#pragma once #include "AC_Fence_config.h" #if AP_FENCE_ENABLED #include #include #include #include #include // bit masks for enabled fence types. Used for TYPE parameter #define AC_FENCE_TYPE_ALT_MAX 1 // high alt fence which usually initiates an RTL #define AC_FENCE_TYPE_CIRCLE 2 // circular horizontal fence (usually initiates an RTL) #define AC_FENCE_TYPE_POLYGON 4 // polygon horizontal fence #define AC_FENCE_TYPE_ALT_MIN 8 // low alt fence which usually initiates an RTL // valid actions should a fence be breached #define AC_FENCE_ACTION_REPORT_ONLY 0 // report to GCS that boundary has been breached but take no further action #define AC_FENCE_ACTION_RTL_AND_LAND 1 // return to launch and, if that fails, land #define AC_FENCE_ACTION_ALWAYS_LAND 2 // always land #define AC_FENCE_ACTION_SMART_RTL 3 // smartRTL, if that fails, RTL, it that still fails, land #define AC_FENCE_ACTION_BRAKE 4 // brake, if that fails, land #define AC_FENCE_ACTION_SMART_RTL_OR_LAND 5 // SmartRTL, if that fails, Land #define AC_FENCE_ACTION_GUIDED 6 // guided mode, with target waypoint as fence return point #define AC_FENCE_ACTION_GUIDED_THROTTLE_PASS 7 // guided mode, but pilot retains manual throttle control // give up distance #define AC_FENCE_GIVE_UP_DISTANCE 100.0f // distance outside the fence at which we should give up and just land. Note: this is not used by library directly but is intended to be used by the main code class AC_Fence { public: friend class AC_PolyFence_loader; enum class AutoEnable { ALWAYS_DISABLED = 0, ALWAYS_ENABLED = 1, ENABLE_DISABLE_FLOOR_ONLY = 2, ONLY_WHEN_ARMED = 3 }; AC_Fence(); /* Do not allow copies */ CLASS_NO_COPY(AC_Fence); void init() { _poly_loader.init(); } // get singleton instance static AC_Fence *get_singleton() { return _singleton; } /// enable - allows fence to be enabled/disabled. void enable(bool value); /// auto_enabled - automaticaly enable/disable fence depending of flight status AutoEnable auto_enabled() { return static_cast(_auto_enabled.get()); } /// enable_floor - allows fence floor to be enabled/disabled. Note this does not update the eeprom saved value void enable_floor(); /// disable_floor - allows fence floor to be enabled/disabled. Note this does not update the eeprom saved value void disable_floor(); /// auto_enable_fence_on_takeoff - auto enables the fence. Called after takeoff conditions met void auto_enable_fence_after_takeoff(); /// auto_disable_fence_for_landing - auto disables respective fence. Called prior to landing. void auto_disable_fence_for_landing(); /// enabled - returns true if fence is enabled bool enabled() const { return _enabled; } /// present - returns true if fence is present bool present() const; /// get_enabled_fences - returns bitmask of enabled fences uint8_t get_enabled_fences() const; // should be called @10Hz to handle loading from eeprom void update() { _poly_loader.update(); } /// pre_arm_check - returns true if all pre-takeoff checks have completed successfully bool pre_arm_check(const char* &fail_msg) const; /// /// methods to check we are within the boundaries and recover /// /// check - returns the fence type that has been breached (if any) uint8_t check(); // returns true if the destination is within fence (used to reject waypoints outside the fence) bool check_destination_within_fence(const class Location& loc); /// get_breaches - returns bit mask of the fence types that have been breached uint8_t get_breaches() const { return _breached_fences; } /// get_breach_time - returns time the fence was breached uint32_t get_breach_time() const { return _breach_time; } /// get_breach_count - returns number of times we have breached the fence uint16_t get_breach_count() const { return _breach_count; } /// get_breach_distance - returns maximum distance in meters outside /// of the given fences. fence_type is a bitmask here. float get_breach_distance(uint8_t fence_type) const; /// get_action - getter for user requested action on limit breach uint8_t get_action() const { return _action.get(); } /// get_safe_alt - returns maximum safe altitude (i.e. alt_max - margin) float get_safe_alt_max() const { return _alt_max - _margin; } /// get_safe_alt_min - returns the minimum safe altitude (i.e. alt_min + margin) float get_safe_alt_min() const { return _alt_min + _margin; } /// get_radius - returns the fence radius in meters float get_radius() const { return _circle_radius.get(); } /// get_margin - returns the fence margin in meters float get_margin() const { return _margin.get(); } /// get_return_rally - returns whether returning to fence return point or rally point uint8_t get_return_rally() const { return _ret_rally; } /// get_return_rally - returns whether returning to fence return point or rally point float get_return_altitude() const { return _ret_altitude; } /// manual_recovery_start - caller indicates that pilot is re-taking manual control so fence should be disabled for 10 seconds /// should be called whenever the pilot changes the flight mode /// has no effect if no breaches have occurred void manual_recovery_start(); // methods for mavlink SYS_STATUS message (send_sys_status) bool sys_status_present() const; bool sys_status_enabled() const; bool sys_status_failed() const; AC_PolyFence_loader &polyfence(); const AC_PolyFence_loader &polyfence() const; enum class OPTIONS { DISABLE_MODE_CHANGE = 1U << 0, INCLUSION_UNION = 1U << 1, }; static bool option_enabled(OPTIONS opt, const AP_Int16 &options) { return (options.get() & int16_t(opt)) != 0; } bool option_enabled(OPTIONS opt) const { return option_enabled(opt, _options); } static const struct AP_Param::GroupInfo var_info[]; #if AP_SDCARD_STORAGE_ENABLED bool failed_sdcard_storage(void) const { return _poly_loader.failed_sdcard_storage(); } #endif private: static AC_Fence *_singleton; /// check_fence_alt_max - true if max alt fence has been newly breached bool check_fence_alt_max(); /// check_fence_alt_min - true if min alt fence has been newly breached bool check_fence_alt_min(); /// check_fence_polygon - true if polygon fence has been newly breached bool check_fence_polygon(); /// check_fence_circle - true if circle fence has been newly breached bool check_fence_circle(); /// record_breach - update breach bitmask, time and count void record_breach(uint8_t fence_type); /// clear_breach - update breach bitmask, time and count void clear_breach(uint8_t fence_type); // additional checks for the different fence types: bool pre_arm_check_polygon(const char* &fail_msg) const; bool pre_arm_check_circle(const char* &fail_msg) const; bool pre_arm_check_alt(const char* &fail_msg) const; // parameters AP_Int8 _enabled; // fence enable/disable control AP_Int8 _auto_enabled; // top level flag for auto enabling fence AP_Int8 _enabled_fences; // bit mask holding which fences are enabled AP_Int8 _action; // recovery action specified by user AP_Float _alt_max; // altitude upper limit in meters AP_Float _alt_min; // altitude lower limit in meters AP_Float _circle_radius; // circle fence radius in meters AP_Float _margin; // distance in meters that autopilot's should maintain from the fence to avoid a breach AP_Int8 _total; // number of polygon points saved in eeprom AP_Int8 _ret_rally; // return to fence return point or rally point/home AP_Int16 _ret_altitude; // return to this altitude AP_Int16 _options; // options bitmask, see OPTIONS enum // backup fences float _alt_max_backup; // backup altitude upper limit in meters used to refire the breach if the vehicle continues to move further away float _alt_min_backup; // backup altitude lower limit in meters used to refire the breach if the vehicle continues to move further away float _circle_radius_backup; // backup circle fence radius in meters used to refire the breach if the vehicle continues to move further away // breach distances float _alt_max_breach_distance; // distance above the altitude max float _alt_min_breach_distance; // distance below the altitude min float _circle_breach_distance; // distance beyond the circular fence // other internal variables bool _floor_enabled; // fence floor is enabled float _home_distance; // distance from home in meters (provided by main code) float _curr_alt; // breach information uint8_t _breached_fences; // bitmask holding the fence type that was breached (i.e. AC_FENCE_TYPE_ALT_MIN, AC_FENCE_TYPE_CIRCLE) uint32_t _breach_time; // time of last breach in milliseconds uint16_t _breach_count; // number of times we have breached the fence uint32_t _last_breach_notify_sent_ms; // last time we sent a message about newly-breaching the fences uint32_t _manual_recovery_start_ms; // system time in milliseconds that pilot re-took manual control AC_PolyFence_loader _poly_loader{_total, _options}; // polygon fence }; namespace AP { AC_Fence *fence(); }; #endif // AP_FENCE_ENABLED