FFmpeg/libavcodec/riscv/h264dsp_init.c

/*
 * Copyright © 2024 Rémi Denis-Courmont.
 *
 * This file is part of FFmpeg.
 *
 * FFmpeg is free software; you can redistribute it and/or
 * modify it under the terms of the GNU Lesser General Public
 * License as published by the Free Software Foundation; either
 * version 2.1 of the License, or (at your option) any later version.
 *
 * FFmpeg is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
 * Lesser General Public License for more details.
 *
 * You should have received a copy of the GNU Lesser General Public
 * License along with FFmpeg; if not, write to the Free Software
 * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
 */

#include "config.h"

#include <stdint.h>
#include <string.h>

#include "libavutil/attributes.h"
#include "libavutil/cpu.h"
#include "libavutil/riscv/cpu.h"
#include "libavcodec/h264dsp.h"

extern const struct {
    const h264_weight_func weight;
    const h264_biweight_func biweight;
} ff_h264_weight_funcs_8_rvv[];

void ff_h264_v_loop_filter_luma_8_rvv(uint8_t *pix, ptrdiff_t stride,
                                      int alpha, int beta, int8_t *tc0);
void ff_h264_h_loop_filter_luma_8_rvv(uint8_t *pix, ptrdiff_t stride,
                                      int alpha, int beta, int8_t *tc0);
void ff_h264_h_loop_filter_luma_mbaff_8_rvv(uint8_t *pix, ptrdiff_t stride,
                                            int alpha, int beta, int8_t *tc0);

void ff_h264_idct_add_8_rvv(uint8_t *dst, int16_t *block, int stride);
void ff_h264_idct8_add_8_rvv(uint8_t *dst, int16_t *block, int stride);
void ff_h264_idct_add16_8_rvv(uint8_t *dst, const int *blockoffset,
                              int16_t *block, int stride,
                              const uint8_t nnzc[5 * 8]);
void ff_h264_idct_add16intra_8_rvv(uint8_t *dst, const int *blockoffset,
                                   int16_t *block, int stride,
                                   const uint8_t nnzc[5 * 8]);
void ff_h264_idct8_add4_8_rvv(uint8_t *dst, const int *blockoffset,
                              int16_t *block, int stride,
                              const uint8_t nnzc[5 * 8]);

void ff_h264_idct_add_9_rvv(uint8_t *dst, int16_t *block, int stride);
void ff_h264_idct_add_10_rvv(uint8_t *dst, int16_t *block, int stride);
void ff_h264_idct_add_12_rvv(uint8_t *dst, int16_t *block, int stride);
void ff_h264_idct_add_14_rvv(uint8_t *dst, int16_t *block, int stride);

extern int ff_startcode_find_candidate_rvb(const uint8_t *, int);
extern int ff_startcode_find_candidate_rvv(const uint8_t *, int);

av_cold void ff_h264dsp_init_riscv(H264DSPContext *dsp, const int bit_depth,
                                   const int chroma_format_idc)
{
#if HAVE_RV
    int flags = av_get_cpu_flags();

    if (flags & AV_CPU_FLAG_RVB_BASIC)
        dsp->startcode_find_candidate = ff_startcode_find_candidate_rvb;
# if HAVE_RVV
    if (flags & AV_CPU_FLAG_RVV_I32) {
        const bool zvl128b = ff_rv_vlen_least(128);

        if (bit_depth == 8 && zvl128b) {
            for (int i = 0; i < 4; i++) {
                dsp->weight_h264_pixels_tab[i] =
                    ff_h264_weight_funcs_8_rvv[i].weight;
                dsp->biweight_h264_pixels_tab[i] =
                    ff_h264_weight_funcs_8_rvv[i].biweight;
            }

            dsp->h264_v_loop_filter_luma = ff_h264_v_loop_filter_luma_8_rvv;
            dsp->h264_h_loop_filter_luma = ff_h264_h_loop_filter_luma_8_rvv;
            dsp->h264_h_loop_filter_luma_mbaff =
                ff_h264_h_loop_filter_luma_mbaff_8_rvv;

