Cipolla's algorithm

In computational number theory, Cipolla's algorithm is a technique for solving a congruence of the form

x^{2}\equiv n{\pmod {p}},

where $x,n\in \mathbf {F} _{p}$ , so n is the square of x, and where $p$ is an odd prime. Here $\mathbf {F} _{p}$ denotes the finite field with $p$ elements; $\{0,1,\dots ,p-1\}$ . The algorithm is named after Michele Cipolla, an Italian mathematician who discovered it in 1907.

Algorithm

Inputs:

$p$ , an odd prime,
$n\in \mathbf {F} _{p}$ , which is a square.

Outputs:

$x\in \mathbf {F} _{p}$ , satisfying $x^{2}=n.$

Step 1 is to find an $a\in \mathbf {F} _{p}$ such that $a^{2}-n$ is not a square. There is no known algorithm for finding such an $a$ , except the trial and error method. Simply pick an $a$ and by computing the Legendre symbol $(a^{2}-n|p)$ one can see whether $a$ satisfies the condition. The chance that a random $a$ will satisfy is $(p-1)/2p$ . With $p$ large enough this is about $1/2$ .^[1] Therefore, the expected number of trials before finding a suitable a is about 2.

Step 2 is to compute x by computing $x=\left(a+{\sqrt {a^{2}-n}}\right)^{(p+1)/2}$ within the field $\mathbf {F} _{p^{2}}=\mathbf {F} _{p}({\sqrt {a^{2}-n}})$ . This x will be the one satisfying $x^{2}=n.$

If $x^{2}=n$ , then $(-x)^{2}=n$ also holds. And since p is odd, $x\neq -x$ . So whenever a solution x is found, there's always a second solution, -x.

Example

(Note: All elements before step two are considered as an element of $\mathbf {F} _{13}$ and all elements in step two are considered as elements of $\mathbf {F} _{13^{2}}$ ).

Find all x such that $x^{2}=10.$

Before applying the algorithm, it must be checked that $10$ is indeed a square in $\mathbf {F} _{13}$ . Therefore, the Legendre symbol $(10|13)$ has to be equal to 1. This can be computed using Euler's criterion; $(10|13)\equiv 10^{6}\equiv 1{\bmod {1}}3.$ This confirms 10 being a square and hence the algorithm can be applied.

Step 1: Find an a such that $a^{2}-n$ is not a square. As stated, this has to be done by trial and error. Choose $a=2$ . Then $a^{2}-n$ becomes 7. The Legendre symbol $(7|13)$ has to be -1. Again this can be computed using Euler's criterion. $7^{6}=343^{2}\equiv 5^{2}\equiv 25\equiv -1{\bmod {1}}3.$ So $a=2$ is a suitable choice for a.
Step 2: Compute $x=\left(a+{\sqrt {a^{2}-n}}\right)^{(p+1)/2}=\left(2+{\sqrt {-6}}\right)^{7}.$

\left(2+{\sqrt {-6}}\right)^{2}=4+4{\sqrt {-6}}-6=-2+4{\sqrt {-6}}.

\left(2+{\sqrt {-6}}\right)^{4}=\left(-2+4{\sqrt {-6}}\right)^{2}=-1-3{\sqrt {-6}}.

\left(2+{\sqrt {-6}}\right)^{6}=\left(-2+4{\sqrt {-6}}\right)\left(-1-3{\sqrt {-6}}\right)=9+2{\sqrt {-6}}.

\left(2+{\sqrt {-6}}\right)^{7}=\left(9+2{\sqrt {-6}}\right)\left(2+{\sqrt {-6}}\right)=6.

So $x=6$ is a solution, as well as $x=-6{\bmod {1}}3=(-6+13){\bmod {1}}3=7.$ Indeed, $\ 6^{2}=36{\bmod {1}}3=10$ and $7^{2}=49{\bmod {1}}3=10.$

Proof

The first part of the proof is to verify that $\mathbf {F} _{p^{2}}=\mathbf {F} _{p}({\sqrt {a^{2}-n}})=\{x+y{\sqrt {a^{2}-n}}:x,y\in \mathbf {F} _{p}\}$ is indeed a field. For the sake of notation simplicity, $\omega$ is defined as ${\sqrt {a^{2}-n}}$ . Of course, $a^{2}-n$ is a quadratic non-residue, so there is no square root in $\mathbf {F} _{p}$ . This $\omega$ can roughly be seen as analogous to the complex number i. The field arithmetic is quite obvious. Addition is defined as

