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There are a couple of ways to find integer square roots using only integer arithmetic. For example this one. It makes for interesting reading and also a very interesting theory, particularly for my generation where such techniques aren't so useful any more.

The main thing is that it can't use floating point arithmetic, so that rules out newtons method and it's derivations. The only other way I know of to find roots is binomial expansion, but that also requires floating point arithmetic.

What techniques/algorithms are there for computing integral nth roots using only integer arithmetic?

Edit: Thanks for all the answers so far. They all seem to be slightly more intelligent trial and improvement. Is there no better way?

Edit2: Ok, so it would seem there is no smart way to do this without trial/improvement and either newtons method or a binary search. Can anyone provide a comparison of the two in theory? I have run a number of benchmarks between the two and found them quite similar.

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What is your required range of input values ? –  Paul R Jan 11 '12 at 21:27
    
@PaulR, Ideally it could be extensible, but I think you can assume both the base and the number will be 32 bit (unsigned) integers for now. –  Matt Jan 11 '12 at 21:32
    
Which integer operations are you permitting? Square roots are a special case because it's possible to extract them using just addition, subtraction and shifts. –  Neil Jan 11 '12 at 21:39
    
@Neil, I don't want to place restrictions on it, as this is not for a particular application, but I would say a list similar to say the C list of integer operators: addition, subtraction, multiplication, (integer) division, modulo and bitwise operations. Ofc speed is always a consideration, but don't worry about it too much. –  Matt Jan 11 '12 at 21:46
    
In general: there is nothing in the world that you can do with floating point arithmetic and can't do with integer arithmetic almost the same way. At least because floating point arithmetic itself is implementable pretty easy via integer arithmetic. –  Serge Dundich Jan 12 '12 at 7:55
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5 Answers

up vote 5 down vote accepted

You can use Newton's method using only integer arithmetic, the step is the same as for floating point arithmetic, except you have to replace floating point operators with the corresponding integer operators in languages which have different operators for these.

Let's say you want to find the integer-k-th root of a > 0, which should be the largest integer r such that r^k <= a. You start with any positive integer (of course a good starting point helps).

int_type step(int_type k, int_type a, int_type x) {
    return ((k-1)*x + a/x^(k-1))/k;
}

int_type root(int_type k, int_type a) {
    int_type x = 1, y = step(k,a,x);
    do {
        x = y;
        y = step(k,a,x);
    }while(y < x);
    return x;
}

Except for the very first step, you have x == r <==> step(k,a,x) >= x.

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After looking again at newton raphson, I found there was a way to do it, but it very often reached a point where is flipped between two numbers (e.g. square root of 15 flips between 3 and 4). To counter for this the full solution is here –  Matt Jan 11 '12 at 22:27
    
For square roots, it's flipping precisely for a = n*n-1 between n-1 and n. I'm not sure if for higher powers there are more values that lead to flipping, but whenever the step increases the approximation to the root - excepting the very first step, if the starting point was smaller than the target - you're done, the smaller value is the integer root. –  Daniel Fischer Jan 11 '12 at 22:35
    
That is the same conclusion I reached, which is why I arrived at the code posted in my above comment. Regardless of base the values that flip seem to always be above and below the root, so the root is inbetween those two numbers (hence why it flips) my code deals with that. –  Matt Jan 12 '12 at 8:01
    
Ok, so it would appear the flipping is far more complex than I previously imagined (take the cube root of 7 and it flips between 1, 2 and 3. From that I can only imagine that the flipping is between n possible numbers for the nth root of A. This adds a lot of complexity to the algorithm. –  Matt Jan 12 '12 at 16:37
1  
Ok, I have this sorted. However, it would appear overflow is going to be a huge problem as you reach even reasonable sized numbers due to the use of x^(n-1) as that will result in overflow at even small values. No doubt this is a limitation of any solution using powers, but surely there is a way that does not require using very large values. If not then this solution is very limited, even with low exponents. –  Matt Jan 13 '12 at 17:06
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One obvious way would be to use binary search together with exponentiation by squaring. This will allow you to find nthRoot(x, n) in O(log (x + n)): binary search in [0, x] for the largest integer k such that k^n <= x. For some k, if k^n <= x, reduce the search to [k + 1, x], otherwise reduce it to [0, k].

Do you require something smarter or faster?

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I am interested to see if there are any methods that do not involve trial an improvement. Though exponentiation by squaring is a good find thanks, –  Matt Jan 12 '12 at 8:04
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It seems to me that the Shifting nth root algorithm provides exactly what you want:

The shifting nth root algorithm is an algorithm for extracting the nth root of a positive real number which proceeds iteratively by shifting in n digits of the radicand, starting with the most significant, and produces one digit of the root on each iteration, in a manner similar to long division.

There are worked examples on the linked wikipedia page.

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From the wikipedia page: "When the base is larger than the radicand, the algorithm degenerates to binary search". I will have a look if possibly working with (effectively) hex rather than binary will improve the algorithm. –  Matt Jan 13 '12 at 16:01
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One easy solution is to use the binary search.

Assume we are finding nth root of x.

Function GetRange(x,n):
    y=1
    While y^n < x:
        y*2
    return (y/2,y)

Function BinSearch(a,b,x,):
    if a == b+1:
        if x-a^n < b^n - x:
           return a
        else:
           return b
    c = (a+b)/2
    if n< c^n:
        return BinSearch(a,c,x,n)
    else:
        return BinSearch(c,b,x,n)

a,b = GetRange(x,n)
print BinSearch(a,b,x,n)

===Faster Version===

Function BinSearch(a,b,x,):
    w1 = x-a^n
    w2 = b^n - x
    if a <= b+1:
        if w1 < w2:
           return a
        else:
           return b
    c = (w2*a+w1*b)/(w1+w2)
    if n< c^n:
        return BinSearch(a,c,x,n)
    else:
        return BinSearch(c,b,x,n)
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In Perl, you calculate the nth root of x with

exp(log($x) / $n);

which suggests the simple expedient of using the integral version of the above as a first approximation and probing with binary search until you get as close as you can with an integer value.

sub
log2
{
    my ($n) = @_;
    my $count = -1;

    while ($n > 0) {
        $n >>= 1;
        $count++;
    }
    return $count;
}

sub
nth_root
{
    my ($n, $nth) = @_;

    my $log2root = log2($n) / $nth;
    my $start = 2 ** $log2root;
    my $end = 2 ** ($log2root + 1);
    my $root;

    while ($start < $end) {
        $root = int(($start + $end) / 2);
        if ($root ** $nth > $n) {
            $end = $root;
        } else {
            $start = $root + 1;
        }
    }
    return $root;
}
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Thanks, that looks like a good method for an initial guess, and I didn't know about that. I also happen to know of a very good integer log2 function (that is not shifting individual bits and adding). I will probably use that as an initial guess to something like newton raphson rather than the binary search as suggested here and by others. –  Matt Jan 12 '12 at 8:40
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