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CydandClaude Fable 5 0ca6b5b01f RGB keyboard lamp mirror: vRIO Dynamic Lighting port, live in-game
The polish-backlog item, implemented from vRIO KeyboardLampMirror:
game-commanded RIO lamp states paint per-key RGB keyboards through
Windows Dynamic Lighting (WinRT LampArray). Keys bound to lamp
addresses in the active bindings profile glow with the panel palette
(red banks, yellow Secondary/Screen columns), flash modes use the
exact L4MFDVIEW formula so keyboard and on-screen buttons blink in
step, unbound keys are blacked out so the board reads as the button
field, and zone-lit keyboards fall back to a board-wide mirror of the
strongest lamp. Advantage over vRIO: Dynamic Lighting grants LEDs to
the FOREGROUND app - which is the game - so no Windows settings
dance.

Isolation: L4KEYLIGHT.cpp compiles /std:c++17 + DEFAULT packing +
conformance (per-file vcxproj settings; the engine /Zp1 would break
the WinRT ABI) with a scalars-only interface, and all WinRT work runs
on a private worker thread (watcher, claiming, 100ms paint loop).
On by default with a bindings map present; RP412KEYLIGHT=0 opts out;
missing Dynamic Lighting logs once and stays dormant.

Verified live on the dev laptop: claimed its 24-zone keyboard
(board-wide mirror) during a race; race cycling with per-race
start/stop of the mirror thread stays green.

Co-Authored-By: Claude Fable 5 <noreply@anthropic.com>
2026-07-13 10:49:35 -05:00