\left(x_{1}+y_{1}\omega \right)+\left(x_{2}+y_{2}\omega \right)=\left(x_{1}+x_{2}\right)+\left(y_{1}+y_{2}\right)\omega

Multiplication is also defined as usual. With keeping in mind that $\omega ^{2}=a^{2}-n$ , it becomes

\left(x_{1}+y_{1}\omega \right)\left(x_{2}+y_{2}\omega \right)=x_{1}x_{2}+x_{1}y_{2}\omega +y_{1}x_{2}\omega +y_{1}y_{2}\omega ^{2}=\left(x_{1}x_{2}+y_{1}y_{2}\left(a^{2}-n\right)\right)+\left(x_{1}y_{2}+y_{1}x_{2}\right)\omega

Now the field properties have to be checked. The properties of closure under addition and multiplication, associativity, commutativity and distributivity are easily seen. This is because in this case the field $\mathbf {F} _{p^{2}}$ is somewhat resembles the field of complex numbers (with $\omega$ being the analogon of i).
The additive identity is $0$ , or more formally $0+0\omega$ : Let $\alpha \in \mathbf {F} _{p^{2}}$ , then

\alpha +0=(x+y\omega )+(0+0\omega )=(x+0)+(y+0)\omega =x+y\omega =\alpha

The multiplicative identity is $1$ , or more formally $1+0\omega$ :

\alpha \cdot 1=(x+y\omega )(1+0\omega )=\left(x\cdot 1+0\cdot y\left(a^{2}-n\right)\right)+(x\cdot 0+1\cdot y)\omega =x+y\omega =\alpha

The only thing left for $\mathbf {F} _{p^{2}}$ being a field is the existence of additive and multiplicative inverses. It is easily seen that the additive inverse of $x+y\omega$ is $-x-y\omega$ , which is an element of $\mathbf {F} _{p^{2}}$ , because $-x,-y\in \mathbf {F} _{p}$ . In fact, those are the additive inverse elements of x and y. For showing that every non-zero element $\alpha$ has a multiplicative inverse, write down $\alpha =x_{1}+y_{1}\omega$ and $\alpha ^{-1}=x_{2}+y_{2}\omega$ . In other words,

(x_{1}+y_{1}\omega )(x_{2}+y_{2}\omega )=\left(x_{1}x_{2}+y_{1}y_{2}\left(n^{2}-a\right)\right)+\left(x_{1}y_{2}+y_{1}x_{2}\right)\omega =1

So the two equalities $x_{1}x_{2}+y_{1}y_{2}(n^{2}-a)=1$ and $x_{1}y_{2}+y_{1}x_{2}=0$ must hold. Working out the details gives expressions for $x_{2}$ and $y_{2}$ , namely

x_{2}=-y_{1}^{-1}x_{1}\left(y_{1}\left(n^{2}-a\right)-x_{1}^{2}y_{1}^{-1}\right)^{-1}

y_{2}=\left(y_{1}\left(n^{2}-a\right)-x_{1}^{2}y_{1}^{-1}\right)^{-1}

The inverse elements which are shown in the expressions of $x_{2}$ and $y_{2}$ do exist, because these are all elements of $\mathbf {F} _{p}$ . This completes the first part of the proof, showing that $\mathbf {F} _{p^{2}}$ is a field.

The second and middle part of the proof is showing that for every element $x+y\omega \in \mathbf {F} _{p^{2}}:(x+y\omega )^{p}=x-y\omega$ . By definition, $\omega ^{2}=a^{2}-n$ is not a square in $\mathbf {F} _{p}$ . Euler's criterion then says that

\omega ^{p-1}=\left(\omega ^{2}\right)^{\frac {p-1}{2}}=-1

Thus $\omega ^{p}=-\omega$ . This, together with Fermat's little theorem (which says that $x^{p}=x$ for all $x\in \mathbf {F} _{p}$ ) and the knowledge that in fields of characteristic p the equation $\left(a+b\right)^{p}=a^{p}+b^{p}$ holds, shows the desired result

