#include "rpc_i.h" #include #include #include #include #include #include #include #include #include #include #include #define TAG "RpcSrv" typedef enum { RpcEvtNewData = (1 << 0), RpcEvtDisconnect = (1 << 1), } RpcEvtFlags; #define RPC_ALL_EVENTS (RpcEvtNewData | RpcEvtDisconnect) DICT_DEF2(RpcHandlerDict, pb_size_t, M_DEFAULT_OPLIST, RpcHandler, M_POD_OPLIST) typedef struct { RpcSystemAlloc alloc; RpcSystemFree free; void* context; } RpcSystemCallbacks; static RpcSystemCallbacks rpc_systems[] = { { .alloc = rpc_system_system_alloc, .free = NULL, }, { .alloc = rpc_system_storage_alloc, .free = rpc_system_storage_free, }, { .alloc = rpc_system_app_alloc, .free = rpc_system_app_free, }, { .alloc = rpc_system_gui_alloc, .free = rpc_system_gui_free, }, { .alloc = rpc_system_gpio_alloc, .free = NULL, }, { .alloc = rpc_system_property_alloc, .free = NULL, }, { .alloc = rpc_desktop_alloc, .free = rpc_desktop_free, }, }; struct RpcSession { Rpc* rpc; FuriThread* thread; RpcHandlerDict_t handlers; FuriStreamBuffer* stream; PB_Main* decoded_message; bool terminate; void** system_contexts; bool decode_error; FuriMutex* callbacks_mutex; RpcSendBytesCallback send_bytes_callback; RpcBufferIsEmptyCallback buffer_is_empty_callback; RpcSessionClosedCallback closed_callback; RpcSessionTerminatedCallback terminated_callback; RpcOwner owner; void* context; }; struct Rpc { FuriMutex* busy_mutex; size_t sessions_count; }; RpcOwner rpc_session_get_owner(RpcSession* session) { furi_assert(session); return session->owner; } static void rpc_close_session_process(const PB_Main* request, void* context) { furi_assert(request); furi_assert(context); RpcSession* session = (RpcSession*)context; rpc_send_and_release_empty(session, request->command_id, PB_CommandStatus_OK); furi_mutex_acquire(session->callbacks_mutex, FuriWaitForever); if(session->closed_callback) { session->closed_callback(session->context); } else { FURI_LOG_W(TAG, "Session stop isn't processed by transport layer"); } furi_mutex_release(session->callbacks_mutex); } void rpc_session_set_context(RpcSession* session, void* context) { furi_assert(session); furi_mutex_acquire(session->callbacks_mutex, FuriWaitForever); session->context = context; furi_mutex_release(session->callbacks_mutex); } void rpc_session_set_close_callback(RpcSession* session, RpcSessionClosedCallback callback) { furi_assert(session); furi_mutex_acquire(session->callbacks_mutex, FuriWaitForever); session->closed_callback = callback; furi_mutex_release(session->callbacks_mutex); } void rpc_session_set_send_bytes_callback(RpcSession* session, RpcSendBytesCallback callback) { furi_assert(session); furi_mutex_acquire(session->callbacks_mutex, FuriWaitForever); session->send_bytes_callback = callback; furi_mutex_release(session->callbacks_mutex); } void rpc_session_set_buffer_is_empty_callback( RpcSession* session, RpcBufferIsEmptyCallback callback) { furi_assert(session); furi_mutex_acquire(session->callbacks_mutex, FuriWaitForever); session->buffer_is_empty_callback = callback; furi_mutex_release(session->callbacks_mutex); } void rpc_session_set_terminated_callback( RpcSession* session, RpcSessionTerminatedCallback callback) { furi_assert(session); furi_mutex_acquire(session->callbacks_mutex, FuriWaitForever); session->terminated_callback = callback; furi_mutex_release(session->callbacks_mutex); } /* Doesn't forbid using rpc_feed_bytes() after session close - it's safe. * Because any bytes received in buffer will be flushed before next session. * If bytes get into stream buffer before it's get emptied and this * command is gets processed - it's safe either way. But case of it is quite * odd: client sends close request and sends command after. */ size_t rpc_session_feed(RpcSession* session, uint8_t* encoded_bytes, size_t size, uint32_t timeout) { furi_assert(session); furi_assert(encoded_bytes); if(!size) return 0; size_t bytes_sent = furi_stream_buffer_send(session->stream, encoded_bytes, size, timeout); furi_thread_flags_set(furi_thread_get_id(session->thread), RpcEvtNewData); return bytes_sent; } size_t rpc_session_get_available_size(RpcSession* session) { furi_assert(session); return furi_stream_buffer_spaces_available(session->stream); } bool rpc_pb_stream_read(pb_istream_t* istream, pb_byte_t* buf, size_t count) { furi_assert(istream); furi_assert(buf); RpcSession* session = istream->state; furi_assert(session); furi_assert(istream->bytes_left); uint32_t flags = 