Document Live Cam + Mission Review architecture (CAMERA-REVIEW-NOTES.md)
Researched from the readable RP MUNGA source (BT shares the engine): host roles are assigned per-IP in the mission egg (hostType= on each pilot page); a CameraShip/MissionReview host gets a CameraDirector player that auto-cuts to the top-ranked pilot every 10s, with manual flight via the same cockpit hardware as pods (CameraRIOMapper) and fixed clamped trackside cameras authored in-game into MAPS/<map>.cam. Mission Review records raw NetworkPackets (SpoolFile -> last.spl) and replays them through a networkless playback app with timestamp bias -- the replay re-simulates the battle from replication traffic. Same BTL4OPT.EXE serves every role; standing up Live Cam on the emulated pod LAN is an egg edit, not a build. Co-Authored-By: Claude Fable 5 <noreply@anthropic.com>
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# Live Cam & Mission Review — how the VWE games did it
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Research notes, 2026-07-08. Sources: `CODE/RP/MUNGA` + `CODE/RP/MUNGA_L4`
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(the readable Red Planet tree; BattleTech shares the MUNGA engine and has the
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matching `CODE/BT/BT_L4/BTL4PB.HPP` + `CODE/BT/MUNGA/SPOOLER.HPP`), the
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`sda4/BTLIVE/MAPS/*.CAM` files, and the mission eggs. Everything below is from
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the code itself, not conjecture, except where marked.
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Both features ride the same insight: the game is a **replicated-entity
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network simulation**. Every machine on the mission LAN runs the full sim and
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mirrors the others' entities from network traffic (master/replicant, see
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`HOST.HPP`). A spectator view is therefore just *one more host* that renders
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without piloting — and a replay is just *the same network traffic played back
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from a file*.
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## 1. Host roles come from the mission egg
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`HOST.HPP:41`:
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```cpp
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enum HostType {
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GameMachineHostType, // 0 — a pod
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CameraShipHostType, // 1 — Live Cam station
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MissionReviewHostType, // 2 — replay station
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ConsoleHostType // 3 — the ops console
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};
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```
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The console assigns a role to every IP on the mission when it authors the
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egg. Each `[pilots] pilot=<ip>` page carries a **mandatory `hostType=` key**
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(`MISSION.CPP:480` — boot aborts with *"ERROR: no host type in egg!"* if
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absent). Our own `cavern.egg` shows a pod: `[200.0.0.113] hostType=0 ...`.
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At player-creation time, `Registry::MakePlayer` (`REGISTRY.CPP:255`) switches
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on the local host's type:
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- `GameMachineHostType` → an ordinary `Player` (pod pilot);
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- `CameraShipHostType` / `MissionReviewHostType` → a **`CameraDirector`**
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player (the comment notes "Not a CameraShip to run on a POD!").
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- Additionally, if the mission's `gamemodel` field is `"camera"`, the
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player's *vehicle* gets `CameraShipPlayerFlag` — so a GameMachine host can
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also fly a camera ("VTV, Mech, CameraShip w/controls" per the comment).
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**The same game EXE serves every role** — pod, camera, review — chosen purely
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by the egg. This is the actionable heart of it for us (§5).
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## 2. Live Cam = CameraShip + CameraDirector
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Classes: `CAMSHIP.HPP/CPP` (the flying camera vehicle, a `Mover` entity) and
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`DIRECTOR.HPP/CPP` (the auto-director, a `Player` subclass).
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- **CameraDirector** (`DIRECTOR.CPP:184 BeADirector`): every frame it checks
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`timeLeftOnPlayer`; when it expires it finds the **top-ranked player**
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(`FindPlayerByRank(0)` over the "Players" entity group) and, if the leader
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changed, dispatches a `CameraShip::DirectionMessage{goalEntity,
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timeOnCamera, focusOffset}` and resets the shot clock to **10 seconds**.
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So the default broadcast is "follow the leader, re-cut every 10 s".
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- **HUD** (`DIRECTOR.CPP:118 UpdateHUD` + `CameraShipHUDRenderable` in
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`L4VIDRND.CPP:2199`): the feed overlays the followed player's identity and
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a **ranking window** cycling 10 s on / 15 s off — always on during the
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final 30 s of the mission, hidden once the mission stops.
