feat(host/windows): resident virtual HID mouse (pf-mouse UMDF minidriver)

Headless Windows hosts (no dongle) stream an INVISIBLE cursor: with no
pointing device present win32k reports SM_MOUSEPRESENT=0 and DWM never
composites a pointer into the pf-vdisplay frame, even though SendInput
moves it. Keep ONE virtual HID mouse devnode alive for the host's
lifetime — the Sunshine/Parsec-class fix, zero client changes.

- pf-mouse: UMDF2 HID minidriver, one fixed identity (PF:MO 5046:4D4F,
  obviously virtual, nothing fingerprints it), one 8-byte input report
  (5 buttons + absolute 15-bit X/Y + wheel + AC-pan). Transport is the
  sealed pad channel verbatim (Global\pfmouse-boot-0 mailbox + unnamed
  MouseShm DATA section) so pf-umdf-util's audited layer serves it
  unchanged; report delivery is event-driven (idle = no HID traffic).
- host: inject::mouse_windows — VirtualMouse (SwDeviceCreate'd devnode +
  channel), ensure_resident() keeper thread started by every
  InjectorService (process-wide, PUNKTFUNK_NO_VIRTUAL_MOUSE opts out),
  vmouse-spike on-glass validation (cursor sweep via HID reports).
- proto: mouse module (magic, boot-name, identity, report layout,
  unit-tested input_report packing).
- SwDeviceProfile grows container_tag so the mouse's ContainerId family
  (PFMO) never groups with a pad's (PFDS) in the Devices UI.
- packaging: pf-mouse rides the gamepad-driver build + install pipeline
  (build-gamepad-drivers.ps1, windows-drivers.yml, driver install
  --gamepad picks up every staged .inf).

On-glass validated on winbox: devnode + HID child bind, SM_MOUSEPRESENT=1
with no physical mouse, cursor sweeps via HID reports (vmouse-spike).

This work was implemented in a parallel session; committed here as the
build prerequisite for the HID compose kick that follows.

Co-Authored-By: Claude Fable 5 <noreply@anthropic.com>
This commit is contained in:
2026-07-17 11:02:10 +02:00
parent 3d9b329084
commit 85dd2bb077
17 changed files with 1024 additions and 8 deletions
+11
View File
@@ -412,6 +412,17 @@ dependencies = [
"wdk-sys",
]
[[package]]
name = "pf-mouse"
version = "0.0.1"
dependencies = [
"pf-driver-proto",
"pf-umdf-util",
"wdk",
"wdk-build",
"wdk-sys",
]
[[package]]
name = "pf-umdf-util"
version = "0.0.1"
+1 -1
View File
@@ -7,7 +7,7 @@
# crates/pf-driver-proto from the main tree.
[workspace]
resolver = "2"
members = ["wdk-probe", "wdk-iddcx", "pf-umdf-util", "pf-vdisplay", "pf-dualsense", "pf-xusb"]
members = ["wdk-probe", "wdk-iddcx", "pf-umdf-util", "pf-vdisplay", "pf-dualsense", "pf-xusb", "pf-mouse"]
[workspace.package]
edition = "2024"
@@ -0,0 +1,32 @@
# pf-mouse - punktfunk virtual HID mouse (absolute pointer) UMDF2 HID minidriver.
# A member of the in-tree drivers workspace (shares the vendored wdk-sys/wdk-build with the bindgen pin
# + the crt-static .cargo/config), built from source per release like the gamepad drivers.
[package]
name = "pf-mouse"
edition.workspace = true
version.workspace = true
license.workspace = true
publish = false
description = "punktfunk virtual HID mouse (absolute pointer) UMDF2 HID minidriver"
[package.metadata.wdk.driver-model]
driver-type = "UMDF"
umdf-version-major = 2
target-umdf-version-minor = 31
[lib]
crate-type = ["cdylib"]
[build-dependencies]
wdk-build.workspace = true
[dependencies]
wdk.workspace = true
wdk-sys.workspace = true
pf-driver-proto.workspace = true
pf-umdf-util.workspace = true
[features]
default = ["hid"]
hid = ["wdk-sys/hid"]
nightly = ["wdk-sys/nightly", "wdk/nightly"]
@@ -0,0 +1,12 @@
// Copyright (c) Microsoft Corporation
// License: MIT OR Apache-2.0
//! Build script for the `sample-umdf-driver` crate.
