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 `Pair`

s 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 ...
```

Implementing `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)]`

.