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Learn about Triple-DES and AES, two popular symmetric encryption algorithms used in network systems security. Understand the need for Triple-DES as a replacement for DES and the benefits of AES. Explore the origins, evaluation criteria, and the winner of the AES competition. Gain knowledge about abstract algebra background, modular arithmetic, and the properties of Triple-DES and AES.
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CSCE 715:Network Systems Security Chin-Tser Huang huangct@cse.sc.edu University of South Carolina
After DES… • More symmetric encryption algorithms • Triple-DES • Advanced Encryption Standards
Triple DES • Clearly a replacement for DES was needed • theoretical attacks that can break it • demonstrated exhaustive key search attacks • Use multiple encryptions with DES implementations • Triple-DES is the chosen form
Why Triple-DES? • Double-DES may suffer from meet-in-the-middle attack • works whenever use a cipher twice • assume C = EK2[EK1[P]], so X = EK1[P] = DK2[C] • given a known pair (P, C), attack by encrypting P with all keys and store • then decrypt C with keys and match X value • can be shown that this attack takes O(256) steps
Triple-DES with Two Keys • Must use 3 encryptions • would seem to need 3 distinct keys • But can use 2 keys with E-D-E sequence • encrypt & decrypt equivalent in security • C = EK1[DK2[EK1[P]]] • if K1=K2 then is compatible with single DES • Standardized in ANSI X9.17 & ISO8732 • No current known practical attacks
Triple-DES with Three Keys • Some proposed attacks on two-key Triple-DES, although none of them practical • Can use Triple-DES with Three-Keys to avoid even these • C = EK3[DK2[EK1[P]]] • Has been adopted by some Internet applications, e.g. PGP, S/MIME
Origins ofAdvanced Encryption Standard • Triple-DES is slow with small blocks • US NIST issued call for ciphers in 1997 • 15 candidates accepted in Jun 1998 • 5 were shortlisted in Aug 1999 • Rijndael was selected as the AES in Oct 2000 • Issued as FIPS PUB 197 standard in Nov 2001
AES Requirements • Private key symmetric block cipher • 128-bit data, 128/192/256-bit keys • Stronger and faster than Triple-DES • Active life of 20-30 years (+ archival use) • Provide full specification and design details • Both C and Java implementations • NIST has released all submissions and unclassified analyses
AES Evaluation Criteria • Initial criteria • security – effort to practically cryptanalyze • cost – computational • algorithm & implementation characteristics • Final criteria • general security • software & hardware implementation ease • implementation attacks • flexibility (in en/decrypt, keying, other factors)
AES Shortlist • Shortlist in Aug 99 after testing and evaluation • MARS (IBM) - complex, fast, high security margin • RC6 (USA) - very simple, very fast, low security margin • Rijndael (Belgium) - clean, fast, good security margin • Serpent (Euro) - slow, clean, very high security margin • Twofish (USA) - complex, very fast, high security margin • Subject to further analysis and comment • Contrast between algorithms with • few complex rounds verses many simple rounds • refined existing ciphers verses new proposals
The Winner - Rijndael • Designed by Rijmen-Daemen in Belgium • Has 128/192/256 bit keys, 128 bit data • An iterative rather than feistel cipher • treats data in 4 groups of 4 bytes • operates on an entire block in every round • Designed to be • resistant against known attacks • speed and code compactness on many CPUs • design simplicity • Use finite field
Abstract Algebra Background • Group • Ring • Field
Group • A set of elements or “numbers” • With a binary operation whose result is also in the set (closure) • Obey the following axioms • associative law: (a.b).c = a.(b.c) • has identity e: e.a = a.e = a • has inverses a-1: a.a-1 = e • Abelian group if commutative a.b = b.a