            dsp->h264_idct_add = ff_h264_idct_add_8_rvv;
            dsp->h264_idct8_add = ff_h264_idct8_add_8_rvv;
#  if __riscv_xlen == 64
            dsp->h264_idct_add16 = ff_h264_idct_add16_8_rvv;
            dsp->h264_idct_add16intra = ff_h264_idct_add16intra_8_rvv;
            dsp->h264_idct8_add4 = ff_h264_idct8_add4_8_rvv;
#  endif
        }

        if (bit_depth == 9 && zvl128b)
            dsp->h264_idct_add = ff_h264_idct_add_9_rvv;
        if (bit_depth == 10 && zvl128b)
            dsp->h264_idct_add = ff_h264_idct_add_10_rvv;
        if (bit_depth == 12 && zvl128b)
            dsp->h264_idct_add = ff_h264_idct_add_12_rvv;
        if (bit_depth == 14 && zvl128b)
            dsp->h264_idct_add = ff_h264_idct_add_14_rvv;

        dsp->startcode_find_candidate = ff_startcode_find_candidate_rvv;
    }
# endif
#endif
}
lavc/startcode: add R-V Zbb startcode_find_candidate The main loop processes 8 bytes in 5 instructions. For comparison, the optimal plain strnlen() requires 4 instructions per byte (6.4x worse): LBU; ADDI; BEQZ; BNE. The current libavcodec C code involves 5 instructions per byte (8x worse). Actual benchmarks may be slightly less favourable due to latency from ORC.B to BNE. 2024-05-16 14:13:22 +00:00			`/*`
			`* Copyright © 2024 Rémi Denis-Courmont.`
			`*`
			`* This file is part of FFmpeg.`
			`*`
			`* FFmpeg is free software; you can redistribute it and/or`
			`* modify it under the terms of the GNU Lesser General Public`
			`* License as published by the Free Software Foundation; either`
			`* version 2.1 of the License, or (at your option) any later version.`
			`*`
			`* FFmpeg is distributed in the hope that it will be useful,`
			`* but WITHOUT ANY WARRANTY; without even the implied warranty of`
			`* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU`
			`* Lesser General Public License for more details.`
			`*`
			`* You should have received a copy of the GNU Lesser General Public`
			`* License along with FFmpeg; if not, write to the Free Software`
			`* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA`
			`*/`

			`#include "config.h"`

			`#include <stdint.h>`
lavc/h264dsp: R-V V 8-bit h264_weight_pixels There are two implementations here: - a generic scalable one processing two columns at a time, - a specialised processing one (fixed-size) row at a time. Unsurprisingly, the generic one works out better with smaller widths. With larger widths, the gains from filling vectors are outweighed by the extra cost of strided loads and stores. In other words, memory accesses become the bottleneck. T-Head C908: h264_weight2_8_c: 54.5 h264_weight2_8_rvv_i32: 13.7 h264_weight4_8_c: 101.7 h264_weight4_8_rvv_i32: 27.5 h264_weight8_8_c: 197.0 h264_weight8_8_rvv_i32: 75.5 h264_weight16_8_c: 385.0 h264_weight16_8_rvv_i32: 74.2 SpacemiT X60: h264_weight2_8_c: 48.5 h264_weight2_8_rvv_i32: 8.2 h264_weight4_8_c: 90.7 h264_weight4_8_rvv_i32: 16.5 h264_weight8_8_c: 175.0 h264_weight8_8_rvv_i32: 37.7 h264_weight16_8_c: 342.2 h264_weight16_8_rvv_i32: 66.0 2024-07-04 18:38:48 +00:00			`#include <string.h>`
lavc/startcode: add R-V Zbb startcode_find_candidate The main loop processes 8 bytes in 5 instructions. For comparison, the optimal plain strnlen() requires 4 instructions per byte (6.4x worse): LBU; ADDI; BEQZ; BNE. The current libavcodec C code involves 5 instructions per byte (8x worse). Actual benchmarks may be slightly less favourable due to latency from ORC.B to BNE. 2024-05-16 14:13:22 +00:00
			`#include "libavutil/attributes.h"`
			`#include "libavutil/cpu.h"`
lavc/h264dsp: R-V V 8-bit luma loop filter T-Head C908 (cycles): h264_h_loop_filter_luma_8bpp_c: 297.5 h264_h_loop_filter_luma_8bpp_rvv_i32: 369.2 h264_v_loop_filter_luma_8bpp_c: 862.7 h264_v_loop_filter_luma_8bpp_rvv_i32: 199.7 Performance in the horizontal scenario seems worse than scalar. x86 SSE2 and AVX optimisations are similarly affected. This is presumably caused by unlucky inputs from checkasm, such that the C code short-circuits almost all filter calculations. 2024-06-28 18:56:12 +00:00			`#include "libavutil/riscv/cpu.h"`
lavc/startcode: add R-V Zbb startcode_find_candidate The main loop processes 8 bytes in 5 instructions. For comparison, the optimal plain strnlen() requires 4 instructions per byte (6.4x worse): LBU; ADDI; BEQZ; BNE. The current libavcodec C code involves 5 instructions per byte (8x worse). Actual benchmarks may be slightly less favourable due to latency from ORC.B to BNE. 2024-05-16 14:13:22 +00:00			`#include "libavcodec/h264dsp.h"`

