# Rewriting C# code in F#

Just messing about with F# and I was trying to create a basic Lagrange Interpolation function based on this C# version (copied from a C++ wiki entry):

``````    double Lagrange(double[] pos, double[] val, double desiredPos)
{
double retVal = 0;

for (int i = 0; i < val.Length; ++i)
{
double weight = 1;

for (int j = 0; j < val.Length; ++j)
{
// The i-th term has to be skipped
if (j != i)
{
weight *= (desiredPos - pos[j]) / (pos[i] - pos[j]);
}
}

retVal += weight * val[i];
}

return retVal;
}
``````

The best I could come up with using my limited knowledge of F# and functional programming was:

``````let rec GetWeight desiredPos i j (pos : float[]) weight =
match i with
| i when j = pos.Length -> weight
| i when i = j -> GetWeight desiredPos i (j+1) pos weight
| i -> GetWeight desiredPos i (j+1) pos (weight * (desiredPos - pos.[j])/(pos.[i] - pos.[j]) )

let rec Lagrange (pos : float[]) (vals : float[]) desiredPos result counter =
match counter with
| counter when counter = pos.Length -> result
| counter -> Lagrange pos vals desiredPos (result + (GetWeight desiredPos counter 0 pos 1.0)* vals.[counter]) (counter+1)
``````

Can someone provide a better/tidier F# version based on the same C# code?

-
I think this is a good example of when imperative code is easier to read and maintain than functional. –  gradbot Oct 21 '09 at 15:52

Folding over sequences is a common way to replace loops with an accumulator.

``````let Lagrange(pos:_[], v:_[], desiredPos) =
seq {0 .. v.Length-1}
|> Seq.fold (fun retVal i ->
seq {for j in 0 .. pos.Length-1 do if i <> j then yield j}
|> Seq.fold (fun w j -> w * (desiredPos - pos.[j]) / (pos.[i] - pos.[j])) 1.0
|> (fun weight -> weight * v.[i] + retVal)) 0.0
``````
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Thanks for the edit Brian. –  gradbot Oct 21 '09 at 20:07

The part that makes your functional solution ugly is skipping the i'th element, which means indices. Pull that out into a reusable function so that all the ugly index handling is isolated. I call mine RoundRobin.

``````let RoundRobin l = seq {
for i in {0..Seq.length l - 1} do
yield (Seq.nth i l, Seq.take i l |> Seq.append <| Seq.skip (i+1) l)
}
``````

It could be a lot uglier if you want to produce an efficient version, though.

I couldn't find `product` in the Seq module, so I wrote my own.

``````let prod (l : seq<float>) = Seq.reduce (*) l
``````

Now producing the code is fairly simple:

``````let Lagrange pos value desiredPos = Seq.sum (seq {
for (v,(p,rest)) in Seq.zip value (RoundRobin pos) do
yield v * prod (seq { for p' in rest do yield (desiredPos - p') / (p - p') })
})
``````

RoundRobin ensures that pos[i] is not included with the rest of pos in the inner loop. To include the `val` array, I zipped it with the round-robinned `pos` array.

The lesson here is that indexing is very ugly in a functional style. Also I discovered a cool trick: `|> Seq.append <|` gives you infix syntax for appending sequences. Not quite as nice as `^` though.

-

I think this works fine as imperative code:

``````let LagrangeI(pos:_[], v:_[], desiredPos) =
let mutable retVal = 0.0
for i in 0..v.Length-1 do
let mutable weight = 1.0
for j in 0..pos.Length-1 do
// The i-th term has to be skipped
if j <> i then
weight <- weight * (desiredPos - pos.[j]) / (pos.[i] - pos.[j])
retVal <- retVal + weight * v.[i]
retVal
``````

but if you want functional, some folds (along with mapi since you often need to carry the indices along) work well:

``````let LagrangeF(pos:_[], v:_[], desiredPos) =
v |> Seq.mapi (fun i x -> i, x)
|> Seq.fold (fun retVal (i,vi) ->
let weight =
pos |> Seq.mapi (fun j x -> j<>i, x)
|> Seq.fold (fun weight (ok, posj) ->
if ok then
weight * (desiredPos - posj) / (pos.[i] - posj)
else
weight) 1.0
retVal + weight * vi) 0.0
``````

