Symmetric 2 Dimensional Array

What would the code be to test whether an array is two-dimensional? For one dimension I know that reversing the list will work. For two-dimensions I know that the opposite row / column must be the same. In other words [1][2] must equal [2][1] and so forth.

(defun symmetric-check (list) (equal list (reverse list)))

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Array: (setf arr (make-array '(2 2) :initial-contents '((1 2) (2 3)))) –  Tequila Feb 12 '12 at 16:53

It depends on your definition of symmetry.

In linear algebra, a matrix is called symmetric iff it is equal to its transpose (this is equivalent to saying that M[i, j] = M[j, i] for all i and j). Thus,

``````(defun matrix-symmetric-p (m)
(equal m (transpose-matrix m)))

(defun transpose-matrix (m)
;; implement this
...)
``````

I strongly recommend using actual arrays, though, because it will make doing things like this easier and much more efficient.

``````(defun matrix-symmetric-p (m)
(loop for i from 0 below (array-dimension m 0)
always
(loop for j from 0 below (array-dimension m 1)
always
(= (aref m i j) (aref m j i)))))
``````
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For a non-square matrix this code would crash... also you are checking each pair twice. Why using `loop` even when its syntax is actually more verbose than the lispier `dotimes`? –  6502 Feb 12 '12 at 9:19
@6502 True, but the definition of symmetry I used doesn't make sense for a non-square matrix anyway. `dotimes` would necessitate using something like `block` and `return-from` (note that I used the `always` directive) and would therefore be a bit uglier, semantically. –  Matthias Benkard Feb 12 '12 at 15:15
I put the "actual array" through the test I needed, and it worked. Thanks, –  Tequila Feb 12 '12 at 17:17

First of all implementing a matrix using a list of lists is inefficient if you need random access because that is going to cost `O(n + m)` instead of the cheaper `O(1)` using a bidimensional array.

To check for symmetry the first thing is ensuring that the matrix is square and then you just need to check that element `m_ij` is equal to element `m_ji` for all pairs.

Since you need checking all pairs for symmetry it makes sense to only consider `i > j` to avoid doing each test twice (`>` and not `>=` because clearly `m_ii` is equal to itself).

As an added bonus checking for symmetry doesn't require considering main diagonal elements.

``````(defun symmetric (m)
(let ((rows (array-dimension m 0))
(cols (array-dimension m 1)))
(when (= rows cols)
(dotimes (i rows T)
(dotimes (j i)
(unless (= (aref m i j) (aref m j i))
(return-from symmetric NIL)))))))

(let ((m (make-array (list 5 5) :initial-element 0)))
(dotimes (i 5)
(dotimes (j 5)
(setf (aref m i j) (* (1+ i) (1+ j)))))
(print m)
(print (symmetric m))
(setf (aref m 3 2) 9)
(print m)
(print (symmetric m)))
``````
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However, the title is vague, given your example, the analogue would probably be this:

``````(defun symmetric-2d-list-p (list)
(equal (reverse (mapcar #'reverse list)) list))

(symmetric-2d-list-p '((1 1 1) (2 2) (3) (2 2) (1 1 1))) ; T
(symmetric-2d-list-p '((2 1 2) (2 2) (3) (2 2) (2 1 2))) ; T
(symmetric-2d-list-p '((1 1 1) (2 2) (3 4) (2 2) (1 1 1))) ; NIL
``````

But you really want to clarify, because 2d arrays are entirely different things, then lists containing lists.

It may certainly be a better answer, the one that doesn't require creation of additional lists. I really did it this way because of your original example. Hopefully someone will post a more optimal version.

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