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574 lines
22 KiB
Plaintext
574 lines
22 KiB
Plaintext
#version 450
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/*
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Quasi Infinite Zoom Voronoi
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---------------------------
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The infinite zoom effect has been keeping me amused for years.
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This one is based on something I wrote some time ago, but was inspired by Fabrice Neyret's
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"Infinite Fall" shader. I've aired on the side of caution and called it "quasi infinite,"
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just in case it doesn't adhere to his strict infinite zoom standards. :)
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Seriously though, I put together a couple of overly optimized versions a couple of days ago,
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just for fun, and Fabrice's comments were pretty helpful. I also liked the way he did the
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layer rotation in his "Infinite Fall" version, so I'm using that. The rest is stock standard
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infinite zoom stuff that has been around for years.
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Most people like to use noise for this effect, so I figured I'd do something different
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and use Voronoi. I've also bump mapped it, added specular highlights, etc. It was
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tempting to add a heap of other things, but I wanted to keep the example relatively simple.
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By the way, most of the code is basic bump mapping and lighting. The infinite zoom code
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takes up just a small portion.
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Fabrice Neyret's versions:
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infinite fall - short
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https://www.shadertoy.com/view/ltjXWW
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infinite fall - FabriceNeyret2
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https://www.shadertoy.com/view/4sl3RX
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Other examples:
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Fractal Noise - mu6k
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https://www.shadertoy.com/view/Msf3Wr
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Infinite Sierpinski - gleurop
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https://www.shadertoy.com/view/MdfGR8
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Infinite Zoom - fizzer
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https://www.shadertoy.com/view/MlXGW7
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Private link to a textured version of this.
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Bumped Infinite Zoom Texture - Shane
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https://www.shadertoy.com/view/Xl2XWw
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*/
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layout(std140, set = 0, binding = 0) uniform UBO
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{
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mat4 MVP;
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vec4 OutputSize;
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vec4 OriginalSize;
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vec4 SourceSize;
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uint FrameCount;
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} global;
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#pragma stage vertex
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layout(location = 0) in vec4 Position;
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layout(location = 1) in vec2 TexCoord;
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layout(location = 0) out vec2 vTexCoord;
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const vec2 madd = vec2(0.5, 0.5);
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void main()
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{
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gl_Position = global.MVP * Position;
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vTexCoord = gl_Position.xy;
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}
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#pragma stage fragment
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layout(location = 0) in vec2 vTexCoord;
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layout(location = 0) out vec4 FragColor;
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float iGlobalTime = float(global.FrameCount)*0.025;
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vec2 iResolution = global.OutputSize.xy;
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/*
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Fractal Flythrough
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------------------
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Moving a camera through a fractal object. It's a work in progress.
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I was looking at one of Dr2's shaders that involved moving a camera through a set of way points (set
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out on the XZ plane), and thought it'd be cool to do a similar 3D version. The idea was to create a
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repetitive kind of fractal object, give the open space nodes a set random direction, create some
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spline points, then run a smooth camera through them. Simple... right? It always seems simple in my
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head, but gets progressively harder when I try it in a shader. :)
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I've run into that classic up-vector, camera flipping problem... At least, I think that's the problem?
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Anyway, I'm hoping the solution is simple, and that someone reading this will be able to point me in
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the right direction.
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For now, I've set up a set of 16 random looping points that the camera seems reasonably comfortable
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with. Just for the record, the general setup works nicely, until the camera loops back on itself in
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the YZ plane. I'm guessing that increasing the number of way points may eradicate some of the
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intermittent camera spinning, but I figured I'd leave things alone and treat it as a feature. :)
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By the way, I was thankful to have Otavio Good's spline setup in his "Alien Beacon" shader as a
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reference. On a side note, that particular shader is one of my all time favorites on this site.
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The rendering materials are slightly inspired by the Steampunk genre. Timber, granite, brass, etc.
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It needs spinning turbines, gears, rivots, and so forth, but that stuff's expensive. Maybe later.
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Tambako Jaguar did a really cool shader in the Steampunk aesthetic. The link is below.
