/* * Copyright (C) 2008 The Android Open Source Project * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE * COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS * OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include "system_properties/system_properties.h" #include #include #include #include #include #include #include #include #include #include #include #include "private/ErrnoRestorer.h" #include "private/bionic_futex.h" #include "system_properties/context_node.h" #include "system_properties/prop_area.h" #include "system_properties/prop_info.h" #define SERIAL_DIRTY(serial) ((serial)&1) #define SERIAL_VALUE_LEN(serial) ((serial) >> 24) #define APPCOMPAT_PREFIX "ro.appcompat_override." static bool is_dir(const char* pathname) { struct stat info; if (stat(pathname, &info) == -1) { return false; } return S_ISDIR(info.st_mode); } bool SystemProperties::Init(const char* filename) { // This is called from __libc_init_common, and should leave errno at 0 (http://b/37248982). ErrnoRestorer errno_restorer; if (initialized_) { contexts_->ResetAccess(); return true; } properties_filename_ = filename; if (!InitContexts(false)) { return false; } initialized_ = true; return true; } bool SystemProperties::InitContexts(bool load_default_path) { if (is_dir(properties_filename_.c_str())) { if (access(PROP_TREE_FILE, R_OK) == 0) { auto serial_contexts = new (contexts_data_) ContextsSerialized(); contexts_ = serial_contexts; if (!serial_contexts->Initialize(false, properties_filename_.c_str(), nullptr, load_default_path)) { return false; } } else { contexts_ = new (contexts_data_) ContextsSplit(); if (!contexts_->Initialize(false, properties_filename_.c_str(), nullptr)) { return false; } } } else { contexts_ = new (contexts_data_) ContextsPreSplit(); if (!contexts_->Initialize(false, properties_filename_.c_str(), nullptr)) { return false; } } return true; } bool SystemProperties::AreaInit(const char* filename, bool* fsetxattr_failed) { return AreaInit(filename, fsetxattr_failed, false); } // Note: load_default_path is only used for testing, as it will cause properties to be loaded from // one file (specified by PropertyInfoAreaFile.LoadDefaultPath), but be written to "filename". bool SystemProperties::AreaInit(const char* filename, bool* fsetxattr_failed, bool load_default_path) { properties_filename_ = filename; auto serial_contexts = new (contexts_data_) ContextsSerialized(); contexts_ = serial_contexts; if (!serial_contexts->Initialize(true, properties_filename_.c_str(), fsetxattr_failed, load_default_path)) { return false; } appcompat_filename_ = PropertiesFilename(properties_filename_.c_str(), "appcompat_override"); appcompat_override_contexts_ = nullptr; if (access(appcompat_filename_.c_str(), F_OK) != -1) { auto* appcompat_contexts = new (appcompat_override_contexts_data_) ContextsSerialized(); if (!appcompat_contexts->Initialize(true, appcompat_filename_.c_str(), fsetxattr_failed, load_default_path)) { // The appcompat folder exists, but initializing it failed return false; } else { appcompat_override_contexts_ = appcompat_contexts; } } initialized_ = true; return true; } bool SystemProperties::Reload(bool load_default_path) { if (!initialized_) { return true; } return InitContexts(load_default_path); } uint32_t SystemProperties::AreaSerial() { if (!initialized_) { return -1; } prop_area* pa = contexts_->GetSerialPropArea(); if (!pa) { return -1; } // Make sure this read fulfilled before __system_property_serial return atomic_load_explicit(pa->serial(), memory_order_acquire); } const prop_info* SystemProperties::Find(const char* name) { if (!initialized_) { return nullptr; } prop_area* pa = contexts_->GetPropAreaForName(name); if (!pa) { async_safe_format_log(ANDROID_LOG_WARN, "libc", "Access denied finding property \"%s\"", name); return nullptr; } return pa->find(name); } static bool is_appcompat_override(const char* name) { return strncmp(name, APPCOMPAT_PREFIX, strlen(APPCOMPAT_PREFIX)) == 0; } static bool is_read_only(const char* name) { return strncmp(name, "ro.", 3) == 0; } uint32_t SystemProperties::ReadMutablePropertyValue(const prop_info* pi, char* value) { // We assume the memcpy below gets serialized by the acquire fence. uint32_t new_serial = load_const_atomic(&pi->serial, memory_order_acquire); uint32_t serial; unsigned int len; for (;;) { serial = new_serial; len = SERIAL_VALUE_LEN(serial); if (__predict_false(SERIAL_DIRTY(serial))) { // See the comment in the prop_area constructor. prop_area* pa = contexts_->GetPropAreaForName(pi->name); memcpy(value, pa->dirty_backup_area(), len + 1); } else { memcpy(value, pi->value, len + 