There are several issues here, let's start first with the most obvious:

## Modeling problems

You have a relation (`result/2`

is maybe not the best name), and this relation is supposed to model when `decline`

and when `offer`

should be true. Before reading your program, I prefer to ask Prolog:

?- result(X, decline), result(X, offer).
X in 11..20 ;
false.

So for the values from 11 up to 20, your relation is ambiguous. If you want to make a decision, then fix this relation first. Actually, I would start with

- a better name for the relation that makes clear it is a relation
- no imperative verbiage (like
`Input`

or imperatives)
- a more compact formulation, you don't need so many
`(=)/2`

goals in your program. Instead, you can write it like:

heigth_decision(I, decline) :-
I #< 10.

## Answers and success vs. solutions in CLP

And then there is another problem which is more fundamental. This is actually much more serious, since all the SO-answers given so far ignore this aspect entirely. It is about the notion of answers and success and on the other hand the notion of solutions.

When you ask a query in Prolog - what you get back is an **answer**. Such an answer might contain solutions, like the answer `L = [_,_]`

which contains infinitely many solutions. Or an answer may contain exactly one solution like `Decision = decline`

. But there is much more in between if you are using constraints like `library(clpfd)`

.

You can now get finitely many solutions:

?- abs(X) #< 3.
X in -2..2.

Or infinitely many:

?- X #> Y.
Y#=<X+ -1.

But you can get also exactly one solution, which does not look like one:

?- 2^X #= 1.
2^X#=1.

So, just to restate this: We have here exactly one solution in the integers, but for Prolog this is way too complex. What we got back was an answer that states: Yes that is all true, provided _{all this fine print is true}.

Worse, sometimes we get answers back that do not contain any solution.

?- X^X#=0.
X^X#=0.

If Prolog would be smart enough, it would answer `false`

. But it cannot be always that smart, simply because you can easily formulate undecidable problems. Such an answer is sometimes called **inconsistency**. The German notion **Scheinlösung** (~fake solution, but with less negative connotation) conveys the idea a bit better.

So an answer may contain solutions, but some answers do not contain solutions at all. For this reason, the success of a goal cannot be taken as the existence of a solution! That is, all SO-answers suggesting some kind of commit as (;)/2 – if-then-else, once/1, or !/0 are all incorrect, if they take the success as a solution. To see this, try them with:

?- X^X#=0, result(X,decline).
X in 11..sup,
X^X#=0 ;
false.
?- X^X#=0, result(X,offer).
X in 0..20,
X^X#=0.

So how can you now be sure of anything?

You can rely on the failure of a goal.

You can try `labeling/2`

, but this only works on finite domains.

You can use `call_residue_vars/2`

and `copy_term/3`

to determine if there are constraints "hanging around"

Unfortunately, you cannot entirely rely on SWI's toplevel which hides constraints that are unrelated to the variables in an answer. Only SICStus does display them correctly.

isan order within clauses of a predicate. I think changing the constraints for the Input variable is the solution here. – gusbro Nov 22 '12 at 14:56`Input=15`

, then the second goal should not be considered anymore" means that "all possible answers" should be just`[decline]`

, right? – larsmans Nov 22 '12 at 15:09`Result=decline`

if`Input in 11..sup`

and`Result=offer`

if`Input in 0..10`

– ri5b6 Nov 22 '12 at 15:11