feat(host): capture-stall watch — DWM-level self-diagnosis for the Exclusive-topology stutter
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Field repro (Mounjay, still present on 0.9.0): the ~4 s double-jolt stutter appears ONLY while the virtual display is the sole active display (Exclusive topology) and stops the instant Windows switches to Extend — live, both ways. Cross-project research (Apollo #179/#358/#368/#563/#776, VDD #36, Tom's HW) points at the display/present path BELOW capture: an inactive-but-connected DisplayPort head being periodically serviced (standby HPD/AUX/link events), with a DWM software-vsync clock beat as the secondary (different-signature) class. Neither ends in anything our recovery-side detector can see unless the client actually loses data — so give the HOST a direct sensor at the ring: - StallWatch (idd_push.rs): a >150 ms hole in DWM frame delivery counts as a capture stall only when the 8 preceding frames arrived within 400 ms — sustained >=20 fps flow, so an idle desktop, a caret blink, or a paused video can never trip it. Per-stall debug line; when stalls settle into an evenly-spaced multi-second cycle, one rate-limited WARN names the class: 'capture stalls are METRONOMIC', with the topology=primary/extend and refresh-rate leads. Ring-recreate recovery gaps reset the watch (self- inflicted, already logged by the recreate path). - The evenly-spaced-cycle detector moves out of punktfunk1.rs into metronome.rs (RecoveryCadence -> Metronome, unchanged logic + tests) so the IDR-serve detector and the stall watch share one implementation; the recovery WARN now cross-references the capture-stall lines. Diagnosis map for an Exclusive-mode stutter log: 'slow display-descriptor poll' = something holds the win32k display lock; 'capture stalls are METRONOMIC' without it = DWM stopped composing (DP servicing / present clock, below us); recovery-IDR METRONOMIC alone = frames flowed but clients lost data. Verified: Linux tests+clippy+fmt clean; Windows (RTX box) 220/220 + clippy clean. Co-Authored-By: Claude Fable 5 <noreply@anthropic.com>
This commit is contained in:
@@ -565,6 +565,81 @@ impl Drop for DescriptorPoller {
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}
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}
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/// A detected capture stall: a multi-hundred-ms hole in DWM's frame delivery that opened while the
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/// desktop was actively composing right beforehand (see [`StallWatch`]).
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struct Stall {
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/// How long the hole lasted (last fresh frame → the frame that ended it).
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gap: Duration,
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/// `Some(mean period)` when this stall completes a metronomic cycle (see
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/// [`crate::metronome::Metronome`]).
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metronomic: Option<Duration>,
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}
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/// Capture-stall watch — the "sole virtual display" stutter diagnostic (field reports: Exclusive
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/// topology = periodic double-jolt, Extend = smooth, i.e. the disturbance lives in the display/present
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/// path BELOW capture and only while no physical output is active).
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///
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/// On a damage-driven capture an idle desktop legitimately goes quiet (no damage → no frames), so a
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/// gap only counts as a stall when the [`Self::RECENT`] frames before it all arrived within
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/// [`Self::ACTIVE_SPAN`] — sustained ≥ ~20 fps flow (a game or video), not a blinking caret or a
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/// mouse twitch. Each stall feeds a [`crate::metronome::Metronome`], so periodic stalls self-diagnose
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/// in the log WITHOUT needing any client keyframe request — discriminating "DWM stopped composing"
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/// from encode/network causes that the recovery-cadence detector covers. Pure logic — unit-tested
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/// below; the caller does the logging.
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struct StallWatch {
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/// The last [`Self::RECENT`] fresh-frame instants (pre-gap history for the activity gate).
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recent: std::collections::VecDeque<Instant>,
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cadence: crate::metronome::Metronome,
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}
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impl StallWatch {
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/// Frames of pre-gap history that must be tight for flow to count as active. Stalls are thus
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/// naturally spaced ≥ RECENT frame times apart — no extra log rate limit needed.
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const RECENT: usize = 8;
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/// The RECENT pre-gap frames must all fit in this span (8 frames in 400 ms ≈ ≥ 20 fps flow —
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/// loose enough for a 30 fps-capped game, tight enough to reject idle-desktop damage).
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const ACTIVE_SPAN: Duration = Duration::from_millis(400);
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/// The smallest hole that counts as a stall (~9 missed frames at 60 Hz) — well below the
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/// reported 300–700 ms freezes, above encode/present jitter.
