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So I was going through the orange book (3rd edition) and I came across a passage in chapter 9 about the invariant qualifier. And it says:

The invariant qualifier instructs the compiler and linked to ignore expressions and functions that are not directly related to the computation of the output.

This passage comes after two similar snippets of code:

uniform mat4 MVPmatrix;
// ...

in vec4 MCVertex;
// ...

a(); // does not modify gl_Position, MVP or MCVertex

// ...
// Transform vertex to clip space
gl_Position = MVP * MCVertex;

and

uniform mat4 MVPmatrix;
// ...

invariant gl_Position;
in vec4 MCVertex;
// ...

a(); // does not modify gl_Position, MVP or MCVertex

// ...
// Transform vertex to clip space
gl_Position = MVP * MCVertex;

The book then goes on to state:

The first case may or may not compute the transformed positions in exactly the same way no matter what unrelated function or expression is linked to the shader. This can cause problems in rendering if a multipass algorithm is used to render the same geometry more than once.

Which has me confused. If a() in no way affects the variables involved in calculating the transformed position, then how would the computation vary? (And how exactly does adding invariant help with that?). And referring to the first quote, what exactly do they mean by "ignoring the unrelated functions" ? Do they just not get executed?

2 Answers 2

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The purpose of invariant is to make sure the computation you're doing will result in the same result always, no matter what the shader optimizer will do to the shader (notably across multiple shader compilations).

I find the phrasing of the orange book to be poor (and misleading, as you've noted). The GLSL specification (language 1.2) section 4.6 is much clearer:

In this section, variance refers to the possibility of getting different values from the same expression in different programs. For example, say two vertex shaders, in different programs, each set gl_Position with the same expression in both shaders, and the input values into that expression are the same when both shaders run. It is possible, due to independent compilation of the two shaders, that the values assigned to gl_Position are not exactly the same when the two shaders run. In this example, this can cause problems with alignment of geometry in a multi-pass algorithm. In general, such variance between shaders is allowed. When such variance does not exist for a particular output variable, that variable is said to be invariant.

and it goes on to explain that the invariant qualifier gets you guarantees to avoid this issue.

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  • i dont think this answers the origin two questions . and the quote block neither
    – suitianshi
    Feb 26, 2014 at 13:02
  • @suitianshi: the OP wanted to understand invariant, and went on to dissect what the orange book had to say about it. The orange book content can essentially be considered wrong. So I elected to answer from the original source, the GLSL spec. The original questions are trying to understand wrong statements. What correct answer would you want?
    – Bahbar
    Feb 26, 2014 at 13:27
  • i found a page that describes why we would need a "invariant" sometimes. It says the multi-pass issue can be caused by cpu instructions reorder (and something else, sorry that I don't remember it clear and can't find the content again). For example, if i render a triangle twice with the same shader programs but during the two pass i get a sleep or go shopping, then the resulting two triangles may not overlap(of course, the offset can be really small). Actually i have read the GLSL spec, but still be confused.
    – suitianshi
    Feb 27, 2014 at 4:16
  • 1
    You might have read it right here, from Bartek's answer. That, to the best of my knowledge, is not true. I had taken Bartek's answer as hyperbole, and not actual things that do indeed create variance. I'd want to see an actual example of it before I believe it.FYI, I wrote GL drivers in the past, and was working on actually implementing that invariant keyword. It was all about shader compiler generating the exact same shader instruction stream. But... my own example doesn't make it necessarily always true.
    – Bahbar
    Feb 27, 2014 at 12:43
  • @Bahbar An upvote on my answer made me come back and see that comment. I'd say that your experience there is more than enough to explain what could happen in the driver, as those are always "human" takes at the spec. Back then I was actually working in a Driver Validation team so I can appreciate the difficulty of that problem. And yes, my answer obviously wasn't meant to be taken literally - rather than, it was supposed to point out that the context of the compilation could be different, in a broad sense. Apr 23, 2017 at 17:05
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invariant keyword is, (in short and in contrast to Bahbar's more detailed answer) more about very subtle computational differences that might appear in, as you've mentioned, multiple geometry passes.

Here's an example: You draw an arbitrary, weird (to make it harder) triangle on the screen. The rasterizer gets normalized vertices and calculates all the fragments that it occupies, then runs a fragment shader on it. Now, imagine you'd like to draw another triangle exactly on top of it, but 3 hours later, while your PC is submerged, the temperature drops and you eat a lunch in the meantime. You recompile the shaders then, and bam...

All of those potentially can impact the rasterizer. Shader optimizations might kick in and make minuscular changes to the output. Whilst still technically correct, the result doesn't necessarily have to be exactly the same as the first triangle, and "the problems" will be some pixel from the first one left over.

invariant ensures that a potentially slower approach is taken. I am not a driver architect, mind you, but in general that might mean a few additional state resets, cleanups, or sometimes state stack push/pops. Only then you're left with the "clean" computational state, and as long as your hardware is alright, the result should be exactly the same.

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