/* * Copyright (C) 2015, 2018 "IoT.bzh" * Author "Romain Forlot" * Author "Loic Collignon" * * 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 "low-can-hat.hpp" #include "low-can-apidef.h" #include #include #include #include #include #include #include #include #include #include "openxc.pb.h" #include "application.hpp" #include "../can/can-encoder.hpp" #include "../can/can-bus.hpp" #include "../can/signals.hpp" #include "../can/message/message.hpp" #include "../utils/signals.hpp" #include "../diagnostic/diagnostic-message.hpp" #include "../utils/openxc-utils.hpp" #include "../utils/signals.hpp" #ifdef USE_FEATURE_J1939 #include "../can/message/j1939-message.hpp" #include #endif ///***************************************************************************** /// /// Controller Definitions and Callbacks /// ///****************************************************************************/ int config_low_can(afb_api_t apiHandle, CtlSectionT *section, json_object *json_obj) { AFB_DEBUG("Config %s", json_object_to_json_string(json_obj)); CtlConfigT *ctrlConfig = (CtlConfigT *) afb_api_get_userdata(apiHandle); int active_message_set = 0; json_object *dev_mapping = nullptr; const char *diagnotic_bus = nullptr; if(! ctrlConfig || ! ctrlConfig->external) return -1; application_t *application = (application_t*) ctrlConfig->external; if(wrap_json_unpack(json_obj, "{si, s?s}", "active_message_set", &active_message_set, "diagnostic_bus", &diagnotic_bus)) return -1; application->set_active_message_set((uint8_t)active_message_set); if(wrap_json_unpack(json_obj, "{so}", "dev-mapping", &dev_mapping)) return -1; application->get_can_bus_manager().set_can_devices(dev_mapping); /// Initialize Diagnostic manager that will handle obd2 requests. /// We pass by default the first CAN bus device to its Initialization. if(! diagnotic_bus || application_t::instance().get_diagnostic_manager().initialize(diagnotic_bus)) AFB_WARNING("Diagnostic Manager: not initialized. No diagnostic messages will be processed."); return 0; } CtlSectionT ctlSections_[] = { [0]={.key="config" , .uid="config", .info=nullptr, .loadCB=config_low_can, .handle=nullptr, .actions=nullptr}, [1]={.key="plugins" , .uid="plugins", .info=nullptr, .loadCB=PluginConfig, .handle=nullptr, .actions=nullptr}, [2]={.key=nullptr , .uid=nullptr, .info=nullptr, .loadCB=nullptr, .handle=nullptr, .actions=nullptr}, }; ///***************************************************************************** /// /// Subscription and unsubscription /// ///****************************************************************************/ /// @brief This will determine if an event handle needs to be created and checks if /// we got a valid afb_event to get subscribe or unsubscribe. After that launch the subscription or unsubscription /// against the application framework using that event handle. static int subscribe_unsubscribe_signal(afb_req_t request, bool subscribe, std::shared_ptr& can_subscription, map_subscription& s) { int ret = 0; int sub_index = can_subscription->get_index(); bool subscription_exists = s.count(sub_index); // Susbcription part if(subscribe) { /* There is no valid request to subscribe so this must be an * internal permanent diagnostic request. Skip the subscription * part and don't register it into the current "low-can" * subsciptions. */ if(! request) return 0; // Event doesn't exist , so let's create it if ((ret = can_subscription->subscribe(request)) < 0) return ret; if(! subscription_exists) s[sub_index] = can_subscription; return ret; } // Unsubscrition part if(! subscription_exists) { AFB_NOTICE("There isn't any valid subscriptions for that request."); return ret; } else if (subscription_exists && ! afb_event_is_valid(s[sub_index]->get_event()) ) { AFB_NOTICE("Event isn't valid, no need to unsubscribed."); return ret; } if( (ret = s[sub_index]->unsubscribe(request)) < 0) return ret; s.find(sub_index)->second->set_index(-1); s.erase(sub_index); return ret; } static int add_to_event_loop(std::shared_ptr& can_subscription) { struct sd_event_source* event_source = nullptr; return ( sd_event_add_io(afb_daemon_get_event_loop(), &event_source, can_subscription->get_socket()->socket(), EPOLLIN, read_message, can_subscription.get())); } static