/* This program 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 program 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 . */ /* Initial protocol implementation was provided by FETtec */ /* Strongly modified by Amilcar Lucas, IAV GmbH */ #include #include #include #include #include "AP_FETtecOneWire.h" #if AP_FETTEC_ONEWIRE_ENABLED extern const AP_HAL::HAL& hal; // Set to 0 when no ESC hardware is available and you want to test the UART send function #ifndef HAL_AP_FETTEC_CONFIGURE_ESCS #define HAL_AP_FETTEC_CONFIGURE_ESCS 1 #endif #if HAL_AP_FETTEC_HALF_DUPLEX static constexpr uint32_t HALF_DUPLEX_BAUDRATE = 2000000; #endif static constexpr uint32_t FULL_DUPLEX_BAUDRATE = 500000; const AP_Param::GroupInfo AP_FETtecOneWire::var_info[] { // @Param: MASK // @DisplayName: Servo channel output bitmask // @Description: Servo channel mask specifying FETtec ESC output. // @Bitmask: 0:SERVO1,1:SERVO2,2:SERVO3,3:SERVO4,4:SERVO5,5:SERVO6,6:SERVO7,7:SERVO8,8:SERVO9,9:SERVO10,10:SERVO11,11:SERVO12 // @RebootRequired: True // @User: Standard AP_GROUPINFO_FLAGS("MASK", 1, AP_FETtecOneWire, _motor_mask_parameter, 0, AP_PARAM_FLAG_ENABLE), // @Param: RVMASK // @DisplayName: Servo channel reverse rotation bitmask // @Description: Servo channel mask to reverse rotation of FETtec ESC outputs. // @Bitmask: 0:SERVO1,1:SERVO2,2:SERVO3,3:SERVO4,4:SERVO5,5:SERVO6,6:SERVO7,7:SERVO8,8:SERVO9,9:SERVO10,10:SERVO11,11:SERVO12 // @User: Standard AP_GROUPINFO("RVMASK", 2, AP_FETtecOneWire, _reverse_mask_parameter, 0), #if HAL_WITH_ESC_TELEM // @Param: POLES // @DisplayName: Nr. electrical poles // @Description: Number of motor electrical poles // @Range: 2 50 // @User: Standard AP_GROUPINFO("POLES", 3, AP_FETtecOneWire, _pole_count_parameter, 14), #endif AP_GROUPEND }; AP_FETtecOneWire *AP_FETtecOneWire::_singleton; AP_FETtecOneWire::AP_FETtecOneWire() { AP_Param::setup_object_defaults(this, var_info); #if CONFIG_HAL_BOARD == HAL_BOARD_SITL if (_singleton != nullptr) { AP_HAL::panic("AP_FETtecOneWire must be singleton"); } #endif _singleton = this; } /** initialize the serial port */ void AP_FETtecOneWire::init_uart() { if (_uart != nullptr) { return; } const AP_SerialManager& serial_manager = AP::serialmanager(); _uart = serial_manager.find_serial(AP_SerialManager::SerialProtocol_FETtecOneWire, 0); if (_uart == nullptr) { return; // no serial port available, so nothing to do here } _uart->set_flow_control(AP_HAL::UARTDriver::FLOW_CONTROL_DISABLE); _uart->set_unbuffered_writes(true); uint32_t uart_baud { FULL_DUPLEX_BAUDRATE }; #if HAL_AP_FETTEC_HALF_DUPLEX if (_uart->get_options() & _uart->OPTION_HDPLEX) { //Half-Duplex is enabled _use_hdplex = true; uart_baud = HALF_DUPLEX_BAUDRATE; GCS_SEND_TEXT(MAV_SEVERITY_INFO, "FTW using Half-Duplex"); } else { GCS_SEND_TEXT(MAV_SEVERITY_INFO, "FTW using Full-Duplex"); } #endif _uart->begin(uart_baud); } /// initialize the device driver: configure serial port, wake-up and configure ESCs void AP_FETtecOneWire::init() { init_uart(); if (_uart == nullptr) { return; // no serial port available, so nothing to do here } _motor_mask = uint32_t(_motor_mask_parameter); // take a copy that will not change after we leave this function _esc_count = __builtin_popcount(_motor_mask); #if HAL_WITH_ESC_TELEM // OneWire supports telemetry in at most 15 ESCs, because of the 4 bit limitation // on the fast-throttle command. But we are still limited to the // number of ESCs the telem library will collect data for. if (_esc_count == 0 || _motor_mask >= (1U << MIN(15, ESC_TELEM_MAX_ESCS))) { #else // OneWire supports at most 24 ESCs without telemetry if (_esc_count == 0 || _motor_mask >= (1U << MIN(24, NUM_SERVO_CHANNELS))) { #endif _invalid_mask = true; return; } // we have a uart and the desired ESC combination id valid, allocate some memory: _escs = new ESC[_esc_count]; if (_escs == nullptr) { return; } // initialise ESC ids. This enforces that the FETtec ESC ids // inside FETtec ESCs need to be contiguous and start at ID 1 // which is required by fast-throttle commands. uint8_t esc_offset = 0; // offset into our device-driver dynamically-allocated array of ESCs uint8_t esc_id = 1; // ESC ids inside FETtec protocol are one-indexed uint8_t servo_chan_offset = 0; // offset into _motor_mask_parameter array for (uint32_t mask = _motor_mask; mask != 0; mask >>= 1, servo_chan_offset++) { if (mask & 0x1) { _escs[esc_offset].servo_ofs = servo_chan_offset; _escs[esc_offset].id = esc_id++; esc_offset++; } } _invalid_mask = false; // mask is good GCS_SEND_TEXT(MAV_SEVERITY_INFO, "FETtec: allocated %u motors", _esc_count); // We expect to be able to send a fast-throttle command in each loop. // 8 bits - OneWire Header // 4 bits - telemetry request // 11 bits - throttle value per ESC // 8 bits - frame CRC const uint16_t net_bit_count = 8 + 4 + (_esc_count * 11) + 8; // 7 dummy for rounding up the division by 8 const uint16_t fast_throttle_byte_count = (net_bit_count + 7)/8; uint16_t telemetry_byte_count { 0U }; #if HAL_WITH_ESC_TELEM // Telemetry is fetched from each loop in turn. telemetry_byte_count = sizeof(u.packed_tlm) + 1; // assume 9 pause bits between TX and RX _fast_throttle_byte_count = fast_throttle_byte_count; #endif uint32_t uart_baud { FULL_DUPLEX_BAUDRATE }; #if HAL_AP_FETTEC_HALF_DUPLEX if (_use_hdplex == true) { //Half-Duplex is enabled uart_baud = HALF_DUPLEX_BAUDRATE; } #endif _min_fast_throttle_period_us = (fast_throttle_byte_count + telemetry_byte_count) * 9 * 1000000 / uart_baud + 300; // 300us extra reserve // tell SRV_Channels about ESC capabilities // this is a bit soonish because we have not seen the ESCs on the bus yet, // but saves us having to use a state variable to ensure doing this latter just once SRV_Channels::set_digital_outputs(_motor_mask, 0); _init_done = true; } /** transmits data to ESCs @param bytes bytes to transmit @param length number of bytes to transmit @return false there's no space in the UART for this message */ bool AP_FETtecOneWire::transmit(const uint8_t* bytes, const uint8_t length) { const uint32_t now = AP_HAL::micros(); if (now - _last_transmit_us < _min_fast_throttle_period_us) { // in case the SRV_Channels::push() is running at very high rates, limit the period // this function gets executed because FETtec needs a time gap between frames // this also prevents one loop to do multiple actions, like reinitialize an ESC and sending a fast-throttle