# RP412 Front End & Steam Multiplayer — Design Notes Findings from reading TeslaConsole's Red Planet control code (`TeslaSuite/Console/TeslaConsole.RedPlanet/`) against the game side (`MUNGA_L4/L4NET.CPP`, `MUNGA/NETWORK.cpp`), and how a Steam front end maps onto it. Written 2026-07-12 for the implement-decision. ## 1. What the console actually does TeslaConsole is four things, and RP412's front end must absorb all four: ### a) Pod control channel (`Munga.Net`, TCP console port) Per-pod state machine (`RPGame.cs`): take **ownership** of a pod, watch its app state, and drive the lifecycle: ``` WaitingForEgg --egg chunks--> (ACK, 5s retry) WaitingForLaunch --RunMissionMessage--> RunningMission --telemetry--> EndMission (final scores) --AbortMissionMessage--> reset ``` The egg is sent as `EggFileMessage` chunks of 1000 bytes with an `AcknowledgeEggFileMessage` reply from the pod. ### b) The mission egg (the ENTIRE mission definition) A NotationFile-format text file (`RPMission.ToEggString()`), newline→NUL: ```ini [mission] adventure=Red Planet, scenario, map, time, weather, temperature, compression, length (seconds) [pilots] ordered pilot= list (players, then cameras) [
] per participant: hostType, dropzone, name, bitmapindex, loadzones, vehicle, color, badge (+ team/position in football) [largebitmap] player names PRE-RENDERED as 1bpp bitmaps for the plasma [smallbitmap] glass (128x32 and 64x16), generated by the console [ordinals] 1st-4th place plasma graphics (hardcoded art) ``` The game already loads a local egg with `-egg ` (standalone mode) — the same text format. **Building an egg locally = the whole single-player front end problem.** ### c) The catalog (`RedPlanet/RPConfig.xml`) Two scenarios — **Martian Death Race** and **Martian Football** (2-color teams, crusher/blocker/runner positions) — 11 maps, ~30 vehicles (sharing a handful of models), 9 colors, 11 badges, day/night, 3 weather levels, with per-scenario exclusion lists. Clean data file; reusable as-is. ### d) Results & telemetry During the mission the pods stream `VTVBooster/Damaged/Killed/Scored/ ScoreUpdate` and `EndMission(finalScore)` to the console host, which records them (`RPMissionRecorder`) into `RPMissionResults` and prints score sheets. The consumer version wants this as a post-race results screen (and, later, Steam leaderboards/achievements fed from the same events). ## 2. How the pods network with each other (the key finding) The console does NOT relay gameplay. Every pod receives the *same* egg, and `L4NetworkManager::StartConnecting` builds a **deterministic full TCP mesh** from the ordered `[pilots]` list: - Resolve each address (`ip[:port]`, default = game port). - Entries **before your own**: open a TCP connection to them. - Entries **after your own**: listen for their incoming connection. - No entry matching a local address → single-user mode, immediate load. - Egg-from-network (`SlaveMode`) → ACK the egg, wait for mesh completion. So the "lobby protocol" is simply: *agree on an ordered participant list, then everyone meshes*. This is an exceptionally good fit for Steam. ## 3. Steam mapping (plan) | Arcade concept | Steam concept | |---|---| | TeslaConsole operator | **Lobby owner** (host player) | | Pod list / Site Management | `ISteamMatchmaking` lobby members | | Pilot config dialog | In-lobby cockpit UI; member data (name/vehicle/color/badge) via lobby member data | | Egg delivery + ACK | Owner builds the canonical egg, distributes via lobby data or reliable P2P channel; same ACK semantics | | `[pilots]` host addresses | **Ordered SteamID list** — same list, different address type | | TCP mesh (`StartConnecting`) | `ISteamNetworkingSockets` P2P mesh over SDR: ConnectP2P to earlier entries, accept later ones — the connect/listen ordering ports 1:1 | | Console telemetry sink | Lobby owner doubles as the console host (results collection); results screen replaces the printout | | Site network / fixed IPs | NAT traversal + IP privacy for free via Steam Datagram Relay | Transport seam: mirror the `RIOBase` pattern at the L4NET layer — a `NetTransport` interface with the existing WinSock TCP implementation (LAN/dev, keeps working today) and a Steam-sockets implementation (retail). `L4Host` keeps its identity/queue role; only connect/listen/send/recv move behind the interface. **Status (2026-07-12): the seam is IN.