Cryptography General Interview Preparation Guide
Elevate your Cryptography General interview readiness with our detailed compilation of 51 questions. Our questions cover a wide range of topics in Cryptography General to ensure youre well-prepared. Whether youre new to the field or have years of experience, these questions are designed to help you succeed. Access the free PDF to get all 51 questions and give yourself the best chance of acing your Cryptography General interview. This resource is perfect for thorough preparation and confidence building.51 Cryptography General Questions and Answers:
1 :: What is RSA?
RSA is a public-key cryptosystem for both encryption and authentication; it was invented in 1977 by Ron Rivest, Adi Shamir, and Leonard Adleman [RSA78]. It works as follows: take two large primes, p and q, and find their product n = pq ; n is called the modulus. Choose a number, e, less than n and relatively prime to (p-1)(q-1), which means that e and (p-1)(q-1) have no common factors except 1. Find another number d such that (ed - 1) is divisible by (p-1)(q-1). The values e and d are called the public and private exponents, respectively. The public key is the pair (n,e); the private key is (n,d). The factors p and q maybe kept with the private key, or destroyed.
2 :: How Fast is RSA?
An "RSA operation," whether for encrypting or decrypting, signing or verifying, is essentially a modular exponentiation, which can be performed by a series of modular multiplications.
In practical applications, it is common to choose a small public exponent for the public key; in fact, entire groups of users can use the same public exponent, each with a different modulus. (There are some restrictions on the prime factors of the modulus when the public exponent is fixed.) This makes encryption faster than decryption and verification faster than signing. With typical modular exponentiation algorithms, public-key operations take O(k2) steps, private-key operations take O( k3) steps, and key generation takes O(k4) steps, where k is the number of bits in the modulus. ( O-notation refers to the upper bound on the asymptotic running time of an algorithm.) "Fast multiplication" techniques, such as FFT-based methods, require asymptotically fewer steps, though in practice they are not as common due to their great software complexity and the fact that they may actually be slower for typical key sizes.
In practical applications, it is common to choose a small public exponent for the public key; in fact, entire groups of users can use the same public exponent, each with a different modulus. (There are some restrictions on the prime factors of the modulus when the public exponent is fixed.) This makes encryption faster than decryption and verification faster than signing. With typical modular exponentiation algorithms, public-key operations take O(k2) steps, private-key operations take O( k3) steps, and key generation takes O(k4) steps, where k is the number of bits in the modulus. ( O-notation refers to the upper bound on the asymptotic running time of an algorithm.) "Fast multiplication" techniques, such as FFT-based methods, require asymptotically fewer steps, though in practice they are not as common due to their great software complexity and the fact that they may actually be slower for typical key sizes.
3 :: What Would it Take to Break RSA?
There are a few possible interpretations of "breaking RSA." The most damaging would be for an attacker to discover the private key corresponding to a given public key; this would enable the attacker both to read all messages encrypted with the public key and to forge signatures. The obvious way to do this attack is to factor the public modulus, n, into its two prime factors, p and q. From p, q, and e, the public exponent, the attacker can easily get d, the private exponent. The hard part is factoring n; the security of RSA depends on factoring being difficult. In fact, the task of recovering the private key is equivalent to the task of factoring the modulus: you can use d to factor n, as well as use the factorization of n to find d. It should be noted that hardware improvements alone will not weaken RSA, as long as appropriate key lengths are used; in fact, hardware improvements should increase the security of RSA.
4 :: Are Strong Primes Necessary in RSA?
In the literature pertaining to RSA, it has often been suggested that in choosing a key pair, one should use so-called "strong" primes p and q to generate the modulus n. Strong primes are those with certain properties that make the product n hard to factor by specific factoring methods; such properties have included, for example, the existence of a large prime factor of p-1 and a large prime factor of p+1. The reason for these concerns is that some factoring methods are especially suited to primes p such that p -1 or p+1 has only small factors; strong primes are resistant to these attacks.
5 :: How Large a Modulus (Key) Should be Used in RSA?
The best size for an RSA modulus depends on one's security needs. The larger the modulus, the greater the security, but also the slower the RSA operations. One should choose a modulus length upon consideration, first, of one's security needs, such as the value of the protected data and how long it needs to be protected, and, second, of how powerful one's potential enemies are.
Odlyzko's paper considers the security of RSA key sizes based on factoring techniques available in 1995 and the ability to tap large computational resources via computer networks. A specific assessment of the security of 512-bit RSA keys shows that one may be factored for less than $1,000,000 in cost and eight months of effort in 1997 [Rob95d]. It is believed that 512-bit keys no longer provide sufficient security with the advent of new factoring algorithms and distributed computing. Such keys should not be used after 1997 or 1998. Recommended key sizes are now 768 bits for personal use, 1024 bits for corporate use, and 2048 bits for extremely valuable keys like the key pair of a certifying authority. A 768-bit key is expected to be secure until at least the year 2004.
