# Calculate square root of a BigInteger (System.Numerics.BigInteger)

.NET 4.0 provides the `System.Numerics.BigInteger` type for arbitrarily-large integers. I need to compute the square root (or a reasonable approximation -- e.g., integer square root) of a `BigInteger`. So that I don't have to reimplement the wheel, does anyone have a nice extension method for this?

• The simplest feasible way to compute a square root to an arbitrary precision is probably Newton's method. – mqp Aug 7 '10 at 23:16
• Sorry, but my brain hurts from just starting to think about the math behind this :-P. And the nubers are to big to cast to a long? – Alxandr Aug 7 '10 at 23:17
• Yes, I'd need around 256 bits, possibly 512 - so no cheating with ulongs – Anonym Aug 8 '10 at 1:01

Check if BigInteger is not a perfect square has code to compute the integer square root of a Java BigInteger. Here it is translated into C#, as an extension method.

``````    public static BigInteger Sqrt(this BigInteger n)
{
if (n == 0) return 0;
if (n > 0)
{
int bitLength = Convert.ToInt32(Math.Ceiling(BigInteger.Log(n, 2)));
BigInteger root = BigInteger.One << (bitLength / 2);

while (!isSqrt(n, root))
{
root += n / root;
root /= 2;
}

return root;
}

throw new ArithmeticException("NaN");
}

private static Boolean isSqrt(BigInteger n, BigInteger root)
{
BigInteger lowerBound = root*root;
BigInteger upperBound = (root + 1)*(root + 1);

return (n >= lowerBound && n < upperBound);
}
``````

Informal testing indicates that this is about 75X slower than Math.Sqrt, for small integers. The VS profiler points to the multiplications in isSqrt as the hotspots.

• BigInteger does not optimize the division operator. Bitshift right one instead of dividing by two will improve performance (at least in my case). – GeirGrusom Oct 28 '11 at 6:59
• The UpperBound definition can also be rewritten as the polynomial expansion `BigInteger upperBound = lowerBound + root + root + 1` or inlined in the return as `return n >= lowerBound && n <= lowerBound + root + root` – Jesan Fafon Aug 13 '14 at 22:57

I am not sure if Newton's Method is the best way to compute bignum square roots, because it involves divisions which are slow for bignums. You can use a CORDIC method, which uses only addition and shifts (shown here for unsigned ints)

``````static uint isqrt(uint x)
{
int b=15; // this is the next bit we try
uint r=0; // r will contain the result
uint r2=0; // here we maintain r squared
while(b>=0)
{
uint sr2=r2;
uint sr=r;
// compute (r+(1<<b))**2, we have r**2 already.
r2+=(uint)((r<<(1+b))+(1<<(b+b)));
r+=(uint)(1<<b);
if (r2>x)
{
r=sr;
r2=sr2;
}
b--;
}
return r;
}
``````

There's a similar method which uses only addition and shifts, called 'Dijkstras Square Root', explained for example here:

• This computes the integer square root of an integer. If you need decimals, you can pre-scale the operand. – Nordic Mainframe Aug 8 '10 at 0:31
• you can compute to arbitrary precision by continuing the loop for negative values of b and converting left shifts of -n to right shifts of n. – Chris Dodd Aug 8 '10 at 19:28
• Easily adapted to 64-bit long, which is what I needed. Thanks! – yoyo Sep 4 '13 at 20:49
• so how to scale this ? change b to what ? – bigworld12 Feb 19 '19 at 16:20
• and by scaling i mean to arbitrary bit length (using BigInteger) – bigworld12 Feb 19 '19 at 16:22

Short answer: (but beware, see below for more details)

``````Math.Pow(Math.E, BigInteger.Log(pd) / 2)
``````

Where `pd` represents the `BigInteger` on which you want to perform the square root operation.

Another way to understanding this problem is understanding how square roots and logs work.

If you have the equation `5^x = 25`, to solve for `x` we must use logs. In this example, I will use natural logs (logs in other bases are also possible, but the natural log is the easy way).

``````5^x = 25
``````

Rewriting, we have:

``````x(ln 5) = ln 25
``````

To isolate x, we have

``````x = ln 25 / ln 5
``````

We see this results in `x = 2`. But since we already know x (x = 2, in 5^2), let's change what we don't know and write a new equation and solve for the new unknown. Let x be the result of the square root operation. This gives us

``````2 = ln 25 / ln x
``````

Rewriting to isolate x, we have

``````ln x = (ln 25) / 2
``````

To remove the log, we now use a special identity of the natural log and the special number e. Specifically, `e^ln x = x`. Rewriting the equation now gives us

``````e^ln x = e^((ln 25) / 2)
``````

Simplifying the left hand side, we have

``````x = e^((ln 25) / 2)
``````

where x will be the square root of 25. You could also extend this idea to any root or number, and the general formula for the yth root of x becomes `e^((ln x) / y)`.

