# Double Squares: counting numbers which are sums of two perfect squares

A double-square number is an integer X which can be expressed as the sum of two perfect squares. For example, 10 is a double-square because 10 = 32 + 12. Given X, how can we determine the number of ways in which it can be written as the sum of two squares? For example, 10 can only be written as 32 + 12 (we don't count 12 + 32 as being different). On the other hand, 25 can be written as 52 + 02 or as 42 + 32.

You need to solve this problem for 0 ≤ X ≤ 2,147,483,647.

Examples:

• 10 => 1
• 25 => 2
• 3 => 0
• 0 => 1
• 1 => 1
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Just noting, this round has now ended. –  marcog Jan 11 '11 at 11:10
wasn't popularized as much as codejam. Just came to know about it. –  Senthil Kumaran Jan 11 '11 at 11:14
@Senthil Probably a good thing as the platform experienced a number of problems. –  marcog Jan 11 '11 at 11:15

Factor the number n, and check if it has a prime factor p with odd valuation, such that p = 3 (mod 4). It does if and only if n is not a sum of two squares.

The number of solutions has a closed form expression involving the number of divisors of n. See this, Theorem 3 for a precise statement.

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IIRC, this is the best solution. (The same problem was on SPOJ or somewhere.) For the factoring, it also helps to precompute a list of primes upto √MAX using a sieve.) –  ShreevatsaR Jan 11 '11 at 12:13
This algorithm is not fast as simple brute force one, because brute force algorithm is O(√n), but finding primes lower than `√n` with sieve is O(√n log log (n)), and if we assume log log n for this case is small, still it's O(√n) and also number of single operations on this is bigger than simple ones. –  Saeed Amiri Jan 11 '11 at 15:54
@Saeed: you compute the primes once only. Then it is factoring (which is indeed O(sqrt(n)) worst case, but much better on average). One way or the other, you need to brute force. –  Alexandre C. Jan 11 '11 at 16:22
Ok, so you saying finding primes lower than 2,147,483,647 and save it in array, there are around 99940774 primes lower than int limit (n/ln(n)), it will takes huge amount of memory, also still the number of primes lower than √n is √n/ln(√n) which is around √n, so if your basic computations are bigger than simple brute force algorithm basic computations ( ln(n) times), your running time is still slower than simple one. and if you wanna compare it simply, write your code, compare with i.e marcog simple algorithm. –  Saeed Amiri Jan 12 '11 at 6:10
@Saeed: you have to compute primes up to 46340. You could do it by hand if you wanted. –  Alexandre C. Jan 12 '11 at 9:30
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Here's a much simpler solution:

``````create list of squares in the given range (that's 46340 values for the example given)

for each square value x
if list contains a value y such that x + y = target value (i.e. does [target - x] exist in list)
output √x, √y as solution (roots can be stored in a std::map lookup created in the first step)
``````
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+1, basically the same approach I used in the contest. –  MAK Jan 11 '11 at 18:32

Looping through all pairs (a, b) is infeasible given the constrains on X. There is a faster way though!

For fixed a, we can work out b: b = √(X - a2). b won't always be an integer though, so we have to check this. Due to precision issues, perform the check with a small tolerance: if b is x.99999, we can be fairly certain it's an integer. So we loop through all possible values of a and count all cases where b is an integer. We need to be careful not to double-count, so we place the constraint that a <= b. For X = a2 + b2, a will be at most √(X/2) with this constraint.

Here is an implementation of this algorithm in C++:

``````int count = 0;
// add EPS to avoid flooring x.99999 to x
for (int a = 0; a <= sqrt(X/2) + EPS; a++) {
int b2 = X - a*a; // b^2
int b = (int) (sqrt(b2) + EPS);
if (abs(b - sqrt(b2)) < EPS) // check b is an integer
count++;
}
cout << count << endl;
``````

See it on ideone with sample input

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`For X = a2 + b2, a and b will each be at most √(X/2)` errr... what? Doesn't this directly contradict the example you gave yourself in the question? –  fearofawhackplanet Jan 11 '11 at 11:15
@fear Err, silly mistake I'll fix. –  marcog Jan 11 '11 at 11:17

Here is my simple answer in `O(sqrt(n))` complexity

``````x^2 + y^2 = n
x^2 = n-y^2
x = sqrt(n - y^2)
``````

x should be integer so `(n-y^2)` should be perfect square. Loop to `y=[0, sqrt(n)]` and check whether `(n-y^2)` is perfect square or not

Pseudocode :

``````count = 0;
for y in range(0, sqrt(n))
if( isPerfectSquare(n - y^2))
count++
return count/2
``````
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I was in a hurry, so solved it using a rather brute-force approach (very similar to marcog's) using Python 2.6.

``````def is_perfect_square(x):
rt = int(math.sqrt(x))
return rt*rt == x

def double_sqaures(n):
rng = int(math.sqrt(n))
ways = 0
for i in xrange(rng+1):
if is_perfect_square(n - i*i):
ways +=1
if ways % 2 == 0:
ways = ways // 2
else:
ways = ways // 2 + 1
return ways
``````

Note: `ways` will be odd when the number is a perfect sqaure.

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The number of solutions (x,y) of

x^2+y^2=n

over the integers is exactly 4 times the number of divisors of n congruent to 1 mod 4. Similar identities exist also for the problems

x^2 + 2y^2 = n

and

x^2 + y^2 + z^2 + w^2 = n.

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-1 for not caring to do proper research. There is such a simple formula, but it is different from what you describe. For more information, see mathworld.wolfram.com/SumofSquaresFunction.html –  vog Sep 18 at 16:54
According to your statement, n=9 would have 8 solutions, because it has two divisors d with d mod 4 = 1 (namely, d=1 and d=9). However, n=9 has no solutions at all! –  vog Sep 18 at 17:06
@vog `9 = 3^2 + 0^2` in the same way `25 = 5^2 + 0^2` in the problem statement. Not defending the answer, just nitpicking. –  Geobits Sep 18 at 20:16