/* 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 . */ // Automatic Identification System, https://gpsd.gitlab.io/gpsd/AIVDM.html // ToDo: enable receiving of the Mavlink AIS message, type bitmask? #include "AP_AIS.h" #if HAL_AIS_ENABLED #include #include #include const AP_Param::GroupInfo AP_AIS::var_info[] = { // @Param: TYPE // @DisplayName: AIS receiver type // @Description: AIS receiver type // @Values: 0:None,1:NMEA AIVDM message // @User: Standard // @RebootRequired: True AP_GROUPINFO_FLAGS("TYPE", 1, AP_AIS, _type, 0, AP_PARAM_FLAG_ENABLE), // @Param: LIST_MAX // @DisplayName: AIS vessel list size // @Description: AIS list size of nearest vessels. Longer lists take longer to refresh with lower SRx_ADSB values. // @Range: 1 100 // @User: Advanced AP_GROUPINFO("LIST_MAX", 2, AP_AIS, _max_list, 25), // @Param: TIME_OUT // @DisplayName: AIS vessel time out // @Description: if no updates are received in this time a vessel will be removed from the list // @Units: s // @Range: 1 2000 // @User: Advanced AP_GROUPINFO("TIME_OUT", 3, AP_AIS, _time_out, 600), // @Param: LOGGING // @DisplayName: AIS logging options // @Description: Bitmask of AIS logging options // @Bitmask: 0:Log all AIVDM messages,1:Log only unsupported AIVDM messages,2:Log decoded messages // @User: Advanced AP_GROUPINFO("LOGGING", 4, AP_AIS, _log_options, AIS_OPTIONS_LOG_UNSUPPORTED_RAW | AIS_OPTIONS_LOG_DECODED), AP_GROUPEND }; // constructor AP_AIS::AP_AIS() { AP_Param::setup_object_defaults(this, var_info); } // Initialize the AIS object and prepare it for use void AP_AIS::init() { if (!enabled()) { return; } _uart = AP::serialmanager().find_serial(AP_SerialManager::SerialProtocol_AIS, 0); if (_uart == nullptr) { return; } _uart->begin(AP::serialmanager().find_baudrate(AP_SerialManager::SerialProtocol_AIS, 0)); } // update AIS, expected to be called at 20hz void AP_AIS::update() { if (!_uart || !enabled()) { return; } // read any available lines uint32_t nbytes = MIN(_uart->available(),1024U); while (nbytes-- > 0) { const int16_t byte = _uart->read(); if (byte == -1) { break; } const char c = byte; if (decode(c)) { const bool log_all = (_log_options & AIS_OPTIONS_LOG_ALL_RAW) != 0; const bool log_unsupported = ((_log_options & AIS_OPTIONS_LOG_UNSUPPORTED_RAW) != 0) && !log_all; // only log unsupported if not logging all if (_incoming.total > AIVDM_BUFFER_SIZE) { // no point in trying to decode it wont fit if (log_all || log_unsupported) { log_raw(&_incoming); } break; } if (log_all) { log_raw(&_incoming); } if (_incoming.num == 1 && _incoming.total == 1) { // single part message if (!payload_decode(_incoming.payload) && log_unsupported) { // could not decode so log log_raw(&_incoming); } } else if (_incoming.num == _incoming.total) { // last part of a multi part message uint8_t index = 0; uint8_t msg_parts[_incoming.num - 1]; for (uint8_t i = 0; i < AIVDM_BUFFER_SIZE; i++) { // look for the rest of the message from the start of the buffer // we assume the mesage has be received in the correct order if (_AIVDM_buffer[i].num == (index + 1) && _AIVDM_buffer[i].total == _incoming.total && _AIVDM_buffer[i].ID == _incoming.ID) { msg_parts[index] = i; index++; if (index >= _incoming.num) { break; } } } // did we find the right number? if (_incoming.num != index) { // could not find all of the message, save messages if (log_unsupported) { for (uint8_t i = 0; i < index; i++) { log_raw(&_AIVDM_buffer[msg_parts[i]]); } log_raw(&_incoming); } // remove for (uint8_t