Esempio n. 1
0
address C1_MacroAssembler::call_c_with_frame_resize(address dest, int frame_resize) {
  if (frame_resize) { resize_frame(-frame_resize, R0); }
#if defined(ABI_ELFv2)
  address return_pc = call_c(dest, relocInfo::runtime_call_type);
#else
  address return_pc = call_c(CAST_FROM_FN_PTR(FunctionDescriptor*, dest), relocInfo::runtime_call_type);
#endif
  if (frame_resize) { resize_frame(frame_resize, R0); }
  return return_pc;
}
Esempio n. 2
0
static int check_cabac( int cpu_ref, int cpu_new )
{
    int ret = 0, ok, used_asm = 1;
    if( cpu_ref || run_cabac_c == run_cabac_asm)
        return 0;
    set_func_name( "cabac_encode_decision" );
    memcpy( buf4, buf3, 0x1000 );
    call_c( run_cabac_c, buf3 );
    call_a( run_cabac_asm, buf4 );
    ok = !memcmp( buf3, buf4, 0x1000 );
    report( "cabac :" );
    return ret;
}
Esempio n. 3
0
static int check_mc( int cpu_ref, int cpu_new )
{
    x264_mc_functions_t mc_c;
    x264_mc_functions_t mc_ref;
    x264_mc_functions_t mc_a;
    x264_pixel_function_t pixel;

    uint8_t *src     = &buf1[2*32+2];
    uint8_t *src2[4] = { &buf1[3*64+2], &buf1[5*64+2],
                         &buf1[7*64+2], &buf1[9*64+2] };
    uint8_t *dst1    = buf3;
    uint8_t *dst2    = buf4;

    int dx, dy, i, j, k, w;
    int ret = 0, ok, used_asm;

    x264_mc_init( 0, &mc_c );
    x264_mc_init( cpu_ref, &mc_ref );
    x264_mc_init( cpu_new, &mc_a );
    x264_pixel_init( 0, &pixel );

#define MC_TEST_LUMA( w, h ) \
        if( mc_a.mc_luma != mc_ref.mc_luma && !(w&(w-1)) && h<=16 ) \
        { \
            set_func_name( "mc_luma_%dx%d", w, h );\
            used_asm = 1; \
            memset(buf3, 0xCD, 1024); \
            memset(buf4, 0xCD, 1024); \
            call_c( mc_c.mc_luma, dst1, 32, src2, 64, dx, dy, w, h ); \
            call_a( mc_a.mc_luma, dst2, 32, src2, 64, dx, dy, w, h ); \
            if( memcmp( buf3, buf4, 1024 ) ) \
            { \
                fprintf( stderr, "mc_luma[mv(%d,%d) %2dx%-2d]     [FAILED]\n", dx, dy, w, h ); \
                ok = 0; \
            } \
        } \
        if( mc_a.get_ref != mc_ref.get_ref ) \
        { \
            uint8_t *ref = dst2; \
            int ref_stride = 32; \
            set_func_name( "get_ref_%dx%d", w, h );\
            used_asm = 1; \
            memset(buf3, 0xCD, 1024); \
            memset(buf4, 0xCD, 1024); \
            call_c( mc_c.mc_luma, dst1, 32, src2, 64, dx, dy, w, h ); \
            ref = (uint8_t*) call_a( mc_a.get_ref, ref, &ref_stride, src2, 64, dx, dy, w, h ); \
            for( i=0; i<h; i++ ) \
                if( memcmp( dst1+i*32, ref+i*ref_stride, w ) ) \
                { \
                    fprintf( stderr, "get_ref[mv(%d,%d) %2dx%-2d]     [FAILED]\n", dx, dy, w, h ); \
                    ok = 0; \
                    break; \
                } \
        }

#define MC_TEST_CHROMA( w, h ) \
        if( mc_a.mc_chroma != mc_ref.mc_chroma ) \
        { \
            set_func_name( "mc_chroma_%dx%d", w, h );\
            used_asm = 1; \
            memset(buf3, 0xCD, 1024); \
            memset(buf4, 0xCD, 1024); \
            call_c( mc_c.mc_chroma, dst1, 16, src, 32, dx, dy, w, h ); \
            call_a( mc_a.mc_chroma, dst2, 16, src, 32, dx, dy, w, h ); \
            /* mc_chroma width=2 may write garbage to the right of dst. ignore that. */\
            for( j=0; j<h; j++ ) \
                for( i=w; i<4; i++ ) \
                    dst2[i+j*16] = dst1[i+j*16]; \
            if( memcmp( buf3, buf4, 1024 ) ) \
            { \
                fprintf( stderr, "mc_chroma[mv(%d,%d) %2dx%-2d]     [FAILED]\n", dx, dy, w, h ); \
                ok = 0; \
            } \
        }
    ok = 1; used_asm = 0;
    for( dy = -8; dy < 8; dy++ )
        for( dx = -128; dx < 128; dx++ )
        {
            if( rand()&15 ) continue; // running all of them is too slow
            MC_TEST_LUMA( 20, 18 );
            MC_TEST_LUMA( 16, 16 );
            MC_TEST_LUMA( 16, 8 );
            MC_TEST_LUMA( 12, 10 );
            MC_TEST_LUMA( 8, 16 );
            MC_TEST_LUMA( 8, 8 );
            MC_TEST_LUMA( 8, 4 );
            MC_TEST_LUMA( 4, 8 );
            MC_TEST_LUMA( 4, 4 );
        }
    report( "mc luma :" );

