Excessive Integers

Question

For a positive integer n with the prime factorization n = p1^e1 * p2^e2 * ... pk^ek where p1,...,pk are primes and e1,...,ek are positive integers, we can define two functions:

• Ω(n) = e1+e2+...+ek the number of prime divisors (counted with multiplicity) (A001222)
  • ω(n) = k the number of distinct prime divisors. (A001221)

With those two functions we define the excess e(n) = Ω(n) - ω(n) (A046660). This can be considered as a measure of how close a number is to being squarefree.

Challenge

For a given positive integer n return e(n).

Examples

For n = 12 = 2^2 * 3 we have Ω(12) = 2+1 and ω(12) = 2 and therefore e(12) = Ω(12) - ω(12) = 1. For any squarefree number n we obivously have e(n) = 0. The first few terms are

1       0
2       0
3       0
4       1
5       0
6       0
7       0
8       2
9       1
10      0
11      0
12      1
13      0
14      0
15      0

Some more details in the OEIS wiki.

Answer 1

MATL, 7 5 bytes

Yfd~s

Try it online! Or verify all test cases.

Explanation

Yf    % Implicit input. Obtain prime factors, sorted and with repetitions
d     % Consecutive differences
~     % Logical negate: zeros become 1, nonzeros become 0
s     % Sum. Implicit display

Answer 2

Brachylog, 11 bytes

$pPd:Pr:la-

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Explanation

$pP            P is the list of prime factors of the Input
  Pd           Remove all duplicates in P
    :Pr        Construct the list [P, P minus duplicates]
       :la     Apply "length" to the two elements of that list
          -    Output is the subtraction of the first element by the second one

Answer 3

Mathematica, 23 bytes

PrimeOmega@#-PrimeNu@#&

Very boring. FactorInteger already takes up 13 bytes, and I can't see much that can be done with the remaining 10.

Answer 4

Jelly, 5 bytes

ÆfI¬S

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Verify all testcases.

Port of Luis Mendo's answer in MATL.

ÆfI¬S

Æf     Implicit input. Obtain prime factors, sorted and with repetitions
  I    Consecutive differences
   ¬   Logical negate: zeros become 1, nonzeros become 0
    S  Sum. Implicit display

Answer 5

J, 11 10 bytes

Saved 1 byte thanks to Jonah.

1#.1-~:@q:

Answer 6

05AB1E, 6 bytes

Òg¹fg-

Explanation

Òg      # number of prime factors with duplicates
     -  # minus
  ¹fg   # number of prime factors without duplicates

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Answer 7

Haskell, 65 bytes

(c%x)n|x>n=c|mod n x>0=c%(x+1)$n|y<-div n x=(c+0^mod y x)%x$y
0%2

Answer 8

05AB1E, 4 bytes

Ò¥_O

Port of @LuisMendo's MATL answer.

Try it online or verify the first 15 test cases.

Explanation:

Ò       # Get all prime factors with duplicates from the (implicit) input
        # (automatically sorted from lowest to highest)
 ¥      # Get all deltas
  _     # Check if it's equal to 0 (0 becomes 1; everything else becomes 0)
   O    # Take the sum (and output implicitly)

Answer 9

Husk, ⁵ 4 bytes

ΣẊ=p

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-1 byte from Dominic Van Essen.

Answer 10

Pyth, 7 bytes

-lPQl{P

Try it online.

Answer 11

C, 74 bytes

f(n,e,r,i){r=0;for(i=2;n>1;i++,r+=e?e-1:e)for(e=0;n%i<1;e++)n/=i;return r;}

Ideone it!

Answer 12

Python 2, 57 56 bytes

f=lambda n,k=2:n/k and[f(n,k+1),(n/k%k<1)+f(n/k)][n%k<1]

Thanks to @JonathanAllan for golfing off 1 byte!

Test it on Ideone.

Answer 13

Python 2, 100 99 98 96 bytes

n=input()
i=2
f=[]
while i<n:
 if n%i:i+=1
 else:n/=i;f+=i,
if-~n:f+=n,
print len(f)-len(set(f))

Most of the code is taken up by a golfed version of this SO answer, which stores the prime factors of the input in f. Then we simply use set manipulation to calculate the excess factors.

Thanks to Leaky Nun for saving 1 3 bytes!

Answer 14

Brachylog, 11 bytes

$p@b:la:-a+

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Verify all testcases. (The wrapper is longer than the function...)

$p@b:la:-a+

$p            prime factorization
  @b          group blocks of equal elements
    :la       length of each
       :-a    each minus 1
          +   sum

Answer 15

S.I.L.O.S, 113 bytes

readIO
t=2
lbla
e=0
GOTO b
lblc
i/t
e+1
lblb
m=i
m%t
n=1
n-m
if n c
d=e
d/d
e-d
r+e
A=i
A-1
t+1
if A a
printInt r

Try it online!

A port of my answer in C.

