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h264: V3D shaders for the 8 diagonal qpel positions

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Closes the put_ qpel QPU matrix.  Adds mc11/12/13/21/23/31/32/33 —
each composes two half-pel anchor outputs via L2 rounded-average:

  mc11 ¼¼ : avg(mc20[r,   c],   mc02[r,   c])
  mc12 ¼½ : avg(mc22[r,   c],   mc02[r,   c])
  mc13 ¼¾ : avg(mc20[r+1, c],   mc02[r,   c])
  mc21 ½¼ : avg(mc22[r,   c],   mc20[r,   c])
  mc23 ½¾ : avg(mc22[r,   c],   mc20[r+1, c])
  mc31 ¾¼ : avg(mc20[r,   c],   mc02[r,   c+1])
  mc32 ¾½ : avg(mc22[r,   c],   mc02[r,   c+1])
  mc33 ¾¾ : avg(mc20[r+1, c],   mc02[r,   c+1])

Per-lane structure: each lane runs the FULL cascade for BOTH anchors
at its own (r, c) target, then L2 averages.  No shared memory.
Shaders inline hpel_h() / hpel_v() / hpel_hv() helpers (the latter
does the 13×6 int16 cascade per cell).  ~88 lines each.

Shaders generated from a python template (POSITIONS table + format
string) — the 8 .comp files are 1:1 with the C reference's
DEFINE_DIAG_REF macro from fourier PR #18.

Dispatch plumbing: shared dispatch_h264_qpel_diag_qpu helper covers
all 8 (same src envelope as mc22: src_max = src_off + 10*stride + 11,
covering rows -2..+10 and cols -2..+10 for any (r±1, c±1) offset).

Recipe table: all 8 DAEDALUS_KERNEL_H264_QPEL_MC{11..33} flipped to
QPU.  Public dispatchers re-defined via DEFINE_QPEL_DIAG_PUBLIC macro
(replaces the old DEFINE_QPEL_DISPATCH which fast-failed QPU).

Verified on hertz:

  $ ./build/test_api_h264 | grep "qpel mc[1-3][1-3]"
    H.264 qpel mc11: 2048/2048 bytes bit-exact (100.0000%)
    H.264 qpel mc12: 2048/2048 bytes bit-exact (100.0000%)
    H.264 qpel mc13: 2048/2048 bytes bit-exact (100.0000%)
    H.264 qpel mc21: 2048/2048 bytes bit-exact (100.0000%)
    H.264 qpel mc23: 2048/2048 bytes bit-exact (100.0000%)
    H.264 qpel mc31: 2048/2048 bytes bit-exact (100.0000%)
    H.264 qpel mc32: 2048/2048 bytes bit-exact (100.0000%)
    H.264 qpel mc33: 2048/2048 bytes bit-exact (100.0000%)

  Meaningful: the (r±1, c±1) offsets are easy to transpose between
  positions; passing first try on the asymmetric variants (mc13/23/31/33)
  means the position-specific shifts are correct in all 8 templates.

put_ qpel QPU matrix is now COMPLETE: 15 of 15 useful positions
(mc00 = integer copy, no shader needed).  avg_ qpel positions
(15 more) remain on CPU NEON; can land as a follow-up since avg_
is just put_ + one extra L2 against existing dst.

  put_  mc20 ✓  mc02 ✓  mc22 ✓  (anchors)
        mc10 ✓  mc30 ✓  mc01 ✓  mc03 ✓  (single-axis ¼-pel)
        mc11 ✓  mc12 ✓  mc13 ✓  (this PR — row-1 diagonals)
        mc21 ✓                    mc23 ✓  (this PR — row-2 diagonals)
        mc31 ✓  mc32 ✓  mc33 ✓  (this PR — row-3 diagonals)
  avg_  all 15 — CPU NEON
This commit is contained in:
Claude (noether)
2026-05-25 19:14:42 +02:00
parent 224f4be9e2
commit 746533582e
10 changed files with 857 additions and 21 deletions
Download Patch File Download Diff File Expand all files Collapse all files
CMakeLists.txt
+13 -5
View File
@@ -372,10 +372,10 @@ if (DAEDALUS_BUILD_VULKAN)
VERBATIM VERBATIM
) )
# Quarter-pel single-axis variants (mc10/30/01/03) — each is the # Quarter-pel single-axis variants (mc10/30/01/03) + diagonal
# corresponding half-pel filter + L2 average with an integer-source # variants (mc11/12/13/21/23/31/32/33) — each composes 1-2 half-pel
# pixel. Same WG geometry as mc20/mc02. # results with optional L2 averaging. Same WG geometry as mc20/mc02.
foreach(_mc mc10 mc30 mc01 mc03) foreach(_mc mc10 mc30 mc01 mc03 mc11 mc12 mc13 mc21 mc23 mc31 mc32 mc33)
set(_spv ${CMAKE_BINARY_DIR}/v3d_h264_qpel_${_mc}.spv) set(_spv ${CMAKE_BINARY_DIR}/v3d_h264_qpel_${_mc}.spv)
add_custom_command( add_custom_command(
OUTPUT ${_spv} OUTPUT ${_spv}
@@ -389,7 +389,7 @@ if (DAEDALUS_BUILD_VULKAN)
set(H264_QPEL_${_mc}_SPV ${_spv}) set(H264_QPEL_${_mc}_SPV ${_spv})
endforeach() endforeach()
add_custom_target(daedalus_shaders ALL DEPENDS ${NOOP_SPV} ${IDCT8_SPV} ${LPF_SPV} ${MC_SPV} ${LPF8_SPV} ${CDEF_SPV} ${H264DEBLOCK_SPV} ${H264DEBLOCK_H_SPV} ${H264DEBLOCK_CHROMA_V_SPV} ${H264DEBLOCK_CHROMA_H_SPV} ${H264_IDCT4_SPV} ${H264_IDCT8_SPV} ${H264_QPEL_MC20_SPV} ${H264_QPEL_MC02_SPV} ${H264_QPEL_MC22_SPV} ${H264_QPEL_mc10_SPV} ${H264_QPEL_mc30_SPV} ${H264_QPEL_mc01_SPV} ${H264_QPEL_mc03_SPV}) add_custom_target(daedalus_shaders ALL DEPENDS ${NOOP_SPV} ${IDCT8_SPV} ${LPF_SPV} ${MC_SPV} ${LPF8_SPV} ${CDEF_SPV} ${H264DEBLOCK_SPV} ${H264DEBLOCK_H_SPV} ${H264DEBLOCK_CHROMA_V_SPV} ${H264DEBLOCK_CHROMA_H_SPV} ${H264_IDCT4_SPV} ${H264_IDCT8_SPV} ${H264_QPEL_MC20_SPV} ${H264_QPEL_MC02_SPV} ${H264_QPEL_MC22_SPV} ${H264_QPEL_mc10_SPV} ${H264_QPEL_mc30_SPV} ${H264_QPEL_mc01_SPV} ${H264_QPEL_mc03_SPV} ${H264_QPEL_mc11_SPV} ${H264_QPEL_mc12_SPV} ${H264_QPEL_mc13_SPV} ${H264_QPEL_mc21_SPV} ${H264_QPEL_mc23_SPV} ${H264_QPEL_mc31_SPV} ${H264_QPEL_mc32_SPV} ${H264_QPEL_mc33_SPV})