    ok = 1; used_asm = 0;
    for( dy = -1; dy < 9; dy++ )
        for( dx = -1; dx < 9; dx++ )
        {
            MC_TEST_CHROMA( 8, 8 );
            MC_TEST_CHROMA( 8, 4 );
            MC_TEST_CHROMA( 4, 8 );
            MC_TEST_CHROMA( 4, 4 );
            MC_TEST_CHROMA( 4, 2 );
            MC_TEST_CHROMA( 2, 4 );
            MC_TEST_CHROMA( 2, 2 );
        }
    report( "mc chroma :" );
#undef MC_TEST_LUMA
#undef MC_TEST_CHROMA

#define MC_TEST_AVG( name, ... ) \
    for( i = 0, ok = 1, used_asm = 0; i < 10; i++ ) \
    { \
        memcpy( buf3, buf1, 1024 ); \
        memcpy( buf4, buf1, 1024 ); \
        if( mc_a.name[i] != mc_ref.name[i] ) \
        { \
            set_func_name( "%s_%s", #name, pixel_names[i] );\
            used_asm = 1; \
            call_c1( mc_c.name[i], buf3, 32, buf2, 16, ##__VA_ARGS__ ); \
            call_a1( mc_a.name[i], buf4, 32, buf2, 16, ##__VA_ARGS__ ); \
            if( memcmp( buf3, buf4, 1024 ) )               \
            { \
                ok = 0; \
                fprintf( stderr, #name "[%d]: [FAILED]\n", i ); \
            } \
            call_c2( mc_c.name[i], buf3, 32, buf2, 16, ##__VA_ARGS__ ); \
            call_a2( mc_a.name[i], buf4, 32, buf2, 16, ##__VA_ARGS__ ); \
        } \
    }
    MC_TEST_AVG( avg );
    report( "mc avg :" );
    ok = 1; used_asm = 0;
    for( w = -64; w <= 128 && ok; w++ )
        MC_TEST_AVG( avg_weight, w );
    report( "mc wpredb :" );

    if( mc_a.hpel_filter != mc_ref.hpel_filter )
    {
        uint8_t *src = buf1+8+2*64;
        uint8_t *dstc[3] = { buf3+8, buf3+8+16*64, buf3+8+32*64 };
        uint8_t *dsta[3] = { buf4+8, buf4+8+16*64, buf4+8+32*64 };
        set_func_name( "hpel_filter" );
        ok = 1; used_asm = 1;
        memset( buf3, 0, 4096 );
        memset( buf4, 0, 4096 );
        call_c( mc_c.hpel_filter, dstc[0], dstc[1], dstc[2], src, 64, 48, 10 );
        call_a( mc_a.hpel_filter, dsta[0], dsta[1], dsta[2], src, 64, 48, 10 );
        for( i=0; i<3; i++ )
            for( j=0; j<10; j++ )
                //FIXME ideally the first pixels would match too, but they aren't actually used
                if( memcmp( dstc[i]+j*64+2, dsta[i]+j*64+2, 43 ) )
                {
                    ok = 0;
                    fprintf( stderr, "hpel filter differs at plane %c line %d\n", "hvc"[i], j );
                    for( k=0; k<48; k++ )
                        printf("%02x%s", dstc[i][j*64+k], (k+1)&3 ? "" : " ");
                    printf("\n");
                    for( k=0; k<48; k++ )
                        printf("%02x%s", dsta[i][j*64+k], (k+1)&3 ? "" : " ");
                    printf("\n");
                    break;
                }
        report( "hpel filter :" );
    }