Odlyzko's paper considers the security of RSA key sizes based on factoring techniques available in 1995 and the ability to tap large computational resources via computer networks. A specific assessment of the security of 512-bit RSA keys shows that one may be factored for less than $1,000,000 in cost and eight months of effort in 1997 [Rob95d]. It is believed that 512-bit keys no longer provide sufficient security with the advent of new factoring algorithms and distributed computing. Such keys should not be used after 1997 or 1998. Recommended key sizes are now 768 bits for personal use, 1024 bits for corporate use, and 2048 bits for extremely valuable keys like the key pair of a certifying authority. A 768-bit key is expected to be secure until at least the year 2004.
6 :: How Large Should the Primes be?
The two primes, p and q, which compose the modulus, should be of roughly equal length; this will make the modulus harder to factor than if one of the primes was very small. Thus if one chooses to use a 768-bit modulus, the primes should each have length approximately 384 bits. If the two primes are extremely close (identical except for, say, 100 - 200 bits), there is a potential security risk, but the probability that two randomly chosen primes are so close is negligible.
7 :: Can Users of RSA run out of Distinct Primes?
There are enough prime numbers that RSA users will never run out of them. The Prime Number Theorem states that the number of primes less than or equal to n is asymptotically n/log n. This means that the number of prime numbers of length 512 bits or less is about 10150, which is a number greater than the number of atoms in the known universe.
8 :: How do You Know if a Number is Prime?
It is generally recommended to use probabilistic primality testing, which is much quicker than actually proving that a number is prime. One can use a probabilistic test that determines whether a number is prime with arbitrarily small probability of error, say, less than 2-100.
9 :: How is RSA Used for Authentication in Practice? What are RSA Digital Signatures?
RSA is usually combined with a hash function to sign a message.
Suppose Alice wishes to send a signed message to Bob. She applies a hash function to the message to create a message digest, which serves as a "digital fingerprint" of the message. She then encrypts the message digest with her RSA private key; this is the digital signature, which she sends to Bob along with the message itself. Bob, upon receiving the message and signature, decrypts the signature with Alice's public key to recover the message digest. He then hashes the message with the same hash function Alice used and compares the result to the message digest decrypted from the signature. If they are exactly equal, the signature has been successfully verified and he can be confident that the message did indeed come from Alice. If they are not equal, then the message either originated elsewhere or was altered after it was signed, and he rejects the message. With the method just described, anybody read the message and verify the signature. This may not be applicable to situations where Alice wishes to retain the secrecy of the document. In this case she may wish to sign the document then encrypt it using Bob's public key. Bob will then need to decrypt using his private key and verify the signature on the recovered message using Alice's public key. A third party can also verify the signature at this stage.
Suppose Alice wishes to send a signed message to Bob. She applies a hash function to the message to create a message digest, which serves as a "digital fingerprint" of the message. She then encrypts the message digest with her RSA private key; this is the digital signature, which she sends to Bob along with the message itself. Bob, upon receiving the message and signature, decrypts the signature with Alice's public key to recover the message digest. He then hashes the message with the same hash function Alice used and compares the result to the message digest decrypted from the signature. If they are exactly equal, the signature has been successfully verified and he can be confident that the message did indeed come from Alice. If they are not equal, then the message either originated elsewhere or was altered after it was signed, and he rejects the message. With the method just described, anybody read the message and verify the signature. This may not be applicable to situations where Alice wishes to retain the secrecy of the document. In this case she may wish to sign the document then encrypt it using Bob's public key. Bob will then need to decrypt using his private key and verify the signature on the recovered message using Alice's public key. A third party can also verify the signature at this stage.
10 :: What are the Alternatives to RSA?
Many other public-key cryptosystems have been proposed, as a look through the proceedings of the annual Crypto, Eurocrypt, and Asiacrypt conferences quickly reveals. Some of the public-key cryptosystems will be discussed in previous Question.
A mathematical problem called the knapsack problem was the basis for several systems, but these have lost favor because several versions were broken. Another system, designed by ElGamal, is based on the discrete logarithm problem. The ElGamal system was, in part, the basis for several later signature methods, including one by Schnorr [Sch90], which in turn was the basis for DSS, the Digital Signature Standard. The ElGamal system has been used successfully in applications; it is slower for encryption and verification than RSA and its signatures are larger than RSA signatures.
In 1976, before RSA, Diffie and Hellman proposed a system for key exchange only; it permits secure exchange of keys in an otherwise conventional secret-key system. This system is in use today.
A mathematical problem called the knapsack problem was the basis for several systems, but these have lost favor because several versions were broken. Another system, designed by ElGamal, is based on the discrete logarithm problem. The ElGamal system was, in part, the basis for several later signature methods, including one by Schnorr [Sch90], which in turn was the basis for DSS, the Digital Signature Standard. The ElGamal system has been used successfully in applications; it is slower for encryption and verification than RSA and its signatures are larger than RSA signatures.
In 1976, before RSA, Diffie and Hellman proposed a system for key exchange only; it permits secure exchange of keys in an otherwise conventional secret-key system. This system is in use today.