/* * This file is free software: you can redistribute it and/or modify it * under the terms of the GNU General Public License as published by the * Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This file is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. * See the GNU General Public License for more details. * * You should have received a copy of the GNU General Public License along * with this program. If not, see . * * Author: Eugene Shamaev, Siddharth Bharat Purohit */ #include #include #if HAL_ENABLE_DRONECAN_DRIVERS #include "AP_DroneCAN.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "AP_DroneCAN_DNA_Server.h" #include #include #include #include #include #if AP_DRONECAN_SERIAL_ENABLED #include "AP_DroneCAN_serial.h" #endif #if AP_RELAY_DRONECAN_ENABLED #include #endif extern const AP_HAL::HAL& hal; // setup default pool size #ifndef DRONECAN_NODE_POOL_SIZE #if HAL_CANFD_SUPPORTED #define DRONECAN_NODE_POOL_SIZE 16384 #else #define DRONECAN_NODE_POOL_SIZE 8192 #endif #endif #if HAL_CANFD_SUPPORTED #define DRONECAN_STACK_SIZE 8192 #else #define DRONECAN_STACK_SIZE 4096 #endif #ifndef AP_DRONECAN_VOLZ_FEEDBACK_ENABLED #define AP_DRONECAN_VOLZ_FEEDBACK_ENABLED 0 #endif #define AP_DRONECAN_GETSET_TIMEOUT_MS 100 // timeout waiting for response from node after 0.1 sec #define debug_dronecan(level_debug, fmt, args...) do { AP::can().log_text(level_debug, "DroneCAN", fmt, ##args); } while (0) // Translation of all messages from DroneCAN structures into AP structures is done // in AP_DroneCAN and not in corresponding drivers. // The overhead of including definitions of DSDL is very high and it is best to // concentrate in one place. // table of user settable CAN bus parameters const AP_Param::GroupInfo AP_DroneCAN::var_info[] = { // @Param: NODE // @DisplayName: DroneCAN node that is used for this network // @Description: DroneCAN node should be set implicitly // @Range: 1 250 // @User: Advanced AP_GROUPINFO("NODE", 1, AP_DroneCAN, _dronecan_node, 10), // @Param: SRV_BM // @DisplayName: Output channels to be transmitted as servo over DroneCAN // @Description: Bitmask with one set for channel to be transmitted as a servo command over DroneCAN // @Bitmask: 0: Servo 1, 1: Servo 2, 2: Servo 3, 3: Servo 4, 4: Servo 5, 5: Servo 6, 6: Servo 7, 7: Servo 8, 8: Servo 9, 9: Servo 10, 10: Servo 11, 11: Servo 12, 12: Servo 13, 13: Servo 14, 14: Servo 15, 15: Servo 16, 16: Servo 17, 17: Servo 18, 18: Servo 19, 19: Servo 20, 20: Servo 21, 21: Servo 22, 22: Servo 23, 23: Servo 24, 24: Servo 25, 25: Servo 26, 26: Servo 27, 27: Servo 28, 28: Servo 29, 29: Servo 30, 30: Servo 31, 31: Servo 32 // @User: Advanced AP_GROUPINFO("SRV_BM", 2, AP_DroneCAN, _servo_bm, 0), // @Param: ESC_BM // @DisplayName: Output channels to be transmitted as ESC over DroneCAN // @Description: Bitmask with one set for channel to be transmitted as a ESC command over DroneCAN // @Bitmask: 0: ESC 1, 1: ESC 2, 2: ESC 3, 3: ESC 4, 4: ESC 5, 5: ESC 6, 6: ESC 7, 7: ESC 8, 8: ESC 9, 9: ESC 10, 10: ESC 11, 11: ESC 12, 12: ESC 13, 13: ESC 14, 14: ESC 15, 15: ESC 16, 16: ESC 17, 17: ESC 18, 18: ESC 19, 19: ESC 20, 20: ESC 21, 21: ESC 22, 22: ESC 23, 23: ESC 24, 24: ESC 25, 25: ESC 26, 26: ESC 27, 27: ESC 28, 28: ESC 29, 29: ESC 30, 30: ESC 31, 31: ESC 32 // @User: Advanced AP_GROUPINFO("ESC_BM", 3, AP_DroneCAN, _esc_bm, 0), // @Param: SRV_RT // @DisplayName: Servo output rate // @Description: Maximum transmit rate for servo outputs // @Range: 1 200 // @Units: Hz // @User: Advanced AP_GROUPINFO("SRV_RT", 4, AP_DroneCAN, _servo_rate_hz, 50), // @Param: OPTION // @DisplayName: DroneCAN options // @Description: Option flags // @Bitmask: 0:ClearDNADatabase,1:IgnoreDNANodeConflicts,2:EnableCanfd,3:IgnoreDNANodeUnhealthy,4:SendServoAsPWM,5:SendGNSS,6:UseHimarkServo,7:HobbyWingESC,8:EnableStats // @User: Advanced AP_GROUPINFO("OPTION", 5, AP_DroneCAN, _options, 0), // @Param: NTF_RT // @DisplayName: Notify State rate // @Description: Maximum transmit rate for Notify State Message // @Range: 1 200 // @Units: Hz // @User: Advanced AP_GROUPINFO("NTF_RT", 6, AP_DroneCAN, _notify_state_hz, 20), // @Param: ESC_OF // @DisplayName: ESC Output channels offset // @Description: Offset for ESC numbering in DroneCAN ESC RawCommand messages. This allows for more efficient packing of ESC command messages. If your ESCs are on servo functions 5 to 8 and you set this parameter to 4 then the ESC RawCommand will be sent with the first 4 slots filled. This can be used for more efficient usage of CAN bandwidth // @Range: 0 18 // @User: Advanced AP_GROUPINFO("ESC_OF", 7, AP_DroneCAN, _esc_offset, 0), // @Param: POOL // @DisplayName: CAN pool size // @Description: Amount of memory in bytes to allocate for the DroneCAN memory pool. More memory is needed for higher CAN bus loads // @Range: 1024 16384 // @User: Advanced AP_GROUPINFO("POOL", 8, AP_DroneCAN, _pool_size, DRONECAN_NODE_POOL_SIZE), // @Param: ESC_RV // @DisplayName: Bitmask for output channels for reversible ESCs over DroneCAN. // @Description: Bitmask with one set for each output channel that uses a reversible ESC over DroneCAN. Reversible ESCs use both positive and negative values in RawCommands, with positive commanding the forward direction and negative commanding the reverse direction. // @Bitmask: 0: ESC 1, 1: ESC 2, 2: ESC 3, 3: ESC 4, 4: ESC 5, 5: ESC 6, 6: ESC 7, 7: ESC 8, 8: ESC 9, 9: ESC 10, 10: ESC 11, 11: ESC 12, 12: ESC 13, 13: ESC 14, 14: ESC 15, 15: ESC 16, 16: ESC 17, 17: ESC 18, 18: ESC 19, 19: ESC 20, 20: ESC 21, 21: ESC 22, 22: ESC 23, 23: ESC 24, 24: ESC 25, 25: ESC 26, 26: ESC 27, 27: ESC 28, 28: ESC 29, 29: ESC 30, 30: ESC 31, 31: ESC 32 // @User: Advanced AP_GROUPINFO("ESC_RV", 9, AP_DroneCAN, _esc_rv, 0), #if AP_RELAY_DRONECAN_ENABLED // @Param: RLY_RT // @DisplayName: DroneCAN relay output rate // @Description: Maximum transmit rate for relay outputs, note that this rate is per message each message does 1 relay, so if with more relays will take longer to update at the same rate, a extra message will be sent when a relay changes state // @Range: 0 200 // @Units: Hz // @User: Advanced AP_GROUPINFO("RLY_RT", 23, AP_DroneCAN, _relay.rate_hz, 0), #endif #if AP_DRONECAN_SERIAL_ENABLED /* due to the parameter tree depth limitation we can't use a sub-table for the serial parameters */ // @Param: SER_EN // @DisplayName: DroneCAN Serial enable // @Description: Enable DroneCAN virtual serial ports // @Values: 0:Disabled, 1:Enabled // @RebootRequired: True // @User: Advanced AP_GROUPINFO_FLAGS("SER_EN", 10, AP_DroneCAN, serial.enable, 0, AP_PARAM_FLAG_ENABLE), // @Param: S1_NOD // @DisplayName: Serial CAN remote node number // @Description: CAN remote node number for serial port // @Range: 0 127 // @RebootRequired: True // @User: Advanced AP_GROUPINFO("S1_NOD", 11, AP_DroneCAN, serial.ports[0].node, 0), // @Param: S1_IDX // @DisplayName: DroneCAN Serial1 index // @Description: Serial port number on remote CAN node // @Range: 0 100 // @Values: -1:Disabled,0:Serial0,1:Serial1,2:Serial2,3:Serial3,4:Serial4,5:Serial5,6:Serial6 // @RebootRequired: True // @User: Advanced AP_GROUPINFO("S1_IDX", 12, AP_DroneCAN, serial.ports[0].idx, -1), // @Param: S1_BD // @DisplayName: DroneCAN Serial default baud rate // @Description: Serial baud rate on remote CAN node // @CopyFieldsFrom: SERIAL1_BAUD // @RebootRequired: True // @User: Advanced AP_GROUPINFO("S1_BD", 13, AP_DroneCAN, serial.ports[0].state.baud, 57600), // @Param: S1_PRO // @DisplayName: Serial protocol of DroneCAN serial port // @Description: Serial protocol of DroneCAN serial port // @CopyFieldsFrom: SERIAL1_PROTOCOL // @RebootRequired: True // @User: Advanced AP_GROUPINFO("S1_PRO", 14, AP_DroneCAN, serial.ports[0].state.protocol, -1), #if AP_DRONECAN_SERIAL_NUM_PORTS > 1 // @Param: S2_NOD // @DisplayName: Serial CAN remote node number // @Description: CAN remote node number for serial port // @CopyFieldsFrom: CAN_D1_UC_S1_NOD AP_GROUPINFO("S2_NOD", 15, AP_DroneCAN, serial.ports[1].node, 0), // @Param: S2_IDX // @DisplayName: Serial port number on remote CAN node // @Description: Serial port number on remote CAN node // @CopyFieldsFrom: CAN_D1_UC_S1_IDX AP_GROUPINFO("S2_IDX", 16, AP_DroneCAN, serial.ports[1].idx, -1), // @Param: S2_BD // @DisplayName: DroneCAN Serial default baud rate // @Description: Serial baud rate on remote CAN node // @CopyFieldsFrom: CAN_D1_UC_S1_BD AP_GROUPINFO("S2_BD", 17, AP_DroneCAN, serial.ports[1].state.baud, 57600), // @Param: S2_PRO // @DisplayName: Serial protocol of DroneCAN serial port // @Description: Serial protocol of DroneCAN serial port // @CopyFieldsFrom: CAN_D1_UC_S1_PRO AP_GROUPINFO("S2_PRO", 18, AP_DroneCAN, serial.ports[1].state.protocol, -1), #endif #if AP_DRONECAN_SERIAL_NUM_PORTS > 2 // @Param: S3_NOD // @DisplayName: Serial CAN remote node number // @Description: CAN node number for serial port // @CopyFieldsFrom: CAN_D1_UC_S1_NOD AP_GROUPINFO("S3_NOD", 19, AP_DroneCAN, serial.ports[2].node, 0), // @Param: S3_IDX // @DisplayName: Serial port number on remote CAN node // @Description: Serial port number on remote CAN node // @CopyFieldsFrom: CAN_D1_UC_S1_IDX AP_GROUPINFO("S3_IDX", 20, AP_DroneCAN, serial.ports[2].idx, 0), // @Param: S3_BD // @DisplayName: Serial baud rate on remote CAN node // @Description: Serial baud rate on remote CAN node // @CopyFieldsFrom: CAN_D1_UC_S1_BD AP_GROUPINFO("S3_BD", 21, AP_DroneCAN, serial.ports[2].state.baud, 57600), // @Param: S3_PRO // @DisplayName: Serial protocol of DroneCAN serial port // @Description: Serial protocol of DroneCAN serial port // @CopyFieldsFrom: CAN_D1_UC_S1_PRO AP_GROUPINFO("S3_PRO", 22, AP_DroneCAN, serial.ports[2].state.protocol, -1), #endif #endif // AP_DRONECAN_SERIAL_ENABLED // RLY_RT is index 23 but has to be above SER_EN so its not hidden AP_GROUPEND }; // this is the timeout in milliseconds for periodic message types. We // set this to 1 to minimise resend of stale msgs #define CAN_PERIODIC_TX_TIMEOUT_MS 2 AP_DroneCAN::AP_DroneCAN(const int driver_index) : _driver_index(driver_index), canard_iface(driver_index), _dna_server(*this, canard_iface, driver_index) { AP_Param::setup_object_defaults(this, var_info); for (uint8_t i = 0; i < DRONECAN_SRV_NUMBER; i++) { _SRV_conf[i].esc_pending = false; _SRV_conf[i].servo_pending = false; } debug_dronecan(AP_CANManager::LOG_INFO, "AP_DroneCAN constructed\n\r"); } AP_DroneCAN::~AP_DroneCAN() { } AP_DroneCAN *AP_DroneCAN::get_dronecan(uint8_t driver_index) { if (driver_index >= AP::can().get_num_drivers() || AP::can().get_driver_type(driver_index) != AP_CAN::Protocol::DroneCAN) { return nullptr; } return static_cast(AP::can().get_driver(driver_index)); } bool AP_DroneCAN::add_interface(AP_HAL::CANIface* can_iface) { if (!canard_iface.add_interface(can_iface)) { debug_dronecan(AP_CANManager::LOG_ERROR, "DroneCAN: can't add DroneCAN interface\n\r"); return false; } return true; } void AP_DroneCAN::init(uint8_t driver_index, bool enable_filters) { if (driver_index != _driver_index) { debug_dronecan(AP_CANManager::LOG_ERROR, "DroneCAN: init called with wrong driver_index"); return; } if (_initialized) { debug_dronecan(AP_CANManager::LOG_ERROR, "DroneCAN: init called more than once\n\r"); return; } node_info_rsp.name.len = hal.util->snprintf((char*)node_info_rsp.name.data, sizeof(node_info_rsp.name.data), "org.ardupilot:%u", driver_index); node_info_rsp.software_version.major = AP_DRONECAN_SW_VERS_MAJOR; node_info_rsp.software_version.minor = AP_DRONECAN_SW_VERS_MINOR; node_info_rsp.hardware_version.major = AP_DRONECAN_HW_VERS_MAJOR; node_info_rsp.hardware_version.minor = AP_DRONECAN_HW_VERS_MINOR; #if HAL_CANFD_SUPPORTED if (option_is_set(Options::CANFD_ENABLED)) { canard_iface.set_canfd(true); } #endif uint8_t uid_len = sizeof(uavcan_protocol_HardwareVersion::unique_id); uint8_t unique_id[sizeof(uavcan_protocol_HardwareVersion::unique_id)]; mem_pool = new uint32_t[_pool_size/sizeof(uint32_t)]; if (mem_pool == nullptr) { debug_dronecan(AP_CANManager::LOG_ERROR, "DroneCAN: Failed to allocate memory pool\n\r"); return; } canard_iface.init(mem_pool, (_pool_size/sizeof(uint32_t))*sizeof(uint32_t), _dronecan_node); if (!hal.util->get_system_id_unformatted(unique_id, uid_len)) { return; } unique_id[uid_len - 1] += _dronecan_node; memcpy(node_info_rsp.hardware_version.unique_id, unique_id, uid_len); //Start Servers if (!