    if( mc_a.frame_init_lowres_core != mc_ref.frame_init_lowres_core )
    {
        uint8_t *dstc[4] = { buf3, buf3+1024, buf3+2048, buf3+3072 };
        uint8_t *dsta[4] = { buf4, buf4+1024, buf4+2048, buf3+3072 };
        set_func_name( "lowres_init" );
        for( w=40; w<=48; w+=8 )
            if( mc_a.frame_init_lowres_core != mc_ref.frame_init_lowres_core )
            {
                int stride = (w+8)&~15;
                used_asm = 1;
                call_c( mc_c.frame_init_lowres_core, buf1, dstc[0], dstc[1], dstc[2], dstc[3], w*2, stride, w, 16 );
                call_a( mc_a.frame_init_lowres_core, buf1, dsta[0], dsta[1], dsta[2], dsta[3], w*2, stride, w, 16 );
                for( i=0; i<16; i++)
                {
                    for( j=0; j<4; j++)
                        if( memcmp( dstc[j]+i*stride, dsta[j]+i*stride, w ) )
                        {
                            ok = 0;
                            fprintf( stderr, "frame_init_lowres differs at plane %d line %d\n", j, i );
                            for( k=0; k<w; k++ )
                                printf( "%d ", dstc[j][k+i*stride] );
                            printf("\n");
                            for( k=0; k<w; k++ )
                                printf( "%d ", dsta[j][k+i*stride] );
                            printf("\n");
                            break;
                        }
                }
            }
        report( "lowres init :" );
    }

    return ret;
}
Esempio n. 4
0
static int check_dct( int cpu_ref, int cpu_new )
{
    x264_dct_function_t dct_c;
    x264_dct_function_t dct_ref;
    x264_dct_function_t dct_asm;
    x264_quant_function_t qf;
    int ret = 0, ok, used_asm, i, interlace;
    DECLARE_ALIGNED_16( int16_t dct1[16][4][4] );
    DECLARE_ALIGNED_16( int16_t dct2[16][4][4] );
    DECLARE_ALIGNED_16( int16_t dct4[16][4][4] );
    DECLARE_ALIGNED_16( int16_t dct8[4][8][8] );
    x264_t h_buf;
    x264_t *h = &h_buf;

    x264_dct_init( 0, &dct_c );
    x264_dct_init( cpu_ref, &dct_ref);
    x264_dct_init( cpu_new, &dct_asm );

    memset( h, 0, sizeof(*h) );
    h->pps = h->pps_array;
    x264_param_default( &h->param );
    h->param.analyse.i_luma_deadzone[0] = 0;
    h->param.analyse.i_luma_deadzone[1] = 0;
    h->param.analyse.b_transform_8x8 = 1;
    for( i=0; i<6; i++ )
        h->pps->scaling_list[i] = x264_cqm_flat16;
    x264_cqm_init( h );
    x264_quant_init( h, 0, &qf );

#define TEST_DCT( name, t1, t2, size ) \
    if( dct_asm.name != dct_ref.name ) \
    { \
        set_func_name( #name );\
        used_asm = 1; \
        call_c( dct_c.name, t1, buf1, buf2 ); \
        call_a( dct_asm.name, t2, buf1, buf2 ); \
        if( memcmp( t1, t2, size ) ) \
        { \
            ok = 0; \
            fprintf( stderr, #name " [FAILED]\n" ); \
        } \
    }
    ok = 1; used_asm = 0;
    TEST_DCT( sub4x4_dct, dct1[0], dct2[0], 16*2 );
    TEST_DCT( sub8x8_dct, dct1, dct2, 16*2*4 );
    TEST_DCT( sub16x16_dct, dct1, dct2, 16*2*16 );
    report( "sub_dct4 :" );

    ok = 1; used_asm = 0;
    TEST_DCT( sub8x8_dct8, (void*)dct1[0], (void*)dct2[0], 64*2 );
    TEST_DCT( sub16x16_dct8, (void*)dct1, (void*)dct2, 64*2*4 );
    report( "sub_dct8 :" );
#undef TEST_DCT

    // fdct and idct are denormalized by different factors, so quant/dequant
    // is needed to force the coefs into the right range.
    dct_c.sub16x16_dct( dct4, buf1, buf2 );
    dct_c.sub16x16_dct8( dct8, buf1, buf2 );
    for( i=0; i<16; i++ )
    {
        qf.quant_4x4( dct4[i], h->quant4_mf[CQM_4IY][20], h->quant4_bias[CQM_4IY][20] );
        qf.dequant_4x4( dct4[i], h->dequant4_mf[CQM_4IY], 20 );
    }
    for( i=0; i<4; i++ )
    {
        qf.quant_8x8( dct8[i], h->quant8_mf[CQM_8IY][20], h->quant8_bias[CQM_8IY][20] );
        qf.dequant_8x8( dct8[i], h->dequant8_mf[CQM_8IY], 20 );
    }

