Cryptography

RSA with multiple primes

Posted on by John

Typically RSA public keys are the product of two large primes, npq. But there’s no reason they couldn’t be the product of say three primes, npqr, or more primes, as long as φ(n), or λ(n), is calculated correctly.

Encryption is done the same way. Decryption could be done the same way, except there is the opportunity for it to be more efficient. The trick is to use the CRT (Chinese Remainder Theorem) in a way similar to Garner’s algorithm. This is why RSA with multiple primes is sometimes used for digital signatures.

The difficulty of factoring n using the GNFS algorithm doesn’t change depending on the number of factors n has, as long as all the factors are sufficiently large, far too large to find using trial division.

Daniel Bernstein’s post-quantum RSA paper was based on keys that are the product of a large number of 4096-bit primes. This way all the arithmetic is carried out modulo 4096-bit primes, not modulo terabyte primes.

A quiet change to RSA

Posted on by John

An RSA public key is a pair of numbers (en) where e is an exponent and npq where p and q are large prime numbers. The original RSA paper said choose a private key d and compute e. In practice now we choose e and compute d. Furthermore, e is now almost always 65537 for reasons given here. So the public key is essentially just n.

Euler’s totient function

The relationship between the exponent and the private decryption key in the original RSA paper was

ed = 1 mod φ(n).

It is easy to compute e given d, or d given e, when you know Euler’s totient function of n,

φ(n) = (p − 1)(q − 1).

The security of RSA encryption rests on the assumption that it is impractical to compute φ(n) unless you know p and q.

Carmichael’s totient function

Gradually over the course of several years, the private key d changed from being the solution to

ed = 1 mod φ(n)

to being the solution to

ed = 1 mod λ(n)

where Euler‘s totient function φ(n) was replaced with Carmichael‘s totient function λ(n).

The heart of the original RSA paper was Euler’s generalization of Fermat’s little theorem which says if a is relatively prime to m, then

aφ(n) = 1 (mod n)

Carmichael’s λ(n) is defined to be the smallest number that can replace φ(n) in the equation above. It follows that λ(n) divides φ(n).

Why the change?

Using Carmichael’s totient rather than Euler’s totient results in smaller private keys and thus faster decryption. When n = pq for odd primes p and q,

λ(n) = lcm( (p − 1), (q − 1) ) = (p − 1)(q − 1) / gcd( (p − 1), (q − 1) )

so λ(n) is smaller than φ(n) by a factor of gcd( (p − 1), (q − 1) ). At a minimum, this factor is at least 2 since p − 1 and q − 1 are even numbers.

However, an experiment suggests this was a trivial savings. When I generated ten RSA public keys the gcd was never more than 8.

from sympy import randprime, gcd

for _ in range(10):
    p = randprime(2**1023, 2**1024)
    q = randprime(2**1023, 2**1024)
    print(gcd(p-1, q-1))

I repeated the experiment with 100 samples. The median of the gcd’s was 2, the mean was 35.44, and the maximum was 2370. So the while gcd might be moderately large, but it is usually just 2 or 4.

Better efficiency

The efficiency gained from using Carmichael’s totient is minimal. More efficiency can be gained by using Garner’s algorithm.

Time needed to factor large integers

Posted on by John

The optimal choice of factoring algorithm depends on the size of the number you want to factor. For numbers larger than a googol (10100) the GNFS (general number field sieve) algorithm is the fastest known factoring algorithm, making GNFS the algorithm of choice for trying to factor public keys for RSA encryption

The expected time required to factor a number n using the GNFS is proportional to

exp( f(n) g(n) )

where f(n) is relatively constant and g(n) varies more strongly with n. More specifically

f(n) = (64/9)1/3 + o(1)

and

g(n) = (log n)1/3 (log log n)2/3.

The notation o(1) means a term that goes to zero as n increases. Very often in practice you can ignore o(1) terms when your value of n is large. In cryptographic applications n is certainly large, at least 21024, and yet the o(1) term is still significant for values of n seen in practice. I’ve seen one source say that for keys used in practice the o(1) term is around 0.27.

Security levels

It is widely stated that factoring a 1024-bit private key is comparable in difficulty to breaking an 80-bit symmetric encryption key, i.e. that 1024-bit keys provide 80-bit security.

