/* 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 . */ #pragma once #include "AP_RangeFinder_config.h" #include #include #include #include #include #include #include "AP_RangeFinder_Params.h" // Maximum number of range finder instances available on this platform #ifndef RANGEFINDER_MAX_INSTANCES #if AP_RANGEFINDER_ENABLED #define RANGEFINDER_MAX_INSTANCES 10 #else #define RANGEFINDER_MAX_INSTANCES 1 #endif #endif #define RANGEFINDER_GROUND_CLEARANCE_CM_DEFAULT 10 #define RANGEFINDER_PREARM_ALT_MAX_CM 200 #if CONFIG_HAL_BOARD == HAL_BOARD_SITL #define RANGEFINDER_PREARM_REQUIRED_CHANGE_CM 0 #else #define RANGEFINDER_PREARM_REQUIRED_CHANGE_CM 50 #endif class AP_RangeFinder_Backend; class RangeFinder { friend class AP_RangeFinder_Backend; //UAVCAN drivers are initialised in the Backend, hence list of drivers is needed there. friend class AP_RangeFinder_DroneCAN; public: RangeFinder(); /* Do not allow copies */ CLASS_NO_COPY(RangeFinder); // RangeFinder driver types enum class Type { NONE = 0, #if AP_RANGEFINDER_ANALOG_ENABLED ANALOG = 1, #endif #if AP_RANGEFINDER_MAXSONARI2CXL_ENABLED MBI2C = 2, #endif #if AP_RANGEFINDER_PULSEDLIGHTLRF_ENABLED PLI2C = 3, #endif // PX4 = 4, // no longer used, but may be in some user's parameters #if AP_RANGEFINDER_PWM_ENABLED PX4_PWM= 5, #endif #if AP_RANGEFINDER_BBB_PRU_ENABLED BBB_PRU= 6, #endif #if AP_RANGEFINDER_LWI2C_ENABLED LWI2C = 7, #endif #if AP_RANGEFINDER_LIGHTWARE_SERIAL_ENABLED LWSER = 8, #endif #if AP_RANGEFINDER_BEBOP_ENABLED BEBOP = 9, #endif #if AP_RANGEFINDER_MAVLINK_ENABLED MAVLink = 10, #endif #if AP_RANGEFINDER_USD1_SERIAL_ENABLED USD1_Serial = 11, #endif #if AP_RANGEFINDER_LEDDARONE_ENABLED LEDDARONE = 12, #endif #if AP_RANGEFINDER_MAXBOTIX_SERIAL_ENABLED MBSER = 13, #endif #if AP_RANGEFINDER_TRI2C_ENABLED TRI2C = 14, #endif #if AP_RANGEFINDER_PULSEDLIGHTLRF_ENABLED PLI2CV3= 15, #endif VL53L0X = 16, #if AP_RANGEFINDER_NMEA_ENABLED NMEA = 17, #endif #if AP_RANGEFINDER_WASP_ENABLED WASP = 18, #endif #if AP_RANGEFINDER_BENEWAKE_TF02_ENABLED BenewakeTF02 = 19, #endif #if AP_RANGEFINDER_BENEWAKE_TFMINI_ENABLED BenewakeTFmini = 20, #endif #if AP_RANGEFINDER_PULSEDLIGHTLRF_ENABLED PLI2CV3HP = 21, #endif #if AP_RANGEFINDER_PWM_ENABLED PWM = 22, #endif #if AP_RANGEFINDER_BLPING_ENABLED BLPing = 23, #endif #if AP_RANGEFINDER_DRONECAN_ENABLED UAVCAN = 24, #endif #if AP_RANGEFINDER_BENEWAKE_TFMINIPLUS_ENABLED BenewakeTFminiPlus = 25, #endif #if AP_RANGEFINDER_LANBAO_ENABLED Lanbao = 26, #endif #if AP_RANGEFINDER_BENEWAKE_TF03_ENABLED BenewakeTF03 = 27, #endif VL53L1X_Short = 28, #if AP_RANGEFINDER_LEDDARVU8_ENABLED LeddarVu8_Serial = 29, #endif #if AP_RANGEFINDER_HC_SR04_ENABLED HC_SR04 = 30, #endif #if AP_RANGEFINDER_GYUS42V2_ENABLED GYUS42v2 = 31, #endif #if HAL_MSP_RANGEFINDER_ENABLED MSP = 32, #endif #if AP_RANGEFINDER_USD1_CAN_ENABLED USD1_CAN = 33, #endif #if AP_RANGEFINDER_BENEWAKE_CAN_ENABLED Benewake_CAN = 34, #endif #if AP_RANGEFINDER_TERARANGER_SERIAL_ENABLED TeraRanger_Serial = 35, #endif #if AP_RANGEFINDER_LUA_ENABLED Lua_Scripting = 36, #endif #if AP_RANGEFINDER_NOOPLOOP_ENABLED NoopLoop_P = 37, #endif #if AP_RANGEFINDER_TOFSENSEP_CAN_ENABLED TOFSenseP_CAN = 38, #endif #if AP_RANGEFINDER_NRA24_CAN_ENABLED NRA24_CAN = 39, #endif #if AP_RANGEFINDER_TOFSENSEF_I2C_ENABLED TOFSenseF_I2C = 40, #endif #if AP_RANGEFINDER_JRE_SERIAL_ENABLED JRE_Serial = 41, #endif #if AP_RANGEFINDER_AINSTEIN_LR_D1_ENABLED Ainstein_LR_D1 = 42, #endif #if AP_RANGEFINDER_SIM_ENABLED SIM = 100, #endif }; enum class Function { LINEAR = 0, INVERTED = 1, HYPERBOLA = 2 }; enum class Status { NotConnected = 0, NoData, OutOfRangeLow, OutOfRangeHigh, Good }; static constexpr int8_t SIGNAL_QUALITY_MIN = 0; static constexpr int8_t SIGNAL_QUALITY_MAX = 100; static constexpr int8_t SIGNAL_QUALITY_UNKNOWN = -1; // The RangeFinder_State structure is filled in by the backend driver struct RangeFinder_State { float distance_m; // distance in meters int8_t signal_quality_pct; // measurement quality in percent 0-100, -1 -> quality is unknown uint16_t voltage_mv; // voltage in