/* 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 . */ /* Simulator for the RPLidar proximity sensors */ #include "SIM_PS_RPLidar.h" #if HAL_SIM_PS_RPLIDARA2_ENABLED #include #include #include using namespace SITL; uint32_t PS_RPLidar::packet_for_location(const Location &location, uint8_t *data, uint8_t buflen) { return 0; } void PS_RPLidar::move_preamble_in_buffer() { uint8_t i; for (i=0; i<_buflen; i++) { if ((uint8_t)_buffer[i] == PREAMBLE) { break; } } if (i == 0) { return; } memmove(_buffer, &_buffer[i], _buflen-i); _buflen = _buflen - i; } void PS_RPLidar::update_input() { const ssize_t n = read_from_autopilot(&_buffer[_buflen], ARRAY_SIZE(_buffer) - _buflen - 1); if (n < 0) { // TODO: do better here if (errno != EAGAIN && errno != EWOULDBLOCK && errno != 0) { AP_HAL::panic("Failed to read from autopilot"); } } else { _buflen += n; } switch (_inputstate) { case InputState::WAITING_FOR_PREAMBLE: move_preamble_in_buffer(); if (_buflen == 0) { return; } set_inputstate(InputState::GOT_PREAMBLE); // consume the preamble: memmove(_buffer, &_buffer[1], _buflen-1); _buflen--; FALLTHROUGH; case InputState::GOT_PREAMBLE: if (_buflen == 0) { return; } switch ((Command)_buffer[0]) { case Command::STOP: // consume the command: memmove(_buffer, &_buffer[1], _buflen-1); _buflen--; set_inputstate(InputState::WAITING_FOR_PREAMBLE); set_state(State::IDLE); return; case Command::SCAN: // consume the command: memmove(_buffer, &_buffer[1], _buflen-1); _buflen--; send_response_descriptor(0x05, SendMode::SRMR, DataType::Unknown81); set_inputstate(InputState::WAITING_FOR_PREAMBLE); set_state(State::SCANNING); return; case Command::GET_HEALTH: { // consume the command: memmove(_buffer, &_buffer[1], _buflen-1); _buflen--; send_response_descriptor(0x03, SendMode::SRSR, DataType::Unknown06); // now send the health: const uint8_t health[3] {}; // all zeros fine for now const ssize_t ret = write_to_autopilot((const char*)health, ARRAY_SIZE(health)); if (ret != ARRAY_SIZE(health)) { abort(); } set_inputstate(InputState::WAITING_FOR_PREAMBLE); return; } case Command::GET_DEVICE_INFO: { // consume the command: memmove(_buffer, &_buffer[1], _buflen-1); _buflen--; send_response_descriptor(0x14, SendMode::SRSR, DataType::Unknown04); // now send the device info: struct PACKED _device_info { uint8_t model; uint8_t firmware_minor; uint8_t firmware_major; uint8_t hardware; uint8_t serial[16]; } device_info; device_info.model = device_info_model(); device_info.firmware_minor = 17; device_info.firmware_major = 42; device_info.hardware = 6; const ssize_t ret = write_to_autopilot((const char*)&device_info, sizeof(device_info)); if (ret != sizeof(device_info)) { abort(); } set_inputstate(InputState::WAITING_FOR_PREAMBLE); return; } case Command::FORCE_SCAN: abort(); case Command::RESET: // consume the command: memmove(_buffer, &_buffer[1], _buflen-1); _buflen--; set_inputstate(InputState::RESETTING_START); return; default: AP_HAL::panic("Bad command received (%02x)", (uint8_t)_buffer[0]); } case InputState::RESETTING_START: _firmware_info_offset = 0; set_inputstate(InputState::RESETTING_SEND_FIRMWARE_INFO); FALLTHROUGH; case InputState::RESETTING_SEND_FIRMWARE_INFO: { const ssize_t written = write_to_autopilot(&FIRMWARE_INFO[_firmware_info_offset], strlen(FIRMWARE_INFO) - _firmware_info_offset); if (written <= 0) { AP_HAL::panic("Failed to write to autopilot"); } _firmware_info_offset += written; if (_firmware_info_offset < strlen(FIRMWARE_INFO)) { return; } set_inputstate(InputState::WAITING_FOR_PREAMBLE); return; } } } void PS_RPLidar::update_output_scan(const Location &location) { const uint32_t now = AP_HAL::millis(); if (last_scan_output_time_ms == 0) { last_scan_output_time_ms = now; return; } const uint32_t time_delta = (now - last_scan_output_time_ms); const uint32_t samples_per_second = 1000; const float samples_per_ms = samples_per_second / 1000.0f; const uint32_t sample_count = time_delta / samples_per_ms; const float degrees_per_ms = 3600 / 1000.0f; const float degrees_per_sample = degrees_per_ms / samples_per_ms; // ::fprintf(stderr, "Packing %u samples in for %ums interval (%f degrees/sample)\n", sample_count, time_delta, degrees_per_sample); last_scan_output_time_ms += sample_count/samples_per_ms; for (uint32_t i=0; i max_range()) { // sensor returns zero for out-of-range distance = 0.0f; } const uint16_t distance_q2 = (distance*1000 * 4); // m->mm and *4 struct PACKED { uint8_t startbit : 1; ///< on the first revolution 1 else 0 uint8_t not_startbit : 1; ///< complementary to startbit uint8_t quality : 6; ///< Related the reflected laser pulse strength uint8_t checkbit : 1; ///< always set to 1 uint16_t angle_q6 : 15; ///< Actual heading = angle_q6/64.0 Degree uint16_t distance_q2 : 16; ///< Actual Distance = distance_q2/4.0 mm } send_buffer; send_buffer.startbit = is_start_packet; send_buffer.not_startbit = !is_start_packet; send_buffer.quality = quality; send_buffer.checkbit = 1; send_buffer.angle_q6 = angle_q6; send_buffer.distance_q2 = distance_q2; static_assert(sizeof(send_buffer) == 5, "send_buffer correct size"); const ssize_t ret = write_to_autopilot((const char*)&send_buffer, sizeof(send_buffer)); if (ret != sizeof(send_buffer)) { abort(); } } } void PS_RPLidar::update_output(const Location &location) { switch (_state) { case State::IDLE: return; case State::SCANNING: update_output_scan(location); return; } } void PS_RPLidar::update(const Location &location) { update_input(); update_output(location); } void PS_RPLidar::send_response_descriptor(uint32_t data_response_length, SendMode sendmode, DataType datatype) { const uint8_t send_buffer[] = { 0xA5, 0x5A, uint8_t((data_response_length >> 0) & 0xff), uint8_t((data_response_length >> 8) & 0xff), uint8_t((data_response_length >> 16) & 0xff), uint8_t(((data_response_length >> 24) & 0xff) | (uint8_t) sendmode), (uint8_t)datatype }; static_assert(ARRAY_SIZE(send_buffer) == 7, "send_buffer correct size"); const ssize_t ret = write_to_autopilot((const char*)send_buffer, ARRAY_SIZE(send_buffer)); if (ret != ARRAY_SIZE(send_buffer)) { abort(); } } #endif // HAL_SIM_PS_RPLIDARA2_ENABLED