Now to apply this specifically to C#, BigIntegers, and this question specifically, we simply implement the formula. WARNING: Although the math is correct, there are finite limits. This method will only get you in the neighborhood, with a large unknown range (depending on how big of a number you operate on). Perhaps this is why Microsoft did not implement such a method.

``````// A sample generated public key modulus
var pd = BigInteger.Parse("101017638707436133903821306341466727228541580658758890103412581005475252078199915929932968020619524277851873319243238741901729414629681623307196829081607677830881341203504364437688722228526603134919021724454060938836833023076773093013126674662502999661052433082827512395099052335602854935571690613335742455727");
var sqrt = Math.Pow(Math.E, BigInteger.Log(pd) / 2);

Console.WriteLine(sqrt);
``````

NOTE: The `BigInteger.Log()` method returns a double, so two concerns arise. 1) The number is imprecise, and 2) there is an upper limit on what `Log()` can handle for `BigInteger` inputs. To examine the upper limit, we can look at normal form for the natural log, that is `ln x = y`. In other words, `e^y = x`. Since `double` is the return type of `BigInteger.Log()`, it would stand to reason the largest `BigInteger` would then be e raised to `double.MaxValue`. On my computer, that would `e^1.79769313486232E+308`. The imprecision is unhandled. Anyone want to implement `BigDecimal` and update `BigInteger.Log()`?

Consumer beware, but it will get you in the neighborhood, and squaring the result does produce a number similar to the original input, up to so many digits and not as precise as RedGreenCode's answer. Happy (square) rooting! ;)

You can convert this to the language and variable types of your choice. Here is a truncated squareroot in JavaScript (freshest for me) that takes advantage of 1+3+5...+nth odd number = n^2. All the variables are integers, and it only adds and subtracts.

``````var truncSqrt = function(n) {
var oddNumber = 1;
var result = 0;
while (n >= oddNumber) {
n -= oddNumber;
oddNumber += 2;
result++;
}
return result;
};
``````
• really curious how this performs relative to other methods. – Jeremy Kahan Sep 22 '16 at 5:38

It has been almost 10 years but hopefully, this will help someone. Here is the one I have been using. It does not use any slow division.

``````    // Source: http://mjs5.com/2016/01/20/c-biginteger-square-root-function/  Michael Steiner, Jan 2016
// Slightly modified to correct error below 6. (thank you M Ktsis D)
public static BigInteger Sqrt(BigInteger number)
{
if (number < 9)
{
if (number == 0)
return 0;
if (number < 4)
return 1;
else
return 2;
}

BigInteger n = 0, p = 0;
var high = number >> 1;
var low = BigInteger.Zero;

while (high > low + 1)
{
n = (high + low) >> 1;
p = n * n;
if (number < p)
{
high = n;
}
else if (number > p)
{
low = n;
}
else
{
break;
}
}
return number == p ? n : low;
}
``````

Update: Thank you to M Ktsis D for finding a bug in this. It has been corrected with a guard clause.

• Added guard clause for numbers 1 and 4 will make this answer perfect. – M Ktsis D Apr 2 at 4:32
• Thanks so much! You're a hero –  killereks Jun 28 at 12:03