# v3d_runner — reusable Vulkan plumbing. # v3d_runner — reusable Vulkan plumbing.
add_library(v3d_runner STATIC src/v3d_runner.c) add_library(v3d_runner STATIC src/v3d_runner.c)
@@ -534,6 +534,14 @@ if (DAEDALUS_BUILD_VULKAN)
${H264_QPEL_mc30_SPV} ${H264_QPEL_mc30_SPV}
${H264_QPEL_mc01_SPV} ${H264_QPEL_mc01_SPV}
${H264_QPEL_mc03_SPV} ${H264_QPEL_mc03_SPV}
${H264_QPEL_mc11_SPV}
${H264_QPEL_mc12_SPV}
${H264_QPEL_mc13_SPV}
${H264_QPEL_mc21_SPV}
${H264_QPEL_mc23_SPV}
${H264_QPEL_mc31_SPV}
${H264_QPEL_mc32_SPV}
${H264_QPEL_mc33_SPV}
DESTINATION ${CMAKE_INSTALL_DATADIR}/daedalus-fourier/shaders DESTINATION ${CMAKE_INSTALL_DATADIR}/daedalus-fourier/shaders
) )
endif() endif()
src/daedalus_core.c
+140 -16
View File
@@ -64,6 +64,14 @@ struct daedalus_ctx {
v3d_pipeline h264_qpel_mc01_pipe; v3d_pipeline h264_qpel_mc01_pipe;
int h264_qpel_mc03_pipe_ready; int h264_qpel_mc03_pipe_ready;
v3d_pipeline h264_qpel_mc03_pipe; v3d_pipeline h264_qpel_mc03_pipe;
int h264_qpel_mc11_pipe_ready; v3d_pipeline h264_qpel_mc11_pipe;
int h264_qpel_mc12_pipe_ready; v3d_pipeline h264_qpel_mc12_pipe;
int h264_qpel_mc13_pipe_ready; v3d_pipeline h264_qpel_mc13_pipe;
int h264_qpel_mc21_pipe_ready; v3d_pipeline h264_qpel_mc21_pipe;
int h264_qpel_mc23_pipe_ready; v3d_pipeline h264_qpel_mc23_pipe;
int h264_qpel_mc31_pipe_ready; v3d_pipeline h264_qpel_mc31_pipe;
int h264_qpel_mc32_pipe_ready; v3d_pipeline h264_qpel_mc32_pipe;
int h264_qpel_mc33_pipe_ready; v3d_pipeline h264_qpel_mc33_pipe;
}; };
daedalus_ctx *daedalus_ctx_create(void) daedalus_ctx *daedalus_ctx_create(void)
@@ -130,6 +138,14 @@ void daedalus_ctx_destroy(daedalus_ctx *ctx)
if (ctx->h264_qpel_mc30_pipe_ready) v3d_runner_destroy_pipeline(ctx->runner, &ctx->h264_qpel_mc30_pipe); if (ctx->h264_qpel_mc30_pipe_ready) v3d_runner_destroy_pipeline(ctx->runner, &ctx->h264_qpel_mc30_pipe);
if (ctx->h264_qpel_mc01_pipe_ready) v3d_runner_destroy_pipeline(ctx->runner, &ctx->h264_qpel_mc01_pipe); if (ctx->h264_qpel_mc01_pipe_ready) v3d_runner_destroy_pipeline(ctx->runner, &ctx->h264_qpel_mc01_pipe);
if (ctx->h264_qpel_mc03_pipe_ready) v3d_runner_destroy_pipeline(ctx->runner, &ctx->h264_qpel_mc03_pipe); if (ctx->h264_qpel_mc03_pipe_ready) v3d_runner_destroy_pipeline(ctx->runner, &ctx->h264_qpel_mc03_pipe);
if (ctx->h264_qpel_mc11_pipe_ready) v3d_runner_destroy_pipeline(ctx->runner, &ctx->h264_qpel_mc11_pipe);
if (ctx->h264_qpel_mc12_pipe_ready) v3d_runner_destroy_pipeline(ctx->runner, &ctx->h264_qpel_mc12_pipe);
if (ctx->h264_qpel_mc13_pipe_ready) v3d_runner_destroy_pipeline(ctx->runner, &ctx->h264_qpel_mc13_pipe);
if (ctx->h264_qpel_mc21_pipe_ready) v3d_runner_destroy_pipeline(ctx->runner, &ctx->h264_qpel_mc21_pipe);
if (ctx->h264_qpel_mc23_pipe_ready) v3d_runner_destroy_pipeline(ctx->runner, &ctx->h264_qpel_mc23_pipe);
if (ctx->h264_qpel_mc31_pipe_ready) v3d_runner_destroy_pipeline(ctx->runner, &ctx->h264_qpel_mc31_pipe);
if (ctx->h264_qpel_mc32_pipe_ready) v3d_runner_destroy_pipeline(ctx->runner, &ctx->h264_qpel_mc32_pipe);
if (ctx->h264_qpel_mc33_pipe_ready) v3d_runner_destroy_pipeline(ctx->runner, &ctx->h264_qpel_mc33_pipe);
v3d_runner_destroy(ctx->runner); v3d_runner_destroy(ctx->runner);
} }
free(ctx); free(ctx);
@@ -171,14 +187,14 @@ daedalus_substrate daedalus_recipe_substrate_for(daedalus_kernel k)
case DAEDALUS_KERNEL_H264_QPEL_MC30: return DAEDALUS_SUBSTRATE_QPU; /* v3d_h264_qpel_mc30.spv */ case DAEDALUS_KERNEL_H264_QPEL_MC30: return DAEDALUS_SUBSTRATE_QPU; /* v3d_h264_qpel_mc30.spv */
case DAEDALUS_KERNEL_H264_QPEL_MC01: return DAEDALUS_SUBSTRATE_QPU; /* v3d_h264_qpel_mc01.spv */ case DAEDALUS_KERNEL_H264_QPEL_MC01: return DAEDALUS_SUBSTRATE_QPU; /* v3d_h264_qpel_mc01.spv */
case DAEDALUS_KERNEL_H264_QPEL_MC03: return DAEDALUS_SUBSTRATE_QPU; /* v3d_h264_qpel_mc03.spv */ case DAEDALUS_KERNEL_H264_QPEL_MC03: return DAEDALUS_SUBSTRATE_QPU; /* v3d_h264_qpel_mc03.spv */
case DAEDALUS_KERNEL_H264_QPEL_MC11: return DAEDALUS_SUBSTRATE_CPU; /* diagonal ¼¼ */ case DAEDALUS_KERNEL_H264_QPEL_MC11: return DAEDALUS_SUBSTRATE_QPU; /* v3d_h264_qpel_mc11.spv */
case DAEDALUS_KERNEL_H264_QPEL_MC12: return DAEDALUS_SUBSTRATE_CPU; /* diagonal ¼½ */ case DAEDALUS_KERNEL_H264_QPEL_MC12: return DAEDALUS_SUBSTRATE_QPU; /* v3d_h264_qpel_mc12.spv */
case DAEDALUS_KERNEL_H264_QPEL_MC13: return DAEDALUS_SUBSTRATE_CPU; /* diagonal ¼¾ */ case DAEDALUS_KERNEL_H264_QPEL_MC13: return DAEDALUS_SUBSTRATE_QPU; /* v3d_h264_qpel_mc13.spv */
case DAEDALUS_KERNEL_H264_QPEL_MC21: return DAEDALUS_SUBSTRATE_CPU; /* diagonal ½¼ */ case DAEDALUS_KERNEL_H264_QPEL_MC21: return DAEDALUS_SUBSTRATE_QPU; /* v3d_h264_qpel_mc21.spv */
case DAEDALUS_KERNEL_H264_QPEL_MC23: return DAEDALUS_SUBSTRATE_CPU; /* diagonal ½¾ */ case DAEDALUS_KERNEL_H264_QPEL_MC23: return DAEDALUS_SUBSTRATE_QPU; /* v3d_h264_qpel_mc23.spv */
case DAEDALUS_KERNEL_H264_QPEL_MC31: return DAEDALUS_SUBSTRATE_CPU; /* diagonal ¾¼ */ case DAEDALUS_KERNEL_H264_QPEL_MC31: return DAEDALUS_SUBSTRATE_QPU; /* v3d_h264_qpel_mc31.spv */
case DAEDALUS_KERNEL_H264_QPEL_MC32: return DAEDALUS_SUBSTRATE_CPU; /* diagonal ¾½ */ case DAEDALUS_KERNEL_H264_QPEL_MC32: return DAEDALUS_SUBSTRATE_QPU; /* v3d_h264_qpel_mc32.spv */
case DAEDALUS_KERNEL_H264_QPEL_MC33: return DAEDALUS_SUBSTRATE_CPU; /* diagonal ¾¾ */ case DAEDALUS_KERNEL_H264_QPEL_MC33: return DAEDALUS_SUBSTRATE_QPU; /* v3d_h264_qpel_mc33.spv */
