I have a (SWI-)Prolog program that uses CLP(FD) variables in an utterly massive way (²). I am moving lists of CLP(FD) items in and out of several predicates (¹), and their constraints grow exponentially. My code works for small lists, but when I try to use it for long lists of elements (where the amount of constraints for each element becomes enormous) I end up with an **Out of global stack** error.

My point is whether I can use a different method for passing such huge arguments without using the stack. My first thought was to use `asserta`

to store the intermediate results in the dynamic database but I'm not sure if I'll be able to store uninstantiated variables or CLP(FD) constraints that way. And I don't know if this is an optimal solution either...

**¹ MORE DETAILS:** What I need is an overlap of N lists of length L where the first elements are offseted. However, the offsets are not bound but are CLP(FD) variables.

**² EVEN MORE DETAILS:** Basically, I have a number of lists where each element has thousands of constraints. Each element constraints are basically holding information about its value, which is linked to a "*master-variable*" value. Depending on the *master-variable*'s value, each list item will have a value or another.

Since I already had problems with the implementation of such list generator and I asked here for some advice, you can see the actual list-maker predicate, `overlap_at/5`

, here.

`overlap_lists/4`

is the predicate which is issuing the error (it **does** work fine for `Rs`

's lengths of less than 140 elements AND less than 10 `Cs`

elements):

```
% Cs -> lists that have to be overlapped. Their items are integers.
% Ss -> Offsets per each list. They are CLP(FD) variables.
% Rs -> (not important here)
% Os -> List of overlapped elements.
overlap_lists(Cs,Ss,Rs,Os) :-
length(Rs,L),
zeros(Zs,L), % The initial list to overlap with is a list filled with zeros.
overlap(Cs,Ss,Zs,Os),
list_limit(Os,Rs). % Constrains the consumptions
overlap([],[],Fs,Fs) :- !.
overlap([C|Cs],[S|Ss],Os,Fs) :-
fd_inf(S,Inf),
overlap_at(Os,C,S,Inf,Os2),!,
overlap(Cs,Ss,Os2,Fs).
overlap_at([], _, _, _, []).
overlap_at([A|As], Bs, S, N0, [AB|ABs]) :-
overlap_here(Bs, [A|As], [AB|ABs], Conj),
S #= N0 #==> Conj,
S #> N0 #==> AB #= A,
N1 #= N0 + 1,
overlap_at(As, Bs, S, N1, ABs).
overlap_here(_, [], _, 1) :- !.
overlap_here([], [A|As], [AB|ABs], (AB #= A #/\ Rest)) :-
overlap_here([], As, ABs, Rest).
overlap_here([B|Bs], [A|As], [AB|ABs], (AB #= A + B #/\ Rest)) :-
overlap_here(Bs, As, ABs, Rest).
```