iarv/Meck
1
0
Fork 1
mirror of https://github.com/pelgraine/Meck.git synced 2026-03-28 17:42:44 +01:00
Code Issues Packages Projects Releases Wiki Activity
Files
e91ad4bac49552311f56ee9bdb5b86c831b93ea4
Meck/examples/companion_radio/MyMesh.cpp

2814 lines
105 KiB
C++
Raw Blame History

This file contains ambiguous Unicode characters
This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.
#include "MyMesh.h"
#include <Arduino.h> // needed for PlatformIO
#include <Mesh.h>
#include "RadioPresets.h" // Shared radio presets (serial CLI + settings screen)
#ifdef HAS_4G_MODEM
#include "ModemManager.h" // Serial CLI modem commands
#endif
#define CMD_APP_START 1
#define CMD_SEND_TXT_MSG 2
#define CMD_SEND_CHANNEL_TXT_MSG 3
#define CMD_GET_CONTACTS 4 // with optional 'since' (for efficient sync)
#define CMD_GET_DEVICE_TIME 5
#define CMD_SET_DEVICE_TIME 6
#define CMD_SEND_SELF_ADVERT 7
#define CMD_SET_ADVERT_NAME 8
#define CMD_ADD_UPDATE_CONTACT 9
#define CMD_SYNC_NEXT_MESSAGE 10
#define CMD_SET_RADIO_PARAMS 11
#define CMD_SET_RADIO_TX_POWER 12
#define CMD_RESET_PATH 13
#define CMD_SET_ADVERT_LATLON 14
#define CMD_REMOVE_CONTACT 15
#define CMD_SHARE_CONTACT 16
#define CMD_EXPORT_CONTACT 17
#define CMD_IMPORT_CONTACT 18
#define CMD_REBOOT 19
#define CMD_GET_BATT_AND_STORAGE 20 // was CMD_GET_BATTERY_VOLTAGE
#define CMD_SET_TUNING_PARAMS 21
#define CMD_DEVICE_QEURY 22
#define CMD_EXPORT_PRIVATE_KEY 23
#define CMD_IMPORT_PRIVATE_KEY 24
#define CMD_SEND_RAW_DATA 25
#define CMD_SEND_LOGIN 26
#define CMD_SEND_STATUS_REQ 27
#define CMD_HAS_CONNECTION 28
#define CMD_LOGOUT 29 // 'Disconnect'
#define CMD_GET_CONTACT_BY_KEY 30
#define CMD_GET_CHANNEL 31
#define CMD_SET_CHANNEL 32
#define CMD_SIGN_START 33
#define CMD_SIGN_DATA 34
#define CMD_SIGN_FINISH 35
#define CMD_SEND_TRACE_PATH 36
#define CMD_SET_DEVICE_PIN 37
#define CMD_SET_OTHER_PARAMS 38
#define CMD_SEND_TELEMETRY_REQ 39 // can deprecate this
#define CMD_GET_CUSTOM_VARS 40
#define CMD_SET_CUSTOM_VAR 41
#define CMD_GET_ADVERT_PATH 42
#define CMD_GET_TUNING_PARAMS 43
// NOTE: CMD range 44..49 parked, potentially for WiFi operations
#define CMD_SEND_BINARY_REQ 50
#define CMD_FACTORY_RESET 51
#define CMD_SEND_PATH_DISCOVERY_REQ 52
#define CMD_SET_FLOOD_SCOPE 54 // v8+
#define CMD_SEND_CONTROL_DATA 55 // v8+
#define CMD_GET_STATS 56 // v8+, second byte is stats type
// Control data sub-types for active node discovery
#define CTL_TYPE_NODE_DISCOVER_REQ 0x80
#define CTL_TYPE_NODE_DISCOVER_RESP 0x90
#define CMD_SEND_ANON_REQ 57
#define CMD_SET_AUTOADD_CONFIG 58
#define CMD_GET_AUTOADD_CONFIG 59
// Stats sub-types for CMD_GET_STATS
#define STATS_TYPE_CORE 0
#define STATS_TYPE_RADIO 1
#define STATS_TYPE_PACKETS 2
#define RESP_CODE_OK 0
#define RESP_CODE_ERR 1
#define RESP_CODE_CONTACTS_START 2 // first reply to CMD_GET_CONTACTS
#define RESP_CODE_CONTACT 3 // multiple of these (after CMD_GET_CONTACTS)
#define RESP_CODE_END_OF_CONTACTS 4 // last reply to CMD_GET_CONTACTS
#define RESP_CODE_SELF_INFO 5 // reply to CMD_APP_START
#define RESP_CODE_SENT 6 // reply to CMD_SEND_TXT_MSG
#define RESP_CODE_CONTACT_MSG_RECV 7 // a reply to CMD_SYNC_NEXT_MESSAGE (ver < 3)
#define RESP_CODE_CHANNEL_MSG_RECV 8 // a reply to CMD_SYNC_NEXT_MESSAGE (ver < 3)
#define RESP_CODE_CURR_TIME 9 // a reply to CMD_GET_DEVICE_TIME
#define RESP_CODE_NO_MORE_MESSAGES 10 // a reply to CMD_SYNC_NEXT_MESSAGE
#define RESP_CODE_EXPORT_CONTACT 11
#define RESP_CODE_BATT_AND_STORAGE 12 // a reply to a CMD_GET_BATT_AND_STORAGE
#define RESP_CODE_DEVICE_INFO 13 // a reply to CMD_DEVICE_QEURY
#define RESP_CODE_PRIVATE_KEY 14 // a reply to CMD_EXPORT_PRIVATE_KEY
#define RESP_CODE_DISABLED 15
#define RESP_CODE_CONTACT_MSG_RECV_V3 16 // a reply to CMD_SYNC_NEXT_MESSAGE (ver >= 3)
#define RESP_CODE_CHANNEL_MSG_RECV_V3 17 // a reply to CMD_SYNC_NEXT_MESSAGE (ver >= 3)
#define RESP_CODE_CHANNEL_INFO 18 // a reply to CMD_GET_CHANNEL
#define RESP_CODE_SIGN_START 19
#define RESP_CODE_SIGNATURE 20
#define RESP_CODE_CUSTOM_VARS 21
#define RESP_CODE_ADVERT_PATH 22
#define RESP_CODE_TUNING_PARAMS 23
#define RESP_CODE_STATS 24 // v8+, second byte is stats type
#define RESP_CODE_AUTOADD_CONFIG 25
#define SEND_TIMEOUT_BASE_MILLIS 500
#define FLOOD_SEND_TIMEOUT_FACTOR 16.0f
#define DIRECT_SEND_PERHOP_FACTOR 6.0f
#define DIRECT_SEND_PERHOP_EXTRA_MILLIS 250
#define LAZY_CONTACTS_WRITE_DELAY 5000
#define PUBLIC_GROUP_PSK "izOH6cXN6mrJ5e26oRXNcg=="
// these are _pushed_ to client app at any time
#define PUSH_CODE_ADVERT 0x80
#define PUSH_CODE_PATH_UPDATED 0x81
#define PUSH_CODE_SEND_CONFIRMED 0x82
#define PUSH_CODE_MSG_WAITING 0x83
#define PUSH_CODE_RAW_DATA 0x84
#define PUSH_CODE_LOGIN_SUCCESS 0x85
#define PUSH_CODE_LOGIN_FAIL 0x86
#define PUSH_CODE_STATUS_RESPONSE 0x87
#define PUSH_CODE_LOG_RX_DATA 0x88
#define PUSH_CODE_TRACE_DATA 0x89
#define PUSH_CODE_NEW_ADVERT 0x8A
#define PUSH_CODE_TELEMETRY_RESPONSE 0x8B
#define PUSH_CODE_BINARY_RESPONSE 0x8C
#define PUSH_CODE_PATH_DISCOVERY_RESPONSE 0x8D
#define PUSH_CODE_CONTROL_DATA 0x8E // v8+
#define PUSH_CODE_CONTACT_DELETED 0x8F // used to notify client app of deleted contact when overwriting oldest
#define PUSH_CODE_CONTACTS_FULL 0x90 // used to notify client app that contacts storage is full
#define ERR_CODE_UNSUPPORTED_CMD 1
#define ERR_CODE_NOT_FOUND 2
#define ERR_CODE_TABLE_FULL 3
#define ERR_CODE_BAD_STATE 4
#define ERR_CODE_FILE_IO_ERROR 5
#define ERR_CODE_ILLEGAL_ARG 6
#define MAX_SIGN_DATA_LEN (8 * 1024) // 8K
// Auto-add config bitmask
// Bit 0: If set, overwrite oldest non-favourite contact when contacts file is full
// Bits 1-4: these indicate which contact types to auto-add when manual_contact_mode = 0x01
#define AUTO_ADD_OVERWRITE_OLDEST (1 << 0) // 0x01 - overwrite oldest non-favourite when full
#define AUTO_ADD_CHAT (1 << 1) // 0x02 - auto-add Chat (Companion) (ADV_TYPE_CHAT)
#define AUTO_ADD_REPEATER (1 << 2) // 0x04 - auto-add Repeater (ADV_TYPE_REPEATER)
#define AUTO_ADD_ROOM_SERVER (1 << 3) // 0x08 - auto-add Room Server (ADV_TYPE_ROOM)
#define AUTO_ADD_SENSOR (1 << 4) // 0x10 - auto-add Sensor (ADV_TYPE_SENSOR)
void MyMesh::writeOKFrame() {
uint8_t buf[1];
buf[0] = RESP_CODE_OK;
_serial->writeFrame(buf, 1);
}
void MyMesh::writeErrFrame(uint8_t err_code) {
uint8_t buf[2];
buf[0] = RESP_CODE_ERR;
buf[1] = err_code;
_serial->writeFrame(buf, 2);
}
void MyMesh::writeDisabledFrame() {
uint8_t buf[1];
buf[0] = RESP_CODE_DISABLED;
_serial->writeFrame(buf, 1);
}
void MyMesh::writeContactRespFrame(uint8_t code, const ContactInfo &contact) {
int i = 0;
out_frame[i++] = code;
memcpy(&out_frame[i], contact.id.pub_key, PUB_KEY_SIZE);
i += PUB_KEY_SIZE;
out_frame[i++] = contact.type;
out_frame[i++] = contact.flags;
out_frame[i++] = contact.out_path_len;
memcpy(&out_frame[i], contact.out_path, MAX_PATH_SIZE);
i += MAX_PATH_SIZE;
StrHelper::strzcpy((char *)&out_frame[i], contact.name, 32);
i += 32;
memcpy(&out_frame[i], &contact.last_advert_timestamp, 4);
i += 4;
memcpy(&out_frame[i], &contact.gps_lat, 4);
i += 4;
memcpy(&out_frame[i], &contact.gps_lon, 4);
i += 4;
memcpy(&out_frame[i], &contact.lastmod, 4);
i += 4;
_serial->writeFrame(out_frame, i);
}
void MyMesh::updateContactFromFrame(ContactInfo &contact, uint32_t& last_mod, const uint8_t *frame, int len) {
int i = 0;
uint8_t code = frame[i++]; // eg. CMD_ADD_UPDATE_CONTACT
memcpy(contact.id.pub_key, &frame[i], PUB_KEY_SIZE);
i += PUB_KEY_SIZE;
contact.type = frame[i++];
contact.flags = frame[i++];
contact.out_path_len = frame[i++];
memcpy(contact.out_path, &frame[i], MAX_PATH_SIZE);
i += MAX_PATH_SIZE;
memcpy(contact.name, &frame[i], 32);
i += 32;
memcpy(&contact.last_advert_timestamp, &frame[i], 4);
i += 4;
if (len >= i + 8) { // optional fields
memcpy(&contact.gps_lat, &frame[i], 4);
i += 4;
memcpy(&contact.gps_lon, &frame[i], 4);
i += 4;
if (len >= i + 4) {
memcpy(&last_mod, &frame[i], 4);
}
}
}
bool MyMesh::Frame::isChannelMsg() const {
return buf[0] == RESP_CODE_CHANNEL_MSG_RECV || buf[0] == RESP_CODE_CHANNEL_MSG_RECV_V3;
}
void MyMesh::addToOfflineQueue(const uint8_t frame[], int len) {
if (offline_queue_len >= OFFLINE_QUEUE_SIZE) {
MESH_DEBUG_PRINTLN("WARN: offline_queue is full!");
int pos = 0;
while (pos < offline_queue_len) {
if (offline_queue[pos].isChannelMsg()) {
for (int i = pos; i < offline_queue_len - 1; i++) { // delete oldest channel msg from queue
offline_queue[i] = offline_queue[i + 1];
}
MESH_DEBUG_PRINTLN("INFO: removed oldest channel message from queue.");
offline_queue[offline_queue_len - 1].len = len;
memcpy(offline_queue[offline_queue_len - 1].buf, frame, len);
return;
}
pos++;
}
MESH_DEBUG_PRINTLN("INFO: no channel messages to remove from queue.");
} else {
offline_queue[offline_queue_len].len = len;
memcpy(offline_queue[offline_queue_len].buf, frame, len);
offline_queue_len++;
}
}
int MyMesh::getFromOfflineQueue(uint8_t frame[]) {
if (offline_queue_len > 0) { // check offline queue
size_t len = offline_queue[0].len; // take from top of queue
memcpy(frame, offline_queue[0].buf, len);
offline_queue_len--;
for (int i = 0; i < offline_queue_len; i++) { // delete top item from queue
offline_queue[i] = offline_queue[i + 1];
}
return len;
}
return 0; // queue is empty
}
float MyMesh::getAirtimeBudgetFactor() const {
return _prefs.airtime_factor;
}
int MyMesh::getInterferenceThreshold() const {
return 0; // disabled for now, until currentRSSI() problem is resolved
}
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);
}
uint8_t MyMesh::getExtraAckTransmitCount() const {
return _prefs.multi_acks;
}
void MyMesh::logRxRaw(float snr, float rssi, const uint8_t raw[], int len) {
if (_serial->isConnected() && len + 3 <= MAX_FRAME_SIZE) {
int i = 0;
out_frame[i++] = PUSH_CODE_LOG_RX_DATA;
out_frame[i++] = (int8_t)(snr * 4);
out_frame[i++] = (int8_t)(rssi);
memcpy(&out_frame[i], raw, len);
i += len;
_serial->writeFrame(out_frame, i);
}
}
bool MyMesh::isAutoAddEnabled() const {
return (_prefs.manual_add_contacts & 1) == 0;
}
bool MyMesh::shouldAutoAddContactType(uint8_t contact_type) const {
if ((_prefs.manual_add_contacts & 1) == 0) {
return true;
}
uint8_t type_bit = 0;
switch (contact_type) {
case ADV_TYPE_CHAT:
type_bit = AUTO_ADD_CHAT;
break;
case ADV_TYPE_REPEATER:
type_bit = AUTO_ADD_REPEATER;
break;
case ADV_TYPE_ROOM:
type_bit = AUTO_ADD_ROOM_SERVER;
break;
case ADV_TYPE_SENSOR:
type_bit = AUTO_ADD_SENSOR;
break;
default:
return false; // Unknown type, don't auto-add
}
return (_prefs.autoadd_config & type_bit) != 0;
}
bool MyMesh::shouldOverwriteWhenFull() const {
return (_prefs.autoadd_config & AUTO_ADD_OVERWRITE_OLDEST) != 0;
}
void MyMesh::onContactOverwrite(const uint8_t* pub_key) {
if (_serial->isConnected()) {
out_frame[0] = PUSH_CODE_CONTACT_DELETED;
memcpy(&out_frame[1], pub_key, PUB_KEY_SIZE);
_serial->writeFrame(out_frame, 1 + PUB_KEY_SIZE);
}
}
void MyMesh::onContactsFull() {
if (_serial->isConnected()) {
out_frame[0] = PUSH_CODE_CONTACTS_FULL;
_serial->writeFrame(out_frame, 1);
}
}
void MyMesh::onDiscoveredContact(ContactInfo &contact, bool is_new, uint8_t path_len, const uint8_t* path) {
if (_serial->isConnected()) {
if (is_new) {
writeContactRespFrame(PUSH_CODE_NEW_ADVERT, contact);
} else {
out_frame[0] = PUSH_CODE_ADVERT;
memcpy(&out_frame[1], contact.id.pub_key, PUB_KEY_SIZE);
_serial->writeFrame(out_frame, 1 + PUB_KEY_SIZE);
}
}
#ifdef DISPLAY_CLASS
if (_ui && !_prefs.buzzer_quiet) _ui->notify(UIEventType::newContactMessage); //buzz if enabled
#endif
// add inbound-path to mem cache
if (path && path_len <= sizeof(AdvertPath::path)) { // check path is valid
AdvertPath* p = advert_paths;
uint32_t oldest = 0xFFFFFFFF;
for (int i = 0; i < ADVERT_PATH_TABLE_SIZE; i++) { // check if already in table, otherwise evict oldest
if (memcmp(advert_paths[i].pubkey_prefix, contact.id.pub_key, sizeof(AdvertPath::pubkey_prefix)) == 0) {
