tests/checkasm/vp9dsp.c - nest-android-app/ffmpeg - Git at Google

 /*
  * Copyright (c) 2015 Ronald S. Bultje <rsbultje@gmail.com>
  *
  * 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 <math.h>
 #include <string.h>
 #include "checkasm.h"
 #include "libavcodec/vp9data.h"
 #include "libavcodec/vp9dsp.h"
 #include "libavutil/common.h"
 #include "libavutil/internal.h"
 #include "libavutil/intreadwrite.h"
 #include "libavutil/mathematics.h"

 static const uint32_t pixel_mask[3] = { 0xffffffff, 0x03ff03ff, 0x0fff0fff };
 #define SIZEOF_PIXEL ((bit_depth + 7) / 8)

 #define randomize_buffers()                                        \
     do {                                                           \
         uint32_t mask = pixel_mask[(bit_depth - 8) >> 1];          \
         int k;                                                     \
         for (k = -4;  k < SIZEOF_PIXEL * FFMAX(8, size); k += 4) { \
             uint32_t r = rnd() & mask;                             \
             AV_WN32A(a + k, r);                                    \
         }                                                          \
         for (k = 0; k < size * SIZEOF_PIXEL; k += 4) {             \
             uint32_t r = rnd() & mask;                             \
             AV_WN32A(l + k, r);                                    \
         }                                                          \
     } while (0)

 static void check_ipred(void)
 {
     LOCAL_ALIGNED_32(uint8_t, a_buf, [64 * 2]);
     uint8_t *a = &a_buf[32 * 2];
     LOCAL_ALIGNED_32(uint8_t, l, [32 * 2]);
     LOCAL_ALIGNED_32(uint8_t, dst0, [32 * 32 * 2]);
     LOCAL_ALIGNED_32(uint8_t, dst1, [32 * 32 * 2]);
     VP9DSPContext dsp;
     int tx, mode, bit_depth;
     declare_func_emms(AV_CPU_FLAG_MMX | AV_CPU_FLAG_MMXEXT, void, uint8_t *dst, ptrdiff_t stride,
                       const uint8_t *left, const uint8_t *top);
     static const char *const mode_names[N_INTRA_PRED_MODES] = {
         [VERT_PRED] = "vert",
         [HOR_PRED] = "hor",
         [DC_PRED] = "dc",
         [DIAG_DOWN_LEFT_PRED] = "diag_downleft",
         [DIAG_DOWN_RIGHT_PRED] = "diag_downright",
         [VERT_RIGHT_PRED] = "vert_right",
         [HOR_DOWN_PRED] = "hor_down",
         [VERT_LEFT_PRED] = "vert_left",
         [HOR_UP_PRED] = "hor_up",
         [TM_VP8_PRED] = "tm",
         [LEFT_DC_PRED] = "dc_left",
         [TOP_DC_PRED] = "dc_top",
         [DC_128_PRED] = "dc_128",
         [DC_127_PRED] = "dc_127",
         [DC_129_PRED] = "dc_129",
     };

     for (bit_depth = 8; bit_depth <= 12; bit_depth += 2) {
         ff_vp9dsp_init(&dsp, bit_depth, 0);
         for (tx = 0; tx < 4; tx++) {
             int size = 4 << tx;

             for (mode = 0; mode < N_INTRA_PRED_MODES; mode++) {
                 if (check_func(dsp.intra_pred[tx][mode], "vp9_%s_%dx%d_%dbpp",
                                mode_names[mode], size, size, bit_depth)) {
                     randomize_buffers();
                     call_ref(dst0, size * SIZEOF_PIXEL, l, a);
                     call_new(dst1, size * SIZEOF_PIXEL, l, a);
                     if (memcmp(dst0, dst1, size * size * SIZEOF_PIXEL))
                         fail();
                     bench_new(dst1, size * SIZEOF_PIXEL,l, a);
                 }
             }
         }
     }
     report("ipred");
 }

 #undef randomize_buffers

 #define randomize_buffers() \
     do { \
         uint32_t mask = pixel_mask[(bit_depth - 8) >> 1];                  \
         for (y = 0; y < sz; y++) {                                         \
             for (x = 0; x < sz * SIZEOF_PIXEL; x += 4) {                   \
                 uint32_t r = rnd() & mask;                                 \
                 AV_WN32A(dst + y * sz * SIZEOF_PIXEL + x, r);              \
                 AV_WN32A(src + y * sz * SIZEOF_PIXEL + x, rnd() & mask);   \
             }                                                              \
             for (x = 0; x < sz; x++) {                                     \
                 if (bit_depth == 8) {                                      \
                     coef[y * sz + x] = src[y * sz + x] - dst[y * sz + x];  \
                 } else {                                                   \
                     ((int32_t *) coef)[y * sz + x] =                       \
                         ((uint16_t *) src)[y * sz + x] -                   \
                         ((uint16_t *) dst)[y * sz + x];                    \
                 }                                                          \
             }                                                              \
         }                                                                  \
     } while(0)

 // wht function copied from libvpx
 static void fwht_1d(double *out, const double *in, int sz)
 {
     double t0 = in[0] + in[1];
     double t3 = in[3] - in[2];
     double t4 = trunc((t0 - t3) * 0.5);
     double t1 = t4 - in[1];
     double t2 = t4 - in[2];

     out[0] = t0 - t2;
     out[1] = t2;
     out[2] = t3 + t1;
     out[3] = t1;
 }

 // standard DCT-II
 static void fdct_1d(double *out, const double *in, int sz)
 {
     int k, n;

     for (k = 0; k < sz; k++) {
         out[k] = 0.0;
         for (n = 0; n < sz; n++)
             out[k] += in[n] * cos(M_PI * (2 * n + 1) * k / (sz * 2.0));
     }
     out[0] *= M_SQRT1_2;
 }

 // see "Towards jointly optimal spatial prediction and adaptive transform in
 // video/image coding", by J. Han, A. Saxena, and K. Rose
 // IEEE Proc. ICASSP, pp. 726-729, Mar. 2010.
 static void fadst4_1d(double *out, const double *in, int sz)
 {
     int k, n;

     for (k = 0; k < sz; k++) {
         out[k] = 0.0;
         for (n = 0; n < sz; n++)
             out[k] += in[n] * sin(M_PI * (n + 1) * (2 * k + 1) / (sz * 2.0 + 1.0));
     }
 }