#define TEST_IDCT( name, src ) \
    if( dct_asm.name != dct_ref.name ) \
    { \
        set_func_name( #name );\
        used_asm = 1; \
        memcpy( buf3, buf1, 32*32 ); \
        memcpy( buf4, buf1, 32*32 ); \
        memcpy( dct1, src, 512 ); \
        memcpy( dct2, src, 512 ); \
        call_c1( dct_c.name, buf3, (void*)dct1 ); \
        call_a1( dct_asm.name, buf4, (void*)dct2 ); \
        if( memcmp( buf3, buf4, 32*32 ) ) \
        { \
            ok = 0; \
            fprintf( stderr, #name " [FAILED]\n" ); \
        } \
        call_c2( dct_c.name, buf3, (void*)dct1 ); \
        call_a2( dct_asm.name, buf4, (void*)dct2 ); \
    }
    ok = 1; used_asm = 0;
    TEST_IDCT( add4x4_idct, dct4 );
    TEST_IDCT( add8x8_idct, dct4 );
    TEST_IDCT( add16x16_idct, dct4 );
    report( "add_idct4 :" );

    ok = 1; used_asm = 0;
    TEST_IDCT( add8x8_idct8, dct8 );
    TEST_IDCT( add16x16_idct8, dct8 );
    report( "add_idct8 :" );
#undef TEST_IDCT

    ok = 1; used_asm = 0;
    if( dct_asm.dct4x4dc != dct_ref.dct4x4dc )
    {
        DECLARE_ALIGNED_16( int16_t dct1[4][4] ) = {{-12, 42, 23, 67},{2, 90, 89,56},{67,43,-76,91},{56,-78,-54,1}};
        DECLARE_ALIGNED_16( int16_t dct2[4][4] ) = {{-12, 42, 23, 67},{2, 90, 89,56},{67,43,-76,91},{56,-78,-54,1}};
        set_func_name( "dct4x4dc" );
        used_asm = 1;
        call_c1( dct_c.dct4x4dc, dct1 );
        call_a1( dct_asm.dct4x4dc, dct2 );
        if( memcmp( dct1, dct2, 32 ) )
        {
            ok = 0;
            fprintf( stderr, " - dct4x4dc :        [FAILED]\n" );
        }
        call_c2( dct_c.dct4x4dc, dct1 );
        call_a2( dct_asm.dct4x4dc, dct2 );
    }
    if( dct_asm.idct4x4dc != dct_ref.idct4x4dc )
    {
        DECLARE_ALIGNED_16( int16_t dct1[4][4] ) = {{-12, 42, 23, 67},{2, 90, 89,56},{67,43,-76,91},{56,-78,-54,1}};
        DECLARE_ALIGNED_16( int16_t dct2[4][4] ) = {{-12, 42, 23, 67},{2, 90, 89,56},{67,43,-76,91},{56,-78,-54,1}};
        set_func_name( "idct4x4dc" );
        used_asm = 1;
        call_c1( dct_c.idct4x4dc, dct1 );
        call_a1( dct_asm.idct4x4dc, dct2 );
        if( memcmp( dct1, dct2, 32 ) )
        {
            ok = 0;
            fprintf( stderr, " - idct4x4dc :        [FAILED]\n" );
        }
        call_c2( dct_c.idct4x4dc, dct1 );
        call_a2( dct_asm.idct4x4dc, dct2 );
    }
    report( "(i)dct4x4dc :" );

    ok = 1; used_asm = 0;
    if( dct_asm.dct2x2dc != dct_ref.dct2x2dc )
    {
        DECLARE_ALIGNED_16( int16_t dct1[2][2] ) = {{-12, 42},{2, 90}};
        DECLARE_ALIGNED_16( int16_t dct2[2][2] ) = {{-12, 42},{2, 90}};
        set_func_name( "dct2x2dc" );
        used_asm = 1;
        call_c( dct_c.dct2x2dc, dct1 );
        call_a( dct_asm.dct2x2dc, dct2 );
        if( memcmp( dct1, dct2, 4*2 ) )
        {
            ok = 0;
            fprintf( stderr, " - dct2x2dc :        [FAILED]\n" );
        }
    }
    if( dct_asm.idct2x2dc != dct_ref.idct2x2dc )
    {
        DECLARE_ALIGNED_16( int16_t dct1[2][2] ) = {{-12, 42},{2, 90}};
        DECLARE_ALIGNED_16( int16_t dct2[2][2] ) = {{-12, 42},{2, 90}};
        set_func_name( "idct2x2dc" );
        used_asm = 1;
        call_c( dct_c.idct2x2dc, dct1 );
        call_a( dct_asm.idct2x2dc, dct2 );
        if( memcmp( dct1, dct2, 4*2 ) )
        {
            ok = 0;
            fprintf( stderr, " - idct2x2dc :       [FAILED]\n" );
        }
    }
    report( "(i)dct2x2dc :" );

    x264_zigzag_function_t zigzag_c;
    x264_zigzag_function_t zigzag_ref;
    x264_zigzag_function_t zigzag_asm;

    DECLARE_ALIGNED_16( int16_t level1[64] );
    DECLARE_ALIGNED_16( int16_t level2[64] );