//!
//! Based on the [`wdk_build::Config`] parsed from the build tree, this build
//! script will provide `Cargo` with the necessary information to build the
//! driver binary (ex. linker flags)
fn main() -> Result<(), wdk_build::ConfigError> {
wdk_build::configure_wdk_binary_build()
}
@@ -0,0 +1,79 @@
;/*++
; punktfunk virtual HID mouse (absolute pointer) — UMDF2 HID minidriver INF.
; Same skeleton as pf_dualsense.inx (the WDK vhidmini2 UMDF2 shape).
; Depends on MsHidUmdf.inf (build >= 22000).
; Install: devgen /add /hardwareid "root\pf_mouse" (after pnputil /add-driver /install)
;--*/
[Version]
Signature="$WINDOWS NT$"
Class=HIDClass
ClassGuid={745a17a0-74d3-11d0-b6fe-00a0c90f57da}
Provider=%ProviderString%
CatalogFile=pf_mouse.cat
PnpLockdown=1
[DestinationDirs]
DefaultDestDir = 13
[SourceDisksNames]
1=%Disk_Description%,,,
[SourceDisksFiles]
pf_mouse.dll=1
[Manufacturer]
%ManufacturerString%=pf, NT$ARCH$.10.0...22000
[pf.NT$ARCH$.10.0...22000]
; Hardware ids: `root\pf_mouse` for a root-enumerated devnode (devgen/devcon tests); `pf_mouse` for
; the host's SwDeviceCreate'd resident pointer (the `root\` prefix is reserved for root enumeration,
; so SwDeviceCreate rejects it with E_INVALIDARG).
%DeviceDesc%=pfMouse, root\pf_mouse, pf_mouse
[pfMouse.NT]
CopyFiles=UMDriverCopy
Include=MsHidUmdf.inf
Needs=MsHidUmdf.NT
Include=WUDFRD.inf
Needs=WUDFRD_LowerFilter.NT
[pfMouse.NT.hw]
Include=MsHidUmdf.inf
Needs=MsHidUmdf.NT.hw
Include=WUDFRD.inf
Needs=WUDFRD_LowerFilter.NT.hw
[pfMouse.NT.Services]
Include=MsHidUmdf.inf
Needs=MsHidUmdf.NT.Services
Include=WUDFRD.inf
Needs=WUDFRD_LowerFilter.NT.Services
[pfMouse.NT.Filters]
Include=WUDFRD.inf
Needs=WUDFRD_LowerFilter.NT.Filters
[pfMouse.NT.Wdf]
UmdfService="pf_mouse", pf_mouse_Install
UmdfServiceOrder=pf_mouse
UmdfKernelModeClientPolicy=AllowKernelModeClients
UmdfFileObjectPolicy=AllowNullAndUnknownFileObjects
UmdfMethodNeitherAction=Copy
UmdfFsContextUsePolicy=CanUseFsContext2
; Its own WUDFHost so the driver's per-device statics never collide with a gamepad's (parity with
; the pad INFs — and the resident mouse outlives any session, so isolation is cheap insurance).
UmdfHostProcessSharing=ProcessSharingDisabled
[pf_mouse_Install]
UmdfLibraryVersion=$UMDFVERSION$
ServiceBinary="%13%\pf_mouse.dll"
[UMDriverCopy]
pf_mouse.dll
[Strings]
ProviderString ="punktfunk"
ManufacturerString ="punktfunk"
ClassName ="HID device"
Disk_Description ="punktfunk Mouse Installation Disk"
DeviceDesc ="punktfunk Virtual Mouse"
@@ -0,0 +1,477 @@
// punktfunk virtual HID mouse — UMDF2 HID minidriver (absolute pointer).
//
// Why it exists: with NO pointing device present (a headless streaming host — no dongle), win32k
// reports the cursor as absent (`SM_MOUSEPRESENT` = 0) and DWM never composites a cursor into the
// pf-vdisplay frame, so the streamed desktop has an invisible pointer even though `SendInput`
// moves it. This driver keeps a resident HID mouse devnode alive for the host service's lifetime,
// which makes Windows always consider a pointer present and draw the cursor — the industry-standard
// fix (what Sunshine/Parsec-class virtual-input drivers achieve). Injection stays `SendInput`;
// the report path below is exercised by `punktfunk-host vmouse-spike` (validation) and is the
// future higher-fidelity injection route.