case DAEDALUS_KERNEL_H264_QPEL_AVG_MC20: return DAEDALUS_SUBSTRATE_CPU; /* biprediction anchors */ case DAEDALUS_KERNEL_H264_QPEL_AVG_MC20: return DAEDALUS_SUBSTRATE_CPU; /* biprediction anchors */
case DAEDALUS_KERNEL_H264_QPEL_AVG_MC02: return DAEDALUS_SUBSTRATE_CPU; case DAEDALUS_KERNEL_H264_QPEL_AVG_MC02: return DAEDALUS_SUBSTRATE_CPU;
case DAEDALUS_KERNEL_H264_QPEL_AVG_MC22: return DAEDALUS_SUBSTRATE_CPU; case DAEDALUS_KERNEL_H264_QPEL_AVG_MC22: return DAEDALUS_SUBSTRATE_CPU;
@@ -1734,6 +1750,95 @@ DEFINE_QPEL_AXIS_QPU(mc03, "v3d_h264_qpel_mc03.spv", 1)
#undef DEFINE_QPEL_AXIS_QPU #undef DEFINE_QPEL_AXIS_QPU
/* Diagonals share the mc22-style src envelope (rows -2..+10, cols
* -2..+10) because they compose mc22 with mc20/mc02, sometimes
* with (r+1, c) or (r, c+1) offsets. */
static int dispatch_h264_qpel_diag_qpu(daedalus_ctx *ctx,
v3d_pipeline *pipe, int *pipe_ready, const char *spv,
uint8_t *dst, const uint8_t *src, size_t stride,
size_t n_blocks, const daedalus_h264_qpel_meta *meta)
{
if (!*pipe_ready) {
if (v3d_runner_create_pipeline(ctx->runner, spv,
3, sizeof(h264_qpel_mc20_pc), pipe) != 0)
return -1;
*pipe_ready = 1;
}
size_t meta_bytes = n_blocks * 4 * sizeof(uint32_t);
size_t src_max = 0, dst_max = 0;
for (size_t i = 0; i < n_blocks; i++) {
size_t s_end = meta[i].src_off + (size_t) 10 * stride + 11;
size_t d_end = meta[i].dst_off + (size_t) 7 * stride + 8;
if (s_end > src_max) src_max = s_end;
if (d_end > dst_max) dst_max = d_end;
}
v3d_buffer bs = {0}, bd = {0}, bm = {0};
if (v3d_runner_create_buffer(ctx->runner, src_max, &bs)) return -1;
if (v3d_runner_create_buffer(ctx->runner, dst_max, &bd)) {
v3d_runner_destroy_buffer(ctx->runner, &bs); return -1;
}
if (v3d_runner_create_buffer(ctx->runner, meta_bytes, &bm)) {
v3d_runner_destroy_buffer(ctx->runner, &bd);
v3d_runner_destroy_buffer(ctx->runner, &bs); return -1;
}
memcpy(bs.mapped, src, src_max);
memcpy(bd.mapped, dst, dst_max);
uint32_t *m = bm.mapped;
for (size_t i = 0; i < n_blocks; i++) {
m[4*i+0] = meta[i].dst_off;
m[4*i+1] = meta[i].src_off;
m[4*i+2] = 0;
m[4*i+3] = 0;
}
v3d_buffer binds[3] = { bs, bd, bm };
if (v3d_runner_bind_buffers(ctx->runner, pipe, binds, 3)) goto fail;
h264_qpel_mc20_pc pc = { .n_blocks = (uint32_t) n_blocks,
.stride_u8 = (uint32_t) stride };
VkCommandBuffer cb = v3d_runner_alloc_cmdbuf(ctx->runner);
if (cb == VK_NULL_HANDLE) goto fail;
VkCommandBufferBeginInfo cbbi = { .sType = VK_STRUCTURE_TYPE_COMMAND_BUFFER_BEGIN_INFO };
vkBeginCommandBuffer(cb, &cbbi);
vkCmdBindPipeline(cb, VK_PIPELINE_BIND_POINT_COMPUTE, pipe->pipeline);
vkCmdBindDescriptorSets(cb, VK_PIPELINE_BIND_POINT_COMPUTE,
pipe->layout, 0, 1, &pipe->desc_set, 0, NULL);
vkCmdPushConstants(cb, pipe->layout, VK_SHADER_STAGE_COMPUTE_BIT,
0, sizeof(pc), &pc);
vkCmdDispatch(cb, (uint32_t) n_blocks, 1, 1);
vkEndCommandBuffer(cb);
if (v3d_runner_submit_wait(ctx->runner, cb)) goto fail;
memcpy(dst, bd.mapped, dst_max);
v3d_runner_destroy_buffer(ctx->runner, &bm);
v3d_runner_destroy_buffer(ctx->runner, &bd);
v3d_runner_destroy_buffer(ctx->runner, &bs);
return 0;
fail:
v3d_runner_destroy_buffer(ctx->runner, &bm);
v3d_runner_destroy_buffer(ctx->runner, &bd);
v3d_runner_destroy_buffer(ctx->runner, &bs);
return -1;
}
#define DEFINE_QPEL_DIAG_QPU(name) \
static int dispatch_h264_qpel_ ## name ## _qpu(daedalus_ctx *ctx, \
uint8_t *dst, const uint8_t *src, size_t stride, \
size_t n_blocks, const daedalus_h264_qpel_meta *meta) \
{ \
return dispatch_h264_qpel_diag_qpu(ctx, &ctx->h264_qpel_ ## name ## _pipe, \
&ctx->h264_qpel_ ## name ## _pipe_ready, \
"v3d_h264_qpel_" #name ".spv", dst, src, stride, n_blocks, meta); \
}
DEFINE_QPEL_DIAG_QPU(mc11)
DEFINE_QPEL_DIAG_QPU(mc12)
DEFINE_QPEL_DIAG_QPU(mc13)
DEFINE_QPEL_DIAG_QPU(mc21)
DEFINE_QPEL_DIAG_QPU(mc23)
DEFINE_QPEL_DIAG_QPU(mc31)
DEFINE_QPEL_DIAG_QPU(mc32)
DEFINE_QPEL_DIAG_QPU(mc33)
#undef DEFINE_QPEL_DIAG_QPU
/* -------------------- Public dispatch entry points -------------- */ /* -------------------- Public dispatch entry points -------------- */
#define ROUTE_CPU_ONLY(_kernel, _cpu_fn, ...) \ #define ROUTE_CPU_ONLY(_kernel, _cpu_fn, ...) \
@@ -2011,14 +2116,33 @@ DEFINE_QPEL_DISPATCH_QPU(mc30, DAEDALUS_KERNEL_H264_QPEL_MC30)
DEFINE_QPEL_DISPATCH_QPU(mc01, DAEDALUS_KERNEL_H264_QPEL_MC01) DEFINE_QPEL_DISPATCH_QPU(mc01, DAEDALUS_KERNEL_H264_QPEL_MC01)
DEFINE_QPEL_DISPATCH_QPU(mc03, DAEDALUS_KERNEL_H264_QPEL_MC03) DEFINE_QPEL_DISPATCH_QPU(mc03, DAEDALUS_KERNEL_H264_QPEL_MC03)
#undef DEFINE_QPEL_DISPATCH_QPU #undef DEFINE_QPEL_DISPATCH_QPU
DEFINE_QPEL_DISPATCH(mc11, DAEDALUS_KERNEL_H264_QPEL_MC11) /* mc11..mc33 diagonals — QPU-capable, same macro shape as mc10/30/01/03. */
DEFINE_QPEL_DISPATCH(mc12, DAEDALUS_KERNEL_H264_QPEL_MC12) #define DEFINE_QPEL_DIAG_PUBLIC(suffix, kernel) \
DEFINE_QPEL_DISPATCH(mc13, DAEDALUS_KERNEL_H264_QPEL_MC13) int daedalus_dispatch_h264_qpel_ ## suffix(daedalus_ctx *ctx, \
DEFINE_QPEL_DISPATCH(mc21, DAEDALUS_KERNEL_H264_QPEL_MC21) daedalus_substrate sub, uint8_t *dst, const uint8_t *src, size_t stride, \
DEFINE_QPEL_DISPATCH(mc23, DAEDALUS_KERNEL_H264_QPEL_MC23) size_t n_blocks, const daedalus_h264_qpel_meta *meta) \
DEFINE_QPEL_DISPATCH(mc31, DAEDALUS_KERNEL_H264_QPEL_MC31) { \
