/* 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 . */ /* * ArduPilot device driver for SLAMTEC RPLIDAR A2 (16m range version) * * ALL INFORMATION REGARDING PROTOCOL WAS DERIVED FROM RPLIDAR DATASHEET: * * https://www.slamtec.com/en/Lidar * http://bucket.download.slamtec.com/63ac3f0d8c859d3a10e51c6b3285fcce25a47357/LR001_SLAMTEC_rplidar_protocol_v1.0_en.pdf * * Author: Steven Josefs, IAV GmbH * Based on the LightWare SF40C ArduPilot device driver from Randy Mackay * */ #include "AP_Proximity_config.h" #if AP_PROXIMITY_RPLIDARA2_ENABLED #include "AP_Proximity_RPLidarA2.h" #include #include "AP_Proximity_RPLidarA2.h" #include #include #include #define RP_DEBUG_LEVEL 0 #if RP_DEBUG_LEVEL #include #define Debug(level, fmt, args ...) do { if (level <= RP_DEBUG_LEVEL) { gcs().send_text(MAV_SEVERITY_INFO, fmt, ## args); } } while (0) #else #define Debug(level, fmt, args ...) #endif #define COMM_ACTIVITY_TIMEOUT_MS 200 // Commands //----------------------------------------- // Commands without payload and response #define RPLIDAR_PREAMBLE 0xA5 #define RPLIDAR_CMD_STOP 0x25 #define RPLIDAR_CMD_SCAN 0x20 #define RPLIDAR_CMD_FORCE_SCAN 0x21 #define RPLIDAR_CMD_RESET 0x40 // Commands without payload but have response #define RPLIDAR_CMD_GET_DEVICE_INFO 0x50 #define RPLIDAR_CMD_GET_DEVICE_HEALTH 0x52 // Commands with payload and have response #define RPLIDAR_CMD_EXPRESS_SCAN 0x82 extern const AP_HAL::HAL& hal; void AP_Proximity_RPLidarA2::update(void) { if (_uart == nullptr) { return; } get_readings(); // check for timeout and set health status if (AP_HAL::millis() - _last_distance_received_ms > COMM_ACTIVITY_TIMEOUT_MS) { set_status(AP_Proximity::Status::NoData); Debug(1, "LIDAR NO DATA"); if (AP_HAL::millis() - _last_reset_ms > 10000) { reset_rplidar(); } } else { set_status(AP_Proximity::Status::Good); } } // get maximum distance (in meters) of sensor float AP_Proximity_RPLidarA2::distance_max() const { switch (model) { case Model::UNKNOWN: return 0.0f; case Model::A1: return 8.0f; case Model::A2: return 16.0f; } return 0.0f; } // get minimum distance (in meters) of sensor float AP_Proximity_RPLidarA2::distance_min() const { switch (model) { case Model::UNKNOWN: return 0.0f; case Model::A1: return 0.2f; case Model::A2: return 0.2f; } return 0.0f; } void AP_Proximity_RPLidarA2::reset_rplidar() { static const uint8_t tx_buffer[2] {RPLIDAR_PREAMBLE, RPLIDAR_CMD_RESET}; _uart->write(tx_buffer, 2); Debug(1, "LIDAR reset"); // To-Do: ensure delay of 8m after sending reset request _last_reset_ms = AP_HAL::millis(); _state = State::RESET; reset(); } // set Lidar into SCAN mode void AP_Proximity_RPLidarA2::send_scan_mode_request() { static const uint8_t tx_buffer[2] {RPLIDAR_PREAMBLE, RPLIDAR_CMD_SCAN}; _uart->write(tx_buffer, 2); Debug(1, "Sent scan mode request"); } // send request for sensor health void AP_Proximity_RPLidarA2::send_request_for_health() //not called yet { static const uint8_t tx_buffer[2] {RPLIDAR_PREAMBLE, RPLIDAR_CMD_GET_DEVICE_HEALTH}; _uart->write(tx_buffer, 2); Debug(1, "Sent health request"); } // send request for device information void AP_Proximity_RPLidarA2::send_request_for_device_info() { static const uint8_t