mb_ordered.c

mpeng Lib

/*  
 * Copyright (c) 1992 The Regents of the University of California.
 * All rights reserved.
 * 
 * Permission to use, copy, modify, and distribute this software and its
 * documentation for any purpose, without fee, and without written agreement is
 * hereby granted, provided that the above copyright notice and the following
 * two paragraphs appear in all copies of this software.
 * 
 * IN NO EVENT SHALL THE UNIVERSITY OF CALIFORNIA BE LIABLE TO ANY PARTY FOR
 * DIRECT, INDIRECT, SPECIAL, INCIDENTAL, OR CONSEQUENTIAL DAMAGES ARISING OUT
 * OF THE USE OF THIS SOFTWARE AND ITS DOCUMENTATION, EVEN IF THE UNIVERSITY OF
 * CALIFORNIA HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
 * 
 * THE UNIVERSITY OF CALIFORNIA SPECIFICALLY DISCLAIMS ANY WARRANTIES,
 * INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY
 * AND FITNESS FOR A PARTICULAR PURPOSE.  THE SOFTWARE PROVIDED HEREUNDER IS
 * ON AN "AS IS" BASIS, AND THE UNIVERSITY OF CALIFORNIA HAS NO OBLIGATION TO
 * PROVIDE MAINTENANCE, SUPPORT, UPDATES, ENHANCEMENTS, OR MODIFICATIONS.
 */
/* This file contains C code to implement an ordered dither. */

#include <config.h>
#include <malloc.h>
#include <memory.h>
#include "video.h"
#include "proto.h"
#include "dither.h"
#include "my_dmalloc.h"

#define DITH_SIZE 16


/* Structures used to implement macroblock ordered
   dither algorithm.
*/

static unsigned char ***ditherPtr[DITH_SIZE];


/*
 *--------------------------------------------------------------
 *
 *  InitMBOrderedDither--
 *
 *	Structures intialized for ordered dithering. 
 *
 * Results:
 *	None.
 *
 * Side effects:
 *      None.
 *
 *--------------------------------------------------------------
 */

void
InitMBOrderedDither()
{
  unsigned char ****pos_2_cb;
  unsigned char ***cb_2_cr;
  unsigned char **cr_2_l;
  int cb_val, cb_rval, cr_val, cr_rval, l_val, l_rval;
  int i, j, pos;
  int err_range, threshval;

  pos_2_cb = (unsigned char ****) malloc (DITH_SIZE*sizeof(unsigned char ***));
  cb_2_cr = (unsigned char ***) malloc(CB_RANGE*sizeof(unsigned char **));
  cr_2_l = (unsigned char **) malloc(CR_RANGE*sizeof(unsigned char *));

  for (pos=0; pos<DITH_SIZE; pos++) {
    
    pos_2_cb[pos] = (unsigned char ***) malloc(256*(sizeof(unsigned char **)));

    for (j=0; j<CB_RANGE; j++) {
      cb_2_cr[j] = (unsigned char **) malloc(256*(sizeof(unsigned char *)));
    }

    for (cb_val=0; cb_val<cb_values[0]; cb_val++) {
      (pos_2_cb[pos])[cb_val] = cb_2_cr[0];
    }

    for (cb_rval=0; cb_rval<(CB_RANGE-1); cb_rval++) {
      err_range = cb_values[cb_rval+1] - cb_values[cb_rval];
      threshval = ((pos*err_range)/DITH_SIZE)+cb_values[cb_rval];

      for (cb_val=cb_values[cb_rval]; cb_val<cb_values[cb_rval+1]; cb_val++) {
	if (cb_val>threshval) (pos_2_cb[pos])[cb_val] = cb_2_cr[cb_rval+1];
	else (pos_2_cb[pos])[cb_val] = cb_2_cr[cb_rval];
      }
    }

    for (cb_val=cb_values[CB_RANGE-1]; cb_val<256; cb_val++) {
      (pos_2_cb[pos])[cb_val] = cb_2_cr[CB_RANGE-1];
    }

    for (cb_rval=0; cb_rval<CB_RANGE; cb_rval++) {
      
      for (j=0; j<CR_RANGE; j++) {
	cr_2_l[j] = (unsigned char *) malloc(256*(sizeof(unsigned char)));
      }

      for (cr_val=0; cr_val < cr_values[0]; cr_val++) {
	(cb_2_cr[cb_rval])[cr_val] = cr_2_l[0];
      }