p = &advert_paths[i]; // found
break;
}
if (advert_paths[i].recv_timestamp < oldest) {
oldest = advert_paths[i].recv_timestamp;
p = &advert_paths[i];
}
}
memcpy(p->pubkey_prefix, contact.id.pub_key, sizeof(p->pubkey_prefix));
strcpy(p->name, contact.name);
p->recv_timestamp = getRTCClock()->getCurrentTime();
p->path_len = path_len;
memcpy(p->path, path, p->path_len);
}
// Buffer for on-device discovery UI
if (_discoveryActive && _discoveredCount < MAX_DISCOVERED_NODES) {
bool dup = false;
for (int i = 0; i < _discoveredCount; i++) {
if (contact.id.matches(_discovered[i].contact.id)) {
// Update existing entry with fresher data
_discovered[i].contact = contact;
_discovered[i].path_len = path_len;
_discovered[i].already_in_contacts = !is_new;
// Preserve snr if already set by active discovery response
dup = true;
Serial.printf("[Discovery] Updated: %s (hops=%d)\n", contact.name, path_len);
break;
}
}
if (!dup) {
_discovered[_discoveredCount].contact = contact;
_discovered[_discoveredCount].path_len = path_len;
_discovered[_discoveredCount].snr = 0; // no SNR from passive advert
_discovered[_discoveredCount].already_in_contacts = !is_new;
_discoveredCount++;
Serial.printf("[Discovery] Found: %s (hops=%d, is_new=%d, total=%d)\n",
contact.name, path_len, is_new, _discoveredCount);
}
}
if (!is_new) dirty_contacts_expiry = futureMillis(LAZY_CONTACTS_WRITE_DELAY); // only schedule lazy write for contacts that are in contacts[]
}
static int sort_by_recent(const void *a, const void *b) {
return ((AdvertPath *) b)->recv_timestamp - ((AdvertPath *) a)->recv_timestamp;
}
int MyMesh::getRecentlyHeard(AdvertPath dest[], int max_num) {
if (max_num > ADVERT_PATH_TABLE_SIZE) max_num = ADVERT_PATH_TABLE_SIZE;
qsort(advert_paths, ADVERT_PATH_TABLE_SIZE, sizeof(advert_paths[0]), sort_by_recent);
for (int i = 0; i < max_num; i++) {
dest[i] = advert_paths[i];
}
return max_num;
}
void MyMesh::onContactPathUpdated(const ContactInfo &contact) {
out_frame[0] = PUSH_CODE_PATH_UPDATED;
memcpy(&out_frame[1], contact.id.pub_key, PUB_KEY_SIZE);
_serial->writeFrame(out_frame, 1 + PUB_KEY_SIZE); // NOTE: app may not be connected
dirty_contacts_expiry = futureMillis(LAZY_CONTACTS_WRITE_DELAY);
}
ContactInfo* MyMesh::processAck(const uint8_t *data) {
// see if matches any in a table
for (int i = 0; i < EXPECTED_ACK_TABLE_SIZE; i++) {
if (memcmp(data, &expected_ack_table[i].ack, 4) == 0) { // got an ACK from recipient
out_frame[0] = PUSH_CODE_SEND_CONFIRMED;
memcpy(&out_frame[1], data, 4);
uint32_t trip_time = _ms->getMillis() - expected_ack_table[i].msg_sent;
memcpy(&out_frame[5], &trip_time, 4);
_serial->writeFrame(out_frame, 9);
// NOTE: the same ACK can be received multiple times!
expected_ack_table[i].ack = 0; // clear expected hash, now that we have received ACK
return expected_ack_table[i].contact;
}
}
return checkConnectionsAck(data);
}
void MyMesh::queueMessage(const ContactInfo &from, uint8_t txt_type, mesh::Packet *pkt,
uint32_t sender_timestamp, const uint8_t *extra, int extra_len, const char *text) {
int i = 0;
if (app_target_ver >= 3) {
out_frame[i++] = RESP_CODE_CONTACT_MSG_RECV_V3;
out_frame[i++] = (int8_t)(pkt->getSNR() * 4);
out_frame[i++] = 0; // reserved1
out_frame[i++] = 0; // reserved2
} else {
out_frame[i++] = RESP_CODE_CONTACT_MSG_RECV;
}
memcpy(&out_frame[i], from.id.pub_key, 6);
i += 6; // just 6-byte prefix
uint8_t path_len = out_frame[i++] = pkt->isRouteFlood() ? pkt->path_len : 0xFF;
out_frame[i++] = txt_type;
memcpy(&out_frame[i], &sender_timestamp, 4);
i += 4;
if (extra_len > 0) {
memcpy(&out_frame[i], extra, extra_len);
i += extra_len;
}
int tlen = strlen(text); // TODO: UTF-8 ??
if (i + tlen > MAX_FRAME_SIZE) {
tlen = MAX_FRAME_SIZE - i;
}
memcpy(&out_frame[i], text, tlen);
i += tlen;
addToOfflineQueue(out_frame, i);
if (_serial->isConnected()) {
uint8_t frame[1];
frame[0] = PUSH_CODE_MSG_WAITING; // send push 'tickle'
_serial->writeFrame(frame, 1);
}
#ifdef DISPLAY_CLASS
// we only want to show text messages on display, not cli data
bool should_display = txt_type == TXT_TYPE_PLAIN || txt_type == TXT_TYPE_SIGNED_PLAIN;
if (should_display && _ui) {
const uint8_t* msg_path = (pkt->isRouteFlood() && pkt->path_len > 0) ? pkt->path : nullptr;
_ui->newMsg(path_len, from.name, text, offline_queue_len, msg_path);
if (!_prefs.buzzer_quiet) _ui->notify(UIEventType::contactMessage); //buzz if enabled
}
#endif
}
bool MyMesh::filterRecvFloodPacket(mesh::Packet* packet) {
// Check if this incoming flood packet is a repeat of a message we recently sent
if (packet->payload_len >= SENT_FINGERPRINT_SIZE) {
unsigned long now = millis();
for (int i = 0; i < SENT_TRACK_SIZE; i++) {
SentMsgTrack* t = &_sent_track[i];
if (!t->active) continue;
// Expire old entries
if ((now - t->sent_millis) > SENT_TRACK_EXPIRY_MS) {
t->active = false;
continue;
}
// Compare payload fingerprint
if (memcmp(packet->payload, t->fingerprint, SENT_FINGERPRINT_SIZE) == 0) {
t->repeat_count++;
MESH_DEBUG_PRINTLN("SentTrack: heard repeat #%d (SNR=%.1f)", t->repeat_count, packet->getSNR());
#ifdef DISPLAY_CLASS
if (_ui) {
char buf[40];
snprintf(buf, sizeof(buf), "Sent! (%d)", t->repeat_count);
_ui->showAlert(buf, 2000); // show/extend alert with updated count
}
#endif
break; // found match, no need to check other entries
}
}
}
return false; // never filter — let normal processing continue
}
void MyMesh::sendFloodScoped(const ContactInfo& recipient, mesh::Packet* pkt, uint32_t delay_millis) {
// TODO: dynamic send_scope, depending on recipient and current 'home' Region
if (send_scope.isNull()) {
sendFlood(pkt, delay_millis);
} else {
uint16_t codes[2];
codes[0] = send_scope.calcTransportCode(pkt);
codes[1] = 0; // REVISIT: set to 'home' Region, for sender/return region?
sendFlood(pkt, codes, delay_millis);
}
}
void MyMesh::sendFloodScoped(const mesh::GroupChannel& channel, mesh::Packet* pkt, uint32_t delay_millis) {
// Capture payload fingerprint for repeat tracking before sending
if (pkt->payload_len >= SENT_FINGERPRINT_SIZE) {
SentMsgTrack* t = &_sent_track[_sent_track_idx];
memcpy(t->fingerprint, pkt->payload, SENT_FINGERPRINT_SIZE);
t->repeat_count = 0;
t->sent_millis = millis();
t->active = true;
_sent_track_idx = (_sent_track_idx + 1) % SENT_TRACK_SIZE;
MESH_DEBUG_PRINTLN("SentTrack: captured fingerprint for channel msg");
}
// TODO: have per-channel send_scope
if (send_scope.isNull()) {
sendFlood(pkt, delay_millis);
} else {
uint16_t codes[2];
codes[0] = send_scope.calcTransportCode(pkt);
codes[1] = 0; // REVISIT: set to 'home' Region, for sender/return region?
sendFlood(pkt, codes, delay_millis);
}
}
void MyMesh::onMessageRecv(const ContactInfo &from, mesh::Packet *pkt, uint32_t sender_timestamp,
const char *text) {
markConnectionActive(from); // in case this is from a server, and we have a connection
queueMessage(from, TXT_TYPE_PLAIN, pkt, sender_timestamp, NULL, 0, text);
}
void MyMesh::onCommandDataRecv(const ContactInfo &from, mesh::Packet *pkt, uint32_t sender_timestamp,
const char *text) {
markConnectionActive(from); // in case this is from a server, and we have a connection
queueMessage(from, TXT_TYPE_CLI_DATA, pkt, sender_timestamp, NULL, 0, text);
// Forward CLI response to UI admin screen if admin session is active
#ifdef DISPLAY_CLASS
if (_admin_contact_idx >= 0 && _ui) {
_ui->onAdminCliResponse(from.name, text);
}
#endif
}
void MyMesh::onSignedMessageRecv(const ContactInfo &from, mesh::Packet *pkt, uint32_t sender_timestamp,
const uint8_t *sender_prefix, const char *text) {
markConnectionActive(from);
// from.sync_since change needs to be persisted
dirty_contacts_expiry = futureMillis(LAZY_CONTACTS_WRITE_DELAY);
queueMessage(from, TXT_TYPE_SIGNED_PLAIN, pkt, sender_timestamp, sender_prefix, 4, text);
}
void MyMesh::onChannelMessageRecv(const mesh::GroupChannel &channel, mesh::Packet *pkt, uint32_t timestamp,
const char *text) {
int i = 0;
if (app_target_ver >= 3) {
out_frame[i++] = RESP_CODE_CHANNEL_MSG_RECV_V3;
out_frame[i++] = (int8_t)(pkt->getSNR() * 4);
out_frame[i++] = 0; // reserved1
out_frame[i++] = 0; // reserved2
} else {
out_frame[i++] = RESP_CODE_CHANNEL_MSG_RECV;
}
uint8_t channel_idx = findChannelIdx(channel);
out_frame[i++] = channel_idx;
uint8_t path_len = out_frame[i++] = pkt->isRouteFlood() ? pkt->path_len : 0xFF;
out_frame[i++] = TXT_TYPE_PLAIN;
memcpy(&out_frame[i], &timestamp, 4);
i += 4;
int tlen = strlen(text); // TODO: UTF-8 ??
if (i + tlen > MAX_FRAME_SIZE) {
tlen = MAX_FRAME_SIZE - i;
}
memcpy(&out_frame[i], text, tlen);
i += tlen;
addToOfflineQueue(out_frame, i);
if (_serial->isConnected()) {
uint8_t frame[1];
frame[0] = PUSH_CODE_MSG_WAITING; // send push 'tickle'
_serial->writeFrame(frame, 1);
}
#ifdef DISPLAY_CLASS
// Get the channel name from the channel index
const char *channel_name = "Unknown";
ChannelDetails channel_details;
if (getChannel(channel_idx, channel_details)) {
channel_name = channel_details.name;
}
if (_ui) {
const uint8_t* msg_path = (pkt->isRouteFlood() && pkt->path_len > 0) ? pkt->path : nullptr;
_ui->newMsg(path_len, channel_name, text, offline_queue_len, msg_path);
if (!_prefs.buzzer_quiet) _ui->notify(UIEventType::channelMessage); //buzz if enabled
}
#endif
}
void MyMesh::queueSentChannelMessage(uint8_t channel_idx, uint32_t timestamp, const char* sender, const char* text) {
// Format message the same way as onChannelMessageRecv for BLE app sync
// This allows sent messages from device keyboard to appear in the app
int i = 0;
if (app_target_ver >= 3) {
out_frame[i++] = RESP_CODE_CHANNEL_MSG_RECV_V3;
out_frame[i++] = 0; // SNR not applicable for sent messages
out_frame[i++] = 0; // reserved1
out_frame[i++] = 0; // reserved2
} else {
out_frame[i++] = RESP_CODE_CHANNEL_MSG_RECV;
}
out_frame[i++] = channel_idx;
out_frame[i++] = 0; // path_len = 0 indicates local/sent message
out_frame[i++] = TXT_TYPE_PLAIN;
memcpy(&out_frame[i], &timestamp, 4);
i += 4;
// Format as "sender: text" like the app expects
char formatted[MAX_FRAME_SIZE];
snprintf(formatted, sizeof(formatted), "%s: %s", sender, text);
int tlen = strlen(formatted);
if (i + tlen > MAX_FRAME_SIZE) {
tlen = MAX_FRAME_SIZE - i;
}
memcpy(&out_frame[i], formatted, tlen);
i += tlen;
addToOfflineQueue(out_frame, i);
// If app is connected, send push notification
if (_serial->isConnected()) {
uint8_t frame[1];
frame[0] = PUSH_CODE_MSG_WAITING;
_serial->writeFrame(frame, 1);
}
}
bool MyMesh::uiSendDirectMessage(uint32_t contact_idx, const char* text) {
ContactInfo contact;
if (!getContactByIdx(contact_idx, contact)) return false;
ContactInfo* recipient = lookupContactByPubKey(contact.id.pub_key, PUB_KEY_SIZE);
if (!recipient) return false;
uint32_t timestamp = getRTCClock()->getCurrentTimeUnique();
uint32_t expected_ack, est_timeout;
int result = sendMessage(*recipient, timestamp, 0, text, expected_ack, est_timeout);
if (result == MSG_SEND_FAILED) {
MESH_DEBUG_PRINTLN("UI: DM send failed to %s", recipient->name);
return false;
}
// Track expected ACK for delivery confirmation
if (expected_ack) {
expected_ack_table[next_ack_idx].msg_sent = _ms->getMillis();
expected_ack_table[next_ack_idx].ack = expected_ack;
expected_ack_table[next_ack_idx].contact = recipient;
next_ack_idx = (next_ack_idx + 1) % EXPECTED_ACK_TABLE_SIZE;
}
MESH_DEBUG_PRINTLN("UI: DM sent to %s (%s), ack=0x%08X timeout=%dms",
recipient->name, result == MSG_SEND_SENT_FLOOD ? "flood" : "direct",
expected_ack, est_timeout);
return true;
}
bool MyMesh::uiLoginToRepeater(uint32_t contact_idx, const char* password, uint32_t& est_timeout_ms) {
ContactInfo contact;
if (!getContactByIdx(contact_idx, contact)) return false;
ContactInfo* recipient = lookupContactByPubKey(contact.id.pub_key, PUB_KEY_SIZE);
if (!recipient) return false;
// Force flood routing for login — a mobile repeater's direct path may be stale.
