ffmpeg/libavutil/aarch64/tx_float_init.c

/*
 * 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
 */

#define TX_FLOAT
#include "libavutil/tx_priv.h"
#include "libavutil/attributes.h"
#include "libavutil/aarch64/cpu.h"

TX_DECL_FN(fft2,      neon)
TX_DECL_FN(fft4_fwd,  neon)
TX_DECL_FN(fft4_inv,  neon)
TX_DECL_FN(fft8,      neon)
TX_DECL_FN(fft8_ns,   neon)
TX_DECL_FN(fft16,     neon)
TX_DECL_FN(fft16_ns,  neon)
TX_DECL_FN(fft32,     neon)
TX_DECL_FN(fft32_ns,  neon)
TX_DECL_FN(fft_sr,    neon)
TX_DECL_FN(fft_sr_ns, neon)

static av_cold int neon_init(AVTXContext *s, const FFTXCodelet *cd,
                             uint64_t flags, FFTXCodeletOptions *opts,
                             int len, int inv, const void *scale)
{
    ff_tx_init_tabs_float(len);
    if (cd->max_len == 2)
        return ff_tx_gen_ptwo_revtab(s, opts);
    else
        return ff_tx_gen_split_radix_parity_revtab(s, len, inv, opts, 8, 0);
}

const FFTXCodelet * const ff_tx_codelet_list_float_aarch64[] = {
    TX_DEF(fft2,      FFT,  2,  2, 2, 0, 128, NULL,      neon, NEON, AV_TX_INPLACE, 0),
    TX_DEF(fft2,      FFT,  2,  2, 2, 0, 192, neon_init, neon, NEON, AV_TX_INPLACE | FF_TX_PRESHUFFLE, 0),
    TX_DEF(fft4_fwd,  FFT,  4,  4, 2, 0, 128, NULL,      neon, NEON, AV_TX_INPLACE | FF_TX_FORWARD_ONLY, 0),
    TX_DEF(fft4_fwd,  FFT,  4,  4, 2, 0, 192, neon_init, neon, NEON, AV_TX_INPLACE | FF_TX_PRESHUFFLE, 0),
    TX_DEF(fft4_inv,  FFT,  4,  4, 2, 0, 128, NULL,      neon, NEON, AV_TX_INPLACE | FF_TX_INVERSE_ONLY, 0),
    TX_DEF(fft8,      FFT,  8,  8, 2, 0, 128, neon_init, neon, NEON, AV_TX_INPLACE, 0),
    TX_DEF(fft8_ns,   FFT,  8,  8, 2, 0, 192, neon_init, neon, NEON, AV_TX_INPLACE | FF_TX_PRESHUFFLE, 0),
    TX_DEF(fft16,     FFT, 16, 16, 2, 0, 128, neon_init, neon, NEON, AV_TX_INPLACE, 0),
    TX_DEF(fft16_ns,  FFT, 16, 16, 2, 0, 192, neon_init, neon, NEON, AV_TX_INPLACE | FF_TX_PRESHUFFLE, 0),
    TX_DEF(fft32,     FFT, 32, 32, 2, 0, 128, neon_init, neon, NEON, AV_TX_INPLACE, 0),
    TX_DEF(fft32_ns,  FFT, 32, 32, 2, 0, 192, neon_init, neon, NEON, AV_TX_INPLACE | FF_TX_PRESHUFFLE, 0),

    TX_DEF(fft_sr,    FFT, 64, 131072, 2, 0, 128, neon_init, neon, NEON, 0, 0),
    TX_DEF(fft_sr_ns, FFT, 64, 131072, 2, 0, 192, neon_init, neon, NEON, AV_TX_INPLACE | FF_TX_PRESHUFFLE, 0),

