#include "MyMesh.h" #include /* ------------------------------ Config -------------------------------- */ #ifndef LORA_FREQ #define LORA_FREQ 915.0 #endif #ifndef LORA_BW #define LORA_BW 250 #endif #ifndef LORA_SF #define LORA_SF 10 #endif #ifndef LORA_CR #define LORA_CR 5 #endif #ifndef LORA_TX_POWER #define LORA_TX_POWER 20 #endif #ifndef ADVERT_NAME #define ADVERT_NAME "repeater" #endif #ifndef ADVERT_LAT #define ADVERT_LAT 0.0 #endif #ifndef ADVERT_LON #define ADVERT_LON 0.0 #endif #ifndef ADMIN_PASSWORD #define ADMIN_PASSWORD "password" #endif #ifndef SERVER_RESPONSE_DELAY #define SERVER_RESPONSE_DELAY 300 #endif #ifndef TXT_ACK_DELAY #define TXT_ACK_DELAY 200 #endif #define FIRMWARE_VER_LEVEL 1 #define REQ_TYPE_GET_STATUS 0x01 // same as _GET_STATS #define REQ_TYPE_KEEP_ALIVE 0x02 #define REQ_TYPE_GET_TELEMETRY_DATA 0x03 #define REQ_TYPE_GET_ACCESS_LIST 0x05 #define REQ_TYPE_GET_NEIGHBOURS 0x06 #define RESP_SERVER_LOGIN_OK 0 // response to ANON_REQ #define CLI_REPLY_DELAY_MILLIS 600 #define LAZY_CONTACTS_WRITE_DELAY 5000 void MyMesh::putNeighbour(const mesh::Identity &id, uint32_t timestamp, float snr) { #if MAX_NEIGHBOURS // check if neighbours enabled // find existing neighbour, else use least recently updated uint32_t oldest_timestamp = 0xFFFFFFFF; NeighbourInfo *neighbour = &neighbours[0]; for (int i = 0; i < MAX_NEIGHBOURS; i++) { // if neighbour already known, we should update it if (id.matches(neighbours[i].id)) { neighbour = &neighbours[i]; break; } // otherwise we should update the least recently updated neighbour if (neighbours[i].heard_timestamp < oldest_timestamp) { neighbour = &neighbours[i]; oldest_timestamp = neighbour->heard_timestamp; } } // update neighbour info neighbour->id = id; neighbour->advert_timestamp = timestamp; neighbour->heard_timestamp = getRTCClock()->getCurrentTime(); neighbour->snr = (int8_t)(snr * 4); #endif } uint8_t MyMesh::handleLoginReq(const mesh::Identity& sender, const uint8_t* secret, uint32_t sender_timestamp, const uint8_t* data, bool is_flood) { ClientInfo* client = NULL; if (data[0] == 0) { // blank password, just check if sender is in ACL client = acl.getClient(sender.pub_key, PUB_KEY_SIZE); if (client == NULL) { #if MESH_DEBUG MESH_DEBUG_PRINTLN("Login, sender not in ACL"); #endif } } if (client == NULL) { uint8_t perms; if (strcmp((char *)data, _prefs.password) == 0) { // check for valid admin password perms = PERM_ACL_ADMIN; } else if (strcmp((char *)data, _prefs.guest_password) == 0) { // check guest password perms = PERM_ACL_GUEST; } else { #if MESH_DEBUG MESH_DEBUG_PRINTLN("Invalid password: %s", data); #endif return 0; } client = acl.putClient(sender, 0); // add to contacts (if not already known) if (sender_timestamp <= client->last_timestamp) { MESH_DEBUG_PRINTLN("Possible login replay attack!"); return 0; // FATAL: client table is full -OR- replay attack } MESH_DEBUG_PRINTLN("Login success!"); client->last_timestamp = sender_timestamp; client->last_activity = getRTCClock()->getCurrentTime(); client->permissions &= ~0x03; client->permissions |= perms; memcpy(client->shared_secret, secret, PUB_KEY_SIZE); if (perms != PERM_ACL_GUEST) { // keep number of FS writes to a minimum dirty_contacts_expiry = futureMillis(LAZY_CONTACTS_WRITE_DELAY); } } if (is_flood) { client->out_path_len = -1; // need to rediscover out_path } uint32_t now = getRTCClock()->getCurrentTimeUnique(); memcpy(reply_data, &now, 4); // response packets always prefixed with timestamp reply_data[4] = RESP_SERVER_LOGIN_OK; reply_data[5] = 0; // Legacy: was recommended keep-alive interval (secs / 16) reply_data[6] = client->isAdmin() ? 1 : 0; reply_data[7] = client->permissions; getRNG()->random(&reply_data[8], 4); // random blob to help packet-hash uniqueness reply_data[12] = FIRMWARE_VER_LEVEL; // New field return 13; // reply length } int MyMesh::handleRequest(ClientInfo *sender, uint32_t sender_timestamp, uint8_t *payload, size_t payload_len) { // uint32_t now = getRTCClock()->getCurrentTimeUnique(); // memcpy(reply_data, &now, 4); // response packets always prefixed with timestamp memcpy(reply_data, &sender_timestamp, 4); // reflect sender_timestamp back in response packet (kind of like a 'tag') if (payload[0] == REQ_TYPE_GET_STATUS) { // guests can also access this now RepeaterStats stats; stats.batt_milli_volts = board.getBattMilliVolts(); stats.curr_tx_queue_len = _mgr->getOutboundCount(0xFFFFFFFF); stats.noise_floor = (int16_t)_radio->getNoiseFloor(); stats.last_rssi = (int16_t)radio_driver.getLastRSSI(); stats.n_packets_recv = radio_driver.getPacketsRecv(); stats.n_packets_sent = radio_driver.getPacketsSent(); stats.total_air_time_secs = getTotalAirTime() / 1000; stats.total_up_time_secs = uptime_millis / 1000; stats.n_sent_flood = getNumSentFlood(); stats.n_sent_direct = getNumSentDirect(); stats.n_recv_flood = getNumRecvFlood(); stats.n_recv_direct = getNumRecvDirect(); stats.err_events = _err_flags; stats.last_snr = (int16_t)(radio_driver.getLastSNR() * 4); stats.n_direct_dups = ((SimpleMeshTables *)getTables())->getNumDirectDups(); stats.n_flood_dups = ((SimpleMeshTables *)getTables())->getNumFloodDups(); stats.total_rx_air_time_secs = getReceiveAirTime() / 1000; memcpy(&reply_data[4], &stats, sizeof(stats)); return 4 + sizeof(stats); // reply_len } if (payload[0] == REQ_TYPE_GET_TELEMETRY_DATA) { uint8_t perm_mask = ~(payload[1]); // NEW: first reserved byte (of 4), is now inverse mask to apply to permissions telemetry.reset(); telemetry.addVoltage(TELEM_CHANNEL_SELF, (float)board.getBattMilliVolts() / 1000.0f); // query other sensors -- target specific if ((sender->permissions & PERM_ACL_ROLE_MASK) == PERM_ACL_GUEST) { perm_mask = 0x00; // just base telemetry allowed } sensors.querySensors(perm_mask, telemetry); uint8_t tlen = telemetry.getSize(); memcpy(&reply_data[4], telemetry.getBuffer(), tlen); return 4 + tlen; // reply_len } if (payload[0] == REQ_TYPE_GET_ACCESS_LIST && sender->isAdmin()) { uint8_t res1 = payload[1]; // reserved for future (extra query params) uint8_t res2 = payload[2]; if (res1 == 0 && res2 == 0) { uint8_t ofs = 4; for (int i = 0; i < acl.getNumClients() && ofs + 7 <= sizeof(reply_data) - 4; i++) { auto c = acl.getClientByIdx(i); if (c->permissions == 0) continue; // skip deleted entries memcpy(&reply_data[ofs], c->id.pub_key, 6); ofs += 6; // just 6-byte pub_key prefix reply_data[ofs++] = c->permissions; } return ofs; } } if (payload[0] == REQ_TYPE_GET_NEIGHBOURS) { uint8_t request_version = payload[1]; if (request_version == 0) { // reply data offset (after response sender_timestamp/tag) int reply_offset = 4; // get request params uint8_t count = payload[2]; // how many neighbours to fetch (0-255) uint16_t offset; memcpy(&offset, &payload[3], 2); // offset from start of neighbours list (0-65535) uint8_t order_by = payload[5]; // how to order neighbours. 0=newest_to_oldest, 1=oldest_to_newest, 2=strongest_to_weakest, 3=weakest_to_strongest uint8_t pubkey_prefix_length = payload[6]; // how many bytes of neighbour pub key we want // we also send a 4 byte random blob in payload[7...10] to help packet uniqueness MESH_DEBUG_PRINTLN("REQ_TYPE_GET_NEIGHBOURS count=%d, offset=%d, order_by=%d, pubkey_prefix_length=%d", count, offset, order_by, pubkey_prefix_length); // clamp pub key prefix length to max pub key length if(pubkey_prefix_length > PUB_KEY_SIZE){ pubkey_prefix_length = PUB_KEY_SIZE; MESH_DEBUG_PRINTLN("REQ_TYPE_GET_NEIGHBOURS invalid pubkey_prefix_length=%d clamping to %d", pubkey_prefix_length, PUB_KEY_SIZE); } // create copy of neighbours list, skipping empty entries so we can sort it separately from main list int16_t neighbours_count = 0; NeighbourInfo* sorted_neighbours[MAX_NEIGHBOURS]; for (int i = 0; i < MAX_NEIGHBOURS; i++) { auto neighbour = &neighbours[i]; if (neighbour->heard_timestamp > 0) { sorted_neighbours[neighbours_count] = neighbour; neighbours_count++; } } // sort neighbours based on order if (order_by == 0) { // sort by newest to oldest MESH_DEBUG_PRINTLN("REQ_TYPE_GET_NEIGHBOURS sorting newest to oldest"); std::sort(sorted_neighbours, sorted_neighbours + neighbours_count, [](const NeighbourInfo* a, const NeighbourInfo* b) { return a->heard_timestamp > b->heard_timestamp; // desc }); } else if (order_by == 1) { // sort by oldest to newest MESH_DEBUG_PRINTLN("REQ_TYPE_GET_NEIGHBOURS sorting oldest to newest"); std::sort(sorted_neighbours, sorted_neighbours + neighbours_count, [](const NeighbourInfo* a, const NeighbourInfo* b) { return a->heard_timestamp < b->heard_timestamp; // asc }); } else if (order_by == 2) { // sort by strongest to weakest MESH_DEBUG_PRINTLN("REQ_TYPE_GET_NEIGHBOURS sorting strongest to weakest"); std::sort(sorted_neighbours, sorted_neighbours + neighbours_count, [](const NeighbourInfo* a, const NeighbourInfo* b) { return a->snr > b->snr; // desc }); } else if (order_by == 3) { // sort by weakest to strongest MESH_DEBUG_PRINTLN("REQ_TYPE_GET_NEIGHBOURS sorting weakest to strongest"); std::sort(sorted_neighbours, sorted_neighbours + neighbours_count, [](const NeighbourInfo* a, const NeighbourInfo* b) { return a->snr < b->snr; // asc }); } // build results buffer int results_count = 0; int results_offset = 0; uint8_t results_buffer[130]; for(int index = 0; index < count && index + offset < neighbours_count; index++){ // stop if we can't fit another entry in results int entry_size = pubkey_prefix_length + 4 + 1; if(results_offset + entry_size > sizeof(results_buffer)){ MESH_DEBUG_PRINTLN("REQ_TYPE_GET_NEIGHBOURS no more entries can fit in results buffer"); break; } // add next neighbour to results auto neighbour = sorted_neighbours[index + offset]; uint32_t heard_seconds_ago = getRTCClock()->getCurrentTime() - neighbour->heard_timestamp; memcpy(&results_buffer[results_offset], neighbour->id.pub_key, pubkey_prefix_length); results_offset += pubkey_prefix_length; memcpy(&results_buffer[results_offset], &heard_seconds_ago, 4); results_offset += 4; memcpy(&results_buffer[results_offset], &neighbour->snr, 1); results_offset += 1; results_count++; } // build reply MESH_DEBUG_PRINTLN("REQ_TYPE_GET_NEIGHBOURS neighbours_count=%d results_count=%d", neighbours_count, results_count); memcpy(&reply_data[reply_offset], &neighbours_count, 2); reply_offset += 2; memcpy(&reply_data[reply_offset], &results_count, 2); reply_offset += 2; memcpy(&reply_data[reply_offset], &results_buffer, results_offset); reply_offset += results_offset; return reply_offset; } } return 0; // unknown command } mesh::Packet *MyMesh::createSelfAdvert() { uint8_t app_data[MAX_ADVERT_DATA_SIZE]; uint8_t app_data_len = _cli.buildAdvertData(ADV_TYPE_REPEATER, app_data); return createAdvert(self_id, app_data, app_data_len); } File MyMesh::openAppend(const char *fname) { #if defined(NRF52_PLATFORM) || defined(STM32_PLATFORM) return _fs->open(fname, FILE_O_WRITE); #elif defined(RP2040_PLATFORM) return _fs->open(fname, "a"); #else return _fs->open(fname, "a", true); #endif } bool MyMesh::allowPacketForward(const mesh::Packet *packet) { if (_prefs.disable_fwd) return false; if (packet->isRouteFlood() && packet->path_len >= _prefs.flood_max) return false; if (packet->isRouteFlood() && recv_pkt_region == NULL) { MESH_DEBUG_PRINTLN("allowPacketForward: unknown transport code, or wildcard not allowed for FLOOD packet"); return false; } return true; } const char *MyMesh::getLogDateTime() { static char tmp[32]; uint32_t now = getRTCClock()->getCurrentTime(); DateTime dt = DateTime(now); sprintf(tmp, "%02d:%02d:%02d - %d/%d/%d U", dt.hour(), dt.minute(), dt.second(), dt.day(), dt.month(), dt.year()); return tmp; } void MyMesh::logRxRaw(float snr, float rssi, const uint8_t raw[], int len) { #if MESH_PACKET_LOGGING Serial.print(getLogDateTime()); Serial.print(" RAW: "); mesh::Utils::printHex(Serial, raw, len); Serial.println(); #endif } void MyMesh::logRx(mesh::Packet *pkt, int len, float score) { #ifdef WITH_BRIDGE if (_prefs.bridge_pkt_src == 1) { bridge.sendPacket(pkt); } #endif #ifdef WITH_MQTT if (_mqtt_bridge && _mqtt_bridge->isConnected()) { _mqtt_bridge->publishPacketRx(pkt, len, _radio->getLastSNR(), _radio->getLastRSSI()); } #endif if (_logging) { File f = openAppend(PACKET_LOG_FILE); if (f) { f.print(getLogDateTime()); f.printf(": RX, len=%d (type=%d, route=%s, payload_len=%d) SNR=%d RSSI=%d score=%d", len, pkt->getPayloadType(), pkt->isRouteDirect() ? "D" : "F", pkt->payload_len, (int)_radio->getLastSNR(), (int)_radio->getLastRSSI(), (int)(score * 1000)); if (pkt->getPayloadType() == PAYLOAD_TYPE_PATH || pkt->getPayloadType() == PAYLOAD_TYPE_REQ || pkt->getPayloadType() == PAYLOAD_TYPE_RESPONSE || pkt->getPayloadType() == PAYLOAD_TYPE_TXT_MSG) { f.printf(" [%02X -> %02X]\n", (uint32_t)pkt->payload[1], (uint32_t)pkt->payload[0]); } else { f.printf("\n"); } f.close(); } } } void MyMesh::logTx(mesh::Packet *pkt, int len) { #ifdef WITH_BRIDGE if (_prefs.bridge_pkt_src == 0) { bridge.sendPacket(pkt); } #endif #ifdef WITH_MQTT if (_mqtt_bridge && _mqtt_bridge->isConnected()) { _mqtt_bridge->publishPacketTx(pkt, len); } #endif if (_logging) { File f = openAppend(PACKET_LOG_FILE); if (f) { f.print(getLogDateTime()); f.printf(": TX, len=%d (type=%d, route=%s, payload_len=%d)", len, pkt->getPayloadType(), pkt->isRouteDirect() ? "D" : "F", pkt->payload_len); if (pkt->getPayloadType() == PAYLOAD_TYPE_PATH || pkt->getPayloadType() == PAYLOAD_TYPE_REQ || pkt->getPayloadType() == PAYLOAD_TYPE_RESPONSE || pkt->getPayloadType() == PAYLOAD_TYPE_TXT_MSG) { f.printf(" [%02X -> %02X]\n", (uint32_t)pkt->payload[1], (uint32_t)pkt->payload[0]); } else { f.printf("\n"); } f.close(); } } } void MyMesh::logTxFail(mesh::Packet *pkt, int len) { if (_logging) { File f = openAppend(PACKET_LOG_FILE); if (f) { f.print(getLogDateTime()); f.printf(": TX FAIL!, len=%d (type=%d, route=%s, payload_len=%d)\n", len, pkt->getPayloadType(), pkt->isRouteDirect() ? "D" : "F", pkt->payload_len); f.close(); } } } int MyMesh::calcRxDelay(float score, uint32_t air_time) const { if (_prefs.rx_delay_base <= 0.0f) return 0; return (int)((pow(_prefs.rx_delay_base, 0.85f - score) - 1.0) * air_time); } uint32_t MyMesh::getRetransmitDelay(const mesh::Packet *packet) { uint32_t t = (_radio->getEstAirtimeFor(packet->path_len + packet->payload_len + 2) * _prefs.tx_delay_factor); return getRNG()->nextInt(0, 5*t + 1); } uint32_t MyMesh::getDirectRetransmitDelay(const mesh::Packet *packet) { uint32_t t = (_radio->getEstAirtimeFor(packet->path_len + packet->payload_len + 2) * _prefs.direct_tx_delay_factor); return getRNG()->nextInt(0, 5*t + 1); } bool MyMesh::filterRecvFloodPacket(mesh::Packet* pkt) { // just try to determine region for packet (apply later in allowPacketForward()) if (pkt->getRouteType() == ROUTE_TYPE_TRANSPORT_FLOOD) { recv_pkt_region = region_map.findMatch(pkt, REGION_DENY_FLOOD); } else if (pkt->getRouteType() == ROUTE_TYPE_FLOOD) { if (region_map.getWildcard().flags & REGION_DENY_FLOOD) { recv_pkt_region = NULL; } else { recv_pkt_region = ®ion_map.getWildcard(); } } else { recv_pkt_region = NULL; } // do normal processing return false; } void MyMesh::onAnonDataRecv(mesh::Packet *packet, const uint8_t *secret, const mesh::Identity &sender, uint8_t *data, size_t len) { if (packet->getPayloadType() == PAYLOAD_TYPE_ANON_REQ) { // received an initial request by a possible admin // client (unknown at this stage) uint32_t timestamp; memcpy(×tamp, data, 4); data[len] = 0; // ensure null terminator uint8_t reply_len; if (data[4] == 0 || data[4] >= ' ') { // is password, ie. a login request reply_len = handleLoginReq(sender, secret, timestamp, &data[4], packet->isRouteFlood()); //} else if (data[4] == ANON_REQ_TYPE_*) { // future type codes // TODO } else { reply_len = 0; // unknown request type } if (reply_len == 0) return; // invalid request if (packet->isRouteFlood()) { // let this sender know path TO here, so they can use sendDirect(), and ALSO encode the response mesh::Packet* path = createPathReturn(sender, secret, packet->path, packet->path_len, PAYLOAD_TYPE_RESPONSE, reply_data, reply_len); if (path) sendFlood(path, SERVER_RESPONSE_DELAY); } else { mesh::Packet* reply = createDatagram(PAYLOAD_TYPE_RESPONSE, sender, secret, reply_data, reply_len); if (reply) sendFlood(reply, SERVER_RESPONSE_DELAY); } } } int MyMesh::searchPeersByHash(const uint8_t *hash) { int n = 0; for (int i = 0; i < acl.getNumClients(); i++) { if (acl.getClientByIdx(i)->id.isHashMatch(hash)) { matching_peer_indexes[n++] = i; // store the INDEXES of matching contacts (for subsequent 'peer' methods) } } return n; } void MyMesh::getPeerSharedSecret(uint8_t *dest_secret, int peer_idx) { int i = matching_peer_indexes[peer_idx]; if (i >= 0 && i < acl.getNumClients()) { // lookup pre-calculated shared_secret