Sorry for the previous posting. It was my first post
and I posted as an unregistered user. I obviously
haven't figured out how to format text yet.

I've created an account (user dlm) and I'm making a
second attempt -- here goes.

I've been working on learning Racket/Scheme for a while
now and this site looks like a great place to share and
learn from others.

I'm not 100% sure of the spec on this question and
have my doubts that my code actually solves the problem
at hand but I think it's readable enough to be modified
as needed

Readability is one of the things I've been working on
and would appreciate feedback/suggestions from others.

dlm.

My 2 cents :

```
(define (process-list? lst)
(let*([pair-0 (list-ref lst 0)]
[pair-1 (list-ref lst 1)])
(and (= (car pair-0) (car pair-1))
(< (cdr pair-0) (cdr pair-1)))))
(define (make-odd/even-sets data)
(let*([x (car (list-ref data 0))]
[y-start (cdr (list-ref data 0))]
[max (cdr (list-ref data 1))])
(define (loop y evens odds)
(if (<= y max)
(loop (add1 y)
(if (even? y) (cons (cons x y) evens) evens)
(if (odd? y) (cons (cons x y) odds) odds))
(list (reverse odds) (reverse evens))))
(loop y-start '() '())))
(define (main data)
(if (process-list? data)
(let*([odd/even (make-odd/even-sets data)])
(printf "~a~n" (list-ref odd/even 0))
(printf "~a~n" (list-ref odd/even 1)))
(printf "Invalid list~n" )))
(main '((1 . 1) (1 . 7)) )
```

UPDATE:

Hi gn66,

I don't know how much I can actually do in terms of the
game itself but I might be able to give you some
pointers/ideas.

A major thing to look for in improving code is to to
look for repeating code applied to specific situations
and try to think of ways to generalize. At first the
generalized form can seam harder to read when you don't
see what's going on but once you fully understand it
it's actually easier, not only to read but modify.

Looking at your code the 'adjacent' procedure jumps out
as something that could be shortened so I'll use that as
an example. Let's start by first ignoring the boundary
conditions and look for the generial pattern of
operations (example: where you put the logic for
conditional test can have a big effect on the size of the
code).

```
(define (adjacent p)
(list (do-pos (+ (line-pos p) 1) (column-pos p))
(do-pos (- (line-pos p) 1) (column-pos p))
(do-pos (line-pos p) (+ (column-pos p) 1))
(do-pos (line-pos p) (- (column-pos p) 1))) )
```

The problem here can be partitioned into 2 different
problems: 1) changing line postions + - 1 and
2) changing row positions + - 1. Both applying
the same operations to different components of the
position. So let's just work with one.

(instead of a while loop lets look at MAP which is
like a "while list not empty" loop)

Using 'map' to apply an operation to data list(s)
is pretty straight forward:

```
(map (lambda (val) (+ val 5))
'(10 20 30))
```

If needed you can inclose it inside the scope of a procdure
to maintain state information such as a counter:

```
(define (test lst)
(let*([i 0])
(map (lambda (val)
(set! i (+ i 1))
(+ val i))
lst)))
(test '(10 20 30))
```

Or pass in values to use in the operation:

```
(define (test lst amount)
(map (lambda (val) (+ val amount))
lst))
(test '(10 20 30) 100)
```

Now turn your thinking inside out and consider that
it's possible to have it map a list of operations to
some data rather than data to the operation.

```
(define (test val operations-lst)
(map (lambda (operation) (operation val))
operations-lst))
(test 10 (list sub1 add1))
```

Now we have the tools to start creating a new
'adjacent' procedure:

```
(define (adjacent p)
(define (up/down p) ;; operations applied to the line componet
(map (lambda (operation)
(cons (operation (line-pos p)) (column-pos p)))
(list add1 sub1)))
(define (left/right p) ;; operations applied to the column componet
(map (lambda (operation)
(cons (line-pos p) (operation (column-pos p))))
(list add1 sub1)))
(append (up/down p) (left/right p))
)
(adjacent (do-pos 1 1))
```

This works find for positions that aren't on the boundary
but just as the old saying goes "it's sometimes easier to do
something and then apologize for it than it is to first ask
permission". Let's take the same approach and let the errant
situations occur then remove them. The 'filter' command is
just the tool for the job.

The 'filter' command is similiar to the map command in that
it takes a list of values and passes them to a function. The
'map' command returns a new list containing new elements
that correpsond to each element consumed. Filter returns
the original values but only the ones that the (predicate)
function "approves of" (returns true for).

```
(filter
(lambda (val) (even? val))
'(1 2 3 4 5 6 7 8))
```

will return the list (2 4 6 8)

So adding this to the new 'adjacent' procedure we get:

```
(define (adjacent p)
(define (up/down p)
(map (lambda (operation)
(cons (operation (line-pos p)) (column-pos p)))
(list add1 sub1)))
(define (left/right p)
(map (lambda (operation)
(cons (line-pos p) (operation (column-pos p))))
(list add1 sub1)))
(define (select-valid p-lst)
(filter
(lambda (p) (and (>= (line-pos p) 0) (>= (column-pos p) 0)
(<= (line-pos p) 7) (<= (column-pos p) 7)))
p-lst))
(select-valid
(append (up/down p) (left/right p))))
```

As for the "while cycles" you asked about: you need to
develop the ability to "extract" information like this from
existing examples. You can explore different aspects of
existing code by trying to remove as much code as you can
and still get it to work for what you are interested in
(using print statements to get a window onto what's going
on). This is a great way to learn.

From my first posting cut out the loop that creates the
evens/odds list. When you try to run you find out what is
missing (the dependencies) from the error messages so
just define them as needed:

```
(define x 1)
(define max 5)
(define (loop y evens odds)
(if (<= y max)
(loop (add1 y)
(if (even? y) (cons (cons x y) evens) evens)
(if (odd? y) (cons (cons x y) odds) odds))
(list (reverse odds) (reverse evens))))
(loop 1 '() '())
```

Add a print statement to get info on the mechanics of how
it works:

(define x 1)
(define max 5)
(define y-start 1)

```
(define (loop y evens odds)
(if (<= y max)
(begin
(printf "section 1 : y=~a~n" y)
(loop (add1 y)
(if (even? y) (cons (cons x y) evens) evens)
(if (odd? y) (cons (cons x y) odds) odds)))
(begin
(printf "section 2 : y=~a~n" y)
(list (reverse odds) (reverse evens))
)))
(loop y-start '() '())
```

Now remove parts you aren't interested in or don't need,
which may take some exploration:

```
(let*([max 5])
(define (loop y)
(if (<= y max)
(begin
(printf "section 1 : y=~a~n" y)
(loop (add1 y)))
(begin
(printf "section 2 : y=~a~n" y)
'()
)))
(loop 1))
```

Now you should be able to more easily see the mechanics of a
recursive while loop and use this as a simple template
to apply to other situations.

I hope this helps and I hope it doesn't cross the line
on the "subjective questions" guidelines -- I'm new to
this site and hope to fit in as it looks like a great
resource.