veejay/veejay-current/veejay-server/libsubsample/subsample.c

/*
 * subsample.c:  Routines to do chroma subsampling.  ("Work In Progress")
 *
 *
 *  Copyright (C) 2001 Matthew J. Marjanovic <maddog@mir.com>
 *                2004 Niels Elburg <nwelburg@gmail.com>
 *
 *  This program 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.
 *
 *  This program 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 this program; if not, write to the Free Software
 *  Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA  02111-1307, USA.
 *
 */



#include <config.h>

#ifdef HAVE_ASM_MMX
#include "mmx.h"
#endif

#include <stdlib.h>
#include <string.h>
#include <stdint.h>
#include <assert.h>
#include <libvje/vje.h>
#include <libsubsample/subsample.h>
#include <mjpegtools/mjpeg_types.h>
#include <libvjmem/vjmem.h>
#include <libvjmsg/vj-msg.h>
#include <libvje/vje.h>
#include <libyuv/yuvconv.h>
#include <veejay/vj-task.h>

const char *ssm_id[SSM_COUNT] = {
  "unknown",
  "420_jpeg",
  "420_mpeg2",
#if 0
  "420_dv_pal",
  "411_dv_ntsc"
#endif
};


const char *ssm_description[SSM_COUNT] = {
  "unknown/illegal",
  "4:2:0, JPEG/MPEG-1, interstitial siting",
  "4:2:0, MPEG-2, horizontal cositing",
#if 0
  "4:2:0, DV-PAL, cosited, Cb/Cr line alternating",
  "4:1:1, DV-NTSC"
  "4:2:2",
#endif
};


#define    RUP8(num)(((num)+8)&~8)

// forward decl
void ss_420_to_422(uint8_t *buffer, int width, int height);
void ss_422_to_420(uint8_t *buffer, int width, int height);

/*************************************************************************
 * Chroma Subsampling
 *************************************************************************/


/* vertical/horizontal interstitial siting
 *
 *    Y   Y   Y   Y
 *      C       C
 *    Y   Y   Y   Y
 *
 *    Y   Y   Y   Y
 *      C       C
 *    Y   Y   Y   Y
 *
 */

/*
static void ss_444_to_420jpeg(uint8_t *buffer, int width, int height)
{
  uint8_t *in0, *in1, *out;
  int x, y;

  in0 = buffer;
  in1 = buffer + width;
  out = buffer;
  for (y = 0; y < height; y += 2) {
    for (x = 0; x < width; x += 2) {
      *out = (in0[0] + in0[1] + in1[0] + in1[1]) >> 2;
      in0 += 2;
      in1 += 2;
      out++;
    }
    in0 += width;
    in1 += width;
  }
}
*/
/*

        using weighted averaging for subsampling 2x2 -> 1x1
	here, 4 pixels are filled in each inner loop, (weighting
        16 source pixels)
*/

static void ss_444_to_420jpeg(uint8_t *buffer, int width, int height)
{
  const uint8_t *in0, *in1;
  uint8_t *out;
  int x, y = height;
  in0 = buffer;
  in1 = buffer + width;
  out = buffer;
  for (y = 0; y < height; y += 4) {
    for (x = 0; x < width; x += 4) {
     out[0] = (in0[0] + 3 * (in0[1] + in1[0]) + (9 * in1[1]) + 8) >> 4;
     out[1] = (in0[2] + 3 * (in0[3] + in1[2]) + (9 * in1[3]) + 8) >> 4;
     out[2] = (in0[4] + 3 * (in0[5] + in1[4]) + (9 * in1[5]) + 8) >> 4;
     out[3] = (in0[6] + 3 * (in0[7] + in1[6]) + (9 * in1[7]) + 8) >> 4;

      in0 += 8;
      in1 += 8;
      out += 4;
    }
    for (  ; x < width; x +=2 )
    {
 	out[0] = (in0[0] + 3 * (in0[1] + in1[0]) + (9 * in1[1]) + 8) >> 4;
        in0 += 2;
        in1 += 2;
	out++;
    }
    in0 += width*2;
    in1 += width*2;
  }
}
static void ss_444_to_420jpeg_cp(uint8_t *buffer,uint8_t *dest, int width, int height)
{
  const uint8_t *in0, *in1;
  uint8_t *out;
  int x, y = height;
  in0 = buffer;
  in1 = buffer + width;
  out = dest;
  for (y = 0; y < height; y += 4) {
    for (x = 0; x < width; x += 4) {
     out[0] = (in0[0] + 3 * (in0[1] + in1[0]) + (9 * in1[1]) + 8) >> 4;
     out[1] = (in0[2] + 3 * (in0[3] + in1[2]) + (9 * in1[3]) + 8) >> 4;
     out[2] = (in0[4] + 3 * (in0[5] + in1[4]) + (9 * in1[5]) + 8) >> 4;
     out[3] = (in0[6] + 3 * (in0[7] + in1[6]) + (9 * in1[7]) + 8) >> 4;

