// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*- static void init_commands() { g.command_index = NO_COMMAND; command_nav_index = NO_COMMAND; command_cond_index = NO_COMMAND; prev_nav_index = NO_COMMAND; command_cond_queue.id = NO_COMMAND; command_nav_queue.id = NO_COMMAND; } // Getters // ------- static struct Location get_cmd_with_index(int i) { struct Location temp; // Find out proper location in memory by using the start_byte position + the index // -------------------------------------------------------------------------------- if (i >= g.command_total) { // we do not have a valid command to load // return a WP with a "Blank" id temp.id = CMD_BLANK; // no reason to carry on return temp; }else{ // we can load a command, we don't process it yet // read WP position uint16_t mem = (WP_START_BYTE) + (i * WP_SIZE); temp.id = hal.storage->read_byte(mem); mem++; temp.options = hal.storage->read_byte(mem); mem++; temp.p1 = hal.storage->read_byte(mem); mem++; temp.alt = hal.storage->read_dword(mem); // alt is stored in CM! Alt is stored relative! mem += 4; temp.lat = hal.storage->read_dword(mem); // lat is stored in decimal * 10,000,000 mem += 4; temp.lng = hal.storage->read_dword(mem); // lon is stored in decimal * 10,000,000 } // Add on home altitude if we are a nav command (or other command with altitude) and stored alt is relative //if((temp.id < MAV_CMD_NAV_LAST || temp.id == MAV_CMD_CONDITION_CHANGE_ALT) && temp.options & MASK_OPTIONS_RELATIVE_ALT){ //temp.alt += home.alt; //} if(temp.options & WP_OPTION_RELATIVE) { // If were relative, just offset from home temp.lat += home.lat; temp.lng += home.lng; } return temp; } // Setters // ------- static void set_cmd_with_index(struct Location temp, int i) { i = constrain(i, 0, g.command_total.get()); //cliSerial->printf("set_command: %d with id: %d\n", i, temp.id); // store home as 0 altitude!!! // Home is always a MAV_CMD_NAV_WAYPOINT (16) if (i == 0) { temp.alt = 0; temp.id = MAV_CMD_NAV_WAYPOINT; } uint16_t mem = WP_START_BYTE + (i * WP_SIZE); hal.storage->write_byte(mem, temp.id); mem++; hal.storage->write_byte(mem, temp.options); mem++; hal.storage->write_byte(mem, temp.p1); mem++; hal.storage->write_dword(mem, temp.alt); // Alt is stored in CM! mem += 4; hal.storage->write_dword(mem, temp.lat); // Lat is stored in decimal degrees * 10^7 mem += 4; hal.storage->write_dword(mem, temp.lng); // Long is stored in decimal degrees * 10^7 // Make sure our WP_total if(g.command_total < (i+1)) g.command_total.set_and_save(i+1); } static int32_t get_RTL_alt() { if(g.rtl_altitude <= 0) { return min(current_loc.alt, RTL_ALT_MAX); }else if (g.rtl_altitude < current_loc.alt) { return min(current_loc.alt, RTL_ALT_MAX); }else{ return g.rtl_altitude; } } //******************************************************************************** // This function sets the waypoint and modes for Return to Launch // It's not currently used //******************************************************************************** /* * This function sets the next waypoint command * It precalculates all the necessary stuff. */ static void set_next_WP(struct Location *wp) { // copy the current WP into the OldWP slot // --------------------------------------- if (next_WP.lat == 0 || command_nav_index <= 1) { prev_WP = current_loc; }else{ if (get_distance_cm(¤t_loc, &next_WP) < 500) prev_WP = next_WP; else prev_WP = current_loc; } // Load the next_WP slot // --------------------- next_WP.options = wp->options; next_WP.lat = wp->lat; next_WP.lng = wp->lng; // Set new target altitude so we can track it for climb_rate // To-Do: remove the restriction on negative altitude targets (after testing) set_new_altitude(max(wp->alt,100)); // recalculate waypoint distance and bearing wp_distance = get_distance_cm(¤t_loc, &next_WP); wp_bearing = get_bearing_cd(&prev_WP, &next_WP); original_wp_bearing = wp_bearing; // to check if we have missed the WP } // set_next_WP_latlon - update just lat and lon targets for nav controllers static void set_next_WP_latlon(uint32_t lat, uint32_t lon) { // save current location as previous location prev_WP = current_loc; // Load the next_WP slot next_WP.lat = lat; next_WP.lng = lon; // recalculate waypoint distance and bearing // To-Do: these functions are too expensive to be called every time we update the next_WP wp_distance = get_distance_cm(¤t_loc, &next_WP); wp_bearing = get_bearing_cd(&prev_WP, &next_WP); original_wp_bearing = wp_bearing; // to check if we have missed the WP } // run this at setup on the ground // ------------------------------- static void init_home() { set_home_is_set(true); home.id = MAV_CMD_NAV_WAYPOINT; home.lng = g_gps->longitude; // Lon * 10**7 home.lat = g_gps->latitude; // Lat * 10**7 home.alt = 0; // Home is always 0 // Save Home to EEPROM // ------------------- // no need to save this to EPROM set_cmd_with_index(home, 0); // set inertial nav's home position inertial_nav.set_current_position(g_gps->longitude, g_gps->latitude); if (g.log_bitmask & MASK_LOG_CMD) Log_Write_Cmd(0, &home); // update navigation scalers. used to offset the shrinking longitude as we go towards the poles scaleLongDown = longitude_scale(&home); scaleLongUp = 1.0f/scaleLongDown; // Save prev loc this makes the calcs look better before commands are loaded prev_WP = home; // Load home for a default guided_WP // ------------- guided_WP = home; guided_WP.alt += g.rtl_altitude; }