material-maker/addons/procedural_material/common.shader
Rodolphe Suescun 18015aec93 Implemented multi-pass nodes and fixed blur. Various other fixes.
* Added a "constant wave" in the pattern node
* Updated graphEdit to detect and forbid loops
* Modified code that renders to texture to update a texture instead of returning one (so we avoid updating everything and rely on everything being updated automatically wrt textures)
* base library is loaded from filesystem (instead of package) if available
2018-08-12 19:25:18 +02:00

218 lines
6.2 KiB
GLSL

float rand(vec2 x) {
return fract(cos(dot(x, vec2(13.9898, 8.141))) * 43758.5453);
}
vec2 rand2(vec2 x) {
return fract(cos(vec2(dot(x, vec2(13.9898, 8.141)),
dot(x, vec2(3.4562, 17.398)))) * 43758.5453);
}
vec3 rand3(vec2 x) {
return fract(cos(vec3(dot(x, vec2(13.9898, 8.141)),
dot(x, vec2(3.4562, 17.398)),
dot(x, vec2(13.254, 5.867)))) * 43758.5453);
}
float wave_constant(float x) {
return 1.0;
}
float wave_sin(float x) {
return 0.5-0.5*cos(3.1415928*2.0*x);
}
float wave_triangle(float x) {
x = fract(x);
return min(2.0*x, 2.0-2.0*x);
}
float wave_square(float x) {
return (fract(x) < 0.5) ? 0.0 : 1.0;
}
float mix_multiply(float x, float y) {
return x*y;
}
float mix_add(float x, float y) {
return min(x+y, 1.0);
}
float mix_max(float x, float y) {
return max(x, y);
}
float mix_min(float x, float y) {
return min(x, y);
}
float mix_min(float x, float y) {
return min(x, y);
}
float mix_xor(float x, float y) {
return min(x+y, 2.0-x-y);
}
float mix_pow(float x, float y) {
return pow(x, y);
}
vec3 blend_normal(vec2 uv, vec3 c1, vec3 c2, float opacity) {
return opacity*c1 + (1.0-opacity)*c2;
}
vec3 blend_dissolve(vec2 uv, vec3 c1, vec3 c2, float opacity) {
if (rand(uv) < opacity) {
return c1;
} else {
return c2;
}
}
vec3 blend_multiply(vec2 uv, vec3 c1, vec3 c2, float opacity) {
return opacity*c1*c2 + (1.0-opacity)*c2;
}
vec3 blend_screen(vec2 uv, vec3 c1, vec3 c2, float opacity) {
return opacity*(1.0-(1.0-c1)*(1.0-c2)) + (1.0-opacity)*c2;
}
float blend_overlay_f(float c1, float c2) {
return (c1 < 0.5) ? (2.0*c1*c2) : (1.0-2.0*(1.0-c1)*(1.0-c2));
}
vec3 blend_overlay(vec2 uv, vec3 c1, vec3 c2, float opacity) {
return opacity*vec3(blend_overlay_f(c1.x, c2.x), blend_overlay_f(c1.y, c2.y), blend_overlay_f(c1.z, c2.z)) + (1.0-opacity)*c2;
}
vec3 blend_hard_light(vec2 uv, vec3 c1, vec3 c2, float opacity) {
return opacity*0.5*(c1*c2+blend_overlay(uv, c1, c2, 1.0)) + (1.0-opacity)*c2;
}
float blend_soft_light_f(float c1, float c2) {
return (c2 < 0.5) ? (2.0*c1*c2+c1*c1*(1.0-2.0*c2)) : 2.0*c1*(1.0-c2)+sqrt(c1)*(2.0*c2-1.0);
}
vec3 blend_soft_light(vec2 uv, vec3 c1, vec3 c2, float opacity) {
return opacity*vec3(blend_soft_light_f(c1.x, c2.x), blend_soft_light_f(c1.y, c2.y), blend_soft_light_f(c1.z, c2.z)) + (1.0-opacity)*c2;
}
float blend_burn_f(float c1, float c2) {
return (c1==0.0)?c1:max((1.0-((1.0-c2)/c1)),0.0);
}
vec3 blend_burn(vec2 uv, vec3 c1, vec3 c2, float opacity) {
return opacity*vec3(blend_burn_f(c1.x, c2.x), blend_burn_f(c1.y, c2.y), blend_burn_f(c1.z, c2.z)) + (1.0-opacity)*c2;
}
float blend_dodge_f(float c1, float c2) {
return (c1==1.0)?c1:min(c2/(1.0-c1),1.0);
}