#define TEST_ZIGZAG_SCAN( name, t1, t2, dct, size )   \
    if( zigzag_asm.name != zigzag_ref.name ) \
    { \
        set_func_name( "zigzag_"#name"_%s", interlace?"field":"frame" );\
        used_asm = 1; \
        call_c( zigzag_c.name, t1, dct ); \
        call_a( zigzag_asm.name, t2, dct ); \
        if( memcmp( t1, t2, size*sizeof(int16_t) ) ) \
        { \
            ok = 0; \
            fprintf( stderr, #name " [FAILED]\n" ); \
        } \
    }

#define TEST_ZIGZAG_SUB( name, t1, t2, size ) \
    if( zigzag_asm.name != zigzag_ref.name ) \
    { \
        set_func_name( "zigzag_"#name"_%s", interlace?"field":"frame" );\
        used_asm = 1; \
        memcpy( buf3, buf1, 16*FDEC_STRIDE ); \
        memcpy( buf4, buf1, 16*FDEC_STRIDE ); \
        call_c1( zigzag_c.name, t1, buf2, buf3 );  \
        call_a1( zigzag_asm.name, t2, buf2, buf4 ); \
        if( memcmp( t1, t2, size*sizeof(int16_t) )|| memcmp( buf3, buf4, 16*FDEC_STRIDE ) )  \
        { \
            ok = 0; \
            fprintf( stderr, #name " [FAILED]\n" ); \
        } \
        call_c2( zigzag_c.name, t1, buf2, buf3 );  \
        call_a2( zigzag_asm.name, t2, buf2, buf4 ); \
    }

    interlace = 0;
    x264_zigzag_init( 0, &zigzag_c, 0 );
    x264_zigzag_init( cpu_ref, &zigzag_ref, 0 );
    x264_zigzag_init( cpu_new, &zigzag_asm, 0 );

    ok = 1; used_asm = 0;
    TEST_ZIGZAG_SCAN( scan_8x8, level1, level2, (void*)dct1, 64 );
    TEST_ZIGZAG_SCAN( scan_4x4, level1, level2, dct1[0], 16  );
    TEST_ZIGZAG_SUB( sub_4x4, level1, level2, 16 );
    report( "zigzag_frame :" );

    interlace = 1;
    x264_zigzag_init( 0, &zigzag_c, 1 );
    x264_zigzag_init( cpu_ref, &zigzag_ref, 1 );
    x264_zigzag_init( cpu_new, &zigzag_asm, 1 );

    ok = 1; used_asm = 0;
    TEST_ZIGZAG_SCAN( scan_8x8, level1, level2, (void*)dct1, 64 );
    TEST_ZIGZAG_SCAN( scan_4x4, level1, level2, dct1[0], 16  );
    TEST_ZIGZAG_SUB( sub_4x4, level1, level2, 16 );
    report( "zigzag_field :" );
#undef TEST_ZIGZAG_SCAN
#undef TEST_ZIGZAG_SUB

    return ret;
}
Esempio n. 5
0
static int check_pixel( int cpu_ref, int cpu_new )
{
    x264_pixel_function_t pixel_c;
    x264_pixel_function_t pixel_ref;
    x264_pixel_function_t pixel_asm;
    x264_predict_t predict_16x16[4+3];
    x264_predict_t predict_8x8c[4+3];
    x264_predict_t predict_4x4[9+3];
    x264_predict8x8_t predict_8x8[9+3];
    DECLARE_ALIGNED_16( uint8_t edge[33] );
    uint16_t cost_mv[32];
    int ret = 0, ok, used_asm;
    int i, j;

    x264_pixel_init( 0, &pixel_c );
    x264_pixel_init( cpu_ref, &pixel_ref );
    x264_pixel_init( cpu_new, &pixel_asm );
    x264_predict_16x16_init( 0, predict_16x16 );
    x264_predict_8x8c_init( 0, predict_8x8c );
    x264_predict_8x8_init( 0, predict_8x8 );
    x264_predict_4x4_init( 0, predict_4x4 );
    x264_predict_8x8_filter( buf2+40, edge, ALL_NEIGHBORS, ALL_NEIGHBORS );

#define TEST_PIXEL( name, align ) \
    for( i = 0, ok = 1, used_asm = 0; i < 7; i++ ) \
    { \
        int res_c, res_asm; \
        if( pixel_asm.name[i] != pixel_ref.name[i] ) \
        { \
            set_func_name( "%s_%s", #name, pixel_names[i] ); \
            for( j=0; j<64; j++ ) \
            { \
                used_asm = 1; \
                res_c   = call_c( pixel_c.name[i], buf1, 16, buf2+j*!align, 64 ); \
                res_asm = call_a( pixel_asm.name[i], buf1, 16, buf2+j*!align, 64 ); \
                if( res_c != res_asm ) \
                { \
                    ok = 0; \
                    fprintf( stderr, #name "[%d]: %d != %d [FAILED]\n", i, res_c, res_asm ); \
                    break; \
                } \
            } \
        } \
    } \
    report( "pixel " #name " :" );

