perf(latency): tier-0 attribution + tier-1 send-path levers from the latency plan
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design/latency-reduction-2026-07.md T0.1/T0.2/T1.2/T1.3:
- T1.2 rate-capped front-loaded pacing: the paced overflow's budget is now
min(0.9x slack, overflow wire time at ~3x the live encoder bitrate)
(PUNKTFUNK_PACE_FACTOR, 0 = legacy deadline-only spread). A 300 KB-1 MB
frame's tail leaves in ~2-5 ms instead of smearing across ~15 ms at 60 fps;
GameStream schedule byte-identical (pins unchanged).
- T1.3 data-first wire order: packetize emits every block's data shards before
any parity (per-block parity pools keep all blocks' parity alive for the
second pass), so lossless completion stops waiting behind the parity tail.
EOF = last emitted packet; receiver already order-agnostic.
- T0.1 staged 0xCF: HostTiming gains an append-extensible per-stage tail
(queue/encode/pace us; seal+channel-wait derived as residual) - no cap bit
needed, old peers read the 13-byte prefix. Joined client-side into
Stats::host_{queue,encode,xfer,pace}_ms, the OSD detailed tier, and the
probe's report.
- T0.2 true on-glass present timing: VK_KHR_present_id/present_wait enabled
when supported; a PresentTimer waiter thread resolves each present id to
real visibility, replacing the submit-time display stamp (which undercounts
by up to a refresh and hides a silent-FIFO standing queue).
Validated on .21: core 185 + host 185 tests, pf-presenter 19, clippy
-D warnings across all five touched crates; loss-harness recovery curve
unchanged; C ABI harness round-trips.
Co-Authored-By: Claude Fable 5 <noreply@anthropic.com>
This commit is contained in:
@@ -32,10 +32,13 @@ pub struct Packetizer {
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/// Every other data shard is a `shard_payload`-sized slice straight into the frame buffer —
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/// blocks are consecutive shard ranges, so only the frame's last shard can be partial.
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tail: Vec<u8>,
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/// Reusable parity buffers for [`ErasureCoder::encode_into`] (plan Phase 1.4): grows once
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/// to the session's high-water recovery count, then every block's parity is generated
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/// into it with zero allocations.
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recovery: Vec<Vec<u8>>,
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/// Reusable PER-BLOCK parity buffers for [`ErasureCoder::encode_into`] (plan Phase 1.4):
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/// one pool per block index, each growing once to its high-water recovery count, then
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/// every frame's parity is generated into them with zero allocations. Per-block (not one
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/// shared pool) because the data-first wire order (latency plan T1.3) emits every block's
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/// DATA shards before any block's parity — all blocks' parity must stay alive until the
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/// frame's second emission pass.
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recovery: Vec<Vec<Vec<u8>>>,
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}
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impl Packetizer {
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@@ -103,6 +106,15 @@ impl Packetizer {
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/// ([`Session::seal_frame`](crate::session::Session::seal_frame)). An `emit` error aborts
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/// the frame mid-way (packet numbering has already advanced — callers treat it as fatal).
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///
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/// Wire order is DATA-FIRST (latency plan T1.3): every block's data shards in block order,
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/// then every block's parity shards in block order. In the lossless case a frame completes
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/// the moment its last DATA shard arrives, so the completion-gating packet no longer sits
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/// behind the parity tail of the paced spread (~fec% of the spread saved). The receiver is
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/// order-agnostic (headers are self-describing; the reassembler completes each block on
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/// `data + recovery ≥ k`), so this is not a wire-format change. `FLAG_SOF` stays on the
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/// first emitted packet (block 0, shard 0); `FLAG_EOF` marks the last emitted packet —
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/// the final parity shard, or the final data shard of a FEC-free frame.
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///
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/// `frame_index`: `Some(i)` stamps the AU with the caller's index — the punktfunk/1 encode
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/// loop numbers video AUs itself so the encoder's RFI bookkeeping (LTR marks, DPB timestamps)
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/// is 1:1 with what the client sees, surviving encoder rebuilds/resets that restart internal
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@@ -152,7 +164,6 @@ impl Packetizer {
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self.tail[..rem].copy_from_slice(&frame[full_shards * payload..]);
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}
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let tail = &self.tail;
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let recovery_pool = &mut self.recovery;
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let shard_at = |s: usize| -> &[u8] {
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if s < full_shards {
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&frame[s * payload..(s + 1) * payload]
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@@ -160,41 +171,30 @@ impl Packetizer {
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tail.as_slice()
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}
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};
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// Per-block shard geometry (deterministic — recomputed in both passes).
