source-engine/togles/linuxwin/stb_dxt_104.h

// stb_dxt.h - v1.04 - DXT1/DXT5 compressor - public domain
// original by fabian "ryg" giesen - ported to C by stb
// use '#define STB_DXT_IMPLEMENTATION' before including to create the implementation
//
// USAGE:
//   call stb_compress_dxt_block() for every block (you must pad)
//     source should be a 4x4 block of RGBA data in row-major order;
//     A is ignored if you specify alpha=0; you can turn on dithering
//     and "high quality" using mode.
//
// version history:
//   v1.04  - (ryg) default to no rounding bias for lerped colors (as per S3TC/DX10 spec);
//            single color match fix (allow for inexact color interpolation);
//            optimal DXT5 index finder; "high quality" mode that runs multiple refinement steps.
//   v1.03  - (stb) endianness support
//   v1.02  - (stb) fix alpha encoding bug
//   v1.01  - (stb) fix bug converting to RGB that messed up quality, thanks ryg & cbloom
//   v1.00  - (stb) first release

#ifndef STB_INCLUDE_STB_DXT_H
#define STB_INCLUDE_STB_DXT_H

// compression mode (bitflags)
#define STB_DXT_NORMAL    0
#define STB_DXT_DITHER    1   // use dithering. dubious win. never use for normal maps and the like!
#define STB_DXT_HIGHQUAL  2   // high quality mode, does two refinement steps instead of 1. ~30-40% slower.

void stb_compress_dxt_block(unsigned char *dest, const unsigned char *src, int alpha, int mode);
#define STB_COMPRESS_DXT_BLOCK

#ifdef STB_DXT_IMPLEMENTATION

// configuration options for DXT encoder. set them in the project/makefile or just define
// them at the top.

// STB_DXT_USE_ROUNDING_BIAS
//     use a rounding bias during color interpolation. this is closer to what "ideal"
//     interpolation would do but doesn't match the S3TC/DX10 spec. old versions (pre-1.03)
//     implicitly had this turned on. 
//
//     in case you're targeting a specific type of hardware (e.g. console programmers):
//     NVidia and Intel GPUs (as of 2010) as well as DX9 ref use DXT decoders that are closer
//     to STB_DXT_USE_ROUNDING_BIAS. AMD/ATI, S3 and DX10 ref are closer to rounding with no bias.
//     you also see "(a*5 + b*3) / 8" on some old GPU designs.
// #define STB_DXT_USE_ROUNDING_BIAS

#include <stdlib.h>
#include <math.h>
#include <string.h> // memset

static unsigned char stb__Expand5[32];
static unsigned char stb__Expand6[64];
static unsigned char stb__OMatch5[256][2];
static unsigned char stb__OMatch6[256][2];
static unsigned char stb__QuantRBTab[256+16];
static unsigned char stb__QuantGTab[256+16];

static int stb__Mul8Bit(int a, int b)
{
  int t = a*b + 128;
  return (t + (t >> 8)) >> 8;
}

static void stb__From16Bit(unsigned char *out, unsigned short v)
{
   int rv = (v & 0xf800) >> 11;
   int gv = (v & 0x07e0) >>  5;
   int bv = (v & 0x001f) >>  0;

   out[0] = stb__Expand5[rv];
   out[1] = stb__Expand6[gv];
   out[2] = stb__Expand5[bv];
   out[3] = 0;
}

static unsigned short stb__As16Bit(int r, int g, int b)
{
   return (stb__Mul8Bit(r,31) << 11) + (stb__Mul8Bit(g,63) << 5) + stb__Mul8Bit(b,31);
}

// linear interpolation at 1/3 point between a and b, using desired rounding type
static int stb__Lerp13(int a, int b)
{
#ifdef STB_DXT_USE_ROUNDING_BIAS
   // with rounding bias
   return a + stb__Mul8Bit(b-a, 0x55);
#else
   // without rounding bias
   // replace "/ 3" by "* 0xaaab) >> 17" if your compiler sucks or you really need every ounce of speed.
   return (2*a + b) / 3;
#endif
}

// lerp RGB color
static void stb__Lerp13RGB(unsigned char *out, unsigned char *p1, unsigned char *p2)
{
   out[0] = stb__Lerp13(p1[0], p2[0]);
   out[1] = stb__Lerp13(p1[1], p2[1]);
   out[2] = stb__Lerp13(p1[2], p2[2]);
}

/****************************************************************************/

// compute table to reproduce constant colors as accurately as possible
static void stb__PrepareOptTable(unsigned char *Table,const unsigned char *expand,int size)
{
   int i,mn,mx;
   for (i=0;i<256;i++) {
      int bestErr = 256;
      for (mn=0;mn<size;mn++) {
         for (mx=0;mx<size;mx++) {
            int mine = expand[mn];
            int maxe = expand[mx];
            int err = abs(stb__Lerp13(maxe, mine) - i);
            
            // DX10 spec says that interpolation must be within 3% of "correct" result,
            // add this as error term. (normally we'd expect a random distribution of
            // +-1.5% error, but nowhere in the spec does it say that the error has to be
            // unbiased - better safe than sorry).
            err += abs(maxe - mine) * 3 / 100;
            
            if(err < bestErr)
            { 
               Table[i*2+0] = mx;
               Table[i*2+1] = mn;
               bestErr = err;
            }
         }
      }
   }
}

static void stb__EvalColors(unsigned char *color,unsigned short c0,unsigned short c1)
{
   stb__From16Bit(color+ 0, c0);
   stb__From16Bit(color+ 4, c1);
   stb__Lerp13RGB(color+ 8, color+0, color+4);
   stb__Lerp13RGB(color+12, color+4, color+0);
}

// Block dithering function. Simply dithers a block to 565 RGB.
// (Floyd-Steinberg)
static void stb__DitherBlock(unsigned char *dest, unsigned char *block)
{
  int err[8],*ep1 = err,*ep2 = err+4, *et;
  int ch,y;

