# Explain the continuation example on p.137 of The Little Schemer

The code in question is this:

``````(define multirember&co
(lambda (a lat col)
(cond
((null? lat)
(col (quote ()) (quote ())))
((eq? (car lat) a)
(multirember&co a
(cdr lat)
(lambda (newlat seen)
(col newlat
(cons (car lat) seen)))))
(else
(multirember&co a
(cdr lat)
(lambda (newlat seen)
(col (cons (car lat) newlat)
seen))))))
``````

I've stared at this all day but I can't quite seem to understand it. When you recur on the function you are re-defining `col` but in the examples they seem to use the original definition. Why wouldn't it change. How can you recur on it without passing in the parameters `newlat` and `seen`.

It's hard to explain my question because I seem to just be missing a piece. If perhaps someone could give a more explicit walk-through than the book I may be able to understand how it works.

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Someone else was confused about the same program: rhinocerus.net/forum/lang-scheme/… –  darvids0n Aug 10 '11 at 1:35

Let's step through an example; maybe that will help. :-) For simplicity, I'm just going to use `list` as the collector/continuation, which will just return a list with the arguments to the continuation.

``````(multirember&co 'foo '(foo bar) list)
``````

At the start,

``````a = 'foo
lat = '(foo bar)
col = list
``````

At the first iteration, the `(eq? (car lat) a)` condition matches, since `lat` is not empty, and the first element of `lat` is `'foo`. This sets up the next recursion to `multirember&co` thusly:

``````a = 'foo
lat = '(bar)
col = (lambda (newlat seen)
(list newlat (cons 'foo seen))
``````

At the next iteration, the `else` matches: since `lat` is not empty, and the first element of `lat` is `'bar` (and not `'foo`). Thus, for the next recursion, we then have:

``````a = 'foo
lat = '()
col = (lambda (newlat seen)
((lambda (newlat seen)
(list newlat (cons 'foo seen)))
(cons 'bar newlat)
seen))
``````

For ease of human reading (and avoid confusion), we can rename the parameters (due to lexical scoping), without any change to the program's semantics:

``````col = (lambda (newlat1 seen1)
((lambda (newlat2 seen2)
(list newlat2 (cons 'foo seen2)))
(cons 'bar newlat1)
seen1))
``````

Finally, the `(null? lat)` clause matches, since `lat` is now empty. So we call

``````(col '() '())
``````

which expands to:

``````((lambda (newlat1 seen1)
((lambda (newlat2 seen2)
(list newlat2 (cons 'foo seen2)))
(cons 'bar newlat1)
seen1))
'() '())
``````

which (when substituting `newlat1 = '()` and `seen1 = '()`) becomes

``````((lambda (newlat2 seen2)
(list newlat2 (cons 'foo seen2)))
(cons 'bar '())
'())
``````

or (evaluating `(cons 'bar '())`)

``````((lambda (newlat2 seen2)
(list newlat2 (cons 'foo seen2)))
'(bar)
'())
``````

Now, substituting the values `newlat2 = '(bar)` and `seen2 = '()`, we get

``````(list '(bar) (cons 'foo '()))
``````

or, in other words,

``````(list '(bar) '(foo))
``````

to give our final result of

``````'((bar) (foo))
``````
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First of all, thanks for a thorough and thoughtful explanation. I am still a bit fuzzy on how you get the actual parameters for the inner lambda. How did you know that newlat2 = '(bar) and seen2 = '()? –  nweiler Aug 10 '11 at 16:16
Let's step you through a simpler example of how argument substitution works. :-) Say you have a function, `(define ** (lambda (x y) (exp (* (log x) y))))`. If you then call `(** 42 24)`, then that calls the lambda with `x = 42` and `y = 24`. Since `**` is the same as the lambda, the equivalent expression is `((lambda (x y) (exp (* (log x) y))) 42 24)`. Hopefully that makes some sense. :-) –  Chris Jester-Young Aug 10 '11 at 18:43
Now to directly answer your question of how we get `newlat2 = '(bar)` and `seen2 = '()`, it's simply calling that lambda with those given arguments. Consider the expression `((lambda (newlat2 seen2) ...) '(bar) '())`. If we gave that lambda a name, say `inner`, then that expression simply becomes `(inner '(bar) '())`. It's easy to see, then, why inside the lambda, `newlat2` and `seen2` would have the values listed. –  Chris Jester-Young Aug 10 '11 at 18:46
Oh wow, okay I think I see it now. You nailed it with your last explanation. I see now why the lambdas have two parens before them. The first is defining the function and the second is evaluating it and it includes the two arguments at the end. Thanks so much! –  nweiler Aug 10 '11 at 20:52

I found a wonderful answer here: http://www.michaelharrison.ws/weblog/?p=34

I've been struggling through this too. The key is to understand lexical scoping (for me, à la Javascript) and the inner functions passed to multirember&co on the eq and not eq branches. Understand that, and you'll understand the entire procedure.