Ring • A set of elements with two operations (addition and multiplication) which are: • an abelian group with addition operation • multiplication • has closure • is associative • distributive over addition: a(b+c) = ab + ac • Commutative ring if multiplication operation is commutative • Integral domain if multiplication operation has identity and no zero divisors
Field • A set of numbers with two operations • integral domain • multiplicative inverse: aa-1 = a-1a= 1 • Infinite field if infinite number of elements • Finite field if finite number of elements
Modular Arithmetic • Define modulo operatora mod n to be remainder when a is divided by n • Use the term congruence for: a ≡ b mod n • when divided by n, a and b have same remainder • e.g. 100 34 mod 11 • b is called the residue of a mod n if 0 b n-1 • with integers can write a = qn + b
Divisor • A non-zero number b is a divisor of a if for some m have a=mb (a,b,m all integers) • That is, b divides a with no remainder • Denote as b|a • E.g. all of 1,2,3,4,6,8,12,24 divide 24
Modular Arithmetic • Can do modular arithmetic with any group of integers Zn = {0, 1, … , n-1} • Form a commutative ring for addition • With a multiplicative identity • Some peculiarities • if (a+b)≡(a+c) mod n then b≡c mod n • but (ab)≡(ac) mod n then b≡c mod n only if a is relatively prime to n
Greatest Common Divisor (GCD) • GCD (a,b) of a and b is the largest number that divides evenly into both a and b • e.g. GCD(60,24) = 12 • Two numbers are called relatively prime if they have no common factors (except 1) • e.g. 8 and 15 relatively prime as GCD(8,15) = 1
Euclid's GCD Algorithm • Use following theorem • GCD(a,b) = GCD(b, a mod b) • Euclid's Algorithm to compute GCD(a,b) • A=a, B=b • while B>0 • R = A mod B • A = B, B = R • return A
Galois Fields • Finite fields play a key role in cryptography • Number of elements in a finite field must be a power of a prime pn • Known as Galois fields • Denoted GF(pn) • In particular often use the following forms • GF(p) • GF(2n)
Galois Fields GF(p) • GF(p) is set of integers {0,1, … , p-1} with arithmetic operations modulo prime p • Form a finite field • have multiplicative inverses • Hence arithmetic is “well-behaved” and can do addition, subtraction, multiplication, and division without leaving the field GF(p)
Finding Multiplicative Inverses • By extending Euclid’s algorithm gcd(a, b) = d = ax + by a = q1b + r1 r1 = ax1 + by1 b = q2r1 + r2 r2 = ax2 + by2 r1 = q3r2 + r3 r3 = ax3 + by3 …… rn-2 = qnrn-1 + rn rn = axn + byn Can derive ri = ri-2 – ri-1qi And xi = xi-2 – qixi-1 yi = yi-2 – qiyi-1
Polynomial Arithmetic • Can compute using polynomials • Several alternatives available • ordinary polynomial arithmetic • poly arithmetic with coords mod p • poly arithmetic with coords mod p and polynomials mod M(x)
Ordinary Polynomial Arithmetic • Add or subtract corresponding coefficients • Multiply all terms by each other • E.g. let f(x) = x3 + x2 + 2 and g(x) = x2 – x + 1 f(x) + g(x) = x3 + 2x2 – x + 3 f(x) – g(x) = x3 + x + 1 f(x) x g(x) = x5 + 3x2 – 2x + 2
Polynomial Arithmetic with Modulo Coefficients • Compute value of each coefficient as modulo some value • Could be modulo any prime • But we are most interested in mod 2 • i.e. all coefficients are 0 or 1 • e.g. let f(x) = x3 + x2,g(x) = x2 + x + 1 f(x) + g(x) = x3 + x + 1 f(x) x g(x) = x5 + x2
Modular Polynomial Arithmetic • Can write any polynomial in the form • f(x) = q(x) g(x) + r(x) • can interpret r(x) as being a remainder • r(x) = f(x) mod g(x) • If no remainder say g(x) divides f(x) • If g(x) has no divisors other than itself and 1 say it is irreducible (or prime) polynomial • Polynomial arithmetic modulo an irreducible polynomial forms a field
Polynomial GCD • Can find greatest common divisor for polynomials • c(x) = GCD(a(x), b(x)) if c(x) is the poly of greatest degree which divides both a(x), b(x) • can adapt Euclid’s Algorithm to find it: • EUCLID[a(x), b(x)] 1. A(x) = a(x); B(x) = b(x) 2. if B(x) = 0 return A(x) = gcd[a(x), b(x)] 3. R(x) = A(x) mod B(x) 4. A(x) B(x) 5. B(x) R(x) 6. goto 2