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const STALL_MIN: Duration = Duration::from_millis(150);
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fn new() -> Self {
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Self {
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recent: std::collections::VecDeque::with_capacity(Self::RECENT + 1),
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cadence: crate::metronome::Metronome::new(),
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}
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}
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/// Forget the flow history (a ring recreate's gap is self-inflicted, not a DWM stall — without
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/// the reset the first post-recreate frame would read as one).
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fn reset(&mut self) {
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self.recent.clear();
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}
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/// Record a fresh driver frame at `now`; `Some` exactly when it ended a stall.
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fn note_fresh(&mut self, now: Instant) -> Option<Stall> {
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let was_active = self.recent.len() == Self::RECENT
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&& self
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.recent
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.back()
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.zip(self.recent.front())
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.is_some_and(|(b, f)| b.duration_since(*f) <= Self::ACTIVE_SPAN);
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let gap = self.recent.back().map(|last| now.duration_since(*last));
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self.recent.push_back(now);
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if self.recent.len() > Self::RECENT {
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self.recent.pop_front();
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}
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let gap = gap?;
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if !was_active || gap < Self::STALL_MIN {
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return None;
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}
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Some(Stall {
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gap,
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metronomic: self.cadence.note(now),
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})
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}
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}
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pub struct IddPushCapturer {
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device: ID3D11Device,
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context: ID3D11DeviceContext,
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@@ -615,6 +690,10 @@ pub struct IddPushCapturer {
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last_liveness: Instant,
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/// Rate-limits the mid-session [`kick_dwm_compose`] nudge (recovery window only).
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last_kick: Instant,
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/// Capture-stall watch (see [`StallWatch`]): flags multi-hundred-ms DWM composition holes
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/// during active flow and warns when they turn metronomic — the sole-virtual-display
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/// periodic-stutter diagnostic.
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stall_watch: StallWatch,
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/// Host-owned ROTATING output ring NVENC encodes (one YUV texture per slot). Rotating it per frame
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/// is the precondition for pipelining the encode loop: while NVENC encodes frame N's texture on the
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/// ASIC, frame N+1's convert writes a DIFFERENT texture — the two overlap. Format = `out_format()`:
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@@ -995,6 +1074,7 @@ impl IddPushCapturer {
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last_fresh: Instant::now(),
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last_liveness: Instant::now(),
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last_kick: Instant::now(),
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stall_watch: StallWatch::new(),
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out_ring: Vec::new(),
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out_idx: 0,
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video_conv: None,
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@@ -1441,8 +1521,34 @@ impl IddPushCapturer {
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self.out_idx = (i + 1) % self.out_ring.len();
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self.last_seq = seq;
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self.last_present = Some((out.clone(), pf));
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self.recovering_since = None; // a fresh frame resumed → recovered
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self.last_fresh = Instant::now(); // feeds the driver-death watch
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let now = Instant::now();
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if self.recovering_since.take().is_some() {
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// A fresh frame resumed → recovered. The recovery gap is self-inflicted (ring
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// recreate, already logged by the recreate path) — reset the stall watch so it
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// doesn't read as a DWM stall.
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self.stall_watch.reset();
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} else if let Some(stall) = self.stall_watch.note_fresh(now) {
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// debug (not warn): a single hole also happens when content legitimately pauses;
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// the reportable signal is the metronomic cycle below. Mounjay-class triage runs
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// at debug level, and the web-console debug ring captures these.
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tracing::debug!(
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gap_ms = stall.gap.as_millis() as u64,
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"IDD-push capture stall — the desktop was composing at speed, then DWM \
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delivered no frame for the gap; the present path stalled below capture"
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);
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if let Some(period) = stall.metronomic {
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tracing::warn!(
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period_s = format!("{:.2}", period.as_secs_f64()),
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"capture stalls are METRONOMIC — DWM stops composing the virtual display \
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on a stable period, i.e. a periodic display-path disturbance BELOW \
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capture (DWM present clock / GPU driver / display-poller software). \
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Correlate with 'slow display-descriptor poll'; if that never fires, the \
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disturbance is outside punktfunk — try display topology=primary or \
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extend (keep a physical output active), or a different refresh rate"
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);
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}
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}
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self.last_fresh = now; // feeds the driver-death watch
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Ok(Some(CapturedFrame {
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width: self.width,
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height: self.height,
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@@ -1576,3 +1682,99 @@ impl Drop for IddPushCapturer {
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// `design/idd-push-security.md`). _keepalive drops after, REMOVEing the virtual display.
