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feat(windows): pf-vdisplay-proto — owned host<->driver ABI crate (rewrite M0)

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First foundation of the Windows-host rewrite (docs/windows-host-rewrite.md): a
self-contained, no_std + bytemuck crate that defines the host<->driver binary
contract ONCE — the control-plane IOCTLs (add/remove/set-render-adapter/ping/
get-info/clear-all) and the IDD-push frame transport (SharedHeader, the
(gen<<40|seq<<8|slot) FrameToken, the Global\pfvd-* name scheme, driver-status
codes). Previously these were hand-duplicated byte-for-byte across
idd_push.rs/frame_transport.rs and sudovda.rs/control.rs with only "must match"
comments; here const size-asserts + bytemuck round-trips make any drift a COMPILE
error.

Clean break from SudoVDA: a freshly-minted interface GUID (not e5bcc234), a
contiguous 0x900 op space (not the gappy 0x800/0x888/0x8FF), a u64 session id (not
the 16-byte GUID + pid-mangling), a single u32 protocol version. Self-contained
(no workspace inheritance, no Windows deps) so the out-of-workspace driver build
graph can path-dep it identically. 7 tests green on Linux; clippy + fmt clean.

Also lands the full rewrite plan in docs/windows-host-rewrite.md (decisions:
greenfield; IDD-push primary incl. secure desktop, WGC+DDA demoted to fallbacks;
unify drivers on windows-drivers-rs + solve /INTEGRITYCHECK; keep GameStream,
default secure).

Co-Authored-By: Claude Opus 4.8 (1M context) <noreply@anthropic.com>
This commit is contained in:
Enrico Bühler
2026-06-24 06:49:50 +00:00
parent e2c9bfd3d9
commit 0b663cefb6
5 changed files with 969 additions and 0 deletions
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Cargo.lock
Generated
+21
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@@ -453,6 +453,20 @@ name = "bytemuck"
version = "1.25.0"
source = "registry+https://github.com/rust-lang/crates.io-index"
checksum = "c8efb64bd706a16a1bdde310ae86b351e4d21550d98d056f22f8a7f7a2183fec"
dependencies = [
"bytemuck_derive",
]
[[package]]
name = "bytemuck_derive"
version = "1.10.2"
source = "registry+https://github.com/rust-lang/crates.io-index"
checksum = "f9abbd1bc6865053c427f7198e6af43bfdedc55ab791faed4fbd361d789575ff"
dependencies = [
"proc-macro2",
"quote",
"syn",
]
[[package]]
name = "bytes"
@@ -2404,6 +2418,13 @@ version = "2.3.2"
source = "registry+https://github.com/rust-lang/crates.io-index"
checksum = "9b4f627cb1b25917193a259e49bdad08f671f8d9708acfd5fe0a8c1455d87220"
[[package]]
name = "pf-vdisplay-proto"
version = "0.0.1"
dependencies = [
"bytemuck",
]
[[package]]
name = "pin-project-lite"
version = "0.2.17"
Cargo.toml
+1
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@@ -3,6 +3,7 @@ resolver = "2"
members = [
"crates/punktfunk-core",
"crates/punktfunk-host",
"crates/pf-vdisplay-proto",
"clients/probe",
"clients/linux",
"clients/windows",
crates/pf-vdisplay-proto/Cargo.toml
+19
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@@ -0,0 +1,19 @@
# Shared host<->driver binary contract for the punktfunk pf-vdisplay virtual display.
#
# Deliberately self-contained (no `*.workspace = true` inheritance, no Windows deps): this crate is a
# path dependency of BOTH the host workspace (crates/punktfunk-host) AND the out-of-workspace driver
# workspace (packaging/windows/drivers/), so it must resolve identically from either build graph. It is
# `no_std` (+ alloc) and platform-neutral; the GUID/LUID are plain integers each side converts to its
# own OS type. Defining every wire struct ONCE here — with `const` size/offset asserts + bytemuck
# round-trips — makes host<->driver ABI drift a COMPILE error instead of a silent frame/IOCTL corruption.
[package]
name = "pf-vdisplay-proto"
version = "0.0.1"
edition = "2021"
rust-version = "1.82"
license = "MIT OR Apache-2.0"
description = "Shared host<->driver binary contract for the punktfunk pf-vdisplay virtual display (control IOCTLs + IDD-push frame transport)."
publish = false
[dependencies]
bytemuck = { version = "1.19", features = ["derive"] }
crates/pf-vdisplay-proto/src/lib.rs
+311
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@@ -0,0 +1,311 @@
//! Shared binary contract between the punktfunk host and the `pf-vdisplay` IddCx driver.
//!
//! Two planes:
//! * [`control`] — the low-frequency `DeviceIoControl` plane (add/remove a virtual monitor, pin the
//! render adapter, keepalive, info, clear-all). Owned, clean, versioned — NOT the SudoVDA ABI.
//! * [`frame`] — the IDD-push frame transport: the host creates a ring of shared keyed-mutex textures
//! (+ a header + a frame-ready event) and the driver opens them and publishes composited frames into
//! them. This crate owns the [`frame::SharedHeader`] layout, the [`frame::FrameToken`] packing, the
//! `Global\` object-name scheme, and the driver-status codes.
//!
//! Both planes were previously hand-duplicated, byte-for-byte, across `idd_push.rs`/`frame_transport.rs`
//! and `vdisplay/sudovda.rs`/`control.rs` with only "must match" comments guarding them. Defining them
//! once here — with bytemuck `Pod` derives and `const` size asserts — makes any drift a compile error.
//!
//! The GUID and LUID are carried as plain integers; the host converts to `windows::core::GUID` /
//! `windows::Win32::Foundation::LUID` and the driver to its own bindgen types via the same constants.
#![cfg_attr(not(test), no_std)]
extern crate alloc;
/// Freshly-minted pf-vdisplay device-interface GUID — `{70667664-7044-5350-a1b2-c3d4e5f60001}`.
/// Deliberately NOT SudoVDA's `{e5bcc234-…}`: we own the driver, so a private interface GUID signals
/// it and removes any accidental coexistence with a real SudoVDA install. Construct on each side via
/// `GUID::from_u128(PF_VDISPLAY_INTERFACE_GUID_U128)`.
pub const PF_VDISPLAY_INTERFACE_GUID_U128: u128 = 0x7066_7664_7044_5350_a1b2_c3d4_e5f6_0001;
/// Bumped on any incompatible change to either plane. Exchanged via [`control::IOCTL_GET_INFO`]; host
/// and driver assert a match at startup so a mismatched pair fails loudly instead of corrupting.
pub const PROTOCOL_VERSION: u32 = 1;
/// `CTL_CODE(FILE_DEVICE_UNKNOWN = 0x22, func, METHOD_BUFFERED = 0, FILE_ANY_ACCESS = 0)`.
pub const fn ctl_code(func: u32) -> u32 {
(0x22u32 << 16) | (func << 2)
}
/// The control (`DeviceIoControl`) plane: add/remove a virtual monitor + adapter pin + keepalive.
pub mod control {
use super::ctl_code;
use bytemuck::{Pod, Zeroable};
// Contiguous op space at 0x900 — distinct from SudoVDA's gappy 0x800/0x888/0x8FF numbering.
/// Add a virtual monitor at a mode → [`AddReply`]. Input [`AddRequest`].
pub const IOCTL_ADD: u32 = ctl_code(0x900);
/// Remove a virtual monitor by session id. Input [`RemoveRequest`].
pub const IOCTL_REMOVE: u32 = ctl_code(0x901);
/// Pin the IddCx render adapter (hybrid-GPU IDD-push). Input [`SetRenderAdapterRequest`].
pub const IOCTL_SET_RENDER_ADAPTER: u32 = ctl_code(0x902);
/// Keepalive (resets the driver watchdog). No payload.
pub const IOCTL_PING: u32 = ctl_code(0x903);
/// Version + watchdog handshake → [`InfoReply`]. No input.
pub const IOCTL_GET_INFO: u32 = ctl_code(0x904);
/// Tear down every virtual monitor (host-startup orphan reap). No payload. First-class op — NOT the
/// SudoVDA "send-and-hope-it's-ignored" hack.
pub const IOCTL_CLEAR_ALL: u32 = ctl_code(0x905);
/// `IOCTL_ADD` input. A monotonic `session_id` keys the monitor (the host's refcount manager owns
/// collision safety — no more SudoVDA's 16-byte GUID + pid-mangling). The driver advertises this
/// mode as preferred; the host still CCD-forces the active mode (the OS activates IDDs at a default).