    NULL,
};
lavu/tx: implement aarch64 NEON SIMD FFT The fastest fast Fourier transform in not just the west, but the world, now for the most popular toy ISA. On a high level, it follows the design of the AVX2 version closely, with the exception that the input is slightly less permuted as we don't have to do lane switching with the input on double 4pt and 8pt. On a low level, the lack of subadd/addsub instructions REALLY penalizes any attempt at writing an FFT. That single register matters a lot, and reloading it simply takes unacceptably long. In x86 land, vendors would've noticed developers need this. In ARM land, you get a badly designed complex multiplication instruction we cannot use, that's not present on 95% of devices. Because only compilers matter, right? Future optimization options are very few, perhaps better register management to use more ld1/st1s. All timings below are in cycles: A53: Length \| C \| New (lavu) \| Old (lavc) \| FFTW ------ \|-------------\|-------------\|-------------\|----- 4 \| 842 \| 420 \| 1210 \| 1460 8 \| 1538 \| 1020 \| 1850 \| 2520 16 \| 3717 \| 1900 \| 3700 \| 3990 32 \| 9156 \| 4070 \| 8289 \| 8860 64 \| 21160 \| 9931 \| 18600 \| 19625 128 \| 49180 \| 23278 \| 41922 \| 41922 256 \| 112073 \| 53876 \| 93202 \| 101092 512 \| 252864 \| 122884 \| 205897 \| 207868 1024 \| 560512 \| 278322 \| 458071 \| 453053 2048 \| 1295402 \| 775835 \| 1038205 \| 1020265 4096 \| 3281263 \| 2021221 \| 2409718 \| 2577554 8192 \| 8577845 \| 4780526 \| 5673041 \| 6802722 Apple M1 New - Total for len 512 reps 2097152 = 1.459141 s Old - Total for len 512 reps 2097152 = 2.251344 s FFTW - Total for len 512 reps 2097152 = 1.868429 s New - Total for len 1024 reps 4194304 = 6.490080 s Old - Total for len 1024 reps 4194304 = 9.604949 s FFTW - Total for len 1024 reps 4194304 = 7.889281 s New - Total for len 16384 reps 262144 = 10.374001 s Old - Total for len 16384 reps 262144 = 15.266713 s FFTW - Total for len 16384 reps 262144 = 12.341745 s New - Total for len 65536 reps 8192 = 1.769812 s Old - Total for len 65536 reps 8192 = 4.209413 s FFTW - Total for len 65536 reps 8192 = 3.012365 s New - Total for len 131072 reps 4096 = 1.942836 s Old - Segfaults FFTW - Total for len 131072 reps 4096 = 3.713713 s Thanks to wbs for some simplifications, assembler fixes and a review and to jannau for giving it a look. 2022-02-03 11:27:03 +00:00			`/*`
			`* 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`
			`*/`

			`#define TX_FLOAT`
			`#include "libavutil/tx_priv.h"`
			`#include "libavutil/attributes.h"`
			`#include "libavutil/aarch64/cpu.h"`

			`TX_DECL_FN(fft2, neon)`
			`TX_DECL_FN(fft4_fwd, neon)`
			`TX_DECL_FN(fft4_inv, neon)`
			`TX_DECL_FN(fft8, neon)`
			`TX_DECL_FN(fft8_ns, neon)`
			`TX_DECL_FN(fft16, neon)`
			`TX_DECL_FN(fft16_ns, neon)`
			`TX_DECL_FN(fft32, neon)`
			`TX_DECL_FN(fft32_ns, neon)`
			`TX_DECL_FN(fft_sr, neon)`
			`TX_DECL_FN(fft_sr_ns, neon)`