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Besides camera path, there's a whole bunch of improvements I'd like to make to this. I've relied on
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occlusion to mask the fact that there are no shadows. I'm hoping to free up some cycles, so I can put
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them back in. I'd also like to add extra detail, but that also slows things down. As for the comments,
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they're very rushed, but I'll tidy those up as well.
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References:
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Alien Beacon - Otavio Good
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https://www.shadertoy.com/view/ld2SzK
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Steampunk Turbine - TambakoJaguar
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https://www.shadertoy.com/view/lsd3zf
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// The main inspiration for this shader.
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Mandelmaze in Daylight - dr2
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https://www.shadertoy.com/view/MdVGRc
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*/
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const float FAR = 50.0; // Far plane.
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// Used to identify individual scene objects. In this case, there are only three: The metal framework, the gold
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// and the timber.
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float objID = 0.; // Wood = 1., Metal = 2., Gold = 3..
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// Simple hash function.
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float hash( float n ){ return fract(cos(n)*45758.5453); }
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// Tri-Planar blending function. Based on an old Nvidia writeup:
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// GPU Gems 3 - Ryan Geiss: https://developer.nvidia.com/gpugems/GPUGems3/gpugems3_ch01.html
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vec3 tex3D(sampler2D t, in vec3 p, in vec3 n ){
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n = max(abs(n), 0.001);
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n /= dot(n, vec3(1));
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vec3 tx = texture(t, p.yz).xyz;
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vec3 ty = texture(t, p.zx).xyz;
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vec3 tz = texture(t, p.xy).xyz;
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// Textures are stored in sRGB (I think), so you have to convert them to linear space
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// (squaring is a rough approximation) prior to working with them... or something like that. :)
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// Once the final color value is gamma corrected, you should see correct looking colors.
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return (tx*tx*n.x + ty*ty*n.y + tz*tz*n.z);
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}
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// Common formula for rounded squares, for all intended purposes.
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float lengthN(in vec2 p, in float n){ p = pow(abs(p), vec2(n)); return pow(p.x + p.y, 1.0/n); }
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// The camera path: There are a few spline setups on Shadertoy, but this one is a slight variation of
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// Otavio Good's spline setup in his "Alien Beacon" shader: https://www.shadertoy.com/view/ld2SzK
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//
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// Spline point markers ("cp" for camera point). The camera visits each point in succession, then loops
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// back to the first point, when complete, in order to repeat the process. In case it isn't obvious, each
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// point represents an open space juncture in the object that links to the previous and next point.
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// Of course, running a camera in a straight line between points wouldn't produce a smooth camera effect,
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// so we apply the Catmull-Rom equation to the line segment.
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vec3 cp[16];
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void setCamPath(){
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// The larger fractal object has nodes in a 4x4x4 grid.
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// The smaller one in a 2x2x2 grid. The following points
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// map a path to various open areas throughout the object.
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const float sl = 2.*.96;
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const float bl = 4.*.96;
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cp[0] = vec3(0, 0, 0);
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cp[1] = vec3(0, 0, bl);
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cp[2] = vec3(sl, 0, bl);
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cp[3] = vec3(sl, 0, sl);
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cp[4] = vec3(sl, sl, sl);
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cp[5] = vec3(-sl, sl, sl);
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cp[6] = vec3(-sl, 0, sl);
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cp[7] = vec3(-sl, 0, 0);
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cp[8] = vec3(0, 0, 0);
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cp[9] = vec3(0, 0, -bl);
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cp[10] = vec3(0, bl, -bl);
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cp[11] = vec3(-sl, bl, -bl);
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cp[12] = vec3(-sl, 0, -bl);
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cp[13] = vec3(-sl, 0, 0);
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cp[14] = vec3(-sl, -sl, 0);
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cp[15] = vec3(0, -sl, 0);
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// Tighening the radius a little, so that the camera doesn't hit the walls.
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// I should probably hardcode this into the above... Done.
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//for(int i=0; i<16; i++) cp[i] *= .96;
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}
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// Standard Catmull-Rom equation. The equation takes in the line segment end points (p1 and p2), the
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// points on either side (p0 and p3), the current fractional distance (t) along the segment, then
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// returns the the smooth (cubic interpolated) position. The end result is a smooth transition
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// between points... Look up a diagram on the internet. That should make it clearer.