memcpy(dest_secret, acl.getClientByIdx(i)->shared_secret, PUB_KEY_SIZE); } else { MESH_DEBUG_PRINTLN("getPeerSharedSecret: Invalid peer idx: %d", i); } } static bool isShare(const mesh::Packet *packet) { if (packet->hasTransportCodes()) { return packet->transport_codes[0] == 0 && packet->transport_codes[1] == 0; // codes { 0, 0 } means 'send to nowhere' } return false; } void MyMesh::onAdvertRecv(mesh::Packet *packet, const mesh::Identity &id, uint32_t timestamp, const uint8_t *app_data, size_t app_data_len) { mesh::Mesh::onAdvertRecv(packet, id, timestamp, app_data, app_data_len); // chain to super impl // if this a zero hop advert (and not via 'Share'), add it to neighbours if (packet->path_len == 0 && !isShare(packet)) { AdvertDataParser parser(app_data, app_data_len); if (parser.isValid() && parser.getType() == ADV_TYPE_REPEATER) { // just keep neigbouring Repeaters putNeighbour(id, timestamp, packet->getSNR()); } } } void MyMesh::onPeerDataRecv(mesh::Packet *packet, uint8_t type, int sender_idx, const uint8_t *secret, uint8_t *data, size_t len) { int i = matching_peer_indexes[sender_idx]; if (i < 0 || i >= acl.getNumClients()) { // get from our known_clients table (sender SHOULD already be known in this context) MESH_DEBUG_PRINTLN("onPeerDataRecv: invalid peer idx: %d", i); return; } ClientInfo* client = acl.getClientByIdx(i); if (type == PAYLOAD_TYPE_REQ) { // request (from a Known admin client!) uint32_t timestamp; memcpy(×tamp, data, 4); if (timestamp > client->last_timestamp) { // prevent replay attacks int reply_len = handleRequest(client, timestamp, &data[4], len - 4); if (reply_len == 0) return; // invalid command client->last_timestamp = timestamp; client->last_activity = getRTCClock()->getCurrentTime(); if (packet->isRouteFlood()) { // let this sender know path TO here, so they can use sendDirect(), and ALSO encode the response mesh::Packet *path = createPathReturn(client->id, secret, packet->path, packet->path_len, PAYLOAD_TYPE_RESPONSE, reply_data, reply_len); if (path) sendFlood(path, SERVER_RESPONSE_DELAY); } else { mesh::Packet *reply = createDatagram(PAYLOAD_TYPE_RESPONSE, client->id, secret, reply_data, reply_len); if (reply) { if (client->out_path_len >= 0) { // we have an out_path, so send DIRECT sendDirect(reply, client->out_path, client->out_path_len, SERVER_RESPONSE_DELAY); } else { sendFlood(reply, SERVER_RESPONSE_DELAY); } } } } else { MESH_DEBUG_PRINTLN("onPeerDataRecv: possible replay attack detected"); } } else if (type == PAYLOAD_TYPE_TXT_MSG && len > 5 && client->isAdmin()) { // a CLI command uint32_t sender_timestamp; memcpy(&sender_timestamp, data, 4); // timestamp (by sender's RTC clock - which could be wrong) uint8_t flags = (data[4] >> 2); // message attempt number, and other flags if (!(flags == TXT_TYPE_PLAIN || flags == TXT_TYPE_CLI_DATA)) { MESH_DEBUG_PRINTLN("onPeerDataRecv: unsupported text type received: flags=%02x", (uint32_t)flags); } else if (sender_timestamp >= client->last_timestamp) { // prevent replay attacks bool is_retry = (sender_timestamp == client->last_timestamp); client->last_timestamp = sender_timestamp; client->last_activity = getRTCClock()->getCurrentTime(); // len can be > original length, but 'text' will be padded with zeroes data[len] = 0; // need to make a C string again, with null terminator if (flags == TXT_TYPE_PLAIN) { // for legacy CLI, send Acks uint32_t ack_hash; // calc truncated hash of the message timestamp + text + sender pub_key, to prove // to sender that we got it mesh::Utils::sha256((uint8_t *)&ack_hash, 4, data, 5 + strlen((char *)&data[5]), client->id.pub_key, PUB_KEY_SIZE); mesh::Packet *ack = createAck(ack_hash); if (ack) { if (client->out_path_len < 0) { sendFlood(ack, TXT_ACK_DELAY); } else { sendDirect(ack, client->out_path, client->out_path_len, TXT_ACK_DELAY); } } } uint8_t temp[166]; char *command = (char *)&data[5]; char *reply = (char *)&temp[5]; if (is_retry) { *reply = 0; } else { handleCommand(sender_timestamp, command, reply); } int text_len = strlen(reply); if (text_len > 0) { uint32_t timestamp = getRTCClock()->getCurrentTimeUnique(); if (timestamp == sender_timestamp) { // WORKAROUND: the two timestamps need to be different, in the CLI view timestamp++; } memcpy(temp, ×tamp, 4); // mostly an extra blob to help make packet_hash unique temp[4] = (TXT_TYPE_CLI_DATA << 2); // NOTE: legacy was: TXT_TYPE_PLAIN auto reply = createDatagram(PAYLOAD_TYPE_TXT_MSG, client->id, secret, temp, 5 + text_len); if (reply) { if (client->out_path_len < 0) { sendFlood(reply, CLI_REPLY_DELAY_MILLIS); } else { sendDirect(reply, client->out_path, client->out_path_len, CLI_REPLY_DELAY_MILLIS); } } } } else { MESH_DEBUG_PRINTLN("onPeerDataRecv: possible replay attack detected"); } } } bool MyMesh::onPeerPathRecv(mesh::Packet *packet, int sender_idx, const uint8_t *secret, uint8_t *path, uint8_t path_len, uint8_t extra_type, uint8_t *extra, uint8_t extra_len) { // TODO: prevent replay attacks int i = matching_peer_indexes[sender_idx]; if (i >= 0 && i < acl.getNumClients()) { // get from our known_clients table (sender SHOULD already be known in this context) MESH_DEBUG_PRINTLN("PATH to client, path_len=%d", (uint32_t)path_len); auto client = acl.getClientByIdx(i); memcpy(client->out_path, path, client->out_path_len = path_len); // store a copy of path, for sendDirect() client->last_activity = getRTCClock()->getCurrentTime(); } else { MESH_DEBUG_PRINTLN("onPeerPathRecv: invalid peer idx: %d", i); } // NOTE: no reciprocal path send!! return false; } #define CTL_TYPE_NODE_DISCOVER_REQ 0x80 #define CTL_TYPE_NODE_DISCOVER_RESP 0x90 