# RNodeTHV4 — Reticulum Boundary Node for Heltec WiFi LoRa 32 V3 / V4 A custom firmware for the **Heltec WiFi LoRa 32 V3** and **V4** (ESP32-S3 + SX1262) that operates as a **Boundary Node** — bridging a local LoRa radio network with a remote TCP/IP backbone (such as [rmap.world](https://rmap.world)) over WiFi. ``` Android / Sideband Remote ┌──────────┐ ┌────────────┐ Reticulum │ Sideband │◄── BT ──►│ RNode (BT) │ Backbone │ App │ └─────┬──────┘ (rnsd / └──────────┘ │ rmap.world) LoRa Radio ▲ │ ┌──────────────┐ WiFi │ ◄── RF mesh ──────► │ RNodeTHV4 │ ◄─TCP──┘ │ │ Boundary Node│ ▲ Other RNodes └──────────────┘ │ ┌───┴───┐ │ Router│ └───────┘ ``` Built on [microReticulum](https://github.com/attermann/microReticulum) (a C++ port of the [Reticulum](https://reticulum.network/) network stack) and the [RNode firmware](https://github.com/markqvist/RNode_Firmware) by Mark Qvist. ## Features - **Bidirectional LoRa ↔ TCP bridging** — local LoRa mesh nodes can reach the global Reticulum backbone and vice versa - **Web-based configuration portal** — WiFi SSID/password, backbone host/port, LoRa parameters, all configurable via captive portal - **OLED status display** — real-time status indicators for LoRa, WiFi, WAN (backbone), LAN (local TCP), plus IP address, port, and airtime - **Optional local TCP server** — serve local devices on your WiFi in addition to the backbone connection - **Automatic reconnection** — WiFi and TCP connections recover from drops with exponential backoff - **ESP32 memory-optimized** — table sizes, timeouts, and caching tuned for the constrained MCU environment - **Dual board support** — supports both Heltec V3 (8MB flash) and V4 (16MB flash, 2MB PSRAM) with automatic board and PSRAM detection ## Hardware Both the **Heltec WiFi LoRa 32 V3** and **V4** are supported. These boards were chosen for their ample flash and LoRa capabilities. PSRAM availability varies — the V4 ships with 2 MB PSRAM, while the V3 uses the ESP32-S3FN8 which has **no PSRAM**. The firmware **detects PSRAM at runtime** and allocates the TLSF memory pool from SPIRAM when available, falling back to internal SRAM (~170 KB) on boards without PSRAM. | Component | Heltec V3 | Heltec V4 | |-----------|-----------|----------| | **MCU** | ESP32-S3 (ESP32-S3FN8) | ESP32-S3 (ESP32-S3FH4R2) | | **Flash** | 8 MB | 16 MB | | **PSRAM** | None | 2 MB (QSPI) | | **Radio** | SX1262 | SX1262 + GC1109 PA | | **TX Power** | Up to 22 dBm | Up to 28 dBm | | **Display** | SSD1306 OLED 128×64 | SSD1306 OLED 128×64 | | **WiFi** | 2.4 GHz 802.11 b/g/n | 2.4 GHz 802.11 b/g/n | | **USB** | Native USB CDC | Native USB CDC | ## Quick Start ### Option A: Easy Flash (no PlatformIO required) The easiest way to flash a pre-built firmware. You only need Python 3 and a USB cable. ```bash # Install esptool (one time) pip install esptool # Clone this repo (or download just flash.py + the firmware binary) git clone https://github.com/jrl290/RNodeTHV4.git cd RNodeTHV4 # Download latest firmware from GitHub Releases and flash # (auto-detects V3 vs V4 from flash size) python flash.py --download # Or specify board explicitly python flash.py --download --board v3 python flash.py --download --board v4 # Or flash a local binary python flash.py --file rnodethv4_firmware.bin ``` The flash utility auto-detects whether a V3 or V4 is connected by querying the flash size (8MB = V3, 16MB = V4). You can override with `--board v3` or `--board v4`. It will list all available serial ports and prompt you to choose one. If no ports are detected, you may need to hold the **BOOT** button while pressing **RESET** to enter download mode. ### Option B: Build from Source (PlatformIO) For development or customization: ```bash # Prerequisites: PlatformIO installed (VS Code extension or CLI) git clone https://github.com/jrl290/RNodeTHV4.git cd RNodeTHV4 # Build for V4 pio run -e heltec_V4_boundary # Build for V3 pio run -e heltec_V3_boundary # Flash (via PlatformIO) pio run -e heltec_V4_boundary -t upload # Or create a merged binary and flash with the utility python flash.py --merge-only # creates merged firmware bin python flash.py # flash it (auto-detects board) # Monitor serial output (optional) pio device monitor -e heltec_V4_boundary ``` ### Option C: Manual esptool Flash If you have the merged binary (`rnodethv4_firmware.bin`), you can flash