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}
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}
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#[cfg(test)]
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mod tests {
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use super::*;
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/// Feed a [`StallWatch`] fresh frames at the given offsets (ms from a common origin) and
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/// return what each `note_fresh` produced.
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fn watch_run(offsets_ms: &[u64]) -> Vec<Option<Stall>> {
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let base = Instant::now();
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let mut w = StallWatch::new();
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offsets_ms
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.iter()
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.map(|ms| w.note_fresh(base + Duration::from_millis(*ms)))
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.collect()
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}
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/// 60 fps flow (16 ms cadence) for `frames` frames starting at `start_ms`, appended to `out`.
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fn flow(out: &mut Vec<u64>, start_ms: u64, frames: u64) {
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out.extend((0..frames).map(|i| start_ms + i * 16));
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}
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#[test]
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fn stall_detected_after_active_flow() {
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// 20 frames of 60 fps flow, then a 300 ms hole — the resuming frame reads as a stall.
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let mut t = Vec::new();
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flow(&mut t, 0, 20); // last frame at 304 ms
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t.push(604);
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let out = watch_run(&t);
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assert!(out[..20].iter().all(Option::is_none));
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let stall = out[20].as_ref().expect("hole after active flow is a stall");
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assert_eq!(stall.gap.as_millis(), 300);
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assert!(stall.metronomic.is_none(), "one stall is not a cycle");
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}
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#[test]
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fn idle_desktop_gaps_are_not_stalls() {
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// Caret-blink damage: frames ~530 ms apart — the activity gate never opens, so neither
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// the blink gaps nor a long idle hole count.
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let t: Vec<u64> = (0..12).map(|i| i * 530).chain([20_000]).collect();
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assert!(watch_run(&t).iter().all(Option::is_none));
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}
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#[test]
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fn thirty_fps_content_still_qualifies_as_active() {
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// A 30 fps-capped game (33 ms cadence): 8 pre-gap frames span 231 ms ≤ ACTIVE_SPAN, so a
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// 200 ms hole still reads as a stall.
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let mut t: Vec<u64> = (0..10).map(|i| i * 33).collect(); // last at 297 ms
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t.push(497);
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let out = watch_run(&t);
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assert!(out[10].is_some(), "30 fps flow must pass the activity gate");
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}
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#[test]
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fn metronomic_stalls_self_diagnose() {
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// The field signature: ~300 ms DWM holes every 4 s inside 60 fps flow. Stalls land at the
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// cycle BOUNDARIES (5 cycles → 4 stalls); the 4th completes the metronome streak and
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// reports the ~4 s period.
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let mut t = Vec::new();
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for cycle in 0..5u64 {
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// ~3.7 s of flow, then the hole to the next cycle start.
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flow(&mut t, cycle * 4_000, 232); // last frame at cycle*4000 + 3696
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}
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let out = watch_run(&t);
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let stalls: Vec<&Stall> = out.iter().flatten().collect();
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assert_eq!(stalls.len(), 4, "each cycle boundary is one stall");
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assert!(stalls[..3].iter().all(|s| s.metronomic.is_none()));
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let period = stalls[3]
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.metronomic
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.expect("the 4th evenly-spaced event completes the metronome streak");
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assert!(
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(period.as_secs_f64() - 4.0).abs() < 0.3,
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"period={period:?}"
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);
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}
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#[test]
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fn reset_swallows_the_recreate_gap() {
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// Active flow, then a ring recreate (reset), then flow resumes 800 ms later — the resume
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// frame must NOT read as a stall, and detection re-arms afterwards.
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let base = Instant::now();
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let at = |ms: u64| base + Duration::from_millis(ms);
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let mut w = StallWatch::new();
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for i in 0..20u64 {
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assert!(w.note_fresh(at(i * 16)).is_none());
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}
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w.reset();
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assert!(w.note_fresh(at(1_104)).is_none(), "recreate gap swallowed");
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for i in 1..20u64 {
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assert!(w.note_fresh(at(1_104 + i * 16)).is_none());
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}
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assert!(
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w.note_fresh(at(1_104 + 19 * 16 + 300)).is_some(),
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"detection re-armed after the reset"
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);
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}
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}
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@@ -50,6 +50,7 @@ mod install;
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mod interactive;
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mod library;
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mod log_capture;
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mod metronome;
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mod mgmt;
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mod mgmt_token;
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mod native_pairing;
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@@ -213,9 +214,9 @@ fn real_main() -> Result<()> {
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// Zero-copy FFI/GPU probe: init the EGL importer + CUDA context (no capture needed).