			`static av_cold int neon_init(AVTXContext s, const FFTXCodelet cd,`
			`uint64_t flags, FFTXCodeletOptions *opts,`
			`int len, int inv, const void *scale)`
			`{`
			`ff_tx_init_tabs_float(len);`
			`if (cd->max_len == 2)`
lavu/tx: refactor to explicitly track and convert lookup table order Necessary for generalizing PFAs. 2022-11-18 23:47:45 +00:00			`return ff_tx_gen_ptwo_revtab(s, opts);`
lavu/tx: implement aarch64 NEON SIMD FFT The fastest fast Fourier transform in not just the west, but the world, now for the most popular toy ISA. On a high level, it follows the design of the AVX2 version closely, with the exception that the input is slightly less permuted as we don't have to do lane switching with the input on double 4pt and 8pt. On a low level, the lack of subadd/addsub instructions REALLY penalizes any attempt at writing an FFT. That single register matters a lot, and reloading it simply takes unacceptably long. In x86 land, vendors would've noticed developers need this. In ARM land, you get a badly designed complex multiplication instruction we cannot use, that's not present on 95% of devices. Because only compilers matter, right? Future optimization options are very few, perhaps better register management to use more ld1/st1s. All timings below are in cycles: A53: Length \| C \| New (lavu) \| Old (lavc) \| FFTW ------ \|-------------\|-------------\|-------------\|----- 4 \| 842 \| 420 \| 1210 \| 1460 8 \| 1538 \| 1020 \| 1850 \| 2520 16 \| 3717 \| 1900 \| 3700 \| 3990 32 \| 9156 \| 4070 \| 8289 \| 8860 64 \| 21160 \| 9931 \| 18600 \| 19625 128 \| 49180 \| 23278 \| 41922 \| 41922 256 \| 112073 \| 53876 \| 93202 \| 101092 512 \| 252864 \| 122884 \| 205897 \| 207868 1024 \| 560512 \| 278322 \| 458071 \| 453053 2048 \| 1295402 \| 775835 \| 1038205 \| 1020265 4096 \| 3281263 \| 2021221 \| 2409718 \| 2577554 8192 \| 8577845 \| 4780526 \| 5673041 \| 6802722 Apple M1 New - Total for len 512 reps 2097152 = 1.459141 s Old - Total for len 512 reps 2097152 = 2.251344 s FFTW - Total for len 512 reps 2097152 = 1.868429 s New - Total for len 1024 reps 4194304 = 6.490080 s Old - Total for len 1024 reps 4194304 = 9.604949 s FFTW - Total for len 1024 reps 4194304 = 7.889281 s New - Total for len 16384 reps 262144 = 10.374001 s Old - Total for len 16384 reps 262144 = 15.266713 s FFTW - Total for len 16384 reps 262144 = 12.341745 s New - Total for len 65536 reps 8192 = 1.769812 s Old - Total for len 65536 reps 8192 = 4.209413 s FFTW - Total for len 65536 reps 8192 = 3.012365 s New - Total for len 131072 reps 4096 = 1.942836 s Old - Segfaults FFTW - Total for len 131072 reps 4096 = 3.713713 s Thanks to wbs for some simplifications, assembler fixes and a review and to jannau for giving it a look. 2022-02-03 11:27:03 +00:00			`else`
lavu/tx: refactor to explicitly track and convert lookup table order Necessary for generalizing PFAs. 2022-11-18 23:47:45 +00:00			`return ff_tx_gen_split_radix_parity_revtab(s, len, inv, opts, 8, 0);`
lavu/tx: implement aarch64 NEON SIMD FFT The fastest fast Fourier transform in not just the west, but the world, now for the most popular toy ISA. On a high level, it follows the design of the AVX2 version closely, with the exception that the input is slightly less permuted as we don't have to do lane switching with the input on double 4pt and 8pt. On a low level, the lack of subadd/addsub instructions REALLY penalizes any attempt at writing an FFT. That single register matters a lot, and reloading it simply takes unacceptably long. In x86 land, vendors would've noticed developers need this. In ARM land, you get a badly designed complex multiplication instruction we cannot use, that's not present on 95% of devices. Because only compilers matter, right? Future optimization options are very few, perhaps better register management to use more ld1/st1s. All timings below are in cycles: A53: Length \| C \| New (lavu) \| Old (lavc) \| FFTW ------ \|-------------\|-------------\|-------------\|----- 4 \| 842 \| 420 \| 1210 \| 1460 8 \| 1538 \| 1020 \| 1850 \| 2520 16 \| 3717 \| 1900 \| 3700 \| 3990 32 \| 9156 \| 4070 \| 8289 \| 8860 64 \| 21160 \| 9931 \| 18600 \| 19625 128 \| 49180 \| 23278 \| 41922 \| 41922 256 \| 112073 \| 53876 \| 93202 \| 101092 512 \| 252864 \| 122884 \| 205897 \| 207868 1024 \| 560512 \| 278322 \| 458071 \| 453053 2048 \| 1295402 \| 775835 \| 1038205 \| 1020265 4096 \| 3281263 \| 2021221 \| 2409718 \| 2577554 8192 \| 8577845 \| 4780526 \| 5673041 \| 6802722 Apple M1 New - Total for len 512 reps 2097152 = 1.459141 s Old - Total for len 512 reps 2097152 = 2.251344 s FFTW - Total for len 512 reps 2097152 = 1.868429 s New - Total for len 1024 reps 4194304 = 6.490080 s Old - Total for len 1024 reps 4194304 = 9.604949 s FFTW - Total for len 1024 reps 4194304 = 7.889281 s New - Total for len 16384 reps 262144 = 10.374001 s Old - Total for len 16384 reps 262144 = 15.266713 s FFTW - Total for len 16384 reps 262144 = 12.341745 s New - Total for len 65536 reps 8192 = 1.769812 s Old - Total for len 65536 reps 8192 = 4.209413 s FFTW - Total for len 65536 reps 8192 = 3.012365 s New - Total for len 131072 reps 4096 = 1.942836 s Old - Segfaults FFTW - Total for len 131072 reps 4096 = 3.713713 s Thanks to wbs for some simplifications, assembler fixes and a review and to jannau for giving it a look. 2022-02-03 11:27:03 +00:00			`}`

