v4k-git-backup/demos/art/shadertoys/Mss3WN.fs

/*by mu6k, Creative Commons Attribution-NonCommercial-ShareAlike 3.0 Unported License.

 I have no idea how I ended up here, but it demosceneish enough to publish.
 You can use the mouse to rotate the camera around the 'object'.
 If you can't see the shadows, increase occlusion_quality.
 If it doesn't compile anymore decrease object_count and render_steps.

 15/06/2013:
 - published
 
 16/06/2013:
 - modified for better performance and compatibility

 muuuuuuuuuuuuuuuuuuuuuuuuuuuuuuuusk!*/

#define occlusion_enabled
#define occlusion_quality 4
//#define occlusion_preview

#define noise_use_smoothstep

#define light_color vec3(0.1,0.4,0.6)
#define light_direction normalize(vec3(.2,1.0,-0.2))
#define light_speed_modifier 1.0

#define object_color vec3(0.9,0.1,0.1)
#define object_count 9
#define object_speed_modifier 1.0

#define render_steps 33

float hash(float x)
{
	return fract(sin(x*.0127863)*17143.321);
}

float hash(vec2 x)
{
	return fract(cos(dot(x.xy,vec2(2.31,53.21))*124.123)*412.0); 
}

vec3 cc(vec3 color, float factor,float factor2) //a wierd color modifier
{
	float w = color.x+color.y+color.z;
	return mix(color,vec3(w)*factor,w*factor2);
}

float hashmix(float x0, float x1, float interp)
{
	x0 = hash(x0);
	x1 = hash(x1);
	#ifdef noise_use_smoothstep
	interp = smoothstep(0.0,1.0,interp);
	#endif
	return mix(x0,x1,interp);
}

float noise(float p) // 1D noise
{
	float pm = mod(p,1.0);
	float pd = p-pm;
	return hashmix(pd,pd+1.0,pm);
}

vec3 rotate_y(vec3 v, float angle)
{
	float ca = cos(angle); float sa = sin(angle);
	return v*mat3(
		+ca, +.0, -sa,
		+.0,+1.0, +.0,
		+sa, +.0, +ca);
}

vec3 rotate_x(vec3 v, float angle)
{
	float ca = cos(angle); float sa = sin(angle);
	return v*mat3(
		+1.0, +.0, +.0,
		+.0, +ca, -sa,
		+.0, +sa, +ca);
}

float max3(float a, float b, float c)//returns the maximum of 3 values
{
	return max(a,max(b,c));
}

vec3 bpos[object_count];//position for each metaball

float dist(vec3 p)//distance function
{
	float d=1024.0;
	float nd;
	for (int i=0 ;i<object_count; i++)
	{
		vec3 np = p+bpos[i];
		float shape0 = max3(abs(np.x),abs(np.y),abs(np.z))-1.0;
		float shape1 = length(np)-1.0;
		nd = shape0+(shape1-shape0)*2.0;
		d = mix(d,nd,smoothstep(-1.0,+1.0,d-nd));
	}
	return d;
}

vec3 normal(vec3 p,float e) //returns the normal, uses the distance function
{
	float d=dist(p);
	return normalize(vec3(dist(p+vec3(e,0,0))-d,dist(p+vec3(0,e,0))-d,dist(p+vec3(0,0,e))-d));
}

vec3 light = light_direction; //global variable that holds light direction

vec3 background(vec3 d)//render background
{
	float t=iGlobalTime*0.5*light_speed_modifier;
	float qq = dot(d,light)*.5+.5;
	float bgl = qq;
	float q = (bgl+noise(bgl*6.0+t)*.85+noise(bgl*12.0+t)*.85);
	q+= pow(qq,32.0)*2.0;
	vec3 sky = vec3(0.1,0.4,0.6)*q;
	return sky;
}

float occlusion(vec3 p, vec3 d)//returns how much a point is visible from a given direction
{
	float occ = 1.0;
	p=p+d;
	for (int i=0; i<occlusion_quality; i++)
	{
		float dd = dist(p);
		p+=d*dd;
		occ = min(occ,dd);
	}
	return max(.0,occ);
}

vec3 object_material(vec3 p, vec3 d)
{
	vec3 color = normalize(object_color*light_color);
	vec3 n = normal(p,0.1);
	vec3 r = reflect(d,n);	
	
	float reflectance = dot(d,r)*.5+.5;reflectance=pow(reflectance,2.0);
	float diffuse = dot(light,n)*.5+.5; diffuse = max(.0,diffuse);
	
	#ifdef occlusion_enabled
		float oa = occlusion(p,n)*.4+.6;
		float od = occlusion(p,light)*.95+.05;
		float os = occlusion(p,r)*.95+.05;
	#else
		float oa=1.0;
		float ob=1.0;
		float oc=1.0;
	#endif
	