  // process channels seperately
  for (ch=0; ch<3; ++ch) {
      unsigned char *bp = block+ch, *dp = dest+ch;
      unsigned char *quant = (ch == 1) ? stb__QuantGTab+8 : stb__QuantRBTab+8;
      memset(err, 0, sizeof(err));
      for(y=0; y<4; ++y) {
         dp[ 0] = quant[bp[ 0] + ((3*ep2[1] + 5*ep2[0]) >> 4)];
         ep1[0] = bp[ 0] - dp[ 0];
         dp[ 4] = quant[bp[ 4] + ((7*ep1[0] + 3*ep2[2] + 5*ep2[1] + ep2[0]) >> 4)];
         ep1[1] = bp[ 4] - dp[ 4];
         dp[ 8] = quant[bp[ 8] + ((7*ep1[1] + 3*ep2[3] + 5*ep2[2] + ep2[1]) >> 4)];
         ep1[2] = bp[ 8] - dp[ 8];
         dp[12] = quant[bp[12] + ((7*ep1[2] + 5*ep2[3] + ep2[2]) >> 4)];
         ep1[3] = bp[12] - dp[12];
         bp += 16;
         dp += 16;
         et = ep1, ep1 = ep2, ep2 = et; // swap
      }
   }
}

// The color matching function
static unsigned int stb__MatchColorsBlock(unsigned char *block, unsigned char *color,int dither)
{
   unsigned int mask = 0;
   int dirr = color[0*4+0] - color[1*4+0];
   int dirg = color[0*4+1] - color[1*4+1];
   int dirb = color[0*4+2] - color[1*4+2];
   int dots[16];
   int stops[4];
   int i;
   int c0Point, halfPoint, c3Point;

   for(i=0;i<16;i++)
      dots[i] = block[i*4+0]*dirr + block[i*4+1]*dirg + block[i*4+2]*dirb;

   for(i=0;i<4;i++)
      stops[i] = color[i*4+0]*dirr + color[i*4+1]*dirg + color[i*4+2]*dirb;

   // think of the colors as arranged on a line; project point onto that line, then choose
   // next color out of available ones. we compute the crossover points for "best color in top
   // half"/"best in bottom half" and then the same inside that subinterval.
   //
   // relying on this 1d approximation isn't always optimal in terms of euclidean distance,
   // but it's very close and a lot faster.
   // http://cbloomrants.blogspot.com/2008/12/12-08-08-dxtc-summary.html
   
   c0Point   = (stops[1] + stops[3]) >> 1;
   halfPoint = (stops[3] + stops[2]) >> 1;
   c3Point   = (stops[2] + stops[0]) >> 1;

   if(!dither) {
      // the version without dithering is straightforward
      for (i=15;i>=0;i--) {
         int dot = dots[i];
         mask <<= 2;

         if(dot < halfPoint)
           mask |= (dot < c0Point) ? 1 : 3;
         else
           mask |= (dot < c3Point) ? 2 : 0;
      }
  } else {
      // with floyd-steinberg dithering
      int err[8],*ep1 = err,*ep2 = err+4;
      int *dp = dots, y;

      c0Point   <<= 4;
      halfPoint <<= 4;
      c3Point   <<= 4;
      for(i=0;i<8;i++)
         err[i] = 0;

      for(y=0;y<4;y++)
      {
         int dot,lmask,step;

         dot = (dp[0] << 4) + (3*ep2[1] + 5*ep2[0]);
         if(dot < halfPoint)
           step = (dot < c0Point) ? 1 : 3;
         else
           step = (dot < c3Point) ? 2 : 0;
         ep1[0] = dp[0] - stops[step];
         lmask = step;

         dot = (dp[1] << 4) + (7*ep1[0] + 3*ep2[2] + 5*ep2[1] + ep2[0]);
         if(dot < halfPoint)
           step = (dot < c0Point) ? 1 : 3;
         else
           step = (dot < c3Point) ? 2 : 0;
         ep1[1] = dp[1] - stops[step];
         lmask |= step<<2;

         dot = (dp[2] << 4) + (7*ep1[1] + 3*ep2[3] + 5*ep2[2] + ep2[1]);
         if(dot < halfPoint)
           step = (dot < c0Point) ? 1 : 3;
         else
           step = (dot < c3Point) ? 2 : 0;
         ep1[2] = dp[2] - stops[step];
         lmask |= step<<4;

         dot = (dp[3] << 4) + (7*ep1[2] + 5*ep2[3] + ep2[2]);
         if(dot < halfPoint)
           step = (dot < c0Point) ? 1 : 3;
         else
           step = (dot < c3Point) ? 2 : 0;
         ep1[3] = dp[3] - stops[step];
         lmask |= step<<6;

         dp += 4;
         mask |= lmask << (y*8);
         { int *et = ep1; ep1 = ep2; ep2 = et; } // swap
      }
   }

   return mask;
}

// The color optimization function. (Clever code, part 1)
static void stb__OptimizeColorsBlock(unsigned char *block, unsigned short *pmax16, unsigned short *pmin16)
{
  int mind = 0x7fffffff,maxd = -0x7fffffff;
  unsigned char *minp, *maxp;
  double magn;
  int v_r,v_g,v_b;
  static const int nIterPower = 4;
  float covf[6],vfr,vfg,vfb;

  // determine color distribution
  int cov[6];
  int mu[3],min[3],max[3];
  int ch,i,iter;

  for(ch=0;ch<3;ch++)
  {
    const unsigned char *bp = ((const unsigned char *) block) + ch;
    int muv,minv,maxv;

    muv = minv = maxv = bp[0];
    for(i=4;i<64;i+=4)
    {
      muv += bp[i];
      if (bp[i] < minv) minv = bp[i];
      else if (bp[i] > maxv) maxv = bp[i];
    }

    mu[ch] = (muv + 8) >> 4;
    min[ch] = minv;
    max[ch] = maxv;
  }

  // determine covariance matrix
  for (i=0;i<6;i++)
     cov[i] = 0;

  for (i=0;i<16;i++)
  {
    int r = block[i*4+0] - mu[0];
    int g = block[i*4+1] - mu[1];
    int b = block[i*4+2] - mu[2];

    cov[0] += r*r;
    cov[1] += r*g;
    cov[2] += r*b;
    cov[3] += g*g;
    cov[4] += g*b;
    cov[5] += b*b;
  }

