Death Star: Difference between revisions
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Revision as of 06:38, 29 June 2011
You are encouraged to solve this task according to the task description, using any language you may know.
Death Star is a task to display a region that consists of a large sphere with part of a smaller sphere removed from it as a result of geometric subtraction. (This will basically produce a shape like a "death star".)
Brlcad
<lang brlcad># We need a database to hold the objects opendb deathstar.g y
- We will be measuring in kilometers
units km
- Create a sphere of radius 60km centred at the origin
in sph1.s sph 0 0 0 60
- We will be subtracting an overlapping sphere with a radius of 40km
- The resultant hole will be smaller than this, because we only
- only catch the edge
in sph2.s sph 0 90 0 40
- Create a region named deathstar.r which consists of big minus small sphere
r deathstar.r u sph1.s - sph2.s
- We will use a plastic material texture with rgb colour 224,224,224
- with specular lighting value of 0.1 and no inheritance
mater deathstar.r "plastic sp=0.1" 224 224 224 0
- Clear the wireframe display and draw the deathstar
B deathstar.r
- We now trigger the raytracer to see our finished product
rt</lang>
C
<lang C>
- include <stdio.h>
- include <stdlib.h>
- include <math.h>
char shades[] = ".:!*oe&#%@";
double light[3] = { -50, 30, 50 }; void normalize(double * v) {
double len = sqrt(v[0]*v[0] + v[1]*v[1] + v[2]*v[2]); v[0] /= len; v[1] /= len; v[2] /= len;
}
double dot(double *x, double *y) {
double d = x[0]*y[0] + x[1]*y[1] + x[2]*y[2]; return d < 0 ? -d : 0;
}
typedef struct { double cx, cy, cz, r; } sphere_t; sphere_t big = { 20, 20, 0, 20 }, small = { 7, 7, -10, 15 };
int hit_sphere(sphere_t *sph, double x, double y, double *z1, double *z2) { double zsq; x -= sph->cx; y -= sph->cy; zsq = sph->r * sph->r - (x * x + y * y); if (zsq < 0) return 0; zsq = sqrt(zsq); *z1 = sph->cz - zsq; *z2 = sph->cz + zsq; return 1; }
void draw_sphere(double k, double ambient) {
int i, j, intensity; double b; double vec[3], x, y, zb1, zb2, zs1, zs2; for (i = floor(big.cy - big.r); i <= ceil(big.cy + big.r); i++) { y = i + .5; for (j = floor(big.cx - 2 * big.r); j <= ceil(big.cx + 2 * big.r); j++) { x = (j - big.cx) / 2. + .5 + big.cx;
if (!hit_sphere(&big, x, y, &zb1, &zb2)) { putchar(' '); continue; } if (!hit_sphere(&small, x, y, &zs1, &zs2)) { vec[0] = x - big.cx; vec[1] = y - big.cy; vec[2] = zb1 - big.cz; } else { if (zs1 < zb1) { if (zs2 > zb2) { putchar(' '); continue; } if (zs2 > zb1) { vec[0] = small.cx - x; vec[1] = small.cy - y; vec[2] = small.cz - zs2; } else { vec[0] = x - big.cx; vec[1] = y - big.cy; vec[2] = zb1 - big.cz; } } else { vec[0] = x - big.cx; vec[1] = y - big.cy; vec[2] = zb1 - big.cz; } }
normalize(vec); b = pow(dot(light, vec), k) + ambient; intensity = (1 - b) * (sizeof(shades) - 1); if (intensity < 0) intensity = 0; if (intensity >= sizeof(shades) - 1) intensity = sizeof(shades) - 2; putchar(shades[intensity]); } putchar('\n'); }
}
int main() {
normalize(light); draw_sphere(2, .3); return 0;
}</lang>Output:<lang> #######ooo*******
&&&&&###########!!!!!!!!:::!!! &&&&&&&&&###########!:::::::......::: eee&&&&&&&&&&###########:::...............: oooeeeee&&&&&&&&&##########:....................: **ooooeeeee&&&&&&&&&########......................... !!***ooooeeeee&&&&&&&&########........................... :!!!!***ooooeeeee&&&&&&&&######.............................. .::::!!!***ooooeeee&&&&&&&&######............................... ...:::!!!!***ooooeeee&&&&&&&&####.................................. ......:::!!!****oooeeee&&&&&&&&##:::.................................. ........:::!!!***ooooeeee&&&&&&&#::::................................... .........:::!!!****oooeeee&&&&&&&!::::.................................... ...........:::!!!***oooeeee&&&&&!!!:::::................................... ............:::!!!***oooeeee&&&**!!!!::::.................................... ............:::!!!***oooeeee&&***!!!!!::::...................................
