Here's the rule for function sub-typing:

**Argument types must be co-variant, return types must be contra-variant.**

Co-variant == preserves the "A is a subtype of B" hierarchy for the type of the results parameter. Contra-variant == *reverses* ("goes against") the type hierarchy for the arguments parameter.

So, in your example:

```
f1: int -> bool
f2: bool -> bool
```

We can safely conclude that f2 is a subtype of f1. Why? Because (1) looking at just the argument types for both functions, we see that the type hierarchy of "bool is a subtype of int" is in fact co-variant. It preserves the type hierarchy between ints and bools. (2) looking at just the results types for both functions, we see that contra-variance is upheld.

Put another way (the plain English way I think about this subject):

co-variant arguments: "my caller can pass in *more* than I require, but that's okay, because I'll use only what I need to use."
contra-variant arguments: "I can return *more* than the caller requires, but that's okay, he/she will just use what they need, and will ignore the rest"

Let's look at another examples, using structs where everything is an integer:

```
f1: {x,y,z} -> {x,y}
f2: {x,y} -> {x,y,z}
```

So here again, we're asserting that f2 is a subtype of f1 (which it is). Looking at the argument types for both functions (and using the < symbol to denote "is a subtype of"), then if f2 < f1, is {x,y,z} < {x,y} ? The answer is yes. {x,y,z} is co-variant with {x,y}. i.e. in defining the struct {x,y,z} we "inherited" from the {x,y} struct, but added a third member, z.

Looking at the return types for both functions, if f2 < f1, then is {x,y} > {x,y,z}? The answer again is yes. (See above logic).

Yet a third way to think about this, is to assume f2 < f1, then try various casting scenarios, and see if everything works. Example (psuedo-code):

```
F1 = f1;
F2 = f2;
{a,b} = F1({1,2,3}); // call F1 with a {x,y,z} struct of {1,2,3}; This works.
{a,b,c} = F2({1,2}); // call F2 with a {x,y} struct of {1,2}. This also works.
// Now take F2, but treat it like an F1. (Which we should be able to do,
// right? Because F2 is a subtype of F1). Now pass it in the argument type
// F1 expects. Does our assignment still work? It does.
{a,b} = ((F1) F2)({1,2,3});
```