lavc/h264dsp: R-V V 8-bit h264_biweight_pixels T-Head C908: h264_biweight2_8_c: 58.0 h264_biweight2_8_rvv_i32: 11.2 h264_biweight4_8_c: 106.0 h264_biweight4_8_rvv_i32: 22.7 h264_biweight8_8_c: 205.7 h264_biweight8_8_rvv_i32: 50.0 h264_biweight16_8_c: 403.5 h264_biweight16_8_rvv_i32: 83.2 SpacemiT X60: h264_weight2_8_c: 48.2 h264_weight2_8_rvv_i32: 8.2 h264_weight4_8_c: 90.5 h264_weight4_8_rvv_i32: 16.5 h264_weight8_8_c: 175.2 h264_weight8_8_rvv_i32: 38.0 h264_weight16_8_c: 342.2 h264_weight16_8_rvv_i32: 66.0 2024-07-05 20:03:28 +00:00			`extern const struct {`
			`const h264_weight_func weight;`
			`const h264_biweight_func biweight;`
			`} ff_h264_weight_funcs_8_rvv[];`
lavc/h264dsp: R-V V 8-bit h264_weight_pixels There are two implementations here: - a generic scalable one processing two columns at a time, - a specialised processing one (fixed-size) row at a time. Unsurprisingly, the generic one works out better with smaller widths. With larger widths, the gains from filling vectors are outweighed by the extra cost of strided loads and stores. In other words, memory accesses become the bottleneck. T-Head C908: h264_weight2_8_c: 54.5 h264_weight2_8_rvv_i32: 13.7 h264_weight4_8_c: 101.7 h264_weight4_8_rvv_i32: 27.5 h264_weight8_8_c: 197.0 h264_weight8_8_rvv_i32: 75.5 h264_weight16_8_c: 385.0 h264_weight16_8_rvv_i32: 74.2 SpacemiT X60: h264_weight2_8_c: 48.5 h264_weight2_8_rvv_i32: 8.2 h264_weight4_8_c: 90.7 h264_weight4_8_rvv_i32: 16.5 h264_weight8_8_c: 175.0 h264_weight8_8_rvv_i32: 37.7 h264_weight16_8_c: 342.2 h264_weight16_8_rvv_i32: 66.0 2024-07-04 18:38:48 +00:00
lavc/h264dsp: R-V V 8-bit luma loop filter T-Head C908 (cycles): h264_h_loop_filter_luma_8bpp_c: 297.5 h264_h_loop_filter_luma_8bpp_rvv_i32: 369.2 h264_v_loop_filter_luma_8bpp_c: 862.7 h264_v_loop_filter_luma_8bpp_rvv_i32: 199.7 Performance in the horizontal scenario seems worse than scalar. x86 SSE2 and AVX optimisations are similarly affected. This is presumably caused by unlucky inputs from checkasm, such that the C code short-circuits almost all filter calculations. 2024-06-28 18:56:12 +00:00			`void ff_h264_v_loop_filter_luma_8_rvv(uint8_t *pix, ptrdiff_t stride,`
			`int alpha, int beta, int8_t *tc0);`
			`void ff_h264_h_loop_filter_luma_8_rvv(uint8_t *pix, ptrdiff_t stride,`
			`int alpha, int beta, int8_t *tc0);`
lavc/h264dsp: R-V V 8-bit MBAFF loop filter Performance is (unfortunately) the same as with non-MBAFF, since the hardware under test does not short-circuit vector tail calculations. (IMO, a generic solution or work-around should be agreed on, rather than bespoke approaches all over the place.) 2024-06-30 08:24:43 +00:00			`void ff_h264_h_loop_filter_luma_mbaff_8_rvv(uint8_t *pix, ptrdiff_t stride,`
			`int alpha, int beta, int8_t *tc0);`
lavc/h264dsp: R-V V 8-bit luma loop filter T-Head C908 (cycles): h264_h_loop_filter_luma_8bpp_c: 297.5 h264_h_loop_filter_luma_8bpp_rvv_i32: 369.2 h264_v_loop_filter_luma_8bpp_c: 862.7 h264_v_loop_filter_luma_8bpp_rvv_i32: 199.7 Performance in the horizontal scenario seems worse than scalar. x86 SSE2 and AVX optimisations are similarly affected. This is presumably caused by unlucky inputs from checkasm, such that the C code short-circuits almost all filter calculations. 2024-06-28 18:56:12 +00:00
lavc/h264dsp: R-V V 8-bit h264_idct_add T-Head C908 (cycles): h264_idct4_add_8bpp_c: 271.5 h264_idct4_add_8bpp_rvv_i32: 91.5 2024-07-02 19:03:07 +00:00			`void ff_h264_idct_add_8_rvv(uint8_t dst, int16_t block, int stride);`
lavc/h264dsp: R-V V 8-bit h264_idct8_add T-Head C908 (cycles): h264_idct8_add_8bpp_c: 1072.0 h264_idct8_add_8bpp_rvv_i32: 318.5 2024-07-03 16:49:54 +00:00			`void ff_h264_idct8_add_8_rvv(uint8_t dst, int16_t block, int stride);`
lavc/h264dsp: R-V V 8-bit h264_idct_add16 While this tends to be faster than plain C, the performance numbers are all over the place, presuambly due to the conditional character of the main loop. Some additional micro-optimisations should be feasible after the underlying h264_idct_add and h264_idct_dc_add functions are also implemented. Then it will no longer be necesseray to stricly abide by the C ABI. 2024-07-01 20:41:37 +00:00			`void ff_h264_idct_add16_8_rvv(uint8_t dst, const int blockoffset,`
			`int16_t *block, int stride,`
			`const uint8_t nnzc[5 * 8]);`
lavc/h264dsp: R-V V 8-bit h264_idct_add16intra 2024-07-01 20:41:37 +00:00			`void ff_h264_idct_add16intra_8_rvv(uint8_t dst, const int blockoffset,`
			`int16_t *block, int stride,`
			`const uint8_t nnzc[5 * 8]);`
lavc/h264dsp: R-V V 8-bit h264_idct8_add4 2024-07-01 20:41:37 +00:00			`void ff_h264_idct8_add4_8_rvv(uint8_t dst, const int blockoffset,`
			`int16_t *block, int stride,`
			`const uint8_t nnzc[5 * 8]);`
lavc/h264dsp: R-V V 8-bit h264_idct_add16 While this tends to be faster than plain C, the performance numbers are all over the place, presuambly due to the conditional character of the main loop. Some additional micro-optimisations should be feasible after the underlying h264_idct_add and h264_idct_dc_add functions are also implemented. Then it will no longer be necesseray to stricly abide by the C ABI. 2024-07-01 20:41:37 +00:00
lavc/h264dsp: R-V V high-depth h264_idct_add T-Head C908 (cycles): h264_idct4_add_9bpp_c: 248.2 h264_idct4_add_9bpp_rvv_i32: 128.7 h264_idct4_add_10bpp_c: 256.7 h264_idct4_add_10bpp_rvv_i32: 128.7 h264_idct4_add_12bpp_c: 252.5 h264_idct4_add_12bpp_rvv_i32: 129.7 h264_idct4_add_14bpp_c: 258.0 h264_idct4_add_14bpp_rvv_i32: 129.7 2024-07-02 19:03:07 +00:00			`void ff_h264_idct_add_9_rvv(uint8_t dst, int16_t block, int stride);`
			`void ff_h264_idct_add_10_rvv(uint8_t dst, int16_t block, int stride);`
			`void ff_h264_idct_add_12_rvv(uint8_t dst, int16_t block, int stride);`
			`void ff_h264_idct_add_14_rvv(uint8_t dst, int16_t block, int stride);`

