// Copyright (c) 2012 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "dbus/bus.h" #include "base/bind.h" #include "base/logging.h" #include "base/message_loop/message_loop.h" #include "base/message_loop/message_loop_proxy.h" #include "base/stl_util.h" #include "base/strings/stringprintf.h" #include "base/threading/thread.h" #include "base/threading/thread_restrictions.h" #include "base/time/time.h" #include "dbus/exported_object.h" #include "dbus/message.h" #include "dbus/object_manager.h" #include "dbus/object_path.h" #include "dbus/object_proxy.h" #include "dbus/scoped_dbus_error.h" namespace dbus { namespace { const char kDisconnectedSignal[] = "Disconnected"; const char kDisconnectedMatchRule[] = "type='signal', path='/org/freedesktop/DBus/Local'," "interface='org.freedesktop.DBus.Local', member='Disconnected'"; // The NameOwnerChanged member in org.freedesktop.DBus const char kNameOwnerChangedSignal[] = "NameOwnerChanged"; // The match rule used to filter for changes to a given service name owner. const char kServiceNameOwnerChangeMatchRule[] = "type='signal',interface='org.freedesktop.DBus'," "member='NameOwnerChanged',path='/org/freedesktop/DBus'," "sender='org.freedesktop.DBus',arg0='%s'"; // The class is used for watching the file descriptor used for D-Bus // communication. class Watch : public base::MessagePumpLibevent::Watcher { public: explicit Watch(DBusWatch* watch) : raw_watch_(watch) { dbus_watch_set_data(raw_watch_, this, NULL); } virtual ~Watch() { dbus_watch_set_data(raw_watch_, NULL, NULL); } // Returns true if the underlying file descriptor is ready to be watched. bool IsReadyToBeWatched() { return dbus_watch_get_enabled(raw_watch_); } // Starts watching the underlying file descriptor. void StartWatching() { const int file_descriptor = dbus_watch_get_unix_fd(raw_watch_); const int flags = dbus_watch_get_flags(raw_watch_); base::MessageLoopForIO::Mode mode = base::MessageLoopForIO::WATCH_READ; if ((flags & DBUS_WATCH_READABLE) && (flags & DBUS_WATCH_WRITABLE)) mode = base::MessageLoopForIO::WATCH_READ_WRITE; else if (flags & DBUS_WATCH_READABLE) mode = base::MessageLoopForIO::WATCH_READ; else if (flags & DBUS_WATCH_WRITABLE) mode = base::MessageLoopForIO::WATCH_WRITE; else NOTREACHED(); const bool persistent = true; // Watch persistently. const bool success = base::MessageLoopForIO::current()->WatchFileDescriptor( file_descriptor, persistent, mode, &file_descriptor_watcher_, this); CHECK(success) << "Unable to allocate memory"; } // Stops watching the underlying file descriptor. void StopWatching() { file_descriptor_watcher_.StopWatchingFileDescriptor(); } private: // Implement MessagePumpLibevent::Watcher. virtual void OnFileCanReadWithoutBlocking(int file_descriptor) override { const bool success = dbus_watch_handle(raw_watch_, DBUS_WATCH_READABLE); CHECK(success) << "Unable to allocate memory"; } // Implement MessagePumpLibevent::Watcher. virtual void OnFileCanWriteWithoutBlocking(int file_descriptor) override { const bool success = dbus_watch_handle(raw_watch_, DBUS_WATCH_WRITABLE); CHECK(success) << "Unable to allocate memory"; } DBusWatch* raw_watch_; base::MessagePumpLibevent::FileDescriptorWatcher file_descriptor_watcher_; }; // The class is used for monitoring the timeout used for D-Bus method // calls. // // Unlike Watch, Timeout is a ref counted object, to ensure that |this| of // the object is is alive when HandleTimeout() is called. It's unlikely // but it may be possible that HandleTimeout() is called after // Bus::OnRemoveTimeout(). That's why we don't simply delete the object in // Bus::OnRemoveTimeout(). class Timeout : public base::RefCountedThreadSafe { public: explicit Timeout(DBusTimeout* timeout) : raw_timeout_(timeout), monitoring_is_active_(false), is_completed(false) { dbus_timeout_set_data(raw_timeout_, this, NULL); AddRef(); // Balanced on Complete(). } // Returns true if the timeout is ready to be monitored. bool IsReadyToBeMonitored() { return dbus_timeout_get_enabled(raw_timeout_); } // Starts monitoring the timeout. void StartMonitoring(Bus* bus) { bus->GetDBusTaskRunner()->PostDelayedTask( FROM_HERE, base::Bind(&Timeout::HandleTimeout, this), GetInterval()); monitoring_is_active_ = true; } // Stops monitoring the timeout. void StopMonitoring() { // We cannot take back the delayed task we posted in // StartMonitoring(), so we just mark the monitoring is inactive now. monitoring_is_active_ = false; } // Returns the interval. base::TimeDelta GetInterval() { return base::TimeDelta::FromMilliseconds( dbus_timeout_get_interval(raw_timeout_)); } // Cleans up the raw_timeout and marks that timeout is completed. // See the class comment above for why we are doing this. void Complete() { dbus_timeout_set_data(raw_timeout_, NULL, NULL); is_completed = true; Release(); } private: friend class base::RefCountedThreadSafe; ~Timeout() { } // Handles the timeout. void HandleTimeout() { // If the timeout is marked completed, we should do nothing. This can // occur if this function is called after Bus::OnRemoveTimeout(). if (is_completed) return; // Skip if monitoring is canceled. if (!monitoring_is_active_) return; const bool success = dbus_timeout_handle(raw_timeout_); CHECK(success) << "Unable to allocate memory"; } DBusTimeout* raw_timeout_; bool monitoring_is_active_; bool is_completed; }; } // namespace Bus::Options::Options() : bus_type(SESSION), connection_type(PRIVATE) { } Bus::Options::~Options() { } Bus::Bus(const Options& options) : bus_type_(options.bus_type), connection_type_(options.connection_type), dbus_task_runner_(options.dbus_task_runner), on_shutdown_(false /* manual_reset */, false /* initially_signaled */), connection_(NULL), origin_thread_id_(base::PlatformThread::CurrentId()), async_operations_set_up_(false), shutdown_completed_(false), num_pending_watches_(0), num_pending_timeouts_(0), address_(options.address), on_disconnected_closure_(options.disconnected_callback) { // This is safe to call multiple times. dbus_threads_init_default(); // The origin message loop is unnecessary if the client uses synchronous // functions only. if (base::MessageLoop::current()) origin_task_runner_ = base::MessageLoop::current()->message_loop_proxy(); } Bus::~Bus() { DCHECK(!connection_); DCHECK(owned_service_names_.empty()); DCHECK(match_rules_added_.empty()); DCHECK(filter_functions_added_.empty()); DCHECK(registered_object_paths_.empty()); DCHECK_EQ(0, num_pending_watches_); // TODO(satorux): This check fails occasionally in browser_tests for tests // that run very quickly. Perhaps something does not have time to clean up. // Despite the check failing, the tests seem to run fine. crosbug.com/23416 // DCHECK_EQ(0, num_pending_timeouts_); } ObjectProxy* Bus::GetObjectProxy(const std::string& service_name, const ObjectPath& object_path) { return GetObjectProxyWithOptions(service_name, object_path, ObjectProxy::DEFAULT_OPTIONS); } ObjectProxy* Bus::GetObjectProxyWithOptions(const std::string& service_name, const ObjectPath& object_path, int options) { AssertOnOriginThread(); // Check if we already have the requested object proxy. const ObjectProxyTable::key_type key(service_name + object_path.value(), options); ObjectProxyTable::iterator iter = object_proxy_table_.find(key); if (iter != object_proxy_table_.end()) { return iter->second.get(); } scoped_refptr object_proxy = new ObjectProxy(this, service_name, object_path, options); object_proxy_table_[key] = object_proxy; return object_proxy.get(); } bool Bus::RemoveObjectProxy(const std::string& service_name, const ObjectPath& object_path, const base::Closure& callback) { return RemoveObjectProxyWithOptions(service_name, object_path, ObjectProxy::DEFAULT_OPTIONS, callback); } bool Bus::RemoveObjectProxyWithOptions(const std::string& service_name, const ObjectPath& object_path, int options, const base::Closure& callback) { AssertOnOriginThread(); // Check if we have the requested object proxy. const ObjectProxyTable::key_type key(service_name + object_path.value(), options); ObjectProxyTable::iterator iter = object_proxy_table_.find(key); if (iter != object_proxy_table_.end()) { scoped_refptr object_proxy = iter->second; object_proxy_table_.erase(iter); // Object is present. Remove it now and Detach on the DBus thread. GetDBusTaskRunner()->PostTask( FROM_HERE, base::Bind(&Bus::RemoveObjectProxyInternal, this, object_proxy, callback)); return true; } return false; } void Bus::RemoveObjectProxyInternal(scoped_refptr object_proxy, const base::Closure& callback) { AssertOnDBusThread(); object_proxy.get()->Detach(); GetOriginTaskRunner()->PostTask(FROM_HERE, callback); } ExportedObject* Bus::GetExportedObject(const