# Background

I'm looking at this example code from the WebGL2 library PicoGL.js.

It describes a single triangle (three vertices: `(-0.5, -0.5), (0.5, -0.5), (0.0, 0.5)`), each of which is assigned a color (red, green, blue) by the vertex shader:

``````    #version 300 es

layout(location=0) in vec4 position;
layout(location=1) in vec3 color;

out vec3 vColor;
void main() {
vColor = color;
gl_Position = position;
}
``````

The `vColor` output is passed to the fragment shader:

``````    #version 300 es
precision highp float;

in vec3 vColor;

out vec4 fragColor;
void main() {
fragColor = vec4(vColor, 1.0);
}
``````

and together they render the following image: # Question(s)

My understanding is that the vertex shader is called once per vertex, whereas the fragment shader is called once per pixel.

However, the fragment shader references the `vColor` variable, which is only assigned once per call to each vertex, but there are many more pixels than vertices!

The resulting image clearly shows a color gradient - why? Does WebGL automatically interpolate values of `vColor` for pixels in between vertices? If so, how is the interpolation done?

Yes, WebGL automatically interpolates between the values supplied to the 3 vertices.

Copied from this site

A linear interpolation from one value to another would be this formula

``````result = (1 - t) * a + t * b
``````

Where `t` is a value from 0 to 1 representing some position between `a` and `b`. 0 at `a` and 1 at `b`.

For varyings though WebGL uses this formula

``````result = (1 - t) * a / aW + t * b / bW
-----------------------------
(1 - t) / aW + t / bW
``````

Where `aW` is the `W` that was set on `gl_Position.w` when the varying was as set to `a` and `bW` is the `W` that was set on `gl_Position.w` when the varying was set to `b`.

The site linked above shows how that formula generates perspective correct texture mapping coordinates when interpolating varyings