/* * Copyright (C) 2007 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 "property_service.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define _REALLY_INCLUDE_SYS__SYSTEM_PROPERTIES_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 "debug_ramdisk.h" #include "epoll.h" #include "init.h" #include "persistent_properties.h" #include "property_type.h" #include "proto_utils.h" #include "second_stage_resources.h" #include "selinux.h" #include "subcontext.h" #include "system/core/init/property_service.pb.h" #include "util.h" using namespace std::literals; using android::base::ErrnoError; using android::base::Error; using android::base::GetProperty; using android::base::ParseInt; using android::base::ReadFileToString; using android::base::Result; using android::base::Split; using android::base::StartsWith; using android::base::StringPrintf; using android::base::Timer; using android::base::Trim; using android::base::unique_fd; using android::base::WriteStringToFile; using android::properties::BuildTrie; using android::properties::ParsePropertyInfoFile; using android::properties::PropertyInfoAreaFile; using android::properties::PropertyInfoEntry; using android::sysprop::InitProperties::is_userspace_reboot_supported; namespace android { namespace init { class PersistWriteThread; constexpr auto FINGERPRINT_PROP = "ro.build.fingerprint"; constexpr auto LEGACY_FINGERPRINT_PROP = "ro.build.legacy.fingerprint"; constexpr auto ID_PROP = "ro.build.id"; constexpr auto LEGACY_ID_PROP = "ro.build.legacy.id"; constexpr auto VBMETA_DIGEST_PROP = "ro.boot.vbmeta.digest"; constexpr auto DIGEST_SIZE_USED = 8; constexpr auto API_LEVEL_CURRENT = 10000; static bool persistent_properties_loaded = false; static int property_set_fd = -1; static int from_init_socket = -1; static int init_socket = -1; static bool accept_messages = false; static std::mutex accept_messages_lock; static std::thread property_service_thread; static std::unique_ptr persist_write_thread; static PropertyInfoAreaFile property_info_area; struct PropertyAuditData { const ucred* cr; const char* name; }; static int PropertyAuditCallback(void* data, security_class_t /*cls*/, char* buf, size_t len) { auto* d = reinterpret_cast(data); if (!d || !d->name || !d->cr) { LOG(ERROR) << "AuditCallback invoked with null data arguments!"; return 0; } snprintf(buf, len, "property=%s pid=%d uid=%d gid=%d", d->name, d->cr->pid, d->cr->uid, d->cr->gid); return 0; } void StartSendingMessages() { auto lock = std::lock_guard{accept_messages_lock}; accept_messages = true; } void StopSendingMessages() { auto lock = std::lock_guard{accept_messages_lock}; accept_messages = false; } bool CanReadProperty(const std::string& source_context, const std::string& name) { const char* target_context = nullptr; property_info_area->GetPropertyInfo(name.c_str(), &target_context, nullptr); PropertyAuditData audit_data; audit_data.name = name.c_str(); ucred cr = {.pid = 0, .uid = 0, .gid = 0}; audit_data.cr = &cr; return selinux_check_access(source_context.c_str(), target_context, "file", "read", &audit_data) == 0; } static bool CheckMacPerms(const std::string& name, const char* target_context, const char* source_context, const ucred& cr) { if (!target_context || !source_context) { return false; } PropertyAuditData audit_data; audit_data.name = name.c_str(); audit_data.cr = &cr; bool has_access = (selinux_check_access(source_context, target_context, "property_service", "set", &audit_data) == 0); return has_access; } void NotifyPropertyChange(const std::string& name, const std::string& value) { // If init hasn't started its main loop, then it won't be handling property changed messages // anyway, so there's no need to try to send them. auto lock = std::lock_guard{accept_messages_lock}; if (accept_messages) { PropertyChanged(name, value); } } class AsyncRestorecon { public: void TriggerRestorecon(const std::string& path) { auto guard = std::lock_guard{mutex_}; paths_.emplace(path); if (!thread_started_) { thread_started_ = true; std::thread{&AsyncRestorecon::ThreadFunction, this}.detach(); } } private: void ThreadFunction() { auto lock = std::unique_lock{mutex_}; while (!paths_.empty()) { auto path = paths_.front(); paths_.pop(); lock.unlock(); if (selinux_android_restorecon(path.c_str(), SELINUX_ANDROID_RESTORECON_RECURSE) != 0) { LOG(ERROR) << "Asynchronous restorecon of '" << path << "' failed'"; } android::base::SetProperty(kRestoreconProperty, path); lock.lock(); } thread_started_ = false; } std::mutex mutex_; std::queue paths_; bool thread_started_ = false; }; class SocketConnection { public: SocketConnection() = default; SocketConnection(int socket, const ucred& cred) : socket_(socket), cred_(cred) {} SocketConnection(SocketConnection&&) = default; bool RecvUint32(uint32_t* value, uint32_t* timeout_ms) { return RecvFully(value, sizeof(*value), timeout_ms); } bool RecvChars(char* chars, size_t size, uint32_t* timeout_ms) { return RecvFully(chars, size, timeout_ms); } bool RecvString(std::string* value, uint32_t* timeout_ms) { uint32_t len = 0; if (!RecvUint32(&len, timeout_ms)) { return false; } if (len == 0) { *value = ""; return true; } // http://b/35166374: don't allow init to make arbitrarily large allocations. if (len > 0xffff) { LOG(ERROR) << "sys_prop: RecvString asked to read huge string: " << len; errno = ENOMEM; return false; } std::vector chars(len); if (!RecvChars(&chars[0], len, timeout_ms)) { return false; } *value = std::string(&chars[0], len); return true; } bool SendUint32(uint32_t value) { if (!socket_.ok()) { return true; } int result = TEMP_FAILURE_RETRY(send(socket_.get(), &value, sizeof(value), 0)); return result == sizeof(value); } bool GetSourceContext(std::string* source_context) const { char* c_source_context = nullptr; if (getpeercon(socket_.get(), &c_source_context) != 0) { return false; } *source_context = c_source_context; freecon(c_source_context); return true; } [[nodiscard]] int Release() { return socket_.release(); } const ucred& cred() { return cred_; } SocketConnection& operator=(SocketConnection&&) = default; private: bool PollIn(uint32_t* timeout_ms) { struct pollfd ufd = { .fd = socket_.get(), .events = POLLIN, }; while (*timeout_ms > 0) { auto start_time = std::chrono::steady_clock::now(); int nr = poll(&ufd, 1, *timeout_ms); auto now = std::chrono::steady_clock::now(); auto time_elapsed = std::chrono::duration_cast(now - start_time); uint64_t millis = time_elapsed.count(); *timeout_ms = (millis > *timeout_ms) ? 