#include "AP_Camera.h" #if AP_CAMERA_ENABLED #include #include #include #include #include #include #include #include #include "AP_Camera_Backend.h" #include "AP_Camera_Servo.h" #include "AP_Camera_Relay.h" #include "AP_Camera_SoloGimbal.h" #include "AP_Camera_Mount.h" #include "AP_Camera_MAVLink.h" #include "AP_Camera_MAVLinkCamV2.h" const AP_Param::GroupInfo AP_Camera::var_info[] = { // @Param: _MAX_ROLL // @DisplayName: Maximum photo roll angle. // @Description: Postpone shooting if roll is greater than limit. (0=Disable, will shoot regardless of roll). // @User: Standard // @Units: deg // @Range: 0 180 AP_GROUPINFO("_MAX_ROLL", 7, AP_Camera, _max_roll, 0), // @Param: _AUTO_ONLY // @DisplayName: Distance-trigging in AUTO mode only // @Description: When enabled, trigging by distance is done in AUTO mode only. // @Values: 0:Always,1:Only when in AUTO // @User: Standard AP_GROUPINFO("_AUTO_ONLY", 10, AP_Camera, _auto_mode_only, 0), // @Group: 1 // @Path: AP_Camera_Params.cpp AP_SUBGROUPINFO(_params[0], "1", 12, AP_Camera, AP_Camera_Params), #if AP_CAMERA_MAX_INSTANCES > 1 // @Group: 2 // @Path: AP_Camera_Params.cpp AP_SUBGROUPINFO(_params[1], "2", 13, AP_Camera, AP_Camera_Params), #endif AP_GROUPEND }; extern const AP_HAL::HAL& hal; AP_Camera::AP_Camera(uint32_t _log_camera_bit) : log_camera_bit(_log_camera_bit) { AP_Param::setup_object_defaults(this, var_info); _singleton = this; } // set camera trigger distance in a mission void AP_Camera::set_trigger_distance(float distance_m) { if (primary == nullptr) { return; } primary->set_trigger_distance(distance_m); } // momentary switch to change camera between picture and video modes void AP_Camera::cam_mode_toggle() { if (primary == nullptr) { return; } primary->cam_mode_toggle(); } // take a picture void AP_Camera::take_picture() { if (primary == nullptr) { return; } primary->take_picture(); } // start/stop recording video // start_recording should be true to start recording, false to stop recording bool AP_Camera::record_video(bool start_recording) { if (primary == nullptr) { return false; } return primary->record_video(start_recording); } // zoom in, out or hold // zoom out = -1, hold = 0, zoom in = 1 bool AP_Camera::set_zoom_step(int8_t zoom_step) { if (primary == nullptr) { return false; } return primary->set_zoom_step(zoom_step); } // focus in, out or hold // focus in = -1, focus hold = 0, focus out = 1 bool AP_Camera::set_manual_focus_step(int8_t focus_step) { if (primary == nullptr) { return false; } return primary->set_manual_focus_step(focus_step); } // auto focus bool AP_Camera::set_auto_focus() { if (primary == nullptr) { return false; } return primary->set_auto_focus(); } // detect and initialise backends void AP_Camera::init() { // check init has not been called before if (primary != nullptr) { return; } // perform any required parameter conversion convert_params(); // create each instance for (uint8_t instance = 0; instance < AP_CAMERA_MAX_INSTANCES; instance++) { switch ((CameraType)_params[instance].type.get()) { #if AP_CAMERA_SERVO_ENABLED case CameraType::SERVO: _backends[instance] = new AP_Camera_Servo(*this, _params[instance], instance); break; #endif #if AP_CAMERA_RELAY_ENABLED case CameraType::RELAY: _backends[instance] = new AP_Camera_Relay(*this, _params[instance], instance); break; #endif #if AP_CAMERA_SOLOGIMBAL_ENABLED // check for GoPro in Solo camera case CameraType::SOLOGIMBAL: _backends[instance] = new AP_Camera_SoloGimbal(*this, _params[instance], instance); break; #endif #if AP_CAMERA_MOUNT_ENABLED // check for Mount camera case CameraType::MOUNT: _backends[instance] = new AP_Camera_Mount(*this, _params[instance], instance); break; #endif #if AP_CAMERA_MAVLINK_ENABLED // check for MAVLink enabled camera driver case CameraType::MAVLINK: _backends[instance] = new AP_Camera_MAVLink(*this, _params[instance], instance); break; #endif #if AP_CAMERA_MAVLINKCAMV2_ENABLED // check for MAVLink Camv2 driver case CameraType::MAVLINK_CAMV2: _backends[instance] = new AP_Camera_MAVLinkCamV2(*this, _params[instance], instance); break; #endif case CameraType::NONE: break; } // set primary to first non-null instance if (primary == nullptr) { primary = _backends[instance]; } } // init each instance, do it after all instances were created, so that they all know things for (uint8_t instance = 0; instance < AP_CAMERA_MAX_INSTANCES; instance++) { if (_backends[instance] != nullptr) { _backends[instance]->init(); } } } // handle