yuv2rgb.c

从FFMPEG转换而来的H264解码程序,VC下编译..

#define DST1_4(i)					\
	Y = py_1[2*i];				\
	acc = r[Y] + g[Y] + b[Y];	\
	Y = py_1[2*i+1];			\
        acc |= (r[Y] + g[Y] + b[Y])<<4;\
	dst_1[i] = acc;

#define DST2_4(i)					\
	Y = py_2[2*i];				\
	acc = r[Y] + g[Y] + b[Y];	\
	Y = py_2[2*i+1];			\
	acc |= (r[Y] + g[Y] + b[Y])<<4;\
	dst_2[i] = acc;

        RGB(0);
	DST1_4(0);
	DST2_4(0);

	RGB(1);
	DST2_4(1);
	DST1_4(1);

	RGB(2);
	DST1_4(2);
	DST2_4(2);

	RGB(3);
	DST2_4(3);
	DST1_4(3);
EPILOG(4)

PROLOG(yuv2rgb_c_4_ordered_dither, uint8_t)
	const uint8_t *d64= dither_8x8_73[y&7];
	const uint8_t *d128=dither_8x8_220[y&7];
        int acc;

#define DST1bpp4(i,o)					\
	Y = py_1[2*i];				\
	acc = r[Y+d128[0+o]] + g[Y+d64[0+o]] + b[Y+d128[0+o]];	\
	Y = py_1[2*i+1];			\
	acc |= (r[Y+d128[1+o]] + g[Y+d64[1+o]] + b[Y+d128[1+o]])<<4;\
        dst_1[i]= acc;

#define DST2bpp4(i,o)					\
	Y = py_2[2*i];				\
	acc =  r[Y+d128[8+o]] + g[Y+d64[8+o]] + b[Y+d128[8+o]];	\
	Y = py_2[2*i+1];			\
	acc |=  (r[Y+d128[9+o]] + g[Y+d64[9+o]] + b[Y+d128[9+o]])<<4;\
        dst_2[i]= acc;


	RGB(0);
	DST1bpp4(0,0);
	DST2bpp4(0,0);

	RGB(1);
	DST2bpp4(1,2);
	DST1bpp4(1,2);

	RGB(2);
	DST1bpp4(2,4);
	DST2bpp4(2,4);

	RGB(3);
	DST2bpp4(3,6);
	DST1bpp4(3,6);
EPILOG(4)

// This is exactly the same code as yuv2rgb_c_32 except for the types of
// r, g, b, dst_1, dst_2
PROLOG(yuv2rgb_c_4b, uint8_t)
	RGB(0);
	DST1(0);
	DST2(0);

	RGB(1);
	DST2(1);
	DST1(1);

	RGB(2);
	DST1(2);
	DST2(2);

	RGB(3);
	DST2(3);
	DST1(3);
EPILOG(8)

PROLOG(yuv2rgb_c_4b_ordered_dither, uint8_t)
	const uint8_t *d64= dither_8x8_73[y&7];
	const uint8_t *d128=dither_8x8_220[y&7];

#define DST1bpp4b(i,o)					\
	Y = py_1[2*i];				\
	dst_1[2*i] = r[Y+d128[0+o]] + g[Y+d64[0+o]] + b[Y+d128[0+o]];	\
	Y = py_1[2*i+1];			\
	dst_1[2*i+1] = r[Y+d128[1+o]] + g[Y+d64[1+o]] + b[Y+d128[1+o]];

#define DST2bpp4b(i,o)					\
	Y = py_2[2*i];				\
	dst_2[2*i] =  r[Y+d128[8+o]] + g[Y+d64[8+o]] + b[Y+d128[8+o]];	\
	Y = py_2[2*i+1];			\
	dst_2[2*i+1] =  r[Y+d128[9+o]] + g[Y+d64[9+o]] + b[Y+d128[9+o]];


	RGB(0);
	DST1bpp4b(0,0);
	DST2bpp4b(0,0);

	RGB(1);
	DST2bpp4b(1,2);
	DST1bpp4b(1,2);

	RGB(2);
	DST1bpp4b(2,4);
	DST2bpp4b(2,4);

	RGB(3);
	DST2bpp4b(3,6);
	DST1bpp4b(3,6);
EPILOG(8)

PROLOG(yuv2rgb_c_1_ordered_dither, uint8_t)
	const uint8_t *d128=dither_8x8_220[y&7];
	char out_1=0, out_2=0;
	g= c->table_gU[128] + c->table_gV[128];

#define DST1bpp1(i,o)					\
	Y = py_1[2*i];				\
	out_1+= out_1 + g[Y+d128[0+o]];	\
	Y = py_1[2*i+1];			\
	out_1+= out_1 + g[Y+d128[1+o]];

#define DST2bpp1(i,o)					\
	Y = py_2[2*i];				\
	out_2+= out_2 + g[Y+d128[8+o]];	\
	Y = py_2[2*i+1];			\
	out_2+= out_2 + g[Y+d128[9+o]];

	DST1bpp1(0,0);
	DST2bpp1(0,0);