Modular Polynomial Arithmetic • Can compute in field GF(2n) • polynomials with coefficients modulo 2 • whose degree is less than n • hence must reduce modulo an irreducible poly of degree n (for multiplication only) • Form a finite field • Can always find an inverse • can extend Euclid’s Inverse algorithm to find
AES Cipher – Rijndael • Process data as 4 groups of 4 bytes (State) • Has 9/11/13 rounds in which state undergoes: • byte substitution (1 S-box used on every byte) • shift rows (permute bytes between groups/columns) • mix columns (subs using matrix multiply of groups) • add round key (XOR state with key material) • Initial XOR key material & incomplete last round • All operations can be combined into XOR and table lookups, hence very fast and efficient
Byte Substitution • A simple substitution of each byte • Uses one table of 16x16 bytes containing a permutation of all 256 8-bit values • Each byte of state is replaced by byte in corresponding row (left 4 bits) and column (right 4 bits) • eg. byte {95} is replaced by row 9 col 5 byte, which is {2A} • S-box is constructed using a defined transformation of the values in GF(28)
Byte Substitution Rationale • S-box is designed to be resistant to known cryptanalytic attacks • The Rijndael developers sought a design that has a low correlation between input bits and output bits and the property that the output is not a linear mathematical function of the input • Nonlinearity is due to the use of the multiplicative inverse
Shift Rows • Circular byte shift in each row • 1st row is unchanged • 2nd row does 1 byte circular shift to left • 3rd row does 2 byte circular shift to left • 4th row does 3 byte circular shift to left • Decryption does shifts to right • Since state is processed by columns, this step permutes bytes between the columns
Shift Row Rationale • More substantial than it may first appear • The State, as well as the cipher input and output, is treated as an array of four 4-byte columns • On encryption, the first 4 bytes of the plaintext are copied to the first column of State, and so on • The round key is applied to State column by column • Thus, a row shift moves an individual byte from one column to another, which is a linear distance of a multiple of 4 bytes • Shift row ensures that the 4 bytes of one column are spread out to four different columns
Mix Columns • Each column is processed separately • Each byte is replaced by a value dependent on all 4 bytes in the column • Effectively a matrix multiplication in GF(28) using prime poly m(x) =x8+x4+x3+x+1
Mix Columns Rationale • Coefficients of a matrix based on a linear code with maximal distance between code words ensures a good mixing among the bytes of each column • The mix column transformation combined with the shift row transformation ensures that after a few rounds all output bits depend on all input bits
Add Round Key • XOR state with 128 bits of the round key • Again processed by column (though effectively a series of byte operations) • Inverse for decryption is identical since XOR is own inverse, just with correct round key • Designed to be as simple as possible but ensured to affect every bit of State
AES Key Expansion • Take 128/192/256-bit key and expand into array of 44/52/60 32-bit words • Start by copying key into first 4 words • Then loop creating words that depend on values in previous and 4 places back • in 3 of 4 cases just XOR these together • every 4th has S-box + rotate + XOR constant of previous before XOR together • Designed to resist known attacks
AES Decryption • AES decryption is not identical to encryption because steps are done in reverse • But can define an equivalent inverse cipher with steps as for encryption • use inverses of each step • But with a different key schedule • Works since result is unchanged when • swap byte substitution & shift rows • swap mix columns and add (tweaked) round key