_dna_server.init(unique_id, uid_len, _dronecan_node)) { debug_dronecan(AP_CANManager::LOG_ERROR, "DroneCAN: Failed to start DNA Server\n\r"); return; } // Roundup all subscribers from supported drivers #if AP_GPS_DRONECAN_ENABLED AP_GPS_DroneCAN::subscribe_msgs(this); #endif #if AP_COMPASS_DRONECAN_ENABLED AP_Compass_DroneCAN::subscribe_msgs(this); #endif #if AP_BARO_DRONECAN_ENABLED AP_Baro_DroneCAN::subscribe_msgs(this); #endif AP_BattMonitor_DroneCAN::subscribe_msgs(this); #if AP_AIRSPEED_DRONECAN_ENABLED AP_Airspeed_DroneCAN::subscribe_msgs(this); #endif #if AP_OPTICALFLOW_HEREFLOW_ENABLED AP_OpticalFlow_HereFlow::subscribe_msgs(this); #endif #if AP_RANGEFINDER_DRONECAN_ENABLED AP_RangeFinder_DroneCAN::subscribe_msgs(this); #endif #if AP_RCPROTOCOL_DRONECAN_ENABLED AP_RCProtocol_DroneCAN::subscribe_msgs(this); #endif #if AP_EFI_DRONECAN_ENABLED AP_EFI_DroneCAN::subscribe_msgs(this); #endif #if AP_PROXIMITY_DRONECAN_ENABLED AP_Proximity_DroneCAN::subscribe_msgs(this); #endif #if HAL_MOUNT_XACTI_ENABLED AP_Mount_Xacti::subscribe_msgs(this); #endif act_out_array.set_timeout_ms(5); act_out_array.set_priority(CANARD_TRANSFER_PRIORITY_HIGH); esc_raw.set_timeout_ms(2); // esc_raw is one higher than high priority to ensure that it is given higher priority over act_out_array esc_raw.set_priority(CANARD_TRANSFER_PRIORITY_HIGH - 1); #if AP_DRONECAN_HOBBYWING_ESC_SUPPORT esc_hobbywing_raw.set_timeout_ms(2); esc_hobbywing_raw.set_priority(CANARD_TRANSFER_PRIORITY_HIGH); #endif #if AP_DRONECAN_HIMARK_SERVO_SUPPORT himark_out.set_timeout_ms(2); himark_out.set_priority(CANARD_TRANSFER_PRIORITY_HIGH); #endif rgb_led.set_timeout_ms(20); rgb_led.set_priority(CANARD_TRANSFER_PRIORITY_LOW); buzzer.set_timeout_ms(20); buzzer.set_priority(CANARD_TRANSFER_PRIORITY_LOW); safety_state.set_timeout_ms(20); safety_state.set_priority(CANARD_TRANSFER_PRIORITY_LOW); arming_status.set_timeout_ms(20); arming_status.set_priority(CANARD_TRANSFER_PRIORITY_LOW); #if AP_DRONECAN_SEND_GPS gnss_fix2.set_timeout_ms(20); gnss_fix2.set_priority(CANARD_TRANSFER_PRIORITY_LOW); gnss_auxiliary.set_timeout_ms(20); gnss_auxiliary.set_priority(CANARD_TRANSFER_PRIORITY_LOW); gnss_heading.set_timeout_ms(20); gnss_heading.set_priority(CANARD_TRANSFER_PRIORITY_LOW); gnss_status.set_timeout_ms(20); gnss_status.set_priority(CANARD_TRANSFER_PRIORITY_LOW); #endif rtcm_stream.set_timeout_ms(20); rtcm_stream.set_priority(CANARD_TRANSFER_PRIORITY_LOW); notify_state.set_timeout_ms(20); notify_state.set_priority(CANARD_TRANSFER_PRIORITY_LOW); #if HAL_MOUNT_XACTI_ENABLED xacti_copter_att_status.set_timeout_ms(20); xacti_copter_att_status.set_priority(CANARD_TRANSFER_PRIORITY_LOW); xacti_gimbal_control_data.set_timeout_ms(20); xacti_gimbal_control_data.set_priority(CANARD_TRANSFER_PRIORITY_LOW); xacti_gnss_status.set_timeout_ms(20); xacti_gnss_status.set_priority(CANARD_TRANSFER_PRIORITY_LOW); #endif #if AP_RELAY_DRONECAN_ENABLED relay_hardpoint.set_timeout_ms(20); relay_hardpoint.set_priority(CANARD_TRANSFER_PRIORITY_LOW); #endif param_save_client.set_timeout_ms(20); param_save_client.set_priority(CANARD_TRANSFER_PRIORITY_LOW); param_get_set_client.set_timeout_ms(20); param_get_set_client.set_priority(CANARD_TRANSFER_PRIORITY_LOW); node_status.set_priority(CANARD_TRANSFER_PRIORITY_LOWEST); node_status.set_timeout_ms(1000); protocol_stats.set_priority(CANARD_TRANSFER_PRIORITY_LOWEST); protocol_stats.set_timeout_ms(3000); can_stats.set_priority(CANARD_TRANSFER_PRIORITY_LOWEST); can_stats.set_timeout_ms(3000); node_info_server.set_timeout_ms(20); // setup node status node_status_msg.health = UAVCAN_PROTOCOL_NODESTATUS_HEALTH_OK; node_status_msg.mode = UAVCAN_PROTOCOL_NODESTATUS_MODE_OPERATIONAL; node_status_msg.sub_mode = 0; // Spin node for device discovery for (uint8_t i = 0; i < 5; i++) { send_node_status(); canard_iface.process(1000); } hal.util->snprintf(_thread_name, sizeof(_thread_name), "dronecan_%u", driver_index); if (!hal.scheduler->thread_create(FUNCTOR_BIND_MEMBER(&AP_DroneCAN::loop, void), _thread_name, DRONECAN_STACK_SIZE, AP_HAL::Scheduler::PRIORITY_CAN, 0)) { debug_dronecan(AP_CANManager::LOG_ERROR, "DroneCAN: couldn't create thread\n\r"); return; } #if AP_DRONECAN_SERIAL_ENABLED serial.init(this); #endif _initialized = true; debug_dronecan(AP_CANManager::LOG_INFO, "DroneCAN: init done\n\r"); } void AP_DroneCAN::loop(void) { while (true) { if (!_initialized) { hal.scheduler->delay_microseconds(1000); continue; } canard_iface.process(1); safety_state_send(); notify_state_send(); check_parameter_callback_timeout(); send_parameter_request(); send_parameter_save_request(); send_node_status(); _dna_server.verify_nodes(); #if AP_DRONECAN_SEND_GPS && AP_GPS_DRONECAN_ENABLED if (option_is_set(AP_DroneCAN::Options::SEND_GNSS) && !AP_GPS_DroneCAN::instance_exists(this)) { // send if enabled and this interface/driver is not used by the AP_GPS driver gnss_send_fix(); gnss_send_yaw(); } #endif logging(); #if AP_DRONECAN_HOBBYWING_ESC_SUPPORT hobbywing_ESC_update(); #endif if (_SRV_armed_mask != 0) { // we have active servos uint32_t now = AP_HAL::micros(); const uint32_t servo_period_us = 1000000UL / unsigned(_servo_rate_hz.get()); if (now - _SRV_last_send_us >= servo_period_us) { _SRV_last_send_us = now; #if AP_DRONECAN_HIMARK_SERVO_SUPPORT if (option_is_set(Options::USE_HIMARK_SERVO)) { SRV_send_himark(); } else #endif { SRV_send_actuator(); } for (uint8_t i = 0; i < DRONECAN_SRV_NUMBER; i++) { _SRV_conf[i].servo_pending = false; } } } #if AP_DRONECAN_SERIAL_ENABLED serial.update(); #endif #if AP_RELAY_DRONECAN_ENABLED relay_hardpoint_send(); #endif } } #if AP_DRONECAN_HOBBYWING_ESC_SUPPORT void AP_DroneCAN::hobbywing_ESC_update(void) { if (hal.util->get_soft_armed()) { // don't update ID database while disarmed, as it can cause // some hobbywing ESCs to stutter return; } uint32_t now = AP_HAL::millis(); if (now - hobbywing.last_GetId_send_ms >= 1000U) { hobbywing.last_GetId_send_ms = now; com_hobbywing_esc_GetEscID msg; msg.payload.len = 1; msg.payload.data[0] = 0; esc_hobbywing_GetEscID.broadcast(msg); } } /* handle hobbywing GetEscID reply. This gets us the mapping between CAN NodeID and throttle channel */ void AP_DroneCAN::handle_hobbywing_GetEscID(const CanardRxTransfer& transfer, const com_hobbywing_esc_GetEscID& msg) { if (msg.payload.len == 2 && msg.payload.data[0] == transfer.source_node_id) { // throttle channel is 2nd payload byte const uint8_t thr_channel = msg.payload.data[1]; if (thr_channel > 0 && thr_channel <= HOBBYWING_MAX_ESC) { hobbywing.thr_chan[thr_channel-1] = transfer.source_node_id; } } } /* find the ESC index given a CAN node ID */ bool AP_DroneCAN::hobbywing_find_esc_index(uint8_t