  // convert covariance matrix to float, find principal axis via power iter
  for(i=0;i<6;i++)
    covf[i] = cov[i] / 255.0f;

  vfr = (float) (max[0] - min[0]);
  vfg = (float) (max[1] - min[1]);
  vfb = (float) (max[2] - min[2]);

  for(iter=0;iter<nIterPower;iter++)
  {
    float r = vfr*covf[0] + vfg*covf[1] + vfb*covf[2];
    float g = vfr*covf[1] + vfg*covf[3] + vfb*covf[4];
    float b = vfr*covf[2] + vfg*covf[4] + vfb*covf[5];

    vfr = r;
    vfg = g;
    vfb = b;
  }

  magn = fabs(vfr);
  if (fabs(vfg) > magn) magn = fabs(vfg);
  if (fabs(vfb) > magn) magn = fabs(vfb);

   if(magn < 4.0f) { // too small, default to luminance
      v_r = 299; // JPEG YCbCr luma coefs, scaled by 1000.
      v_g = 587;
      v_b = 114;
   } else {
      magn = 512.0 / magn;
      v_r = (int) (vfr * magn);
      v_g = (int) (vfg * magn);
      v_b = (int) (vfb * magn);
   }

   // Pick colors at extreme points
   for(i=0;i<16;i++)
   {
      int dot = block[i*4+0]*v_r + block[i*4+1]*v_g + block[i*4+2]*v_b;

      if (dot < mind) {
         mind = dot;
         minp = block+i*4;
      }

      if (dot > maxd) {
         maxd = dot;
         maxp = block+i*4;
      }
   }

   *pmax16 = stb__As16Bit(maxp[0],maxp[1],maxp[2]);
   *pmin16 = stb__As16Bit(minp[0],minp[1],minp[2]);
}

static int stb__sclamp(float y, int p0, int p1)
{
   int x = (int) y;
   if (x < p0) return p0;
   if (x > p1) return p1;
   return x;
}

// The refinement function. (Clever code, part 2)
// Tries to optimize colors to suit block contents better.
// (By solving a least squares system via normal equations+Cramer's rule)
static int stb__RefineBlock(unsigned char *block, unsigned short *pmax16, unsigned short *pmin16, unsigned int mask)
{
   static const int w1Tab[4] = { 3,0,2,1 };
   static const int prods[4] = { 0x090000,0x000900,0x040102,0x010402 };
   // ^some magic to save a lot of multiplies in the accumulating loop...
   // (precomputed products of weights for least squares system, accumulated inside one 32-bit register)

   float frb,fg;
   unsigned short oldMin, oldMax, min16, max16;
   int i, akku = 0, xx,xy,yy;
   int At1_r,At1_g,At1_b;
   int At2_r,At2_g,At2_b;
   unsigned int cm = mask;

   oldMin = *pmin16;
   oldMax = *pmax16;

   if((mask ^ (mask<<2)) < 4) // all pixels have the same index?
   {
      // yes, linear system would be singular; solve using optimal
      // single-color match on average color
      int r = 8, g = 8, b = 8;
      for (i=0;i<16;++i) {
         r += block[i*4+0];
         g += block[i*4+1];
         b += block[i*4+2];
      }

      r >>= 4; g >>= 4; b >>= 4;

      max16 = (stb__OMatch5[r][0]<<11) | (stb__OMatch6[g][0]<<5) | stb__OMatch5[b][0];
      min16 = (stb__OMatch5[r][1]<<11) | (stb__OMatch6[g][1]<<5) | stb__OMatch5[b][1];
   } else {
      At1_r = At1_g = At1_b = 0;
      At2_r = At2_g = At2_b = 0;
      for (i=0;i<16;++i,cm>>=2) {
         int step = cm&3;
         int w1 = w1Tab[step];
         int r = block[i*4+0];
         int g = block[i*4+1];
         int b = block[i*4+2];

         akku    += prods[step];
         At1_r   += w1*r;
         At1_g   += w1*g;
         At1_b   += w1*b;
         At2_r   += r;
         At2_g   += g;
         At2_b   += b;
      }

      At2_r = 3*At2_r - At1_r;
      At2_g = 3*At2_g - At1_g;
      At2_b = 3*At2_b - At1_b;

      // extract solutions and decide solvability
      xx = akku >> 16;
      yy = (akku >> 8) & 0xff;
      xy = (akku >> 0) & 0xff;

      frb = 3.0f * 31.0f / 255.0f / (xx*yy - xy*xy);
      fg = frb * 63.0f / 31.0f;

      // solve.
      max16 =   stb__sclamp((At1_r*yy - At2_r*xy)*frb+0.5f,0,31) << 11;
      max16 |=  stb__sclamp((At1_g*yy - At2_g*xy)*fg +0.5f,0,63) << 5;
      max16 |=  stb__sclamp((At1_b*yy - At2_b*xy)*frb+0.5f,0,31) << 0;

      min16 =   stb__sclamp((At2_r*xx - At1_r*xy)*frb+0.5f,0,31) << 11;
      min16 |=  stb__sclamp((At2_g*xx - At1_g*xy)*fg +0.5f,0,63) << 5;
      min16 |=  stb__sclamp((At2_b*xx - At1_b*xy)*frb+0.5f,0,31) << 0;
   }

   *pmin16 = min16;
   *pmax16 = max16;
   return oldMin != min16 || oldMax != max16;
}

// Color block compression
static void stb__CompressColorBlock(unsigned char *dest, unsigned char *block, int mode)
{
   unsigned int mask;
   int i;
   int dither;
   int refinecount;
   unsigned short max16, min16;
   unsigned char dblock[16*4],color[4*4];
   
   dither = mode & STB_DXT_DITHER;
   refinecount = (mode & STB_DXT_HIGHQUAL) ? 2 : 1;