      in0 += 8;
      in1 += 8;
      out += 4;
    }
    for (  ; x < width; x +=2 )
    {
 	out[0] = (in0[0] + 3 * (in0[1] + in1[0]) + (9 * in1[1]) + 8) >> 4;
        in0 += 2;
        in1 += 2;
	out++;
    }
    in0 += width*2;
    in1 += width*2;
  }
}
/* horizontal interstitial siting
 *
 *    Y   Y   Y   Y
 *    C   C   C   C     in0 
 *    Y   Y   Y   Y         
 *    C   C   C   C      
 *           
 *    Y   Y   Y   Y       
 *    C       C     	out0  
 *    Y   Y   Y   Y       
 *    C       C  
 *
 *
 */             



 
/* vertical/horizontal interstitial siting
 *
 *    Y   Y   Y   Y
 *      C       C       C      inm
 *    Y   Y   Y   Y           
 *                  
 *    Y   Y   Y - Y           out0
 *      C     | C |     C      in0
 *    Y   Y   Y - Y           out1
 *
 *
 *      C       C       C      inp
 *
 *
 *  Each iteration through the loop reconstitutes one 2x2 block of 
 *   pixels from the "surrounding" 3x3 block of samples...
 *  Boundary conditions are handled by cheap reflection; i.e. the
 *   center sample is simply reused.
 *              
 */             


#define BLANK_CRB in0[1]
#define BLANK_CRB_2 (in0[1] << 1)

static void tr_420jpeg_to_444(uint8_t *data, uint8_t *buffer, int width, int height)
{
  uint8_t *inm, *in0, *inp, *out0, *out1;
  uint8_t cmm, cm0, cmp, c0m, c00, c0p, cpm, cp0, cpp;
  int x, y;

  uint8_t *saveme = data;

  veejay_memcpy(saveme, buffer, width);

  in0 = buffer + ( width * height /4) - 2;
  inm = in0 - width/2;
  inp = in0 + width/2;
  out1 = buffer + (width * height) - 1;
  out0 = out1 - width;