lavc/startcode: add R-V Zbb startcode_find_candidate The main loop processes 8 bytes in 5 instructions. For comparison, the optimal plain strnlen() requires 4 instructions per byte (6.4x worse): LBU; ADDI; BEQZ; BNE. The current libavcodec C code involves 5 instructions per byte (8x worse). Actual benchmarks may be slightly less favourable due to latency from ORC.B to BNE. 2024-05-16 14:13:22 +00:00			`extern int ff_startcode_find_candidate_rvb(const uint8_t *, int);`
lavc/startcode: add R-V V startcode_find_candidate 2024-05-12 10:54:33 +00:00			`extern int ff_startcode_find_candidate_rvv(const uint8_t *, int);`
lavc/startcode: add R-V Zbb startcode_find_candidate The main loop processes 8 bytes in 5 instructions. For comparison, the optimal plain strnlen() requires 4 instructions per byte (6.4x worse): LBU; ADDI; BEQZ; BNE. The current libavcodec C code involves 5 instructions per byte (8x worse). Actual benchmarks may be slightly less favourable due to latency from ORC.B to BNE. 2024-05-16 14:13:22 +00:00
			`av_cold void ff_h264dsp_init_riscv(H264DSPContext *dsp, const int bit_depth,`
			`const int chroma_format_idc)`
			`{`
			`#if HAVE_RV`
			`int flags = av_get_cpu_flags();`

