How can you prove that a choice was made in good faith? For example, if your company selects a cohort of people for random drug testing, how can you convince those who were chosen that they weren’t chosen deliberately? Would a judge find your explanation persuasive? This is something I’ve helped companies with.

It may be impossible to prove that a choice was not deliberate, but you can show good faith by providing evidence that the choice was deliberate by a different criteria than the one in question.

I’ll give four examples, three positive and one negative.

Cliff RNG

My previous three blog posts looked at different aspects of the Cliff random number generator. The generator needs a seed between 0 and 1 to start. Suppose I chose 0.8121086949937715 as my seed. On the one hand, that’s a number with no apparent special features. But you might ask “Hey, why that number?” and you’d be right. I show in the first post in the series how that number was chosen to make the generator start off producing duplicate output.

In the next two posts in the series, I chose π – 3 as my seed. That’s a recognizable number and obviously a deliberate choice. But it has no apparent connection to the random number generator, and so it’s reasonable to assume that the seed wasn’t chosen to make the generator look good or bad.

SHA-2

The SHA-2 cryptographic hash function seventy two 32-bit numbers for initial state that needed to be “random” in some sense. But if the values were actually chosen at random, critics would suspect that the values were chosen to provide a back door. And maybe there is a clever way to pick the initial state that provides a non-obvious exploitable weakness.

The designers of SHA-2 chose the square roots of the first consecutive primes to fill one set of constants, and the cube roots of the first consecutive primes to fill another. See code here.

The initial state is definitely not random. Someone looking at the state would eventually discover where it came from. So while the choice was obviously deliberate, but apparently not designed by any cryptographic criteria.

Curve 25519

Daniel Bernstein’s elliptic curve Curve25519 is widely trusted in part because Bernstein made his design choices transparent. The curve is

y² = x³ + 486662x² + x

over the finite field with 2²⁵⁵-19 elements, hence the name.

2²⁵⁵-19 is the largest prime less than 2²⁵⁵, and being close to 2²⁵⁵ makes the method efficient to implement. The coefficient 48666 is less obvious. But Bernstein explains in his paper that he took the three smallest possible values of this parameter that met the explicit design criteria, and then rejected two of them on objective grounds described at the bottom of the paper.

NIST P-384

The design of elliptic curve NIST P-384 is not as transparent as that of Curve25519 which has lead to speculation that NIST may have designed the curve to have a back door.

The curve has has Weierstrass form

y² = x³ – 3x + b

over the finite field with p elements where

p = 2³⁸⁴ – 2¹²⁸ – 2⁹⁶ + 2³² – 1.

As with Curve25519, the choice of field size was motivated by efficiency; the pattern of powers of 2 enables some tricks for efficient implementation. Also, there are objective reasons why the linear coefficient is -3. But the last coefficient b is the 383-bit number

27580193559959705877849011840389048093056905856361568521428707301988689241309860865136260764883745107765439761230575

which has raised some eyebrows. NIST says the value was chosen at random, though not directly. More specifically, NIST says it first generated a certain 160-bit random number, then applied a common key stretching algorithm to obtain b above. Researchers are divided over whether they believe this. See more in this post.

Conclusion

Sometimes you can’t prove that a choice wasn’t deliberate. In that case the best you can do is show that the choice was deliberate, but by an innocent criteria, one unrelated to the matter at hand.

I tried to do this in the Cliff RNG blog posts by using π as my seed. I couldn’t actually use π because the seed had to be between 0 and 1, but there’s an obvious way to take π and produce a number between 0 and 1.

The designers of SHA-2 took a similar route. Just as π is a natural choice for a real number, primes are natural choices for integers. They couldn’t use integers directly, but they made complicated patterns from simple integers in a natural way by taking roots.

Daniel Bernstein gained the cryptography community’s trust by making his design criteria transparent. Given his criteria, the design was almost inevitable.

NIST was not as persuasive as Daniel Bernstein. They claim to have chosen a 160-bit number at random, and they may very well have. But there’s no way to know whether they generated a lot of 160-bit seeds until they found one that resulted in a constant term that has some special property. They may have chosen their seed in good faith, but they have a not been completely persuasive.

Sometimes it’s not enough to act in good faith; you have to make a persuasive case that you acted in good faith.

RSA encryption is based on the assumption that factoring large integers is hard. However, it’s possible that breaking RSA is easier than factoring. That is, the ability to factor large integers is sufficient for breaking RSA, but it might not be necessary.

Two years after the publication of RSA, Michael Rabin created an alternative that is provably as hard to break as factoring integers.

Like RSA, Rabin’s method begins by selecting two large primes, p and q, and keeping them secret. Their product n = pq is the public key. Given a message m in the form of a number between 0 and n, the cipher text is simply

c = m² mod n.

Rabin showed that if you can recover m from c, then you can factor n.