    TEST_PIXEL( sad, 0 );
    TEST_PIXEL( ssd, 1 );
    TEST_PIXEL( satd, 0 );
    TEST_PIXEL( sa8d, 0 );

#define TEST_PIXEL_X( N ) \
    for( i = 0, ok = 1, used_asm = 0; i < 7; i++ ) \
    { \
        int res_c[4]={0}, res_asm[4]={0}; \
        if( pixel_asm.sad_x##N[i] && pixel_asm.sad_x##N[i] != pixel_ref.sad_x##N[i] ) \
        { \
            set_func_name( "sad_x%d_%s", N, pixel_names[i] ); \
            for( j=0; j<64; j++) \
            { \
                uint8_t *pix2 = buf2+j; \
                used_asm = 1; \
                res_c[0] = pixel_c.sad[i]( buf1, 16, pix2, 64 ); \
                res_c[1] = pixel_c.sad[i]( buf1, 16, pix2+6, 64 ); \
                res_c[2] = pixel_c.sad[i]( buf1, 16, pix2+1, 64 ); \
                if(N==4) \
                { \
                    res_c[3] = pixel_c.sad[i]( buf1, 16, pix2+10, 64 ); \
                    call_a( pixel_asm.sad_x4[i], buf1, pix2, pix2+6, pix2+1, pix2+10, 64, res_asm ); \
                } \
                else \
                    call_a( pixel_asm.sad_x3[i], buf1, pix2, pix2+6, pix2+1, 64, res_asm ); \
                if( memcmp(res_c, res_asm, sizeof(res_c)) ) \
                { \
                    ok = 0; \
                    fprintf( stderr, "sad_x"#N"[%d]: %d,%d,%d,%d != %d,%d,%d,%d [FAILED]\n", \
                             i, res_c[0], res_c[1], res_c[2], res_c[3], \
                             res_asm[0], res_asm[1], res_asm[2], res_asm[3] ); \
                } \
                if(N==4) \
                    call_c2( pixel_c.sad_x4[i], buf1, pix2, pix2+6, pix2+1, pix2+10, 64, res_asm ); \
                else \
                    call_c2( pixel_c.sad_x3[i], buf1, pix2, pix2+6, pix2+1, 64, res_asm ); \
            } \
        } \
    } \
    report( "pixel sad_x"#N" :" );

    TEST_PIXEL_X(3);
    TEST_PIXEL_X(4);

#define TEST_PIXEL_VAR( i ) \
    if( pixel_asm.var[i] != pixel_ref.var[i] ) \
    { \
        uint32_t res_c, res_asm; \
        uint32_t sad_c, sad_asm; \
        set_func_name( "%s_%s", "var", pixel_names[i] ); \
        used_asm = 1; \
        res_c   = call_c( pixel_c.var[i], buf1, 16, &sad_c ); \
        res_asm = call_a( pixel_asm.var[i], buf1, 16, &sad_asm ); \
        if( (res_c != res_asm) || (sad_c != sad_asm) ) \
        { \
            ok = 0; \
            fprintf( stderr, "var[%d]: %d,%d != %d,%d [FAILED]\n", i, res_c, sad_c, res_asm, sad_asm ); \
        } \
    }

    ok = 1; used_asm = 0;
    TEST_PIXEL_VAR( PIXEL_16x16 );
    TEST_PIXEL_VAR( PIXEL_8x8 );
    report( "pixel var :" );

#define TEST_INTRA_SATD( name, pred, satd, i8x8, ... ) \
    if( pixel_asm.name && pixel_asm.name != pixel_ref.name ) \
    { \
        int res_c[3], res_asm[3]; \
        set_func_name( #name );\
        used_asm = 1; \
        memcpy( buf3, buf2, 1024 ); \
        for( i=0; i<3; i++ ) \
        { \
            pred[i]( buf3+40, ##__VA_ARGS__ ); \
            res_c[i] = pixel_c.satd( buf1+40, 16, buf3+40, 32 ); \
        } \
        call_a( pixel_asm.name, buf1+40, i8x8 ? edge : buf3+40, res_asm ); \
        if( memcmp(res_c, res_asm, sizeof(res_c)) ) \
        { \
            ok = 0; \
            fprintf( stderr, #name": %d,%d,%d != %d,%d,%d [FAILED]\n", \
                     res_c[0], res_c[1], res_c[2], \
                     res_asm[0], res_asm[1], res_asm[2] ); \
        } \
    }