1); } atomic_thread_fence(memory_order_acquire); new_serial = load_const_atomic(&pi->serial, memory_order_relaxed); if (__predict_true(serial == new_serial)) { break; } // We need another fence here because we want to ensure that the memcpy in the // next iteration of the loop occurs after the load of new_serial above. We could // get this guarantee by making the load_const_atomic of new_serial // memory_order_acquire instead of memory_order_relaxed, but then we'd pay the // penalty of the memory_order_acquire even in the overwhelmingly common case // that the serial number didn't change. atomic_thread_fence(memory_order_acquire); } return serial; } int SystemProperties::Read(const prop_info* pi, char* name, char* value) { uint32_t serial = ReadMutablePropertyValue(pi, value); if (name != nullptr) { size_t namelen = strlcpy(name, pi->name, PROP_NAME_MAX); if (namelen >= PROP_NAME_MAX) { async_safe_format_log(ANDROID_LOG_ERROR, "libc", "The property name length for \"%s\" is >= %d;" " please use __system_property_read_callback" " to read this property. (the name is truncated to \"%s\")", pi->name, PROP_NAME_MAX - 1, name); } } if (is_read_only(pi->name) && pi->is_long()) { async_safe_format_log( ANDROID_LOG_ERROR, "libc", "The property \"%s\" has a value with length %zu that is too large for" " __system_property_get()/__system_property_read(); use" " __system_property_read_callback() instead.", pi->name, strlen(pi->long_value())); } return SERIAL_VALUE_LEN(serial); } void SystemProperties::ReadCallback(const prop_info* pi, void (*callback)(void* cookie, const char* name, const char* value, uint32_t serial), void* cookie) { // Read only properties don't need to copy the value to a temporary buffer, since it can never // change. We use relaxed memory order on the serial load for the same reason. if (is_read_only(pi->name)) { uint32_t serial = load_const_atomic(&pi->serial, memory_order_relaxed); if (pi->is_long()) { callback(cookie, pi->name, pi->long_value(), serial); } else { callback(cookie, pi->name, pi->value, serial); } return; } char value_buf[PROP_VALUE_MAX]; uint32_t serial = ReadMutablePropertyValue(pi, value_buf); callback(cookie, pi->name, value_buf, serial); } int SystemProperties::Get(const char* name, char* value) { const prop_info* pi = Find(name); if (pi != nullptr) { return Read(pi, nullptr, value); } else { value[0] = 0; return 0; } } int SystemProperties::Update(prop_info* pi, const char* value, unsigned int len) { if (len >= PROP_VALUE_MAX) { return -1; } if (!initialized_) { return -1; } bool have_override = appcompat_override_contexts_ != nullptr; prop_area* serial_pa = contexts_->GetSerialPropArea(); prop_area* override_serial_pa = have_override ? appcompat_override_contexts_->GetSerialPropArea() : nullptr; if (!serial_pa) { return -1; } prop_area* pa = contexts_->GetPropAreaForName(pi->name); prop_area* override_pa = have_override ? appcompat_override_contexts_->GetPropAreaForName(pi->name) : nullptr; if (__predict_false(!pa)) { async_safe_format_log(ANDROID_LOG_ERROR, "libc", "Could not find area for \"%s\"", pi->name); return -1; } CHECK(!have_override || (override_pa && override_serial_pa)); auto* override_pi = const_cast(have_override ? override_pa->find(pi->name) : nullptr); uint32_t serial = atomic_load_explicit(&pi->serial, memory_order_relaxed); unsigned int old_len = SERIAL_VALUE_LEN(serial); // The contract with readers is that whenever the dirty bit is set, an undamaged copy // of the pre-dirty value is available in the dirty backup area. The fence ensures // that we publish our dirty area update before allowing readers to see a // dirty serial. memcpy(pa->dirty_backup_area(), pi->value, old_len + 1); if (have_override) { memcpy(override_pa->dirty_backup_area(), override_pi->value, old_len + 1); } atomic_thread_fence(memory_order_release); serial |= 1; atomic_store_explicit(&pi->serial, serial, memory_order_relaxed); strlcpy(pi->value, value, len + 1); if (have_override) { atomic_store_explicit(&override_pi->serial, serial, memory_order_relaxed); strlcpy(override_pi->value, value, len + 1); } // Now the primary value property area is up-to-date. Let readers know that they should // look at the property value instead of the backup area. atomic_thread_fence(memory_order_release); int new_serial = (len << 24) | ((serial + 1) & 0xffffff); atomic_store_explicit(&pi->serial, new_serial, memory_order_relaxed); if (have_override) { atomic_store_explicit(&override_pi->serial, new_serial, memory_order_relaxed); } __futex_wake(&pi->serial, INT32_MAX); // Fence by side effect