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1e07b26356
git-svn-id: https://dolphin-emu.googlecode.com/svn/trunk@3175 8ced0084-cf51-0410-be5f-012b33b47a6e
633 lines
17 KiB
C
633 lines
17 KiB
C
/*
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Jonathan Dummer
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2007-07-31-10.32
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simple DXT compression / decompression code
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public domain
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*/
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#include "image_DXT.h"
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#include <math.h>
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#include <stdlib.h>
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#include <string.h>
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#include <stdio.h>
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/* set this =1 if you want to use the covarince matrix method...
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which is better than my method of using standard deviations
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overall, except on the infintesimal chance that the power
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method fails for finding the largest eigenvector */
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#define USE_COV_MAT 1
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/********* Function Prototypes *********/
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/*
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Takes a 4x4 block of pixels and compresses it into 8 bytes
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in DXT1 format (color only, no alpha). Speed is valued
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over prettyness, at least for now.
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*/
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void compress_DDS_color_block(
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int channels,
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const unsigned char *const uncompressed,
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unsigned char compressed[8] );
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/*
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Takes a 4x4 block of pixels and compresses the alpha
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component it into 8 bytes for use in DXT5 DDS files.
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Speed is valued over prettyness, at least for now.
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*/
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void compress_DDS_alpha_block(
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const unsigned char *const uncompressed,
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unsigned char compressed[8] );
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/********* Actual Exposed Functions *********/
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int
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save_image_as_DDS
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(
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const char *filename,
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int width, int height, int channels,
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const unsigned char *const data
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)
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{
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/* variables */
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FILE *fout;
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unsigned char *DDS_data;
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DDS_header header;
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int DDS_size;
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/* error check */
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if( (NULL == filename) ||
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(width < 1) || (height < 1) ||
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(channels < 1) || (channels > 4) ||
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(data == NULL ) )
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{
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return 0;
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}
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/* Convert the image */
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if( (channels & 1) == 1 )
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{
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/* no alpha, just use DXT1 */
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DDS_data = convert_image_to_DXT1( data, width, height, channels, &DDS_size );
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} else
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{
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/* has alpha, so use DXT5 */
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DDS_data = convert_image_to_DXT5( data, width, height, channels, &DDS_size );
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}
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/* save it */
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memset( &header, 0, sizeof( DDS_header ) );
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header.dwMagic = ('D' << 0) | ('D' << 8) | ('S' << 16) | (' ' << 24);
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header.dwSize = 124;
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header.dwFlags = DDSD_CAPS | DDSD_HEIGHT | DDSD_WIDTH | DDSD_PIXELFORMAT | DDSD_LINEARSIZE;
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header.dwWidth = width;
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header.dwHeight = height;
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header.dwPitchOrLinearSize = DDS_size;
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header.sPixelFormat.dwSize = 32;
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header.sPixelFormat.dwFlags = DDPF_FOURCC;
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if( (channels & 1) == 1 )
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{
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header.sPixelFormat.dwFourCC = ('D' << 0) | ('X' << 8) | ('T' << 16) | ('1' << 24);
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} else
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{
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header.sPixelFormat.dwFourCC = ('D' << 0) | ('X' << 8) | ('T' << 16) | ('5' << 24);
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}
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header.sCaps.dwCaps1 = DDSCAPS_TEXTURE;
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/* write it out */
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fout = fopen( filename, "wb");
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fwrite( &header, sizeof( DDS_header ), 1, fout );
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fwrite( DDS_data, 1, DDS_size, fout );
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fclose( fout );
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/* done */
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free( DDS_data );
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return 1;
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}
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unsigned char* convert_image_to_DXT1(
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const unsigned char *const uncompressed,
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int width, int height, int channels,
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int *out_size )
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{
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unsigned char *compressed;
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int i, j, x, y;
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unsigned char ublock[16*3];
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unsigned char cblock[8];
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int index = 0, chan_step = 1;
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int block_count = 0;
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/* error check */
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*out_size = 0;