			`const FFTXCodelet * const ff_tx_codelet_list_float_aarch64[] = {`
			`TX_DEF(fft2, FFT, 2, 2, 2, 0, 128, NULL, neon, NEON, AV_TX_INPLACE, 0),`
			`TX_DEF(fft2, FFT, 2, 2, 2, 0, 192, neon_init, neon, NEON, AV_TX_INPLACE \| FF_TX_PRESHUFFLE, 0),`
			`TX_DEF(fft4_fwd, FFT, 4, 4, 2, 0, 128, NULL, neon, NEON, AV_TX_INPLACE \| FF_TX_FORWARD_ONLY, 0),`
			`TX_DEF(fft4_fwd, FFT, 4, 4, 2, 0, 192, neon_init, neon, NEON, AV_TX_INPLACE \| FF_TX_PRESHUFFLE, 0),`
			`TX_DEF(fft4_inv, FFT, 4, 4, 2, 0, 128, NULL, neon, NEON, AV_TX_INPLACE \| FF_TX_INVERSE_ONLY, 0),`
			`TX_DEF(fft8, FFT, 8, 8, 2, 0, 128, neon_init, neon, NEON, AV_TX_INPLACE, 0),`
			`TX_DEF(fft8_ns, FFT, 8, 8, 2, 0, 192, neon_init, neon, NEON, AV_TX_INPLACE \| FF_TX_PRESHUFFLE, 0),`
			`TX_DEF(fft16, FFT, 16, 16, 2, 0, 128, neon_init, neon, NEON, AV_TX_INPLACE, 0),`
			`TX_DEF(fft16_ns, FFT, 16, 16, 2, 0, 192, neon_init, neon, NEON, AV_TX_INPLACE \| FF_TX_PRESHUFFLE, 0),`
			`TX_DEF(fft32, FFT, 32, 32, 2, 0, 128, neon_init, neon, NEON, AV_TX_INPLACE, 0),`
			`TX_DEF(fft32_ns, FFT, 32, 32, 2, 0, 192, neon_init, neon, NEON, AV_TX_INPLACE \| FF_TX_PRESHUFFLE, 0),`

			`TX_DEF(fft_sr, FFT, 64, 131072, 2, 0, 128, neon_init, neon, NEON, 0, 0),`
			`TX_DEF(fft_sr_ns, FFT, 64, 131072, 2, 0, 192, neon_init, neon, NEON, AV_TX_INPLACE \| FF_TX_PRESHUFFLE, 0),`

			`NULL,`
			`};`