/* * Copyright (C) 2008 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 "builtins.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "action.h" #include "bootchart.h" #include "init.h" #include "parser.h" #include "property_service.h" #include "reboot.h" #include "rlimit_parser.h" #include "service.h" #include "util.h" using namespace std::literals::string_literals; using android::base::unique_fd; #define chmod DO_NOT_USE_CHMOD_USE_FCHMODAT_SYMLINK_NOFOLLOW namespace android { namespace init { static constexpr std::chrono::nanoseconds kCommandRetryTimeout = 5s; static Result reboot_into_recovery(const std::vector& options) { std::string err; if (!write_bootloader_message(options, &err)) { return Error() << "Failed to set bootloader message: " << err; } property_set("sys.powerctl", "reboot,recovery"); return Success(); } template static void ForEachServiceInClass(const std::string& classname, F function) { for (const auto& service : ServiceList::GetInstance()) { if (service->classnames().count(classname)) std::invoke(function, service); } } static Result do_class_start(const std::vector& args) { // Starting a class does not start services which are explicitly disabled. // They must be started individually. ForEachServiceInClass(args[1], &Service::StartIfNotDisabled); return Success(); } static Result do_class_stop(const std::vector& args) { ForEachServiceInClass(args[1], &Service::Stop); return Success(); } static Result do_class_reset(const std::vector& args) { ForEachServiceInClass(args[1], &Service::Reset); return Success(); } static Result do_class_restart(const std::vector& args) { ForEachServiceInClass(args[1], &Service::Restart); return Success(); } static Result do_domainname(const std::vector& args) { if (auto result = WriteFile("/proc/sys/kernel/domainname", args[1]); !result) { return Error() << "Unable to write to /proc/sys/kernel/domainname: " << result.error(); } return Success(); } static Result do_enable(const std::vector& args) { Service* svc = ServiceList::GetInstance().FindService(args[1]); if (!svc) return Error() << "Could not find service"; if (auto result = svc->Enable(); !result) { return Error() << "Could not enable service: " << result.error(); } return Success(); } static Result do_exec(const std::vector& args) { auto service = Service::MakeTemporaryOneshotService(args); if (!service) { return Error() << "Could not create exec service"; } if (auto result = service->ExecStart(); !result) { return Error() << "Could not start exec service: " << result.error(); } ServiceList::GetInstance().AddService(std::move(service)); return Success(); } static Result do_exec_background(const std::vector& args) { auto service = Service::MakeTemporaryOneshotService(args); if (!service) { return Error() << "Could not create exec background service"; } if (auto result = service->Start(); !result) { return Error() << "Could not start exec background service: " << result.error(); } ServiceList::GetInstance().AddService(std::move(service)); return Success(); } static Result do_exec_start(const std::vector& args) { Service* service = ServiceList::GetInstance().FindService(args[1]); if (!service) { return Error() << "Service not found"; } if (auto result = service->ExecStart(); !result) { return Error() << "Could not start exec service: " << result.error(); } return Success(); } static Result do_export(const std::vector& args) { if (setenv(args[1].c_str(), args[2].c_str(), 1) == -1) { return ErrnoError() << "setenv() failed"; } return Success(); } static Result do_hostname(const std::vector& args) { if (auto result = WriteFile("/proc/sys/kernel/hostname", args[1]); !result) { return Error() << "Unable to write to /proc/sys/kernel/hostname: " << result.error(); } return Success(); } static Result do_ifup(const std::vector& args) { struct ifreq ifr; strlcpy(ifr.ifr_name, args[1].c_str(), IFNAMSIZ); unique_fd s(TEMP_FAILURE_RETRY(socket(AF_INET, SOCK_DGRAM, 0))); if (s < 0) return ErrnoError() << "opening socket failed"; if (ioctl(s, SIOCGIFFLAGS, &ifr) < 0) { return ErrnoError() << "ioctl(..., SIOCGIFFLAGS, ...) failed"; } ifr.ifr_flags |= IFF_UP; if (ioctl(s, SIOCSIFFLAGS, &ifr) < 0) { return ErrnoError() << "ioctl(..., SIOCSIFFLAGS, ...) failed"; } return Success(); } static Result do_insmod(const std::vector& args) { int flags = 0; auto it = args.begin() + 1; if (!