i = 0; i < index; i++) { buffer_shift(msg_parts[i]); } break; } // combine packets char multi[AIVDM_PAYLOAD_SIZE*_incoming.total]; strncpy(multi,_AIVDM_buffer[msg_parts[0]].payload,AIVDM_PAYLOAD_SIZE); for (uint8_t i = 1; i < _incoming.total - 1; i++) { strncat(multi,_AIVDM_buffer[msg_parts[i]].payload,sizeof(multi)); } strncat(multi,_incoming.payload,sizeof(multi)); const bool decoded = payload_decode(multi); for (uint8_t i = 0; i < _incoming.total; i++) { // unsupported type, log and discard if (!decoded && log_unsupported) { log_raw(&_AIVDM_buffer[msg_parts[i]]); } buffer_shift(msg_parts[i]); } if (!decoded && log_unsupported) { log_raw(&_incoming); } } else { // multi part message, store in buffer bool fits_in = false; for (uint8_t i = 0; i < AIVDM_BUFFER_SIZE; i++) { // find the first free spot if (_AIVDM_buffer[i].num == 0 && _AIVDM_buffer[i].total == 0 && _AIVDM_buffer[i].ID == 0) { _AIVDM_buffer[i] = _incoming; fits_in = true; break; } } if (!fits_in) { // remove the oldest message if (log_unsupported) { // log the unused message before removing it log_raw(&_AIVDM_buffer[0]); } buffer_shift(0); _AIVDM_buffer[AIVDM_BUFFER_SIZE - 1] = _incoming; } } } } // remove expired items from the list const uint32_t now = AP_HAL::millis(); const uint32_t timeout = _time_out * 1000; if (now < timeout) { return; } const uint32_t deadline = now - timeout; for (uint16_t i = 0; i < _list.max_items(); i++) { if (_list[i].last_update_ms < deadline && _list[i].last_update_ms != 0) { clear_list_item(i); } } } // Send a AIS mavlink message void AP_AIS::send(mavlink_channel_t chan) { if (!enabled()) { return; } const uint16_t list_size = _list.max_items(); const uint32_t now = AP_HAL::millis(); uint16_t search_length = 0; while (search_length < list_size) { _send_index++; search_length++; if (_send_index == list_size) { _send_index = 0; } if (_list[_send_index].last_update_ms != 0 && (_list[_send_index].last_send_ms < _list[_send_index].last_update_ms || now -_list[_send_index].last_send_ms > 30000)) { // only re-send if there has been a change or the resend time has expired _list[_send_index].last_send_ms = now; _list[_send_index].info.tslc = (now - _list[_send_index].last_update_ms) * 0.001; mavlink_msg_ais_vessel_send_struct(chan,&_list[_send_index].info); return; } } } // remove the given index from the AIVDM buffer and shift following elements up void AP_AIS::buffer_shift(uint8_t i) { for (uint8_t n = i; n < (AIVDM_BUFFER_SIZE - 1); n++) { _AIVDM_buffer[n].ID = _AIVDM_buffer[n+1].ID; _AIVDM_buffer[n].num = _AIVDM_buffer[n+1].num; _AIVDM_buffer[n].total = _AIVDM_buffer[n+1].total; strncpy(_AIVDM_buffer[n].payload,_AIVDM_buffer[n+1].payload,AIVDM_PAYLOAD_SIZE); } _AIVDM_buffer[AIVDM_BUFFER_SIZE - 1].ID = 0; _AIVDM_buffer[AIVDM_BUFFER_SIZE - 1].num = 0; _AIVDM_buffer[AIVDM_BUFFER_SIZE - 1].total = 0; _AIVDM_buffer[AIVDM_BUFFER_SIZE - 1].payload[0] = 0; } ////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// // Functions related to the vessel list // find vessel index in existing list, if not then return new index if possible bool AP_AIS::get_vessel_index(uint32_t mmsi, uint16_t &index, uint32_t lat, uint32_t lon) { const uint16_t list_size = _list.max_items(); uint16_t empty = 0; bool found_empty = false; for (uint16_t i = 0; i < list_size; i++) { if (_list[i].info.MMSI == mmsi) { index = i; return true; } if (_list[i].last_update_ms == 0 && !found_empty) { found_empty = true; empty = i; } } // got through the list without a match