tx_buffer[2] {RPLIDAR_PREAMBLE, RPLIDAR_CMD_GET_DEVICE_INFO}; _uart->write(tx_buffer, 2); Debug(1, "Sent device information request"); } void AP_Proximity_RPLidarA2::consume_bytes(uint16_t count) { _byte_count -= count; if (_byte_count) { memmove((void*)&_payload[0], (void*)&_payload[count], _byte_count); } } void AP_Proximity_RPLidarA2::reset() { _state = State::RESET; _byte_count = 0; } bool AP_Proximity_RPLidarA2::make_first_byte_in_payload(uint8_t desired_byte) { if (_byte_count == 0) { return false; } if (_payload[0] == desired_byte) { return true; } for (uint8_t i=1; iavailable(); if (nbytes == 0) { return; } const uint32_t bytes_to_read = MIN(nbytes, sizeof(_payload)-_byte_count); if (bytes_to_read == 0) { INTERNAL_ERROR(AP_InternalError::error_t::flow_of_control); reset(); return; } const uint32_t bytes_read = _uart->read(&_payload[_byte_count], bytes_to_read); if (bytes_read == 0) { // this is bad; we were told there were bytes available INTERNAL_ERROR(AP_InternalError::error_t::flow_of_control); reset(); return; } _byte_count += bytes_read; uint32_t previous_loop_byte_count = UINT32_MAX; while (_byte_count) { if (_byte_count >= previous_loop_byte_count) { // this is a serious error, we should always consume some // bytes. Avoid looping forever. INTERNAL_ERROR(AP_InternalError::error_t::flow_of_control); _uart = nullptr; return; } previous_loop_byte_count = _byte_count; switch(_state){ case State::RESET: { // looking for 0x52 at start of buffer; the 62 following // bytes are "information" if (!make_first_byte_in_payload('R')) { // that's 'R' as in RPiLidar return; } if (_byte_count < 63) { return; } #if RP_DEBUG_LEVEL // optionally spit out via mavlink the 63-bytes of cruft // that is spat out on device reset Debug(1, "Got RPLidar Information"); char xbuffer[64]{}; memcpy((void*)xbuffer, (void*)&_payload.information, 63); gcs().send_text(MAV_SEVERITY_INFO, "RPLidar: (%s)", xbuffer); #endif // 63 is the magic number of bytes in the spewed-out // reset data ... so now we'll just drop that stuff on // the floor. consume_bytes(63); send_request_for_device_info(); _state = State::AWAITING_RESPONSE; continue; } case State::AWAITING_RESPONSE: if (_payload[0] != RPLIDAR_PREAMBLE) { // this is a protocol error. Reset. reset(); return; } // descriptor packet has 7 byte in total if (_byte_count < sizeof(_descriptor)) { return; } // identify the payload data after the descriptor static const _descriptor SCAN_DATA_DESCRIPTOR[] { RPLIDAR_PREAMBLE, 0x5A, 0x05, 0x00, 0x00, 0x40, 0x81 }; static const _descriptor HEALTH_DESCRIPTOR[] { RPLIDAR_PREAMBLE, 0x5A, 0x03, 0x00, 0x00, 0x00, 0x06 }; static const _descriptor DEVICE_INFO_DESCRIPTOR[] { RPLIDAR_PREAMBLE, 0x5A, 0x14, 0x00, 0x00, 0x00, 0x04 }; Debug(2,"LIDAR descriptor found"); if (memcmp((void*)&_payload[0], SCAN_DATA_DESCRIPTOR, sizeof(_descriptor)) == 0) { _state = State::AWAITING_SCAN_DATA; } else if (memcmp((void*)&_payload[0], DEVICE_INFO_DESCRIPTOR, sizeof(_descriptor)) == 0) { _state = State::AWAITING_DEVICE_INFO; } else if (memcmp((void*)&_payload[0], HEALTH_DESCRIPTOR, sizeof(_descriptor)) == 0) { _state = State::AWAITING_HEALTH; } else { // unknown descriptor. Ignore it. } consume_bytes(sizeof(_descriptor)); break; case State::AWAITING_DEVICE_INFO: if (_byte_count < sizeof(_payload.device_info)) { return; } parse_response_device_info(); consume_bytes(sizeof(_payload.device_info)); break; case State::AWAITING_SCAN_DATA: if (_byte_count < sizeof(_payload.sensor_scan)) { return; } parse_response_data(); consume_bytes(sizeof(_payload.sensor_scan)); break; case State::AWAITING_HEALTH: if (_byte_count < sizeof(_payload.sensor_health)) { return; } parse_response_health(); consume_bytes(sizeof(_payload.sensor_health)); break; } } } void AP_Proximity_RPLidarA2::parse_response_device_info() { Debug(1, "Received DEVICE_INFO"); switch (_payload.device_info.model) { case 0x18: model = Model::A1; break; case 0x28: model = Model::A2; break; default: Debug(1, "Unknown device (%u)", _payload.device_info.model); } Debug(1, "firmware (%u.%u)", _payload.device_info.firmware_minor, _payload.device_info.firmware_major); Debug(1, "Hardware (%u)", _payload.device_info.hardware); send_scan_mode_request(); _state = State::AWAITING_RESPONSE; } void AP_Proximity_RPLidarA2::parse_response_data() { if (_sync_error) { // out of 5-byte sync mask -> catch new revolution Debug(1, " OUT OF SYNC"); // on first revolution bit 1 = 1, bit 2 = 0 of the first byte if ((_payload[0] & 0x03) == 0x01) { _sync_error = 0; Debug(1, " RESYNC"); } else { return; } } Debug(2, "UART %02x %02x%02x %02x%02x", _payload[0], _payload[2], _payload[1], _payload[4], _payload[3]); //show HEX values // check if valid SCAN packet: a valid packet starts with startbits which are complementary plus a checkbit in byte+1 if (!((_payload.sensor_scan.startbit == !_payload.sensor_scan.not_startbit) && _payload.sensor_scan.checkbit)) { Debug(1, "Invalid Payload"); _sync_error++; return; } const float angle_sign = (params.orientation == 1) ? -1.0f : 1.0f; const float angle_deg = wrap_360(_payload.sensor_scan.angle_q6/64.0f * angle_sign + params.yaw_correction); const float distance_m = (_payload.sensor_scan.distance_q2/4000.0f); #if RP_DEBUG_LEVEL >= 2 const float quality = _payload.sensor_scan.quality; Debug(2, " D%02.2f A%03.1f Q%02d", distance_m, angle_deg, quality); #endif _last_distance_received_ms = AP_HAL::millis(); if (!ignore_reading(angle_deg, distance_m)) { const AP_Proximity_Boundary_3D::Face face = frontend.boundary.get_face(angle_deg); if (face != _last_face) { // distance is for a new face, the previous one can be updated now if (_last_distance_valid) { frontend.boundary.set_face_attributes(_last_face, _last_angle_deg, _last_distance_m, state.instance); } else { // reset distance from last face frontend.boundary.reset_face(face, state.instance); } // initialize the new face _last_face = face; _last_distance_valid = false; } if (distance_m > distance_min()) { // update shortest distance if (!_last_distance_valid || (distance_m < _last_distance_m)) { _last_distance_m = distance_m; _last_distance_valid = true; _last_angle_deg = angle_deg; } // update OA database database_push(_last_angle_deg, _last_distance_m); } } } void AP_Proximity_RPLidarA2::parse_response_health() { // health issue if status is "3" ->HW error if (_payload.sensor_health.status == 3) { Debug(1, "LIDAR Error"); } Debug(1, "LIDAR Healthy"); } #endif // AP_PROXIMITY_RPLIDARA2_ENABLED