/* * This file is part of FFmpeg. * * FFmpeg is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 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 General Public License for more details. * * You should have received a copy of the GNU 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 #include #include "libavutil/float_dsp.h" #include "libavutil/internal.h" #include "libavutil/mem_internal.h" #include "checkasm.h" #define LEN 256 #define randomize_buffer(buf) \ do { \ int i; \ double bmg[2], stddev = 10.0, mean = 0.0; \ \ for (i = 0; i < LEN; i += 2) { \ av_bmg_get(&checkasm_lfg, bmg); \ buf[i] = bmg[0] * stddev + mean; \ buf[i + 1] = bmg[1] * stddev + mean; \ } \ } while(0); static void test_vector_fmul(const float *src0, const float *src1) { LOCAL_ALIGNED_32(float, cdst, [LEN]); LOCAL_ALIGNED_32(float, odst, [LEN]); int i; declare_func(void, float *dst, const float *src0, const float *src1, int len); call_ref(cdst, src0, src1, LEN); call_new(odst, src0, src1, LEN); for (i = 0; i < LEN; i++) { double t = fabs(src0[i]) + fabs(src1[i]) + fabs(src0[i] * src1[i]) + 1.0; if (!float_near_abs_eps(cdst[i], odst[i], t * 2 * FLT_EPSILON)) { fprintf(stderr, "%d: %- .12f - %- .12f = % .12g\n", i, cdst[i], odst[i], cdst[i] - odst[i]); fail(); break; } } bench_new(odst, src0, src1, LEN); } static void test_vector_dmul(const double *src0, const double *src1) { LOCAL_ALIGNED_32(double, cdst, [LEN]); LOCAL_ALIGNED_32(double, odst, [LEN]); int i; declare_func(void, double *dst, const double *src0, const double *src1, int len); call_ref(cdst, src0, src1, LEN); call_new(odst, src0, src1, LEN); for (i = 0; i < LEN; i++) { double t = fabs(src0[i]) + fabs(src1[i]) + fabs(src0[i] * src1[i]) + 1.0; if (!double_near_abs_eps(cdst[i], odst[i], t * 2 * DBL_EPSILON)) { fprintf(stderr, "%d: %- .12f - %- .12f = % .12g\n", i, cdst[i], odst[i], cdst[i] - odst[i]); fail(); break; } } bench_new(odst, src0, src1, LEN); } #define ARBITRARY_FMUL_ADD_CONST 0.005 static void test_vector_fmul_add(const float *src0, const float *src1, const float *src2) { LOCAL_ALIGNED_32(float, cdst, [LEN]); LOCAL_ALIGNED_32(float, odst, [LEN]); int i; declare_func(void, float *dst, const float *src0, const float *src1, const float *src2, int len); call_ref(cdst, src0, src1, src2, LEN); call_new(odst, src0, src1, src2, LEN); for (i = 0; i < LEN; i++) { if (!float_near_abs_eps(cdst[i], odst[i], ARBITRARY_FMUL_ADD_CONST)) { fprintf(stderr, "%d: %- .12f - %- .12f = % .12g\n", i, cdst[i], odst[i], cdst[i] - odst[i]); fail(); break; } } bench_new(odst, src0, src1, src2, LEN); } static void test_vector_fmul_scalar(const float *src0, const float *src1) { LOCAL_ALIGNED_16(float, cdst, [LEN]); LOCAL_ALIGNED_16(float, odst, [LEN]); int i; declare_func(void, float *dst, const float *src, float mul, int len); call_ref(cdst, src0, src1[0], LEN); call_new(odst, src0, src1[0], LEN); for (i = 0; i < LEN; i++) { double t = fabs(src0[i]) + fabs(src1[0]) + fabs(src0[i] * src1[0]) + 1.0; if (!float_near_abs_eps(cdst[i], odst[i], t * 2 * FLT_EPSILON)) { fprintf(stderr, "%d: %- .12f - %- .12f = % .12g\n", i, cdst[i], odst[i], cdst[i] - odst[i]); fail(); break; } } bench_new(odst, src0, src1[0], LEN); } #define