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The Apple client was HEVC/H.264-only: the receive path spoke Annex-B NALs exclusively, so AV1 was never advertised and the codec picker hid it. Add the OBU flavor of the same plumbing (AV1.swift, sibling of AnnexB.swift): a zero-copy OBU walker, a full spec-5.5.1 sequence-header parser, an av1C CMVideoFormatDescription with colorimetry extensions (so isHDRFormat and the presenter stay codec-agnostic), and an ISOBMFF 'av01' sample repack (temporal delimiter stripped, everything size-fielded, one copy per AU). VideoCodec gains .av1 (wire 0x04); both pumps and VideoDecoder route through dispatching formatDescription(fromKeyframe:)/sampleBuffer(au:) — keyframe gating keys on the in-band sequence header exactly as the NAL codecs key on in-band parameter sets, so loss recovery and mid-session reconfigure work unchanged. AV1 sessions require a hardware decoder (VideoToolbox has no software AV1; same fail-fast policy as 4:4:4), and both the Hello advertisement and the Settings picker are gated on VTIsHardwareDecodeSupported — AV1 only appears on devices that can actually decode it (M3-class Macs, A17 Pro-class iPhones; no Apple TV). Tests: real SVT-AV1 blobs (generation recipe in the file) cover the walk, the parse against an independent reference, av1C bytes, delta-TU gating, repack byte-exactness, and — on AV1 hardware — a real VTDecompressionSession decode through VideoDecoder. Host precedence stays HEVC > AV1 > H.264, so AV1 engages only when explicitly picked. Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
265 lines
14 KiB
Swift
265 lines
14 KiB
Swift
// Stage-2 presenter, decode half: explicit VideoToolbox decode of the host's AUs (H.264 /
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// HEVC / AV1 — whatever the Welcome resolved).
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//
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// Stage-1 hands compressed samples to AVSampleBufferDisplayLayer, which decodes AND presents
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// internally with no per-frame callback — so neither decode-completion nor present can be
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// stamped, and frames can't be hand-paced. Here we drive VTDecompressionSession ourselves: the
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// output callback delivers a decoded CVPixelBuffer, we stamp decode-completion, and push it into
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// a ready ring the presenter's display link drains. See docs apple-stage2-presenter.md.
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import CoreMedia
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import CoreVideo
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import Foundation
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import VideoToolbox
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/// One decoded frame waiting to be presented. Owns a retained `CVPixelBuffer` until shown.
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public struct ReadyFrame: @unchecked Sendable {
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/// Host capture clock (the AU's pts), in nanoseconds.
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public let ptsNs: UInt64
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/// Client `CLOCK_REALTIME` instant the AU was received (`AccessUnit.receivedNs`, threaded
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/// through the decode via the frame refcon), in nanoseconds. 0 when unknown (a caller that
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/// didn't stamp receipt) — the decode-stage meter then drops the sample via its sanity guard.
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public let receivedNs: Int64
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/// Client `CLOCK_REALTIME` instant decode completed, in nanoseconds.
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public let decodedNs: Int64
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/// The decoded image — 8-bit NV12 biplanar (SDR) or 10-bit P010 biplanar (HDR), Metal-compatible.
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public let pixelBuffer: CVPixelBuffer
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/// True when the stream is HDR (BT.2020 PQ): the buffer is 10-bit P010 and the presenter must
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/// configure EDR + BT.2020 PQ output. Derived from the decoded buffer's pixel format.
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public let isHDR: Bool
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}
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/// The C output callback can't capture context, so VideoToolbox hands it the refcon we set at
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/// session creation — a pointer back to the owning `VideoDecoder`. The per-frame refcon carries
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/// the AU's `receivedNs` as a pointer bit pattern (a scalar smuggled through the C void*, never
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/// dereferenced) so the decode stage can be computed against decode-completion.
