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https://github.com/sehugg/8bitworkshop.git
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477 lines
13 KiB
C
477 lines
13 KiB
C
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/*
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---------------------------------------------------------------
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TMSOPT v.0.1 - Eduardo A. Robsy Petrus & Arturo Ragozini 2007
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Credits to Rafael Jannone for his Floyd-Steinberg implementation
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---------------------------------------------------------------
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TGA image converter (24 bpp, uncompressed) to TMS9918 format
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---------------------------------------------------------------
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Overview
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---------------------------------------------------------------
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Selects the best solution for each 8x1 pixel block
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Optimization uses the following algorithm:
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(a) Select one 1x8 block, select a couple of colors, apply
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Floyd-Steinberg within the block, compute the squared error,
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repeat for all 105 color combinations, keep the best couple
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of colors.
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(b) Apply Floyd-Steinberg to the current 1x8 block with the best
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two colors seleted before and spread the errors to the
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adjacent blocks.
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(c) repeat (a) and (b) on the next 1x8 block, scan all lines.
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(d) Convert the image in pattern and color definitions (CHR & CLR)
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To load in MSX basic use something like this:
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10 screen 2: color 15,0,0
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20 bload"FILE.CHR",s
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30 bload"FILE.CLR",s
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40 goto 40
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---------------------------------------------------------------
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Compilation instructions
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---------------------------------------------------------------
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Tested with GCC/Win32 [mingw]:
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GCC TMSopt.c -oTMSopt.exe -O3 -s
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It is standard C, so there is a fair chance of being portable!
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NOTE
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In the current release the name of the C file has become scr2floyd.c
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---------------------------------------------------------------
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History
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---------------------------------------------------------------
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Ages ago - algorithm created
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16/05/2007 - first C version (RAW format)
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17/05/2007 - TGA format included, some optimization included
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18/05/2007 - Big optimization (200 times faster), support for
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square errors
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19/05/2007 - Floyd-Stenberg added, scaling for better rounding
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24/05/2007 - Floyd-Stenberg included in the color optimization.
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---------------------------------------------------------------
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Legal disclaimer
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---------------------------------------------------------------
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Do whatever you want to do with this code/program.
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Use at your own risk, all responsability would be declined.
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It would be nice if you credit the authors, though.
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---------------------------------------------------------------
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*/
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// Headers!
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#include<stdio.h>
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#include<time.h>
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#include<limits.h>
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#include<stdlib.h>
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typedef unsigned int uint;
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typedef unsigned char uchar;
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typedef unsigned short ushort;
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typedef unsigned long ulong;
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//#define DEBUG
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#define scale 16
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#define inrange8(t) ((t)<0) ? 0 :(((t)>255) ? 255:(t))
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#define clamp(t) ((t)<0) ? 0 :(((t)>255*scale) ? 255*scale : (t))
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typedef struct {
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float r, g, b;
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} RGB;
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float ColourDistance(RGB e1, RGB e2)
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{
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float r,g,b;
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float rmean;
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e1.r/=scale;
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e1.g/=scale;
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e1.b/=scale;
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e2.r/=scale;
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e2.g/=scale;
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e2.b/=scale;
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rmean = ( (int)e1.r + (int)e2.r ) / 2 ;
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r = ((int)e1.r - (int)e2.r);
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g = ((int)e1.g - (int)e2.g);
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b = ((int)e1.b - (int)e2.b);
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// return r*r+g*g+b*b;
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return ((((512+rmean)*r*r)/256) + 4*g*g + (((767-rmean)*b*b)/256));
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}
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// Just one function for everything
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int main(int argc, char **argv)
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{
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// Vars
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FILE *file,*CHR,*CLR;
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int bc,bp,i,j,x,y,c,p,k,MAXX,MAXY;
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uint n,total=0,done=0,size;
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char *name;
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short image[512+2][512+2][3],header[18],palette[16][3];
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// TMS9918 RGB palette - approximated 50Hz PAL values
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uint pal[16][3]= {
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{ 0,0,0}, // 0 Transparent
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{ 0,0,0}, // 1 Black 0 0 0
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{ 33,200,66}, // 2 Medium green 33 200 66
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{ 94,220,120}, // 3 Light green 94 220 120
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{ 84,85,237}, // 4 Dark blue 84 85 237
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{ 125,118,252}, // 5 Light blue 125 118 252
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{ 212,82,77}, // 6 Dark red 212 82 77
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{ 66,235,245}, // 7 Cyan 66 235 245
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{ 252,85,84}, // 8 Medium red 252 85 84
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{ 255,121,120}, // 9 Light red 255 121 120
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{ 212,193,84}, // A Dark yellow 212 193 84
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{ 230,206,128}, // B Light yellow 230 206 128
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{ 33,176,59}, // C Dark green 33 176 59
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{ 201,91,186}, // D Magenta 201 91 186