DEFINE_QPEL_DISPATCH(mc32, DAEDALUS_KERNEL_H264_QPEL_MC32) daedalus_substrate eff = sub; \
DEFINE_QPEL_DISPATCH(mc33, DAEDALUS_KERNEL_H264_QPEL_MC33) if (eff == DAEDALUS_SUBSTRATE_AUTO) \
eff = daedalus_recipe_substrate_for(kernel); \
if (eff == DAEDALUS_SUBSTRATE_QPU && !daedalus_ctx_has_qpu(ctx)) \
eff = DAEDALUS_SUBSTRATE_CPU; \
if (eff == DAEDALUS_SUBSTRATE_CPU) \
return dispatch_h264_qpel_ ## suffix ## _cpu(ctx, dst, src, stride, \
n_blocks, meta); \
return dispatch_h264_qpel_ ## suffix ## _qpu(ctx, dst, src, stride, \
n_blocks, meta); \
}
DEFINE_QPEL_DIAG_PUBLIC(mc11, DAEDALUS_KERNEL_H264_QPEL_MC11)
DEFINE_QPEL_DIAG_PUBLIC(mc12, DAEDALUS_KERNEL_H264_QPEL_MC12)
DEFINE_QPEL_DIAG_PUBLIC(mc13, DAEDALUS_KERNEL_H264_QPEL_MC13)
DEFINE_QPEL_DIAG_PUBLIC(mc21, DAEDALUS_KERNEL_H264_QPEL_MC21)
DEFINE_QPEL_DIAG_PUBLIC(mc23, DAEDALUS_KERNEL_H264_QPEL_MC23)
DEFINE_QPEL_DIAG_PUBLIC(mc31, DAEDALUS_KERNEL_H264_QPEL_MC31)
DEFINE_QPEL_DIAG_PUBLIC(mc32, DAEDALUS_KERNEL_H264_QPEL_MC32)
DEFINE_QPEL_DIAG_PUBLIC(mc33, DAEDALUS_KERNEL_H264_QPEL_MC33)
#undef DEFINE_QPEL_DIAG_PUBLIC
DEFINE_QPEL_DISPATCH(avg_mc20, DAEDALUS_KERNEL_H264_QPEL_AVG_MC20) DEFINE_QPEL_DISPATCH(avg_mc20, DAEDALUS_KERNEL_H264_QPEL_AVG_MC20)
DEFINE_QPEL_DISPATCH(avg_mc02, DAEDALUS_KERNEL_H264_QPEL_AVG_MC02) DEFINE_QPEL_DISPATCH(avg_mc02, DAEDALUS_KERNEL_H264_QPEL_AVG_MC02)
DEFINE_QPEL_DISPATCH(avg_mc22, DAEDALUS_KERNEL_H264_QPEL_AVG_MC22) DEFINE_QPEL_DISPATCH(avg_mc22, DAEDALUS_KERNEL_H264_QPEL_AVG_MC22)
src/v3d_h264_qpel_mc11.comp
+88
View File
@@ -0,0 +1,88 @@
// daedalus-fourier — H.264 luma qpel mc11 (8x8, diagonal quarter-pel),
// V3D 7.1. Per H.264 §8.4.2.2.1 (table 8-4) — composes two half-pel
// anchors via L2 rounded-average:
//
// mc11[r,c] = avg(mc20(r, c),
// mc02(r, c))
//
// Per-lane structure: each lane computes BOTH anchor outputs at its
// own (r, c) target offset, then L2 averages. No shared memory.
// Same WG geometry as the other qpel shaders.
//
// License: BSD-2-Clause.
#version 450
#extension GL_EXT_shader_8bit_storage : require
#extension GL_EXT_shader_explicit_arithmetic_types : require
layout(local_size_x = 64, local_size_y = 1, local_size_z = 1) in;
layout(binding = 0) readonly buffer Src { uint8_t src[]; } u_src;
layout(binding = 1) buffer Dst { uint8_t dst[]; } u_dst;
layout(binding = 2) readonly buffer Meta { uvec4 meta[]; } u_meta;
layout(push_constant) uniform PC { uint n_blocks, stride_u8, _p0, _p1; } pc;
int hpel_h(uint src_off, uint stride, uint r, uint c) {
uint row_base = src_off + r * stride + c;
int s_m2 = int(u_src.src[row_base - 2u]);
int s_m1 = int(u_src.src[row_base - 1u]);
int s_0 = int(u_src.src[row_base ]);
int s_p1 = int(u_src.src[row_base + 1u]);
int s_p2 = int(u_src.src[row_base + 2u]);
int s_p3 = int(u_src.src[row_base + 3u]);
int v = s_m2 - 5*s_m1 + 20*s_0 + 20*s_p1 - 5*s_p2 + s_p3 + 16;
return clamp(v >> 5, 0, 255);
}
int hpel_v(uint src_off, uint stride, uint r, uint c) {
uint col_base = src_off + c;
int s_m2 = int(u_src.src[col_base + (r - 2u) * stride]);
int s_m1 = int(u_src.src[col_base + (r - 1u) * stride]);
int s_0 = int(u_src.src[col_base + r * stride]);
int s_p1 = int(u_src.src[col_base + (r + 1u) * stride]);
int s_p2 = int(u_src.src[col_base + (r + 2u) * stride]);
int s_p3 = int(u_src.src[col_base + (r + 3u) * stride]);
int v = s_m2 - 5*s_m1 + 20*s_0 + 20*s_p1 - 5*s_p2 + s_p3 + 16;
return clamp(v >> 5, 0, 255);
}
int hpel_hv_row(uint src_off, uint stride, uint rr, uint c) {
// Single row's int16 horizontal lowpass (NOT clipped — used as
// intermediate for the vertical pass of hpel_hv).
uint row_base = src_off + rr * stride + c;
int s_m2 = int(u_src.src[row_base - 2u]);
int s_m1 = int(u_src.src[row_base - 1u]);
int s_0 = int(u_src.src[row_base ]);
int s_p1 = int(u_src.src[row_base + 1u]);
int s_p2 = int(u_src.src[row_base + 2u]);
int s_p3 = int(u_src.src[row_base + 3u]);
return s_m2 - 5*s_m1 + 20*s_0 + 20*s_p1 - 5*s_p2 + s_p3;
}
int hpel_hv(uint src_off, uint stride, uint r, uint c) {
int t0 = hpel_hv_row(src_off, stride, r - 2u, c);
int t1 = hpel_hv_row(src_off, stride, r - 1u, c);
int t2 = hpel_hv_row(src_off, stride, r, c);
int t3 = hpel_hv_row(src_off, stride, r + 1u, c);
int t4 = hpel_hv_row(src_off, stride, r + 2u, c);
int t5 = hpel_hv_row(src_off, stride, r + 3u, c);
int v = t0 - 5*t1 + 20*t2 + 20*t3 - 5*t4 + t5 + 512;
return clamp(v >> 10, 0, 255);
}
void main()
{
uint block_idx = gl_WorkGroupID.x;
if (block_idx >= pc.n_blocks) return;
uint lane = gl_LocalInvocationID.x;
uint r = lane >> 3, c = lane & 7u;
uint dst_off = u_meta.meta[block_idx].x;
uint src_off = u_meta.meta[block_idx].y;
uint stride = pc.stride_u8;
int a = hpel_h(src_off, stride, r, c);
int b = hpel_v(src_off, stride, r, c);
int avg = (a + b + 1) >> 1;
u_dst.dst[dst_off + r * stride + c] = uint8_t(avg);
}
src/v3d_h264_qpel_mc12.comp
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// daedalus-fourier — H.264 luma qpel mc12 (8x8, diagonal quarter-pel),
// V3D 7.1. Per H.264 §8.4.2.2.1 (table 8-4) — composes two half-pel
// anchors via L2 rounded-average:
//
// mc12[r,c] = avg(mc22(r, c),
// mc02(r, c))
//
// Per-lane structure: each lane computes BOTH anchor outputs at its
// own (r, c) target offset, then L2 averages. No shared memory.