			`if (flags & AV_CPU_FLAG_RVB_BASIC)`
			`dsp->startcode_find_candidate = ff_startcode_find_candidate_rvb;`
lavc/startcode: add R-V V startcode_find_candidate 2024-05-12 10:54:33 +00:00			`# if HAVE_RVV`
lavc/h264dsp: R-V V 8-bit luma loop filter T-Head C908 (cycles): h264_h_loop_filter_luma_8bpp_c: 297.5 h264_h_loop_filter_luma_8bpp_rvv_i32: 369.2 h264_v_loop_filter_luma_8bpp_c: 862.7 h264_v_loop_filter_luma_8bpp_rvv_i32: 199.7 Performance in the horizontal scenario seems worse than scalar. x86 SSE2 and AVX optimisations are similarly affected. This is presumably caused by unlucky inputs from checkasm, such that the C code short-circuits almost all filter calculations. 2024-06-28 18:56:12 +00:00			`if (flags & AV_CPU_FLAG_RVV_I32) {`
lavc/h264dsp: R-V V high-depth h264_idct_add T-Head C908 (cycles): h264_idct4_add_9bpp_c: 248.2 h264_idct4_add_9bpp_rvv_i32: 128.7 h264_idct4_add_10bpp_c: 256.7 h264_idct4_add_10bpp_rvv_i32: 128.7 h264_idct4_add_12bpp_c: 252.5 h264_idct4_add_12bpp_rvv_i32: 129.7 h264_idct4_add_14bpp_c: 258.0 h264_idct4_add_14bpp_rvv_i32: 129.7 2024-07-02 19:03:07 +00:00			`const bool zvl128b = ff_rv_vlen_least(128);`

