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phase1: IDCT 8x8 dispatch (High profile transform_8x8_size_flag)

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Adds the High-profile 8x8 luma transform path alongside the existing
4x4 dispatch.  flush_frame now partitions macroblocks by each MB's
transform_8x8 flag and issues a separate luma dispatch per partition:

  - mb.transform_8x8 == 0 (Baseline/Main) → coeffs[0..256) interpreted
    as 16 4x4 blocks, fed to daedalus_recipe_dispatch_h264_idct4
    (existing behaviour, unchanged).
  - mb.transform_8x8 == 1 (High)          → coeffs[0..256) interpreted
    as 4 8x8 blocks (64 int16 each, column-major), fed to the new
    daedalus_recipe_dispatch_h264_idct8 call.

Both luma partitions can be non-empty in the same frame (FFmpeg sets
the flag per-MB).  Each non-empty partition costs one
vkQueueSubmit + vkQueueWaitIdle; empty partitions are skipped
(common case: Baseline streams skip the 8x8 dispatch entirely).

Chroma is unchanged — 4:2:0 chroma always uses the 4x4 transform.

API surface:
  - New uint8_t `transform_8x8` field in `struct daedalus_decoder_mb_input`
    (after deblock_*).  Backwards-compatible at the source level
    because the field defaults to 0 with C99 designated initialisers
    or {0} struct zeroing, both of which select the existing 4x4
    path.  ABI is pre-0.1 (per the header doc) so structural change
    is fine.
  - Mirrored in `struct daedalus_decoder_mb_desc` (internal layout).

Test changes:

  - test_idct_bitexact now exercises a mixed-mode frame: every odd
    raster MB uses 8x8, every even uses 4x4 (so flush_frame's
    partitioning is also under test, not just the underlying shaders).
  - 8x8 C reference (h264_idct8_butterfly + ref_idct8_add)
    transcribed from daedalus-fourier tests/h264_idct8_ref.c per
    H.264 §8.5.13.2.  Block layout column-major; +32 >> 6 rounding;
    add-to-predicted; clip255.
  - Reference luma compute branches per MB on the same mb_8x8[]
    array used to set the input flag.

Verified on hertz (Pi 5 / V3D 7.1 / daedalus-fourier 0.1.0):

  $ ./build/test_idct_bitexact
  test_idct_bitexact: 320x240 (300 MBs), seed=0xfeedface5a5a5a5a
  MB mix: 150 4x4 MBs, 150 8x8 MBs
  Y bytes total:  76800
  Y bytes diff:   0 (0.0000%)
  Cb bytes total: 19200  diff: 0 (0.0000%)
  Cr bytes total: 19200  diff: 0 (0.0000%)
  BIT-EXACT PASS (Y + Cb + Cr)

  $ ctest --test-dir build
  100% tests passed, 0 tests failed out of 2

Bit-exact PASS first try for the 8x8 path — 150 8x8 MBs × 4 blocks =
600 8x8 IDCTs against the spec C reference, identical output.
Validates both the daedalus-fourier IDCT 8x8 shader (already gated
by its own cycle-7 bit-exact test, now also gated end-to-end through
our flush_frame), and our 8x8 layout assumptions (column-major coeffs,
raster sb_y*2+sb_x block order, top-left = mb*16 + sb*8).

What's NOT covered yet (deferred):

  - Z-scan permutation for FFmpeg compatibility (libavcodec intercept
    patch's concern; both 4x4 and 8x8 z-scans differ).
  - Chroma DC / luma Intra16x16 DC Hadamard pre-pass.
  - Mixed intra/inter MB handling — currently all MBs treated as
    residual-only (predicted=0).

