Strong suggestion: follow the Design Recipe for list structures both in spirit and to the letter. This problem is novel enough to you that you won't get it easily. You need the extra support that the Design Recipe steps make you go through.

In this specific case, you *really* need a good suite of examples (test cases) to help you out, because a solution to this problem is not immediately obvious. It's tricker because this function isn't from lists to lists: it's from lists to numbers, so you must have a strong suite to help you catch silly mistakes.

For example, what should?

```
(check-expect (reverse-list empty) <fill-me-in>)
```

be? And should we even consider the empty list? Is it a weird input? Is it sensical? Does the *contract* say that we have to deal with empty lists as input, or can we be guaranteed that it only accepts non-empty lists? This is the sort of thing you need to resolve up front! What you have right now in code can't certainly be right, because the type of your contract... well, you have not expressed a contract formally, but once you do, you'll see that the base case has to be different than what you've written so far.

In the cited link about the Design Recipe, part 5 is critical: once you have the template of your function, you need to understand what kind of thing the natural recursion is computing. Use concrete test cases to help. From looking at your code, it appears that you may have skipped this step, because the code you've written does not appear to consider the question: "What do the natural recursions compute?"

Concretely, if we're doing:

```
(reverse-list (list 1 2 3 4))
```

What do we want the answer to be? You said it yourself:

```
(reverse-list (list 1 2 3 4)) ==> 4321
```

Consider what the *natural recursion* will be:

```
(reverse-list (list 2 3 4))
```

What's the value of this? We know that it must be

```
(reverse-list (list 2 3 4)) ==> 432
```

Once you figure that out, ask yourself: does the value of the natural recursion have any relationship whatsoever to the answer of the original question?

Given that we're trying to solve:

```
(reverse-list (list 1 2 3 4)) ===> 4321
```

and we have the pieces `1`

(the first part of the list) and `432`

(from the natural recursion), can we put together `1`

and `432`

in some way to get `4321`

?

Repeat this for a few examples. And by few, I mean more than one. :) Do this concretely for those examples, and your brain will have a much better shot at pattern matching and generalizing to figure out what the code for the recursive case must be.

That is, once you've gotten enough exercise figuring out how to get the right answer for the concrete cases, go and see if you can express what you were doing with the concrete values back to the original terms in your program. e.g. if you figured out that:

```
we want to get 4321 out of 1 and 432:
=> 1 + 10 * 432
... other examples you worked out...
```

Let's re-express these in prefix notation:

```
we want to get 4321 out of 1 and 432:
=> (+ 1 (* 10 432))
... other examples you worked out...
```

What parts are changing? What parts are staying the same? What does the first changing part stand for? What does the second changing part stand for? That is:

```
we want to get 4321 out of 1 and 432:
=> (+ 1 (* 10 432))
... other examples you worked out ...
we want to get (reverse-list lst) out of (first lst) and (reverse-list (rest lst))
==> ???
```

Once you see the pattern, then you've figured out what the code *needs* to be for the recursive case. But note that you truly need a suite of examples here: trying to generalize out of one specific example isn't enough for your brain to see patterns. Your brain *requires* the repetition from working out multiple examples to be able to start seeing patterns.

`1 + 2x + 3x^2 + 4x^3`

at`x=10`

. The fact that the numbers look "reversed" is a special case when`x=10`

. He may notknowthat this is what he's doing, but it is. :) – dyoo Mar 19 '13 at 5:24`1 + 2*10^1 + 3*10^2 + 4*10^3`

, the direct recursive solution to this will effectively compute`1 + [10 * (2 + [10 * (3 + [10 * 4])])]`

. Just treat this as any other introductory recursive function that you've studied, and you'll solve it. But don't try doing it via repeated computing of exps: it's actuallyharderthan the recursive solution, and it's actually doing much more work than necessary. – dyoo Mar 20 '13 at 4:42