// Same WG geometry as the other qpel shaders.
//
// License: BSD-2-Clause.
#version 450
#extension GL_EXT_shader_8bit_storage : require
#extension GL_EXT_shader_explicit_arithmetic_types : require
layout(local_size_x = 64, local_size_y = 1, local_size_z = 1) in;
layout(binding = 0) readonly buffer Src { uint8_t src[]; } u_src;
layout(binding = 1) buffer Dst { uint8_t dst[]; } u_dst;
layout(binding = 2) readonly buffer Meta { uvec4 meta[]; } u_meta;
layout(push_constant) uniform PC { uint n_blocks, stride_u8, _p0, _p1; } pc;
int hpel_h(uint src_off, uint stride, uint r, uint c) {
uint row_base = src_off + r * stride + c;
int s_m2 = int(u_src.src[row_base - 2u]);
int s_m1 = int(u_src.src[row_base - 1u]);
int s_0 = int(u_src.src[row_base ]);
int s_p1 = int(u_src.src[row_base + 1u]);
int s_p2 = int(u_src.src[row_base + 2u]);
int s_p3 = int(u_src.src[row_base + 3u]);
int v = s_m2 - 5*s_m1 + 20*s_0 + 20*s_p1 - 5*s_p2 + s_p3 + 16;
return clamp(v >> 5, 0, 255);
}
int hpel_v(uint src_off, uint stride, uint r, uint c) {
uint col_base = src_off + c;
int s_m2 = int(u_src.src[col_base + (r - 2u) * stride]);
int s_m1 = int(u_src.src[col_base + (r - 1u) * stride]);
int s_0 = int(u_src.src[col_base + r * stride]);
int s_p1 = int(u_src.src[col_base + (r + 1u) * stride]);
int s_p2 = int(u_src.src[col_base + (r + 2u) * stride]);
int s_p3 = int(u_src.src[col_base + (r + 3u) * stride]);
int v = s_m2 - 5*s_m1 + 20*s_0 + 20*s_p1 - 5*s_p2 + s_p3 + 16;
return clamp(v >> 5, 0, 255);
}
int hpel_hv_row(uint src_off, uint stride, uint rr, uint c) {
// Single row's int16 horizontal lowpass (NOT clipped — used as
// intermediate for the vertical pass of hpel_hv).
uint row_base = src_off + rr * stride + c;
int s_m2 = int(u_src.src[row_base - 2u]);
int s_m1 = int(u_src.src[row_base - 1u]);
int s_0 = int(u_src.src[row_base ]);
int s_p1 = int(u_src.src[row_base + 1u]);
int s_p2 = int(u_src.src[row_base + 2u]);
int s_p3 = int(u_src.src[row_base + 3u]);
return s_m2 - 5*s_m1 + 20*s_0 + 20*s_p1 - 5*s_p2 + s_p3;
}
int hpel_hv(uint src_off, uint stride, uint r, uint c) {
int t0 = hpel_hv_row(src_off, stride, r - 2u, c);
int t1 = hpel_hv_row(src_off, stride, r - 1u, c);
int t2 = hpel_hv_row(src_off, stride, r, c);
int t3 = hpel_hv_row(src_off, stride, r + 1u, c);
int t4 = hpel_hv_row(src_off, stride, r + 2u, c);
int t5 = hpel_hv_row(src_off, stride, r + 3u, c);
int v = t0 - 5*t1 + 20*t2 + 20*t3 - 5*t4 + t5 + 512;
return clamp(v >> 10, 0, 255);
}
void main()
{
uint block_idx = gl_WorkGroupID.x;
if (block_idx >= pc.n_blocks) return;
uint lane = gl_LocalInvocationID.x;
uint r = lane >> 3, c = lane & 7u;
uint dst_off = u_meta.meta[block_idx].x;
uint src_off = u_meta.meta[block_idx].y;
uint stride = pc.stride_u8;
int a = hpel_hv(src_off, stride, r, c);
int b = hpel_v(src_off, stride, r, c);
int avg = (a + b + 1) >> 1;
u_dst.dst[dst_off + r * stride + c] = uint8_t(avg);
}
src/v3d_h264_qpel_mc13.comp
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// daedalus-fourier — H.264 luma qpel mc13 (8x8, diagonal quarter-pel),
// V3D 7.1. Per H.264 §8.4.2.2.1 (table 8-4) — composes two half-pel
// anchors via L2 rounded-average:
//
// mc13[r,c] = avg(mc20(r+1, c),
// mc02(r, c))
//
// Per-lane structure: each lane computes BOTH anchor outputs at its
// own (r, c) target offset, then L2 averages. No shared memory.
// Same WG geometry as the other qpel shaders.
//
// License: BSD-2-Clause.
#version 450
#extension GL_EXT_shader_8bit_storage : require
#extension GL_EXT_shader_explicit_arithmetic_types : require
layout(local_size_x = 64, local_size_y = 1, local_size_z = 1) in;
layout(binding = 0) readonly buffer Src { uint8_t src[]; } u_src;
layout(binding = 1) buffer Dst { uint8_t dst[]; } u_dst;
layout(binding = 2) readonly buffer Meta { uvec4 meta[]; } u_meta;
layout(push_constant) uniform PC { uint n_blocks, stride_u8, _p0, _p1; } pc;
int hpel_h(uint src_off, uint stride, uint r, uint c) {
uint row_base = src_off + r * stride + c;
int s_m2 = int(u_src.src[row_base - 2u]);
int s_m1 = int(u_src.src[row_base - 1u]);
int s_0 = int(u_src.src[row_base ]);
int s_p1 = int(u_src.src[row_base + 1u]);
int s_p2 = int(u_src.src[row_base + 2u]);
int s_p3 = int(u_src.src[row_base + 3u]);
int v = s_m2 - 5*s_m1 + 20*s_0 + 20*s_p1 - 5*s_p2 + s_p3 + 16;
return clamp(v >> 5, 0, 255);
}
int hpel_v(uint src_off, uint stride, uint r, uint c) {
uint col_base = src_off + c;
int s_m2 = int(u_src.src[col_base + (r - 2u) * stride]);
int s_m1 = int(u_src.src[col_base + (r - 1u) * stride]);
int s_0 = int(u_src.src[col_base + r * stride]);
int s_p1 = int(u_src.src[col_base + (r + 1u) * stride]);
int s_p2 = int(u_src.src[col_base + (r + 2u) * stride]);
int s_p3 = int(u_src.src[col_base + (r + 3u) * stride]);
int v = s_m2 - 5*s_m1 + 20*s_0 + 20*s_p1 - 5*s_p2 + s_p3 + 16;
return clamp(v >> 5, 0, 255);
}
int hpel_hv_row(uint src_off, uint stride, uint rr, uint c) {
// Single row's int16 horizontal lowpass (NOT clipped — used as
// intermediate for the vertical pass of hpel_hv).