command without a gap. _period_too_short++; return false; } _last_transmit_us = now; if (length > _uart->txspace()) { return false; } _uart->write(bytes, length); #if HAL_AP_FETTEC_HALF_DUPLEX if (_use_hdplex) { _ignore_own_bytes += length; } #endif return true; } /** transmits a config request to ESCs @param bytes bytes to transmit @param length number of bytes to transmit @return false if vehicle is armed or if transmit(bytes, length) would return false */ bool AP_FETtecOneWire::transmit_config_request(const uint8_t* bytes, const uint8_t length) { if (hal.util->get_soft_armed()) { return false; } return transmit(bytes, length); } /// shifts data to start of buffer based on magic header bytes void AP_FETtecOneWire::move_frame_source_in_receive_buffer(const uint8_t search_start_pos) { uint8_t i; for (i=search_start_pos; i<_receive_buf_used; i++) { // FIXME: full-duplex should add MASTER here as we see our own data if ((FrameSource)u.receive_buf[i] == FrameSource::BOOTLOADER || (FrameSource)u.receive_buf[i] == FrameSource::ESC) { break; } } consume_bytes(i); } /// cut n bytes from start of buffer void AP_FETtecOneWire::consume_bytes(const uint8_t n) { if (n == 0) { return; } // assure the length of the memmove is positive if (_receive_buf_used < n) { return; } memmove(u.receive_buf, &u.receive_buf[n], _receive_buf_used-n); _receive_buf_used = _receive_buf_used - n; } /// returns true if the first message in the buffer is OK bool AP_FETtecOneWire::buffer_contains_ok(const uint8_t length) { if (length != sizeof(u.packed_ok)) { _message_invalid_in_state_count++; return false; } if ((MsgType)u.packed_ok.msg.msgid != MsgType::OK) { return false; } return true; } void AP_FETtecOneWire::handle_message(ESC &esc, const uint8_t length) { // only accept messages from the bootloader when we could // legitimately get a message from the bootloader. Swipes the OK // message for convenience const FrameSource frame_source = (FrameSource)u.packed_ok.frame_source; if (frame_source != FrameSource::ESC) { if (esc.state != ESCState::WAITING_OK_FOR_RUNNING_SW_TYPE) { return; } } switch (esc.state) { case ESCState::UNINITIALISED: case ESCState::WANT_SEND_OK_TO_GET_RUNNING_SW_TYPE: return; case ESCState::WAITING_OK_FOR_RUNNING_SW_TYPE: // "OK" is the only valid response if (!buffer_contains_ok(length)) { return; } switch (frame_source) { case FrameSource::MASTER: // probably half-duplex; should be caught before we get here INTERNAL_ERROR(AP_InternalError::error_t::flow_of_control); break; case FrameSource::BOOTLOADER: esc.set_state(ESCState::WANT_SEND_START_FW); esc.is_awake = true; break; case FrameSource::ESC: #if HAL_AP_FETTEC_ONEWIRE_GET_STATIC_INFO esc.set_state(ESCState::WANT_SEND_REQ_TYPE); #else #if HAL_WITH_ESC_TELEM esc.set_state(ESCState::WANT_SEND_SET_TLM_TYPE); #else esc.set_state(ESCState::WANT_SEND_SET_FAST_COM_LENGTH); #endif #endif // HAL_AP_FETTEC_ONEWIRE_GET_STATIC_INFO esc.is_awake = true; break; } break; case ESCState::WANT_SEND_START_FW: return; case ESCState::WAITING_OK_FOR_START_FW: if (buffer_contains_ok(length)) { #if HAL_AP_FETTEC_ONEWIRE_GET_STATIC_INFO esc.set_state(ESCState::WANT_SEND_REQ_TYPE); #else #if HAL_WITH_ESC_TELEM