/* * Copyright (C) 2015, 2016 "IoT.bzh" * Author "Romain Forlot" * * 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 "obd2/obd2-signals.hpp" #include "utils/signals.hpp" #define OBD2_FUNCTIONAL_BROADCAST_ID 0x7df const char *UNIT_NAMES[10] = { "POURCENT", "DEGREES_CELSIUS", "KPA", "RPM", "GRAMS_SEC", "SECONDS", "KM", "KM_H", "PA", "NM" }; /* * Pre-defined OBD-II PIDs to query for if supported by the vehicle. */ std::vector OBD2_PIDS = { { 0x04, "obd2.engine.load", 0, 100, POURCENT, 5, false}, { 0x05, "obd2.engine.coolant.temperature", -40, 215, DEGREES_CELSIUS, 1, false}, { 0x0a, "obd2.fuel.pressure", 0, 765, KPA, 1, false}, { 0x0b, "obd2.intake.manifold.pressure", 0, 255, KPA, 1, false}, { 0x0c, "obd2.engine.speed", 0, 16383, RPM, 5, false}, { 0x0d, "obd2.vehicle.speed", 0, 255, KM_H, 5, false}, { 0x0f, "obd2.intake.air.temperature", -40, 215, DEGREES_CELSIUS, 1, false}, { 0x10, "obd2.mass.airflow", 0, 655, GRAMS_SEC, 5, false}, { 0x11, "obd2.throttle.position", 0, 100, POURCENT, 5, false}, { 0x1f, "obd2.running.time", 0, 65535, SECONDS, 1, false}, { 0x2d, "obd2.EGR.error", -100, 99, POURCENT, 0, false}, { 0x2f, "obd2.fuel.level", 0, 100, POURCENT, 1, false}, { 0x33, "obd2.barometric.pressure", 0, 255, KPA, 1, false}, { 0x4c, "obd2.commanded.throttle.position", 0, 100, POURCENT, 1, false}, { 0x52, "obd2.ethanol.fuel.percentage", 0, 100, POURCENT, 1, false}, { 0x5a, "obd2.accelerator.pedal.position", 0, 100, POURCENT, 5, false}, { 0x5b, "obd2.hybrid.battery-pack.remaining.life", 0, 100, POURCENT, 5, false}, { 0x5c, "obd2.engine.oil.temperature",-40, 210, DEGREES_CELSIUS, 1, false}, { 0x63, "obd2.engine.torque", 0, 65535, NM, 1, false} }; uint32_t get_signal_id(obd2_signals_t& sig) { return sig.get_pid(); } std::vector& get_obd2_signals() { return OBD2_PIDS; } obd2_signals_t::obd2_signals_t(uint8_t pid, const char* generic_name, const int min, const int max, enum UNIT unit, int frequency, bool supported) : pid_{pid}, generic_name_{generic_name}, min_{min}, max_{max}, unit_{unit}, frequency_{frequency}, supported_{supported} { } uint32_t obd2_signals_t::get_pid() { return (uint32_t)pid_; } /** * @fn std::vector find_signals(const openxc_DynamicField &key) * @brief return signals name found searching through CAN_signals and OBD2 pid * * @param[in] const openxc_DynamicField : can contain numeric or string value in order to search against * can signals or obd2 signals name. * * @return std::vector Vector of signals name found. */ void obd2_signals_t::find_obd2_signals(const openxc_DynamicField &key, std::vector& found_signals) { switch(key.type) { case openxc_DynamicField_Type::openxc_DynamicField_Type_STRING: lookup_signals_by_name(key.string_value, get_obd2_signals(), found_signals); break; case openxc_DynamicField_Type::openxc_DynamicField_Type_NUM: lookup_signals_by_id(key.numeric_value, get_obd2_signals(), found_signals); break; default: ERROR(binder_interface, "find_signals: wrong openxc_DynamicField specified. Use openxc_DynamicField_Type_NUM or openxc_DynamicField_Type_STRING type only."); break; } DEBUG(binder_interface, "Found %d signal(s)", (int)found_signals.size()); } bool obd2_signals_t::is_obd2_response(can_message_t can_message) { /* if(can_message.get_id() >= 0x7E8 && can_message.get_id() <= 0x7EF) { openxc_VehicleMessage message = {0}; message.has_type = true; message.type = openxc_VehicleMessage_Type_DIAGNOSTIC; message.has_diagnostic_response = true; message.diagnostic_response = {0}; message.diagnostic_response.has_bus = true; message.diagnostic_response.bus = bus->address; message.diagnostic_response.has_message_id = true; //7DF should respond with a random message id between 7e8 and 7ef //7E0 through 7E7 should respond with a id that is 8 higher (7E0->7E8) if(can_message.get_id() == 0x7DF) { message.diagnostic_response.message_id = rand()%(0x7EF-0x7E8 + 1) + 0x7E8; } else if(commandRequest->message_id >= 0x7E0 && commandRequest->message_id <= 0x7E7) { message.diagnostic_response.message_id = commandRequest->message_id + 8; } message.diagnostic_response.has_mode = true; message.diagnostic_response.mode = commandRequest->mode; if(commandRequest->has_pid) { message.diagnostic_response.has_pid = true; message.diagnostic_response.pid = commandRequest->pid; } message.diagnostic_response.has_value = true; message.diagnostic_response.value = rand() % 100; pipeline::publish(&message, &getConfiguration()->pipeline); } else //If it's outside the range, the command_request will return false { debug("Sent message ID is outside the valid range for emulator (7DF to 7E7)"); status=false; } return false; } void obd2_signals_t::add_request(int pid) { DiagnosticRequest request = { arbitration_id: OBD2_FUNCTIONAL_BROADCAST_ID, mode: 0x1, has_true, pid}; } /** * @brief Check if a request is an OBD-II PID request. * * @return true if the request is a mode 1 request and it has a 1 byte PID. */ bool obd2_signals_t::is_obd2_request(DiagnosticRequest* request) { return request->mode == 0x1 && request->has_pid && request->pid < 0xff; } /** * @brief Check if requested signal name is an obd2 pid * * @return true if name began with obd2 else false. */ bool obd2_signals_t::is_obd2_signal(const char *name) { if(fnmatch("obd2.*", name, FNM_CASEFOLD) == 0) return true; return false; } /** * @brief Decode the payload of an OBD-II PID. * * This function matches the type signature for a DiagnosticResponseDecoder, so * it can be used as the decoder for a DiagnosticRequest. It returns the decoded * value of the PID, using the standard formulas (see * http://en.wikipedia.org/wiki/OBD-II_PIDs#Mode_01). * * @param[in] DiagnosticResponse response - the received DiagnosticResponse (the data is in response.payload, * a byte array). This is most often used when the byte order is * signiticant, i.e. with many OBD-II PID formulas. * @param[in] float parsed_payload - the entire payload of the response parsed as an int. */ float obd2_signals_t::decode_obd2_response(const DiagnosticResponse* response, float parsedPayload) { return diagnostic_decode_obd2_pid(response); }