node_id, uint8_t &esc_index) const { for (uint8_t i=0; iget_statistics(); if (bus_stats == nullptr) { continue; } dronecan_protocol_CanStats can_stats_msg; can_stats_msg.interface = i; can_stats_msg.tx_requests = bus_stats->tx_requests; can_stats_msg.tx_rejected = bus_stats->tx_rejected; can_stats_msg.tx_overflow = bus_stats->tx_overflow; can_stats_msg.tx_success = bus_stats->tx_success; can_stats_msg.tx_timedout = bus_stats->tx_timedout; can_stats_msg.tx_abort = bus_stats->tx_abort; can_stats_msg.rx_received = bus_stats->rx_received; can_stats_msg.rx_overflow = bus_stats->rx_overflow; can_stats_msg.rx_errors = bus_stats->rx_errors; can_stats_msg.busoff_errors = bus_stats->num_busoff_err; can_stats.broadcast(can_stats_msg); } } } void AP_DroneCAN::handle_node_info_request(const CanardRxTransfer& transfer, const uavcan_protocol_GetNodeInfoRequest& req) { node_info_rsp.status = node_status_msg; node_info_rsp.status.uptime_sec = AP_HAL::millis() / 1000; node_info_server.respond(transfer, node_info_rsp); } int16_t AP_DroneCAN::scale_esc_output(uint8_t idx){ static const int16_t cmd_max = ((1<<13)-1); float scaled = 0; //Check if this channel has a reversible ESC. If it does, we can send negative commands. if ((((uint32_t) 1) << idx) & _esc_rv) { scaled = cmd_max * (hal.rcout->scale_esc_to_unity(_SRV_conf[idx].pulse)); } else { scaled = cmd_max * (hal.rcout->scale_esc_to_unity(_SRV_conf[idx].pulse) + 1.0) / 2.0; scaled = constrain_float(scaled, 0, cmd_max); } return static_cast(scaled); } ///// SRV output ///// void AP_DroneCAN::SRV_send_actuator(void) { uint8_t starting_servo = 0; bool repeat_send; WITH_SEMAPHORE(SRV_sem); do { repeat_send = false; uavcan_equipment_actuator_ArrayCommand msg; uint8_t i; // DroneCAN can hold maximum of 15 commands in one frame for (i = 0; starting_servo < DRONECAN_SRV_NUMBER && i < 15; starting_servo++) { uavcan_equipment_actuator_Command cmd; /* * Servo output uses a range of 1000-2000 PWM for scaling. * This converts output PWM from [1000:2000] range to [-1:1] range that * is passed to servo as unitless type via DroneCAN. * This approach allows for MIN/TRIM/MAX values to be used fully on * autopilot side and for servo it should have the setup to provide maximum * physically possible throws at [-1:1] limits. */ if (_SRV_conf[starting_servo].servo_pending && ((((uint32_t) 1) << starting_servo) & _SRV_armed_mask)) { cmd.actuator_id = starting_servo + 1; if (option_is_set(Options::USE_ACTUATOR_PWM)) { cmd.command_type = UAVCAN_EQUIPMENT_ACTUATOR_COMMAND_COMMAND_TYPE_PWM; cmd.command_value = _SRV_conf[starting_servo].pulse; } else { cmd.command_type = UAVCAN_EQUIPMENT_ACTUATOR_COMMAND_COMMAND_TYPE_UNITLESS; cmd.command_value = constrain_float(((float) _SRV_conf[starting_servo].pulse - 1000.0) / 500.0 - 1.0, -1.0, 1.0); } msg.commands.data[i] = cmd; i++; } } msg.commands.len = i; if (i > 0) { if (act_out_array.broadcast(msg) > 0) { _srv_send_count++; } else { _fail_send_count++; } if (i == 15) { repeat_send = true; } } } while (repeat_send); } #if AP_DRONECAN_HIMARK_SERVO_SUPPORT /* Himark servo output. This uses com.himark.servo.ServoCmd packets */ void AP_DroneCAN::SRV_send_himark(void) { WITH_SEMAPHORE(SRV_sem); // ServoCmd can hold maximum of 17 commands. First find the highest pending servo < 17 int8_t highest_to_send = -1; for (int8_t i = 16; i >= 0; i--) { if (_SRV_conf[i].servo_pending && ((1U< 0) { k = 0; for (uint8_t i = esc_offset; i < max_esc_num && k < 20; i++) { if ((((uint32_t) 1) << i) & _ESC_armed_mask) { esc_msg.cmd.data[k] = scale_esc_output(i); } else { esc_msg.cmd.data[k] = static_cast(0); } k++; } esc_msg.cmd.len = k; if (esc_raw.broadcast(esc_msg)) { _esc_send_count++; } else { _fail_send_count++; } // immediately push data to CAN bus canard_iface.processTx(true); } for (uint8_t i = 0; i < DRONECAN_SRV_NUMBER; i++) { _SRV_conf[i].esc_pending = false; } } #if AP_DRONECAN_HOBBYWING_ESC_SUPPORT /* support for Hobbywing DroneCAN ESCs */ void AP_DroneCAN::SRV_send_esc_hobbywing(void) { com_hobbywing_esc_RawCommand esc_msg; uint8_t active_esc_num = 0, max_esc_num = 0; uint8_t k = 0; // esc offset allows for efficient packing of higher ESC numbers in RawCommand const uint8_t esc_offset = constrain_int16(_esc_offset.get(), 0, DRONECAN_SRV_NUMBER); // find out how many esc we have enabled and if they are active at all for (uint8_t i = esc_offset; i < DRONECAN_SRV_NUMBER; i++) { if ((((uint32_t) 1) << i) & _ESC_armed_mask) { max_esc_num = i + 1; if (_SRV_conf[i].esc_pending) { active_esc_num++; } } } // if at least one is active (update) we need to send to all if (active_esc_num > 0) { k = 0; for (uint8_t i = esc_offset; i < max_esc_num && k < 20; i++) { if ((((uint32_t) 1) << i) & _ESC_armed_mask) { esc_msg.command.data[k] = scale_esc_output(i); } else { esc_msg.command.data[k] = static_cast(0); } k++; } esc_msg.command.len = k; if (esc_hobbywing_raw.broadcast(esc_msg)) { _esc_send_count++; } else { _fail_send_count++; } // immediately push data to CAN bus canard_iface.processTx(true); } } #endif // AP_DRONECAN_HOBBYWING_ESC_SUPPORT void AP_DroneCAN::SRV_push_servos() { WITH_SEMAPHORE(SRV_sem); for (uint8_t i = 0; i < DRONECAN_SRV_NUMBER; i++) { // Check if this channels has any function assigned if (SRV_Channels::channel_function(i) >= SRV_Channel::k_none) { _SRV_conf[i].pulse = SRV_Channels::srv_channel(i)->get_output_pwm(); _SRV_conf[i].esc_pending = true; _SRV_conf[i].servo_pending = true; } } uint32_t servo_armed_mask = _servo_bm; uint32_t esc_armed_mask = _esc_bm; const bool safety_off = hal.util->safety_switch_state() != AP_HAL::Util::SAFETY_DISARMED; if (!safety_off) { AP_BoardConfig *boardconfig = AP_BoardConfig::get_singleton(); if (boardconfig != nullptr) { const uint32_t safety_mask = boardconfig->get_safety_mask(); servo_armed_mask &= safety_mask; esc_armed_mask &= safety_mask; } else { servo_armed_mask = 0; esc_armed_mask = 0; } } _SRV_armed_mask = servo_armed_mask; _ESC_armed_mask = esc_armed_mask; if (_ESC_armed_mask != 0) { // push ESCs as fast as we can #if AP_DRONECAN_HOBBYWING_ESC_SUPPORT if (option_is_set(Options::USE_HOBBYWING_ESC)) { SRV_send_esc_hobbywing(); } else #endif { SRV_send_esc(); } } } // notify state send void AP_DroneCAN::notify_state_send() { uint32_t now = AP_HAL::millis(); if (_notify_state_hz == 0 || (now - _last_notify_state_ms) < uint32_t(1000 / _notify_state_hz)) { return; } ardupilot_indication_NotifyState msg; msg.vehicle_state = 0; if (AP_Notify::flags.initialising) { msg.vehicle_state |= 1 << ARDUPILOT_INDICATION_NOTIFYSTATE_VEHICLE_STATE_INITIALISING; } if (AP_Notify::flags.armed) { msg.vehicle_state |= 1 << ARDUPILOT_INDICATION_NOTIFYSTATE_VEHICLE_STATE_ARMED; } if (AP_Notify::flags.flying) { msg.vehicle_state |= 1 << ARDUPILOT_INDICATION_NOTIFYSTATE_VEHICLE_STATE_FLYING; } if (AP_Notify::flags.compass_cal_running) { msg.vehicle_state |= 1 << ARDUPILOT_INDICATION_NOTIFYSTATE_VEHICLE_STATE_MAGCAL_RUN; } if (AP_Notify::flags.ekf_bad) { msg.vehicle_state |= 1 << ARDUPILOT_INDICATION_NOTIFYSTATE_VEHICLE_STATE_EKF_BAD; } if (AP_Notify::flags.esc_calibration) { msg.vehicle_state |= 1 << ARDUPILOT_INDICATION_NOTIFYSTATE_VEHICLE_STATE_ESC_CALIBRATION; } if (AP_Notify::flags.failsafe_battery) { msg.vehicle_state |= 1 << ARDUPILOT_INDICATION_NOTIFYSTATE_VEHICLE_STATE_FAILSAFE_BATT; } if (AP_Notify::flags.failsafe_gcs) { msg.vehicle_state |= 1 << ARDUPILOT_INDICATION_NOTIFYSTATE_VEHICLE_STATE_FAILSAFE_GCS; } if (AP_Notify::flags.failsafe_radio) { msg.vehicle_state |= 1 << ARDUPILOT_INDICATION_NOTIFYSTATE_VEHICLE_STATE_FAILSAFE_RADIO; } if (AP_Notify::flags.firmware_update) { msg.vehicle_state |= 1 << ARDUPILOT_INDICATION_NOTIFYSTATE_VEHICLE_STATE_FW_UPDATE; } if (AP_Notify::flags.gps_fusion) { msg.vehicle_state |= 1 << ARDUPILOT_INDICATION_NOTIFYSTATE_VEHICLE_STATE_GPS_FUSION; } if (AP_Notify::flags.gps_glitching) { msg.vehicle_state |= 1 << ARDUPILOT_INDICATION_NOTIFYSTATE_VEHICLE_STATE_GPS_GLITCH; } if (AP_Notify::flags.have_pos_abs) { msg.vehicle_state |= 1 << ARDUPILOT_INDICATION_NOTIFYSTATE_VEHICLE_STATE_POS_ABS_AVAIL; } if (AP_Notify::flags.leak_detected) { msg.vehicle_state |= 1 << ARDUPILOT_INDICATION_NOTIFYSTATE_VEHICLE_STATE_LEAK_DET; } if (AP_Notify::flags.parachute_release) { msg.vehicle_state |= 1 << ARDUPILOT_INDICATION_NOTIFYSTATE_VEHICLE_STATE_CHUTE_RELEASED; } if (AP_Notify::flags.powering_off) { msg.vehicle_state |= 1 << ARDUPILOT_INDICATION_NOTIFYSTATE_VEHICLE_STATE_POWERING_OFF; } if (AP_Notify::flags.pre_arm_check) { msg.vehicle_state |= 1 << ARDUPILOT_INDICATION_NOTIFYSTATE_VEHICLE_STATE_PREARM; } if (AP_Notify::flags.pre_arm_gps_check) { msg.vehicle_state |= 1 << ARDUPILOT_INDICATION_NOTIFYSTATE_VEHICLE_STATE_PREARM_GPS; } if (AP_Notify::flags.save_trim) { msg.vehicle_state |= 1 << ARDUPILOT_INDICATION_NOTIFYSTATE_VEHICLE_STATE_SAVE_TRIM; } if (AP_Notify::flags.vehicle_lost) { msg.vehicle_state |= 1 << ARDUPILOT_INDICATION_NOTIFYSTATE_VEHICLE_STATE_LOST; } if (AP_Notify::flags.video_recording) { msg.vehicle_state |= 1 << ARDUPILOT_INDICATION_NOTIFYSTATE_VEHICLE_STATE_VIDEO_RECORDING; } if (AP_Notify::flags.waiting_for_throw) { msg.vehicle_state |= 1 << ARDUPILOT_INDICATION_NOTIFYSTATE_VEHICLE_STATE_THROW_READY; } #ifndef HAL_BUILD_AP_PERIPH const AP_Vehicle* vehicle = AP::vehicle(); if (vehicle != nullptr) { if (vehicle->is_landing()) { msg.vehicle_state |= 1 << ARDUPILOT_INDICATION_NOTIFYSTATE_VEHICLE_STATE_IS_LANDING; } if (vehicle->is_taking_off()) { msg.vehicle_state |= 1 << ARDUPILOT_INDICATION_NOTIFYSTATE_VEHICLE_STATE_IS_TAKING_OFF; } } #endif // HAL_BUILD_AP_PERIPH msg.aux_data_type = ARDUPILOT_INDICATION_NOTIFYSTATE_VEHICLE_YAW_EARTH_CENTIDEGREES; uint16_t yaw_cd = (uint16_t)(360.0f - degrees(AP::ahrs().get_yaw()))*100.0f; const uint8_t *data = (uint8_t *)&yaw_cd; for (uint8_t i=0; i<2; i++) { msg.aux_data.data[i] = data[i]; } msg.aux_data.len = 2; notify_state.broadcast(msg); _last_notify_state_ms = AP_HAL::millis(); } #if AP_DRONECAN_SEND_GPS void AP_DroneCAN::gnss_send_fix() { const AP_GPS &gps = AP::gps(); const uint32_t gps_lib_time_ms = gps.last_message_time_ms(); if (_gnss.last_gps_lib_fix_ms == gps_lib_time_ms) { return; } _gnss.last_gps_lib_fix_ms = gps_lib_time_ms; /* send Fix2 packet */ uavcan_equipment_gnss_Fix2 pkt {}; const Location &loc = gps.location(); const Vector3f &vel = gps.velocity(); pkt.timestamp.usec = AP_HAL::micros64(); pkt.gnss_timestamp.usec = gps.time_epoch_usec(); if (pkt.gnss_timestamp.usec == 0) { pkt.gnss_time_standard = UAVCAN_EQUIPMENT_GNSS_FIX2_GNSS_TIME_STANDARD_NONE; } else { pkt.gnss_time_standard = UAVCAN_EQUIPMENT_GNSS_FIX2_GNSS_TIME_STANDARD_UTC; } pkt.longitude_deg_1e8 = uint64_t(loc.lng) * 10ULL; pkt.latitude_deg_1e8 = uint64_t(loc.lat) * 10ULL; pkt.height_ellipsoid_mm = loc.alt * 10; pkt.height_msl_mm = loc.alt * 10; for (uint8_t i=0; i<3; i++) { pkt.ned_velocity[i] = vel[i]; } pkt.sats_used = gps.num_sats(); switch (gps.status()) { case AP_GPS::GPS_Status::NO_GPS: case AP_GPS::GPS_Status::NO_FIX: pkt.status = UAVCAN_EQUIPMENT_GNSS_FIX2_STATUS_NO_FIX; pkt.mode = UAVCAN_EQUIPMENT_GNSS_FIX2_MODE_SINGLE; pkt.sub_mode = UAVCAN_EQUIPMENT_GNSS_FIX2_SUB_MODE_DGPS_OTHER; break; case AP_GPS::GPS_Status::GPS_OK_FIX_2D: pkt.status = UAVCAN_EQUIPMENT_GNSS_FIX2_STATUS_2D_FIX; pkt.mode = UAVCAN_EQUIPMENT_GNSS_FIX2_MODE_SINGLE; pkt.sub_mode = UAVCAN_EQUIPMENT_GNSS_FIX2_SUB_MODE_DGPS_OTHER; break; case AP_GPS::GPS_Status::GPS_OK_FIX_3D: pkt.status = UAVCAN_EQUIPMENT_GNSS_FIX2_STATUS_3D_FIX; pkt.mode = UAVCAN_EQUIPMENT_GNSS_FIX2_MODE_SINGLE; pkt.sub_mode = UAVCAN_EQUIPMENT_GNSS_FIX2_SUB_MODE_DGPS_OTHER; break; case AP_GPS::GPS_Status::GPS_OK_FIX_3D_DGPS: pkt.status = UAVCAN_EQUIPMENT_GNSS_FIX2_STATUS_3D_FIX; pkt.mode = UAVCAN_EQUIPMENT_GNSS_FIX2_MODE_DGPS; pkt.sub_mode = UAVCAN_EQUIPMENT_GNSS_FIX2_SUB_MODE_DGPS_SBAS; break; case AP_GPS::GPS_Status::GPS_OK_FIX_3D_RTK_FLOAT: pkt.status = UAVCAN_EQUIPMENT_GNSS_FIX2_STATUS_3D_FIX; pkt.mode = UAVCAN_EQUIPMENT_GNSS_FIX2_MODE_RTK; pkt.sub_mode = UAVCAN_EQUIPMENT_GNSS_FIX2_SUB_MODE_RTK_FLOAT; break; case AP_GPS::GPS_Status::GPS_OK_FIX_3D_RTK_FIXED: pkt.status = UAVCAN_EQUIPMENT_GNSS_FIX2_STATUS_3D_FIX; pkt.mode = UAVCAN_EQUIPMENT_GNSS_FIX2_MODE_RTK; pkt.sub_mode = UAVCAN_EQUIPMENT_GNSS_FIX2_SUB_MODE_RTK_FIXED; break; } pkt.covariance.len = 6; float hacc; if (gps.horizontal_accuracy(hacc)) { pkt.covariance.data[0] = pkt.covariance.data[1] = sq(hacc); } float vacc; if (gps.vertical_accuracy(vacc)) { pkt.covariance.data[2] = sq(vacc); } float sacc; if (gps.speed_accuracy(sacc)) { const float vc3 = sq(sacc); pkt.covariance.data[3] = pkt.covariance.data[4] = pkt.covariance.data[5] = vc3; } gnss_fix2.broadcast(pkt); const uint32_t now_ms = AP_HAL::millis(); if (now_ms - _gnss.last_send_status_ms >= 1000) { _gnss.last_send_status_ms = now_ms; /* send aux packet */ uavcan_equipment_gnss_Auxiliary pkt_auxiliary {}; pkt_auxiliary.hdop = gps.get_hdop() * 0.01; pkt_auxiliary.vdop = gps.get_vdop() * 0.01; gnss_auxiliary.broadcast(pkt_auxiliary); /* send Status packet */ ardupilot_gnss_Status pkt_status {}; pkt_status.healthy = gps.is_healthy(); if (gps.logging_present() && gps.logging_enabled() && !gps.logging_failed()) { pkt_status.status |= ARDUPILOT_GNSS_STATUS_STATUS_LOGGING; } uint8_t idx; // unused if (pkt_status.healthy && !gps.first_unconfigured_gps(idx)) { pkt_status.status |= ARDUPILOT_GNSS_STATUS_STATUS_ARMABLE; } uint32_t error_codes; if (gps.get_error_codes(error_codes)) { pkt_status.error_codes = error_codes; } gnss_status.broadcast(pkt_status); } } void AP_DroneCAN::gnss_send_yaw() { const AP_GPS &gps = AP::gps(); if (!gps.have_gps_yaw()) { return; } float yaw_deg, yaw_acc_deg; uint32_t yaw_time_ms; if (!gps.gps_yaw_deg(yaw_deg, yaw_acc_deg, yaw_time_ms) && yaw_time_ms != _gnss.last_lib_yaw_time_ms) { return; } _gnss.last_lib_yaw_time_ms = yaw_time_ms; ardupilot_gnss_Heading pkt_heading {}; pkt_heading.heading_valid = true; pkt_heading.heading_accuracy_valid = is_positive(yaw_acc_deg); pkt_heading.heading_rad = radians(yaw_deg); pkt_heading.heading_accuracy_rad = radians(yaw_acc_deg); gnss_heading.broadcast(pkt_heading); } #endif // AP_DRONECAN_SEND_GPS // SafetyState send void AP_DroneCAN::safety_state_send() { uint32_t now = AP_HAL::millis(); if (now - _last_safety_state_ms < 500) { // update at 2Hz return; } _last_safety_state_ms = now; { // handle SafetyState ardupilot_indication_SafetyState safety_msg; auto state = hal.util->safety_switch_state(); if (_SRV_armed_mask != 0 || _ESC_armed_mask != 0) { // if we are outputting any servos or ESCs due to // BRD_SAFETY_MASK then we need to advertise safety as // off, this changes LEDs to indicate unsafe and allows // AP_Periph ESCs and servos to run state = AP_HAL::Util::SAFETY_ARMED; } switch (state) { case AP_HAL::Util::SAFETY_ARMED: safety_msg.status = ARDUPILOT_INDICATION_SAFETYSTATE_STATUS_SAFETY_OFF; safety_state.broadcast(safety_msg); break; case AP_HAL::Util::SAFETY_DISARMED: safety_msg.status = ARDUPILOT_INDICATION_SAFETYSTATE_STATUS_SAFETY_ON; safety_state.broadcast(safety_msg); break; default: // nothing to send break; } } { // handle ArmingStatus uavcan_equipment_safety_ArmingStatus arming_msg; arming_msg.status = hal.util->get_soft_armed() ? UAVCAN_EQUIPMENT_SAFETY_ARMINGSTATUS_STATUS_FULLY_ARMED : UAVCAN_EQUIPMENT_SAFETY_ARMINGSTATUS_STATUS_DISARMED; arming_status.broadcast(arming_msg); } } // Send relay outputs with hardpoint msg #if AP_RELAY_DRONECAN_ENABLED void AP_DroneCAN::relay_hardpoint_send() { const uint32_t now = AP_HAL::millis(); if ((_relay.rate_hz == 0) || ((now - _relay.last_send_ms) < uint32_t(1000 / _relay.rate_hz))) { // Rate limit per user config return; } _relay.last_send_ms = now; AP_Relay *relay = AP::relay(); if (relay == nullptr) { return; } uavcan_equipment_hardpoint_Command msg {}; // Relay will populate the next command to send and update the last index // This will cycle through each relay in turn if (relay->dronecan.populate_next_command(_relay.last_index, msg)) { relay_hardpoint.broadcast(msg); } } #endif // AP_RELAY_DRONECAN_ENABLED /* handle Button message */ void AP_DroneCAN::handle_button(const CanardRxTransfer& transfer, const ardupilot_indication_Button& msg) { switch (msg.button) { case ARDUPILOT_INDICATION_BUTTON_BUTTON_SAFETY: { AP_BoardConfig *brdconfig = AP_BoardConfig::get_singleton(); if (brdconfig && brdconfig->safety_button_handle_pressed(msg.press_time)) { AP_HAL::Util::safety_state state = hal.util->safety_switch_state(); if (state == AP_HAL::Util::SAFETY_ARMED) { hal.rcout->force_safety_on(); } else { hal.rcout->force_safety_off(); } } break; } } } /* handle traffic report */ void AP_DroneCAN::handle_traffic_report(const CanardRxTransfer& transfer, const ardupilot_equipment_trafficmonitor_TrafficReport& msg) { #if HAL_ADSB_ENABLED AP_ADSB *adsb = AP::ADSB(); if (!adsb || !adsb->enabled()) { // ADSB not enabled return; } AP_ADSB::adsb_vehicle_t vehicle; mavlink_adsb_vehicle_t &pkt = vehicle.info; pkt.ICAO_address = msg.icao_address; pkt.tslc = msg.tslc; pkt.lat = msg.latitude_deg_1e7; pkt.lon = msg.longitude_deg_1e7; pkt.altitude = msg.alt_m * 1000; pkt.heading = degrees(msg.heading) * 100; pkt.hor_velocity = norm(msg.velocity[0], msg.velocity[1]) * 100; pkt.ver_velocity = -msg.velocity[2] * 100; pkt.squawk = msg.squawk; for (uint8_t i=0; i<9; i++) { pkt.callsign[i] = msg.callsign[i]; } pkt.emitter_type = msg.traffic_type; if (msg.alt_type == ARDUPILOT_EQUIPMENT_TRAFFICMONITOR_TRAFFICREPORT_ALT_TYPE_PRESSURE_AMSL) { pkt.flags |= ADSB_FLAGS_VALID_ALTITUDE; pkt.altitude_type = ADSB_ALTITUDE_TYPE_PRESSURE_QNH; } else if (msg.alt_type == ARDUPILOT_EQUIPMENT_TRAFFICMONITOR_TRAFFICREPORT_ALT_TYPE_WGS84) { pkt.flags |= ADSB_FLAGS_VALID_ALTITUDE; pkt.altitude_type = ADSB_ALTITUDE_TYPE_GEOMETRIC; } if (msg.lat_lon_valid) { pkt.flags |= ADSB_FLAGS_VALID_COORDS; } if (msg.heading_valid) { pkt.flags |= ADSB_FLAGS_VALID_HEADING; } if (msg.velocity_valid) { pkt.flags |= ADSB_FLAGS_VALID_VELOCITY; } if (msg.callsign_valid) { pkt.flags |= ADSB_FLAGS_VALID_CALLSIGN; } if (msg.ident_valid) { pkt.flags |= ADSB_FLAGS_VALID_SQUAWK; } if (msg.simulated_report) { pkt.flags |= ADSB_FLAGS_SIMULATED; } if (msg.vertical_velocity_valid) { pkt.flags |= ADSB_FLAGS_VERTICAL_VELOCITY_VALID; } if (msg.baro_valid) { pkt.flags |= ADSB_FLAGS_BARO_VALID; } vehicle.last_update_ms = AP_HAL::millis() - (vehicle.info.tslc * 1000); adsb->handle_adsb_vehicle(vehicle); #endif } /* handle actuator status message */ void AP_DroneCAN::handle_actuator_status(const CanardRxTransfer& transfer, const uavcan_equipment_actuator_Status& msg) { #if HAL_LOGGING_ENABLED // log as CSRV message AP::logger().Write_ServoStatus(AP_HAL::micros64(), msg.actuator_id, msg.position, msg.force, msg.speed, msg.power_rating_pct, 0, 0, 0, 0, 0, 0); #endif } #if AP_DRONECAN_HIMARK_SERVO_SUPPORT /* handle himark ServoInfo message */ void AP_DroneCAN::handle_himark_servoinfo(const CanardRxTransfer& transfer, const com_himark_servo_ServoInfo &msg) { #if HAL_LOGGING_ENABLED // log as CSRV message