# Can someone help explain this scheme procedure

question: ((lambda (x y) (x y)) (lambda (x) (* x x)) (* 3 3))

this was #1 on the midterm, i put "81 9" he thought i forgot to cross one out lawl, so i cross out 81, and he goes aww. Anyways, i dont understand why its 81.

I understand why (lambda (x) (* x x)) (* 3 3) = 81, but the first lambda i dont understand what the x and y values are there, and what the [body] (x y) does.

So i was hoping someone could explain to me why the first part doesnt seem like it does anything.

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why would you add the tag homework ddaa? it isnt homework it was a test question i got wrong, and i was looking for information on why. –  chicken Oct 21 '08 at 21:20
Mh... Because I could! Right, that was not warranted. –  ddaa Oct 21 '08 at 21:24

This needs some indentation to clarify

``````((lambda (x y) (x y))
(lambda (x) (* x x))
(* 3 3))
``````
• `(lambda (x y) (x y))`; call `x` with `y` as only parameter.
• `(lambda (x) (* x x))`; evaluate to the square of its parameter.
• `(* 3 3)`; evaluate to 9

So the whole thing means: "call the square function with the 9 as parameter".

EDIT: The same thing could be written as

``````((lambda (x) (* x x))
(* 3 3))
``````

I guess the intent of the exercise is to highlight how evaluating a scheme form involves an implicit function application.

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The answers posted so far are good, so rather than duplicating what they already said, perhaps here is another way you could look at the program:

``````(define (square x) (* x x))

(define (call-with arg fun) (fun arg))

(call-with (* 3 3) square)
``````

Does it still look strange?

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Perhaps translating that code to Common Lisp helps clarify its behaviour:

``````((lambda (x y) (funcall x y)) (lambda (x) (* x x)) (* 3 3))
``````

Or even more explicitly:

``````(funcall (lambda (x y) (funcall x y))
(lambda (x) (* x x))
(* 3 3))
``````

Indeed, that first lambda doesn't do anything useful, since it boils down to:

``````(funcall (lambda (x) (* x x)) (* 3 3))
``````

which equals

``````(let ((x (* 3 3)))
(* x x))
``````

equals

``````(let ((x 9))
(* x x))
``````

equals

``````(* 9 9)
``````

equals 81.

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Let's look at this again...

``````((lambda (x y) (x y)) (lambda (x) (* x x)) (* 3 3))
``````

To evaluate a form we evaluate each part of it in turn. We have three elements in our form. This one is on the first (function) position:

``````(lambda (x y) (x y))
``````

This is a second element of a form and a first argument to the function:

``````(lambda (x) (* x x))
``````

Last element of the form, so a second argument to the function.

``````(* 3 3)
``````

Order of evaluation doesn't matter in this case, so let's just start from the left.

``````(lambda (x y) (x y))
``````

Lambda creates a function, so this evaluates to a function that takes two arguments, x and y, and then applies x to y (in other words, calls x with a single argument y). Let's call this call-1.

``````(lambda (x) (* x x))
``````

This evaluates to a function that takes a single argument and returns a square of this argument. So we can just call this square.

``````(* 3 3)
``````

This obviously evaluates to 9.

OK, so after this first run of evaluation we have:

``````(call-1 square 9)
``````

To evaluate this, we call call-1 with two arguments, square and 9. Applying call-1 gives us:

``````(square 9)
``````

Since that's what call-1 does - it calls its first argument with its second argument. Now, square of 9 is 81, which is the value of the whole expression.

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