Closes the "IDCT 8x8 (High profile)" item from PR #3's deferred list.
This commit is contained in:
Claude (noether)
2026-05-24 22:41:05 +02:00
parent 5fa495964d
commit adaabb1f63
4 changed files with 203 additions and 73 deletions
Download Patch File Download Diff File Expand all files Collapse all files
include/daedalus_decoder.h
+13 -3
View File
@@ -75,9 +75,19 @@ struct daedalus_decoder_mb_input {
int8_t deblock_alpha_c0; int8_t deblock_alpha_c0;
int8_t deblock_beta; int8_t deblock_beta;
/* Transform coefficients — 256 luma (4x4 x 16) + 64 cb + 64 cr, /* High-profile 8x8 transform selector.
* column-major within each 4x4 block (matches FFmpeg convention). * 0 = the 256-int16 luma section of coeffs[] holds 16 4x4 blocks
* Caller-owned; copied during append. */ * (16 coeffs each, raster sb_y*4+sb_x); the chroma section is
* always 4x4.
* 1 = the 256-int16 luma section holds 4 8x8 blocks (64 coeffs
* each, raster sb_y*2+sb_x). Set per H.264's
* transform_8x8_size_flag. Chroma remains 4x4 (4:2:0).
*/
uint8_t transform_8x8;
/* Transform coefficients — 256 luma + 64 cb + 64 cr int16, all
* 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 */ const int16_t *coeffs; /* points at exactly 384 int16_t */
}; };
src/daedalus_decoder.c
+82 -49
View File
@@ -119,6 +119,7 @@ int daedalus_decoder_append_mb(daedalus_decoder *dec,
d->deblock_disable = mb->deblock_disable; d->deblock_disable = mb->deblock_disable;
d->deblock_alpha_c0 = mb->deblock_alpha_c0; d->deblock_alpha_c0 = mb->deblock_alpha_c0;
d->deblock_beta = mb->deblock_beta; d->deblock_beta = mb->deblock_beta;
d->transform_8x8 = mb->transform_8x8;
memcpy(&dec->coeffs[(size_t) expected * 384], memcpy(&dec->coeffs[(size_t) expected * 384],
mb->coeffs, mb->coeffs,
@@ -179,74 +180,104 @@ int daedalus_decoder_flush_frame(daedalus_decoder *dec,
int rc = 0; int rc = 0;
/* ---- Build frame-scaled luma-4x4 dispatch ---- */ /* ---- Build frame-scaled luma dispatches (4x4 + 8x8) ---- */
const size_t n_luma_blocks_per_mb = 16; /* Two partitions of the per-MB luma section based on each MB's
const size_t n_luma_blocks = (size_t) dec->n_mbs * n_luma_blocks_per_mb; * transform_8x8 flag:
*
/* Scratch Y plane — coded-size byte buffer. Zero-initialised so * transform_8x8 == 0 → 16 4x4 blocks contribute to the 4x4
* the IDCT-ADD-clip operation reduces to clip255(IDCT) per block * dispatch (16 coeffs each).
* (predicted=0 because no intra/MC has run yet). */ * transform_8x8 == 1 → 4 8x8 blocks contribute to the 8x8
* dispatch (64 coeffs each).
*
* Both partitions can be non-empty in the same frame (FFmpeg sets
* transform_8x8_size_flag per MB), so we allocate worst-case for
* each and track actual counts.
*/
const size_t y_stride_int = (size_t) dec->width; const size_t y_stride_int = (size_t) dec->width;
const size_t y_size = y_stride_int * (size_t) dec->height; const size_t y_size = y_stride_int * (size_t) dec->height;
uint8_t *scratch_y = calloc(1, y_size); uint8_t *scratch_y = calloc(1, y_size);
int16_t *flat_coeffs = malloc(n_luma_blocks * 16 * sizeof(int16_t));
daedalus_h264_block_meta *meta = malloc(
n_luma_blocks * sizeof(daedalus_h264_block_meta));
if (!scratch_y || !flat_coeffs || !meta) { const size_t worst_4x4 = (size_t) dec->n_mbs * 16;