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vec3 Catmull(vec3 p0, vec3 p1, vec3 p2, vec3 p3, float t){
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return (((-p0 + p1*3. - p2*3. + p3)*t*t*t + (p0*2. - p1*5. + p2*4. - p3)*t*t + (-p0 + p2)*t + p1*2.)*.5);
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}
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// Camera path. Determine the segment number (segNum), and how far - timewise - we are along it (segTime).
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// Feed the segment, the appropriate adjoining segments, and the segment time into the Catmull-Rom
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// equation to produce a camera position. The process is pretty simple, once you get the hang of it.
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vec3 camPath(float t){
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const int aNum = 16;
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t = fract(t/float(aNum))*float(aNum); // Repeat every 16 time units.
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// Segment number. Range: [0, 15], in this case.
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float segNum = floor(t);
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// Segment portion. Analogous to how far we are alone the individual line segment. Range: [0, 1].
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float segTime = t - segNum;
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if (segNum == 0.) return Catmull(cp[aNum-1], cp[0], cp[1], cp[2], segTime);
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for(int i=1; i<aNum-2; i++){
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if (segNum == float(i)) return Catmull(cp[i-1], cp[i], cp[i+1], cp[i+2], segTime);
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}
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if (segNum == float(aNum-2)) return Catmull(cp[aNum-3], cp[aNum-2], cp[aNum-1], cp[0], segTime);
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if (segNum == float(aNum-1)) return Catmull(cp[aNum-2], cp[aNum-1], cp[0], cp[1], segTime);
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return vec3(0);
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}
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// Smooth minimum function. There are countless articles, but IQ explains it best here:
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// http://iquilezles.org/www/articles/smin/smin.htm
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float sminP( float a, float b, float s ){
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float h = clamp( 0.5+0.5*(b-a)/s, 0.0, 1.0 );
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return mix( b, a, h ) - s*h*(1.0-h);
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}
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// Creating the scene geometry.
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//
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// There are two intertwined fractal objects. One is a gold and timber lattice, spread out in a 4x4x4
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// grid. The second is some metallic tubing spread out over a 2x2x2 grid. Each are created by combining
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// repeat objects with various operations. All of it is pretty standard.
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//
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// The code is a little fused together, in order to save some cycles, but if you're interested in the
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// process, I have a "Menger Tunnel" example that's a little easier to decipher.
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float map(in vec3 q){
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///////////
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// The grey section. I have another Menger example, if you'd like to look into that more closely.
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// Layer one.
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vec3 p = abs(fract(q/4.)*4. - 2.);
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float tube = min(max(p.x, p.y), min(max(p.y, p.z), max(p.x, p.z))) - 4./3. - .015;// + .05;
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// Layer two.
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p = abs(fract(q/2.)*2. - 1.);
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//d = max(d, min(max(p.x, p.y), min(max(p.y, p.z), max(p.x, p.z))) - s/3.);// + .025
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tube = max(tube, sminP(max(p.x, p.y), sminP(max(p.y, p.z), max(p.x, p.z), .05), .05) - 2./3.);// + .025
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///////
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// The gold and timber paneling.
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//
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// A bit of paneling, using a combination of repeat objects. We're doing it here in layer two, just
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// to save an extra "fract" call. Very messy, but saves a few cycles... maybe.
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//float panel = sminP(length(p.xy),sminP(length(p.yz),length(p.xz), 0.25), 0.125)-0.45; // EQN 1
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//float panel = sqrt(min(dot(p.xy, p.xy),min(dot(p.yz, p.yz),dot(p.xz, p.xz))))-0.5; // EQN 2
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//float panel = min(max(p.x, p.y),min(max(p.y, p.z),max(p.x, p.z)))-0.5; // EQN 3
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float panel = sminP(max(p.x, p.y),sminP(max(p.y, p.z),max(p.x, p.z), .125), .125)-0.5; // EQN 3
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// Gold strip. Probably not the best way to do this, but it gets the job done.
