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# Sum of number of divisor of number between a and b inclusive

Let there be a function g(x)=number of divisor of x. Given two integers a and b we need to find->

g(a)+g(a+1)....+g(b).

I thought this step->

``````for every x from a to b

sum+=number of divisor of x(in sqrt(x) complexity)
``````

but its given 1<=a<=b<=2^31-1

So to iterate between a and b can cost me a lot of time....for eg->if a=1 and b=2^31-1.

Is there a better way to do?

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Are you given many `a` and `b` pairs or just one? – Dukeling Oct 15 '13 at 12:48
There can be many pairs in a test case! – user2826957 Oct 15 '13 at 12:49
You may learn more at en.wikipedia.org/wiki/Divisor_function – High Performance Mark Oct 15 '13 at 12:52
@user2826957 what's |b-a|? – Akashdeep Saluja Oct 15 '13 at 14:35
@ Akashdeep Saluja Its given b>=a... – user2826957 Oct 15 '13 at 16:48

Here's some simple but reasonably efficient Python code that does the job.

``````import math

def T(n):
"Return sum_{i=1}^n d(i), where d(i) is the number of divisors of i."
f = int(math.floor(math.sqrt(n)))
return 2 * sum(n // x for x in range(1, f+1)) - f**2

def count_divisors(a, b):
"Return sum_{i=a}^b d(i), where d(i) is the number of divisors of i."
return T(b) - T(a-1)
``````

Explanation: it's enough to be able to compute the sum from `1` to `b`, then we can do two separate computations and subtract to get the sum from `a` to `b`. Finding the sum of the divisor function from `1` to `b` amounts to computing sequence A006218 from the online encyclopaedia of integer sequences. That sequence is equivalent to the sum of `floor(n / d)` as `d` ranges over all integers from `1` to `n`.

And now that sequence can be thought of as the number of integer-valued points under the hyperbola `xy=n`. We can use the symmetry of the hyperbola around the line `x = y`, and count the integer points with `x <= sqrt(n)` and those with `y <= sqrt(n)`. That ends up double counting the points with both `x` and `y` less than `sqrt(n)`, so we subtract the square of `floor(sqrt(n))` to compensate. All this is explained (briefly) in the introduction to this paper.

Remarks:

• the algorithm has running time `O(sqrt(b))`, and constant space requirements. Improvements in running time are possible at the expense of space; see the paper referred to above.

• for really large `n`, you'll want a proper integer square root rather than using `floor(math.sqrt(n))`, to avoid problems with floating-point inaccuracies. That's not a problem with the sort of `n` that you're looking at. With typical IEEE 754 floating-point and a correctly rounded square root operation, you're not going to run into trouble until `n` exceeds `2**52`.

• if `a` and `b` are really close, there may be more efficient solutions.

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Very elegant answer with a couple of nice tricks that are well explained and fully understandable to people who have never heard of the divisor summatory function (`T`, A006218). Plus a clean, concise and efficient code. Good job! – Bolo Oct 15 '13 at 18:27

Because the desired result is the total number of divisors for all the numbers in a range, there's no need to count divisors of individual numbers in the range; instead, count the number of times 1 is a divisor, 2 is a divisor, etc. This is an O(b) computation.

That is, add up `b-(a-1)`, `b/2 - (a-1)/2`, `b/3 - (a-1)/3`, etc. .

In the python code shown below (which uses python operator // for integer division with truncation) divisors from 2 to about b/2 are counted using a `for` loop. Note that divisors that are smaller than `b` but larger than `max(a, b/2)` occur once each and need not be counted in a loop. The code uses the expression `b-max(a,(b+1)//2+1)+1` to count them. Output is shown after the program.

When `k` different `a,b` sets are to be treated, it is possible to compute all the answers in time O(k+`bₘₐₓ`) where `bₘₐₓ` is the largest value of `b`.

