To start with, let's redefine your predicates so they don't do any unnecessary I/O:

```
takeout(X,[X|R],R).
takeout(X,[F |R],[F|S]) :- takeout(X,R,S).
perm([X|Y],Z) :- perm(Y,W), takeout(X,Z,W).
perm([],[]).
```

Now you have what could be considered a "pure" permutation function:

```
?- perm([1,2,3], X).
X = [1, 2, 3] ;
X = [2, 1, 3] ;
X = [2, 3, 1] ;
X = [1, 3, 2] ;
X = [3, 1, 2] ;
X = [3, 2, 1] ;
false.
```

So, suppose you have a max_heap function that takes a list of values and produces a tree. I'll let you worry about that, so let's just posit that it exists and is called `max_heap/2`

and let's further posit that you have a way to display this attractively called `display_heap/1`

. To "take" the permutation and "send" it as a parameter to these functions, you're really saying in math-ese: suppose P is a permutation of X, let's make a max_heap with it and display it. Or, suppose P is a permutation of X, H is a max heap made from X, let's display H:

```
show_heaps(List) :- perm(List, P), max_heap(P, H), display_heap(H).
```

This says the same thing as my English sentence: suppose P is a permutation of the list, then H is a heap representation of it, then display it. Technically, `display_heap/1`

is still a predicate which could be true or false for a given heap. In practice, it will always be true, and if you run this you'll still have to hit `;`

repeatedly to say, give me another solution, unless you use a failure-driven loop or an extralogical predicate like `findall/3`

to cause all the solutions to be found.

**Edit**: Let's discuss failure-driven loops and `findall/3`

. First let me add some new predicates, because I don't know exactly what you're doing, but it doesn't matter for our purposes.

```
double([X|Xs], [Y|Ys]) :- Y is X*2, double(Xs, Ys).
double([],[]).
showlist(Xs) :- print(Xs).
```

So now I have a predicate `double/2`

which doubles the values in the list and a predicate `showlist/1`

that prints the list on standard output. We can try it out like so:

```
?- perm([1,2,3], X), double(X, Y), showlist(Y).
[2,4,6]
X = [1, 2, 3],
Y = [2, 4, 6] ;
[4,2,6]
X = [2, 1, 3],
Y = [4, 2, 6] ;
[4,6,2]
X = [2, 3, 1],
Y = [4, 6, 2] ;
[2,6,4]
X = [1, 3, 2],
Y = [2, 6, 4] ;
[6,2,4]
X = [3, 1, 2],
Y = [6, 2, 4] ;
[6,4,2]
X = [3, 2, 1],
Y = [6, 4, 2] ;
false.
```

When you type `;`

you're saying, "or?" to Prolog. In other words, you're saying "what else?" You're telling Prolog, in effect, this isn't the answer I want, try and find me another answer I like better. You can formalize this process with a failure-driven loop:

```
?- perm([1,2,3], X), double(X, Y), showlist(Y), fail.
[2,4,6][4,2,6][4,6,2][2,6,4][6,2,4][6,4,2]
false.
```

So now you see the output from each permutation having gone through `double/2`

there, and then Prolog reported false. That's what one means by something like this:

```
show_all_heaps(List) :- perm(List, X), double(X, Y), showlist(Y), nl, fail.
show_all_heaps(_).
```

Look at how that works:

```
?- show_all_heaps([1,2,3]).
[2,4,6]
[4,2,6]
[4,6,2]
[2,6,4]
[6,2,4]
[6,4,2]
true.
```

The other option is using `findall/3`

, which looks more like this:

```
?- findall(Y, (perm([1,2,3], X), double(X, Y)), Ys).
Ys = [[2, 4, 6], [4, 2, 6], [4, 6, 2], [2, 6, 4], [6, 2, 4], [6, 4, 2]].
```

Using this to solve your problem is probably beyond the scope of whatever homework it is you're working on though.