// The companion protocol does the same for telemetry requests.
int8_t save_path_len = recipient->out_path_len;
recipient->out_path_len = -1;
int result = sendLogin(*recipient, password, est_timeout_ms);
recipient->out_path_len = save_path_len; // restore
if (result == MSG_SEND_FAILED) {
MESH_DEBUG_PRINTLN("UI: Admin login send failed to %s", recipient->name);
est_timeout_ms = 0;
return false;
}
clearPendingReqs();
memcpy(&pending_login, recipient->id.pub_key, 4);
_admin_contact_idx = contact_idx;
MESH_DEBUG_PRINTLN("UI: Admin login sent to %s (flood, was path_len=%d), timeout=%dms",
recipient->name, (int)save_path_len, est_timeout_ms);
return true;
}
bool MyMesh::uiSendCliCommand(uint32_t contact_idx, const char* command) {
ContactInfo contact;
if (!getContactByIdx(contact_idx, contact)) return false;
ContactInfo* recipient = lookupContactByPubKey(contact.id.pub_key, PUB_KEY_SIZE);
if (!recipient) return false;
uint32_t timestamp = getRTCClock()->getCurrentTimeUnique();
uint32_t est_timeout;
int result = sendCommandData(*recipient, timestamp, 0, command, est_timeout);
if (result == MSG_SEND_FAILED) {
MESH_DEBUG_PRINTLN("UI: CLI command send failed to %s: %s", recipient->name, command);
return false;
}
_admin_contact_idx = contact_idx;
MESH_DEBUG_PRINTLN("UI: CLI command sent to %s (%s): %s, timeout=%dms",
recipient->name, result == MSG_SEND_SENT_FLOOD ? "flood" : "direct",
command, est_timeout);
return true;
}
bool MyMesh::uiSendTelemetryRequest(uint32_t contact_idx) {
ContactInfo contact;
if (!getContactByIdx(contact_idx, contact)) return false;
ContactInfo* recipient = lookupContactByPubKey(contact.id.pub_key, PUB_KEY_SIZE);
if (!recipient) return false;
uint32_t tag, est_timeout;
int result = sendRequest(*recipient, REQ_TYPE_GET_TELEMETRY_DATA, tag, est_timeout);
if (result == MSG_SEND_FAILED) {
MESH_DEBUG_PRINTLN("UI: Telemetry request send failed to %s", recipient->name);
return false;
}
clearPendingReqs();
pending_telemetry = tag;
MESH_DEBUG_PRINTLN("UI: Telemetry request sent to %s (%s), timeout=%dms",
recipient->name, result == MSG_SEND_SENT_FLOOD ? "flood" : "direct",
est_timeout);
return true;
}
uint8_t MyMesh::onContactRequest(const ContactInfo &contact, uint32_t sender_timestamp, const uint8_t *data,
uint8_t len, uint8_t *reply) {
if (data[0] == REQ_TYPE_GET_TELEMETRY_DATA) {
uint8_t permissions = 0;
uint8_t cp = contact.flags >> 1; // LSB used as 'favourite' bit (so only use upper bits)
if (_prefs.telemetry_mode_base == TELEM_MODE_ALLOW_ALL) {
permissions = TELEM_PERM_BASE;
} else if (_prefs.telemetry_mode_base == TELEM_MODE_ALLOW_FLAGS) {
permissions = cp & TELEM_PERM_BASE;
}
if (_prefs.telemetry_mode_loc == TELEM_MODE_ALLOW_ALL) {
permissions |= TELEM_PERM_LOCATION;
} else if (_prefs.telemetry_mode_loc == TELEM_MODE_ALLOW_FLAGS) {
permissions |= cp & TELEM_PERM_LOCATION;
}
if (_prefs.telemetry_mode_env == TELEM_MODE_ALLOW_ALL) {
permissions |= TELEM_PERM_ENVIRONMENT;
} else if (_prefs.telemetry_mode_env == TELEM_MODE_ALLOW_FLAGS) {
permissions |= cp & TELEM_PERM_ENVIRONMENT;
}
uint8_t perm_mask = ~(data[1]); // NEW: first reserved byte (of 4), is now inverse mask to apply to permissions
permissions &= perm_mask;
if (permissions & TELEM_PERM_BASE) { // only respond if base permission bit is set
telemetry.reset();
telemetry.addVoltage(TELEM_CHANNEL_SELF, (float)board.getBattMilliVolts() / 1000.0f);
// query other sensors -- target specific
sensors.querySensors(permissions, telemetry);
memcpy(reply, &sender_timestamp,
4); // reflect sender_timestamp back in response packet (kind of like a 'tag')
uint8_t tlen = telemetry.getSize();
memcpy(&reply[4], telemetry.getBuffer(), tlen);
return 4 + tlen;
}
}
return 0; // unknown
}
void MyMesh::onContactResponse(const ContactInfo &contact, const uint8_t *data, uint8_t len) {
uint32_t tag;
memcpy(&tag, data, 4);
if (pending_login && memcmp(&pending_login, contact.id.pub_key, 4) == 0) { // check for login response
// yes, is response to pending sendLogin()
pending_login = 0;
int i = 0;
if (memcmp(&data[4], "OK", 2) == 0) { // legacy Repeater login OK response
out_frame[i++] = PUSH_CODE_LOGIN_SUCCESS;
out_frame[i++] = 0; // legacy: is_admin = false
memcpy(&out_frame[i], contact.id.pub_key, 6);
i += 6; // pub_key_prefix
#ifdef DISPLAY_CLASS
// Notify UI of successful legacy login
if (_ui) _ui->onAdminLoginResult(true, 0, tag);
#endif
} else if (data[4] == RESP_SERVER_LOGIN_OK) { // new login response
uint16_t keep_alive_secs = ((uint16_t)data[5]) * 16;
if (keep_alive_secs > 0) {
startConnection(contact, keep_alive_secs);
}
out_frame[i++] = PUSH_CODE_LOGIN_SUCCESS;
out_frame[i++] = data[6]; // permissions (eg. is_admin)
memcpy(&out_frame[i], contact.id.pub_key, 6);
i += 6; // pub_key_prefix
memcpy(&out_frame[i], &tag, 4);
i += 4; // NEW: include server timestamp
out_frame[i++] = data[7]; // NEW (v7): ACL permissions
out_frame[i++] = data[12]; // FIRMWARE_VER_LEVEL
#ifdef DISPLAY_CLASS
// Notify UI of successful login
if (_ui) _ui->onAdminLoginResult(true, data[6], tag);
#endif
} else {
out_frame[i++] = PUSH_CODE_LOGIN_FAIL;
out_frame[i++] = 0; // reserved
memcpy(&out_frame[i], contact.id.pub_key, 6);
i += 6; // pub_key_prefix
#ifdef DISPLAY_CLASS
// Notify UI of login failure
if (_ui) _ui->onAdminLoginResult(false, 0, 0);
#endif
}
_serial->writeFrame(out_frame, i);
} else if (len > 4 && // check for status response
pending_status &&
memcmp(&pending_status, contact.id.pub_key, 4) == 0 // legacy matching scheme
// FUTURE: tag == pending_status
) {
pending_status = 0;
int i = 0;
out_frame[i++] = PUSH_CODE_STATUS_RESPONSE;
out_frame[i++] = 0; // reserved
memcpy(&out_frame[i], contact.id.pub_key, 6);
i += 6; // pub_key_prefix
memcpy(&out_frame[i], &data[4], len - 4);
i += (len - 4);
_serial->writeFrame(out_frame, i);
} else if (len > 4 && tag == pending_telemetry) { // check for matching response tag
pending_telemetry = 0;
MESH_DEBUG_PRINTLN("Telemetry response received from %s, len=%d", contact.name, len);
int i = 0;
out_frame[i++] = PUSH_CODE_TELEMETRY_RESPONSE;
out_frame[i++] = 0; // reserved
memcpy(&out_frame[i], contact.id.pub_key, 6);
i += 6; // pub_key_prefix
memcpy(&out_frame[i], &data[4], len - 4);
i += (len - 4);
_serial->writeFrame(out_frame, i);
#ifdef DISPLAY_CLASS
// Route telemetry data to UI (LPP buffer after the 4-byte tag)
if (_ui) _ui->onAdminTelemetryResult(&data[4], len - 4);
#endif
} else if (len > 4 && tag == pending_req) { // check for matching response tag
pending_req = 0;
int i = 0;
out_frame[i++] = PUSH_CODE_BINARY_RESPONSE;
out_frame[i++] = 0; // reserved
memcpy(&out_frame[i], &tag, 4); // app needs to match this to RESP_CODE_SENT.tag
i += 4;
memcpy(&out_frame[i], &data[4], len - 4);
i += (len - 4);
_serial->writeFrame(out_frame, i);
}
}
bool MyMesh::onContactPathRecv(ContactInfo& contact, uint8_t* in_path, uint8_t in_path_len, uint8_t* out_path, uint8_t out_path_len, uint8_t extra_type, uint8_t* extra, uint8_t extra_len) {
if (extra_type == PAYLOAD_TYPE_RESPONSE && extra_len > 4) {
uint32_t tag;
memcpy(&tag, extra, 4);
if (tag == pending_discovery) { // check for matching response tag)
pending_discovery = 0;
if (in_path_len > MAX_PATH_SIZE || out_path_len > MAX_PATH_SIZE) {
MESH_DEBUG_PRINTLN("onContactPathRecv, invalid path sizes: %d, %d", in_path_len, out_path_len);
} else {
int i = 0;
out_frame[i++] = PUSH_CODE_PATH_DISCOVERY_RESPONSE;
out_frame[i++] = 0; // reserved
memcpy(&out_frame[i], contact.id.pub_key, 6);
i += 6; // pub_key_prefix
out_frame[i++] = out_path_len;
memcpy(&out_frame[i], out_path, out_path_len);
i += out_path_len;
out_frame[i++] = in_path_len;
memcpy(&out_frame[i], in_path, in_path_len);
i += in_path_len;
// NOTE: telemetry data in 'extra' is discarded at present
_serial->writeFrame(out_frame, i);
}
return false; // DON'T send reciprocal path!