Python code:

``````def countdivisors(a,b):
mid = (b+1)//2+1
count = b-a+1 +b-max(a,mid)+1 # Count for d=1 & d=n
for d in xrange(2,mid):
count += b//d - (a-1)//d
return count
# Test it:
a=7
for b in range(a,a+16):
print '{:3} {:3} : {:5}'.format(a, b, countdivisors(a,b))
``````

Output:

``````  7   7 :     2
7   8 :     6
7   9 :     9
7  10 :    13
7  11 :    15
7  12 :    21
7  13 :    23
7  14 :    27
7  15 :    31
7  16 :    36
7  17 :    38
7  18 :    44
7  19 :    46
7  20 :    52
7  21 :    56
7  22 :    60
``````
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You can sieve for the count of divisors, then sum the counts:

``````function divCount(a,b)
num := makeArray(1..b, 0)
for i from 1 to b
for j from i to b step i
num[j] := num[j] + 1
sum := 0
for i from a to b
sum := sum + num[i]
return sum
``````

This is similar to a Sieve of Eratosthenes, but instead of marking off the composites it counts each divisor for every number, including both primes and composites. If b is too large, you can perform the sieving in segments.

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To save time, you can cap the inner loop at sqrt(b) and add 2 instead. If it equals the square root exactly you add just 1. – Bigtoes Oct 15 '13 at 13:22
@Geobits I don't think you can. We're creating a sieve, not calculating all divisors of a number. – Dukeling Oct 15 '13 at 13:52
@Dukeling Well, you can do what I had in mind, I just said it completely wrong. See my answer for what I actually meant. – Bigtoes Oct 15 '13 at 16:20

Another sieve-based answer, but with a better time complexity than the others. This one also handles segmentation easily, since it only sieves numbers `{a...b}` on each run. The function returns an `int[]` with the number of divisors for each number from `a` to `b`. Just sum them up to get the final answer.

If your inputs are larger, you can split it up and add the sums from each returned segment.

Java:

``````public static int[] getDivisorCount(int a, int b){
int[] sieve = new int[b - a + 1];
double max = Math.ceil(Math.sqrt(b));
for(int i = 1; i <= max; i++){
int j = (a / i) * i;
if(j < a)
j += i;
for( ; j <= b; j += i){
double root = Math.sqrt(j);
if(i < root){
sieve[j - a] += 2;
}else if(i == root){
sieve[j - a]++;
}
}
}
return sieve;
}
``````

The outer loop runs `sqrt(b)` times. The inner loop runs something like `log(b-a)` times, so unless I'm mistaken, the final complexity should be something like `O(sqrt(b) * log(b))`, since worst case is `a=1`. Feel free to correct me on that.

If you're handling large inputs and you have the space to spare, you might want to consider prepopulating a `sqrt` table to get it out of the inner loop. It would speed it up, and if you've got the memory to spare, there's no real down side to it.

For a quick test, here's an ideone.com example.

Edit: If you're looking for a sieve, this is fine. However, I must say that jwpat7's answer is 1)faster, 2) constant space, and 3) more elegant (IMO). There's basically no reason to use a sieve unless you're interested in the mechanics of it.

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We can adapt this algorithm: http://en.wikipedia.org/wiki/Sieve_of_Eratosthenes by adding 1 to all multiples instead of flagging them as "not prime"

it will be o(n.ln(n)) with a=1 and b=n (i think)

algorithm for 1 to n:

``````g: array of n elements
for i starting with 2 to n
if g[i]== 0
for each multiple of i <n
g[i] += 1
``````
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In the sieve method we skip some composite numbers like 12, but they may be are divisor of some numbers between a and b, and we should count them multiple time. – Saeed Amiri Oct 15 '13 at 14:42
Yes, i didn't see that. It will work if test if g[i]==0 before looping on each multiple of i. We will only add 1 if i is prime. – pdem Oct 16 '13 at 10:20