   // check if block is constant
   for (i=1;i<16;i++)
      if (((unsigned int *) block)[i] != ((unsigned int *) block)[0])
         break;

   if(i == 16) { // constant color
      int r = block[0], g = block[1], b = block[2];
      mask  = 0xaaaaaaaa;
      max16 = (stb__OMatch5[r][0]<<11) | (stb__OMatch6[g][0]<<5) | stb__OMatch5[b][0];
      min16 = (stb__OMatch5[r][1]<<11) | (stb__OMatch6[g][1]<<5) | stb__OMatch5[b][1];
   } else {
      // first step: compute dithered version for PCA if desired
      if(dither)
         stb__DitherBlock(dblock,block);

      // second step: pca+map along principal axis
      stb__OptimizeColorsBlock(dither ? dblock : block,&max16,&min16);
      if (max16 != min16) {
         stb__EvalColors(color,max16,min16);
         mask = stb__MatchColorsBlock(block,color,dither);
      } else
         mask = 0;

      // third step: refine (multiple times if requested)
      for (i=0;i<refinecount;i++) {
         unsigned int lastmask = mask;
         
         if (stb__RefineBlock(dither ? dblock : block,&max16,&min16,mask)) {
            if (max16 != min16) {
               stb__EvalColors(color,max16,min16);
               mask = stb__MatchColorsBlock(block,color,dither);
            } else {
               mask = 0;
               break;
            }
         }
         
         if(mask == lastmask)
            break;
      }
  }

  // write the color block
  if(max16 < min16)
  {
     unsigned short t = min16;
     min16 = max16;
     max16 = t;
     mask ^= 0x55555555;
  }

  dest[0] = (unsigned char) (max16);
  dest[1] = (unsigned char) (max16 >> 8);
  dest[2] = (unsigned char) (min16);
  dest[3] = (unsigned char) (min16 >> 8);
  dest[4] = (unsigned char) (mask);
  dest[5] = (unsigned char) (mask >> 8);
  dest[6] = (unsigned char) (mask >> 16);
  dest[7] = (unsigned char) (mask >> 24);
}

// Alpha block compression (this is easy for a change)
static void stb__CompressAlphaBlock(unsigned char *dest,unsigned char *src,int mode)
{
   int i,dist,bias,dist4,dist2,bits,mask;

   // find min/max color
   int mn,mx;
   mn = mx = src[3];

   for (i=1;i<16;i++)
   {
      if (src[i*4+3] < mn) mn = src[i*4+3];
      else if (src[i*4+3] > mx) mx = src[i*4+3];
   }

   // encode them
   ((unsigned char *)dest)[0] = mx;
   ((unsigned char *)dest)[1] = mn;
   dest += 2;

   // determine bias and emit color indices
   // given the choice of mx/mn, these indices are optimal:
   // http://fgiesen.wordpress.com/2009/12/15/dxt5-alpha-block-index-determination/
   dist = mx-mn;
   dist4 = dist*4;
   dist2 = dist*2;
   bias = (dist < 8) ? (dist - 1) : (dist/2 + 2);
   bias -= mn * 7;
   bits = 0,mask=0;
   
   for (i=0;i<16;i++) {
      int a = src[i*4+3]*7 + bias;
      int ind,t;

      // select index. this is a "linear scale" lerp factor between 0 (val=min) and 7 (val=max).
      t = (a >= dist4) ? -1 : 0; ind =  t & 4; a -= dist4 & t;
      t = (a >= dist2) ? -1 : 0; ind += t & 2; a -= dist2 & t;
      ind += (a >= dist);
      
      // turn linear scale into DXT index (0/1 are extremal pts)
      ind = -ind & 7;
      ind ^= (2 > ind);

      // write index
      mask |= ind << bits;
      if((bits += 3) >= 8) {
         *dest++ = mask;
         mask >>= 8;
         bits -= 8;
      }
   }
}

static void stb__InitDXT()
{
   int i;
   for(i=0;i<32;i++)
      stb__Expand5[i] = (i<<3)|(i>>2);

   for(i=0;i<64;i++)
      stb__Expand6[i] = (i<<2)|(i>>4);

   for(i=0;i<256+16;i++)
   {
      int v = i-8 < 0 ? 0 : i-8 > 255 ? 255 : i-8;
      stb__QuantRBTab[i] = stb__Expand5[stb__Mul8Bit(v,31)];
      stb__QuantGTab[i] = stb__Expand6[stb__Mul8Bit(v,63)];
   }

   stb__PrepareOptTable(&stb__OMatch5[0][0],stb__Expand5,32);
   stb__PrepareOptTable(&stb__OMatch6[0][0],stb__Expand6,64);
}

void stb_compress_dxt_block(unsigned char *dest, const unsigned char *src, int alpha, int mode)
{
   static int init=1;
   if (init) {
      stb__InitDXT();
      init=0;
   }

   if (alpha) {
      stb__CompressAlphaBlock(dest,(unsigned char*) src,mode);
      dest += 8;
   }

   stb__CompressColorBlock(dest,(unsigned char*) src,mode);
}
#endif // STB_DXT_IMPLEMENTATION

#endif // STB_INCLUDE_STB_DXT_H
Fix shaders compilation, replace some opengl functions with opengles analogs 3 years ago			`// stb_dxt.h - v1.04 - DXT1/DXT5 compressor - public domain`
			`// original by fabian "ryg" giesen - ported to C by stb`
			`// use '#define STB_DXT_IMPLEMENTATION' before including to create the implementation`
			`//`
			`// USAGE:`
			`// call stb_compress_dxt_block() for every block (you must pad)`
			`// source should be a 4x4 block of RGBA data in row-major order;`
			`// A is ignored if you specify alpha=0; you can turn on dithering`
			`// and "high quality" using mode.`
			`//`
			`// version history:`
			`// v1.04 - (ryg) default to no rounding bias for lerped colors (as per S3TC/DX10 spec);`
			`// single color match fix (allow for inexact color interpolation);`
			`// optimal DXT5 index finder; "high quality" mode that runs multiple refinement steps.`
			`// v1.03 - (stb) endianness support`
			`// v1.02 - (stb) fix alpha encoding bug`
			`// v1.01 - (stb) fix bug converting to RGB that messed up quality, thanks ryg & cbloom`
			`// v1.00 - (stb) first release`