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let block_data_count = |b: usize| ((b + 1) * max_block).min(total_data) - b * max_block;
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// One parity pool per block, reused across frames (steady-state zero-alloc).
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if self.recovery.len() < block_count {
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self.recovery.resize_with(block_count, Vec::new);
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}
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// Total parity across the frame decides where FLAG_EOF lands (the last emitted packet).
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let mut total_recovery = 0usize;
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for b in 0..block_count {
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let first = b * max_block;
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let last = ((b + 1) * max_block).min(total_data);
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let block_data_count = last - first;
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// This block's data shards: references into `frame` (plus the staged tail).
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let data_shards: Vec<&[u8]> = (first..last).map(shard_at).collect();
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let recovery_count = self.fec.recovery_for(block_data_count);
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coder.encode_into(&data_shards, recovery_count, recovery_pool)?;
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let recovery = &*recovery_pool;
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let total_shards = block_data_count + recovery_count;
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if total_shards > u16::MAX as usize {
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let k = block_data_count(b);
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let m = self.fec.recovery_for(k);
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if k + m > u16::MAX as usize {
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return Err(PunktfunkError::Unsupported("block shard count exceeds u16"));
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}
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total_recovery += m;
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}
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for shard_index in 0..total_shards {
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let body: &[u8] = if shard_index < block_data_count {
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data_shards[shard_index]
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} else {
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&recovery[shard_index - block_data_count]
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};
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let seq = self.next_seq;
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self.next_seq = self.next_seq.wrapping_add(1);
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let mut flags = FLAG_PIC;
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if b == 0 && shard_index == 0 {
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flags |= FLAG_SOF;
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}
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if b + 1 == block_count && shard_index + 1 == total_shards {
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flags |= FLAG_EOF;
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}
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let mut emit_one =
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|next_seq: &mut u32, b: usize, shard_index: usize, body: &[u8], flags: u8| {
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let seq = *next_seq;
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*next_seq = next_seq.wrapping_add(1);
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let k = block_data_count(b);
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let hdr = PacketHeader {
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pts_ns,
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frame_index,
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@@ -203,8 +203,8 @@ impl Packetizer {
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user_flags,
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block_index: b as u16,
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block_count: block_count as u16,
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data_shards: block_data_count as u16,
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recovery_shards: recovery_count as u16,
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data_shards: k as u16,
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recovery_shards: self.fec.recovery_for(k) as u16,
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shard_index: shard_index as u16,
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shard_bytes: payload as u16,
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magic: PUNKTFUNK_MAGIC,
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@@ -212,9 +212,48 @@ impl Packetizer {
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fec_scheme: coder.scheme() as u8,
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flags,
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};
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emit(&hdr, body)?;
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emit(&hdr, body)
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};
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let mut next_seq = self.next_seq;
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// Pass 1 — per block: generate parity into the block's pool, emit the DATA shards.
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for b in 0..block_count {
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let first = b * max_block;
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let k = block_data_count(b);
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// This block's data shards: references into `frame` (plus the staged tail).
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let data_shards: Vec<&[u8]> = (first..first + k).map(shard_at).collect();
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let recovery_count = self.fec.recovery_for(k);
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coder.encode_into(&data_shards, recovery_count, &mut self.recovery[b])?;
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for (shard_index, body) in data_shards.iter().enumerate() {
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let mut flags = FLAG_PIC;
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if b == 0 && shard_index == 0 {
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flags |= FLAG_SOF;
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}
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if total_recovery == 0 && b + 1 == block_count && shard_index + 1 == k {
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flags |= FLAG_EOF;
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}
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emit_one(&mut next_seq, b, shard_index, body, flags)?;
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}
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}
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// Pass 2 — per block: emit the parity shards (the frame's tail on the wire).