	#ifndef occlusion_preview
		color = 
		color*oa*.2 + //ambient
		color*diffuse*od*.7 + //diffuse
		background(r)*os*reflectance*.7; //reflection
	#else
		color=vec3((oa+od+os)*.3);
	#endif
	
	return color;
}

#define offset1 4.7
#define offset2 4.6

void mainImage( out vec4 fragColor, in vec2 fragCoord )
{
	vec2 uv = fragCoord.xy / iResolution.xy - 0.5;
	uv.x *= iResolution.x/iResolution.y; //fix aspect ratio
	vec3 mouse = vec3(iMouse.xy/iResolution.xy - 0.5,iMouse.z-.5);
	
	float t = iGlobalTime*.5*object_speed_modifier + 2.0;
	
	for (int i=0 ;i<object_count; i++) //position for each metaball
	{
		bpos[i] = 1.3*vec3(
			sin(t*0.967+float(i)*42.0),
			sin(t*.423+float(i)*152.0),
			sin(t*.76321+float(i)));
	}
	
	//setup the camera
	vec3 p = vec3(.0,0.0,-4.0);
	p = rotate_x(p,mouse.y*9.0+offset1);
	p = rotate_y(p,mouse.x*9.0+offset2);
	vec3 d = vec3(uv,1.0);
	d.z -= length(d)*.5; //lens distort
	d = normalize(d);
	d = rotate_x(d,mouse.y*9.0+offset1);
	d = rotate_y(d,mouse.x*9.0+offset2);
	
	//and action!
	float dd;
	vec3 color;
	for (int i=0; i<render_steps; i++) //raymarch
	{
		dd = dist(p);
		p+=d*dd*.7;
		if (dd<.04 || dd>4.0) break;
	}
	
	if (dd<0.5) //close enough
		color = object_material(p,d);
	else
		color = background(d);
	
	//post procesing
	color *=.85;
	color = mix(color,color*color,0.3);
	color -= hash(color.xy+uv.xy)*.015;
	color -= length(uv)*.1;
	color =cc(color,.5,.6);
	fragColor = vec4(color,1.0);
}
v4k initial commit 2023-08-10 14:30:56 +00:00			`/*by mu6k, Creative Commons Attribution-NonCommercial-ShareAlike 3.0 Unported License.`

			`I have no idea how I ended up here, but it demosceneish enough to publish.`
			`You can use the mouse to rotate the camera around the 'object'.`
			`If you can't see the shadows, increase occlusion_quality.`
			`If it doesn't compile anymore decrease object_count and render_steps.`

			`15/06/2013:`
			`- published`

			`16/06/2013:`
			`- modified for better performance and compatibility`

			`muuuuuuuuuuuuuuuuuuuuuuuuuuuuuuuusk!*/`

			`#define occlusion_enabled`
			`#define occlusion_quality 4`
			`//#define occlusion_preview`

			`#define noise_use_smoothstep`

			`#define light_color vec3(0.1,0.4,0.6)`
			`#define light_direction normalize(vec3(.2,1.0,-0.2))`
			`#define light_speed_modifier 1.0`

			`#define object_color vec3(0.9,0.1,0.1)`
			`#define object_count 9`
			`#define object_speed_modifier 1.0`

			`#define render_steps 33`

			`float hash(float x)`
			`{`
			`return fract(sin(x.0127863)17143.321);`
			`}`

			`float hash(vec2 x)`
			`{`
			`return fract(cos(dot(x.xy,vec2(2.31,53.21))124.123)412.0);`
			`}`

			`vec3 cc(vec3 color, float factor,float factor2) //a wierd color modifier`
			`{`
			`float w = color.x+color.y+color.z;`
			`return mix(color,vec3(w)factor,wfactor2);`
			`}`

			`float hashmix(float x0, float x1, float interp)`
			`{`
			`x0 = hash(x0);`
			`x1 = hash(x1);`
			`#ifdef noise_use_smoothstep`
			`interp = smoothstep(0.0,1.0,interp);`
			`#endif`
			`return mix(x0,x1,interp);`
			`}`

			`float noise(float p) // 1D noise`
			`{`
			`float pm = mod(p,1.0);`
			`float pd = p-pm;`
			`return hashmix(pd,pd+1.0,pm);`
			`}`

			`vec3 rotate_y(vec3 v, float angle)`
			`{`
			`float ca = cos(angle); float sa = sin(angle);`
			`return v*mat3(`
			`+ca, +.0, -sa,`
			`+.0,+1.0, +.0,`
			`+sa, +.0, +ca);`
			`}`

			`vec3 rotate_x(vec3 v, float angle)`
			`{`
			`float ca = cos(angle); float sa = sin(angle);`
			`return v*mat3(`
			`+1.0, +.0, +.0,`
			`+.0, +ca, -sa,`
			`+.0, +sa, +ca);`
			`}`

			`float max3(float a, float b, float c)//returns the maximum of 3 values`
			`{`
			`return max(a,max(b,c));`
			`}`