#[repr(C)]
#[derive(Clone, Copy, Pod, Zeroable, Debug, PartialEq, Eq)]
pub struct AddRequest {
pub session_id: u64,
pub width: u32,
pub height: u32,
pub refresh_hz: u32,
pub _reserved: u32,
}
/// `IOCTL_ADD` reply: the OS target id + the adapter LUID the IDD landed on (split low/high to
/// match `windows` `LUID { LowPart: u32, HighPart: i32 }`).
#[repr(C)]
#[derive(Clone, Copy, Pod, Zeroable, Debug, PartialEq, Eq)]
pub struct AddReply {
pub adapter_luid_low: u32,
pub adapter_luid_high: i32,
pub target_id: u32,
pub _reserved: u32,
}
/// `IOCTL_REMOVE` input.
#[repr(C)]
#[derive(Clone, Copy, Pod, Zeroable, Debug, PartialEq, Eq)]
pub struct RemoveRequest {
pub session_id: u64,
}
/// `IOCTL_SET_RENDER_ADAPTER` input (the GPU the IddCx swap-chain should render on).
#[repr(C)]
#[derive(Clone, Copy, Pod, Zeroable, Debug, PartialEq, Eq)]
pub struct SetRenderAdapterRequest {
pub luid_low: u32,
pub luid_high: i32,
}
/// `IOCTL_GET_INFO` reply: the protocol version (asserted against [`super::PROTOCOL_VERSION`]) and
/// the watchdog timeout the host must ping within.
#[repr(C)]
#[derive(Clone, Copy, Pod, Zeroable, Debug, PartialEq, Eq)]
pub struct InfoReply {
pub protocol_version: u32,
pub watchdog_timeout_s: u32,
}
// Layout is load-bearing across the process boundary — pin it. (bytemuck's Pod derive already
// rejects any internal padding; these assert the externally-visible sizes too.)
const _: () = {
assert!(core::mem::size_of::<AddRequest>() == 24);
assert!(core::mem::size_of::<AddReply>() == 16);
assert!(core::mem::size_of::<RemoveRequest>() == 8);
assert!(core::mem::size_of::<SetRenderAdapterRequest>() == 8);
assert!(core::mem::size_of::<InfoReply>() == 8);
};
}
/// The IDD-push frame transport: the host-created shared ring header, the publish token, the names, and
/// the driver-status codes. The texture ring itself is host-created D3D11 keyed-mutex textures (opened
/// by name on the driver side); only the *layout/contract* lives here.
pub mod frame {
use alloc::string::String;
use bytemuck::{Pod, Zeroable};
/// Header magic (`"PFVD"` LE). The host stamps it LAST (after the ring textures exist) so the driver
/// only attaches to a fully-published ring.
pub const MAGIC: u32 = 0x4456_4650;
/// Frame-plane version (independent bump of the header layout).
pub const VERSION: u32 = 1;
/// Ring slots. Headroom so the driver's 0 ms-timeout publish always finds a free slot while the host
/// holds one across the convert/copy + the pipelined encode. MUST be identical on both sides — it is,
/// because both read this one constant.
pub const RING_LEN: u32 = 6;
/// `driver_status` values the driver writes into the host header (the host logs them on a timeout).
pub const DRV_STATUS_NONE: u32 = 0;
/// Driver attached to the ring and is publishing.
pub const DRV_STATUS_OPENED: u32 = 1;
/// Driver could not open the host's textures — render-adapter mismatch (it renders on a different GPU
/// than where the host created the ring). `driver_status_detail` carries the HRESULT.
pub const DRV_STATUS_TEX_FAIL: u32 = 2;
/// Driver has no `ID3D11Device1` to open shared resources.
pub const DRV_STATUS_NO_DEVICE1: u32 = 3;
/// The shared metadata header (host-created, mapped by both sides). Atomic fields (`magic`, `latest`,
/// `generation`) are accessed via each side's own atomic view over the mapping; this is the layout.
#[repr(C)]
#[derive(Clone, Copy, Pod, Zeroable, Debug)]
pub struct SharedHeader {
pub magic: u32,
pub version: u32,
/// Bumped by the host on a ring recreate (HDR-mode flip → new texture format/names). The driver
/// re-attaches when it changes; a publish carries it so the host rejects a stale-ring publish.
pub generation: u32,
pub ring_len: u32,
pub width: u32,
pub height: u32,
pub dxgi_format: u32,
pub _pad: u32,
/// Driver-written after each copy; host loads `Acquire`. See [`FrameToken`].
pub latest: u64,
pub qpc_pts: u64,
/// Driver-written: the adapter the swap-chain actually renders on (mismatch detection).
pub driver_render_luid_low: u32,
pub driver_render_luid_high: i32,
/// Driver-written status (visibility channel — UMDF hides OutputDebugString + the restricted
/// token blocks file writes, so this header is how the driver reports state).
pub driver_status: u32,
pub driver_status_detail: u32,
}
/// The `SharedHeader.latest` publish token: `(generation << 40) | (seq << 8) | slot`.
/// `generation` is 24-bit, `seq` 32-bit, `slot` 8-bit. The generation tag lets the host REJECT a
/// publish from a stale ring (an old-generation publisher racing a mid-session recreate) so it never
/// consumes an unwritten new-ring slot — eliminating the toggle-time garbage frame.
#[derive(Clone, Copy, Debug, PartialEq, Eq)]
pub struct FrameToken {
pub generation: u32,
pub seq: u32,
pub slot: u8,
}
impl FrameToken {
/// Low 24 bits of `generation` are significant (see the field docs).
pub const GENERATION_MASK: u32 = 0x00FF_FFFF;
pub const fn pack(self) -> u64 {
(((self.generation & Self::GENERATION_MASK) as u64) << 40)
| (((self.seq as u64) & 0xFFFF_FFFF) << 8)
| (self.slot as u64)
}
pub const fn unpack(v: u64) -> Self {
Self {
generation: ((v >> 40) as u32) & Self::GENERATION_MASK,
seq: ((v >> 8) & 0xFFFF_FFFF) as u32,
slot: (v & 0xFF) as u8,
}
}
}
/// `Global\pfvd-hdr-<target>` — the shared metadata header mapping name.
pub fn header_name(target_id: u32) -> String {
alloc::format!("Global\\pfvd-hdr-{target_id}")
}
/// `Global\pfvd-evt-<target>` — the frame-ready auto-reset event name.
pub fn event_name(target_id: u32) -> String {
alloc::format!("Global\\pfvd-evt-{target_id}")
}
/// `Global\pfvd-tex-<target>-<generation>-<slot>` — a ring texture's shared-handle name. The
/// generation in the name means a recreate's new textures never collide with the old ring's
/// not-yet-released handles.
pub fn texture_name(target_id: u32, generation: u32, slot: u32) -> String {
alloc::format!("Global\\pfvd-tex-{target_id}-{generation}-{slot}")
}
const _: () = {
assert!(core::mem::size_of::<SharedHeader>() == 64);
};
}
#[cfg(test)]
mod tests {
use super::*;
use bytemuck::Zeroable;
#[test]
fn frame_token_roundtrips() {
for (g, s, slot) in [
(1u32, 0u32, 0u8),
(5, 12_345, 3),
(frame::FrameToken::GENERATION_MASK, 0xFFFF_FFFF, 5),
(0, 1, 255),
] {
let t = frame::FrameToken {
generation: g,
seq: s,
slot,
};
assert_eq!(frame::FrameToken::unpack(t.pack()), t);
}
}
#[test]
fn frame_token_packing_matches_legacy_layout() {
// The legacy code packed (gen<<40)|(seq<<8)|slot by hand; lock the bit positions.