(x+y\omega )^{p}=x^{p}+y^{p}\omega ^{p}=x-y\omega

The third and last part of the proof is to show that if $x_{0}=\left(a+\omega \right)^{\frac {p+1}{2}}\in \mathbf {F} _{p^{2}}$ , then $x_{0}^{2}=n\in \mathbf {F} _{p}$ .
Compute

x_{0}^{2}=\left(a+\omega \right)^{p+1}=(a+\omega )(a+\omega )^{p}=(a+\omega )(a-\omega )=a^{2}-\omega ^{2}=a^{2}-\left(a^{2}-n\right)=n

Note that this computation took place in $\mathbf {F} _{p^{2}}$ , so this $x_{0}\in \mathbf {F} _{p^{2}}$ . But with Lagrange's theorem, stating that a non-zero polynomial of degree n has at most n roots in any field K, and the knowledge that $x^{2}-n$ has 2 roots in $\mathbf {F} _{p}$ , these roots must be all of the roots in $\mathbf {F} _{p^{2}}$ . It was just shown that $x_{0}$ and $-x_{0}$ are roots of $x^{2}-n$ in $\mathbf {F} _{p^{2}}$ , so it must be that $x_{0},-x_{0}\in \mathbf {F} _{p}$ .^[2]

Speed

After finding a suitable a, the number of operations required for the algorithm is $4m+2k-4$ multiplications, $4m-2$ sums, where m is the number of digits in the binary representation of p and k is the number of ones in this representation. To find a by trial and error, the expected number of computations of the Legendre symbol is 2. But one can be lucky with the first try and one may need more than 2 tries. In the field $\mathbf {F} _{p^{2}}$ , the following two equalities hold

(x+y\omega )^{2}=\left(x^{2}+y^{2}\omega ^{2}\right)+\left(\left(x+y\right)^{2}-x^{2}-y^{2}\right)\omega ,

where $\omega ^{2}=a^{2}-n$ is known in advance. This computation needs 4 multiplications and 4 sums.

\left(x+y\omega \right)^{2}\left(c+\omega \right)=\left(cd-b\left(x+d\right)\right)+\left(d^{2}-by\right)\omega ,

where $d=(x+yc)$ and $b=ny$ . This operation needs 6 multiplications and 4 sums.

Assuming that $p\equiv 1{\pmod {4}},$ (in the case $p\equiv 3{\pmod {4}}$ , the direct computation $x\equiv \pm n^{\frac {p+1}{4}}$ is much faster) the binary expression of $(p+1)/2$ has $m-1$ digits, of which k are ones. So for computing a $(p+1)/2$ power of $\left(a+\omega \right)$ , the first formula has to be used $n-k-1$ times and the second $k-1$ times.

For this, Cipolla's algorithm is better than the Tonelli–Shanks algorithm if and only if $S(S-1)>8m+20$ , with $2^{S}$ being the maximum power of 2 which divides $p-1$ .^[3]

References

↑ R. Crandall, C. Pomerance Prime Numbers: A Computational Perspective Springer-Verlag, (2001) p. 157
↑ M. Baker Cipolla's Algorithm for finding square roots mod p
↑ Gonzalo Tornaria Square roots modulo p

Sources

E. Bach, J.O. Shallit Algorithmic Number Theory: Efficient algorithms MIT Press, (1996)

Number-theoretic algorithms

Primality tests	AKS test APR test Baillie–PSW Elliptic curve Pocklington Fermat Lucas Lucas–Lehmer Lucas–Lehmer–Riesel Proth's theorem Pépin's Quadratic Frobenius test Solovay–Strassen Miller–Rabin

Prime-generating	Sieve of Atkin Sieve of Eratosthenes Sieve of Sundaram Wheel factorization

Integer factorization	Continued fraction (CFRAC) Dixon's Lenstra elliptic curve (ECM) Euler's Pollard's rho p − 1 p + 1 Quadratic sieve (QS) General number field sieve (GNFS) Special number field sieve (SNFS) Rational sieve Fermat's Shanks' square forms Trial division Shor's

Multiplication	Ancient Egyptian Long Karatsuba Toom–Cook Schönhage–Strassen Fürer's

Discrete logarithm	Baby-step giant-step Pollard rho Pollard kangaroo Pohlig–Hellman Index calculus Function field sieve

Greatest common divisor	Binary Euclidean Extended Euclidean Lehmer's

Modular square root	Cipolla Pocklington's Tonelli–Shanks

Other algorithms	Chakravala Cornacchia LLL Integer square root Modular exponentiation Schoof's

Italics indicate that algorithm is for numbers of special forms

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