#include "AP_DAL.h" #include #include #include #include #include #include #if APM_BUILD_TYPE(APM_BUILD_Replay) #include #include #endif extern const AP_HAL::HAL& hal; AP_DAL *AP_DAL::_singleton = nullptr; bool AP_DAL::force_write; bool AP_DAL::logging_started; void AP_DAL::start_frame(AP_DAL::FrameType frametype) { #if !APM_BUILD_TYPE(APM_BUILD_AP_DAL_Standalone) && !APM_BUILD_TYPE(APM_BUILD_Replay) if (!init_done) { init_sensors(); } const AP_AHRS &ahrs = AP::ahrs(); const uint32_t imu_us = AP::ins().get_last_update_usec(); if (_last_imu_time_us == imu_us) { _RFRF.frame_types |= uint8_t(frametype); return; } _last_imu_time_us = imu_us; // we force write all msgs when logging starts bool logging = AP::logger().logging_started() && AP::logger().allow_start_ekf(); if (logging && !logging_started) { force_write = true; } logging_started = logging; end_frame(); _RFRF.frame_types = uint8_t(frametype); _RFRH.time_flying_ms = AP::vehicle()->get_time_flying_ms(); _RFRH.time_us = AP_HAL::micros64(); WRITE_REPLAY_BLOCK(RFRH, _RFRH); // update RFRN data const log_RFRN old = _RFRN; _RFRN.armed = hal.util->get_soft_armed(); _home = ahrs.get_home(); _RFRN.lat = _home.lat; _RFRN.lng = _home.lng; _RFRN.alt = _home.alt; _RFRN.EAS2TAS = AP::baro().get_EAS2TAS(); _RFRN.vehicle_class = (uint8_t)ahrs.get_vehicle_class(); _RFRN.fly_forward = ahrs.get_fly_forward(); _RFRN.takeoff_expected = ahrs.get_takeoff_expected(); _RFRN.touchdown_expected = ahrs.get_touchdown_expected(); _RFRN.ahrs_airspeed_sensor_enabled = AP::ahrs().airspeed_sensor_enabled(); _RFRN.available_memory = hal.util->available_memory(); _RFRN.ahrs_trim = ahrs.get_trim(); _RFRN.opticalflow_enabled = AP::opticalflow() && AP::opticalflow()->enabled(); _RFRN.wheelencoder_enabled = AP::wheelencoder() && (AP::wheelencoder()->num_sensors() > 0); WRITE_REPLAY_BLOCK_IFCHANGED(RFRN, _RFRN, old); // update body conversion _rotation_vehicle_body_to_autopilot_body = ahrs.get_rotation_vehicle_body_to_autopilot_body(); _ins.start_frame(); _baro.start_frame(); _gps.start_frame(); _compass.start_frame(); if (_airspeed) { _airspeed->start_frame(); } if (_rangefinder) { _rangefinder->start_frame(); } if (_beacon) { _beacon->start_frame(); } #if HAL_VISUALODOM_ENABLED if (_visualodom) { _visualodom->start_frame(); } #endif // populate some derivative values: _micros = _RFRH.time_us; _millis = _RFRH.time_us / 1000UL; force_write = false; #endif } // for EKF usage to enable takeoff expected to true void AP_DAL::set_takeoff_expected() { #if !APM_BUILD_TYPE(APM_BUILD_AP_DAL_Standalone) && !APM_BUILD_TYPE(APM_BUILD_Replay) AP_AHRS &ahrs = AP::ahrs(); ahrs.set_takeoff_expected(true); #endif } /* setup optional sensor backends */ void AP_DAL::init_sensors(void) { init_done = true; bool alloc_failed = false; /* we only allocate the DAL backends if we had at least one sensor at the time we startup the EKF */ auto *rng = AP::rangefinder(); if (rng && rng->num_sensors() > 0) { alloc_failed |= (_rangefinder = new AP_DAL_RangeFinder) == nullptr; } auto *aspeed = AP::airspeed(); if (aspeed != nullptr && aspeed->get_num_sensors() > 0) { alloc_failed |= (_airspeed = new AP_DAL_Airspeed) == nullptr; } auto *bcn = AP::beacon(); if (bcn != nullptr && bcn->enabled()) { alloc_failed |= (_beacon = new AP_DAL_Beacon) == nullptr; } #if HAL_VISUALODOM_ENABLED auto *vodom = AP::visualodom(); if (vodom != nullptr && vodom->enabled()) { alloc_failed |= (_visualodom = new AP_DAL_VisualOdom) == nullptr; } #endif if (alloc_failed) { AP_BoardConfig::config_error("Unable to allocate DAL backends"); } } /* end a frame. Must be called on all events and injections of data (eg flow) and before starting a new frame */ void AP_DAL::end_frame(void) { if (_RFRF.frame_types != 0) { WRITE_REPLAY_BLOCK(RFRF, _RFRF); _RFRF.frame_types = 0; } } void AP_DAL::log_event2(AP_DAL::Event event) { #if !APM_BUILD_TYPE(APM_BUILD_AP_DAL_Standalone) && !APM_BUILD_TYPE(APM_BUILD_Replay) end_frame(); struct log_REV2 pkt{ event : uint8_t(event), }; WRITE_REPLAY_BLOCK(REV2, pkt); #endif } void AP_DAL::log_SetOriginLLH2(const Location &loc) { #if !APM_BUILD_TYPE(APM_BUILD_AP_DAL_Standalone) && !APM_BUILD_TYPE(APM_BUILD_Replay) struct log_RSO2 pkt{ lat : loc.lat, lng : loc.lng, alt : loc.alt, }; WRITE_REPLAY_BLOCK(RSO2, pkt); #endif } void AP_DAL::log_writeDefaultAirSpeed2(const float aspeed, const float uncertainty) { #if !APM_BUILD_TYPE(APM_BUILD_AP_DAL_Standalone) && !APM_BUILD_TYPE(APM_BUILD_Replay) struct log_RWA2 pkt{ airspeed: aspeed, uncertainty: uncertainty, }; WRITE_REPLAY_BLOCK(RWA2, pkt); #endif } void AP_DAL::log_event3(AP_DAL::Event event) { #if !APM_BUILD_TYPE(APM_BUILD_AP_DAL_Standalone) && !APM_BUILD_TYPE(APM_BUILD_Replay) end_frame(); struct log_REV3 pkt{ event : uint8_t(event), }; WRITE_REPLAY_BLOCK(REV3, pkt); #endif } void AP_DAL::log_SetOriginLLH3(const Location &loc) { #if !APM_BUILD_TYPE(APM_BUILD_AP_DAL_Standalone) && !APM_BUILD_TYPE(APM_BUILD_Replay) struct log_RSO3 pkt{ lat : loc.lat, lng : loc.lng, alt : loc.alt, }; WRITE_REPLAY_BLOCK(RSO3, pkt); #endif } void AP_DAL::log_writeDefaultAirSpeed3(const float aspeed, const float uncertainty) { #if !APM_BUILD_TYPE(APM_BUILD_AP_DAL_Standalone) && !APM_BUILD_TYPE(APM_BUILD_Replay) struct log_RWA3 pkt{ airspeed: aspeed, uncertainty: uncertainty }; WRITE_REPLAY_BLOCK(RWA3, pkt); #endif } void AP_DAL::log_writeEulerYawAngle(float yawAngle, float yawAngleErr, uint32_t timeStamp_ms, uint8_t type) { #if !APM_BUILD_TYPE(APM_BUILD_AP_DAL_Standalone) && !APM_BUILD_TYPE(APM_BUILD_Replay) struct log_REY3 pkt{ yawangle : yawAngle, yawangleerr : yawAngleErr, timestamp_ms : timeStamp_ms, type : type, }; WRITE_REPLAY_BLOCK(REY3, pkt); #endif } int AP_DAL::snprintf(char* str, size_t size, const char *format, ...) const { va_list ap; va_start(ap, format); int res = hal.util->vsnprintf(str, size, format, ap); va_end(ap); return res; } void *AP_DAL::malloc_type(size_t size, Memory_Type mem_type) const { return hal.util->malloc_type(size, AP_HAL::Util::Memory_Type(mem_type)); } // map core number for replay uint8_t AP_DAL::logging_core(uint8_t c) const { #if APM_BUILD_TYPE(APM_BUILD_Replay) return c+100U; #else return c; #endif } // write out a DAL log message. If old_msg is non-null, then // only write if the content has changed void AP_DAL::WriteLogMessage(enum LogMessages msg_type, void *msg, const void *old_msg, uint8_t msg_size) { if (!logging_started) { // we're not logging return; } // we use the _end byte to hold a flag for forcing output uint8_t &_end = ((uint8_t *)msg)[msg_size]; if (old_msg && !force_write && _end == 0 && memcmp(msg, old_msg, msg_size) == 0) { // no change, skip this block write return; } if (!AP::logger().WriteReplayBlock(msg_type, msg, msg_size)) { // mark for forced write next time _end = 1; } else { _end = 0; } } /* check if we are low on CPU for this core. This needs to capture the timing of running the cores */ bool AP_DAL::ekf_low_time_remaining(EKFType etype, uint8_t core) { static_assert(INS_MAX_INSTANCES <= 4, "max 4 IMUs"); const uint8_t mask = (1U<<(core+(uint8_t(etype)*4))); #if !APM_BUILD_TYPE(APM_BUILD_AP_DAL_Standalone) && !APM_BUILD_TYPE(APM_BUILD_Replay) /* if we have used more than 1/3 of the time for a loop then we return true, indicating that we are low on CPU. This changes the scheduling of fusion between lanes */ const auto &imu = AP::ins(); if ((AP_HAL::micros() - imu.get_last_update_usec())*1.0e-6 > imu.get_loop_delta_t()*0.33) { _RFRF.core_slow |= mask; } else { _RFRF.core_slow &= ~mask; } #endif return (_RFRF.core_slow & mask) != 0; } // log optical flow data void AP_DAL::writeOptFlowMeas(const uint8_t rawFlowQuality, const Vector2f &rawFlowRates, const Vector2f &rawGyroRates, const uint32_t msecFlowMeas, const Vector3f &posOffset) { end_frame(); const log_ROFH old = _ROFH; _ROFH.rawFlowQuality = rawFlowQuality; _ROFH.rawFlowRates = rawFlowRates; _ROFH.rawGyroRates = rawGyroRates; _ROFH.msecFlowMeas = msecFlowMeas; _ROFH.posOffset = posOffset; WRITE_REPLAY_BLOCK_IFCHANGED(ROFH, _ROFH, old); } // log external navigation data void AP_DAL::writeExtNavData(const Vector3f &pos, const Quaternion &quat, float posErr, float angErr, uint32_t timeStamp_ms, uint16_t delay_ms, uint32_t resetTime_ms) { end_frame(); const log_REPH old = _REPH; _REPH.pos = pos; _REPH.quat = quat; _REPH.posErr = posErr; _REPH.angErr = angErr; _REPH.timeStamp_ms = timeStamp_ms; _REPH.delay_ms = delay_ms; _REPH.resetTime_ms = resetTime_ms; WRITE_REPLAY_BLOCK_IFCHANGED(REPH, _REPH, old); } // log external velocity data void AP_DAL::writeExtNavVelData(const Vector3f &vel, float err, uint32_t timeStamp_ms, uint16_t delay_ms) { end_frame(); const log_REVH old = _REVH; _REVH.vel = vel; _REVH.err = err; _REVH.timeStamp_ms = timeStamp_ms; _REVH.delay_ms = delay_ms; WRITE_REPLAY_BLOCK_IFCHANGED(REVH, _REVH, old); } // log wheel odomotry data void AP_DAL::writeWheelOdom(float delAng, float delTime, uint32_t timeStamp_ms, const Vector3f &posOffset, float radius) { end_frame(); const log_RWOH old = _RWOH; _RWOH.delAng = delAng; _RWOH.delTime = delTime; _RWOH.timeStamp_ms = timeStamp_ms; _RWOH.posOffset = posOffset; _RWOH.radius = radius; WRITE_REPLAY_BLOCK_IFCHANGED(RWOH, _RWOH, old); } void AP_DAL::writeBodyFrameOdom(float quality, const Vector3f &delPos, const Vector3f &delAng, float delTime, uint32_t timeStamp_ms, uint16_t delay_ms, const Vector3f &posOffset) { end_frame(); const log_RBOH old = _RBOH; _RBOH.quality = quality; _RBOH.delPos = delPos; _RBOH.delAng = delAng; _RBOH.delTime = delTime; _RBOH.timeStamp_ms = timeStamp_ms; WRITE_REPLAY_BLOCK_IFCHANGED(RBOH, _RBOH, old); } #if APM_BUILD_TYPE(APM_BUILD_Replay) /* handle frame message. This message triggers the EKF2/EKF3 updates and logging */ void AP_DAL::handle_message(const log_RFRF &msg, NavEKF2 &ekf2, NavEKF3 &ekf3) { _RFRF.core_slow = msg.core_slow; /* note that we need to handle the case of LOG_REPLAY=1 with LOG_DISARMED=0. To handle this we need to record the start of the filter */ const uint8_t frame_types = msg.frame_types; if (frame_types & uint8_t(AP_DAL::FrameType::InitialiseFilterEKF2)) { ekf2_init_done = ekf2.InitialiseFilter(); } if (frame_types & uint8_t(AP_DAL::FrameType::UpdateFilterEKF2)) { if (!ekf2_init_done) { ekf2_init_done = ekf2.InitialiseFilter(); } if (ekf2_init_done) { ekf2.UpdateFilter(); } } if (frame_types & uint8_t(AP_DAL::FrameType::InitialiseFilterEKF3)) { ekf3_init_done = ekf3.InitialiseFilter(); } if (frame_types & uint8_t(AP_DAL::FrameType::UpdateFilterEKF3)) { if (!ekf3_init_done) { ekf3_init_done = ekf3.InitialiseFilter(); } if (ekf3_init_done) { ekf3.UpdateFilter(); } } if (frame_types & uint8_t(AP_DAL::FrameType::LogWriteEKF2)) { ekf2.Log_Write(); } if (frame_types & uint8_t(AP_DAL::FrameType::LogWriteEKF3)) { ekf3.Log_Write(); } } /* handle optical flow message */ void AP_DAL::handle_message(const log_ROFH &msg, NavEKF2 &ekf2, NavEKF3 &ekf3) { _ROFH = msg; ekf2.writeOptFlowMeas(msg.rawFlowQuality, msg.rawFlowRates, msg.rawGyroRates, msg.msecFlowMeas, msg.posOffset); ekf3.writeOptFlowMeas(msg.rawFlowQuality, msg.rawFlowRates, msg.rawGyroRates, msg.msecFlowMeas, msg.posOffset); } /* handle external position data */ void AP_DAL::handle_message(const log_REPH &msg, NavEKF2 &ekf2, NavEKF3 &ekf3) { _REPH = msg; ekf2.writeExtNavData(msg.pos, msg.quat, msg.posErr, msg.angErr, msg.timeStamp_ms, msg.delay_ms, msg.resetTime_ms); ekf3.writeExtNavData(msg.pos, msg.quat, msg.posErr, msg.angErr, msg.timeStamp_ms, msg.delay_ms, msg.resetTime_ms); } /* handle external velocity data */ void AP_DAL::handle_message(const log_REVH &msg, NavEKF2 &ekf2, NavEKF3 &ekf3) { _REVH = msg; ekf2.writeExtNavVelData(msg.vel, msg.err, msg.timeStamp_ms, msg.delay_ms); ekf3.writeExtNavVelData(msg.vel, msg.err, msg.timeStamp_ms, msg.delay_ms); } /* handle wheel odomotry data */ void AP_DAL::handle_message(const log_RWOH &msg, NavEKF2 &ekf2, NavEKF3 &ekf3) { _RWOH = msg; // note that EKF2 does not support wheel odomotry ekf3.writeWheelOdom(msg.delAng, msg.delTime, msg.timeStamp_ms, msg.posOffset, msg.radius); } /* handle body frame odomotry */ void AP_DAL::handle_message(const log_RBOH &msg, NavEKF2 &ekf2, NavEKF3 &ekf3) { _RBOH = msg; // note that EKF2 does not support body frame odomotry ekf3.writeBodyFrameOdom(msg.quality, msg.delPos, msg.delAng, msg.delTime, msg.timeStamp_ms, msg.delay_ms, msg.posOffset); } #endif // APM_BUILD_Replay namespace AP { AP_DAL &dal() { return *AP_DAL::get_singleton(); } }; /* replay printf. To debug replay failures add rprintf() calls into EKF2/EKF3 and compare /tmp/replay.log to /tmp/real.log */ void rprintf(const char *format, ...) { #if (APM_BUILD_TYPE(APM_BUILD_Replay) || CONFIG_HAL_BOARD == HAL_BOARD_SITL) && CONFIG_HAL_BOARD != HAL_BOARD_CHIBIOS #if APM_BUILD_TYPE(APM_BUILD_Replay) const char *fname = "/tmp/replay.log"; #elif CONFIG_HAL_BOARD == HAL_BOARD_SITL const char *fname = "/tmp/real.log"; #endif static FILE *f; if (!f) { f = ::fopen(fname, "w"); } va_list ap; va_start(ap, format); vfprintf(f, format, ap); fflush(f); va_end(ap); #endif }