imcat/imcat.c

135 lines
3.4 KiB
C
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2018-04-18 20:14:04 +02:00
#include <stdio.h>
#include <stdlib.h>
#include <assert.h>
#include <math.h>
#define STB_IMAGE_IMPLEMENTATION
#include "stb_image.h"
static int termw=0, termh=0;
#define RESETALL "\x1b[0m"
static void print_image( int w, int h, unsigned char* data )
{
const int linesz = 16384;
char line[ linesz ];
unsigned char* reader = data;
for ( int y=0; y<h; ++y )
{
line[0] = 0;
for ( int x=0; x<w; ++x )
{
strncat( line, "\x1b[48;2;", sizeof(line) - strlen(line) - 1 );
char tripl[80];
unsigned char r = *reader++;
unsigned char g = *reader++;
unsigned char b = *reader++;
unsigned char a = *reader++;
(void) a;
snprintf( tripl, sizeof(tripl), "%d;%d;%dm ", r,g,b );
strncat( line, tripl, sizeof(line) - strlen(line) - 1 );
}
strncat( line, RESETALL, sizeof(line) - strlen(line) - 1 );
puts( line );
}
assert( reader = data + w * h * 4 );
}
static int process_image( const char* nm )
{
int imw=0,imh=0,n=0;
unsigned char *data = stbi_load( nm, &imw, &imh, &n, 4 );
if ( !data )
return -1;
//fprintf( stderr, "%s has dimension %dx%d w %d components.\n", nm, imw, imh, n );
float aspectratio = imw / (float) imh;
float pixels_per_char = imw / (float)termw;
if ( pixels_per_char < 1 ) pixels_per_char = 1;
int kernelsize = (int) floorf( pixels_per_char );
if ( (kernelsize&1) == 0 ) kernelsize--;
if ( !kernelsize ) kernelsize=1;
const int kernelradius = (kernelsize-1)/2;
const int outw = imw < termw ? imw : termw;
const int outh = (int) roundf( outw / aspectratio );
//fprintf( stderr, "pixels per char: %f, kernelsize: %d, out: %dx%d\n", pixels_per_char, kernelsize, outw, outh );
unsigned char out[ outh ][ outw ][ 4 ];
for ( int y=0; y<outh; ++y )
for ( int x=0; x<outw; ++x )
{
const int cx = (int) roundf( pixels_per_char * x );
const int cy = (int) roundf( pixels_per_char * y );
int acc[4] = {0,0,0,0};
int numsamples=0;
int sy = cy-kernelradius;
sy = sy < 0 ? 0 : sy;
int ey = cy+kernelradius;
ey = ey >= imh ? imh-1 : ey;
int sx = cx-kernelradius;
sx = sx < 0 ? 0 : sx;
int ex = cx+kernelradius;
ex = ex >= imw ? imw-1 : ex;
for ( int yy = sy; yy <= ey; ++yy )
for ( int xx = sx; xx <= ex; ++xx )
{
unsigned char* reader = data + ( yy * imw * 4 ) + xx * 4;
acc[ 0 ] += reader[0];
acc[ 1 ] += reader[1];
acc[ 2 ] += reader[2];
acc[ 3 ] += reader[3];
numsamples++;
}
out[ y ][ x ][ 0 ] = acc[ 0 ] / numsamples;
out[ y ][ x ][ 1 ] = acc[ 1 ] / numsamples;
out[ y ][ x ][ 2 ] = acc[ 2 ] / numsamples;
out[ y ][ x ][ 3 ] = acc[ 3 ] / numsamples;
}
stbi_image_free( data );
data = 0;
print_image( outw, outh, (unsigned char*) out );
return 0;
}
int main( int argc, char* argv[] )
{
if ( argc == 1 || !strcmp( argv[1], "--help" ) )
{
fprintf( stderr, "Usage: %s image [image2 .. imageN]\n", argv[0] );
exit( 0 );
}
// Step 1: figure out the width and height of terminal.
FILE* f = popen( "stty size", "r" );
if ( !f )
{
fprintf( stderr, "%s: Failed to determine terminal size using stty.\n", argv[0] );
exit( 1 );
}
const int num = fscanf( f, "%d %d", &termh, &termw );
assert( num == 2 );
pclose( f );
fprintf( stderr, "Your terminal is size %dx%d\n", termw, termh );
for ( int i=1; i<argc; ++i )
{
const char* nm = argv[ i ];
int rv = process_image( nm );
if ( rv < 0 )
fprintf( stderr, "Could not load image %s\n", nm );
}
return 0;
}