/* * 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: Oliver Walters */ #include #include #include "AP_PiccoloCAN.h" #if HAL_PICCOLO_CAN_ENABLE #include #include #include #include #include #include #include #include #include #include #include #include extern const AP_HAL::HAL& hal; #define debug_can(level_debug, fmt, args...) do { AP::can().log_text(level_debug, "PiccoloCAN", fmt, ##args); } while (0) // table of user-configurable Piccolo CAN bus parameters const AP_Param::GroupInfo AP_PiccoloCAN::var_info[] = { // @Param: ESC_BM // @DisplayName: ESC channels // @Description: Bitmask defining which ESC (motor) channels are to be transmitted over Piccolo CAN // @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 // @User: Advanced AP_GROUPINFO("ESC_BM", 1, AP_PiccoloCAN, _esc_bm, 0xFFFF), // @Param: ESC_RT // @DisplayName: ESC output rate // @Description: Output rate of ESC command messages // @Units: Hz // @User: Advanced // @Range: 1 500 AP_GROUPINFO("ESC_RT", 2, AP_PiccoloCAN, _esc_hz, PICCOLO_MSG_RATE_HZ_DEFAULT), AP_GROUPEND }; AP_PiccoloCAN::AP_PiccoloCAN() { AP_Param::setup_object_defaults(this, var_info); debug_can(AP_CANManager::LOG_INFO, "PiccoloCAN: constructed\n\r"); } AP_PiccoloCAN *AP_PiccoloCAN::get_pcan(uint8_t driver_index) { if (driver_index >= AP::can().get_num_drivers() || AP::can().get_driver_type(driver_index) != AP_CANManager::Driver_Type_PiccoloCAN) { return nullptr; } return static_cast(AP::can().get_driver(driver_index)); } bool AP_PiccoloCAN::add_interface(AP_HAL::CANIface* can_iface) { if (_can_iface != nullptr) { debug_can(AP_CANManager::LOG_ERROR, "PiccoloCAN: Multiple Interface not supported\n\r"); return false; } _can_iface = can_iface; if (_can_iface == nullptr) { debug_can(AP_CANManager::LOG_ERROR, "PiccoloCAN: CAN driver not found\n\r"); return false; } if (!_can_iface->is_initialized()) { debug_can(AP_CANManager::LOG_ERROR, "PiccoloCAN: Driver not initialized\n\r"); return false; } if (!_can_iface->set_event_handle(&_event_handle)) { debug_can(AP_CANManager::LOG_ERROR, "PiccoloCAN: Cannot add event handle\n\r"); return false; } return true; } // initialize PiccoloCAN bus void AP_PiccoloCAN::init(uint8_t driver_index, bool enable_filters) { _driver_index = driver_index; debug_can(AP_CANManager::LOG_DEBUG, "PiccoloCAN: starting init\n\r"); if (_initialized) { debug_can(AP_CANManager::LOG_ERROR, "PiccoloCAN: already initialized\n\r"); return; } // start calls to loop in separate thread if (!hal.scheduler->thread_create(FUNCTOR_BIND_MEMBER(&AP_PiccoloCAN::loop, void), _thread_name, 4096, AP_HAL::Scheduler::PRIORITY_MAIN, 1)) { debug_can(AP_CANManager::LOG_ERROR, "PiccoloCAN: couldn't create thread\n\r"); return; } _initialized = true; snprintf(_thread_name, sizeof(_thread_name), "PiccoloCAN_%u", driver_index); debug_can(AP_CANManager::LOG_DEBUG, "PiccoloCAN: init done\n\r"); } // loop to send output to CAN devices in background thread void AP_PiccoloCAN::loop() { AP_HAL::CANFrame txFrame; AP_HAL::CANFrame rxFrame; uint16_t esc_tx_counter = 0; // CAN Frame ID components uint8_t frame_id_group; // Piccolo message group uint16_t frame_id_device; // Device identifier while (true) { _esc_hz = constrain_int16(_esc_hz, PICCOLO_MSG_RATE_HZ_MIN, PICCOLO_MSG_RATE_HZ_MAX); uint16_t escCmdRateMs = (uint16_t) ((float) 1000 / _esc_hz); if (!