Besides being declarative, functional programming encompasses the ability to abstract fundamental requirements of concrete types, that is, generic programming. Your algorithms will be applicable in a general way as long as the requirements (F# calls them constraints) are met, independent of concrete data structures.
As stated in your problem description, you might have a sequence (the most general data structure for an ordered collection of objects) of anything, from which the key can be extracted. Those keys shall be tested for inequality, so there's an equality constraint. Relying on the order of the sequence, the anythings are unconstrained. Represented as a F# signature, your input data is described by source:seq<'T>
and the key projection function as projection:('T -> 'Key) when 'Key : equality
.
As a complete function signature, I would like to suggest projection:('T -> 'Key) -> source:seq<'T> -> seq<'T * 'T> when 'Key : equality
. Returning a sequence of pairs avoids introducing an additional type parameter. It matches the input, except for some selective rearrangement. Here's a possible implementation of this function, with no claims on efficiency or even correctness. Note that the equality constraint on 'Key
is inferred, never explicitly spelled out.
let whenKeyChanges (projection : 'T -> 'Key) (source : seq<'T>) =
// Wrap in option to mark start and end of sequence
// and compute value of every key once
seq{ yield None
yield! Seq.map (fun x -> Some(x, projection x)) source
yield None }
// Create tuples of adjacent elements in order to
// test their keys for inequality
|> Seq.pairwise
// Project to singleton in case of the first and the
// last element of the sequence, or to a two-element
// sequence if keys are not equal; concatenate the
// results to obtain a flat sequence again
|> Seq.collect (function
| None, Some x | Some x, None -> [x]
| Some(_, kx as x), Some(_, ky as y)
when kx <> ky -> [x; y]
| _ -> [] )
// Create tuples of adjacent elements a second time.
|> Seq.pairwise
// Only the first and then every other pair will contain
// indentical keys
|> Seq.choose (fun ((x, kx), (y, ky)) ->
if kx = ky then Some(x, y) else None )
Sample application on a concrete (X * string) list
, the key being X. It works just as well on your seq<record>
when the key is fetched by (fun r -> r.Name)
.
type X = A | B | C
[ A, "10:01"
A, "10:02"
A, "10:03"
B, "11:15"
B, "11:25"
B, "11:30"
C, "12:00"
A, "13:01"
A, "13:05" ] |> whenKeyChanges fst
// val it : seq<(X * string) * (X * string)> =
// seq
// [((A, "10:01"), (A, "10:03")); ((B, "11:15"), (B, "11:30"));
// ((C, "12:00"), (C, "12:00")); ((A, "13:01"), (A, "13:05"))]