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- **CameraShip** (`CAMSHIP.CPP:340 FollowGoal`): aims at
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`focusOffset × goal->localToWorld`, tracks the goal's linear position, and
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asks the director for a new goal when `timeOnCamera` runs out. Camera
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height is operator-adjustable (`ApplyControlledCameraHeight`).
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### Manual camera operation
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`CAMMPPR.HPP` (`CameraControlsMapper` subsystem) + `L4MPPR.HPP`: the camera
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station reads **the same cockpit hardware as a pod** — there are three
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concrete mappers: `CameraL4Mapper`, `CameraThrustmasterMapper`, and
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`CameraRIOMapper` (a full RIO cockpit could fly the camera). Attributes:
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stick / throttle / pedals / reverse-thrust / drive-camera / slide-or-clamp.
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Buttons: **DirectorMode** toggle (auto-director vs manual),
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**Increment/DecrementCamera** (cut between fixed cameras), and
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**Create/Delete/OutputCameraInstances** — the camera-authoring workflow.
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### Fixed trackside cameras — the `.CAM` files
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`CAMINST.HPP/CPP` + `CAMMGR.CPP` (`CameraInstanceManager`): each map has a
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notation file **`MAPS/<map>.cam`** (e.g. `sda4/BTLIVE/MAPS/ARENA1.CAM`)
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holding `[cameraN]` pages:
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```ini
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[camera0]
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cameraID=0
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cameraType=DefaultCameraType ; or AlwaysSeesCameraType
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tranx/y/z = position
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quatx/y/z/w = orientation
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minYawClamp/maxYawClamp ; pan limits (radians)
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minPitchClamp/maxPitchClamp ; tilt limits
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```
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These are broadcast-style **fixed cameras with pan/tilt clamps**;
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`CameraInstance::CalculateCameraRotation` pans them to track the goal within
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the clamps. They were authored *in-game*: the operator flies to a spot,
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presses CreateCameraInstance, and OutputCameraInstances writes the `.cam`
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file back out (`CameraInstanceManager::WriteNotationFile`).
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## 3. Mission Review = record the network, replay the network
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### Recording (`SPOOLER.HPP/CPP`, `L4SPLR.HPP`)
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- `SpoolFile` is a `MemoryStream` of **raw `NetworkPacket`s** (header +
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payload, back to back). States: Empty → Spooling → Stored → Playing.
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`SpoolPacket()` appends (hard-exits if the RAM buffer fills);
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`SaveAs`/`Read` move it to/from disk. The canonical file name is
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**`last.spl`** (`SPOOLER.CPP:251,274`) — same "last mission" convention as
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`LAST.EGG`.
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- `MissionReviewApplicationManager` owns a pool of `spool_count` RAM buffers
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of `spool_size` each.
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- `L4SpoolingApplication` (+ `L4SpoolingNetworkManager`,
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`SpoolingInterestManager`) is the **recorder**: its
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`ReceiveNetworkPacket()` override tees every packet arriving over the
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mission LAN into the active spool *while also processing it normally* — so
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the recording host fully participates (renders, directs cameras) as it
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records. A `missionSpooled` flag tracks state; the spool is stored (→
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`last.spl`) when the mission stops.
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Because the recorder simply captures **received replication traffic**, the
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recording is exactly what any spectator host saw: entity creations, state
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updates, weapon events, kills — everything needed to re-simulate the battle,
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at a tiny fraction of the size of video.
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### Playback (`BTL4PB.HPP`, `L4SPLR.HPP`)
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- `BTL4PlaybackApplication` (BT flavor of `RPPlaybackApplication`) is a full
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game application whose network manager is `L4PlaybackNetworkManager` — a
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`NetworkManager` with **no real network**: `CheckBuffers()` sources
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packets from the `SpoolFile` instead of the wire.