let t = frame::FrameToken {
generation: 7,
seq: 42,
slot: 3,
};
assert_eq!(t.pack(), (7u64 << 40) | (42u64 << 8) | 3u64);
}
#[test]
fn shared_header_is_pod_and_64_bytes() {
let mut h = frame::SharedHeader::zeroed();
h.magic = frame::MAGIC;
h.width = 5120;
h.height = 1440;
let bytes = bytemuck::bytes_of(&h);
assert_eq!(bytes.len(), 64);
let back: frame::SharedHeader = *bytemuck::from_bytes(bytes);
assert_eq!(back.magic, frame::MAGIC);
assert_eq!(back.width, 5120);
assert_eq!(back.height, 1440);
}
#[test]
fn control_structs_roundtrip_through_bytes() {
let req = control::AddRequest {
session_id: 0xDEAD_BEEF_CAFE_F00D,
width: 3840,
height: 2160,
refresh_hz: 120,
_reserved: 0,
};
let bytes = bytemuck::bytes_of(&req);
assert_eq!(bytes.len(), 24);
assert_eq!(*bytemuck::from_bytes::<control::AddRequest>(bytes), req);
}
#[test]
fn names_are_stable() {
assert_eq!(frame::header_name(10), "Global\\pfvd-hdr-10");
assert_eq!(frame::event_name(10), "Global\\pfvd-evt-10");
assert_eq!(frame::texture_name(10, 3, 5), "Global\\pfvd-tex-10-3-5");
}
#[test]
fn ctl_codes_are_contiguous_and_distinct() {
assert_eq!(control::IOCTL_ADD, ctl_code(0x900));
let all = [
control::IOCTL_ADD,
control::IOCTL_REMOVE,
control::IOCTL_SET_RENDER_ADAPTER,
control::IOCTL_PING,
control::IOCTL_GET_INFO,
control::IOCTL_CLEAR_ALL,
];
for (i, a) in all.iter().enumerate() {
for b in &all[i + 1..] {
assert_ne!(a, b);
}
}
}
#[test]
fn guid_is_not_sudovda() {
const SUDOVDA: u128 = 0xE5BC_C234_1E0C_418A_A0D4_EF8B_7501_414D;
assert_ne!(PF_VDISPLAY_INTERFACE_GUID_U128, SUDOVDA);
}
}
docs/windows-host-rewrite.md
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# Windows Host Rewrite — Design & Plan
Status: **proposed** (2026-06-24). This plan takes the current, hard-won Windows host (pf-vdisplay
all-Rust IddCx driver + IDD-push zero-copy capture, live-validated 5120×1440@240 HDR on the RTX box)
as a *knowledge base* and re-derives a clean, stable, well-layered architecture from it. It drops all
SudoVDA back-compat (we own both ends now) and drives `unsafe` to a contained minimum.
It supersedes the stale conclusion in `docs/windows-virtual-display-rust-port.md` ("IDD-push not
viable") — that verdict was written in the *same commit* (`e2c9bfd`) that shipped the working
922-line consumer + 424-line producer. **IDD-push works and is the architecture.** The breakthrough the
prose never recorded: once the CCD topology makes the virtual display the sole composited desktop in the
console session, DWM composites to it and the IddCx swap-chain *is* assigned
(`run_core: FIRST FRAME acquired — DWM IS compositing the virtual display!`). Per the owner, **IDD-push
also captures the secure desktop (Winlogon / UAC / lock)** — so it is the universal primary path, not
just the normal-desktop path.
### Decisions resolved (2026-06-24)
| # | Decision | Chosen |
|---|----------|--------|
| A. Execution | greenfield vs staged | **Greenfield rewrite** — rebuild the Windows host fresh against the clean architecture, salvaging the validated "jewels" (§1) verbatim. (Risk acknowledged: no CI for the Windows paths — mitigated by the §1 preservation checklist + on-glass gates, §10.) |
| B. Capture surface | IDD-only / IDD+secure-DDA / keep fallbacks | **IDD-push primary for everything (incl. the secure desktop); keep WGC + DDA as fallbacks.** |
| C. Driver binding stack | wdf-umdf vs windows-drivers-rs | **Extend `microsoft/windows-drivers-rs`** with an `iddcx` subset; unify all three drivers on it; **solve `/INTEGRITYCHECK` properly** (§6). |
| D. GameStream on Windows | keep / keep-secure-default / drop | **Keep Moonlight compat; flip the installer/service default to secure `serve`** (GameStream an explicit opt-in). |
---
## 0. Goals (from the brief)
1. **Clean, stable, well-layered architecture.** Decompose the god-files, give every subsystem one
owner, and replace the ~40-knob `PUNKTFUNK_*` env soup with a typed config resolved once per session.
2. **Drop every trace of SudoVDA back-compat.** We own the driver (`pf-vdisplay`) and the host. The
byte-identical IOCTL ABI, the reused `{e5bcc234}` GUID, the `sudovda` module name, the "SudoVDA
ignores this" conditionals — all pure liability now.
3. **Minimize `unsafe`.** ~480 `unsafe` occurrences across the Windows surface; the large majority are
FFI-mechanical (windows-rs/NVENC/WDK already return `Result`). Target: host ~144→~35, drivers
~227→~60, with the irreducible floor *contained* in 34 named modules under
`deny(unsafe_op_in_unsafe_fn)`.
### Non-goals / invariants (do not regress)
- **Linux host behavior is out of scope and must not change.** The host crate is shared; Linux is
validated across KWin/gamescope/Mutter/Sway. Touch only the seams.
- **`punktfunk-core` stays the one linked core.** Protocol/FEC/crypto/QUIC live there behind the C
ABI; the host is a leaf binary. No protocol changes here.
- **No async on the per-frame path.** Native threads only (the existing discipline).
---
## 1. What we KEEP (validated, load-bearing — port, don't rewrite)
These are expensive empirical wins. The rewrite relocates/wraps them but must preserve behavior
byte-for-byte:
- **The IDD-push frame transport shape**: host-creates / driver-opens shared keyed-mutex texture ring
with the permissive `D:(A;;GA;;;WD)` SDDL (forced by the restricted WUDFHost token, mirrors the
gamepad drivers); the generation-tagged `latest = gen<<40 | seq<<8 | slot` stale-ring reject (kills
the HDR-flip garbage frame); 0 ms try-acquire / drop-on-full publish (never block the swap-chain
thread); the host output ring `OUT_RING` + `pipeline_depth=2` overlap of convert/copy vs NVENC.
- **The IddCx driver internals that earned their keep**: `edid.rs` in full (128-byte EDID + CTA-861.3
HDR block, serial-as-index round-trip, dual checksums); the HDR enablement recipe (`CAN_PROCESS_FP16`
+ the `*2` mode DDIs + `set_gamma_ramp`/`set_default_hdr_metadata` accept-stubs + `HIGH_COLOR_SPACE` +
8|10 bpc); `DEVICE_POOL` one-device-per-render-LUID (the NVIDIA UMD-thread/VRAM leak fix); stamping
the OS target id onto the monitor context (the recreated-monitor `target_id=0` fix); the swap-chain
processor's two real leak fixes (borrow `IDXGIDevice` across `SetDevice` retries; check `terminate`
at the loop top during a frame burst).
- **The monitor-lifecycle concurrency correctness**: serialized ADD/REMOVE/teardown, the documented
lock order, the watchdog CAS + re-check-under-lock, the creation grace window, the
generation-stamped lease (a stale lease can't tear down a fresh monitor). *Structure* can change;
these properties must survive.
- **The CCD topology fixes**: `isolate_displays_ccd` (the iGPU-attached-monitor hybrid-box correctness;
the `SDC_FORCE_MODE_ENUMERATION` re-commit that drives `COMMIT_MODES → ASSIGN_SWAPCHAIN`); restore
topology *before* REMOVE.
- **The HDR color math**: `hdr.rs` verbatim (pure, unit-tested, ST.2086 G/B/R + big-endian SEI);
`HdrConverter`/`HdrP010Converter` + the f64 `p010_reference` + `hdr_p010_selftest`; `VideoConverter`
(RGB→NV12/P010 on the video engine — a measured latency win); the cursor decomposition
(`convert_pointer_shape` color/masked/monochrome edge cases).