  for (y = height; y > 0; y -= 2) {
    if (y == 2) {
      in0 = saveme + width/2 - 2;
      inp = in0 + width/2;
    }
    for (x = width; x > 0; x -= 2) {
#if 0
      if ((x == 2) && (y == 2)) {
	cmm = in0[1];
	cm0 = in0[1];
	cmp = in0[2];
	c0m = in0[1];
	c0p = in0[2];
	cpm = inp[1];
	cp0 = inp[1];
	cpp = inp[2];
      } else if ((x == 2) && (y == height)) {
	cmm = inm[1];
	cm0 = inm[1];
	cmp = inm[2];
	c0m = in0[1];
	c0p = in0[2];
	cpm = in0[1];
	cp0 = in0[1];
	cpp = in0[2];
      } else if ((x == width) && (y == height)) {
	cmm = inm[0];
	cm0 = inm[1];
	cmp = inm[1];
	c0m = in0[0];
	c0p = in0[1];
	cpm = in0[0];
	cp0 = in0[1];
	cpp = in0[1];
      } else if ((x == width) && (y == 2)) {
	cmm = in0[0];
	cm0 = (y == 2) ? BLANK_CRB : inm[1];
      cmp = ((x == width) || (y == 2)) ? BLANK_CRB : inm[2];
      c0m = (x == 2) ? BLANK_CRB : in0[0];
      c0p = (x == width) ? BLANK_CRB : in0[2];
      cpm = ((x == 2) || (y == height)) ? BLANK_CRB : inp[0];
      cp0 = (y == height) ? BLANK_CRB : inp[1];
      cpp = ((x == width) || (y == height)) ? BLANK_CRB : inp[2];
      } else if (x == 2) {
      cmm = ((x == 2) || (y == 2)) ? BLANK_CRB : inm[0];
      cm0 = (y == 2) ? BLANK_CRB : inm[1];
      cmp = ((x == width) || (y == 2)) ? BLANK_CRB : inm[2];
      c0m = (x == 2) ? BLANK_CRB : in0[0];
      c0p = (x == width) ? BLANK_CRB : in0[2];
      cpm = ((x == 2) || (y == height)) ? BLANK_CRB : inp[0];
      cp0 = (y == height) ? BLANK_CRB : inp[1];
      cpp = ((x == width) || (y == height)) ? BLANK_CRB : inp[2];
      } else if (y == 2) {
      cmm = ((x == 2) || (y == 2)) ? BLANK_CRB : inm[0];
      cm0 = (y == 2) ? BLANK_CRB : inm[1];
      cmp = ((x == width) || (y == 2)) ? BLANK_CRB : inm[2];
      c0m = (x == 2) ? BLANK_CRB : in0[0];
      c0p = (x == width) ? BLANK_CRB : in0[2];
      cpm = ((x == 2) || (y == height)) ? BLANK_CRB : inp[0];
      cp0 = (y == height) ? BLANK_CRB : inp[1];
      cpp = ((x == width) || (y == height)) ? BLANK_CRB : inp[2];
      } else if (x == width) {
      cmm = ((x == 2) || (y == 2)) ? BLANK_CRB : inm[0];
      cm0 = (y == 2) ? BLANK_CRB : inm[1];
      cmp = ((x == width) || (y == 2)) ? BLANK_CRB : inm[2];
      c0m = (x == 2) ? BLANK_CRB : in0[0];
      c0p = (x == width) ? BLANK_CRB : in0[2];
      cpm = ((x == 2) || (y == height)) ? BLANK_CRB : inp[0];
      cp0 = (y == height) ? BLANK_CRB : inp[1];
      cpp = ((x == width) || (y == height)) ? BLANK_CRB : inp[2];
      } else if (y == height) {
      cmm = ((x == 2) || (y == 2)) ? BLANK_CRB : inm[0];
      cm0 = (y == 2) ? BLANK_CRB : inm[1];
      cmp = ((x == width) || (y == 2)) ? BLANK_CRB : inm[2];
      c0m = (x == 2) ? BLANK_CRB : in0[0];
      c0p = (x == width) ? BLANK_CRB : in0[2];
      cpm = ((x == 2) || (y == height)) ? BLANK_CRB : inp[0];
      cp0 = (y == height) ? BLANK_CRB : inp[1];
      cpp = ((x == width) || (y == height)) ? BLANK_CRB : inp[2];
      } else {
      cmm = ((x == 2) || (y == 2)) ? BLANK_CRB : inm[0];
      cm0 = (y == 2) ? BLANK_CRB : inm[1];
      cmp = ((x == width) || (y == 2)) ? BLANK_CRB : inm[2];
      c0m = (x == 2) ? BLANK_CRB : in0[0];
      c0p = (x == width) ? BLANK_CRB : in0[2];
      cpm = ((x == 2) || (y == height)) ? BLANK_CRB : inp[0];
      cp0 = (y == height) ? BLANK_CRB : inp[1];
      cpp = ((x == width) || (y == height)) ? BLANK_CRB : inp[2];
      }
      c00 = in0[1];

      cmm = ((x == 2) || (y == 2)) ? BLANK_CRB : inm[0];
      cm0 = (y == 2) ? BLANK_CRB : inm[1];
      cmp = ((x == width) || (y == 2)) ? BLANK_CRB : inm[2];
      c0m = (x == 2) ? BLANK_CRB : in0[0];
      c0p = (x == width) ? BLANK_CRB : in0[2];
      cpm = ((x == 2) || (y == height)) ? BLANK_CRB : inp[0];
      cp0 = (y == height) ? BLANK_CRB : inp[1];
      cpp = ((x == width) || (y == height)) ? BLANK_CRB : inp[2];
#else
      cmm = ((x == 2) || (y == 2)) ? BLANK_CRB : inm[0];
      cm0 = (y == 2) ? BLANK_CRB : inm[1];
      cmp = ((x == width) || (y == 2)) ? BLANK_CRB : inm[2];
      c0m = (x == 2) ? BLANK_CRB : in0[0];
      c00 = in0[1];
      c0p = (x == width) ? BLANK_CRB : in0[2];
      cpm = ((x == 2) || (y == height)) ? BLANK_CRB : inp[0];
      cp0 = (y == height) ? BLANK_CRB : inp[1];
      cpp = ((x == width) || (y == height)) ? BLANK_CRB : inp[2];
#endif
      inm--;
      in0--;
      inp--;