incoming mavlink messages void AP_Camera::handle_message(mavlink_channel_t chan, const mavlink_message_t &msg) { if (msg.msgid == MAVLINK_MSG_ID_DIGICAM_CONTROL) { // decode deprecated MavLink message that controls camera. __mavlink_digicam_control_t packet; mavlink_msg_digicam_control_decode(&msg, &packet); control(packet.session, packet.zoom_pos, packet.zoom_step, packet.focus_lock, packet.shot, packet.command_id); return; } // call each instance for (uint8_t instance = 0; instance < AP_CAMERA_MAX_INSTANCES; instance++) { if (_backends[instance] != nullptr) { _backends[instance]->handle_message(chan, msg); } } } // handle command_long mavlink messages MAV_RESULT AP_Camera::handle_command_long(const mavlink_command_long_t &packet) { switch (packet.command) { case MAV_CMD_DO_DIGICAM_CONFIGURE: configure(packet.param1, packet.param2, packet.param3, packet.param4, packet.param5, packet.param6, packet.param7); return MAV_RESULT_ACCEPTED; case MAV_CMD_DO_DIGICAM_CONTROL: control(packet.param1, packet.param2, packet.param3, packet.param4, packet.param5, packet.param6); return MAV_RESULT_ACCEPTED; case MAV_CMD_DO_SET_CAM_TRIGG_DIST: set_trigger_distance(packet.param1); if (is_equal(packet.param3, 1.0f)) { take_picture(); } return MAV_RESULT_ACCEPTED; case MAV_CMD_SET_CAMERA_ZOOM: if (is_equal(packet.param1, (float)ZOOM_TYPE_CONTINUOUS)) { set_zoom_step((int8_t)packet.param2); return MAV_RESULT_ACCEPTED; } return MAV_RESULT_UNSUPPORTED; case MAV_CMD_SET_CAMERA_FOCUS: // accept any of the auto focus types if (is_equal(packet.param1, (float)FOCUS_TYPE_AUTO) || is_equal(packet.param1, (float)FOCUS_TYPE_AUTO_SINGLE) || is_equal(packet.param1, (float)FOCUS_TYPE_AUTO_CONTINUOUS)) { set_auto_focus(); return MAV_RESULT_ACCEPTED; } // accept step or continuous manual focus if (is_equal(packet.param1, (float)FOCUS_TYPE_CONTINUOUS)) { set_manual_focus_step((int8_t)packet.param2); return MAV_RESULT_ACCEPTED; } return MAV_RESULT_UNSUPPORTED; case MAV_CMD_IMAGE_START_CAPTURE: if (!is_zero(packet.param2) || !is_equal(packet.param3, 1.0f) || !is_zero(packet.param4)) { // time interval is not supported // multiple image capture is not supported // capture sequence number is not supported return MAV_RESULT_UNSUPPORTED; } take_picture(); return MAV_RESULT_ACCEPTED; case MAV_CMD_VIDEO_START_CAPTURE: case MAV_CMD_VIDEO_STOP_CAPTURE: { bool success = false; const bool start_recording = (packet.command == MAV_CMD_VIDEO_START_CAPTURE); const uint8_t stream_id = packet.param1; // Stream ID if (stream_id == 0) { // stream id of 0 interpreted as primary camera success = record_video(start_recording); } else { // convert stream id to instance id success = record_video(stream_id - 1, start_recording); } if (success) { return MAV_RESULT_ACCEPTED; } else { return MAV_RESULT_FAILED; } } default: return MAV_RESULT_UNSUPPORTED; } } // set camera trigger distance in a mission void AP_Camera::set_trigger_distance(uint8_t instance, float distance_m) { auto *backend = get_instance(instance); if (backend == nullptr) { return; } // call backend backend->set_trigger_distance(distance_m); } // momentary switch to change camera between picture and video modes void AP_Camera::cam_mode_toggle(uint8_t instance) { auto *backend = get_instance(instance); if (backend == nullptr) { return; } // call backend backend->cam_mode_toggle(); } // configure camera void AP_Camera::configure(float shooting_mode, float shutter_speed, float aperture, float ISO, float exposure_type, float cmd_id, float engine_cutoff_time) { if (primary == nullptr) { return; } primary->configure(shooting_mode, shutter_speed, aperture, ISO, exposure_type, cmd_id, engine_cutoff_time); } void AP_Camera::configure(uint8_t instance, float shooting_mode, float shutter_speed, float aperture, float ISO, float exposure_type, float cmd_id, float engine_cutoff_time) { auto *backend = get_instance(instance); if (backend == nullptr) { return; } // call backend backend->configure(shooting_mode, shutter_speed, aperture, ISO, exposure_type, cmd_id, engine_cutoff_time); } // handle camera control void AP_Camera::control(float session, float zoom_pos, float zoom_step, float focus_lock, float shooting_cmd, float cmd_id) { if (primary == nullptr) { return; } primary->control(session, zoom_pos, zoom_step, focus_lock, shooting_cmd, cmd_id); } void AP_Camera::control(uint8_t instance, float session, float zoom_pos, float zoom_step, float