However, Rabin’s method does not decrypt uniquely. For every cipher text c, there are four possible clear texts. This may seem like a show stopper, but there are ways to get around it. You could pad messages with some sort of hash before encryption so that is extremely unlikely that more than one of the four decryption possibilities will have the right format. It is also possible to make the method uniquely invertible by placing some restrictions on the primes used.

I don’t know that Rabin’s method has been used in practice. I suspect that the assurance that attacks are as hard as factoring integers isn’t valuable enough to inspire people to put in the effort to harden the method for practical use [1].

There’s growing suspicion that factoring may not be as hard as we’ve thought. And we know that if large scale quantum computing becomes practical, factoring integers will be easy.

My impression is that researchers are more concerned about a breakthrough in factoring than they are about a way to break RSA without factoring [2, 3].

Related posts

• RSA numbers and factoring
• Between now and quantum

[1] One necessary step in practical implementation of Rabin’s method would be to make sure m > √n. Otherwise you could recover m by taking the integer square root rather than having to take a modular square root. The former is easy and the latter is hard.

[2] There are attacks against RSA that do not involve factoring, but they mostly exploit implementation flaws. They are not a frontal assault on the math problem posed by RSA.

[3] By “breaktrhough” I meant a huge improvement in efficiency. But another kind of breaktrough is conceivable. Someone could prove that factoring really is hard (on classical computers) by establishing a lower bound. That seems very unlikely, but it would be interesting. Maybe it would spark renewed interest in Rabin’s method.

A function that satisfies

f(x*y) = f(x)*f(y)

is called a homomorphism. The symbol “*” can stand for any operation, and it need not stand for the same thing on both sides of the equation. Technically * is the group operation, and if the function f maps elements of one group to another, the group operation may be different in the two groups.

Examples

Below are three examples of homomorphisms that people usually see before learning the term “homomorphism.”

Exponential

For example, the function f(x) = e^x is a homomorphism where * stands for addition of real numbers on the left and multiplication of positive real numbers on the right. That is,

e^x+y = e^x e^y.

In words, the exponential of a sum is the product of exponentials.

Determinants

Another example of a homomorphism is determinant. Let A and B be two n by n matrices. Then

det(AB) = det(A) det(B).

In words, the determinant of a product is the product of determinants. But “product” refers to two different things in the previous sentence. The first product is a matrix product and the second product is a product of real numbers.

Fourier transform

One last example of a homomorphism is the Fourier transform F. It satisfies

F(f * g) = F(f) F(g)

where the group operation * on the left is convolution. In words, the Fourier transform of the convolution of two functions is the product of their Fourier transforms.

Homomorphic encryption

Homomorphic encryption is an encryption algorithm that is also a homomorphism. It allows the recipient of encrypted data to encrypt the result of some computation without knowing the inputs. I give three examples below.

Simple substitution

Here’s a trivial example. Suppose you have a simple substitution cipher, i.e. ever letter is simply replaced by some other letter. This is homomorphic encryption where the group operation is string concatenation [1]. If you encrypt two unknown words as xxw and jkh, I know that the encrypted form of the two words stuck together is xxwjkh.

A block cipher like AES is also homomorphic with respect to concatenation, if implemented naively. That is,

E(A + B) = E(A) + E(B)

where + means concatenation. The encrypted form of the concatenation of two blocks is the concatenation of the two blocks encrypted separately.

The approach is called Electronic Code Book or ECB mode. It’s never used in practice. Instead, you might use something like Cipher Block Chaining, CBC mode. Here the encrypted form of one block is XOR’d with the next clear block before encrypting it. [2]

An important point here is that when we say an encryption method is homomorphic, we have to say what operations its homomorphic with respect to. Being homomorphic with respect to concatenation is not useful, and is in fact a weakness.

Goldwasser-Micali

A non-trivial example is the Goldwasser-Micali algorithm. If you’re given the encrypted form of two bits, you can compute an encrypted form of the XOR of the two bits without knowing the value of either bit. Specifically, bits are encoded as large numbers modulo a public key. If c₁ and c₂ are encrypted forms of bits b₁ and b₂, then c₁ c₂ is an encrypted form of

b₁ ⊕ b₂.

The same bit can be encrypted many different ways, so this isn’t a homomorphism in the simplest mathematical sense. That’s why I said “an encrypted form” rather than “the encrypted form.” This is common in homomorphic encryption.

Paillier

The Paillier encryption algorithm is something like RSA, and is homomorphic with respect to addition of messages. That is, if you encrypt two messages, m₁ and m₂, and multiply the results, you get something that decrypts to m₁ + m₂. Here the addition and multiplication are modulo some large integer.

As with the G-M algorithm above, encryption is not unique. Decryption is unique, but there’s a random choice involved in the encryption process. The recipient of the encoded data is able to compute an encrypted form of their sum.

The Paillier algorithm lets you encrypt two numbers and have someone securely add them for you without learning what the two numbers were. That doesn’t sound very exciting in itself, but it’s a useful building block for more useful protocols. For example, you may want to let someone carry out statistical calculations on private data without letting them see the data itself.