0 : *timeout_ms - millis; if (nr > 0) { return true; } if (nr == 0) { // Timeout break; } if (nr < 0 && errno != EINTR) { PLOG(ERROR) << "sys_prop: error waiting for uid " << cred_.uid << " to send property message"; return false; } else { // errno == EINTR // Timer rounds milliseconds down in case of EINTR we want it to be rounded up // to avoid slowing init down by causing EINTR with under millisecond timeout. if (*timeout_ms > 0) { --(*timeout_ms); } } } LOG(ERROR) << "sys_prop: timeout waiting for uid " << cred_.uid << " to send property message."; return false; } bool RecvFully(void* data_ptr, size_t size, uint32_t* timeout_ms) { size_t bytes_left = size; char* data = static_cast(data_ptr); while (*timeout_ms > 0 && bytes_left > 0) { if (!PollIn(timeout_ms)) { return false; } int result = TEMP_FAILURE_RETRY(recv(socket_.get(), data, bytes_left, MSG_DONTWAIT)); if (result <= 0) { PLOG(ERROR) << "sys_prop: recv error"; return false; } bytes_left -= result; data += result; } if (bytes_left != 0) { LOG(ERROR) << "sys_prop: recv data is not properly obtained."; } return bytes_left == 0; } unique_fd socket_; ucred cred_; DISALLOW_COPY_AND_ASSIGN(SocketConnection); }; class PersistWriteThread { public: PersistWriteThread(); void Write(std::string name, std::string value, SocketConnection socket); private: void Work(); private: std::thread thread_; std::mutex mutex_; std::condition_variable cv_; std::deque> work_; }; static std::optional PropertySet(const std::string& name, const std::string& value, SocketConnection* socket, std::string* error) { size_t valuelen = value.size(); if (!IsLegalPropertyName(name)) { *error = "Illegal property name"; return {PROP_ERROR_INVALID_NAME}; } if (auto result = IsLegalPropertyValue(name, value); !result.ok()) { *error = result.error().message(); return {PROP_ERROR_INVALID_VALUE}; } prop_info* pi = (prop_info*)__system_property_find(name.c_str()); if (pi != nullptr) { // ro.* properties are actually "write-once". if (StartsWith(name, "ro.")) { *error = "Read-only property was already set"; return {PROP_ERROR_READ_ONLY_PROPERTY}; } __system_property_update(pi, value.c_str(), valuelen); } else { int rc = __system_property_add(name.c_str(), name.size(), value.c_str(), valuelen); if (rc < 0) { *error = "__system_property_add failed"; return {PROP_ERROR_SET_FAILED}; } } // Don't write properties to disk until after we have read all default // properties to prevent them from being overwritten by default values. if (socket && persistent_properties_loaded && StartsWith(name, "persist.")) { if (persist_write_thread) { persist_write_thread->Write(name, value, std::move(*socket)); return {}; } WritePersistentProperty(name, value); } NotifyPropertyChange(name, value); return {PROP_SUCCESS}; } // Helper for PropertySet, for the case where no socket is used, and therefore an asynchronous // return is not possible. static uint32_t PropertySetNoSocket(const std::string& name, const std::string& value, std::string* error) { auto ret = PropertySet(name, value, nullptr, error); CHECK(ret.has_value()); return *ret; } static uint32_t SendControlMessage(const std::string& msg, const std::string& name, pid_t pid, SocketConnection* socket, std::string* error) { auto lock = std::lock_guard{accept_messages_lock}; if (!accept_messages) { *error = "Received control message after shutdown, ignoring"; return PROP_ERROR_HANDLE_CONTROL_MESSAGE; } // We must release the fd before sending it to init, otherwise there will be a race with init. // If init calls close() before Release(), then fdsan will see the wrong tag and abort(). int fd = -1; if (socket != nullptr && SelinuxGetVendorAndroidVersion() > __ANDROID_API_Q__) { fd = socket->Release(); } bool queue_success = QueueControlMessage(msg, name, pid, fd); if (!queue_success && fd != -1) { uint32_t response = PROP_ERROR_HANDLE_CONTROL_MESSAGE; TEMP_FAILURE_RETRY(send(fd, &response, sizeof(response), 0)); close(fd); } return PROP_SUCCESS; } bool CheckControlPropertyPerms(const std::string& name, const std::string& value, const std::string& source_context, const ucred& cr) { // We check the legacy method first but these properties are dontaudit, so we only log an audit // if the newer method fails as well. We only do this with the legacy ctl. properties. if (name == "ctl.start" || name == "ctl.stop" || name == "ctl.restart") { // The legacy permissions model is that ctl. properties have their name ctl. and // their value is the name of the service to apply that action to. Permissions for these // actions are based on the service, so we must create a fake name of ctl. to // check permissions. auto control_string_legacy = "ctl." + value; const char* target_context_legacy = nullptr; const char* type_legacy = nullptr; property_info_area->GetPropertyInfo(control_string_legacy.c_str(), &target_context_legacy, &type_legacy); if (CheckMacPerms(control_string_legacy, target_context_legacy, source_context.c_str(), cr)) { return true; } } auto control_string_full = name + "$" + value; const char* target_context_full = nullptr; const char* type_full = nullptr; property_info_area->GetPropertyInfo(control_string_full.c_str(), &target_context_full, &type_full); return CheckMacPerms(control_string_full, target_context_full, source_context.c_str(), cr); } // This returns one of the enum of PROP_SUCCESS or PROP_ERROR*. uint32_t CheckPermissions(const std::string& name, const std::string& value, const std::string& source_context, const ucred& cr, std::string* error) { if (!IsLegalPropertyName(name)) { *error = "Illegal property name"; return PROP_ERROR_INVALID_NAME; } if (StartsWith(name, "ctl.")) { if (!CheckControlPropertyPerms(name, value, source_context, cr)) { *error = StringPrintf("Invalid permissions to perform '%s' on '%s'", name.c_str() + 4, value.c_str()); return PROP_ERROR_HANDLE_CONTROL_MESSAGE; } return PROP_SUCCESS; } const char* target_context = nullptr; const char* type = nullptr; property_info_area->GetPropertyInfo(name.c_str(), &target_context, &type); if (!CheckMacPerms(name, target_context, source_context.c_str(), cr)) { *error = "SELinux permission check failed"; return PROP_ERROR_PERMISSION_DENIED; } if (!CheckType(type, value)) { *error = StringPrintf("Property type check failed, value doesn't match expected type '%s'", (type ?: "(null)")); return PROP_ERROR_INVALID_VALUE; } return PROP_SUCCESS; } // This returns one of the enum of PROP_SUCCESS or PROP_ERROR*, or std::nullopt // if asynchronous. std::optional HandlePropertySet(const std::string& name, const std::string& value, const std::string& source_context, const ucred& cr, SocketConnection* socket, std::string* error) { if (auto ret = CheckPermissions(name, value, source_context, cr, error); ret != PROP_SUCCESS) { return {ret}; } if (StartsWith(name, "ctl.")) { return {SendControlMessage(name.c_str() + 4, value, cr.pid, socket, error)}; } // sys.powerctl is a special property that is used to make the device reboot. We want to log // any process that sets this property to be able to accurately blame the cause of a shutdown. if (name == "sys.powerctl") { std::string cmdline_path = StringPrintf("proc/%d/cmdline", cr.pid); std::string process_cmdline; std::string process_log_string; if (ReadFileToString(cmdline_path, &process_cmdline)) { // Since cmdline is null deliminated, .c_str() conveniently gives us just the process // path. process_log_string = StringPrintf(" (%s)", process_cmdline.c_str()); } LOG(INFO) << "Received sys.powerctl='" << value << "' from pid: " << cr.pid << process_log_string; if (!value.empty()) { DebugRebootLogging(); } if (value == "reboot,userspace" && !is_userspace_reboot_supported().value_or(false)) { *error = "Userspace reboot is not supported by this device"; return {PROP_ERROR_INVALID_VALUE}; } } // If a process other than init is writing a non-empty value, it means that process is // requesting that init performs a restorecon operation on the path specified by 'value'. // We use a thread to do this restorecon operation to prevent holding up init, as it may take // a long time to complete. if (name == kRestoreconProperty && cr.pid != 1 && !value.empty()) { static AsyncRestorecon async_restorecon; async_restorecon.TriggerRestorecon(value); return {PROP_SUCCESS}; } return PropertySet(name, value, socket, error); } // Helper for HandlePropertySet, for the case where no socket is used, and // therefore an asynchronous return is not possible. uint32_t HandlePropertySetNoSocket(const std::string& name, const std::string& value, const std::string& source_context, const ucred& cr, std::string* error) { auto ret = HandlePropertySet(name, value, source_context, cr, nullptr, error); CHECK(ret.has_value()); return *ret; } static void handle_property_set_fd() { static constexpr uint32_t kDefaultSocketTimeout = 2000; /* ms */ int s = accept4(property_set_fd, nullptr, nullptr, SOCK_CLOEXEC); if (s == -1) { return; } ucred cr; socklen_t cr_size = sizeof(cr); if (getsockopt(s, SOL_SOCKET, SO_PEERCRED, &cr, &cr_size) < 0) { close(s); PLOG(ERROR) << "sys_prop: unable to get SO_PEERCRED"; return; } SocketConnection socket(s, cr); uint32_t timeout_ms = kDefaultSocketTimeout; uint32_t cmd = 0; if (!socket.RecvUint32(&cmd, &timeout_ms)) { PLOG(ERROR) << "sys_prop: error while reading command from the socket"; socket.SendUint32(PROP_ERROR_READ_CMD); return; } switch (cmd) { case PROP_MSG_SETPROP: { char prop_name[PROP_NAME_MAX]; char prop_value[PROP_VALUE_MAX]; if (!socket.RecvChars(prop_name, PROP_NAME_MAX, &timeout_ms) || !socket.RecvChars(prop_value, PROP_VALUE_MAX, &timeout_ms)) { PLOG(ERROR) << "sys_prop(PROP_MSG_SETPROP): error while reading name/value from the socket"; return; } prop_name[PROP_NAME_MAX-1] = 0; prop_value[PROP_VALUE_MAX-1] = 0; std::string source_context; if (!socket.GetSourceContext(&source_context)) { PLOG(ERROR) << "Unable to set property '" << prop_name << "': getpeercon() failed"; return; } const auto& cr = socket.cred(); std::string error; auto result = HandlePropertySetNoSocket(prop_name, prop_value, source_context, cr, &error); if (result != PROP_SUCCESS) { LOG(ERROR) << "Unable to set property '" << prop_name << "' from uid:" << cr.uid << " gid:" << cr.gid << " pid:" << cr.pid << ": " << error; } break; } case PROP_MSG_SETPROP2: { std::string name; std::string value; if (!socket.RecvString(&name, &timeout_ms) || !socket.RecvString(&value, &timeout_ms)) { PLOG(ERROR) << "sys_prop(PROP_MSG_SETPROP2): error while reading name/value from the socket"; socket.SendUint32(PROP_ERROR_READ_DATA); return; } std::string source_context; if (!socket.GetSourceContext(&source_context)) { PLOG(ERROR) << "Unable to set property '" << name << "': getpeercon() failed"; socket.SendUint32(PROP_ERROR_PERMISSION_DENIED); return; } // HandlePropertySet takes ownership of the socket if the set is handled asynchronously. const auto& cr = socket.cred(); std::string error; auto result = HandlePropertySet(name, value, source_context, cr, &socket, &error); if (!result) { // Result will be sent after completion. return; } if (*result != PROP_SUCCESS) { LOG(ERROR) << "Unable to set property '" << name << "' from uid:" << cr.uid << " gid:" << cr.gid << " pid:" << cr.pid << ": " << error; } socket.SendUint32(*result); break; } default: LOG(ERROR) << "sys_prop: invalid command " << cmd; socket.SendUint32(PROP_ERROR_INVALID_CMD); break; } } uint32_t InitPropertySet(const std::string& name, const std::string& value) { ucred cr = {.pid = 1, .uid = 0, .gid = 0}; std::string error; auto result = HandlePropertySetNoSocket(name, value, kInitContext, cr, &error); if (result != PROP_SUCCESS) { LOG(ERROR) << "Init cannot set '" << name << "' to '" << value << "': " << error; } return result; } static Result load_properties_from_file(const char*, const char*, std::map*); /* * Filter is used to decide which properties to load: NULL loads all keys, * "ro.foo.*" is a prefix match, and "ro.foo.bar" is an exact match. */ static void LoadProperties(char* data, const char* filter, const char* filename, std::map* properties) { char *key, *value, *eol, *sol, *tmp, *fn; size_t flen = 0; static constexpr const char* const kVendorPathPrefixes[4] = { "/vendor", "/odm", "/vendor_dlkm", "/odm_dlkm", }; const char* context = kInitContext; if (SelinuxGetVendorAndroidVersion() >= __ANDROID_API_P__) { for (const auto& vendor_path_prefix : kVendorPathPrefixes) { if (StartsWith(filename, vendor_path_prefix)) { context = kVendorContext; } } } if (filter) { flen = strlen(filter); } sol = data; while ((eol = strchr(sol, '\n'))) { key = sol; *eol++ = 0; sol = eol; while (isspace(*key)) key++; if (*key == '#') continue; tmp = eol - 2; while ((tmp > key) && isspace(*tmp)) *tmp-- = 0; if (!strncmp(key, "import ", 7) && flen == 0) { fn = key + 7; while (isspace(*fn)) fn++; key = strchr(fn, ' '); if (key) { *key++ = 0; while (isspace(*key)) key++; } std::string raw_filename(fn); auto expanded_filename = ExpandProps(raw_filename); if (!expanded_filename.ok()) { LOG(ERROR) << "Could not expand filename ': " << expanded_filename.error(); continue; } if (auto res = load_properties_from_file(expanded_filename->c_str(), key, properties); !res.ok()) { LOG(WARNING) << res.error(); } } else { value = strchr(key, '='); if (!value) continue; *value++ = 0; tmp = value - 2; while ((tmp > key) && isspace(*tmp)) *tmp-- = 0; while (isspace(*value)) value++; if (flen > 0) { if (filter[flen - 1] == '*') { if (strncmp(key, filter, flen - 1) != 0) continue; } else { if (strcmp(key, filter) != 0) continue; } } if (StartsWith(key, "ctl.") || key == "sys.powerctl"s || std::string{key} == kRestoreconProperty) { LOG(ERROR) << "Ignoring disallowed property '" << key << "' with special meaning in prop file '" << filename << "'"; continue; } ucred cr = {.pid = 1, .uid = 0, .gid = 0}; std::string error; if (CheckPermissions(key, value, context, cr, &error) == PROP_SUCCESS) { auto it = properties->find(key); if (it == properties->end()) { (*properties)[key] = value; } else if (it->second != value) { LOG(WARNING) << "Overriding previous property '" << key << "':'" << it->second << "' with new value '" << value << "'"; it->second = value; } } else { LOG(ERROR) << "Do not have permissions to set '" << key << "' to '" << value << "' in property file '" << filename << "': " << error; } } } } // Filter is used to decide which properties to load: NULL loads all keys, // "ro.foo.*" is a prefix match, and "ro.foo.bar" is an exact match. static Result load_properties_from_file(const char* filename, const char* filter, std::map* properties) { Timer t; auto file_contents = ReadFile(filename); if (!file_contents.ok()) { return Error() << "Couldn't load property file '" << filename << "': " << file_contents.error(); } file_contents->push_back('\n'); LoadProperties(file_contents->data(), filter, filename, properties); LOG(VERBOSE) << "(Loading properties from " << filename << " took " << t << ".)"; return {}; } static void LoadPropertiesFromSecondStageRes(std::map* properties) { std::string prop = GetRamdiskPropForSecondStage(); if (access(prop.c_str(), R_OK) != 0) { CHECK(errno == ENOENT) << "Cannot access " << prop << ": " << strerror(errno); return; } if (auto res = load_properties_from_file(prop.c_str(), nullptr, properties); !res.ok()) { LOG(WARNING) << res.error(); } } // persist.sys.usb.config values can't be combined on build-time when property // files are split into each partition. // So we need to apply the same rule of build/make/tools/post_process_props.py // on runtime. static void update_sys_usb_config() { bool is_debuggable = android::base::GetBoolProperty("ro.debuggable", false); std::string config = android::base::GetProperty("persist.sys.usb.config", ""); // b/150130503, add (config == "none") condition here to prevent appending // ",adb" if "none" is explicitly defined in default prop. if (config.empty() || config == "none") { InitPropertySet("persist.sys.usb.config", is_debuggable ? "adb" : "none"); } else if (is_debuggable && config.find("adb") == std::string::npos && config.length() + 4 < PROP_VALUE_MAX) { config.append(",adb"); InitPropertySet("persist.sys.usb.config", config); } } static void load_override_properties() { if (ALLOW_LOCAL_PROP_OVERRIDE) { std::map properties; load_properties_from_file("/data/local.prop", nullptr, &properties); for (const auto& [name, value] : properties) { std::string error; if (PropertySetNoSocket(name, value, &error) != PROP_SUCCESS) { LOG(ERROR) << "Could not set '" << name << "' to '" << value << "' in /data/local.prop: " << error; } } } } // If the ro.product.