The OP's code works for me. However I felt motivated to improve it and
I implemented the same idea (but a bit more powerful).

The semantics are the same as Matlab's vertcat.
The function appends all arguments into one big matrix.

Note that due to the declarations my code should be super efficient.

```
(deftype mat ()
"Non-square matrices. Last index is columns, i.e. row-major order."
`(simple-array single-float 2))
(defun are-all-elements-typep (type ls)
(reduce #'(lambda (b x) (and b (typep x type)))
ls))
(defun are-all-matrix-heights-equalp (ls)
(let ((first-height (array-dimension (first ls) 0)))
(reduce #'(lambda (b x) (and b
(= first-height
(array-dimension x 0))))
ls)))
(defun vertcat (&rest rest)
(declare (type cons rest))
(unless (are-all-elements-typep 'mat rest)
(break "At least one of the arguments isn't a matrix."))
(unless (are-all-matrix-heights-equalp rest)
(break "All Matrices must have the same number of rows."))
(let* ((height (array-dimension (first rest) 0))
(widths (mapcar #'(lambda (mat) (array-dimension mat 1)) rest))
(result (make-array (list height
(reduce #'+ widths))
:element-type 'single-float))
(current-width 0))
(dotimes (m (length rest))
(let ((e (elt rest m)))
(destructuring-bind (y x) (array-dimensions e)
(dotimes (j y)
(dotimes (i x)
(setf (aref result j (+ current-width i))
(aref e j i))))
(incf current-width (elt widths m)))))
(the mat result)))
#+nil
(let ((a (make-array '(2 3)
:initial-contents '((1s0 2s0 3s0)
(2s0 4s0 5s0))
:element-type 'single-float))
(b (make-array '(2 2)
:initial-contents '((6s0 7s0)
(9s0 8s0))
:element-type 'single-float)))
(vertcat a b a))
;=> #2A ((1.0 2.0 3.0 6.0 7.0 1.0 2.0 3.0) (2.0 4.0 5.0 9.0 8.0 2.0 4.0 5.0))
```