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- `SpoolerTask` (an `ApplicationTask`) walks the spool with `NextPacket()`
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and `DispatchPacket()`s each one into the app, using **`timeBias`** to
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shift the recorded timestamps onto the playback clock — packets are
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released on the same relative schedule they were recorded, so the replayed
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entities move exactly as they did live.
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- The playback host's player is again a `CameraDirector` (host type switch,
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§1) — so a review session *is* the Live Cam presentation (auto-cuts to the
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leader, ranking overlays, fixed trackside cameras) running over recorded
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traffic. This is what the debrief room / take-home tapes showed.
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### What's NOT in the repo
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The readable tree is partial: `L4SPLR.CPP` (SpoolerTask::Execute pacing,
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exact spool start/stop triggers) and `BTL4PB.CPP` are missing — only their
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headers survive. The compiled implementations are in the era binaries. The
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trigger for "start spooling" (console message vs automatic at mission start)
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is therefore unconfirmed; the message-handler names
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(`Run/Stop/AbortMissionMessageHandler` on the spooling app) suggest it simply
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records from RunMission to StopMission.
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## 4. The physical setup at a center (period context, inferred)
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A "camera ship" machine = one more networked PC with a Division board, its
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out-the-window video feeding the spectator monitors (and the VHS deck for
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take-home tapes). The mission-review station = the same machine (or another)
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replaying `last.spl` into the debrief room after the mission. Both could be
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driven hands-off (CameraDirector) or by an operator with a joystick/RIO.
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## 5. What this means for OUR pod project
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1. **No new binary needed.** BTL4OPT.EXE already contains all of it. A Live
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Cam station = a second emulated machine on the pod LAN whose egg page
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says `hostType=1`. Mission Review = `hostType=2` + a `last.spl`.
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2. **The console app owns the roles.** When the TeslaSuite console port
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authors eggs, adding a camera-host page is how you light this up — it's
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an egg field, not a build variant.
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3. **We can record spools ourselves.** The spool format is trivial (length-
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prefixed file of raw NetworkPackets, `SPOOLER.CPP:50-95`); our emulated
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NIC path (slirp/pcap) could tee mission traffic into a `last.spl`
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independently of any spooling host — giving Mission Review of any pod
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session after the fact.
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4. **Camera authoring works from a cockpit.** `CameraRIOMapper` means the
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vRIO can fly the camera ship and author `.cam` files for our arenas.
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5. **Renderer note:** a camera/review host renders through the same Division
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wire our bridge already decodes — the bridge should work unchanged for a
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spectator host, modulo the `CameraShipHUDRenderable` overlays (2D HUD
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layer, same 0x29/0x2b dpl2d path as the pod HUD).
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## Quick reference — the cast
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| Piece | File | Role |
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|---|---|---|
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| `HostType` enum | `MUNGA/HOST.HPP` | pod / camera / review / console, set per-IP in the egg (`hostType=`) |
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| `Registry::MakePlayer` | `MUNGA/REGISTRY.CPP` | host type → `Player` or `CameraDirector` |
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| `CameraDirector` | `MUNGA/DIRECTOR.*` | auto-director: cut to rank-0 player every 10 s; ranking-window HUD |
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| `CameraShip` | `MUNGA/CAMSHIP.*` | the flying camera vehicle (a Mover entity) |
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| `CameraControlsMapper` | `MUNGA/CAMMPPR.*` | stick/throttle/pedals camera flight, director toggle, camera authoring buttons |
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| `CameraL4/Thrustmaster/RIOMapper` | `MUNGA_L4/L4MPPR.*` | camera station input bindings (RIO cockpit supported) |
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| `CameraInstance(Manager)` | `MUNGA/CAMINST.*`, `CAMMGR.CPP` | fixed clamped cameras; reads/writes `MAPS/<map>.cam` |
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| `SpoolFile` | `MUNGA/SPOOLER.*` | NetworkPacket recording; `last.spl` on disk |
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| `L4SpoolingApplication` | `MUNGA_L4/L4SPLR.HPP` | records the mission LAN while participating |
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| `BTL4PlaybackApplication` + `SpoolerTask` | `BT_L4/BTL4PB.HPP` | replays the spool with `timeBias` re-timing; no real network |
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