      *(out1--) = (1*cpp + 3*(cp0+c0p) + 9*c00 + 8) >> 4;
      *(out1--) = (1*cpm + 3*(cp0+c0m) + 9*c00 + 8) >> 4;
      *(out0--) = (1*cmp + 3*(cm0+c0p) + 9*c00 + 8) >> 4;
      *(out0--) = (1*cmm + 3*(cm0+c0m) + 9*c00 + 8) >> 4;
    }
    out1 -= width;
    out0 -= width;
  }
}

// lame box filter
// the dampening of high frequencies depend
// on the directions these frequencies occur in the
// image, resulting in clear edges between certain
// group of pixels.

static void ss_420jpeg_to_444(uint8_t *buffer, int width, int height)
{
#ifndef HAVE_ASM_MMX
  uint8_t *in, *out0, *out1;
  int x, y;
  in = buffer + (width * height / 4) - 1;
  out1 = buffer + (width * height) - 1;
  out0 = out1 - width;
  for (y = height - 1; y >= 0; y -= 2) {
    for (x = width - 1; x >= 0; x -=2) {
      uint8_t val = *(in--);
      *(out1--) = val;
      *(out1--) = val;
      *(out0--) = val;
      *(out0--) = val;
    }
    out0 -= width;
    out1 -= width;
  }
#else
	int x,y;
	const int mmx_stride = width >> 3;
	uint8_t *src = buffer + ((width * height) >> 2)-1;
	uint8_t *dst = buffer + (width * height) -1;
	uint8_t *dst2 = dst - width;

	for( y = height-1; y >= 0; y -= 2)
	{
		for( x = 0; x < mmx_stride; x ++ )
		{
			movq_m2r( *src,mm0 );
			movq_m2r( *src,mm1 );
			movq_r2m(mm0, *dst );
			movq_r2m(mm1, *(dst+8) );
			movq_r2m(mm0, *dst2 );
			movq_r2m(mm1, *(dst2+8) );
			dst += 16;
			dst2 += 16;
			src += 8;
		}
		dst -= width;	
		dst2 -= width;
	}
#endif
}


void ss_420_to_422(uint8_t *buffer, int width, int height)
{

	//todo, 1x2 super sampling (box)
}

void ss_422_to_420(uint8_t *buffer, int width, int height )
{

	//todo 2x1 down sampling (box)
}

#ifdef HAVE_ASM_MMX
#undef HAVE_K6_2PLUS
#if !defined( HAVE_ASM_MMX2) && defined( HAVE_ASM_3DNOW )
#define HAVE_K6_2PLUS
#endif

#undef _EMMS

#ifdef HAVE_K6_2PLUS
/* On K6 femms is faster of emms. On K7 femms is directly mapped on emms. */
#define _EMMS     "femms"
#else
#define _EMMS     "emms"
#endif

#endif

#ifdef HAVE_ASM_MMX
/* for small memory blocks (<256 bytes) this version is faster */
#define small_memcpy(to,from,n)\
{\
register unsigned long int dummy;\
__asm__ __volatile__(\
  "rep; movsb"\
  :"=&D"(to), "=&S"(from), "=&c"(dummy)\
  :"0" (to), "1" (from),"2" (n)\
  : "memory");\
}

static  inline	void	copy8( uint8_t *dst, uint8_t *in )
{
	__asm__ __volatile__ (
		"movq	(%0),	%%mm0\n"
		"movq %%mm0, (%1)\n"
		:: "r" (in), "r" (dst) : "memory" );
}

static	inline	void	copy16( uint8_t *dst, uint8_t *in)
{
	__asm__ __volatile__ (
		"movq	(%0),	%%mm0\n"
		"movq  8(%0),	%%mm1\n"
		"movq  %%mm0,   (%1)\n"
		"movq  %%mm1,   8(%1)\n"
		:: "r" (in), "r" (dst) : "memory" );
}

static	inline void	copy_width( uint8_t *dst, uint8_t *in, int width )
{
	int w = width >> 4;
	int x;
	uint8_t *d = dst;
	uint8_t *i = in;

	for( x = 0; x < w; x ++ )
	{
		copy16( d, i );
		d += 16;
		i += 16;
	}

	x = (width % 16);
	if( x )
		small_memcpy( d, i, x);
}

static	inline	void	load_mask16to8()
{
	const uint64_t mask = 0x00ff00ff00ff00ffLL;
	const uint8_t *m    = (uint8_t*)&mask;

