Munching squares: Difference between revisions
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[[File:PureBasic_XOR_Pattern.png|Sample display of PureBasic solution|200px]] |
[[File:PureBasic_XOR_Pattern.png|Sample display of PureBasic solution|200px]] |
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=={{header|Python}}== |
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{{libheader|PIL}} |
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<lang Python>import Image, ImageDraw |
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image = Image.new("RGB", (256, 256)) |
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drawingTool = ImageDraw.Draw(image) |
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for x in range(256): |
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for y in range(256): |
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drawingTool.point((x, y), (0, x^y, 0)) |
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del drawingTool |
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image.save("xorpic.png", "PNG")</lang> |
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[[File:PythonXORPic.png|Sample produced by the above code|200px]] |
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=={{header|Ruby}}== |
=={{header|Ruby}}== |
Revision as of 03:33, 16 March 2012
Render a graphical pattern where each pixel is colored by the value of 'x xor y' from a color table.
Ada
Uses the Cairo component of GtkAda to create and save as png <lang Ada>with Cairo; use Cairo; with Cairo.Png; use Cairo.Png; with Cairo.Image_Surface; use Cairo.Image_Surface; procedure XorPattern is
type xorable is mod 256; Surface : Cairo_Surface; Data : RGB24_Array_Access; Status : Cairo_Status; Num : Byte;
begin
Data := new RGB24_Array(0..256*256-1); for x in Natural range 0..255 loop for y in Natural range 0..255 loop Num := Byte(xorable(x) xor xorable(y)); Data(x+256*y) := RGB24_Data'(Num,0,Num); end loop; end loop; Surface := Create_For_Data_RGB24(Data, 256, 256); Status := Write_To_Png (Surface, "AdaXorPattern.png"); pragma Assert (Status = Cairo_Status_Success);
C
<lang c>#include <stdlib.h>
- include <stdio.h>
- include <math.h>
- include <string.h>
void hue_to_rgb(double hue, double sat, unsigned char *p) { double x; int c = 255 * sat; hue /= 60; x = (1 - fabs(fmod(hue, 2) - 1)) * 255;
switch((int)hue) { case 0: p[0] = c; p[1] = x; p[2] = 0; return; case 1: p[0] = x; p[1] = c; p[2] = 0; return; case 2: p[0] = 0; p[1] = c; p[2] = x; return; case 3: p[0] = 0; p[1] = x; p[2] = c; return; case 4: p[0] = x; p[1] = 0; p[2] = c; return; case 5: p[0] = c; p[1] = 0; p[2] = x; return; } }
int main(void) { const int size = 512; int i, j; unsigned char *colors = malloc(size * 3); unsigned char *pix = malloc(size * size * 3), *p; FILE *fp;
for (i = 0; i < size; i++) hue_to_rgb(i * 240. / size, i * 1. / size, colors + 3 * i);
for (i = 0, p = pix; i < size; i++) for (j = 0; j < size; j++, p += 3) memcpy(p, colors + (i ^ j) * 3, 3);
fp = fopen("xor.ppm", "wb"); fprintf(fp, "P6\n%d %d\n255\n", size, size); fwrite(pix, size * size * 3, 1, fp); fclose(fp);
C#
<lang csharp>using System.Drawing; using System.Drawing.Imaging; using System.Linq;
class XORPattern {
static void Main() { var size = 0x100; var black = Color.Black.ToArgb(); var palette = Enumerable.Range(black, size).Select(Color.FromArgb).ToArray(); using (var image = new Bitmap(size, size)) { for (var x = 0; x < size; x++) { for (var y = 0; y < size; y++) { image.SetPixel(x, y, palette[x ^ y]); } } image.Save("XORPatternCSharp.png", ImageFormat.Png); } }
