_str(), NULL)) { // clang-format on PLOG(ERROR) << "Failed to exec"; } } else { // clang-format off if (execl(kSdcardFsPath, kSdcardFsPath, "-u", "1023", // AID_MEDIA_RW "-g", "1023", // AID_MEDIA_RW "-U", std::to_string(getMountUserId()).c_str(), mRawPath.c_str(), stableName.c_str(), NULL)) { // clang-format on PLOG(ERROR) << "Failed to exec"; } } LOG(ERROR) << "sdcardfs exiting"; _exit(1); } if (sdcardFsPid == -1) { PLOG(ERROR) << getId() << " failed to fork"; return -errno; } nsecs_t start = systemTime(SYSTEM_TIME_BOOTTIME); while (before == GetDevice(mSdcardFsFull)) { LOG(DEBUG) << "Waiting for sdcardfs to spin up..."; usleep(50000); // 50ms nsecs_t now = systemTime(SYSTEM_TIME_BOOTTIME); if (nanoseconds_to_milliseconds(now - start) > 5000) { LOG(WARNING) << "Timed out while waiting for sdcardfs to spin up"; return -ETIMEDOUT; } } /* sdcardfs will have exited already. The filesystem will still be running */ TEMP_FAILURE_RETRY(waitpid(sdcardFsPid, nullptr, 0)); } // We need to mount FUSE *after* sdcardfs, since the FUSE daemon may depend // on sdcardfs being up. LOG(INFO) << "Mounting public fuse volume"; android::base::unique_fd fd; int user_id = getMountUserId(); int result = MountUserFuse(user_id, getInternalPath(), stableName, &fd); if (result != 0) { LOG(ERROR) << "Failed to mount public fuse volume"; doUnmount(); return -result; } mFuseMounted = true; auto callback = getMountCallback(); if (callback) { bool is_ready = false; callback->onVolumeChecking(std::move(fd), getPath(), getInternalPath(), &is_ready); if (!is_ready) { LOG(ERROR) << "Failed to complete public volume mount"; doUnmount(); return -EIO; } } ConfigureReadAheadForFuse(GetFuseMountPathForUser(user_id, stableName), 256u); // See comment in model/EmulatedVolume.cpp ConfigureMaxDirtyRatioForFuse(GetFuseMountPathForUser(user_id, stableName), 40u); auto vol_manager = VolumeManager::Instance(); // Create bind mounts for all running users for (userid_t started_user : vol_manager->getStartedUsers()) { userid_t mountUserId = getMountUserId(); if (started_user == mountUserId) { // No need to bind mount for the user that owns the mount continue; } if (mountUserId != VolumeManager::Instance()->getSharedStorageUser(started_user)) { // No need to bind if the user does not share storage with the mount owner continue; } // Create mount directory for the user as there is a chance that no other Volume is mounted // for the user (ex: if the user is just started), so /mnt/user/user_id does not exist yet. auto mountDirStatus = PrepareMountDirForUser(started_user); if (mountDirStatus != OK) { LOG(ERROR) << "Failed to create Mount Directory for user " << started_user; } auto bindMountStatus = bindMountForUser(started_user); if (bindMountStatus != OK) { LOG(ERROR) << "Bind Mounting Public Volume: " << stableName << " for user: " << started_user << "Failed. Error: " << bindMountStatus; } } return OK; } status_t PublicVolume::bindMountForUser(userid_t user_id) { userid_t mountUserId = getMountUserId(); std::string stableName = getId(); if (!mFsUuid.empty()) { stableName = mFsUuid; } LOG(INFO) << "Bind Mounting Public Volume for user: " << user_id << ".Mount owner: " << mountUserId; auto sourcePath = GetFuseMountPathForUser(mountUserId, stableName); auto destPath = GetFuseMountPathForUser(user_id, stableName); PrepareDir(destPath, 0770, AID_ROOT, AID_MEDIA_RW); auto mountRes = BindMount(sourcePath, destPath); LOG(INFO) << "Mount status: " << mountRes; return mountRes; } status_t PublicVolume::doUnmount() { // Unmount the storage before we kill the FUSE process. If we kill // the FUSE process first, most file system operations will return // ENOTCONN until the unmount completes. This is an exotic and unusual // error code and might cause broken behaviour in applications. KillProcessesUsingPath(getPath()); if (mFuseMounted) { // Use UUID as stable name, if available std::string stableName = getId(); if (!mFsUuid.empty()) { stableName = mFsUuid; } // Unmount bind mounts for running users auto vol_manager = VolumeManager::Instance(); int user_id = getMountUserId(); for (int started_user : vol_manager->getStartedUsers()) { if (started_user == user_id) { // No need to remove bind mount for the user that owns the mount continue; } LOG(INFO) << "Removing Public Volume Bind Mount for: " << started_user; auto mountPath = GetFuseMountPathForUser(started_user, stableName); ForceUnmount(mountPath); rmdir(mountPath.c_str()); } if (UnmountUserFuse(getMountUserId(), getInternalPath(), stableName) != OK) { PLOG(INFO) << "UnmountUserFuse failed on public fuse volume"; return -errno; } mFuseMounted = false; } ForceUnmount(kAsecPath); if (mUseSdcardFs) { ForceUnmount(mSdcardFsDefault); ForceUnmount(mSdcardFsRead); ForceUnmount(mSdcardFsWrite); ForceUnmount(mSdcardFsFull); rmdir(mSdcardFsDefault.c_str()); rmdir(mSdcardFsRead.c_str()); rmdir(mSdcardFsWrite.c_str()); rmdir(mSdcardFsFull.c_str()); mSdcardFsDefault.clear(); mSdcardFsRead.clear(); mSdcardFsWrite.clear(); mSdcardFsFull.clear(); } if (ForceUnmount(mRawPath) != 0){ umount2(mRawPath.c_str(),MNT_DETACH); PLOG(INFO) << "use umount lazy if force unmount fail"; } if(rmdir(mRawPath.c_str()) != 0) { PLOG(INFO) << "rmdir mRawPath=" << mRawPath << " fail"; KillProcessesUsingPath(getPath()); } mRawPath.clear(); return OK; } status_t PublicVolume::doFormat(const std::string& fsType) { bool isVfatSup = vfat::IsSupported(); bool isExfatSup = exfat::IsSupported(); status_t res = OK; enum { NONE, VFAT, EXFAT } fsPick = NONE; // Resolve auto requests if (fsType == "auto" && isVfatSup && isExfatSup) { uint64_t size = 0; res = GetBlockDevSize(mDevPath, &size); if (res != OK) { LOG(ERROR) << "Couldn't get device size " << mDevPath; return res; } // If both vfat & exfat are supported use exfat for SDXC (>~32GiB) cards if (size > 32896LL * 1024 * 1024) { fsPick = EXFAT; } else { fsPick = VFAT; } } else if (fsType == "auto" && isExfatSup) { fsPick = EXFAT; } else if (fsType == "auto" && isVfatSup) { fsPick = VFAT; } // Resolve explicit requests if (fsType == "vfat" && isVfatSup) { fsPick = VFAT; } else if (fsType == "exfat" && isExfatSup) { fsPick = EXFAT; } if (WipeBlockDevice(mDevPath) != OK) { LOG(WARNING) << getId() << " failed to wipe"; } if (fsPick == VFAT) { res = vfat::Format(mDevPath, 0); } else if (fsPick == EXFAT) { res = exfat::Format(mDevPath); } else { LOG(ERROR) << "Unsupported filesystem " << fsType; return -EINVAL; } if (res != OK) { LOG(ERROR) << getId() << " failed to format"; res = -errno; } return res; } } // namespace vold } // namespace android