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if( (width < 1) || (height < 1) ||
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(NULL == uncompressed) ||
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(channels < 1) || (channels > 4) )
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{
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return NULL;
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}
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/* for channels == 1 or 2, I do not step forward for R,G,B values */
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if( channels < 3 )
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{
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chan_step = 0;
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}
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/* get the RAM for the compressed image
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(8 bytes per 4x4 pixel block) */
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*out_size = ((width+3) >> 2) * ((height+3) >> 2) * 8;
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compressed = (unsigned char*)malloc( *out_size );
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/* go through each block */
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for( j = 0; j < height; j += 4 )
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{
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for( i = 0; i < width; i += 4 )
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{
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/* copy this block into a new one */
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int idx = 0;
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int mx = 4, my = 4;
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if( j+4 >= height )
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{
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my = height - j;
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}
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if( i+4 >= width )
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{
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mx = width - i;
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}
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for( y = 0; y < my; ++y )
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{
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for( x = 0; x < mx; ++x )
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{
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ublock[idx++] = uncompressed[(j+y)*width*channels+(i+x)*channels];
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ublock[idx++] = uncompressed[(j+y)*width*channels+(i+x)*channels+chan_step];
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ublock[idx++] = uncompressed[(j+y)*width*channels+(i+x)*channels+chan_step+chan_step];
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}
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for( x = mx; x < 4; ++x )
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{
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ublock[idx++] = ublock[0];
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ublock[idx++] = ublock[1];
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ublock[idx++] = ublock[2];
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}
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}
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for( y = my; y < 4; ++y )
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{
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for( x = 0; x < 4; ++x )
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{
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ublock[idx++] = ublock[0];
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ublock[idx++] = ublock[1];
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ublock[idx++] = ublock[2];
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}
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}
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/* compress the block */
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++block_count;
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compress_DDS_color_block( 3, ublock, cblock );
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/* copy the data from the block into the main block */
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for( x = 0; x < 8; ++x )
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{
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compressed[index++] = cblock[x];
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}
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}
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}
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return compressed;
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}
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unsigned char* convert_image_to_DXT5(
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const unsigned char *const uncompressed,
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int width, int height, int channels,
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int *out_size )
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{
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unsigned char *compressed;
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int i, j, x, y;
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unsigned char ublock[16*4];
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unsigned char cblock[8];
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int index = 0, chan_step = 1;
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int block_count = 0, has_alpha;
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/* error check */
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*out_size = 0;
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if( (width < 1) || (height < 1) ||
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(NULL == uncompressed) ||
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(channels < 1) || ( channels > 4) )
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{
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return NULL;
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}
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/* for channels == 1 or 2, I do not step forward for R,G,B vales */
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if( channels < 3 )
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{
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chan_step = 0;
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}
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/* # channels = 1 or 3 have no alpha, 2 & 4 do have alpha */
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has_alpha = 1 - (channels & 1);
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/* get the RAM for the compressed image
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(16 bytes per 4x4 pixel block) */
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*out_size = ((width+3) >> 2) * ((height+3) >> 2) * 16;
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compressed = (unsigned char*)malloc( *out_size );
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/* go through each block */
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for( j = 0; j < height; j += 4 )
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{
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for( i = 0; i < width; i += 4 )
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{
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/* local variables, and my block counter */
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int idx = 0;
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int mx = 4, my = 4;
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if( j+4 >= height )
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{
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my = height - j;
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}
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if( i+4 >= width )
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{
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mx = width - i;
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}
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for( y = 0; y < my; ++y )
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{
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for( x = 0; x < mx; ++x )