}
}
// let base class handle received path and data
return BaseChatMesh::onContactPathRecv(contact, in_path, in_path_len, out_path, out_path_len, extra_type, extra, extra_len);
}
void MyMesh::onControlDataRecv(mesh::Packet *packet) {
// --- Active discovery response interception ---
if (_discoveryActive && packet->payload_len >= 6) {
uint8_t resp_type = packet->payload[0] & 0xF0;
if (resp_type == CTL_TYPE_NODE_DISCOVER_RESP) {
uint8_t node_type = packet->payload[0] & 0x0F;
int8_t snr_scaled = (int8_t)packet->payload[1]; // SNR × 4 (how well repeater heard us)
uint32_t tag;
memcpy(&tag, &packet->payload[2], 4);
// Validate: tag must match ours AND payload must include full 32-byte pubkey
if (tag == _discoveryTag && packet->payload_len >= 6 + PUB_KEY_SIZE) {
const uint8_t* pubkey = &packet->payload[6];
// Dedup check against existing buffer entries (pre-seeded or earlier responses)
for (int i = 0; i < _discoveredCount; i++) {
if (_discovered[i].contact.id.matches(pubkey)) {
// Already in buffer — update SNR (active discovery data is fresher)
_discovered[i].snr = snr_scaled;
Serial.printf("[Discovery] Updated SNR for %s: %d\n",
_discovered[i].contact.name, snr_scaled);
return;
}
}
// New node — add if room
if (_discoveredCount < MAX_DISCOVERED_NODES) {
DiscoveredNode& node = _discovered[_discoveredCount];
memset(&node.contact, 0, sizeof(ContactInfo));
memcpy(node.contact.id.pub_key, pubkey, PUB_KEY_SIZE);
node.contact.type = node_type;
node.snr = snr_scaled;
node.path_len = packet->path_len;
// Try to resolve name from contacts table
ContactInfo* existing = lookupContactByPubKey(pubkey, PUB_KEY_SIZE);
if (existing) {
strncpy(node.contact.name, existing->name, sizeof(node.contact.name) - 1);
node.already_in_contacts = true;
} else {
// Show hex prefix as placeholder name
snprintf(node.contact.name, sizeof(node.contact.name),
"%02X%02X%02X%02X",
pubkey[0], pubkey[1], pubkey[2], pubkey[3]);
node.already_in_contacts = false;
}
_discoveredCount++;
Serial.printf("[Discovery] Active response: %s type=%d snr=%d hops=%d (total=%d)\n",
node.contact.name, node_type, snr_scaled, packet->path_len, _discoveredCount);
}
}
return; // consumed — don't forward discovery responses to BLE
}
}
// --- Original BLE forwarding for non-discovery control data ---
if (packet->payload_len + 4 > sizeof(out_frame)) {
MESH_DEBUG_PRINTLN("onControlDataRecv(), payload_len too long: %d", packet->payload_len);
return;
}
int i = 0;
out_frame[i++] = PUSH_CODE_CONTROL_DATA;
out_frame[i++] = (int8_t)(_radio->getLastSNR() * 4);
out_frame[i++] = (int8_t)(_radio->getLastRSSI());
out_frame[i++] = packet->path_len;
memcpy(&out_frame[i], packet->payload, packet->payload_len);
i += packet->payload_len;
if (_serial->isConnected()) {
_serial->writeFrame(out_frame, i);
} else {
MESH_DEBUG_PRINTLN("onControlDataRecv(), data received while app offline");
}
}
void MyMesh::onRawDataRecv(mesh::Packet *packet) {
if (packet->payload_len + 4 > sizeof(out_frame)) {
MESH_DEBUG_PRINTLN("onRawDataRecv(), payload_len too long: %d", packet->payload_len);
return;
}
int i = 0;
out_frame[i++] = PUSH_CODE_RAW_DATA;
out_frame[i++] = (int8_t)(_radio->getLastSNR() * 4);
out_frame[i++] = (int8_t)(_radio->getLastRSSI());
out_frame[i++] = 0xFF; // reserved (possibly path_len in future)
memcpy(&out_frame[i], packet->payload, packet->payload_len);
i += packet->payload_len;
if (_serial->isConnected()) {
_serial->writeFrame(out_frame, i);
} else {
MESH_DEBUG_PRINTLN("onRawDataRecv(), data received while app offline");
}
}
void MyMesh::onTraceRecv(mesh::Packet *packet, uint32_t tag, uint32_t auth_code, uint8_t flags,
const uint8_t *path_snrs, const uint8_t *path_hashes, uint8_t path_len) {
uint8_t path_sz = flags & 0x03; // NEW v1.11+
if (12 + path_len + (path_len >> path_sz) + 1 > sizeof(out_frame)) {
MESH_DEBUG_PRINTLN("onTraceRecv(), path_len is too long: %d", (uint32_t)path_len);
return;
}
int i = 0;
out_frame[i++] = PUSH_CODE_TRACE_DATA;
out_frame[i++] = 0; // reserved
out_frame[i++] = path_len;
out_frame[i++] = flags;
memcpy(&out_frame[i], &tag, 4);
i += 4;
memcpy(&out_frame[i], &auth_code, 4);
i += 4;
memcpy(&out_frame[i], path_hashes, path_len);
i += path_len;
memcpy(&out_frame[i], path_snrs, path_len >> path_sz);
i += path_len >> path_sz;
out_frame[i++] = (int8_t)(packet->getSNR() * 4); // extra/final SNR (to this node)
if (_serial->isConnected()) {
_serial->writeFrame(out_frame, i);
} else {
MESH_DEBUG_PRINTLN("onTraceRecv(), data received while app offline");
}
}
uint32_t MyMesh::calcFloodTimeoutMillisFor(uint32_t pkt_airtime_millis) const {
return SEND_TIMEOUT_BASE_MILLIS + (FLOOD_SEND_TIMEOUT_FACTOR * pkt_airtime_millis);
}
uint32_t MyMesh::calcDirectTimeoutMillisFor(uint32_t pkt_airtime_millis, uint8_t path_len) const {
return SEND_TIMEOUT_BASE_MILLIS +
((pkt_airtime_millis * DIRECT_SEND_PERHOP_FACTOR + DIRECT_SEND_PERHOP_EXTRA_MILLIS) *
(path_len + 1));
}
void MyMesh::onSendTimeout() {}
MyMesh::MyMesh(mesh::Radio &radio, mesh::RNG &rng, mesh::RTCClock &rtc, SimpleMeshTables &tables, DataStore& store, AbstractUITask* ui)
: BaseChatMesh(radio, *new ArduinoMillis(), rng, rtc, *new StaticPoolPacketManager(16), tables),
_serial(NULL), telemetry(MAX_PACKET_PAYLOAD - 4), _store(&store), _ui(ui) {
_iter_started = false;
_cli_rescue = false;
offline_queue_len = 0;
app_target_ver = 0;
clearPendingReqs();
next_ack_idx = 0;
sign_data = NULL;
dirty_contacts_expiry = 0;
memset(advert_paths, 0, sizeof(advert_paths));
memset(send_scope.key, 0, sizeof(send_scope.key));
memset(_sent_track, 0, sizeof(_sent_track));
_sent_track_idx = 0;
_admin_contact_idx = -1;
_discoveredCount = 0;
_discoveryActive = false;
_discoveryTimeout = 0;
_discoveryTag = 0;
// defaults
memset(&_prefs, 0, sizeof(_prefs));
_prefs.airtime_factor = 1.0; // one half
strcpy(_prefs.node_name, "NONAME");
_prefs.freq = LORA_FREQ;
_prefs.sf = LORA_SF;
_prefs.bw = LORA_BW;
_prefs.cr = LORA_CR;
_prefs.tx_power_dbm = LORA_TX_POWER;
_prefs.buzzer_quiet = 0;
_prefs.gps_enabled = 0; // GPS disabled by default
_prefs.gps_interval = 0; // No automatic GPS updates by default
//_prefs.rx_delay_base = 10.0f; enable once new algo fixed
}
void MyMesh::begin(bool has_display) {
BaseChatMesh::begin();
if (!_store->loadMainIdentity(self_id)) {
self_id = radio_new_identity(); // create new random identity
int count = 0;
while (count < 10 && (self_id.pub_key[0] == 0x00 || self_id.pub_key[0] == 0xFF)) { // reserved id hashes
self_id = radio_new_identity();
count++;
}
_store->saveMainIdentity(self_id);
}
// if name is provided as a build flag, use that as default node name instead
#ifdef ADVERT_NAME
strcpy(_prefs.node_name, ADVERT_NAME);
#else
// use hex of first 4 bytes of identity public key as default node name
char pub_key_hex[10];
mesh::Utils::toHex(pub_key_hex, self_id.pub_key, 4);
strcpy(_prefs.node_name, pub_key_hex);
#endif
// load persisted prefs
_store->loadPrefs(_prefs, sensors.node_lat, sensors.node_lon);
// sanitise bad pref values
_prefs.rx_delay_base = constrain(_prefs.rx_delay_base, 0, 20.0f);
_prefs.airtime_factor = constrain(_prefs.airtime_factor, 0, 9.0f);
_prefs.freq = constrain(_prefs.freq, 400.0f, 2500.0f);
_prefs.bw = constrain(_prefs.bw, 7.8f, 500.0f);
_prefs.sf = constrain(_prefs.sf, 5, 12);
_prefs.cr = constrain(_prefs.cr, 5, 8);
_prefs.tx_power_dbm = constrain(_prefs.tx_power_dbm, 1, MAX_LORA_TX_POWER);
_prefs.buzzer_quiet = constrain(_prefs.buzzer_quiet, 0, 1); // Ensure boolean 0 or 1
_prefs.gps_enabled = constrain(_prefs.gps_enabled, 0, 1); // Ensure boolean 0 or 1
_prefs.gps_interval = constrain(_prefs.gps_interval, 0, 86400); // Max 24 hours
_prefs.utc_offset_hours = constrain(_prefs.utc_offset_hours, -12, 14); // Valid timezone range
#ifdef BLE_PIN_CODE // 123456 by default
if (_prefs.ble_pin == 0) {
#ifdef DISPLAY_CLASS
if (has_display && BLE_PIN_CODE == 123456) {
StdRNG rng;
_active_ble_pin = rng.nextInt(100000, 999999); // random pin each session
} else {
_active_ble_pin = BLE_PIN_CODE; // otherwise static pin
}
#else
_active_ble_pin = BLE_PIN_CODE; // otherwise static pin
#endif
} else {
_active_ble_pin = _prefs.ble_pin;
}
#else
_active_ble_pin = 0;
#endif
initContacts(); // allocate contacts array from PSRAM (deferred from constructor)
resetContacts();
_store->loadContacts(this);
bootstrapRTCfromContacts();
addChannel("Public", PUBLIC_GROUP_PSK); // pre-configure Andy's public channel
_store->loadChannels(this);
radio_set_params(_prefs.freq, _prefs.bw, _prefs.sf, _prefs.cr);
radio_set_tx_power(_prefs.tx_power_dbm);
}
const char *MyMesh::getNodeName() {
return _prefs.node_name;
}
NodePrefs *MyMesh::getNodePrefs() {
return &_prefs;
}
uint32_t MyMesh::getBLEPin() {
return _active_ble_pin;
}
void MyMesh::startInterface(BaseSerialInterface &serial) {
_serial = &serial;
serial.enable();
}
void MyMesh::handleCmdFrame(size_t len) {
if (cmd_frame[0] == CMD_DEVICE_QEURY && len >= 2) { // sent when app establishes connection
app_target_ver = cmd_frame[1]; // which version of protocol does app understand
int i = 0;
out_frame[i++] = RESP_CODE_DEVICE_INFO;
out_frame[i++] = FIRMWARE_VER_CODE;
out_frame[i++] = MAX_CONTACTS / 2; // v3+
out_frame[i++] = MAX_GROUP_CHANNELS; // v3+
memcpy(&out_frame[i], &_prefs.ble_pin, 4);
i += 4;
memset(&out_frame[i], 0, 12);
strcpy((char *)&out_frame[i], FIRMWARE_BUILD_DATE);
i += 12;
StrHelper::strzcpy((char *)&out_frame[i], board.getManufacturerName(), 40);
i += 40;
StrHelper::strzcpy((char *)&out_frame[i], FIRMWARE_VERSION, 20);
i += 20;
_serial->writeFrame(out_frame, i);
} else if (cmd_frame[0] == CMD_APP_START &&
len >= 8) { // sent when app establishes connection, respond with node ID
// cmd_frame[1..7] reserved future
char *app_name = (char *)&cmd_frame[8];
cmd_frame[len] = 0; // make app_name null terminated
MESH_DEBUG_PRINTLN("App %s connected", app_name);
_iter_started = false; // stop any left-over ContactsIterator
int i = 0;
out_frame[i++] = RESP_CODE_SELF_INFO;
out_frame[i++] = ADV_TYPE_CHAT; // what this node Advert identifies as (maybe node's pronouns too?? :-)
out_frame[i++] = _prefs.tx_power_dbm;
out_frame[i++] = MAX_LORA_TX_POWER;
memcpy(&out_frame[i], self_id.pub_key, PUB_KEY_SIZE);
i += PUB_KEY_SIZE;
int32_t lat, lon;
lat = (sensors.node_lat * 1000000.0);
lon = (sensors.node_lon * 1000000.0);
memcpy(&out_frame[i], &lat, 4);
i += 4;
memcpy(&out_frame[i], &lon, 4);
i += 4;
out_frame[i++] = _prefs.multi_acks; // new v7+
out_frame[i++] = _prefs.advert_loc_policy;
out_frame[i++] = (_prefs.telemetry_mode_env << 4) | (_prefs.telemetry_mode_loc << 2) |
(_prefs.telemetry_mode_base); // v5+
out_frame[i++] = _prefs.manual_add_contacts;
uint32_t freq = _prefs.freq * 1000;
memcpy(&out_frame[i], &freq, 4);
i += 4;
uint32_t bw = _prefs.bw * 1000;
memcpy(&out_frame[i], &bw, 4);
i += 4;
out_frame[i++] = _prefs.sf;
out_frame[i++] = _prefs.cr;
int tlen = strlen(_prefs.node_name); // revisit: UTF_8 ??
memcpy(&out_frame[i], _prefs.node_name, tlen);
i += tlen;
_serial->writeFrame(out_frame, i);
} else if (cmd_frame[0] == CMD_SEND_TXT_MSG && len >= 14) {
int i = 1;
uint8_t txt_type = cmd_frame[i++];
uint8_t attempt = cmd_frame[i++];
uint32_t msg_timestamp;
memcpy(&msg_timestamp, &cmd_frame[i], 4);
i += 4;
uint8_t *pub_key_prefix = &cmd_frame[i];
i += 6;
ContactInfo *recipient = lookupContactByPubKey(pub_key_prefix, 6);
if (recipient && (txt_type == TXT_TYPE_PLAIN || txt_type == TXT_TYPE_CLI_DATA)) {
char *text = (char *)&cmd_frame[i];
int tlen = len - i;
uint32_t est_timeout;
text[tlen] = 0; // ensure null
int result;
uint32_t expected_ack;
if (txt_type == TXT_TYPE_CLI_DATA) {
msg_timestamp = getRTCClock()->getCurrentTimeUnique(); // Use node's RTC instead of app timestamp to avoid tripping replay protection
result = sendCommandData(*recipient, msg_timestamp, attempt, text, est_timeout);
expected_ack = 0; // no Ack expected
} else {
result = sendMessage(*recipient, msg_timestamp, attempt, text, expected_ack, est_timeout);
}
// TODO: add expected ACK to table
if (result == MSG_SEND_FAILED) {
writeErrFrame(ERR_CODE_TABLE_FULL);
} else {
if (expected_ack) {
expected_ack_table[next_ack_idx].msg_sent = _ms->getMillis(); // add to circular table
expected_ack_table[next_ack_idx].ack = expected_ack;
expected_ack_table[next_ack_idx].contact = recipient;
next_ack_idx = (next_ack_idx + 1) % EXPECTED_ACK_TABLE_SIZE;