      for (cr_rval=0; cr_rval<(CR_RANGE-1); cr_rval++) {
	err_range = cr_values[cr_rval+1] - cr_values[cr_rval];
	threshval = ((pos*err_range)/DITH_SIZE)+cr_values[cr_rval];
	
	for (cr_val=cr_values[cr_rval]; cr_val<cr_values[cr_rval+1]; cr_val++) {
	  if (cr_val>threshval) (cb_2_cr[cb_rval])[cr_val] = cr_2_l[cr_rval+1];
	  else (cb_2_cr[cb_rval])[cr_val] = cr_2_l[cr_rval];
	}
      }
      
      for (cr_val=cr_values[CR_RANGE-1]; cr_val<256; cr_val++) {
	(cb_2_cr[cb_rval])[cr_val] = cr_2_l[CR_RANGE-1];
      }
      
      for (cr_rval=0; cr_rval<CR_RANGE; cr_rval++) {
	
	for (l_val = 0; l_val < lum_values[0]; l_val++) {
	  (cr_2_l[cr_rval])[l_val] = pixel[cb_rval+(cr_rval*CB_RANGE)+
					    (0*CR_RANGE*CB_RANGE)];
	}

	for (l_rval=0; l_rval<(LUM_RANGE-1); l_rval++) {
	  err_range = lum_values[l_rval+1] - lum_values[l_rval];
	  threshval = ((pos*err_range) /DITH_SIZE) + lum_values[l_rval];

	  for (l_val = lum_values[l_rval]; l_val < lum_values[l_rval+1]; l_val++) {
	    if (l_val>threshval) (cr_2_l[cr_rval])[l_val] = 
	      pixel[cb_rval+(cr_rval*CB_RANGE)+((l_rval+1)*CR_RANGE*CB_RANGE)];
	    else (cr_2_l[cr_rval])[l_val] =
	      pixel[cb_rval+(cr_rval*CB_RANGE)+(l_rval*CR_RANGE*CB_RANGE)];
	  }
	}

	for (l_val = lum_values[LUM_RANGE-1]; l_val < 256; l_val++) {
	  (cr_2_l[cr_rval])[l_val] = 
	    pixel[cb_rval+(cr_rval*CB_RANGE)+((LUM_RANGE-1)*CR_RANGE*CB_RANGE)];
	}
      }
    }
  }

  for (i=0; i<DITH_SIZE; i++) {
    ditherPtr[i] = pos_2_cb[i];
  }
}



/*
 *--------------------------------------------------------------
 *
 * MBOrderedDitherImage --
 *
 *	Dithers an image using an ordered dither at macroblock level.
 *	Assumptions made:
 *	  1) The color space is allocated y:cr:cb = 8:4:4
 *	  2) The spatial resolution of y:cr:cb is 4:1:1
 *      The channels are dithered based on the standard
 *      ordered dither pattern for a 4x4 area. 
 *
 * Results:
 *	None.
 *
 * Side effects:
 *	None.
 *
 *--------------------------------------------------------------
 */
void
MBOrderedDitherImage (lum, cr, cb, out, h, w)
    unsigned char *lum;
    unsigned char *cr;
    unsigned char *cb;
    unsigned char *out;
    int h, w;
{
  unsigned char *l, *r, *b, *o1, *o2;
  unsigned char *l2;
  unsigned char L, R, B;
  int i, j, mbaddr, mbwidth;
  unsigned char ***dp0 = ditherPtr[0];
  unsigned char ***dp2 = ditherPtr[2];
  unsigned char ***dp4 = ditherPtr[4];
  unsigned char ***dp6 = ditherPtr[6];
  unsigned char ***dp8 = ditherPtr[8];
  unsigned char ***dp10 = ditherPtr[10];
  unsigned char ***dp12 = ditherPtr[12];
  unsigned char ***dp14 = ditherPtr[14];
  unsigned char ***dp1 = ditherPtr[1];
  unsigned char ***dp3 = ditherPtr[3];
  unsigned char ***dp5 = ditherPtr[5];
  unsigned char ***dp7 = ditherPtr[7];
  unsigned char ***dp9 = ditherPtr[9];
  unsigned char ***dp11 = ditherPtr[11];
  unsigned char ***dp13 = ditherPtr[13];
  unsigned char ***dp15 = ditherPtr[15];

  l = lum;
  l2 = lum + w;
  r = cr;
  b = cb;
  o1 = out;
  o2 = out+w;
  mbwidth = w / 16;

  for (i=0; i<h; i+=4) {

    mbaddr = (i / 16) * mbwidth ;

    for (j=0; j<w; j+=8) {

      if (ditherFlags[mbaddr+(j/16)]) {
	R = r[0]; B = b[0];
	