			`if (bit_depth == 8 && zvl128b) {`
lavc/h264dsp: R-V V 8-bit h264_biweight_pixels T-Head C908: h264_biweight2_8_c: 58.0 h264_biweight2_8_rvv_i32: 11.2 h264_biweight4_8_c: 106.0 h264_biweight4_8_rvv_i32: 22.7 h264_biweight8_8_c: 205.7 h264_biweight8_8_rvv_i32: 50.0 h264_biweight16_8_c: 403.5 h264_biweight16_8_rvv_i32: 83.2 SpacemiT X60: h264_weight2_8_c: 48.2 h264_weight2_8_rvv_i32: 8.2 h264_weight4_8_c: 90.5 h264_weight4_8_rvv_i32: 16.5 h264_weight8_8_c: 175.2 h264_weight8_8_rvv_i32: 38.0 h264_weight16_8_c: 342.2 h264_weight16_8_rvv_i32: 66.0 2024-07-05 20:03:28 +00:00			`for (int i = 0; i < 4; i++) {`
			`dsp->weight_h264_pixels_tab[i] =`
			`ff_h264_weight_funcs_8_rvv[i].weight;`
			`dsp->biweight_h264_pixels_tab[i] =`
			`ff_h264_weight_funcs_8_rvv[i].biweight;`
			`}`
lavc/h264dsp: R-V V 8-bit h264_weight_pixels There are two implementations here: - a generic scalable one processing two columns at a time, - a specialised processing one (fixed-size) row at a time. Unsurprisingly, the generic one works out better with smaller widths. With larger widths, the gains from filling vectors are outweighed by the extra cost of strided loads and stores. In other words, memory accesses become the bottleneck. T-Head C908: h264_weight2_8_c: 54.5 h264_weight2_8_rvv_i32: 13.7 h264_weight4_8_c: 101.7 h264_weight4_8_rvv_i32: 27.5 h264_weight8_8_c: 197.0 h264_weight8_8_rvv_i32: 75.5 h264_weight16_8_c: 385.0 h264_weight16_8_rvv_i32: 74.2 SpacemiT X60: h264_weight2_8_c: 48.5 h264_weight2_8_rvv_i32: 8.2 h264_weight4_8_c: 90.7 h264_weight4_8_rvv_i32: 16.5 h264_weight8_8_c: 175.0 h264_weight8_8_rvv_i32: 37.7 h264_weight16_8_c: 342.2 h264_weight16_8_rvv_i32: 66.0 2024-07-04 18:38:48 +00:00
lavc/h264dsp: R-V V 8-bit luma loop filter T-Head C908 (cycles): h264_h_loop_filter_luma_8bpp_c: 297.5 h264_h_loop_filter_luma_8bpp_rvv_i32: 369.2 h264_v_loop_filter_luma_8bpp_c: 862.7 h264_v_loop_filter_luma_8bpp_rvv_i32: 199.7 Performance in the horizontal scenario seems worse than scalar. x86 SSE2 and AVX optimisations are similarly affected. This is presumably caused by unlucky inputs from checkasm, such that the C code short-circuits almost all filter calculations. 2024-06-28 18:56:12 +00:00			`dsp->h264_v_loop_filter_luma = ff_h264_v_loop_filter_luma_8_rvv;`
			`dsp->h264_h_loop_filter_luma = ff_h264_h_loop_filter_luma_8_rvv;`
lavc/h264dsp: R-V V 8-bit MBAFF loop filter Performance is (unfortunately) the same as with non-MBAFF, since the hardware under test does not short-circuit vector tail calculations. (IMO, a generic solution or work-around should be agreed on, rather than bespoke approaches all over the place.) 2024-06-30 08:24:43 +00:00			`dsp->h264_h_loop_filter_luma_mbaff =`
			`ff_h264_h_loop_filter_luma_mbaff_8_rvv;`
lavc/h264dsp: R-V V 8-bit h264_idct_add16 While this tends to be faster than plain C, the performance numbers are all over the place, presuambly due to the conditional character of the main loop. Some additional micro-optimisations should be feasible after the underlying h264_idct_add and h264_idct_dc_add functions are also implemented. Then it will no longer be necesseray to stricly abide by the C ABI. 2024-07-01 20:41:37 +00:00
lavc/h264dsp: R-V V 8-bit h264_idct_add T-Head C908 (cycles): h264_idct4_add_8bpp_c: 271.5 h264_idct4_add_8bpp_rvv_i32: 91.5 2024-07-02 19:03:07 +00:00			`dsp->h264_idct_add = ff_h264_idct_add_8_rvv;`
lavc/h264dsp: R-V V 8-bit h264_idct8_add T-Head C908 (cycles): h264_idct8_add_8bpp_c: 1072.0 h264_idct8_add_8bpp_rvv_i32: 318.5 2024-07-03 16:49:54 +00:00			`dsp->h264_idct8_add = ff_h264_idct8_add_8_rvv;`
lavc/h264dsp: R-V V 8-bit h264_idct_add16 While this tends to be faster than plain C, the performance numbers are all over the place, presuambly due to the conditional character of the main loop. Some additional micro-optimisations should be feasible after the underlying h264_idct_add and h264_idct_dc_add functions are also implemented. Then it will no longer be necesseray to stricly abide by the C ABI. 2024-07-01 20:41:37 +00:00			`# if __riscv_xlen == 64`
			`dsp->h264_idct_add16 = ff_h264_idct_add16_8_rvv;`
lavc/h264dsp: R-V V 8-bit h264_idct_add16intra 2024-07-01 20:41:37 +00:00			`dsp->h264_idct_add16intra = ff_h264_idct_add16intra_8_rvv;`
lavc/h264dsp: R-V V 8-bit h264_idct8_add4 2024-07-01 20:41:37 +00:00			`dsp->h264_idct8_add4 = ff_h264_idct8_add4_8_rvv;`
lavc/h264dsp: R-V V 8-bit h264_idct_add16 While this tends to be faster than plain C, the performance numbers are all over the place, presuambly due to the conditional character of the main loop. Some additional micro-optimisations should be feasible after the underlying h264_idct_add and h264_idct_dc_add functions are also implemented. Then it will no longer be necesseray to stricly abide by the C ABI. 2024-07-01 20:41:37 +00:00			`# endif`
lavc/h264dsp: R-V V 8-bit luma loop filter T-Head C908 (cycles): h264_h_loop_filter_luma_8bpp_c: 297.5 h264_h_loop_filter_luma_8bpp_rvv_i32: 369.2 h264_v_loop_filter_luma_8bpp_c: 862.7 h264_v_loop_filter_luma_8bpp_rvv_i32: 199.7 Performance in the horizontal scenario seems worse than scalar. x86 SSE2 and AVX optimisations are similarly affected. This is presumably caused by unlucky inputs from checkasm, such that the C code short-circuits almost all filter calculations. 2024-06-28 18:56:12 +00:00			`}`
lavc/h264dsp: R-V V high-depth h264_idct_add T-Head C908 (cycles): h264_idct4_add_9bpp_c: 248.2 h264_idct4_add_9bpp_rvv_i32: 128.7 h264_idct4_add_10bpp_c: 256.7 h264_idct4_add_10bpp_rvv_i32: 128.7 h264_idct4_add_12bpp_c: 252.5 h264_idct4_add_12bpp_rvv_i32: 129.7 h264_idct4_add_14bpp_c: 258.0 h264_idct4_add_14bpp_rvv_i32: 129.7 2024-07-02 19:03:07 +00:00
			`if (bit_depth == 9 && zvl128b)`
			`dsp->h264_idct_add = ff_h264_idct_add_9_rvv;`
			`if (bit_depth == 10 && zvl128b)`
			`dsp->h264_idct_add = ff_h264_idct_add_10_rvv;`
			`if (bit_depth == 12 && zvl128b)`
			`dsp->h264_idct_add = ff_h264_idct_add_12_rvv;`
			`if (bit_depth == 14 && zvl128b)`
			`dsp->h264_idct_add = ff_h264_idct_add_14_rvv;`