    ok = 1; used_asm = 0;
    TEST_INTRA_SATD( intra_satd_x3_16x16, predict_16x16, satd[PIXEL_16x16], 0 );
    TEST_INTRA_SATD( intra_satd_x3_8x8c, predict_8x8c, satd[PIXEL_8x8], 0 );
    TEST_INTRA_SATD( intra_satd_x3_4x4, predict_4x4, satd[PIXEL_4x4], 0 );
    TEST_INTRA_SATD( intra_sa8d_x3_8x8, predict_8x8, sa8d[PIXEL_8x8], 1, edge );
    report( "intra satd_x3 :" );

    if( pixel_asm.ssim_4x4x2_core != pixel_ref.ssim_4x4x2_core ||
        pixel_asm.ssim_end4 != pixel_ref.ssim_end4 )
    {
        float res_c, res_a;
        int sums[5][4] = {{0}};
        used_asm = ok = 1;
        x264_emms();
        res_c = x264_pixel_ssim_wxh( &pixel_c,   buf1+2, 32, buf2+2, 32, 32, 28 );
        res_a = x264_pixel_ssim_wxh( &pixel_asm, buf1+2, 32, buf2+2, 32, 32, 28 );
        if( fabs(res_c - res_a) > 1e-6 )
        {
            ok = 0;
            fprintf( stderr, "ssim: %.7f != %.7f [FAILED]\n", res_c, res_a );
        }
        set_func_name( "ssim_core" );
        call_c2( pixel_c.ssim_4x4x2_core,   buf1+2, 32, buf2+2, 32, sums );
        call_a2( pixel_asm.ssim_4x4x2_core, buf1+2, 32, buf2+2, 32, sums );
        set_func_name( "ssim_end" );
        call_c2( pixel_c.ssim_end4,   sums, sums, 4 );
        call_a2( pixel_asm.ssim_end4, sums, sums, 4 );
        report( "ssim :" );
    }

    ok = 1; used_asm = 0;
    for( i=0; i<32; i++ )
        cost_mv[i] = i*10;
    for( i=0; i<100 && ok; i++ )
        if( pixel_asm.ads[i&3] != pixel_ref.ads[i&3] )
        {
            DECLARE_ALIGNED_16( uint16_t sums[72] );
            DECLARE_ALIGNED_16( int dc[4] );
            int16_t mvs_a[32], mvs_c[32];
            int mvn_a, mvn_c;
            int thresh = rand() & 0x3fff;
            set_func_name( "esa_ads" );
            for( j=0; j<72; j++ )
                sums[j] = rand() & 0x3fff;
            for( j=0; j<4; j++ )
                dc[j] = rand() & 0x3fff;
            used_asm = 1;
            mvn_c = call_c( pixel_c.ads[i&3], dc, sums, 32, cost_mv, mvs_c, 28, thresh );
            mvn_a = call_a( pixel_asm.ads[i&3], dc, sums, 32, cost_mv, mvs_a, 28, thresh );
            if( mvn_c != mvn_a || memcmp( mvs_c, mvs_a, mvn_c*sizeof(*mvs_c) ) )
            {
                ok = 0;
                printf("c%d: ", i&3);
                for(j=0; j<mvn_c; j++)
                    printf("%d ", mvs_c[j]);
                printf("\na%d: ", i&3);
                for(j=0; j<mvn_a; j++)
                    printf("%d ", mvs_a[j]);
                printf("\n\n");
            }
        }
    report( "esa ads:" );

    return ret;
}
Esempio n. 6
0
inline address MacroAssembler::call_stub(address function_entry) {
  return call_c(function_entry);
}
Esempio n. 7
0
int check_intra( int cpu_ref, int cpu_new ){

    int ret = 0, ok = 1, used_asm = 0;
    ALIGNED_ARRAY_32( pixel, edge,[36] );
    ALIGNED_ARRAY_32( pixel, edge2,[36] );
    ALIGNED_ARRAY_32( pixel, fdec,[FDEC_STRIDE*20] );
    
    struct
    {
        vbench_predict_t      predict_16x16[4+3];
        vbench_predict_t      predict_8x8c[4+3];
        vbench_predict_t      predict_8x16c[4+3];
        vbench_predict8x8_t   predict_8x8[9+3];
        vbench_predict_t      predict_4x4[9+3];
        vbench_predict_8x8_filter_t predict_8x8_filter;
    } ip_c, ip_ref, ip_a;

    vbench_predict_16x16_init( 0, ip_c.predict_16x16 );
    vbench_predict_8x8c_init( 0, ip_c.predict_8x8c );
    vbench_predict_8x16c_init( 0, ip_c.predict_8x16c );
    vbench_predict_8x8_init( 0, ip_c.predict_8x8, &ip_c.predict_8x8_filter );
    vbench_predict_4x4_init( 0, ip_c.predict_4x4 );