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{
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ublock[idx++] = uncompressed[(j+y)*width*channels+(i+x)*channels];
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ublock[idx++] = uncompressed[(j+y)*width*channels+(i+x)*channels+chan_step];
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ublock[idx++] = uncompressed[(j+y)*width*channels+(i+x)*channels+chan_step+chan_step];
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ublock[idx++] =
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has_alpha * uncompressed[(j+y)*width*channels+(i+x)*channels+channels-1]
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+ (1-has_alpha)*255;
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}
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for( x = mx; x < 4; ++x )
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{
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ublock[idx++] = ublock[0];
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ublock[idx++] = ublock[1];
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ublock[idx++] = ublock[2];
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ublock[idx++] = ublock[3];
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}
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}
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for( y = my; y < 4; ++y )
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{
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for( x = 0; x < 4; ++x )
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{
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ublock[idx++] = ublock[0];
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ublock[idx++] = ublock[1];
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ublock[idx++] = ublock[2];
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ublock[idx++] = ublock[3];
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}
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}
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/* now compress the alpha block */
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compress_DDS_alpha_block( ublock, cblock );
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/* copy the data from the compressed alpha block into the main buffer */
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for( x = 0; x < 8; ++x )
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{
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compressed[index++] = cblock[x];
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}
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/* then compress the color block */
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++block_count;
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compress_DDS_color_block( 4, ublock, cblock );
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/* copy the data from the compressed color block into the main buffer */
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for( x = 0; x < 8; ++x )
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{
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compressed[index++] = cblock[x];
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}
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}
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}
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return compressed;
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}
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/********* Helper Functions *********/
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int convert_bit_range( int c, int from_bits, int to_bits )
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{
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int b = (1 << (from_bits - 1)) + c * ((1 << to_bits) - 1);
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return (b + (b >> from_bits)) >> from_bits;
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}
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int rgb_to_565( int r, int g, int b )
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{
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return
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(convert_bit_range( r, 8, 5 ) << 11) |
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(convert_bit_range( g, 8, 6 ) << 05) |
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(convert_bit_range( b, 8, 5 ) << 00);
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}
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void rgb_888_from_565( unsigned int c, int *r, int *g, int *b )
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{
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*r = convert_bit_range( (c >> 11) & 31, 5, 8 );
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*g = convert_bit_range( (c >> 05) & 63, 6, 8 );
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*b = convert_bit_range( (c >> 00) & 31, 5, 8 );
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}
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void compute_color_line_STDEV(
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const unsigned char *const uncompressed,
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int channels,
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float point[3], float direction[3] )
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{
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const float inv_16 = 1.0f / 16.0f;
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int i;
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float sum_r = 0.0f, sum_g = 0.0f, sum_b = 0.0f;
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float sum_rr = 0.0f, sum_gg = 0.0f, sum_bb = 0.0f;
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float sum_rg = 0.0f, sum_rb = 0.0f, sum_gb = 0.0f;
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/* calculate all data needed for the covariance matrix
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( to compare with _rygdxt code) */
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for( i = 0; i < 16*channels; i += channels )
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{
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sum_r += uncompressed[i+0];
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sum_rr += uncompressed[i+0] * uncompressed[i+0];
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sum_g += uncompressed[i+1];
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sum_gg += uncompressed[i+1] * uncompressed[i+1];
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sum_b += uncompressed[i+2];
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sum_bb += uncompressed[i+2] * uncompressed[i+2];
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sum_rg += uncompressed[i+0] * uncompressed[i+1];
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sum_rb += uncompressed[i+0] * uncompressed[i+2];
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sum_gb += uncompressed[i+1] * uncompressed[i+2];
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}
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/* convert the sums to averages */
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sum_r *= inv_16;
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sum_g *= inv_16;
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sum_b *= inv_16;
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/* and convert the squares to the squares of the value - avg_value */
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sum_rr -= 16.0f * sum_r * sum_r;
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sum_gg -= 16.0f * sum_g * sum_g;
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sum_bb -= 16.0f * sum_b * sum_b;
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sum_rg -= 16.0f * sum_r * sum_g;
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sum_rb -= 16.0f * sum_r * sum_b;
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sum_gb -= 16.0f * sum_g * sum_b;
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/* the point on the color line is the average */
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point[0] = sum_r;
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point[1] = sum_g;
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point[2] = sum_b;
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#if USE_COV_MAT
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/*
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The following idea was from ryg.