esc.set_state(ESCState::WANT_SEND_SET_TLM_TYPE); #else esc.set_state(ESCState::WANT_SEND_SET_FAST_COM_LENGTH); #endif #endif // HAL_AP_FETTEC_ONEWIRE_GET_STATIC_INFO } break; #if HAL_AP_FETTEC_ONEWIRE_GET_STATIC_INFO case ESCState::WANT_SEND_REQ_TYPE: return; case ESCState::WAITING_ESC_TYPE: if (length != sizeof(u.packed_esc_type)) { _message_invalid_in_state_count++; return; } esc.type = u.packed_esc_type.msg.type; esc.set_state(ESCState::WANT_SEND_REQ_SW_VER); break; case ESCState::WANT_SEND_REQ_SW_VER: return; case ESCState::WAITING_SW_VER: if (length != sizeof(u.packed_sw_ver)) { _message_invalid_in_state_count++; return; } esc.firmware_version = u.packed_sw_ver.msg.version; esc.firmware_subversion = u.packed_sw_ver.msg.subversion; esc.set_state(ESCState::WANT_SEND_REQ_SN); break; case ESCState::WANT_SEND_REQ_SN: return; case ESCState::WAITING_SN: if (length != sizeof(u.packed_sn)) { _message_invalid_in_state_count++; return; } static_assert(ARRAY_SIZE(u.packed_sn.msg.sn) == ARRAY_SIZE(esc.serial_number), "Serial number array length missmatch"); memcpy(esc.serial_number, u.packed_sn.msg.sn, ARRAY_SIZE(u.packed_sn.msg.sn)); #if HAL_WITH_ESC_TELEM esc.set_state(ESCState::WANT_SEND_SET_TLM_TYPE); #else esc.set_state(ESCState::WANT_SEND_SET_FAST_COM_LENGTH); #endif break; #endif // HAL_AP_FETTEC_ONEWIRE_GET_STATIC_INFO #if HAL_WITH_ESC_TELEM case ESCState::WANT_SEND_SET_TLM_TYPE: return; case ESCState::WAITING_SET_TLM_TYPE_OK: if (buffer_contains_ok(length)) { esc.set_state(ESCState::WANT_SEND_SET_FAST_COM_LENGTH); } break; #endif case ESCState::WANT_SEND_SET_FAST_COM_LENGTH: return; case ESCState::WAITING_SET_FAST_COM_LENGTH_OK: if (buffer_contains_ok(length)) { esc.set_state(ESCState::RUNNING); } break; case ESCState::RUNNING: // we only expect telemetry messages in this state #if HAL_WITH_ESC_TELEM if (!esc.telem_expected) { esc.unexpected_telem++; #if CONFIG_HAL_BOARD == HAL_BOARD_SITL AP_HAL::panic("unexpected telemetry"); #endif return; } esc.telem_expected = false; return handle_message_telem(esc); #else return; #endif // HAL_WITH_ESC_TELEM } } #if HAL_WITH_ESC_TELEM void AP_FETtecOneWire::handle_message_telem(ESC &esc) { // the following two methods are coming from AP_ESC_Telem: const TLM &tlm = u.packed_tlm.msg; // update rpm and error rate float error_rate_pct = 0; if (_fast_throttle_cmd_count > _esc_count) { error_rate_pct = (tlm.tx_err_count-esc.error_count_at_throttle_count_overflow)*(float)100/(float)_fast_throttle_cmd_count; } else { // the telemetry is requested in a round-robin, sequential fashion // so the in the first _esc_count times all ESCs get to initialize this esc.error_count_at_throttle_count_overflow = tlm.tx_err_count; } update_rpm(esc.servo_ofs, tlm.rpm*(100*2/_pole_count_parameter), error_rate_pct); // update power and temperature telem data TelemetryData t {}; t.temperature_cdeg = tlm.temp * 100; t.voltage = tlm.voltage * 0.01f; t.current = tlm.current * 0.01f; t.consumption_mah = tlm.consumption_mah; update_telem_data( esc.servo_ofs, t, TelemetryType::TEMPERATURE| TelemetryType::VOLTAGE| TelemetryType::CURRENT| TelemetryType::CONSUMPTION); esc.last_telem_us = AP_HAL::micros(); } #endif // HAL_WITH_ESC_TELEM // reads data from the