 // see "A Butterfly Structured Design of The Hybrid Transform Coding Scheme",
 // by Jingning Han, Yaowu Xu, and Debargha Mukherjee
 // http://static.googleusercontent.com/media/research.google.com/en//pubs/archive/41418.pdf
 static void fadst_1d(double *out, const double *in, int sz)
 {
     int k, n;

     for (k = 0; k < sz; k++) {
         out[k] = 0.0;
         for (n = 0; n < sz; n++)
             out[k] += in[n] * sin(M_PI * (2 * n + 1) * (2 * k + 1) / (sz * 4.0));
     }
 }

 typedef void (*ftx1d_fn)(double *out, const double *in, int sz);
 static void ftx_2d(double *out, const double *in, enum TxfmMode tx,
                    enum TxfmType txtp, int sz)
 {
     static const double scaling_factors[5][4] = {
         { 4.0, 16.0 * M_SQRT1_2 / 3.0, 16.0 * M_SQRT1_2 / 3.0, 32.0 / 9.0 },
         { 2.0, 2.0, 2.0, 2.0 },
         { 1.0, 1.0, 1.0, 1.0 },
         { 0.25 },
         { 4.0 }
     };
     static const ftx1d_fn ftx1d_tbl[5][4][2] = {
         {
             { fdct_1d, fdct_1d },
             { fadst4_1d, fdct_1d },
             { fdct_1d, fadst4_1d },
             { fadst4_1d, fadst4_1d },
         }, {
             { fdct_1d, fdct_1d },
             { fadst_1d, fdct_1d },
             { fdct_1d, fadst_1d },
             { fadst_1d, fadst_1d },
         }, {
             { fdct_1d, fdct_1d },
             { fadst_1d, fdct_1d },
             { fdct_1d, fadst_1d },
             { fadst_1d, fadst_1d },
         }, {
             { fdct_1d, fdct_1d },
         }, {
             { fwht_1d, fwht_1d },
         },
     };
     double temp[1024];
     double scaling_factor = scaling_factors[tx][txtp];
     int i, j;

     // cols
     for (i = 0; i < sz; ++i) {
         double temp_out[32];

         ftx1d_tbl[tx][txtp][0](temp_out, &in[i * sz], sz);
         // scale and transpose
         for (j = 0; j < sz; ++j)
             temp[j * sz + i] = temp_out[j] * scaling_factor;
     }

     // rows
     for (i = 0; i < sz; i++)
         ftx1d_tbl[tx][txtp][1](&out[i * sz], &temp[i * sz], sz);
 }

 static void ftx(int16_t *buf, enum TxfmMode tx,
                 enum TxfmType txtp, int sz, int bit_depth)
 {
     double ind[1024], outd[1024];
     int n;

     emms_c();
     for (n = 0; n < sz * sz; n++) {
         if (bit_depth == 8)
             ind[n] = buf[n];
         else
             ind[n] = ((int32_t *) buf)[n];
     }
     ftx_2d(outd, ind, tx, txtp, sz);
     for (n = 0; n < sz * sz; n++) {
         if (bit_depth == 8)
             buf[n] = lrint(outd[n]);
         else
             ((int32_t *) buf)[n] = lrint(outd[n]);
     }
 }

 static int copy_subcoefs(int16_t *out, const int16_t *in, enum TxfmMode tx,
                          enum TxfmType txtp, int sz, int sub, int bit_depth)
 {
     // copy the topleft coefficients such that the return value (being the
     // coefficient scantable index for the eob token) guarantees that only
     // the topleft $sub out of $sz (where $sz >= $sub) coefficients in both
     // dimensions are non-zero. This leads to braching to specific optimized
     // simd versions (e.g. dc-only) so that we get full asm coverage in this
     // test

     int n;
     const int16_t *scan = vp9_scans[tx][txtp];
     int eob;

     for (n = 0; n < sz * sz; n++) {
         int rc = scan[n], rcx = rc % sz, rcy = rc / sz;

         // find eob for this sub-idct
         if (rcx >= sub || rcy >= sub)
             break;

         // copy coef
         if (bit_depth == 8) {
             out[rc] = in[rc];
         } else {
             AV_COPY32(&out[rc * 2], &in[rc * 2]);
         }
     }

     eob = n;

     for (; n < sz * sz; n++) {
         int rc = scan[n];

         // zero
         if (bit_depth == 8) {
             out[rc] = 0;
         } else {
             AV_ZERO32(&out[rc * 2]);
         }
     }

     return eob;
 }

 static int iszero(const int16_t *c, int sz)
 {
     int n;

     for (n = 0; n < sz / sizeof(int16_t); n += 2)
         if (AV_RN32A(&c[n]))
             return 0;

     return 1;
 }

 #define SIZEOF_COEF (2 * ((bit_depth + 7) / 8))

 static void check_itxfm(void)
 {
     LOCAL_ALIGNED_32(uint8_t, src, [32 * 32 * 2]);
     LOCAL_ALIGNED_32(uint8_t, dst, [32 * 32 * 2]);
     LOCAL_ALIGNED_32(uint8_t, dst0, [32 * 32 * 2]);
     LOCAL_ALIGNED_32(uint8_t, dst1, [32 * 32 * 2]);
     LOCAL_ALIGNED_32(int16_t, coef, [32 * 32 * 2]);
     LOCAL_ALIGNED_32(int16_t, subcoef0, [32 * 32 * 2]);
     LOCAL_ALIGNED_32(int16_t, subcoef1, [32 * 32 * 2]);
     declare_func_emms(AV_CPU_FLAG_MMX | AV_CPU_FLAG_MMXEXT, void, uint8_t *dst, ptrdiff_t stride, int16_t *block, int eob);
     VP9DSPContext dsp;
     int y, x, tx, txtp, bit_depth, sub;
     static const char *const txtp_types[N_TXFM_TYPES] = {
         [DCT_DCT] = "dct_dct", [DCT_ADST] = "adst_dct",
         [ADST_DCT] = "dct_adst", [ADST_ADST] = "adst_adst"
     };

     for (bit_depth = 8; bit_depth <= 12; bit_depth += 2) {
         ff_vp9dsp_init(&dsp, bit_depth, 0);

         for (tx = TX_4X4; tx <= N_TXFM_SIZES /* 4 = lossless */; tx++) {
             int sz = 4 << (tx & 3);
             int n_txtps = tx < TX_32X32 ? N_TXFM_TYPES : 1;

             for (txtp = 0; txtp < n_txtps; txtp++) {
                 if (check_func(dsp.itxfm_add[tx][txtp], "vp9_inv_%s_%dx%d_add_%d",
                                tx == 4 ? "wht_wht" : txtp_types[txtp], sz, sz,
                                bit_depth)) {
                     randomize_buffers();
                     ftx(coef, tx, txtp, sz, bit_depth);

                     for (sub = (txtp == 0) ? 1 : 2; sub <= sz; sub <<= 1) {
                         int eob;