			`#ifndef STB_INCLUDE_STB_DXT_H`
			`#define STB_INCLUDE_STB_DXT_H`

			`// compression mode (bitflags)`
			`#define STB_DXT_NORMAL 0`
			`#define STB_DXT_DITHER 1 // use dithering. dubious win. never use for normal maps and the like!`
			`#define STB_DXT_HIGHQUAL 2 // high quality mode, does two refinement steps instead of 1. ~30-40% slower.`

			`void stb_compress_dxt_block(unsigned char dest, const unsigned char src, int alpha, int mode);`
			`#define STB_COMPRESS_DXT_BLOCK`

			`#ifdef STB_DXT_IMPLEMENTATION`

			`// configuration options for DXT encoder. set them in the project/makefile or just define`
			`// them at the top.`

			`// STB_DXT_USE_ROUNDING_BIAS`
			`// use a rounding bias during color interpolation. this is closer to what "ideal"`
			`// interpolation would do but doesn't match the S3TC/DX10 spec. old versions (pre-1.03)`
			`// implicitly had this turned on.`
			`//`
			`// in case you're targeting a specific type of hardware (e.g. console programmers):`
			`// NVidia and Intel GPUs (as of 2010) as well as DX9 ref use DXT decoders that are closer`
			`// to STB_DXT_USE_ROUNDING_BIAS. AMD/ATI, S3 and DX10 ref are closer to rounding with no bias.`
			`// you also see "(a5 + b3) / 8" on some old GPU designs.`
			`// #define STB_DXT_USE_ROUNDING_BIAS`

			`#include <stdlib.h>`
			`#include <math.h>`
			`#include <string.h> // memset`

			`static unsigned char stb__Expand5[32];`
			`static unsigned char stb__Expand6[64];`
			`static unsigned char stb__OMatch5[256][2];`
			`static unsigned char stb__OMatch6[256][2];`
			`static unsigned char stb__QuantRBTab[256+16];`
			`static unsigned char stb__QuantGTab[256+16];`

			`static int stb__Mul8Bit(int a, int b)`
			`{`
			`int t = a*b + 128;`
			`return (t + (t >> 8)) >> 8;`
			`}`

			`static void stb__From16Bit(unsigned char *out, unsigned short v)`
			`{`
			`int rv = (v & 0xf800) >> 11;`
			`int gv = (v & 0x07e0) >> 5;`
			`int bv = (v & 0x001f) >> 0;`

			`out[0] = stb__Expand5[rv];`
			`out[1] = stb__Expand6[gv];`
			`out[2] = stb__Expand5[bv];`
			`out[3] = 0;`
			`}`

			`static unsigned short stb__As16Bit(int r, int g, int b)`
			`{`
			`return (stb__Mul8Bit(r,31) << 11) + (stb__Mul8Bit(g,63) << 5) + stb__Mul8Bit(b,31);`
			`}`

			`// linear interpolation at 1/3 point between a and b, using desired rounding type`
			`static int stb__Lerp13(int a, int b)`
			`{`
			`#ifdef STB_DXT_USE_ROUNDING_BIAS`
			`// with rounding bias`
			`return a + stb__Mul8Bit(b-a, 0x55);`
			`#else`
			`// without rounding bias`
			`// replace "/ 3" by "* 0xaaab) >> 17" if your compiler sucks or you really need every ounce of speed.`
			`return (2*a + b) / 3;`
			`#endif`
			`}`

			`// lerp RGB color`
			`static void stb__Lerp13RGB(unsigned char out, unsigned char p1, unsigned char *p2)`
			`{`
			`out[0] = stb__Lerp13(p1[0], p2[0]);`
			`out[1] = stb__Lerp13(p1[1], p2[1]);`
			`out[2] = stb__Lerp13(p1[2], p2[2]);`
			`}`

			`/****************************************************************************/`

			`// compute table to reproduce constant colors as accurately as possible`
			`static void stb__PrepareOptTable(unsigned char Table,const unsigned char expand,int size)`
			`{`
			`int i,mn,mx;`
			`for (i=0;i<256;i++) {`
			`int bestErr = 256;`
			`for (mn=0;mn<size;mn++) {`
			`for (mx=0;mx<size;mx++) {`
			`int mine = expand[mn];`
			`int maxe = expand[mx];`
			`int err = abs(stb__Lerp13(maxe, mine) - i);`

			`// DX10 spec says that interpolation must be within 3% of "correct" result,`
			`// add this as error term. (normally we'd expect a random distribution of`
			`// +-1.5% error, but nowhere in the spec does it say that the error has to be`
			`// unbiased - better safe than sorry).`
			`err += abs(maxe - mine) * 3 / 100;`

			`if(err < bestErr)`
			`{`
			`Table[i*2+0] = mx;`
			`Table[i*2+1] = mn;`
			`bestErr = err;`
			`}`
			`}`
			`}`
			`}`
			`}`

			`static void stb__EvalColors(unsigned char *color,unsigned short c0,unsigned short c1)`
			`{`
			`stb__From16Bit(color+ 0, c0);`
			`stb__From16Bit(color+ 4, c1);`
			`stb__Lerp13RGB(color+ 8, color+0, color+4);`
			`stb__Lerp13RGB(color+12, color+4, color+0);`
			`}`

			`// Block dithering function. Simply dithers a block to 565 RGB.`
			`// (Floyd-Steinberg)`
			`static void stb__DitherBlock(unsigned char dest, unsigned char block)`
			`{`
			`int err[8],ep1 = err,ep2 = err+4, *et;`
			`int ch,y;`

			`// process channels seperately`
			`for (ch=0; ch<3; ++ch) {`
			`unsigned char bp = block+ch, dp = dest+ch;`
			`unsigned char *quant = (ch == 1) ? stb__QuantGTab+8 : stb__QuantRBTab+8;`
			`memset(err, 0, sizeof(err));`
			`for(y=0; y<4; ++y) {`
			`dp[ 0] = quant[bp[ 0] + ((3ep2[1] + 5ep2[0]) >> 4)];`
			`ep1[0] = bp[ 0] - dp[ 0];`
			`dp[ 4] = quant[bp[ 4] + ((7ep1[0] + 3ep2[2] + 5*ep2[1] + ep2[0]) >> 4)];`
			`ep1[1] = bp[ 4] - dp[ 4];`
			`dp[ 8] = quant[bp[ 8] + ((7ep1[1] + 3ep2[3] + 5*ep2[2] + ep2[1]) >> 4)];`
			`ep1[2] = bp[ 8] - dp[ 8];`
			`dp[12] = quant[bp[12] + ((7ep1[2] + 5ep2[3] + ep2[2]) >> 4)];`
			`ep1[3] = bp[12] - dp[12];`
			`bp += 16;`
			`dp += 16;`
			`et = ep1, ep1 = ep2, ep2 = et; // swap`
			`}`
			`}`
			`}`