const size_t worst_8x8 = (size_t) dec->n_mbs * 4;
int16_t *coeffs4 = malloc(worst_4x4 * 16 * sizeof(int16_t));
int16_t *coeffs8 = malloc(worst_8x8 * 64 * sizeof(int16_t));
daedalus_h264_block_meta *meta4 = malloc(worst_4x4 * sizeof(*meta4));
daedalus_h264_block_meta *meta8 = malloc(worst_8x8 * sizeof(*meta8));
if (!scratch_y || !coeffs4 || !coeffs8 || !meta4 || !meta8) {
rc = -1; rc = -1;
goto cleanup; goto cleanup;
} }
/* Raster-order layout: walk each MB, then each of its 16 luma 4×4 /* Walk MBs in raster order, append each MB's luma blocks to the
* sub-blocks in raster order (sb_y=0..3 outer, sb_x=0..3 inner). * partition selected by its transform_8x8 flag.
* *
* NB: H.264's actual per-MB 4×4 coefficient scan order is the * NB: per-MB 4x4 / 8x8 coefficient ORDER inside the H.264 bitstream
* z-scan from spec §6.4.3 / fig 6-10. We're using a flat raster * follows the z-scan from spec §6.4.3 / fig 6-10. We're using
* here because Phase 1 stage 1 only validates the dispatch * flat raster on the input side too (sb_y outer, sb_x inner) for
* round-trip; bit-exact against an FFmpeg reference requires the * Phase 1 self-consistency; the z-scan permutation is the
* z-scan permutation and is a follow-on test. The per-MB * libavcodec-intercept patch's responsibility.
* coeffs[] field's first 256 entries are interpreted as 16 */
* consecutive 4×4 blocks in the same raster order on the input size_t bi4 = 0, bi8 = 0;
* side, so this is self-consistent for the validation. */
size_t bi = 0;
for (int mb_y = 0; mb_y < dec->mb_height; mb_y++) { for (int mb_y = 0; mb_y < dec->mb_height; mb_y++) {
for (int mb_x = 0; mb_x < dec->mb_width; mb_x++) { for (int mb_x = 0; mb_x < dec->mb_width; mb_x++) {
int mb_idx = mb_y * dec->mb_width + mb_x; int mb_idx = mb_y * dec->mb_width + mb_x;
const struct daedalus_decoder_mb_desc *d = &dec->mb_descs[mb_idx];
const int16_t *mb_coeffs = &dec->coeffs[(size_t) mb_idx * 384]; const int16_t *mb_coeffs = &dec->coeffs[(size_t) mb_idx * 384];
for (int sb_y = 0; sb_y < 4; sb_y++) { if (d->transform_8x8) {
for (int sb_x = 0; sb_x < 4; sb_x++) { /* 4 luma 8x8 blocks, raster sb_y*2+sb_x. */
/* Block top-left pixel in the coded Y plane. */ for (int sb_y = 0; sb_y < 2; sb_y++) {
size_t px_y = (size_t) mb_y * 16 + (size_t) sb_y * 4; for (int sb_x = 0; sb_x < 2; sb_x++) {
size_t px_x = (size_t) mb_x * 16 + (size_t) sb_x * 4; size_t px_y = (size_t) mb_y * 16 + (size_t) sb_y * 8;
meta[bi].dst_off = (uint32_t) (px_y * y_stride_int + px_x); size_t px_x = (size_t) mb_x * 16 + (size_t) sb_x * 8;
meta8[bi8].dst_off = (uint32_t)
/* Copy 16 coeffs for this block from the per-MB (px_y * y_stride_int + px_x);
* coeffs[] (luma offset = block_idx * 16). */ int block_in_mb = sb_y * 2 + sb_x;
int block_in_mb = sb_y * 4 + sb_x; memcpy(&coeffs8[bi8 * 64],
memcpy(&flat_coeffs[bi * 16], &mb_coeffs[block_in_mb * 64],
&mb_coeffs[block_in_mb * 16], 64 * sizeof(int16_t));
16 * sizeof(int16_t)); bi8++;
bi++; }
}
} else {
/* 16 luma 4x4 blocks, raster sb_y*4+sb_x. */
for (int sb_y = 0; sb_y < 4; sb_y++) {
for (int sb_x = 0; sb_x < 4; sb_x++) {
size_t px_y = (size_t) mb_y * 16 + (size_t) sb_y * 4;
size_t px_x = (size_t) mb_x * 16 + (size_t) sb_x * 4;
meta4[bi4].dst_off = (uint32_t)
(px_y * y_stride_int + px_x);
