There are actually two different ways of implementing continuation builders in F#. One is to represent delayed computations using the monadic type (if it supports some way of representing delayed computations, like `Async<'T>`

or the `unit -> option<'T>`

type as shown by kkm.

However, you can also use the flexibility of F# computation expressions and use a different type as a return value of `Delay`

. Then you need to modify the `Combine`

operation accordingly and also implement `Run`

member, but it all works out quite nicely:

```
type OptionBuilder() =
member x.Bind(v, f) = Option.bind f v
member x.Return(v) = Some v
member x.Zero() = Some ()
member x.Combine(v, f:unit -> _) = Option.bind f v
member x.Delay(f : unit -> 'T) = f
member x.Run(f) = f()
member x.While(cond, f) =
if cond() then x.Bind(f(), fun _ -> x.While(cond, f))
else x.Zero()
let maybe = OptionBuilder()
```

The trick is that F# compiler uses `Delay`

when you have a computation that needs to be delayed - that is: 1) to wrap the whole computation, 2) when you sequentially compose computations, e.g. using `if`

inside the computation and 3) to delay bodies of `while`

or `for`

.

In the above definition, the `Delay`

member returns `unit -> M<'a>`

instead of `M<'a>`

, but that's perfectly fine because `Combine`

and `While`

take `unit -> M<'a>`

as their second argument. Moreover, by adding `Run`

that evaluates the function, the result of `maybe { .. }`

block (a delayed function) is evaluated, because the whole block is passed to `Run`

:

```
// As usual, the type of 'res' is 'Option<int>'
let res = maybe {
// The whole body is passed to `Delay` and then to `Run`
let! a = Some 3
let b = ref 0
while !b < 10 do
let! n = Some () // This body will be delayed & passed to While
incr b
if a = 3 then printfn "got 3"
else printfn "got something else"
// Code following `if` is delayed and passed to Combine
return a }
```

This is a way to define computation builder for non-delayed types that is most likely more efficient than wrapping type inside a function (as in kkm's solution) and it does not require defining a special delayed version of the type.

Note that this problem does not happen in e.g. Haskell, because that is a lazy language, so it does not need to delay computations explicitly. I think that the F# translation is quite elegant as it allows dealing with both types that are delayed (using `Delay`

that returns `M<'a>`

) and types that represent just an immediate result (using `Delay`

that returns a function & `Run`

).

`let delay f = fun () -> f()`

? – Daniel Jan 27 '12 at 23:10`Maybe`

monad implementation in FSharpx github.com/fsharp/fsharpx/blob/master/src/FSharpx.Core/Monad.fs ? – pad Jan 27 '12 at 23:45`Delay f = f`

and`Run f = f()`

should probably work, assuming that you adjust the types of`While`

,`Combine`

, etc. accordingly. – kvb Jan 28 '12 at 3:02`delay`

with a type`(unit -> M<'T>) -> (unit -> M<'T>)`

(as suggested by @kvb). If you modify the remaining definitions to match this type, everything will work just fine. See my answer for more complex definition. (The trick is that computation builder can simply use different type for non-delayed and delayed computations). – Tomas Petricek Jan 28 '12 at 16:53