//
// Structure is pf-dualsense minus the identity zoo: one fixed HID identity (PF:MO, an obviously
// virtual VID/PID no software matches on), one 8-byte input report (5 buttons + absolute 15-bit
// X/Y + wheel + AC-pan), no feature/output reports. The host channel is the **sealed pad channel**
// (design/gamepad-channel-sealing.md) verbatim — mailbox `Global\pfmouse-boot-<i>`, unnamed
// `pf_driver_proto::mouse::MouseShm` DATA section — so the whole handshake + shared-memory surface
// lives in `pf_umdf_util` (the audited unsafe layer) and this crate's logic is 100% SAFE Rust; the
// only `unsafe` here is the unavoidable WDF setup FFI, each with a `// SAFETY:` proof.
//
// Report delivery is EVENT-DRIVEN like a real mouse: the timer completes a pended READ_REPORT only
// when the host bumped `in_seq` — an idle section generates no HID traffic (a constant report
// stream would read as user activity to the OS: idle timers, display sleep).
#![allow(non_snake_case, non_upper_case_globals, clippy::missing_safety_doc)]
// Every remaining `unsafe {}` (all WDF setup FFI) must carry a `// SAFETY:` proof.
#![deny(unsafe_op_in_unsafe_fn)]
#![deny(clippy::undocumented_unsafe_blocks)]
use core::sync::atomic::{AtomicPtr, AtomicU32, Ordering};
use pf_driver_proto::mouse::{
MOUSE_PID, MOUSE_REPORT_ID, MOUSE_REPORT_LEN, MOUSE_VER, MOUSE_VID, MouseShm,
};
use pf_umdf_util::channel::{ChannelClient, ChannelConfig};
use pf_umdf_util::nt_success;
use pf_umdf_util::wdf::{self, Request};
use wdk_sys::{
NTSTATUS, PCUNICODE_STRING, PDRIVER_OBJECT, PWDFDEVICE_INIT, ULONG, WDF_DRIVER_CONFIG,
WDF_IO_QUEUE_CONFIG, WDF_NO_HANDLE, WDF_NO_OBJECT_ATTRIBUTES, WDF_OBJECT_ATTRIBUTES,
WDF_TIMER_CONFIG, WDFDEVICE, WDFDRIVER, WDFQUEUE, WDFQUEUE__, WDFREQUEST, WDFTIMER,
call_unsafe_wdf_function_binding, windows::OutputDebugStringA,
};
// ---- NTSTATUS values ----
const STATUS_SUCCESS: NTSTATUS = 0;
const STATUS_NOT_IMPLEMENTED: NTSTATUS = 0xC000_0002u32 as NTSTATUS;
// ---- HID minidriver IOCTLs: CTL_CODE(FILE_DEVICE_KEYBOARD=0x0b, id, METHOD_NEITHER=3, ANY) ----
const fn hid_ctl(id: u32) -> u32 {
(0x0000_000b << 16) | (id << 2) | 3
}
const IOCTL_HID_GET_DEVICE_DESCRIPTOR: u32 = hid_ctl(0);
const IOCTL_HID_GET_REPORT_DESCRIPTOR: u32 = hid_ctl(1);
const IOCTL_HID_READ_REPORT: u32 = hid_ctl(2);
const IOCTL_HID_WRITE_REPORT: u32 = hid_ctl(3);
const IOCTL_HID_GET_DEVICE_ATTRIBUTES: u32 = hid_ctl(9);
const IOCTL_HID_GET_STRING: u32 = hid_ctl(4);
const IOCTL_UMDF_HID_SET_OUTPUT_REPORT: u32 = hid_ctl(22);
const IOCTL_UMDF_HID_GET_INPUT_REPORT: u32 = hid_ctl(23);
// ---- WDF enum values ----
const WdfIoQueueDispatchParallel: i32 = 2;
const WdfIoQueueDispatchManual: i32 = 3;
const WdfUseDefault: i32 = 2; // WDF_TRI_STATE
const WdfExecutionLevelInheritFromParent: i32 = 1; // WDF_EXECUTION_LEVEL
const WdfSynchronizationScopeInheritFromParent: i32 = 1; // WDF_SYNCHRONIZATION_SCOPE
// HID report descriptor (80 bytes): one application collection (Generic Desktop / Mouse), report
// id 0x01 — 5 buttons, ABSOLUTE 15-bit X/Y (logical 0..=32767), relative wheel + AC-pan. Absolute
// axes so a future report-driven injection maps 1:1 onto the desktop, and so the OS treats the
// device as a pointer that never "drifts"; presence (not fidelity) is this driver's job today.