lavc/startcode: add R-V V startcode_find_candidate 2024-05-12 10:54:33 +00:00			`dsp->startcode_find_candidate = ff_startcode_find_candidate_rvv;`
lavc/h264dsp: R-V V 8-bit luma loop filter T-Head C908 (cycles): h264_h_loop_filter_luma_8bpp_c: 297.5 h264_h_loop_filter_luma_8bpp_rvv_i32: 369.2 h264_v_loop_filter_luma_8bpp_c: 862.7 h264_v_loop_filter_luma_8bpp_rvv_i32: 199.7 Performance in the horizontal scenario seems worse than scalar. x86 SSE2 and AVX optimisations are similarly affected. This is presumably caused by unlucky inputs from checkasm, such that the C code short-circuits almost all filter calculations. 2024-06-28 18:56:12 +00:00			`}`
lavc/startcode: add R-V V startcode_find_candidate 2024-05-12 10:54:33 +00:00			`# endif`
lavc/startcode: add R-V Zbb startcode_find_candidate The main loop processes 8 bytes in 5 instructions. For comparison, the optimal plain strnlen() requires 4 instructions per byte (6.4x worse): LBU; ADDI; BEQZ; BNE. The current libavcodec C code involves 5 instructions per byte (8x worse). Actual benchmarks may be slightly less favourable due to latency from ORC.B to BNE. 2024-05-16 14:13:22 +00:00			`#endif`
			`}`