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This looks great. Thanks! –  nweiler Oct 1 '11 at 14:18

Here's some output:

``````> (multirember&co 'tuna '(and tuna) a-friend)
#f
> (multirember&co 'tuna '(and not) a-friend)
#t
``````

Here's a col to give back a list of non-matches:

``````(define list-not  (lambda (x y) x))
``````

and its use:

``````> (multirember&co 'tuna '(and not) list-not)
(and not)
``````
-

I hope this walkthrough helps

As Chris suggested, I've renamed newlat/seen to n/s and added an index. The book gives horrible names to the functions (a-friend new-friend latest-fried), so I just kept L (for lambda) and the definition.

``````multirember&co 'tuna '(strawberries tuna and swordfish) a-friend)
multirember&co 'tuna '(tuna and swordfish) (L(n1 s1)(a-friend (cons 'strawberries n1) s1))
multirember&co 'tuna '(and swordfish) (L(n2 s2)((L(n1 s1)(a-friend (cons 'strawberries n1) s1)) n2 (cons 'tuna s2))
multirember&co 'tuna '(swordfish) (L(n3 s3)((L(n2 s2)((L(n1 s1)(a-friend (cons 'strawberries n1) s1)) n2 (cons 'tuna s2)) (cons 'and n3) s3))
multirember&co 'tuna '() (L(n4 s4)((L(n3 s3)((L(n2 s2)((L(n1 s1)(a-friend (cons 'strawberries n1) s1)) n2 (cons 'tuna s2)) (cons 'and n3) s3)) (cons 'swordfish n4) s4))

((lambda(n4 s4)((lambda(n3 s3)((lambda(n2 s2)((lambda(n1 s1)(a-friend (cons 'strawberries n1) s1)) n2 (cons 'tuna s2))) (cons 'and n3) s3)) (cons 'swordfish n4) s4)) '() '())
((lambda(n3 s3)((lambda(n2 s2)((lambda(n1 s1)(a-friend (cons 'strawberries n1) s1)) n2 (cons 'tuna s2))) (cons 'and n3) s3)) '(swordfish) '())
((lambda(n2 s2)((lambda(n1 s1)(a-friend (cons 'strawberries n1) s1)) n2 (cons 'tuna s2))) '(and swordfish) '())
((lambda(n1 s1)(a-friend (cons 'strawberries n1) s1)) '(and swordfish) '(tuna))
(a-friend '(strawberries and swordfish) '(tuna))
``````
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The code does not build the solution, as it happens usually, but it builds a code that computes the solution, exactly as when you would build the tree using low level operations, like `cons`, `+`, `-`, etc, instead of using high level accumulators or filters.

This is why it is difficult to say if the process is iterative or recursive, because, by the definition of the iterative processes, they use a finite amount of memory for the local state. However, this kind of process uses much memory, but this is allocated in environment, not in local parameters.

First, I duplicate the code here, to be able to see the correspondence without scrolling too much:

``````(define multirember&co
(lambda (a lat col)
(cond
((null? lat)
(col (quote ()) (quote ())))
((eq? (car lat) a)
(multirember&co a
(cdr lat)
(lambda (newlat seen)
(col newlat
(cons (car lat) seen)))))
(else
(multirember&co a
(cdr lat)
(lambda (newlat seen)
(col (cons (car lat) newlat)
seen)))))))
``````

Let us try to split the problem to see what really happens.

• Case 1:

``````(multirember&co 'a
'()
(lambda (x y) (list x y)))

is the same as

(let ((col (lambda (x y) (list x y))))
(col '() '()))
``````

This is a trivial case, it never loops.

Now the interesting cases:

• Case 2:

``````(multirember&co 'a
'(x)
(lambda (x y) (list x y)))

is the same as

(let ((col
(let ((col (lambda (x y) (list x y)))
(lat '(x))
(a 'a))
(lambda (newlat seen)
(col (cons (car lat) newlat)
seen)))))
(col '() '()))
``````

In this case, the process produces this code as result, and finally evaluates it. Note that locally it is still tail-recursive, but globally it is a recursive process, and it requires memory not by allocating some data structure, but by having the evaluator allocate only environment frames. Each loop deepens the environment by adding 1 new frame.

• Case 3

``````(multirember&co 'a
'(a)
(lambda (x y) (list x y)))

is the same as

(let ((col
(let ((col (lambda (x y) (list x y)))
(lat '(a))
(a 'a))
(lambda (newlat seen)
(col newlat
(cons (car lat) seen))))))
(col '() '()))
``````

This builds the code , but on the other branch, that accumulates a result in the other variable.

All the other cases are combinations of 1 of these 3 cases, and it is clear how each 1 acts, by adding a new layer.

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