[brand|device|manufacturer|model|name] properties have not been explicitly // set, derive them from ro.product.${partition}.* properties static void property_initialize_ro_product_props() { const char* RO_PRODUCT_PROPS_PREFIX = "ro.product."; const char* RO_PRODUCT_PROPS[] = { "brand", "device", "manufacturer", "model", "name", }; const char* RO_PRODUCT_PROPS_ALLOWED_SOURCES[] = { "odm", "product", "system_ext", "system", "vendor", }; const char* RO_PRODUCT_PROPS_DEFAULT_SOURCE_ORDER = "product,odm,vendor,system_ext,system"; const std::string EMPTY = ""; std::string ro_product_props_source_order = GetProperty("ro.product.property_source_order", EMPTY); if (!ro_product_props_source_order.empty()) { // Verify that all specified sources are valid for (const auto& source : Split(ro_product_props_source_order, ",")) { // Verify that the specified source is valid bool is_allowed_source = false; for (const auto& allowed_source : RO_PRODUCT_PROPS_ALLOWED_SOURCES) { if (source == allowed_source) { is_allowed_source = true; break; } } if (!is_allowed_source) { LOG(ERROR) << "Found unexpected source in ro.product.property_source_order; " "using the default property source order"; ro_product_props_source_order = RO_PRODUCT_PROPS_DEFAULT_SOURCE_ORDER; break; } } } else { ro_product_props_source_order = RO_PRODUCT_PROPS_DEFAULT_SOURCE_ORDER; } for (const auto& ro_product_prop : RO_PRODUCT_PROPS) { std::string base_prop(RO_PRODUCT_PROPS_PREFIX); base_prop += ro_product_prop; std::string base_prop_val = GetProperty(base_prop, EMPTY); if (!base_prop_val.empty()) { continue; } for (const auto& source : Split(ro_product_props_source_order, ",")) { std::string target_prop(RO_PRODUCT_PROPS_PREFIX); target_prop += source; target_prop += '.'; target_prop += ro_product_prop; std::string target_prop_val = GetProperty(target_prop, EMPTY); if (!target_prop_val.empty()) { LOG(INFO) << "Setting product property " << base_prop << " to '" << target_prop_val << "' (from " << target_prop << ")"; std::string error; auto res = PropertySetNoSocket(base_prop, target_prop_val, &error); if (res != PROP_SUCCESS) { LOG(ERROR) << "Error setting product property " << base_prop << ": err=" << res << " (" << error << ")"; } break; } } } } static void property_initialize_build_id() { std::string build_id = GetProperty(ID_PROP, ""); if (!build_id.empty()) { return; } std::string legacy_build_id = GetProperty(LEGACY_ID_PROP, ""); std::string vbmeta_digest = GetProperty(VBMETA_DIGEST_PROP, ""); if (vbmeta_digest.size() < DIGEST_SIZE_USED) { LOG(ERROR) << "vbmeta digest size too small " << vbmeta_digest; // Still try to set the id field in the unexpected case. build_id = legacy_build_id; } else { // Derive the ro.build.id by appending the vbmeta digest to the base value. build_id = legacy_build_id + "." + vbmeta_digest.substr(0, DIGEST_SIZE_USED); } std::string error; auto res = PropertySetNoSocket(ID_PROP, build_id, &error); if (res != PROP_SUCCESS) { LOG(ERROR) << "Failed to set " << ID_PROP << " to " << build_id; } } static std::string ConstructBuildFingerprint(bool legacy) { const std::string UNKNOWN = "unknown"; std::string build_fingerprint = GetProperty("ro.product.brand", UNKNOWN); build_fingerprint += '/'; build_fingerprint += GetProperty("ro.product.name", UNKNOWN); build_fingerprint += '/'; build_fingerprint += GetProperty("ro.product.device", UNKNOWN); build_fingerprint += ':'; build_fingerprint += GetProperty("ro.build.version.release_or_codename", UNKNOWN); build_fingerprint += '/'; std::string build_id = legacy ? GetProperty(LEGACY_ID_PROP, UNKNOWN) : GetProperty(ID_PROP, UNKNOWN); build_fingerprint += build_id; build_fingerprint += '/'; build_fingerprint += GetProperty("ro.build.version.incremental", UNKNOWN); build_fingerprint += ':'; build_fingerprint += GetProperty("ro.build.type", UNKNOWN); build_fingerprint += '/'; build_fingerprint += GetProperty("ro.build.tags", UNKNOWN); return build_fingerprint; } // Derive the legacy build fingerprint if we overwrite the build id at runtime. static void property_derive_legacy_build_fingerprint() { std::string legacy_build_fingerprint = GetProperty(LEGACY_FINGERPRINT_PROP, ""); if (!legacy_build_fingerprint.empty()) { return; } // The device doesn't have a legacy build id, skipping the legacy fingerprint. std::string legacy_build_id = GetProperty(LEGACY_ID_PROP, ""); if (legacy_build_id.empty()) { return; } legacy_build_fingerprint = ConstructBuildFingerprint(true /* legacy fingerprint */); LOG(INFO) << "Setting property '" << LEGACY_FINGERPRINT_PROP << "' to '" << legacy_build_fingerprint << "'"; std::string error; auto res = PropertySetNoSocket(LEGACY_FINGERPRINT_PROP, legacy_build_fingerprint, &error); if (res != PROP_SUCCESS) { LOG(ERROR) << "Error setting property '" << LEGACY_FINGERPRINT_PROP << "': err=" << res << " (" << error << ")"; } } // If the ro.build.fingerprint property has not been set, derive it from constituent pieces static void property_derive_build_fingerprint() { std::string build_fingerprint = GetProperty("ro.build.fingerprint", ""); if (!build_fingerprint.empty()) { return; } build_fingerprint = ConstructBuildFingerprint(false /* legacy fingerprint */); LOG(INFO) << "Setting property '" << FINGERPRINT_PROP << "' to '" << build_fingerprint << "'"; std::string error; auto res = PropertySetNoSocket(FINGERPRINT_PROP, build_fingerprint, &error); if (res != PROP_SUCCESS) { LOG(ERROR) << "Error setting property '" << FINGERPRINT_PROP << "': err=" << res << " (" << error << ")"; } } // If the ro.product.cpu.abilist* properties have not been explicitly // set, derive them from ro.