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#[cfg(target_os = "linux")]
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Some("zerocopy-probe") => zerocopy::probe(),
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// Hidden: the isolated GPU-import worker the capture path spawns from /proc/self/exe
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// (design/zerocopy-worker-isolation.md) — never run by hand; --fd names the inherited
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// socketpair end.
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// Hidden: the isolated GPU-import worker the capture path spawns from a pinned fd to its
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// own executable image (design/zerocopy-worker-isolation.md) — never run by hand; --fd
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// names the inherited socketpair end.
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#[cfg(target_os = "linux")]
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Some("zerocopy-worker") => zerocopy::worker::run_from_args(&args[1..]),
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// NV12 colour self-test (no display/capture needed): convert a known RGBA pattern to NV12
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@@ -0,0 +1,151 @@
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//! Detector for METRONOMIC event cycles — evenly-spaced disturbances repeating every few seconds.
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//!
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//! The "periodic double-jolt" symptom class field reports keep describing is a host/display-side
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//! disturbance on a stable multi-second period (display-topology churn, display-poller software,
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//! virtual-display present timing). Random network loss is bursty and irregular; a stable period is
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//! a machine, and saying so in the host log turns a "nothing in the logs :/" report into a
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//! self-diagnosis. Two feeds today: served client-recovery IDRs (`punktfunk1`) and IDD-push capture
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//! stalls (`capture::windows::idd_push`).
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use std::collections::VecDeque;
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use std::time::{Duration, Instant};
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/// Pure evenly-spaced-events detector (unit-tested below).
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///
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/// Events within [`Self::COALESCE`] count as ONE (a double-jolt's paired disturbances — e.g. the
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/// cooldown re-issue of a lost keyframe ~0.7 s after the first — are one user-visible cycle). When
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/// the gaps between the last [`Self::STREAK`] events are all within ±[`Self::TOLERANCE`] of their
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/// mean, [`Self::note`] returns the mean period for the caller to warn with, then stays quiet for
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/// [`Self::REWARN`] while the cycle persists.
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pub(crate) struct Metronome {
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events: VecDeque<Instant>,
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last_warn: Option<Instant>,
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}
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impl Metronome {
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/// Events closer together than this are the same user-visible disturbance.
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const COALESCE: Duration = Duration::from_millis(1500);
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/// Consecutive evenly-spaced events before the cycle counts as metronomic.
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const STREAK: usize = 4;
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/// "Evenly spaced" = every gap within this fraction of the mean gap.
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const TOLERANCE: f64 = 0.2;
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/// Once warned, re-warn at most this often while the cycle persists.
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const REWARN: Duration = Duration::from_secs(30);
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pub(crate) fn new() -> Self {
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Self {
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events: VecDeque::new(),
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last_warn: None,
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}
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}
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/// Record a disturbance at `now`; `Some(mean period)` exactly when the metronomic-cycle
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/// warning should fire.
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pub(crate) fn note(&mut self, now: Instant) -> Option<Duration> {
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if self
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.events
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.back()
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.is_some_and(|last| now.duration_since(*last) < Self::COALESCE)
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{
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return None;
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}
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self.events.push_back(now);
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if self.events.len() > Self::STREAK {
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self.events.pop_front();
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}
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if self.events.len() < Self::STREAK {
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return None;
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}
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let gaps: Vec<f64> = self
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.events
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.iter()
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.zip(self.events.iter().skip(1))
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.map(|(a, b)| b.duration_since(*a).as_secs_f64())
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.collect();
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let mean = gaps.iter().sum::<f64>() / gaps.len() as f64;
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if mean <= 0.0
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|| gaps
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.iter()
|
||||
.any(|g| (g - mean).abs() > mean * Self::TOLERANCE)
|
||||
{
|
||||
return None;
|
||||
}
|
||||
if self
|
||||
.last_warn
|
||||
.is_some_and(|t| now.duration_since(t) < Self::REWARN)
|
||||
{
|
||||
return None;
|
||||
}
|
||||
self.last_warn = Some(now);
|
||||
Some(Duration::from_secs_f64(mean))
|
||||
}
|
||||
}
|
||||
|
||||
#[cfg(test)]
|
||||
mod tests {
|
||||
use super::*;
|
||||
|
||||
/// Feed a [`Metronome`] a schedule of event offsets (ms from a common origin) and return
|
||||
/// what each `note` produced.