}</lang> Output:
D
<lang d>import std.stdio;
void main() {
enum width = 512, height = 512;
auto f = File("xor_pattern.ppm", "wb"); f.writefln("P6\n%d %d\n255", width, height); foreach (y; 0 .. height) foreach (x; 0 .. width) { ubyte c = (x ^ y) & ubyte.max; f.rawWrite(cast(ubyte[3])[255 - c, c / 2, c]); }
}</lang>
Gnuplot
<lang gnuplot>set pm3d map set size square set isosamples 255,255 splot [0:255][0:255]-(floor(x)^floor(y))</lang>
Haskell
<lang haskell>import Data.ByteString import Data.Bits
main = Data.ByteString.writeFile "out.pgm" (pack (fmap (fromIntegral . fromEnum) "P5\n256 256\n256\n" ++ [x `xor` y | x <- [0..255], y <- [0..255]])) </lang>
Go
<lang go>package main
import (
"image" "image/png" "os"
)
func main() {
g := image.NewGray(image.Rect(0, 0, 256, 256)) for i := range g.Pix { g.Pix[i] = uint8(i>>8 ^ i) } f, _ := os.Create("xor.png") png.Encode(f, g) f.Close()
}</lang>
Icon and Unicon
<lang Icon>link printf
procedure main(A) #: XOR graphic
wsize := 512 cmax := 32768 wparms := ["Xmas Xor Graphic","g",sprintf("size=%d,%d",wsize),"bg=black"] &window := open!wparms | stop("Unable to open window") every y := 0 to wsize - 1 do every x := 0 to wsize - 1 do { c := cmax/wsize * iand(wsize-1,ixor(x,y)) Fg(sprintf("%d,%d,%d",c,cmax-c,0)) DrawPoint(x,y) } until Event() == &lpress # wait for left button to quit close(&window)
end</lang>
printf.icn provides formatting
J
<lang J> require 'viewmat'
viewmat ~:"1/&.#: ~ i.256</lang>
Java
This example will repeat the pattern if you expand the window. <lang java>import java.awt.Color; import java.awt.Graphics;
import javax.swing.JFrame; import javax.swing.JPanel;
public class XorPattern extends JFrame{
private JPanel xorPanel;
public XorPattern(){ xorPanel = new JPanel(){ @Override public void paint(Graphics g) { for(int y = 0; y < getHeight();y++){ for(int x = 0; x < getWidth();x++){ g.setColor(new Color(0, (x ^ y) % 256, 0)); g.drawLine(x, y, x, y); } } } }; add(xorPanel); setSize(300, 300); setDefaultCloseOperation(JFrame.EXIT_ON_CLOSE); setVisible(true); }
public static void main(String[] args){ new XorPattern(); }
Liberty BASIC
<lang lb>
nomainwin
w =512 ' allow for title bar and window border WindowWidth =w +2 WindowHeight =w +34
open "XOR Pattern" for graphics_nsb_nf as #w
#w "trapclose quit"
#w "down"
for x =0 to w -1 for y =0 to w -1 b =( x xor y) and 255 print b #w "color "; 255 -b; " "; b /2; " "; b #w "set "; x; " "; w -y -1 scan next y next x
#w "flush"
wait
sub quit j$ close #w end end sub
</lang> Image available at [[1]]
Mathematica
<lang Mathematica>ListDensityPlot[
Table[Table[ FromDigits[BitXor[IntegerDigits[x, 2, 8], IntegerDigits[y, 2, 8]], 2], {x, 0, 255}], {y, 0, 255}]]</lang>
Output #1:
<lang Mathematica>ArrayPlot[Array[BitXor, {511, 511}]]</lang> Output #2:
MATLAB
<lang matlab>size = 256; [x,y] = meshgrid([0:size-1]);
c = bitxor(x,y);
colormap bone(size); image(c); axis equal;</lang>
OCaml
<lang ocaml>open Graphics
let () =
open_graph ""; resize_window 256 256; for y = 0 to pred (size_y()) do for x = 0 to pred (size_x()) do let v = (x lxor y) land 0xFF in set_color (rgb v (255 - v) 0); plot x y done; done; ignore(read_key())</lang>
Run with:
$ ocaml graphics.cma xor_pattern.ml
Output:
Octave
<lang Octave>size = 256; [x,y] = meshgrid([0:size-1]);
c = bitxor(x,y);
colormap(jet(size)); image(c); axis equal;</lang>
Perl
<lang perl>use GD;
my $img = new GD::Image(256, 256, 1);
for my $y(0..255) {