ObjectPath& object_path) { AssertOnOriginThread(); // Check if we already have the requested exported object. ExportedObjectTable::iterator iter = exported_object_table_.find(object_path); if (iter != exported_object_table_.end()) { return iter->second.get(); } scoped_refptr exported_object = new ExportedObject(this, object_path); exported_object_table_[object_path] = exported_object; return exported_object.get(); } void Bus::UnregisterExportedObject(const ObjectPath& object_path) { AssertOnOriginThread(); // Remove the registered object from the table first, to allow a new // GetExportedObject() call to return a new object, rather than this one. ExportedObjectTable::iterator iter = exported_object_table_.find(object_path); if (iter == exported_object_table_.end()) return; scoped_refptr exported_object = iter->second; exported_object_table_.erase(iter); // Post the task to perform the final unregistration to the D-Bus thread. // Since the registration also happens on the D-Bus thread in // TryRegisterObjectPath(), and the task runner we post to is a // SequencedTaskRunner, there is a guarantee that this will happen before any // future registration call. GetDBusTaskRunner()->PostTask( FROM_HERE, base::Bind(&Bus::UnregisterExportedObjectInternal, this, exported_object)); } void Bus::UnregisterExportedObjectInternal( scoped_refptr exported_object) { AssertOnDBusThread(); exported_object->Unregister(); } ObjectManager* Bus::GetObjectManager(const std::string& service_name, const ObjectPath& object_path) { AssertOnOriginThread(); // Check if we already have the requested object manager. const ObjectManagerTable::key_type key(service_name + object_path.value()); ObjectManagerTable::iterator iter = object_manager_table_.find(key); if (iter != object_manager_table_.end()) { return iter->second.get(); } scoped_refptr object_manager = new ObjectManager(this, service_name, object_path); object_manager_table_[key] = object_manager; return object_manager.get(); } bool Bus::RemoveObjectManager(const std::string& service_name, const ObjectPath& object_path, const base::Closure& callback) { AssertOnOriginThread(); DCHECK(!callback.is_null()); const ObjectManagerTable::key_type key(service_name + object_path.value()); ObjectManagerTable::iterator iter = object_manager_table_.find(key); if (iter == object_manager_table_.end()) return false; // ObjectManager is present. Remove it now and CleanUp on the DBus thread. scoped_refptr object_manager = iter->second; object_manager_table_.erase(iter); GetDBusTaskRunner()->PostTask( FROM_HERE, base::Bind(&Bus::RemoveObjectManagerInternal, this, object_manager, callback)); return true; } void Bus::RemoveObjectManagerInternal( scoped_refptr object_manager, const base::Closure& callback) { AssertOnDBusThread(); DCHECK(object_manager.get()); object_manager->CleanUp(); // The ObjectManager has to be deleted on the origin thread since it was // created there. GetOriginTaskRunner()->PostTask( FROM_HERE, base::Bind(&Bus::RemoveObjectManagerInternalHelper, this, object_manager, callback)); } void Bus::RemoveObjectManagerInternalHelper( scoped_refptr object_manager, const base::Closure& callback) { AssertOnOriginThread(); DCHECK(object_manager.get()); // Release the object manager and run the callback. object_manager = NULL; callback.Run(); } void Bus::GetManagedObjects() { for (ObjectManagerTable::iterator iter = object_manager_table_.begin(); iter != object_manager_table_.end(); ++iter) { iter->second->GetManagedObjects(); } } bool Bus::Connect() { // dbus_bus_get_private() and dbus_bus_get() are blocking calls. AssertOnDBusThread(); // Check if it's already initialized. if (connection_) return true; ScopedDBusError error; if (bus_type_ == CUSTOM_ADDRESS) { if (connection_type_ == PRIVATE) { connection_ = dbus_connection_open_private(address_.c_str(), error.get()); } else { connection_ = dbus_connection_open(address_.c_str(), error.get()); } } else { const DBusBusType dbus_bus_type = static_cast(bus_type_); if (connection_type_ == PRIVATE) { connection_ = dbus_bus_get_private(dbus_bus_type, error.get()); } else { connection_ = dbus_bus_get(dbus_bus_type, error.get()); } } if (!connection_) { LOG(ERROR) << "Failed to connect to the bus: " << (error.is_set() ? error.message() : ""); return false; } if (bus_type_ == CUSTOM_ADDRESS) { // We should call