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(https://mollyrocket.com/forums/viewtopic.php?t=392)
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The method worked great (less RMSE than mine) most of
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the time, but had some issues handling some simple
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boundary cases, like full green next to full red,
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which would generate a covariance matrix like this:
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| 1 -1 0 |
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| -1 1 0 |
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| 0 0 0 |
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For a given starting vector, the power method can
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generate all zeros! So no starting with {1,1,1}
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as I was doing! This kind of error is still a
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slight posibillity, but will be very rare.
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*/
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/* use the covariance matrix directly
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(1st iteration, don't use all 1.0 values!) */
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sum_r = 1.0f;
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sum_g = 2.718281828f;
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sum_b = 3.141592654f;
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direction[0] = sum_r*sum_rr + sum_g*sum_rg + sum_b*sum_rb;
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direction[1] = sum_r*sum_rg + sum_g*sum_gg + sum_b*sum_gb;
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direction[2] = sum_r*sum_rb + sum_g*sum_gb + sum_b*sum_bb;
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/* 2nd iteration, use results from the 1st guy */
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sum_r = direction[0];
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sum_g = direction[1];
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sum_b = direction[2];
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direction[0] = sum_r*sum_rr + sum_g*sum_rg + sum_b*sum_rb;
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direction[1] = sum_r*sum_rg + sum_g*sum_gg + sum_b*sum_gb;
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direction[2] = sum_r*sum_rb + sum_g*sum_gb + sum_b*sum_bb;
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/* 3rd iteration, use results from the 2nd guy */
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sum_r = direction[0];
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sum_g = direction[1];
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sum_b = direction[2];
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direction[0] = sum_r*sum_rr + sum_g*sum_rg + sum_b*sum_rb;
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direction[1] = sum_r*sum_rg + sum_g*sum_gg + sum_b*sum_gb;
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direction[2] = sum_r*sum_rb + sum_g*sum_gb + sum_b*sum_bb;
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#else
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/* use my standard deviation method
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(very robust, a tiny bit slower and less accurate) */
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direction[0] = sqrt( sum_rr );
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direction[1] = sqrt( sum_gg );
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direction[2] = sqrt( sum_bb );
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/* which has a greater component */
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if( sum_gg > sum_rr )
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{
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/* green has greater component, so base the other signs off of green */
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if( sum_rg < 0.0f )
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{
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direction[0] = -direction[0];
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}
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if( sum_gb < 0.0f )
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{
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direction[2] = -direction[2];
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}
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} else
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{
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/* red has a greater component */
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if( sum_rg < 0.0f )