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// Identifying the gold strip region, then edging it out a little... for whatever reason. :)
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float strip = step(p.x, .75)*step(p.y, .75)*step(p.z, .75);
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panel -= (strip)*.025;
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// Timber bulge. Just another weird variation.
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//float bulge = (max(max(p.x, p.y), p.z) - .55);//length(p)-1.;//
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//panel -= bulge*(1.-step(p.x, .75)*step(p.y, .75)*step(p.z, .75))*bulge*.25;
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// Repeat field entity two, which is just an abstract object repeated every half unit.
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p = abs(fract(q*2.)*.5 - .25);
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float pan2 = min(p.x, min(p.y,p.z))-.05;
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// Combining the two entities above.
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panel = max(abs(panel), abs(pan2)) - .0425;
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/////////
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// Layer three. 3D space is divided by three.
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p = abs(fract(q*1.5)/1.5 - 1./3.);
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tube = max(tube, min(max(p.x, p.y), min(max(p.y, p.z), max(p.x, p.z))) - 2./9. + .025); // + .025
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// Layer three. 3D space is divided by two, instead of three, to give some variance.
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p = abs(fract(q*3.)/3. - 1./6.);
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tube = max(tube, min(max(p.x, p.y), min(max(p.y, p.z), max(p.x, p.z))) - 1./9. - .035); //- .025
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// Object ID: Equivalent to: if(tube<panel)objID=2; else objID = 1.; //etc.
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//
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// By the way, if you need to identify multiple objects, you're better off doing it in a seperate pass,
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// after the raymarching function. Having multiple "if" statements in a distance field equation can
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// slow things down considerably.
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//objID = 2. - step(tube, panel) + step(panel, tube)*(strip);
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objID = 1.+ step(tube, panel) + step(panel, tube)*(strip)*2.;
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//objID = 1. + step(panel, tube)*(strip) + step(tube, panel)*2.;
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return min(panel, tube);
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}
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float trace(in vec3 ro, in vec3 rd){
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float t = 0.0, h;
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for(int i = 0; i < 92; i++){
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h = map(ro+rd*t);
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// Note the "t*b + a" addition. Basically, we're putting less emphasis on accuracy, as
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// "t" increases. It's a cheap trick that works in most situations... Not all, though.
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if(abs(h)<0.001*(t*.25 + 1.) || t>FAR) break; // Alternative: 0.001*max(t*.25, 1.)
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t += h*.8;
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}
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return t;
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}
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// The reflections are pretty subtle, so not much effort is being put into them. Only eight iterations.
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float refTrace(vec3 ro, vec3 rd){
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float t = 0.0;
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for(int i=0; i<16; i++){
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float d = map(ro + rd*t);
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if (d < 0.0025*(t*.25 + 1.) || t>FAR) break;
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t += d;
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}
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return t;
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}
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/*
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// Tetrahedral normal, to save a couple of "map" calls. Courtesy of IQ.
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vec3 calcNormal(in vec3 p){
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// Note the slightly increased sampling distance, to alleviate artifacts due to hit point inaccuracies.
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vec2 e = vec2(0.0025, -0.0025);
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return normalize(e.xyy * map(p + e.xyy) + e.yyx * map(p + e.yyx) + e.yxy * map(p + e.yxy) + e.xxx * map(p + e.xxx));
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}
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*/
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// Standard normal function. It's not as fast as the tetrahedral calculation, but more symmetrical. Due to
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// the intricacies of this particular scene, it's kind of needed to reduce jagged effects.
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vec3 calcNormal(in vec3 p) {
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const vec2 e = vec2(0.005, 0);
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return normalize(vec3(map(p + e.xyy) - map(p - e.xyy), map(p + e.yxy) - map(p - e.yxy), map(p + e.yyx) - map(p - e.yyx)));
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}
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// I keep a collection of occlusion routines... OK, that sounded really nerdy. :)
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// Anyway, I like this one. I'm assuming it's based on IQ's original.
