Since the `_+_`

-Operation for `Nat`

is usually defined recursively in the first argument, its obviously non-trivial for the type-checker to know that `i + 0 == i`

. However, I frequently run into this issue when I write functions on fixed-size Vectors.

One example: How can I define an Agda-function

```
swap : {A : Set}{m n : Nat} -> Vec A (n + m) -> Vec A (m + n)
```

which puts the first `n`

values at the end of the vector?

Since a simple solution in Haskell would be

```
swap 0 xs = xs
swap n (x:xs) = swap (n-1) (xs ++ [x])
```

I tried it analogously in Agda like this:

```
swap : {A : Set}{m n : Nat} -> Vec A (n + m) -> Vec A (m + n)
swap {_} {_} {zero} xs = xs
swap {_} {_} {suc i} (x :: xs) = swap {_} {_} {i} (xs ++ (x :: []))
```

But the type checker fails with the message (which relates to the the `{zero}`

-case in the above `swap`

-Definition):

```
.m != .m + zero of type Nat
when checking that the expression xs has type Vec .A (.m + zero)
```

So, my question: How to teach Agda, that `m == m + zero`

? And how to write such a `swap`

Function in Agda?

`n`

) implicit in your signature of`swap`

, since Agda won't be able to infer it. – copumpkin Oct 19 '12 at 3:49`swap`

is used)? – phynfo Oct 19 '12 at 13:14`Vec Nat (5 + 3)`

. That addition will reduce the type immediately to`Vec Nat 8`

, which Agda will then try to unify with`Vec A (n + m)`

and will then throw its hands up in the air (i.e., make your term yellow) because it can't magically do subtraction. I'm reasonably sure that even with Agda's fancy Miller pattern unification, there won't be any cases where it can infer`n`

and`m`

from context. – copumpkin Oct 19 '12 at 14:24