                         if (sub < sz) {
                             eob = copy_subcoefs(subcoef0, coef, tx, txtp,
                                                 sz, sub, bit_depth);
                         } else {
                             eob = sz * sz;
                             memcpy(subcoef0, coef, sz * sz * SIZEOF_COEF);
                         }

                         memcpy(dst0, dst, sz * sz * SIZEOF_PIXEL);
                         memcpy(dst1, dst, sz * sz * SIZEOF_PIXEL);
                         memcpy(subcoef1, subcoef0, sz * sz * SIZEOF_COEF);
                         call_ref(dst0, sz * SIZEOF_PIXEL, subcoef0, eob);
                         call_new(dst1, sz * SIZEOF_PIXEL, subcoef1, eob);
                         if (memcmp(dst0, dst1, sz * sz * SIZEOF_PIXEL) ||
                             !iszero(subcoef0, sz * sz * SIZEOF_COEF) ||
                             !iszero(subcoef1, sz * sz * SIZEOF_COEF))
                             fail();
                     }
                     bench_new(dst, sz * SIZEOF_PIXEL, coef, sz * sz);
                 }
             }
         }
     }
     report("itxfm");
 }

 #undef randomize_buffers

 #define setpx(a,b,c) \
     do { \
         if (SIZEOF_PIXEL == 1) { \
             buf0[(a) + (b) * jstride] = av_clip_uint8(c); \
         } else { \
             ((uint16_t *)buf0)[(a) + (b) * jstride] = av_clip_uintp2(c, bit_depth); \
         } \
     } while (0)

 // c can be an assignment and must not be put under ()
 #define setdx(a,b,c,d) setpx(a,b,c-(d)+(rnd()%((d)*2+1)))
 #define setsx(a,b,c,d) setdx(a,b,c,(d) << (bit_depth - 8))
 static void randomize_loopfilter_buffers(int bidx, int lineoff, int str,
                                          int bit_depth, int dir, const int *E,
                                          const int *F, const int *H, const int *I,
                                          uint8_t *buf0, uint8_t *buf1)
 {
     uint32_t mask = (1 << bit_depth) - 1;
     int off = dir ? lineoff : lineoff * 16;
     int istride = dir ? 1 : 16;
     int jstride = dir ? str : 1;
     int i, j;
     for (i = 0; i < 2; i++) /* flat16 */ {
         int idx = off + i * istride, p0, q0;
         setpx(idx,  0, q0 = rnd() & mask);
         setsx(idx, -1, p0 = q0, E[bidx] >> 2);
         for (j = 1; j < 8; j++) {
             setsx(idx, -1 - j, p0, F[bidx]);
             setsx(idx, j, q0, F[bidx]);
         }
     }
     for (i = 2; i < 4; i++) /* flat8 */ {
         int idx = off + i * istride, p0, q0;
         setpx(idx,  0, q0 = rnd() & mask);
         setsx(idx, -1, p0 = q0, E[bidx] >> 2);
         for (j = 1; j < 4; j++) {
             setsx(idx, -1 - j, p0, F[bidx]);
             setsx(idx, j, q0, F[bidx]);
         }
         for (j = 4; j < 8; j++) {
             setpx(idx, -1 - j, rnd() & mask);
             setpx(idx, j, rnd() & mask);
         }
     }
     for (i = 4; i < 6; i++) /* regular */ {
         int idx = off + i * istride, p2, p1, p0, q0, q1, q2;
         setpx(idx,  0, q0 = rnd() & mask);
         setsx(idx,  1, q1 = q0, I[bidx]);
         setsx(idx,  2, q2 = q1, I[bidx]);
         setsx(idx,  3, q2,      I[bidx]);
         setsx(idx, -1, p0 = q0, E[bidx] >> 2);
         setsx(idx, -2, p1 = p0, I[bidx]);
         setsx(idx, -3, p2 = p1, I[bidx]);
         setsx(idx, -4, p2,      I[bidx]);
         for (j = 4; j < 8; j++) {
             setpx(idx, -1 - j, rnd() & mask);
             setpx(idx, j, rnd() & mask);
         }
     }
     for (i = 6; i < 8; i++) /* off */ {
         int idx = off + i * istride;
         for (j = 0; j < 8; j++) {
             setpx(idx, -1 - j, rnd() & mask);
             setpx(idx, j, rnd() & mask);
         }
     }
 }
 #define randomize_buffers(bidx, lineoff, str) \
         randomize_loopfilter_buffers(bidx, lineoff, str, bit_depth, dir, \
                                      E, F, H, I, buf0, buf1)

 static void check_loopfilter(void)
 {
     LOCAL_ALIGNED_32(uint8_t, base0, [32 + 16 * 16 * 2]);
     LOCAL_ALIGNED_32(uint8_t, base1, [32 + 16 * 16 * 2]);
     VP9DSPContext dsp;
     int dir, wd, wd2, bit_depth;
     static const char *const dir_name[2] = { "h", "v" };
     static const int E[2] = { 20, 28 }, I[2] = { 10, 16 };
     static const int H[2] = { 7, 11 }, F[2] = { 1, 1 };
     declare_func(void, uint8_t *dst, ptrdiff_t stride, int E, int I, int H);

     for (bit_depth = 8; bit_depth <= 12; bit_depth += 2) {
         ff_vp9dsp_init(&dsp, bit_depth, 0);

         for (dir = 0; dir < 2; dir++) {
             int midoff = (dir ? 8 * 8 : 8) * SIZEOF_PIXEL;
             int midoff_aligned = (dir ? 8 * 8 : 16) * SIZEOF_PIXEL;
             uint8_t *buf0 = base0 + midoff_aligned;
             uint8_t *buf1 = base1 + midoff_aligned;

             for (wd = 0; wd < 3; wd++) {
                 // 4/8/16wd_8px
                 if (check_func(dsp.loop_filter_8[wd][dir],
                                "vp9_loop_filter_%s_%d_8_%dbpp",
                                dir_name[dir], 4 << wd, bit_depth)) {
                     randomize_buffers(0, 0, 8);
                     memcpy(buf1 - midoff, buf0 - midoff,
                            16 * 8 * SIZEOF_PIXEL);
                     call_ref(buf0, 16 * SIZEOF_PIXEL >> dir, E[0], I[0], H[0]);
                     call_new(buf1, 16 * SIZEOF_PIXEL >> dir, E[0], I[0], H[0]);
                     if (memcmp(buf0 - midoff, buf1 - midoff, 16 * 8 * SIZEOF_PIXEL))
                         fail();
                     bench_new(buf1, 16 * SIZEOF_PIXEL >> dir, E[0], I[0], H[0]);
                 }
             }

             midoff = (dir ? 16 * 8 : 8) * SIZEOF_PIXEL;
             midoff_aligned = (dir ? 16 * 8 : 16) * SIZEOF_PIXEL;

             buf0 = base0 + midoff_aligned;
             buf1 = base1 + midoff_aligned;