dbus_bus_register here, otherwise unique name can not be // acquired. According to dbus specification, it is responsible to call // org.freedesktop.DBus.Hello method at the beging of bus connection to // acquire unique name. In the case of dbus_bus_get, dbus_bus_register is // called internally. if (!dbus_bus_register(connection_, error.get())) { LOG(ERROR) << "Failed to register the bus component: " << (error.is_set() ? error.message() : ""); return false; } } // We shouldn't exit on the disconnected signal. dbus_connection_set_exit_on_disconnect(connection_, false); // Watch Disconnected signal. AddFilterFunction(Bus::OnConnectionDisconnectedFilter, this); AddMatch(kDisconnectedMatchRule, error.get()); return true; } void Bus::ClosePrivateConnection() { // dbus_connection_close is blocking call. AssertOnDBusThread(); DCHECK_EQ(PRIVATE, connection_type_) << "non-private connection should not be closed"; dbus_connection_close(connection_); } void Bus::ShutdownAndBlock() { AssertOnDBusThread(); if (shutdown_completed_) return; // Already shutdowned, just return. // Unregister the exported objects. for (ExportedObjectTable::iterator iter = exported_object_table_.begin(); iter != exported_object_table_.end(); ++iter) { iter->second->Unregister(); } // Release all service names. for (std::set::iterator iter = owned_service_names_.begin(); iter != owned_service_names_.end();) { // This is a bit tricky but we should increment the iter here as // ReleaseOwnership() may remove |service_name| from the set. const std::string& service_name = *iter++; ReleaseOwnership(service_name); } if (!owned_service_names_.empty()) { LOG(ERROR) << "Failed to release all service names. # of services left: " << owned_service_names_.size(); } // Detach from the remote objects. for (ObjectProxyTable::iterator iter = object_proxy_table_.begin(); iter != object_proxy_table_.end(); ++iter) { iter->second->Detach(); } // Clean up the object managers. for (ObjectManagerTable::iterator iter = object_manager_table_.begin(); iter != object_manager_table_.end(); ++iter) { iter->second->CleanUp(); } // Release object proxies and exported objects here. We should do this // here rather than in the destructor to avoid memory leaks due to // cyclic references. object_proxy_table_.clear(); exported_object_table_.clear(); // Private connection should be closed. if (connection_) { // Remove Disconnected watcher. ScopedDBusError error; RemoveFilterFunction(Bus::OnConnectionDisconnectedFilter, this); RemoveMatch(kDisconnectedMatchRule, error.get()); if (connection_type_ == PRIVATE) ClosePrivateConnection(); // dbus_connection_close() won't unref. dbus_connection_unref(connection_); } connection_ = NULL; shutdown_completed_ = true; } void Bus::ShutdownOnDBusThreadAndBlock() { AssertOnOriginThread(); DCHECK(dbus_task_runner_.get()); GetDBusTaskRunner()->PostTask( FROM_HERE, base::Bind(&Bus::ShutdownOnDBusThreadAndBlockInternal, this)); // http://crbug.com/125222 base::ThreadRestrictions::ScopedAllowWait allow_wait; // Wait until the shutdown is complete on the D-Bus thread. // The shutdown should not hang, but set timeout just in case. const int kTimeoutSecs = 3; const base::TimeDelta timeout(base::TimeDelta::FromSeconds(kTimeoutSecs)); const bool signaled = on_shutdown_.TimedWait(timeout); LOG_IF(ERROR, !signaled) << "Failed to shutdown the bus"; } void Bus::RequestOwnership(const std::string& service_name, ServiceOwnershipOptions options, OnOwnershipCallback on_ownership_callback) { AssertOnOriginThread(); GetDBusTaskRunner()->PostTask( FROM_HERE, base::Bind(&Bus::RequestOwnershipInternal, this, service_name, options, on_ownership_callback)); } void Bus::RequestOwnershipInternal(const std::string& service_name, ServiceOwnershipOptions options, OnOwnershipCallback on_ownership_callback) { AssertOnDBusThread(); bool success = Connect(); if (success) success = RequestOwnershipAndBlock(service_name, options); GetOriginTaskRunner()->PostTask(FROM_HERE, base::Bind(on_ownership_callback, service_name, success)); } bool Bus::RequestOwnershipAndBlock(const std::string& service_name, ServiceOwnershipOptions options) { DCHECK(connection_); // dbus_bus_request_name() is a blocking call. AssertOnDBusThread(); // Check if we already own the service name. if (owned_service_names_.find(service_name) != owned_service_names_.end()) { return