............:::!!!***ooooeeeooo****!!!!:::::................................... ............:::!!!***oooeeooooo*****!!!!:::::.................................. ...........:::!!!***oooeeeeooooo*****!!!!:::::.................................
- ........:::!!!!***o&&eeeeeeooooo*****!!!!:::::................................
- !!!!***&&&&&&eeeeeeooooo*****!!!!!:::::.............................:
- &&&&&&&&&&&&eeeeeeooooo*****!!!!!::::::...........................:
- &&&&&&&&&&&&eeeeeeoooooo*****!!!!!::::::........................:!
- &&&&&&&&&&&&eeeeeeoooooo*****!!!!!!::::::.....................::!
- &&&&&&&&&&&&eeeeeeoooooo*****!!!!!::::::........................:!
##############&&&&&&&&&&&&eeeeeeeoooooo*****!!!!!!:::::::................:::! ###############&&&&&&&&&&&&&eeeeeeoooooo******!!!!!!!::::::::::.....::::::!!* ###############&&&&&&&&&&&&&eeeeeeeoooooo*******!!!!!!!::::::::::::::::!!!* ################&&&&&&&&&&&&&&eeeeeeeooooooo*******!!!!!!!!!!!!!!!!!!!!!**o #################&&&&&&&&&&&&&eeeeeeeeooooooo*********!!!!!!!!!!!!!!****o #################&&&&&&&&&&&&&&eeeeeeeeoooooooo**********************oe ##################&&&&&&&&&&&&&&&eeeeeeeeoooooooooo*************ooooe #################&&&&&&&&&&&&&&&&eeeeeeeeeeoooooooooooooooooooooe ##################&&&&&&&&&&&&&&&&&eeeeeeeeeeeeooooooooooooeeee ##################&&&&&&&&&&&&&&&&&&eeeeeeeeeeeeeeeeeeeeee& ###################&&&&&&&&&&&&&&&&&&&&&eeeeeeeeeeee&&& ####################&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&& ####################&&&&&&&&&&&&&&&&&&&&&&&&& #####################&&&&&&&&&&&&&&&&&& ############################### #################
</lang>
Openscad
<lang openscad>// We are performing geometric subtraction
difference() {
// Create the primary sphere of radius 60 centred at the origin
translate(v = [0,0,0]) { sphere(60); }
/*Subtract an overlapping sphere with a radius of 40 The resultant hole will be smaller than this, because we only only catch the edge */
translate(v = [0,90,0]) { sphere(40); }
}</lang>
POV-Ray
<lang POV-Ray>camera { perspective location <0.0 , .8 ,-3.0> look_at 0
aperture .1 blur_samples 20 variance 1/100000 focal_point 0}
light_source{< 3,3,-3> color rgb 1}
sky_sphere { pigment{ color rgb <0,.2,.5>}}
plane {y,-5 pigment {color rgb .54} normal {hexagon} }
difference {
sphere { 0,1 } sphere { <-1,1,-1>,1 } texture { pigment{ granite } finish { phong 1 reflection {0.10 metallic 0.5} } }