0; size_t bytes_received = 0; while(1) { bytes_received += furi_stream_buffer_receive( session->stream, buf + bytes_received, count - bytes_received, 0); if(furi_stream_buffer_is_empty(session->stream)) { if(session->buffer_is_empty_callback) { session->buffer_is_empty_callback(session->context); } } if(session->decode_error) { /* never go out till RPC_EVENT_DISCONNECT come */ bytes_received = 0; } if(count == bytes_received) { break; } else { flags = furi_thread_flags_wait(RPC_ALL_EVENTS, FuriFlagWaitAny, FuriWaitForever); if(flags & RpcEvtDisconnect) { if(furi_stream_buffer_is_empty(session->stream)) { session->terminate = true; istream->bytes_left = 0; bytes_received = 0; break; } else { /* Save disconnect flag and continue reading buffer */ furi_thread_flags_set(furi_thread_get_id(session->thread), RpcEvtDisconnect); } } else if(flags & RpcEvtNewData) { // Just wake thread up } } } #if SRV_RPC_DEBUG rpc_debug_print_data("INPUT", buf, bytes_received); #endif return (count == bytes_received); } static bool rpc_pb_content_callback(pb_istream_t* stream, const pb_field_t* field, void** arg) { furi_assert(stream); RpcSession* session = stream->state; furi_assert(session); furi_assert(field); RpcHandler* handler = RpcHandlerDict_get(session->handlers, field->tag); if(handler && handler->decode_submessage) { handler->decode_submessage(stream, field, arg); } return true; } static int32_t rpc_session_worker(void* context) { furi_assert(context); RpcSession* session = (RpcSession*)context; Rpc* rpc = session->rpc; FURI_LOG_D(TAG, "Session started"); while(1) { pb_istream_t istream = { .callback = rpc_pb_stream_read, .state = session, .errmsg = NULL, .bytes_left = SIZE_MAX, }; bool message_decode_failed = false; if(pb_decode_ex(&istream, &PB_Main_msg, session->decoded_message, PB_DECODE_DELIMITED)) { #if SRV_RPC_DEBUG FURI_LOG_I(TAG, "INPUT:"); rpc_debug_print_message(session->decoded_message); #endif RpcHandler* handler = RpcHandlerDict_get(session->handlers, session->decoded_message->which_content); if(handler && handler->message_handler) { furi_check(furi_mutex_acquire(rpc->busy_mutex, FuriWaitForever) == FuriStatusOk); handler->message_handler(session->decoded_message, handler->context); furi_check(furi_mutex_release(rpc->busy_mutex) == FuriStatusOk); } else if(session->decoded_message->which_content == 0) { /* Receiving zeroes means message is 0-length, which * is valid for proto3: all fields are filled with default values. * 0 - is default value for which_content field. * Mark it as decode error, because there is no content message * in Main message with tag 0. */ message_decode_failed = true; } else if(!handler && !session->terminate) { FURI_LOG_E( TAG, "Message(%d) decoded, but not implemented", session->decoded_message->which_content); rpc_send_and_release_empty( session, session->decoded_message->command_id, PB_CommandStatus_ERROR_NOT_IMPLEMENTED); } } else { message_decode_failed = true; } if(message_decode_failed) { furi_stream_buffer_reset(session->stream); if(!session->terminate) { /* Protobuf can't determine start and end of message. * Handle this by adding varint at beginning * of a message (PB_ENCODE_DELIMITED). But decoding fail * means we can't be sure next bytes are varint for next * message, so the only way to close session. * RPC itself can't make decision to close session. It has * to notify: * 1) down layer (transport) * 2) other side (companion app) * Who are responsible to handle RPC session lifecycle. * Companion receives 2 messages: ERROR_DECODE and session_closed. */ FURI_LOG_E(TAG, "Decode failed, error: \'%.128s\'", PB_GET_ERROR(&istream)); session->decode_error = true; rpc_send_and_release_empty(session, 0, PB_CommandStatus_ERROR_DECODE); furi_mutex_acquire(session->callbacks_mutex, FuriWaitForever); if(session->closed_callback) { session->closed_callback(session->context); } furi_mutex_release(session->callbacks_mutex); if(session->owner == RpcOwnerBle) { // Disconnect BLE session FURI_LOG_E("RPC", "BLE session closed due to a decode error"); Bt* bt = furi_record_open(RECORD_BT); bt_set_profile(bt, BtProfileSerial); furi_record_close(RECORD_BT); FURI_LOG_E("RPC", "Finished disconnecting the BLE session"); } } } pb_release(&PB_Main_msg, session->decoded_message); if(session->terminate) { FURI_LOG_D(TAG, "Session terminated"); break; } } return 0; } static void rpc_session_thread_pending_callback(void* context, uint32_t arg) { UNUSED(arg); RpcSession* session = (RpcSession*)context; for(size_t i = 0; i < COUNT_OF(rpc_systems); ++i) { if(rpc_systems[i].free) { (rpc_systems[i].free)(session->system_contexts[i]); } } free(session->system_contexts); free(session->decoded_message); RpcHandlerDict_clear(session->handlers); furi_stream_buffer_free(session->stream); furi_mutex_acquire(session->callbacks_mutex, FuriWaitForever); if(session->terminated_callback) { session->terminated_callback(session->context); } furi_mutex_release(session->callbacks_mutex); furi_mutex_free(session->callbacks_mutex); furi_thread_join(session->thread); furi_thread_free(session->thread); free(session); } static void rpc_session_thread_state_callback(FuriThreadState thread_state, void* context) { if(thread_state == FuriThreadStateStopped) { furi_timer_pending_callback(rpc_session_thread_pending_callback, context, 0); } } RpcSession* rpc_session_open(Rpc* rpc, RpcOwner owner) { furi_assert(rpc); RpcSession* session = malloc(sizeof(RpcSession)); session->callbacks_mutex = furi_mutex_alloc(FuriMutexTypeNormal); session->stream = furi_stream_buffer_alloc(RPC_BUFFER_SIZE, 1); session->rpc = rpc; session->terminate = false; session->decode_error = false; session->owner = owner; RpcHandlerDict_init(session->handlers); session->decoded_message = malloc(sizeof(PB_Main)); session->decoded_message->cb_content.funcs.decode = rpc_pb_content_callback; session->decoded_message->cb_content.arg = session; session->system_contexts = malloc(COUNT_OF(rpc_systems) * sizeof(void*)); for(size_t i = 0; i < COUNT_OF(rpc_systems); ++i) { session->system_contexts[i] = rpc_systems[i].alloc(session); } RpcHandler rpc_handler = { .message_handler = rpc_close_session_process, .decode_submessage = NULL, .context = session, }; rpc_add_handler(session, PB_Main_stop_session_tag, &rpc_handler); session->thread = furi_thread_alloc_ex("RpcSessionWorker", 3072, rpc_session_worker, session); furi_thread_set_state_context(session->thread, session); furi_thread_set_state_callback(session->thread, rpc_session_thread_state_callback); furi_thread_start(session->thread); rpc->sessions_count++; return session; } void rpc_session_close(RpcSession* session) { furi_assert(session); furi_assert(session->rpc); session->rpc->sessions_count--; rpc_session_set_send_bytes_callback(session, NULL); rpc_session_set_close_callback(session, NULL); rpc_session_set_buffer_is_empty_callback(session, NULL); furi_thread_flags_set(furi_thread_get_id(session->thread), RpcEvtDisconnect); } void rpc_on_system_start(void* p) { UNUSED(p); Rpc* rpc = malloc(sizeof(Rpc)); rpc->busy_mutex = furi_mutex_alloc(FuriMutexTypeNormal); Cli* cli = furi_record_open(RECORD_CLI); cli_add_command( cli, "start_rpc_session", CliCommandFlagParallelSafe, rpc_cli_command_start_session, rpc); furi_record_create(RECORD_RPC, rpc); } void rpc_add_handler(RpcSession* session, pb_size_t message_tag, RpcHandler* handler) { furi_assert(RpcHandlerDict_get(session->handlers, message_tag) == NULL); RpcHandlerDict_set_at(session->handlers, message_tag, *handler); } void rpc_send(RpcSession* session, PB_Main* message) { furi_assert(session); furi_assert(message); pb_ostream_t ostream = PB_OSTREAM_SIZING; #if SRV_RPC_DEBUG FURI_LOG_I(TAG, "OUTPUT:"); rpc_debug_print_message(message); #endif bool result = pb_encode_ex(&ostream, &PB_Main_msg, message, PB_ENCODE_DELIMITED); furi_check(result && ostream.bytes_written); uint8_t* buffer = malloc(ostream.bytes_written); ostream = pb_ostream_from_buffer(buffer, ostream.bytes_written); pb_encode_ex(&ostream, &PB_Main_msg, message, PB_ENCODE_DELIMITED); #if SRV_RPC_DEBUG rpc_debug_print_data("OUTPUT", buffer, ostream.bytes_written); #endif furi_mutex_acquire(session->callbacks_mutex, FuriWaitForever); if(session->send_bytes_callback) { session->send_bytes_callback(session->context, buffer, ostream.bytes_written); } furi_mutex_release(session->callbacks_mutex); free(buffer); } void rpc_send_and_release(RpcSession* session, PB_Main* message) { rpc_send(session, message); pb_release(&PB_Main_msg, message); } void rpc_send_and_release_empty(RpcSession* session, uint32_t command_id, PB_CommandStatus status) { furi_assert(session); PB_Main message = { .command_id = command_id, .command_status = status, .has_next = false, .which_content = PB_Main_empty_tag, }; rpc_send_and_release(session, &message); pb_release(&PB_Main_msg, &message); } size_t rpc_get_sessions_count(Rpc* rpc) { return rpc->sessions_count; }