			`// The color matching function`
			`static unsigned int stb__MatchColorsBlock(unsigned char block, unsigned char color,int dither)`
			`{`
			`unsigned int mask = 0;`
			`int dirr = color[04+0] - color[14+0];`
			`int dirg = color[04+1] - color[14+1];`
			`int dirb = color[04+2] - color[14+2];`
			`int dots[16];`
			`int stops[4];`
			`int i;`
			`int c0Point, halfPoint, c3Point;`

			`for(i=0;i<16;i++)`
			`dots[i] = block[i4+0]dirr + block[i4+1]dirg + block[i4+2]dirb;`

			`for(i=0;i<4;i++)`
			`stops[i] = color[i4+0]dirr + color[i4+1]dirg + color[i4+2]dirb;`

			`// think of the colors as arranged on a line; project point onto that line, then choose`
			`// next color out of available ones. we compute the crossover points for "best color in top`
			`// half"/"best in bottom half" and then the same inside that subinterval.`
			`//`
			`// relying on this 1d approximation isn't always optimal in terms of euclidean distance,`
			`// but it's very close and a lot faster.`
			`// http://cbloomrants.blogspot.com/2008/12/12-08-08-dxtc-summary.html`

			`c0Point = (stops[1] + stops[3]) >> 1;`
			`halfPoint = (stops[3] + stops[2]) >> 1;`
			`c3Point = (stops[2] + stops[0]) >> 1;`

			`if(!dither) {`
			`// the version without dithering is straightforward`
			`for (i=15;i>=0;i--) {`
			`int dot = dots[i];`
			`mask <<= 2;`

			`if(dot < halfPoint)`
			`mask \|= (dot < c0Point) ? 1 : 3;`
			`else`
			`mask \|= (dot < c3Point) ? 2 : 0;`
			`}`
			`} else {`
			`// with floyd-steinberg dithering`
			`int err[8],ep1 = err,ep2 = err+4;`
			`int *dp = dots, y;`

			`c0Point <<= 4;`
			`halfPoint <<= 4;`
			`c3Point <<= 4;`
			`for(i=0;i<8;i++)`
			`err[i] = 0;`

			`for(y=0;y<4;y++)`
			`{`
			`int dot,lmask,step;`

			`dot = (dp[0] << 4) + (3ep2[1] + 5ep2[0]);`
			`if(dot < halfPoint)`
			`step = (dot < c0Point) ? 1 : 3;`
			`else`
			`step = (dot < c3Point) ? 2 : 0;`
			`ep1[0] = dp[0] - stops[step];`
			`lmask = step;`

			`dot = (dp[1] << 4) + (7ep1[0] + 3ep2[2] + 5*ep2[1] + ep2[0]);`
			`if(dot < halfPoint)`
			`step = (dot < c0Point) ? 1 : 3;`
			`else`
			`step = (dot < c3Point) ? 2 : 0;`
			`ep1[1] = dp[1] - stops[step];`
			`lmask \|= step<<2;`

			`dot = (dp[2] << 4) + (7ep1[1] + 3ep2[3] + 5*ep2[2] + ep2[1]);`
			`if(dot < halfPoint)`
			`step = (dot < c0Point) ? 1 : 3;`
			`else`
			`step = (dot < c3Point) ? 2 : 0;`
			`ep1[2] = dp[2] - stops[step];`
			`lmask \|= step<<4;`

			`dot = (dp[3] << 4) + (7ep1[2] + 5ep2[3] + ep2[2]);`
			`if(dot < halfPoint)`
			`step = (dot < c0Point) ? 1 : 3;`
			`else`
			`step = (dot < c3Point) ? 2 : 0;`
			`ep1[3] = dp[3] - stops[step];`
			`lmask \|= step<<6;`

			`dp += 4;`
			`mask \|= lmask << (y*8);`
			`{ int *et = ep1; ep1 = ep2; ep2 = et; } // swap`
			`}`
			`}`

			`return mask;`
			`}`

			`// The color optimization function. (Clever code, part 1)`
			`static void stb__OptimizeColorsBlock(unsigned char block, unsigned short pmax16, unsigned short *pmin16)`
			`{`
			`int mind = 0x7fffffff,maxd = -0x7fffffff;`
			`unsigned char minp, maxp;`
			`double magn;`
			`int v_r,v_g,v_b;`
			`static const int nIterPower = 4;`
			`float covf[6],vfr,vfg,vfb;`

			`// determine color distribution`
			`int cov[6];`
			`int mu[3],min[3],max[3];`
			`int ch,i,iter;`

			`for(ch=0;ch<3;ch++)`
			`{`
			`const unsigned char bp = ((const unsigned char ) block) + ch;`
			`int muv,minv,maxv;`

			`muv = minv = maxv = bp[0];`
			`for(i=4;i<64;i+=4)`
			`{`
			`muv += bp[i];`
			`if (bp[i] < minv) minv = bp[i];`
			`else if (bp[i] > maxv) maxv = bp[i];`
			`}`

			`mu[ch] = (muv + 8) >> 4;`
			`min[ch] = minv;`
			`max[ch] = maxv;`
			`}`

			`// determine covariance matrix`
			`for (i=0;i<6;i++)`
			`cov[i] = 0;`

			`for (i=0;i<16;i++)`
			`{`
			`int r = block[i*4+0] - mu[0];`
			`int g = block[i*4+1] - mu[1];`
			`int b = block[i*4+2] - mu[2];`

			`cov[0] += r*r;`
			`cov[1] += r*g;`
			`cov[2] += r*b;`
			`cov[3] += g*g;`
			`cov[4] += g*b;`
			`cov[5] += b*b;`
			`}`