uint row_base = src_off + rr * stride + c;
int s_m2 = int(u_src.src[row_base - 2u]);
int s_m1 = int(u_src.src[row_base - 1u]);
int s_0 = int(u_src.src[row_base ]);
int s_p1 = int(u_src.src[row_base + 1u]);
int s_p2 = int(u_src.src[row_base + 2u]);
int s_p3 = int(u_src.src[row_base + 3u]);
return s_m2 - 5*s_m1 + 20*s_0 + 20*s_p1 - 5*s_p2 + s_p3;
}
int hpel_hv(uint src_off, uint stride, uint r, uint c) {
int t0 = hpel_hv_row(src_off, stride, r - 2u, c);
int t1 = hpel_hv_row(src_off, stride, r - 1u, c);
int t2 = hpel_hv_row(src_off, stride, r, c);
int t3 = hpel_hv_row(src_off, stride, r + 1u, c);
int t4 = hpel_hv_row(src_off, stride, r + 2u, c);
int t5 = hpel_hv_row(src_off, stride, r + 3u, c);
int v = t0 - 5*t1 + 20*t2 + 20*t3 - 5*t4 + t5 + 512;
return clamp(v >> 10, 0, 255);
}
void main()
{
uint block_idx = gl_WorkGroupID.x;
if (block_idx >= pc.n_blocks) return;
uint lane = gl_LocalInvocationID.x;
uint r = lane >> 3, c = lane & 7u;
uint dst_off = u_meta.meta[block_idx].x;
uint src_off = u_meta.meta[block_idx].y;
uint stride = pc.stride_u8;
int a = hpel_h(src_off, stride, r+1u, c);
int b = hpel_v(src_off, stride, r, c);
int avg = (a + b + 1) >> 1;
u_dst.dst[dst_off + r * stride + c] = uint8_t(avg);
}
src/v3d_h264_qpel_mc21.comp
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// daedalus-fourier — H.264 luma qpel mc21 (8x8, diagonal quarter-pel),
// V3D 7.1. Per H.264 §8.4.2.2.1 (table 8-4) — composes two half-pel
// anchors via L2 rounded-average:
//
// mc21[r,c] = avg(mc22(r, c),
// mc20(r, c))
//
// Per-lane structure: each lane computes BOTH anchor outputs at its
// own (r, c) target offset, then L2 averages. No shared memory.
// Same WG geometry as the other qpel shaders.
//
// License: BSD-2-Clause.
#version 450
#extension GL_EXT_shader_8bit_storage : require
#extension GL_EXT_shader_explicit_arithmetic_types : require
layout(local_size_x = 64, local_size_y = 1, local_size_z = 1) in;
layout(binding = 0) readonly buffer Src { uint8_t src[]; } u_src;
layout(binding = 1) buffer Dst { uint8_t dst[]; } u_dst;
layout(binding = 2) readonly buffer Meta { uvec4 meta[]; } u_meta;
layout(push_constant) uniform PC { uint n_blocks, stride_u8, _p0, _p1; } pc;
int hpel_h(uint src_off, uint stride, uint r, uint c) {
uint row_base = src_off + r * stride + c;
int s_m2 = int(u_src.src[row_base - 2u]);
int s_m1 = int(u_src.src[row_base - 1u]);
int s_0 = int(u_src.src[row_base ]);
int s_p1 = int(u_src.src[row_base + 1u]);
int s_p2 = int(u_src.src[row_base + 2u]);
int s_p3 = int(u_src.src[row_base + 3u]);
int v = s_m2 - 5*s_m1 + 20*s_0 + 20*s_p1 - 5*s_p2 + s_p3 + 16;
return clamp(v >> 5, 0, 255);
}
int hpel_v(uint src_off, uint stride, uint r, uint c) {
uint col_base = src_off + c;
int s_m2 = int(u_src.src[col_base + (r - 2u) * stride]);
int s_m1 = int(u_src.src[col_base + (r - 1u) * stride]);
int s_0 = int(u_src.src[col_base + r * stride]);
int s_p1 = int(u_src.src[col_base + (r + 1u) * stride]);
int s_p2 = int(u_src.src[col_base + (r + 2u) * stride]);
int s_p3 = int(u_src.src[col_base + (r + 3u) * stride]);
int v = s_m2 - 5*s_m1 + 20*s_0 + 20*s_p1 - 5*s_p2 + s_p3 + 16;
return clamp(v >> 5, 0, 255);
}
int hpel_hv_row(uint src_off, uint stride, uint rr, uint c) {
// Single row's int16 horizontal lowpass (NOT clipped — used as
// intermediate for the vertical pass of hpel_hv).
uint row_base = src_off + rr * stride + c;
int s_m2 = int(u_src.src[row_base - 2u]);
int s_m1 = int(u_src.src[row_base - 1u]);
int s_0 = int(u_src.src[row_base ]);
int s_p1 = int(u_src.src[row_base + 1u]);
int s_p2 = int(u_src.src[row_base + 2u]);
int s_p3 = int(u_src.src[row_base + 3u]);
return s_m2 - 5*s_m1 + 20*s_0 + 20*s_p1 - 5*s_p2 + s_p3;
}
int hpel_hv(uint src_off, uint stride, uint r, uint c) {
int t0 = hpel_hv_row(src_off, stride, r - 2u, c);
int t1 = hpel_hv_row(src_off, stride, r - 1u, c);
int t2 = hpel_hv_row(src_off, stride, r, c);
int t3 = hpel_hv_row(src_off, stride, r + 1u, c);
int t4 = hpel_hv_row(src_off, stride, r + 2u, c);
int t5 = hpel_hv_row(src_off, stride, r + 3u, c);
int v = t0 - 5*t1 + 20*t2 + 20*t3 - 5*t4 + t5 + 512;
return clamp(v >> 10, 0, 255);
}
void main()
{
uint block_idx = gl_WorkGroupID.x;
if (block_idx >= pc.n_blocks) return;
uint lane = gl_LocalInvocationID.x;
uint r = lane >> 3, c = lane & 7u;
uint dst_off = u_meta.meta[block_idx].x;
uint src_off = u_meta.meta[block_idx].y;
uint stride = pc.stride_u8;
int a = hpel_hv(src_off, stride, r, c);
int b = hpel_h(src_off, stride, r, c);
int avg = (a + b + 1) >> 1;
u_dst.dst[dst_off + r * stride + c] = uint8_t(avg);
}
src/v3d_h264_qpel_mc23.comp
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// daedalus-fourier — H.264 luma qpel mc23 (8x8, diagonal quarter-pel),
// V3D 7.1. Per H.264 §8.4.2.2.1 (table 8-4) — composes two half-pel
// anchors via L2 rounded-average:
//
// mc23[r,c] = avg(mc22(r, c),
// mc20(r+1, c))
//
// Per-lane structure: each lane computes BOTH anchor outputs at its
// own (r, c) target offset, then L2 averages. No shared memory.
// Same WG geometry as the other qpel shaders.
//
// License: BSD-2-Clause.
#version 450
#extension GL_EXT_shader_8bit_storage : require
#extension GL_EXT_shader_explicit_arithmetic_types : require
layout(local_size_x = 64, local_size_y = 1, local_size_z = 1) in;
layout(binding = 0) readonly buffer Src { uint8_t src[]; } u_src;
layout(binding = 1) buffer Dst { uint8_t dst[]; } u_dst;
layout(binding = 2) readonly buffer Meta { uvec4 meta[]; } u_meta;
layout(push_constant) uniform PC { uint n_blocks, stride_u8, _p0, _p1; } pc;
int hpel_h(uint src_off, uint stride, uint r, uint c) {
uint row_base = src_off + r * stride + c;
int s_m2 = int(u_src.src[row_base - 2u]);
int s_m1 = int(u_src.src[row_base - 1u]);
int s_0 = int(u_src.src[row_base ]);
int s_p1 = int(u_src.src[row_base + 1u]);
int s_p2 = int(u_src.src[row_base + 2u]);
int s_p3 = int(u_src.src[row_base + 3u]);
int v = s_m2 - 5*s_m1 + 20*s_0 + 20*s_p1 - 5*s_p2 + s_p3 + 16;
return clamp(v >> 5, 0, 255);
}
int hpel_v(uint src_off, uint stride, uint r, uint c) {
uint col_base = src_off + c;
int s_m2 = int(u_src.src[col_base + (r - 2u) * stride]);
int s_m1 = int(u_src.src[col_base + (r - 1u) * stride]);
int s_0 = int(u_src.src[col_base + r * stride]);
int s_p1 = int(u_src.src[col_base + (r + 1u) * stride]);
int s_p2 = int(u_src.src[col_base + (r + 2u) * stride]);
int s_p3 = int(u_src.src[col_base + (r + 3u) * stride]);
int v = s_m2 - 5*s_m1 + 20*s_0 + 20*s_p1 - 5*s_p2 + s_p3 + 16;
return clamp(v >> 5, 0, 255);
}
int hpel_hv_row(uint src_off, uint stride, uint rr, uint c) {
// Single row's int16 horizontal lowpass (NOT clipped — used as
// intermediate for the vertical pass of hpel_hv).
