I am studying Prolog using Ivan Bratko book: Programming for Artificial Intelligence and I am finding some problems trying to understand how work an exercise that use graphs to decide how to move blocks and to arrange them in an order.
This is an image related to what the program have to do:
As you can see in the previous image the blocks A,B,C can be moved using a number of admissible moves that are:
- A block can be moved only if it is at the top of the stack
- A block can be moved on the ground (on a void stack)
- A block can be moved over another block (at the top of another stack that contains some others blocks)
So these admissible moves induce a graph of the possible transitions between one state and another state in the graph, something like this:
So, as you can se in the previous graph I can represent a situation using a list of 3 sublist.
Each sublist represent a stack where I can put the blocks according to the previous constraints
So for example the situation of the central node of the previous graph can be represented by:
[[A], [B], [C]]
Because each stack contain a single block
The situation represented by the node at the top left where I stacked one below the other blocks C,A,B can be represented by:
[[C,A,B], , ]
because all the blocks are in a single stack (the first one)
Now, I have to write a predicate s(Situation1, Situation2) that is TRUE if Situation1 and Situation1 are two representations of the world of blocks (like the previous) and there is a legal move allowed between Situazion1 and Situazion2.
So I could represent this thing in the following using a series of facts like (this thing is shown on the slides of my teacher and not on the Bratko book:
s([[A|RA],B,C],[RA,[A|B],C]). s([[A|RA],B,C],[RA,B,[A|C]]). …
I interpret it in this way: I have 2 stacks:
Situation1 = [A|RA], B, C] where RA is the rest of the first stack without the block A (in this case it is void because this is the situation in which I have one block in each stacks)
Situation2 = [RA,[A|B],C] that is another situation with the first stack that is void (RA), the second stack that is the old second stack with the A block on the top and the third stack that contains only the C block
So it represents a legal transition...so I could declare a series of facts that represents explicitly all the possibles transitions.
But this is not good idea (I can have many transitions to encode in facts) so on the Bratko book implement programmatically the s(Situation1, Situation2) predicate in this way:
/* BASE CASE: If I delete X from List and X is the HEAD of List, NewList is the Tail of List */ del(X, [X|Tail], Tail). /* GENERAL CASE: If the head of List is not X then the program have to delete X in the Tail of List */ del(X, [Y|Tail], [Y|Tail1]) :- del(X, Tail, Tail1). s(Stacks, [Stack1, [Top1|Stack2] | OtherStacks]) :- del([Top1|Stack1], Stacks, Stacks1), del(Stack1, Stacks1, OtherStacks). goal(Situation) :- member([a,b,c], Situation). solve(N,[N]) :- goal(N).
The del/3 predicate it is very simple (simply delete an X item from a list) and there is not much interesting.
I have some problem to understand how work the s/2 predicate that calculate legal moves.
On the book say:
The successor relation can be programmed according to the following rule: Situation2 is a SUCCESSOR of Situation1 if there are two stacks: Stack1 and Stack2 in Situation1 and the top block of Stack1 can be moved on Stack2
Intuitively this is not difficult to me because it appear clear that a move is legal if I can take a block by the top of one of the 3 stack and I can put it on the top of another stack (also a void stack, that corresponds to the situation in which I put a block on the ground)
But I am finding many difficult to understand the previous code of s/2 predicate when it write:
s(Stacks, [Stack1, [Top1|Stack2] | OtherStacks]) :- del([Top1|Stack1], Stacks, Stacks1), del(Stack1, Stacks1, OtherStacks).
I have some difficult to understand how read it and what exactly do when use del/3 predicate and also what exactly represent Stacks, Stack1, Stack2, Stacks1 variable