	__asm __volatile(
		"movq		(%0), %%mm4\n\t"
		:: "r" (m)
	);

}

static	inline	void	down_sample16to8( uint8_t *out, uint8_t *in )
{
	//@ down sample by dropping right pixels
	__asm __volatile(
		"movq		(%0), %%mm1\n\t"
		"movq		8(%0),%%mm3\n\t"
		"pxor		%%mm5,%%mm5\n\t"
		"pand		%%mm4,%%mm1\n\t"
		"pand		%%mm4,%%mm3\n\t"
		"packuswb	%%mm1,%%mm2\n\t"
		"packuswb	%%mm3,%%mm5\n\t"
		"psrlq		$32, %%mm2\n\t"
		"por		%%mm5,%%mm2\n\t"
		"movq		%%mm2, (%1)\n\t"
		:: "r" (in), "r" (out)
	);
}
#endif

static void ss_444_to_422_cp(uint8_t *data, uint8_t *buffer, uint8_t *dest, int width, int height)
{
	const int dst_stride = width >> 1;
	int x,y;
#ifdef HAVE_ASM_MMX
	int mmxdst_stride=dst_stride >> 3;
	int left = dst_stride % 8;
#endif
	uint8_t *src = (uint8_t*) data;
	uint8_t *dst;

#ifdef HAVE_ASM_MMX
	load_mask16to8();
#endif
	for(y = 0; y < height; y ++)
	{
		src = buffer + (y*width);
		dst = dest + (y*dst_stride);

#if defined (HAVE_ASM_MMX) || defined (HAVE_ASM_MMX2)
		copy_width( src, buffer + (y*width), width );

		for( x= 0; x < mmxdst_stride; x++ )
		{
			down_sample16to8( dst, src );
			src += 16;
			dst += 8;
		}
		for(x=0; x < left; x++)
		{
			*(dst++) = ( src[0] + src[1] + 1 ) >> 1;
			src += 2;
		}
#else
		for(x=0; x < dst_stride; x++)
		{
			*(dst++) = ( src[0] + src[1] + 1 ) >> 1;
			src += 2;
		}

#endif
	}
}

//@ data = input, buffer = output
static void ss_444_to_422(uint8_t *data, uint8_t *buffer, int width, int height)
{
	const int dst_stride = width >> 1;
	int x,y;
#ifdef HAVE_ASM_MMX
	int mmxdst_stride=dst_stride >> 3;
	int left = dst_stride % 8;
#endif
	uint8_t *src = (uint8_t*) data;
//	uint8_t *src = buffer;
	uint8_t *dst;

#ifdef HAVE_ASM_MMX
	load_mask16to8();
#endif
	for(y = 0; y < height; y ++)
	{
		src = (uint8_t*) data;
		dst = buffer + (y*dst_stride);

#if defined (HAVE_ASM_MMX) || defined (HAVE_ASM_MMX2)
		copy_width( src, buffer + (y*width), width );

		for( x= 0; x < mmxdst_stride; x++ )
		{
			down_sample16to8( dst, src );
			src += 16;
			dst += 8;
		}
		for(x=0; x < left; x++)
		{
			*(dst++) = ( src[0] + src[1] + 1 ) >> 1;
			src += 2;
		}
#else
		for( x = 0; x < dst_stride; x ++ )
		{
			*(dst++) = (src[0] + src[1] + 1 ) >> 1;
			src += 2;
		}
#endif
	}
}
#ifdef HAVE_ASM_MMX

static	inline	void	super_sample8to16( uint8_t *in, uint8_t *out )
{
	//@ super sample by duplicating pixels
	__asm__ __volatile__ (
		"\n\tpxor	%%mm2,%%mm2"
		"\n\tpxor	%%mm4,%%mm4"
		"\n\tmovq	(%0), %%mm1"  
		"\n\tpunpcklbw	%%mm1,%%mm2" 
		"\n\tpunpckhbw	%%mm1,%%mm4"   
		"\n\tmovq	%%mm2,%%mm5"
		"\n\tmovq	%%mm4,%%mm6"
		"\n\tpsrlq	$8, %%mm5"    
		"\n\tpsrlq	$8, %%mm6"  
		"\n\tpor	%%mm5,%%mm2"
		"\n\tpor	%%mm6,%%mm4"	
		"\n\tmovq	%%mm2, (%1)"
		"\n\tmovq	%%mm4, 8(%1)"
		:: "r" (in), "r" (out)

