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Integer square root

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In number theory, the integer square root (isqrt) of a positive integer n is the positive integer m which is the greatest integer less than or equal to the square root of n,

For example, because and .

Algorithm

One way of calculating and is to use Newton's method to find a solution for the equation , giving the iterative formula

The sequence converges quadratically to as . It can be proven that if is chosen as the initial guess, one can stop as soon as

to ensure that

Using only integer division

For computing for very large integers n, one can use the quotient of Euclidean division for both of the division operations. This has the advantage of only using integers for each intermediate value, thus making the use of floating point representations of large numbers unnecessary. It is equivalent to using the iterative formula

By using the fact that

one can show that this will reach within a finite number of iterations.

However, is not necessarily a fixed point of the above iterative formula. Indeed, it can be shown that is a fixed point if and only if is not a perfect square. If is a perfect square, the sequence ends up in a period-two cycle between and instead of converging.

Domain of computation

Although is irrational for many , the sequence contains only rational terms when is rational. Thus, with this method it is unnecessary to exit the field of rational numbers in order to calculate , a fact which has some theoretical advantages.

Stopping criterion

One can prove that is the largest possible number for which the stopping criterion

ensures in the algorithm above.

In implementations which use number formats that cannot represent all rational numbers exactly (for example, floating point), a stopping constant less than one should be used to protect against roundoff errors.

See also