#[rustfmt::skip]
static MOUSE_RDESC: [u8; 80] = [
0x05, 0x01, // Usage Page (Generic Desktop)
0x09, 0x02, // Usage (Mouse)
0xA1, 0x01, // Collection (Application)
0x85, 0x01, // Report ID (1)
0x09, 0x01, // Usage (Pointer)
0xA1, 0x00, // Collection (Physical)
0x05, 0x09, // Usage Page (Button)
0x19, 0x01, // Usage Minimum (1)
0x29, 0x05, // Usage Maximum (5)
0x15, 0x00, // Logical Minimum (0)
0x25, 0x01, // Logical Maximum (1)
0x75, 0x01, // Report Size (1)
0x95, 0x05, // Report Count (5)
0x81, 0x02, // Input (Data,Var,Abs) — buttons 1..5
0x75, 0x03, // Report Size (3)
0x95, 0x01, // Report Count (1)
0x81, 0x03, // Input (Const) — pad
0x05, 0x01, // Usage Page (Generic Desktop)
0x09, 0x30, // Usage (X)
0x09, 0x31, // Usage (Y)
0x15, 0x00, // Logical Minimum (0)
0x26, 0xFF, 0x7F, // Logical Maximum (32767)
0x75, 0x10, // Report Size (16)
0x95, 0x02, // Report Count (2)
0x81, 0x02, // Input (Data,Var,Abs) — absolute X/Y
0x09, 0x38, // Usage (Wheel)
0x15, 0x81, // Logical Minimum (-127)
0x25, 0x7F, // Logical Maximum (127)
0x75, 0x08, // Report Size (8)
0x95, 0x01, // Report Count (1)
0x81, 0x06, // Input (Data,Var,Rel) — wheel
0x05, 0x0C, // Usage Page (Consumer)
0x0A, 0x38, 0x02, // Usage (AC Pan)
0x15, 0x81, // Logical Minimum (-127)
0x25, 0x7F, // Logical Maximum (127)
0x75, 0x08, // Report Size (8)
0x95, 0x01, // Report Count (1)
0x81, 0x06, // Input (Data,Var,Rel) — horizontal wheel
0xC0, // End Collection
0xC0, // End Collection
];
// HID descriptor (9 bytes, packed): len, type=0x21, bcdHID=0x0100, country=0, numDesc=1, then
// {reportType=0x22, wReportLength = 80 (0x0050)}.
static HID_DESC: [u8; 9] = [0x09, 0x21, 0x00, 0x01, 0x00, 0x01, 0x22, 0x50, 0x00];
// HID_DEVICE_ATTRIBUTES (32 bytes): Size(u32)=32, VendorID, ProductID, VersionNumber, Reserved[11].
fn hid_attrs() -> [u8; 32] {
let mut a = [0u8; 32];
a[0..4].copy_from_slice(&32u32.to_le_bytes());
a[4..6].copy_from_slice(&MOUSE_VID.to_le_bytes());
a[6..8].copy_from_slice(&MOUSE_PID.to_le_bytes());
a[8..10].copy_from_slice(&MOUSE_VER.to_le_bytes());
a
}
/// A report that answers a client's GET_INPUT_REPORT query before the host published anything:
/// id + all-zero state. Never fed into the input stream (READ_REPORT completes only on a fresh
/// host publish), so it cannot warp the cursor to (0,0).
const NEUTRAL_REPORT: [u8; MOUSE_REPORT_LEN] = {
let mut r = [0u8; MOUSE_REPORT_LEN];
r[0] = MOUSE_REPORT_ID;
r
};
static MANUAL_QUEUE: AtomicPtr<WDFQUEUE__> = AtomicPtr::new(core::ptr::null_mut());
/// The latest host-published report (kept for GET_INPUT_REPORT queries).