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{ 204,204,204}, // E Gray 204 204 204
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{ 255,255,255} // F White 255 255 255
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};
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// Scale palette
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for (i=0;i<16;i++)
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for (k=0;k<3;k++)
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palette[i][k] = scale*pal[i][k];
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// Get time
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clock();
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// Application prompt
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printf("TMSopt v.0.1 - TGA 24bpp to TMS9918 converter.\nCoded by Eduardo A. Robsy Petrus & Arturo Ragozini 2007.\n\n");
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printf("Credits to Rafael Jannone for his Floyd-Steinberg implementation.\n \n");
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// Guess the name of the image I used for testing
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#ifdef DEBUG
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argc = 2;
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argv[1] = malloc(20);
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argv[1][0] = 'l';
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argv[1][1] = 'e';
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argv[1][2] = 'n';
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argv[1][3] = 'n';
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argv[1][4] = 'a';
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argv[1][5] = '_';
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argv[1][6] = '.';
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argv[1][7] = 't';
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argv[1][8] = 'g';
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argv[1][9] = 'a';
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argv[1][10] = 0;
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#endif
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// Test if only one command-line parameter is available
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if (argc==1)
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{
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printf("Syntax: TMSopt [file.tga]\n");
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return 1;
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}
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// Open source image (TGA, 24-bit, uncompressed)
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if ((file=fopen(argv[1],"rb"))==NULL)
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{
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printf("cannot open %s file!\n",argv[1]);
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return 2;
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}
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// Read TGA header
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for (i=0;i<18;i++) header[i]=fgetc(file);
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// Check header info
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for (i=0,n=0;i<12;i++) n+=header[i];
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// I deleted the check on n, was it important ?
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if ((header[2]!=2)||(header[17])||(header[16]!=24))
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{
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printf("Unsupported file format!\n");
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return 3;
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}
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// Calculate size
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MAXX=header[12]|header[13]<<8;
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MAXY=header[14]|header[15]<<8;
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size=((MAXX+7)>>3)*MAXY;
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// Check size limits
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if ((!MAXX)||(MAXX>512)||(!MAXY)||(MAXY>512))
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{
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printf("Unsupported size!");
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return 4;
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}
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// Load image data
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for (y=MAXY-1;y>=0;y--)
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for (x=0;x<MAXX;x++)
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for (k=0;k<3;k++)
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image[x+1][y+1][2-k]=((short)fgetc(file))*scale; // Scale image
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for (x=0;x<MAXX;x++)
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for (k=0;k<3;k++)
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image[x][0][k] = image[x][1][k];
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for (y=0;y<MAXY;y++)
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for (k=0;k<3;k++)
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image[0][y][k] = image[1][0][k];
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// Close file
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fclose(file);
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// Information
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printf("Converting %s (%i,%i) to TMS9918 format ",argv[1],MAXX,MAXY);
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printf("in (%i,%i) screen 2 tiles... ",((MAXX+7)>>3),((MAXY+7)>>3));
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// Image processing
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for (y=0;y<((MAXY+7)>>3);y++)
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for (j=0;j<8;j++)
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for (x=0;x<((MAXX+7)>>3);x++)
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{
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// Generate alternatives
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uchar c1, c2;
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uchar bc1, bc2;
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uint bv;
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uint bs = INT_MAX;
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uint yy = 1+((y<<3)|j);
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for (c1=1;c1<16;c1++)
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{
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RGB cp1 = {palette[c1][0],palette[c1][1],palette[c1][2]};
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for (c2=c1+1;c2<16;c2++)
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{
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RGB cp2 = {palette[c2][0],palette[c2][1],palette[c2][2]};
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uint xx = 1+(x<<3);
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RGB ppp = {clamp(image[xx][yy][0]),clamp(image[xx][yy][1]),clamp(image[xx][yy][2])};
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uint cs = 0;
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uint cv = 0;
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for (i=0;i<8;i++)
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{
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short e10 = (ppp.r-cp1.r);
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short e11 = (ppp.g-cp1.g);
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short e12 = (ppp.b-cp1.b);
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long mc1 = ColourDistance(cp1,ppp);
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short e20 = (ppp.r-cp2.r);
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short e21 = (ppp.g-cp2.g);
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short e22 = (ppp.b-cp2.b);
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long mc2 = ColourDistance(cp2,ppp);
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cs += (mc1>mc2) ? mc2 : mc1;
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if (cs>bs) break;
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cv |= ((mc1>mc2)<<i);
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xx++;
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if (mc1>mc2)
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{
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ppp.r = clamp(image[xx][yy][0]) + 7*e20/16;
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ppp.g = clamp(image[xx][yy][1]) + 7*e21/16;
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ppp.b = clamp(image[xx][yy][2]) + 7*e22/16;
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}
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else
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{
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ppp.r = clamp(image[xx][yy][0]) + 7*e10/16;
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ppp.g = clamp(image[xx][yy][1]) + 7*e11/16;
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ppp.b = clamp(image[xx][yy][2]) + 7*e12/16;
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}
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}
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if (cs<bs)
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{
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bs = cs;
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bv = cv;