			`vec3 bpos[object_count];//position for each metaball`

			`float dist(vec3 p)//distance function`
			`{`
			`float d=1024.0;`
			`float nd;`
			`for (int i=0 ;i<object_count; i++)`
			`{`
			`vec3 np = p+bpos[i];`
			`float shape0 = max3(abs(np.x),abs(np.y),abs(np.z))-1.0;`
			`float shape1 = length(np)-1.0;`
			`nd = shape0+(shape1-shape0)*2.0;`
			`d = mix(d,nd,smoothstep(-1.0,+1.0,d-nd));`
			`}`
			`return d;`
			`}`

			`vec3 normal(vec3 p,float e) //returns the normal, uses the distance function`
			`{`
			`float d=dist(p);`
			`return normalize(vec3(dist(p+vec3(e,0,0))-d,dist(p+vec3(0,e,0))-d,dist(p+vec3(0,0,e))-d));`
			`}`

			`vec3 light = light_direction; //global variable that holds light direction`

			`vec3 background(vec3 d)//render background`
			`{`
			`float t=iGlobalTime0.5light_speed_modifier;`
			`float qq = dot(d,light)*.5+.5;`
			`float bgl = qq;`
			`float q = (bgl+noise(bgl6.0+t).85+noise(bgl12.0+t).85);`
			`q+= pow(qq,32.0)*2.0;`
			`vec3 sky = vec3(0.1,0.4,0.6)*q;`
			`return sky;`
			`}`

			`float occlusion(vec3 p, vec3 d)//returns how much a point is visible from a given direction`
			`{`
			`float occ = 1.0;`
			`p=p+d;`
			`for (int i=0; i<occlusion_quality; i++)`
			`{`
			`float dd = dist(p);`
			`p+=d*dd;`
			`occ = min(occ,dd);`
			`}`
			`return max(.0,occ);`
			`}`

			`vec3 object_material(vec3 p, vec3 d)`
			`{`
			`vec3 color = normalize(object_color*light_color);`
			`vec3 n = normal(p,0.1);`
			`vec3 r = reflect(d,n);`

			`float reflectance = dot(d,r)*.5+.5;reflectance=pow(reflectance,2.0);`
			`float diffuse = dot(light,n)*.5+.5; diffuse = max(.0,diffuse);`

			`#ifdef occlusion_enabled`
			`float oa = occlusion(p,n)*.4+.6;`
			`float od = occlusion(p,light)*.95+.05;`
			`float os = occlusion(p,r)*.95+.05;`
			`#else`
			`float oa=1.0;`
			`float ob=1.0;`
			`float oc=1.0;`
			`#endif`

			`#ifndef occlusion_preview`
			`color =`
			`coloroa.2 + //ambient`
			`colordiffuseod*.7 + //diffuse`
			`background(r)osreflectance*.7; //reflection`
			`#else`
			`color=vec3((oa+od+os)*.3);`
			`#endif`

			`return color;`
			`}`

			`#define offset1 4.7`
			`#define offset2 4.6`

			`void mainImage( out vec4 fragColor, in vec2 fragCoord )`
			`{`
			`vec2 uv = fragCoord.xy / iResolution.xy - 0.5;`
			`uv.x *= iResolution.x/iResolution.y; //fix aspect ratio`
			`vec3 mouse = vec3(iMouse.xy/iResolution.xy - 0.5,iMouse.z-.5);`

			`float t = iGlobalTime.5object_speed_modifier + 2.0;`

			`for (int i=0 ;i<object_count; i++) //position for each metaball`
			`{`
			`bpos[i] = 1.3*vec3(`
			`sin(t0.967+float(i)42.0),`
			`sin(t.423+float(i)152.0),`
			`sin(t*.76321+float(i)));`
			`}`

			`//setup the camera`
			`vec3 p = vec3(.0,0.0,-4.0);`
			`p = rotate_x(p,mouse.y*9.0+offset1);`
			`p = rotate_y(p,mouse.x*9.0+offset2);`
			`vec3 d = vec3(uv,1.0);`
			`d.z -= length(d)*.5; //lens distort`
			`d = normalize(d);`
			`d = rotate_x(d,mouse.y*9.0+offset1);`
			`d = rotate_y(d,mouse.x*9.0+offset2);`

			`//and action!`
			`float dd;`
			`vec3 color;`
			`for (int i=0; i<render_steps; i++) //raymarch`
			`{`
			`dd = dist(p);`
			`p+=ddd.7;`
			`if (dd<.04 \|\| dd>4.0) break;`
			`}`

			`if (dd<0.5) //close enough`
			`color = object_material(p,d);`
			`else`
			`color = background(d);`

			`//post procesing`
			`color *=.85;`
			`color = mix(color,color*color,0.3);`
			`color -= hash(color.xy+uv.xy)*.015;`
			`color -= length(uv)*.1;`
			`color =cc(color,.5,.6);`
			`fragColor = vec4(color,1.0);`
			`}`