             // 16wd_16px loopfilter
             if (check_func(dsp.loop_filter_16[dir],
                            "vp9_loop_filter_%s_16_16_%dbpp",
                            dir_name[dir], bit_depth)) {
                 randomize_buffers(0, 0, 16);
                 randomize_buffers(0, 8, 16);
                 memcpy(buf1 - midoff, buf0 - midoff, 16 * 16 * SIZEOF_PIXEL);
                 call_ref(buf0, 16 * SIZEOF_PIXEL, E[0], I[0], H[0]);
                 call_new(buf1, 16 * SIZEOF_PIXEL, E[0], I[0], H[0]);
                 if (memcmp(buf0 - midoff, buf1 - midoff, 16 * 16 * SIZEOF_PIXEL))
                     fail();
                 bench_new(buf1, 16 * SIZEOF_PIXEL, E[0], I[0], H[0]);
             }

             for (wd = 0; wd < 2; wd++) {
                 for (wd2 = 0; wd2 < 2; wd2++) {
                     // mix2 loopfilter
                     if (check_func(dsp.loop_filter_mix2[wd][wd2][dir],
                                    "vp9_loop_filter_mix2_%s_%d%d_16_%dbpp",
                                    dir_name[dir], 4 << wd, 4 << wd2, bit_depth)) {
                         randomize_buffers(0, 0, 16);
                         randomize_buffers(1, 8, 16);
                         memcpy(buf1 - midoff, buf0 - midoff, 16 * 16 * SIZEOF_PIXEL);
 #define M(a) (((a)[1] << 8) | (a)[0])
                         call_ref(buf0, 16 * SIZEOF_PIXEL, M(E), M(I), M(H));
                         call_new(buf1, 16 * SIZEOF_PIXEL, M(E), M(I), M(H));
                         if (memcmp(buf0 - midoff, buf1 - midoff, 16 * 16 * SIZEOF_PIXEL))
                             fail();
                         bench_new(buf1, 16 * SIZEOF_PIXEL, M(E), M(I), M(H));
 #undef M
                     }
                 }
             }
         }
     }
     report("loopfilter");
 }

 #undef setsx
 #undef setpx
 #undef setdx
 #undef randomize_buffers

 #define DST_BUF_SIZE (size * size * SIZEOF_PIXEL)
 #define SRC_BUF_STRIDE 72
 #define SRC_BUF_SIZE ((size + 7) * SRC_BUF_STRIDE * SIZEOF_PIXEL)
 #define src (buf + 3 * SIZEOF_PIXEL * (SRC_BUF_STRIDE + 1))

 #define randomize_buffers()                               \
     do {                                                  \
         uint32_t mask = pixel_mask[(bit_depth - 8) >> 1]; \
         int k;                                            \
         for (k = 0; k < SRC_BUF_SIZE; k += 4) {           \
             uint32_t r = rnd() & mask;                    \
             AV_WN32A(buf + k, r);                         \
         }                                                 \
         if (op == 1) {                                    \
             for (k = 0; k < DST_BUF_SIZE; k += 4) {       \
                 uint32_t r = rnd() & mask;                \
                 AV_WN32A(dst0 + k, r);                    \
                 AV_WN32A(dst1 + k, r);                    \
             }                                             \
         }                                                 \
     } while (0)

 static void check_mc(void)
 {
     LOCAL_ALIGNED_32(uint8_t, buf, [72 * 72 * 2]);
     LOCAL_ALIGNED_32(uint8_t, dst0, [64 * 64 * 2]);
     LOCAL_ALIGNED_32(uint8_t, dst1, [64 * 64 * 2]);
     VP9DSPContext dsp;
     int op, hsize, bit_depth, filter, dx, dy;
     declare_func_emms(AV_CPU_FLAG_MMX | AV_CPU_FLAG_MMXEXT, void, uint8_t *dst, ptrdiff_t dst_stride,
                       const uint8_t *ref, ptrdiff_t ref_stride,
                  int h, int mx, int my);
     static const char *const filter_names[4] = {
         "8tap_smooth", "8tap_regular", "8tap_sharp", "bilin"
     };
     static const char *const subpel_names[2][2] = { { "", "h" }, { "v", "hv" } };
     static const char *const op_names[2] = { "put", "avg" };
     char str[256];

     for (op = 0; op < 2; op++) {
         for (bit_depth = 8; bit_depth <= 12; bit_depth += 2) {
             ff_vp9dsp_init(&dsp, bit_depth, 0);
             for (hsize = 0; hsize < 5; hsize++) {
                 int size = 64 >> hsize;

                 for (filter = 0; filter < 4; filter++) {
                     for (dx = 0; dx < 2; dx++) {
                         for (dy = 0; dy < 2; dy++) {
                             if (dx || dy) {
                                 snprintf(str, sizeof(str),
                                          "%s_%s_%d%s", op_names[op],
                                          filter_names[filter], size,
                                          subpel_names[dy][dx]);
                             } else {
                                 snprintf(str, sizeof(str),
                                          "%s%d", op_names[op], size);
                             }
                             if (check_func(dsp.mc[hsize][filter][op][dx][dy],
                                            "vp9_%s_%dbpp", str, bit_depth)) {
                                 int mx = dx ? 1 + (rnd() % 14) : 0;
                                 int my = dy ? 1 + (rnd() % 14) : 0;
                                 randomize_buffers();
                                 call_ref(dst0, size * SIZEOF_PIXEL,
                                          src, SRC_BUF_STRIDE * SIZEOF_PIXEL,
                                          size, mx, my);
                                 call_new(dst1, size * SIZEOF_PIXEL,
                                          src, SRC_BUF_STRIDE * SIZEOF_PIXEL,
                                          size, mx, my);
                                 if (memcmp(dst0, dst1, DST_BUF_SIZE))
                                     fail();

                                 // simd implementations for each filter of subpel
                                 // functions are identical
                                 if (filter >= 1 && filter <= 2) continue;
                                 // 10/12 bpp for bilin are identical
                                 if (bit_depth == 12 && filter == 3) continue;