static INPUT_REPORT: std::sync::Mutex<[u8; MOUSE_REPORT_LEN]> =
std::sync::Mutex::new(NEUTRAL_REPORT);
/// The last `in_seq` a READ_REPORT was completed for — the event-driven gate. NOT advanced when no
/// read is pended (the next tick retries), so a publish is never dropped while a reader exists.
static DELIVERED_SEQ: AtomicU32 = AtomicU32::new(0);
// ---- the sealed host channel: layouts + offsets from pf_driver_proto (drift = compile error) ----
const SHM_MAGIC: u32 = pf_driver_proto::mouse::MOUSE_MAGIC; // "PFMO"
const SHM_SIZE: usize = core::mem::size_of::<MouseShm>();
const GAMEPAD_PROTO_VERSION: u32 = pf_driver_proto::gamepad::GAMEPAD_PROTO_VERSION;
// MouseShm field offsets (the driver reads report + in_seq, writes the health marks).
const OFF_IN_SEQ: usize = core::mem::offset_of!(MouseShm, in_seq);
const OFF_REPORT: usize = core::mem::offset_of!(MouseShm, report);
const OFF_DRIVER_PROTO: usize = core::mem::offset_of!(MouseShm, driver_proto);
const OFF_DRIVER_HEARTBEAT: usize = core::mem::offset_of!(MouseShm, driver_heartbeat);
const OFF_PAD_INDEX: usize = core::mem::offset_of!(MouseShm, pad_index);
/// The sealed-channel client (`ProcessSharingDisabled` gives the mouse its own WUDFHost, so this
/// static is per-device). The handshake/adoption/validation state machine lives in `pf_umdf_util`.
static CHANNEL: ChannelClient = ChannelClient::new();
/// This device's channel config (magic/size/index offset + our logger).
fn channel_cfg() -> ChannelConfig {
ChannelConfig {
tag: "pf-mouse",
boot_name_prefix: "Global\\pfmouse-boot-",
data_magic: SHM_MAGIC,
data_size: SHM_SIZE,
pad_index_off: OFF_PAD_INDEX,
log,
}
}
/// Whether the world-writable bring-up file log is enabled (resolved once). OPT-IN — debug builds,
/// or the `PFMOUSE_DEBUG_LOG` (system-wide) env var — the same policy as the pad drivers (audit
/// §4.4): a RELEASE driver never writes the Public file. DebugView can't see the UMDF host across
/// session 0, so the file stays the bring-up diagnostic when enabled.
fn file_log_enabled() -> bool {
use std::sync::OnceLock;
static ON: OnceLock<bool> = OnceLock::new();
*ON.get_or_init(|| cfg!(debug_assertions) || std::env::var_os("PFMOUSE_DEBUG_LOG").is_some())
}
/// Process-lifetime append handle to the bring-up log, opened ONCE and shared via a `Mutex`
/// (pf-vdisplay's pattern) — no per-line open/close.
fn file_appender() -> Option<&'static std::sync::Mutex<std::fs::File>> {
use std::sync::OnceLock;
static APPENDER: OnceLock<Option<std::sync::Mutex<std::fs::File>>> = OnceLock::new();
APPENDER
.get_or_init(|| {
if !file_log_enabled() {
return None;
}
std::fs::OpenOptions::new()
.create(true)
.append(true)
.open("C:\\Users\\Public\\pfmouse-driver.log")
.ok()
.map(std::sync::Mutex::new)
})
.as_ref()
}
fn log(s: &str) {
if let Ok(c) = std::ffi::CString::new(s) {
// SAFETY: `c` is a valid NUL-terminated string for the duration of the call.
unsafe { OutputDebugStringA(c.as_ptr().cast()) };
}
use std::io::Write;
if let Some(m) = file_appender()
&& let Ok(mut f) = m.lock()
{
let _ = writeln!(f, "{s}");
}
}
macro_rules! dbglog { ($($a:tt)*) => { log(&format!($($a)*)) } }
#[unsafe(export_name = "DriverEntry")]
pub unsafe extern "system" fn driver_entry(
driver: PDRIVER_OBJECT,
registry_path: PCUNICODE_STRING,
) -> NTSTATUS {
log("[pf-mouse] DriverEntry");
// SAFETY: zeroed WDF_DRIVER_CONFIG is a valid all-null config; we then set Size + the callback.