	L = l[0];
	o1[0] = ((dp0[B])[R])[L];
	L = l[1];
	o1[1] = ((dp8[B])[R])[L];
	L = l2[0];
	o2[0] = ((dp12[B])[R])[L];
	L = l2[1];
	o2[1] = ((dp4[B])[R])[L];
	
	R = r[1]; B = b[1];
	
	L = l[2];
	o1[2] = ((dp2[B])[R])[L];
	L = l[3];
	o1[3] = ((dp10[B])[R])[L];
	L = l2[2];
	o2[2] = ((dp14[B])[R])[L];
	L = l2[3];
	o2[3] = ((dp6[B])[R])[L];
	
	R = r[2]; B = b[2];
	
	L = l[4];
	o1[4] = ((dp0[B])[R])[L];
	L = l[5];
	o1[5] = ((dp8[B])[R])[L];
	L = l2[4];
	o2[4] = ((dp12[B])[R])[L];
	L = l2[5];
	o2[5] = ((dp4[B])[R])[L];
	
	R = r[3]; B = b[3];
	
	L = l[6];
	o1[6] = ((dp2[B])[R])[L];
	L = l[7];
	o1[7] = ((dp10[B])[R])[L];
	L = l2[6];
	o2[6] = ((dp14[B])[R])[L];
	L = l2[7];
	o2[7] = ((dp6[B])[R])[L];
      }
      
      l += 8;
      l2 += 8;
      r += 4;
      b += 4;
      o1 += 8;
      o2 += 8;
    }
    
    l += w; l2 += w;
    o1 += w; o2 += w;

    for (j=0; j<w; j+=8) {

      if (ditherFlags[mbaddr+(j/16)]) {

	R = r[0]; B = b[0];
	
	L = l[0];
	o1[0] = ((dp3[B])[R])[L];
	L = l[1];
	o1[1] = ((dp11[B])[R])[L];
	L = l2[0];
	o2[0] = ((dp15[B])[R])[L];
	L = l2[1];
	o2[1] = ((dp7[B])[R])[L];
	
	R = r[1]; B = b[1];
	
	L = l[2];
	o1[2] = ((dp1[B])[R])[L];
	L = l[3];
	o1[3] = ((dp9[B])[R])[L];
	L = l2[2];
	o2[2] = ((dp13[B])[R])[L];
	L = l2[3];
	o2[3] = ((dp5[B])[R])[L];
	
	R = r[2]; B = b[2];
	
	L = l[4];
	o1[4] = ((dp3[B])[R])[L];
	L = l[5];
	o1[5] = ((dp11[B])[R])[L];
	L = l2[4];
	o2[4] = ((dp15[B])[R])[L];
	L = l2[5];
	o2[5] = ((dp7[B])[R])[L];
	
	R = r[3]; B = b[3];
	
	L = l[6];
	o1[6] = ((dp1[B])[R])[L];
	L = l[7];
	o1[7] = ((dp9[B])[R])[L];
	L = l2[6];
	o2[6] = ((dp13[B])[R])[L];
	L = l2[7];
	o2[7] = ((dp5[B])[R])[L];
      }

      l += 8;
      l2 += 8;
      r += 4;
      b += 4;
      o1 += 8;
      o2 += 8;
    }
    
    l += w; l2 += w;
    o1 += w; o2 += w;
  }
}

void
MBOrderedDitherDisplayCopy(vid_stream, mb_addr, motion_forw, r_right_forw,
	    r_down_forw, motion_back, r_right_back, r_down_back, past, future)
    VidStream *vid_stream;
    int mb_addr;
    int motion_forw, r_right_forw, r_down_forw;
    int motion_back, r_right_back, r_down_back;
    unsigned char *past, *future;
{
  int right_back, right_forw, down_back, down_forw;
  unsigned char *dest;
  unsigned char *src1, *src2;
  int row, col, row_size, rr;
  int mc, mr;

  row = (mb_addr / vid_stream->mb_width) << 4;
  col = (mb_addr % vid_stream->mb_width) << 4;
  row_size = vid_stream->mb_width << 4;

  dest = vid_stream->current->display + (row * row_size) + col;

  if (motion_forw) {
    right_forw = r_right_forw >> 1;
    down_forw = r_down_forw >> 1;
    src1 = past + ((row + down_forw) * row_size) + (col + right_forw);
  }

