The following code uses the Euclidean algorithm to calculate gcd(a,b) and integers s, t such that sa+tb=gcd(a,b) (for a Discrete Mathematics course). I coded it in C, and perhaps this will clearly illustrate the algorithm.
gcd.c:
#include <stdio.h>
int gcd_st(int m, int n, int *s, int *t) {
int a, b, res, tmp;
a = m>n?m:n;
b = m>n?n:m;
if(!b) {
*s = 1;
*t = 0;
return a;
}
res = gcd_st(b, a%b, s, t);
tmp = *t;
*t = *s - *t*(a/b);
*s = tmp;
return res;
}
int main() {
int st[2];
for(int i=0; i<100000000; i++)
gcd_st(42, 56, st, st+1);
for(int i=0; i<100000000; i++)
gcd_st(273, 110, st, st+1);
int res = gcd_st(42, 56, st, st+1);
printf("%d %d %d\n", res, st[0], st[1]);
res = gcd_st(273, 110, st, st+1);
printf("%d %d %d\n", res, st[0], st[1]);
}
Just for fun, I decided to code it in Scheme (Lisp) as well. At first, I tested it on MIT Scheme's implementation, and then using Racket's implementation.
gcd.scm (without first two lines); gcd.rkt (including first two lines):
#!/usr/bin/racket
#lang racket/base
(define (gcd_st m n)
(let ((a (max m n)) (b (min m n)))
(if (= b 0) (list a 1 0)
(let ((res (gcd_st b (remainder a b))))
(let ((val (list-ref res 0))
(s (list-ref res 1))
(t (list-ref res 2)))
(list val t (- s (* t (quotient a b)))))))))
(define (loop n fn)
(if (= n 0) 0
(loop (- n 1) fn)))
(loop 100000000 (lambda () (gcd_st 42 56)))
(loop 100000000 (lambda () (gcd_st 273 110)))
(display "a b: (gcd s t)\n42 56: ")
(display (gcd_st 42 56))
(display "\n273 110: ")
(display (gcd_st 273 110))
(display "\n")
Both programs run 10^8 iterations on two sample cases and produce the same output. However, the two Scheme implementations (which share the same code/algorithm) differ greatly in performance. The Racket implementation is also a great deal quicker than the C implementation, which in turn is much faster than the MIT-Scheme implementation.
The time difference is so drastic I thought maybe Racket was optimizing out the entire loop, since the result is never used, but the time still does seem to scale linearly with loop iterations. Is it possible that it is doing some introspection and optimizing out some of the code in the loop?
$ time ./gcd.rkt # Racket
0
0
a b: (gcd s t)
42 56: (14 1 -1)
273 110: (1 27 -67)
real 0m0.590s
user 0m0.565s
sys 0m0.023s
$ time scheme --quiet <gcd.scm # MIT-Scheme
a b: (gcd s t)
42 56: (14 1 -1)
273 110: (1 27 -67)
real 0m59.250s
user 0m58.886s
sys 0m0.129s
$ time ./gcd.out # C
14 1 -1
1 27 -67
real 0m7.987s
user 0m7.967s
sys 0m0.000s
Why is the Racket implementation so much quicker?
=====
Update: If anyone's wondering, here are the results using the corrected loop function taking the answer into account:
loop:
(define (loop n fn)
(fn)
(if (= n 1) 0
(loop (- n 1) fn)))
Racket (still slightly outperforms C, even including its setup time):
real 0m7.544s
user 0m7.472s
sys 0m0.050s
MIT Scheme
real 9m59.392s
user 9m57.568s
sys 0m0.113s
The question still holds about the large difference between the Scheme implementations (still large), however. I'll ask this separately to ignore confusion with the previous error.
timeform to get timing for just running the function, without startup time etc: docs.racket-lang.org/reference/…quotient/remainderand multiple values: docs.racket-lang.org/reference/…quotientandremainderaren't even being called in the loop though. The problem here is it's not being called. See my answer for details. Also, while it's true that Racket is not especially optimized, keep in mind in this post, it's out performing MIT Scheme, not slower. So Racket not being well optimized can't be the answer. I'm actually still wondering why MIT Scheme is so much slower than Racket when simply counting down from 100 million in a loop.