	DST2bpp1(1,2);
	DST1bpp1(1,2);

	DST1bpp1(2,4);
	DST2bpp1(2,4);

	DST2bpp1(3,6);
	DST1bpp1(3,6);

	dst_1[0]= out_1;
	dst_2[0]= out_2;
EPILOG(1)

SwsFunc yuv2rgb_get_func_ptr (SwsContext *c)
{
#if defined(ARCH_X86) || defined(ARCH_X86_64)
    if(c->params.cpu & SWS_CPU_CAPS_MMX2){
	switch(c->dstFormat){
	case IMGFMT_BGR32: return yuv420_rgb32_MMX2;
	case IMGFMT_BGR24: return yuv420_rgb24_MMX2;
	case IMGFMT_BGR16: return yuv420_rgb16_MMX2;
	case IMGFMT_BGR15: return yuv420_rgb15_MMX2;
	}
    }
    if(c->params.cpu & SWS_CPU_CAPS_MMX){
	switch(c->dstFormat){
	case IMGFMT_BGR32: return yuv420_rgb32_MMX;
	case IMGFMT_BGR24: return yuv420_rgb24_MMX;
	case IMGFMT_BGR16: return yuv420_rgb16_MMX;
	case IMGFMT_BGR15: return yuv420_rgb15_MMX;
	}
    }
#endif
#ifdef HAVE_MLIB
    {
	SwsFunc t= yuv2rgb_init_mlib(c);
	if(t) return t;
}
#endif
#ifdef HAVE_ALTIVEC
    if (c->params.cpu & SWS_CPU_CAPS_ALTIVEC)
    {
	SwsFunc t = yuv2rgb_init_altivec(c);
	if(t) return t;
    }
#endif

    MSG_WARN("No accelerated colorspace conversion found\n");

    switch(c->dstFormat){
    case IMGFMT_RGB32:
    case IMGFMT_BGR32: return yuv2rgb_c_32;
    case IMGFMT_RGB24: return yuv2rgb_c_24_rgb;
    case IMGFMT_BGR24: return yuv2rgb_c_24_bgr;
    case IMGFMT_RGB16:
    case IMGFMT_BGR16:
    case IMGFMT_RGB15:
    case IMGFMT_BGR15: return yuv2rgb_c_16;
    case IMGFMT_RGB8:
    case IMGFMT_BGR8:  return yuv2rgb_c_8_ordered_dither;
    case IMGFMT_RGB4:
    case IMGFMT_BGR4:  return yuv2rgb_c_4_ordered_dither;
    case IMGFMT_RG4B:
    case IMGFMT_BG4B:  return yuv2rgb_c_4b_ordered_dither;
    case IMGFMT_RGB1:
    case IMGFMT_BGR1:  return yuv2rgb_c_1_ordered_dither;
    default:
    	assert(0);
    }
    return NULL;
}

static int div_round (int dividend, int divisor)
{
    if (dividend > 0)
        return (dividend + (divisor>>1)) / divisor;
    else
        return -((-dividend + (divisor>>1)) / divisor);
}

int yuv2rgb_c_init_tables (SwsContext *c, const int inv_table[4], int fullRange, int brightness, int contrast, int saturation)
{
    const int isRgb = IMGFMT_IS_BGR(c->dstFormat);
    const int bpp = isRgb?IMGFMT_RGB_DEPTH(c->dstFormat):IMGFMT_BGR_DEPTH(c->dstFormat);
    int i;
    uint8_t table_Y[1024];
    uint32_t *table_32 = 0;
    uint16_t *table_16 = 0;
    uint8_t *table_8 = 0;
    uint8_t *table_332 = 0;
    uint8_t *table_121 = 0;
    uint8_t *table_1 = 0;
    int entry_size = 0;
    unsigned char *table_r = 0, *table_g = 0, *table_b = 0;
    unsigned char *table_start;

    int64_t crv =  inv_table[0];
    int64_t cbu =  inv_table[1];
    int64_t cgu = -inv_table[2];
    int64_t cgv = -inv_table[3];
    int64_t cy  = 1<<16;
    int64_t oy  = 0;

//printf("%lld %lld %lld %lld %lld\n", cy, crv, cbu, cgu, cgv);
    if(!fullRange){
	cy= (cy*255) / 219;
	oy= 16<<16;
    }

    cy = (cy *contrast             )>>16;
    crv= (crv*contrast * saturation)>>32;
    cbu= (cbu*contrast * saturation)>>32;
    cgu= (cgu*contrast * saturation)>>32;
    cgv= (cgv*contrast * saturation)>>32;
//printf("%lld %lld %lld %lld %lld\n", cy, crv, cbu, cgu, cgv);
    oy -= 256*brightness;

    for (i = 0; i < 1024; i++) {
        int j;

	j= (cy*(((i - 384)<<16) - oy) + (1<<31))>>32;
        j = (j < 0) ? 0 : ((j > 255) ? 255 : j);
        table_Y[i] = j;
    }

    switch (bpp) {
    case 32:
	       table_start= table_32 = malloc ((197 + 2*682 + 256 + 132) * sizeof (uint32_t));