let mut config: WDF_DRIVER_CONFIG = unsafe { core::mem::zeroed() };
config.Size = core::mem::size_of::<WDF_DRIVER_CONFIG>() as ULONG;
config.EvtDriverDeviceAdd = Some(evt_device_add);
// SAFETY: all pointers valid; driver/registry_path provided by the loader.
unsafe {
call_unsafe_wdf_function_binding!(
WdfDriverCreate,
driver,
registry_path,
WDF_NO_OBJECT_ATTRIBUTES,
&mut config,
WDF_NO_HANDLE.cast::<WDFDRIVER>()
)
}
}
extern "C" fn evt_device_add(_driver: WDFDRIVER, mut device_init: PWDFDEVICE_INIT) -> NTSTATUS {
log("[pf-mouse] EvtDeviceAdd");
// Mark as a filter (HID minidriver sits below mshidumdf.sys).
// SAFETY: device_init is provided by the framework and non-null.
unsafe { call_unsafe_wdf_function_binding!(WdfFdoInitSetFilter, device_init) };
let mut device: WDFDEVICE = core::ptr::null_mut();
// SAFETY: device_init valid; attributes allowed null; device receives the handle.
let st = unsafe {
call_unsafe_wdf_function_binding!(
WdfDeviceCreate,
&mut device_init,
WDF_NO_OBJECT_ATTRIBUTES,
&mut device
)
};
if !nt_success(st) {
dbglog!("[pf-mouse] WdfDeviceCreate failed 0x{:08x}", st as u32);
return st;
}
// SAFETY: `device` is the live device just created — the exact contract this fn requires.
let shm_idx = unsafe { wdf::query_location_index(device) };
CHANNEL.set_index(shm_idx);
dbglog!("[pf-mouse] shm index = {shm_idx}");
// Default parallel queue handling all IOCTLs.
// SAFETY: zeroed config then fields set; Size matches the struct.
let mut qcfg: WDF_IO_QUEUE_CONFIG = unsafe { core::mem::zeroed() };
qcfg.Size = core::mem::size_of::<WDF_IO_QUEUE_CONFIG>() as ULONG;
qcfg.DispatchType = WdfIoQueueDispatchParallel;
qcfg.PowerManaged = WdfUseDefault;
qcfg.DefaultQueue = 1;
qcfg.EvtIoDeviceControl = Some(evt_io_device_control);
// WDF_IO_QUEUE_CONFIG_INIT sets this to (ULONG)-1 (unlimited); mem::zeroed left it 0,
// which on a parallel queue means present ZERO requests → EvtIoDeviceControl never fires.
qcfg.Settings.Parallel.NumberOfPresentedRequests = u32::MAX;
let mut default_queue: WDFQUEUE = core::ptr::null_mut();
// SAFETY: device + config valid; attributes null; queue receives the handle.
let st = unsafe {
call_unsafe_wdf_function_binding!(
WdfIoQueueCreate,
device,
&mut qcfg,
WDF_NO_OBJECT_ATTRIBUTES,
&mut default_queue
)
};
if !nt_success(st) {
dbglog!(
"[pf-mouse] default WdfIoQueueCreate failed 0x{:08x}",
st as u32
);
return st;
}
// Manual queue: pended READ_REPORT requests are completed by the timer on fresh host input.
// SAFETY: zeroed config then fields set.
let mut mcfg: WDF_IO_QUEUE_CONFIG = unsafe { core::mem::zeroed() };
mcfg.Size = core::mem::size_of::<WDF_IO_QUEUE_CONFIG>() as ULONG;
mcfg.DispatchType = WdfIoQueueDispatchManual;
mcfg.PowerManaged = WdfUseDefault;
let mut manual_queue: WDFQUEUE = core::ptr::null_mut();
// SAFETY: device + config valid; attributes null; queue receives the handle.
let st = unsafe {
call_unsafe_wdf_function_binding!(
WdfIoQueueCreate,
device,
&mut mcfg,
WDF_NO_OBJECT_ATTRIBUTES,
&mut manual_queue
)
};
if !nt_success(st) {
dbglog!(
"[pf-mouse] manual WdfIoQueueCreate failed 0x{:08x}",
st as u32
);
return st;
}
MANUAL_QUEUE.store(manual_queue, Ordering::SeqCst);
// Periodic timer (parent = manual queue): sealed-channel pump + health marks + event-driven
// READ_REPORT completion. 8 ms — the proven pf-dualsense cadence; the mouse is presence-first
// (SendInput injects), so a 125 Hz ceiling on the validation/report path is fine.
// SAFETY: zeroed config then fields set.
let mut tcfg: WDF_TIMER_CONFIG = unsafe { core::mem::zeroed() };
tcfg.Size = core::mem::size_of::<WDF_TIMER_CONFIG>() as ULONG;
tcfg.EvtTimerFunc = Some(evt_timer);
tcfg.Period = 8; // ms
tcfg.AutomaticSerialization = 1; // TRUE — UMDF requires a serialized timer (vhidmini2 pattern)
// SAFETY: a zeroed WDF_OBJECT_ATTRIBUTES is a valid all-null attributes struct; we set Size + the
// fields we use below.
let mut tattr: WDF_OBJECT_ATTRIBUTES = unsafe { core::mem::zeroed() };
tattr.Size = core::mem::size_of::<WDF_OBJECT_ATTRIBUTES>() as ULONG;
tattr.ParentObject = manual_queue.cast();
// mem::zeroed leaves these at 0 (Invalid) → set them like WDF_OBJECT_ATTRIBUTES_INIT
// (matches the working vhidmini2 UMDF timer setup; avoids 0xc0200209 / 0xc00000bb).
tattr.ExecutionLevel = WdfExecutionLevelInheritFromParent;
tattr.SynchronizationScope = WdfSynchronizationScopeInheritFromParent;
let mut timer: WDFTIMER = core::ptr::null_mut();
// SAFETY: config + attributes valid; timer receives the handle.
let st = unsafe {
call_unsafe_wdf_function_binding!(WdfTimerCreate, &mut tcfg, &mut tattr, &mut timer)
};
if !nt_success(st) {
dbglog!("[pf-mouse] WdfTimerCreate failed 0x{:08x}", st as u32);
return st;
}
// SAFETY: timer valid; -80000 == 8ms relative due time (100ns units, negative = relative).
let _started = unsafe { call_unsafe_wdf_function_binding!(WdfTimerStart, timer, -80000i64) };
log("[pf-mouse] device ready (HID mouse 5046:4D4F)");
STATUS_SUCCESS
}
extern "C" fn evt_io_device_control(
_queue: WDFQUEUE,
request: WDFREQUEST,
_output_len: usize,
_input_len: usize,
ioctl: ULONG,
) {
// SAFETY: `request` is the live request for THIS EvtIoDeviceControl invocation — exactly the
// contract `Request::new` requires. Everything after is safe (the token owns completion).
let request = unsafe { Request::new(request) };
// Skip the READ_REPORT cadence so the log stays readable; the descriptor handshake still logs.
if ioctl != IOCTL_HID_READ_REPORT {
dbglog!("[pf-mouse] ioctl 0x{ioctl:08x} out={_output_len} in={_input_len}");
}
// READ_REPORT forwards to the manual queue (the timer completes it on fresh input) — this
// CONSUMES the request token, so it's handled apart from the status-and-complete paths below.
if ioctl == IOCTL_HID_READ_REPORT {
let mq: WDFQUEUE = MANUAL_QUEUE.load(Ordering::SeqCst);
// SAFETY: `mq` is the manual queue created in EvtDeviceAdd (a live WDFQUEUE of this device).
match unsafe { request.forward_to_queue(mq) } {
Ok(()) => {} // framework owns it now (completed by the timer)
Err((req, st)) => req.complete(st), // forward failed → complete with the error
}
return;
}
let status: NTSTATUS = match ioctl {
IOCTL_HID_GET_DEVICE_DESCRIPTOR => request.copy_to_output(&HID_DESC),
IOCTL_HID_GET_DEVICE_ATTRIBUTES => request.copy_to_output(&hid_attrs()),
IOCTL_HID_GET_REPORT_DESCRIPTOR => request.copy_to_output(&MOUSE_RDESC),
IOCTL_UMDF_HID_GET_INPUT_REPORT => {
let report = INPUT_REPORT.lock().map(|g| *g).unwrap_or(NEUTRAL_REPORT);
request.copy_to_output(&report)
}
// No output reports are declared; ack a stray write instead of failing the sender.