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float calcAO(in vec3 pos, in vec3 nor)
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{
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float sca = 2.0, occ = 0.0;
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for( int i=0; i<5; i++ ){
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float hr = 0.01 + float(i)*0.5/4.0;
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float dd = map(nor * hr + pos);
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occ += (hr - dd)*sca;
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sca *= 0.7;
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}
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return clamp( 1.0 - occ, 0.0, 1.0 );
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}
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// Texture bump mapping. Four tri-planar lookups, or 12 texture lookups in total. I tried to
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// make it as concise as possible. Whether that translates to speed, or not, I couldn't say.
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vec3 texBump( sampler2D tx, in vec3 p, in vec3 n, float bf){
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const vec2 e = vec2(0.001, 0);
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// Three gradient vectors rolled into a matrix, constructed with offset greyscale texture values.
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mat3 m = mat3( tex3D(tx, p - e.xyy, n), tex3D(tx, p - e.yxy, n), tex3D(tx, p - e.yyx, n));
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vec3 g = vec3(0.299, 0.587, 0.114)*m; // Converting to greyscale.
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g = (g - dot(tex3D(tx, p , n), vec3(0.299, 0.587, 0.114)) )/e.x; g -= n*dot(n, g);
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return normalize( n + g*bf ); // Bumped normal. "bf" - bump factor.
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}
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void mainImage( out vec4 fragColor, in vec2 fragCoord ){
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// Screen coordinates.
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vec2 u = (fragCoord - iResolution.xy*0.5)/iResolution.y;
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float speed = iGlobalTime*0.35 + 8.;
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// Initiate the camera path spline points. Kind of wasteful not making this global, but I wanted
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// it self contained... for better or worse. I'm not really sure what the GPU would prefer.
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setCamPath();
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// Camera Setup.
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vec3 ro = camPath(speed); // Camera position, doubling as the ray origin.
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vec3 lk = camPath(speed + .5); // "Look At" position.
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vec3 lp = camPath(speed + .5) + vec3(0, .25, 0); // Light position, somewhere near the moving camera.
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// Using the above to produce the unit ray-direction vector.
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float FOV = 1.57; // FOV - Field of view.
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vec3 fwd = normalize(lk-ro);
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vec3 rgt = normalize(vec3(fwd.z, 0, -fwd.x));
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vec3 up = (cross(fwd, rgt));
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// Unit direction ray.
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vec3 rd = normalize(fwd + FOV*(u.x*rgt + u.y*up));
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// Raymarch the scene.
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float t = trace(ro, rd);
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// Initialize the scene color.
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vec3 col = vec3(0);
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// Scene hit, so color the pixel. Technically, the object should always be hit, so it's tempting to
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// remove this entire branch... but I'll leave it, for now.
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if(t<FAR){
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// This looks a little messy and haphazard, but it's really just some basic lighting, and application
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// of the following material properties: Wood = 1., Metal = 2., Gold = 3..
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float ts = 1.; // Texture scale.
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// Global object ID. It needs to be saved just after the raymarching equation, since other "map" calls,
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// like normal calculations will give incorrect results. Found that out the hard way. :)
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float saveObjID = objID;
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vec3 pos = ro + rd*t; // Scene postion.
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vec3 nor = calcNormal(pos); // Normal.
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vec3 sNor = nor;
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// Apply some subtle texture bump mapping to the panels and the metal tubing.
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nor = texBump(iChannel0, pos*ts, nor, 0.002); // + step(saveObjID, 1.5)*0.002
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// Reflected ray. Note that the normal is only half bumped. It's fake, but it helps
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// taking some of the warping effect off of the reflections.
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vec3 ref = reflect(rd, normalize(sNor*.5 + nor*.5));
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col = tex3D(iChannel0, pos*ts, nor); // Texture pixel at the scene postion.
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vec3 li = lp - pos; // Point light.
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float lDist = max(length(li), .001); // Surface to light distance.
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float atten = 1./(1.0 + lDist*0.125 + lDist*lDist*.05); // Light attenuation.
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li /= lDist; // Normalizing the point light vector.
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float occ = calcAO( pos, nor ); // Occlusion.
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float dif = clamp(dot(nor, li), 0.0, 1.0); // Diffuse.
