After writing this article I decided to put my money where my mouth is and started to convert a previous project of mine to use `recursion-schemes`

.

The data structure in question is a lazy kdtree. Please have a look at the implementations with explicit and implicit recursion.

This is mostly a straightforward conversion along the lines of:

```
data KDTree v a = Node a (Node v a) (Node v a) | Leaf v a
```

to

```
data KDTreeF v a f = NodeF a f f | Leaf v a
```

Now after benchmarking the whole shebang I find that the `KDTreeF`

version is about **two times slower** than the *normal* version (find the whole run here).

Is it just the additional `Fix`

wrapper that slows me down here? And is there anything I could do against this?

## Caveats:

- At the moment this is specialized to (V3 Double).
- This is cata- after anamorphism application. Hylomorphism isn't suitable for kdtrees.
- I use
`cata (fmap foo algebra)`

several times. Is this good practice? - I use Edwards
`recursion-schemes`

package.

## Edit 1:

Is this related? https://ghc.haskell.org/trac/ghc/wiki/NewtypeWrappers
Is `newtype Fix f = Fix (f (Fix f))`

not "free"?

## Edit 2:

Just did another bunch of benchmarks. This time I tested tree construction and deconstruction. Benchmark here: https://dl.dropboxusercontent.com/u/2359191/2014-05-15-kdtree-bench-03.html

While the Core output indicates that intermediate data structures are not removed completely and it is not surprising that the linear searches dominate now, the `KDTreeF`

s now are slightly faster than the `KDTree`

s. Doesn't matter much though.

`data KDTree v a = Node a (Identity (Node v a)) (Identity (Node v a)) | Leaf v a`

, just to see if the extra indirection is the culprit. Make sure`Identity`

is not a`newtype`

. – chi May 14 '14 at 20:24_nntests are wrapped in`data Identity a = MkId { unId :: a}`

as you suggested. I'd say it is slower now ... but not as slow as the morphism version. – fho May 14 '14 at 20:46