UART, calling handle_message on any message found void AP_FETtecOneWire::read_data_from_uart() { /* a frame looks like: byte 1 = frame header (0x02 = bootloader, 0x03 = ESC firmware) byte 2 = sender ID (5bit) byte 3 & 4 = frame type (always 0x00, 0x00 used for bootloader. here just for compatibility) byte 5 = frame length over all bytes byte 6 - X = answer type, followed by the payload byte X+1 = 8bit CRC */ #if HAL_AP_FETTEC_HALF_DUPLEX //ignore own bytes if (_use_hdplex) { while (_ignore_own_bytes > 0 && _uart->available()) { _ignore_own_bytes--; _uart->read(); } } #endif uint32_t bytes_to_read = MIN(_uart->available(), 128U); uint32_t last_bytes_to_read = 0; while (bytes_to_read && bytes_to_read != last_bytes_to_read) { last_bytes_to_read = bytes_to_read; // read as much from the uart as we can: const uint8_t space = ARRAY_SIZE(u.receive_buf) - _receive_buf_used; const uint32_t nbytes = _uart->read(&u.receive_buf[_receive_buf_used], space); _receive_buf_used += nbytes; bytes_to_read -= nbytes; move_frame_source_in_receive_buffer(); // borrow the "OK" message to retrieve the frame length from the buffer: const uint8_t frame_length = u.packed_ok.frame_length; if (_receive_buf_used < frame_length) { continue; } if (crc8_dvb_update(0, u.receive_buf, frame_length-1) != u.receive_buf[frame_length-1]) { // bad message; shift away this frame_source byte to try to find // another message #if CONFIG_HAL_BOARD == HAL_BOARD_SITL AP_HAL::panic("bad message"); #endif crc_rec_err_cnt++; move_frame_source_in_receive_buffer(1); continue; } // borrow the "OK" message to retrieve the frame_source from the buffer: const FrameSource frame_source = (FrameSource)u.packed_ok.frame_source; if (frame_source == FrameSource::MASTER) { // this is our own message - we'd best be running in // half-duplex or we're in trouble! consume_bytes(frame_length); continue; } // borrow the "OK" message to retrieve the esc id from the buffer: const uint8_t esc_id = u.packed_ok.esc_id; bool handled = false; // FIXME: we could scribble down the last ESC we sent a // message to here and use it rather than doing this linear // search: for (uint8_t i=0; i<_esc_count; i++) { auto &esc = _escs[i]; if (esc.id != esc_id) { continue; } handle_message(esc, frame_length); handled = true; break; } if (!handled) { _unknown_esc_message++; } consume_bytes(frame_length); } } /** packs a single fast-throttle command frame containing the throttle for all configured OneWire ESCs. @param motor_values a 16bit array containing the throttle values that should be sent to the motors. 0-2000 where 1001-2000 is positive rotation and 0-999 reversed rotation @param esc_id_to_request_telem_from the ESC to request telemetry from */ void AP_FETtecOneWire::pack_fast_throttle_command(const uint16_t *motor_values, uint8_t *fast_throttle_command, const uint8_t length, const uint8_t esc_id_to_request_telem_from) { // byte 1: // bit 0,1,2,3 = ESC ID, Bit 4 = MSB bit of first ESC (11bit) throttle value, bit 5,6,7 = frame header // so AAAABCCC // A = ID from the ESC telemetry is requested from. ESC ID == 0 means no request. // B = MSB from first throttle value // C = frame header fast_throttle_command[0] = esc_id_to_request_telem_from << 4; // 0 here means no telemetry request fast_throttle_command[0] |= ((motor_values[0] >> 10) & 0x01) << 3; fast_throttle_command[0] |= (uint8_t)FrameSource::MASTER; // byte 2: // AAABBBBB // A = next 3 bits from (11bit) throttle value // B = 5bit target ID fast_throttle_command[1] = (((motor_values[0] >> 7) & 0x07)) << 5; fast_throttle_command[1] |= 0x1F; // All IDs // following bytes are the rest 7 bit of the first (11bit) throttle value, // and all bits from all other throttle values, followed by the CRC byte uint8_t mot = 0; uint8_t bits_remaining_in_this_pwm = 7; for (uint8_t out_byte_offset = 2; out_byte_offset= 8) { // const uint8_t mask = 0xFF << (11-bits_remaining_in_this_pwm); fast_throttle_command[out_byte_offset] = (motor_values[mot] >> (bits_remaining_in_this_pwm-8)) & 0xFF; bits_remaining_in_this_pwm -= 8; } else { const uint8_t mask = (1U<> (11-bits_to_copy_from_second_pwm); } bits_remaining_in_this_pwm = 11 - bits_to_copy_from_second_pwm; } } fast_throttle_command[length-1] = crc8_dvb_update(0, fast_throttle_command, length-1); } void AP_FETtecOneWire::escs_set_values(const uint16_t* motor_values) { uint8_t esc_id_to_request_telem_from = 0; #if HAL_WITH_ESC_TELEM ESC &esc_to_req_telem_from = _escs[_esc_ofs_to_request_telem_from++]; if (_esc_ofs_to_request_telem_from >= _esc_count) { _esc_ofs_to_request_telem_from = 0; } esc_id_to_request_telem_from = esc_to_req_telem_from.id; #endif uint8_t fast_throttle_command[_fast_throttle_byte_count]; pack_fast_throttle_command(motor_values, fast_throttle_command, sizeof(fast_throttle_command), esc_id_to_request_telem_from); #if HAL_AP_FETTEC_HALF_DUPLEX // last byte of signal can be used to make sure the first TLM byte is correct, in case of spike corruption // FIXME: use this somehow _last_crc = fast_throttle_command[_fast_throttle_byte_count - 1]; #endif // No command was yet sent, so no reply is expected and all information // on the receive buffer is either garbage or noise. Discard it _uart->discard_input(); _receive_buf_used = 0; // send throttle commands to all configured ESCs in a single packet transfer if (transmit(fast_throttle_command, sizeof(fast_throttle_command))) { #if HAL_WITH_ESC_TELEM esc_to_req_telem_from.telem_expected = true; // used to make sure that the returned telemetry comes from this ESC and not another esc_to_req_telem_from.telem_requested = true; // used to check if this ESC is periodically sending telemetry _fast_throttle_cmd_count++; #endif } } bool AP_FETtecOneWire::pre_arm_check(char *failure_msg, const uint8_t failure_msg_len) const { if (_motor_mask_parameter == 0) { return true; // No FETtec ESCs are expected, no need to run further pre-arm checks } if (_uart == nullptr) { hal.util->snprintf(failure_msg, failure_msg_len, "No uart"); return false; } if (_invalid_mask) { hal.util->snprintf(failure_msg, failure_msg_len, "Invalid motor mask"); return false; } #if HAL_WITH_ESC_TELEM if (_pole_count_parameter < 2) { hal.util->snprintf(failure_msg, failure_msg_len, "Invalid pole count %u", uint8_t(_pole_count_parameter)); return false; } uint8_t no_telem = 0; const uint32_t now = AP_HAL::micros(); #endif uint8_t not_running = 0; for (uint8_t i=0; i<_esc_count; i++) { auto &esc = _escs[i]; if (esc.state != ESCState::RUNNING) { not_running++; continue; } #if HAL_WITH_ESC_TELEM if (now - esc.last_telem_us > max_telem_interval_us) { no_telem++; } #endif } if (not_running != 0) { hal.util->snprintf(failure_msg, failure_msg_len, "%u of %u ESCs are not running", not_running, _esc_count); return false; } if (!