true; } ScopedDBusError error; const int result = dbus_bus_request_name(connection_, service_name.c_str(), options, error.get()); if (result != DBUS_REQUEST_NAME_REPLY_PRIMARY_OWNER) { LOG(ERROR) << "Failed to get the ownership of " << service_name << ": " << (error.is_set() ? error.message() : ""); return false; } owned_service_names_.insert(service_name); return true; } bool Bus::ReleaseOwnership(const std::string& service_name) { DCHECK(connection_); // dbus_bus_request_name() is a blocking call. AssertOnDBusThread(); // Check if we already own the service name. std::set::iterator found = owned_service_names_.find(service_name); if (found == owned_service_names_.end()) { LOG(ERROR) << service_name << " is not owned by the bus"; return false; } ScopedDBusError error; const int result = dbus_bus_release_name(connection_, service_name.c_str(), error.get()); if (result == DBUS_RELEASE_NAME_REPLY_RELEASED) { owned_service_names_.erase(found); return true; } else { LOG(ERROR) << "Failed to release the ownership of " << service_name << ": " << (error.is_set() ? error.message() : "") << ", result code: " << result; return false; } } bool Bus::SetUpAsyncOperations() { DCHECK(connection_); AssertOnDBusThread(); if (async_operations_set_up_) return true; // Process all the incoming data if any, so that OnDispatchStatus() will // be called when the incoming data is ready. ProcessAllIncomingDataIfAny(); bool success = dbus_connection_set_watch_functions(connection_, &Bus::OnAddWatchThunk, &Bus::OnRemoveWatchThunk, &Bus::OnToggleWatchThunk, this, NULL); CHECK(success) << "Unable to allocate memory"; success = dbus_connection_set_timeout_functions(connection_, &Bus::OnAddTimeoutThunk, &Bus::OnRemoveTimeoutThunk, &Bus::OnToggleTimeoutThunk, this, NULL); CHECK(success) << "Unable to allocate memory"; dbus_connection_set_dispatch_status_function( connection_, &Bus::OnDispatchStatusChangedThunk, this, NULL); async_operations_set_up_ = true; return true; } DBusMessage* Bus::SendWithReplyAndBlock(DBusMessage* request, int timeout_ms, DBusError* error) { DCHECK(connection_); AssertOnDBusThread(); return dbus_connection_send_with_reply_and_block( connection_, request, timeout_ms, error); } void Bus::SendWithReply(DBusMessage* request, DBusPendingCall** pending_call, int timeout_ms) { DCHECK(connection_); AssertOnDBusThread(); const bool success = dbus_connection_send_with_reply( connection_, request, pending_call, timeout_ms); CHECK(success) << "Unable to allocate memory"; } void Bus::Send(DBusMessage* request, uint32* serial) { DCHECK(connection_); AssertOnDBusThread(); const bool success = dbus_connection_send(connection_, request, serial); CHECK(success) << "Unable to allocate memory"; } bool Bus::AddFilterFunction(DBusHandleMessageFunction filter_function, void* user_data) { DCHECK(connection_); AssertOnDBusThread(); std::pair filter_data_pair = std::make_pair(filter_function, user_data); if (filter_functions_added_.find(filter_data_pair) != filter_functions_added_.end()) { VLOG(1) << "Filter function already exists: " << filter_function << " with associated data: " << user_data; return false; } const bool success = dbus_connection_add_filter( connection_, filter_function, user_data, NULL); CHECK(success) << "Unable to allocate memory"; filter_functions_added_.insert(filter_data_pair); return true; } bool Bus::RemoveFilterFunction(DBusHandleMessageFunction filter_function, void* user_data) { DCHECK(connection_); AssertOnDBusThread(); std::pair filter_data_pair = std::make_pair(filter_function, user_data); if (filter_functions_added_.find(filter_data_pair) == filter_functions_added_.end()) { VLOG(1) << "Requested to remove an unknown filter function: " << filter_function << " with associated data: " << user_data; return false; } dbus_connection_remove_filter(connection_, filter_function, user_data); filter_functions_added_.erase(filter_data_pair); return true; } void Bus::AddMatch(const std::string& match_rule, DBusError* error) { DCHECK(connection_); AssertOnDBusThread(); std::map::iterator iter = match_rules_added_.find(match_rule); if (iter != match_rules_added_.end()) { // The already existing rule's counter is incremented. iter->second++; VLOG(1) << "Match rule already exists: " << match_rule; return; } dbus_bus_add_match(connection_, match_rule.c_str(), error); match_rules_added_[match_rule] = 