vkDeviceWaitIdle's external-sync rule claims EVERY queue on the device;
with Vulkan Video the session pump concurrently submits FFmpeg decode
work to the shared device's video queue, so the resize path's wait-idle
(and the video-image/staging rebuilds') raced it — observed as a crash
on window resize mid-stream (software/VAAPI never touched the device
from the pump, which is why this only appeared now).
Mid-session quiescing is now fence-only ( waits the single
in-flight fence, which covers every command buffer WE submitted), and
the replaced swapchain + its per-image semaphores/overlay targets are
parked in a retire list — the presentation engine may still hold the old
swapchain's final semaphore wait, which no fence covers — and destroyed
after the next present on the successor completes a fence cycle. The one
legitimate device-wide idle left is teardown, and the run loop now JOINS
the pump thread first (SessionHandle carries the JoinHandle; quick — the
pump notices stop within its 20 ms receive timeout).
Co-Authored-By: Claude Fable 5 <noreply@anthropic.com>
The Vulkan path's receive_frame returns at SUBMISSION (~0.1 ms) — the
hardware decodes asynchronously, so the decode stat was truthful but
measured the wrong boundary. The pump now ships the frame to the
presenter FIRST, then waits the frame's timeline fence (vkWaitSemaphores
resolved through the shared device's proc chain) and stamps
received→decode-COMPLETE — true NVDEC time at zero pipeline cost, since
the presenter's own GPU wait is what actually gates sampling. Software/
VAAPI keep their synchronous stamps.
Also: Alt+Enter joins F11 as the fullscreen toggle (some keyboards' Fn
layer sends a media key for plain F11 — observed on glass as
'F11 only works with shift'); the shell's shortcuts panel lists both.
Co-Authored-By: Claude Fable 5 <noreply@anthropic.com>
The silent settings-driven software path cost a debugging round on the
first Vulkan Video glass test (stale decoder=software from the VAAPI-
broken-on-NVIDIA era) — now it says so. Module docs updated: auto is
vulkan → vaapi → software.
Validated on glass (RTX 5070 Ti, HEVC 4K@144): decode 11 ms → 0.1 ms,
e2e p50 ~115 ms → 8.6 ms (the old number was software-decode queueing,
not clock skew), 144 fps locked, 2686 frames, zero errors.
Co-Authored-By: Claude Fable 5 <noreply@anthropic.com>
FFmpeg's Vulkan Video decoder now runs on the PRESENTER's own VkDevice —
the decoded VkImage feeds the existing CICP CSC pass directly: zero
copy, no interop, and NVIDIA gets hardware decode for the first time
(its VAAPI is unusable by design). One decode architecture for every
vendor going forward; VAAPI-dmabuf and software remain the fallbacks
(auto: vulkan → vaapi → software; PUNKTFUNK_DECODER=vulkan pins it).
Presenter: instance 1.3; probes VK_KHR_video_queue/decode_queue + codec
extensions, a VIDEO_DECODE queue family (+ its codec caps via
QueueFamilyVideoPropertiesKHR), and the samplerYcbcrConversion/
timelineSemaphore/synchronization2 features — all enabled at device
creation when present, exported as a VulkanDecodeDevice handle bundle.
Decoder: AVVulkanDeviceContext built over those handles via pf-ffvk
(features chain, extension lists, deprecated queue indices + the qf[]
map); get_format supplies OUR frames context with MUTABLE_FORMAT so the
presenter's per-plane views are legal; output is DecodedImage::VkFrame
carrying AVVkFrame/frames-ctx pointers plus the lock fns.
Present: R8+R8G8 plane views over the multiplanar image, the live sync
state read under the AVVulkanFramesContext lock, a timeline-semaphore
wait(sem_value)/signal(sem_value+1) folded into the submit, layout/
queue-family/sem_value written back per FFmpeg's contract, and the frame
guard parked in the retire queue until the fence. CSC pass + video
framebuffer are now unconditional (NVIDIA has no dmabuf-import path).
Verified on the RTX 5070 Ti: device creates with decode_qf=3,
caps=DECODE_H264|H265|AV1|VP9; swapchain unaffected. Live stream
validation next.
Co-Authored-By: Claude Fable 5 <noreply@anthropic.com>
Under infinite GOP the pump only re-requested an IDR when the
reassembler's drop count climbed. A lost initial IDR (or a mid-GOP join)
delivers complete-but-undecodable delta frames instead — the reassembler
never drops, so recovery never fired and the stream froze on the last
good frame while libavcodec flooded stderr with missing-reference
errors. Reproduced at 4K@144 (large IDRs, higher loss); lower modes hid
it. Now a 3-frame no-output streak (~50 ms) forces a fresh IDR,
throttled and re-armed across the request→IDR round trip. Verified on
glass: 4K@144 recovers and holds. Also quiets libavcodec's raw stderr
(it bypassed tracing) to fatal-only, PUNKTFUNK_FFMPEG_LOG restores it.
Co-Authored-By: Claude Opus 4.8 (1M context) <noreply@anthropic.com>
punktfunk-session streams one --connect session in an SDL3 window: ash
swapchain with a transfer-only letterboxed blit of the software-decode
path (no graphics pipeline until the phase-2 dmabuf/CSC pass), the
ui_stream input-capture state machine on SDL events (scancode→VK table
cross-checked against the evdev one), gamepads via a new caller-pumped
GamepadService mode (SDL video owns the main thread here), and the
shell↔session stdout contract: {"ready":true}, per-window stats:
lines, JSON error + exit codes 0/2/3/4. Strict trust — no pin, no
connect. Design: punktfunk-planning linux-client-rearchitecture.md.
Co-Authored-By: Claude Fable 5 <noreply@anthropic.com>
Session pump, FFmpeg decode, PipeWire audio, SDL3 gamepads, keymap, trust
store, mDNS discovery, library client and Wake-on-LAN move verbatim from
clients/linux into crates/pf-client-core, shared with the upcoming Vulkan
session binary (punktfunk-planning: linux-client-rearchitecture.md).
The GTK client re-exports them at the crate root so every existing
crate::-path keeps resolving; its manifest drops the moved-only deps.
Co-Authored-By: Claude Fable 5 <noreply@anthropic.com>