int block_in_mb = sb_y * 4 + sb_x;
memcpy(&coeffs4[bi4 * 16],
&mb_coeffs[block_in_mb * 16],
16 * sizeof(int16_t));
bi4++;
}
} }
} }
} }
} }
/* assert bi == n_luma_blocks; the loop math guarantees it */ /* assert bi4 + bi8*4 == n_mbs*16; loop math guarantees it */
/* ---- One Vulkan submit + wait for the whole frame's luma IDCT. /* ---- One Vulkan submit + wait per non-empty luma partition.
* AUTO substrate picks QPU per the post-decree recipe table; falls * AUTO substrate picks QPU per the post-decree recipe table; falls
* back to CPU NEON if the daedalus-fourier ctx wasn't QPU-capable. */ * back to CPU NEON if the daedalus-fourier ctx wasn't QPU-capable.
int dr = daedalus_recipe_dispatch_h264_idct4(dec->dctx, * Skipping the dispatch when the partition is empty avoids the
scratch_y, y_stride_int, * shader-pool warm-up cost on the common case (a typical Baseline
flat_coeffs, * stream is all-4x4 → 8x8 dispatch is no-op). */
n_luma_blocks, if (bi4 > 0) {
meta); int dr = daedalus_recipe_dispatch_h264_idct4(dec->dctx,
if (dr != 0) { scratch_y, y_stride_int,
rc = -3; /* GPU dispatch failure */ coeffs4, bi4, meta4);
goto cleanup; if (dr != 0) { rc = -3; goto cleanup; }
}
if (bi8 > 0) {
int dr = daedalus_recipe_dispatch_h264_idct8(dec->dctx,
scratch_y, y_stride_int,
coeffs8, bi8, meta8);
if (dr != 0) { rc = -3; goto cleanup; }
} }
/* ---- Copy Y out to caller's plane at the requested stride. ---- */ /* ---- Copy Y out to caller's plane at the requested stride. ---- */
@@ -362,8 +393,10 @@ int daedalus_decoder_flush_frame(daedalus_decoder *dec,
} }
cleanup: cleanup:
free(meta); free(meta8);
free(flat_coeffs); free(meta4);
free(coeffs8);
free(coeffs4);
free(scratch_y); free(scratch_y);
dec->mbs_appended = 0; dec->mbs_appended = 0;
return rc; return rc;
src/internal.h
+2 -1
View File
@@ -41,7 +41,8 @@ struct daedalus_decoder_mb_desc {
uint8_t deblock_disable; uint8_t deblock_disable;
int8_t deblock_alpha_c0; int8_t deblock_alpha_c0;
int8_t deblock_beta; int8_t deblock_beta;
uint8_t _pad1; uint8_t transform_8x8; /* 0 = 4 luma blocks of 4x4 (16 total),
* 1 = 4 luma blocks of 8x8. */
}; };
struct daedalus_decoder { struct daedalus_decoder {
tests/test_idct_bitexact.c
+106 -20
View File
@@ -19,13 +19,15 @@
* layout is a separate concern (handled in the eventual libavcodec- * layout is a separate concern (handled in the eventual libavcodec-
* intercept patch). * intercept patch).
* *
* Covers BOTH luma (Y plane, 16 blocks/MB) and chroma (UV plane, * Covers Y (4x4 + 8x8) and chroma (4x4 Cb + Cr, NV12-interleaved).
* 4 Cb + 4 Cr blocks/MB, NV12-interleaved). Random coeffs for all * Half the MBs use transform_8x8=1 (4 luma 8x8 blocks), half use
* three components; reference IDCT applied per block. The chroma * transform_8x8=0 (16 luma 4x4 blocks); both partitions are
* exercised in the same frame so the flush_frame partitioning logic
* is also under test, not just the underlying shaders. Random coeffs
* for all components; reference IDCT applied per block. The chroma
* compare deinterleaves NV12 UV back into separate Cb/Cr expectations. * compare deinterleaves NV12 UV back into separate Cb/Cr expectations.
* *
* Not in scope (covered by other tests / future PRs): * Not in scope (covered by other tests / future PRs):