To find the security level of a 1024-bit RSA key, the size of the o(1) term matters. But given this, if we want to find the security level of more RSA key sizes, it doesn’t matter how big the o(1) term is. It only that the term is roughly constant over the range of key sizes we are interested in.

If f(n) is relatively constant, then the log of the time to factor n is proportional to g(n), and the log of the time to break an encryption with security level k is proportional to k. So the security level of a key n should be proportional to g(n). Let’s see if that’s the case, using the reported security levels of various key sizes.

import numpy as np

# RSA key sizes and security levels
data = {
    1024 : 80,
    2048 : 112,
    3072 : 128,
    4096 : 140,
    7680 : 192,
}
for d in data:
    x = d*np.log(2) # natural log of 2^d
    y = x**(1/3)*(np.log(x)**(2/3)) 
    print(data[d]/y)

This prints the following:

2.5580
2.6584
2.5596
2.4819
2.6237

So the ratio is fairly constant, as expected. All the reported security levels are multiples of 4, which suggests there was some rounding done before reporting them. This would account for some of the variation above.

The output above suggests that the security level of an RSA key with b bits is roughly

2.55 x1/3 log(x)2/3

where x = log(2) b.

Aside on RSA security

RSA encryption is not broken by factoring keys but by exploiting implementation flaws.

Factoring a 2048-bit RSA key would require more energy than the world produces in a year, as explained here.

Post-quantum RSA with gargantuan keys

Posted on by John

If and when practical scalable quantum computers become available, RSA encryption would be broken, at least for key sizes currently in use. A quantum computer could use Shor’s algorithm factor n-bit numbers in time on the order of n². The phrase “quantum leap” is misused and overused, but this would legitimately be a quantum leap.

That said, Shor’s method isn’t instantaneous, even on a hypothetical machine that does not yet exist and may never exist. Daniel Bernstein estimates that RSA encryption with terabyte public keys would be secure even in a post-quantum world.

Bernstein said on a recent podcast that he isn’t seriously suggesting using RSA with terabyte keys. Computing the necessary key size is an indirect way of illustrating how impractical post-quantum RSA would be.

Related posts

Silent Payments

Posted on by John

Bitcoin transactions appear to be private because names are not attached to accounts. But that is not sufficient to ensure privacy; if it were, much of my work in data privacy would be unnecessary. It’s quite possible to identify people in data that does not contain any direct identifiers.

I hesitate to use the term pseudonymization because people define it multiple ways, but I’d say Bitcoin addresses provide pseudonymization but not necessarily deidentification.

Privacy and public ledgers are in tension. The Bitcoin ledger is superficially private because it does not contain user information, only addresses [1]. However, transaction details are publicly recorded on the blockchain.

To add some privacy to Bitcoin, addresses are typically used only once. Wallet software generates new addresses for each transaction, and so it’s not trivial to track all the money flowing between two people. But it’s not impossible either. Forensic tools make it possible to identify parties behind blockchain transactions via metadata and correlating information on the blockchain with information available off-chain.

Silent Payments

Suppose you want to take donations via Bitcoin. If you put a Bitcoin address on your site, that address has to be permanent, and it’s publicly associated with you. It would be trivial to identify (the addresses of) everyone who sends you a donation.

Silent payments provide a way to work around this problem. Alice could send donations to Bob repeatedly without it being obvious who either party is, and Bob would not have to change his site. To be clear, there would be no way to tell from the addresses that funds are moving between Alice and Bob. The metadata vulnerabilities remain.

Silent payments are not implemented in Bitcoin Core, but there are partial implementations out there. See BIP 352.

The silent payment proposal depends on ECDH (elliptic curve Diffie-Hellman) key exchange, so I’ll do a digression on ECDH before returning to silent payments per se.

ECDH

The first thing to know about elliptic curves, as far as cryptography is concerned, is that there is a way to add two points on an elliptic curve and obtain a third point. This turns the curve into an Abelian group.