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{
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direction[1] = -direction[1];
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}
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if( sum_rb < 0.0f )
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{
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direction[2] = -direction[2];
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}
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}
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#endif
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}
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void LSE_master_colors_max_min(
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int *cmax, int *cmin,
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int channels,
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const unsigned char *const uncompressed )
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{
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int i, j;
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/* the master colors */
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int c0[3], c1[3];
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/* used for fitting the line */
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float sum_x[] = { 0.0f, 0.0f, 0.0f };
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float sum_x2[] = { 0.0f, 0.0f, 0.0f };
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float dot_max = 1.0f, dot_min = -1.0f;
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float vec_len2 = 0.0f;
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float dot;
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/* error check */
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if( (channels < 3) || (channels > 4) )
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{
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return;
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}
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compute_color_line_STDEV( uncompressed, channels, sum_x, sum_x2 );
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vec_len2 = 1.0f / ( 0.00001f +
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sum_x2[0]*sum_x2[0] + sum_x2[1]*sum_x2[1] + sum_x2[2]*sum_x2[2] );
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/* finding the max and min vector values */
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dot_max =
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(
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sum_x2[0] * uncompressed[0] +
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sum_x2[1] * uncompressed[1] +
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sum_x2[2] * uncompressed[2]
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);
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dot_min = dot_max;
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for( i = 1; i < 16; ++i )
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{
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dot =
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(
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sum_x2[0] * uncompressed[i*channels+0] +
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sum_x2[1] * uncompressed[i*channels+1] +
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sum_x2[2] * uncompressed[i*channels+2]
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);
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if( dot < dot_min )
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{
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dot_min = dot;
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} else if( dot > dot_max )
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{
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dot_max = dot;
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}
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}
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/* and the offset (from the average location) */
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dot = sum_x2[0]*sum_x[0] + sum_x2[1]*sum_x[1] + sum_x2[2]*sum_x[2];
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dot_min -= dot;
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dot_max -= dot;
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/* post multiply by the scaling factor */
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dot_min *= vec_len2;
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dot_max *= vec_len2;
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/* OK, build the master colors */
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for( i = 0; i < 3; ++i )