	);
}
#endif

static void tr_422_to_444(uint8_t *data, uint8_t *buffer, int width, int height)
{
	int x,y;
	const int stride = width >> 1;

#ifndef HAVE_ASM_MMX
	for( y = height-1; y > 0 ; y -- )
	{
		uint8_t *dst = buffer + (y * width);
		uint8_t *src = buffer + (y * stride);
		for(x=0; x < stride; x++) // for 1 row
		{
			dst[0] = src[x]; //put to dst
			dst[1] = src[x];
			dst+=2; // increment dst
		}
	}
#else

	const int mmx_stride = stride >> 3;
	int left = (mmx_stride % 8)-1;
	if( left < 0 ) left = 0;
	for( y = height-1; y > 0 ; y -- )
	{
		uint8_t *src = buffer + (y * stride);
		uint8_t *dst = buffer + (y * width);
		for(x=0; x < mmx_stride; x++) // for 1 row
		{
			super_sample8to16(src,dst );
			src += 8;
			dst += 16;
		}
	/*	for(x=0; x < left; x++) // for 1 row
		{
			dst[0] = src[x]; //put to dst
			dst[1] = src[x];
			dst+=2; // increment dst
		}*/
	}
#endif
}

static void tr_422_to_444t(uint8_t *dst, uint8_t *src, int width, int height)
{
	int x,y;
	const int stride = width >> 1;
#ifndef HAVE_ASM_MMX
	for( y = height; y > 0 ; y -- )
	{
		uint8_t *d = dst + (y * width);
		uint8_t *s = src + (y * stride);
		for(x=0; x < stride; x++) // for 1 row
		{
			d[0] = s[x]; //put to dst
			d[1] = s[x];
			d+=2; // increment dst
		}
	}
#else
	const int mmx_stride = stride >> 3;
	int left = (mmx_stride % 8)-1;
	if( left < 0 ) left = 0;
	for( y = height; y > 0 ; y -- )
	{
		uint8_t *s = src + (y * stride);
		uint8_t *d = dst + (y * width);
		for(x=0; x < mmx_stride; x++) // for 1 row
		{
			super_sample8to16(s,d);
			s += 8;
			d += 16;
		}
		for(x=0; x < left; x++) 
		{
			d[0] = src[x]; //put to dst
			d[1] = src[x];
			dst+=2; // increment dst
		}
	}
#endif

}

/* vertical intersitial siting; horizontal cositing
 *
 *    Y   Y   Y   Y
 *    C       C
 *    Y   Y   Y   Y
 *
 *    Y   Y   Y   Y
 *    C       C
 *    Y   Y   Y   Y
 *
 * [1,2,1] kernel for horizontal subsampling:
 *
 *    inX[0] [1] [2]
 *        |   |   |
 *    C   C   C   C
 *         \  |  /
 *          \ | /
 *            C
 */

static void ss_444_to_420mpeg2(uint8_t *buffer, int width, int height)
{
  uint8_t *in0, *in1, *out;
  int x, y;

  in0 = buffer;          /* points to */
  in1 = buffer + width;  /* second of pair of lines */
  out = buffer;
  for (y = 0; y < height; y += 2) {
    /* first column boundary condition -- just repeat it to right */
    *out = (in0[0] + (2 * in0[0]) + in0[1] +
	    in1[0] + (2 * in1[0]) + in1[1]) >> 3;
    out++;
    in0++;
    in1++;
    /* rest of columns just loop */
    for (x = 2; x < width; x += 2) {
      *out = (in0[0] + (2 * in0[1]) + in0[2] +
	      in1[0] + (2 * in1[1]) + in1[2]) >> 3;
      in0 += 2;
      in1 += 2;
      out++;
    }
    in0 += width + 1;
    in1 += width + 1;
  }
}
      
static void	chroma_subsample_task( void *ptr )
{
	vj_task_arg_t *f = (vj_task_arg_t*) ptr;

