I've been knocking around Shadertoy - https://www.shadertoy.com/ - recently, in an effort to learn more about OpenGL and GLSL in particular.

From what I understand so far, the OpenGL user first has to prepare all the geometry to be used and configure the OpenGL server (number of lights allowed, texture storage, etc). Once that's done, the user then has to provide at least one vertex shader program, and one fragment shader program before an OpenGL program compiles.

However, when I look at the code samples on Shadertoy, I only ever see one shader program, and most of the geometry used appears to be written directly into the GLSL code.

How does that work?

My guess is that a vertex shader is already prepared upfront, and that the editable/sample shader is only a fragment shader. But then that doesn't explain the geometry in some of the more complex examples...

Can anyone explain how Shadertoy works?

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ShaderToy is a tool for writing pixel shaders.

What are pixel shaders?

If you render a full screen quad, meaning that each of four points is placed in one of the four corners of the viewport, then the fragment shader for that quad is called pixel shader, because you could say that now each fragment corresponds to exactly one pixel of the screen. So a pixel shader is a fragment shader for a fullscreen quad.

So attributes are always the same and so is a vertex shader:

positions = [ [-1,1], [1,1], [-1,-1], [1,-1] ]
uv = [ [0.0, 0.0], [1.0, 0.0], [0.0, 1.0], [1.0, 1.0] ]

And that quad is rendered as TRIANGLE_STRIP. Also, instead of setting UVs explicitly, some prefer to use fragment shader's built-in variable gl_FragCoord, which is then divided with, for example, a uniform vec2 uScreenResolution.

Vertex shader:

attribute vec2 aPos;
attribute vec2 aUV;
varying vec2 vUV;

void main() {
    gl_Position = vec4(aPos, 0.0, 1.0);
    vUV = aUV;

And fragment shader would then look something like this:

uniform vec2 uScreenResolution;
varying vec2 vUV;

void main() {
    // vUV is equal to gl_FragCoord/uScreenResolution
    // do some pixel shader related work
    gl_FragColor = vec3(someColor);

ShaderToy can supply you with a few uniforms on default, iResolution (aka uScreenResolution), iGlobalTime, iMouse,... which you can use in your pixel shader.

For coding geometry directly into the fragment shader (aka pixel shader), developer use something called ray-tracing. That is quite complex area of programming but in short: You present your geometry through some mathematical formulas, and later in pixel shader, when you wish to check if some pixel is a part of your geometry you use that formula to retrieve that information. Google-ing a bit should give you plenty of resources to read from what and how ray tracers are built exactly, and this might help: How to do ray tracing in modern OpenGL?

Hope this helps.

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  • Do you know why it works this way? is it an artistic choice, or is raytracing generally more efficient than using vertex shaders? – MasterScrat Oct 29 '15 at 21:05
  • 3
    Generally, raytracing is done on CPU, and rays are traced through a pixel, for each pixel in the image. Since pixel shader is a program that is run for each pixel in the rasterized primitive, than it's more natural and intuitive do use fragment shader for raytracing, than vertex shader. It's logical thing to do, right? However, there're things like vertexshaderart.com also. The choice between VS/FS for raytracing on gpu is made when you consider what's the actual output of a certain shader stage. – Abstract Algorithm Oct 30 '15 at 13:59
  • amazing website, also for someone who new to OpenGL and only learned modern OpenGL, "attribute = in" for vertex shader, "varying = out" for vertex shader, "varying = in" fragment shader. – XueYu Mar 22 '17 at 15:58
  • If you are trying to implement yourself, this is what worked for me: shadertoy.com/view/3tX3zl There are versions for WebGL 1 and 2. – Rafael Beckel Sep 13 '19 at 8:00

ShaderToy displays simple GLSL that is programmed to handle all the lighting, geometry, etc, it's not vertex geometry, it's raycasting most of it, the 3D stuff, or you can do 2D shaders, etc.

Any color and spacial maths can be programmed in GLSL language. Combinations of advanced algorithms makes isosurfaces, shapes, and then project textures onto isosurfaces, and raycasting, sending imaginary lines from viewer to distance, intercepts anything in the way, there are many raycasting techniques for 3D.

visit www.iquilezles.org for an idea of the different tools that are used in shadertoy/glsl graphics

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It's just basically pushing GLSL pixel shader source code directly onto the graphics card.The real magic happens in the incredibly clever algorithms that people use to create amazing effects, like ray marching, ray casting, ray tracing. best to have a look at some other live GLSL sandboxes like: http://glsl.heroku.com/ and http://webglplayground.net/. Its basically creating a window typically two triangles which represent the screen, then the shader works on each pixel just like a ray tracer.
I've been looking at these a while now, and the algorithms people use are mind blowing, you'll need to some serious math chops and look up "demo coding" source code to able to wrap your head around them. Many on shader toy, just blow your mind ! So to summarise, you just need to learn GLSL shader coding and algorithms. No easy solution.

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Traditionally in computer graphics, geometry is created using vertices and rendered using some form of materials (e.g. textures with lighting). In GLSL, the vertex shader processes the vertices and the fragment (pixel) shader processes the materials.

But that is not the only way to define shapes. Just as a texture could be procedurally defined (instead of looking up its texels), a shape could be procedurally defined (instead of looking up its geometry).

So, similar to ray tracing, these fragment shaders are able to create shapes without having their geometry defined by vertices.

There's still more ways to define shapes. E.g. volume data (voxels), surface curves, and so on. A computer graphics text should cover some of them.

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