A^2+B^2+C^2+D^2 = N
Given an integer N
, print out all possible combinations of integer values of ABCD
which solve the equation.
I am guessing we can do better than brute force.
I am guessing we can do better than brute force. 


The Wikipedia page has some interesting background information, but Lagrange's foursquare theorem (or, more correctly, Bachet's Theorem  Lagrange only proved it) doesn't really go into detail on how to find said squares. As I said in my comment, the solution is going to be nontrivial. This paper discusses the solvability of foursquare sums. The paper alleges that:
For more information, see Modular Forms. This is not easy to understand unless you have some background in number theory. If you could generalize Ramanujan's 54 forms, you may have an easier time with this. With that said, in the first paper I cite, there is a small snippet which discusses an algorithm that may find every solution (even though I find it a bit hard to follow):
(Emphasis mine.) The algorithm is described as being recursive, but it could easily be implemented iteratively. 


It seems as though all integers can be made by such a combination:
and so forth As I did some initial working in my head, I thought that it would be only the perfect squares that had more than 1 possible solution. However after listing them out it seems to me there is no obvious order to them. However, I thought of an algorithm I think is most appropriate for this situation: The important thing is to use a 4tuple (a, b, c, d). In any given 4tuple which is a solution to a^2 + b^2 + c^2 + d^2 = n, we will set ourselves a constraint that a is always the largest of the 4, b is next, and so on and so forth like:
Also note that a^2 cannot be less than n/4, otherwise the sum of the squares will have to be less than n. Then the algorithm is:
At this point we have selected a particular a, and are now looking at bridging the gap from a^2 to n  i.e. (n  a^2)
and so on and so forth. So the entire algorithm would look something like:
At steps 3b and 5b I use (n  a^2)/3, (n  a^2  b^2)/2. We divide by 3 or 2, respectively, because of the number of values in the tuple not yet 'fixed'. An example: doing this on n = 12:
These are the only two possible tuples  hey presto! 


Naive brute force would be something like:
Unfortunately, this will result in over a trillion loops, not overly efficient. You can actually do substantially better than that by discounting huge numbers of impossibilities at each level, with something like:
It's still brute force, but not quite as brutish inasmuch as it understands when to stop each level of looping as early as possible. On my (relatively) modest box, that takes under a second ^{(a)} to get all solutions for numbers up to 50,000. Beyond that, it starts taking more time:
For So, I would say brute force is perfectly acceptable up to a point. Beyond that, more mathematical solutions would be needed. For even more efficiency, you could only check those solutions where In addition, the body of the Getting the results for
That code follows:
And, as per a suggestion by DSM, the That version is as follows:
^{(a)}: All timings are done with the inner 


nebffa has a great answer. one suggestion:
max_c and max_d can be improved in the same way too. Here is another try:
now the problem is to find 4 numbers from the array that sum(a, b,c,d) = N;
We can loop a from nr down to nr/2 and calculate r = N  S[a]; now the question is to find 3 numbers from S the sum(b,c,d) = r = N S[a]; here is code:
runtime is Here is the test result running java on my VM (time in milliseconds, result# is total num of valid combination, time 1 with printout, time2 without printout):