	switch (f->iparam) {
		case SSM_420_JPEG_BOX:
		case SSM_420_JPEG_TR: 
			ss_444_to_420jpeg(f->input[1], f->width, f->subhei);
  			ss_444_to_420jpeg(f->input[2], f->width, f->subhei);
#ifdef HAVE_ASM_MMX
			__asm__ __volatile__ ( _EMMS:::"memory");
#endif
    		break;
		case SSM_420_MPEG2:
			ss_444_to_420mpeg2(f->input[1], f->width, f->subhei);
			ss_444_to_420mpeg2(f->input[2], f->width, f->subhei);
		break;
		case SSM_422_444:
			//@ src, dst
	   	 	ss_444_to_422_cp(f->priv,f->output[1],f->input[1],f->width,f->subhei);
		    	ss_444_to_422_cp(f->priv,f->output[2],f->input[2],f->width,f->subhei);
#ifdef HAVE_ASM_MMX
			__asm__ __volatile__ ( _EMMS:::"memory");
#endif
    		break;
		case SSM_420_422:
    		ss_422_to_420(f->input[1],f->width,f->subhei);
   			ss_422_to_420(f->input[2],f->width,f->subhei);
   		break;
		default:
		break;

	}
}
static void chroma_supersample_task( void *ptr )
{
	vj_task_arg_t *f = (vj_task_arg_t*) ptr; 

	switch (f->iparam) {
	  case SSM_420_JPEG_BOX:
      	ss_420jpeg_to_444(f->input[1], f->width, f->subhei);
    	ss_420jpeg_to_444(f->input[2], f->width, f->subhei);
#ifdef HAVE_ASM_MMX
	__asm__ __volatile__ ( _EMMS:::"memory");
#endif
    	break;
 	 case SSM_420_JPEG_TR:
   		tr_420jpeg_to_444(f->priv,f->input[1], f->width, f->subhei);
   		tr_420jpeg_to_444(f->priv,f->input[2], f->width, f->subhei);
   		break;
  	 case SSM_422_444:
		tr_422_to_444t(f->input[1],f->output[1],f->width,f->subhei);
   		tr_422_to_444t(f->input[2],f->output[2],f->width,f->subhei);
#ifdef HAVE_ASM_MMX
		__asm__ __volatile__ ( _EMMS:::"memory");
#endif
    	break;
  	case SSM_420_422:
  		ss_420_to_422( f->input[1], f->width, f->subhei );
    	ss_420_to_422( f->input[2], f->width, f->subhei );
    	break;
  	default:
   	 	break;
  }

}

void chroma_subsample_cp(subsample_mode_t mode,VJFrame *frame, uint8_t *ycbcr[], uint8_t *dcbcr[])
{
	if( vj_task_available() ) {
		void *data = vj_task_alloc_internal_buf( frame->len * 2 + (frame->width*2) );
		uint8_t *plane = (uint8_t*) data;
		uint8_t *vplane = plane + frame->len;
		uint8_t *buffer = vplane + frame->len;
		uint8_t *planes[3] = { NULL, plane,vplane };
		uint8_t *temp[3] = { NULL, buffer, NULL };
		int strides[4] = { 0, frame->len, frame->len, 0 };
		vj_frame_copy( ycbcr, planes,strides );
		vj_task_set_sampling( 1 );
		vj_task_set_from_frame( frame );
		vj_task_set_int( mode );
		vj_task_run( ycbcr, planes, temp, NULL, 3,  (performer_job_routine ) &chroma_subsample_task );
		vj_task_free_internal_buf();
		free(data);
		return;
  	}
	
	uint8_t *data = (uint8_t*) vj_malloc(sizeof(uint8_t) * frame->width * 2 );

	switch (mode) {
		case SSM_420_JPEG_BOX:
		case SSM_420_JPEG_TR:
			ss_444_to_420jpeg_cp(ycbcr[1],dcbcr[1], frame->width, frame->height);
			ss_444_to_420jpeg_cp(ycbcr[2],dcbcr[2], frame->width, frame->height);
			break;
		case SSM_420_MPEG2:
 			break;
		case SSM_422_444:
//  			ss_444_to_422_cp(data,ycbcr[1],dcbcr[1],frame->width,frame->height);
//			ss_444_to_422_cp(data,ycbcr[2],dcbcr[2],frame->width,frame->height);
#ifdef HAVE_ASM_MMX
			__asm__ __volatile__ ( _EMMS:::"memory");
#endif
		    break;
  		default:
   		break;
  	}