(*it).compare("-f")) { flags = MODULE_INIT_IGNORE_VERMAGIC | MODULE_INIT_IGNORE_MODVERSIONS; it++; } std::string filename = *it++; std::string options = android::base::Join(std::vector(it, args.end()), ' '); unique_fd fd(TEMP_FAILURE_RETRY(open(filename.c_str(), O_RDONLY | O_NOFOLLOW | O_CLOEXEC))); if (fd == -1) return ErrnoError() << "open(\"" << filename << "\") failed"; int rc = syscall(__NR_finit_module, fd.get(), options.c_str(), flags); if (rc == -1) return ErrnoError() << "finit_module for \"" << filename << "\" failed"; return Success(); } // mkdir [mode] [owner] [group] static Result do_mkdir(const std::vector& args) { mode_t mode = 0755; if (args.size() >= 3) { mode = std::strtoul(args[2].c_str(), 0, 8); } if (!make_dir(args[1], mode)) { /* chmod in case the directory already exists */ if (errno == EEXIST) { if (fchmodat(AT_FDCWD, args[1].c_str(), mode, AT_SYMLINK_NOFOLLOW) == -1) { return ErrnoError() << "fchmodat() failed"; } } else { return ErrnoError() << "mkdir() failed"; } } if (args.size() >= 4) { auto uid = DecodeUid(args[3]); if (!uid) { return Error() << "Unable to decode UID for '" << args[3] << "': " << uid.error(); } Result gid = -1; if (args.size() == 5) { gid = DecodeUid(args[4]); if (!gid) { return Error() << "Unable to decode GID for '" << args[3] << "': " << gid.error(); } } if (lchown(args[1].c_str(), *uid, *gid) == -1) { return ErrnoError() << "lchown failed"; } /* chown may have cleared S_ISUID and S_ISGID, chmod again */ if (mode & (S_ISUID | S_ISGID)) { if (fchmodat(AT_FDCWD, args[1].c_str(), mode, AT_SYMLINK_NOFOLLOW) == -1) { return ErrnoError() << "fchmodat failed"; } } } if (e4crypt_is_native()) { if (e4crypt_set_directory_policy(args[1].c_str())) { const std::vector options = { "--prompt_and_wipe_data", "--reason=set_policy_failed:"s + args[1]}; reboot_into_recovery(options); return Success(); } } return Success(); } /* umount */ static Result do_umount(const std::vector& args) { if (umount(args[1].c_str()) < 0) { return ErrnoError() << "umount() failed"; } return Success(); } static struct { const char *name; unsigned flag; } mount_flags[] = { { "noatime", MS_NOATIME }, { "noexec", MS_NOEXEC }, { "nosuid", MS_NOSUID }, { "nodev", MS_NODEV }, { "nodiratime", MS_NODIRATIME }, { "ro", MS_RDONLY }, { "rw", 0 }, { "remount", MS_REMOUNT }, { "bind", MS_BIND }, { "rec", MS_REC }, { "unbindable", MS_UNBINDABLE }, { "private", MS_PRIVATE }, { "slave", MS_SLAVE }, { "shared", MS_SHARED }, { "defaults", 0 }, { 0, 0 }, }; #define DATA_MNT_POINT "/data" /* mount */ static Result do_mount(const std::vector& args) { const char* options = nullptr; unsigned flags = 0; bool wait = false; for (size_t na = 4; na < args.size(); na++) { size_t i; for (i = 0; mount_flags[i].name; i++) { if (!args[na].compare(mount_flags[i].name)) { flags |= mount_flags[i].flag; break; } } if (!mount_flags[i].name) { if (!args[na].compare("wait")) { wait = true; // If our last argument isn't a flag, wolf it up as an option string. } else if (na + 1 == args.size()) { options = args[na].c_str(); } } } const char* system = args[1].c_str(); const char* source = args[2].c_str(); const char* target = args[3].c_str(); if (android::base::StartsWith(source, "loop@")) { int mode = (flags & MS_RDONLY) ? O_RDONLY : O_RDWR; unique_fd fd(TEMP_FAILURE_RETRY(open(source + 5, mode | O_CLOEXEC))); if (fd < 0) return ErrnoError() << "open(" << source + 5 << ", " << mode << ") failed"; for (size_t n = 0;; n++) { std::string tmp = android::base::StringPrintf("/dev/block/loop%zu", n); unique_fd loop(TEMP_FAILURE_RETRY(open(tmp.c_str(), mode | O_CLOEXEC))); if (loop < 0) return ErrnoError() << "open(" << tmp << ", " << mode << ") failed"; loop_info info; /* if it is a blank loop device */ if (ioctl(loop, LOOP_GET_STATUS, &info) < 0 && errno == ENXIO) { /* if it becomes our loop device */ if (ioctl(loop, LOOP_SET_FD, fd.get()) >= 0) { if (mount(tmp.c_str(), target, system, flags, options) < 0) { ioctl(loop, LOOP_CLR_FD, 0); return ErrnoError() << "mount() failed"; } return Success(); } } } return Error() << "out of loopback devices"; } else { if (wait) wait_for_file(source, kCommandRetryTimeout); if (mount(source, target, system, flags, options) < 0) { return ErrnoError() << "mount() failed"; } } return Success(); } /* Imports .rc files from the specified paths. Default ones are applied if none is given. * * start_index: index of the first path in the args list */ static void import_late(const std::vector& args, size_t start_index, size_t end_index) { auto& action_manager = ActionManager::GetInstance(); auto& service_list = ServiceList::GetInstance(); Parser parser = CreateParser(action_manager, service_list); if (end_index <= start_index) { // Fallbacks for partitions on which early mount isn't enabled. for (const auto& path : late_import_paths) { parser.ParseConfig(path); } late_import_paths.clear(); } else { for (size_t i = start_index; i < end_index; ++i) { parser.ParseConfig(args[i]); } } // Turning this on and letting the INFO logging be discarded adds 0.2s to // Nexus 9 boot time, so it's disabled by default. if (false) DumpState(); } /* mount_fstab * * Call fs_mgr_mount_all() to mount the given fstab */ static Result mount_fstab(const char* fstabfile, int mount_mode) { /* * Call fs_mgr_mount_all() to mount all filesystems. We fork(2) and * do the call in the child to provide protection to the main init * process if anything goes wrong (crash or memory leak), and wait for * the child to finish in the parent. */ pid_t pid = fork(); if (pid > 0) { /* Parent. Wait for the child to return */ int status; int wp_ret = TEMP_FAILURE_RETRY(waitpid(pid, &status, 0)); if (wp_ret == -1) { // Unexpected error code. We will continue anyway. PLOG(WARNING) << "waitpid failed"; } if (WIFEXITED(status)) { return WEXITSTATUS(status); } else { return Error() << "child aborted"; } } else if (pid == 0) { /* child, call fs_mgr_mount_all() */ // So we can always see what fs_mgr_mount_all() does. // Only needed if someone explicitly changes the default log level in their init.rc. android::base::ScopedLogSeverity info(android::base::INFO); struct fstab* fstab = fs_mgr_read_fstab(fstabfile); int child_ret = fs_mgr_mount_all(fstab, mount_mode); fs_mgr_free_fstab(fstab); if (child_ret == -1) { PLOG(ERROR) << "fs_mgr_mount_all returned an error"; } _exit(child_ret); } else { return Error() << "fork() failed"; } } /* Queue event based on fs_mgr return code. * * code: return code of fs_mgr_mount_all * * This function might request a reboot, in which case it will * not return. * * return code is processed based on input code */ static Result queue_fs_event(int code) { if (code == FS_MGR_MNTALL_DEV_NEEDS_ENCRYPTION) { ActionManager::GetInstance().QueueEventTrigger("encrypt"); return Success(); } else if (code == FS_MGR_MNTALL_DEV_MIGHT_BE_ENCRYPTED) { property_set("ro.crypto.state", "encrypted"); property_set("ro.crypto.type", "block"); ActionManager::GetInstance().QueueEventTrigger("defaultcrypto"); return Success(); } else if (code == FS_MGR_MNTALL_DEV_NOT_ENCRYPTED) { property_set("ro.crypto.state", "unencrypted"); ActionManager::GetInstance().QueueEventTrigger("nonencrypted"); return Success(); } else