* - IDCT 8×8 (Phase 1 follow-on)
* - Chroma DC / Intra16x16 DC Hadamard pre-pass * - Chroma DC / Intra16x16 DC Hadamard pre-pass
* - bit-exactness against real H.264 streams (test-vector PR) * - bit-exactness against real H.264 streams (test-vector PR)
* - non-zero predicted pixels (intra prediction lands in Stage 2a) * - non-zero predicted pixels (intra prediction lands in Stage 2a)
@@ -66,6 +68,65 @@ static void h264_idct4_butterfly(const int d[4], int out[4])
out[3] = e - h; out[3] = e - h;
} }
/* 1D 8-point butterfly per H.264 §8.5.13.2. Transcribed from
* daedalus-fourier tests/h264_idct8_ref.c (LGPL-2.1+ in the original —
* algorithm reproduced here for test purposes, no copy of code). */
static void h264_idct8_butterfly(const int d[8], int g[8])
{
int e[8], f[8];
e[0] = d[0] + d[4];
e[1] = -d[3] + d[5] - d[7] - (d[7] >> 1);
e[2] = d[0] - d[4];
e[3] = d[1] + d[7] - d[3] - (d[3] >> 1);
e[4] = (d[2] >> 1) - d[6];
e[5] = -d[1] + d[7] + d[5] + (d[5] >> 1);
e[6] = d[2] + (d[6] >> 1);
e[7] = d[3] + d[5] + d[1] + (d[1] >> 1);
f[0] = e[0] + e[6];
f[1] = e[1] + (e[7] >> 2);
f[2] = e[2] + e[4];
f[3] = e[3] + (e[5] >> 2);
f[4] = e[2] - e[4];
f[5] = (e[3] >> 2) - e[5];
f[6] = e[0] - e[6];
f[7] = e[7] - (e[1] >> 2);
g[0] = f[0] + f[7];
g[1] = f[2] + f[5];
g[2] = f[4] + f[3];
g[3] = f[6] + f[1];
g[4] = f[6] - f[1];
g[5] = f[4] - f[3];
g[6] = f[2] - f[5];
g[7] = f[0] - f[7];
}
static void ref_idct8_add(uint8_t *dst, ptrdiff_t stride, const int16_t *block)
{
/* block layout COLUMN-MAJOR: block[c*8 + r] = coef at (row=r, col=c). */
int tmp[8][8];
for (int r = 0; r < 8; r++) {
int d[8];
for (int c = 0; c < 8; c++) d[c] = block[c * 8 + r];
int g[8];
h264_idct8_butterfly(d, g);
for (int c = 0; c < 8; c++) tmp[r][c] = g[c];
}
int col_out[8][8];
for (int c = 0; c < 8; c++) {
int d[8];
for (int r = 0; r < 8; r++) d[r] = tmp[r][c];
int g[8];
h264_idct8_butterfly(d, g);
for (int r = 0; r < 8; r++) col_out[r][c] = g[r];
}
for (int r = 0; r < 8; r++)
for (int c = 0; c < 8; c++)
dst[r * stride + c] = (uint8_t) clip_u8(
dst[r * stride + c] + ((col_out[r][c] + 32) >> 6));
}
static void ref_idct4_add(uint8_t *dst, ptrdiff_t stride, const int16_t *block) static void ref_idct4_add(uint8_t *dst, ptrdiff_t stride, const int16_t *block)
{ {
/* block layout: COLUMN-MAJOR (matches FFmpeg + daedalus-fourier): /* block layout: COLUMN-MAJOR (matches FFmpeg + daedalus-fourier):
@@ -131,20 +192,31 @@ int main(int argc, char **argv)
} }
} }
/* Per-MB transform mode (deterministic split: every odd raster MB
* is 8x8, every even is 4x4 — exercises BOTH partitions in the
* same frame so the flush_frame partitioning logic is under test). */
uint8_t *mb_8x8 = malloc((size_t) n_mbs);
if (!mb_8x8) { fprintf(stderr, "alloc fail\n"); return 1; }
for (int i = 0; i < n_mbs; i++) mb_8x8[i] = (i & 1) ? 1 : 0;
/* Append in raster order. */ /* Append in raster order. */
struct daedalus_decoder_mb_input mb = {0}; struct daedalus_decoder_mb_input mb = {0};
int n_8x8_mbs = 0, n_4x4_mbs = 0;
for (int my = 0; my < mb_h; my++) { for (int my = 0; my < mb_h; my++) {
for (int mx = 0; mx < mb_w; mx++) { for (int mx = 0; mx < mb_w; mx++) {
int idx = my * mb_w + mx; int idx = my * mb_w + mx;