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let mut parity_left = total_recovery;
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for b in 0..block_count {
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let k = block_data_count(b);
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let recovery_count = self.fec.recovery_for(k);
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for r in 0..recovery_count {
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parity_left -= 1;
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let mut flags = FLAG_PIC;
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if parity_left == 0 {
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flags |= FLAG_EOF;
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}
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let body: &[u8] = &self.recovery[b][r];
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emit_one(&mut next_seq, b, k + r, body, flags)?;
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}
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}
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self.next_seq = next_seq;
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Ok(())
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}
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}
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@@ -370,16 +370,94 @@ fn e2e_roundtrip(
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/// 100 bytes / 16 = 7 shards → blocks of (4 data + 2 rec) and (3 data + 2 rec).
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#[test]
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fn e2e_multiblock_loss_reorder_dup_gf16() {
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// Packet order: blk0 = idx 0..6 (4 data + 2 rec), blk1 = idx 6..11 (3 data + 2 rec).
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// Data-first wire order (T1.3): blk0 data = idx 0..4, blk1 data = idx 4..7,
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// blk0 rec = idx 7..9, blk1 rec = idx 9..11.
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// Kill 2 data in block 0 and 1 data in block 1 — all within the 50% budget.
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e2e_roundtrip(FecScheme::Gf16, 100, 50, &[0, 2, 7], false);
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e2e_roundtrip(FecScheme::Gf16, 100, 50, &[0, 2, 7], true);
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e2e_roundtrip(FecScheme::Gf16, 100, 50, &[0, 2, 5], false);
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e2e_roundtrip(FecScheme::Gf16, 100, 50, &[0, 2, 5], true);
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}
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#[test]
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fn e2e_multiblock_loss_reorder_dup_gf8() {
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e2e_roundtrip(FecScheme::Gf8, 100, 50, &[1, 3, 8], false);
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e2e_roundtrip(FecScheme::Gf8, 100, 50, &[1, 3, 8], true);
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e2e_roundtrip(FecScheme::Gf8, 100, 50, &[1, 3, 6], false);
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e2e_roundtrip(FecScheme::Gf8, 100, 50, &[1, 3, 6], true);
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}
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/// T1.3 pin: the wire order is DATA-FIRST — every block's data shards in block order, then
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/// every block's parity in block order — so the lossless-completion-gating packet (the last
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/// data shard) never sits behind parity in the paced spread. SOF on the first emitted packet,
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/// EOF on the last (a parity shard whenever the frame carries FEC).
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#[test]
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fn packetize_emits_all_data_before_any_parity() {
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use zerocopy::FromBytes;
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let cfg = e2e_config(FecScheme::Gf16, 50);
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let coder = coder_for(FecScheme::Gf16);
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let mut pk = Packetizer::new(&cfg);
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// 100 B / 16 → 7 data shards → blocks (4 data + 2 rec) + (3 data + 2 rec).
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let src: Vec<u8> = (0..100).map(|i| (i * 31 + 3) as u8).collect();
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let pkts = pk.packetize(&src, 1, 0, coder.as_ref()).unwrap();
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assert_eq!(pkts.len(), 11);
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let hdrs: Vec<PacketHeader> = pkts
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.iter()
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.map(|p| PacketHeader::read_from_bytes(&p[..HEADER_LEN]).unwrap())
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.collect();
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// (block_index, shard_index) in emission order.
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let layout: Vec<(u16, u16)> = hdrs
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.iter()
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.map(|h| (h.block_index, h.shard_index))
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.collect();
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assert_eq!(
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layout,
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vec![
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(0, 0),
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(0, 1),
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(0, 2),
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(0, 3), // blk0 data
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(1, 0),
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(1, 1),
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(1, 2), // blk1 data
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(0, 4),
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(0, 5), // blk0 parity
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(1, 3),
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(1, 4), // blk1 parity
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],
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"data-first wire order"
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);
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// A shard is parity iff shard_index >= data_shards; no parity may precede any data.
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let first_parity = hdrs
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.iter()
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.position(|h| h.shard_index >= h.data_shards)
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.unwrap();
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assert!(
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hdrs[first_parity..]
