Daniel Bernstein’s Curve25519 is the elliptic curve

y² = x³ + 486662x² + x

over the prime field with order p = 2²⁵⁵ – 19. The curve is a popular choice in elliptic curve cryptography because its design choices are transparently justified [1] and because cryptography over the curve can be implemented very efficiently. This post will concentrate on one of the tricks that makes ECC over Curve25519 so efficient.

Curve25519 was designed for fast and secure cryptography. One of the things that make it fast is the clever way Bernstein carries out arithmetic mod 2²⁵⁵ – 19 which he describes here.

Bernstein represents numbers mod 2²⁵⁵ – 19 by polynomials whose value at 1 gives the number. That alone is not remarkable, but his choice of representation seems odd until you learn why it was chosen. Each number is represented as a polynomial of the form

∑ u_i xⁱ

where each u_i is an integer multiple k_i of 2^⌈25.5i⌉, and each k_i is an integer between -2²⁵ and 2²⁵ inclusive.

Why this limitation on the k‘s? Pentium cache optimization. In Bernstein’s words:

Why split 255-bit integers into ten 26-bit pieces, rather than nine 29-bit pieces or eight 32-bit pieces? Answer: The coefficients of a polynomial product do not fit into the Pentium M’s fp registers if pieces are too large. The cost of handling larger coefficients outweighs the savings of handling fewer coefficients.

And why unevenly spaced powers of 2: 1, 2²⁶, 2⁵¹, 2⁷⁷, …, 2²³⁰? Some consecutive exponents differ by 25 and some by 26. This looks sorta like a base 2²⁵ or base 2²⁶ representation, but is a mixture of both. Bernstein answers this in his paper.

Bernstein answers this question as well.

Given that there are 10 pieces, why use radix 2^25.5 rather than, e.g., radix 2²⁵ or radix 2²⁶? Answer: My ring R contains 2²⁵⁵x¹⁰ − 19, which represents 0 in Z/(2²⁵⁵ − 19). I will reduce polynomial products modulo 2²⁵⁵x¹⁰ – 19 to eliminate the coefficients of x¹⁰, x¹¹, etc. With radix 2²⁵ , the coefficient of x¹⁰ could not be eliminated. With radix 2²⁶, coefficients would have to be multiplied by 2⁵19 rather than just 19, and the results would not fit into an fp register.

There are a few things to unpack here.

Remember that we’re turning polynomials in to numbers by evaluating them at 1. So when x = 1, 2²⁵⁵x¹⁰ – 19  = p = 2²⁵⁵ – 19, which is the zero in the integers mod  2²⁵⁵ – 19.

If we were using base (radix) 2²⁵ , the largest number we could represent with a 9th degree polynomial with the restrictions above would be 2²⁵⁰ , so we’d need a 10th degree polynomial; we couldn’t eliminate terms containing x¹⁰.

I don’t yet see why working with radix 2²⁶ would overflow an fp register. If you do see why, please leave an explanation in the comments.

Related posts

• Naming elliptic curves
• Curve1174
• Curve secp256k1

[1] When a cryptographic method has an unjustified parameter, it invites suspicion that the parameter was chosen to create an undocumented back door. This is not the case with Curve25519. For example, why does it use p = 2²⁵⁵ – 19? It’s efficient to use a prime close to a large power of 2, and this p is the closes prime to 2²⁵⁵. The coefficient 486662 is not immediately obvious, but Bernstein explains in his paper how it was the smallest integer that met his design criteria.

The RSA encryption algorithm depends indirectly on the assumption that factoring the product of large primes is hard. The algorithm presented here, invented by Shafi Goldwasser and Silvio Micali, depends on the same assumption but in a different way. The Goldwasser-Micali algorithm is more direct than RSA, thought it is also less efficient.

One thing that makes GM interesting is that allows a form of computing on encrypted data that we’ll describe below.

GM in a nutshell

To create a public key, find two large primes p and q and publish N = pq. (There’s one more piece we’ll get to shortly.) You keep p and q private, but publish N, much like with RSA.

Someone can send you a message, one bit at a time, by sending you numbers that either do or do not have a square root mod N.

Sending a 0

If someone wants to send you a 0, they send you a number that has a square root mod N. This is easy to do: they select a number between 1 and N at random, square it mod N, and send you the result.

Determining whether a random number is a square mod N is easy if and only if you know how to factor N. [1]

When you receive the number, you can quickly tell that it is a square because you know how to factor N. The sender knows that it’s a square because he got it by squaring something. You can produce a square without knowing how to factor N, but it’s computationally infeasible to start with a given number and tell whether it’s a square mod N, unless you know the factorization of N.

Sending a 1

Sending a 1 bit is a little more involved. How can someone who cannot factor N produce a number that’s not a square? That’s actually not feasible without some extra information. The public key is not just N. It’s also a number z that is not a square mod N. So the full public key is two numbers, N and z.

To generate a non-square, you first generate a square then multiply it by z.

Example

Suppose you choose p = 314159 and q = 2718281. (Yes, p is a prime. See the post on pi primes. And q comes from the first few digits of e.) In practice you’d choose p and q to be very large, hundreds of digits, and you wouldn’t pick them to have a cute pattern like we did here. You publish N = pq = 853972440679 and imagine it’s too large for anyone to factor (which may be true for someone armed with only pencil and paper).