1; } bool Bus::RemoveMatch(const std::string& match_rule, DBusError* error) { DCHECK(connection_); AssertOnDBusThread(); std::map::iterator iter = match_rules_added_.find(match_rule); if (iter == match_rules_added_.end()) { LOG(ERROR) << "Requested to remove an unknown match rule: " << match_rule; return false; } // The rule's counter is decremented and the rule is deleted when reachs 0. iter->second--; if (iter->second == 0) { dbus_bus_remove_match(connection_, match_rule.c_str(), error); match_rules_added_.erase(match_rule); } return true; } bool Bus::TryRegisterObjectPath(const ObjectPath& object_path, const DBusObjectPathVTable* vtable, void* user_data, DBusError* error) { DCHECK(connection_); AssertOnDBusThread(); if (registered_object_paths_.find(object_path) != registered_object_paths_.end()) { LOG(ERROR) << "Object path already registered: " << object_path.value(); return false; } const bool success = dbus_connection_try_register_object_path( connection_, object_path.value().c_str(), vtable, user_data, error); if (success) registered_object_paths_.insert(object_path); return success; } void Bus::UnregisterObjectPath(const ObjectPath& object_path) { DCHECK(connection_); AssertOnDBusThread(); if (registered_object_paths_.find(object_path) == registered_object_paths_.end()) { LOG(ERROR) << "Requested to unregister an unknown object path: " << object_path.value(); return; } const bool success = dbus_connection_unregister_object_path( connection_, object_path.value().c_str()); CHECK(success) << "Unable to allocate memory"; registered_object_paths_.erase(object_path); } void Bus::ShutdownOnDBusThreadAndBlockInternal() { AssertOnDBusThread(); ShutdownAndBlock(); on_shutdown_.Signal(); } void Bus::ProcessAllIncomingDataIfAny() { AssertOnDBusThread(); // As mentioned at the class comment in .h file, connection_ can be NULL. if (!connection_) return; // It is safe and necessary to call dbus_connection_get_dispatch_status even // if the connection is lost. Otherwise we will miss "Disconnected" signal. // (crbug.com/174431) if (dbus_connection_get_dispatch_status(connection_) == DBUS_DISPATCH_DATA_REMAINS) { while (dbus_connection_dispatch(connection_) == DBUS_DISPATCH_DATA_REMAINS) { } } } base::TaskRunner* Bus::GetDBusTaskRunner() { if (dbus_task_runner_.get()) return dbus_task_runner_.get(); else return GetOriginTaskRunner(); } base::TaskRunner* Bus::GetOriginTaskRunner() { DCHECK(origin_task_runner_.get()); return origin_task_runner_.get(); } bool Bus::HasDBusThread() { return dbus_task_runner_.get() != NULL; } void Bus::AssertOnOriginThread() { DCHECK_EQ(origin_thread_id_, base::PlatformThread::CurrentId()); } void Bus::AssertOnDBusThread() { base::ThreadRestrictions::AssertIOAllowed(); if (dbus_task_runner_.get()) { DCHECK(dbus_task_runner_->RunsTasksOnCurrentThread()); } else { AssertOnOriginThread(); } } std::string Bus::GetServiceOwnerAndBlock(const std::string& service_name, GetServiceOwnerOption options) { AssertOnDBusThread(); MethodCall get_name_owner_call("org.freedesktop.DBus", "GetNameOwner"); MessageWriter writer(&get_name_owner_call); writer.AppendString(service_name); VLOG(1) << "Method call: " << get_name_owner_call.ToString(); const ObjectPath obj_path("/org/freedesktop/DBus"); if (!get_name_owner_call.SetDestination("org.freedesktop.DBus") || !get_name_owner_call.SetPath(obj_path)) { if (options == REPORT_ERRORS) LOG(ERROR) << "Failed to get name owner."; return ""; } ScopedDBusError error; DBusMessage* response_message = SendWithReplyAndBlock(get_name_owner_call.raw_message(), ObjectProxy::TIMEOUT_USE_DEFAULT, error.get()); if (!response_message) { if (options == REPORT_ERRORS) { LOG(ERROR) << "Failed to get name owner. Got " << error.name() << ": " << error.message(); } return ""; } scoped_ptr response(Response::FromRawMessage(response_message)); MessageReader reader(response.get()); std::string service_owner; if (!reader.PopString(&service_owner)) service_owner.clear(); return service_owner; } void Bus::GetServiceOwner(const std::string& service_name, const GetServiceOwnerCallback& callback) { AssertOnOriginThread(); GetDBusTaskRunner()->PostTask( FROM_HERE, base::Bind(&Bus::GetServiceOwnerInternal, this, service_name, callback)); } void Bus::GetServiceOwnerInternal(const std::string& service_name, const