int subscribe_unsubscribe_diagnostic_messages(afb_req_t request, bool subscribe, list_ptr_diag_msg_t diagnostic_messages, struct event_filter_t& event_filter, map_subscription& s, bool perm_rec_diag_req) { int rets = 0; application_t& app = application_t::instance(); diagnostic_manager_t& diag_m = app.get_diagnostic_manager(); for(const auto& sig : diagnostic_messages) { DiagnosticRequest* diag_req = new DiagnosticRequest(sig->build_diagnostic_request()); event_filter.frequency = event_filter.frequency == 0 ? sig->get_frequency() : event_filter.frequency; std::shared_ptr can_subscription; auto it = std::find_if(s.begin(), s.end(), [&sig](std::pair > sub) { return (! sub.second->get_diagnostic_message().empty()); }); can_subscription = it != s.end() ? it->second : std::make_shared(low_can_subscription_t(event_filter)); // If the requested diagnostic message is not supported by the car then unsubcribe it // no matter what we want, worst case will be a failed unsubscription but at least we won't // poll a PID for nothing. if(sig->get_supported() && subscribe) { if (!app.is_engine_on()) AFB_WARNING("signal: Engine is off, %s won't received responses until it's on", sig->get_name().c_str()); diag_m.add_recurring_request(diag_req, sig->get_name().c_str(), false, sig->get_decoder(), sig->get_callback(), event_filter.frequency, perm_rec_diag_req); if(can_subscription->create_rx_filter(sig) < 0) return -1; AFB_DEBUG("Signal: %s subscribed", sig->get_name().c_str()); if(it == s.end() && add_to_event_loop(can_subscription) < 0) { diag_m.cleanup_request( diag_m.find_recurring_request(*diag_req), true); AFB_WARNING("signal: %s isn't supported. Canceling operation.", sig->get_name().c_str()); return -1; } } else { if(sig->get_supported()) { AFB_DEBUG("%s cancelled due to unsubscribe", sig->get_name().c_str()); } else { AFB_WARNING("signal: %s isn't supported. Canceling operation.", sig->get_name().c_str()); return -1; } } int ret = subscribe_unsubscribe_signal(request, subscribe, can_subscription, s); if(ret < 0) return ret; rets++; } return rets; } static int subscribe_unsubscribe_signals(afb_req_t request, bool subscribe, list_ptr_signal_t signals, struct event_filter_t& event_filter, map_subscription& s) { int rets = 0; for(const auto& sig: signals) { auto it = std::find_if(s.begin(), s.end(), [&sig, &event_filter](std::pair > sub) { return sub.second->is_signal_subscription_corresponding(sig, event_filter) ; }); std::shared_ptr can_subscription; if(it != s.end()) can_subscription = it->second; else { can_subscription = std::make_shared(low_can_subscription_t(event_filter)); if(can_subscription->create_rx_filter(sig) < 0) return -1; if(add_to_event_loop(can_subscription) < 0) return -1; } if(subscribe_unsubscribe_signal(request, subscribe, can_subscription, s) < 0) return -1; rets++; AFB_DEBUG("%s Signal: %s %ssubscribed", sig->get_message()->is_fd() ? "FD": "", sig->get_name().c_str(), subscribe ? "":"un"); } return rets; } /// /// @brief subscribe to all signals in the vector signals /// /// @param[in] afb_req request : contains original request use to subscribe or unsubscribe /// @param[in] subscribe boolean value, which chooses between a subscription operation or an unsubscription /// @param[in] signals - struct containing vectors with signal_t and diagnostic_messages to subscribe /// @param[in] event_filter - stuct containing filter on the signal /// /// @return Number of correctly subscribed signal /// static int subscribe_unsubscribe_signals(afb_req_t request, bool subscribe, const struct utils::signals_found& signals, struct event_filter_t& event_filter) { int rets = 0; utils::signals_manager_t& sm = utils::signals_manager_t::instance(); std::lock_guard subscribed_signals_lock(sm.get_subscribed_signals_mutex()); map_subscription& s = sm.get_subscribed_signals(); rets += subscribe_unsubscribe_diagnostic_messages(request, subscribe, signals.diagnostic_messages, event_filter, s, false); rets += subscribe_unsubscribe_signals(request, subscribe, signals.signals, event_filter, s); return rets; } static event_filter_t generate_filter(json_object* args) { event_filter_t