                                 bench_new(dst1, size * SIZEOF_PIXEL,
                                           src, SRC_BUF_STRIDE * SIZEOF_PIXEL,
                                           size, mx, my);
                             }
                         }
                     }
                 }
             }
         }
     }
     report("mc");
 }

 void checkasm_check_vp9dsp(void)
 {
     check_ipred();
     check_itxfm();
     check_loopfilter();
     check_mc();
 }
	/*
	* Copyright (c) 2015 Ronald S. Bultje <rsbultje@gmail.com>
	*
	* 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 <math.h>
	#include <string.h>
	#include "checkasm.h"
	#include "libavcodec/vp9data.h"
	#include "libavcodec/vp9dsp.h"
	#include "libavutil/common.h"
	#include "libavutil/internal.h"
	#include "libavutil/intreadwrite.h"
	#include "libavutil/mathematics.h"

	static const uint32_t pixel_mask[3] = { 0xffffffff, 0x03ff03ff, 0x0fff0fff };
	#define SIZEOF_PIXEL ((bit_depth + 7) / 8)

	#define randomize_buffers() \
	do { \
	uint32_t mask = pixel_mask[(bit_depth - 8) >> 1]; \
	int k; \
	for (k = -4; k < SIZEOF_PIXEL * FFMAX(8, size); k += 4) { \
	uint32_t r = rnd() & mask; \
	AV_WN32A(a + k, r); \
	} \
	for (k = 0; k < size * SIZEOF_PIXEL; k += 4) { \
	uint32_t r = rnd() & mask; \
	AV_WN32A(l + k, r); \
	} \
	} while (0)

	static void check_ipred(void)
	{
	LOCAL_ALIGNED_32(uint8_t, a_buf, [64 * 2]);
	uint8_t a = &a_buf[32 2];
	LOCAL_ALIGNED_32(uint8_t, l, [32 * 2]);
	LOCAL_ALIGNED_32(uint8_t, dst0, [32 * 32 * 2]);
	LOCAL_ALIGNED_32(uint8_t, dst1, [32 * 32 * 2]);
	VP9DSPContext dsp;
	int tx, mode, bit_depth;
	declare_func_emms(AV_CPU_FLAG_MMX \| AV_CPU_FLAG_MMXEXT, void, uint8_t *dst, ptrdiff_t stride,
	const uint8_t left, const uint8_t top);
	static const char *const mode_names[N_INTRA_PRED_MODES] = {
	[VERT_PRED] = "vert",
	[HOR_PRED] = "hor",
	[DC_PRED] = "dc",
	[DIAG_DOWN_LEFT_PRED] = "diag_downleft",
	[DIAG_DOWN_RIGHT_PRED] = "diag_downright",
	[VERT_RIGHT_PRED] = "vert_right",
	[HOR_DOWN_PRED] = "hor_down",
	[VERT_LEFT_PRED] = "vert_left",
	[HOR_UP_PRED] = "hor_up",
	[TM_VP8_PRED] = "tm",
	[LEFT_DC_PRED] = "dc_left",
	[TOP_DC_PRED] = "dc_top",
	[DC_128_PRED] = "dc_128",
	[DC_127_PRED] = "dc_127",
	[DC_129_PRED] = "dc_129",
	};

	for (bit_depth = 8; bit_depth <= 12; bit_depth += 2) {
	ff_vp9dsp_init(&dsp, bit_depth, 0);
	for (tx = 0; tx < 4; tx++) {
	int size = 4 << tx;

	for (mode = 0; mode < N_INTRA_PRED_MODES; mode++) {
	if (check_func(dsp.intra_pred[tx][mode], "vp9_%s_%dx%d_%dbpp",
	mode_names[mode], size, size, bit_depth)) {
	randomize_buffers();
	call_ref(dst0, size * SIZEOF_PIXEL, l, a);
	call_new(dst1, size * SIZEOF_PIXEL, l, a);
	if (memcmp(dst0, dst1, size * size * SIZEOF_PIXEL))
	fail();
	bench_new(dst1, size * SIZEOF_PIXEL,l, a);
	}
	}
	}
	}
	report("ipred");
	}

	#undef randomize_buffers

	#define randomize_buffers() \
	do { \
	uint32_t mask = pixel_mask[(bit_depth - 8) >> 1]; \
	for (y = 0; y < sz; y++) { \
	for (x = 0; x < sz * SIZEOF_PIXEL; x += 4) { \
	uint32_t r = rnd() & mask; \
	AV_WN32A(dst + y * sz * SIZEOF_PIXEL + x, r); \
	AV_WN32A(src + y * sz * SIZEOF_PIXEL + x, rnd() & mask); \
	} \
	for (x = 0; x < sz; x++) { \
	if (bit_depth == 8) { \
	coef[y * sz + x] = src[y * sz + x] - dst[y * sz + x]; \
	} else { \
	((int32_t ) coef)[y sz + x] = \
	((uint16_t ) src)[y sz + x] - \
	((uint16_t ) dst)[y sz + x]; \
	} \
	} \
	} \
	} while(0)

	// wht function copied from libvpx
	static void fwht_1d(double out, const double in, int sz)
	{
	double t0 = in[0] + in[1];
	double t3 = in[3] - in[2];
	double t4 = trunc((t0 - t3) * 0.5);
	double t1 = t4 - in[1];
	double t2 = t4 - in[2];

	out[0] = t0 - t2;
	out[1] = t2;
	out[2] = t3 + t1;
	out[3] = t1;
	}

	// standard DCT-II
	static void fdct_1d(double out, const double in, int sz)
	{
	int k, n;

	for (k = 0; k < sz; k++) {
	out[k] = 0.0;
	for (n = 0; n < sz; n++)
	out[k] += in[n] * cos(M_PI * (2 * n + 1) * k / (sz * 2.0));
	}
	out[0] *= M_SQRT1_2;
	}

	// see "Towards jointly optimal spatial prediction and adaptive transform in
	// video/image coding", by J. Han, A. Saxena, and K. Rose
	// IEEE Proc. ICASSP, pp. 726-729, Mar. 2010.
	static void fadst4_1d(double out, const double in, int sz)
	{
	int k, n;

	for (k = 0; k < sz; k++) {
	out[k] = 0.0;
	for (n = 0; n < sz; n++)
	out[k] += in[n] * sin(M_PI * (n + 1) * (2 * k + 1) / (sz * 2.0 + 1.0));
	}
	}