    vbench_predict_16x16_init( cpu_ref, ip_ref.predict_16x16 );
    vbench_predict_8x8c_init( cpu_ref, ip_ref.predict_8x8c );
    vbench_predict_8x16c_init( cpu_ref, ip_ref.predict_8x16c );
    vbench_predict_8x8_init( cpu_ref, ip_ref.predict_8x8, &ip_ref.predict_8x8_filter );
    vbench_predict_4x4_init( cpu_ref, ip_ref.predict_4x4 );

    vbench_predict_16x16_init( cpu_new, ip_a.predict_16x16 );
    vbench_predict_8x8c_init( cpu_new, ip_a.predict_8x8c );
    vbench_predict_8x16c_init( cpu_new, ip_a.predict_8x16c );
    vbench_predict_8x8_init( cpu_new, ip_a.predict_8x8, &ip_a.predict_8x8_filter );
    vbench_predict_4x4_init( cpu_new, ip_a.predict_4x4 );

    memcpy( fdec, pbuf1, 32*20 * sizeof(pixel) );\

    ip_c.predict_8x8_filter( fdec+48, edge, ALL_NEIGHBORS, ALL_NEIGHBORS );

#define INTRA_TEST( name, dir, w, h, align, bench, ... )\
    if( ip_a.name[dir] != ip_ref.name[dir] )\
    {\
        set_func_name( "intra_%s_%s", #name, intra_##name##_names[dir] );\
        used_asm = 1;\
        memcpy( pbuf3, fdec, FDEC_STRIDE*20 * sizeof(pixel) );\
        memcpy( pbuf4, fdec, FDEC_STRIDE*20 * sizeof(pixel) );\
        for( int a = 0; a < ( 64/sizeof(pixel) ); a += align )\
        {\
            call_c##bench( ip_c.name[dir], pbuf3+48+a, ##__VA_ARGS__ );\
            call_a##bench( ip_a.name[dir], pbuf4+48+a, ##__VA_ARGS__ );\
            if( memcmp( pbuf3, pbuf4, FDEC_STRIDE*20 * sizeof(pixel) ) )\
            {\
                fprintf( stderr, #name "[%d] :  [FAILED]\n", dir );\
                ok = 0;\
                if( ip_c.name == (void *)ip_c.predict_8x8 )\
                {\
                    for( int k = -1; k < 16; k++ )\
                        printf( "%2x ", edge[16+k] );\
                    printf( "\n" );\
                }\
                for( int j = 0; j < h; j++ )\
                {\
                    if( ip_c.name == (void *)ip_c.predict_8x8 )\
                        printf( "%2x ", edge[14-j] );\
                    for( int k = 0; k < w; k++ )\
                        printf( "%2x ", pbuf4[48+k+j*FDEC_STRIDE] );\
                    printf( "\n" );\
                }\
                printf( "\n" );\
                for( int j = 0; j < h; j++ )\
                {\
                    if( ip_c.name == (void *)ip_c.predict_8x8 )\
                        printf( "   " );\
                    for( int k = 0; k < w; k++ )\
                        printf( "%2x ", pbuf3[48+k+j*FDEC_STRIDE] );\
                    printf( "\n" );\
                }\
                break;\
            }\
        }\
    }

    for( int i = 0; i < 12; i++ )
        INTRA_TEST(   predict_4x4, i,  4,  4,  4, );
    for( int i = 0; i < 7; i++ )
        INTRA_TEST(  predict_8x8c, i,  8,  8, 16, );
    for( int i = 0; i < 7; i++ )
        INTRA_TEST( predict_8x16c, i,  8, 16, 16, );
    for( int i = 0; i < 7; i++ )
        INTRA_TEST( predict_16x16, i, 16, 16, 16, );
    for( int i = 0; i < 12; i++ )
        INTRA_TEST(   predict_8x8, i,  8,  8,  8, , edge );

    set_func_name("intra_predict_8x8_filter");
    if( ip_a.predict_8x8_filter != ip_ref.predict_8x8_filter )
    {
        used_asm = 1;
        for( int i = 0; i < 32; i++ )
        {
            if( !(i&7) || ((i&MB_TOPRIGHT) && !(i&MB_TOP)) )
                continue;
            int neighbor = (i&24)>>1;
            memset( edge,  0, 36*sizeof(pixel) );
            memset( edge2, 0, 36*sizeof(pixel) );
            call_c( ip_c.predict_8x8_filter, pbuf1+48, edge,  neighbor, i&7 );
            call_a( ip_a.predict_8x8_filter, pbuf1+48, edge2, neighbor, i&7 );
            if( !(neighbor&MB_TOPLEFT) )
                edge[15] = edge2[15] = 0;
            if( memcmp( edge+7, edge2+7, (i&MB_TOPRIGHT ? 26 : i&MB_TOP ? 17 : 8) * sizeof(pixel) ) )
            {
                fprintf( stderr, "predict_8x8_filter :  [FAILED] %d %d\n", (i&24)>>1, i&7);
                ok = 0;
            }
        }