if (found_empty) { index = empty; _list[index].info.MMSI = mmsi; return true; } // no space in the list if (list_size < _max_list) { // if we can try and expand if (_list.expand(1)) { index = list_size; _list[index].info.MMSI = mmsi; return true; } } // could not expand list, either because of memory or max list param // if we have a valid incoming location we can bump a further item from the list if (lat == 0 && lon == 0) { return false; } struct Location current_loc; if (!AP::ahrs().get_position(current_loc)) { return false; } struct Location loc; float dist; float max_dist = 0; for (uint16_t i = 0; i < list_size; i++) { loc.lat = _list[i].info.lat; loc.lng = _list[i].info.lon; dist = loc.get_distance(current_loc); if (dist > max_dist) { max_dist = dist; index = i; } } // find the current distance loc.lat = lat; loc.lng = lon; dist = loc.get_distance(current_loc); if (dist < max_dist) { clear_list_item(index); _list[index].info.MMSI = mmsi; return true; } return false; } void AP_AIS::clear_list_item(uint16_t index) { if (index < _list.max_items()) { memset(&_list[index],0,sizeof(ais_vehicle_t)); } } ////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// // Functions for decoding AIVDM payload mesages bool AP_AIS::payload_decode(const char *payload) { // the mesage type is defined by the first character const uint8_t type = payload_char_decode(payload[0]); switch (type) { case 1: // Position Report Class A case 2: // Position Report Class A (Assigned schedule) case 3: // Position Report Class A (Response to interrogation) return decode_position_report(payload, type); case 4: // Base Station Report return decode_base_station_report(payload); case 5: // Static and Voyage Related Data return decode_static_and_voyage_data(payload); default: return false; } } bool AP_AIS::decode_position_report(const char *payload, uint8_t type) { if (strlen(payload) != 28) { return false; } uint8_t repeat = get_bits(payload, 6, 7); uint32_t mmsi = get_bits(payload, 8, 37); uint8_t nav = get_bits(payload, 38, 41); int8_t rot = get_bits_signed(payload, 42, 49); uint16_t sog = get_bits(payload, 50, 59); bool pos_acc = get_bits(payload, 60, 60); int32_t lon = get_bits_signed(payload, 61, 88) * ((1.0f / 600000.0f)*1e7); int32_t lat = get_bits_signed(payload, 89, 115) * ((1.0f / 600000.0f)*1e7); uint16_t cog = get_bits(payload, 116, 127) * 10; uint16_t head = get_bits(payload, 128, 136) * 100; uint8_t sec_utc = get_bits(payload, 137, 142); uint8_t maneuver = get_bits(payload, 143, 144); // 145 - 147: spare bool raim = get_bits(payload, 148, 148); uint32_t radio = get_bits(payload, 149, 167); // log the raw infomation if ((_log_options & AIS_OPTIONS_LOG_DECODED) != 0) { const struct log_AIS_msg1 pkt{ LOG_PACKET_HEADER_INIT(LOG_AIS_MSG1), time_us : AP_HAL::micros64(), type : type, repeat : repeat, mmsi : mmsi, nav : nav, rot : rot, sog : sog, pos_acc : pos_acc, lon : lon, lat : lat, cog : cog, head : head, sec_utc : sec_utc, maneuver : maneuver, raim : raim, radio : radio }; AP::logger().WriteBlock(&pkt, sizeof(pkt)); } uint16_t index; if (!get_vessel_index(mmsi, index, lat, lon)) { // no room in the vessel list return true; } // mask of flags that we receive in this message const uint16_t mask = ~(AIS_FLAGS_POSITION_ACCURACY | AIS_FLAGS_VALID_COG | AIS_FLAGS_VALID_VELOCITY | AIS_FLAGS_VALID_TURN_RATE | AIS_FLAGS_TURN_RATE_SIGN_ONLY); uint16_t flags = _list[index].info.flags & mask; // clear all flags that will be updated if (pos_acc) { flags |= AIS_FLAGS_POSITION_ACCURACY; } if (cog < 36000) { flags |= AIS_FLAGS_VALID_COG; } if (sog < 1023) { flags |= AIS_FLAGS_VALID_VELOCITY; } if (sog == 1022) { flags |= AIS_FLAGS_HIGH_VELOCITY; } if (rot > -128) { flags |= AIS_FLAGS_VALID_TURN_RATE; } if (rot == 127 || rot == -127) { flags |= AIS_FLAGS_TURN_RATE_SIGN_ONLY; } else { rot = powf((rot / 4.733f),2.0f) / 6.0f; } _list[index].info.lat = lat; // int32_t [degE7] Latitude _list[index].info.lon = lon; // int32_t [degE7] Longitude _list[index].info.COG = cog; // uint16_t [cdeg] Course over ground _list[index].info.heading = head; // uint16_t [cdeg] True heading _list[index].info.velocity = sog; // uint16_t [cm/s] Speed over ground _list[index].info.flags = flags; // uint16_t Bitmask to indicate various statuses including valid data fields _list[index].info.turn_rate = rot; // int8_t [cdeg/s] Turn rate _list[index].info.navigational_status = nav; // uint8_t Navigational status _list[index].last_update_ms = AP_HAL::millis(); return true; } bool AP_AIS::decode_base_station_report(const char *payload) { if (strlen(payload) != 28) { return false; } uint8_t repeat = get_bits(payload, 6, 7); uint32_t mmsi = get_bits(payload, 8, 37); uint16_t year = get_bits(payload, 38, 51); uint8_t month = get_bits(payload, 52, 55); uint8_t day = get_bits(payload, 56, 60); uint8_t hour = get_bits(payload, 61, 65); uint8_t minute = get_bits(payload, 66, 71); uint8_t second = get_bits(payload, 72, 77); bool fix = get_bits(payload, 78, 78); int32_t lon = get_bits_signed(payload, 79, 106) * ((1.0f / 600000.0f)*1e7); int32_t lat = get_bits_signed(payload, 107, 133) * ((1.0f / 600000.0f)*1e7); uint8_t epfd = get_bits(payload, 134, 137); // 138 - 147: spare bool raim = get_bits(payload, 148, 148); uint32_t radio = get_bits(payload, 149, 167); // log the raw infomation if ((_log_options & AIS_OPTIONS_LOG_DECODED) != 0) { struct log_AIS_msg4 pkt { LOG_PACKET_HEADER_INIT(LOG_AIS_MSG4), time_us : AP_HAL::micros64(), repeat : repeat, mmsi : mmsi, year : year, month : month, day : day, hour : hour, minute : minute, second : second, fix : fix, lon : lon, lat : lat, epfd : epfd, raim : raim, radio : radio }; AP::logger().WriteBlock(&pkt, sizeof(pkt)); } uint16_t index; if (!get_vessel_index(mmsi, index)) { return true; } _list[index].info.lat = lat; // int32_t [degE7] Latitude _list[index].info.lon = lon; // int32_t [degE7] Longitude _list[index].last_update_ms = AP_HAL::millis(); return true; } bool AP_AIS::decode_static_and_voyage_data(const char *payload) { if (strlen(payload) != 71) { return false; } char call_sign[8]; char name[21]; char dest[21]; uint8_t repeat = get_bits(payload, 6, 7); uint32_t mmsi = get_bits(payload, 8, 37); uint8_t ver = get_bits(payload, 38, 39); uint32_t imo = get_bits(payload, 40, 69); get_char(payload, call_sign, 70, 111); get_char(payload, name, 112, 231); uint8_t vessel_type = get_bits(payload, 232, 239); uint16_t bow_dim = get_bits(payload, 240, 248); uint16_t stern_dim = get_bits(payload, 249, 257); uint8_t port_dim = get_bits(payload, 258, 263); uint8_t star_dim = get_bits(payload, 264, 269); uint8_t fix = get_bits(payload, 270, 273); //uint8_t month = get_bits(payload, 274, 277); // too much for a single log //uint8_t day = get_bits(payload, 278, 282); //uint8_t hour = get_bits(payload, 283, 287); //uint8_t minute = get_bits(payload, 288, 293); uint8_t draught = get_bits(payload, 294, 301); get_char(payload, dest, 302, 421); bool dte = get_bits(payload, 422, 422); // 423 - 