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{
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/* color 0 */
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c0[i] = (int)(0.5f + sum_x[i] + dot_max * sum_x2[i]);
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if( c0[i] < 0 )
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{
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c0[i] = 0;
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} else if( c0[i] > 255 )
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{
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c0[i] = 255;
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|
}
|
|
/* color 1 */
|
|
c1[i] = (int)(0.5f + sum_x[i] + dot_min * sum_x2[i]);
|
|
if( c1[i] < 0 )
|
|
{
|
|
c1[i] = 0;
|
|
} else if( c1[i] > 255 )
|
|
{
|
|
c1[i] = 255;
|
|
}
|
|
}
|
|
/* down_sample (with rounding?) */
|
|
i = rgb_to_565( c0[0], c0[1], c0[2] );
|
|
j = rgb_to_565( c1[0], c1[1], c1[2] );
|
|
if( i > j )
|
|
{
|
|
*cmax = i;
|
|
*cmin = j;
|
|
} else
|
|
{
|
|
*cmax = j;
|
|
*cmin = i;
|
|
}
|
|
}
|
|
|
|
void
|
|
compress_DDS_color_block
|
|
(
|
|
int channels,
|
|
const unsigned char *const uncompressed,
|
|
unsigned char compressed[8]
|
|
)
|
|
{
|
|
/* variables */
|
|
int i;
|
|
int next_bit;
|
|
int enc_c0, enc_c1;
|
|
int c0[4], c1[4];
|
|
float color_line[] = { 0.0f, 0.0f, 0.0f, 0.0f };
|
|
float vec_len2 = 0.0f, dot_offset = 0.0f;
|
|
/* stupid order */
|
|
int swizzle4[] = { 0, 2, 3, 1 };
|
|
/* get the master colors */
|
|
LSE_master_colors_max_min( &enc_c0, &enc_c1, channels, uncompressed );
|
|
/* store the 565 color 0 and color 1 */
|
|
compressed[0] = (enc_c0 >> 0) & 255;
|
|
compressed[1] = (enc_c0 >> 8) & 255;
|
|
compressed[2] = (enc_c1 >> 0) & 255;
|
|
compressed[3] = (enc_c1 >> 8) & 255;
|
|
/* zero out the compressed data */
|
|
compressed[4] = 0;
|
|
compressed[5] = 0;
|
|
compressed[6] = 0;
|
|
compressed[7] = 0;
|
|
/* reconstitute the master color vectors */
|
|
rgb_888_from_565( enc_c0, &c0[0], &c0[1], &c0[2] );
|
|
rgb_888_from_565( enc_c1, &c1[0], &c1[1], &c1[2] );
|
|
/* the new vector */
|
|
vec_len2 = 0.0f;
|
|
for( i = 0; i < 3; ++i )
|
|
{
|
|
color_line[i] = (float)(c1[i] - c0[i]);
|
|
vec_len2 += color_line[i] * color_line[i];
|
|
}
|
|
if( vec_len2 > 0.0f )
|
|
{
|
|
vec_len2 = 1.0f / vec_len2;
|
|
}
|
|
/* pre-proform the scaling */
|
|
color_line[0] *= vec_len2;
|
|
color_line[1] *= vec_len2;
|
|
color_line[2] *= vec_len2;
|
|
/* compute the offset (constant) portion of the dot product */
|
|
dot_offset = color_line[0]*c0[0] + color_line[1]*c0[1] + color_line[2]*c0[2];
|
|
/* store the rest of the bits */
|
|
next_bit = 8*4;
|
|
for( i = 0; i < 16; ++i )
|
|
{
|
|
/* find the dot product of this color, to place it on the line
|
|
(should be [-1,1]) */
|
|
int next_value = 0;
|
|
float dot_product =
|
|
color_line[0] * uncompressed[i*channels+0] +
|
|
color_line[1] * uncompressed[i*channels+1] +
|
|
color_line[2] * uncompressed[i*channels+2] -
|
|
dot_offset;
|
|
/* map to [0,3] */
|
|
next_value = (int)( dot_product * 3.0f + 0.5f );
|
|
if( next_value > 3 )
|
|
{
|
|
next_value = 3;
|
|
} else if( next_value < 0 )
|
|
{
|
|
next_value = 0;
|
|
}
|
|
/* OK, store this value */
|
|
compressed[next_bit >> 3] |= swizzle4[ next_value ] << (next_bit & 7);
|
|
next_bit += 2;
|
|
}
|
|
/* done compressing to DXT1 */
|
|
}
|
|
|
|
void
|
|
compress_DDS_alpha_block
|
|
(
|
|
const unsigned char *const uncompressed,
|
|
unsigned char compressed[8]
|
|
)
|
|
{
|
|
/* variables */
|
|
int i;
|
|
int next_bit;
|
|
int a0, a1;
|
|
float scale_me;
|
|
/* stupid order */
|
|
int swizzle8[] = { 1, 7, 6, 5, 4, 3, 2, 0 };
|
|
/* get the alpha limits (a0 > a1) */
|
|
a0 = a1 = uncompressed[3];
|
|
for( i = 4+3; i < 16*4; i += 4 )
|
|
{
|
|
if( uncompressed[i] > a0 )
|
|
{
|
|
a0 = uncompressed[i];
|
|
} else if( uncompressed[i] < a1 )
|
|
{
|
|
a1 = uncompressed[i];
|
|
}
|
|
}
|
|
/* store those limits, and zero the rest of the compressed dataset */
|
|
compressed[0] = a0;
|
|
compressed[1] = a1;
|
|
/* zero out the compressed data */
|
|
compressed[2] = 0;
|
|
compressed[3] = 0;
|
|
compressed[4] = 0;
|
|
compressed[5] = 0;
|
|
compressed[6] = 0;
|
|
compressed[7] = 0;
|
|
/* store the all of the alpha values */
|
|
next_bit = 8*2;
|
|
scale_me = 7.9999f / (a0 - a1);
|
|
for( i = 3; i < 16*4; i += 4 )
|
|
{
|
|
/* convert this alpha value to a 3 bit number */
|
|
int svalue;
|
|
int value = (int)((uncompressed[i] - a1) * scale_me);
|
|
svalue = swizzle8[ value&7 ];
|
|
/* OK, store this value, start with the 1st byte */
|
|
compressed[next_bit >> 3] |= svalue << (next_bit & 7);
|
|
if( (next_bit & 7) > 5 )
|
|
{
|
|
/* spans 2 bytes, fill in the start of the 2nd byte */
|
|
compressed[1 + (next_bit >> 3)] |= svalue >> (8 - (next_bit & 7) );
|
|
}
|
|
next_bit += 3;
|
|
}
|
|
/* done compressing to DXT1 */
|
|
}
|