	free(data);
}

void chroma_subsample(subsample_mode_t mode, VJFrame *frame, uint8_t *ycbcr[] )
{
	if( vj_task_available() ) {
		void *data = vj_task_alloc_internal_buf( frame->len * 2 + (frame->width*2) );
		uint8_t *plane = (uint8_t*) data;
		uint8_t *vplane = plane + frame->len;
		uint8_t *buffer = vplane + frame->len;
		uint8_t *planes[3] = { NULL, plane,vplane };
		uint8_t *temp[3] = { NULL, buffer, NULL };
		int strides[4] = { 0, frame->len, frame->len, 0 };
		vj_frame_copy( ycbcr, planes,strides );
		vj_task_set_sampling( 1 );
		vj_task_set_from_frame( frame );
		vj_task_set_int( mode );
		vj_task_run( ycbcr, planes, temp, NULL, 3,  (performer_job_routine ) &chroma_subsample_task );
		vj_task_free_internal_buf();
		free(data);
		return;
  	}
	
	uint8_t *data = (uint8_t*) vj_malloc( sizeof(uint8_t) * frame->width * 2 );

	switch (mode) {
		case SSM_420_JPEG_BOX:
		case SSM_420_JPEG_TR: 
			ss_444_to_420jpeg(ycbcr[1], frame->width, frame->height);
 			ss_444_to_420jpeg(ycbcr[2], frame->width, frame->height);
#ifdef HAVE_ASM_MMX
			__asm__ __volatile__ ( _EMMS:::"memory");
#endif
			break;
		case SSM_420_MPEG2:
			ss_444_to_420mpeg2(ycbcr[1], frame->width, frame->height);
			ss_444_to_420mpeg2(ycbcr[2], frame->width, frame->height);
			break;
		case SSM_422_444:
		    ss_444_to_422(data,ycbcr[1],frame->width,frame->height);
		    ss_444_to_422(data,ycbcr[2],frame->width,frame->height);
#ifdef HAVE_ASM_MMX
			__asm__ __volatile__ ( _EMMS:::"memory");
#endif
    		break;
		case SSM_420_422:
			ss_422_to_420(ycbcr[1],frame->width,frame->height);
			ss_422_to_420(ycbcr[2],frame->width,frame->height);
			break;
		default:
		break;
  	}
	free(data);
}


void chroma_supersample(subsample_mode_t mode,VJFrame *frame, uint8_t *ycbcr[] )
{	
  if( vj_task_available() ) {
	void *data = vj_task_alloc_internal_buf( frame->uv_len * 4 ); //@ 4:2:2

	uint8_t *plane = (uint8_t*) data;
	uint8_t *vplane = plane + frame->uv_len;
	uint8_t *planes[4] = { NULL, plane,vplane,NULL };
	int strides[4] = { 0, frame->uv_len, frame->uv_len, 0 };
	vj_frame_copy( ycbcr, planes,strides);
	vj_task_set_sampling ( 1 );
	vj_task_set_from_frame( frame );
	vj_task_set_int( mode );
	vj_task_run( frame->data,planes, NULL, NULL,3, (performer_job_routine) &chroma_supersample_task );
	vj_task_free_internal_buf();
	free(data);
	return;
  }
  uint8_t *data = (uint8_t*) vj_malloc( sizeof(uint8_t) * frame->width * 2 );

  switch (mode) {
		case SSM_420_JPEG_BOX:
	      	ss_420jpeg_to_444(ycbcr[1], frame->width, frame->height);
	    	ss_420jpeg_to_444(ycbcr[2], frame->width, frame->height);
#ifdef HAVE_ASM_MMX
			__asm__ __volatile__ ( _EMMS:::"memory");
#endif
		break;
		case SSM_420_JPEG_TR:
			tr_420jpeg_to_444(data,ycbcr[1], frame->width, frame->height);
			tr_420jpeg_to_444(data,ycbcr[2], frame->width, frame->height);
		break;
		case SSM_422_444:
 			tr_422_to_444(data,ycbcr[1],frame->width,frame->height);
 			tr_422_to_444(data,ycbcr[2],frame->width,frame->height);
#ifdef HAVE_ASM_MMX
			__asm__ __volatile__ ( _EMMS:::"memory");
#endif
    break;
 		case SSM_420_422:
    		ss_420_to_422( ycbcr[1], frame->width, frame->height );
    		ss_420_to_422( ycbcr[2], frame->width, frame->height );
    	break;
  	default:
   		break;
  }

  free( data );

}