Learning_GTK4_tree/demos/gtk-demo/cogs2.glsl

227 lines
5.2 KiB
GLSL

uniform float iTime;
// Originally from: https://www.shadertoy.com/view/3ljyDD
// License CC0: Hexagonal tiling + cog wheels
// Nothing fancy, just hexagonal tiling + cog wheels
#define PI 3.141592654
#define TAU (2.0*PI)
#define MROT(a) mat2(cos(a), sin(a), -sin(a), cos(a))
float hash(in vec2 co) {
return fract(sin(dot(co.xy ,vec2(12.9898,58.233))) * 13758.5453);
}
float pcos(float a) {
return 0.5 + 0.5*cos(a);
}
void rot(inout vec2 p, float a) {
float c = cos(a);
float s = sin(a);
p = vec2(c*p.x + s*p.y, -s*p.x + c*p.y);
}
float modPolar(inout vec2 p, float repetitions) {
float angle = 2.0*PI/repetitions;
float a = atan(p.y, p.x) + angle/2.;
float r = length(p);
float c = floor(a/angle);
a = mod(a,angle) - angle/2.;
p = vec2(cos(a), sin(a))*r;
// For an odd number of repetitions, fix cell index of the cell in -x direction
// (cell index would be e.g. -5 and 5 in the two halves of the cell):
if (abs(c) >= (repetitions/2.0)) c = abs(c);
return c;
}
float pmin(float a, float b, float k) {
float h = clamp( 0.5+0.5*(b-a)/k, 0.0, 1.0 );
return mix( b, a, h ) - k*h*(1.0-h);
}
const vec2 sz = vec2(1.0, sqrt(3.0));
const vec2 hsz = 0.5*sz;
const float smallCount = 16.0;
vec2 hextile(inout vec2 p) {
// See Art of Code: Hexagonal Tiling Explained!
// https://www.youtube.com/watch?v=VmrIDyYiJBA
vec2 p1 = mod(p, sz)-hsz;
vec2 p2 = mod(p - hsz*1.0, sz)-hsz;
vec2 p3 = mix(p2, p1, vec2(length(p1) < length(p2)));
vec2 n = p3 - p;
p = p3;
return n;
}
float circle(vec2 p, float r) {
return length(p) - r;
}
float box(vec2 p, vec2 b) {
vec2 d = abs(p)-b;
return length(max(d,0.0)) + min(max(d.x,d.y),0.0);
}
float unevenCapsule(vec2 p, float r1, float r2, float h) {
p.x = abs(p.x);
float b = (r1-r2)/h;
float a = sqrt(1.0-b*b);
float k = dot(p,vec2(-b,a));
if( k < 0.0 ) return length(p) - r1;
if( k > a*h ) return length(p-vec2(0.0,h)) - r2;
return dot(p, vec2(a,b) ) - r1;
}
float cogwheel(vec2 p, float innerRadius, float outerRadius, float cogs, float holes) {
float cogWidth = 0.25*innerRadius*TAU/cogs;
float d0 = circle(p, innerRadius);
vec2 icp = p;
modPolar(icp, holes);
icp -= vec2(innerRadius*0.55, 0.0);
float d1 = circle(icp, innerRadius*0.25);
vec2 cp = p;
modPolar(cp, cogs);
cp -= vec2(innerRadius, 0.0);
float d2 = unevenCapsule(cp.yx, cogWidth, cogWidth*0.75, (outerRadius-innerRadius));
float d3 = circle(p, innerRadius*0.20);
float d = 1E6;
d = min(d, d0);
d = pmin(d, d2, 0.5*cogWidth);
d = min(d, d2);
d = max(d, -d1);
d = max(d, -d3);