426: spare // log the raw infomation if ((_log_options & AIS_OPTIONS_LOG_DECODED) != 0) { struct log_AIS_msg5 pkt { LOG_PACKET_HEADER_INIT(LOG_AIS_MSG5), time_us : AP_HAL::micros64(), repeat : repeat, mmsi : mmsi, ver : ver, imo : imo, call_sign : {}, name : {}, vessel_type : vessel_type, bow_dim : bow_dim, stern_dim : stern_dim, port_dim : port_dim, star_dim : star_dim, fix : fix, draught : draught, dest : {}, dte : dte }; strncpy(pkt.call_sign, call_sign, sizeof(pkt.call_sign)); strncpy(pkt.name, name, sizeof(pkt.name)); strncpy(pkt.dest, dest, sizeof(pkt.dest)); AP::logger().WriteBlock(&pkt, sizeof(pkt)); } uint16_t index; if (!get_vessel_index(mmsi, index)) { return true; } // mask of flags that we receive in this message const uint16_t mask = ~(AIS_FLAGS_VALID_DIMENSIONS | AIS_FLAGS_LARGE_BOW_DIMENSION | AIS_FLAGS_LARGE_STERN_DIMENSION | AIS_FLAGS_LARGE_STARBOARD_DIMENSION | AIS_FLAGS_VALID_CALLSIGN | AIS_FLAGS_VALID_NAME); uint16_t flags = _list[index].info.flags & mask; // clear all flags that will be updated if (bow_dim != 0 && stern_dim != 0 && port_dim != 0 && star_dim != 0) { flags |= AIS_FLAGS_VALID_DIMENSIONS; if (bow_dim == 511) { flags |= AIS_FLAGS_LARGE_BOW_DIMENSION; } if (stern_dim == 511) { flags |= AIS_FLAGS_LARGE_STERN_DIMENSION; } if (port_dim == 63) { flags |= AIS_FLAGS_LARGE_PORT_DIMENSION; } if (star_dim == 63) { flags |= AIS_FLAGS_LARGE_STARBOARD_DIMENSION; } } if (strlen(call_sign) != 0) { flags |= AIS_FLAGS_VALID_CALLSIGN; } if (strlen(name) != 0) { flags |= AIS_FLAGS_VALID_NAME; } _list[index].info.dimension_bow = bow_dim; // uint16_t [m] Distance from lat/lon location to bow _list[index].info.dimension_stern = stern_dim; // uint16_t [m] Distance from lat/lon location to stern _list[index].info.flags = flags; // uint16_t Bitmask to indicate various statuses including valid data fields _list[index].info.type = vessel_type; // uint8_t Type of vessels _list[index].info.dimension_port = port_dim; // uint8_t [m] Distance from lat/lon location to port side _list[index].info.dimension_starboard = star_dim; // uint8_t [m] Distance from lat/lon location to starboard side memcpy(_list[index].info.callsign,call_sign,sizeof(_list[index].info.callsign)); // char The vessel callsign memcpy(_list[index].info.name,name,sizeof(_list[index].info.name)); // char The vessel name // note that the last contact time is not updated, this message does not provide a location for a valid vessel a location must be received return true; } ////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// // Functions for decoding AIVDM payload bits // decode bits to a char array void AP_AIS::get_char(const char *payload, char *array, uint16_t low, uint16_t high) { bool found_char = false; uint8_t length = ((high - low) + 1)/6; for (uint8_t i = length; i > 0; i--) { uint8_t ascii = get_bits(payload, low + (i-1)*6, (low + (i*6)) - 1); if (ascii < 32) { ascii += 64; } if (ascii == 64 || (ascii == 32 && !found_char)) { // '@' marks end of string, remove trailing spaces array[i-1] = 0; } else { found_char = true; array[i-1] = ascii; } } array[length] = 0; // always null terminate } // read the specified bits from the char array each char giving 6 bits uint32_t AP_AIS::get_bits(const char *payload, uint16_t low, uint16_t high) { uint8_t char_low = low / 6; uint8_t bit_low = low % 6; uint8_t char_high = high / 6; uint8_t bit_high = (high % 6) + 1; uint32_t val = 0; for (uint8_t index = 0; index <= char_high - char_low; index++) { uint8_t value = payload_char_decode(payload[char_low + index]); uint8_t mask = 0b111111; if (index == 0) { mask = mask >> bit_low; } value &= mask; if (index == char_high - char_low) { value = value >> (6 - bit_high); val = val << bit_high; } else { val = val << 6; } val |= value; } return val; } // read the specified bits from the char array each char giving 6 bits // As the values are a arbitrary length the sign bit is in the wrong place for standard length varables int32_t AP_AIS::get_bits_signed(const char *payload, uint16_t low, uint16_t high) { uint32_t value = get_bits(payload, low, high); if (get_bits(payload, low, low)) { // check sign bit // negative number return value | (UINT32_MAX << (high - low)); } return value; } // Convert payload chars to bits uint8_t AP_AIS::payload_char_decode(const char c) { uint8_t value = c; value -= 48; if (value > 40) { value -= 8; } return value; } ////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// // Functions for decoding and logging AIVDM NMEA sentence // log a raw AIVDM a message void AP_AIS::log_raw(const AIVDM *msg) { struct log_AIS_raw pkt{ LOG_PACKET_HEADER_INIT(LOG_AIS_RAW_MSG), time_us : AP_HAL::micros64(), num : msg->num, total : msg->total, ID : msg->ID, payload : {} }; memcpy(pkt.payload, msg->payload, sizeof(pkt.payload)); AP::logger().WriteBlock(&pkt, sizeof(pkt)); } // add a single character to the buffer and attempt to decode // returns true if a complete sentence was successfully decoded bool AP_AIS::decode(char c) { switch (c) { case ',': // end of a term, add to checksum _checksum ^= c; FALLTHROUGH; case '\r': case '\n': case '*': { if (_sentence_done) { return false; } // null terminate and decode latest term _term[_term_offset] = 0; bool valid_sentence = decode_latest_term(); // move onto next term _term_number++; _term_offset = 0; _term_is_checksum = (c == '*'); return valid_sentence; } case '!': // sentence begin _sentence_valid = false; _term_number = 0; _term_offset = 0; _checksum = 0; _term_is_checksum = false; _sentence_done = false; return false; } // ordinary characters are added to term if (_term_offset < sizeof(_term) - 1) { _term[_term_offset++] = c; } if (!_term_is_checksum) { _checksum ^= c; } return false; } // decode the most recently consumed term // returns true if new sentence has just passed checksum test and is validated bool AP_AIS::decode_latest_term() { // handle the last term in a message if (_term_is_checksum) { _sentence_done = true; uint8_t checksum = 16 * char_to_hex(_term[0]) + char_to_hex(_term[1]); return ((checksum == _checksum) && _sentence_valid); } // the first term determines the sentence type if (_term_number == 0) { if (strcmp(_term, "AIVDM") == 0) { // we found the sentence type for AIS _sentence_valid = true; } return false; } // if this is not the sentence we want then wait for another if (!_sentence_valid) { return false; } switch (_term_number) { case 1: _incoming.total = strtol(_term, NULL, 10); break; case 2: _incoming.num = strtol(_term, NULL, 10); break; case 3: _incoming.ID = 0; if (strlen(_term) > 0) { _incoming.ID = strtol(_term, NULL, 10); } else if (_incoming.num != 1 || _incoming.total != 1) { // only allow no ID if this is a single part message _sentence_valid = false; } break; // case 4, chanel, either A or B, discarded case 5: if (strlen(_term) == 0) { _sentence_valid = false; } else { strcpy(_incoming.payload,_term); } break; //case 5, number of fill bits, discarded } return false; } #endif // HAL_AIS_ENABLED