			`// convert covariance matrix to float, find principal axis via power iter`
			`for(i=0;i<6;i++)`
			`covf[i] = cov[i] / 255.0f;`

			`vfr = (float) (max[0] - min[0]);`
			`vfg = (float) (max[1] - min[1]);`
			`vfb = (float) (max[2] - min[2]);`

			`for(iter=0;iter<nIterPower;iter++)`
			`{`
			`float r = vfrcovf[0] + vfgcovf[1] + vfb*covf[2];`
			`float g = vfrcovf[1] + vfgcovf[3] + vfb*covf[4];`
			`float b = vfrcovf[2] + vfgcovf[4] + vfb*covf[5];`

			`vfr = r;`
			`vfg = g;`
			`vfb = b;`
			`}`

			`magn = fabs(vfr);`
			`if (fabs(vfg) > magn) magn = fabs(vfg);`
			`if (fabs(vfb) > magn) magn = fabs(vfb);`

			`if(magn < 4.0f) { // too small, default to luminance`
			`v_r = 299; // JPEG YCbCr luma coefs, scaled by 1000.`
			`v_g = 587;`
			`v_b = 114;`
			`} else {`
			`magn = 512.0 / magn;`
			`v_r = (int) (vfr * magn);`
			`v_g = (int) (vfg * magn);`
			`v_b = (int) (vfb * magn);`
			`}`

			`// Pick colors at extreme points`
			`for(i=0;i<16;i++)`
			`{`
			`int dot = block[i4+0]v_r + block[i4+1]v_g + block[i4+2]v_b;`

			`if (dot < mind) {`
			`mind = dot;`
			`minp = block+i*4;`
			`}`

			`if (dot > maxd) {`
			`maxd = dot;`
			`maxp = block+i*4;`
			`}`
			`}`

			`*pmax16 = stb__As16Bit(maxp[0],maxp[1],maxp[2]);`
			`*pmin16 = stb__As16Bit(minp[0],minp[1],minp[2]);`
			`}`

			`static int stb__sclamp(float y, int p0, int p1)`
			`{`
			`int x = (int) y;`
			`if (x < p0) return p0;`
			`if (x > p1) return p1;`
			`return x;`
			`}`

			`// The refinement function. (Clever code, part 2)`
			`// Tries to optimize colors to suit block contents better.`
			`// (By solving a least squares system via normal equations+Cramer's rule)`
			`static int stb__RefineBlock(unsigned char block, unsigned short pmax16, unsigned short *pmin16, unsigned int mask)`
			`{`
			`static const int w1Tab[4] = { 3,0,2,1 };`
			`static const int prods[4] = { 0x090000,0x000900,0x040102,0x010402 };`
			`// ^some magic to save a lot of multiplies in the accumulating loop...`
			`// (precomputed products of weights for least squares system, accumulated inside one 32-bit register)`

			`float frb,fg;`
			`unsigned short oldMin, oldMax, min16, max16;`
			`int i, akku = 0, xx,xy,yy;`
			`int At1_r,At1_g,At1_b;`
			`int At2_r,At2_g,At2_b;`
			`unsigned int cm = mask;`

			`oldMin = *pmin16;`
			`oldMax = *pmax16;`

			`if((mask ^ (mask<<2)) < 4) // all pixels have the same index?`
			`{`
			`// yes, linear system would be singular; solve using optimal`
			`// single-color match on average color`
			`int r = 8, g = 8, b = 8;`
			`for (i=0;i<16;++i) {`
			`r += block[i*4+0];`
			`g += block[i*4+1];`
			`b += block[i*4+2];`
			`}`

			`r >>= 4; g >>= 4; b >>= 4;`

			`max16 = (stb__OMatch5[r][0]<<11) \| (stb__OMatch6[g][0]<<5) \| stb__OMatch5[b][0];`
			`min16 = (stb__OMatch5[r][1]<<11) \| (stb__OMatch6[g][1]<<5) \| stb__OMatch5[b][1];`
			`} else {`
			`At1_r = At1_g = At1_b = 0;`
			`At2_r = At2_g = At2_b = 0;`
			`for (i=0;i<16;++i,cm>>=2) {`
			`int step = cm&3;`
			`int w1 = w1Tab[step];`
			`int r = block[i*4+0];`
			`int g = block[i*4+1];`
			`int b = block[i*4+2];`

			`akku += prods[step];`
			`At1_r += w1*r;`
			`At1_g += w1*g;`
			`At1_b += w1*b;`
			`At2_r += r;`
			`At2_g += g;`
			`At2_b += b;`
			`}`

			`At2_r = 3*At2_r - At1_r;`
			`At2_g = 3*At2_g - At1_g;`
			`At2_b = 3*At2_b - At1_b;`

			`// extract solutions and decide solvability`
			`xx = akku >> 16;`
			`yy = (akku >> 8) & 0xff;`
			`xy = (akku >> 0) & 0xff;`

			`frb = 3.0f * 31.0f / 255.0f / (xxyy - xyxy);`
			`fg = frb * 63.0f / 31.0f;`

			`// solve.`
			`max16 = stb__sclamp((At1_ryy - At2_rxy)*frb+0.5f,0,31) << 11;`
			`max16 \|= stb__sclamp((At1_gyy - At2_gxy)*fg +0.5f,0,63) << 5;`
			`max16 \|= stb__sclamp((At1_byy - At2_bxy)*frb+0.5f,0,31) << 0;`

			`min16 = stb__sclamp((At2_rxx - At1_rxy)*frb+0.5f,0,31) << 11;`
			`min16 \|= stb__sclamp((At2_gxx - At1_gxy)*fg +0.5f,0,63) << 5;`
			`min16 \|= stb__sclamp((At2_bxx - At1_bxy)*frb+0.5f,0,31) << 0;`
			`}`

			`*pmin16 = min16;`
			`*pmax16 = max16;`
			`return oldMin != min16 \|\| oldMax != max16;`
			`}`

