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wip: predicted samples plumbing

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This commit is contained in:
Claude (noether)
2026-05-25 22:58:00 +02:00
parent 0b6482bc8f
commit 3d0a2a3b02
3 changed files with 107 additions and 9 deletions
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include/daedalus_decoder.h
+20
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@@ -89,6 +89,26 @@ struct daedalus_decoder_mb_input {
* column-major within each 4x4 or 8x8 block (matches FFmpeg
* convention). Caller-owned; copied during append. */
const int16_t *coeffs; /* points at exactly 384 int16_t */
/* Reconstructed predicted samples for this MB, planar order:
* [ 0 .. 256) — 16×16 luma, ROW-MAJOR raster (row 0 cols 0..15,
* row 1 cols 0..15, ..., row 15 cols 0..15)
* [256 .. 320) — 8×8 Cb, ROW-MAJOR raster
* [320 .. 384) — 8×8 Cr, ROW-MAJOR raster
*
* The caller (libavcodec's CPU intra-prediction kernels for Phase 1
* I-frames; MC fallback for Phase 2 P-frames before GPU MC lands)
* populates this from neighbour samples per H.264 §8.3 / §8.4.
* `flush_frame()`'s reconstruction step is `clip255(predicted +
* idct(coeffs))` — the IDCT shader reads dst, adds the inverse
* transform, writes clipped — so a non-zero `predicted` here makes
* the output pixel a valid H.264 reconstruction; zero means
* residual-only (used by IDCT-isolation tests).
*
* NULL is legal and means "all-zero predicted samples" for this MB
* (the per-frame predicted buffer is zeroed at flush time so a NULL
* is indistinguishable from explicit zeros). */
const uint8_t *predicted; /* NULL or exactly 384 uint8_t */
};
/* -------------------------------------------------------------------
src/daedalus_decoder.c
+73 -9
View File
@@ -54,7 +54,18 @@ daedalus_decoder *daedalus_decoder_create(int width, int height)
dec->mb_descs = calloc((size_t) dec->n_mbs, sizeof(*dec->mb_descs));
dec->coeffs = calloc((size_t) dec->n_mbs * 384, sizeof(int16_t));
if (!dec->mb_descs || !dec->coeffs) {
/* Predicted-samples buffers — zero-initialised so a frame where
* every append_mb gets NULL `predicted` decodes residual-only
* (the Stage 1 scaffold contract). flush_frame zeroes these at
* end-of-frame to maintain that invariant for the next frame. */
const size_t pred_y_size = (size_t) width * (size_t) height;
const size_t pred_uv_size = pred_y_size / 2;
dec->predicted_y = calloc(1, pred_y_size);
dec->predicted_uv = calloc(1, pred_uv_size);
if (!dec->mb_descs || !dec->coeffs ||
!dec->predicted_y || !dec->predicted_uv) {
daedalus_decoder_destroy(dec);
return NULL;
}
@@ -66,6 +77,8 @@ void daedalus_decoder_destroy(daedalus_decoder *dec)
{
if (!dec)
return;
free(dec->predicted_uv);
free(dec->predicted_y);
free(dec->coeffs);
free(dec->mb_descs);
if (dec->dctx)
@@ -153,6 +166,34 @@ int daedalus_decoder_append_mb(daedalus_decoder *dec,
mb->coeffs,
384 * sizeof(int16_t));
/* Splat predicted samples into frame-scoped planes at raster
* (mb_y*16, mb_x*16) for luma, (mb_y*8, mb_x*8) for each chroma
* component. NULL → leave buffers as-is (zeroed at create + at
* end of each flush_frame); that's the zero-predictor contract. */
if (mb->predicted) {
const size_t y_stride = (size_t) dec->width;
const size_t uv_stride = (size_t) dec->width / 2;
const size_t uv_plane = uv_stride * ((size_t) dec->height / 2);
const uint8_t *p_y = mb->predicted;
const uint8_t *p_cb = mb->predicted + 256;
const uint8_t *p_cr = mb->predicted + 256 + 64;
uint8_t *dst_y = &dec->predicted_y[
(size_t) mb->mb_y * 16 * y_stride + (size_t) mb->mb_x * 16];
uint8_t *dst_cb = &dec->predicted_uv[
(size_t) mb->mb_y * 8 * uv_stride + (size_t) mb->mb_x * 8];
uint8_t *dst_cr = &dec->predicted_uv[uv_plane +
(size_t) mb->mb_y * 8 * uv_stride + (size_t) mb->mb_x * 8];
for (int r = 0; r < 16; r++)
memcpy(&dst_y[(size_t) r * y_stride], &p_y[r * 16], 16);
for (int r = 0; r < 8; r++) {
memcpy(&dst_cb[(size_t) r * uv_stride], &p_cb[r * 8], 8);
memcpy(&dst_cr[(size_t) r * uv_stride], &p_cr[r * 8], 8);
}
}
dec->mbs_appended++;
return 0;
}
@@ -174,14 +215,18 @@ int daedalus_decoder_append_mb(daedalus_decoder *dec,
* int16 (64 Cb + 64 Cr); dispatch into a planar Cb||Cr scratch
* buffer (W*H/4 each, concatenated W*H/2 total); CPU-interleave
* into the caller's NV12 UV plane post-dispatch.