}
out_frame[0] = RESP_CODE_SENT;
out_frame[1] = (result == MSG_SEND_SENT_FLOOD) ? 1 : 0;
memcpy(&out_frame[2], &expected_ack, 4);
memcpy(&out_frame[6], &est_timeout, 4);
_serial->writeFrame(out_frame, 10);
}
} else {
writeErrFrame(recipient == NULL
? ERR_CODE_NOT_FOUND
: ERR_CODE_UNSUPPORTED_CMD); // unknown recipient, or unsuported TXT_TYPE_*
}
} else if (cmd_frame[0] == CMD_SEND_CHANNEL_TXT_MSG) { // send GroupChannel msg
int i = 1;
uint8_t txt_type = cmd_frame[i++]; // should be TXT_TYPE_PLAIN
uint8_t channel_idx = cmd_frame[i++];
uint32_t msg_timestamp;
memcpy(&msg_timestamp, &cmd_frame[i], 4);
i += 4;
const char *text = (char *)&cmd_frame[i];
int text_len = len - i;
cmd_frame[len] = '\0'; // Null-terminate for C string use
if (txt_type != TXT_TYPE_PLAIN) {
writeErrFrame(ERR_CODE_UNSUPPORTED_CMD);
} else {
ChannelDetails channel;
bool success = getChannel(channel_idx, channel);
if (success && sendGroupMessage(msg_timestamp, channel.channel, _prefs.node_name, text, len - i)) {
writeOKFrame();
#ifdef DISPLAY_CLASS
if (_ui) {
_ui->addSentChannelMessage(channel_idx, _prefs.node_name, text);
}
#endif
} else {
writeErrFrame(ERR_CODE_NOT_FOUND); // bad channel_idx
}
}
} else if (cmd_frame[0] == CMD_GET_CONTACTS) { // get Contact list
if (_iter_started) {
writeErrFrame(ERR_CODE_BAD_STATE); // iterator is currently busy
} else {
if (len >= 5) { // has optional 'since' param
memcpy(&_iter_filter_since, &cmd_frame[1], 4);
} else {
_iter_filter_since = 0;
}
uint8_t reply[5];
reply[0] = RESP_CODE_CONTACTS_START;
uint32_t count = getNumContacts(); // total, NOT filtered count
memcpy(&reply[1], &count, 4);
_serial->writeFrame(reply, 5);
// start iterator
_iter = startContactsIterator();
_iter_started = true;
_most_recent_lastmod = 0;
}
} else if (cmd_frame[0] == CMD_SET_ADVERT_NAME && len >= 2) {
int nlen = len - 1;
if (nlen > sizeof(_prefs.node_name) - 1) nlen = sizeof(_prefs.node_name) - 1; // max len
memcpy(_prefs.node_name, &cmd_frame[1], nlen);
_prefs.node_name[nlen] = 0; // null terminator
savePrefs();
writeOKFrame();
} else if (cmd_frame[0] == CMD_SET_ADVERT_LATLON && len >= 9) {
int32_t lat, lon, alt = 0;
memcpy(&lat, &cmd_frame[1], 4);
memcpy(&lon, &cmd_frame[5], 4);
if (len >= 13) {
memcpy(&alt, &cmd_frame[9], 4); // for FUTURE support
}
if (lat <= 90 * 1E6 && lat >= -90 * 1E6 && lon <= 180 * 1E6 && lon >= -180 * 1E6) {
sensors.node_lat = ((double)lat) / 1000000.0;
sensors.node_lon = ((double)lon) / 1000000.0;
savePrefs();
writeOKFrame();
} else {
writeErrFrame(ERR_CODE_ILLEGAL_ARG); // invalid geo coordinate
}
} else if (cmd_frame[0] == CMD_GET_DEVICE_TIME) {
uint8_t reply[5];
reply[0] = RESP_CODE_CURR_TIME;
uint32_t now = getRTCClock()->getCurrentTime();
memcpy(&reply[1], &now, 4);
_serial->writeFrame(reply, 5);
} else if (cmd_frame[0] == CMD_SET_DEVICE_TIME && len >= 5) {
uint32_t secs;
memcpy(&secs, &cmd_frame[1], 4);
uint32_t curr = getRTCClock()->getCurrentTime();
if (secs >= curr) {
getRTCClock()->setCurrentTime(secs);
writeOKFrame();
} else {
writeErrFrame(ERR_CODE_ILLEGAL_ARG);
}
} else if (cmd_frame[0] == CMD_SEND_SELF_ADVERT) {
mesh::Packet* pkt;
if (_prefs.advert_loc_policy == ADVERT_LOC_NONE) {
pkt = createSelfAdvert(_prefs.node_name);
} else {
pkt = createSelfAdvert(_prefs.node_name, sensors.node_lat, sensors.node_lon);
}
if (pkt) {
if (len >= 2 && cmd_frame[1] == 1) { // optional param (1 = flood, 0 = zero hop)
sendFlood(pkt);
} else {
sendZeroHop(pkt);
}
writeOKFrame();
} else {
writeErrFrame(ERR_CODE_TABLE_FULL);
}
} else if (cmd_frame[0] == CMD_RESET_PATH && len >= 1 + 32) {
uint8_t *pub_key = &cmd_frame[1];
ContactInfo *recipient = lookupContactByPubKey(pub_key, PUB_KEY_SIZE);
if (recipient) {
recipient->out_path_len = -1;
// recipient->lastmod = ?? shouldn't be needed, app already has this version of contact
dirty_contacts_expiry = futureMillis(LAZY_CONTACTS_WRITE_DELAY);
writeOKFrame();
} else {
writeErrFrame(ERR_CODE_NOT_FOUND); // unknown contact
}
} else if (cmd_frame[0] == CMD_ADD_UPDATE_CONTACT && len >= 1 + 32 + 2 + 1) {
uint8_t *pub_key = &cmd_frame[1];
ContactInfo *recipient = lookupContactByPubKey(pub_key, PUB_KEY_SIZE);
uint32_t last_mod = getRTCClock()->getCurrentTime(); // fallback value if not present in cmd_frame
if (recipient) {
updateContactFromFrame(*recipient, last_mod, cmd_frame, len);
recipient->lastmod = last_mod;
dirty_contacts_expiry = futureMillis(LAZY_CONTACTS_WRITE_DELAY);
writeOKFrame();
} else {
ContactInfo contact;
updateContactFromFrame(contact, last_mod, cmd_frame, len);
contact.lastmod = last_mod;
contact.sync_since = 0;
if (addContact(contact)) {
dirty_contacts_expiry = futureMillis(LAZY_CONTACTS_WRITE_DELAY);
writeOKFrame();
} else {
writeErrFrame(ERR_CODE_TABLE_FULL);
}
}
} else if (cmd_frame[0] == CMD_REMOVE_CONTACT) {
uint8_t *pub_key = &cmd_frame[1];
ContactInfo *recipient = lookupContactByPubKey(pub_key, PUB_KEY_SIZE);
if (recipient && removeContact(*recipient)) {
dirty_contacts_expiry = futureMillis(LAZY_CONTACTS_WRITE_DELAY);
writeOKFrame();
} else {
writeErrFrame(ERR_CODE_NOT_FOUND); // not found, or unable to remove
}
} else if (cmd_frame[0] == CMD_SHARE_CONTACT) {
uint8_t *pub_key = &cmd_frame[1];
ContactInfo *recipient = lookupContactByPubKey(pub_key, PUB_KEY_SIZE);
if (recipient) {
if (shareContactZeroHop(*recipient)) {
writeOKFrame();
} else {
writeErrFrame(ERR_CODE_TABLE_FULL); // unable to send
}
} else {
writeErrFrame(ERR_CODE_NOT_FOUND);
}
} else if (cmd_frame[0] == CMD_GET_CONTACT_BY_KEY) {
uint8_t *pub_key = &cmd_frame[1];
ContactInfo *contact = lookupContactByPubKey(pub_key, PUB_KEY_SIZE);
if (contact) {
writeContactRespFrame(RESP_CODE_CONTACT, *contact);
} else {
writeErrFrame(ERR_CODE_NOT_FOUND); // not found
}
} else if (cmd_frame[0] == CMD_EXPORT_CONTACT) {
if (len < 1 + PUB_KEY_SIZE) {
// export SELF
mesh::Packet* pkt;
if (_prefs.advert_loc_policy == ADVERT_LOC_NONE) {
pkt = createSelfAdvert(_prefs.node_name);
} else {
pkt = createSelfAdvert(_prefs.node_name, sensors.node_lat, sensors.node_lon);
}
if (pkt) {
pkt->header |= ROUTE_TYPE_FLOOD; // would normally be sent in this mode
out_frame[0] = RESP_CODE_EXPORT_CONTACT;
uint8_t out_len = pkt->writeTo(&out_frame[1]);
releasePacket(pkt); // undo the obtainNewPacket()
_serial->writeFrame(out_frame, out_len + 1);
} else {
writeErrFrame(ERR_CODE_TABLE_FULL); // Error
}
} else {
uint8_t *pub_key = &cmd_frame[1];
ContactInfo *recipient = lookupContactByPubKey(pub_key, PUB_KEY_SIZE);
uint8_t out_len;
if (recipient && (out_len = exportContact(*recipient, &out_frame[1])) > 0) {
out_frame[0] = RESP_CODE_EXPORT_CONTACT;
_serial->writeFrame(out_frame, out_len + 1);
} else {
writeErrFrame(ERR_CODE_NOT_FOUND); // not found
}
}
} else if (cmd_frame[0] == CMD_IMPORT_CONTACT && len > 2 + 32 + 64) {
if (importContact(&cmd_frame[1], len - 1)) {
dirty_contacts_expiry = futureMillis(LAZY_CONTACTS_WRITE_DELAY);
writeOKFrame();
} else {
writeErrFrame(ERR_CODE_ILLEGAL_ARG);
}
} else if (cmd_frame[0] == CMD_SYNC_NEXT_MESSAGE) {
int out_len;
if ((out_len = getFromOfflineQueue(out_frame)) > 0) {
_serial->writeFrame(out_frame, out_len);
#ifdef DISPLAY_CLASS
if (_ui) {
_ui->msgRead(offline_queue_len);
// Mark channel as read when BLE companion app syncs the message.
// Frame layout V3: [resp_code][snr][res1][res2][channel_idx][path_len]...
// Frame layout V1: [resp_code][channel_idx][path_len]...
bool is_v3_ch = (out_frame[0] == RESP_CODE_CHANNEL_MSG_RECV_V3);
bool is_old_ch = (out_frame[0] == RESP_CODE_CHANNEL_MSG_RECV);
if (is_v3_ch || is_old_ch) {
uint8_t ch_idx = is_v3_ch ? out_frame[4] : out_frame[1];
_ui->markChannelReadFromBLE(ch_idx);
}
}
#endif
} else {
out_frame[0] = RESP_CODE_NO_MORE_MESSAGES;
_serial->writeFrame(out_frame, 1);
}
} else if (cmd_frame[0] == CMD_SET_RADIO_PARAMS) {
int i = 1;
uint32_t freq;
memcpy(&freq, &cmd_frame[i], 4);
i += 4;
uint32_t bw;
memcpy(&bw, &cmd_frame[i], 4);
i += 4;
uint8_t sf = cmd_frame[i++];
uint8_t cr = cmd_frame[i++];
if (freq >= 300000 && freq <= 2500000 && sf >= 5 && sf <= 12 && cr >= 5 && cr <= 8 && bw >= 7000 &&
bw <= 500000) {
_prefs.sf = sf;
_prefs.cr = cr;
_prefs.freq = (float)freq / 1000.0;
_prefs.bw = (float)bw / 1000.0;
savePrefs();
radio_set_params(_prefs.freq, _prefs.bw, _prefs.sf, _prefs.cr);
MESH_DEBUG_PRINTLN("OK: CMD_SET_RADIO_PARAMS: f=%d, bw=%d, sf=%d, cr=%d", freq, bw, (uint32_t)sf,
(uint32_t)cr);
writeOKFrame();
} else {
MESH_DEBUG_PRINTLN("Error: CMD_SET_RADIO_PARAMS: f=%d, bw=%d, sf=%d, cr=%d", freq, bw, (uint32_t)sf,
(uint32_t)cr);
writeErrFrame(ERR_CODE_ILLEGAL_ARG);
}
} else if (cmd_frame[0] == CMD_SET_RADIO_TX_POWER) {
if (cmd_frame[1] > MAX_LORA_TX_POWER) {
writeErrFrame(ERR_CODE_ILLEGAL_ARG);
} else {
_prefs.tx_power_dbm = cmd_frame[1];
savePrefs();
radio_set_tx_power(_prefs.tx_power_dbm);
writeOKFrame();
}
} else if (cmd_frame[0] == CMD_SET_TUNING_PARAMS) {
int i = 1;
uint32_t rx, af;
memcpy(&rx, &cmd_frame[i], 4);
i += 4;
memcpy(&af, &cmd_frame[i], 4);
i += 4;
_prefs.rx_delay_base = ((float)rx) / 1000.0f;
_prefs.airtime_factor = ((float)af) / 1000.0f;
savePrefs();
writeOKFrame();
} else if (cmd_frame[0] == CMD_GET_TUNING_PARAMS) {
uint32_t rx = _prefs.rx_delay_base * 1000, af = _prefs.airtime_factor * 1000;
int i = 0;
out_frame[i++] = RESP_CODE_TUNING_PARAMS;
memcpy(&out_frame[i], &rx, 4); i += 4;
memcpy(&out_frame[i], &af, 4); i += 4;
_serial->writeFrame(out_frame, i);
} else if (cmd_frame[0] == CMD_SET_OTHER_PARAMS) {
_prefs.manual_add_contacts = cmd_frame[1];
if (len >= 3) {
_prefs.telemetry_mode_base = cmd_frame[2] & 0x03; // v5+
_prefs.telemetry_mode_loc = (cmd_frame[2] >> 2) & 0x03;
_prefs.telemetry_mode_env = (cmd_frame[2] >> 4) & 0x03;
if (len >= 4) {
_prefs.advert_loc_policy = cmd_frame[3];
if (len >= 5) {
_prefs.multi_acks = cmd_frame[4];
}
}
}
savePrefs();
writeOKFrame();
} else if (cmd_frame[0] == CMD_REBOOT && memcmp(&cmd_frame[1], "reboot", 6) == 0) {
if (dirty_contacts_expiry) { // is there are pending dirty contacts write needed?
saveContacts();
}
board.reboot();
} else if (cmd_frame[0] == CMD_GET_BATT_AND_STORAGE) {
uint8_t reply[11];
int i = 0;
reply[i++] = RESP_CODE_BATT_AND_STORAGE;
uint16_t battery_millivolts = board.getBattMilliVolts();
uint32_t used = _store->getStorageUsedKb();
uint32_t total = _store->getStorageTotalKb();
memcpy(&reply[i], &battery_millivolts, 2); i += 2;
memcpy(&reply[i], &used, 4); i += 4;
memcpy(&reply[i], &total, 4); i += 4;
_serial->writeFrame(reply, i);
} else if (cmd_frame[0] == CMD_EXPORT_PRIVATE_KEY) {
#if ENABLE_PRIVATE_KEY_EXPORT
uint8_t reply[65];
reply[0] = RESP_CODE_PRIVATE_KEY;
self_id.writeTo(&reply[1], 64);
_serial->writeFrame(reply, 65);
#else
writeDisabledFrame();
#endif
} else if (cmd_frame[0] == CMD_IMPORT_PRIVATE_KEY && len >= 65) {
#if ENABLE_PRIVATE_KEY_IMPORT
if (!mesh::LocalIdentity::validatePrivateKey(&cmd_frame[1])) {
writeErrFrame(ERR_CODE_ILLEGAL_ARG); // invalid key
} else {
mesh::LocalIdentity identity;
identity.readFrom(&cmd_frame[1], 64);
if (_store->saveMainIdentity(identity)) {
self_id = identity;
writeOKFrame();
// re-load contacts, to invalidate ecdh shared_secrets
resetContacts();
_store->loadContacts(this);
} else {
writeErrFrame(ERR_CODE_FILE_IO_ERROR);
}
}
#else
writeDisabledFrame();
#endif
} else if (cmd_frame[0] == CMD_SEND_RAW_DATA && len >= 6) {
int i = 1;
int8_t path_len = cmd_frame[i++];
if (path_len >= 0 && i + path_len + 4 <= len) { // minimum 4 byte payload
uint8_t *path = &cmd_frame[i];
i += path_len;
auto pkt = createRawData(&cmd_frame[i], len - i);
if (pkt) {
sendDirect(pkt, path, path_len);
writeOKFrame();
} else {
writeErrFrame(ERR_CODE_TABLE_FULL);
}
} else {
writeErrFrame(ERR_CODE_UNSUPPORTED_CMD); // flood, not supported (yet)
}
} else if (cmd_frame[0] == CMD_SEND_LOGIN && len >= 1 + PUB_KEY_SIZE) {
uint8_t *pub_key = &cmd_frame[1];
ContactInfo *recipient = lookupContactByPubKey(pub_key, PUB_KEY_SIZE);
char *password = (char *)&cmd_frame[1 + PUB_KEY_SIZE];
cmd_frame[len] = 0; // ensure null terminator in password
if (recipient) {
uint32_t est_timeout;
int result = sendLogin(*recipient, password, est_timeout);
if (result == MSG_SEND_FAILED) {
writeErrFrame(ERR_CODE_TABLE_FULL);
} else {
clearPendingReqs();
memcpy(&pending_login, recipient->id.pub_key, 4); // match this to onContactResponse()
out_frame[0] = RESP_CODE_SENT;