_initialized) { debug_can(AP_CANManager::LOG_ERROR, "PiccoloCAN: not initialized\n\r"); hal.scheduler->delay_microseconds(10000); continue; } uint64_t timeout = AP_HAL::micros64() + 250ULL; // 1ms loop delay hal.scheduler->delay_microseconds(1000); // Transmit ESC commands at regular intervals if (esc_tx_counter++ > escCmdRateMs) { esc_tx_counter = 0; send_esc_messages(); } // Look for any message responses on the CAN bus while (read_frame(rxFrame, timeout)) { // Extract group and device ID values from the frame identifier frame_id_group = (rxFrame.id >> 24) & 0x1F; frame_id_device = (rxFrame.id >> 8) & 0xFF; // Only accept extended messages if ((rxFrame.id & AP_HAL::CANFrame::FlagEFF) == 0) { continue; } switch (MessageGroup(frame_id_group)) { // ESC messages exist in the ACTUATOR group case MessageGroup::ACTUATOR: switch (ActuatorType(frame_id_device)) { case ActuatorType::ESC: if (handle_esc_message(rxFrame)) { // Returns true if the message was successfully decoded } break; default: // Unknown actuator type break; } break; default: break; } } } } // write frame on CAN bus, returns true on success bool AP_PiccoloCAN::write_frame(AP_HAL::CANFrame &out_frame, uint64_t timeout) { if (!_initialized) { debug_can(AP_CANManager::LOG_ERROR, "PiccoloCAN: Driver not initialized for write_frame\n\r"); return false; } bool read_select = false; bool write_select = true; bool ret = _can_iface->select(read_select, write_select, &out_frame, timeout); if (!ret || !write_select) { return false; } return (_can_iface->send(out_frame, timeout, AP_HAL::CANIface::AbortOnError) == 1); } // read frame on CAN bus, returns true on succses bool AP_PiccoloCAN::read_frame(AP_HAL::CANFrame &recv_frame, uint64_t timeout) { if (!_initialized) { debug_can(AP_CANManager::LOG_ERROR, "PiccoloCAN: Driver not initialized for read_frame\n\r"); return false; } bool read_select = true; bool write_select = false; bool ret = _can_iface->select(read_select, write_select, nullptr, timeout); if (!ret || !read_select) { // No frame available return false; } uint64_t time; AP_HAL::CANIface::CanIOFlags flags {}; return (_can_iface->receive(recv_frame, time, flags) == 1); } // called from SRV_Channels void AP_PiccoloCAN::update() { /* Read out the ESC commands from the channel mixer */ for (uint8_t i = 0; i < PICCOLO_CAN_MAX_NUM_ESC; i++) { if (is_esc_channel_active(i)) { uint16_t output = 0; SRV_Channel::Aux_servo_function_t motor_function = SRV_Channels::get_motor_function(i); if (SRV_Channels::get_output_pwm(motor_function, output)) { _esc_info[i].command = output; _esc_info[i].newCommand = true; } } } } // send ESC messages over CAN void AP_PiccoloCAN::send_esc_messages(void) { AP_HAL::CANFrame txFrame; uint64_t timeout = AP_HAL::micros64() + 1000ULL; // No ESCs are selected? Don't send anything if (_esc_bm == 0x00) { return; } // System is armed - send out ESC commands if (hal.util->get_soft_armed()) { bool send_cmd = false; int16_t cmd[4] {}; uint8_t idx; // Transmit bulk command packets to 4x ESC simultaneously for (uint8_t ii = 0; ii < PICCOLO_CAN_MAX_GROUP_ESC; ii++) { send_cmd = false; for (uint8_t jj = 0; jj < 4; jj++) { idx = (ii * 4) + jj; // Skip an ESC if the motor channel is not enabled if (!is_esc_channel_active(idx)) { continue; } /* Check if the ESC is software-inhibited. * If so, send a message to enable it. */ if (is_esc_present(idx) && !is_esc_enabled(idx)) { encodeESC_EnablePacket(&txFrame); txFrame.id |= (idx + 1); write_frame(txFrame, timeout); } else if (_esc_info[idx].newCommand) { send_cmd = true; cmd[jj] = _esc_info[idx].command; _esc_info[idx].newCommand = false; } else { // A command of 0xFFFF is 'out of range' and will be ignored by the corresponding ESC cmd[jj] = 0xFFFF; } } if (send_cmd) { encodeESC_CommandMultipleESCsPacket( &txFrame, cmd[0], cmd[1], cmd[2], cmd[3], (PKT_ESC_SETPOINT_1 + ii) ); // Broadcast the command to all ESCs txFrame.id |= 0xFF; write_frame(txFrame, timeout); } } } else { // System is NOT armed - send a "disable" message to all ESCs on the bus // Command all ESC into software disable mode encodeESC_DisablePacket(&txFrame); // Set