Next you need to find a number z that is not a square mod N. You do that by trying numbers at random until you find one that is not a square mod p and not a square mod q. You can do that by using Legendre symbols, It turns out z = 400005 will work.

So you tell the world your public key is (853972440679, 400005).

Someone wanting to send you a 0 bit chooses a number between 1 and N = 853972440679, say 731976377724. Then they square it and take the remainder by N to get 592552305778, and so they send you 592552305778. You can tell, using Legendre symbols, that this is a square mod p and mod q, so it’s a square mod N.

If they had wanted to send you a 1, they could have sent us 592552305778 * 400005 mod N = 41827250972, which you could tell isn’t a square mod N.

Homomorphic encryption

Homomorphic encryption lets you compute things on encrypted data without having to first decrypt it. The GM encryption algorithm is homomorphic in the sense that you can compute an encrypted form of the XOR of two bits from an encrypted form of each bit. Specifically, if c₁ and c₂ are encrypted forms of bits b₁ and b₂, then c₁ c₂ is an encrypted form of b₁ ⊕ b₂. Let’s see why this is, and where there’s a small wrinkle.

Suppose our two bits are both 0s. Then c₁ and c₂ are squares mod N, and c₁ c₂ is a square mod N.

Now suppose one bit is a 0 and the other is a 1. Then either c₁ is a square mod N and c₂ isn’t or vice versa, but in either case their product is not a square mod N.

Finally suppose both our bits are 1s. Since 1⊕1 = 0, we’d like to say that c₁ c₂ is a square mod N. Is it?

The product of two non-squares is not necessarily a non-square. For example, 2 and 3 are not squares mod 35, and neither is their product 6 [2]. But if we followed the recipe above, and calculated c₁ and c₂ both by multiplying a square by the z in the public key, then we’re OK. That is, if c₁ = x²z and c₂ = y²z, then c₁c₂ = x²y²z², which is a square. So if you return non-squares that you find as expected, you get the homomorphic property. If you somehow find your own non-squares, they might not work.

Related posts

• Computing Legendre and Jacobi symbols
• Blum Blum Shub secure RNG

[1] As far as we know. There may be an efficient way to tell whether x is a square mod N without factoring N, but no such method has been published. The problem of actually finding modular square roots is equivalent to factoring, but simply telling whether modular square roots exist, without having to produce the roots, may be easier.

If quantum computing becomes practical, then factoring will be efficient and so telling whether numbers are squares modulo a composite number will be efficient.

[2] You could find all the squares mod 35 by hand, or you could let Python do it for you:

>>> set([x*x % 35 for x in range(35)])
{0, 1, 4, 9, 11, 14, 15, 16, 21, 25, 29, 30}

There are an infinite number of elliptic curves, but a small number that are used in elliptic curve cryptography (ECC), and these special curves have names. Apparently there are no hard and fast rules for how the names are chosen, but there are patterns.

The named elliptic curves are over a prime field, i.e. a finite field with a prime number of elements p, denoted GF(p). The number of points on the elliptic curve is on the order of p [1].

The curve names usually contain a number which is the number of bits in the binary representation of p. Let’s see how that plays out with a few named elliptic curves.

In Curve25519, p = 2²⁵⁵ – 19 and in Curve 383187, p = 2³⁸³ – 187. Here the number of bits in p is part of the name but another number is stuck on.

The only mystery on the list is Curve1174 where p has 251 bits. The equation for the curve is

x² + y² = 1 – 1174 x²y²

and so the 1174 in the name comes from a coefficient rather than from the number of bits in p.

Edwards curves

The equation for Curve1174 doesn’t look like an elliptic curve. It doesn’t have the familiar (Weierstrass) form

y² = x³ + ax + b

It is an example of an Edwards curve, named after Harold Edwards. So are all the curves above whose names start with “E”. These curves have the form

x² + y² = 1 + d x² y².

where d is not 0 or 1. So some Edwards curves are named after their d parameter and some are named after the number of bits in p.

It’s not obvious that an Edwards curve can be changed into Weierstrass form, but apparently it’s possible; this paper goes into the details.

The advantage of Edwards curves is that the elliptic curve group addition has a simple, convenient form. Also, when d is not a square in the underlying field, there are no exceptional points to consider for group addition.

Is d = -1174 a square in the field underlying Curve1174? For that curve p = 2²⁵¹ – 9, and we can use the Jacobi symbol code from earlier this week to show that d is not a square.

    p = 2**251 - 9
    d = p-1174
    print(jacobi(d, p))

This prints -1, indicating that d is not a square. Note that we set d to p – 1174 rather than -1174 because our code assumes the first argument is positive, and -1174 and p – 1174 are equivalent mod p.

Update: More on addition on Curve1174.

Prefix conventions

A US government publication (FIPS PUB 186-4) mandates the following prefixes:

• P for curves over a prime field,
• B for curves over a binary field (i.e. GF(2ⁿ)), and
• K for Koblitz fields.

The ‘k’ in secp256k1 also stands for Koblitz.

The M prefix above stands for Montgomery.

Related posts

• Elliptic curves over finite fields
• A tale of two elliptic curves

[1] It is difficult to compute the exact number of points on an elliptic curve over a prime field. However, the number is roughly p ± 2√p. More precisely, Hasse’s theorem says