return d;
}
float ccell1(vec2 p, float r) {
float d = 1E6;
const float bigCount = 60.0;
vec2 cp0 = p;
rot(cp0, -iTime*TAU/bigCount);
float d0 = cogwheel(cp0, 0.36, 0.38, bigCount, 5.0);
vec2 cp1 = p;
float nm = modPolar(cp1, 6.0);
cp1 -= vec2(0.5, 0.0);
rot(cp1, 0.2+TAU*nm/2.0 + iTime*TAU/smallCount);
float d1 = cogwheel(cp1, 0.11, 0.125, smallCount, 5.0);
d = min(d, d0);
d = min(d, d1);
return d;
}
float ccell2(vec2 p, float r) {
float d = 1E6;
vec2 cp0 = p;
float nm = modPolar(cp0, 6.0);
vec2 cp1 = cp0;
const float off = 0.275;
const float count = smallCount + 2.0;
cp0 -= vec2(off, 0.0);
rot(cp0, 0.+TAU*nm/2.0 - iTime*TAU/count);
float d0 = cogwheel(cp0, 0.09, 0.105, count, 5.0);
cp1 -= vec2(0.5, 0.0);
rot(cp1, 0.2+TAU*nm/2.0 + iTime*TAU/smallCount);
float d1 = cogwheel(cp1, 0.11, 0.125, smallCount, 5.0);
float l = length(p);
float d2 = l - (off+0.055);
float d3 = d2 + 0.020;;
vec2 tp0 = p;
modPolar(tp0, 60.0);
tp0.x -= off;
float d4 = box(tp0, vec2(0.0125, 0.005));
float ctime = -(iTime*0.05 + r)*TAU;
vec2 tp1 = p;
rot(tp1, ctime*12.0);
tp1.x -= 0.13;
float d5 = box(tp1, vec2(0.125, 0.005));
vec2 tp2 = p;
rot(tp2, ctime);
tp2.x -= 0.13*0.5;
float d6 = box(tp2, vec2(0.125*0.5, 0.0075));
float d7 = l - 0.025;
float d8 = l - 0.0125;
d = min(d, d0);
d = min(d, d1);
d = min(d, d2);
d = max(d, -d3);
d = min(d, d4);
d = min(d, d5);
d = min(d, d6);
d = min(d, d7);
d = max(d, -d8);
return d;
}
float df(vec2 p, float scale, inout vec2 nn) {
p /= scale;
nn = hextile(p);
nn = floor(nn + 0.5);
float r = hash(nn);
float d;;
if (r < 0.5) {
d = ccell1(p, r);
} else {
d = ccell2(p, r);
}
return d*scale;
}
vec3 postProcess(vec3 col, vec2 q) {
//col = saturate(col);
col=pow(clamp(col,0.0,1.0),vec3(0.75));
col=col*0.6+0.4*col*col*(3.0-2.0*col); // contrast
col=mix(col, vec3(dot(col, vec3(0.33))), -0.4); // satuation
col*=0.5+0.5*pow(19.0*q.x*q.y*(1.0-q.x)*(1.0-q.y),0.7); // vigneting
return col;
}
void mainImage(out vec4 fragColor, in vec2 fragCoord, in vec2 resolution, in vec2 uv) {
vec2 q = fragCoord/resolution.xy;
vec2 p = -1.0 + 2.0*q;
p.x *= resolution.x/resolution.y;
float tm = iTime*0.1;
p += vec2(cos(tm), sin(tm*sqrt(0.5)));
float z = mix(0.5, 1.0, pcos(tm*sqrt(0.3)));
float aa = 4.0 / resolution.y;
vec2 nn = vec2(0.0);
float d = df(p, z, nn);
vec3 col = vec3(160.0)/vec3(255.0);
vec3 baseCol = vec3(0.3);
vec4 logoCol = vec4(baseCol, 1.0)*smoothstep(-aa, 0.0, -d);
col = mix(col, logoCol.xyz, pow(logoCol.w, 8.0));
col += 0.4*pow(abs(sin(20.0*d)), 0.6);
col = postProcess(col, q);
fragColor = vec4(col, 1.0);
}