The dcg makes use of a concept called difference lists. Let's assume you want to do parsing (you can also generate lists with these predicates, but let's ignore that for now).
if you parse a list, like
[the,man,kisses,the,woman]. You can see this as a train of words, I "borrowed" the train analogy from @Vikramnath Venkatasubramani, so credits to him/her. Now if we call
C will return
What happens is that at each predicate will disconnect zero, one or more wagons. So it means that in the case of:
np/2 will disconnect the wagons
[the,man], resulting in the fact that it still stores the remaining train
B=[kisses,the,woman]. Now the
vp/2 will disconnect all the remaining wagons resulting in
C=, an empty train.
How is this implemented
Let's consider the implementation of part of the grammar.
So as said before, you call
np/2 will have to disconnect the wagons that form the noun-phrase:
np/2 on his turn calls
det/2 will disconnect the determiner:
n/2 will disconnect the noun
man, so to make it more explicit:
det/2 no longer redirects its responsibilities, it is implemented as:
Now in case we do pattern matching, this will ground to:
So this means it has disconnected the
The advantage of using this approach is that disconnecting can be done in constant time. Indeed, the predicate is not aware of the entire tail of the list.
Furthermore it would allow to disconnect multiple words in a fact. For instance say, you add your name as a noun:
in that case
n/2 will disconnect two wagons at once. Other predicates do not need to be aware of this, nor does
s/2 for instance have to decide at which point it splits the train between the
np/2 and the
vp/2: it lets
np/2 disconnect as much wagons as it wants, and
vp/2 will aim to work with the remainder of the train.