398 lines
9.2 KiB
C++

//===========================================================================//
// L4KEYLIGHT.cpp - Windows Dynamic Lighting keyboard mirror.
//
// COMPILED APART FROM THE ENGINE: /std:c++17, DEFAULT struct packing,
// conformance mode (see the per-file settings in Munga_L4.vcxproj).
// No engine headers may be included here - the engine compiles /Zp1
// and its types would take a different layout in this translation
// unit. The l4keylight.h interface is scalars only for that reason.
//
// Everything WinRT runs on a private worker thread: device watcher,
// keyboard claiming, and a 100 ms paint loop that mirrors the lamp
// bytes (same flash formula as the on-screen cockpit buttons in
// L4MFDVIEW, so the board and the screen blink in step).
//===========================================================================//
#include <windows.h>
#include <atomic>
#include <mutex>
#include <thread>
#include <vector>
#include <cstring>
#include <cstdio>
#include <winrt/base.h>
#include <winrt/Windows.Foundation.h>
#include <winrt/Windows.Foundation.Collections.h>
#include <winrt/Windows.Devices.Enumeration.h>
#include <winrt/Windows.Devices.Lights.h>
#include <winrt/Windows.System.h>
#include <winrt/Windows.UI.h>
#pragma comment(lib, "windowsapp.lib")
#include "l4keylight.h"
namespace
{
using namespace winrt;
using namespace winrt::Windows::Devices::Enumeration;
using namespace winrt::Windows::Devices::Lights;
using winrt::Windows::UI::Color;
using winrt::Windows::System::VirtualKey;
struct KeyEntry
{
int virtualKey;
int address;
bool yellow;
};
struct ClaimedArray
{
hstring id;
LampArray array{ nullptr };
bool perKey = false;
bool baseCoated = false;
};
std::mutex gLock;
std::vector<KeyEntry> gMap;
unsigned char gLamps[64] = {};
void (*gLogger)(const char *) = nullptr;
std::atomic<bool> gRunning{ false };
std::thread gWorker;
void Log(const char *line)
{
void (*logger)(const char *);
{
std::lock_guard<std::mutex> hold(gLock);
logger = gLogger;
}
if (logger != nullptr)
{
logger(line);
}
}
void Logf(const char *format, ...)
{
char line[256];
va_list args;
va_start(args, format);
_vsnprintf_s(line, sizeof(line), _TRUNCATE, format, args);
va_end(args);
Log(line);
}
//---------------------------------------------------------------
// Lamp byte -> brightness level 0-3, animating the flash modes.
// Identical to LampLevel in L4MFDVIEW.cpp so the keyboard and the
// on-screen buttons blink together.
//---------------------------------------------------------------
int LampLevel(int lamp_state)
{
int mode = lamp_state & 0x03;
int level1 = (lamp_state >> 2) & 0x03;
int level2 = (lamp_state >> 4) & 0x03;
if (mode == 0)
{
return level1;
}
static const int half_period[4] = { 0, 500, 250, 125 };
return ((GetTickCount() / half_period[mode]) & 1) ? level2 : level1;
}
//---------------------------------------------------------------
// The panel palette (vRIO's KeyboardLampMirror shades): red for
// the banks, yellow for Secondary/Screen; the off shade keeps the
// bound keys faintly visible so the board reads as a button field.
//---------------------------------------------------------------
Color Shade(int level, bool yellow)
{
Color color;
color.A = 255;
if (yellow)
{
if (level >= 3) { color.R = 245; color.G = 210; color.B = 60; }
else if (level >= 1) { color.R = 140; color.G = 118; color.B = 38; }
else { color.R = 70; color.G = 60; color.B = 24; }
}
else
{
if (level >= 3) { color.R = 230; color.G = 70; color.B = 70; }
else if (level >= 1) { color.R = 120; color.G = 50; color.B = 50; }
else { color.R = 64; color.G = 40; color.B = 40; }
}
return color;
}
bool SameColor(const Color &a, const Color &b)
{
return a.A == b.A && a.R == b.R && a.G == b.G && a.B == b.B;
}
//---------------------------------------------------------------
// The worker: watcher + claim + paint loop
//---------------------------------------------------------------
void Worker()
{
try
{
init_apartment();
}
catch (...)
{
// apartment already set on this thread; carry on
}
std::mutex claimedLock;
std::vector<ClaimedArray> claimed;
bool anySeen = false;
DeviceWatcher watcher{ nullptr };
try
{
watcher = DeviceInformation::CreateWatcher(LampArray::GetDeviceSelector());
watcher.Added([&](DeviceWatcher const &, DeviceInformation const &info)
{
try
{
LampArray array = LampArray::FromIdAsync(info.Id()).get();
if (array == nullptr ||
array.LampArrayKind() != LampArrayKind::Keyboard)
{
return; // mice / strips / cases stay untouched
}
anySeen = true;
ClaimedArray entry;
entry.id = info.Id();
entry.array = array;
entry.perKey = array.SupportsVirtualKeys();
{
std::lock_guard<std::mutex> hold(claimedLock);
claimed.push_back(entry);
}
Logf(entry.perKey
? "KeyLight: + %ls (%d LEDs, per-key)"
: "KeyLight: + %ls (%d zones - board-wide mirror)",
info.Name().c_str(), (int) array.LampCount());
}
catch (...)
{
Log("KeyLight: could not open a lamp array");
}
});
watcher.Removed([&](DeviceWatcher const &, DeviceInformationUpdate const &update)
{
std::lock_guard<std::mutex> hold(claimedLock);
for (size_t i = 0; i < claimed.size(); ++i)
{
if (claimed[i].id == update.Id())
{
claimed.erase(claimed.begin() + i);
Log("KeyLight: keyboard disconnected");
break;
}
}
});
watcher.Updated([](DeviceWatcher const &, DeviceInformationUpdate const &)
{
// required for the watcher to progress
});
watcher.Start();
}
catch (...)
{
Log("KeyLight: Dynamic Lighting unavailable on this system");
return;
}
//
// Paint loop: 100 ms cadence, repaint only on change
//
std::vector<Color> lastColors;
int waited = 0;
while (gRunning.load())
{
Sleep(50);
waited += 50;
if (waited < 100)
{
continue;
}
waited = 0;
std::vector<KeyEntry> map;
unsigned char lamps[64];
{
std::lock_guard<std::mutex> hold(gLock);
map = gMap;
memcpy(lamps, gLamps, sizeof(lamps));
}
std::vector<Color> colors(map.size());
std::vector<VirtualKey> keys(map.size());
int bestLevel = 0;
bool bestYellow = false;
bool changed = (lastColors.size() != map.size());
for (size_t i = 0; i < map.size(); ++i)
{
int address = map[i].address;
int level = (address >= 0 && address < 64)
? LampLevel(lamps[address]) : 0;
if (level > bestLevel)
{
bestLevel = level;
bestYellow = map[i].yellow;
}
colors[i] = Shade(level, map[i].yellow);
keys[i] = (VirtualKey) map[i].virtualKey;
if (!changed && !SameColor(colors[i], lastColors[i]))
{
changed = true;
}
}
std::lock_guard<std::mutex> hold(claimedLock);
bool freshClaim = false;
for (ClaimedArray &entry : claimed)
{
if (!entry.baseCoated)
{
freshClaim = true;
}
}
if (!changed && !freshClaim)
{
continue;
}
Color aggregate = Shade(bestLevel, bestYellow);
for (ClaimedArray &entry : claimed)
{
try
{
if (entry.perKey)
{
if (!entry.baseCoated)
{
Color black;
black.A = 255; black.R = 0; black.G = 0; black.B = 0;
entry.array.SetColor(black);
entry.baseCoated = true;
}
if (!map.empty())
{
entry.array.SetColorsForKeys(
array_view<Color const>(colors.data(), colors.data() + colors.size()),
array_view<VirtualKey const>(keys.data(), keys.data() + keys.size()));
}
}
else
{
entry.baseCoated = true;
entry.array.SetColor(aggregate);
}
}
catch (...)
{
// device wobble; the watcher handles removal
}
}
lastColors = colors;
}
//
// Releasing the arrays hands the LEDs back to Windows
//
try
{
watcher.Stop();
}
catch (...)
{
}
{
std::lock_guard<std::mutex> hold(claimedLock);
claimed.clear();
}
if (!anySeen)
{
Log("KeyLight: no Dynamic Lighting keyboard was found this session");
}
}
}
//########################################################################
// The scalar interface (safe across the packing boundary)
//########################################################################
void
KeyLight_SetLogger(void (*logger)(const char *line))
{
std::lock_guard<std::mutex> hold(gLock);
gLogger = logger;
}
void
KeyLight_SetMap(
const int *virtual_keys,
const int *addresses,
const unsigned char *yellow,
int count
)
{
std::lock_guard<std::mutex> hold(gLock);
gMap.clear();
gMap.reserve(count);
for (int i = 0; i < count; ++i)
{
KeyEntry entry;
entry.virtualKey = virtual_keys[i];
entry.address = addresses[i];
entry.yellow = (yellow[i] != 0);
gMap.push_back(entry);
}
}
void
KeyLight_UpdateLamps(const unsigned char *lamp_state, int count)
{
if (count > 64)
{
count = 64;
}
std::lock_guard<std::mutex> hold(gLock);
memcpy(gLamps, lamp_state, count);
}
void
KeyLight_Start()
{
if (gRunning.exchange(true))
{
return;
}
gWorker = std::thread(Worker);
}
void
KeyLight_Stop()
{
if (!gRunning.exchange(false))
{
return;
}
if (gWorker.joinable())
{
gWorker.join();
}
}