_init_done) { hal.util->snprintf(failure_msg, failure_msg_len, "Not initialised"); return false; } #if HAL_WITH_ESC_TELEM if (no_telem != 0) { hal.util->snprintf(failure_msg, failure_msg_len, "%u of %u ESCs are not sending telemetry", no_telem, _esc_count); return false; } #endif return true; } void AP_FETtecOneWire::configure_escs() { if (_uart->available()) { // don't attempt to configure if we've unread data return; } // note that we return as soon as we've transmitted anything in // case we're in one-wire mode for (uint8_t i=0; i<_esc_count; i++) { auto &esc = _escs[i]; switch (esc.state) { case ESCState::UNINITIALISED: esc.state = ESCState::WANT_SEND_OK_TO_GET_RUNNING_SW_TYPE; FALLTHROUGH; case ESCState::WANT_SEND_OK_TO_GET_RUNNING_SW_TYPE: // probe for bootloader or running firmware if (transmit_config_request(PackedMessage{esc.id, OK{}})) { esc.is_awake = false; // Assume the ESC is asleep or unavailable esc.set_state(ESCState::WAITING_OK_FOR_RUNNING_SW_TYPE); } return; case ESCState::WAITING_OK_FOR_RUNNING_SW_TYPE: if (!esc.is_awake) { esc.set_state(ESCState::WANT_SEND_OK_TO_GET_RUNNING_SW_TYPE); // go back to try to wake up the ESC } return; case ESCState::WANT_SEND_START_FW: if (transmit_config_request(PackedMessage{esc.id, START_FW{}})) { esc.set_state(ESCState::WAITING_OK_FOR_START_FW); } return; case ESCState::WAITING_OK_FOR_START_FW: return; #if HAL_AP_FETTEC_ONEWIRE_GET_STATIC_INFO case ESCState::WANT_SEND_REQ_TYPE: if (transmit_config_request(PackedMessage{esc.id, REQ_TYPE{}})) { esc.set_state(ESCState::WAITING_ESC_TYPE); } return; case ESCState::WAITING_ESC_TYPE: return; case ESCState::WANT_SEND_REQ_SW_VER: if (transmit_config_request(PackedMessage{esc.id, REQ_SW_VER{}})) { esc.set_state(ESCState::WAITING_SW_VER); } return; case ESCState::WAITING_SW_VER: return; case ESCState::WANT_SEND_REQ_SN: if (transmit_config_request(PackedMessage{esc.id, REQ_SN{}})) { esc.set_state(ESCState::WAITING_SN); } return; case ESCState::WAITING_SN: return; #endif // HAL_AP_FETTEC_ONEWIRE_GET_STATIC_INFO #if HAL_WITH_ESC_TELEM case ESCState::WANT_SEND_SET_TLM_TYPE: if (transmit_config_request(PackedMessage{esc.id, SET_TLM_TYPE{1}})) { esc.set_state(ESCState::WAITING_SET_TLM_TYPE_OK); } return; case ESCState::WAITING_SET_TLM_TYPE_OK: return; #endif case ESCState::WANT_SEND_SET_FAST_COM_LENGTH: if (transmit_config_request(PackedMessage{esc.id, SET_FAST_COM_LENGTH{ _fast_throttle_byte_count, _escs[0].id, _esc_count }})) { esc.set_state(ESCState::WAITING_SET_FAST_COM_LENGTH_OK); } return; case ESCState::WAITING_SET_FAST_COM_LENGTH_OK: return; case ESCState::RUNNING: _running_mask |= (1U << esc.servo_ofs); break; } } } /// periodically called from SRV_Channels::push() void AP_FETtecOneWire::update() { if (!