Related

• Encryption posts
• Data privacy

[1] Strings with concatenation don’t form a group because there are no inverses. So technically we have a homomorphism of semigroups, not groups.

[2] There’s a famous example of the weakness of ECB mode using the Linux penguin logo. If you encrypt the logo image using ECB mode, you can still recognize the penguin in the encrypted version since repetitive parts of the original image correspond to repetitive parts of the encrypted image. If you use CBC mode, however, the encrypted image becomes white noise.

The AES (Advanced Encryption Standard) algorithm takes in blocks of 128 or more bits [1] and applies a sequence of substitutions and permutations. The substitutions employ an “S-box”, named the Rijndael S-box after its designers [2], an invertible nonlinear transformation that works on 8 bits at a time.

There are 256 = 16 × 16 possible 8-bit numbers, and so the S-box can be represented as a 16 by 16 table mapping inputs to outputs. You can find the tables representing the S-box and its inverse in this text file in org-mode format.

This post will look in detail at how the entries of that table are filled. A high-level description of the design is as follows. For an 8-bit number x,

1. Invert in GF(2⁸)
2. Multiply by a matrix L
3. Add a constant c.

Next we dive into what each of these steps mean. And at the end we’ll work an example in detail.

My source is The Block Cipher Companion by Knudsen and Robshaw.

Inversion in GF(2⁸)

Steps 1 and 3 take the inverse of a number as a member of the finite field GF(2⁸), a finite field with 2⁸ elements.

The number of elements in a finite field determines the field, up to isomorphism. That is, in a sense there is only one field with 2⁸ = 256 elements. In fact there are 30 different fields with 256 elements (see this post for where that number came from). The 30 fields are isomorphic, but when we’re doing actual calculations, rather than abstract theory, we need to specify which representation we’re using.

Finite fields can be specified as polynomials modulo an irreducible polynomial. To carry out our calculations we need to specify a particular irreducible 8th degree polynomial with binary coefficients. The one that AES uses is

p(x) = x⁸ + x⁴ + x³ + x + 1.

So by taking the inverse in GF(2⁸) we mean to take an 8-bit number y, interpret it as a polynomial with binary coefficients, and find another 8-bit number x^-1 such that when we multiply them as polynomials, and take the remainder after dividing by p(x) we get the polynomial 1.

There’s one wrinkle in this procedure: only 255 of the 256 elements of GF(2⁸) have an inverse. There is no inverse for 0, but for our purposes we’ll take the inverse of 0 to be 0.

Multiplication by L

The matrix L we need here is the 8 by 8 binary matrix whose entries are

        10001111
        11000111
        11100011
        11110001
        11111000
        01111100
        00111110
        00011111

When we say to multiply x^-1 by L we mean to think of x^-1 as a vector over the field of two elements, and carry out matrix multiplication in that context.

Additive constant

The constant that we add is 0x63. The reason an additive constant was chosen was so that a zero input would not map to a zero output. Note that “addition” here is vector addition, and is carried out over the field of two elements, just as the multiplication above. This amounts to XOR of the bits.

Manual calculation example

To make everything above more concrete, we’ll calculate one entry of the table by hand.

Lets start with input y = 0x11 = 0b10001. We represent y as the polynomial f(x) = x⁴ + 1 and look for a polynomial g(x) such that the remainder when f(x) g(x) is divided by p(x) defined above is 1.

The process of finding g is complicated—maybe I’ll blog about it in the future—but I claim

g(x) = x⁷ + x⁵ + x⁴ + x²

which means the inverse of y in GF(2⁸), represented in binary, is 0b10110100 = 0xB4. You can find a table of inverses here.

Next we multiply the matrix L by the vector made from the bits of y^-1. However, there is a gotcha here. When Knudsen and Robshaw say to multiply the bits of y^-1 by L, they assume the bits are arranged from least significant to most significant. Since the bits of y^-1 are 10110100, we multiply L by the vector

[0, 0, 1, 0, 1, 1, 0, 1].

This multiplication gives us the vector

[1, 0, 0, 0, 0, 1, 1, 1].

Next we add the vector formed from the bits of 0x63, again from least significant to most significant. That means we lay out 0x63 = 0b01100011 as

[1, 1, 0, 0, 0, 1, 1, 0].

This gives us the result

[0, 1, 0, 0, 0, 0, 0, 1].

Reading the bits from least significant to most, this gives 0x82.

In sum, we’ve verified that the AES S-box takes 0x11 to 0x82, as stated in the table.

Related posts

• Entropy extractor
• Between now and quantum

[1] The Rijndael block cipher operates on blocks whose size is a multiple of 32 bits. The AES standard adopted Rijndael with block sizes 128, 192, and 256.

[2] “Rijndael” is a play on the designers of the cipher, Vincent Rijmen and Joan Daemen.