Proper divisors
The proper divisors of a positive integer N are those numbers, other than N itself, that divide N without remainder.
For N > 1 they will always include 1, but for N == 1 their are no proper divisors.
For example the proper divisors of 6 are 1, 2, and 3. The proper divisors of 100 are 1, 2, 4, 5, 10, 20, 25, and 50.
- Task
- Create a routine to generate all the proper divisors of a number.
- use it to show the proper divisors of the numbers 1 to 10 inclusive.
- Find a number in the range 1 to 20,000 with the most proper divisors. Show the number and just the count of how many proper divisors it has.
Show all output here.
- Cf.
D
Currently the lambda of the filter allocates a closure on the GC-managed heap. <lang d>void main() /*@safe*/ {
import std.stdio, std.algorithm, std.range, std.typecons;
immutable properDivs = (in uint n) pure nothrow @safe /*@nogc*/ => iota(1, (n + 1) / 2 + 1).filter!(x => n % x == 0 && n != x);
iota(1, 11).map!properDivs.writeln; iota(1, 20_001).map!(n => tuple(properDivs(n).count, n)).reduce!max.writeln;
}</lang>
- Output:
[[], [1], [1], [1, 2], [1], [1, 2, 3], [1], [1, 2, 4], [1, 3], [1, 2, 5]] Tuple!(uint, int)(79, 18480)
The Run-time is about 0.67 seconds with the ldc2 compiler.
J
The proper divisors of an integer are the Factors of an integer without the integer itself.
So, borrowing from the J implementation of that related task:
<lang J>factors=: [: /:~@, */&>@{@((^ i.@>:)&.>/)@q:~&__ properDivisors=: factors -. -.&1</lang>
Proper divisors of numbers 1 through 10:
<lang J> (,&": ' -- ' ,&": properDivisors)&>1+i.10 1 -- 1 2 -- 1 3 -- 1 4 -- 1 2 5 -- 1 6 -- 1 2 3 7 -- 1 8 -- 1 2 4 9 -- 1 3 10 -- 1 2 5</lang>
Number(s) not exceeding 20000 with largest number of proper divisors (and the count of those divisors):
<lang J> (, #@properDivisors)&> 1+I.(= >./) #@properDivisors@> 1+i.20000 15120 79 18480 79</lang>
Note that it's more efficient to simply count factors here, when selecting the candidate numbers.
<lang J> (, #@properDivisors)&> 1+I.(= >./) #@factors@> 1+i.20000 15120 79 18480 79</lang>
We could also arbitrarily toss either 15120 or 18480, if that were important.
Java
<lang java5>import java.util.Collections; import java.util.LinkedList; import java.util.List;
public class Proper{
public static List<Integer> properDivs(int n){ List<Integer> divs = new LinkedList<Integer>(); divs.add(1); for(int x = 2; x < n; x++){ if(n % x == 0) divs.add(x); } Collections.sort(divs); return divs; } public static void main(String[] args){ for(int x = 1; x <= 10; x++){ System.out.println(x + ": " + properDivs(x)); } int x = 0, count = 0; for(int n = 1; n <= 20000; n++){ if(properDivs(n).size() > count){ x = n; count = properDivs(n).size(); } } System.out.println(x + ": " + count); }
}</lang>
- Output:
1: [1] 2: [1] 3: [1] 4: [1, 2] 5: [1] 6: [1, 2, 3] 7: [1] 8: [1, 2, 4] 9: [1, 3] 10: [1, 2, 5] 15120: 79
Perl
Using a module for divisors
<lang perl>use ntheory qw/divisors/;
- Uses the task definition of pd(1) = 1, not the OEIS A032741 definition.
sub proper_divisors {
my $n = shift; return if $n == 0; return 1 if $n == 1; my @d = divisors($n); pop @d; @d;
} say "$_: ", join " ", proper_divisors($_) for 1..10;
- 1. For the max, we can do a traditional loop.
my($max,$ind) = (0,0); for (1..20000) {
my $nd = scalar proper_divisors($_); ($max,$ind) = ($nd,$_) if $nd > $max;
} say "$max $ind";
- 2. Or we can use List::Util's max with decoration (this exploits its implementation)
{
use List::Util qw/max/; no warnings 'numeric'; say max(map { scalar(proper_divisors($_)) . " $_" } 1..20000);
}</lang>
- Output:
1: 1 2: 1 3: 1 4: 1 2 5: 1 6: 1 2 3 7: 1 8: 1 2 4 9: 1 3 10: 1 2 5 79 15120 79 18480
Note that the first code will choose the first max, while the second chooses the last.
Python
Python: Literal
A very literal interpretation <lang python>>>> def proper_divs2(n): ... return {x for x in range(1, (n + 1) // 2 + 1) if n % x == 0 and n != x} ... >>> [proper_divs2(n) for n in range(1, 11)] [set(), {1}, {1}, {1, 2}, {1}, {1, 2, 3}, {1}, {1, 2, 4}, {1, 3}, {1, 2, 5}] >>> >>> n, length = max(((n, len(proper_divs2(n))) for n in range(1, 20001)), key=lambda pd: pd[1]) >>> n 15120 >>> length 79 >>> </lang>
Python: From prime factors
I found a reference on how to generate factors from all the prime factors and the number of times each prime factor goes into N - its multiplicity.
For example, given N having prime factors P(i) with associated multiplicity M(i}) then the factors are given by:
for m[0] in range(M(0) + 1): for m[1] in range(M[1] + 1): ... for m[i - 1] in range(M[i - 1] + 1): mult = 1 for j in range(i): mult *= P[j] ** m[j] yield mult
This version is over an order of magnitude faster for generating the proper divisors of the first 20,000 integers; at the expense of simplicity. <lang python>from math import sqrt from functools import lru_cache, reduce from collections import Counter from itertools import product
MUL = int.__mul__
def prime_factors(n):
'Map prime factors to their multiplicity for n' d = _divs(n) d = [] if d == [n] else (d[:-1] if d[-1] == d else d) pf = Counter(d) return dict(pf)
@lru_cache(maxsize=None) def _divs(n):
'Memoized recursive function returning prime factors of n as a list' for i in range(2, int(sqrt(n)+1)): d, m = divmod(n, i) if not m: return [i] + _divs(d) return [n]
def proper_divs(n):
Return the set of proper divisors of n. pf = prime_factors(n) pfactors, occurrences = pf.keys(), pf.values() multiplicities = product(*(range(oc + 1) for oc in occurrences)) divs = {reduce(MUL, (pf**m for pf, m in zip(pfactors, multis)), 1) for multis in multiplicities} try: divs.remove(n) except KeyError: pass return divs or ({1} if n != 1 else set())
if __name__ == '__main__':
rangemax = 20000 print([proper_divs(n) for n in range(1, 11)]) print(*max(((n, len(proper_divs(n))) for n in range(1, 20001)), key=lambda pd: pd[1]))</lang>
- Output:
[set(), {1}, {1}, {1, 2}, {1}, {1, 2, 3}, {1}, {1, 2, 4}, {1, 3}, {1, 2, 5}] 15120 79