out_frame[1] = (result == MSG_SEND_SENT_FLOOD) ? 1 : 0;
memcpy(&out_frame[2], &pending_login, 4);
memcpy(&out_frame[6], &est_timeout, 4);
_serial->writeFrame(out_frame, 10);
}
} else {
writeErrFrame(ERR_CODE_NOT_FOUND); // contact not found
}
} else if (cmd_frame[0] == CMD_SEND_ANON_REQ && len > 1 + PUB_KEY_SIZE) {
uint8_t *pub_key = &cmd_frame[1];
ContactInfo *recipient = lookupContactByPubKey(pub_key, PUB_KEY_SIZE);
uint8_t *data = &cmd_frame[1 + PUB_KEY_SIZE];
if (recipient) {
uint32_t tag, est_timeout;
int result = sendAnonReq(*recipient, data, len - (1 + PUB_KEY_SIZE), tag, est_timeout);
if (result == MSG_SEND_FAILED) {
writeErrFrame(ERR_CODE_TABLE_FULL);
} else {
clearPendingReqs();
pending_req = tag; // match this to onContactResponse()
out_frame[0] = RESP_CODE_SENT;
out_frame[1] = (result == MSG_SEND_SENT_FLOOD) ? 1 : 0;
memcpy(&out_frame[2], &tag, 4);
memcpy(&out_frame[6], &est_timeout, 4);
_serial->writeFrame(out_frame, 10);
}
} else {
writeErrFrame(ERR_CODE_NOT_FOUND); // contact not found
}
} else if (cmd_frame[0] == CMD_SEND_STATUS_REQ && len >= 1 + PUB_KEY_SIZE) {
uint8_t *pub_key = &cmd_frame[1];
ContactInfo *recipient = lookupContactByPubKey(pub_key, PUB_KEY_SIZE);
if (recipient) {
uint32_t tag, est_timeout;
int result = sendRequest(*recipient, REQ_TYPE_GET_STATUS, tag, est_timeout);
if (result == MSG_SEND_FAILED) {
writeErrFrame(ERR_CODE_TABLE_FULL);
} else {
clearPendingReqs();
// FUTURE: pending_status = tag; // match this in onContactResponse()
memcpy(&pending_status, recipient->id.pub_key, 4); // legacy matching scheme
out_frame[0] = RESP_CODE_SENT;
out_frame[1] = (result == MSG_SEND_SENT_FLOOD) ? 1 : 0;
memcpy(&out_frame[2], &tag, 4);
memcpy(&out_frame[6], &est_timeout, 4);
_serial->writeFrame(out_frame, 10);
}
} else {
writeErrFrame(ERR_CODE_NOT_FOUND); // contact not found
}
} else if (cmd_frame[0] == CMD_SEND_PATH_DISCOVERY_REQ && cmd_frame[1] == 0 && len >= 2 + PUB_KEY_SIZE) {
uint8_t *pub_key = &cmd_frame[2];
ContactInfo *recipient = lookupContactByPubKey(pub_key, PUB_KEY_SIZE);
if (recipient) {
uint32_t tag, est_timeout;
// 'Path Discovery' is just a special case of flood + Telemetry req
uint8_t req_data[9];
req_data[0] = REQ_TYPE_GET_TELEMETRY_DATA;
req_data[1] = ~(TELEM_PERM_BASE); // NEW: inverse permissions mask (ie. we only want BASE telemetry)
memset(&req_data[2], 0, 3); // reserved
getRNG()->random(&req_data[5], 4); // random blob to help make packet-hash unique
auto save = recipient->out_path_len; // temporarily force sendRequest() to flood
recipient->out_path_len = -1;
int result = sendRequest(*recipient, req_data, sizeof(req_data), tag, est_timeout);
recipient->out_path_len = save;
if (result == MSG_SEND_FAILED) {
writeErrFrame(ERR_CODE_TABLE_FULL);
} else {
clearPendingReqs();
pending_discovery = tag; // match this in onContactResponse()
out_frame[0] = RESP_CODE_SENT;
out_frame[1] = (result == MSG_SEND_SENT_FLOOD) ? 1 : 0;
memcpy(&out_frame[2], &tag, 4);
memcpy(&out_frame[6], &est_timeout, 4);
_serial->writeFrame(out_frame, 10);
}
} else {
writeErrFrame(ERR_CODE_NOT_FOUND); // contact not found
}
} else if (cmd_frame[0] == CMD_SEND_TELEMETRY_REQ && len >= 4 + PUB_KEY_SIZE) { // can deprecate, in favour of CMD_SEND_BINARY_REQ
uint8_t *pub_key = &cmd_frame[4];
ContactInfo *recipient = lookupContactByPubKey(pub_key, PUB_KEY_SIZE);
if (recipient) {
uint32_t tag, est_timeout;
int result = sendRequest(*recipient, REQ_TYPE_GET_TELEMETRY_DATA, tag, est_timeout);
if (result == MSG_SEND_FAILED) {
writeErrFrame(ERR_CODE_TABLE_FULL);
} else {
clearPendingReqs();
pending_telemetry = tag; // match this in onContactResponse()
out_frame[0] = RESP_CODE_SENT;
out_frame[1] = (result == MSG_SEND_SENT_FLOOD) ? 1 : 0;
memcpy(&out_frame[2], &tag, 4);
memcpy(&out_frame[6], &est_timeout, 4);
_serial->writeFrame(out_frame, 10);
}
} else {
writeErrFrame(ERR_CODE_NOT_FOUND); // contact not found
}
} else if (cmd_frame[0] == CMD_SEND_TELEMETRY_REQ && len == 4) { // 'self' telemetry request
telemetry.reset();
telemetry.addVoltage(TELEM_CHANNEL_SELF, (float)board.getBattMilliVolts() / 1000.0f);
// query other sensors -- target specific
sensors.querySensors(0xFF, telemetry);
int i = 0;
out_frame[i++] = PUSH_CODE_TELEMETRY_RESPONSE;
out_frame[i++] = 0; // reserved
memcpy(&out_frame[i], self_id.pub_key, 6);
i += 6; // pub_key_prefix
uint8_t tlen = telemetry.getSize();
memcpy(&out_frame[i], telemetry.getBuffer(), tlen);
i += tlen;
_serial->writeFrame(out_frame, i);
} else if (cmd_frame[0] == CMD_SEND_BINARY_REQ && len >= 2 + PUB_KEY_SIZE) {
uint8_t *pub_key = &cmd_frame[1];
ContactInfo *recipient = lookupContactByPubKey(pub_key, PUB_KEY_SIZE);
if (recipient) {
uint8_t *req_data = &cmd_frame[1 + PUB_KEY_SIZE];
uint32_t tag, est_timeout;
int result = sendRequest(*recipient, req_data, len - (1 + PUB_KEY_SIZE), tag, est_timeout);
if (result == MSG_SEND_FAILED) {
writeErrFrame(ERR_CODE_TABLE_FULL);
} else {
clearPendingReqs();
pending_req = tag; // match this in onContactResponse()
out_frame[0] = RESP_CODE_SENT;
out_frame[1] = (result == MSG_SEND_SENT_FLOOD) ? 1 : 0;
memcpy(&out_frame[2], &tag, 4);
memcpy(&out_frame[6], &est_timeout, 4);
_serial->writeFrame(out_frame, 10);
}
} else {
writeErrFrame(ERR_CODE_NOT_FOUND); // contact not found
}
} else if (cmd_frame[0] == CMD_HAS_CONNECTION && len >= 1 + PUB_KEY_SIZE) {
uint8_t *pub_key = &cmd_frame[1];
if (hasConnectionTo(pub_key)) {
writeOKFrame();
} else {
writeErrFrame(ERR_CODE_NOT_FOUND);
}
} else if (cmd_frame[0] == CMD_LOGOUT && len >= 1 + PUB_KEY_SIZE) {
uint8_t *pub_key = &cmd_frame[1];
stopConnection(pub_key);
writeOKFrame();
} else if (cmd_frame[0] == CMD_GET_CHANNEL && len >= 2) {
uint8_t channel_idx = cmd_frame[1];
ChannelDetails channel;
if (getChannel(channel_idx, channel)) {
int i = 0;
out_frame[i++] = RESP_CODE_CHANNEL_INFO;
out_frame[i++] = channel_idx;
strcpy((char *)&out_frame[i], channel.name);
i += 32;
memcpy(&out_frame[i], channel.channel.secret, 16);
i += 16; // NOTE: only 128-bit supported
_serial->writeFrame(out_frame, i);
} else {
writeErrFrame(ERR_CODE_NOT_FOUND);
}
} else if (cmd_frame[0] == CMD_SET_CHANNEL && len >= 2 + 32 + 32) {
writeErrFrame(ERR_CODE_UNSUPPORTED_CMD); // not supported (yet)
} else if (cmd_frame[0] == CMD_SET_CHANNEL && len >= 2 + 32 + 16) {
uint8_t channel_idx = cmd_frame[1];
ChannelDetails channel;
StrHelper::strncpy(channel.name, (char *)&cmd_frame[2], 32);
memset(channel.channel.secret, 0, sizeof(channel.channel.secret));
memcpy(channel.channel.secret, &cmd_frame[2 + 32], 16); // NOTE: only 128-bit supported
if (setChannel(channel_idx, channel)) {
saveChannels();
writeOKFrame();
} else {
writeErrFrame(ERR_CODE_NOT_FOUND); // bad channel_idx
}
} else if (cmd_frame[0] == CMD_SIGN_START) {
out_frame[0] = RESP_CODE_SIGN_START;
out_frame[1] = 0; // reserved
uint32_t len = MAX_SIGN_DATA_LEN;
memcpy(&out_frame[2], &len, 4);
_serial->writeFrame(out_frame, 6);
if (sign_data) {
free(sign_data);
}
sign_data = (uint8_t *)malloc(MAX_SIGN_DATA_LEN);
sign_data_len = 0;
} else if (cmd_frame[0] == CMD_SIGN_DATA && len > 1) {
if (sign_data == NULL || sign_data_len + (len - 1) > MAX_SIGN_DATA_LEN) {
writeErrFrame(sign_data == NULL ? ERR_CODE_BAD_STATE : ERR_CODE_TABLE_FULL); // error: too long
} else {
memcpy(&sign_data[sign_data_len], &cmd_frame[1], len - 1);
sign_data_len += (len - 1);
writeOKFrame();
}
} else if (cmd_frame[0] == CMD_SIGN_FINISH) {
if (sign_data) {
self_id.sign(&out_frame[1], sign_data, sign_data_len);
free(sign_data); // don't need sign_data now
sign_data = NULL;
out_frame[0] = RESP_CODE_SIGNATURE;
_serial->writeFrame(out_frame, 1 + SIGNATURE_SIZE);
} else {
writeErrFrame(ERR_CODE_BAD_STATE);
}
} else if (cmd_frame[0] == CMD_SEND_TRACE_PATH && len > 10 && len - 10 < MAX_PACKET_PAYLOAD-5) {
uint8_t path_len = len - 10;
uint8_t flags = cmd_frame[9];
uint8_t path_sz = flags & 0x03; // NEW v1.11+
if ((path_len >> path_sz) > MAX_PATH_SIZE || (path_len % (1 << path_sz)) != 0) { // make sure is multiple of path_sz
writeErrFrame(ERR_CODE_ILLEGAL_ARG);
} else {
uint32_t tag, auth;
memcpy(&tag, &cmd_frame[1], 4);
memcpy(&auth, &cmd_frame[5], 4);
auto pkt = createTrace(tag, auth, flags);
if (pkt) {
sendDirect(pkt, &cmd_frame[10], path_len);
uint32_t t = _radio->getEstAirtimeFor(pkt->payload_len + pkt->path_len + 2);
uint32_t est_timeout = calcDirectTimeoutMillisFor(t, path_len);
out_frame[0] = RESP_CODE_SENT;
out_frame[1] = 0;
memcpy(&out_frame[2], &tag, 4);
memcpy(&out_frame[6], &est_timeout, 4);
_serial->writeFrame(out_frame, 10);
} else {
writeErrFrame(ERR_CODE_TABLE_FULL);
}
}
} else if (cmd_frame[0] == CMD_SET_DEVICE_PIN && len >= 5) {
// get pin from command frame
uint32_t pin;
memcpy(&pin, &cmd_frame[1], 4);
// ensure pin is zero, or a valid 6 digit pin
if (pin == 0 || (pin >= 100000 && pin <= 999999)) {
_prefs.ble_pin = pin;
savePrefs();
writeOKFrame();
} else {
writeErrFrame(ERR_CODE_ILLEGAL_ARG);
}
} else if (cmd_frame[0] == CMD_GET_CUSTOM_VARS) {
out_frame[0] = RESP_CODE_CUSTOM_VARS;
char *dp = (char *)&out_frame[1];
for (int i = 0; i < sensors.getNumSettings() && dp - (char *)&out_frame[1] < 140; i++) {
if (i > 0) {
*dp++ = ',';
}
strcpy(dp, sensors.getSettingName(i));
dp = strchr(dp, 0);
*dp++ = ':';
strcpy(dp, sensors.getSettingValue(i));
dp = strchr(dp, 0);
}
_serial->writeFrame(out_frame, dp - (char *)out_frame);
} else if (cmd_frame[0] == CMD_SET_CUSTOM_VAR && len >= 4) {
cmd_frame[len] = 0;
char *sp = (char *)&cmd_frame[1];
char *np = strchr(sp, ':'); // look for separator char
if (np) {
*np++ = 0; // modify 'cmd_frame', replace ':' with null
bool success = sensors.setSettingValue(sp, np);
if (success) {
#if ENV_INCLUDE_GPS == 1
// Update node preferences for GPS settings
if (strcmp(sp, "gps") == 0) {
_prefs.gps_enabled = (np[0] == '1') ? 1 : 0;
savePrefs();
} else if (strcmp(sp, "gps_interval") == 0) {
uint32_t interval_seconds = atoi(np);
_prefs.gps_interval = constrain(interval_seconds, 0, 86400);
savePrefs();
}
#endif
// UTC offset for local clock display (works regardless of GPS)
if (strcmp(sp, "utc_offset") == 0) {
int offset = atoi(np);
_prefs.utc_offset_hours = constrain(offset, -12, 14);
savePrefs();
}
writeOKFrame();
} else {
writeErrFrame(ERR_CODE_ILLEGAL_ARG);
}
} else {
writeErrFrame(ERR_CODE_ILLEGAL_ARG);
}
} else if (cmd_frame[0] == CMD_GET_ADVERT_PATH && len >= PUB_KEY_SIZE+2) {
// FUTURE use: uint8_t reserved = cmd_frame[1];
uint8_t *pub_key = &cmd_frame[2];
AdvertPath* found = NULL;
for (int i = 0; i < ADVERT_PATH_TABLE_SIZE; i++) {
auto p = &advert_paths[i];
if (memcmp(p->pubkey_prefix, pub_key, sizeof(p->pubkey_prefix)) == 0) {
found = p;
break;
}
}
if (found) {
out_frame[0] = RESP_CODE_ADVERT_PATH;
memcpy(&out_frame[1], &found->recv_timestamp, 4);
out_frame[5] = found->path_len;
memcpy(&out_frame[6], found->path, found->path_len);
_serial->writeFrame(out_frame, 6 + found->path_len);
} else {
writeErrFrame(ERR_CODE_NOT_FOUND);
}
} else if (cmd_frame[0] == CMD_GET_STATS && len >= 2) {
uint8_t stats_type = cmd_frame[1];
if (stats_type == STATS_TYPE_CORE) {
int i = 0;
out_frame[i++] = RESP_CODE_STATS;
out_frame[i++] = STATS_TYPE_CORE;
uint16_t battery_mv = board.getBattMilliVolts();
uint32_t uptime_secs = _ms->getMillis() / 1000;
uint8_t queue_len = (uint8_t)_mgr->getOutboundCount(0xFFFFFFFF);
memcpy(&out_frame[i], &battery_mv, 2); i += 2;
memcpy(&out_frame[i], &uptime_secs, 4); i += 4;
memcpy(&out_frame[i], &_err_flags, 2); i += 2;
out_frame[i++] = queue_len;
_serial->writeFrame(out_frame, i);
} else if (stats_type == STATS_TYPE_RADIO) {
int i = 0;
out_frame[i++] = RESP_CODE_STATS;
out_frame[i++] = STATS_TYPE_RADIO;
int16_t noise_floor = (int16_t)_radio->getNoiseFloor();
int8_t last_rssi = (int8_t)radio_driver.getLastRSSI();
int8_t last_snr = (int8_t)(radio_driver.getLastSNR() * 4); // scaled by 4 for 0.25 dB precision
uint32_t tx_air_secs = getTotalAirTime() / 1000;
uint32_t rx_air_secs = getReceiveAirTime() / 1000;
memcpy(&out_frame[i], &noise_floor, 2); i += 2;
out_frame[i++] = last_rssi;
out_frame[i++] = last_snr;
memcpy(&out_frame[i], &tx_air_secs, 4); i += 4;
memcpy(&out_frame[i], &rx_air_secs, 4); i += 4;
_serial->writeFrame(out_frame, i);
} else if (stats_type == STATS_TYPE_PACKETS) {
int i = 0;
out_frame[i++] = RESP_CODE_STATS;
out_frame[i++] = STATS_TYPE_PACKETS;