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dif = pow(dif, 4.)*2.;
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float spe = pow(max(dot(reflect(-li, nor), -rd), 0.), 8.); // Object specular.
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float spe2 = spe*spe; // Global specular.
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float refl = .35; // Reflection coefficient. Different for different materials.
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// Reflection color. Mostly fake.
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// Cheap reflection: Not entirely accurate, but the reflections are pretty subtle, so not much
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// effort is being put in.
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float rt = refTrace(pos + ref*0.1, ref); // Raymarch from "sp" in the reflected direction.
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float rSaveObjID = objID; // IDs change with reflection. Learned that the hard way. :)
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vec3 rsp = pos + ref*rt; // Reflected surface hit point.
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vec3 rsn = calcNormal(rsp); // Normal at the reflected surface. Too costly to bump reflections.
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vec3 rCol = tex3D(iChannel0, rsp*ts, rsn); // Texel at "rsp."
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vec3 rLi = lp-rsp;
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float rlDist = max(length(rLi), 0.001);
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rLi /= rlDist;
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float rDiff = max(dot(rsn, rLi), 0.); // Diffuse light at "rsp."
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rDiff = pow(rDiff, 4.)*2.;
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float rAtten = 1./(1. + rlDist*0.125 + rlDist*rlDist*.05);
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if(rSaveObjID>1.5 && rSaveObjID<2.5){
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rCol = vec3(1)*dot(rCol, vec3(.299, .587, .114))*.7 + rCol*.15;//*.7+.2
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//rDiff *= 1.35;
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}
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if(rSaveObjID>2.5){
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//float rc = dot(rCol, vec3(.299, .587, .114));
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vec3 rFire = pow(vec3(1.5, 1, 1)*rCol, vec3(8, 2, 1.5));//*.5+rc*.5;
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rCol = min(mix(vec3(1.5, .9, .375), vec3(.75, .375, .3), rFire), 2.)*.5 + rCol;
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}
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rCol *= (rDiff + .35)*rAtten; // Reflected color. Not accurate, but close enough.
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// Grey metal inner tubing.
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if(saveObjID>1.5 && saveObjID<2.5){
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// Grey out the limestone wall color.
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col = vec3(1)*dot(col, vec3(.299, .587, .114))*.7 + col*.15;
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refl = .5;
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//dif *= 1.35;
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//spe2 *= 1.35;
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}
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// Gold trimming properties. More effort should probably be put in here.
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// I could just write "saveObjID == 3.," but I get a little paranoid where floats are concerned. :)
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if(saveObjID>2.5){
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// For the screen image, we're interested in the offset height and depth positions. Ie: pOffs.zy.
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// Pixelized dot pattern shade.
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//float c = dot(col, vec3(.299, .587, .114));
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vec3 fire = pow(vec3(1.5, 1, 1)*col, vec3(8, 2, 1.5));//*.5+c*.5;
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col = min(mix(vec3(1, .9, .375), vec3(.75, .375, .3), fire), 2.)*.5 + col;//
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refl = .65;
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//dif *= 1.5;
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//spe2 *= 1.5;
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}
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// Combining everything together to produce the scene color.
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col = col*(dif + .35 + vec3(.35, .45, .5)*spe) + vec3(.7, .9, 1)*spe2 + rCol*refl;
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col *= occ*atten; // Applying occlusion.
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}
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// Applying some very slight fog in the distance. This is technically an inside scene...
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// Or is it underground... Who cares, it's just a shader. :)
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col = mix(min(col, 1.), vec3(0), 1.-exp(-t*t/FAR/FAR*20.));//smoothstep(0., FAR-20., t)
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//col = mix(min(col, 1.), vec3(0), smoothstep(0., FAR-35., t));//smoothstep(0., FAR-20., t)
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// Done.
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fragColor = vec4(sqrt(max(col, 0.)), 1.0);
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}
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void main(void)
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{
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//just some shit to wrap shadertoy's stuff
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vec2 FragCoord = vTexCoord.xy*global.OutputSize.xy;
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FragCoord.y = -FragCoord.y;
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mainImage(FragColor,FragCoord);
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}
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