it with a single esptool command: ```bash esptool.py --chip esp32s3 --port /dev/ttyACM0 --baud 921600 \ write_flash -z --flash_mode qio --flash_freq 80m --flash_size 16MB \ 0x0 rnodethv4_firmware.bin ``` Replace `/dev/ttyACM0` with your serial port (`/dev/cu.usbmodem*` on macOS, `COM3` on Windows). On first boot (or if no configuration is found), the device automatically enters the **Configuration Portal**. ## Configuration Portal ### Entering Config Mode The config portal activates automatically on: - **First boot** — when no saved configuration exists - **Button hold >5 seconds** — hold the PRG button for 5+ seconds, the device reboots into config mode When active, the device creates a WiFi access point named **`RNode-Boundary-Setup`** (open network). A captive portal should appear automatically when you connect; if not, browse to `http://192.168.4.1`. ### Config Page Options The web form has four sections: #### 📶 WiFi Network | Field | Description | |-------|-------------| | **WiFi** | Enable/Disable (disable for LoRa-only repeater mode) | | **SSID** | Your WiFi network name | | **Password** | WiFi password | #### 🌐 TCP Backbone | Field | Description | |-------|-------------| | **Mode** | `Disabled` or `Client (connect to backbone)` | | **Backbone Host** | IP address or hostname of backbone server (e.g. `rmap.world`) | | **Backbone Port** | TCP port (default: `4242`) | #### 📡 Local TCP Server (optional) | Field | Description | |-------|-------------| | **Local TCP Server** | Enable/Disable — runs a TCP server on your WiFi for local Reticulum nodes to connect | | **TCP Port** | Port to listen on (default: `4242`) | #### 📻 LoRa Radio | Field | Description | |-------|-------------| | **Frequency** | e.g. `867.200` MHz — must match your other RNodes | | **Bandwidth** | 7.8 kHz – 500 kHz (typically `125 kHz`) | | **Spreading Factor** | SF6 – SF12 (typically `SF7` for backbone, `SF10` for long range) | | **Coding Rate** | 4/5 – 4/8 | | **TX Power** | 2 – 28 dBm | After saving, the device reboots with the new configuration applied. ## OLED Display Layout The 128×64 OLED is split into two panels: ### Left Panel — Status Indicators (64×64) ``` ● LORA ← filled circle = radio online ○ wifi ← unfilled circle = WiFi disconnected ● WAN ← filled = backbone TCP connected ● LAN ← filled = local TCP client connected ──────────────── Air:0.3% ← current LoRa airtime ▓▓▓▓▓ ||||||| ← battery, signal quality ``` - **Filled circle (●)** = active/connected - **Unfilled circle (○)** = inactive/disconnected - Labels are UPPERCASE when active, lowercase when inactive (except LAN which is always uppercase) - **LAN row is hidden** when the Local TCP Server is disabled in configuration — the remaining layout stays in place ### Right Panel — Device Info (64×64) ``` ▓▓ RNodeTHV4 ▓▓ ← title bar (inverted) 867.200MHz ← LoRa frequency SF7 125k ← spreading factor & bandwidth ──────────────── ← separator 192.168.1.42 ← WiFi IP address (or "No WiFi") Port:4242 ← Local TCP server port ──────────────── ← separator ``` - **Port** shows the Local TCP server port (the port local nodes connect to), not the backbone port - **Port line is hidden** when the Local TCP Server is disabled ## Interface Modes The firmware runs up to **three RNS interfaces** simultaneously, using different interface modes to control announce propagation and routing behavior: ### LoRa Interface — `MODE_ACCESS_POINT` The LoRa radio operates in **Access Point mode**. In Reticulum, this means: - The interface broadcasts its own announces but **blocks rebroadcast of remote announces** from crossing to LoRa - This prevents backbone announces (hundreds of remote destinations) from flooding the limited-bandwidth LoRa channel - Local nodes discover the boundary node directly; the boundary node answers path requests for remote destinations from its cache ### TCP Backbone Interface — `MODE_BOUNDARY` The TCP backbone connection uses `MODE_BOUNDARY` (`0x20`), a custom implementation of the Reticulum boundary concept adapted for the memory-constrained ESP32 environment. In this implementation, boundary mode means: - Incoming announces from the backbone are received and cached, but **not stored in the path table by default** — only stored when specifically requested via a path request from a local LoRa node - This prevents the path table (limited to 48 entries on ESP32) from being overwhelmed by thousands of backbone destinations - When the path table needs to be culled, **boundary-mode paths are evicted first**, preserving locally-needed LoRa paths ### Optional Local TCP Server — `MODE_ACCESS_POINT` If enabled, a TCP server on the WiFi network allows local Reticulum nodes to connect. It also uses Access Point mode, with the same announce filtering as LoRa. **Implementation details:** - Each TCP interface must have a **unique name** to produce a unique interface hash — the backbone uses `"TcpInterface"` and the local server uses `"LocalTcpInterface"`. Without distinct names, both interfaces produce the same hash, causing the interface map lookup to fail when routing packets. - TCP interfaces are configured with a **10 Mbps bitrate**, which causes Reticulum's Transport to prefer TCP paths over LoRa paths (typically ~1–10 kbps) when both are available for the same destination. - When the Local TCP Server is disabled, its status indicator (LAN) and port number are hidden from the OLED display. ## Routing & Memory Customizations The ESP32-S3 has limited RAM compared to a desktop Reticulum node. Several customizations were made to the microReticulum library to operate reliably within these constraints: ### Table Size Limits | Table | Default (Desktop) | RNodeTHV4 | Rationale | |-------|-------------------|-----------|-----------| | Path table (`_destination_table`) | Unbounded | **48 entries** | Prevents unbounded growth; boundary paths evicted first | | Hash list (`_hashlist`) | 1,000,000 | **32** | Packet dedup list; small is fine for low-throughput LoRa | | Path request tags (`_max_pr_tags`) | 32,000 | **32** | Pending path requests rarely exceed a few dozen | | Known destinations | 100 | **24** | Identity cache; rarely need more on a boundary node | | Max queued announces | 16 | **4** | Outbound announce queue; LoRa is slow, no point queuing many | | Max receipts | 1,024 | **20** | Packet receipt tracking | ### Timeout Reductions | Setting | Default | RNodeTHV4 | Rationale | |---------|---------|-----------|-----------| | Destination timeout | 7 days | **1 day** | Free memory faster; stale paths re-resolve automatically | | Pathfinder expiry | 7 days | **1 day** | Same as above | | AP path time | 24 hours | **6 hours** | AP paths go stale faster in mesh environments | | Roaming path time | 6 hours | **1 hour** | Mobile nodes change paths frequently | | Table cull interval | 5 seconds | **60 seconds** | Less CPU overhead on culling | | Job/Clean/Persist intervals | 5m/15m/12h | **60s/60s/60s** | More frequent housekeeping for MCU stability | ### Selective Backbone Caching The most critical optimization: **backbone announces are not stored in the path table by default**. A backbone like `rmap.world` may advertise hundreds of destinations. Storing them all would evict every local LoRa path. Instead: 1. Backbone announces are received and their packets cached to flash storage 2. When a local LoRa node requests a path, the boundary checks its cache and responds directly 3. Only **specifically requested** paths get a path table entry 4. Path table culling prioritizes evicting backbone entries over local ones ### Default Route Forwarding When a transport-addressed packet arrives from LoRa but the boundary has no path table entry for it, the firmware: 1. Strips the transport headers (converts `HEADER_2` → `HEADER_1/BROADCAST`) 2. Forwards the raw packet to the backbone interface 3. Creates reverse-table entries so proofs can route back to the sender This acts as a **default route** — any packet the boundary can't route locally gets forwarded to the backbone. ### Cached Packet Unpacking Fix The original microReticulum `get_cached_packet()` function called `update_hash()` after deserializing cached packets from flash. However, `update_hash()` only computes the packet hash — it does **not** parse the raw bytes into fields like `destination_hash`, `data`, `flags`, etc. This was changed to call `unpack()` instead, which parses all packet fields AND computes the hash. Without this fix, path responses contained empty destination hashes and were silently dropped by LoRa nodes. > **Note:** `unpack()` only parses the plaintext routing envelope (destination hash, flags, hops, transport headers). It does not decrypt