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.iter()
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.all(|h| h.shard_index >= h.data_shards),
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"no data shard after the first parity shard"
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);
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// Stream seqs stay strictly sequential in emission order (the nonce contract).
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for (i, w) in hdrs.windows(2).enumerate() {
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assert_eq!(w[1].stream_seq, w[0].stream_seq + 1, "seq gap at {i}");
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}
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assert_eq!(hdrs[0].flags & FLAG_SOF, FLAG_SOF, "SOF on first packet");
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assert_eq!(
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hdrs.last().unwrap().flags & FLAG_EOF,
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FLAG_EOF,
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"EOF on last (parity) packet"
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);
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assert_eq!(
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hdrs.iter().filter(|h| h.flags & FLAG_EOF != 0).count(),
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1,
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"exactly one EOF"
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);
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// FEC-free frame: EOF falls on the last data shard instead.
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let cfg0 = e2e_config(FecScheme::Gf16, 0);
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let mut pk0 = Packetizer::new(&cfg0);
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let pkts0 = pk0.packetize(&src, 2, 0, coder.as_ref()).unwrap();
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assert_eq!(pkts0.len(), 7, "no parity at 0% FEC");
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let last = PacketHeader::read_from_bytes(&pkts0.last().unwrap()[..HEADER_LEN]).unwrap();
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assert_eq!(last.flags & FLAG_EOF, FLAG_EOF, "EOF on last data shard");
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assert!(last.shard_index < last.data_shards, "last packet is data");
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}
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/// Zero losses, in order: the pure fast path (no codec call, recovered == 0) must still
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@@ -545,28 +545,63 @@ pub struct HostTiming {
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/// Host capture→sent duration, µs (saturated at `u32::MAX` ≈ 71 min — far past the 10 s
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/// client-side sanity clamp anyway).
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pub host_us: u32,
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/// Per-stage split of `host_us` (latency plan T0.1). `None` from a host that predates the
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/// extended datagram — the 0xCF wire is APPEND-extensible (decode reads the 13-byte prefix
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/// and takes the stage tail only when present), so no capability bit is needed in either
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/// direction: old client + new host reads the prefix, new client + old host gets `None`.
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pub stages: Option<HostStages>,
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}
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/// Wire length of a [`HOST_TIMING_MAGIC`] datagram: tag + u64 pts + u32 µs = 13 bytes.
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const HOST_TIMING_LEN: usize = 1 + 8 + 4;
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/// The extended 0xCF's per-stage split of [`HostTiming::host_us`], all µs against the same
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/// capture anchor. The stages tile the host pipeline as
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/// `host_us = queue + encode + (seal/FEC + channel-wait = the residual) + pace`, so the client
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/// derives the residual as `host_us − queue_us − encode_us − pace_us` — no fifth field needed.
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#[derive(Clone, Copy, Debug, PartialEq, Eq)]
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pub struct HostStages {
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/// Capture delivery → encoder submit (the capture ring / channel-queue age; 0 for
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/// re-encoded hold frames, which never waited).
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pub queue_us: u32,
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/// Encoder submit → bitstream ready (scheduling wait + ASIC time).
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pub encode_us: u32,
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/// Paced send: first byte handed to the socket → last packet sent (the microburst spread).
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pub pace_us: u32,
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}
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/// Encode a [`HostTiming`] into a [`HOST_TIMING_MAGIC`] datagram.
|
||||
/// Wire length of a legacy [`HOST_TIMING_MAGIC`] datagram: tag + u64 pts + u32 µs = 13 bytes.
|
||||
const HOST_TIMING_LEN: usize = 1 + 8 + 4;
|
||||
/// Wire length with the [`HostStages`] tail appended: + 3 × u32 = 25 bytes.
|
||||
const HOST_TIMING_STAGES_LEN: usize = HOST_TIMING_LEN + 12;
|
||||
|
||||
/// Encode a [`HostTiming`] into a [`HOST_TIMING_MAGIC`] datagram (extended form when `stages`
|
||||
/// is set — an older client parses the prefix and ignores the tail).