_init_done) { init(); return; // the rest of this function can only run after fully initted } // read all data from incoming serial: read_data_from_uart(); const uint32_t now = AP_HAL::micros(); #if HAL_WITH_ESC_TELEM if (!hal.util->get_soft_armed()) { _reverse_mask = _reverse_mask_parameter; // update this only when disarmed // if we haven't seen an ESC in a while, the user might // have power-cycled them. Try re-initialising. for (uint8_t i=0; i<_esc_count; i++) { auto &esc = _escs[i]; if (!esc.telem_requested || now - esc.last_telem_us < 1000000U ) { // telem OK continue; } _running_mask &= ~(1U << esc.servo_ofs); GCS_SEND_TEXT(MAV_SEVERITY_WARNING, "No telem from esc id=%u. Resetting it.", esc.id); //GCS_SEND_TEXT(MAV_SEVERITY_WARNING, "unknown %u, invalid %u, too short %u, unexpected: %u, crc_err %u", _unknown_esc_message, _message_invalid_in_state_count, _period_too_short, esc.unexpected_telem, crc_rec_err_cnt); esc.set_state(ESCState::WANT_SEND_OK_TO_GET_RUNNING_SW_TYPE); esc.telem_requested = false; } } #endif // HAL_WITH_ESC_TELEM if (now - _last_transmit_us < 700U) { // in case the SRV_Channels::push() is running at very high rates, limit the period // this function gets executed because FETtec needs a time gap between frames _period_too_short++; return; } #if defined(STM32F4) if (_uart->tx_pending()) { // there is unsent data in the send buffer, // do not send more data because FETtec needs a time gap between frames _period_too_short++; return; } #endif #if HAL_AP_FETTEC_CONFIGURE_ESCS // run ESC configuration state machines if needed if (_running_mask != _motor_mask) { configure_escs(); return; // do not send fast-throttle command if a configuration command just got sent } #endif // get ESC set points uint16_t motor_pwm[_esc_count]; for (uint8_t i = 0; i < _esc_count; i++) { const ESC &esc = _escs[i]; const SRV_Channel* c = SRV_Channels::srv_channel(esc.servo_ofs); // check if safety switch has been pushed if ( (hal.util->safety_switch_state() == AP_HAL::Util::SAFETY_DISARMED) || (c == nullptr)) { // this should never ever happen, but just in case ... motor_pwm[i] = 1000; // stop motor continue; } motor_pwm[i] = constrain_int16(c->get_output_pwm(), 1000, 2000); fet_debug("esc=%u in: %u", esc.id, motor_pwm[i]); if (_reverse_mask & (1U << i)) { motor_pwm[i] = 2000-motor_pwm[i]; } } // send motor setpoints to ESCs, and request for telemetry data escs_set_values(motor_pwm); } #if HAL_AP_FETTEC_ESC_BEEP /** makes all connected ESCs beep @param beep_frequency a 8 bit value from 0-255. higher make a higher beep */ void AP_FETtecOneWire::beep(const uint8_t beep_frequency) { for (uint8_t i=0; i<_esc_count; i++) { auto &esc = _escs[i]; if (esc.state != ESCState::RUNNING) { continue; } transmit_config_request(PackedMessage{esc.id, Beep{beep_frequency}}); } } #endif // HAL_AP_FETTEC_ESC_BEEP #if HAL_AP_FETTEC_ESC_LIGHT /** sets the racewire color for all ESCs r = red brightness g = green brightness b = blue brightness */ void AP_FETtecOneWire::led_color(const uint8_t r, const uint8_t g, const uint8_t b) { for (uint8_t i=0; i<_esc_count; i++) { auto &esc = _escs[i]; if (esc.state != ESCState::RUNNING) { continue; } transmit_config_request(PackedMessage{esc.id, LEDColour{r, g, b}}); } } #endif // HAL_AP_FETTEC_ESC_LIGHT #endif // AP_FETTEC_ONEWIRE_ENABLED