To attack problems like this, first describe a data type that captures the operations you want in your DSL, rather than concentrating on surface syntax. Once you've got the data type in hand, you should have a much easier time with the problem.
From a first glance, it looks like we can design 3 fundamental forms in your language:
We can represent this disjoint class with primitive strings and structures. Let's call this class as a whole a 'pexpr', for "printable expr". In code:
;; An pexpr is one of the following:
;; * a primitive string,
;; * a seq, or
;; * a repeat
(struct seq (bodies) #:transparent) ;; bodies is a list of pexpr
(struct repeat (n body) #:transparent) ;; n is a number, body is a pexpr
It might help to make some helper functions as abbreviations since "seq" and "repeat" are themselves a bit long-winded.
;; For convenience, we define some abbreviations s and r for seq and repeat,
(define (s . bodies)
(define (r n . bodies)
(repeat n (seq bodies)))
Your example "I" string can be written as this:
(r 3 (r 9 "X") "\n")
(r 6 (r 3 " ") (r 3 "X") "\n")
(r 3 (r 9 "X") "\n")))
Note that this encoding has an explicit representation for newlines which, from the surface syntax alone, is implicit. It then becomes the job of a parser to take lines in your surface syntax and turning them into pexprs, but that shouldn't be too difficult. Hopefully. :)
Anyway, the interpret function, then, becomes a matter of filling in the details for a template like this:
(define (interpret pexpr)
[(struct seq (bodies))
[(struct repeat (n body))
where the '...'s should be easy to fill in.
This approach to these kinds of problems is one described by How to Design Programs and Programming Languages: Application and Interpretation. I'd recommend looking at them: they're good stuff.