for my $x(0..255) { my $color = $img->colorAllocate( abs(255 - $x - $y), (255-$x) ^ $y , $x ^ (255-$y)); $img->setPixel($x, $y, $color); }
}
PHP
<lang php>header("Content-Type: image/png");
$w = 256; $h = 256;
$im = imagecreate($w, $h)
or die("Cannot Initialize new GD image stream");
$color = array(); for($i=0;$i<256;$i++) {
array_push($color,imagecolorallocate($im,sin(($i)*(2*3.14/256))*128+128,$i/2,$i));
}
for($i=0;$i<$w;$i++) {
for($j=0;$j<$h;$j++) { imagesetpixel($im,$i,$j,$color[$i^$j]); }
}
imagepng($im); imagedestroy($im);</lang>
Prolog
Works with SWI-Prolog and his GUI XPCE. <lang Prolog>xor_pattern :- new(D, window('XOR Pattern')), send(D, size, size(512,512)), new(Img, image(@nil, width := 512, height := 512 , kind := pixmap)),
forall(between(0,511, I), ( forall(between(0,511, J), ( V is I xor J, R is (V * 1024) mod 65536, G is (65536 - V * 1024) mod 65536, ( V mod 2 =:= 0 -> B is (V * 4096) mod 65536 ; B is (65536 - (V * 4096)) mod 65536), send(Img, pixel(I, J, colour(@default, R, G, B))))))),
new(Bmp, bitmap(Img)), send(D, display, Bmp, point(0,0)), send(D, open). </lang>
PureBasic
<lang purebasic>#palletteSize = 128 Procedure.f XorPattern(x, y) ;compute the gradient value from the pixel values
Protected result = x ! y ProcedureReturn Mod(result, #palletteSize) / #palletteSize
EndProcedure
Procedure drawPattern()
StartDrawing(ImageOutput(0)) DrawingMode(#PB_2DDrawing_Gradient) CustomGradient(@XorPattern()) ;specify a gradient pallette from which only specific indexes will be used For i = 1 To #palletteSize GradientColor(1 / i, i * $BACE9B) ; or alternatively use $BEEFDEAD Next Box(0, 0, ImageWidth(0), ImageHeight(0)) StopDrawing()
EndProcedure
If OpenWindow(0, 0, 0, 128, 128, "XOR Pattern", #PB_Window_SystemMenu)
CreateImage(0, WindowWidth(0), WindowHeight(0)) drawPattern() ImageGadget(0, 0, 0, ImageWidth(0), ImageHeight(0), ImageID(0)) Repeat event = WaitWindowEvent(20) Until event = #PB_Event_CloseWindow
Python
<lang Python>import Image, ImageDraw
image = Image.new("RGB", (256, 256)) drawingTool = ImageDraw.Draw(image)
for x in range(256):
for y in range(256): drawingTool.point((x, y), (0, x^y, 0))
del drawingTool image.save("xorpic.png", "PNG")</lang>
Ruby
Uses Raster graphics operations/Ruby
<lang ruby>load 'raster_graphics.rb'
class Pixmap
def self.xor_pattern(width, height, rgb1, rgb2) # create colour table size = 256 colours = Array.new(size) do |i| RGBColour.new( (rgb1.red + (rgb2.red - rgb1.red) * i / size), (rgb1.green + (rgb2.green - rgb1.green) * i / size), (rgb1.blue + (rgb2.blue - rgb1.blue) * i / size), ) end
# create the image pixmap = new(width, height) pixmap.each_pixel do |x, y| pixmap[x,y] = colours[(x^y)%size] end pixmap end
end
img = Pixmap.xor_pattern(384, 384, RGBColour::RED, RGBColour::YELLOW) img.save_as_png('xorpattern.png')</lang>
Tcl
<lang tcl>package require Tk
proc xorImage {img table} {
set data {} set h [image height $img] set w [image width $img] for {set y 0} {$y < $h} {incr y} {
set row {} for {set x 0} {$x < $w} {incr x} { lappend row [lindex $table [expr {($x^$y) % [llength $table]}]] } lappend data $row
} $img put $data
} proc inRange {i f t} {expr {$f + ($t-$f)*$i/255}} proc mkTable {rf rt gf gt bf bt} {
for {set i 0} {$i < 256} {incr i} {
lappend tbl [format "#%02x%02x%02x" \ [inRange $i $rf $rt] [inRange $i $gf $gt] [inRange $i $bf $bt]]
} return $tbl
}
set img [image create photo -width 512 -height 512] xorImage $img [mkTable 0 255 64 192 255 0] pack [label .l -image $img]</lang>