event_filter; struct json_object *filter, *obj; // computes the filter if (json_object_object_get_ex(args, "filter", &filter)) { if (json_object_object_get_ex(filter, "frequency", &obj) && (json_object_is_type(obj, json_type_double) || json_object_is_type(obj, json_type_int))) event_filter.frequency = (float)json_object_get_double(obj); if (json_object_object_get_ex(filter, "min", &obj) && (json_object_is_type(obj, json_type_double) || json_object_is_type(obj, json_type_int))) event_filter.min = (float)json_object_get_double(obj); if (json_object_object_get_ex(filter, "max", &obj) && (json_object_is_type(obj, json_type_double) || json_object_is_type(obj, json_type_int))) event_filter.max = (float)json_object_get_double(obj); if (json_object_object_get_ex(filter, "promisc", &obj) && (json_object_is_type(obj, json_type_boolean))) event_filter.promisc = (bool)json_object_get_boolean(obj); if (json_object_object_get_ex(filter, "rx_id", &obj) && (json_object_is_type(obj, json_type_int))) event_filter.rx_id = (canid_t) json_object_get_int(obj); if (json_object_object_get_ex(filter, "tx_id", &obj) && (json_object_is_type(obj, json_type_int))) event_filter.tx_id = (canid_t) json_object_get_int(obj); } return event_filter; } static int one_subscribe_unsubscribe_events(afb_req_t request, bool subscribe, const std::string& tag, json_object* args) { int ret = 0; struct utils::signals_found sf; // subscribe or unsubscribe openxc_DynamicField search_key = build_DynamicField(tag); sf = utils::signals_manager_t::instance().find_signals(search_key); #ifdef USE_FEATURE_ISOTP if(sf.signals.size() > 1) { sf.signals.remove_if([](std::shared_ptr x){ bool isotp = x->get_message()->is_isotp(); if(isotp) AFB_NOTICE("ISO TP messages need to be subscribed one by one (rx, tx)"); return isotp; }); } #endif if (sf.signals.empty() && sf.diagnostic_messages.empty()) { AFB_NOTICE("No signal(s) found for %s.", tag.c_str()); ret = -1; } else { event_filter_t event_filter = generate_filter(args); ret = subscribe_unsubscribe_signals(request, subscribe, sf, event_filter); } return ret; } static int one_subscribe_unsubscribe_id(afb_req_t request, bool subscribe, const uint32_t& id, json_object *args) { int ret = 0; std::shared_ptr message_definition = application_t::instance().get_message_definition(id); struct utils::signals_found sf; if(message_definition) sf.signals = list_ptr_signal_t(message_definition->get_signals().begin(), message_definition->get_signals().end()); if(sf.signals.empty()) { AFB_NOTICE("No signal(s) found for %d.", id); ret = -1; } else { event_filter_t event_filter = generate_filter(args); ret = subscribe_unsubscribe_signals(request, subscribe, sf, event_filter); } return ret; } static int process_one_subscribe_args(afb_req_t request, bool subscribe, json_object *args) { int rc = 0, rc2=0; json_object *x = nullptr, *event = nullptr, *id = nullptr; // 2 cases : ID(PGN) and event json_object_object_get_ex(args,"event",&event); json_object_object_get_ex(args,"id",&id) || json_object_object_get_ex(args,"pgn",&id); if( args == NULL || (id && ((std::string)json_object_get_string(id)).compare("*") == 0)) { rc = one_subscribe_unsubscribe_events(request, subscribe, "*", args); } else { if(event) { if (json_object_get_type(event) != json_type_array) // event is set before and check if it's an array { rc = one_subscribe_unsubscribe_events(request, subscribe, json_object_get_string(event), args); } else // event is set and it's not an array { for (int i = 0 ; i < json_object_array_length(event); i++) { x = json_object_array_get_idx(event, i); rc2 = one_subscribe_unsubscribe_events(request, subscribe, json_object_get_string(x), args); if (rc >= 0) rc = rc2 >= 0 ? rc + rc2 : rc2; } } } if(id) { if (json_object_get_type(id) != json_type_array) // id is set before and check if it's an array { rc = one_subscribe_unsubscribe_id(request, subscribe, json_object_get_int(id), args); } else // event is set and it's not an array { for (int i = 0 ; i < json_object_array_length(id); i++) { x = json_object_array_get_idx(id, i); rc2 = one_subscribe_unsubscribe_id(request, subscribe, json_object_get_int(x), args); if (rc >= 0) rc = rc2 >= 0 ? rc + rc2 : rc2; } } } } return