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bc1 = c1;
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bc2 = c2;
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}
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}
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}
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// Here we have the best colors and the best pattern for line j
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short quant_error;
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uint xx = 1+((x<<3));
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for (i=0;i<8;i++,xx++)
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for (k=0;k<3;k++)
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{
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// Compute the quantization error
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if (bv&(1<<i))
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{
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quant_error = (clamp(image[xx][yy][k]) - palette[bc2][k])/16;
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image[xx][yy][k] = palette[bc2][k];
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}
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else
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{
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quant_error = (clamp(image[xx][yy][k]) - palette[bc1][k])/16;
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image[xx][yy][k] = palette[bc1][k];
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}
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// Spread the quantization error
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short q2 = quant_error<<1;
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image[xx+1][yy+1][k] = clamp(image[xx+1][yy+1][k])+ quant_error; // 1 *
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quant_error += q2 ;
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image[xx-1][yy+1][k] = clamp(image[xx-1][yy+1][k])+ quant_error; // 3 *
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quant_error += q2 ;
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image[xx+0][yy+1][k] = clamp(image[xx+0][yy+1][k])+ quant_error; // 5 *
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quant_error += q2 ;
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image[xx+1][yy+0][k] = clamp(image[xx+1][yy+0][k])+ quant_error; // 7 *
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}
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// Update status counter
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if (done*100/size<(done+1)*100/size)
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printf("\b\b\b%2i%%",100*done/size);
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done++;
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total++;
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}
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// Conversion done
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printf("\b\b\bOk \n");
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// Create TMS output files (CHR, CLR)
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argv[1][strlen(argv[1])-3]='C';
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argv[1][strlen(argv[1])-2]='H';
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argv[1][strlen(argv[1])-1]='R';
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CHR=fopen(argv[1],"wb");
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argv[1][strlen(argv[1])-2]='L';
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CLR=fopen(argv[1],"wb");
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fputc(0xFE,CLR); // Binary data
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fputc(0x00,CLR); // Start at 2000h
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fputc(0x20,CLR);
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fputc(0xFF,CLR); // Stop at 37FFh
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fputc(0x37,CLR);
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fputc(0x00,CLR); // Run
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fputc(0x00,CLR);
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fputc(0xFE,CHR); // Binary data
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fputc(0x00,CHR); // Start at 0000h
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fputc(0x00,CHR);
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fputc(0xFF,CHR); // Stop at 17FFh
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fputc(0x17,CHR);
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fputc(0x00,CHR); // Run
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fputc(0x00,CHR);
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// Save best pattern and colour combination
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// NOTE1:
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// THIS PART CAN BE LARGELY CUTTED AND OPTIMIZED REUSING
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// RESULTS FROM THE PREVIOUS LOOP, BUT WHO CARES?
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// NOTE2:
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// This code can be used for conversion without dithering
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for (y=0;y<((MAXY+7)>>3);y++)
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for (x=0;(x<(MAXX+7)>>3);x++)
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for (j=0;j<8;j++)
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{
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uchar c1,c2;
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uint bs = INT_MAX;
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uchar bp = 0, bc = 0;
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uint yy = 1+((y<<3)|j);
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for (c1=1;c1<16;c1++)
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{
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RGB cp1 = {palette[c1][0],palette[c1][1],palette[c1][2]};
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for (c2=c1+1;c2<16;c2++)
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{
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RGB cp2 = {palette[c2][0],palette[c2][1],palette[c2][2]};
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uint cs = 0;
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uint cp = 0;
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for (i=0;i<8;i++)
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{
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uint xx = 1+((x<<3)|i);
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RGB ppp = {clamp(image[xx][yy][0]),clamp(image[xx][yy][1]),clamp(image[xx][yy][2])};
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long mc1 = ColourDistance(cp1,ppp);
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long mc2 = ColourDistance(cp2,ppp);
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cp = (cp<<1) | (mc1>mc2);
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cs += (mc1>mc2) ? mc2 : mc1;
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if (cs>bs) break;
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}
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if (cs<bs)
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{
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bs=cs;
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bp=cp;
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bc=c2*16+c1;
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}
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}
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}
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fputc(bc,CLR);
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fputc(bp,CHR);
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}
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fclose(CHR);
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fclose(CLR);
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// Generate new name
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name = malloc(0x100);
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argv[1][strlen(argv[1])-4]=0;
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strcpy(name,argv[1]);
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strcat(name,"_tms.tga");
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// Save file header
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file=fopen(name,"wb");
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for (i=0;i<18;i++) fputc(header[i],file);
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// Save image data
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for (y=MAXY-1;y>=0;y--)
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for (x=0;x<MAXX;x++)
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for (k=0;k<3;k++)
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fputc(inrange8(image[1+x][1+y][2-k]/scale),file); // Scale to char
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// Close file
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fclose(file);
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// Prompt elapsed time
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printf("%.2f million combinations analysed in %.2f seconds.\n",total/1e6,(float)clock()/(float)CLOCKS_PER_SEC);
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printf("Note: the .CLR and .CHR files have correct headers only for 256x192 images. \n");
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return 0;
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}
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