        entry_size = sizeof (uint32_t);
        table_r = table_32 + 197;
        table_b = table_32 + 197 + 685;
        table_g = table_32 + 197 + 2*682;

        for (i = -197; i < 256+197; i++)
	    ((uint32_t *)table_r)[i] = table_Y[i+384] << (isRgb ? 16 : 0);
        for (i = -132; i < 256+132; i++)
            ((uint32_t *)table_g)[i] = table_Y[i+384] << 8;
        for (i = -232; i < 256+232; i++)
	    ((uint32_t *)table_b)[i] = table_Y[i+384] << (isRgb ? 0 : 16);
        break;

    case 24:
       	table_start= table_8 = malloc ((256 + 2*232) * sizeof (uint8_t));

        entry_size = sizeof (uint8_t);
        table_r = table_g = table_b = table_8 + 232;

        for (i = -232; i < 256+232; i++)
            ((uint8_t * )table_b)[i] = table_Y[i+384];
        break;

    case 15:
    case 16:
	       table_start= table_16 = malloc ((197 + 2*682 + 256 + 132) * sizeof (uint16_t));

        entry_size = sizeof (uint16_t);
        table_r = table_16 + 197;
        table_b = table_16 + 197 + 685;
        table_g = table_16 + 197 + 2*682;

        for (i = -197; i < 256+197; i++) {
            int j = table_Y[i+384] >> 3;

	    if (isRgb)
                j <<= ((bpp==16) ? 11 : 10);

            ((uint16_t *)table_r)[i] = j;
        }
        for (i = -132; i < 256+132; i++) {
            int j = table_Y[i+384] >> ((bpp==16) ? 2 : 3);

            ((uint16_t *)table_g)[i] = j << 5;
        }
        for (i = -232; i < 256+232; i++) {
            int j = table_Y[i+384] >> 3;

	    if (!isRgb)
                j <<= ((bpp==16) ? 11 : 10);

            ((uint16_t *)table_b)[i] = j;
        }
        break;

    case 8:
	table_start= table_332 = malloc ((197 + 2*682 + 256 + 132) * sizeof (uint8_t));

	entry_size = sizeof (uint8_t);
	table_r = table_332 + 197;
	table_b = table_332 + 197 + 685;
	table_g = table_332 + 197 + 2*682;

	for (i = -197; i < 256+197; i++) {
	    int j = (table_Y[i+384 - 16] + 18)/36;

	    if (isRgb)
		j <<= 5;

	    ((uint8_t *)table_r)[i] = j;
	}
	for (i = -132; i < 256+132; i++) {
	    int j = (table_Y[i+384 - 16] + 18)/36;

	    if (!isRgb)
		j <<= 1;

	    ((uint8_t *)table_g)[i] = j << 2;
	}
	for (i = -232; i < 256+232; i++) {
	    int j = (table_Y[i+384 - 37] + 43)/85;

	    if (!isRgb)
		j <<= 6;

	    ((uint8_t *)table_b)[i] = j;
	}
	break;
    case 4:
    case 4|128:
	table_start= table_121 = malloc ((197 + 2*682 + 256 + 132) * sizeof (uint8_t));

	entry_size = sizeof (uint8_t);
	table_r = table_121 + 197;
	table_b = table_121 + 197 + 685;
	table_g = table_121 + 197 + 2*682;

	for (i = -197; i < 256+197; i++) {
	    int j = table_Y[i+384 - 110] >> 7;

	    if (isRgb)
		j <<= 3;

	    ((uint8_t *)table_r)[i] = j;
	}
	for (i = -132; i < 256+132; i++) {
	    int j = (table_Y[i+384 - 37]+ 43)/85;

	    ((uint8_t *)table_g)[i] = j << 1;
	}
	for (i = -232; i < 256+232; i++) {
	    int j =table_Y[i+384 - 110] >> 7;

	    if (!isRgb)
		j <<= 3;

	    ((uint8_t *)table_b)[i] = j;
	}
	break;

    case 1:
	table_start= table_1 = malloc (256*2 * sizeof (uint8_t));

	entry_size = sizeof (uint8_t);
	table_g = table_1;
	table_r = table_b = NULL;

	for (i = 0; i < 256+256; i++) {
	    int j = table_Y[i + 384 - 110]>>7;

	    ((uint8_t *)table_g)[i] = j;
	}
	break;

    default:
	table_start= NULL;
	MSG_ERR("%ibpp not supported by yuv2rgb\n", bpp);
	//free mem?
	return -1;
    }

    for (i = 0; i < 256; i++) {
	c->table_rV[i] = table_r + entry_size * div_round (crv * (i-128), 76309);
	c->table_gU[i] = table_g + entry_size * div_round (cgu * (i-128), 76309);
	c->table_gV[i] = entry_size * div_round (cgv * (i-128), 76309);
	c->table_bU[i] = table_b + entry_size * div_round (cbu * (i-128), 76309);
    }

    if(c->yuvTable) free(c->yuvTable);
    c->yuvTable= table_start;
    return 0;
}