|
||||
fn cadence_run(offsets_ms: &[u64]) -> Vec<Option<Duration>> {
|
||||
let base = Instant::now();
|
||||
let mut c = Metronome::new();
|
||||
offsets_ms
|
||||
.iter()
|
||||
.map(|ms| c.note(base + Duration::from_millis(*ms)))
|
||||
.collect()
|
||||
}
|
||||
|
||||
#[test]
|
||||
fn cadence_detects_metronomic_events() {
|
||||
// Four events ~4 s apart (±5%) → the fourth trips the detector at ~4 s.
|
||||
let out = cadence_run(&[0, 4_000, 8_100, 11_950]);
|
||||
assert_eq!(out[..3], [None, None, None]);
|
||||
let period = out[3].expect("metronomic series must be detected");
|
||||
assert!(
|
||||
(period.as_secs_f64() - 3.98).abs() < 0.2,
|
||||
"period={period:?}"
|
||||
);
|
||||
}
|
||||
|
||||
#[test]
|
||||
fn cadence_coalesces_double_jolt_pairs() {
|
||||
// The field signature: a jolt pair (second event ~0.7 s after the first, e.g. the IDR
|
||||
// cooldown re-issue) every ~4 s. Each pair is ONE event; detection still lands on the
|
||||
// ~4 s cycle.
|
||||
let out = cadence_run(&[
|
||||
0, 700, // pair 1
|
||||
4_000, 4_700, // pair 2
|
||||
8_000, 8_650, // pair 3
|
||||
12_000, // pair 4 (first event trips it)
|
||||
]);
|
||||
assert!(out[..6].iter().all(Option::is_none));
|
||||
let period = out[6].expect("coalesced pairs must still read as a 4 s cycle");
|
||||
assert!(
|
||||
(period.as_secs_f64() - 4.0).abs() < 0.2,
|
||||
"period={period:?}"
|
||||
);
|
||||
}
|
||||
|
||||
#[test]
|
||||
fn cadence_ignores_irregular_bursts() {
|
||||
// Genuine Wi-Fi-style loss: irregular gaps → never flagged.
|
||||
assert!(cadence_run(&[0, 2_000, 9_000, 12_500, 21_000])
|
||||
.iter()
|
||||
.all(Option::is_none));
|
||||
}
|
||||
|
||||
#[test]
|
||||
fn cadence_rewarns_at_most_every_30s() {
|
||||
// A persisting 4 s cycle: warn on the 4th event (t=12 s), then stay quiet until ≥30 s
|
||||
// past the warn — the t=44 s event (index 11) is the first at or beyond t=42 s.
|
||||
let offsets: Vec<u64> = (0..12).map(|i| i * 4_000).collect();
|
||||
let out = cadence_run(&offsets);
|
||||
let warned: Vec<usize> = out
|
||||
.iter()
|
||||
.enumerate()
|
||||
.filter_map(|(i, o)| o.map(|_| i))
|
||||
.collect();
|
||||
assert_eq!(warned, vec![3, 11], "warn indices");
|
||||
}
|
||||
}
|
||||
@@ -3230,82 +3230,6 @@ struct SessionContext {
|
||||
launch: Option<String>,
|
||||
}
|
||||
|
||||
/// Detector for METRONOMIC client keyframe-recovery cycles — the "periodic double-jolt" symptom
|
||||
/// class field reports keep describing: a host/display-side disturbance repeating every few
|
||||
/// seconds (display-topology churn, display-poller software, virtual-display timing), where each
|
||||
/// cycle ends in a client keyframe request the host serves. Random network loss is bursty and
|
||||
/// irregular; a stable period is a machine, and saying so in the host log turns a "nothing in the
|
||||
/// logs :/" report into a self-diagnosis.