rc; } static void do_subscribe_unsubscribe(afb_req_t request, bool subscribe) { int rc = 0; struct json_object *args, *x; args = afb_req_json(request); if (json_object_get_type(args) == json_type_array) { for(int i = 0; i < json_object_array_length(args); i++) { x = json_object_array_get_idx(args, i); rc += process_one_subscribe_args(request, subscribe, x); } } else { rc += process_one_subscribe_args(request, subscribe, args); } if (rc >= 0) afb_req_success(request, NULL, NULL); else afb_req_fail(request, "error", NULL); } void auth(afb_req_t request) { afb_req_session_set_LOA(request, 1); afb_req_success(request, NULL, NULL); } void subscribe(afb_req_t request) { do_subscribe_unsubscribe(request, true); } void unsubscribe(afb_req_t request) { do_subscribe_unsubscribe(request, false); } static int send_message(message_t *message, const std::string& bus_name, uint32_t flags, event_filter_t &event_filter, std::shared_ptr signal) { if(bus_name.empty()) return -1; std::map >& cd = application_t::instance().get_can_devices(); if( cd.count(bus_name) == 0) cd[bus_name] = std::make_shared(low_can_subscription_t(event_filter)); cd[bus_name]->set_signal(signal); if(flags&CAN_PROTOCOL) return low_can_subscription_t::tx_send(*cd[bus_name], message, bus_name); #ifdef USE_FEATURE_ISOTP else if(flags&ISOTP_PROTOCOL) return low_can_subscription_t::isotp_send(*cd[bus_name], message, bus_name); #endif #ifdef USE_FEATURE_J1939 else if(flags&J1939_PROTOCOL) return low_can_subscription_t::j1939_send(*cd[bus_name], message, bus_name); #endif else return -1; } static void write_raw_frame(afb_req_t request, const std::string& bus_name, message_t *message, struct json_object *can_data, uint32_t flags, event_filter_t &event_filter) { struct utils::signals_found sf; utils::signals_manager_t::instance().lookup_signals_by_id(message->get_id(), application_t::instance().get_all_signals(), sf.signals); if( !sf.signals.empty() ) { AFB_DEBUG("ID WRITE RAW : %d", sf.signals.front()->get_message()->get_id()); if(flags & CAN_PROTOCOL) { if(sf.signals.front()->get_message()->is_fd()) { AFB_DEBUG("CANFD_MAX_DLEN"); message->set_flags(CAN_PROTOCOL_WITH_FD_FRAME); message->set_maxdlen(CANFD_MAX_DLEN); } else { AFB_DEBUG("CAN_MAX_DLEN"); message->set_maxdlen(CAN_MAX_DLEN); } if(sf.signals.front()->get_message()->is_isotp()) { flags = ISOTP_PROTOCOL; message->set_maxdlen(MAX_ISOTP_FRAMES * message->get_maxdlen()); } } #ifdef USE_FEATURE_J1939 if(flags&J1939_PROTOCOL) message->set_maxdlen(J1939_MAX_DLEN); #endif if(message->get_length() > 0 && message->get_length() <= message->get_maxdlen()) { std::vector data; for (int i = 0 ; i < message->get_length() ; i++) { struct json_object *one_can_data = json_object_array_get_idx(can_data, i); data.push_back((json_object_is_type(one_can_data, json_type_int)) ? (uint8_t)json_object_get_int(one_can_data) : 0); } message->set_data(data); } else { if(flags&CAN_PROTOCOL) afb_req_fail(request, "Invalid", "Frame BCM"); else if(flags&J1939_PROTOCOL) afb_req_fail(request, "Invalid", "Frame J1939"); else if(flags&ISOTP_PROTOCOL) afb_req_fail(request, "Invalid", "Frame ISOTP"); else afb_req_fail(request, "Invalid", "Frame"); return; } if(! send_message(message, application_t::instance().get_can_bus_manager().get_can_device_name(bus_name), flags, event_filter, sf.signals.front())) afb_req_success(request, nullptr, "Message correctly sent"); else afb_req_fail(request, "Error", "sending the message. See the log for more details."); } else { afb_req_fail(request, "Error", "no find id in signals. See the log for more details."); } } static void write_frame(afb_req_t request, const std::string& bus_name, json_object *json_value, event_filter_t &event_filter) { message_t *message; uint32_t id; uint32_t length; struct json_object *can_data = nullptr; std::vector data; AFB_DEBUG("JSON content %s", json_object_get_string(json_value)); if(!wrap_json_unpack(json_value, "{si, si, so !}", "can_id", &id, "can_dlc", &length, "can_data", &can_data)) { message = new can_message_t(0, id, length, false, 0, data, 0); write_raw_frame(request, bus_name, message, can_data, CAN_PROTOCOL, event_filter); } #ifdef USE_FEATURE_J1939 else if(!wrap_json_unpack(json_value, "{si, si, so !