- **NVENC tuning**: caps-probe-before-configure (disambiguate unsupported-config vs too-high-bitrate;
10-bit→8-bit graceful downgrade); the bitrate-clamp binary search (finds each GPU's real ceiling);
true RFI over the DPB; the low-latency configs (CBR, infinite GOP, P-only, ~1-frame VBV).
- **The gamepad driver wins**: the SwDeviceCreate identity recipe (enumerator with no `_`; mandatory
completion callback; synthesized `USB\VID_054C&PID_0CE6` compat-ids for native-DS5 detection; the
non-null per-pad `ContainerId` dodging the xinput1_4 slot-skip); one `pf_dualsense` serving
DualSense+DS4 via a `device_type` byte; XUSB declining `WAIT_*` to force synchronous `GET_STATE`;
the static HID descriptors/feature blobs; per-pad index via `pszDeviceLocation`.
- **The session-glue patterns**: the `Capturer`/`VirtualDisplay`/`Encoder` trait seam + RAII keepalive
teardown; host-lifetime shared services (`InjectorService`/`MicService`/`AudioCapSlot`) with
per-session gamepads; the encode|send thread split + microburst pacing; `build_pipeline_with_retry`
+ permanent-vs-transient classification; the control-task `select!` + adaptive-FEC; the GameStream
`VideoPacketizer` (GF8 Cauchy, Moonlight byte-exact); the pairing/trust handshake.
- **The SCM supervisor model**: Session-0 LocalSystem supervisor → token-retarget →
`CreateProcessAsUserW` `serve` into the console session, relaunch-on-session-change, kill-on-close
Job Object; the file-append log-mask; the two-tier logging init.
- **Build/CI wins**: the `wdf-umdf-sys` build.rs SDK-version resolution (picks the SDK version that
actually contains `iddcx`, not the max base SDK); the ARM64 cross-compile off the x64 runner; the
thin-.iss / fat-binary installer delegating to `service install`.
---
## 2. Target architecture
### 2.1 Crate & workspace strategy
**Keep ONE shared `crates/punktfunk-host` crate** (do *not* split `punktfunk-host-windows`). The host is
a leaf binary consumed by nobody; the "one core, linked everywhere" invariant is already satisfied by
`punktfunk-core`. A split would only fork the genuinely-shared session glue, traits, and `hdr.rs`. The
cfg-sprawl win comes instead from confining all Windows code under one `src/windows/` subtree behind a
single `#[cfg(windows)] mod windows;` seam, with backend impls next to their trait's dispatch point.
**Pull the three drivers into ONE in-tree driver workspace** (`packaging/windows/drivers/`) on a single
binding stack, one `rust-toolchain.toml`, one signing recipe, one CI build. Today they are 23 disjoint
cargo packages on two incompatible WDK stacks (see §6).
**Add ONE shared `no_std` ABI crate** (`crates/pf-vdisplay-proto`, name TBD) consumed by both the host
crate and the driver workspace. It owns *every* cross-process binary contract that is currently
hand-duplicated with "must match" comments. This is the single highest-value correctness change (§4.1).
### 2.2 Target file tree (host crate)
```
crates/punktfunk-host/src/
main.rs clap-derive subcommand dispatch only (kills parse_serve/parse_spike/hand --help)
config.rs HostConfig (typed; parsed ONCE from host.env/env/flags) + config_dir
session/
mod.rs SessionFactory, SessionPlan, SessionContext, Session (the ONLY teardown path)
server.rs QUIC accept loop, handshake, shared-service wiring
serve_session.rs resolve_* → Welcome/Start → spawn → RAII teardown
control.rs mid-stream renegotiation select! loop
pipeline.rs REAL shared encode|send split, send_loop, FrameMsg, pacing (used by native AND GameStream)
capture.rs Capturer trait + CapturedFrame/PixelFormat/FramePayload (platform-neutral)
capture/linux.rs
capture/windows/ mod.rs (dispatch), idd_push.rs, dda.rs, wgc.rs, secure_desktop.rs*
vdisplay.rs VirtualDisplay/VirtualOutput trait + open() dispatch (neutral)
vdisplay/{kwin,gamescope,mutter,wlroots}.rs
vdisplay/windows.rs was sudovda.rs → PfVirtualDisplay + VirtualDisplayManager
encode.rs Encoder trait, EncodedFrame, validate_dimensions, open_encoder dispatch
encode/{linux,vaapi,sw}.rs
encode/windows/ mod.rs (dispatch), nvenc.rs, nvenc_sys.rs, ffmpeg_win/{mod,system,zerocopy,d3d11va_ffi}.rs
hdr.rs PRESERVE VERBATIM
inject.rs / inject/linux/* / inject/windows/{mod,sendinput,pad_manager,xusb,dualsense,dualshock4,swdevice,section}.rs
inject/proto/{dualsense,dualshock4}.rs shared pure codecs (PRESERVE)
audio.rs / audio/linux.rs / audio/windows/{mod,wasapi_cap,wasapi_mic}.rs
windows/ mod.rs, d3d/{mod,texture,ring,convert}.rs, color/{hdr,p010,video_proc}.rs,
cursor.rs, display_ccd.rs, adapter.rs, process.rs (Token/Event/Job/Child/spawn_as_user),
service.rs (SCM; uses process.rs), win32u_hook.rs*, gpu_priority.rs
session_tuning.rs (PRESERVE) / pwinit.rs / discovery.rs / mgmt.rs / native_pairing.rs / library.rs
gamestream/ unchanged module set; stream.rs slims by reusing session/pipeline.rs
```
`*` = survives only per the secure-desktop / WGC product decisions (§5, §11).
### 2.3 The seam traits (keep the shape; tighten 3 things)
```rust
trait VirtualDisplay: Send {
fn name(&self) -> &str;
fn create(&self, mode: Mode) -> Result<VirtualOutput>;
fn set_launch_command(&self, cmd: Option<String>); // per-instance, not a global env var
}
struct VirtualOutput {
node_id: u32,
preferred_mode: Mode,
#[cfg(windows)] win_capture: WinCaptureTarget, // target_id + adapter_luid + monitor_gen (carried, not ambient)
keepalive: Box<dyn VirtualLease>,
}
trait VirtualLease: Send { // Drop = release; replaces the sudovda free-fns + CURRENT_MON_GEN reach-in
fn set_hdr(&self, on: bool) -> Result<()>;
fn hdr_enabled(&self) -> bool;
fn await_released(&self, timeout: Duration) -> bool;
}
trait Capturer: Send {
fn next_frame(&mut self) -> Result<CapturedFrame>;
fn try_latest(&mut self) -> Option<CapturedFrame>;
fn set_active(&mut self, a: bool);
fn hdr_meta(&self) -> Option<HdrMeta>;
fn pipeline_depth(&self) -> usize;
}
fn open_capturer(vout: VirtualOutput, want: OutputFormat) -> Result<Box<dyn Capturer>>; // format+HDR passed IN
trait Encoder: Send {
fn submit(&mut self, f: &CapturedFrame) -> Result<()>;
fn poll(&mut self) -> Option<EncodedFrame>;
fn flush(&mut self);
fn request_keyframe(&mut self);
fn caps(&self) -> EncoderCaps; // query, don't rely on default no-ops
fn set_hdr_meta(&mut self, m: Option<HdrMeta>);
fn invalidate_ref_frames(&mut self, lo: u64, hi: u64) -> bool;
}
fn open_encoder(plan: &EncodePlan) -> Result<Box<dyn Encoder>>;
trait AudioCapturer: Send { fn next_chunk(&mut self) -> Result<Vec<f32>>; fn channels(&self) -> u16; fn drain(&mut self); }
trait VirtualMic: Send { fn push(&mut self, pcm: &[f32]); fn channels(&self) -> u16; }
trait InputInjector: Send { fn inject(&mut self, e: &InputEvent); }
trait PadManager: Send { /* handle/apply_rich/pump/heartbeat — Box<dyn PadManager> via select(GamepadPref), replaces the PadBackend enum */ }
```
The three tightenings: (1) `Capturer` takes the desired `OutputFormat` IN — kills the
`capture → encode::windows_resolved_backend()` back-reference that's recomputed in `dxgi.rs`; (2) HDR
control + monitor-release become `VirtualLease` methods so the session glue never names a concrete
backend and contains zero `unsafe`; (3) optional encoder capabilities are queried via `EncoderCaps`.