${partition}.product.cpu.abilist* properties. static void property_initialize_ro_cpu_abilist() { // From high to low priority. const char* kAbilistSources[] = { "product", "odm", "vendor", "system", }; const std::string EMPTY = ""; const char* kAbilistProp = "ro.product.cpu.abilist"; const char* kAbilist32Prop = "ro.product.cpu.abilist32"; const char* kAbilist64Prop = "ro.product.cpu.abilist64"; // If the properties are defined explicitly, just use them. if (GetProperty(kAbilistProp, EMPTY) != EMPTY) { return; } // Find the first source defining these properties by order. std::string abilist32_prop_val; std::string abilist64_prop_val; for (const auto& source : kAbilistSources) { const auto abilist32_prop = std::string("ro.") + source + ".product.cpu.abilist32"; const auto abilist64_prop = std::string("ro.") + source + ".product.cpu.abilist64"; abilist32_prop_val = GetProperty(abilist32_prop, EMPTY); abilist64_prop_val = GetProperty(abilist64_prop, EMPTY); // The properties could be empty on 32-bit-only or 64-bit-only devices, // but we cannot identify a property is empty or undefined by GetProperty(). // So, we assume both of these 2 properties are empty as undefined. if (abilist32_prop_val != EMPTY || abilist64_prop_val != EMPTY) { break; } } // Merge ABI lists for ro.product.cpu.abilist auto abilist_prop_val = abilist64_prop_val; if (abilist32_prop_val != EMPTY) { if (abilist_prop_val != EMPTY) { abilist_prop_val += ","; } abilist_prop_val += abilist32_prop_val; } // Set these properties const std::pair set_prop_list[] = { {kAbilistProp, abilist_prop_val}, {kAbilist32Prop, abilist32_prop_val}, {kAbilist64Prop, abilist64_prop_val}, }; for (const auto& [prop, prop_val] : set_prop_list) { LOG(INFO) << "Setting property '" << prop << "' to '" << prop_val << "'"; std::string error; auto res = PropertySetNoSocket(prop, prop_val, &error); if (res != PROP_SUCCESS) { LOG(ERROR) << "Error setting property '" << prop << "': err=" << res << " (" << error << ")"; } } } static int read_api_level_props(const std::vector& api_level_props) { int api_level = API_LEVEL_CURRENT; for (const auto& api_level_prop : api_level_props) { api_level = android::base::GetIntProperty(api_level_prop, API_LEVEL_CURRENT); if (api_level != API_LEVEL_CURRENT) { break; } } return api_level; } static void property_initialize_ro_vendor_api_level() { // ro.vendor.api_level shows the api_level that the vendor images (vendor, odm, ...) are // required to support. constexpr auto VENDOR_API_LEVEL_PROP = "ro.vendor.api_level"; // Api level properties of the board. The order of the properties must be kept. std::vector BOARD_API_LEVEL_PROPS = {"ro.board.api_level", "ro.board.first_api_level"}; // Api level properties of the device. The order of the properties must be kept. std::vector DEVICE_API_LEVEL_PROPS = {"ro.product.first_api_level", "ro.build.version.sdk"}; int api_level = std::min(read_api_level_props(BOARD_API_LEVEL_PROPS), read_api_level_props(DEVICE_API_LEVEL_PROPS)); std::string error; auto res = PropertySetNoSocket(VENDOR_API_LEVEL_PROP, std::to_string(api_level), &error); if (res != PROP_SUCCESS) { LOG(ERROR) << "Failed to set " << VENDOR_API_LEVEL_PROP << " with " << api_level << ": " << error << "(" << res << ")"; } } void PropertyLoadBootDefaults() { // We read the properties and their values into a map, in order to always allow properties // loaded in the later property files to override the properties in loaded in the earlier // property files, regardless of if they are "ro." properties or not. std::map properties; if (IsRecoveryMode()) { if (auto res = load_properties_from_file("/prop.default", nullptr, &properties); !res.ok()) { LOG(ERROR) << res.error(); } } // //etc/build.prop is the canonical location of the build-time properties since S. // Falling back to //defalt.prop and //build.prop only when legacy path has to // be supported, which is controlled by the support_legacy_path_until argument. const auto load_properties_from_partition = [&properties](const std::string& partition, int support_legacy_path_until) { auto path = "/" + partition + "/etc/build.prop"; if (load_properties_from_file(path.c_str(), nullptr, &properties).ok()) { return; } // To read ro..build.version.sdk, temporarily load the legacy paths into a // separate map. Then by comparing its value with legacy_version, we know that if the // partition is old enough so that we need to respect the legacy paths. std::map temp; auto legacy_path1 = "/" + partition + "/default.prop"; auto legacy_path2 = "/" + partition + "/build.prop"; load_properties_from_file(legacy_path1.c_str(), nullptr, &temp); load_properties_from_file(legacy_path2.c_str(), nullptr, &temp); bool support_legacy_path = false; auto version_prop_name = "ro." + partition + ".build.version.sdk"; auto it = temp.find(version_prop_name); if (it == temp.end()) { // This is embarassing. Without the prop, we can't determine how old the partition is. // Let's be conservative by assuming it is very very old. support_legacy_path = true; } else if (int value; ParseInt(it->second.c_str(), &value) && value <= support_legacy_path_until) { support_legacy_path = true; } if (support_legacy_path) { // We don't update temp into properties directly as it might skip any (future) logic // for resolving duplicates implemented in load_properties_from_file. Instead, read // the files again into the properties map. load_properties_from_file(legacy_path1.c_str(), nullptr, &properties); load_properties_from_file(legacy_path2.c_str(), nullptr, &properties); } else { LOG(FATAL) << legacy_path1 << " and " << legacy_path2 << " were not loaded " << "because " << version_prop_name << "(" << it->second << ") is newer " << "than " << support_legacy_path_until; } }; // Order matters here. The more the partition is specific to a product, the higher its // precedence is. LoadPropertiesFromSecondStageRes(&properties); // system should have build.prop, unlike the other partitions if (auto res = load_properties_from_file("/system/build.prop", nullptr, &properties); !res.ok()) { LOG(WARNING) << res.error(); } load_properties_from_partition("system_ext", /* support_legacy_path_until */ 30); load_properties_from_file("/system_dlkm/etc/build.prop", nullptr, &properties); // TODO(b/117892318): uncomment the following condition when vendor.imgs for aosp_* targets are // all updated. // if (SelinuxGetVendorAndroidVersion() <= __ANDROID_API_R__) { load_properties_from_file("/vendor/default.prop", nullptr, &properties); // } load_properties_from_file("/vendor/build.prop", nullptr, &properties); load_properties_from_file("/vendor_dlkm/etc/build.prop", nullptr, &properties); load_properties_from_file("/odm_dlkm/etc/build.prop", nullptr, &properties); load_properties_from_partition("odm", /* support_legacy_path_until */ 28); load_properties_from_partition("product", /* support_legacy_path_until */ 30); if (access(kDebugRamdiskProp, R_OK) == 0) { LOG(INFO) << "Loading " << kDebugRamdiskProp; if (auto res = load_properties_from_file(kDebugRamdiskProp, nullptr, &properties); !res.ok()) { LOG(WARNING) << res.error(); } } for (const auto& [name, value] : properties) { std::string error; if (PropertySetNoSocket(name, value, &error) != PROP_SUCCESS) { LOG(ERROR) << "Could not set '" << name << "' to '" << value << "' while loading .prop files" << error; } } property_initialize_ro_product_props(); property_initialize_build_id(); property_derive_build_fingerprint(); property_derive_legacy_build_fingerprint(); property_initialize_ro_cpu_abilist(); property_initialize_ro_vendor_api_level(); update_sys_usb_config(); } bool LoadPropertyInfoFromFile(const std::string& filename, std::vector* property_infos) { auto file_contents = std::string(); if (!ReadFileToString(filename, &file_contents)) { PLOG(ERROR) << "Could not read properties from '" << filename << "'"; return false; } auto errors = std::vector{}; bool require_prefix_or_exact = SelinuxGetVendorAndroidVersion() >= __ANDROID_API_R__; ParsePropertyInfoFile(file_contents, require_prefix_or_exact, property_infos, &errors); // Individual parsing errors are reported but do not cause a failed boot, which is what // returning false would do here. for (const auto& error : errors) { LOG(ERROR) << "Could not read line from '" << filename << "': " << error; } return true; } void CreateSerializedPropertyInfo() { auto property_infos = std::vector(); if (access("/system/etc/selinux/plat_property_contexts", R_OK) != -1) { if (!LoadPropertyInfoFromFile("/system/etc/selinux/plat_property_contexts", &property_infos)) { return; } // Don't check for failure here, since we don't always have all of these partitions. // E.g. In case of recovery, the vendor partition will not have mounted and we // still need the system / platform properties to function. if (access("/dev/selinux/apex_property_contexts", R_OK) != -1) { LoadPropertyInfoFromFile("/dev/selinux/apex_property_contexts", &property_infos); } if (access("/system_ext/etc/selinux/system_ext_property_contexts", R_OK) != -1) { LoadPropertyInfoFromFile("/system_ext/etc/selinux/system_ext_property_contexts", &property_infos); } if (access("/vendor/etc/selinux/vendor_property_contexts", R_OK) != -1) { LoadPropertyInfoFromFile("/vendor/etc/selinux/vendor_property_contexts", &property_infos); } if (access("/product/etc/selinux/product_property_contexts", R_OK) != -1) { LoadPropertyInfoFromFile("/product/etc/selinux/product_property_contexts", &property_infos); } if (access("/odm/etc/selinux/odm_property_contexts", R_OK) != -1) { LoadPropertyInfoFromFile("/odm/etc/selinux/odm_property_contexts", &property_infos); } } else { if (!LoadPropertyInfoFromFile("/plat_property_contexts", &property_infos)) { return; } LoadPropertyInfoFromFile("/system_ext_property_contexts", &property_infos); LoadPropertyInfoFromFile("/vendor_property_contexts", &property_infos); LoadPropertyInfoFromFile("/product_property_contexts", &property_infos); LoadPropertyInfoFromFile("/odm_property_contexts", &property_infos); LoadPropertyInfoFromFile("/dev/selinux/apex_property_contexts", &property_infos); } auto serialized_contexts = std::string(); auto error = std::string(); if (!BuildTrie(property_infos, "u:object_r:default_prop:s0", "string", &serialized_contexts, &error)) { LOG(ERROR) << "Unable to serialize property contexts: " << error; return; } constexpr static const char kPropertyInfosPath[] = "/dev/__properties__/property_info"; if (!WriteStringToFile(serialized_contexts, kPropertyInfosPath, 0444, 0, 0, false)) { PLOG(ERROR) << "Unable to write serialized property infos to file"; } selinux_android_restorecon(kPropertyInfosPath, 0); } static void ExportKernelBootProps() { constexpr const char* UNSET = ""; struct { const char* src_prop; const char* dst_prop; const char* default_value; } prop_map[] = { // clang-format off { "ro.boot.serialno", "ro.serialno", UNSET, }, { "ro.boot.mode", "ro.bootmode", "unknown", }, { "ro.boot.baseband", "ro.baseband", "unknown", }, { "ro.boot.bootloader", "ro.bootloader", "unknown", }, { "ro.boot.hardware", "ro.hardware", "unknown", }, { "ro.boot.revision", "ro.revision", "0", }, // clang-format on }; for (const auto& prop : prop_map) { std::string value = GetProperty(prop.src_prop, prop.default_value); if (value != UNSET) InitPropertySet(prop.dst_prop, value); } } static void ProcessKernelDt() { if (!is_android_dt_value_expected("compatible", "android,firmware")) { return; } std::unique_ptr dir(opendir(get_android_dt_dir().c_str()), closedir); if (!dir) return; std::string dt_file; struct dirent* dp; while ((dp = readdir(dir.get())) != NULL) { if (dp->d_type != DT_REG || !strcmp(dp->d_name, "compatible") || !strcmp(dp->d_name, "name")) { continue; } std::string file_name = get_android_dt_dir() + dp->d_name; android::base::ReadFileToString(file_name, &dt_file); std::replace(dt_file.begin(), dt_file.end(), ',', '.'); InitPropertySet("ro.boot."s + dp->d_name, dt_file); } } constexpr auto ANDROIDBOOT_PREFIX = "androidboot."sv; static void ProcessKernelCmdline() { ImportKernelCmdline([&](const std::string& key, const std::string& value) { if (StartsWith(key, ANDROIDBOOT_PREFIX)) { InitPropertySet("ro.boot." + key.substr(ANDROIDBOOT_PREFIX.size()), value); } }); } static void ProcessBootconfig() { ImportBootconfig([&](const std::string& key, const std::string& value) { if (StartsWith(key, ANDROIDBOOT_PREFIX)) { InitPropertySet("ro.boot." + key.substr(ANDROIDBOOT_PREFIX.size()), value); } }); } void PropertyInit() { selinux_callback cb; cb.func_audit = PropertyAuditCallback; selinux_set_callback(SELINUX_CB_AUDIT, cb); mkdir("/dev/__properties__", S_IRWXU | S_IXGRP | S_IXOTH); CreateSerializedPropertyInfo(); if (__system_property_area_init()) { LOG(FATAL) << "Failed to initialize property area"; } if (!property_info_area.LoadDefaultPath()) { LOG(FATAL) << "Failed to load serialized property info file"; } // If arguments are passed both on the command line and in DT, // properties set in DT always have priority over the command-line ones. ProcessKernelDt(); ProcessKernelCmdline(); ProcessBootconfig(); // Propagate the kernel variables to internal variables // used by init as well as the current required properties. ExportKernelBootProps(); PropertyLoadBootDefaults(); } static void HandleInitSocket() { auto message = ReadMessage(init_socket); if (!message.ok()) { LOG(ERROR) << "Could not read message from init_dedicated_recv_socket: " << message.error(); return; } auto init_message = InitMessage{}; if (!init_message.ParseFromString(*message)) { LOG(ERROR) << "Could not parse message from init"; return; } switch (init_message.msg_case()) { case InitMessage::kLoadPersistentProperties: { load_override_properties(); // Read persistent properties after all default values have been loaded. auto persistent_properties = LoadPersistentProperties(); for (const auto& persistent_property_record : persistent_properties.properties()) { InitPropertySet(persistent_property_record.name(), persistent_property_record.value()); } // Apply debug ramdisk special settings after persistent properties are loaded. if (android::base::GetBoolProperty("ro.force.debuggable", false)) { // Always enable usb adb if device is booted with debug ramdisk. update_sys_usb_config(); } InitPropertySet("ro.persistent_properties.ready", "true"); persistent_properties_loaded = true; break; } default: LOG(ERROR) << "Unknown message type from init: " << init_message.msg_case(); } } static void PropertyServiceThread() { Epoll epoll; if (auto result = epoll.Open(); !result.ok()) { LOG(FATAL) << result.error(); } if (auto result = epoll.RegisterHandler(property_set_fd, handle_property_set_fd); !result.ok()) { LOG(FATAL) << result.error(); } if (auto result = epoll.RegisterHandler(init_socket, HandleInitSocket); !result.ok()) { LOG(FATAL) << result.error(); } while (true) { auto epoll_result = epoll.Wait(std::nullopt); if (!epoll_result.ok()) { LOG(ERROR) << epoll_result.error(); } } } PersistWriteThread::PersistWriteThread() { auto new_thread = std::thread([this]() -> void { Work(); }); thread_.swap(new_thread); } void PersistWriteThread::Work() { while (true) { std::tuple item; // Grab the next item within the lock. { std::unique_lock lock(mutex_); while (work_.empty()) { cv_.wait(lock); } item = std::move(work_.front()); work_.pop_front(); } std::this_thread::sleep_for(1s); // Perform write/fsync outside the lock. WritePersistentProperty(std::get<0>(item), std::get<1>(item)); NotifyPropertyChange(std::get<0>(item), std::get<1>(item)); SocketConnection& socket = std::get<2>(item); socket.SendUint32(PROP_SUCCESS); } } void PersistWriteThread::Write(std::string name, std::string value, SocketConnection socket) { { std::unique_lock lock(mutex_); work_.emplace_back(std::move(name), std::move(value), std::move(socket)); } cv_.notify_all(); } void StartPropertyService(int* epoll_socket) { InitPropertySet("ro.property_service.version", "2"); int sockets[2]; if (socketpair(AF_UNIX, SOCK_SEQPACKET | SOCK_CLOEXEC, 0, sockets) != 0) { PLOG(FATAL) << "Failed to socketpair() between property_service and init"; } *epoll_socket = from_init_socket = sockets[0]; init_socket = sockets[1]; StartSendingMessages(); if (auto result = CreateSocket(PROP_SERVICE_NAME, SOCK_STREAM | SOCK_CLOEXEC | SOCK_NONBLOCK, /*passcred=*/false, /*should_listen=*/false, 0666, /*uid=*/0, /*gid=*/0, /*socketcon=*/{}); result.ok()) { property_set_fd = *result; } else { LOG(FATAL) << "start_property_service socket creation failed: " << result.error(); } listen(property_set_fd, 8); auto new_thread = std::thread{PropertyServiceThread}; property_service_thread.swap(new_thread); auto async_persist_writes = android::base::GetBoolProperty("ro.property_service.async_persist_writes", false); if (async_persist_writes) { persist_write_thread = std::make_unique(); } } } // namespace init } // namespace android