}", "pgn", &id, "length", &length, "data", &can_data)) { message = new j1939_message_t(length, data, 0, J1939_NO_NAME, (pgn_t)id, J1939_NO_ADDR); write_raw_frame(request, bus_name, message, can_data, J1939_PROTOCOL, event_filter); } #endif else { afb_req_fail(request, "Invalid", "Frame object malformed"); return; } delete message; } static void write_signal(afb_req_t request, const std::string& name, json_object *json_value, event_filter_t &event_filter) { struct canfd_frame cfd; struct utils::signals_found sf; signal_encoder encoder = nullptr; bool send = true; ::memset(&cfd, 0, sizeof(cfd)); openxc_DynamicField search_key = build_DynamicField(name); sf = utils::signals_manager_t::instance().find_signals(search_key); openxc_DynamicField dynafield_value = build_DynamicField(json_value); if (sf.signals.empty()) { afb_req_fail_f(request, "No signal(s) found for %s. Message not sent.", name.c_str()); return; } std::shared_ptr sig = sf.signals.front(); if(! sig->get_writable()) { afb_req_fail_f(request, "%s isn't writable. Message not sent.", sig->get_name().c_str()); return; } uint64_t value = (encoder = sig->get_encoder()) ? encoder(*sig, dynafield_value, &send) : encoder_t::encode_DynamicField(*sig, dynafield_value, &send); uint32_t flags = INVALID_FLAG; if(sig->get_message()->is_j1939()) flags = J1939_PROTOCOL; else if(sig->get_message()->is_isotp()) flags = ISOTP_PROTOCOL; else flags = CAN_PROTOCOL; // cfd = encoder_t::build_frame(sig, value); message_t *message = encoder_t::build_message(sig, value, false, false); if(! send_message(message, sig->get_message()->get_bus_device_name(), flags, event_filter, sig) && send) afb_req_success(request, nullptr, "Message correctly sent"); else afb_req_fail(request, "Error", "Sending the message. See the log for more details."); if(sig->get_message()->is_j1939()) #ifdef USE_FEATURE_J1939 delete (j1939_message_t*) message; #else afb_req_fail(request, "Warning", "J1939 not implemented in your kernel."); #endif else delete (can_message_t*) message; } void write(afb_req_t request) { struct json_object* args = nullptr, *json_value = nullptr, *name = nullptr; args = afb_req_json(request); if(args != NULL) { event_filter_t event_filter = generate_filter(args); if(json_object_object_get_ex(args,"bus_name",&name)) { if(json_object_object_get_ex(args,"frame",&json_value)) write_frame(request, (std::string)json_object_get_string(name), json_value, event_filter); else afb_req_fail(request, "Error", "Request argument malformed"); } else if(json_object_object_get_ex(args,"signal_name",&name)) { if(json_object_object_get_ex(args,"signal_value",&json_value)) write_signal(request, (std::string)json_object_get_string(name), json_value, event_filter); else afb_req_fail(request, "Error", "Request argument malformed"); } else { afb_req_fail(request, "Error", "Request argument malformed"); } } else { afb_req_fail(request, "Error", "Request argument null"); } } static struct json_object *get_signals_value(const std::string& name) { struct utils::signals_found sf; struct json_object *ans = nullptr; openxc_DynamicField search_key = build_DynamicField(name); sf = utils::signals_manager_t::instance().find_signals(search_key); if (sf.signals.empty()) { AFB_WARNING("No signal(s) found for %s.", name.c_str()); return NULL; } ans = json_object_new_array(); for(const auto& sig: sf.signals) { struct json_object *jobj = json_object_new_object(); json_object_object_add(jobj, "event", json_object_new_string(sig->get_name().c_str())); json_object_object_add(jobj, "value", json_object_new_double(sig->get_last_value())); json_object_array_add(ans, jobj); } return ans; } void get(afb_req_t request) { int rc = 0; struct json_object* args = nullptr, *json_name = nullptr; json_object *ans = nullptr; args = afb_req_json(request); // Process about Raw CAN message on CAN bus directly if (args != nullptr && (json_object_object_get_ex(args, "event", &json_name) && json_object_is_type(json_name, json_type_string) )) { ans = get_signals_value(json_object_get_string(json_name)); if (!ans) rc = -1; } else { AFB_ERROR("Request argument malformed. Please use the following syntax:"); rc = -1; } if (rc >= 