### 2.4 SessionFactory + typed plan (the single biggest clarity lever)
Today the Windows capture/topology/encoder decision is made by ~40 scattered env reads, recomputed in
THREE places (`capture_virtual_output`, `should_use_helper`, `virtual_stream`) with no single owner and
a latent mirrored-dispatch bug (capture and encode can disagree on the backend). Replace with:
```rust
struct SessionPlan {
display: DisplayBackend,
capture: CaptureBackend, // IddPush | Dda | Wgc
topology: SessionTopology, // SingleProcess | TwoProcessRelay
encoder: EncoderBackend, // Nvenc | Amf | Qsv | Software
input_format: OutputFormat,
bit_depth: u8, hdr: bool, pipeline_depth: usize,
}
struct SessionFactory { cfg: Arc<HostConfig>, vdm: Arc<VirtualDisplayManager>, injector, mic, audio }
impl SessionFactory {
fn plan(&self, welcome: &Welcome) -> SessionPlan; // resolves ONCE from HostConfig; no env reads downstream
fn build(&self, plan: &SessionPlan, ctx: SessionContext) -> Result<Session>; // owns the RAII chain
}
```
`build()` owns the chain `vdm.lease(mode) → open_capturer(vout, fmt) → open_encoder(plan) → spawn
pipeline`, and `Session::drop` is the only teardown path. This kills the env soup, makes the deployed
path readable, and removes the capture/encode backend-disagreement bug class. It also lets us drop the
1213-arg `#[allow(too_many_arguments)]` signatures (a `SessionContext` struct) and the dead
`Compositor` ceremony threaded through the Windows path.
### 2.5 Ownership model — delete the global statics
Today the lifecycle is smeared across `IDD_PERSIST` + `open_or_reuse` (dead code), `CURRENT_MON_GEN`
(read per-frame), `IDD_SETUP_LOCK`/`IDD_SESSION_STOP` (the preempt dance), `MGR: Mutex<Mgr>`, and on
the driver side `ADAPTER`/`MONITOR_MODES`/`NEXT_ID`/`WATCHDOG_*`/`DEVICE_POOL`. Replace with:
- A host-lifetime **`VirtualDisplayManager`** owning a *typed* `OwnedHandle` device handle (not a raw
`isize` smuggled across threads) and the refcounted Idle/Active/Lingering state machine (preserve the
machine — it's earned).
- A per-session **`MonitorLease`** whose `Drop` releases the refcount; the monitor **generation carried
through `WinCaptureTarget`** instead of the ambient `CURRENT_MON_GEN`.
- On the driver: **wire `EvtCleanupCallback` for `MonitorContext`** (only `DeviceContext` has it today)
so the `SwapChainProcessor` + D3D resources drop via WDF RAII — deleting `free_swap_chain_processor`
and the manual-free-before-departure dance that is the **documented dominant reconnect leak**. Move
the process-global driver state into the `DeviceContext`; collapse the 3-way monitor identity
(`MONITOR_MODES` / EDID serial / context stamp) to one `Monitor` owned by the context.
---
## 3. The host↔driver contract (own it; define once)
### 3.1 `pf-vdisplay-proto` (no_std, bytemuck/zerocopy)
One crate, both build graphs (path dep). Owns:
- **Control plane**: a fresh interface GUID; a contiguous, versioned op enum; `#[repr(C)]` request/reply
structs carrying only used fields.
- **Frame plane**: `SharedHeader`, the `FrameToken { generation, seq, slot }` with `pack`/`unpack`
(replacing the hand-twiddled `gen<<40|seq<<8|slot` on both sides), the `Global\pfvd-*` name helpers.
- **Gamepad sections**: `XusbShm` (64 B) and `PadShm` (256 B, incl. `device_type`) layouts.
- Derive `FromBytes`/`IntoBytes`/`Pod`; `const` size+offset asserts; round-trip tests. **ABI drift
becomes a compile error, not a runtime corruption.** (bytemuck is already a dep in the driver +
wdf-umdf-sys.) This deletes every `OFF_*` constant + `read/write_unaligned` on both sides of every
boundary — the largest single block of shared-memory `unsafe`, and the top drift hazard.
### 3.2 Control plane — keep DeviceIoControl, redesign the ABI
`DeviceIoControl` is the correct WDF idiom for a driver with no control device and is low-frequency
(ADD/REMOVE per session + a keepalive); the shared-memory pattern buys nothing here. Keep it; redesign
the surface:
- Ops actually needed: `Add(mode, identity) → {luid, target_id}`, `Remove`, `SetRenderAdapter`
(now **unconditional** — pf-vdisplay honors it for hybrid-GPU IDD-push; drop the SudoVDA-parity
default-off branch), `ClearAll` (first-class startup orphan reap, not an "ignored by SudoVDA" hack),
`GetInfo` (a real version handshake), and keepalive (see §3.4).
- Drop the SudoVDA-isms: `AddParams.device_name[14]`/`serial[14]` (ignored), the 16-byte GUID → a
monotonic `u64` session id (the refcount manager owns collision safety; retires `next_monitor_guid`'s
pid-mangling), the 4-byte `{major,minor,incr,test}` version tuple → one `u32`, the gappy
`0x800/0x888/0x8FF` func numbering → contiguous.
- One typed IOCTL dispatch helper retrieves+validates+aligns the buffers and hands the body a safe
`&Req` / `&mut MaybeUninit<Reply>` — collapses ~20 of `control.rs`'s 29 `unsafe` blocks.
### 3.3 Frame plane — keep the inversion, retire the scaffolding
Keep the host-creates / driver-opens ring exactly. **Remove the bring-up scaffolding** that diagnosed
the now-solved `run_core=0` mystery: the `DebugBlock` channel + `DBG_MAGIC`, `spawn_observer` /
`PUNKTFUNK_IDD_PUSH_OBSERVE`, the `error!`-as-`info!` logging, the intentional handle leak, and the
20 s blind no-frame deadline (replace with the `DRV_STATUS_OPENED` handshake as a bounded liveness
signal).
### 3.4 Driver swap-chain reuse — the one open root cause
Today a *reused* IddCx monitor's swap-chain dies after ~2 sessions (target id resolves to 0, `SetDevice`
fails `0x80070057`, then an access violation), forcing fresh-monitor-per-session + the host-side
preempt/`wait_for_monitor_released` dance + the `IDD_PERSIST` "create once, never recreate" workaround.
The fix is in the **driver**: with `EvtCleanupCallback` wired + state owned by `DeviceContext` + the
identity collapsed to one `Monitor` (the recreate-path bugs are exactly the 3-way identity desync), the
clean recreate should become stable. **If** that holds, delete `IDD_SETUP_LOCK`/`IDD_SESSION_STOP` +
the preempt dance and unblock `max_concurrent>1` on Windows. **If** it can't be fixed cheaply, isolate
the residual serialization inside `VirtualDisplayManager` (not smeared back into the session loop).
Separately, evaluate replacing the polling watchdog (PING/countdown/grace/linger constellation) with a
**WDF file-object `EvtFileClose`** (host holds the control handle open; close = host gone) — feasibility
TBD on UMDF/IddCx.
---
## 4. Capture strategy
**IDD-push is the universal primary path — normal AND secure desktop (Decision B).** It composes
in-process (cross-session via `Global\` shared textures: driver in WUDFHost/Session 0, `serve` in the
console session), needs no DXGI Desktop Duplication and no `win32u` reparenting hook, is live-validated
at 5K@240 HDR, and (per the owner) also captures the secure desktop (Winlogon/UAC/lock). So there is no
separate "secure capturer" in the primary path: the same `IddPushCapturer` spans the lock screen and
UAC. Capture selection moves into a typed `CaptureBackend` in the `SessionPlan` — replacing the 3-way
env branch with `IddPush` (default) → `Dda`/`Wgc` (explicit fallbacks).