You can bootstrap this addition to create a multiplication operation: given a point g on an elliptic curve and an integer nng means add g to itself n times. Multiplication can be implemented efficiently even when n is an enormous number. However, and this is key, multiplication cannot be undone efficiently. Given g and n, you can compute ng quickly, but it’s practically impossible to start with knowledge of ng and g and recover n. To put it another way, multiplication is efficient but division is practically impossible [2].

Suppose Alice and Bob both agree on an elliptic curve and a point g on the curve. This information can be public. ECDH lets Alice and Bob share a secret as follows. Alice generates a large random integer a, her private key, and computes a public key A = ag. Similarly, Bob generates a large random integer b and computes a public key Bbg. They’re shared secret is

aBbA.

Alice can compute aB because she (alone) knows a and B is public information. Similarly Bob can compute bA. The two points on the curve aB and bA are the same because

aBabgbagbA.

Back to silent payments

ECDH lets Alice and Bob share a secret, a point on a (very large) elliptic curve. This is the heart of silent payments.

In its simplest form, Alice can send Bob funds using the address

PB + hash(aBg.

A slightly more complicated form lets Alice send Bob funds multiple times. The kth time she sends money to Bob she uses the address

PB + hash(aB || kg

where || denotes concatenation.

But how do you know k? You have to search the blockchain to determine k, much like the way hierarchical wallets search the blockchain. Is the address corresponding to k = 0 on the blockchain? Then try again with k = 1. Keep doing this until you find the first unused k. Making this process more efficient is one of the things that is being worked on to fully implement silent payments.

Note that Bob needs to make B public, but B is not a Bitcoin address per se; it’s information needed to generate addresses via the process described above. Actual addresses are never reused.

Related posts

[1] Though if you obtain your Bitcoin through an exchange, KYC laws require them to save a lot of private information.

[2] Recovering n from ng is known as the discrete logarithm problem. It would be more logical to call it the discrete division problem, but if you write the group operation on an elliptic curve as multiplication rather than addition, then it’s a discrete logarithm, i.e. trying to solve for an unknown exponent. If and when a large-scale quantum computer exists, the discrete logarithm problem will be practical to solve, but presumably not until then.

Measuring cryptographic strength in liters of boiling water

Posted on by John

I was listening to a podcast with Bill Buchanan recently in which he demonstrated the difficulty of various cryptographic tasks by the amount of energy they would use and how much water that would boil. Some tasks would require enough energy to boil a teaspoon of water, some a swimming pool, and some all the world’s oceans.

This is a fantastic way to compare the difficulty of various operations. There’s an old saying “you can’t boil the ocean,” and so it’s intuitively clear that encryption that you would need to boil an ocean to break is secure for all practical purposes [1]. Also, using energy rather than time removes the question of how much work is being done in parallel.

Buchanan credits Lenstra et al [2] with the idea of using units of boiling water.

The new approach was inspired by a remark made by the third author during his presentation of the factorization of the 768-bit RSA challenge at Crypto 2010: We estimate that the energy required for the factorization would have sufficed to bring two 20° C Olympic size swimming pools to a boil. This amount of energy was estimated as half a million kWh.

In the paper’s terminology, 745-bit RSA encryption and 65-bit symmetric key encryption both have “pool security” because the energy required to break them would boil an Olympic pool.

Security is typically measured in terms of symmetric encryption, so 65-bit security is “pool security.” Similarly, 114-bit security is “global security,” meaning that breaking it would require an amount of energy that could boil all the water on planet Earth, about 1.4 billion cubic kilometers of water.

World energy production is around 30,000 TWh per year, so one year of energy production could break 91-bit symmetric encryption or boil the water in Lake Geneva.

Because the difficulty in breaking symmetric encryption is an exponential function of the key length n, we can reverse engineer the formula the paper used to convert key lengths to water volumes, i.e. n bits of security requires the energy to boil

6.777 × 10−14 2n

liters of water.

[1] If all the assumptions that go into your risk model are correct: the software is implemented correctly, there are no unforeseen algorithmic improvements, keys were generated randomly, etc.

[2] Arjen Lenstra, Thorsten Kleinjung, and Emannuel Thomé. Universal security: from bits to mips to pools, lakes, and beyond.

