It seems that one thing that can add to confusion here is the liberal use of
list. I'm going to start approaching your problem using Haskell notation for types.
:: means "has type", and
[Foo] means "list of Foo".
list1 :: [Symbol]
list2 :: [Number]
type Pair = (Symbol, Number)
(combiner list1 list2) :: [Pair]
Now it looks like you want to approach this problem with a
foldr over list2.
foldr :: (a -> b -> b) -> b -> [a] -> b
foldr requires a
step :: a -> b -> b and a
start :: b. Since we want the final result to be a
[Pair], that means that
b = [Pair].
start will probably be the empty list, then. Since list2 fills the
[a] slot, that means that
a = Number. Therefore for our problem,
step :: Number -> [Pair] -> [Pair]
combiner :: [Symbol] -> [Number] -> [Pair]
combiner list1 list2 = foldr step start list2
where step :: Number -> [Pair] -> [Pair]
step a b = undefined
start = 
So far this is the same as the
foldr that you wrote, except I haven't defined the
step yet. So what is the step function? From the type, we know it must take a
Number and a
[Pair] and produce a
[Pair]. But what do these inputs mean? Well the
Number input will be some element of
list2. And the
[Pair] input will be the "result of the fold so far". So we'll want to take our
Number, and do something to create the
Pairs for it, and then slap those onto the result so far. This is the point at which my code begins to differ from yours.
step a b = append (doSomething a) b
doSomething :: Number -> [Pair]
doSomething a = undefined
Since you, using Racket, will probably define
doSomething as an anonymous function, that means
list1 is in scope. (Since it is in the where clause of the function in Haskell, it is in scope). You will probably use that list to generate the combinations.
doSomething a = ... a ... list1 ...
doSomething is left as an exercise for the reader, as is translating back into Racket. Note that the type signature for the Haskell function that I'm defining here,
combiner, can be generalized to
[a] -> [b] -> [(a,b)].