Furthermore, we have a predefined gl_FragColor.
Let's start with this. No, you don't have the predefined
gl_FragColor. That was removed from core OpenGL 3.1 and above. Unless you're using compatibility (in which case, your 3.30 shaders should say
#version 330 compatibility at the top), you should never use this.
Now, back to user-defined fragment shader outputs. But first, a quick analogy.
Remember how, in vertex shaders, you have inputs? And these inputs represent vertex attribute indices, the numbers you pass to
glEnableVertexAttribArray and so forth? You set up which input pulls from which attribute. In GLSL 3.30, you use this syntax:
layout(location = 2) in color;
This sets the
color vertex shader input to come from attribute location 2. Before 3.30 (or without ARB_explicit_attrib_location), you would have to either set this up explicitly with
glBindAttrbLocation before linking or query the program for the attribute index with
glGetAttribLocation. If you don't explicitly provide an attribute location, GLSL will assign a location arbitrarily (ie: in an implementation-defined manor).
Setting it in the shader is almost always the better option.
In any case, fragment shader outputs work almost exactly the same way. Fragment shaders can write to multiple buffers. Therefore, you need to indicate which output goes to which buffer.
This process begins with the fragment output location value. It's set very similarly to vertex shader input locations:
layout(location = 1) out secColor;
There are also the API functions
glGetFragDataLocation, which are analogous to
But there's one important difference. When you don't explicitly specify an attribute location, GL assigns them arbitrarily. When you don't explicitly specify a fragment shader output, GL 3.3 and above (that's a change from prior versions) will assign them all to location 0.
And this makes sense. The most common case is rendering a single output to a single buffer. Using the default draw buffer and the default framebuffer, location 0 is piped directly to the back buffer. If you use
glDrawBuffer to change what you render to, then you're changing what location 0 renders to. So everything just works.
Now to be fair, your program should have failed to link when you used two outputs that didn't get different output locations. What probably happened was that your compiler optimized the one you didn't write to out, so it kinda forgot about it when it came time to check for linker errors.