You're describing lists, so you could use DCGs for the task, since they usually yield easily readable code. Furthermore, you could use an additional argument to count the elements in the list as it's being traversed. Consider the following code:
list_filtered_length(L,F,Len) :- % the filtered list F is described
phrase(filtered_len(L,Len,0),F). % by the DCG filtered_len//3
filtered_len([],N,N) --> % if the list is empty, the counter is the length
[]. % and the filtered list is empty
filtered_len([(A,2)|Ps],N,C0) --> % if the head of the list is (A,2)
{C1 is C0+1}, % the counter is increased
[(A,2)], % (A,2) is in the filtered list
filtered_len(Ps,N,C1). % the same for the tail
filtered_len([(_,B)|Ps],N,C) --> % if the head of the list is (_,B)
{dif(B,2)}, % with B not being 2, it's not in the list
filtered_len(Ps,N,C). % the same for the tail
Querying this predicate with your example yields the desired result:
?- list_filtered_length([(1,2),(3,4),(5,2),(4,2),(8,0)],F,Len).
F = [ (1, 2), (5, 2), (4, 2)],
Len = 3 ;
false.
Obviously, if you want to apply a different filter, you have to rewrite the two recursive DCG rules. It would be nicer to have the filter defined as a separate predicate and to pass it as an argument, therefore making the predicate more versatile. It would also be nice to have the predicate succeed deterministically if there's only a single solution. This can be realized with if_/3 and (=)/3. In order to be used as the first argument of if_/3
, the filter predicate needs to reify its truth value as an additional argument:
filter_t((_,X),T) :-
if_(X=2,T=true,T=false).
As you can see, the last argument is true
if the filter condition holds and false
otherwise:
?- filter_t((1,1),T).
T = false.
?- filter_t((1,2),T).
T = true.
Now the predicate can be redefined with an additional argument for the filter like so:
list_filtered_by_length(L,LF,F_2,Len) :- % F_2 is the filter argument
phrase(filtered_by_len(L,F_2,Len,0),LF).
filtered_by_len([],_F_2,N,N) -->
[].
filtered_by_len([P|Ps],F_2,N,C0) -->
{if_(call(F_2,P),(X=[P], C1 is C0+1),
(X=[], C1 = C0))},
X, % X is in the filtered list
filtered_by_len(Ps,F_2,N,C1).
If the head of the list meets the filter condition (call(F_2,P)
), it is in the filtered list (X=[P]
) and the counter is increased (C1 is C0+1
), otherwise it is not in the list (X=[]
) and the counter is not increased (C1 = C0
).
Now the example query succeeds deterministically:
?- list_filtered_by_length([(1,2),(3,4),(5,2),(4,2),(8,0)],F,filter_t,Len).
F = [ (1, 2), (5, 2), (4, 2)],
Len = 3.
If you want to filter for something else, just define a different filter predicate. For example, if you want to filter all pairs of equal elements from a list of pairs, you can define...
filter2_t(X-Y,T) :-
if_(X=Y,T=true,T=false).
... and then query:
?- list_filtered_by_length([a-a,b-c,d-d,e-f],F,filter2_t,Len).
F = [a-a, d-d],
Len = 2.
EDIT
Alternatively, you can express this relation quite compactly by using tfilter/3, as suggested by @false in the comments. Just as with the DCG version you pass a reifying filter predicate as third argument that is then used as the first argument of tfilter/3
. Subsequently the length of the filtered list is described by the built-in length/2
.
list_filtered_by_length(L,FL,F_2,Len) :-
tfilter(F_2,L,FL),
length(FL,Len).
The above queries yield the same answers as with the DCG version.