void MyMesh::onControlDataRecv(mesh::Packet* packet) { uint8_t type = packet->payload[0] & 0xF0; // just test upper 4 bits if (type == CTL_TYPE_NODE_DISCOVER_REQ && packet->payload_len >= 6 && discover_limiter.allow(rtc_clock.getCurrentTime())) { int i = 1; uint8_t filter = packet->payload[i++]; uint32_t tag; memcpy(&tag, &packet->payload[i], 4); i += 4; uint32_t since; if (packet->payload_len >= i+4) { // optional since field memcpy(&since, &packet->payload[i], 4); i += 4; } else { since = 0; } if ((filter & (1 << ADV_TYPE_REPEATER)) != 0 && _prefs.discovery_mod_timestamp >= since) { bool prefix_only = packet->payload[0] & 1; uint8_t data[6 + PUB_KEY_SIZE]; data[0] = CTL_TYPE_NODE_DISCOVER_RESP | ADV_TYPE_REPEATER; // low 4-bits for node type data[1] = packet->_snr; // let sender know the inbound SNR ( x 4) memcpy(&data[2], &tag, 4); // include tag from request, for client to match to memcpy(&data[6], self_id.pub_key, PUB_KEY_SIZE); auto resp = createControlData(data, prefix_only ? 6 + 8 : 6 + PUB_KEY_SIZE); if (resp) { sendZeroHop(resp, getRetransmitDelay(resp)*4); // apply random delay (widened x4), as multiple nodes can respond to this } } } } MyMesh::MyMesh(mesh::MainBoard &board, mesh::Radio &radio, mesh::MillisecondClock &ms, mesh::RNG &rng, mesh::RTCClock &rtc, mesh::MeshTables &tables) : mesh::Mesh(radio, ms, rng, rtc, *new StaticPoolPacketManager(32), tables), _cli(board, rtc, sensors, &_prefs, this), telemetry(MAX_PACKET_PAYLOAD - 4), region_map(key_store), temp_map(key_store), discover_limiter(4, 120) // max 4 every 2 minutes #if defined(WITH_RS232_BRIDGE) , bridge(&_prefs, WITH_RS232_BRIDGE, _mgr, &rtc) #endif #if defined(WITH_ESPNOW_BRIDGE) , bridge(&_prefs, _mgr, &rtc) #endif { last_millis = 0; uptime_millis = 0; next_local_advert = next_flood_advert = 0; dirty_contacts_expiry = 0; set_radio_at = revert_radio_at = 0; _logging = false; region_load_active = false; #if MAX_NEIGHBOURS memset(neighbours, 0, sizeof(neighbours)); #endif // defaults memset(&_prefs, 0, sizeof(_prefs)); _prefs.airtime_factor = 1.0; // one half _prefs.rx_delay_base = 0.0f; // turn off by default, was 10.0; _prefs.tx_delay_factor = 0.5f; // was 0.25f _prefs.direct_tx_delay_factor = 0.2f; // was zero StrHelper::strncpy(_prefs.node_name, ADVERT_NAME, sizeof(_prefs.node_name)); _prefs.node_lat = ADVERT_LAT; _prefs.node_lon = ADVERT_LON; StrHelper::strncpy(_prefs.password, ADMIN_PASSWORD, sizeof(_prefs.password)); _prefs.freq = LORA_FREQ; _prefs.sf = LORA_SF; _prefs.bw = LORA_BW; _prefs.cr = LORA_CR; _prefs.tx_power_dbm = LORA_TX_POWER; _prefs.advert_interval = 1; // default to 2 minutes for NEW installs _prefs.flood_advert_interval = 12; // 12 hours _prefs.flood_max = 64; _prefs.interference_threshold = 0; // disabled // bridge defaults _prefs.bridge_enabled = 1; // enabled _prefs.bridge_delay = 500; // milliseconds _prefs.bridge_pkt_src = 0; // logTx _prefs.bridge_baud = 115200; // baud rate _prefs.bridge_channel = 1; // channel 1 StrHelper::strncpy(_prefs.bridge_secret, "LVSITANOS", sizeof(_prefs.bridge_secret)); // Owner info default (empty) _prefs.owner_info[0] = 0; // GPS defaults _prefs.gps_enabled = 0; _prefs.gps_interval = 0; _prefs.advert_loc_policy = ADVERT_LOC_PREFS; _prefs.adc_multiplier = 0.0f; // 0.0f means use default board multiplier } void MyMesh::begin(FILESYSTEM *fs) { mesh::Mesh::begin(); _fs = fs; // load persisted prefs _cli.loadPrefs(_fs); acl.load(_fs); // TODO: key_store.begin(); region_map.load(_fs); #if defined(WITH_BRIDGE) if (_prefs.bridge_enabled) { bridge.begin(); } #endif #ifdef WITH_MQTT // Initialize MQTT gateway (WiFi) initMQTT(); #endif #ifdef WITH_ETHERNET // Initialize MQTT gateway (Ethernet) initEthernet(); #endif radio_set_params(_prefs.freq, _prefs.bw, _prefs.sf, _prefs.cr); radio_set_tx_power(_prefs.tx_power_dbm); updateAdvertTimer(); updateFloodAdvertTimer(); board.setAdcMultiplier(_prefs.adc_multiplier); #if ENV_INCLUDE_GPS == 1 applyGpsPrefs(); #endif } void MyMesh::applyTempRadioParams(float freq, float bw, uint8_t sf, uint8_t cr, int timeout_mins) { set_radio_at = futureMillis(2000); // give CLI reply some time to be sent back, before applying temp radio params pending_freq = freq; pending_bw = bw; pending_sf = sf; pending_cr = cr; revert_radio_at = futureMillis(2000 + timeout_mins * 60 * 1000); // schedule when to revert radio params } bool MyMesh::formatFileSystem() { #if defined(NRF52_PLATFORM) || defined(STM32_PLATFORM) return InternalFS.format(); #elif defined(RP2040_PLATFORM) return LittleFS.format(); #elif defined(ESP32) return SPIFFS.format(); #else #error "need to implement file system erase" return false; #endif } void MyMesh::sendSelfAdvertisement(int delay_millis) { mesh::Packet *pkt = createSelfAdvert(); if (pkt) { sendFlood(pkt, delay_millis); } else { MESH_DEBUG_PRINTLN("ERROR: unable to create advertisement packet!"); } } void MyMesh::updateAdvertTimer() { if (_prefs.advert_interval > 0) { // schedule local advert timer next_local_advert = futureMillis(((uint32_t)_prefs.advert_interval) * 2 * 60 * 1000); } else { next_local_advert = 0; // stop the timer } } void MyMesh::updateFloodAdvertTimer() { if (_prefs.flood_advert_interval > 0) { // schedule flood advert timer next_flood_advert = futureMillis(((uint32_t)_prefs.flood_advert_interval) * 60 * 60 * 1000); } else { next_flood_advert = 0; // stop the timer } } void MyMesh::dumpLogFile() { #if defined(RP2040_PLATFORM) File f = _fs->open(PACKET_LOG_FILE, "r"); #else File f = _fs->open(PACKET_LOG_FILE); #endif if (f) { while (f.available()) { int c = f.read(); if (c < 