### The problem leading to the error

There are a few places in your code where you could end up calling `car`

with something that's not a `pair`

, (and so violate the contract that `car`

's argument should be a `pair`

). One such thing, as the error message indicates, is `2`

. In particular, after checking that `(= 1 1)`

(since `1`

is the value of `(1 2 3)`

and `(1 3 2)`

), you recurse into the left branches of the trees with

```
(tree-equal? (left T1) (left T2))
```

Now, `(left T1)`

produces `2`

, and `(left T2)`

produces `3`

. Neither is `null`

, so you end up getting to the following line with `2 == T1`

and `3 == T2`

.

```
(= (value T1) (value T2))
```

Since `value`

is defined as `car`

, you're trying to call `car`

with `2`

.

### Some other issues…

After that's resolved, there are still some issues with your comparison function, some of which are simply stylistic, and some of which are actually going to cause problems.

```
(define (tree-equal? T1 T2)
(if (and (null? T1) (null? T2))
#t
(if (= (value T1) (value T2))
(tree-equal? (left T1) (left T2))
(tree-equal? (right T1) (right T2)))))
```

You're right to check that *if* both trees are `null?`

, then they are the same. What happens if one of them is `null?`

and the other isn't, though? You'll continue by calling `value`

on `()`

, which is no good. If the other isn't `null?`

, but isn't a list either, you'll try calling `value`

on it, and that would fail too. In the case that you do get two trees, and they happen to have the same value, then you check their left sides, and if they don't have the same value, you check their right sides. (This is how `if`

works.) I expect that you really want to check that they have the same value *and* have the same left *and* have the same right.

You can actually simplify this with some boolean logic (the comments to the right should help). This uses a `tree?`

predicate which you haven't defined yet, but it's not difficult, and it makes *this* code much easier to read.

```
(define (tree-equal? T1 T2) ; T1 and T2 are tree-equal iff
(or (eq? T1 T2) ; 1. are the same (this covers both being null), OR
(and (tree? T1) (tree? T2) ; 2. a. both are trees, AND
(eq? (value T1) (value T2)) ; b. values are eq, AND
(tree-equal? (left T1) (left T2)) ; c. lefts are tree-equal, AND
(tree-equal? (right T1) (right T2))))) ; d. rights are tree-equal
```

### On the traditional meaning of “tree” in Lisps

Now, I understand that you're using binary trees that have elements at each intermediate nodes, but I'll point out that “tree” is often used in Lisp contexts to denote an arbitrary structure built out of cons cells (i.e., pairs). The same approach can be used to compare them, but it's a little bit cleaner:

```
(define (tree-eq? t1 t2)
(or (eq? t1 t2)
(and (pair? t1) (pair? t2)
(tree-eq? (car t1) (car t2))
(tree-eq? (cdr t1) (cdr t2)))))
```

This comparison function will, coincidentally, work for your type of tree as well, since one of your nodes has the form

```
(value . (left . (right . ())))
```

so the recursive calls would still end up processing the values, lefts, and rights from two trees at the same time. Of course, this would also recognize equivalent trees (in the traditional sense) that aren't actually legal trees (in the sense of your question). That's why it's important to have a corresponding `tree?`

function (`pair?`

serves just fine for the traditional case).