vec3 blend_dodge(vec2 uv, vec3 c1, vec3 c2, float opacity) {
return opacity*vec3(blend_dodge_f(c1.x, c2.x), blend_dodge_f(c1.y, c2.y), blend_dodge_f(c1.z, c2.z)) + (1.0-opacity)*c2;
}
vec3 blend_lighten(vec2 uv, vec3 c1, vec3 c2, float opacity) {
return opacity*max(c1, c2) + (1.0-opacity)*c2;
}
vec3 blend_darken(vec2 uv, vec3 c1, vec3 c2, float opacity) {
return opacity*min(c1, c2) + (1.0-opacity)*c2;
}
vec2 transform(vec2 uv, vec2 translate, float rotate, vec2 scale) {
vec2 rv;
uv -= vec2(0.5);
rv.x = cos(rotate)*uv.x + sin(rotate)*uv.y;
rv.y = -sin(rotate)*uv.x + cos(rotate)*uv.y;
rv /= scale;
rv += vec2(0.5);
rv -= translate;
return rv;
}
vec2 transform_repeat(vec2 uv, vec2 translate, float rotate, vec2 scale) {
return fract(transform(uv, translate, rotate, scale));
}
vec2 transform_norepeat(vec2 uv, vec2 translate, float rotate, vec2 scale) {
return clamp(transform(uv, translate, rotate, scale), vec2(0.0), vec2(1.0));
}
vec3 bricks(vec2 uv, vec2 count, float offset, float mortar, float bevel) {
mortar /= max(count.x, count.y);
bevel /= max(count.x, count.y);
float x = uv.x*count.x+offset*step(0.5, fract(uv.y*count.y*0.5));
float fract_x = fract(x);
float slope_x = 1.0/(bevel*count.x);
float off = 0.5*mortar/bevel;
float f1 = fract_x*slope_x-off;
float f2 = (1.0-fract_x)*slope_x-off;
float y = uv.y*count.y;
float fract_y = fract(uv.y*count.y);
float slope_y = 1.0/(bevel*count.y);
float f3 = fract_y*slope_y-off;
float f4 = (1.0-fract_y)*slope_y-off;
return vec3(max(0.0, min(1.0, min(min(f1, f2), min(f3, f4)))), floor(mod(x, count.x)), floor(mod(y, count.y)));
}
float colored_bricks(vec2 uv, vec2 count, float offset) {
float x = floor(uv.x*count.x+offset*step(0.5, fract(uv.y*count.y*0.5)));
float y = floor(uv.y*count.y);
return fract(x/3.0+y/7.0);
}
float perlin(vec2 uv, vec2 size, int iterations, float persistence, int seed) {
uv += vec2(float(seed)*0.1234567);
float rv = 0.0;
float coef = 1.0;
float acc = 0.0;
for (int i = 0; i < iterations; ++i) {
vec2 step = vec2(1.0)/size;
float f0 = rand(floor(fract(uv)*size));
float f1 = rand(floor(fract(uv+vec2(step.x, 0.0))*size));
float f2 = rand(floor(fract(uv+vec2(0.0, step.y))*size));
float f3 = rand(floor(fract(uv+vec2(step.x, step.y))*size));
vec2 mixval = fract(uv*size);
mixval = 0.5*(1.0-cos(3.1415928*mixval));
rv += coef * mix(mix(f0, f1, mixval.x), mix(f2, f3, mixval.x), mixval.y);
acc += coef;
size *= 2.0;
coef *= persistence;
}
return rv / acc;
}
vec4 voronoi(vec2 uv, vec2 size, float intensity, int seed) {
uv += vec2(float(seed)*0.1234567);
uv *= size;
float best_distance0 = 1.0;
float best_distance1 = 1.0;
vec2 point0;
vec2 point1;
vec2 p0 = floor(uv);
for (int dx = -1; dx < 2; ++dx) {
for (int dy = -1; dy < 2; ++dy) {
vec2 d = vec2(float(dx), float(dy));
vec2 p = p0+d;
p += rand2(mod(p, size));
float distance = length((uv - p) / size);
if (best_distance0 > distance) {
best_distance1 = best_distance0;
best_distance0 = distance;
point1 = point0;
point0 = p;
} else if (best_distance1 > distance) {
best_distance1 = distance;
point1 = p;
}
}
}
float edge_distance = dot(uv - 0.5*(point0+point1), normalize(point0-point1));
return vec4(point0, best_distance0*length(size)*intensity, edge_distance);
}