**WGC + DDA are kept as fallbacks, not deleted (Decision B).** They cover non-IddCx / pre-pf-vdisplay
hardware and act as a safety net if IDD-push fails to attach. But they are **demoted**: they are no
longer the default, no longer entangled with the secure-desktop mux, and selected only via the explicit
`CaptureBackend` fallback in the plan. This lets the DDA module shed the parts that existed *only* to
make virtual-display-over-DDA survive on a hybrid box, while the genuinely-useful capture/recovery core
stays:
- **Scope the `win32u` self-modifying-code hook + the GPU-pref hook to the DDA fallback leg** (one
`win32u_hook::install()`), so the primary IDD-push path never touches them. Re-confirm whether DDA
even needs the `win32u` hook against pf-vdisplay (it may not — open verification item).
- **The two-process WGC relay's secure-desktop mux is retired** — IDD-push handles the secure desktop
directly, so `desktop_watch.rs` + `composed_flip.rs` + the `virtual_stream_relay` monolith are no
longer needed for their original purpose. Keep a **minimal** WGC fallback capturer if the WGC backend
is retained; do not port the 400-line relay state machine. (The cross-session input concern below is
handled by the `InputInjector`/topology abstraction, not the AU video relay.)
**Shared D3D primitives** move out of `dxgi.rs` (today the de-facto dumping ground that `wgc.rs` and
`idd_push.rs` import from) into `windows/d3d/` (typed `Texture2d`/`Ring`/`CopyResource`/`Map`-as-bytes),
`windows/color/` (the converters + `hdr_p010_selftest` verbatim), and `windows/cursor.rs`. All three
capturers consume them — deletes the duplicated `tex_desc`, cursor, HDR-poll, repeat-last logic.
**The texture-ownership contract becomes type-level.** NVENC encodes the capturer's texture *in place*
(no copy), sound today only because the IDD-push capturer rotates `OUT_RING` and the loop honors
`pipeline_depth()` — an undocumented cross-module coupling that is *already* a latent corruption risk.
Fix: either the encoder always `CopySubresourceRegion`s (as `ffmpeg_win` does), or the capturer hands an
explicitly-leased ring texture with a documented lifetime. No more relying on the synchronous-loop
assumption.
**The IDD-push input question** (must confirm on-glass): capture+encode run in `serve`; input must reach
the *streamed* (console-session) desktop. If `serve` runs in the console session, `SendInput` works
directly. A code comment flags "SendInput from Session 0 can't reach Session 1" — so the architecture
must make `InputInjector` satisfiable either by in-session `SendInput` *or* by a tiny **input-only
Session-1 agent** (re-scope the old WGC helper to input only). The `SessionPlan.topology` expresses
this.
---
## 5. Encode layer
- Resolve backend + input format + pipeline depth **once** into `EncodePlan` and hand it to both the
capturer and the encoder factory — kill the duplicated `windows_resolved_backend()` call in `dxgi.rs`
(the highest-severity coupling). Trim `open_video`'s 8-arg grab-bag (`cuda` is always false on
Windows; `bit_depth` is overridden by the capture format anyway).
- **`nvenc_sys.rs`**: a thin safe wrapper — RAII `NvSession`/`NvBitstream`/`NvRegistration`/
`NvMappedInput` (Drop = destroy/unregister/unmap) + an `NV_ENC_CONFIG` builder. The public encoder
then has near-zero `unsafe` and no hand-written teardown loops. (The SDK table already returns
`Result` via `result_without_string()`.) This is the single biggest encode-side `unsafe` reduction.
- **`ffmpeg_win`**: RAII `AvFrame`/`SwsCtx`/`HwDeviceCtx`/`HwFramesCtx` delete every manual `av_*_free`
and the error-path cleanup ladders (also the biggest leak-risk reduction); a checked `MappedSurface`
for the staging readback; a `const` size-assert on the hand-mirrored `AVD3D11VA*` structs in a
dedicated `d3d11va_ffi` submodule (silent FFmpeg ABI drift is currently undetectable). Keep
system-readback the default; zero-copy stays opt-in/experimental (no AMD/Intel lab box).
- **HDR symmetry**: make in-band ST.2086/CLL SEI a shared post-encode step so AMF/QSV get the same
mastering metadata as NVENC (today only NVENC attaches it; AMF/QSV rely solely on the 0xCE datagram).
Centralize "when does the client learn HDR metadata" in one owner.
- Keep `hdr.rs`, the `Encoder` trait, `EncodedFrame`, `validate_dimensions`, the caps-probe + RFI logic
verbatim. Delete the `pipeline.rs` `pump_once` doc stub (the real loop is `session/pipeline.rs`).
---
## 6. Drivers — one binding stack (`windows-drivers-rs`), one workspace, one signing recipe
Today: `pf-vdisplay` on the vendored **`wdf-umdf`** stack; `pf_dualsense` + `pf_xusb` on
**`microsoft/windows-drivers-rs`** (`wdk`/`wdk-sys`/`wdk-build`). Two bindgen passes, two SDK
resolutions, two `NTSTATUS`, two build systems, two signing recipes.
**Decision C: unify all three on `microsoft/windows-drivers-rs`** (the official Microsoft stack), in one
in-tree `packaging/windows/drivers/` workspace, edition 2024, one `rust-toolchain.toml`, one CI build.
The gamepad drivers already ship on it; the work is to **migrate `pf-vdisplay` onto it** and **add the
IddCx surface** it lacks today.
**Required pieces of this migration (each a Phase-0/early task):**
1. **Add an `iddcx` subset to `wdk-sys`.** IddCx DDIs are *not* WDF-table functions — they are direct
`IddCxStub` exports — so the extension is bounded: an `ApiSubset::Iddcx` + `iddcx` feature →
bindgen `IddCx.h` + link `IddCxStub`, then ~15 thin `extern`/wrapper fns. Use the current
`wdf-umdf/src/iddcx.rs` (~345 LOC, validated) as a **line-by-line oracle**, including the IddCx 1.10
`*2` HDR DDIs (`IddCxSwapChainReleaseAndAcquireBuffer2`, `IDARG_*2`, `_METADATA2`).
2. **Solve `/INTEGRITYCHECK` for self-signed loading — properly.** `wdk-build` links the driver with
`/INTEGRITYCHECK`, which a self-signed cert can't satisfy (CodeIntegrity 3004/3089). Today the
gamepad drivers hand-patch the FORCE_INTEGRITY PE bit post-link. Replace that hack with a robust
solution, in order of preference: (a) **override the linker flag** — drop `/INTEGRITYCHECK` via
`wdk-build` config / `RUSTFLAGS`/`link-args` if it can be suppressed cleanly; else (b) a
**deterministic, tested CI post-link tool** (a small Rust/PowerShell step that clears bit `0x80` at
`e_lfanew+0x5e` and re-signs, run in CI, not by hand) so it's reproducible and not a footgun; (c) for
a public build, real **attestation signing** (Partner Center) satisfies `/INTEGRITYCHECK`
legitimately. Pick (a) if feasible; (b) as the fleet-self-signed fallback. This is the headline cost
of choosing this stack and must be nailed in Phase 0.
3. **Backport the `wdf-umdf-sys` build.rs SDK-resolution fix** into `wdk-build` (or a local override):
resolve `IddCx.h`/`IddCxStub` by the SDK version that *actually contains* `um\x64\iddcx`, not the max
base SDK (the real failure where a newer base SDK shadows the WDK SDK). windows-drivers-rs's default
resolution doesn't exercise IddCx today, so this likely needs porting.
4. **Port `pf-vdisplay`'s typed safety wins** onto the new stack: re-create the
`WDF_DECLARE_CONTEXT_TYPE!` `Arc<RwLock<T>>` context abstraction (the gold-standard contained
`unsafe`); the version-gate protocol (`IddCxIsFunctionAvailable!` / `IDD_STRUCTURE_SIZE!`); and a
thin safe wrapper layer so the gamepad drivers stop emitting raw `call_unsafe_wdf_function_binding!`
everywhere (the biggest driver-`unsafe` lever).