uint32_t recv = radio_driver.getPacketsRecv();
uint32_t sent = radio_driver.getPacketsSent();
uint32_t n_sent_flood = getNumSentFlood();
uint32_t n_sent_direct = getNumSentDirect();
uint32_t n_recv_flood = getNumRecvFlood();
uint32_t n_recv_direct = getNumRecvDirect();
memcpy(&out_frame[i], &recv, 4); i += 4;
memcpy(&out_frame[i], &sent, 4); i += 4;
memcpy(&out_frame[i], &n_sent_flood, 4); i += 4;
memcpy(&out_frame[i], &n_sent_direct, 4); i += 4;
memcpy(&out_frame[i], &n_recv_flood, 4); i += 4;
memcpy(&out_frame[i], &n_recv_direct, 4); i += 4;
_serial->writeFrame(out_frame, i);
} else {
writeErrFrame(ERR_CODE_ILLEGAL_ARG); // invalid stats sub-type
}
} else if (cmd_frame[0] == CMD_FACTORY_RESET && memcmp(&cmd_frame[1], "reset", 5) == 0) {
if (_serial) {
MESH_DEBUG_PRINTLN("Factory reset: disabling serial interface to prevent reconnects (BLE/WiFi)");
_serial->disable(); // Phone app disconnects before we can send OK frame so it's safe here
}
bool success = _store->formatFileSystem();
if (success) {
writeOKFrame();
delay(1000);
board.reboot(); // doesn't return
} else {
writeErrFrame(ERR_CODE_FILE_IO_ERROR);
}
} else if (cmd_frame[0] == CMD_SET_FLOOD_SCOPE && len >= 2 && cmd_frame[1] == 0) {
if (len >= 2 + 16) {
memcpy(send_scope.key, &cmd_frame[2], sizeof(send_scope.key)); // set curr scope TransportKey
} else {
memset(send_scope.key, 0, sizeof(send_scope.key)); // set scope to null
}
writeOKFrame();
} else if (cmd_frame[0] == CMD_SEND_CONTROL_DATA && len >= 2 && (cmd_frame[1] & 0x80) != 0) {
auto resp = createControlData(&cmd_frame[1], len - 1);
if (resp) {
sendZeroHop(resp);
writeOKFrame();
} else {
writeErrFrame(ERR_CODE_TABLE_FULL);
}
} else if (cmd_frame[0] == CMD_SET_AUTOADD_CONFIG) {
_prefs.autoadd_config = cmd_frame[1];
savePrefs();
writeOKFrame();
} else if (cmd_frame[0] == CMD_GET_AUTOADD_CONFIG) {
int i = 0;
out_frame[i++] = RESP_CODE_AUTOADD_CONFIG;
out_frame[i++] = _prefs.autoadd_config;
_serial->writeFrame(out_frame, i);
} else {
writeErrFrame(ERR_CODE_UNSUPPORTED_CMD);
MESH_DEBUG_PRINTLN("ERROR: unknown command: %02X", cmd_frame[0]);
}
}
void MyMesh::enterCLIRescue() {
_cli_rescue = true;
cli_command[0] = 0;
Serial.println("========= CLI Rescue =========");
}
void MyMesh::checkCLIRescueCmd() {
int len = strlen(cli_command);
while (Serial.available() && len < sizeof(cli_command)-1) {
char c = Serial.read();
if (c != '\n') {
cli_command[len++] = c;
cli_command[len] = 0;
}
Serial.print(c); // echo
}
if (len == sizeof(cli_command)-1) { // command buffer full
cli_command[sizeof(cli_command)-1] = '\r';
}
if (len > 0 && cli_command[len - 1] == '\r') { // received complete line
cli_command[len - 1] = 0; // replace newline with C string null terminator
// =====================================================================
// GET commands — read settings
// =====================================================================
if (memcmp(cli_command, "get ", 4) == 0) {
const char* key = &cli_command[4];
if (strcmp(key, "name") == 0) {
Serial.printf(" > %s\n", _prefs.node_name);
} else if (strcmp(key, "freq") == 0) {
Serial.printf(" > %.3f\n", _prefs.freq);
} else if (strcmp(key, "bw") == 0) {
Serial.printf(" > %.1f\n", _prefs.bw);
} else if (strcmp(key, "sf") == 0) {
Serial.printf(" > %d\n", _prefs.sf);
} else if (strcmp(key, "cr") == 0) {
Serial.printf(" > %d\n", _prefs.cr);
} else if (strcmp(key, "tx") == 0) {
Serial.printf(" > %d\n", _prefs.tx_power_dbm);
} else if (strcmp(key, "utc") == 0) {
Serial.printf(" > %d\n", _prefs.utc_offset_hours);
} else if (strcmp(key, "notify") == 0) {
Serial.printf(" > %s\n", _prefs.kb_flash_notify ? "on" : "off");
} else if (strcmp(key, "gps") == 0) {
Serial.printf(" > %s (interval: %ds)\n",
_prefs.gps_enabled ? "on" : "off", _prefs.gps_interval);
} else if (strcmp(key, "pin") == 0) {
Serial.printf(" > %06d\n", _prefs.ble_pin);
} else if (strcmp(key, "radio") == 0) {
Serial.printf(" > freq=%.3f bw=%.1f sf=%d cr=%d tx=%d\n",
_prefs.freq, _prefs.bw, _prefs.sf, _prefs.cr, _prefs.tx_power_dbm);
} else if (strcmp(key, "pubkey") == 0) {
char hex[PUB_KEY_SIZE * 2 + 1];
mesh::Utils::toHex(hex, self_id.pub_key, PUB_KEY_SIZE);
Serial.printf(" > %s\n", hex);
} else if (strcmp(key, "firmware") == 0) {
Serial.printf(" > %s\n", FIRMWARE_VERSION);
} else if (strcmp(key, "channels") == 0) {
bool found = false;
for (uint8_t i = 0; i < MAX_GROUP_CHANNELS; i++) {
ChannelDetails ch;
if (getChannel(i, ch) && ch.name[0] != '\0') {
Serial.printf(" [%d] %s\n", i, ch.name);
found = true;
} else {
break;
}
}
if (!found) Serial.println(" (no channels)");
} else if (strcmp(key, "presets") == 0) {
Serial.println(" Available radio presets:");
for (int i = 0; i < (int)NUM_RADIO_PRESETS; i++) {
Serial.printf(" %2d %-30s %.3f MHz BW%.1f SF%d CR%d TX%d\n",
i, RADIO_PRESETS[i].name, RADIO_PRESETS[i].freq,
RADIO_PRESETS[i].bw, RADIO_PRESETS[i].sf,
RADIO_PRESETS[i].cr, RADIO_PRESETS[i].tx_power);
}
#ifdef HAS_4G_MODEM
} else if (strcmp(key, "modem") == 0) {
Serial.printf(" > %s\n", ModemManager::loadEnabledConfig() ? "on" : "off");
} else if (strcmp(key, "apn") == 0) {
Serial.printf(" > %s\n", modemManager.getAPN());
} else if (strcmp(key, "imei") == 0) {
Serial.printf(" > %s\n", modemManager.getIMEI());
#endif
} else if (strcmp(key, "all") == 0) {
Serial.println(" === Meck Device Settings ===");
Serial.printf(" name: %s\n", _prefs.node_name);
Serial.printf(" freq: %.3f\n", _prefs.freq);
Serial.printf(" bw: %.1f\n", _prefs.bw);
Serial.printf(" sf: %d\n", _prefs.sf);
Serial.printf(" cr: %d\n", _prefs.cr);
Serial.printf(" tx: %d\n", _prefs.tx_power_dbm);
Serial.printf(" utc: %d\n", _prefs.utc_offset_hours);
Serial.printf(" notify: %s\n", _prefs.kb_flash_notify ? "on" : "off");
Serial.printf(" gps: %s (interval: %ds)\n",
_prefs.gps_enabled ? "on" : "off", _prefs.gps_interval);
Serial.printf(" pin: %06d\n", _prefs.ble_pin);
#ifdef HAS_4G_MODEM
Serial.printf(" modem: %s\n", ModemManager::loadEnabledConfig() ? "on" : "off");
Serial.printf(" apn: %s\n", modemManager.getAPN());
Serial.printf(" imei: %s\n", modemManager.getIMEI());
#endif
// Detect current preset
bool presetFound = false;
for (int i = 0; i < (int)NUM_RADIO_PRESETS; i++) {
if (_prefs.freq == RADIO_PRESETS[i].freq && _prefs.bw == RADIO_PRESETS[i].bw &&
_prefs.sf == RADIO_PRESETS[i].sf && _prefs.cr == RADIO_PRESETS[i].cr) {
Serial.printf(" preset: %s\n", RADIO_PRESETS[i].name);
presetFound = true;
break;
}
}
if (!presetFound) Serial.println(" preset: (custom)");
Serial.printf(" firmware: %s\n", FIRMWARE_VERSION);
char hex[PUB_KEY_SIZE * 2 + 1];
mesh::Utils::toHex(hex, self_id.pub_key, PUB_KEY_SIZE);
Serial.printf(" pubkey: %s\n", hex);
// List channels
Serial.println(" channels:");
bool chFound = false;
for (uint8_t i = 0; i < MAX_GROUP_CHANNELS; i++) {
ChannelDetails ch;
if (getChannel(i, ch) && ch.name[0] != '\0') {
Serial.printf(" [%d] %s\n", i, ch.name);
chFound = true;
} else {
break;
}
}
if (!chFound) Serial.println(" (none)");
} else {
Serial.printf(" Error: unknown key '%s' (try 'help')\n", key);
}
// =====================================================================
// SET commands — write settings
// =====================================================================
} else if (memcmp(cli_command, "set ", 4) == 0) {
const char* config = &cli_command[4];
if (memcmp(config, "name ", 5) == 0) {
const char* val = &config[5];
// Validate name (same rules as CommonCLI)
bool valid = true;
const char* p = val;
while (*p) {
if (*p == '[' || *p == ']' || *p == '/' || *p == '\\' ||
*p == ':' || *p == ',' || *p == '?' || *p == '*') {
valid = false;
break;
}
p++;
}
if (valid && strlen(val) > 0) {
strncpy(_prefs.node_name, val, sizeof(_prefs.node_name) - 1);
_prefs.node_name[sizeof(_prefs.node_name) - 1] = '\0';
savePrefs();
Serial.printf(" > name = %s\n", _prefs.node_name);
} else {
Serial.println(" Error: invalid name (no []/:,?* chars)");
}
} else if (memcmp(config, "freq ", 5) == 0) {
float f = atof(&config[5]);
if (f >= 400.0f && f <= 928.0f) {
_prefs.freq = f;
savePrefs();
radio_set_params(_prefs.freq, _prefs.bw, _prefs.sf, _prefs.cr);
Serial.printf(" > freq = %.3f (applied)\n", _prefs.freq);
} else {
Serial.println(" Error: freq out of range (400-928)");
}
} else if (memcmp(config, "bw ", 3) == 0) {
float bw = atof(&config[3]);
if (bw >= 7.8f && bw <= 500.0f) {
_prefs.bw = bw;
savePrefs();
radio_set_params(_prefs.freq, _prefs.bw, _prefs.sf, _prefs.cr);
Serial.printf(" > bw = %.1f (applied)\n", _prefs.bw);
} else {
Serial.println(" Error: bw out of range (7.8-500)");
}
} else if (memcmp(config, "sf ", 3) == 0) {
int sf = atoi(&config[3]);
if (sf >= 5 && sf <= 12) {
_prefs.sf = (uint8_t)sf;
savePrefs();
radio_set_params(_prefs.freq, _prefs.bw, _prefs.sf, _prefs.cr);
Serial.printf(" > sf = %d (applied)\n", _prefs.sf);
} else {
Serial.println(" Error: sf out of range (5-12)");
}
} else if (memcmp(config, "cr ", 3) == 0) {
int cr = atoi(&config[3]);
if (cr >= 5 && cr <= 8) {
_prefs.cr = (uint8_t)cr;
savePrefs();
radio_set_params(_prefs.freq, _prefs.bw, _prefs.sf, _prefs.cr);
Serial.printf(" > cr = %d (applied)\n", _prefs.cr);
} else {
Serial.println(" Error: cr out of range (5-8)");
}
} else if (memcmp(config, "tx ", 3) == 0) {
int tx = atoi(&config[3]);
if (tx >= 1 && tx <= MAX_LORA_TX_POWER) {
_prefs.tx_power_dbm = (uint8_t)tx;
savePrefs();
radio_set_tx_power(_prefs.tx_power_dbm);
Serial.printf(" > tx = %d (applied)\n", _prefs.tx_power_dbm);
} else {
Serial.printf(" Error: tx out of range (1-%d)\n", MAX_LORA_TX_POWER);
}
} else if (memcmp(config, "utc ", 4) == 0) {
int utc = atoi(&config[4]);
if (utc >= -12 && utc <= 14) {
_prefs.utc_offset_hours = (int8_t)utc;
savePrefs();
Serial.printf(" > utc = %d\n", _prefs.utc_offset_hours);
} else {
Serial.println(" Error: utc out of range (-12 to 14)");
}
} else if (memcmp(config, "notify ", 7) == 0) {
if (strcmp(&config[7], "on") == 0) {
_prefs.kb_flash_notify = 1;
} else if (strcmp(&config[7], "off") == 0) {
_prefs.kb_flash_notify = 0;
} else {
Serial.println(" Error: use 'on' or 'off'");
cli_command[0] = 0;
return;
}
savePrefs();
Serial.printf(" > notify = %s\n", _prefs.kb_flash_notify ? "on" : "off");
} else if (memcmp(config, "pin ", 4) == 0) {
_prefs.ble_pin = atoi(&config[4]);
savePrefs();
Serial.printf(" > pin is now %06d\n", _prefs.ble_pin);
} else if (memcmp(config, "radio ", 6) == 0) {
// Composite: "set radio <freq> <bw> <sf> <cr>"
char tmp[64];
strncpy(tmp, &config[6], sizeof(tmp) - 1);
tmp[sizeof(tmp) - 1] = '\0';
const char* parts[4];
int num = mesh::Utils::parseTextParts(tmp, parts, 4);
if (num == 4) {
float freq = strtof(parts[0], nullptr);
float bw = strtof(parts[1], nullptr);
int sf = atoi(parts[2]);
int cr = atoi(parts[3]);
if (freq >= 400.0f && freq <= 928.0f && bw >= 7.8f && bw <= 500.0f
&& sf >= 5 && sf <= 12 && cr >= 5 && cr <= 8) {
_prefs.freq = freq;
_prefs.bw = bw;
_prefs.sf = (uint8_t)sf;
_prefs.cr = (uint8_t)cr;
savePrefs();
radio_set_params(_prefs.freq, _prefs.bw, _prefs.sf, _prefs.cr);
radio_set_tx_power(_prefs.tx_power_dbm);
Serial.printf(" > radio = %.3f/%.1f/SF%d/CR%d TX:%d (applied)\n",
_prefs.freq, _prefs.bw, _prefs.sf, _prefs.cr, _prefs.tx_power_dbm);
} else {
Serial.println(" Error: invalid radio params");
}
} else {
Serial.println(" Usage: set radio <freq> <bw> <sf> <cr>");
}
} else if (memcmp(config, "preset ", 7) == 0) {
const char* name = &config[7];
// Try exact match first (case-insensitive)
bool found = false;
for (int i = 0; i < (int)NUM_RADIO_PRESETS; i++) {
if (strcasecmp(RADIO_PRESETS[i].name, name) == 0) {
_prefs.freq = RADIO_PRESETS[i].freq;
_prefs.bw = RADIO_PRESETS[i].bw;
_prefs.sf = RADIO_PRESETS[i].sf;
_prefs.cr = RADIO_PRESETS[i].cr;
_prefs.tx_power_dbm = RADIO_PRESETS[i].tx_power;
savePrefs();
radio_set_params(_prefs.freq, _prefs.bw, _prefs.sf, _prefs.cr);
radio_set_tx_power(_prefs.tx_power_dbm);
Serial.printf(" > Applied preset '%s' (%.3f/%.1f/SF%d/CR%d TX:%d)\n",
RADIO_PRESETS[i].name, _prefs.freq, _prefs.bw,
_prefs.sf, _prefs.cr, _prefs.tx_power_dbm);
found = true;
break;
}
}
// Try by index number if name didn't match
if (!found) {
char* endp;
long idx = strtol(name, &endp, 10);
if (endp != name && *endp == '\0' && idx >= 0 && idx < (int)NUM_RADIO_PRESETS) {
_prefs.freq = RADIO_PRESETS[idx].freq;
_prefs.bw = RADIO_PRESETS[idx].bw;