ARBITRARY_FMUL_WINDOW_CONST 0.008 static void test_vector_fmul_window(const float *src0, const float *src1, const float *win) { LOCAL_ALIGNED_16(float, cdst, [LEN]); LOCAL_ALIGNED_16(float, odst, [LEN]); int i; declare_func(void, float *dst, const float *src0, const float *src1, const float *win, int len); call_ref(cdst, src0, src1, win, LEN / 2); call_new(odst, src0, src1, win, LEN / 2); for (i = 0; i < LEN; i++) { if (!float_near_abs_eps(cdst[i], odst[i], ARBITRARY_FMUL_WINDOW_CONST)) { fprintf(stderr, "%d: %- .12f - %- .12f = % .12g\n", i, cdst[i], odst[i], cdst[i] - odst[i]); fail(); break; } } bench_new(odst, src0, src1, win, LEN / 2); } #define ARBITRARY_FMAC_SCALAR_CONST 0.005 static void test_vector_fmac_scalar(const float *src0, const float *src1, const float *src2) { LOCAL_ALIGNED_32(float, cdst, [LEN]); LOCAL_ALIGNED_32(float, odst, [LEN]); int i; declare_func(void, float *dst, const float *src, float mul, int len); memcpy(cdst, src2, LEN * sizeof(*src2)); memcpy(odst, src2, LEN * sizeof(*src2)); call_ref(cdst, src0, src1[0], LEN); call_new(odst, src0, src1[0], LEN); for (i = 0; i < LEN; i++) { if (!float_near_abs_eps(cdst[i], odst[i], ARBITRARY_FMAC_SCALAR_CONST)) { fprintf(stderr, "%d: %- .12f - %- .12f = % .12g\n", i, cdst[i], odst[i], cdst[i] - odst[i]); fail(); break; } } memcpy(odst, src2, LEN * sizeof(*src2)); bench_new(odst, src0, src1[0], LEN); } static void test_vector_dmul_scalar(const double *src0, const double *src1) { LOCAL_ALIGNED_32(double, cdst, [LEN]); LOCAL_ALIGNED_32(double, odst, [LEN]); int i; declare_func(void, double *dst, const double *src, double mul, int len); call_ref(cdst, src0, src1[0], LEN); call_new(odst, src0, src1[0], LEN); for (i = 0; i < LEN; i++) { double t = fabs(src1[0]) + fabs(src0[i]) + fabs(src1[0] * src0[i]) + 1.0; if (!double_near_abs_eps(cdst[i], odst[i], t * 2 * DBL_EPSILON)) { fprintf(stderr, "%d: %- .12f - %- .12f = % .12g\n", i, cdst[i], odst[i], cdst[i] - odst[i]); fail(); break; } } bench_new(odst, src0, src1[0], LEN); } #define ARBITRARY_DMAC_SCALAR_CONST 0.005 static void test_vector_dmac_scalar(const double *src0, const double *src1, const double *src2) { LOCAL_ALIGNED_32(double, cdst, [LEN]); LOCAL_ALIGNED_32(double, odst, [LEN]); int i; declare_func(void, double *dst, const double *src, double mul, int len); memcpy(cdst, src2, LEN * sizeof(*src2)); memcpy(odst, src2, LEN * sizeof(*src2)); call_ref(cdst, src0, src1[0], LEN); call_new(odst, src0, src1[0], LEN); for (i = 0; i < LEN; i++) { if (!double_near_abs_eps(cdst[i], odst[i], ARBITRARY_DMAC_SCALAR_CONST)) { fprintf(stderr, "%d: %- .12f - %- .12f = % .12g\n", i, cdst[i], odst[i], cdst[i] - odst[i]); fail(); break; } } memcpy(odst, src2, LEN * sizeof(*src2)); bench_new(odst, src0, src1[0], LEN); } static void test_butterflies_float(const float *src0, const float *src1) { LOCAL_ALIGNED_16(float, cdst, [LEN]); LOCAL_ALIGNED_16(float, odst, [LEN]); LOCAL_ALIGNED_16(float, cdst1, [LEN]); LOCAL_ALIGNED_16(float, odst1, [LEN]); int i; declare_func(void, float *av_restrict src0, float *av_restrict src1, int len); memcpy(cdst, src0, LEN * sizeof(*src0)); memcpy(cdst1, src1, LEN * sizeof(*src1)); memcpy(odst, src0, LEN * sizeof(*src0)); memcpy(odst1, src1, LEN * sizeof(*src1)); call_ref(cdst, cdst1, LEN); call_new(odst, odst1, LEN); for (i = 0; i < LEN; i++) { if (!float_near_abs_eps(cdst[i], odst[i], FLT_EPSILON) || !float_near_abs_eps(cdst1[i], odst1[i], FLT_EPSILON)) { fprintf(stderr, "%d: %- .12f - %- .12f = % .12g\n", i, cdst[i], odst[i], cdst[i] - odst[i]); fprintf(stderr, "%d: %- .12f - %- .12f = % .12g\n", i, cdst1[i], odst1[i], cdst1[i] - odst1[i]); fail(); break; } } memcpy(odst, src0, LEN * sizeof(*src0)); memcpy(odst1, src1, LEN * sizeof(*src1)); bench_new(odst, odst1, LEN); } #define ARBITRARY_SCALARPRODUCT_CONST 0.2 static void test_scalarproduct_float(const float *src0, const float *src1) { float cprod, oprod; declare_func_float(float, const float *src0, const float *src1, int len); cprod = call_ref(src0, src1, LEN); oprod = call_new(src0, src1, LEN); if (!float_near_abs_eps(cprod, oprod, ARBITRARY_SCALARPRODUCT_CONST)) { fprintf(stderr, "%- .12f - %- .12f = % .12g\n", cprod, oprod, cprod - oprod); fail(); } bench_new(src0, src1, LEN); } void checkasm_check_float_dsp(void) { LOCAL_ALIGNED_32(float, src0, [LEN]); LOCAL_ALIGNED_32(float, src1, [LEN]); LOCAL_ALIGNED_32(float, src2, [LEN]); LOCAL_ALIGNED_16(float, src3, [LEN]); LOCAL_ALIGNED_16(float, src4, [LEN]); LOCAL_ALIGNED_16(float, src5, [LEN]); LOCAL_ALIGNED_32(double, dbl_src0, [LEN]); LOCAL_ALIGNED_32(double, dbl_src1, [LEN]); LOCAL_ALIGNED_32(double, dbl_src2, [LEN]); AVFloatDSPContext *fdsp = avpriv_float_dsp_alloc(1); if (!fdsp) { fprintf(stderr, "floatdsp: Out of memory error\n"); return; } randomize_buffer(src0); randomize_buffer(src1); randomize_buffer(src2); randomize_buffer(src3); randomize_buffer(src4); randomize_buffer(src5); randomize_buffer(dbl_src0); randomize_buffer(dbl_src1); randomize_buffer(dbl_src2); if (check_func(fdsp->vector_fmul, "vector_fmul")) test_vector_fmul(src0, src1); if (check_func(fdsp->vector_fmul_add, "vector_fmul_add")) test_vector_fmul_add(src0, src1, src2); if (check_func(fdsp->vector_fmul_scalar, "vector_fmul_scalar")) test_vector_fmul_scalar(src3, src4); if (check_func(fdsp->vector_fmul_reverse, "vector_fmul_reverse")) test_vector_fmul(src0, src1); if (check_func(fdsp->vector_fmul_window, "vector_fmul_window")) test_vector_fmul_window(src3, src4, src5); report("vector_fmul"); if (check_func(fdsp->vector_fmac_scalar, "vector_fmac_scalar")) test_vector_fmac_scalar(src0, src1, src2); report("vector_fmac"); if (check_func(fdsp->vector_dmul, "vector_dmul")) test_vector_dmul(dbl_src0, dbl_src1); if (check_func(fdsp->vector_dmul_scalar, "vector_dmul_scalar")) test_vector_dmul_scalar(dbl_src0, dbl_src1); report("vector_dmul"); if (check_func(fdsp->vector_dmac_scalar, "vector_dmac_scalar")) test_vector_dmac_scalar(dbl_src0, dbl_src1, dbl_src2); report("vector_dmac"); if (check_func(fdsp->butterflies_float, "butterflies_float")) test_butterflies_float(src3, src4); report("butterflies_float"); if (check_func(fdsp->scalarproduct_float, "scalarproduct_float")) test_scalarproduct_float(src3, src4); report("scalarproduct_float"); av_freep(&fdsp); }