atomic_store_explicit(serial_pa->serial(), atomic_load_explicit(serial_pa->serial(), memory_order_relaxed) + 1, memory_order_release); if (have_override) { atomic_store_explicit(override_serial_pa->serial(), atomic_load_explicit(serial_pa->serial(), memory_order_relaxed) + 1, memory_order_release); } __futex_wake(serial_pa->serial(), INT32_MAX); return 0; } int SystemProperties::Add(const char* name, unsigned int namelen, const char* value, unsigned int valuelen) { if (namelen < 1) { async_safe_format_log(ANDROID_LOG_ERROR, "libc", "__system_property_add failed: name length 0"); return -1; } if (valuelen >= PROP_VALUE_MAX && !is_read_only(name)) { async_safe_format_log(ANDROID_LOG_ERROR, "libc", "__system_property_add failed: \"%s\" value too long: %d >= PROP_VALUE_MAX", name, valuelen); return -1; } if (!initialized_) { async_safe_format_log(ANDROID_LOG_ERROR, "libc", "__system_property_add failed: properties not initialized"); return -1; } prop_area* serial_pa = contexts_->GetSerialPropArea(); if (serial_pa == nullptr) { async_safe_format_log(ANDROID_LOG_ERROR, "libc", "__system_property_add failed: property area not found"); return -1; } prop_area* pa = contexts_->GetPropAreaForName(name); if (!pa) { async_safe_format_log(ANDROID_LOG_ERROR, "libc", "__system_property_add failed: access denied for \"%s\"", name); return -1; } if (!pa->add(name, namelen, value, valuelen)) { async_safe_format_log(ANDROID_LOG_ERROR, "libc", "__system_property_add failed: add failed for \"%s\"", name); return -1; } if (appcompat_override_contexts_ != nullptr) { bool is_override = is_appcompat_override(name); const char* override_name = name; if (is_override) override_name += strlen(APPCOMPAT_PREFIX); prop_area* other_pa = appcompat_override_contexts_->GetPropAreaForName(override_name); prop_area* other_serial_pa = appcompat_override_contexts_->GetSerialPropArea(); CHECK(other_pa && other_serial_pa); // We may write a property twice to overrides, once for the ro.*, and again for the // ro.appcompat_override.ro.* property. If we've already written, then we should essentially // perform an Update, not an Add. auto other_pi = const_cast(other_pa->find(override_name)); if (!other_pi) { if (other_pa->add(override_name, strlen(override_name), value, valuelen)) { atomic_store_explicit( other_serial_pa->serial(), atomic_load_explicit(other_serial_pa->serial(), memory_order_relaxed) + 1, memory_order_release); } } else if (is_override) { // We already wrote the ro.*, but appcompat_override.ro.* should override that. We don't // need to do the usual dirty bit setting, as this only happens during the init process, // before any readers are started. Check that only init or root can write appcompat props. CHECK(getpid() == 1 || getuid() == 0); atomic_thread_fence(memory_order_release); strlcpy(other_pi->value, value, valuelen + 1); } } // There is only a single mutator, but we want to make sure that // updates are visible to a reader waiting for the update. atomic_store_explicit(serial_pa->serial(), atomic_load_explicit(serial_pa->serial(), memory_order_relaxed) + 1, memory_order_release); __futex_wake(serial_pa->serial(), INT32_MAX); return 0; } uint32_t SystemProperties::WaitAny(uint32_t old_serial) { uint32_t new_serial; Wait(nullptr, old_serial, &new_serial, nullptr); return new_serial; } bool SystemProperties::Wait(const prop_info* pi, uint32_t old_serial, uint32_t* new_serial_ptr, const timespec* relative_timeout) { // Are we waiting on the global serial or a specific serial? atomic_uint_least32_t* serial_ptr; if (pi == nullptr) { if (!initialized_) { return -1; } prop_area* serial_pa = contexts_->GetSerialPropArea(); if (serial_pa == nullptr) { return -1; } serial_ptr = serial_pa->serial(); } else { serial_ptr = const_cast(&pi->serial); } uint32_t new_serial; do { int rc; if ((rc = __futex_wait(serial_ptr, old_serial, relative_timeout)) != 0 && rc == -ETIMEDOUT) { return false; } new_serial = load_const_atomic(serial_ptr, memory_order_acquire); } while (new_serial == old_serial); *new_serial_ptr = new_serial; return true; } const prop_info* SystemProperties::FindNth(unsigned n) { struct find_nth { const uint32_t sought; uint32_t current; const prop_info* result; explicit find_nth(uint32_t n) : sought(n), current(0), result(nullptr) { } static void fn(const prop_info* pi, void* ptr) { find_nth* self = reinterpret_cast(ptr); if (self->current++ == self->sought) self->result = pi; } } state(n); Foreach(find_nth::fn, &state); return state.result; } int SystemProperties::Foreach(void (*propfn)(const prop_info* pi, void* cookie), void* cookie) { if (!initialized_) { return -1; } contexts_->ForEach(propfn, cookie); return 0; }