I don't know the math here, so I used some random values to test to (hopefully) ensure I screwed nothing up:

``````let pos = [| 1.0; 2.0; 3.0 |]
let v = [|8.0; 4.0; 9.0 |]

printfn "%f" (LagrangeI(pos, v, 2.5))  // 5.375
printfn "%f" (LagrangeF(pos, v, 2.5))  // 5.375
``````
-
You could also do away with mapi by having your fold accumulator be a tuple containing the index. v |> fold (fun (retVal, i) posi -> newRetValuefunction, i+1) (0.0, 0) –  gradbot Oct 21 '09 at 20:48
This does produce the same answers as the original C# code for my data –  Matt Clarke Oct 22 '09 at 7:51

Here's a non-recursive solution. It's a bit funky because the algorithm requires indices, but hopefully it shows how F#'s functions can be composed:

``````let Lagrange (pos : float[]) (vals : float[]) desiredPos =
let weight pos desiredPos (i,v) =
let w = pos |> Array.mapi (fun j p -> j,p)
|> Array.filter (fun (j,p) -> i <> j)
|> Array.fold (fun acc (j,p) -> acc * (desiredPos - p)/(pos.[i] - p)) 1.
w * v
vals |> Array.mapi (fun i v -> i,v)
|> Array.sumBy (weight pos desiredPos)
``````
-
``````            let rec GetWeight desiredPos i j (pos : float[]) weight =
if j = pos.Length then weight
elif i = j then GetWeight desiredPos i (j+1) pos weight
else GetWeight desiredPos i (j+1) pos (weight * (desiredPos - pos.[j])/(pos.[i] - pos.[j]) )

let rec Lagrange (pos : float[]) (vals : float[]) desiredPos result counter =
if counter = pos.Length then result
else Lagrange pos vals desiredPos (result + (GetWeight desiredPos counter 0 pos 1.0)* vals.[counter]) (counter+1)
``````

Personally I think that simple if/elif/else constructs look here much better without such overheads as

``````match i with
|i when i=...
``````
-

If you're just messing about then here's a version similar to Brian's that uses function currying and the tuple pipe operator.

``````let Lagrange(pos:_[], v:_[], desiredPos) =
let foldi f state = Seq.mapi (fun i x -> i, x) >> Seq.fold f state
(0.0, v) ||> foldi (fun retVal (i, posi) ->
(1.0, pos) ||> foldi (fun weight (j, posj) ->
if j <> i then
(desiredPos - posj) / (posi - posj)
else
1.0)
|> (fun weight -> weight * posi + retVal))
``````
-

My attempt:

``````let Lagrange(p:_[], v, desiredPos) =
let Seq_multiply = Seq.fold (*) 1.0
let distance i j = if (i=j) then 1.0 else (desiredPos-p.[j])/(p.[i]-p.[j])
let weight i = p |> Seq.mapi (fun j _ -> distance i j) |> Seq_multiply
v |> Seq.mapi (fun i vi -> (weight i)*vi) |> Seq.sum
``````

Refactor by making the inner loop a function. Also we can make the code more straightforward and "understandable" by defining some meaningful functions.

Also, this rewrite highlights a bug in your original code (and all other variants). The distance function should actually be:

``````let distance i j = if (p.[i]=p.[j]) then 1.0 else (desiredPos-p.[j])/(p.[i]-p.[j])
``````

to avoid the general div-by-zero error. This leads to a generic and indexless solution:

``````let Lagrange(p, v, desiredPos) =
let distance pi pj = if (pi=pj) then 1.0 else (desiredPos-pj)/(pi-pj)
let weight pi vi = p |> Seq.map (distance pi) |> Seq.fold (*) vi
Seq.map2 weight p v |> Seq.sum
``````
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