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private let decoderOutputCallback: VTDecompressionOutputCallback = {
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refcon, frameRefcon, status, _, imageBuffer, pts, _ in
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guard let refcon else { return }
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let receivedNs = frameRefcon.map { Int64(Int(bitPattern: $0)) } ?? 0
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Unmanaged<VideoDecoder>.fromOpaque(refcon)
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.takeUnretainedValue()
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.handleDecoded(status: status, imageBuffer: imageBuffer, pts: pts, receivedNs: receivedNs)
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}
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/// Owns a `VTDecompressionSession` rebuilt whenever the format description changes (every IDR /
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/// mode change, the same trigger stage-1 uses). Thread-safe: `decode` runs on the pump thread,
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/// the output callback on a VT-managed thread; the only shared mutable state is the session +
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/// format, guarded by `lock`. `@unchecked Sendable` — the lock enforces the contract.
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public final class VideoDecoder: @unchecked Sendable {
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private let lock = NSLock()
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private var session: VTDecompressionSession?
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private var format: CMVideoFormatDescription?
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/// Called on the VT thread for each successfully decoded frame — stamp + enqueue, don't block.
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private let onDecoded: @Sendable (ReadyFrame) -> Void
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/// Called on the VT thread when a frame fails to decode (bad data / decoder reset) so the
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/// pump can re-gate on the next IDR.
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private let onDecodeError: @Sendable (OSStatus) -> Void
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/// Whether the negotiated stream is full-chroma 4:4:4 (`connection.isChroma444`), set once at
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/// session start before any decode. Selects the 4:4:4 decode pixel format (orthogonal to bit
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/// depth / HDR). Read inside `createSessionLocked` under `lock`.
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private var chroma444 = false
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/// The negotiated codec (`connection.videoCodec`), set once at session start. Drives the
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/// bitstream framing (H.264/HEVC NAL parsing vs AV1 OBU repack). Read under `lock`.
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private var codec: VideoCodec = .hevc
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public init(
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onDecoded: @escaping @Sendable (ReadyFrame) -> Void,
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onDecodeError: @escaping @Sendable (OSStatus) -> Void = { _ in }
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) {
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self.onDecoded = onDecoded
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self.onDecodeError = onDecodeError
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}
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deinit { teardown() }
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/// Select the chroma subsampling of the decode output (4:2:0 vs full-chroma 4:4:4). Call once at
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/// session start, before decoding, from `connection.isChroma444`. Takes effect on the next
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/// session (re)build. Thread-safe.
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public func setChroma444(_ on: Bool) {
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lock.lock()
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chroma444 = on
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lock.unlock()
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}
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/// Select the negotiated codec (H.264 / HEVC / AV1). Call once at session start, before
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/// decoding, from `connection.videoCodec`. Thread-safe.
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public func setCodec(_ c: VideoCodec) {
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lock.lock()
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codec = c
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lock.unlock()
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}
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/// Submit one AU for asynchronous decode, (re)creating the session if `format` changed. The
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/// caller resolves `format` from the keyframe exactly as stage-1 does
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/// (`VideoCodec.formatDescription(fromKeyframe:)`). Returns false if the session couldn't be
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/// created or the frame couldn't be submitted.
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@discardableResult
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public func decode(au: AccessUnit, format newFormat: CMVideoFormatDescription) -> Bool {
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lock.lock()
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let needsNew: Bool = {
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guard let session, let format else { return true }
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if CMFormatDescriptionEqual(format, otherFormatDescription: newFormat) { return false }
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// A new desc that the live session can still accept (rare for HEVC) avoids a rebuild.
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return !VTDecompressionSessionCanAcceptFormatDescription(session, formatDescription: newFormat)
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}()
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if needsNew, !createSessionLocked(format: newFormat) {
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lock.unlock()
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return false
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}
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// Submit WHILE holding the lock so a concurrent reset()/teardown (main thread) can't
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// invalidate the session between here and DecodeFrame. The VT output callback takes the
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// ring lock, not this one, so there's no re-entrancy. DecodeFrame is async — non-blocking.