focus_lock, float shooting_cmd, float cmd_id) { auto *backend = get_instance(instance); if (backend == nullptr) { return; } // call backend backend->control(session, zoom_pos, zoom_step, focus_lock, shooting_cmd, cmd_id); } /* Send camera feedback to the GCS */ void AP_Camera::send_feedback(mavlink_channel_t chan) const { // call each instance for (uint8_t instance = 0; instance < AP_CAMERA_MAX_INSTANCES; instance++) { if (_backends[instance] != nullptr) { _backends[instance]->send_camera_feedback(chan); } } } /* update; triggers by distance moved and camera trigger */ void AP_Camera::update() { // call each instance for (uint8_t instance = 0; instance < AP_CAMERA_MAX_INSTANCES; instance++) { if (_backends[instance] != nullptr) { _backends[instance]->update(); } } } // take_picture - take a picture void AP_Camera::take_picture(uint8_t instance) { auto *backend = get_instance(instance); if (backend == nullptr) { return; } // call backend backend->take_picture(); } // start/stop recording video. returns true on success // start_recording should be true to start recording, false to stop recording bool AP_Camera::record_video(uint8_t instance, bool start_recording) { auto *backend = get_instance(instance); if (backend == nullptr) { return false; } // call backend return backend->record_video(start_recording); } // zoom in, out or hold. returns true on success // zoom out = -1, hold = 0, zoom in = 1 bool AP_Camera::set_zoom_step(uint8_t instance, int8_t zoom_step) { auto *backend = get_instance(instance); if (backend == nullptr) { return false; } // call each instance return backend->set_zoom_step(zoom_step); } // focus in, out or hold. returns true on success // focus in = -1, focus hold = 0, focus out = 1 bool AP_Camera::set_manual_focus_step(uint8_t instance, int8_t focus_step) { auto *backend = get_instance(instance); if (backend == nullptr) { return false; } // call backend return backend->set_manual_focus_step(focus_step); } // auto focus. returns true on success bool AP_Camera::set_auto_focus(uint8_t instance) { auto *backend = get_instance(instance); if (backend == nullptr) { return false; } // call backend return backend->set_auto_focus(); } // return backend for instance number AP_Camera_Backend *AP_Camera::get_instance(uint8_t instance) { if (instance >= ARRAY_SIZE(_backends)) { return nullptr; } return _backends[instance]; } // perform any required parameter conversion void AP_Camera::convert_params() { // exit immediately if CAM1_TYPE has already been configured if (_params[0].type.configured()) { return; } // below conversions added Feb 2023 ahead of 4.4 release // convert CAM_TRIGG_TYPE to CAM1_TYPE int8_t cam_trigg_type = 0; int8_t cam1_type = 0; IGNORE_RETURN(AP_Param::get_param_by_index(this, 0, AP_PARAM_INT8, &cam_trigg_type)); if ((cam_trigg_type == 0) && SRV_Channels::function_assigned(SRV_Channel::k_cam_trigger)) { // CAM_TRIGG_TYPE was 0 (Servo) and camera trigger servo function was assigned so set CAM1_TYPE = 1 (Servo) cam1_type = 1; } if ((cam_trigg_type >= 1) && (cam_trigg_type <= 3)) { // CAM_TRIGG_TYPE was set to Relay, GoPro or Mount cam1_type = cam_trigg_type + 1; } _params[0].type.set_and_save(cam1_type); // convert CAM_DURATION (in deci-seconds) to CAM1_DURATION (in seconds) int8_t cam_duration = 0; if (AP_Param::get_param_by_index(this, 1, AP_PARAM_INT8, &cam_duration) && (cam_duration > 0)) { _params[0].trigger_duration.set_and_save(cam_duration * 0.1); } // convert CAM_MIN_INTERVAL (in milliseconds) to CAM1__INTRVAL_MIN (in seconds) int16_t cam_min_interval = 0; if (AP_Param::get_param_by_index(this, 6, AP_PARAM_INT16, &cam_min_interval) && (cam_min_interval > 0)) { _params[0].interval_min.set_and_save(cam_min_interval * 0.001f); } // find Camera's top level key uint16_t k_param_camera_key; if (!AP_Param::find_top_level_key_by_pointer(this, k_param_camera_key)) { return; } // table parameters to convert without scaling static const AP_Param::ConversionInfo camera_param_conversion_info[] { { k_param_camera_key, 2, AP_PARAM_INT16, "CAM1_SERVO_ON" }, { k_param_camera_key, 3, AP_PARAM_INT16, "CAM1_SERVO_OFF" }, { k_param_camera_key, 4, AP_PARAM_FLOAT, "CAM1_TRIGG_DIST" }, { k_param_camera_key, 5, AP_PARAM_INT8, "CAM1_RELAY_ON" }, { k_param_camera_key, 8, AP_PARAM_INT8, "CAM1_FEEDBAK_PIN" }, { k_param_camera_key, 9, AP_PARAM_INT8, "CAM1_FEEDBAK_POL" }, }; uint8_t table_size = ARRAY_SIZE(camera_param_conversion_info); for (uint8_t i=0; i