|
||||
pub fn encode_host_timing_datagram(t: &HostTiming) -> Vec<u8> {
|
||||
let mut b = Vec::with_capacity(HOST_TIMING_LEN);
|
||||
let mut b = Vec::with_capacity(HOST_TIMING_STAGES_LEN);
|
||||
b.push(HOST_TIMING_MAGIC);
|
||||
b.extend_from_slice(&t.pts_ns.to_le_bytes());
|
||||
b.extend_from_slice(&t.host_us.to_le_bytes());
|
||||
if let Some(s) = &t.stages {
|
||||
b.extend_from_slice(&s.queue_us.to_le_bytes());
|
||||
b.extend_from_slice(&s.encode_us.to_le_bytes());
|
||||
b.extend_from_slice(&s.pace_us.to_le_bytes());
|
||||
}
|
||||
b
|
||||
}
|
||||
|
||||
/// Parse a [`HOST_TIMING_MAGIC`] datagram → [`HostTiming`]. `None` on bad tag or a short buffer
|
||||
/// (the fixed length bounds every read before it happens).
|
||||
/// (the fixed lengths bound every read before it happens). A datagram carrying only the 13-byte
|
||||
/// prefix (an older host) yields `stages: None`.
|
||||
pub fn decode_host_timing_datagram(b: &[u8]) -> Option<HostTiming> {
|
||||
if b.len() < HOST_TIMING_LEN || b[0] != HOST_TIMING_MAGIC {
|
||||
return None;
|
||||
}
|
||||
let stages = (b.len() >= HOST_TIMING_STAGES_LEN).then(|| HostStages {
|
||||
queue_us: u32::from_le_bytes(b[13..17].try_into().unwrap()),
|
||||
encode_us: u32::from_le_bytes(b[17..21].try_into().unwrap()),
|
||||
pace_us: u32::from_le_bytes(b[21..25].try_into().unwrap()),
|
||||
});
|
||||
Some(HostTiming {
|
||||
pts_ns: u64::from_le_bytes(b[1..9].try_into().unwrap()),
|
||||
host_us: u32::from_le_bytes(b[9..13].try_into().unwrap()),
|
||||
stages,
|
||||
})
|
||||
}
|
||||
|
||||
@@ -266,6 +266,7 @@ fn host_timing_datagram_roundtrip_and_truncation() {
|
||||
let t = HostTiming {
|
||||
pts_ns: 1_751_500_000_123_456_789, // a realistic 2026 CLOCK_REALTIME capture stamp
|
||||
host_us: 4_321,
|
||||
stages: None,
|
||||
};
|
||||
let d = encode_host_timing_datagram(&t);
|
||||
assert_eq!(d[0], HOST_TIMING_MAGIC);
|
||||
@@ -278,6 +279,33 @@ fn host_timing_datagram_roundtrip_and_truncation() {
|
||||
let mut bad = d.clone();
|
||||
bad[0] = HDR_META_MAGIC;
|
||||
assert_eq!(decode_host_timing_datagram(&bad), None);
|
||||
|
||||
// Extended form (T0.1): the stage tail roundtrips; a truncated tail (an old host's 13-byte
|
||||
// datagram, or anything short of the full 25) degrades to `stages: None`, never a partial
|
||||
// read; the prefix fields stay identical in both forms (the append-extensibility contract).
|
||||
let ts = HostTiming {
|
||||
stages: Some(HostStages {
|
||||
queue_us: 900,
|
||||
encode_us: 3_100,
|
||||
pace_us: 2_500,
|
||||
}),
|
||||
..t
|
||||
};
|
||||
let ds = encode_host_timing_datagram(&ts);
|
||||
assert_eq!(ds.len(), 25);
|
||||
assert_eq!(
|
||||
&ds[..13],
|
||||
&d[..13],
|
||||
"prefix is byte-identical to the legacy form"
|
||||
);
|
||||
assert_eq!(decode_host_timing_datagram(&ds), Some(ts));
|
||||
for n in 13..ds.len() {
|
||||
assert_eq!(
|
||||
decode_host_timing_datagram(&ds[..n]),
|
||||
Some(t),
|
||||
"partial stage tail ({n} B) must degrade to the legacy decode"
|
||||
);
|
||||
}
|
||||
}
|
||||
|
||||
#[test]
|
||||
|
||||
Reference in New Issue
Block a user