** `MUNGA_L4/L4NETTRANSPORT.h/.cpp` defines `NetTransport` (startup/cleanup, local-address list, ip[:port] resolve, connect/listen/accept/close, send/receive, remote-address) with `WinsockNetTransport` as the process default; L4NET.CPP contains no raw Winsock calls anymore. `MUNGA_L4/L4STEAMTRANSPORT.h` documents the per-method ISteamNetworkingSockets mapping (FakeIP keeps the `[pilots]` list as IPv4 strings) and stays behind `RP412_STEAM` until the Steamworks SDK is dropped at `extern\steamworks` (partner-login download). Remaining Steam work: SDK drop → implement `SteamNetTransport` → lobby UI in the front end (owner collects FakeIPs/loadouts via lobby data, builds and distributes the canonical egg, runs the RPL4CONSOLE marshal) → install with `NetTransport_Set` at WinMain when launched under Steam. **Multi-pod verified (2026-07-12):** `tools/two-pod-test.ps1` runs two `-net` pods on loopback (console ports 1501/1601 → game ports 1502/1602) marshaled by a minimal console feeder built on TeslaSuite's vendored `Munga Net.dll`. Confirmed end to end through the seam: egg chunks + per-pod ACK after "All connections completed!" (pod A listened, pod B connected from its bound game port — the deterministic mesh), both pods raced the same 60s mission, StopMission(0) ended it, and both pods returned EndMission final scores. The feeder is exactly the marshal the Steam lobby owner will run in-process. **SteamNetTransport implemented (2026-07-12, SDK 1.64 vendored at `extern/steamworks_sdk_164`):** `L4STEAMTRANSPORT.cpp` is the full FakeIP implementation — `SteamNetTransport_Install()` (SteamAPI init, relay access, `BeginAsyncRequestFakeIP(2)`: fake port 0 = console channel, 1 = game mesh) swaps the process wire when `RP412STEAM=1`; any failure logs and stays on TCP. Addressing convention: all pods launch with the same `-net` port, eggs carry `:`, and only the transport maps engine ports ↔ Steam fake ports (peers fed by `SteamNetTransport_RegisterPeer`). Runtime-verified on this box: `SteamNetTransport: up as 169.254.59.52 (fake ports 32256 console, 32257 game)` under AppID 480, graceful TCP fallback without Steam, default boot untouched. `steam_api.dll` ships in the dist. Remaining for Steam multiplayer: the lobby (front-end UI + `ISteamMatchmaking`): owner collects each member's FakeIP + fake game port + loadout via lobby member data, feeds `RegisterPeer` on every pod, builds/distributes the canonical egg over a reliable channel, and runs the RPL4CONSOLE marshal. Needs a second Steam account/machine to test end to end. ## 4. Implementation options (decide here) **A. In-engine front end (recommended).** Port the egg builder (~300 lines: `RPMission/RPPlayer.ToEggString` + the plasma name-bitmap generator) to C++ inside RP_L4. New application state before `WaitingForEgg`: a menu that renders on the cockpit displays we just built — scenario/map/weather/length on the viewscreen, selections driven by the MFD buttons and map presets (the cockpit IS the menu — maximally pod-authentic). Single player works immediately: build egg → hand to the existing egg-load path. Multiplayer then layers the Steam lobby under the same UI (owner builds the egg, distributes, mesh over Steam sockets). **B. Standalone launcher app** (C#, reuse TeslaConsole code nearly verbatim, drive the game via `-net` + console port like the arcade). Fastest to stand up, but a second process, not cockpit-feel, and awkward under Steam (overlay, launch flow, no in-game rejoin). Useful as a dev tool, not the product. **C. Hybrid:** in-engine UI, but mission/egg logic in a small shared C++ library so a dev console tool and the game share one egg builder. ### Open decisions 1. Front end location — Option A (in-engine, cockpit-rendered) confirmed? 2. v1 scenario scope — Death Race only, or Football (needs teams UI) too? 3. Results screen — post-race on the cockpit displays (replaces printout)? 4. Steam model — lobby-owner-as-console confirmed? (Implies owner migration handling later; the egg re-issue path makes host migration plausible.) 5. Pilot identity — Steam persona as pilot name; vehicle/color/badge persisted per player (Steam Cloud later)?