_prefs.sf = RADIO_PRESETS[idx].sf;
_prefs.cr = RADIO_PRESETS[idx].cr;
_prefs.tx_power_dbm = RADIO_PRESETS[idx].tx_power;
savePrefs();
radio_set_params(_prefs.freq, _prefs.bw, _prefs.sf, _prefs.cr);
radio_set_tx_power(_prefs.tx_power_dbm);
Serial.printf(" > Applied preset '%s' (%.3f/%.1f/SF%d/CR%d TX:%d)\n",
RADIO_PRESETS[idx].name, _prefs.freq, _prefs.bw,
_prefs.sf, _prefs.cr, _prefs.tx_power_dbm);
found = true;
}
}
if (!found) {
Serial.printf(" Error: unknown preset '%s' (try 'get presets')\n", name);
}
} else if (memcmp(config, "channel.add ", 12) == 0) {
const char* name = &config[12];
if (strlen(name) == 0) {
Serial.println(" Error: channel name required");
cli_command[0] = 0;
return;
}
// Build channel name with # prefix if not present
char chanName[32];
if (name[0] == '#') {
strncpy(chanName, name, sizeof(chanName));
} else {
chanName[0] = '#';
strncpy(&chanName[1], name, sizeof(chanName) - 1);
}
chanName[31] = '\0';
// Generate 128-bit PSK from SHA-256 of channel name
ChannelDetails newCh;
memset(&newCh, 0, sizeof(newCh));
strncpy(newCh.name, chanName, sizeof(newCh.name));
newCh.name[31] = '\0';
uint8_t hash[32];
mesh::Utils::sha256(hash, 32, (const uint8_t*)chanName, strlen(chanName));
memcpy(newCh.channel.secret, hash, 16);
// Find next empty slot
bool added = false;
for (uint8_t i = 0; i < MAX_GROUP_CHANNELS; i++) {
ChannelDetails existing;
if (!getChannel(i, existing) || existing.name[0] == '\0') {
if (setChannel(i, newCh)) {
saveChannels();
Serial.printf(" > Added channel '%s' at slot %d\n", chanName, i);
added = true;
}
break;
}
}
if (!added) Serial.println(" Error: no empty channel slots");
} else if (memcmp(config, "channel.del ", 12) == 0) {
int idx = atoi(&config[12]);
if (idx <= 0) {
Serial.println(" Error: cannot delete channel 0 (public)");
} else if (idx >= MAX_GROUP_CHANNELS) {
Serial.printf(" Error: index out of range (1-%d)\n", MAX_GROUP_CHANNELS - 1);
} else {
// Verify channel exists
ChannelDetails ch;
if (!getChannel(idx, ch) || ch.name[0] == '\0') {
Serial.printf(" Error: no channel at index %d\n", idx);
} else {
// Compact: shift channels down
int total = 0;
for (uint8_t i = 0; i < MAX_GROUP_CHANNELS; i++) {
ChannelDetails tmp;
if (getChannel(i, tmp) && tmp.name[0] != '\0') {
total = i + 1;
} else {
break;
}
}
for (int i = idx; i < total - 1; i++) {
ChannelDetails next;
if (getChannel(i + 1, next)) {
setChannel(i, next);
}
}
ChannelDetails empty;
memset(&empty, 0, sizeof(empty));
setChannel(total - 1, empty);
saveChannels();
Serial.printf(" > Deleted channel %d ('%s'), compacted %d channels\n",
idx, ch.name, total);
}
}
#ifdef HAS_4G_MODEM
} else if (memcmp(config, "apn ", 4) == 0) {
const char* apn = &config[4];
if (strlen(apn) > 0) {
modemManager.setAPN(apn);
Serial.printf(" > apn = %s\n", apn);
} else {
ModemManager::saveAPNConfig("");
Serial.println(" > apn cleared (will auto-detect on next boot)");
}
} else if (strcmp(config, "modem on") == 0) {
ModemManager::saveEnabledConfig(true);
modemManager.begin();
Serial.println(" > modem enabled");
} else if (strcmp(config, "modem off") == 0) {
ModemManager::saveEnabledConfig(false);
modemManager.shutdown();
Serial.println(" > modem disabled");
#endif
} else {
Serial.printf(" Error: unknown setting '%s' (try 'help')\n", config);
}
// =====================================================================
// HELP command
// =====================================================================
} else if (strcmp(cli_command, "help") == 0) {
Serial.println("=== Meck Serial CLI ===");
Serial.println(" get <key> Read a setting");
Serial.println(" set <key> <value> Write a setting");
Serial.println("");
Serial.println(" Settings keys:");
Serial.println(" name, freq, bw, sf, cr, tx, utc, notify, pin");
Serial.println("");
Serial.println(" Compound commands:");
Serial.println(" get all Dump all settings");
Serial.println(" get radio Show all radio params");
Serial.println(" get channels List channels");
Serial.println(" get presets List radio presets");
Serial.println(" get pubkey Show public key");
Serial.println(" get firmware Show firmware version");
Serial.println(" set radio <f> <bw> <sf> <cr> Set all radio params");
Serial.println(" set preset <name|num> Apply radio preset");
Serial.println(" set channel.add <name> Add hashtag channel");
Serial.println(" set channel.del <idx> Delete channel by index");
#ifdef HAS_4G_MODEM
Serial.println("");
Serial.println(" 4G modem:");
Serial.println(" get/set apn, get imei, set modem on/off");
#endif
Serial.println("");
Serial.println(" System:");
Serial.println(" rebuild Erase & rebuild filesystem");
Serial.println(" erase Format filesystem");
Serial.println(" reboot Restart device");
Serial.println(" ls / cat / rm File operations");
// =====================================================================
// Existing system commands (unchanged)
// =====================================================================
} else if (strcmp(cli_command, "rebuild") == 0) {
bool success = _store->formatFileSystem();
if (success) {
_store->saveMainIdentity(self_id);
savePrefs();
saveContacts();
saveChannels();
Serial.println(" > erase and rebuild done");
} else {
Serial.println(" Error: erase failed");
}
} else if (strcmp(cli_command, "erase") == 0) {
bool success = _store->formatFileSystem();
if (success) {
Serial.println(" > erase done");
} else {
Serial.println(" Error: erase failed");
}
} else if (memcmp(cli_command, "ls", 2) == 0) {
// get path from command e.g: "ls /adafruit"
const char *path = &cli_command[3];
bool is_fs2 = false;
if (memcmp(path, "UserData/", 9) == 0) {
path += 8; // skip "UserData"
} else if (memcmp(path, "ExtraFS/", 8) == 0) {
path += 7; // skip "ExtraFS"
is_fs2 = true;
}
Serial.printf("Listing files in %s\n", path);
// log each file and directory
File root = _store->openRead(path);
if (is_fs2 == false) {
if (root) {
File file = root.openNextFile();
while (file) {
if (file.isDirectory()) {
Serial.printf("[dir] UserData%s/%s\n", path, file.name());
} else {
Serial.printf("[file] UserData%s/%s (%d bytes)\n", path, file.name(), file.size());
}
// move to next file
file = root.openNextFile();
}
root.close();
}
}
if (is_fs2 == true || strlen(path) == 0 || strcmp(path, "/") == 0) {
if (_store->getSecondaryFS() != nullptr) {
File root2 = _store->openRead(_store->getSecondaryFS(), path);
File file = root2.openNextFile();
while (file) {
if (file.isDirectory()) {
Serial.printf("[dir] ExtraFS%s/%s\n", path, file.name());
} else {
Serial.printf("[file] ExtraFS%s/%s (%d bytes)\n", path, file.name(), file.size());
}
// move to next file
file = root2.openNextFile();
}
root2.close();
}
}
} else if (memcmp(cli_command, "cat", 3) == 0) {
// get path from command e.g: "cat /contacts3"
const char *path = &cli_command[4];
bool is_fs2 = false;
if (memcmp(path, "UserData/", 9) == 0) {
path += 8; // skip "UserData"
} else if (memcmp(path, "ExtraFS/", 8) == 0) {
path += 7; // skip "ExtraFS"
is_fs2 = true;
} else {
Serial.println("Invalid path provided, must start with UserData/ or ExtraFS/");
cli_command[0] = 0;
return;
}
// log file content as hex
File file = _store->openRead(path);
if (is_fs2 == true) {
file = _store->openRead(_store->getSecondaryFS(), path);
}
if(file){
// get file content
int file_size = file.available();
uint8_t buffer[file_size];
file.read(buffer, file_size);
// print hex
mesh::Utils::printHex(Serial, buffer, file_size);
Serial.print("\n");
file.close();
}
} else if (memcmp(cli_command, "rm ", 3) == 0) {
// get path from command e.g: "rm /adv_blobs"
const char *path = &cli_command[3];
MESH_DEBUG_PRINTLN("Removing file: %s", path);
// ensure path is not empty, or root dir
if(!path || strlen(path) == 0 || strcmp(path, "/") == 0){
Serial.println("Invalid path provided");
} else {
bool is_fs2 = false;
if (memcmp(path, "UserData/", 9) == 0) {
path += 8; // skip "UserData"
} else if (memcmp(path, "ExtraFS/", 8) == 0) {
path += 7; // skip "ExtraFS"
is_fs2 = true;
}
// remove file
bool removed;
if (is_fs2) {
MESH_DEBUG_PRINTLN("Removing file from ExtraFS: %s", path);
removed = _store->removeFile(_store->getSecondaryFS(), path);
} else {
MESH_DEBUG_PRINTLN("Removing file from UserData: %s", path);
removed = _store->removeFile(path);
}
if(removed){
Serial.println("File removed");
} else {
Serial.println("Failed to remove file");
}
}
} else if (strcmp(cli_command, "reboot") == 0) {
board.reboot(); // doesn't return
} else {
Serial.println(" Error: unknown command (try 'help')");
}
cli_command[0] = 0; // reset command buffer
}
}
void MyMesh::checkSerialInterface() {
size_t len = _serial->checkRecvFrame(cmd_frame);
if (len > 0) {
handleCmdFrame(len);
} else if (_iter_started // check if our ContactsIterator is 'running'
&& !_serial->isWriteBusy() // don't spam the Serial Interface too quickly!
) {
ContactInfo contact;
if (_iter.hasNext(this, contact)) {
if (contact.lastmod > _iter_filter_since) { // apply the 'since' filter
writeContactRespFrame(RESP_CODE_CONTACT, contact);
if (contact.lastmod > _most_recent_lastmod) {
_most_recent_lastmod = contact.lastmod; // save for the RESP_CODE_END_OF_CONTACTS frame
}
}
} else { // EOF
out_frame[0] = RESP_CODE_END_OF_CONTACTS;
memcpy(&out_frame[1], &_most_recent_lastmod,
4); // include the most recent lastmod, so app can update their 'since'
_serial->writeFrame(out_frame, 5);
_iter_started = false;
}
//} else if (!_serial->isWriteBusy()) {
// checkConnections(); // TODO - deprecate the 'Connections' stuff
}
}
void MyMesh::loop() {
BaseChatMesh::loop();
if (_cli_rescue) {
checkCLIRescueCmd();
} else {
checkSerialInterface();
}
// is there are pending dirty contacts write needed?
if (dirty_contacts_expiry && millisHasNowPassed(dirty_contacts_expiry)) {
saveContacts();
dirty_contacts_expiry = 0;
}
// Discovery scan timeout
if (_discoveryActive && millisHasNowPassed(_discoveryTimeout)) {
_discoveryActive = false;
Serial.printf("[Discovery] Scan complete: %d nodes found\n", _discoveredCount);
}
#ifdef DISPLAY_CLASS
if (_ui) _ui->setHasConnection(_serial->isConnected());
#endif
}
bool MyMesh::advert() {
mesh::Packet* pkt;
if (_prefs.advert_loc_policy == ADVERT_LOC_NONE) {
pkt = createSelfAdvert(_prefs.node_name);
} else {
pkt = createSelfAdvert(_prefs.node_name, sensors.node_lat, sensors.node_lon);
}
if (pkt) {
sendZeroHop(pkt);
return true;
} else {
return false;
}
}
void MyMesh::startDiscovery(uint32_t duration_ms) {
_discoveredCount = 0;
_discoveryActive = true;
_discoveryTimeout = futureMillis(duration_ms);
_discoveryTag = getRNG()->nextInt(1, 0xFFFFFFFF);
Serial.printf("[Discovery] Active scan started (%lu ms, tag=%08X)\n",
duration_ms, _discoveryTag);
// --- Send active discovery request (CTL_TYPE_NODE_DISCOVER_REQ) ---
// Repeaters with firmware v1.11+ will respond with their pubkey + SNR
uint8_t ctl_payload[10];
ctl_payload[0] = CTL_TYPE_NODE_DISCOVER_REQ; // 0x80, prefix_only=0 (full 32-byte pubkeys)
ctl_payload[1] = (1 << ADV_TYPE_REPEATER) // repeaters
| (1 << ADV_TYPE_ROOM); // rooms (repeaters with chat)
memcpy(&ctl_payload[2], &_discoveryTag, 4); // random correlation tag
uint32_t since = 0; // accept all firmware versions
memcpy(&ctl_payload[6], &since, 4);
auto pkt = createControlData(ctl_payload, sizeof(ctl_payload));
if (pkt) {
sendZeroHop(pkt);
Serial.println("[Discovery] Sent CTL_TYPE_NODE_DISCOVER_REQ (zero-hop)");
} else {
Serial.println("[Discovery] ERROR: createControlData returned NULL (packet pool full?)");
}
}
void MyMesh::stopDiscovery() {
_discoveryActive = false;
}
bool MyMesh::addDiscoveredToContacts(int idx) {
if (idx < 0 || idx >= _discoveredCount) return false;
if (_discovered[idx].already_in_contacts) return true; // already there
// Retrieve cached raw advert packet and import it
uint8_t buf[256];
int plen = getBlobByKey(_discovered[idx].contact.id.pub_key, PUB_KEY_SIZE, buf);
if (plen > 0) {
bool ok = importContact(buf, (uint8_t)plen);
if (ok) {
_discovered[idx].already_in_contacts = true;
dirty_contacts_expiry = futureMillis(LAZY_CONTACTS_WRITE_DELAY);
MESH_DEBUG_PRINTLN("Discovery: added contact '%s'", _discovered[idx].contact.name);
}
return ok;
}
MESH_DEBUG_PRINTLN("Discovery: no cached advert blob for contact '%s'", _discovered[idx].contact.name);
return false;
}
Reference in New Issue View Git Blame Copy Permalink