Testing Prolog Difference lists

I've been reading about how great difference lists are and I was hoping to test some examples from the books. But it seems that you can't pass lists as input in just the same way as, for instance append([1,2,3], [4,5], X), where X=[1,2,3,4,5]. Strangely, no book I've consulted ever mentions this.

I'm running the code on swipl and I'm interested in testing out a difference append predicate:

``````dapp(A-B,B-C,A-C).
``````

and a "rotate first element of list" predicate:

``````drotate([H|T]-T1,R-S) :- dapp(T-T1,[H|L]-L,R-S).
``````

Any ideas, how I can test these predicates in swipl?

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Try:

``````dapp([1,2,3|X] - X,[4,5,6] - [],Y - []).
drotate([1,2,3|X] - X,Y - []).
``````

Y is the answer for both predicates.

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That did the trick! I never thought about trying Y-[], thanks! –  Daniel Loureiro Jul 9 '11 at 14:58
actually, it could be anything, just make make sure it's the same for 2nd and 3rd argument. e.g.: dapp([1,2,3|X] - X,[4,5,6] - Z,Y - Z). –  LeleDumbo Jul 9 '11 at 15:04

The definition of `drotate` can be simplified:

``````dapp(A-B,B-C,A-C).
drotate([H|T]-T1,R-S) :- % dapp(T-T1,[H|L]-L,R-S).
%% use the definition of dapp:
T=R, T1=[H|L], L=S.
``````

IOW, simply,

``````drotate([H|R]-[H|L],R-L).
``````

Now, any difference list is usually written out as a pair, `A-B`. So a call to `drotate` might be `drotate([1,2,3|Z]-Z,R-L)` with intent to see the output in `R-L` variables. But matching this call with the last definition, we get `Z=[1|L]`, i.e. the logvar Z, presumably non-instantiated before the call, gets instantiated by it, actually adding `1` at the end of the open-ended list `[1,2,3|Z]-Z`, turning it into `[1,2,3,1|L]-L`. `R` just gets pointed at the 2nd elt of the newly enlarged list by matching `[H|R]` with the list.

``````?- drotate([1,2,3|Z]-Z,R-L).

Z = [1|_G345]
R = [2, 3, 1|_G345]
L = _G345

Yes
``````

But it could also be called with the truly circular data, `A-A=[1,2,3|Z]-Z, drotate(A-Z,R-L)`:

``````?- A-A=[1,2,3|Z]-Z, drotate(A-Z,R-L).

A = [1, 2, 3, 1, 2, 3, 1, 2, 3|...]
Z = [1, 2, 3, 1, 2, 3, 1, 2, 3|...]
R = [2, 3, 1, 2, 3, 1, 2, 3, 1|...]
L = [2, 3, 1, 2, 3, 1, 2, 3, 1|...]

Yes
``````
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