Dunno anything about Visual Prolog, but in normal Prolog, I'd do something like the following...
First, I'd denote an empty btree as the atom
btree and represent a non-empty btree as a structure of arity 3, thus:
btree( Payload, LeftChildren, RightChildren )
Payload is the data for the node (an integer apparently), with
RightChildren being the btrees representing, respectively, the left and right children of the current node.
Traversing the tree to count those nodes with even-valued nodes is simple. The public predicate has arity 2, accepting the [bound] btree structure to be examined, and a bound or unbound value representing the count of even items. It calls an internal, recursive "helper" predicate that walks a tree and develops the count.
count_even( T , N ) :- count_even( T , 0 , N ) .
The internal predicate is simple as well. Having arity 3, the first argument is the tree to be examined, the second is an accumulator and the third is the final count (which won't be unified until the very end). There are two possible cases.
If the tree is empty, we have the final count:
count_even( btree , N , N ) .
If the tree is non-empty, we examine the current node, then recursively walk the left and right child trees, thusly:
count_even( btree( V , L , R ) , T , N ) :-
is_even( V , X ) ,
T1 is T+X ,
count_even( L , T1 , T2 ) ,
count_even( R , T2 , N )
We also need a trivial helper to tell us whether a particular value is even or odd:
is_even( V , 1 ) :- 0 is V mod 2 , ! .
is_even( V , 0 ) .
It should be noted that the data structure you're using is not a b-tree, per se: it is a binary tree.
B-trees are something of a generalization of a height-balanced binary tree optimized for disk storage. Each node has a variable number of keys and a variable number of children (corresponding to the number of keys). For more information, see
Here's a picture of a B-tree:
And a picture of a binary tree: