# How does eq? in Racket work?

At my university we had to work with Racket and since I kind of liked it, I bought the recently published book "Realm Of Racket" from No Starch.

It's great so far, however, I cannot figure out what they mean in Chapter 4 when they try to explain how eq? works:

1. At first, they explain how equal? compares whether two values consist of identical pieces. OK, no problem, I got that: equal? does pretty much the same thing as Java's equals(someObject) method. If two objects/structs/whatever are the same contentwise, #t is being returned.
2. Then, I figured, eq? must be the equivalent to Java's == operator, which doesn't compare contentwise but based on references.
3. This thought seemed to be confirmed by the following sentence in the book: "eq? compares whether changing one structure changes the other structure..." Great! Let's compare it to the following piece of Java code:

``````Point p1 = new Point(5, 5);
Point p2 = p1;
System.out.println(p1 == p2);   // true, since the reference has been copied.
System.out.println(p1.x);       // 5
System.out.println(p2.x);       // 5
p1.x = 42;
System.out.println(p1.x);       // 42
System.out.println(p2.x);       // Accordingly, 42
``````

Let's try this in Racket:

``````(define cons1 (cons 1 empty))
(define cons2 cons1)
(eq? cons1 cons2)           ;; #t, since the refernce has been copied.
(set! cons1 (cons 2 empty))
cons1                       ;; Returns '(2) - as expected.
cons2                       ;; Still returns '(1).
``````

Why? cons2 points to cons1, which itself points to '(2). Additionally, didn't they just say that they are equal as soon as one changes the other?

Obviously, right now I don't get why this doesn't behave as expected and because of that, I don't see what eq? is doing. Maybe I am wrong and it does not have anything to do with references...

If someone knows about this, please share your wisdom ;)

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## 3 Answers

For a technical explanation of how `eq?` works, take a look at the current specification, you won't find a more detailed reference. Or simply check Racket's documentation on the subject, in particular the procedures `eq?`, `eqv?` and `equal?`. Regarding your question - the result is as expected and correct in the Scheme code, let's see why. Notice that in this line in Java:

``````p1.x = 42;
``````

You're modifying the same object that's being pointed at by both `p1` and `p2`. Whereas in this line:

``````(set! cons1 (cons 2 empty))
``````

You're creating a new, different object and setting `cons1` to point to it, but `cons2` is still pointing to the old object. You can confirm this, after the previous line, the comparison `(eq? cons1 cons2)` will return `#f`.

The point is: the examples are not equivalent. The Java example deals with a single object that's being pointed at by two different references, whereas the Scheme example deals with two objects and two references.

For comparison purposes, here's a Scheme example that's similar to the Java code, and works as you expected because in here we're modifying a single mutable object that's being pointed at by two references:

``````#lang racket
(require scheme/mpair) ;; `m` stands for "mutable"

(define p1 (mlist 5 5))
(define p2 p1)

(eq? p1 p2)       ;; #t
(mcar p1)         ;;  5
(mcar p2)         ;;  5

(set-mcar! p1 42)
(eq? p1 p2)       ;; #t
(mcar p1)         ;; 42
(mcar p2)         ;; 42
``````
-

Ah: you want to make sure you're changing structure. In your example, it is actually not changing the structure of an existing value, but rather constructing a whole new value and directing `cons1` to it. You have the concept right: `eq?` is pretty much Java's `==`.

Just to analogize, here's the mistake in Java form just so you see what went wrong:

``````int[] lst1 = new int[] { 1 };       // (define cons1 (cons 1 empty))
int[] lst2 = lst1;                  // (define cons2 cons1)
System.out.println(lst1 == lst2);   // (eq? cons1 cons2)
lst1 = new int[] { 2 };             // (set! cons1 (cons 2 empty))
System.out.println(lst1[0]);        // (list-ref cons1 0)
System.out.println(lst2[0]);        // (list-ref cons2 0)
``````

In fact, at this point, you'll want to check for `eq?`-ness at the end of this: you'll see that the two are no longer `eq?`: they're two distinct values.

What you really want is to do mutation on the structure, rather than a variable rebinding. In Racket, since lists are immutable, you'll want to use a different data structure that allows for mutation. Vectors are one example datatype that can demonstrate. Let's "Rosetta" this up again so you see the analogy:

``````(define vec1 (vector 1))          ;; int[] vec1 = new int[] { 1 };
(define vec2 vec1)                ;; int[] vec2 = vec1;
(eq? vec1 vec2)                   ;; System.out.println(vec1 == vec2);
(vector-set! vec1 0 2)            ;; vec1[0] = 2;
(vector-ref vec1 0)               ;; System.out.println(vec1[0]);
(vector-ref vec2 0)               ;; System.out.println(vec2[0]);
``````
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You are correct, that `eq?` compares references to determine equality. This is much more efficient than `equal?`, which must recursively compare objects.

The Racket documentation explicitly defines each, as well as the related `eqv?` function:

equal?

Two values are equal? if and only if they are eqv?, unless otherwise specified for a particular datatype.

Datatypes with further specification of equal? include strings, byte strings, pairs, mutable pairs, vectors, boxes, hash tables, and inspectable structures. In the last six cases, equality is recursively defined; if both v1 and v2 contain reference cycles, they are equal when the infinite unfoldings of the values would be equal.

Examples:

``````> (equal? 'yes 'yes)
#t
> (equal? 'yes 'no)
#f
> (equal? (expt 2 100) (expt 2 100))
#t
> (equal? 2 2.0)
#f
> (equal? (make-string 3 #\z) (make-string 3 #\z))
#t
``````

eqv?

Two values are eqv? if and only if they are eq?, unless otherwise specified for a particular datatype.

The number and character datatypes are the only ones for which eqv? differs from eq?.

Examples:

``````> (eqv? 'yes 'yes)
#t
> (eqv? 'yes 'no)
#f
> (eqv? (expt 2 100) (expt 2 100))
#t
> (eqv? 2 2.0)
#f
> (eqv? (integer->char 955) (integer->char 955))
#t
> (eqv? (make-string 3 #\z) (make-string 3 #\z))
#f
``````

eq?

Return #t if v1 and v2 refer to the same object, #f otherwise.

Examples:

``````> (eq? 'yes 'yes)
#t
> (eq? 'yes 'no)
#f
> (let ([v (mcons 1 2)]) (eq? v v))
#t
> (eq? (mcons 1 2) (mcons 1 2))
#f
> (eq? (make-string 3 #\z) (make-string 3 #\z))
#f
``````
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The `eq?` parts must be what is garanteed to be `eq?`. There are much more that are `eq?` in reality but probably not garanteed to be in the future, like: `(eq? (+ 4 5) (+ 5 4)) ==> #t`, `(eq? 5e100 5e100) ==> #t`, `(eq? "racketeer" "racketeer") ==> #t`. see docs.racket-lang.org/reference/… – Sylwester Jul 11 '13 at 0:00