# Looping vs recursion with F#

The example code here solves a project Euler problem:

Starting with the number 1 and moving to the right in a clockwise direction a 5 by 5 spiral is formed as follows:

`````` 21 22 23 24 25
20  7  8  9 10
19  6  1  2 11
18  5  4  3 12
17 16 15 14 13
``````

It can be verified that the sum of the numbers on the diagonals is 101.

What is the sum of the numbers on the diagonals in a 1001 by 1001 spiral formed in the same way?

but my question is a matter of functional programming style rather than about how to get the answer (I already have it). I am trying to teach myself a bit about functional programming by avoiding imperative loops in my solutions, and so came up with the following recursive function to solve problem 28:

``````let answer =
let dimensions = 1001
let max_number = dimensions * dimensions

let rec loop total increment increment_count current =
if current > max_number then total
else
let new_inc, new_inc_count =
if increment_count = 4 then increment + 2, 0
else increment, increment_count + 1
loop (total + current) new_inc new_inc_count (current + increment)
loop 0 2 1 1
``````

However, it seems to me my function is a bit of a mess. The following imperative version is shorter and clearer, even after taking into account the fact that F# forces you to explicitly declare variables as mutable and doesn't include a += operator:

``````let answer =
let dimensions = 1001
let mutable total = 1
let mutable increment = 2
let mutable current = 1

for spiral_layer_index in {1..(dimensions- 1) / 2} do
for increment_index in {1..4} do
current <- current + increment
total <- total + current
increment <- increment + 2
total
``````

Disregarding the fact that people with more maths ability have solved the problem analytically, is there a better way to do this in a functional style? I also tried using Seq.unfold to create a sequence of values and then piping the resulting sequence into Seq.sum, but this ended up being even messier than my recursive version.

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both of your algorithms look messy because of variable names. I solved that problem and stared for 10 minutes into your code but still didn't got what is your intention in each line. Especially when you name variables like `a` and `b`. Whether you use loop or recursion here doesn't matter. –  Snowbear Mar 5 '12 at 1:07
I've edited the variable names to be a bit more useful –  junichiro Mar 5 '12 at 1:27
BTW: Your imperative solution produces different result than the functional solution. –  Tomas Petricek Mar 5 '12 at 1:52
now edited so they give the same answer –  junichiro Mar 5 '12 at 2:02

Since you didn't describe the problem you're trying to solve, this answer is based only on the F# code you posted. I agree that the functional version is a bit messy, but I believe it could be clearer. I don't really understand the nested `for` loop in your imperative solution:

``````for increment_index in {1..4} do
current <- current + increment
total <- total + current
``````

You're not using the `increment_index` for anything, so you could just multiply `increment` and `current` by four and get the same result:

``````total <- total + 4*current + 10*increment
current <- current + 4*increment
``````

``````let mutable total = 0
let mutable increment = 2
let mutable current = 1

for spiral_layer_index in {1..(dimensions- 1) / 2} do
total <- total + 4*current + 10*increment
current <- current + 4*increment
increment <- increment + 2
total
``````

If you rewrite this to a recursive function, it becomes just:

``````let rec loop index (total, current, increment) =
if index > (dimensions - 1) / 2 then total
else loop (index + 1) ( total + 4*current + 10*increment,
current + 4*increment, increment + 2 )
let total = loop 1 (0, 2, 1)
``````

The same thing could be also written using `Seq.fold` like this (this is even more "functional", because in functional programming, you use recursion only to implement basic functions, like `fold` that can then be re-used):

``````let total, _, _=
{1 .. (dimensions - 1) / 2} |> Seq.fold (fun (total, current, increment) _ ->
(total + 4*current + 10*increment, current + 4 * increment, increment + 2)) (0, 1, 2)
``````

NOTE: I'm not sure if this actually implements what you want. It is just a simplification of your imperative solution and then rewrite of that using a recursive function...

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In fact, this is Project Euler Problem 28 and my F# solution circa November 21, 2011 is quite similar to one suggested in Tomas' answer:

``````let problem028 () =
[1..500]
|> List.fold (fun (accum, last) n ->
(accum + 4*last + 20*n, last + 8*n)) (1,1)
|> fst
``````

Indeed, solution of the original problem takes just one-liner simple fold over the list of all involved squares with corners at diagonal nodes while threading through the accumulated sum and value of current diagonal element. Folding is one of the major idioms of functional programming; there is a great classic paper A tutorial on the universality and expressiveness of fold that covers many important facets of this core pattern.

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Here's more of a direct translation of your imperative solution.

``````let answer =
let dimensions = 1001
let sMax = (dimensions - 1) / 2
let iMax = 4

let rec spiral total increment s current =
let rec innerLoop total i current =
if i <= iMax then
let current = current + increment
innerLoop (total + current) (i + 1) current
else
total, current

if s <= sMax then
let total, current = innerLoop total 1 current
spiral total (increment + 2) (s + 1) current
else
total

spiral 1 2 1 1
``````
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