AP::logger().Write_ServoStatus(AP_HAL::micros64(), msg.servo_id, msg.pos_sensor*0.01, 0, 0, 0, msg.pos_cmd*0.01, msg.voltage*0.01, msg.current*0.01, msg.motor_temp*0.2-40, msg.pcb_temp*0.2-40, msg.error_status); #endif } #endif // AP_DRONECAN_HIMARK_SERVO_SUPPORT #if AP_DRONECAN_VOLZ_FEEDBACK_ENABLED void AP_DroneCAN::handle_actuator_status_Volz(const CanardRxTransfer& transfer, const com_volz_servo_ActuatorStatus& msg) { #if HAL_LOGGING_ENABLED AP::logger().WriteStreaming( "CVOL", "TimeUS,Id,Pos,Cur,V,Pow,T", "s#dAv%O", "F-00000", "QBfffBh", AP_HAL::micros64(), msg.actuator_id, ToDeg(msg.actual_position), msg.current * 0.025f, msg.voltage * 0.2f, msg.motor_pwm * (100.0/255.0), int16_t(msg.motor_temperature) - 50); #endif } #endif /* handle ESC status message */ void AP_DroneCAN::handle_ESC_status(const CanardRxTransfer& transfer, const uavcan_equipment_esc_Status& msg) { #if HAL_WITH_ESC_TELEM const uint8_t esc_offset = constrain_int16(_esc_offset.get(), 0, DRONECAN_SRV_NUMBER); const uint8_t esc_index = msg.esc_index + esc_offset; if (!is_esc_data_index_valid(esc_index)) { return; } TelemetryData t { .temperature_cdeg = int16_t((KELVIN_TO_C(msg.temperature)) * 100), .voltage = msg.voltage, .current = msg.current, }; update_rpm(esc_index, msg.rpm, msg.error_count); update_telem_data(esc_index, t, (isnan(msg.current) ? 0 : AP_ESC_Telem_Backend::TelemetryType::CURRENT) | (isnan(msg.voltage) ? 0 : AP_ESC_Telem_Backend::TelemetryType::VOLTAGE) | (isnan(msg.temperature) ? 0 : AP_ESC_Telem_Backend::TelemetryType::TEMPERATURE)); #endif } bool AP_DroneCAN::is_esc_data_index_valid(const uint8_t index) { if (index > DRONECAN_SRV_NUMBER) { // printf("DroneCAN: invalid esc index: %d. max index allowed: %d\n\r", index, DRONECAN_SRV_NUMBER); return false; } return true; } /* handle LogMessage debug */ void AP_DroneCAN::handle_debug(const CanardRxTransfer& transfer, const uavcan_protocol_debug_LogMessage& msg) { #if HAL_LOGGING_ENABLED if (AP::can().get_log_level() != AP_CANManager::LOG_NONE) { // log to onboard log and mavlink GCS_SEND_TEXT(MAV_SEVERITY_INFO, "CAN[%u] %s", transfer.source_node_id, msg.text.data); } else { // only log to onboard log AP::logger().Write_MessageF("CAN[%u] %s", transfer.source_node_id, msg.text.data); } #endif } /* check for parameter get/set response timeout */ void AP_DroneCAN::check_parameter_callback_timeout() { WITH_SEMAPHORE(_param_sem); // return immediately if not waiting for get/set parameter response if (param_request_sent_ms == 0) { return; } const uint32_t now_ms = AP_HAL::millis(); if (now_ms - param_request_sent_ms > AP_DRONECAN_GETSET_TIMEOUT_MS) { param_request_sent_ms = 0; param_int_cb = nullptr; param_float_cb = nullptr; param_string_cb = nullptr; } } /* send any queued request to get/set parameter called from loop */ void AP_DroneCAN::send_parameter_request() { WITH_SEMAPHORE(_param_sem); if (param_request_sent) { return; } param_get_set_client.request(param_request_node_id, param_getset_req); param_request_sent = true; } /* set named float parameter on node */ bool AP_DroneCAN::set_parameter_on_node(uint8_t node_id, const char *name, float value, ParamGetSetFloatCb *cb) { WITH_SEMAPHORE(_param_sem); // fail if waiting for any previous get/set request if (param_int_cb != nullptr || param_float_cb != nullptr || param_string_cb != nullptr) { return false; } param_getset_req.index = 0; param_getset_req.name.len = strncpy_noterm((char*)param_getset_req.name.data, name, sizeof(param_getset_req.name.data)-1); param_getset_req.value.real_value = value; param_getset_req.value.union_tag = UAVCAN_PROTOCOL_PARAM_VALUE_REAL_VALUE; param_float_cb = cb; param_request_sent = false; param_request_sent_ms = AP_HAL::millis(); param_request_node_id = node_id; return true; } /* set named integer parameter on node */ bool AP_DroneCAN::set_parameter_on_node(uint8_t node_id, const char *name, int32_t value, ParamGetSetIntCb *cb) { WITH_SEMAPHORE(_param_sem); // fail if waiting for any previous get/set request if (param_int_cb != nullptr || param_float_cb != nullptr || param_string_cb != nullptr) { return false; } param_getset_req.index = 0; param_getset_req.name.len = strncpy_noterm((char*)param_getset_req.name.data, name, sizeof(param_getset_req.name.data)-1); param_getset_req.value.integer_value = value; param_getset_req.value.union_tag = UAVCAN_PROTOCOL_PARAM_VALUE_INTEGER_VALUE; param_int_cb = cb; param_request_sent = false; param_request_sent_ms = AP_HAL::millis(); param_request_node_id = node_id; return true; } /* set named string parameter on node */ bool AP_DroneCAN::set_parameter_on_node(uint8_t node_id, const char *name, const string &value, ParamGetSetStringCb *cb) { WITH_SEMAPHORE(_param_sem); // fail if waiting for any previous get/set request if (param_int_cb != nullptr || param_float_cb != nullptr || param_string_cb != nullptr) { return false; } param_getset_req.index = 0; param_getset_req.name.len = strncpy_noterm((char*)param_getset_req.name.data, name, sizeof(param_getset_req.name.data)-1); memcpy(¶m_getset_req.value.string_value, (const void*)&value, sizeof(value)); param_getset_req.value.union_tag = UAVCAN_PROTOCOL_PARAM_VALUE_STRING_VALUE; param_string_cb = cb; param_request_sent = false; param_request_sent_ms = AP_HAL::millis(); param_request_node_id = node_id; return true; } /* get named float parameter on node */ bool AP_DroneCAN::get_parameter_on_node(uint8_t node_id, const char *name, ParamGetSetFloatCb *cb) { WITH_SEMAPHORE(_param_sem); // fail if waiting for any previous get/set request if (param_int_cb != nullptr || param_float_cb != nullptr || param_string_cb != nullptr) { return false; } param_getset_req.index = 0; param_getset_req.name.len = strncpy_noterm((char*)param_getset_req.name.data, name, sizeof(param_getset_req.name.data)); param_getset_req.value.union_tag = UAVCAN_PROTOCOL_PARAM_VALUE_EMPTY; param_float_cb = cb; param_request_sent = false; param_request_sent_ms = AP_HAL::millis(); param_request_node_id = node_id; return true; } /* get named integer parameter on node */ bool AP_DroneCAN::get_parameter_on_node(uint8_t node_id, const char *name, ParamGetSetIntCb *cb) { WITH_SEMAPHORE(_param_sem); // fail if waiting for any previous get/set request if (param_int_cb != nullptr || param_float_cb != nullptr || param_string_cb != nullptr) { return false; } param_getset_req.index = 0; param_getset_req.name.len = strncpy_noterm((char*)param_getset_req.name.data, name, sizeof(param_getset_req.name.data)); param_getset_req.value.union_tag = UAVCAN_PROTOCOL_PARAM_VALUE_EMPTY; param_int_cb = cb; param_request_sent = false; param_request_sent_ms = AP_HAL::millis(); param_request_node_id = node_id; return true; } /* get named string parameter on node */ bool AP_DroneCAN::get_parameter_on_node(uint8_t node_id, const char *name, ParamGetSetStringCb *cb) { WITH_SEMAPHORE(_param_sem); // fail if waiting for any previous get/set request if (param_int_cb != nullptr || param_float_cb != nullptr || param_string_cb != nullptr) { return false; } param_getset_req.index = 0; param_getset_req.name.len = strncpy_noterm((char*)param_getset_req.name.data, name, sizeof(param_getset_req.name.data)); param_getset_req.value.union_tag = UAVCAN_PROTOCOL_PARAM_VALUE_EMPTY; param_string_cb = cb; param_request_sent = false; param_request_sent_ms = AP_HAL::millis(); param_request_node_id = node_id; return true; } void AP_DroneCAN::handle_param_get_set_response(const CanardRxTransfer& transfer, const uavcan_protocol_param_GetSetResponse& rsp) { WITH_SEMAPHORE(_param_sem); if (!param_int_cb && !param_float_cb && !param_string_cb) { return; } if ((rsp.value.union_tag == UAVCAN_PROTOCOL_PARAM_VALUE_INTEGER_VALUE) && param_int_cb) { int32_t val = rsp.value.integer_value; if ((*param_int_cb)(this, transfer.source_node_id, (const char*)rsp.name.data, val)) { // we want the parameter to be set with val param_getset_req.index = 0; memcpy(param_getset_req.name.data, rsp.name.data, rsp.name.len); param_getset_req.value.integer_value = val; param_getset_req.value.union_tag = UAVCAN_PROTOCOL_PARAM_VALUE_INTEGER_VALUE; param_request_sent = false; param_request_sent_ms = AP_HAL::millis(); param_request_node_id = transfer.source_node_id; return; } } else if ((rsp.value.union_tag == UAVCAN_PROTOCOL_PARAM_VALUE_REAL_VALUE) && param_float_cb) { float val = rsp.value.real_value; if ((*param_float_cb)(this, transfer.source_node_id, (const char*)rsp.name.data, val)) { // we want the parameter to be set with val param_getset_req.index = 0; memcpy(param_getset_req.name.data, rsp.name.data, rsp.name.len); param_getset_req.value.real_value = val; param_getset_req.value.union_tag = UAVCAN_PROTOCOL_PARAM_VALUE_REAL_VALUE; param_request_sent = false; param_request_sent_ms = AP_HAL::millis(); param_request_node_id = transfer.source_node_id; return; } } else if ((rsp.value.union_tag == UAVCAN_PROTOCOL_PARAM_VALUE_STRING_VALUE) && param_string_cb) { string val; memcpy(&val, &rsp.value.string_value, sizeof(val)); if ((*param_string_cb)(this, transfer.source_node_id, (const char*)rsp.name.data, val)) { // we want the parameter to be set with val param_getset_req.index = 0; memcpy(param_getset_req.name.data, rsp.name.data, rsp.name.len); memcpy(¶m_getset_req.value.string_value, &val, sizeof(val)); param_getset_req.value.union_tag = UAVCAN_PROTOCOL_PARAM_VALUE_STRING_VALUE; param_request_sent = false; param_request_sent_ms = AP_HAL::millis(); param_request_node_id = transfer.source_node_id; return; } } param_request_sent_ms = 0; param_int_cb = nullptr; param_float_cb = nullptr; param_string_cb = nullptr; } void AP_DroneCAN::send_parameter_save_request() { WITH_SEMAPHORE(_param_save_sem); if (param_save_request_sent) { return; } param_save_client.request(param_save_request_node_id, param_save_req); param_save_request_sent = true; } bool AP_DroneCAN::save_parameters_on_node(uint8_t node_id, ParamSaveCb *cb) { WITH_SEMAPHORE(_param_save_sem); if (save_param_cb != nullptr) { //busy return false; } param_save_req.opcode = UAVCAN_PROTOCOL_PARAM_EXECUTEOPCODE_REQUEST_OPCODE_SAVE; param_save_request_sent = false; param_save_request_node_id = node_id; save_param_cb = cb; return true; } // handle parameter save request response void AP_DroneCAN::handle_param_save_response(const CanardRxTransfer& transfer, const uavcan_protocol_param_ExecuteOpcodeResponse& rsp) { WITH_SEMAPHORE(_param_save_sem); if (!save_param_cb) { return; } (*save_param_cb)(this, transfer.source_node_id, rsp.ok); save_param_cb = nullptr; } // Send Reboot command // Note: Do not call this from outside DroneCAN thread context, // THIS IS NOT A THREAD SAFE API! void AP_DroneCAN::send_reboot_request(uint8_t node_id) { uavcan_protocol_RestartNodeRequest request; request.magic_number = UAVCAN_PROTOCOL_RESTARTNODE_REQUEST_MAGIC_NUMBER; restart_node_client.request(node_id, request); } // check if a option is set and if it is then reset it to 0. // return true if it was set bool AP_DroneCAN::check_and_reset_option(Options option) { bool ret = option_is_set(option); if (ret) { _options.set_and_save(int16_t(_options.get() & ~uint16_t(option))); } return ret; } // handle prearm check bool AP_DroneCAN::prearm_check(char* fail_msg, uint8_t fail_msg_len) const { // forward this to DNA_Server return _dna_server.prearm_check(fail_msg, fail_msg_len); } /* periodic logging */ void AP_DroneCAN::logging(void) { #if HAL_LOGGING_ENABLED const uint32_t now_ms = AP_HAL::millis(); if (now_ms - last_log_ms < 1000) { return; } last_log_ms = now_ms; if (HAL_NUM_CAN_IFACES <= _driver_index) { // no interface? return; } const auto *iface = hal.can[_driver_index]; if (iface == nullptr) { return; } const auto *stats = iface->get_statistics(); if (stats == nullptr) { // statistics not implemented on this interface return; } const auto &s = *stats; AP::logger().WriteStreaming("CANS", "TimeUS,I,T,Trq,Trej,Tov,Tto,Tab,R,Rov,Rer,Bo,Etx,Stx,Ftx", "s#-------------", "F--------------", "QBIIIIIIIIIIIII", AP_HAL::micros64(), _driver_index, s.tx_success, s.tx_requests, s.tx_rejected, s.tx_overflow, s.tx_timedout, s.tx_abort, s.rx_received, s.rx_overflow, s.rx_errors, s.num_busoff_err, _esc_send_count, _srv_send_count, _fail_send_count); #endif // HAL_LOGGING_ENABLED } // add an 11 bit auxillary driver bool AP_DroneCAN::add_11bit_driver(CANSensor *sensor) { return canard_iface.add_11bit_driver(sensor); } // handler for outgoing frames for auxillary drivers bool AP_DroneCAN::write_aux_frame(AP_HAL::CANFrame &out_frame, const uint64_t timeout_us) { if (out_frame.isExtended()) { // don't allow extended frames to be sent by auxillary driver return false; } return canard_iface.write_aux_frame(out_frame, timeout_us); } #endif // HAL_NUM_CAN_IFACES