  if (motion_back) {
    right_back = r_right_back >> 1;
    down_back = r_down_back >> 1;
    src2 = future + ((row + down_back) * row_size) + (col + right_back);
  }
   
  if (motion_forw) {
    if (motion_back) {
      for (rr = 0; rr<16; rr++) {
	dest[0] = src1[0];	dest[1] = src2[1];
	dest[2] = src1[2];	dest[3] = src2[3];
	dest[4] = src1[4];	dest[5] = src2[5];
	dest[6] = src1[6];	dest[7] = src2[7];
	dest[8] = src1[8];	dest[9] = src2[9];
	dest[10] = src1[10];	dest[11] = src2[11];
	dest[12] = src1[12];	dest[13] = src2[13];
	dest[14] = src1[14];	dest[15] = src2[15];

	dest += row_size;
	src1 += row_size;
	src2 += row_size;
      }
    }
    else {
      mc = col & 0x3;
      mr = right_forw & 0x3;
      if (!mc && !mr) {
	/* Use 32 bit copy */
	int *d, *s;

	d = (int *) dest;
	s = (int *) src1;
	row_size /= 4;
	
	for (rr = 0; rr < 16; rr++) {
	  d[0] = s[0];
	  d[1] = s[1];
	  d[2] = s[2];
	  d[3] = s[3]; 
	  d += row_size;
	  s += row_size;
	}
      } else if ((!mc || (mc == 2)) &&
		 (!mr || (mr == 2))) {
	/* Use 16 bit copy */
	short int *d, * s;
	
	d = (short int *) dest;
	s = (short int *) src1;
	row_size /= 2;
	
	for (rr = 0; rr < 16; rr++) {
	  d[0] = s[0];
	  d[1] = s[1];
	  d[2] = s[2];
	  d[3] = s[3]; 
	  d[4] = s[4];
	  d[5] = s[5];
	  d[6] = s[6];
	  d[7] = s[7]; 
	  d += row_size;
	  s += row_size;
	}
      }
      else {
	for (rr = 0; rr < 16; rr++) {
	  dest[0] = src1[0];
	  dest[1] = src1[1];
	  dest[2] = src1[2];
	  dest[3] = src1[3];
	  dest[4] = src1[4];
	  dest[5] = src1[5];
	  dest[6] = src1[6];
	  dest[7] = src1[7];
	  dest[8] = src1[8];
	  dest[9] = src1[9];
	  dest[10] = src1[10];
	  dest[11] = src1[11];
	  dest[12] = src1[12];
	  dest[13] = src1[13];
	  dest[14] = src1[14];
	  dest[15] = src1[15];
	  
	  dest += row_size;
	  src1 += row_size;
	}
      }
    }
  }
  else if (motion_back) {
    mc = col & 0x3;
    mr = right_back & 0x3;
    if (!mc && !mr) {
      /* Use 32 bit copy */
      int *d, *s;
      
      d = (int *) dest;
      s = (int *) src2;
      row_size /= 4;
      
      for (rr = 0; rr < 16; rr++) {
	d[0] = s[0];
	d[1] = s[1];
	d[2] = s[2];
	d[3] = s[3]; 
	d += row_size;
	s += row_size;
      }
    }
    else if ((!mc || mc == 2) &&
	     (!mr || mr == 2)) {
      /* Use 8 bit copy */
      short int *d, *s;
      
      d = (short int *) dest;
      s = (short int *) src2;
      row_size /= 2;
      
      for (rr = 0; rr < 16; rr++) {
	d[0] = s[0];
	d[1] = s[1];
	d[2] = s[2];
	d[3] = s[3]; 
	d[4] = s[4];
	d[5] = s[5];
	d[6] = s[6];
	d[7] = s[7]; 
	d += row_size;
	s += row_size;
      }
    }
    else {
      for (rr = 0; rr < 16; rr++) {
	/* Use 8 bit copy */
	dest[0] = src2[0];
	dest[1] = src2[1];
	dest[2] = src2[2];
	dest[3] = src2[3];
	dest[4] = src2[4];
	dest[5] = src2[5];
	dest[6] = src2[6];
	dest[7] = src2[7];
	dest[8] = src2[8];
	dest[9] = src2[9];
	dest[10] = src2[10];
	dest[11] = src2[11];
	dest[12] = src2[12];
	dest[13] = src2[13];
	dest[14] = src2[14];
	dest[15] = src2[15];
	
	dest += row_size;
	src2 += row_size;
      }
    }
  }
}