the ESC address to the broadcast ID (0xFF) txFrame.id |= 0xFF; write_frame(txFrame, timeout); } } // interpret an ESC message received over CAN bool AP_PiccoloCAN::handle_esc_message(AP_HAL::CANFrame &frame) { uint64_t timestamp = AP_HAL::micros64(); // The ESC address is the lower byte of the address uint8_t addr = frame.id & 0xFF; // Ignore any ESC with node ID of zero if (addr == 0x00) { return false; } // Subtract to get the address in memory addr -= 1; // Maximum number of ESCs allowed if (addr >= PICCOLO_CAN_MAX_NUM_ESC) { return false; } PiccoloESC_Info_t &esc = _esc_info[addr]; bool result = true; /* * The STATUS_A packet has slight variations between Gen-1 and Gen-2 ESCs. * We can differentiate between the different versions, * and coerce the "legacy" values into the modern values * Legacy STATUS_A packet variables */ ESC_LegacyStatusBits_t legacyStatus; ESC_LegacyWarningBits_t legacyWarnings; ESC_LegacyErrorBits_t legacyErrors; // Throw the packet against each decoding routine if (decodeESC_StatusAPacket(&frame, &esc.mode, &esc.status, &esc.setpoint, &esc.rpm)) { esc.newTelemetry = true; update_rpm(addr, esc.rpm); } else if (decodeESC_LegacyStatusAPacket(&frame, &esc.mode, &legacyStatus, &legacyWarnings, &legacyErrors, &esc.setpoint, &esc.rpm)) { // The status / warning / error bits need to be converted to modern values // Note: Not *all* of the modern status bits are available in the Gen-1 packet esc.status.hwInhibit = legacyStatus.hwInhibit; esc.status.swInhibit = legacyStatus.swInhibit; esc.status.afwEnabled = legacyStatus.afwEnabled; esc.status.direction = legacyStatus.timeout; esc.status.timeout = legacyStatus.timeout; esc.status.starting = legacyStatus.starting; esc.status.commandSource = legacyStatus.commandSource; esc.status.running = legacyStatus.running; // Copy the legacy warning information across esc.warnings.overspeed = legacyWarnings.overspeed; esc.warnings.overcurrent = legacyWarnings.overcurrent; esc.warnings.escTemperature = legacyWarnings.escTemperature; esc.warnings.motorTemperature = legacyWarnings.motorTemperature; esc.warnings.undervoltage = legacyWarnings.undervoltage; esc.warnings.overvoltage = legacyWarnings.overvoltage; esc.warnings.invalidPWMsignal = legacyWarnings.invalidPWMsignal; esc.warnings.settingsChecksum = legacyErrors.settingsChecksum; // There are no common error bits between the Gen-1 and Gen-2 ICD } else if (decodeESC_StatusBPacket(&frame, &esc.voltage, &esc.current, &esc.dutyCycle, &esc.escTemperature, &esc.motorTemperature)) { TelemetryData t { .temperature_cdeg = int16_t(esc.escTemperature * 100), .voltage = float(esc.voltage) * 0.01f, .current = float(esc.current) * 0.01f, }; update_telem_data(addr, t, AP_ESC_Telem_Backend::TelemetryType::CURRENT | AP_ESC_Telem_Backend::TelemetryType::VOLTAGE | AP_ESC_Telem_Backend::TelemetryType::TEMPERATURE); esc.newTelemetry = true; } else if (decodeESC_StatusCPacket(&frame, &esc.fetTemperature, &esc.pwmFrequency, &esc.timingAdvance)) { TelemetryData t { }; t.motor_temp_cdeg = int16_t(esc.fetTemperature * 100); update_telem_data(addr, t, AP_ESC_Telem_Backend::TelemetryType::MOTOR_TEMPERATURE); esc.newTelemetry = true; } else if (decodeESC_WarningErrorStatusPacket(&frame, &esc.warnings, &esc.errors)) { esc.newTelemetry = true; } else if (decodeESC_FirmwarePacketStructure(&frame, &esc.firmware)) { // TODO } else if (decodeESC_AddressPacketStructure(&frame, &esc.address)) { // TODO } else if (decodeESC_EEPROMSettingsPacketStructure(&frame, &esc.eeprom)) { // TODO } else { result = false; } if (result) { // Reset the Rx timestamp esc.last_rx_msg_timestamp = timestamp; } return result; } /** * Check if a given ESC channel is "active" (has been configured correctly) */ bool AP_PiccoloCAN::is_esc_channel_active(uint8_t chan) { // First check if the particular ESC channel is enabled in the channel mask if (((_esc_bm >> chan) & 0x01) == 0x00) { return false; } // Check if a motor function is assigned for this motor channel SRV_Channel::Aux_servo_function_t motor_function = SRV_Channels::get_motor_function(chan); if (SRV_Channels::function_assigned(motor_function)) { return true; } return false; } /** * Determine if an ESC is present on the CAN bus (has telemetry data been received) */ bool AP_PiccoloCAN::is_esc_present(uint8_t chan, uint64_t timeout_ms) const { if (chan >= PICCOLO_CAN_MAX_NUM_ESC) { return false; } const PiccoloESC_Info_t &esc = _esc_info[chan]; // No messages received from this ESC if (esc.last_rx_msg_timestamp == 0) { return false; } uint64_t now = AP_HAL::micros64(); uint64_t timeout_us = timeout_ms * 1000ULL; if (now > (esc.last_rx_msg_timestamp + timeout_us)) { return false; } return true; } /** * Check if a given ESC is enabled (both hardware and software enable flags) */ bool AP_PiccoloCAN::is_esc_enabled(uint8_t chan) { if (chan >= PICCOLO_CAN_MAX_NUM_ESC) { return false; } // If the ESC is not present, we cannot determine if it is enabled or not if (!is_esc_present(chan)) { return false; } PiccoloESC_Info_t &esc = _esc_info[chan]; if (esc.status.hwInhibit || esc.status.swInhibit) { return false; } // ESC is present, and enabled return true; } bool AP_PiccoloCAN::pre_arm_check(char* reason, uint8_t reason_len) { // Check that each required ESC is present on the bus for (uint8_t ii = 0; ii < PICCOLO_CAN_MAX_NUM_ESC; ii++) { // Skip any ESC channels where the motor channel is not enabled if (is_esc_channel_active(ii)) { if (!is_esc_present(ii)) { snprintf(reason, reason_len, "ESC %u not detected", ii + 1); return false; } PiccoloESC_Info_t &esc = _esc_info[ii]; if (esc.status.hwInhibit) { snprintf(reason, reason_len, "ESC %u is hardware inhibited", (ii + 1)); return false; } } } return true; } /* Piccolo Glue Logic * The following functions are required by the auto-generated protogen code. */ //! \return the packet data pointer from the packet uint8_t* getESCVelocityPacketData(void* pkt) { AP_HAL::CANFrame* frame = (AP_HAL::CANFrame*) pkt; return (uint8_t*) frame->data; } //! \return the packet data pointer from the packet, const const uint8_t* getESCVelocityPacketDataConst(const void* pkt) { AP_HAL::CANFrame* frame = (AP_HAL::CANFrame*) pkt; return (const uint8_t*) frame->data; } //! Complete a packet after the data have been encoded void finishESCVelocityPacket(void* pkt, int size, uint32_t packetID) { AP_HAL::CANFrame* frame = (AP_HAL::CANFrame*) pkt; if (size > AP_HAL::CANFrame::MaxDataLen) { size = AP_HAL::CANFrame::MaxDataLen; } frame->dlc = size; /* Encode the CAN ID * 0x07mm20dd * - 07 = ACTUATOR group ID * - mm = Message ID * - 20 = ESC actuator type * - dd = Device ID * * Note: The Device ID (lower 8 bits of the frame ID) will have to be inserted later */ uint32_t id = (((uint8_t) AP_PiccoloCAN::MessageGroup::ACTUATOR) << 24) | // CAN Group ID ((packetID & 0xFF) << 16) | // Message ID (((uint8_t) AP_PiccoloCAN::ActuatorType::ESC) << 8); // Actuator type // Extended frame format id |= AP_HAL::CANFrame::FlagEFF; frame->id = id; } //! \return the size of a packet from the packet header int getESCVelocityPacketSize(const void* pkt) { AP_HAL::CANFrame* frame = (AP_HAL::CANFrame*) pkt; return (int) frame->dlc; } //! \return the ID of a packet from the packet header uint32_t getESCVelocityPacketID(const void* pkt) { AP_HAL::CANFrame* frame = (AP_HAL::CANFrame*) pkt; // Extract the message ID field from the 29-bit ID return (uint32_t) ((frame->id >> 16) & 0xFF); } #endif // HAL_PICCOLO_CAN_ENABLE