# Fastest algorithm of getting precise answer (not approximated) when square-rooting

Sorry for unclear title, but I don't know how to state it properly (feel free to edit), so I will give example:

sqrt(108) ~ 10.39... BUT I want it to be like this sqrt(108)=6*sqrt(3) so it means expanding into two numbers

So that's my algorithm

``````i = floor(sqrt(number))                  //just in case, floor returns lowest integer value :)
while (i > 0)                            //in given example number 108
if (number mod (i*i) == 0)
first = i                            //in given example first is 6
second = number / (i*i)              //in given example second is 3
i = 0
i--
``````

Maybe you know better algorithm?

If it matters I will use PHP and of course I will use appropriate syntax

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Any integer factorization algorithm will do, but they are difficult to implement. What makes you think the above will not be fast enough for your purposes? In the practical world, fastest != best if it's too hard to do and unnecessary for the problem at hand. –  mellamokb Feb 18 '11 at 16:12
This algorithm doesn't seem to work for more interesting cases, like 2700. –  Konrad Garus Feb 18 '11 at 16:38
Yeah what I mean was most practical –  Templar Feb 18 '11 at 16:47
@Konrad Garus I tried and it worked with 2700 –  Templar Feb 18 '11 at 16:49
Does it not return 25 * sqrt(108) ? –  Konrad Garus Feb 18 '11 at 17:10

There is no fast algorithm for this. It requires you to find all the square factors. This requires at least some factorizing.

But you can speed up your approach by quite a bit. For a start, you only need to find prime factors up to the cube root of n, and then test whether n itself is a perfect square using the advice from Fastest way to determine if an integer's square root is an integer.

Next speed up, work from the bottom factors up. Every time you find a prime factor, divide n by it repeatedly, accumulating out the squares. As you reduce the size of n, reduce your limit that you'll go to. This lets you take advantage of the fact that most numbers will be divisible by some small numbers, which quickly reduces the size of the number you have left to factor, and lets you cut off your search sooner.

Next performance improvement, start to become smarter about which numbers you do trial divisions by. For instance special case 2, then only test odd numbers. You've just doubled the speed of your algorithm again.

But be aware that, even with all of these speedups, you're just getting more efficient brute force. It is still brute force, and still won't be fast. (Though it will generally be much, much faster than your current idea.)

Here is some pseudocode to make this clear.

``````integer_sqrt = 1
remainder = 1

# First we special case 2.
while 0 == number % 4:
integer_sqrt *= 2
number /= 4

if 0 == number / 2:
number /= 2
remainder *= 2

# Now we run through the odd numbers up to the cube root.
# Note that beyond the cube root there is no way to factor this into
#    prime * prime * product_of_bigger_factors
limit = floor(cube_root(number + 1))
i = 3
while i <= limit:
if 0 == number % i:
while 0 == number % (i*i):
integer_sqrt *= i
number /= i*i
if 0 == number % (i*i):
number /= i
remainder *= i
limit = floor(cube_root(number + 1))
i += 2

# And finally check whether we landed on the square of a prime.

possible_sqrt = floor(sqrt(number + 1))
if number == possible_sqrt * possible_sqrt:
integer_sqrt *= possible_sqrt
else:
remainder *= number

# And the answer is now integer_sqrt * sqrt(remainder)
``````

Note that the various +1s are to avoid problems with the imprecision of floating point numbers.

Running through all of the steps of the algorithm for 2700, here is what happens:

``````number = 2700
integer_sqrt = 1
remainder = 1

enter while loop
number is divisible by 4
integer_sqrt *= 2 # now 2
number /= 4 # now 675

number is not divisible by 4
exit while loop

number is not divisible by 2

limit = floor(cube_root(number + 1)) # now 8
i = 3
enter while loop
i < =limit # 3 < 8
enter while loop
number is divisible by i*i # 9 divides 675
integer_sqrt *= 3 # now 6
number /= 9 # now 75

number is not divisible by i*i # 9 does not divide 75
exit while loop

i divides number # 3 divides 75
number /= 3 # now 25
remainder *= 3 # now 3

limit = floor(cube_root(number + 1)) # now 2

i += 2 # now 5

i is not <= limit # 5 > 2
exit while loop

possible_sqrt = floor(sqrt(number + 1)) # 5

number == possible_sqrt * possible_sqrt # 25 = 5 * 5
integer_sqrt *= possible_sqrt # now 30

# and now answer is integer_sqrt * sqrt(remainder) ie 30 * sqrt(3)
``````
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You said: "then test whether n itself is a perfect square" so can't I test it with if (sqrt (D) = floor(sqrt (D)))? Also speaking about prime numbers, how I can get them, I mean in loop I can increase only by one number –  Templar Feb 18 '11 at 17:35
@Templar: The problem with floor(sqrt(D)) is that imprecision in floating point can cause floor(sqrt(k*k)) to be k-1. But you can test whether n == floor(sqrt(n+1))**2 and that should be reliable for numbers into the trillions. As for finding prime numbers, do as I said. Test 2, then test 3, 5, 7, 9, 11, ... - you will do extra work but you'll get all of the primes. If you want to find only primes and divide by them, that will be a lot of complications, which won't likely pay off until you get past a few million. –  btilly Feb 18 '11 at 18:37
I don't understand, could you show me example, please? –  Templar Feb 18 '11 at 18:56
I have updated with pseudo-code, and a trace of how this algorithm breaks sqrt(2700) into 30*sqrt(3). –  btilly Feb 18 '11 at 20:32
Thanks for such big answer, I will study it –  Templar Feb 19 '11 at 19:34
1. List all prime divisors in increasing order e.g. 2700 = 2*2*3*3*3*5*5. This is the slowest step and requires sqrt(N) operations.
2. Create an accumulator (start with 1). Scan this list. For every pair of numbers, multiply the accumulator by (one of) them. So after scanning the list above, you get 2*3*5.
3. Accumulator is your multiplier. The rest remains under square root.
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Your pessimistic case should be much, much more pessimistic than that. –  btilly Feb 18 '11 at 16:47
@btilly Example? To find list of divisors, 2^N needs N operations, prime numbers need sqrt(P). –  Konrad Garus Feb 18 '11 at 16:54
Sorry, I had not updated my page when I made the comment, and still saw your original log(n) estimate. –  btilly Feb 18 '11 at 17:00