0) afb_req_success(request, ans, NULL); else afb_req_fail(request, "error", NULL); } static struct json_object *list_can_message(const std::string& name) { struct utils::signals_found sf; struct json_object *ans = nullptr; openxc_DynamicField search_key = build_DynamicField(name); sf = utils::signals_manager_t::instance().find_signals(search_key); if (sf.signals.empty() && sf.diagnostic_messages.empty()) { AFB_WARNING("No signal(s) found for %s.", name.c_str()); return NULL; } ans = json_object_new_array(); for(const auto& sig: sf.signals) { json_object_array_add(ans, json_object_new_string(sig->get_name().c_str())); } for(const auto& sig: sf.diagnostic_messages) { json_object_array_add(ans, json_object_new_string(sig->get_name().c_str())); } return ans; } void list(afb_req_t request) { int rc = 0; json_object *ans = nullptr; struct json_object* args = nullptr, *json_name = nullptr; args = afb_req_json(request); const char *name; if ((args != nullptr) && (json_object_object_get_ex(args, "event", &json_name) && json_object_is_type(json_name, json_type_string))) name = json_object_get_string(json_name); else name = "*"; ans = list_can_message(name); if (!ans) rc = -1; if (rc >= 0) afb_req_success(request, ans, NULL); else afb_req_fail(request, "error", NULL); } /// @brief Initialize the binding. /// /// @param[in] service Structure which represent the Application Framework Binder. /// /// @return Exit code, zero if success. int init_binding(afb_api_t api) { int ret = 0; application_t& application = application_t::instance(); can_bus_t& can_bus_manager = application.get_can_bus_manager(); if(application.get_message_set().empty()) { AFB_ERROR("No message_set defined"); return -1; } can_bus_manager.start_threads(); utils::signals_manager_t& sm = utils::signals_manager_t::instance(); if (application.get_diagnostic_manager().is_initialized()) { // Add a recurring dignostic message request to get engine speed at all times. openxc_DynamicField search_key = build_DynamicField("diagnostic_messages.engine.speed"); struct utils::signals_found sf = sm.find_signals(search_key); if(sf.signals.empty() && sf.diagnostic_messages.size() == 1) { afb_req_t request = nullptr; struct event_filter_t event_filter; event_filter.frequency = sf.diagnostic_messages.front()->get_frequency(); map_subscription& s = sm.get_subscribed_signals(); subscribe_unsubscribe_diagnostic_messages(request, true, sf.diagnostic_messages, event_filter, s, true); } } #ifdef USE_FEATURE_J1939 std::string j1939_bus; vect_ptr_msg_def_t current_messages_definition = application.get_messages_definition(); for(std::shared_ptr message_definition: current_messages_definition) { if(message_definition->is_j1939()) { if (j1939_bus == message_definition->get_bus_device_name() ) continue; j1939_bus = message_definition->get_bus_device_name(); std::shared_ptr low_can_j1939 = std::make_shared(); application.set_subscription_address_claiming(low_can_j1939); ret = low_can_subscription_t::open_socket(*low_can_j1939, j1939_bus, J1939_ADDR_CLAIM_PROTOCOL); if(ret < 0) { AFB_ERROR("Error open socket address claiming for j1939 protocol"); return -1; } add_to_event_loop(low_can_j1939); break; } } #endif if(ret) AFB_ERROR("There was something wrong with CAN device Initialization."); return ret; } int load_config(afb_api_t api) { int ret = 0; CtlConfigT *ctlConfig; const char *dirList = getenv("CONTROL_CONFIG_PATH"); std::string bindingDirPath = GetBindingDirPath(api); std::string filepath = bindingDirPath + "/etc"; if (!dirList) dirList=CONTROL_CONFIG_PATH; filepath.append(":"); filepath.append(dirList); const char *configPath = CtlConfigSearch(api, filepath.c_str(), "control"); if (!configPath) { AFB_ERROR_V3("CtlPreInit: No control-%s* config found invalid JSON %s ", GetBinderName(), filepath.c_str()); return -1; } // create one API per file ctlConfig = CtlLoadMetaData(api, configPath); if (!ctlConfig) { AFB_ERROR_V3("CtrlPreInit No valid control config file in:\n-- %s", configPath); return -1; } // Save the config in the api userdata field afb_api_set_userdata(api, ctlConfig); setExternalData(ctlConfig, (void*) &application_t::instance()); ret= CtlLoadSections(api, ctlConfig, ctlSections_); return ret; }