uint row_base = src_off + rr * stride + c;
int s_m2 = int(u_src.src[row_base - 2u]);
int s_m1 = int(u_src.src[row_base - 1u]);
int s_0 = int(u_src.src[row_base ]);
int s_p1 = int(u_src.src[row_base + 1u]);
int s_p2 = int(u_src.src[row_base + 2u]);
int s_p3 = int(u_src.src[row_base + 3u]);
return s_m2 - 5*s_m1 + 20*s_0 + 20*s_p1 - 5*s_p2 + s_p3;
}
int hpel_hv(uint src_off, uint stride, uint r, uint c) {
int t0 = hpel_hv_row(src_off, stride, r - 2u, c);
int t1 = hpel_hv_row(src_off, stride, r - 1u, c);
int t2 = hpel_hv_row(src_off, stride, r, c);
int t3 = hpel_hv_row(src_off, stride, r + 1u, c);
int t4 = hpel_hv_row(src_off, stride, r + 2u, c);
int t5 = hpel_hv_row(src_off, stride, r + 3u, c);
int v = t0 - 5*t1 + 20*t2 + 20*t3 - 5*t4 + t5 + 512;
return clamp(v >> 10, 0, 255);
}
void main()
{
uint block_idx = gl_WorkGroupID.x;
if (block_idx >= pc.n_blocks) return;
uint lane = gl_LocalInvocationID.x;
uint r = lane >> 3, c = lane & 7u;
uint dst_off = u_meta.meta[block_idx].x;
uint src_off = u_meta.meta[block_idx].y;
uint stride = pc.stride_u8;
int a = hpel_hv(src_off, stride, r, c);
int b = hpel_h(src_off, stride, r+1u, c);
int avg = (a + b + 1) >> 1;
u_dst.dst[dst_off + r * stride + c] = uint8_t(avg);
}
src/v3d_h264_qpel_mc31.comp
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// daedalus-fourier — H.264 luma qpel mc31 (8x8, diagonal quarter-pel),
// V3D 7.1. Per H.264 §8.4.2.2.1 (table 8-4) — composes two half-pel
// anchors via L2 rounded-average:
//
// mc31[r,c] = avg(mc20(r, c),
// mc02(r, c+1))
//
// Per-lane structure: each lane computes BOTH anchor outputs at its
// own (r, c) target offset, then L2 averages. No shared memory.
// Same WG geometry as the other qpel shaders.
//
// License: BSD-2-Clause.
#version 450
#extension GL_EXT_shader_8bit_storage : require
#extension GL_EXT_shader_explicit_arithmetic_types : require
layout(local_size_x = 64, local_size_y = 1, local_size_z = 1) in;
layout(binding = 0) readonly buffer Src { uint8_t src[]; } u_src;
layout(binding = 1) buffer Dst { uint8_t dst[]; } u_dst;
layout(binding = 2) readonly buffer Meta { uvec4 meta[]; } u_meta;
layout(push_constant) uniform PC { uint n_blocks, stride_u8, _p0, _p1; } pc;
int hpel_h(uint src_off, uint stride, uint r, uint c) {
uint row_base = src_off + r * stride + c;
int s_m2 = int(u_src.src[row_base - 2u]);
int s_m1 = int(u_src.src[row_base - 1u]);
int s_0 = int(u_src.src[row_base ]);
int s_p1 = int(u_src.src[row_base + 1u]);
int s_p2 = int(u_src.src[row_base + 2u]);
int s_p3 = int(u_src.src[row_base + 3u]);
int v = s_m2 - 5*s_m1 + 20*s_0 + 20*s_p1 - 5*s_p2 + s_p3 + 16;
return clamp(v >> 5, 0, 255);
}
int hpel_v(uint src_off, uint stride, uint r, uint c) {
uint col_base = src_off + c;
int s_m2 = int(u_src.src[col_base + (r - 2u) * stride]);
int s_m1 = int(u_src.src[col_base + (r - 1u) * stride]);
int s_0 = int(u_src.src[col_base + r * stride]);
int s_p1 = int(u_src.src[col_base + (r + 1u) * stride]);
int s_p2 = int(u_src.src[col_base + (r + 2u) * stride]);
int s_p3 = int(u_src.src[col_base + (r + 3u) * stride]);
int v = s_m2 - 5*s_m1 + 20*s_0 + 20*s_p1 - 5*s_p2 + s_p3 + 16;
return clamp(v >> 5, 0, 255);
}
int hpel_hv_row(uint src_off, uint stride, uint rr, uint c) {
// Single row's int16 horizontal lowpass (NOT clipped — used as
// intermediate for the vertical pass of hpel_hv).
uint row_base = src_off + rr * stride + c;
int s_m2 = int(u_src.src[row_base - 2u]);
int s_m1 = int(u_src.src[row_base - 1u]);
int s_0 = int(u_src.src[row_base ]);
int s_p1 = int(u_src.src[row_base + 1u]);
int s_p2 = int(u_src.src[row_base + 2u]);
int s_p3 = int(u_src.src[row_base + 3u]);
return s_m2 - 5*s_m1 + 20*s_0 + 20*s_p1 - 5*s_p2 + s_p3;
}
int hpel_hv(uint src_off, uint stride, uint r, uint c) {
int t0 = hpel_hv_row(src_off, stride, r - 2u, c);
int t1 = hpel_hv_row(src_off, stride, r - 1u, c);
int t2 = hpel_hv_row(src_off, stride, r, c);
int t3 = hpel_hv_row(src_off, stride, r + 1u, c);
int t4 = hpel_hv_row(src_off, stride, r + 2u, c);
int t5 = hpel_hv_row(src_off, stride, r + 3u, c);
int v = t0 - 5*t1 + 20*t2 + 20*t3 - 5*t4 + t5 + 512;
return clamp(v >> 10, 0, 255);
}
void main()
{
uint block_idx = gl_WorkGroupID.x;
if (block_idx >= pc.n_blocks) return;
uint lane = gl_LocalInvocationID.x;
uint r = lane >> 3, c = lane & 7u;
uint dst_off = u_meta.meta[block_idx].x;
uint src_off = u_meta.meta[block_idx].y;
uint stride = pc.stride_u8;
int a = hpel_h(src_off, stride, r, c);
int b = hpel_v(src_off, stride, r, c+1u);
int avg = (a + b + 1) >> 1;
u_dst.dst[dst_off + r * stride + c] = uint8_t(avg);
}
src/v3d_h264_qpel_mc32.comp
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// daedalus-fourier — H.264 luma qpel mc32 (8x8, diagonal quarter-pel),
// V3D 7.1. Per H.264 §8.4.2.2.1 (table 8-4) — composes two half-pel
// anchors via L2 rounded-average:
//
// mc32[r,c] = avg(mc22(r, c),
// mc02(r, c+1))
//
// Per-lane structure: each lane computes BOTH anchor outputs at its
// own (r, c) target offset, then L2 averages. No shared memory.
// Same WG geometry as the other qpel shaders.
//
// License: BSD-2-Clause.
