My Programming Paradigms textbook, Essential of Programming Languages (3rd ed), Chapter 1 has an exercise:
Eliminate the one call to subst-in-s-exp in subst by replacing it by its definition and simplifying the resulting procedure. The result will be a version of subst that does not need subst-in-s-exp. This technique is called inlining, and is used by optimizing compilers.
The original code would have two functions:
subst-in-sexp which basically substitutes the all occurrences of old symbol with new symbol in the input list.
(define subst (lambda (new old slist) (if (null? slist) '() (cons (subst-in-s-exp new old (car slist)) (subst new old (cdr slist)))))) (define subst-in-s-exp (lambda (new old sexp) (if (symbol? sexp) (if (eqv? sexp old) new sexp) (subst new old sexp))))
The answer to this question is to eliminate
subst-in-sexp, which becomes this
(define subst (lambda (slist old new) (cond [ (null? slist) '()] [ (eqv? (car slist) old) (cons new (subst (cdr slist) old new))] [ else (cons (car slist) (subst (cdr slist) old new))])))
Why is in-lining better besides it may be a lot shorter (less space)? Does the size of the recursion changes? In other words, does this inlining creates fewer stack elements?
Moreover, how can I use this idea to make my C++, Python, and Java code faster? Can I extend this idea easily? Thanks.
I tagged this in Scheme (actually, Racket) because this is the choice of language in the book.