arcattackandClaude Fable 5 4e63a7b6c3 Heat: THE AUTHENTIC ELECTRICAL MODEL -- weapons recharge from generators (task #10)
Task #10 set out to fix "scrambled linked-sink routing"; a [heat-link] attach
log proved the routing was NEVER scrambled (every subsystem links its authored
condenser exactly; the "pools in Condenser1" read was the diagnostic-sampler
aliasing trap).  The real defect: emitter.cpp's local FUN_00417ab4 stub
returned NULL, so the whole electrical model was inert and the E7 force-charge
recharged every emitter in ONE frame (~0.3s cycle, 1501 fires/90s, ~1.7e9
heat/s -- the "runaway").

Landed authentically [T1: disasm + byte-verified constants]:
- Emitter ctor @004bb120: seekVoltage = authored fraction x generator
  ratedVoltage (10000); EC = energyTotal/(seekV^2 x 0.5); voltageScale@0x310 =
  (RechargeRate / -ln(1 - 1e-4 x seekV)) / EC -- charge reaches seekV[rec] in
  EXACTLY the authored RechargeRate (PPC 5s, ERL 4s, SRM 3s, ERM 2s) cold.
  Owner-flags ctor gate (the usual gotcha; the this-flags read never armed).
- PoweredSubsystem::ChargeTimeScale (@004b0d50, was a =1.0 stub): voltageScale
  x (1 + thermalResistivity x srcTempRise) -- hot generators charge slower.
  ("voltageScale is never read back" was wrong; corrected + swept.)
- TrackSeekVoltage @004ba838: charging I^2R -> the GENERATOR's pendingHeat
  (~3.5e8/full PPC charge) -- generators self-heat, conduct to their authored
  condensers, and throttle further charging.  The feedback economy closes.
- FailureHeat consumers found: this+0x184 == 2 gates BOTH weapon families
  (@004baa88 emitter: reset firing + hold charge 0; @004bbd36 ballistic:
  recoil=rechargeRate + alarm 7).  Emitter::GetFaultState un-stubbed.
- ProjectileWeaponSimulation @004bbd04 opens with call 0x4b0bd0 (disasm) --
  launchers now run the powered/heat step (their firing heat previously
  accumulated in pendingHeat forever).
- heat.cpp: per-instance BT_HEAT_LOG census (the old shared-static 1-Hz
  sampler aliased); [heat-link] attach log; the stolen-else Verify restored.

Verified live (120s max-rate autofire): PPC ~470-500 (was 55,000), bank
plateaus ~600 and sheds to ambient, generators 1100-1400, ERMLaser
self-regulates at the authored 2000 failure threshold (shutdown-cool-resume).

Co-Authored-By: Claude Fable 5 <noreply@anthropic.com>
2026-07-11 16:59:29 -05:00

BattleTech 4.11 (bt411)

A standalone Windows port of Virtual World Entertainment's arcade BattleTech (Tesla platform, release 4.10, ~199596), reconstructed on the shared RP411 Windows engine. The game boots, renders, and runs a single-player drive → animate → target → fire → damage → destroy loop across all 8 maps, with two-instance multiplayer entity replication working.

This repo is a clean, self-contained extraction of the BattleTech-specific work from the larger reverse-engineering workspace — engine + game + content + build, with nothing from Red Planet or the raw archive dumps. It builds and runs out of the box.

License: the game content (content/) and the original binary are proprietary to Virtual World / the pod owner. This repository is private; do not redistribute.


Layout

CMakeLists.txt      one build: munga_engine lib + bt410_l4 game lib + btl4.exe
engine/
  MUNGA/            shared 2007 sim/render engine (149 .cpp + headers)
  MUNGA_L4/         Win32/D3D9 HAL + renderer + asset loaders (44 .cpp), incl.
                    our BT work: bgfload / L4D3D / L4VIDEO + the image codec
  shim/             minimal ATL shim (USES_CONVERSION/W2A)
  lib/              OpenAL32 / libsndfile import libs + runtime DLLs
game/
  reconstructed/    the reconstructed BT game logic (mech, subsystems, HUD, app; ~47 .cpp)
  original/BT,BT_L4 surviving original BT source + all BT headers
  fwd/              header shims forwarding <NAME.hpp> -> the engine's NAME.h
  btl4main.cpp      WinMain launcher / entry point
content/            runtime data: BTL4.RES, VIDEO/, GAUGE/, AUDIO/, *.EGG, BTDPL.INI
context/            progressive knowledge graph — 18 on-demand topic files (routed by CLAUDE.md)
docs/               format specs + reconstruction ledgers + PROGRESS_LOG.md (full history)
reference/
  decomp/           raw Ghidra pseudocode — source-of-truth for ongoing recon
  ghidra_scripts/   the headless decomp exporter
  glossary.yaml     term / acronym definitions
phases/             restructuring / investigation logs
tools/              btconsole.py (MP console emulator), map/resource scanners
run/                run.cmd helper
CLAUDE.md           knowledge-base ROUTER — identity, protocols, quick-lookup, conventions