GetServiceOwnerCallback& callback) { AssertOnDBusThread(); std::string service_owner; if (Connect()) service_owner = GetServiceOwnerAndBlock(service_name, SUPPRESS_ERRORS); GetOriginTaskRunner()->PostTask(FROM_HERE, base::Bind(callback, service_owner)); } void Bus::ListenForServiceOwnerChange( const std::string& service_name, const GetServiceOwnerCallback& callback) { AssertOnOriginThread(); DCHECK(!service_name.empty()); DCHECK(!callback.is_null()); GetDBusTaskRunner()->PostTask( FROM_HERE, base::Bind(&Bus::ListenForServiceOwnerChangeInternal, this, service_name, callback)); } void Bus::ListenForServiceOwnerChangeInternal( const std::string& service_name, const GetServiceOwnerCallback& callback) { AssertOnDBusThread(); DCHECK(!service_name.empty()); DCHECK(!callback.is_null()); if (!Connect() || !SetUpAsyncOperations()) return; if (service_owner_changed_listener_map_.empty()) { bool filter_added = AddFilterFunction(Bus::OnServiceOwnerChangedFilter, this); DCHECK(filter_added); } ServiceOwnerChangedListenerMap::iterator it = service_owner_changed_listener_map_.find(service_name); if (it == service_owner_changed_listener_map_.end()) { // Add a match rule for the new service name. const std::string name_owner_changed_match_rule = base::StringPrintf(kServiceNameOwnerChangeMatchRule, service_name.c_str()); ScopedDBusError error; AddMatch(name_owner_changed_match_rule, error.get()); if (error.is_set()) { LOG(ERROR) << "Failed to add match rule for " << service_name << ". Got " << error.name() << ": " << error.message(); return; } service_owner_changed_listener_map_[service_name].push_back(callback); return; } // Check if the callback has already been added. std::vector& callbacks = it->second; for (size_t i = 0; i < callbacks.size(); ++i) { if (callbacks[i].Equals(callback)) return; } callbacks.push_back(callback); } void Bus::UnlistenForServiceOwnerChange( const std::string& service_name, const GetServiceOwnerCallback& callback) { AssertOnOriginThread(); DCHECK(!service_name.empty()); DCHECK(!callback.is_null()); GetDBusTaskRunner()->PostTask( FROM_HERE, base::Bind(&Bus::UnlistenForServiceOwnerChangeInternal, this, service_name, callback)); } void Bus::UnlistenForServiceOwnerChangeInternal( const std::string& service_name, const GetServiceOwnerCallback& callback) { AssertOnDBusThread(); DCHECK(!service_name.empty()); DCHECK(!callback.is_null()); ServiceOwnerChangedListenerMap::iterator it = service_owner_changed_listener_map_.find(service_name); if (it == service_owner_changed_listener_map_.end()) return; std::vector& callbacks = it->second; for (size_t i = 0; i < callbacks.size(); ++i) { if (callbacks[i].Equals(callback)) { callbacks.erase(callbacks.begin() + i); break; // There can be only one. } } if (!callbacks.empty()) return; // Last callback for |service_name| has been removed, remove match rule. const std::string name_owner_changed_match_rule = base::StringPrintf(kServiceNameOwnerChangeMatchRule, service_name.c_str()); ScopedDBusError error; RemoveMatch(name_owner_changed_match_rule, error.get()); // And remove |service_owner_changed_listener_map_| entry. service_owner_changed_listener_map_.erase(it); if (service_owner_changed_listener_map_.empty()) { bool filter_removed = RemoveFilterFunction(Bus::OnServiceOwnerChangedFilter, this); DCHECK(filter_removed); } } dbus_bool_t Bus::OnAddWatch(DBusWatch* raw_watch) { AssertOnDBusThread(); // watch will be deleted when raw_watch is removed in OnRemoveWatch(). Watch* watch = new Watch(raw_watch); if (watch->IsReadyToBeWatched()) { watch->StartWatching(); } ++num_pending_watches_; return true; } void Bus::OnRemoveWatch(DBusWatch* raw_watch) { AssertOnDBusThread(); Watch* watch = static_cast(dbus_watch_get_data(raw_watch)); delete watch; --num_pending_watches_; } void Bus::OnToggleWatch(DBusWatch* raw_watch) { AssertOnDBusThread(); Watch* watch = static_cast(dbus_watch_get_data(raw_watch)); if (watch->IsReadyToBeWatched()) { watch->StartWatching(); } else { // It's safe to call this if StartWatching() wasn't called, per // message_pump_libevent.h. watch->StopWatching(); } } dbus_bool_t Bus::OnAddTimeout(DBusTimeout* raw_timeout) { AssertOnDBusThread(); // timeout will be deleted when raw_timeout is removed in // OnRemoveTimeoutThunk(). Timeout* timeout = new Timeout(raw_timeout); if (timeout->IsReadyToBeMonitored()) { timeout->StartMonitoring(this); } ++num_pending_timeouts_; return true; } void Bus::OnRemoveTimeout(DBusTimeout* raw_timeout) { AssertOnDBusThread(); Timeout* timeout = static_cast(dbus_timeout_get_data(raw_timeout)); timeout->Complete(); --num_pending_timeouts_; } void Bus::OnToggleTimeout(DBusTimeout* raw_timeout) { AssertOnDBusThread(); Timeout* timeout = static_cast(dbus_timeout_get_data(raw_timeout)); if (timeout->IsReadyToBeMonitored()) { timeout->StartMonitoring(this); } else { timeout->StopMonitoring(); } } void Bus::OnDispatchStatusChanged(DBusConnection* connection, DBusDispatchStatus status) { DCHECK_EQ(connection, connection_); AssertOnDBusThread(); // We cannot call ProcessAllIncomingDataIfAny() here, as calling // dbus_connection_dispatch() inside DBusDispatchStatusFunction is // prohibited by the D-Bus library. Hence, we post a task here instead. // See comments for dbus_connection_set_dispatch_status_function(). GetDBusTaskRunner()->PostTask(FROM_HERE, base::Bind(&Bus::ProcessAllIncomingDataIfAny, this)); } void Bus::OnConnectionDisconnected(DBusConnection* connection) { AssertOnDBusThread(); if (!on_disconnected_closure_.is_null()) GetOriginTaskRunner()->PostTask(FROM_HERE, on_disconnected_closure_); if (!connection) return; DCHECK(!dbus_connection_get_is_connected(connection)); ShutdownAndBlock(); } void Bus::OnServiceOwnerChanged(DBusMessage* message) { DCHECK(message); AssertOnDBusThread(); // |message| will be unrefed on exit of the function. Increment the // reference so we can use it in Signal::FromRawMessage() below. dbus_message_ref(message); scoped_ptr signal(Signal::FromRawMessage(message)); // Confirm the validity of the NameOwnerChanged signal. if (signal->GetMember() != kNameOwnerChangedSignal || signal->GetInterface() != DBUS_INTERFACE_DBUS || signal->GetSender() != DBUS_SERVICE_DBUS) { return; } MessageReader reader(signal.get()); std::string service_name; std::string old_owner; std::string new_owner; if (!reader.PopString(&service_name) || !reader.PopString(&old_owner) || !reader.PopString(&new_owner)) { return; } ServiceOwnerChangedListenerMap::const_iterator it = service_owner_changed_listener_map_.find(service_name); if (it == service_owner_changed_listener_map_.end()) return; const std::vector& callbacks = it->second; for (size_t i = 0; i < callbacks.size(); ++i) { GetOriginTaskRunner()->PostTask(FROM_HERE, base::Bind(callbacks[i], new_owner)); } } // static dbus_bool_t Bus::OnAddWatchThunk(DBusWatch* raw_watch, void* data) { Bus* self = static_cast(data); return self->OnAddWatch(raw_watch); } // static void Bus::OnRemoveWatchThunk(DBusWatch* raw_watch, void* data) { Bus* self = static_cast(data); self->OnRemoveWatch(raw_watch); } // static void Bus::OnToggleWatchThunk(DBusWatch* raw_watch, void* data) { Bus* self = static_cast(data); self->OnToggleWatch(raw_watch); } // static dbus_bool_t Bus::OnAddTimeoutThunk(DBusTimeout* raw_timeout, void* data) { Bus* self = static_cast(data); return self->OnAddTimeout(raw_timeout); } // static void Bus::OnRemoveTimeoutThunk(DBusTimeout* raw_timeout, void* data) { Bus* self = static_cast(data); self->OnRemoveTimeout(raw_timeout); } // static void Bus::OnToggleTimeoutThunk(DBusTimeout* raw_timeout, void* data) { Bus* self = static_cast(data); self->OnToggleTimeout(raw_timeout); } // static void Bus::OnDispatchStatusChangedThunk(DBusConnection* connection, DBusDispatchStatus status, void* data) { Bus* self = static_cast(data); self->OnDispatchStatusChanged(connection, status); } // static DBusHandlerResult Bus::OnConnectionDisconnectedFilter( DBusConnection* connection, DBusMessage* message, void* data) { if (dbus_message_is_signal(message, DBUS_INTERFACE_LOCAL, kDisconnectedSignal)) { Bus* self = static_cast(data); self->OnConnectionDisconnected(connection); return DBUS_HANDLER_RESULT_HANDLED; } return DBUS_HANDLER_RESULT_NOT_YET_HANDLED; } // static DBusHandlerResult Bus::OnServiceOwnerChangedFilter( DBusConnection* connection, DBusMessage* message, void* data) { if (dbus_message_is_signal(message, DBUS_INTERFACE_DBUS, kNameOwnerChangedSignal)) { Bus* self = static_cast(data); self->OnServiceOwnerChanged(message); } // Always return unhandled to let others, e.g. ObjectProxies, handle the same // signal. return DBUS_HANDLER_RESULT_NOT_YET_HANDLED; } } // namespace dbus