0) break; Serial.print((char)c); } f.close(); } } void MyMesh::setTxPower(uint8_t power_dbm) { radio_set_tx_power(power_dbm); } void MyMesh::formatNeighborsReply(char *reply) { char *dp = reply; #if MAX_NEIGHBOURS // create copy of neighbours list, skipping empty entries so we can sort it separately from main list int16_t neighbours_count = 0; NeighbourInfo* sorted_neighbours[MAX_NEIGHBOURS]; for (int i = 0; i < MAX_NEIGHBOURS; i++) { auto neighbour = &neighbours[i]; if (neighbour->heard_timestamp > 0) { sorted_neighbours[neighbours_count] = neighbour; neighbours_count++; } } // sort neighbours newest to oldest std::sort(sorted_neighbours, sorted_neighbours + neighbours_count, [](const NeighbourInfo* a, const NeighbourInfo* b) { return a->heard_timestamp > b->heard_timestamp; // desc }); for (int i = 0; i < neighbours_count && dp - reply < 134; i++) { NeighbourInfo *neighbour = sorted_neighbours[i]; // add new line if not first item if (i > 0) *dp++ = '\n'; char hex[10]; // get 4 bytes of neighbour id as hex mesh::Utils::toHex(hex, neighbour->id.pub_key, 4); // add next neighbour uint32_t secs_ago = getRTCClock()->getCurrentTime() - neighbour->heard_timestamp; sprintf(dp, "%s:%d:%d", hex, secs_ago, neighbour->snr); while (*dp) dp++; // find end of string } #endif if (dp == reply) { // no neighbours, need empty response strcpy(dp, "-none-"); dp += 6; } *dp = 0; // null terminator } void MyMesh::removeNeighbor(const uint8_t *pubkey, int key_len) { #if MAX_NEIGHBOURS for (int i = 0; i < MAX_NEIGHBOURS; i++) { NeighbourInfo *neighbour = &neighbours[i]; if (memcmp(neighbour->id.pub_key, pubkey, key_len) == 0) { neighbours[i] = NeighbourInfo(); // clear neighbour entry } } #endif } void MyMesh::formatStatsReply(char *reply) { StatsFormatHelper::formatCoreStats(reply, board, *_ms, _err_flags, _mgr); } void MyMesh::formatRadioStatsReply(char *reply) { StatsFormatHelper::formatRadioStats(reply, _radio, radio_driver, getTotalAirTime(), getReceiveAirTime()); } void MyMesh::formatPacketStatsReply(char *reply) { StatsFormatHelper::formatPacketStats(reply, radio_driver, getNumSentFlood(), getNumSentDirect(), getNumRecvFlood(), getNumRecvDirect()); } void MyMesh::saveIdentity(const mesh::LocalIdentity &new_id) { self_id = new_id; #if defined(NRF52_PLATFORM) || defined(STM32_PLATFORM) IdentityStore store(*_fs, ""); #elif defined(ESP32) IdentityStore store(*_fs, "/identity"); #elif defined(RP2040_PLATFORM) IdentityStore store(*_fs, "/identity"); #else #error "need to define saveIdentity()" #endif store.save("_main", self_id); } void MyMesh::clearStats() { radio_driver.resetStats(); resetStats(); ((SimpleMeshTables *)getTables())->resetStats(); } void MyMesh::handleCommand(uint32_t sender_timestamp, char *command, char *reply) { if (region_load_active) { if (StrHelper::isBlank(command)) { // empty/blank line, signal to terminate 'load' operation region_map = temp_map; // copy over the temp instance as new current map region_load_active = false; sprintf(reply, "OK - loaded %d regions", region_map.getCount()); } else { char *np = command; while (*np == ' ') np++; // skip indent int indent = np - command; char *ep = np; while (RegionMap::is_name_char(*ep)) ep++; if (*ep) { *ep++ = 0; } // set null terminator for end of name while (*ep && *ep != 'F') ep++; // look for (optional) flags if (indent > 0 && indent < 8 && strlen(np) > 0) { auto parent = load_stack[indent - 1]; if (parent) { auto old = region_map.findByName(np); auto nw = temp_map.putRegion(np, parent->id, old ? old->id : 0); // carry-over the current ID (if name already exists) if (nw) { nw->flags = old ? old->flags : (*ep == 'F' ? 0 : REGION_DENY_FLOOD); // carry-over flags from curr load_stack[indent] = nw; // keep pointers to parent regions, to resolve parent_id's } } } reply[0] = 0; } return; } while (*command == ' ') command++; // skip leading spaces if (strlen(command) > 4 && command[2] == '|') { // optional prefix (for companion radio CLI) memcpy(reply, command, 3); // reflect the prefix back reply += 3; command += 3; } // handle ACL related commands if (memcmp(command, "setperm ", 8) == 0) { // format: setperm {pubkey-hex} {permissions-int8} char* hex = &command[8]; char* sp = strchr(hex, ' '); // look for separator char if (sp == NULL) { strcpy(reply, "Err - bad params"); } else { *sp++ = 0; // replace space with null terminator uint8_t pubkey[PUB_KEY_SIZE]; int hex_len = min(sp - hex, PUB_KEY_SIZE*2); if (mesh::Utils::fromHex(pubkey, hex_len / 2, hex)) { uint8_t perms = atoi(sp); if (acl.applyPermissions(self_id, pubkey, hex_len / 2, perms)) { dirty_contacts_expiry = futureMillis(LAZY_CONTACTS_WRITE_DELAY); // trigger acl.save() strcpy(reply, "OK"); } else { strcpy(reply, "Err - invalid params"); } } else { strcpy(reply, "Err - bad pubkey"); } } } else if (sender_timestamp == 0 && strcmp(command, "get acl") == 0) { Serial.println("ACL:"); for (int i = 0; i < acl.getNumClients(); i++) { auto c = acl.getClientByIdx(i); if (c->permissions == 0) continue; // skip deleted (or guest) entries Serial.printf("%02X ", c->permissions); mesh::Utils::printHex(Serial, c->id.pub_key, PUB_KEY_SIZE); Serial.printf("\n"); } reply[0] = 0; } else if (memcmp(command, "region", 6) == 0) { reply[0] = 0; const char* parts[4]; int n = mesh::Utils::parseTextParts(command, parts, 4, ' '); if (n == 1 && sender_timestamp == 0) { region_map.exportTo(Serial); } else if (n >= 2 && strcmp(parts[1], "load") == 0) { temp_map.resetFrom(region_map); // rebuild regions in a temp instance memset(load_stack, 0, sizeof(load_stack)); load_stack[0] = &temp_map.getWildcard(); region_load_active = true; } else if (n >= 2 && strcmp(parts[1], "save") == 0) { _prefs.discovery_mod_timestamp = rtc_clock.getCurrentTime(); // this node is now 'modified' (for discovery info) savePrefs(); bool success = region_map.save(_fs); strcpy(reply, success ? "OK" : "Err - save failed"); } else if (n >= 3 && strcmp(parts[1], "allowf") == 0) { auto region = region_map.findByNamePrefix(parts[2]); if (region) { region->flags &= ~REGION_DENY_FLOOD; strcpy(reply, "OK"); } else { strcpy(reply, "Err - unknown region"); } } else if (n >= 3 && strcmp(parts[1], "denyf") == 0) { auto region = region_map.findByNamePrefix(parts[2]); if (region) { region->flags |= REGION_DENY_FLOOD; strcpy(reply, "OK"); } else { strcpy(reply, "Err - unknown region"); } } else if (n >= 3 && strcmp(parts[1], "get") == 0) { auto region = region_map.findByNamePrefix(parts[2]); if (region) { auto parent = region_map.findById(region->parent); if (parent && parent->id != 0) { sprintf(reply, " %s (%s) %s", region->name, parent->name, (region->flags & REGION_DENY_FLOOD) ? "" : "F"); } else { sprintf(reply, " %s %s", region->name, (region->flags & REGION_DENY_FLOOD) ? "" : "F"); } } else { strcpy(reply, "Err - unknown region"); } } else if (n >= 3 && strcmp(parts[1], "home") == 0) { auto home = region_map.findByNamePrefix(parts[2]); if (home) { region_map.setHomeRegion(home); sprintf(reply, " home is now %s", home->name); } else { strcpy(reply, "Err - unknown region"); } } else if (n == 2 && strcmp(parts[1], "home") == 0) { auto home = region_map.getHomeRegion(); sprintf(reply, " home is %s", home ? home->name : "*"); } else if (n >= 3 && strcmp(parts[1], "put") == 0) { auto parent = n >= 4 ? region_map.findByNamePrefix(parts[3]) : ®ion_map.getWildcard(); if (parent == NULL) { strcpy(reply, "Err - unknown parent"); } else { auto region = region_map.putRegion(parts[2], parent->id); if (region == NULL) { strcpy(reply, "Err - unable to put"); } else { strcpy(reply, "OK"); } } } else if (n >= 3 && strcmp(parts[1], "remove") == 0) { auto region = region_map.findByName(parts[2]); if (region) { if (region_map.removeRegion(*region)) { strcpy(reply, "OK"); } else { strcpy(reply, "Err - not empty"); } } else { strcpy(reply, "Err - not found"); } } else { strcpy(reply, "Err - ??"); } } else{ _cli.handleCommand(sender_timestamp, command, reply); // common CLI commands } } void MyMesh::loop() { #ifdef WITH_BRIDGE bridge.loop(); #endif #ifdef WITH_MQTT // Process WiFi, MQTT, and web server _wifi_mgr.loop(); if (_mqtt_bridge) { _mqtt_bridge->loop(); // Periodic stats publish (every 30 seconds) if (_mqtt_bridge->isConnected() && millis() - _last_mqtt_stats > 30000) { _mqtt_bridge->publishStats( uptime_millis / 1000, radio_driver.getPacketsRecv(), radio_driver.getPacketsSent(), getTotalAirTime() / 1000, (int16_t)_radio->getNoiseFloor() ); _last_mqtt_stats = millis(); // Update web config stats if (_web_config) { WebConfigStats stats; stats.uptime_secs = uptime_millis / 1000; stats.packets_rx = radio_driver.getPacketsRecv(); stats.packets_tx = radio_driver.getPacketsSent(); stats.air_time_secs = getTotalAirTime() / 1000; stats.noise_floor = (int16_t)_radio->getNoiseFloor(); stats.last_rssi = (int16_t)radio_driver.getLastRSSI(); stats.last_snr = radio_driver.getLastSNR(); stats.tx_queue_len = _mgr->getOutboundCount(0xFFFFFFFF); stats.batt_mv = board.getBattMilliVolts(); _web_config->updateStats(stats); } } } #endif #ifdef WITH_ETHERNET // Process Ethernet and MQTT _eth_mgr.loop(); if (_mqtt_bridge) { _mqtt_bridge->loop(); // Periodic stats publish (every 30 seconds) if (_mqtt_bridge->isConnected() && millis() - _last_mqtt_stats > 30000) { _mqtt_bridge->publishStats( uptime_millis / 1000, radio_driver.getPacketsRecv(), radio_driver.getPacketsSent(), getTotalAirTime() / 1000, (int16_t)_radio->getNoiseFloor() ); _last_mqtt_stats = millis(); } } #endif mesh::Mesh::loop(); if (next_flood_advert && millisHasNowPassed(next_flood_advert)) { mesh::Packet *pkt = createSelfAdvert(); if (pkt) sendFlood(pkt); updateFloodAdvertTimer(); // schedule next flood advert updateAdvertTimer(); // also schedule local advert (so they don't overlap) } else if (next_local_advert && millisHasNowPassed(next_local_advert)) { mesh::Packet *pkt = createSelfAdvert(); if (pkt) sendZeroHop(pkt); updateAdvertTimer(); // schedule next local advert } if (set_radio_at && millisHasNowPassed(set_radio_at)) { // apply pending (temporary) radio params set_radio_at = 0; // clear timer radio_set_params(pending_freq, pending_bw, pending_sf, pending_cr); MESH_DEBUG_PRINTLN("Temp radio params"); } if (revert_radio_at && millisHasNowPassed(revert_radio_at)) { // revert radio params to orig revert_radio_at = 0; // clear timer radio_set_params(_prefs.freq, _prefs.bw, _prefs.sf, _prefs.cr); MESH_DEBUG_PRINTLN("Radio params restored"); } // is pending dirty contacts write needed? if (dirty_contacts_expiry && millisHasNowPassed(dirty_contacts_expiry)) { acl.save(_fs); dirty_contacts_expiry = 0; } // update uptime uint32_t now = millis(); uptime_millis += now - last_millis; last_millis = now; } #ifdef WITH_MQTT // MQTT initialization and helper methods void MyMesh::initMQTT() { Serial.println("[MQTT] Initializing WiFi + MQTT gateway..."); // Configure WiFi memset(&_wifi_config, 0, sizeof(_wifi_config)); #ifdef MQTT_WIFI_SSID strncpy(_wifi_config.ssid, MQTT_WIFI_SSID, sizeof(_wifi_config.ssid) - 1); #endif #ifdef MQTT_WIFI_PASS strncpy(_wifi_config.password, MQTT_WIFI_PASS, sizeof(_wifi_config.password) - 1); #endif strncpy(_wifi_config.ap_ssid, "MeshCore", sizeof(_wifi_config.ap_ssid) - 