Suppose we have a datatype of sorted lists, with proof-irrelevant sorting witnesses. We'll use Agda's experimental sized types feature, so that we can hopefully get some recursive functions over the datatype to pass Agda's termination checker.

```
{-# OPTIONS --sized-types #-}
open import Relation.Binary
open import Relation.Binary.PropositionalEquality as P
module ListMerge
{π β}
(A : Set π)
{_<_ : Rel A β}
(isStrictTotalOrder : IsStrictTotalOrder _β‘_ _<_) where
open import Level
open import Size
data SortedList (l u : A) : {ΞΉ : _} β Set (π β β) where
[] : {ΞΉ : _} β .(l < u) β SortedList l u {β ΞΉ}
_β·[_]_ : {ΞΉ : _} (x : A) β .(l < x) β (xs : SortedList x u {ΞΉ}) β
SortedList l u {β ΞΉ}
```

Now, a classic function one would like to define over such a data structure is `merge`

, which takes two sorted lists, and outputs a sorted list containing exactly the elements of the input lists.

```
open IsStrictTotalOrder isStrictTotalOrder
merge : β {l u} β SortedList l u β SortedList l u β SortedList l u
merge xs ([] _) = xs
merge ([] _) ys = ys
merge (x β·[ l<x ] xs) (y β·[ l<y ] ys) with compare x y
... | tri< _ _ _ = x β·[ l<x ] (merge xs (y β·[ _ ] ys))
merge (x β·[ l<x ] xs) (.x β·[ _ ] ys) | triβ _ P.refl _ =
x β·[ l<x ] (merge xs ys)
... | tri> _ _ _ = y β·[ l<y ] (merge (x β·[ _ ] xs) ys)
```

This function seems innocuous enough, except that it can be tricky to convince Agda that it's total. Indeed, without any explicit size indices, the function fails to termination-check. One option is to split the function into two mutually recursive definitions. This works, but adds a certain amount of redundancy to both the definition and associated proofs.

But equally, I'm not sure whether it is even possible to give size indices explicitly so that `merge`

has signature that Agda will accept. These slides discuss `mergesort`

explicitly; the signature given there suggests that the following should work:

```
mergeβ² : β {l u} β {ΞΉ : _} β SortedList l u {ΞΉ} β
{ΞΉβ² : _} β SortedList l u {ΞΉβ²} β SortedList l u
mergeβ² xs ([] _) = xs
mergeβ² ([] _) ys = ys
mergeβ² (x β·[ l<x ] xs) (y β·[ l<y ] ys) with compare x y
... | tri< _ _ _ = x β·[ l<x ] (mergeβ² xs (y β·[ _ ] ys))
mergeβ² (x β·[ l<x ] xs) (.x β·[ _ ] ys) | triβ _ P.refl _ =
x β·[ l<x ] (mergeβ² xs ys)
... | tri> _ _ _ = y β·[ l<y ] (merge' (x β·[ _ ] xs) ys)
```

Here what we're doing is allowing the inputs to have arbitrary (and different) sizes, and specifying that the output has size β.

Unfortunately, with this signature, Agda complains that `.ΞΉ != β of type Size`

, when checking the body `xs`

of the first clause of the definition. I don't claim to understand sized types very well, but I was under the impression that any size ΞΉ would unify with β. Perhaps the semantics of sized types have changed since those slides were written.

So, is my scenario a use-case for which sized type were intended? If so, how should I should use them? If sized types aren't appropriate here, why does the first version of `merge`

above not termination-check, given that the following does:

```
open import Data.Nat
open import Data.List
open import Relation.Nullary
merge : List β β List β β List β
merge (x β· xs) (y β· ys) with x β€? y
... | yes p = x β· merge xs (y β· ys)
... | _ = y β· merge (x β· xs) ys
merge xs ys = xs ++ ys
```

`mergeβ²`

work if you rebuild`xs`

and`ys`

with larger size, something like`promote : β {l u i} β SortedList l u {i} β SortedList l u {β}`

. – Vitus Feb 5 '14 at 0:40`id`

and that might keep the impact on proofs manageable. Thanks, I'll have a look at this when I get a chance. – Roly Feb 5 '14 at 0:47`FiniteMap`

type and`unionWith`

function I asked about before. It seems to work pretty well, so I've added a new answer to my previous question, based on sized types. As for this question, I would suggest promoting your comment to answer; that might make it more visible. – Roly Feb 5 '14 at 23:01