if (code == FS_MGR_MNTALL_DEV_NOT_ENCRYPTABLE) { property_set("ro.crypto.state", "unsupported"); ActionManager::GetInstance().QueueEventTrigger("nonencrypted"); return Success(); } else if (code == FS_MGR_MNTALL_DEV_NEEDS_RECOVERY) { /* Setup a wipe via recovery, and reboot into recovery */ PLOG(ERROR) << "fs_mgr_mount_all suggested recovery, so wiping data via recovery."; const std::vector options = {"--wipe_data", "--reason=fs_mgr_mount_all" }; reboot_into_recovery(options); return Success(); /* If reboot worked, there is no return. */ } else if (code == FS_MGR_MNTALL_DEV_FILE_ENCRYPTED) { if (e4crypt_install_keyring()) { return Error() << "e4crypt_install_keyring() failed"; } property_set("ro.crypto.state", "encrypted"); property_set("ro.crypto.type", "file"); // Although encrypted, we have device key, so we do not need to // do anything different from the nonencrypted case. ActionManager::GetInstance().QueueEventTrigger("nonencrypted"); return Success(); } else if (code > 0) { Error() << "fs_mgr_mount_all() returned unexpected error " << code; } /* else ... < 0: error */ return Error() << "Invalid code: " << code; } /* mount_all [ ]* [--]* * * This function might request a reboot, in which case it will * not return. */ static Result do_mount_all(const std::vector& args) { std::size_t na = 0; bool import_rc = true; bool queue_event = true; int mount_mode = MOUNT_MODE_DEFAULT; const char* fstabfile = args[1].c_str(); std::size_t path_arg_end = args.size(); const char* prop_post_fix = "default"; for (na = args.size() - 1; na > 1; --na) { if (args[na] == "--early") { path_arg_end = na; queue_event = false; mount_mode = MOUNT_MODE_EARLY; prop_post_fix = "early"; } else if (args[na] == "--late") { path_arg_end = na; import_rc = false; mount_mode = MOUNT_MODE_LATE; prop_post_fix = "late"; } } std::string prop_name = "ro.boottime.init.mount_all."s + prop_post_fix; android::base::Timer t; auto mount_fstab_return_code = mount_fstab(fstabfile, mount_mode); if (!mount_fstab_return_code) { return Error() << "mount_fstab() failed " << mount_fstab_return_code.error(); } property_set(prop_name, std::to_string(t.duration().count())); if (import_rc) { /* Paths of .rc files are specified at the 2nd argument and beyond */ import_late(args, 2, path_arg_end); } if (queue_event) { /* queue_fs_event will queue event based on mount_fstab return code * and return processed return code*/ auto queue_fs_result = queue_fs_event(*mount_fstab_return_code); if (!queue_fs_result) { return Error() << "queue_fs_event() failed: " << queue_fs_result.error(); } } return Success(); } static Result do_swapon_all(const std::vector& args) { struct fstab *fstab; int ret; fstab = fs_mgr_read_fstab(args[1].c_str()); ret = fs_mgr_swapon_all(fstab); fs_mgr_free_fstab(fstab); if (ret != 0) return Error() << "fs_mgr_swapon_all() failed"; return Success(); } static Result do_setprop(const std::vector& args) { property_set(args[1], args[2]); return Success(); } static Result do_setrlimit(const std::vector& args) { auto rlimit = ParseRlimit(args); if (!rlimit) return rlimit.error(); if (setrlimit(rlimit->first, &rlimit->second) == -1) { return ErrnoError() << "setrlimit failed"; } return Success(); } static Result do_start(const std::vector& args) { Service* svc = ServiceList::GetInstance().FindService(args[1]); if (!svc) return Error() << "service " << args[1] << " not found"; if (auto result = svc->Start(); !result) { return Error() << "Could not start service: " << result.error(); } return Success(); } static Result do_stop(const std::vector& args) { Service* svc = ServiceList::GetInstance().FindService(args[1]); if (!svc) return Error() << "service " << args[1] << " not found"; svc->Stop(); return Success(); } static Result do_restart(const std::vector& args) { Service* svc = ServiceList::GetInstance().FindService(args[1]); if (!svc) return Error() << "service " << args[1] << " not found"; svc->Restart(); return Success(); } static Result do_trigger(const std::vector& args) { ActionManager::GetInstance().QueueEventTrigger(args[1]); return Success(); } static Result do_symlink(const std::vector& args) { if (symlink(args[1].c_str(), args[2].c_str()) < 0) { // The symlink builtin is often used to create symlinks for older devices to be backwards // compatible with new paths, therefore we skip reporting this error. if (errno == EEXIST && android::base::GetMinimumLogSeverity() > android::base::DEBUG) { return Success(); } return ErrnoError() << "symlink() failed"; } return Success(); } static Result do_rm(const std::vector& args) { if (unlink(args[1].c_str()) < 0) { return ErrnoError() << "unlink() failed"; } return Success(); } static Result do_rmdir(const std::vector& args) { if (rmdir(args[1].c_str()) < 0) { return ErrnoError() << "rmdir() failed"; } return Success(); } static Result do_sysclktz(const std::vector& args) { struct timezone tz = {}; if (!android::base::ParseInt(args[1], &tz.tz_minuteswest)) { return Error() << "Unable to parse mins_west_of_gmt"; } if (settimeofday(nullptr, &tz) == -1) { return ErrnoError() << "settimeofday() failed"; } return Success(); } static Result do_verity_load_state(const std::vector& args) { int mode = -1; bool loaded = fs_mgr_load_verity_state(&mode); if (loaded && mode != VERITY_MODE_DEFAULT) { ActionManager::GetInstance().QueueEventTrigger("verity-logging"); } if (!loaded) return Error() << "Could not load verity state"; return Success(); } static void verity_update_property(fstab_rec *fstab, const char *mount_point, int mode, int status) { property_set("partition."s + mount_point + ".verified", std::to_string(mode)); } static Result do_verity_update_state(const std::vector& args) { if (!fs_mgr_update_verity_state(verity_update_property)) { return Error() << "fs_mgr_update_verity_state() failed"; } return Success(); } static Result do_write(const std::vector& args) { if (auto result = WriteFile(args[1], args[2]); !result) { return Error() << "Unable to write to file '" << args[1] << "': " << result.error(); } return Success(); } static Result readahead_file(const std::string& filename, bool fully) { android::base::unique_fd fd(TEMP_FAILURE_RETRY(open(filename.c_str(), O_RDONLY))); if (fd == -1) { return ErrnoError() << "Error opening file"; } if (posix_fadvise(fd, 0, 0, POSIX_FADV_WILLNEED)) { return ErrnoError() << "Error posix_fadvise file"; } if (readahead(fd, 0, std::numeric_limits::max())) { return ErrnoError() << "Error readahead file"; } if (fully) { char buf[BUFSIZ]; ssize_t n; while ((n = TEMP_FAILURE_RETRY(read(fd, &buf[0], sizeof(buf)))) > 0) { } if (n != 0) { return ErrnoError() << "Error reading file"; } } return Success(); } static Result do_readahead(const std::vector& args) { struct stat sb; if (stat(args[1].c_str(), &sb)) { return ErrnoError() << "Error opening " << args[1]; } bool readfully = false; if (args.size() == 3 && args[2] == "--fully") { readfully = true; } // We will do readahead in a forked process in order not to block init // since it may block while it reads the // filesystem metadata needed to locate the requested blocks. This // occurs frequently with ext[234] on large files using indirect blocks // instead of extents, giving the appearance that the call blocks until // the requested data has been read. pid_t pid = fork(); if (pid == 0) { if (setpriority(PRIO_PROCESS, 0, static_cast(ANDROID_PRIORITY_LOWEST)) != 0) { PLOG(WARNING) << "setpriority failed"; } if (android_set_ioprio(0, IoSchedClass_IDLE, 7)) { PLOG(WARNING) << "ioprio_get failed"; } android::base::Timer t; if (S_ISREG(sb.st_mode)) { if (auto result = readahead_file(args[1], readfully); !result) { LOG(WARNING) << "Unable to readahead '" << args[1] << "': " << result.error(); _exit(EXIT_FAILURE); } } else if (S_ISDIR(sb.st_mode)) { char* paths[] = {const_cast(args[1].data()), nullptr}; std::unique_ptr fts( fts_open(paths, FTS_PHYSICAL | FTS_NOCHDIR | FTS_XDEV, nullptr), fts_close); if (!fts) { PLOG(ERROR) << "Error opening directory: " << args[1]; _exit(EXIT_FAILURE); } // Traverse the entire hierarchy and do readahead for (FTSENT* ftsent = fts_read(fts.get()); ftsent != nullptr; ftsent = fts_read(fts.get())) { if (ftsent->fts_info & FTS_F) { const std::string filename = ftsent->fts_accpath; if (auto result = readahead_file(filename, readfully); !result) { LOG(WARNING) << "Unable to readahead '" << filename << "': " << result.error(); } } } } LOG(INFO) << "Readahead " << args[1] << " took " << t << " asynchronously"; _exit(0); } else if (pid < 0) { return ErrnoError() << "Fork failed"; } return Success(); } static Result do_copy(const std::vector& args) { auto file_contents = ReadFile(args[1]); if (!file_contents) { return Error() << "Could not read input file '" << args[1] << "': " << file_contents.error(); } if (auto result = WriteFile(args[2], *file_contents); !result) { return Error() << "Could not write to output file '" << args[2] << "': " << result.error(); } return Success(); } static Result do_chown(const std::vector& args) { auto uid = DecodeUid(args[1]); if (!uid) { return Error() << "Unable to decode UID for '" << args[1] << "': " << uid.error(); } // GID is optional and pushes the index of path out by one if specified. const std::string& path = (args.size() == 4) ? args[3] : args[2]; Result gid = -1; if (args.size() == 4) { gid = DecodeUid(args[2]); if (!gid) { return Error() << "Unable to decode GID for '" << args[2] << "': " << gid.error(); } } if (lchown(path.c_str(), *uid, *gid) == -1) { return ErrnoError() << "lchown() failed"; } return Success(); } static mode_t get_mode(const char *s) { mode_t mode = 0; while (*s) { if (*s >= '0' && *s <= '7') { mode = (mode<<3) | (*s-'0'); } else { return -1; } s++; } return mode; } static Result do_chmod(const std::vector& args) { mode_t mode = get_mode(args[1].c_str()); if (fchmodat(AT_FDCWD, args[2].c_str(), mode, AT_SYMLINK_NOFOLLOW) < 0) { return ErrnoError() << "fchmodat() failed"; } return Success(); } static Result do_restorecon(const std::vector& args) { int ret = 0; struct flag_type {const char* name; int value;}; static const flag_type flags[] = { {"--recursive", SELINUX_ANDROID_RESTORECON_RECURSE}, {"--skip-ce", SELINUX_ANDROID_RESTORECON_SKIPCE}, {"--cross-filesystems", SELINUX_ANDROID_RESTORECON_CROSS_FILESYSTEMS}, {0, 0} }; int flag = 0; bool in_flags = true; for (size_t i = 1; i < args.size(); ++i) { if (android::base::StartsWith(args[i], "--")) { if (!in_flags) { return Error() << "flags must precede paths"; } bool found = false; for (size_t j = 0; flags[j].name; ++j) { if (args[i] == flags[j].name) { flag |= flags[j].value; found = true; break; } } if (!found) { return Error() << "bad flag " << args[i]; } } else { in_flags = false; if (selinux_android_restorecon(args[i].c_str(), flag) < 0) { ret = errno; } } } if (ret) return ErrnoError() << "selinux_android_restorecon() failed"; return Success(); } static Result do_restorecon_recursive(const std::vector& args) { std::vector non_const_args(args); non_const_args.insert(std::next(non_const_args.begin()), "--recursive"); return do_restorecon(non_const_args); } static Result do_loglevel(const std::vector& args) { // TODO: support names instead/as well? int log_level = -1; android::base::ParseInt(args[1], &log_level); android::base::LogSeverity severity; switch (log_level) { case 7: severity = android::base::DEBUG; break; case 6: severity = android::base::INFO; break; case 5: case 4: severity = android::base::WARNING; break; case 3: severity = android::base::ERROR; break; case 2: case 1: case 0: severity = android::base::FATAL; break; default: return Error() << "invalid log level " << log_level; } android::base::SetMinimumLogSeverity(severity); return Success(); } static Result do_load_persist_props(const std::vector& args) { load_persist_props(); return Success(); } static Result do_load_system_props(const std::vector& args) { load_system_props(); return Success(); } static Result do_wait(const std::vector& args) { auto timeout = kCommandRetryTimeout; if (args.size() == 3) { int timeout_int; if (!android::base::ParseInt(args[2], &timeout_int)) { return Error() << "failed to parse timeout"; } timeout = std::chrono::seconds(timeout_int); } if (wait_for_file(args[1].c_str(), timeout) != 0) { return Error() << "wait_for_file() failed"; } return Success(); } static Result do_wait_for_prop(const std::vector& args) { const char* name = args[1].c_str(); const char* value = args[2].c_str(); size_t value_len = strlen(value); if (!is_legal_property_name(name)) { return Error() << "is_legal_property_name(" << name << ") failed"; } if (value_len >= PROP_VALUE_MAX) { return Error() << "value too long"; } if (!start_waiting_for_property(name, value)) { return Error() << "already waiting for a property"; } return Success(); } static bool is_file_crypto() { return android::base::GetProperty("ro.crypto.type", "") == "file"; } static Result do_installkey(const std::vector& args) { if (!is_file_crypto()) return Success(); auto unencrypted_dir = args[1] + e4crypt_unencrypted_folder; if (!make_dir(unencrypted_dir, 0700) && errno != EEXIST) { return ErrnoError() << "Failed to create " << unencrypted_dir; } std::vector exec_args = {"exec", "/system/bin/vdc", "--wait", "cryptfs", "enablefilecrypto"}; return do_exec(exec_args); } static Result do_init_user0(const std::vector& args) { std::vector exec_args = {"exec", "/system/bin/vdc", "--wait", "cryptfs", "init_user0"}; return do_exec(exec_args); } const BuiltinFunctionMap::Map& BuiltinFunctionMap::map() const { constexpr std::size_t kMax = std::numeric_limits::max(); // clang-format off static const Map builtin_functions = { {"bootchart", {1, 1, do_bootchart}}, {"chmod", {2, 2, do_chmod}}, {"chown", {2, 3, do_chown}}, {"class_reset", {1, 1, do_class_reset}}, {"class_restart", {1, 1, do_class_restart}}, {"class_start", {1, 1, do_class_start}}, {"class_stop", {1, 1, do_class_stop}}, {"copy", {2, 2, do_copy}}, {"domainname", {1, 1, do_domainname}}, {"enable", {1, 1, do_enable}}, {"exec", {1, kMax, do_exec}}, {"exec_background", {1, kMax, do_exec_background}}, {"exec_start", {1, 1, do_exec_start}}, {"export", {2, 2, do_export}}, {"hostname", {1, 1, do_hostname}}, {"ifup", {1, 1, do_ifup}}, {"init_user0", {0, 0, do_init_user0}}, {"insmod", {1, kMax, do_insmod}}, {"installkey", {1, 1, do_installkey}}, {"load_persist_props", {0, 0, do_load_persist_props}}, {"load_system_props", {0, 0, do_load_system_props}}, {"loglevel", {1, 1, do_loglevel}}, {"mkdir", {1, 4, do_mkdir}}, {"mount_all", {1, kMax, do_mount_all}}, {"mount", {3, kMax, do_mount}}, {"umount", {1, 1, do_umount}}, {"readahead", {1, 2, do_readahead}}, {"restart", {1, 1, do_restart}}, {"restorecon", {1, kMax, do_restorecon}}, {"restorecon_recursive", {1, kMax, do_restorecon_recursive}}, {"rm", {1, 1, do_rm}}, {"rmdir", {1, 1, do_rmdir}}, {"setprop", {2, 2, do_setprop}}, {"setrlimit", {3, 3, do_setrlimit}}, {"start", {1, 1, do_start}}, {"stop", {1, 1, do_stop}}, {"swapon_all", {1, 1, do_swapon_all}}, {"symlink", {2, 2, do_symlink}}, {"sysclktz", {1, 1, do_sysclktz}}, {"trigger", {1, 1, do_trigger}}, {"verity_load_state", {0, 0, do_verity_load_state}}, {"verity_update_state", {0, 0, do_verity_update_state}}, {"wait", {1, 2, do_wait}}, {"wait_for_prop", {2, 2, do_wait_for_prop}}, {"write", {2, 2, do_write}}, }; // clang-format on return builtin_functions; } } // namespace init } // namespace android