|
||||
///
|
||||
/// Served forced IDRs within [`Self::COALESCE`] count as ONE event (a double-jolt's paired IDRs —
|
||||
/// the cooldown re-issue of a lost keyframe — are one user-visible disturbance). When the gaps
|
||||
/// between the last [`Self::STREAK`] events are all within ±[`Self::TOLERANCE`] of their mean,
|
||||
/// [`Self::note`] returns the mean period for the caller to warn with, then stays quiet for
|
||||
/// [`Self::REWARN`] while the cycle persists. Pure logic — unit-tested below.
|
||||
struct RecoveryCadence {
|
||||
events: std::collections::VecDeque<std::time::Instant>,
|
||||
last_warn: Option<std::time::Instant>,
|
||||
}
|
||||
|
||||
impl RecoveryCadence {
|
||||
/// Serves closer together than this are the same user-visible disturbance.
|
||||
const COALESCE: std::time::Duration = std::time::Duration::from_millis(1500);
|
||||
/// Consecutive evenly-spaced events before the cycle counts as metronomic.
|
||||
const STREAK: usize = 4;
|
||||
/// "Evenly spaced" = every gap within this fraction of the mean gap.
|
||||
const TOLERANCE: f64 = 0.2;
|
||||
/// Once warned, re-warn at most this often while the cycle persists.
|
||||
const REWARN: std::time::Duration = std::time::Duration::from_secs(30);
|
||||
|
||||
fn new() -> Self {
|
||||
Self {
|
||||
events: std::collections::VecDeque::new(),
|
||||
last_warn: None,
|
||||
}
|
||||
}
|
||||
|
||||
/// Record a served client-recovery IDR at `now`; `Some(mean period)` exactly when the
|
||||
/// metronomic-cycle warning should fire.
|
||||
fn note(&mut self, now: std::time::Instant) -> Option<std::time::Duration> {
|
||||
if self
|
||||
.events
|
||||
.back()
|
||||
.is_some_and(|last| now.duration_since(*last) < Self::COALESCE)
|
||||
{
|
||||
return None;
|
||||
}
|
||||
self.events.push_back(now);
|
||||
if self.events.len() > Self::STREAK {
|
||||
self.events.pop_front();
|
||||
}
|
||||
if self.events.len() < Self::STREAK {
|
||||
return None;
|
||||
}
|
||||
let gaps: Vec<f64> = self
|
||||
.events
|
||||
.iter()
|
||||
.zip(self.events.iter().skip(1))
|
||||
.map(|(a, b)| b.duration_since(*a).as_secs_f64())
|
||||
.collect();
|
||||
let mean = gaps.iter().sum::<f64>() / gaps.len() as f64;
|
||||
if mean <= 0.0
|
||||
|| gaps
|
||||
.iter()
|
||||
.any(|g| (g - mean).abs() > mean * Self::TOLERANCE)
|
||||
{
|
||||
return None;
|
||||
}
|
||||
if self
|
||||
.last_warn
|
||||
.is_some_and(|t| now.duration_since(t) < Self::REWARN)
|
||||
{
|
||||
return None;
|
||||
}
|
||||
self.last_warn = Some(now);
|
||||
Some(std::time::Duration::from_secs_f64(mean))
|
||||
}
|
||||
}
|
||||
|
||||
fn virtual_stream(ctx: SessionContext) -> Result<()> {
|
||||
// This thread runs the capture+encode loop (single-process — the only topology: Linux portal /
|
||||
// synthetic, Windows in-process IDD-push). Elevate it so a CPU-heavy game can't deschedule our GPU
|
||||
@@ -3521,8 +3445,8 @@ fn virtual_stream(ctx: SessionContext) -> Result<()> {
|
||||
// opening GOP, instead of answering it with a redundant second IDR.
|
||||
let mut last_forced_idr: Option<std::time::Instant> = Some(std::time::Instant::now());
|
||||
// Self-diagnosis for the periodic-stutter class: warns when the served recovery IDRs settle
|
||||
// into a stable multi-second rhythm (see [`RecoveryCadence`]).
|
||||
let mut recovery_cadence = RecoveryCadence::new();
|
||||
// into a stable multi-second rhythm (see [`crate::metronome::Metronome`]).
