I'm playing with functional capacities of Python 3 and I tried to implement classical algorithm for calculating Hamming numbers. That's the numbers which have as prime factors only 2, 3 or 5. First Hamming numbers are 2, 3, 4, 5, 6, 8, 10, 12, 15, 16, 18, 20 and so on.
My implementation is the following:
def scale(s, m): return (x*m for x in s) def merge(s1, s2): it1, it2 = iter(s1), iter(s2) x1, x2 = next(it1), next(it2) if x1 < x2: x = x1 it = iter(merge(it1, s2)) elif x1 > x2: x = x2 it = iter(merge(s1, it2)) else: x = x1 it = iter(merge(it1, it2)) yield x while True: yield next(it) def integers(): n = 0 while True: n += 1 yield n m2 = scale(integers(), 2) m3 = scale(integers(), 3) m5 = scale(integers(), 5) m23 = merge(m2, m3) hamming_numbers = merge(m23, m5)
The problem it that merge seems just doesn't work. Before that I implemented Sieve of Eratosthenes the same way, and it worked perfectly okay:
def sieve(s): it = iter(s) x = next(it) yield x it = iter(sieve(filter(lambda y: x % y, it))) while True: yield next(it)
This one uses the same techniques as my merge operation. So I can't see any difference. Do you have any ideas?
(I know that all of these can be implemented other ways, but my goal exactly to understand generators and pure functional capabilities, including recursion, of Python, without using class declarations or special pre-built Python functions.)
UPD: For Will Ness here's my implementation of this algorithms in LISP (Racket actually):
(define (scale str m) (stream-map (lambda (x) (* x m)) str)) (define (integers-from n) (stream-cons n (integers-from (+ n 1)))) (define (merge s1 s2) (let ((x1 (stream-first s1)) (x2 (stream-first s2))) (cond ((< x1 x2) (stream-cons x1 (merge (stream-rest s1) s2))) ((> x1 x2) (stream-cons x2 (merge s1 (stream-rest s2)))) (else (stream-cons x1 (merge (stream-rest s1) (stream-rest s2))))))) (define integers (integers-from 1)) (define hamming-numbers (stream-cons 1 (merge (scale hamming-numbers 2) (merge (scale hamming-numbers 3) (scale hamming-numbers 5)))))