I have been reading through the answers and comments of my previous question and I have tried applying the given explanations on an example from Bratko (Prolog Programming for Artificial Intelligence, p. 130), but I am not sure I understand it completely. The example is described below:

I read the tree and the code as follows:

In the goal list `C :- P, Q, R, !, S, T, U.`

Prolog will one by one try to instantiate the variables, as normal, to eventually get to `true.`

. Let's say that a value is found for `P`

and `Q`

, and the first try on `R`

fails, then Prolog can back track to the case where `P`

and `Q`

were found, and try another option for `R`

if available. However, if `R`

is found as well (leading to `P, Q, R = true.`

), and `!`

succeeds as it always does, we throw away any *choice points* and there's nothing to back track to from that point on (not even `C :- V.`

). What this means is that if no results can be found for `S`

, the goal `C :- P, Q, R, !, S, T, U.`

will fail immediately. *But* Prolog can still backtrack to `A :- B, C, D.`

to find other values for `B`

. If another match is found for `B`

, `C`

will be tried again anew. And so on.

Assuming that my interpretation is correct, if the goal `C :- P, Q, R, !, S, T, U.`

succeeds or fails regardless of the value of `B`

, how would you improve efficiency? My guess would be to re-write `A :- B, C, D.`

as `A :- B, !, C, D`

.

Is my interpretation correct? And what about my improvement in efficiency, given some a-priori information on `C`

?