While unifying, also: adopt WDF device contexts for per-pad state (drop the
`UmdfHostProcessSharing=ProcessSharingDisabled`-dependent statics → true multi-pad-per-host); replace
`mem::zeroed()` configs with the `WDF_*_CONFIG_INIT` initializers (kills the recurring zeroed-default
bug class that already caused 3 driver bugs); cache the shm view (RAII `ShmView`) instead of
re-mapping ~125×/s; **delete the world-writable `C:\Users\Public\*.log` driver logging** and the "M0
spike" naming; collapse `is_nt_error()`/`dyn-Any`/`From<()>`-as-error into a typed `IntoDriverResult`;
collapse the per-call dispatch `unsafe` into one generic `dispatch()` helper.
**Provenance note:** confirm where `wdk`/`wdk-sys`/`wdk-build` come from (the gamepad drivers' Cargo.toml
path-deps `../../crates/wdk*` don't exist in this checkout — they resolve inside a windows-drivers-rs
checkout on the dev box). Pin them as crates.io deps or a vendored, version-pinned copy so the driver
workspace builds reproducibly in CI.
---
## 7. Input, audio, service, packaging
- **Input**: consolidate the host-side device plumbing (`create_swdevice`/`create_shm_section`/
`SwDeviceProfile`) into one `inject/windows/swdevice.rs` used by all three managers (XUSB included,
which currently re-implements its own). The shm layouts come from `pf-vdisplay-proto`. Re-scope the
cross-session helper (if any) to input-only.
- **Audio**: small, already fairly clean. Replace the lone `newdev.dll` `LoadLibrary`+`transmute`
(`wasapi_mic.rs`, the audio runtime's *only* `unsafe`) with the windows-rs `DiInstallDriverW` binding
(or move provisioning to the installer) → zero `unsafe` in the audio runtime.
- **Service / process**: one `windows/process.rs` owning RAII `Token`/`Event`/`Job`/`Child` + a single
`spawn_as_user()` used by BOTH the SCM supervisor and any helper — deletes the duplicated
token-dup/`merged_env_block`/`CreateProcessAsUserW` machinery and ~12 manual `CloseHandle` sites. Add
a **cooperative stop**: a named stop event the supervisor sets and `serve` waits on, so Stop runs RAII
teardown (today `TerminateProcess` skips Drop → the virtual monitor lingers, the documented
stale-monitor gotcha); `TerminateProcess` only as a bounded fallback.
- **Packaging/CI**: keep the thin-.iss / fat-binary model; add a `punktfunk-host web install/uninstall`
subcommand to absorb the web-setup PowerShell. **Build + sign the unified driver workspace in CI from
source** (or a CI guard that fails on stale-vendored-DLL / un-bumped DriverVer) so the driver can't
silently drift from its source. Mint the **fresh pf-vdisplay GUID** coordinated across host + driver +
INF. Single source of truth for version → build + ISCC AppVersion + INF DriverVer. Investigate
retiring `nefconc` by creating the ROOT devnode via SwDevice/CM in Rust. Keep the
devgen-never / nefconc-only and DriverVer-bump gotchas codified.
---
## 8. Unsafe-reduction program (run at port time, not as a separate pass)
- **P0 lints first** (a few lines, before new code): `#![deny(unsafe_op_in_unsafe_fn)]` (host crate has
none today; the driver workspace already has it), `#![warn(clippy::undocumented_unsafe_blocks)]`,
`#![warn(clippy::multiple_unsafe_ops_per_block)]`. Generated bindings keep their opt-out.
- **P0 std handle ownership**: `std::os::windows::io::OwnedHandle` / `std::fs::File::from_raw_handle`
everywhere a raw `HANDLE`/`isize` is held (events/jobs/tokens/sections/pipes). Used in **zero** host
files today — the single biggest cheap win. Deletes the bespoke `unsafe impl Read/Write/Drop`
(`HandleReader`), the never-closed sudovda control handle, the `AtomicIsize` HANDLE globals, ~6 manual
`CloseHandle` sites — and fixes real leaks.
- **P0 the proto crate** (§3.1) — kills the shared-memory pointer-cast `unsafe`.
- **P1 typed wrappers**: `windows/d3d/` (most COM calls already return `Result`; per-frame loop bodies
become `unsafe`-free, the irreducible keyed-mutex/`from_raw_parts` lands in one `frame_xfer` fn);
`nvenc_sys` + RAII ffmpeg (§5); one `windows/process.rs` (§7); collapse the 21 `unsafe impl Send`
onto one audited `SendPtr<T>`/`ThreadBound<T>` (directly de-risks the NVENC in-place coupling).
- **P2 contain the irreducible**: `win32u_hook.rs` (one `install()`; scope to secure-DDA or drop),
`gpu_priority.rs` (the D3DKMT transmute), the WDF context-blob macro, the IddCx swap-chain DDI +
`from_raw_borrowed` (wrap in a typed `SwapChain` guard returning a borrowed `AcquiredSurface<'_>`).
Document a `// SAFETY:` per residual site.
- **P2 delete `unsafe` by deleting code**: the `present_trigger` dead diagnostic, the `DebugBlock`
channel, `spawn_observer`, `IDD_PERSIST`/`open_or_reuse`, `helpers.rs Sendable<T>`, the WGC-open
thread-watchdog hack (gone with WGC), the driver file-logging.
Estimated: host ~144→~35, drivers ~227→~60, residual concentrated and auditable. (`#![forbid(unsafe)]`
is impossible for the drivers and the per-frame D3D path — the realistic target is *containment*.)
---
## 9. SudoVDA decoupling (mechanical rename + scrub)
`vdisplay/sudovda.rs``vdisplay/windows.rs`; `SudoVdaDisplay``PfVirtualDisplay`; scrub "SudoVDA"
from all log/error/doc strings across `capture.rs`/`dxgi.rs`/`wgc*.rs`/`idd_push.rs`/`punktfunk1.rs`/
`main.rs`/`sendinput.rs` (141 refs / 15 files). **Split the reach-in helpers out** of the vdisplay
backend (they're display-utility, not virtual-display creation): `set_advanced_color`,
`advanced_color_enabled`, `resolve_gdi_name`, `isolate/restore_displays_ccd`, `set_active_mode`
`windows/display_ccd.rs` (collapsing the 4× copy-pasted `QueryDisplayConfig` preamble into one safe
`query_active_config()`); `resolve_render_adapter_luid``windows/adapter.rs`. Both vdisplay and
capture then depend on these as peers, breaking the circular reach-in. `WinCaptureTarget` moves to a
neutral location (defined in `dxgi.rs`, constructed in `sudovda.rs` today). Drop the dual-driver
fallback conditionals. Expose HDR/monitor-release as `VirtualLease` methods (zero `unsafe` in the
session glue).
---
## 10. Build plan (greenfield — Decision A)
A from-scratch rebuild of the Windows host against the clean architecture, **salvaging the §1 jewels
verbatim** (the already-clean, already-tested modules: `hdr.rs`, `edid.rs`, the `inject/proto` codecs,
the HDR/cursor converters + their self-tests, the GF8 packetizer, the pairing handshake). The old
Windows code stays in-tree, untouched, as the *reference implementation* until the new path reaches
parity on glass, then is deleted.
**Greenfield-risk mitigation (the survey's strong caveat stands):** almost none of this is
CI-validatable — the Windows backends + drivers need the RTX box (192.168.1.173) + the build VM, and
**AMF/QSV have no lab hardware at all**. A greenfield rewrite therefore carries real risk of silently
dropping a layered bug-fix. Two guardrails are mandatory:
1. **The §1 preservation checklist is a test/assert contract**, not prose: each rebuilt module ports its
hard-won invariants as unit tests or runtime asserts — RAII teardown order (restore displays *before*
REMOVE), keyed-mutex held only across convert/copy, `terminate` checked at the swap-chain loop top,
magic stamped last, `OUT_RING` texture rotation under `pipeline_depth>1`, the NVENC caps-probe
downgrade, the SwDeviceCreate identity recipe. A rebuild that drops one fails its own test.
2. **On-glass A/B gates** at each milestone below, on the RTX box, against the current shipping build:
1080p60, 5K@240 HDR, reconnect-storm, secure desktop (lock/UAC), multi-pad. Nothing replaces the old
path until its A/B passes.
