Fermat's Two Squares Theorem

Theorem
Let $p$ be a prime number.

Then $p$ can be expressed as the sum of two squares either:
 * $p = 2$

or:
 * $p \equiv 1 \pmod 4$

The expression of a prime of the form $4 k + 1$ as the sum of two squares is unique except for the order of the two summands.

Proof of Existence
There are three possibilities for a prime:
 * 1) $p = 2$, or
 * 2) $p \equiv 1 \pmod 4$, or
 * 3) $p \equiv 3 \pmod 4$.

Necessary Condition
Suppose $p$ can be expressed as the sum of two squares.

First we note that $2 = 1^2 + 1^2$, which is the sum of two squares.

This disposes of the case where $p = 2$.

Let $p = a^2 + b^2$.

From Square Modulo 4, either $a^2 \equiv 0$ or $a^2 \equiv 1 \pmod 4$. Similarly for $b^2$.

So $a^2 + b^2 \not \equiv 3 \pmod 4$ whatever $a$ and $b$ are.

So either $p = 2$, or $p \equiv 1 \pmod 4$.

Sufficient Condition
We have already noted that $2 = 1^2 + 1^2$, which is the sum of two squares.

Let $p$ be a prime number of the form $p \equiv 1 \pmod 4$.

Suppose $m p = x^2 + y^2$ has a solution such that $1 < m < p$.

Let $u, v$ be the least absolute residues modulo $m$ of $x$ and $y$ respectively.

That is:
 * $\displaystyle u \equiv x, v \equiv y \pmod m: \frac {-m} 2 < u, v \le \frac m 2$

Then $u^2 + v^2 \equiv x^2 + y^2 \pmod m$.

Thus $\exists r \in \Z, r \ge 0: u^2 + v^2 = m r$.

We are going to establish a descent step.

That is, we aim to show that $r p$ is the sum of two squares with $1 \le r < m$.

First we show that $r$ does lie in this range.

If $r = 0$ then $u = v = 0$ and so $m$ divides both $x$ and $y$.

But then from $m p = x^2 + y^2$ we have that $m \mathop \backslash p$ which can't happen as $p$ is prime.

So:
 * $1 \le r = \dfrac {u^2 + v^2} m \le \dfrac 1 m \times \left({\dfrac {m^2} 4 + \dfrac {n^2} 4}\right) = \dfrac m 2 < m$

So $1 \le r < m$.

Now we show that $r p$ is the sum of two squares.

Multiplying $m p = x^2 + y^2$ and $m r = u^2 + v^2$:

Now:
 * $x u + y v \equiv x^2 + y^2 \equiv 0 \pmod m$, so $m \mathop \backslash x u + y v$
 * $x v - y u \equiv x y - x y \equiv 0 \pmod m$, so $m \mathop \backslash x v - y u$

So, putting $m X = x u + y v, m Y = x v - y u$, we get:


 * $m^2 r p = m^2 X^2 + m^2 Y^2$

That is:
 * $r p = X^2 + Y^2$

Hence the descent step is established.

Next we need to show that $m p = x^2 + y^2$ has a solution for some $m$ with $1 \le m < p$.

From the First Supplement to the Law of Quadratic Reciprocity, we have that $-1$ is a quadratic residue for each prime $p \equiv 1 \pmod 4$.

Hence the congruence $x^2 + 1 \equiv 0 \pmod p$ has a least positive solution $x_1$ such that $1 \le x_1 \le p - 1$.

So there exists a positive integer $m$ such that $m p = x_1^2 + 1^2$.

This is just what we want, because:
 * $m = \dfrac {x_1^2 + 1^2} p \le \dfrac {\left({p - 1}\right)^2 + 1} p = \dfrac {p^2 - 2 \left({p - 1}\right)^2} p < p$

If this solution has $m > 1$, then our descent step (above) guarantees a solution for a smaller positive value of $m$.

Eventually we will reach a solution with $m = 1$, that is:
 * $p = x^2 + y^2$

Proof of Uniqueness
Let $p$ be prime such that $p \equiv 1 \pmod 4$.

Suppose $p = a^2 + b^2 = c^2 + d^2$ where $a > b > 0$ and $c > d > 0$.

We are going to show that $a = c$ and $b = d$.

From the two expressions for $p$, we have:

So we have:
 * $\left({a d - b c}\right) \left({a d + b c}\right) \equiv 0 \pmod p$

From Euclid's Lemma, that means $p \mathrel \backslash \left({a d - b c}\right)$ or $p \mathrel \backslash \left({a d + b c}\right)$.

So, suppose $p \mathrel \backslash \left({a d + b c}\right)$.

Now, we have that each of $a^2, b^2, c^2, d^2$ must be less than $p$.

Hence $0 < a, b, c, d < \sqrt p$.

This implies $0 < a d + b c < 2p$.

That must mean that $a d + b c = p$.

But then:

That means $a c + b d = 0$

But since $a > b$ and $c > d$ we have $a c > b d$.

This contradiction shows that $a d + b c$ can not be divisible by $p$.

So this means $p \mathrel \backslash \left({a d - b c}\right)$.

Similarly, because $0 < a, b, c, d < \sqrt p$ we have:
 * $-p < a d - b c < p$

This means:
 * $a d = b c$

So:
 * $a \mathrel \backslash b c$

But $a \perp b$ otherwise $a^2 + b^2$ has a common divisor greater than $1$ and less than $p$ and it can't because $p$ is prime.

So by Euclid's Lemma $a \mathrel \backslash c$.

So we can put $c = k a$ and so $a d = b c$ becomes $d = k b$.

Hence:
 * $p = c^2 + d^2 = k^2 \left({a^2 + b^2}\right) = k^2 p$

This means $k = 1$ which means $a = c$ and $b = d$ as we wanted to show.

Also known as
It is also known as just the Two Squares Theorem.

Historical Note
This theorem was initially stated without proof by in 1632.

announced its proof in a letter to dated December 25, 1640.

For this reason it is also sometimes referred to as Fermat's Christmas Theorem.