 

How quantum computing would affect Bitcoin

Posted on by John

Bitcoin relies on two kinds of cryptography: digital signatures and hash functions. Quantum computing would be devastating to the former, but not the latter.

To be more specific, the kind of digital signatures used in Bitcoin could in theory be broken by quantum computer using Shor’s algorithm. Digital signatures could use quantum-resistant algorithms [1], but these algorithms are not used in Bitcoin (or much of anything else) at this time.

A quantum computer could use Grover’s algorithm to reduce the time required to reverse hash functions, but this is a much smaller threat. For this post, we will simply assume a quantum computer could break digital signatures but not hash functions.

Digital signatures rely on public key cryptography, but Bitcoin uses something you might call not-so-public key cryptography. Public keys are not necessarily made public. You can receive funds sent to a hash of your public key, but to spend funds you have to reveal your unhashed public key.

This asymmetry means that presumably you could receive funds and be safe from quantum computers as long as you never spend the funds. But once you spend the funds, your public key really is public, published on the blockchain, and a quantum computer could derive your private key from your public key. This is because digital signatures are verified when money is spent, not when it is received.

It is widely believed that practical quantum computing is at least several years away. Maybe large-scale quantum computing is decades away, and maybe it will never happen. Nobody knows. But if quantum computing becomes practical before the world shifts to quantum-resistant cryptography, it would be a catastrophe. It’s hard to appreciate how thoroughly public key cryptography is woven into contemporary life.

Could there be a quantum computer sitting in the basement of the NSA right now? I doubt the NSA could be a decade ahead of public quantum computing efforts, but this is just speculation. Classified cryptography research has historically been ahead of open research. For example, differential cryptanalysis was discovered long before it was made public. I expect the gap between classified and open research is smaller now that there is much more public research in cryptography, but presumably there is still some gap.

Related posts

[1] NIST recommends ML-DSA (Dilithium) and SLH-DSA (SPHINCS+) for post-quantum digital signature algorithms. See FIPS 204 and FIPS 205.

Misleading plots of elliptic curves

Posted on by John

The elliptic curves used in cryptography are over finite fields. They’re not “curves” at all in the colloquial sense of the word. But they are defined by analogy with continuous curves, and so most discussions of elliptic curves in cryptography start by showing a plot of a real elliptic curve.

Here’s a plot of y² = x³ + 2 for real x and y.

That’s fine as far as it goes. Resources quickly go on to say that the curves they’ll be looking at are discrete, and so they may then add something like the following. Here’s the same elliptic curve as above over the integers mod 11.

And again mod 997.

These plots are informative in a couple ways. First, they show that the elements of the curve are discrete points. Second, they show that the points are kinda randomly distributed, which hints at why elliptic curves might be useful in cryptography.

But the implied density of points is entirely wrong. It implies that the density of elliptic curve points increases with the field size increases, when in fact the opposite is true. The source of the confusion is using dots of constant size. A checkerboard graph would be better. Here’s a checkerboard plot for the curve mod 11.

If we were to do the same for the curve mod 997 we’d see nothing. The squares would be too small and too few to see. Here’s a plot for the curve mod 211 that gives a hint of the curve elements as dust in the plot.

An elliptic curve over the integers modulo a prime p lives in a p by p grid, and the number of points satisfying the equation of an elliptic curve is roughly p. So the density of points in the grid that belong to the curve is 1/p.

The elliptic curves used in cryptography are over fields of size 2255 or larger, and so the probability that a pair of x and y values chosen at random would be on the curve is on the order of 2−255, virtually impossible.

We can be more precise than saying the number of points on the curve is roughly p. If p isn’t too large, we can count the number of points on an elliptic curve. For example, the curve

y² = x³ + 2 mod p

has 12, 199, and 988 points when p = 11, 211, and 997. (If you count the points in the plots above for p = 11 you’ll get 11 points. Elliptic curves always have an extra point at infinity not shown.)

Hasse’s theorem gives upper and lower bounds for the number of points N on an elliptic curve over a field of p elements with p prime:

|N − (p + 1)| ≤ 2 √p.

The heuristic for this is that the right hand side of the equation defining an elliptic curve

x³ + ax + b

is a square mod p above half the time. When it is a square, it corresponds to two values of y and when it is not it corresponds to zero points. So on average an elliptic curve mod p has around p ordinary points and one point at infinity.