1); _wifi_config.connect_timeout_ms = 15000; _wifi_config.reconnect_interval_ms = 10000; _wifi_config.max_retries = 5; // Configure MQTT memset(&_mqtt_config, 0, sizeof(_mqtt_config)); #ifdef MQTT_BROKER strncpy(_mqtt_config.broker, MQTT_BROKER, sizeof(_mqtt_config.broker) - 1); #else strncpy(_mqtt_config.broker, "mqtt.example.com", sizeof(_mqtt_config.broker) - 1); #endif #ifdef MQTT_PORT _mqtt_config.port = MQTT_PORT; #else _mqtt_config.port = 1883; #endif #ifdef MQTT_USER strncpy(_mqtt_config.user, MQTT_USER, sizeof(_mqtt_config.user) - 1); #endif #ifdef MQTT_PASS strncpy(_mqtt_config.password, MQTT_PASS, sizeof(_mqtt_config.password) - 1); #endif #ifdef MQTT_TOPIC_PREFIX strncpy(_mqtt_config.topic_prefix, MQTT_TOPIC_PREFIX, sizeof(_mqtt_config.topic_prefix) - 1); #else strncpy(_mqtt_config.topic_prefix, "meshcore/repeater", sizeof(_mqtt_config.topic_prefix) - 1); #endif _mqtt_config.enabled = 1; #ifdef MQTT_USE_TLS _mqtt_config.use_tls = MQTT_USE_TLS; #else _mqtt_config.use_tls = 0; #endif _mqtt_config.keepalive_secs = 60; _mqtt_config.publish_interval_ms = 100; // Start WiFi _wifi_mgr.begin(_wifi_config); // Create MQTT bridge (pass pointer to INetworkManager interface) _mqtt_bridge = new MQTTBridge(&_wifi_mgr, _mgr, &rtc_clock); _mqtt_bridge->begin(_mqtt_config, self_id.pub_key); // Create web config server _web_config = new WebConfig(_wifi_mgr, *_mqtt_bridge); _web_config->begin(&_wifi_config, &_mqtt_config, &_prefs); _web_config->setNodeInfo(self_id.pub_key, _prefs.node_name, FIRMWARE_VERSION); _web_config->setSaveCallback([]() { // Note: In a real implementation, we'd save to preferences file Serial.println("[WebConfig] Save callback triggered"); }); _web_config->setRebootCallback([]() { ESP.restart(); }); _last_mqtt_stats = millis(); Serial.println("[MQTT] Gateway initialized"); } bool MyMesh::isMQTTConnected() const { return _mqtt_bridge && _mqtt_bridge->isConnected(); } bool MyMesh::isWiFiConnected() const { return _wifi_mgr.isConnected(); } void MyMesh::setMQTTEnabled(bool enable) { _mqtt_config.enabled = enable ? 1 : 0; if (_mqtt_bridge) { _mqtt_bridge->updateConfig(_mqtt_config); } } const char* MyMesh::getMQTTStatus() const { if (!_mqtt_bridge) return "not initialized"; if (!_mqtt_config.enabled) return "disabled"; if (_mqtt_bridge->isConnected()) return "connected"; return "disconnected"; } const char* MyMesh::getWiFiStatus() const { switch (_wifi_mgr.getState()) { case NetworkState::CONNECTED: return "connected"; case NetworkState::CONNECTING: return "connecting"; case NetworkState::AP_MODE: return "ap_mode"; default: return "disconnected"; } } IPAddress MyMesh::getWiFiIP() const { return _wifi_mgr.getLocalIP(); } #endif // WITH_MQTT #ifdef WITH_ETHERNET // Ethernet initialization and helper methods void MyMesh::initEthernet() { Serial.println("[ETH] Initializing Ethernet + MQTT gateway..."); // Configure Ethernet (use defaults or build flags) memset(&_eth_config, 0, sizeof(_eth_config)); #ifdef ETH_SPI_SCK _eth_config.spi_sck = ETH_SPI_SCK; #else _eth_config.spi_sck = 19; #endif #ifdef ETH_SPI_MOSI _eth_config.spi_mosi = ETH_SPI_MOSI; #else _eth_config.spi_mosi = 20; #endif #ifdef ETH_SPI_MISO _eth_config.spi_miso = ETH_SPI_MISO; #else _eth_config.spi_miso = 47; #endif #ifdef ETH_SPI_CS _eth_config.spi_cs = ETH_SPI_CS; #else _eth_config.spi_cs = 48; #endif _eth_config.connect_timeout_ms = 30000; _eth_config.reconnect_interval_ms = 5000; _eth_config.use_dhcp = true; // Configure MQTT memset(&_mqtt_config, 0, sizeof(_mqtt_config)); #ifdef MQTT_BROKER strncpy(_mqtt_config.broker, MQTT_BROKER, sizeof(_mqtt_config.broker) - 1); #else strncpy(_mqtt_config.broker, "mqtt.example.com", sizeof(_mqtt_config.broker) - 1); #endif #ifdef MQTT_PORT _mqtt_config.port = MQTT_PORT; #else _mqtt_config.port = 1883; #endif #ifdef MQTT_USER strncpy(_mqtt_config.user, MQTT_USER, sizeof(_mqtt_config.user) - 1); #endif #ifdef MQTT_PASS strncpy(_mqtt_config.password, MQTT_PASS, sizeof(_mqtt_config.password) - 1); #endif #ifdef MQTT_TOPIC_PREFIX strncpy(_mqtt_config.topic_prefix, MQTT_TOPIC_PREFIX, sizeof(_mqtt_config.topic_prefix) - 1); #else strncpy(_mqtt_config.topic_prefix, "meshcore/repeater", sizeof(_mqtt_config.topic_prefix) - 1); #endif _mqtt_config.enabled = 1; _mqtt_config.use_tls = 0; // TLS not typically used with local Ethernet _mqtt_config.keepalive_secs = 60; _mqtt_config.publish_interval_ms = 100; // Start Ethernet _eth_mgr.begin(_eth_config); // Create MQTT bridge (pass pointer to INetworkManager interface) _mqtt_bridge = new MQTTBridge(&_eth_mgr, _mgr, &rtc_clock); _mqtt_bridge->begin(_mqtt_config, self_id.pub_key); _last_mqtt_stats = millis(); Serial.println("[ETH] Gateway initialized"); } bool MyMesh::isMQTTConnected() const { return _mqtt_bridge && _mqtt_bridge->isConnected(); } bool MyMesh::isEthernetConnected() const { return _eth_mgr.isConnected(); } void MyMesh::setMQTTEnabled(bool enable) { _mqtt_config.enabled = enable ? 1 : 0; if (_mqtt_bridge) { _mqtt_bridge->updateConfig(_mqtt_config); } } const char* MyMesh::getMQTTStatus() const { if (!_mqtt_bridge) return "not initialized"; if (!_mqtt_config.enabled) return "disabled"; if (_mqtt_bridge->isConnected()) return "connected"; return "disconnected"; } const char* MyMesh::getEthernetStatus() const { switch (_eth_mgr.getState()) { case NetworkState::CONNECTED: return "connected"; case NetworkState::CONNECTING: return "connecting"; case NetworkState::ERROR: return "error"; default: return "disconnected"; } } IPAddress MyMesh::getEthernetIP() const { return _eth_mgr.getLocalIP(); } #endif // WITH_ETHERNET