	// see "A Butterfly Structured Design of The Hybrid Transform Coding Scheme",
	// by Jingning Han, Yaowu Xu, and Debargha Mukherjee
	// http://static.googleusercontent.com/media/research.google.com/en//pubs/archive/41418.pdf
	static void fadst_1d(double out, const double in, int sz)
	{
	int k, n;

	for (k = 0; k < sz; k++) {
	out[k] = 0.0;
	for (n = 0; n < sz; n++)
	out[k] += in[n] * sin(M_PI * (2 * n + 1) * (2 * k + 1) / (sz * 4.0));
	}
	}

	typedef void (ftx1d_fn)(double out, const double *in, int sz);
	static void ftx_2d(double out, const double in, enum TxfmMode tx,
	enum TxfmType txtp, int sz)
	{
	static const double scaling_factors[5][4] = {
	{ 4.0, 16.0 * M_SQRT1_2 / 3.0, 16.0 * M_SQRT1_2 / 3.0, 32.0 / 9.0 },
	{ 2.0, 2.0, 2.0, 2.0 },
	{ 1.0, 1.0, 1.0, 1.0 },
	{ 0.25 },
	{ 4.0 }
	};
	static const ftx1d_fn ftx1d_tbl[5][4][2] = {
	{
	{ fdct_1d, fdct_1d },
	{ fadst4_1d, fdct_1d },
	{ fdct_1d, fadst4_1d },
	{ fadst4_1d, fadst4_1d },
	}, {
	{ fdct_1d, fdct_1d },
	{ fadst_1d, fdct_1d },
	{ fdct_1d, fadst_1d },
	{ fadst_1d, fadst_1d },
	}, {
	{ fdct_1d, fdct_1d },
	{ fadst_1d, fdct_1d },
	{ fdct_1d, fadst_1d },
	{ fadst_1d, fadst_1d },
	}, {
	{ fdct_1d, fdct_1d },
	}, {
	{ fwht_1d, fwht_1d },
	},
	};
	double temp[1024];
	double scaling_factor = scaling_factors[tx][txtp];
	int i, j;

	// cols
	for (i = 0; i < sz; ++i) {
	double temp_out[32];

	ftx1d_tbl[tx][txtp][0](temp_out, &in[i * sz], sz);
	// scale and transpose
	for (j = 0; j < sz; ++j)
	temp[j * sz + i] = temp_out[j] * scaling_factor;
	}

	// rows
	for (i = 0; i < sz; i++)
	ftx1d_tbl[tx][txtp][1](&out[i * sz], &temp[i * sz], sz);
	}

	static void ftx(int16_t *buf, enum TxfmMode tx,
	enum TxfmType txtp, int sz, int bit_depth)
	{
	double ind[1024], outd[1024];
	int n;

	emms_c();
	for (n = 0; n < sz * sz; n++) {
	if (bit_depth == 8)
	ind[n] = buf[n];
	else
	ind[n] = ((int32_t *) buf)[n];
	}
	ftx_2d(outd, ind, tx, txtp, sz);
	for (n = 0; n < sz * sz; n++) {
	if (bit_depth == 8)
	buf[n] = lrint(outd[n]);
	else
	((int32_t *) buf)[n] = lrint(outd[n]);
	}
	}

	static int copy_subcoefs(int16_t out, const int16_t in, enum TxfmMode tx,
	enum TxfmType txtp, int sz, int sub, int bit_depth)
	{
	// copy the topleft coefficients such that the return value (being the
	// coefficient scantable index for the eob token) guarantees that only
	// the topleft $sub out of $sz (where $sz >= $sub) coefficients in both
	// dimensions are non-zero. This leads to braching to specific optimized
	// simd versions (e.g. dc-only) so that we get full asm coverage in this
	// test

	int n;
	const int16_t *scan = vp9_scans[tx][txtp];
	int eob;

	for (n = 0; n < sz * sz; n++) {
	int rc = scan[n], rcx = rc % sz, rcy = rc / sz;

	// find eob for this sub-idct
	if (rcx >= sub \|\| rcy >= sub)
	break;

	// copy coef
	if (bit_depth == 8) {
	out[rc] = in[rc];
	} else {
	AV_COPY32(&out[rc * 2], &in[rc * 2]);
	}
	}

	eob = n;

	for (; n < sz * sz; n++) {
	int rc = scan[n];

	// zero
	if (bit_depth == 8) {
	out[rc] = 0;
	} else {
	AV_ZERO32(&out[rc * 2]);
	}
	}

	return eob;
	}

	static int iszero(const int16_t *c, int sz)
	{
	int n;

	for (n = 0; n < sz / sizeof(int16_t); n += 2)
	if (AV_RN32A(&c[n]))
	return 0;

	return 1;
	}

	#define SIZEOF_COEF (2 * ((bit_depth + 7) / 8))

	static void check_itxfm(void)
	{
	LOCAL_ALIGNED_32(uint8_t, src, [32 * 32 * 2]);
	LOCAL_ALIGNED_32(uint8_t, dst, [32 * 32 * 2]);
	LOCAL_ALIGNED_32(uint8_t, dst0, [32 * 32 * 2]);
	LOCAL_ALIGNED_32(uint8_t, dst1, [32 * 32 * 2]);
	LOCAL_ALIGNED_32(int16_t, coef, [32 * 32 * 2]);
	LOCAL_ALIGNED_32(int16_t, subcoef0, [32 * 32 * 2]);
	LOCAL_ALIGNED_32(int16_t, subcoef1, [32 * 32 * 2]);
	declare_func_emms(AV_CPU_FLAG_MMX \| AV_CPU_FLAG_MMXEXT, void, uint8_t dst, ptrdiff_t stride, int16_t block, int eob);
	VP9DSPContext dsp;
	int y, x, tx, txtp, bit_depth, sub;
	static const char *const txtp_types[N_TXFM_TYPES] = {
	[DCT_DCT] = "dct_dct", [DCT_ADST] = "adst_dct",
	[ADST_DCT] = "dct_adst", [ADST_ADST] = "adst_adst"
	};

	for (bit_depth = 8; bit_depth <= 12; bit_depth += 2) {
	ff_vp9dsp_init(&dsp, bit_depth, 0);

	for (tx = TX_4X4; tx <= N_TXFM_SIZES /* 4 = lossless */; tx++) {
	int sz = 4 << (tx & 3);
	int n_txtps = tx < TX_32X32 ? N_TXFM_TYPES : 1;

	for (txtp = 0; txtp < n_txtps; txtp++) {
	if (check_func(dsp.itxfm_add[tx][txtp], "vp9_inv_%s_%dx%d_add_%d",
	tx == 4 ? "wht_wht" : txtp_types[txtp], sz, sz,
	bit_depth)) {
	randomize_buffers();
	ftx(coef, tx, txtp, sz, bit_depth);