IOCTL_HID_WRITE_REPORT | IOCTL_UMDF_HID_SET_OUTPUT_REPORT => STATUS_SUCCESS,
IOCTL_HID_GET_STRING => on_get_string(&request),
_ => STATUS_NOT_IMPLEMENTED,
};
dbglog!("[pf-mouse] ioctl 0x{ioctl:08x} -> 0x{:08x}", status as u32);
request.complete(status);
}
// IOCTL_HID_GET_STRING: the input is a ULONG whose low word is the string id and whose high word
// is the language id. Windows polls ids 0x0E/0x0F/0x10 (manufacturer/product/serial) as well as
// the 0/1/2 HID_STRING_ID_* constants — serve both (the pf-dualsense finding).
fn on_get_string(request: &Request) -> NTSTATUS {
let (bytes, _) = match request.input_bytes(4) {
Ok(v) => v,
Err(st) => return st,
};
let id_val: u32 = if bytes.len() >= 4 {
u32::from_le_bytes([bytes[0], bytes[1], bytes[2], bytes[3]])
} else {
0
};
let string_id = id_val & 0xFFFF;
let s: &str = match string_id {
0 | 0x000E => "punktfunk",
2 | 0x0010 => "PFMOUSE00",
_ => "punktfunk Virtual Mouse",
};
let mut wide: Vec<u8> = Vec::with_capacity(s.len() * 2 + 2);
for u in s.encode_utf16() {
wide.extend_from_slice(&u.to_le_bytes());
}
wide.extend_from_slice(&[0, 0]); // NUL terminator (UTF-16)
request.copy_to_output(&wide)
}
extern "C" fn evt_timer(timer: WDFTIMER) {
// One sealed-channel tick: publish our pid / adopt a delivery / detect host-gone (all safe,
// via pf_umdf_util), then stamp the health marks the host watches.
let Some(view) = CHANNEL.pump(&channel_cfg()) else {
return; // host gone or not attached — nothing to deliver, nothing to mark
};
view.write_u32(OFF_DRIVER_PROTO, GAMEPAD_PROTO_VERSION);
let hb = view.read_u32(OFF_DRIVER_HEARTBEAT).wrapping_add(1);
view.write_u32(OFF_DRIVER_HEARTBEAT, hb);
// Event-driven delivery: only when the host published a NEW report (in_seq advanced) does a
// pended READ_REPORT complete. Acquire pairs with the host's Release bump, so the report bytes
// read below are the ones that seq published. If no read is pended right now, DELIVERED_SEQ is
// NOT advanced — the next tick retries while hidclass re-pends its reader.
let seq = view.load_u32(OFF_IN_SEQ, Ordering::Acquire);
if seq == 0 || seq == DELIVERED_SEQ.load(Ordering::Relaxed) {
return;
}
// SAFETY-free queue access: the timer's parent object is the manual queue (set in
// EvtDeviceAdd); the framework guarantees a live handle here.
// SAFETY: see above — WdfTimerGetParentObject on the framework-provided live timer.
let queue =
unsafe { call_unsafe_wdf_function_binding!(WdfTimerGetParentObject, timer) } as WDFQUEUE;
// SAFETY: `queue` is that live manual queue — the exact contract `retrieve_next_request` needs.
let Some(request) = (unsafe { wdf::retrieve_next_request(queue) }) else {
return; // no reader pended — retry next tick (seq stays undelivered)
};
let mut report = [0u8; MOUSE_REPORT_LEN];
view.read_bytes(OFF_REPORT, &mut report);
DELIVERED_SEQ.store(seq, Ordering::Relaxed);
if report[0] == MOUSE_REPORT_ID {
if let Ok(mut g) = INPUT_REPORT.lock() {
*g = report;
}
let st = request.copy_to_output(&report);
request.complete(st);
} else {
// A malformed publish (host bug / torn first write): don't feed hidclass garbage — repend
// by completing nothing this tick. The request was already retrieved, so complete it with
// the last good report instead of dropping it on the floor.
let report = INPUT_REPORT.lock().map(|g| *g).unwrap_or(NEUTRAL_REPORT);
let st = request.copy_to_output(&report);
request.complete(st);
}
}