Prerequisites

  • Visual Studio 2019 BuildTools (MSVC v142, x86). The Community install on the original dev box was broken, hence the explicit BuildTools instance in the configure line below; adjust to your install.
  • CMake ≥ 3.20.
  • Legacy DirectX SDK (June 2010) — the engine uses d3dx9/dinput/dxerr, removed from the modern Windows SDK. Default path C:/Program Files (x86)/Microsoft DirectX SDK (June 2010); override with -DDXSDK=<path>. (The installer may throw a harmless S1023 error — dismiss it; the SDK headers/libs install before the failing redist step.)

OpenAL/libsndfile import libs + DLLs are vendored under engine/lib/; the DLLs are copied next to the exe automatically at build time.

Build (32-bit / Win32)

cmake -S . -B build -G "Visual Studio 16 2019" -A Win32 ^
      -DCMAKE_GENERATOR_INSTANCE="C:/Program Files (x86)/Microsoft Visual Studio/2019/BuildTools"
cmake --build build --config Debug

Must be Win32 — the DirectX SDK link libs are Lib/x86. The link uses /FORCE: the 1995 headers define free functions/globals without inline/extern, so identical symbols appear in many translation units (~124 LNK2005); /FORCE:MULTIPLE keeps the first. UNRESOLVED tolerates a dead offline-tool factory in mech3.cpp that is never called at runtime. (Cleanup task: move those definitions to single TUs + neutralize the dead factory, then drop /FORCE.)

Run

run\run.cmd            REM boots DEV.EGG (grass / day)
run\run.cmd DBASE.EGG  REM any egg in content/

The working directory must be content/ (the engine resolves BTL4.RES, VIDEO\, BTDPL.INI, and eggs relative to cwd); run.cmd handles that. Maps available in BTL4.RES: cavern grass rav polar3 polar4 arena1 arena2 dbase — switch via a copied egg's map= field.

Useful env-var flags (default OFF unless noted)

The authentic stack (gait, collision, real controls) is default-on; set =0 to fall back. Debug/harness flags: BT_FORCE_THROTTLE=1 (auto-walk), BT_SPAWN_ENEMY=1 (spawn a target dummy), BT_FORCE_FIRE=1 (auto-fire), BT_HEAPCHECK=1 (whole-heap validation — slow), BT_BSL=0 (legacy texture decode), BT_DEV_GAUGES=1 (render the cockpit MFDs in a dev window), BT_LOG=<file>. Interactive: WASD drive, Space/Ctrl fire, X all-stop. The complete env-gate table is in context/decomp-reference.md §6 (routed from CLAUDE.md).

Multiplayer (two instances, one box)

instance A:  btl4.exe -egg MP.EGG -net 1501   (BT_LOG=mp_a.log)
instance B:  btl4.exe -net 1601               (BT_LOG=mp_b.log)
console:     python tools/btconsole.py MP.EGG 127.0.0.1:1501 127.0.0.1:1601

-net <port> enables networked mode; the console emulator delivers the mission egg and the launch command. Entity + movement replication works; cross-pod combat is in progress.

Status & continuing the work

The engine, renderer, audio, HAL, build, locomotion, collision, damage, render fidelity, the full cockpit gauge / MFD system (every config binding resolves + every widget builds), and the projectile / missile weapon families are done. Active fronts: per-subsystem polish (the gyroscope integrator; the 0xBD3 message manager that gates the valve / status-message control routes) and cross-pod MP combat. reference/decomp/ holds the raw pseudocode every reconstruction is verified against.

Start with CLAUDE.md — it is the router into the progressive knowledge base: a quick-lookup table pointing to the context/*.md topic files (loaded on demand), the evidence-tier and convention rules, and context/open-questions.md for what's deferred / next. The complete pre-restructure history is preserved verbatim in docs/PROGRESS_LOG.md; docs/*.md holds the detailed running ledgers.

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