	for (sub = (txtp == 0) ? 1 : 2; sub <= sz; sub <<= 1) {
	int eob;

	if (sub < sz) {
	eob = copy_subcoefs(subcoef0, coef, tx, txtp,
	sz, sub, bit_depth);
	} else {
	eob = sz * sz;
	memcpy(subcoef0, coef, sz * sz * SIZEOF_COEF);
	}

	memcpy(dst0, dst, sz * sz * SIZEOF_PIXEL);
	memcpy(dst1, dst, sz * sz * SIZEOF_PIXEL);
	memcpy(subcoef1, subcoef0, sz * sz * SIZEOF_COEF);
	call_ref(dst0, sz * SIZEOF_PIXEL, subcoef0, eob);
	call_new(dst1, sz * SIZEOF_PIXEL, subcoef1, eob);
	if (memcmp(dst0, dst1, sz * sz * SIZEOF_PIXEL) \|\|
	!iszero(subcoef0, sz * sz * SIZEOF_COEF) \|\|
	!iszero(subcoef1, sz * sz * SIZEOF_COEF))
	fail();
	}
	bench_new(dst, sz * SIZEOF_PIXEL, coef, sz * sz);
	}
	}
	}
	}
	report("itxfm");
	}

	#undef randomize_buffers

	#define setpx(a,b,c) \
	do { \
	if (SIZEOF_PIXEL == 1) { \
	buf0[(a) + (b) * jstride] = av_clip_uint8(c); \
	} else { \
	((uint16_t )buf0)[(a) + (b) jstride] = av_clip_uintp2(c, bit_depth); \
	} \
	} while (0)

	// c can be an assignment and must not be put under ()
	#define setdx(a,b,c,d) setpx(a,b,c-(d)+(rnd()%((d)*2+1)))
	#define setsx(a,b,c,d) setdx(a,b,c,(d) << (bit_depth - 8))
	static void randomize_loopfilter_buffers(int bidx, int lineoff, int str,
	int bit_depth, int dir, const int *E,
	const int F, const int H, const int *I,
	uint8_t buf0, uint8_t buf1)
	{
	uint32_t mask = (1 << bit_depth) - 1;
	int off = dir ? lineoff : lineoff * 16;
	int istride = dir ? 1 : 16;
	int jstride = dir ? str : 1;
	int i, j;
	for (i = 0; i < 2; i++) /* flat16 */ {
	int idx = off + i * istride, p0, q0;
	setpx(idx, 0, q0 = rnd() & mask);
	setsx(idx, -1, p0 = q0, E[bidx] >> 2);
	for (j = 1; j < 8; j++) {
	setsx(idx, -1 - j, p0, F[bidx]);
	setsx(idx, j, q0, F[bidx]);
	}
	}
	for (i = 2; i < 4; i++) /* flat8 */ {
	int idx = off + i * istride, p0, q0;
	setpx(idx, 0, q0 = rnd() & mask);
	setsx(idx, -1, p0 = q0, E[bidx] >> 2);
	for (j = 1; j < 4; j++) {
	setsx(idx, -1 - j, p0, F[bidx]);
	setsx(idx, j, q0, F[bidx]);
	}
	for (j = 4; j < 8; j++) {
	setpx(idx, -1 - j, rnd() & mask);
	setpx(idx, j, rnd() & mask);
	}
	}
	for (i = 4; i < 6; i++) /* regular */ {
	int idx = off + i * istride, p2, p1, p0, q0, q1, q2;
	setpx(idx, 0, q0 = rnd() & mask);
	setsx(idx, 1, q1 = q0, I[bidx]);
	setsx(idx, 2, q2 = q1, I[bidx]);
	setsx(idx, 3, q2, I[bidx]);
	setsx(idx, -1, p0 = q0, E[bidx] >> 2);
	setsx(idx, -2, p1 = p0, I[bidx]);
	setsx(idx, -3, p2 = p1, I[bidx]);
	setsx(idx, -4, p2, I[bidx]);
	for (j = 4; j < 8; j++) {
	setpx(idx, -1 - j, rnd() & mask);
	setpx(idx, j, rnd() & mask);
	}
	}
	for (i = 6; i < 8; i++) /* off */ {
	int idx = off + i * istride;
	for (j = 0; j < 8; j++) {
	setpx(idx, -1 - j, rnd() & mask);
	setpx(idx, j, rnd() & mask);
	}
	}
	}
	#define randomize_buffers(bidx, lineoff, str) \
	randomize_loopfilter_buffers(bidx, lineoff, str, bit_depth, dir, \
	E, F, H, I, buf0, buf1)

	static void check_loopfilter(void)
	{
	LOCAL_ALIGNED_32(uint8_t, base0, [32 + 16 * 16 * 2]);
	LOCAL_ALIGNED_32(uint8_t, base1, [32 + 16 * 16 * 2]);
	VP9DSPContext dsp;
	int dir, wd, wd2, bit_depth;
	static const char *const dir_name[2] = { "h", "v" };
	static const int E[2] = { 20, 28 }, I[2] = { 10, 16 };
	static const int H[2] = { 7, 11 }, F[2] = { 1, 1 };
	declare_func(void, uint8_t *dst, ptrdiff_t stride, int E, int I, int H);

	for (bit_depth = 8; bit_depth <= 12; bit_depth += 2) {
	ff_vp9dsp_init(&dsp, bit_depth, 0);

	for (dir = 0; dir < 2; dir++) {
	int midoff = (dir ? 8 * 8 : 8) * SIZEOF_PIXEL;
	int midoff_aligned = (dir ? 8 * 8 : 16) * SIZEOF_PIXEL;
	uint8_t *buf0 = base0 + midoff_aligned;
	uint8_t *buf1 = base1 + midoff_aligned;

	for (wd = 0; wd < 3; wd++) {
	// 4/8/16wd_8px
	if (check_func(dsp.loop_filter_8[wd][dir],
	"vp9_loop_filter_%s_%d_8_%dbpp",
	dir_name[dir], 4 << wd, bit_depth)) {
	randomize_buffers(0, 0, 8);
	memcpy(buf1 - midoff, buf0 - midoff,
	16 * 8 * SIZEOF_PIXEL);
	call_ref(buf0, 16 * SIZEOF_PIXEL >> dir, E[0], I[0], H[0]);
	call_new(buf1, 16 * SIZEOF_PIXEL >> dir, E[0], I[0], H[0]);
	if (memcmp(buf0 - midoff, buf1 - midoff, 16 * 8 * SIZEOF_PIXEL))
	fail();
	bench_new(buf1, 16 * SIZEOF_PIXEL >> dir, E[0], I[0], H[0]);
	}
	}

	midoff = (dir ? 16 * 8 : 8) * SIZEOF_PIXEL;
	midoff_aligned = (dir ? 16 * 8 : 16) * SIZEOF_PIXEL;

	buf0 = base0 + midoff_aligned;
	buf1 = base1 + midoff_aligned;