mb.mb_x = (uint16_t) mx; mb.mb_x = (uint16_t) mx;
mb.mb_y = (uint16_t) my; mb.mb_y = (uint16_t) my;
mb.coeffs = per_mb_coeffs[idx]; mb.coeffs = per_mb_coeffs[idx];
mb.transform_8x8 = mb_8x8[idx];
if (mb_8x8[idx]) n_8x8_mbs++; else n_4x4_mbs++;
if (daedalus_decoder_append_mb(dec, &mb) != 0) { if (daedalus_decoder_append_mb(dec, &mb) != 0) {
fprintf(stderr, "append (%d,%d) failed\n", mx, my); fprintf(stderr, "append (%d,%d) failed\n", mx, my);
return 1; return 1;
} }
} }
} }
printf("MB mix: %d 4x4 MBs, %d 8x8 MBs\n", n_4x4_mbs, n_8x8_mbs);
/* Flush — exercise BOTH the luma path (out_y) and the chroma path /* Flush — exercise BOTH the luma path (out_y) and the chroma path
* (out_uv set to non-NULL so flush_frame runs the chroma dispatch * (out_uv set to non-NULL so flush_frame runs the chroma dispatch
@@ -162,27 +234,40 @@ int main(int argc, char **argv)
} }
/* Compute the reference output: same per-MB → flat raster block /* Compute the reference output: same per-MB → flat raster block
* layout as flush_frame uses. */ * layout as flush_frame uses. Branch per MB on transform_8x8. */
uint8_t *ref_y = calloc(1, y_size); uint8_t *ref_y = calloc(1, y_size);
if (!ref_y) return 1; if (!ref_y) return 1;
/* Need a destructively-mutable copy because the reference IDCT int16_t block_scratch[64]; /* large enough for 8x8 */
* doesn't actually mutate, but the GPU's IDCT shader does zero
* the coeffs. Our reference doesn't zero; that's fine because we
* use a fresh copy per block. */
int16_t block_scratch[16];
for (int my = 0; my < mb_h; my++) { for (int my = 0; my < mb_h; my++) {
for (int mx = 0; mx < mb_w; mx++) { for (int mx = 0; mx < mb_w; mx++) {
int mb_idx = my * mb_w + mx; int mb_idx = my * mb_w + mx;
for (int sb_y = 0; sb_y < 4; sb_y++) { if (mb_8x8[mb_idx]) {
for (int sb_x = 0; sb_x < 4; sb_x++) { /* 4 luma 8x8 blocks, raster sb_y*2+sb_x. */
int block_in_mb = sb_y * 4 + sb_x; for (int sb_y = 0; sb_y < 2; sb_y++) {
memcpy(block_scratch, for (int sb_x = 0; sb_x < 2; sb_x++) {
&per_mb_coeffs[mb_idx][block_in_mb * 16], int block_in_mb = sb_y * 2 + sb_x;
16 * sizeof(int16_t)); memcpy(block_scratch,
size_t px_y = (size_t) my * 16 + (size_t) sb_y * 4; &per_mb_coeffs[mb_idx][block_in_mb * 64],
size_t px_x = (size_t) mx * 16 + (size_t) sb_x * 4; 64 * sizeof(int16_t));
ref_idct4_add(&ref_y[px_y * (size_t) width + px_x], size_t px_y = (size_t) my * 16 + (size_t) sb_y * 8;
width, block_scratch); size_t px_x = (size_t) mx * 16 + (size_t) sb_x * 8;
ref_idct8_add(&ref_y[px_y * (size_t) width + px_x],
width, block_scratch);
}
}
} else {
/* 16 luma 4x4 blocks, raster sb_y*4+sb_x. */
for (int sb_y = 0; sb_y < 4; sb_y++) {
for (int sb_x = 0; sb_x < 4; sb_x++) {
int block_in_mb = sb_y * 4 + sb_x;
memcpy(block_scratch,
&per_mb_coeffs[mb_idx][block_in_mb * 16],
16 * sizeof(int16_t));
size_t px_y = (size_t) my * 16 + (size_t) sb_y * 4;
size_t px_x = (size_t) mx * 16 + (size_t) sb_x * 4;
ref_idct4_add(&ref_y[px_y * (size_t) width + px_x],
width, block_scratch);
}
} }
} }
} }
@@ -278,6 +363,7 @@ int main(int argc, char **argv)
free(ref_y); free(ref_y);
free(gpu_uv); free(gpu_uv);
free(gpu_y); free(gpu_y);
free(mb_8x8);
free(per_mb_coeffs); free(per_mb_coeffs);
daedalus_decoder_destroy(dec); daedalus_decoder_destroy(dec);