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guard let session,
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let sample = codec.sampleBuffer(au: au, format: newFormat)
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else { lock.unlock(); return false }
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var infoOut = VTDecodeInfoFlags()
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let status = VTDecompressionSessionDecodeFrame(
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session,
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sampleBuffer: sample,
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flags: [._EnableAsynchronousDecompression],
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// The AU's receipt instant rides through as a bit pattern (nil for 0 — the output
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// callback maps that back to 0); the callback needs it to stamp the decode stage.
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frameRefcon: UnsafeMutableRawPointer(bitPattern: Int(au.receivedNs)),
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infoFlagsOut: &infoOut)
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lock.unlock()
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if status != noErr {
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onDecodeError(status)
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return false
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}
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return true
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}
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/// Drop the session — the next `decode` rebuilds it. Used on stop and to recover from a
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/// wedged decoder (re-gates on the next in-band parameter sets, like stage-1's flush).
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public func reset() {
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lock.lock()
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teardownLocked()
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lock.unlock()
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}
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private func teardown() {
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lock.lock()
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teardownLocked()
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lock.unlock()
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}
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private func teardownLocked() {
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if let session {
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VTDecompressionSessionWaitForAsynchronousFrames(session)
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VTDecompressionSessionInvalidate(session)
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}
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session = nil
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format = nil
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}
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/// True when `newFormat` carries a PQ (SMPTE ST 2084) or HLG transfer function — i.e. the host
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/// is sending HDR (BT.2020). VideoToolbox populates the transfer-function extension from the
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/// HEVC VUI, so this picks the decode bit depth (10-bit P010/x444 vs 8-bit NV12/444v) from the
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/// stream — and can flip mid-session (a game entering HDR re-inits the host encoder). The
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/// presenter follows the decoded frame's resulting `isHDR`, not the Welcome's latched flag
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/// (`render` reconciles the layer per frame via the idempotent `configure(hdr:)`).
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static func isHDRFormat(_ format: CMVideoFormatDescription) -> Bool {
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guard
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let tf = CMFormatDescriptionGetExtension(
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format, extensionKey: kCMFormatDescriptionExtension_TransferFunction)
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else { return false }
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let s = tf as? String
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return s == (kCMFormatDescriptionTransferFunction_SMPTE_ST_2084_PQ as String)
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|| s == (kCMFormatDescriptionTransferFunction_ITU_R_2100_HLG as String)
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}
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/// `lock` held. Replace the session with one for `newFormat`. SDR streams decode to 8-bit NV12;
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/// HDR streams (BT.2020 PQ) decode to 10-bit P010 so the presenter can drive EDR.
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private func createSessionLocked(format newFormat: CMVideoFormatDescription) -> Bool {
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if let session {
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VTDecompressionSessionWaitForAsynchronousFrames(session)
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VTDecompressionSessionInvalidate(session)
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}
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session = nil
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format = nil
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// Decode pixel format is a 2×2 of (chroma, depth/HDR), both biplanar so the presenter binds
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// plane 0 = luma, plane 1 = interleaved chroma uniformly — 4:4:4 just delivers a full-size
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// chroma plane. 10-bit (P010 / `x444`) for HDR (PQ/HLG), 8-bit (NV12 / `444v`) otherwise.
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let hdr = Self.isHDRFormat(newFormat)
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let pixelFormat: OSType = {
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switch (chroma444, hdr) {
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case (false, false): return kCVPixelFormatType_420YpCbCr8BiPlanarVideoRange // NV12
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case (false, true): return kCVPixelFormatType_420YpCbCr10BiPlanarVideoRange // P010
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case (true, false): return kCVPixelFormatType_444YpCbCr8BiPlanarVideoRange // 444v
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case (true, true): return kCVPixelFormatType_444YpCbCr10BiPlanarVideoRange // x444
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}
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}()
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let imageAttrs: [CFString: Any] = [
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kCVPixelBufferMetalCompatibilityKey: true,
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kCVPixelBufferPixelFormatTypeKey: pixelFormat,
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]
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var callback = VTDecompressionOutputCallbackRecord(
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decompressionOutputCallback: decoderOutputCallback,
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decompressionOutputRefCon: Unmanaged.passUnretained(self).toOpaque())
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// 4:4:4 and AV1 sessions REQUIRE a hardware decoder: both are only advertised when the
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// hardware gate passed (the 4:4:4 probe / `AV1.hardwareDecodeSupported`), so a
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// hardware-incapable mode (e.g. a resolution past a HW ceiling) must fail HERE,
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// synchronously, letting the pump's backstop end the session — rather than silently
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// falling back to a software decoder far too slow for a real-time stream. 4:2:0
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// H.264/HEVC keeps the software fallback (nil spec) as a robustness net.
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let spec: CFDictionary? =
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chroma444 || codec == .av1
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? [kVTVideoDecoderSpecification_RequireHardwareAcceleratedVideoDecoder: true] as CFDictionary
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: nil
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var newSession: VTDecompressionSession?
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let status = VTDecompressionSessionCreate(
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allocator: kCFAllocatorDefault,
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formatDescription: newFormat,
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decoderSpecification: spec,
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imageBufferAttributes: imageAttrs as CFDictionary,
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outputCallback: &callback,
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decompressionSessionOut: &newSession)
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guard status == noErr, let newSession else { return false }
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// Real-time hint: schedule this session for live-streaming latency rather than
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// throughput/efficiency. Best-effort — decoders that don't support the property
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// return an error, which is fine to ignore.
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VTSessionSetProperty(
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newSession, key: kVTDecompressionPropertyKey_RealTime, value: kCFBooleanTrue)
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session = newSession
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format = newFormat
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return true
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}
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/// VT thread. Stamp decode-completion and enqueue, or report the error. `receivedNs` is the
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/// AU's receipt instant threaded through the frame refcon (0 = unknown).
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fileprivate func handleDecoded(
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status: OSStatus, imageBuffer: CVImageBuffer?, pts: CMTime, receivedNs: Int64
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) {
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guard status == noErr, let imageBuffer else {
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onDecodeError(status)
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return
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}
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var ts = timespec()
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clock_gettime(CLOCK_REALTIME, &ts)
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let decodedNs = Int64(ts.tv_sec) * 1_000_000_000 + Int64(ts.tv_nsec)
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// pts was stamped at timescale 1e9 (AnnexB.sampleBuffer); normalize defensively.
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let p = CMTimeConvertScale(pts, timescale: 1_000_000_000, method: .default)
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let ptsNs = p.value > 0 ? UInt64(p.value) : 0
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// HDR iff the decoder produced a 10-bit buffer (we only request a 10-bit format for PQ/HLG
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// streams). Covers 4:2:0 (P010) and 4:4:4 (`x444`), video- and full-range, so a 10-bit 4:4:4
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// HDR frame isn't misclassified as SDR. (The mastering metadata is applied to the presenter's
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// CAMetalLayer via CAEDRMetadata, not to this source buffer — a separate-drawable presenter
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// never composites the source buffer's attachments, so attaching them here would be dead.)
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let fmt = CVPixelBufferGetPixelFormatType(imageBuffer)
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let isHDR =
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fmt == kCVPixelFormatType_420YpCbCr10BiPlanarVideoRange
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|| fmt == kCVPixelFormatType_420YpCbCr10BiPlanarFullRange
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|| fmt == kCVPixelFormatType_444YpCbCr10BiPlanarVideoRange
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|| fmt == kCVPixelFormatType_444YpCbCr10BiPlanarFullRange
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onDecoded(
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ReadyFrame(
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ptsNs: ptsNs, receivedNs: receivedNs, decodedNs: decodedNs,
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pixelBuffer: imageBuffer, isHDR: isHDR))
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}
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}
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