	// 16wd_16px loopfilter
	if (check_func(dsp.loop_filter_16[dir],
	"vp9_loop_filter_%s_16_16_%dbpp",
	dir_name[dir], bit_depth)) {
	randomize_buffers(0, 0, 16);
	randomize_buffers(0, 8, 16);
	memcpy(buf1 - midoff, buf0 - midoff, 16 * 16 * SIZEOF_PIXEL);
	call_ref(buf0, 16 * SIZEOF_PIXEL, E[0], I[0], H[0]);
	call_new(buf1, 16 * SIZEOF_PIXEL, E[0], I[0], H[0]);
	if (memcmp(buf0 - midoff, buf1 - midoff, 16 * 16 * SIZEOF_PIXEL))
	fail();
	bench_new(buf1, 16 * SIZEOF_PIXEL, E[0], I[0], H[0]);
	}

	for (wd = 0; wd < 2; wd++) {
	for (wd2 = 0; wd2 < 2; wd2++) {
	// mix2 loopfilter
	if (check_func(dsp.loop_filter_mix2[wd][wd2][dir],
	"vp9_loop_filter_mix2_%s_%d%d_16_%dbpp",
	dir_name[dir], 4 << wd, 4 << wd2, bit_depth)) {
	randomize_buffers(0, 0, 16);
	randomize_buffers(1, 8, 16);
	memcpy(buf1 - midoff, buf0 - midoff, 16 * 16 * SIZEOF_PIXEL);
	#define M(a) (((a)[1] << 8) \| (a)[0])
	call_ref(buf0, 16 * SIZEOF_PIXEL, M(E), M(I), M(H));
	call_new(buf1, 16 * SIZEOF_PIXEL, M(E), M(I), M(H));
	if (memcmp(buf0 - midoff, buf1 - midoff, 16 * 16 * SIZEOF_PIXEL))
	fail();
	bench_new(buf1, 16 * SIZEOF_PIXEL, M(E), M(I), M(H));
	#undef M
	}
	}
	}
	}
	}
	report("loopfilter");
	}

	#undef setsx
	#undef setpx
	#undef setdx
	#undef randomize_buffers

	#define DST_BUF_SIZE (size * size * SIZEOF_PIXEL)
	#define SRC_BUF_STRIDE 72
	#define SRC_BUF_SIZE ((size + 7) * SRC_BUF_STRIDE * SIZEOF_PIXEL)
	#define src (buf + 3 * SIZEOF_PIXEL * (SRC_BUF_STRIDE + 1))

	#define randomize_buffers() \
	do { \
	uint32_t mask = pixel_mask[(bit_depth - 8) >> 1]; \
	int k; \
	for (k = 0; k < SRC_BUF_SIZE; k += 4) { \
	uint32_t r = rnd() & mask; \
	AV_WN32A(buf + k, r); \
	} \
	if (op == 1) { \
	for (k = 0; k < DST_BUF_SIZE; k += 4) { \
	uint32_t r = rnd() & mask; \
	AV_WN32A(dst0 + k, r); \
	AV_WN32A(dst1 + k, r); \
	} \
	} \
	} while (0)

	static void check_mc(void)
	{
	LOCAL_ALIGNED_32(uint8_t, buf, [72 * 72 * 2]);
	LOCAL_ALIGNED_32(uint8_t, dst0, [64 * 64 * 2]);
	LOCAL_ALIGNED_32(uint8_t, dst1, [64 * 64 * 2]);
	VP9DSPContext dsp;
	int op, hsize, bit_depth, filter, dx, dy;
	declare_func_emms(AV_CPU_FLAG_MMX \| AV_CPU_FLAG_MMXEXT, void, uint8_t *dst, ptrdiff_t dst_stride,
	const uint8_t *ref, ptrdiff_t ref_stride,
	int h, int mx, int my);
	static const char *const filter_names[4] = {
	"8tap_smooth", "8tap_regular", "8tap_sharp", "bilin"
	};
	static const char *const subpel_names[2][2] = { { "", "h" }, { "v", "hv" } };
	static const char *const op_names[2] = { "put", "avg" };
	char str[256];

	for (op = 0; op < 2; op++) {
	for (bit_depth = 8; bit_depth <= 12; bit_depth += 2) {
	ff_vp9dsp_init(&dsp, bit_depth, 0);
	for (hsize = 0; hsize < 5; hsize++) {
	int size = 64 >> hsize;

	for (filter = 0; filter < 4; filter++) {
	for (dx = 0; dx < 2; dx++) {
	for (dy = 0; dy < 2; dy++) {
	if (dx \|\| dy) {
	snprintf(str, sizeof(str),
	"%s_%s_%d%s", op_names[op],
	filter_names[filter], size,
	subpel_names[dy][dx]);
	} else {
	snprintf(str, sizeof(str),
	"%s%d", op_names[op], size);
	}
	if (check_func(dsp.mc[hsize][filter][op][dx][dy],
	"vp9_%s_%dbpp", str, bit_depth)) {
	int mx = dx ? 1 + (rnd() % 14) : 0;
	int my = dy ? 1 + (rnd() % 14) : 0;
	randomize_buffers();
	call_ref(dst0, size * SIZEOF_PIXEL,
	src, SRC_BUF_STRIDE * SIZEOF_PIXEL,
	size, mx, my);
	call_new(dst1, size * SIZEOF_PIXEL,
	src, SRC_BUF_STRIDE * SIZEOF_PIXEL,
	size, mx, my);
	if (memcmp(dst0, dst1, DST_BUF_SIZE))
	fail();

	// simd implementations for each filter of subpel
	// functions are identical
	if (filter >= 1 && filter <= 2) continue;
	// 10/12 bpp for bilin are identical
	if (bit_depth == 12 && filter == 3) continue;

	bench_new(dst1, size * SIZEOF_PIXEL,
	src, SRC_BUF_STRIDE * SIZEOF_PIXEL,
	size, mx, my);
	}
	}
	}
	}
	}
	}
	}
	report("mc");
	}

	void checkasm_check_vp9dsp(void)
	{
	check_ipred();
	check_itxfm();
	check_loopfilter();
	check_mc();
	}