millivolts, if applicable, otherwise 0 enum RangeFinder::Status status; // sensor status uint8_t range_valid_count; // number of consecutive valid readings (maxes out at 10) uint32_t last_reading_ms; // system time of last successful update from sensor const struct AP_Param::GroupInfo *var_info; }; static const struct AP_Param::GroupInfo *backend_var_info[RANGEFINDER_MAX_INSTANCES]; // parameters for each instance static const struct AP_Param::GroupInfo var_info[]; void set_log_rfnd_bit(uint32_t log_rfnd_bit) { _log_rfnd_bit = log_rfnd_bit; } /* Return the number of range finder instances. Note that if users sets up rangefinders with a gap in the types then this is the index of the maximum sensor ID plus one, so this gives the value that should be used when iterating over all sensors */ uint8_t num_sensors(void) const { return num_instances; } // prearm checks bool prearm_healthy(char *failure_msg, const uint8_t failure_msg_len) const; // detect and initialise any available rangefinders void init(enum Rotation orientation_default); // update state of all rangefinders. Should be called at around // 10Hz from main loop void update(void); // Handle an incoming DISTANCE_SENSOR message (from a MAVLink enabled range finder) void handle_msg(const mavlink_message_t &msg); #if HAL_MSP_RANGEFINDER_ENABLED // Handle an incoming DISTANCE_SENSOR message (from a MSP enabled range finder) void handle_msp(const MSP::msp_rangefinder_data_message_t &pkt); #endif // return true if we have a range finder with the specified orientation bool has_orientation(enum Rotation orientation) const; // find first range finder instance with the specified orientation AP_RangeFinder_Backend *find_instance(enum Rotation orientation) const; AP_RangeFinder_Backend *get_backend(uint8_t id) const; // get rangefinder type for an ID Type get_type(uint8_t id) const { return id >= RANGEFINDER_MAX_INSTANCES? Type::NONE : Type(params[id].type.get()); } // get rangefinder address (for AP_Periph CAN) uint8_t get_address(uint8_t id) const { return id >= RANGEFINDER_MAX_INSTANCES? 0 : uint8_t(params[id].address.get()); } // methods to return a distance on a particular orientation from // any sensor which can current supply it float distance_orient(enum Rotation orientation) const; uint16_t distance_cm_orient(enum Rotation orientation) const; int8_t signal_quality_pct_orient(enum Rotation orientation) const; int16_t max_distance_cm_orient(enum Rotation orientation) const; int16_t min_distance_cm_orient(enum Rotation orientation) const; int16_t ground_clearance_cm_orient(enum Rotation orientation) const; MAV_DISTANCE_SENSOR get_mav_distance_sensor_type_orient(enum Rotation orientation) const; RangeFinder::Status status_orient(enum Rotation orientation) const; bool has_data_orient(enum Rotation orientation) const; uint8_t range_valid_count_orient(enum Rotation orientation) const; const Vector3f &get_pos_offset_orient(enum Rotation orientation) const; uint32_t last_reading_ms(enum Rotation orientation) const; // get temperature reading in C. returns true on success and populates temp argument bool get_temp(enum Rotation orientation, float &temp) const; /* set an externally estimated terrain height. Used to enable power saving (where available) at high altitudes. */ void set_estimated_terrain_height(float height) { estimated_terrain_height = height; } static RangeFinder *get_singleton(void) { return _singleton; } protected: AP_RangeFinder_Params params[RANGEFINDER_MAX_INSTANCES]; private: static RangeFinder *_singleton; RangeFinder_State state[RANGEFINDER_MAX_INSTANCES]; AP_RangeFinder_Backend *drivers[RANGEFINDER_MAX_INSTANCES]; uint8_t num_instances; HAL_Semaphore detect_sem; float estimated_terrain_height; Vector3f pos_offset_zero; // allows returning position offsets of zero for invalid requests void detect_instance(uint8_t instance, uint8_t& serial_instance); bool _add_backend(AP_RangeFinder_Backend *driver, uint8_t instance, uint8_t serial_instance=0); uint32_t _log_rfnd_bit = -1; void Log_RFND() const; }; namespace AP { RangeFinder *rangefinder(); };