Related posts

Looking back at Martin Gardner’s RSA article

Posted on by John

Public key cryptography came to the world’s attention via Martin Gardner’s Scientific American article from August 1977 on RSA encryption.

The article’s opening paragraph illustrates what a different world 1977 was in regard to computation and communication.

… in a few decades … the transfer of information will probably be much faster and much cheaper by “electronic mail” than by conventional postal systems.

Gardner quotes Ron Rivest [1] saying that breaking RSA encryption by factoring the product of two 63-digit primes would take about 40 quadrillion years. The article included a challenge, a message encrypted using a 129-digit key, the product of a 64-digit prime and a 65-digit prime. Rivest offered a $100 prize for decrypting the message.

Note the tension between Rivest’s estimate and his bet. It’s as if he were saying “Based on the factoring algorithms and computational hardware now available, it would take forever to decrypt this message. But I’m only willing to bet $100 that that estimate remains valid for long.”

The message was decrypted 16 years later. Unbeknownst to Gardner’s readers in 1977, the challenge message was

THE MAGIC WORDS ARE SQUEAMISH OSSIFRAGE

encoded using 00 for space, 01 for A, 02 for B, etc.  It was decrypted in 1993 by a group of around 600 people using around 1600 computers. Here is a paper describing the effort. In 2015 Nat McHugh factored the key in 47 minutes using 8 CPUs on Google Cloud.

The RSA algorithm presented in Gardner’s article is much simpler than it’s current implementation, though the core idea remains unchanged. Now we use much larger public keys, the product of two 1024 bit (308 digit) primes or larger. Also, RSA isn’t used to encrypt messages per se; RSA is used to exchange symmetric encryption keys, such as AES keys, which are then used to encrypt messages.

RSA is still widely used, though elliptic curve cryptography (ECC) is taking its place, and eventually both RSA and ECC will presumably be replaced with post-quantum methods.

More RSA posts

[1] I met Ron Rivest at the Heidelberg Laureate Forum in 2013. When he introduced himself I said something like “So you’re the ‘R’ in RSA?” He’s probably tired of hearing that, but if so he was too gracious to show it.

Lewis Carroll and Zero Knowledge Proofs

Posted on by John

Illustration from Through the Looking Glass

Elliptic curves are often used in cryptography, and in particular they are used in zero-knowledge proofs (ZKP). Cryptocurrencies such as Zcash use ZKP to protect the privacy of users.

Several of the elliptic curves used in ZKP have whimsical names taken from characters by Lewis Carroll. This post will look at these five elliptic curves:

  • Jubjub
  • Baby Jubjub
  • Bandersnatch
  • Tweedledee
  • Tweedledum

Charles Dodgson was a mathematician, and perhaps there’s some connection from his mathematical work to elliptic curves and ZKP, the connection explored here is with his literary works written under the name Lewis Carroll.

Jabberwocky names

The first three curves—Jubjub, Baby Jubjub, and Bandersnatch—all get their name from Lewis Carroll’s poem Jabberwocky.

“Beware the Jabberwock, my son!
The jaws that bite, the claws that catch!
Beware the Jubjub bird, and shun
The frumious Bandersnatch!”

These curves all have a twisted Edwards curve form and a Montgomery curve form, just like the relationship between Ed25519 and Curve25519 that I wrote about a few days ago.

As its name suggests, the Baby Jubjub elliptic curve is related to the Jubjub curve but smaller.

Bandersnatch is similar to Jubjub, but arithmetic over this curve can be implemented more efficiently.

Looking Glass names

The last two curves—Tweedledum and Tweedledee—take their names from Through the Looking Glass.

And as their names suggest, Tweedledum and Tweedledee and very closely related. Both have the equation

y² = x³ + 5

but over different fields. Tweedledum is defined over the integers mod p and has q elements. Tweedledee is defined over the integers mod q and has p elements. (Mind your ps and qs!)

Here

p = 2254 + 4707489545178046908921067385359695873
q = 2254 + 4707489544292117082687961190295928833

More Lewis Carroll posts

More elliptic curve posts