# In SICP exercise 2.26 using DrScheme, why does cons return a list, instead of a pair of lists?

In SICP exercise 2.26, this Scheme code is given:

``````(define x (list 1 2 3))
(define y (list 4 5 6))
``````

Then this cons call is given:

``````(cons x y)
``````

I expected a pair of lists would result, `((1 2 3) (4 5 6))` but the interpreter gives, `((1 2 3) 4 5 6)` ...a list with 4 elements, the first being a list. Why is y treated differently? I've tried looking up other SICP answers for an explanation, but couldn't find something satisfactory. So could any Scheme/Lisp experts please shed some light on this aspect of cons? Thanks in advance for any insight.

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Thank you to all responders to my question, particularly Nathan and tonio. This newbie in Scheme/Lisp now groks the language a bit better because of your detailed answers. – limist May 28 '10 at 14:18
Also see Recursive range in Lisp adds a period? for a similar explanation. – Joshua Taylor Dec 14 '13 at 15:28

`'((1 2 3) 4 5 6)` is actually a pair of lists. Here's another way to write it:

``````'((1 2 3) . (4 5 6))
``````

However, the printer avoids dotted pair notation whenever it can, so you get the first representation instead. The rule is:

``````'(x . (xs ...))
=>
'(x xs ...)
``````

For any `x` and `xs`. Here, your `x = '(1 2 3)` and `xs = '(4 5 6)`, so you get `((1 2 3) 4 5 6)`.

To see how cons and dotted-pair notation is related, let's shorten the problem to just `'(1)` and `'(6)`. The lowest level way to build a pair of them is this:

``````(cons (cons 1 '()) (cons 6 '()))
``````

Here, `'()` is nil, or the empty list. If we translate this literally to dotted-pair notation, we get this:

``````'((1 . ()) . (6 . ()))
``````

But because the printer collapses dotted-pair notation whenever possible, you get this instead:

``````'((1 . ()) . (6 . ()))
=>
'((1) . (6))    ; <-- x=1, xs=nothing; x=6, xs=nothing
=>
'((1) 6) ; <-- x=1, xs=6
``````
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Thank you for the detailed explanation; I now see that it's a pair of lists, per the collapse of dotted pair notation, and since (cdr (cons x y)) gives the second list. But why does (length (cons x y)) answer 4? Shouldn't it be either 6 (count all elements of both lists), or 2 (count two lists)? – limist May 28 '10 at 14:08
Ah, never mind my comment; I see it's a consequence of the (length) function they give in the book that doesn't deal with nested lists. – limist May 28 '10 at 14:13
@limist: Well, sort of. Your problem (I think) is thinking of List as an opaque, separate data type. It's really just a convention of how to use cons pairs (see tonio's answer). So, to get length 6, you'd write `nested-list`, although this would really be called `tree-size` because it uses the tree convention for conses. On the other hand, to get 2 from `(length (cons '(1 2 3) '(4 5 6))`, you'd have to get 2 for any list. That method ignores the list convention that says that, eg, '(1) is actually `(cons 1 '())`. Its length is 1, not 2, because of the way lists are constructed. – Nathan Shively-Sanders May 28 '10 at 16:19
you're correct in your diagnosis, thank you. :) I realized there was vagueness in my mind about how cons and list are defined when I worked through another SICP problem, and also, some "legacy" mental model from how lists work in python. Thanks again for taking the time to explain things clearly, I appreciate it. – limist Jun 1 '10 at 19:04

`cons` uses the first argument as head of the list, and the second as tail.

You give it a first list `(1 2 3)`, which will constitute the head of the resulting list and a second list `(4 5 6)`, to be used as tail of the list. Thus, you end with `((1 2 3) 4 5 6)`.

Thing of lists as left-to-right combs, ending with empty list (represented as `o` here), and see how they combine.

`````` X=      Y=
/\      /\
1 /\  + 4 /\
2 /\    5 /\
3  o    6  o
``````

You then build:

`````` /\
X  Y
``````

Obtaining:

``````  /\
/\ \
1 /\ \
2 /\ \
3  o/\
4 /\
5 /\
6  o
``````

which is `((1 2 3) 4 5 6` when represented with parenthesis. And this is a pair of lists.

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Yes, I tried to simplify the drawing a bit, but that was not really a success. Will try to improve this. – tonio May 27 '10 at 16:00
Thank you for the diagram explanation, it makes sense now. – limist May 28 '10 at 14:13

I found the diagrams in the Emacs Lisp tutorial particularly helpful when learning Lisp.

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hey, i think you could think of it in this way;

whenever there is a nil, there must be a pair of parenthesis, as follow:

(cons 1 (cons 2 nil))--> (list 1 2)

(let ((x (list 1 2 3)) (y (list 4 5 6))))

1.(cons x y)--> (cons (cons 1 (cons 2 (cons 3 nil))) (cons 4 (cons 5 (cons 6 nil)))) here, the first nil stands for an end of a pair which could be expressed by parenthesis; whereas the second nil stands for the end of the whole pair which use another pair of parenthesis; so, ((1 2 3) 4 5 6)

2.(list x y)-> (cons x (cons y nil); as we know the x contain a nil, so it must be (1 2 3); the second part contains two nils, so ((1 2 3) (4 5 6));

the inner most nil means the outer most parenthesis;

Hope it can help.

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try (list x y) I'm sure it works on common lisp, I don't know about Scheme

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