To model Prolog computations as expressively in Haskell, you need a backtracking monad. This is trivially done using the `LogicT`

monad. Your example as it stands translates to the following:

```
import Control.Monad.Logic
myFunc :: Int -> [Int] -> Logic [Int]
myFunc field acc = ifte (exitCond field acc) (\_-> return acc) $
(do f <- nextField field
guard $ test1 f
myFunc f acc)
`mplus`
(do f <- nextField field
guard $ test2 f
myFunc f (f:acc))
```

Assuming the following implementations for the functions and predicates:

```
nextField i = return (i+1)
test1 f = f < 10
test2 f = f < 20
exitCond f a = guard (f > 15)
```

You use `mplus`

to combine to `Logic`

computations so that if one fails it backtracks and tries the other one. `ifte`

is just a soft cut (there's no hard cut in `logict`

, although I believe it's trivial to implement since `logict`

is based on continuations) to exit when the exiting condition is true. You run your computation as follows:

```
Main> runLogic (myFunc 1 []) (\a r -> a:r) []
[[16,15,14,13,12,11,10],[16,15,14,13,12,11,10,9],[16,15,14,13,12,11,10,8]...
```

`runLogic`

takes the `Logic`

computation, a continuation and an initial value for the output of the continuation. Here I just passed a continuation which will accumulate all results in a list. The above will backtrack and get all solutions, unlike the Prolog example, since we used a soft cut instead of a hard cut. To stop backtracking after getting the first solution you can use `once`

:

```
Main> runLogic (once $ myFunc 1 []) (\a r -> a:r) []
[[16,15,14,13,12,11,10]]
```

you can also use `observe`

to observe the first solution only, without having to pass a continuation:

```
Main> observe (myFunc 1 [])
[16,15,14,13,12,11,10]
```

or even `obserMany`

and `observeAll`

:

```
observeMany 5 (myFunc 1 []) --returns the first 5 solutions
observerAll (myFunc 1 []) --returns a list of all solutions
```

Finally, you will need to install the `logict`

package to get the above code to work. Use `cabal install logict`

to install it.

**Edit: Answering your question in the comments**

Yes, you can do something similar without having to install `logict`

. Although a dedicated backtracking monad makes things less complicated and makes clear what you are trying to do.

To model the `logict`

example above you only need the `[]`

monad

```
myFunc :: Int -> [Int] -> [[Int]]
myFunc field acc | exitCond field acc = return acc
myFunc field acc = do
let m1 = do
f <- nextField field
guard $ test1 f
myFunc f acc
m2 = do
f <- nextField field
guard $ test2 f
myFunc f (f:acc)
in m1 `mplus` m2
nextField i = return $ i + 1
exitCond i a = i > 15
test1 i = i < 10
test2 i = i < 20
```

You can run it as follows:

```
Main> myFunc 1 []
[[16,15,14,13,12,11,10],[16,15,14,13,12,11,10,9],[16,15,14,13,12,11,10,8]...
```

You can also choose how many solutions you want as before:

```
Main> head $ myFunc 1 []
[16,15,14,13,12,11,10]
Main> take 3 $ myFunc 1 []
[[16,15,14,13,12,11,10],[16,15,14,13,12,11,10,9],[16,15,14,13,12,11,10,8]]
```

However, you will need the `Cont`

monad, and thus the `ListT`

monad, to implement a hard cut as in the Prolog example, which was not available in the `logict`

example above:

```
import Control.Monad.Cont
import Control.Monad.Trans.List
myFunc :: Int -> ListT (Cont [[Int]]) [Int]
myFunc field = callCC $ \exit -> do
let g field acc | exitCond field acc = exit acc
g field acc =
let m1 = do
f <- nextField field
guard $ test1 f
g f acc
m2 = do
f <- nextField field
guard $ test2 f
g f (f:acc)
in m1 `mplus` m2
g field []
```

Like Prolog, this last example will not backtrack again after `exitCond`

is satisfied:

```
*Main> runCont (runListT (myFunc 1)) id
[[16,15,14,13,12,11,10]]
```