This is rather similar to your previous question, but with a twist: here we *add*, instead of multiplying. And each element gets squared before adding it:

```
(define (sum-squares lst)
(if (empty? lst)
0
(+ (* (first lst) (first lst))
(sum-squares (rest lst)))))
```

As before, the procedure can also be written using tail recursion:

```
(define (sum-squares lst)
(let loop ([lst lst] [acc 0])
(if (empty? lst)
acc
(loop (rest lst) (+ (* (first lst) (first lst)) acc)))))
```

You must realize that both solutions share the same structure, what changes is:

- We use
`+`

to *combine* the answers, instead of `*`

- We
*square* the current element `(first lst)`

before adding it
- The base case for adding a list is
`0`

(it was `1`

for multiplication)

As a final comment, in a real application you shouldn't use explicit recursion, instead we would use higher-order procedures for composing our solution:

```
(define (square x)
(* x x))
(define (sum-squares lst)
(apply + (map square lst)))
```

Or even shorter, as a one-liner (but it's useful to have a `square`

procedure around, so I prefer the previous solution):

```
(define (sum-squares lst)
(apply + (map (lambda (x) (* x x)) lst)))
```

Of course, any of the above solutions works as expected:

```
(sum-squares '())
=> 0
(sum-squares '(1 2 3))
=> 14
```

`lst`

(shorthand for list), not`1st`

(that's "first") – Óscar López Mar 21 '14 at 14:48