#version 450
#extension GL_EXT_shader_8bit_storage : require
#extension GL_EXT_shader_explicit_arithmetic_types : require
layout(local_size_x = 64, local_size_y = 1, local_size_z = 1) in;
layout(binding = 0) readonly buffer Src { uint8_t src[]; } u_src;
layout(binding = 1) buffer Dst { uint8_t dst[]; } u_dst;
layout(binding = 2) readonly buffer Meta { uvec4 meta[]; } u_meta;
layout(push_constant) uniform PC { uint n_blocks, stride_u8, _p0, _p1; } pc;
int hpel_h(uint src_off, uint stride, uint r, uint c) {
uint row_base = src_off + r * stride + c;
int s_m2 = int(u_src.src[row_base - 2u]);
int s_m1 = int(u_src.src[row_base - 1u]);
int s_0 = int(u_src.src[row_base ]);
int s_p1 = int(u_src.src[row_base + 1u]);
int s_p2 = int(u_src.src[row_base + 2u]);
int s_p3 = int(u_src.src[row_base + 3u]);
int v = s_m2 - 5*s_m1 + 20*s_0 + 20*s_p1 - 5*s_p2 + s_p3 + 16;
return clamp(v >> 5, 0, 255);
}
int hpel_v(uint src_off, uint stride, uint r, uint c) {
uint col_base = src_off + c;
int s_m2 = int(u_src.src[col_base + (r - 2u) * stride]);
int s_m1 = int(u_src.src[col_base + (r - 1u) * stride]);
int s_0 = int(u_src.src[col_base + r * stride]);
int s_p1 = int(u_src.src[col_base + (r + 1u) * stride]);
int s_p2 = int(u_src.src[col_base + (r + 2u) * stride]);
int s_p3 = int(u_src.src[col_base + (r + 3u) * stride]);
int v = s_m2 - 5*s_m1 + 20*s_0 + 20*s_p1 - 5*s_p2 + s_p3 + 16;
return clamp(v >> 5, 0, 255);
}
int hpel_hv_row(uint src_off, uint stride, uint rr, uint c) {
// Single row's int16 horizontal lowpass (NOT clipped — used as
// intermediate for the vertical pass of hpel_hv).
uint row_base = src_off + rr * stride + c;
int s_m2 = int(u_src.src[row_base - 2u]);
int s_m1 = int(u_src.src[row_base - 1u]);
int s_0 = int(u_src.src[row_base ]);
int s_p1 = int(u_src.src[row_base + 1u]);
int s_p2 = int(u_src.src[row_base + 2u]);
int s_p3 = int(u_src.src[row_base + 3u]);
return s_m2 - 5*s_m1 + 20*s_0 + 20*s_p1 - 5*s_p2 + s_p3;
}
int hpel_hv(uint src_off, uint stride, uint r, uint c) {
int t0 = hpel_hv_row(src_off, stride, r - 2u, c);
int t1 = hpel_hv_row(src_off, stride, r - 1u, c);
int t2 = hpel_hv_row(src_off, stride, r, c);
int t3 = hpel_hv_row(src_off, stride, r + 1u, c);
int t4 = hpel_hv_row(src_off, stride, r + 2u, c);
int t5 = hpel_hv_row(src_off, stride, r + 3u, c);
int v = t0 - 5*t1 + 20*t2 + 20*t3 - 5*t4 + t5 + 512;
return clamp(v >> 10, 0, 255);
}
void main()
{
uint block_idx = gl_WorkGroupID.x;
if (block_idx >= pc.n_blocks) return;
uint lane = gl_LocalInvocationID.x;
uint r = lane >> 3, c = lane & 7u;
uint dst_off = u_meta.meta[block_idx].x;
uint src_off = u_meta.meta[block_idx].y;
uint stride = pc.stride_u8;
int a = hpel_hv(src_off, stride, r, c);
int b = hpel_v(src_off, stride, r, c+1u);
int avg = (a + b + 1) >> 1;
u_dst.dst[dst_off + r * stride + c] = uint8_t(avg);
}
src/v3d_h264_qpel_mc33.comp
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// daedalus-fourier — H.264 luma qpel mc33 (8x8, diagonal quarter-pel),
// V3D 7.1. Per H.264 §8.4.2.2.1 (table 8-4) — composes two half-pel
// anchors via L2 rounded-average:
//
// mc33[r,c] = avg(mc20(r+1, c),
// mc02(r, c+1))
//
// Per-lane structure: each lane computes BOTH anchor outputs at its
// own (r, c) target offset, then L2 averages. No shared memory.
// Same WG geometry as the other qpel shaders.
//
// License: BSD-2-Clause.
#version 450
#extension GL_EXT_shader_8bit_storage : require
#extension GL_EXT_shader_explicit_arithmetic_types : require
layout(local_size_x = 64, local_size_y = 1, local_size_z = 1) in;
layout(binding = 0) readonly buffer Src { uint8_t src[]; } u_src;
layout(binding = 1) buffer Dst { uint8_t dst[]; } u_dst;
layout(binding = 2) readonly buffer Meta { uvec4 meta[]; } u_meta;
layout(push_constant) uniform PC { uint n_blocks, stride_u8, _p0, _p1; } pc;
int hpel_h(uint src_off, uint stride, uint r, uint c) {
uint row_base = src_off + r * stride + c;
int s_m2 = int(u_src.src[row_base - 2u]);
int s_m1 = int(u_src.src[row_base - 1u]);
int s_0 = int(u_src.src[row_base ]);
int s_p1 = int(u_src.src[row_base + 1u]);
int s_p2 = int(u_src.src[row_base + 2u]);
int s_p3 = int(u_src.src[row_base + 3u]);
int v = s_m2 - 5*s_m1 + 20*s_0 + 20*s_p1 - 5*s_p2 + s_p3 + 16;
return clamp(v >> 5, 0, 255);
}
int hpel_v(uint src_off, uint stride, uint r, uint c) {
uint col_base = src_off + c;
int s_m2 = int(u_src.src[col_base + (r - 2u) * stride]);
int s_m1 = int(u_src.src[col_base + (r - 1u) * stride]);
int s_0 = int(u_src.src[col_base + r * stride]);
int s_p1 = int(u_src.src[col_base + (r + 1u) * stride]);
int s_p2 = int(u_src.src[col_base + (r + 2u) * stride]);
int s_p3 = int(u_src.src[col_base + (r + 3u) * stride]);
int v = s_m2 - 5*s_m1 + 20*s_0 + 20*s_p1 - 5*s_p2 + s_p3 + 16;
return clamp(v >> 5, 0, 255);
}
int hpel_hv_row(uint src_off, uint stride, uint rr, uint c) {
// Single row's int16 horizontal lowpass (NOT clipped — used as
// intermediate for the vertical pass of hpel_hv).
uint row_base = src_off + rr * stride + c;
int s_m2 = int(u_src.src[row_base - 2u]);
int s_m1 = int(u_src.src[row_base - 1u]);
int s_0 = int(u_src.src[row_base ]);
int s_p1 = int(u_src.src[row_base + 1u]);
int s_p2 = int(u_src.src[row_base + 2u]);
int s_p3 = int(u_src.src[row_base + 3u]);
return s_m2 - 5*s_m1 + 20*s_0 + 20*s_p1 - 5*s_p2 + s_p3;
}
int hpel_hv(uint src_off, uint stride, uint r, uint c) {
int t0 = hpel_hv_row(src_off, stride, r - 2u, c);
int t1 = hpel_hv_row(src_off, stride, r - 1u, c);
int t2 = hpel_hv_row(src_off, stride, r, c);
int t3 = hpel_hv_row(src_off, stride, r + 1u, c);
int t4 = hpel_hv_row(src_off, stride, r + 2u, c);
int t5 = hpel_hv_row(src_off, stride, r + 3u, c);
int v = t0 - 5*t1 + 20*t2 + 20*t3 - 5*t4 + t5 + 512;
return clamp(v >> 10, 0, 255);
}
void main()
{
uint block_idx = gl_WorkGroupID.x;
if (block_idx >= pc.n_blocks) return;
uint lane = gl_LocalInvocationID.x;
uint r = lane >> 3, c = lane & 7u;
uint dst_off = u_meta.meta[block_idx].x;
uint src_off = u_meta.meta[block_idx].y;
uint stride = pc.stride_u8;
int a = hpel_h(src_off, stride, r+1u, c);
int b = hpel_v(src_off, stride, r, c+1u);
int avg = (a + b + 1) >> 1;
u_dst.dst[dst_off + r * stride + c] = uint8_t(avg);
}