Ok, first a few speed tests of some variants posted here. (I only considered methods which give exact results and are at least suitable for BigInteger):

``````+------------------------------+-------+------+------+-------+-------+--------+--------+--------+
| variant - 1000x times        |   2e5 | 2e10 | 2e15 |  2e25 |  2e50 |  2e100 |  2e250 |  2e500 |
+------------------------------+-------+------+------+-------+-------+--------+--------+--------+
| my version                   |  0.03 | 0.04 | 0.04 |  0.76 |  1.44 |   2.23 |   4.84 |  23.05 |
| RedGreenCode (bound opti.)   |  0.56 | 1.20 | 1.80 |  2.21 |  3.71 |   6.10 |  14.53 |  51.48 |
| RedGreenCode (newton method) |  0.80 | 1.21 | 2.12 |  2.79 |  5.23 |   8.09 |  19.90 |  65.36 |
| Nordic Mainframe (CORDIC)    |  2.38 | 5.52 | 9.65 | 19.80 | 46.69 |  90.16 | 262.76 | 637.82 |
| Sunsetquest (without divs)   |  2.37 | 5.48 | 9.11 | 24.50 | 56.83 | 145.52 | 839.08 | 4.62 s |
| Jeremy Kahan (js-port)       | 46.53 | #.## | #.## |  #.## |  #.## |   #.## |   #.## |   #.## |
+------------------------------+-------+------+------+-------+-------+--------+--------+--------+

+------------------------------+--------+--------+--------+---------+---------+--------+--------+
| variant - single             | 2e1000 | 2e2500 | 2e5000 | 2e10000 | 2e25000 |  2e50k | 2e100k |
+------------------------------+--------+--------+--------+---------+---------+--------+--------+
| my version                   |   0.10 |   0.77 |   3.46 |   14.97 |  105.19 | 455.68 | 1,98 s |
| RedGreenCode (bound opti.)   |   0.26 |   1.41 |   6.53 |   25.36 |  182.68 | 777.39 | 3,30 s |
| RedGreenCode (newton method) |   0.33 |   1.73 |   8.08 |   32.07 |  228.50 | 974.40 | 4,15 s |
| Nordic Mainframe (CORDIC)    |   1.83 |   7.73 |  26.86 |   94.55 |  561.03 | 2,25 s | 10.3 s |
| Sunsetquest (without divs)   |  31.84 | 450.80 | 3,48 s |  27.5 s |    #.## |   #.## |   #.## |
| Jeremy Kahan (js-port)       |   #.## |   #.## |   #.## |    #.## |    #.## |   #.## |   #.## |
+------------------------------+--------+--------+--------+---------+---------+--------+--------+

- value example: 2e10 = 20000000000 (result: 141421)
- times in milliseconds or with "s" in seconds
- #.##: need more than 5 minutes (timeout)
``````

Descriptions:

``````Jeremy Kahan (js-port)
``````

Jeremy's simple algorithm works, but the computational effort increases exponentially very fast due to the simple adding/subtracting... :)

``````Sunsetquest (without divs)
``````

The approach without dividing is good, but due to the divide and conquer variant the results converges relatively slowly (especially with large numbers)

``````Nordic Mainframe (CORDIC)
``````

The CORDIC algorithm is already quite powerful, although the bit-by-bit operation of the imuttable BigIntegers generates much overhead.

I have calculated the required bits this way: `int b = Convert.ToInt32(Math.Ceiling(BigInteger.Log(x, 2))) / 2 + 1;`

``````RedGreenCode (newton method)
``````

The proven newton method shows that something old does not have to be slow. Especially the fast convergence of large numbers can hardly be topped.

``````RedGreenCode (bound opti.)
``````

The proposal of Jesan Fafon to save a multiplication has brought a lot here.

``````my version
``````

First: calculate small numbers at the beginning with Math.Sqrt() and as soon as the accuracy of double is no longer sufficient, then use the newton algorithm. However, I try to pre-calculate as many numbers as possible with Math.Sqrt(), which makes the newton algorithm converge much faster.

Here the source:

``````static readonly BigInteger FastSqrtSmallNumber = 4503599761588224UL; // as static readonly = reduce compare overhead

static BigInteger SqrtFast(BigInteger value)
{
if (value <= FastSqrtSmallNumber) // small enough for Math.Sqrt() or negative?
{
if (value.Sign < 0) throw new ArgumentException("Negative argument.");
return (ulong)Math.Sqrt((ulong)value);
}

BigInteger root; // now filled with an approximate value
int byteLen = value.ToByteArray().Length;
if (byteLen < 128) // small enough for direct double conversion?
{
root = (BigInteger)Math.Sqrt((double)value);
}
else // large: reduce with bitshifting, then convert to double (and back)
{
root = (BigInteger)Math.Sqrt((double)(value >> (byteLen - 127) * 8)) << (byteLen - 127) * 4;
}

for (; ; )
{
var root2 = value / root + root >> 1;
if (root2 == root || root2 == root + 1) return root;
root = value / root2 + root2 >> 1;
if (root == root2 || root == root2 + 1) return root2;
}
}
``````