### Build order
- **M0 — Foundations + the `/INTEGRITYCHECK` answer.** Stand up `crates/pf-vdisplay-proto` (the clean,
owned ABI: fresh GUID, the redesigned IOCTL op enum + `#[repr(C)]` structs, `SharedHeader`,
`FrameToken`, the gamepad shm layouts, `const` size-asserts, round-trip tests). Stand up the in-tree
`packaging/windows/drivers/` workspace on `windows-drivers-rs` and **prove the two hard unknowns**:
(a) the `iddcx` `wdk-sys` subset bindgen+links and a trivial IddCx adapter loads; (b) `/INTEGRITYCHECK`
is solved (§6.2) so a self-signed driver loads under Secure Boot with no hand-patching. Add the P0
lints to the host crate. *No host behavior yet.*
- **M1 — pf-vdisplay on the new stack, first light.** Rebuild the IddCx driver against
`windows-drivers-rs`+`iddcx`, clean from the start: `DeviceContext`-owned state (no process-globals),
one `Monitor` identity, `EvtCleanupCallback` on `MonitorContext`, the ported `Arc<RwLock<T>>` context,
the EDID + HDR recipe verbatim, the redesigned control plane from the proto crate. *(On-glass: ADD →
monitor arrives → IDD-push ring attaches → frames flow at 1080p; REMOVE clean.)*
- **M2 — IDD-push capture + NVENC, glass-to-glass.** New `src/windows/` tree: `windows/d3d/` typed
wrappers, `windows/color/` (converters + self-tests), `windows/cursor.rs`, `capture/windows/idd_push.rs`
consuming the proto ring with a **type-level texture-ownership contract** (no in-place-encode
assumption), `encode/windows/{nvenc.rs,nvenc_sys.rs}`, `vdisplay/windows.rs` + `windows/display_ccd.rs`
+ `windows/adapter.rs`. Wire the `SessionFactory`/`SessionPlan` (M2 only needs the IDD-push+NVENC
plan). *(On-glass A/B: 1080p60 + 5K@240 HDR, latency parity with the current build.)*
- **M3 — Service, input, audio, secure desktop.** `windows/process.rs` (RAII Token/Event/Job/Child +
`spawn_as_user` + cooperative stop) + `windows/service.rs`; `inject/windows/*` on the proto shm +
consolidated `swdevice.rs`; `audio/windows/*` (zero-`unsafe` runtime). Confirm IDD-push captures the
secure desktop (lock/UAC) and input reaches the streamed session (in-session `SendInput`, or the
input-only agent if needed). *(On-glass: full session incl. lock screen + UAC + a real pad.)*
- **M4 — Gamepad drivers onto the unified stack.** Rebuild `pf_dualsense` + `pf_xusb` on
`windows-drivers-rs` in the same workspace, WDF device contexts (true multi-pad), proto shm,
`WDF_*_CONFIG_INIT`, no file logging, no "M0 spike" naming. *(On-glass: 2 XInput + 2 DualSense pads,
rumble/lightbar/adaptive-trigger round-trip.)*
- **M5 — Fallbacks + GameStream + AMF/QSV.** Port the demoted WGC + DDA fallback capturers (minimal,
`win32u` hook scoped to the DDA leg); `encode/windows/ffmpeg_win/*` with RAII FFmpeg + the
`d3d11va_ffi` size-assert (system-readback default; zero-copy experimental); GameStream planes reusing
`session/pipeline.rs`, installer default flipped to secure `serve`. *(On-glass: Moonlight client on
the DDA fallback; AMF/QSV stays CI-only.)*
- **M6 — Cut over + delete.** Flip the default to the new path, run the full A/B matrix, then delete the
old `dxgi.rs`/`wgc*`/`sudovda.rs`/`punktfunk1.rs` Windows monoliths + the bring-up scaffolding
(`DebugBlock`/`spawn_observer`/observe gate) + the old gamepad driver crates. Single source of truth
for version; CI builds+signs all drivers from source.
Milestones are roughly dependency-ordered; M0 is the long pole (the `/INTEGRITYCHECK` + `iddcx` proof
gates everything else). M5's AMF/QSV cannot be validated without hardware — keep it system-readback-only
and clearly experimental.
---
## 11. Decisions (resolved 2026-06-24) + open verification items
The five product forks are decided (see the table in §0): **A** greenfield; **B** IDD-push primary for
everything incl. secure desktop, WGC+DDA kept as demoted fallbacks; **C** extend `windows-drivers-rs` +
solve `/INTEGRITYCHECK`; **D** keep GameStream, default secure. On **E (concurrent sessions)**: fix the
driver swap-chain lifecycle regardless (it removes the leak + the preempt dance); treat true
`max_concurrent>1` on Windows as a follow-on once clean reuse is proven on glass.
What remains are **technical unknowns to confirm on the RTX box** (not user decisions):
- **`/INTEGRITYCHECK` resolution path (M0 long pole).** Can `wdk-build` suppress `/INTEGRITYCHECK` via
config/link-args (preferred), or must we keep a deterministic CI post-link bit-clear? Decides the
signing story for all three drivers.
- **`iddcx` subset on `wdk-sys`.** Does the bindgen+`IddCxStub` link cleanly, and does the SDK-resolution
fix need backporting? (windows-drivers-rs doesn't exercise IddCx today.)
- **Driver swap-chain reuse.** Does the clean ownership model (`EvtCleanupCallback` + DeviceContext state
+ single `Monitor` identity) actually fix the "reused swap-chain dies after ~2 sessions" root cause? If
not, the residual serialization stays inside `VirtualDisplayManager`.
- **IDD-push input + secure desktop.** Confirm `serve` runs in the console session so `SendInput` reaches
the streamed desktop (a code comment warns about Session 0→1); confirm IDD-push frames flow through the
lock screen / UAC (owner reports yes — verify and lock it in as the primary, demoting the DDA secure
leg to fallback).
- **Does the demoted DDA fallback still need the `win32u` hook** against pf-vdisplay, or was that purely
a SudoVDA/hybrid pathology? If unneeded, the self-modifying-code hook can be deleted entirely.
- **AMF/QSV** stays CI-only (no hardware) — system-readback default, zero-copy experimental.
---
## 12. Risks
- **Greenfield with no CI (the dominant risk).** The build VM is headless/WARP; the WinUI/hardware/driver
paths need the RTX box, and AMF/QSV have no hardware. A from-scratch rebuild can silently drop a
layered bug-fix. Mitigation: the §1 preservation checklist is a *test/assert contract* per rebuilt
module; on-glass A/B gates the new path before the old one is deleted (M6); keep the old code in-tree
as the reference until parity.
- **`/INTEGRITYCHECK` (M0 long pole).** Choosing `windows-drivers-rs` means self-signed loading depends
on solving it cleanly (§6.2). If neither linker-flag suppression nor a deterministic CI post-link step
works, drivers can't load self-signed — prove this first, it gates everything.
- **`iddcx` on `wdk-sys`** is new surface (windows-drivers-rs doesn't bind IddCx). Bounded
(`IddCxStub` exports + ~15 wrappers, with the validated `wdf-umdf/iddcx.rs` as oracle) but unproven on
this stack — M0 must light it.
- **`pf-vdisplay-proto` spans two cargo build graphs** (host workspace + the driver workspace). Validate
the path-dep resolves on the Windows build env in M0; pin `wdk*` provenance so the driver workspace
builds reproducibly in CI.
- **Driver swap-chain-reuse root cause still undiagnosed.** The clean ownership model *should* fix it;
if not, residual serialization stays inside `VirtualDisplayManager` and `max_concurrent>1` stays
blocked. Keep `await_released` on the trait until reuse is proven on glass.
- **NVENC in-place encode + `pipeline_depth>1`** is a latent corruption risk; the M2 texture-ownership
contract must be type-level (not the synchronous-loop assumption). Verify the ring on glass.
- **Host/driver version drift in the field.** New host + new driver are always built together (greenfield),
but the installer bundles both — enforce a startup version handshake (proto version in both binaries)
and a CI guarantee they're built from the same revision.
- **Big-bang cutover (M6).** Flipping the default and deleting the old monoliths is the riskiest moment;
it is gated on the full A/B matrix passing, and the old code is recoverable from git if a regression
surfaces post-cutover.