I'm trying to duplicate the behavior of the standard length/2 predicate. In particular, I want my predicate to work for bounded and unbounded arguments, like in the example below:
% Case 1 ?- length(X, Y). X = , Y = 0 ; X = [_G4326], Y = 1 ; X = [_G4326, _G4329], Y = 2 ; X = [_G4326, _G4329, _G4332], Y = 3 . % Case 2 ?- length([a,b,c], X). X = 3. % Case 3 ?- length(X, 4). X = [_G4314, _G4317, _G4320, _G4323]. % Case 4 ?- length([a,b,c,d,e], 5). true.
The plain&simple implementation:
my_length(, 0). my_length([_|T], N) :- my_length(T, X), N is 1+X.
has some problems. In Case 3, after producing the correct answer, it goes into an infinite loop. Could this predicate be transformed into a deterministic one? Or non-deterministic that halts with false?
YES! But using red cut. See: http://stackoverflow.com/a/15123016/1545971
After some time, I've managed to code a set of predicates, that mimic the behavior of the build-in length/2. my_len_tail is deterministic and works correct in all Cases 1-4. Could it be done simpler?
my_len_tail(List, Len) :- var(Len)->my_len_tailv(List, 0, Len); my_len_tailnv(List, 0, Len). my_len_tailv(, Acc, Acc). my_len_tailv([_|T], Acc, Len) :- M is Acc+1, my_len_tailv(T, M, Len). my_len_tailnv(, Acc, Acc) :- !. % green! my_len_tailnv([_|T], Acc, Len) :- Acc<Len, M is Acc+1, my_len_tailnv(T, M, Len).
As @DanielLyons suggested in the comments, one can use clpfd to defer less than check. But it still leaves one problem: in Case 3 (
my_len_clp(X, 3)) the predicate is nondeterministic. How it could be fixed?
:-use_module(library(clpfd)). my_len_clp(List, Len) :- my_len_clp(List, 0, Len). my_len_clp(, Acc, Acc). my_len_clp([_|T], Acc, Len) :- Acc#<Len, M is Acc+1, my_len_clp(T, M, Len).
It can be fixed using
zcompare/3 from the CLP(FD) library. See: http://stackoverflow.com/a/15123146/1545971