the end-to-end encrypted payload. Every Reticulum transport node performs equivalent header parsing during normal routing — this is standard behavior, not a security concern. ### Path Table Update Fix The C++ `std::map::insert()` method silently does nothing when a key already exists — unlike Python's `dict[key] = value` which replaces. The original microReticulum code used `insert()` to update path table entries, meaning stale LoRa paths were never replaced by newer TCP paths (or vice versa). This was fixed by calling `erase()` before `insert()`, ensuring updated path entries always replace stale ones. Without this fix, the boundary node would continue routing packets via an old interface even after a better path was learned. ### Interface Name Uniqueness Each RNS interface must have a **unique name** because the name is hashed to produce the interface identifier used in path table lookups. If two interfaces share the same name, they produce the same hash, and `std::map` can only store one — causing the Transport layer to fail to resolve the correct outbound interface for packets. The TcpInterface constructor accepts an explicit `name` parameter: the backbone uses `"TcpInterface"` and the local server uses `"LocalTcpInterface"`. ## Connecting to the Backbone ### Example: Connect to rmap.world In the configuration portal: 1. Set WiFi SSID and password 2. Set TCP Backbone Mode to **Client** 3. Set Backbone Host to `rmap.world` 4. Set Backbone Port to `4242` 5. Save and reboot ### Example: Local rnsd Server On your server, configure `rnsd` with a TCP Server Interface in `~/.reticulum/config`: ```ini [interfaces] [[TCP Server Interface]] type = TCPServerInterface listen_host = 0.0.0.0 listen_port = 4242 ``` Then configure the boundary node as a **Client** pointing to your server's IP. ### Example: rnsd Connects to Boundary On your server, configure `rnsd` with a TCP Client Interface: ```ini [interfaces] [[TCP Client to Boundary]] type = TCPClientInterface target_host = target_port = 4242 ``` Set the boundary node's **Local TCP Server** to **Enabled** (port 4242). ## Architecture ### Key Files | File | Purpose | |------|---------| | `RNode_Firmware.ino` | Main firmware — boundary mode initialization, interface setup, button handling | | `BoundaryMode.h` | Boundary state struct, EEPROM load/save, configuration defaults | | `BoundaryConfig.h` | Web-based captive portal for configuration | | `TcpInterface.h` | TCP interface for both backbone and local server (implements `RNS::InterfaceImpl`) with HDLC framing, unique naming, and 10 Mbps bitrate | | `Display.h` | OLED display layout — boundary-specific status page | | `flash.py` | Flash utility — list serial ports, download from GitHub, merge & flash firmware | | `Boards.h` | Board variant definitions for V3 and V4 | | `platformio.ini` | Build targets: `heltec_V3_boundary`, `heltec_V4_boundary`, and `heltec_V4_boundary-local` | ### Library Patches The firmware depends on [microReticulum](https://github.com/attermann/microReticulum) `0.2.4`, automatically fetched by PlatformIO on first build. After the first build, the library sources under `.pio/libdeps/heltec_V4_boundary/microReticulum/src/` need the patches described in "Routing & Memory Customizations" above. Key files modified: | File | Changes | |------|---------| | `Transport.cpp` | Selective caching, default route forwarding, boundary-aware culling, `get_cached_packet()` unpack fix, path table `erase()+insert()` fix, memory limits | | `Transport.h` | `MODE_BOUNDARY`, `PacketEntry`, `Callbacks`, `cull_path_table()`, configurable table sizes | | `Identity.cpp` | `_known_destinations_maxsize` = 24, `cull_known_destinations()` | | `Type.h` | `MODE_BOUNDARY` = 0x20, reduced `MAX_QUEUED_ANNOUNCES`, `MAX_RECEIPTS`, shorter timeouts | ### Memory Usage (typical, V4) | Resource | Used | Available | |----------|------|----------| | RAM | ~21.7% | 320 KB | | Flash | ~18.4% | 16 MB | | PSRAM | Dynamic | 2 MB | ## License This project is licensed under the **GNU General Public License v3.0** — see [LICENSE](LICENSE) for details. Based on: - [RNode Firmware](https://github.com/markqvist/RNode_Firmware) by Mark Qvist (GPL-3.0) - [microReticulum](https://github.com/attermann/microReticulum) by Chris Attermann (GPL-3.0) - [Reticulum](https://reticulum.network/) by Mark Qvist (MIT)