Let's try to solve a simple problem using `if_/3`

; for example, I will try to partition a list (sorted on a predicate `p/2`

) in two lists: a prefix in which, for every element `X`

, we have `p(X, true)`

, and a rest (in which, if the list was sorted on `p/2`

, we would have `p(X, false)`

.

I will use the library `reif`

as here. So, here is the complete code of my program:

```
:- use_module(reif).
pred_prefix(Pred_1, List, L_true, L_false) :-
pred_prefix_aux(List, Pred_1, L_true, L_false).
pred_prefix_aux([], _, [], []).
pred_prefix_aux([X|Xs], Pred_1, True, False) :-
if_( call(Pred_1, X),
( True = [X|True0],
pred_prefix_aux(Xs, Pred_1, True0, False)
),
( True = [],
False = [X|Xs]
)
).
```

The predicate passed to this meta-predicate will take two arguments: the first is the current list element, and the second will be either `true`

or `false`

. Ideally, this predicate will always succeed and not leave behind choice points.

In the first argument of `if_/2`

, the predicate is evaluated with the current list element; the second argument is what happens when `true`

; the third argument is what happens when `false`

.

With this, I can split a list in leading `a`

s and a rest:

```
?- pred_prefix([X, B]>>(=(a, X, B)), [a,a,b], T, F).
T = [a, a],
F = [b].
?- pred_prefix([X, B]>>(=(a, X, B)), [b,c,d], T, F).
T = [],
F = [b, c, d].
?- pred_prefix([X, B]>>(=(a, X, B)), [b,a], T, F).
T = [],
F = [b, a].
?- pred_prefix([X, B]>>(=(a, X, B)), List, T, F).
List = T, T = F, F = [] ;
List = T, T = [a],
F = [] ;
List = T, T = [a, a],
F = [] ;
List = T, T = [a, a, a],
F = [] .
```

How can you get rid of leading 0's for example:

```
?- pred_prefix([X, B]>>(=(0, X, B)), [0,0,1,2,0,3], _, F).
F = [1, 2, 0, 3].
```

Of course, this could have been written much simpler:

```
drop_leading_zeros([], []).
drop_leading_zeros([X|Xs], Rest) :-
if_(=(0, X), drop_leading_zeros(Xs, Rest), [X|Xs] = Rest).
```

Here I have just removed all unnecessary arguments.

If you would have to do this *without* `if_/3`

, you would have had to write:

```
drop_leading_zeros_a([], []).
drop_leading_zeros_a([X|Xs], Rest) :-
=(0, X, T),
( T == true -> drop_leading_zeros_a(Xs, Rest)
; T == false -> [X|Xs] = Rest
).
```

Here, we assume that `=/3`

will indeed always succeed without choice points and the `T`

will always be either `true`

or `false`

.

And, if we didn't have `=/3`

either, you'd write:

```
drop_leading_zeros_full([], []).
drop_leading_zeros_full([X|Xs], Rest) :-
( X == 0 -> T = true
; X \= 0 -> T = false
; T = true, X = 0
; T = false, dif(0, X)
),
( T == true -> drop_leading_zeros_full(Xs, Rest)
; T == false -> [X|Xs] = Rest
).
```

which is not ideal. But now at least you can see for yourself, in one single place, what is actually going on.

PS: Please read the code and the top level interaction carefully.

`true`

or`false`

("reification"), otherwise an error is thrown.`=/3`

, right below`if_/3`

, from your own link, where you see what it takes to write a predicate that plays along nicely with`if_/3`

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