			`// Color block compression`
			`static void stb__CompressColorBlock(unsigned char dest, unsigned char block, int mode)`
			`{`
			`unsigned int mask;`
			`int i;`
			`int dither;`
			`int refinecount;`
			`unsigned short max16, min16;`
			`unsigned char dblock[164],color[44];`

			`dither = mode & STB_DXT_DITHER;`
			`refinecount = (mode & STB_DXT_HIGHQUAL) ? 2 : 1;`

			`// check if block is constant`
			`for (i=1;i<16;i++)`
			`if (((unsigned int ) block)[i] != ((unsigned int ) block)[0])`
			`break;`

			`if(i == 16) { // constant color`
			`int r = block[0], g = block[1], b = block[2];`
			`mask = 0xaaaaaaaa;`
			`max16 = (stb__OMatch5[r][0]<<11) \| (stb__OMatch6[g][0]<<5) \| stb__OMatch5[b][0];`
			`min16 = (stb__OMatch5[r][1]<<11) \| (stb__OMatch6[g][1]<<5) \| stb__OMatch5[b][1];`
			`} else {`
			`// first step: compute dithered version for PCA if desired`
			`if(dither)`
			`stb__DitherBlock(dblock,block);`

			`// second step: pca+map along principal axis`
			`stb__OptimizeColorsBlock(dither ? dblock : block,&max16,&min16);`
			`if (max16 != min16) {`
			`stb__EvalColors(color,max16,min16);`
			`mask = stb__MatchColorsBlock(block,color,dither);`
			`} else`
			`mask = 0;`

			`// third step: refine (multiple times if requested)`
			`for (i=0;i<refinecount;i++) {`
			`unsigned int lastmask = mask;`

			`if (stb__RefineBlock(dither ? dblock : block,&max16,&min16,mask)) {`
			`if (max16 != min16) {`
			`stb__EvalColors(color,max16,min16);`
			`mask = stb__MatchColorsBlock(block,color,dither);`
			`} else {`
			`mask = 0;`
			`break;`
			`}`
			`}`

			`if(mask == lastmask)`
			`break;`
			`}`
			`}`

			`// write the color block`
			`if(max16 < min16)`
			`{`
			`unsigned short t = min16;`
			`min16 = max16;`
			`max16 = t;`
			`mask ^= 0x55555555;`
			`}`

			`dest[0] = (unsigned char) (max16);`
			`dest[1] = (unsigned char) (max16 >> 8);`
			`dest[2] = (unsigned char) (min16);`
			`dest[3] = (unsigned char) (min16 >> 8);`
			`dest[4] = (unsigned char) (mask);`
			`dest[5] = (unsigned char) (mask >> 8);`
			`dest[6] = (unsigned char) (mask >> 16);`
			`dest[7] = (unsigned char) (mask >> 24);`
			`}`

			`// Alpha block compression (this is easy for a change)`
			`static void stb__CompressAlphaBlock(unsigned char dest,unsigned char src,int mode)`
			`{`
			`int i,dist,bias,dist4,dist2,bits,mask;`

			`// find min/max color`
			`int mn,mx;`
			`mn = mx = src[3];`

			`for (i=1;i<16;i++)`
			`{`
			`if (src[i4+3] < mn) mn = src[i4+3];`
			`else if (src[i4+3] > mx) mx = src[i4+3];`
			`}`

			`// encode them`
			`((unsigned char *)dest)[0] = mx;`
			`((unsigned char *)dest)[1] = mn;`
			`dest += 2;`

			`// determine bias and emit color indices`
			`// given the choice of mx/mn, these indices are optimal:`
			`// http://fgiesen.wordpress.com/2009/12/15/dxt5-alpha-block-index-determination/`
			`dist = mx-mn;`
			`dist4 = dist*4;`
			`dist2 = dist*2;`
			`bias = (dist < 8) ? (dist - 1) : (dist/2 + 2);`
			`bias -= mn * 7;`
			`bits = 0,mask=0;`

			`for (i=0;i<16;i++) {`
			`int a = src[i4+3]7 + bias;`
			`int ind,t;`

			`// select index. this is a "linear scale" lerp factor between 0 (val=min) and 7 (val=max).`
			`t = (a >= dist4) ? -1 : 0; ind = t & 4; a -= dist4 & t;`
			`t = (a >= dist2) ? -1 : 0; ind += t & 2; a -= dist2 & t;`
			`ind += (a >= dist);`

			`// turn linear scale into DXT index (0/1 are extremal pts)`
			`ind = -ind & 7;`
			`ind ^= (2 > ind);`

			`// write index`
			`mask \|= ind << bits;`
			`if((bits += 3) >= 8) {`
			`*dest++ = mask;`
			`mask >>= 8;`
			`bits -= 8;`
			`}`
			`}`
			`}`

			`static void stb__InitDXT()`
			`{`
			`int i;`
			`for(i=0;i<32;i++)`
			`stb__Expand5[i] = (i<<3)\|(i>>2);`

			`for(i=0;i<64;i++)`
			`stb__Expand6[i] = (i<<2)\|(i>>4);`

			`for(i=0;i<256+16;i++)`
			`{`
			`int v = i-8 < 0 ? 0 : i-8 > 255 ? 255 : i-8;`
			`stb__QuantRBTab[i] = stb__Expand5[stb__Mul8Bit(v,31)];`
			`stb__QuantGTab[i] = stb__Expand6[stb__Mul8Bit(v,63)];`
			`}`

			`stb__PrepareOptTable(&stb__OMatch5[0][0],stb__Expand5,32);`
			`stb__PrepareOptTable(&stb__OMatch6[0][0],stb__Expand6,64);`
			`}`

			`void stb_compress_dxt_block(unsigned char dest, const unsigned char src, int alpha, int mode)`
			`{`
			`static int init=1;`
			`if (init) {`
			`stb__InitDXT();`
			`init=0;`
			`}`

			`if (alpha) {`
			`stb__CompressAlphaBlock(dest,(unsigned char*) src,mode);`
			`dest += 8;`
			`}`

			`stb__CompressColorBlock(dest,(unsigned char*) src,mode);`
			`}`
			`#endif // STB_DXT_IMPLEMENTATION`

			`#endif // STB_INCLUDE_STB_DXT_H`