// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*- /* geo-fencing support Andrew Tridgell, December 2011 */ #if GEOFENCE_ENABLED == ENABLED /* The state of geo-fencing. This structure is dynamically allocated the first time it is used. This means we only pay for the pointer and not the structure on systems where geo-fencing is not being used. We store a copy of the boundary in memory as we need to access it very quickly at runtime */ static struct geofence_state { uint8_t num_points; bool boundary_uptodate; bool fence_triggered; uint16_t breach_count; uint8_t breach_type; uint32_t breach_time; /* point 0 is the return point */ Vector2l boundary[MAX_FENCEPOINTS]; } *geofence_state; /* fence boundaries fetch/store */ static Vector2l get_fence_point_with_index(unsigned i) { uint32_t mem; Vector2l ret; if (i > (unsigned)g.fence_total) { return Vector2l(0,0); } // read fence point mem = FENCE_START_BYTE + (i * FENCE_WP_SIZE); ret.x = eeprom_read_dword((uint32_t *)mem); mem += sizeof(uint32_t); ret.y = eeprom_read_dword((uint32_t *)mem); return ret; } // save a fence point static void set_fence_point_with_index(Vector2l &point, unsigned i) { uint32_t mem; if (i >= (unsigned)g.fence_total.get()) { // not allowed return; } mem = FENCE_START_BYTE + (i * FENCE_WP_SIZE); eeprom_write_dword((uint32_t *)mem, point.x); mem += sizeof(uint32_t); eeprom_write_dword((uint32_t *)mem, point.y); if (geofence_state != NULL) { geofence_state->boundary_uptodate = false; } } /* allocate and fill the geofence state structure */ static void geofence_load(void) { uint8_t i; if (geofence_state == NULL) { if (memcheck_available_memory() < 512 + sizeof(struct geofence_state)) { // too risky to enable as we could run out of stack goto failed; } geofence_state = (struct geofence_state *)calloc(1, sizeof(struct geofence_state)); if (geofence_state == NULL) { // not much we can do here except disable it goto failed; } } for (i=0; iboundary[i] = get_fence_point_with_index(i); } geofence_state->num_points = i; if (!Polygon_complete(&geofence_state->boundary[1], geofence_state->num_points-1)) { // first point and last point must be the same goto failed; } if (Polygon_outside(geofence_state->boundary[0], &geofence_state->boundary[1], geofence_state->num_points-1)) { // return point needs to be inside the fence goto failed; } geofence_state->boundary_uptodate = true; geofence_state->fence_triggered = false; gcs_send_text_P(SEVERITY_LOW,PSTR("geo-fence loaded")); return; failed: g.fence_action.set(FENCE_ACTION_NONE); gcs_send_text_P(SEVERITY_HIGH,PSTR("geo-fence setup error")); } /* return true if geo-fencing is enabled */ static bool geofence_enabled(void) { if (g.fence_action == FENCE_ACTION_NONE || g.fence_channel == 0 || APM_RC.InputCh(g.fence_channel-1) < FENCE_ENABLE_PWM) { // geo-fencing is disabled if (geofence_state != NULL) { // re-arm for when the channel trigger is switched on geofence_state->fence_triggered = false; } return false; } if (!g_gps->fix) { // we can't do much without a GPS fix return false; } return true; } /* return true if we have breached the geo-fence minimum altiude */ static bool geofence_check_minalt(void) { if (g.fence_maxalt <= g.fence_minalt) { return false; } if (g.fence_minalt == 0) { return false; } return (current_loc.alt < (g.fence_minalt*100) + home.alt); } /* return true if we have breached the geo-fence maximum altiude */ static bool geofence_check_maxalt(void) { if (g.fence_maxalt <= g.fence_minalt) { return false; } if (g.fence_maxalt == 0) { return false; } return (current_loc.alt > (g.fence_maxalt*100) + home.alt); } /* check if we have breached the geo-fence */ static void geofence_check(bool altitude_check_only) { if (!geofence_enabled()) { return; } /* allocate the geo-fence state if need be */ if (geofence_state == NULL || !geofence_state->boundary_uptodate) { geofence_load(); if (!geofence_enabled()) { // may have been disabled by load return; } } bool outside = false; uint8_t breach_type = FENCE_BREACH_NONE; if (geofence_check_minalt()) { outside = true; breach_type = FENCE_BREACH_MINALT; } else if (geofence_check_maxalt()) { outside = true; breach_type = FENCE_BREACH_MAXALT; } else if (!altitude_check_only) { Vector2l location; location.x = current_loc.lat; location.y = current_loc.lng; outside = Polygon_outside(location, &geofence_state->boundary[1], geofence_state->num_points-1); if (outside) { breach_type = FENCE_BREACH_BOUNDARY; } } if (!outside) { if (geofence_state->fence_triggered && !altitude_check_only) { // we have moved back inside the fence geofence_state->fence_triggered = false; gcs_send_text_P(SEVERITY_LOW,PSTR("geo-fence OK")); } // we're inside, all is good with the world return; } // we are outside the fence if (geofence_state->fence_triggered) { // we have already triggered, don't trigger again until the // user disables/re-enables using the fence channel switch return; } // we are outside, and have not previously triggered. geofence_state->fence_triggered = true; geofence_state->breach_count++; geofence_state->breach_time = millis(); geofence_state->breach_type = breach_type; gcs_send_text_P(SEVERITY_LOW,PSTR("geo-fence triggered")); // see what action the user wants switch (g.fence_action) { case FENCE_ACTION_GUIDED: // fly to the return point, with an altitude half way between // min and max if (g.fence_minalt >= g.fence_maxalt) { // invalid min/max, use RTL_altitude guided_WP.alt = home.alt + (g.RTL_altitude * 100); } else { guided_WP.alt = home.alt + 100*(g.fence_minalt + g.fence_maxalt)/2; } guided_WP.id = 0; guided_WP.p1 = 0; guided_WP.options = 0; guided_WP.lat = geofence_state->boundary[0].x; guided_WP.lng = geofence_state->boundary[0].y; if (control_mode == MANUAL && g.auto_trim) { // make sure we don't auto trim the surfaces on this change control_mode = STABILIZE; } set_mode(GUIDED); break; } } /* return true if geofencing allows stick mixing. When we have triggered failsafe and are in GUIDED mode then stick mixing is disabled. Otherwise the aircraft may not be able to recover from a breach of the geo-fence */ static bool geofence_stickmixing(void) { if (geofence_enabled() && geofence_state != NULL && geofence_state->fence_triggered && control_mode == GUIDED) { // don't mix in user input return false; } // normal mixing rules return true; } /* */ static void geofence_send_status(mavlink_channel_t chan) { if (geofence_enabled() && geofence_state != NULL) { mavlink_msg_fence_status_send(chan, (int8_t)geofence_state->fence_triggered, geofence_state->breach_count, geofence_state->breach_type, geofence_state->breach_time); } } #else // GEOFENCE_ENABLED static void geofence_check(bool altitude_check_only) { } static bool geofence_stickmixing(void) { return true; } static bool geofence_enabled(void) { return false; } #endif // GEOFENCE_ENABLED