flatten are red herrings for this kind of problem. Sure, you could use
flatten, and then count the occurrences in the resulting flattened list. However, it's much more efficient and straightforward to just traverse the nested list.
For simplicity, let's start by implementing the function for the non-nested case. Here's a version that counts occurrences of
'?, for even more simplicity:
[(null? ls) 0]
[(eq? (car ls) '?) (add1 (count-?s (cdr ls)))]
[else (count-?s (cdr ls))])))
Changing this to work on nested lists just requires adding one
cond line. The implementation of
flatten you found contains a hint here: we want to check at each step of the recursion whether the
car of the list is itself a list (However, using
list? is more power than we need; we can use
pair? instead, as long as our input is always a proper, nested list).
Once we know the
car is also a (potentially-nested) list, we need to pass it to a function that knows how to handle lists. Fortunately, we're in the middle of defining one!
[(null? ls) 0]
[(pair? (car ls)) (+ (count-?s* (car ls)) (count-?s* (cdr ls)))]
[(eq? (car ls) '?) (add1 (count-?s* (cdr ls)))]
[else (count-?s* (cdr ls))])))
And that's all there is to it. Very little thought involved, no? So little, in fact, that you can just replace a couple expressions and wind up with a function that does something completely different to the nested list:
[(null? ls) '()]
[(pair? (car ls)) (cons (remove-?s* (car ls)) (remove-?s* (cdr ls)))]
[(eq? (car ls) '?) (remove-?s* (cdr ls))]
[else (cons (car ls) (remove-?s* (cdr ls)))])))
Solving a problem for a nested list is really easy once you've solved it for a flat list.
- Start with the flat list solution.
- Check for a pair in the
- Do the natural recursion on both the
car and the
- Combine the answers with a binary operator that makes sense with the left-hand side of the
null? case, e.g.,