* - Both dispatches use predicted=0 (the scratch buffers are
* calloc'd); the shader does clip255(predicted + idct(coeffs)).
* - Both dispatches pre-fill the scratch from the per-frame
* predicted_y / predicted_uv buffers (accumulated by append_mb's
* per-MB predicted-samples splat). The IDCT shader's
* `dst += idct(coeffs)` + clip255 then folds reconstruction into
* the IDCT pass — no separate Stage 3 dispatch needed.
*
* What's NOT done yet (follow-on Phase 1 sub-PRs):
* - Intra prediction (Stage 2a wavefront): predicted is forced to 0,
* so output pixels are residual-only and not a valid frame decode.
* Sufficient for Vulkan round-trip validation, not for bit-exact
* against FFmpeg.
* - Intra prediction: caller-driven (Q2 decision 2026-05-25, CPU
* intra-pred via FFmpeg NEON kernels). Caller writes the
* intra-predicted samples into mb_input.predicted; this dispatch
* consumes them as the IDCT-add starting state. GPU wavefront
* intra-pred (DESIGN.md Stage 2a) is no longer planned.
* - Motion compensation (Stage 2b): inter MBs not handled.
* - High-profile IDCT 8x8 (Stage 1 extension).
* - Chroma DC / luma Intra16x16 DC Hadamard pre-pass (currently we
@@ -222,9 +267,17 @@ int daedalus_decoder_flush_frame(daedalus_decoder *dec,
* transform_8x8_size_flag per MB), so we allocate worst-case for
* each and track actual counts.
*/
/* Pre-fill the dispatch scratch with the per-MB predicted samples
* accumulated by append_mb. daedalus-fourier's IDCT 4x4/8x8
* shaders implement FFmpeg `idct_add` semantics — dst += idct(coeffs)
* with clip255 — so a non-zero predicted dst becomes the
* reconstruction step (residual + predicted → clip) "for free",
* collapsing DESIGN.md's Stage 3 into Stage 1's existing dispatch. */
const size_t y_stride_int = (size_t) dec->width;
const size_t y_size = y_stride_int * (size_t) dec->height;
uint8_t *scratch_y = calloc(1, y_size);
uint8_t *scratch_y = malloc(y_size);
if (scratch_y)
memcpy(scratch_y, dec->predicted_y, y_size);
const size_t worst_4x4 = (size_t) dec->n_mbs * 16;
const size_t worst_8x8 = (size_t) dec->n_mbs * 4;
@@ -349,7 +402,9 @@ int daedalus_decoder_flush_frame(daedalus_decoder *dec,
const size_t cb_plane_size = chroma_w * chroma_h;
const size_t uv_scratch_size = 2 * cb_plane_size;
scratch_uv = calloc(1, uv_scratch_size);
scratch_uv = malloc(uv_scratch_size);
if (scratch_uv)
memcpy(scratch_uv, dec->predicted_uv, uv_scratch_size);
chroma_coeffs = malloc(n_chroma_blocks * 16 * sizeof(int16_t));
chroma_meta = malloc(n_chroma_blocks *
sizeof(daedalus_h264_block_meta));
@@ -427,6 +482,15 @@ cleanup:
free(coeffs8);
free(coeffs4);
free(scratch_y);
/* Zero the predicted-samples buffers so the next frame starts from
* the all-zero-predictor baseline; MBs whose append_mb gets NULL
* for `predicted` then decode residual-only. */
if (dec->predicted_y)
memset(dec->predicted_y, 0, (size_t) dec->width * (size_t) dec->height);
if (dec->predicted_uv)
memset(dec->predicted_uv, 0, (size_t) dec->width * (size_t) dec->height / 2);
dec->mbs_appended = 0;
return rc;
}
src/internal.h
+14
View File
@@ -62,6 +62,20 @@ struct daedalus_decoder {
int16_t *coeffs; /* n_mbs * 384 */
int mbs_appended; /* per-frame count */
/* Per-frame predicted samples, accumulated by append_mb(), consumed
* by flush_frame() as the initial dst content for the IDCT-add
* dispatch (predicted + idct clip final pixel). Zeroed at end
* of each flush_frame so NULL `mb->predicted` is indistinguishable
* from explicit zeros.
*
* predicted_y: width × height, row-major (stride = width)
* predicted_uv: PLANAR Cb||Cr, each (width/2) × (height/2), so
* size = width × height / 2, with Cb plane at
* offset 0 and Cr at offset (width/2)*(height/2).
* Matches scratch_uv layout in flush_frame. */
uint8_t *predicted_y;
uint8_t *predicted_uv;
/* Output format. */
daedalus_decoder_output_format output_fmt;