full Benchmark-Source:

``````using System;
using System.Numerics;

namespace MathTest
{
class Program
{
static BigInteger SqrtMax(BigInteger value)
{
if (value <= FastSqrtSmallNumber) // small enough for Math.Sqrt() or negative?
{
if (value.Sign < 0) throw new ArgumentException("Negative argument.");
return (ulong)Math.Sqrt((ulong)value);
}

BigInteger root; // now filled with an approximate value
int byteLen = value.ToByteArray().Length;
if (byteLen < 128) // small enough for direct double conversion?
{
root = (BigInteger)Math.Sqrt((double)value);
}
else // large: reduce with bitshifting, then convert to double (and back)
{
root = (BigInteger)Math.Sqrt((double)(value >> (byteLen - 127) * 8)) << (byteLen - 127) * 4;
}

for (; ; )
{
var root2 = value / root + root >> 1;
if (root2 == root || root2 == root + 1) return root;
root = value / root2 + root2 >> 1;
if (root == root2 || root == root2 + 1) return root2;
}
}

// newton method
public static BigInteger SqrtRedGreenCode(BigInteger n)
{
if (n == 0) return 0;
if (n > 0)
{
int bitLength = Convert.ToInt32(Math.Ceiling(BigInteger.Log(n, 2)));
BigInteger root = BigInteger.One << (bitLength / 2);

while (!isSqrtRedGreenCode(n, root))
{
root += n / root;
root /= 2;
}

return root;
}

throw new ArithmeticException("NaN");
}
private static bool isSqrtRedGreenCode(BigInteger n, BigInteger root)
{
BigInteger lowerBound = root * root;
//BigInteger upperBound = (root + 1) * (root + 1);

return n >= lowerBound && n <= lowerBound + root + root;
//return (n >= lowerBound && n < upperBound);
}

// without divisions
public static BigInteger SqrtSunsetquest(BigInteger number)
{
if (number < 9)
{
if (number == 0)
return 0;
if (number < 4)
return 1;
else
return 2;
}

BigInteger n = 0, p = 0;
var high = number >> 1;
var low = BigInteger.Zero;

while (high > low + 1)
{
n = (high + low) >> 1;
p = n * n;
if (number < p)
{
high = n;
}
else if (number > p)
{
low = n;
}
else
{
break;
}
}
return number == p ? n : low;
}

// javascript port
public static BigInteger SqrtJeremyKahan(BigInteger n)
{
var oddNumber = BigInteger.One;
var result = BigInteger.Zero;
while (n >= oddNumber)
{
n -= oddNumber;
oddNumber += 2;
result++;
}
return result;
}

// CORDIC
public static BigInteger SqrtNordicMainframe(BigInteger x)
{
int b = Convert.ToInt32(Math.Ceiling(BigInteger.Log(x, 2))) / 2 + 1;
BigInteger r = 0; // r will contain the result
BigInteger r2 = 0; // here we maintain r squared
while (b >= 0)
{
var sr2 = r2;
var sr = r;
// compute (r+(1<<b))**2, we have r**2 already.
r2 += (r << 1 + b) + (BigInteger.One << b + b);
r += BigInteger.One << b;
if (r2 > x)
{
r = sr;
r2 = sr2;
}
b--;
}
return r;
}

static void Main(string[] args)
{
var t2 = BigInteger.Parse("2" + new string('0', 10000));

//var q1 = SqrtRedGreenCode(t2);
var q2 = SqrtSunsetquest(t2);
//var q3 = SqrtJeremyKahan(t2);
//var q4 = SqrtNordicMainframe(t2);
var q5 = SqrtMax(t2);
//if (q5 != q1) throw new Exception();
if (q5 != q2) throw new Exception();
//if (q5 != q3) throw new Exception();
//if (q5 != q4) throw new Exception();

for (int r = 0; r < 5; r++)
{
var mess = Stopwatch.StartNew();
//for (int i = 0; i < 1000; i++)
{
//var q = SqrtRedGreenCode(t2);
var q = SqrtSunsetquest(t2);
//var q = SqrtJeremyKahan(t2);
//var q = SqrtNordicMainframe(t2);
//var q = SqrtMax(t2);
}
mess.Stop();
Console.WriteLine((mess.ElapsedTicks * 1000.0 / Stopwatch.Frequency).ToString("N2") + " ms");
}
}
}
}
``````
• I noticed you wrote Sunsetquest's on 2e10000 takes "27.5 s". I am calcuating 3.7 s. Can you share your benchmark code? – Sunsetquest Sep 28 at 5:46
• Hello, a little late but I have now added the benchmark code. The test times are still between 27-28 seconds. The calculated results are also correct. Let me know if there is a performance bug... ;-) – MaxKlaxx Oct 14 at 14:19
• Thanks for posting. I could not get ngMax.Zp.TickCount working so I used the built-in "Stopwatch timer = Stopwatch.StartNew(); ..... timer.Stop(); Console.WriteLine(timer.ElapsedMilliseconds);" and still get 3.5s.. but yours is also 11ms at the same time. Seems it is either the "ngMax" or my computer is 8x faster(but I don't think that!). In any case, the benchmark proportions seem accurate - that is what matters. Nice work on a fast function! – Sunsetquest Oct 15 at 15:09
• ngMax.Zp.TickCount returns only one (double) time in milliseconds (with decimal places). Interestingly, it wasn't that at all: I upgraded my project from .Net 4.5 (vs2013) to .Net Core 3.1 (vs2019) and now I'm also able to get to 3.8-3.9 seconds. BigInteger itself seems to have improved a lot in performance in the last years. ^^ – MaxKlaxx Oct 16 at 14:25