Answer 16

Javascript (ES6), 53 51 46 bytes

e=(n,i=2)=>i<n?n%i?e(n,i+1):e(n/=i,i)+!(n%i):0

Saved 5 bytes thanks to Neil

Example:

e=(n,i=2)=>i<n?n%i?e(n,i+1):e(n/=i,i)+!(n%i):0

// computing e(n) for n in [1, 30]
for(var n = 1, list = []; n <= 30; n++) {
  list.push(e(n));
}
console.log(list.join(','));

Answer 17

Bash, 77 bytes

IFS=$'\n '
f=(`factor $1`)
g=(`uniq<<<"${f[*]}"`)
echo $((${#f[*]}-${#g[*]}))

Complete program, with input in $1 and output to stdout.

We set IFS to begin with a newline, so that the expansion "${f[*]}" is newline-separated. We use arithmetic substitution to print the difference between the number of words in the factorisation with the result of filtering through uniq. The number itself is printed as a prefix by factor, but it is also present after filtering, so falls out in the subtraction.

Answer 18

Japt, 6 bytes

k äÎxÌ

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k äÎxÌ     :Implicit input of integer
k          :Prime factors
  ä        :Consecutive pairs reduced by
   Î       :  Signs of differences (0 or -1)
    x      :Sum of
     Ì     :  Signs of differences with -1 (0 -> 1 and -1 -> 0)

Answer 19

Factor + math.primes.factors math.unicode, 40 bytes

[ group-factors unzip Σ swap length - ]

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               ! 12
group-factors  ! { { 2 2 } { 3 1 } }
unzip          ! { 2 3 } { 2 1 }
Σ              ! { 2 3 } 3
swap           ! 3 { 2 3 }
length         ! 3 2
-              ! 1

Answer 20

Pyt, 4 bytes

ḋ₋¬Ʃ

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Port of Leaky Nun's Jelly answer

Answer 21

Haskell, 87 bytes

import Data.Numbers.Primes
import Data.List
x=(\x->length x-length(nub x)).primeFactors

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Answer 22

Kamilalisp, 15 bytes

[-&[⍴] #0 ⊙]@⋔⌹

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Answer 23

Nekomata, 3 bytes

ƒ←∑

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ƒ       Factor; returns a list of unique prime factors and a list of their exponents
 ←      Decrement the exponents
  ∑     Sum

Answer 24

Ruby -rprime, 31 bytes

->n{n.prime_division.sum{_2-1}}

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Answer 25

Python, (with sympy) 66 bytes

import sympy;lambda n:sum(x-1for x in sympy.factorint(n).values())

sympy.factorint returns a dictionary with factors as keys and their multiplicities as values, so the sum of the values is Ω(n) and the number of values is ω(n), so the sum of the decremented values is what we want.

Answer 26

CJam, 11 bytes

ri_mf,\mF,-

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Explanation

ri_         Get an integer from input and duplicate it
   mf,      Get the number of prime factors (with repetition)
      \     Swap top 2 elements on the stack
       mF,  Get the number of prime factors (with exponents)
          - Subtract

Answer 27

C, 158

#define G(a,b) if(a)goto b
#define R return
f(n,i,j,o,w){if(!n)R 0;o=w=i=j=0;a:i+=2;b:if(n%i==0){++j;G(n/=i,b);}o+=!!j;w+=j;i+=(i==2);j=0;G(i*i<n,a);R w-o;}

In the start there is the goto instruction... even if this is more long than yours it is more readable and right [if i not consider n too much big...] one Language that has 10000 library functions is wrost than a Language that with few, 20 or 30 library functions can do all better [because we can not remember all these functions]

#define F for
#define P printf

main(i,r)
{F(i=0; i<100; ++i)
   r=f(i,0,0,0,0),P("[%u|%u]",i,r);
 R  0;
}

/*
 158
 [0|0][1|0][2|0][3|0][4|1][5|0][6|0][7|0][8|2]
 [9|0][10|0][11|0][12|1][13|0][14|0][15|0][16|3]
 [17|0][18|0][19|0][20|1][21|0][22|0][23|0][24|2][25|1][26|0][27|0] [28|1]
 [29|0][30|0][31|0][32|4][33|0][34|0][35|0][36|1]
 [37|0][38|0][39|0][40|2][41|0]
 */

Answer 28

GNU sed + coreutils, 55 bytes

(including +1 for -r flag)

s/^/factor /e
s/ ([^ ]+)(( \1)*)/\2/g
s/[^ ]//g
y/ /1/

Input in decimal, on stdin; output in unary, on stdout.

Explanation

#!/bin/sed -rf

# factor the number
s/^/factor /e
# remove first of each number repeated 0 or more times
s/ ([^ ]+)(( \1)*)/\2/g
# count just the spaces
s/[^ ]//g
y/ /1/

Answer 29

APL(NARS) 35 chars, 70 bytes

{⍵=1:0⋄k-⍨+/+/¨{w=⍵⊃v}¨⍳k←≢v←∪w←π⍵}

the function π find the factorization in prime of its argument; there is few to say it seems clear, but for me does more operations (from factorization) than the minimum...the range of count characters is out golfing languages because it seems too much count, but less than not golfing languages... test:

  f←{⍵=1:0⋄k-⍨+/+/¨{w=⍵⊃v}¨⍳k←≢v←∪w←π⍵}
  f¨1..15
0 0 0 1 0 0 0 2 1 0 0 1 0 0 0 

Answer 30

Arturo, 47 bytes

$=>[k:tally factors.prime&(∑values k)-size k]

Try it!