|
||||
let mut recovery_cadence = crate::metronome::Metronome::new();
|
||||
// Per-stage latency breakdown (PUNKTFUNK_PERF): per-call µs for the GPU-bound stages so we see
|
||||
// exactly where the capture→encoded latency goes — cap=try_latest (ring read + colour convert),
|
||||
// submit=encode_picture launch, wait=lock_bitstream (the scheduling wait + ASIC encode, the one
|
||||
@@ -3733,7 +3657,7 @@ fn virtual_stream(ctx: SessionContext) -> Result<()> {
|
||||
disturbance (display-topology churn, display-poller software, \
|
||||
virtual-display timing) is the likely cause, not random network loss; \
|
||||
correlate with 'slow display-descriptor poll' / 'display descriptor \
|
||||
changed' lines"
|
||||
changed' / 'IDD-push capture stall' lines"
|
||||
);
|
||||
}
|
||||
}
|
||||
@@ -4425,69 +4349,6 @@ mod tests {
|
||||
assert_eq!(dec, snap);
|
||||
}
|
||||
|
||||
/// Feed [`RecoveryCadence`] a schedule of event offsets (ms from a common origin) and return
|
||||
/// what each `note` produced.
|
||||
fn cadence_run(offsets_ms: &[u64]) -> Vec<Option<std::time::Duration>> {
|
||||
let base = std::time::Instant::now();
|
||||
let mut c = RecoveryCadence::new();
|
||||
offsets_ms
|
||||
.iter()
|
||||
.map(|ms| c.note(base + std::time::Duration::from_millis(*ms)))
|
||||
.collect()
|
||||
}
|
||||
|
||||
#[test]
|
||||
fn cadence_detects_metronomic_recoveries() {
|
||||
// Four IDR serves ~4 s apart (±5%) → the fourth trips the detector at ~4 s.
|
||||
let out = cadence_run(&[0, 4_000, 8_100, 11_950]);
|
||||
assert_eq!(out[..3], [None, None, None]);
|
||||
let period = out[3].expect("metronomic series must be detected");
|
||||
assert!(
|
||||
(period.as_secs_f64() - 3.98).abs() < 0.2,
|
||||
"period={period:?}"
|
||||
);
|
||||
}
|
||||
|
||||
#[test]
|
||||
fn cadence_coalesces_double_jolt_pairs() {
|
||||
// The field signature: a jolt pair (second IDR ~0.7 s after the first, the cooldown
|
||||
// re-issue) every ~4 s. Each pair is ONE event; detection still lands on the ~4 s cycle.
|
||||
let out = cadence_run(&[
|
||||
0, 700, // pair 1
|
||||
4_000, 4_700, // pair 2
|
||||
8_000, 8_650, // pair 3
|
||||
12_000, // pair 4 (first serve trips it)
|
||||
]);
|
||||
assert!(out[..6].iter().all(Option::is_none));
|
||||
let period = out[6].expect("coalesced pairs must still read as a 4 s cycle");
|
||||
assert!(
|
||||
(period.as_secs_f64() - 4.0).abs() < 0.2,
|
||||
"period={period:?}"
|
||||
);
|
||||
}
|
||||
|
||||
#[test]
|
||||
fn cadence_ignores_irregular_bursts() {
|
||||
// Genuine Wi-Fi-style loss: irregular gaps → never flagged.
|
||||
assert!(cadence_run(&[0, 2_000, 9_000, 12_500, 21_000])
|
||||
.iter()
|
||||
.all(Option::is_none));
|
||||
}
|
||||
|
||||
#[test]
|
||||
fn cadence_rewarns_at_most_every_30s() {
|
||||
// A persisting 4 s cycle: warn on the 4th event (t=12 s), then stay quiet until ≥30 s
|
||||
// past the warn — the t=44 s event (index 11) is the first at or beyond t=42 s.
|
||||
let offsets: Vec<u64> = (0..12).map(|i| i * 4_000).collect();
|
||||
let out = cadence_run(&offsets);
|
||||
let warned: Vec<usize> = out
|
||||
.iter()
|
||||
.enumerate()
|
||||
.filter_map(|(i, o)| o.map(|_| i))
|
||||
.collect();
|
||||
assert_eq!(warned, vec![3, 11], "warn indices");
|
||||
}
|
||||
|
||||
#[test]
|
||||
fn adapt_fec_maps_loss_to_recovery_band() {
|
||||
// A perfectly clean window (0 loss) lands on the floor.
|
||||
|
||||
Reference in New Issue
Block a user