// mars.cpp - modified by Sean Woods from Brian Gladman's mars6.c for Crypto++ // key setup updated by Wei Dai to reflect IBM's "tweak" proposed in August 1999 /* This is an independent implementation of the MARS encryption */ /* algorithm designed by a team at IBM as a candidate for the US */ /* NIST Advanced Encryption Standard (AES) effort. The algorithm */ /* is subject to Patent action by IBM, who intend to offer royalty */ /* free use if a Patent is granted. */ /* */ /* Copyright in this implementation is held by Dr B R Gladman but */ /* I hereby give permission for its free direct or derivative use */ /* subject to acknowledgment of its origin and compliance with any */ /* constraints that IBM place on the use of the MARS algorithm. */ /* */ /* Dr Brian Gladman (gladman@seven77.demon.co.uk) 4th October 1998 */ #include "pch.h" #include "mars.h" #include "misc.h" NAMESPACE_BEGIN(CryptoPP) ANONYMOUS_NAMESPACE_BEGIN static word32 gen_mask(word32 x) { word32 m; m = (~x ^ (x >> 1)) & 0x7fffffff; m &= (m >> 1) & (m >> 2); m &= (m >> 3) & (m >> 6); if (!m) return 0; m <<= 1; m |= (m << 1); m |= (m << 2); m |= (m << 4); m |= (m << 1) & ~x & 0x80000000; return m & 0xfffffffc; }; NAMESPACE_END void MARS::Base::UncheckedSetKey(const byte *userKey, unsigned int length, const NameValuePairs &) { AssertValidKeyLength(length); // Initialize T[] with the key data FixedSizeSecBlock T; GetUserKey(LITTLE_ENDIAN_ORDER, T.begin(), 15, userKey, length); T[length/4] = length/4; for (unsigned int j=0; j<4; j++) // compute 10 words of K[] in each iteration { unsigned int i; // Do linear transformation for (i=0; i<15; i++) T[i] = T[i] ^ rotlFixed(T[(i+8)%15] ^ T[(i+13)%15], 3) ^ (4*i+j); // Do four rounds of stirring for (unsigned int k=0; k<4; k++) for (i=0; i<15; i++) T[i] = rotlFixed(T[i] + Sbox[T[(i+14)%15]%512], 9); // Store next 10 key words into K[] for (i=0; i<10; i++) EK[10*j+i] = T[4*i%15]; } // Modify multiplication key-words for(unsigned int i = 5; i < 37; i += 2) { word32 w = EK[i] | 3; word32 m = gen_mask(w); if(m) w ^= (rotlMod(Sbox[265 + (EK[i] & 3)], EK[i-1]) & m); EK[i] = w; } } #define f_mix(a,b,c,d) \ r = rotrFixed(a, 8); \ b ^= Sbox[a & 255]; \ b += Sbox[(r & 255) + 256]; \ r = rotrFixed(a, 16); \ a = rotrFixed(a, 24); \ c += Sbox[r & 255]; \ d ^= Sbox[(a & 255) + 256] #define b_mix(a,b,c,d) \ r = rotlFixed(a, 8); \ b ^= Sbox[(a & 255) + 256]; \ c -= Sbox[r & 255]; \ r = rotlFixed(a, 16); \ a = rotlFixed(a, 24); \ d -= Sbox[(r & 255) + 256]; \ d ^= Sbox[a & 255] #define f_ktr(a,b,c,d,i) \ m = a + EK[i]; \ a = rotlFixed(a, 13); \ r = a * EK[i + 1]; \ l = Sbox[m & 511]; \ r = rotlFixed(r, 5); \ l ^= r; \ c += rotlMod(m, r); \ r = rotlFixed(r, 5); \ l ^= r; \ d ^= r; \ b += rotlMod(l, r) #define r_ktr(a,b,c,d,i) \ r = a * EK[i + 1]; \ a = rotrFixed(a, 13); \ m = a + EK[i]; \ l = Sbox[m & 511]; \ r = rotlFixed(r, 5); \ l ^= r; \ c -= rotlMod(m, r); \ r = rotlFixed(r, 5); \ l ^= r; \ d ^= r; \ b -= rotlMod(l, r) typedef BlockGetAndPut Block; void MARS::Enc::ProcessAndXorBlock(const byte *inBlock, const byte *xorBlock, byte *outBlock) const { word32 a, b, c, d, l, m, r; Block::Get(inBlock)(a)(b)(c)(d); a += EK[0]; b += EK[1]; c += EK[2]; d += EK[3]; int i; for (i = 0; i < 2; i++) { f_mix(a,b,c,d); a += d; f_mix(b,c,d,a); b += c; f_mix(c,d,a,b); f_mix(d,a,b,c); } f_ktr(a,b,c,d, 4); f_ktr(b,c,d,a, 6); f_ktr(c,d,a,b, 8); f_ktr(d,a,b,c,10); f_ktr(a,b,c,d,12); f_ktr(b,c,d,a,14); f_ktr(c,d,a,b,16); f_ktr(d,a,b,c,18); f_ktr(a,d,c,b,20); f_ktr(b,a,d,c,22); f_ktr(c,b,a,d,24); f_ktr(d,c,b,a,26); f_ktr(a,d,c,b,28); f_ktr(b,a,d,c,30); f_ktr(c,b,a,d,32); f_ktr(d,c,b,a,34); for (i = 0; i < 2; i++) { b_mix(a,b,c,d); b_mix(b,c,d,a); c -= b; b_mix(c,d,a,b); d -= a; b_mix(d,a,b,c); } a -= EK[36]; b -= EK[37]; c -= EK[38]; d -= EK[39]; Block::Put(xorBlock, outBlock)(a)(b)(c)(d); } void MARS::Dec::ProcessAndXorBlock(const byte *inBlock, const byte *xorBlock, byte *outBlock) const { word32 a, b, c, d, l, m, r; Block::Get(inBlock)(d)(c)(b)(a); d += EK[36]; c += EK[37]; b += EK[38]; a += EK[39]; int i; for (i = 0; i < 2; i++) { f_mix(a,b,c,d); a += d; f_mix(b,c,d,a); b += c; f_mix(c,d,a,b); f_mix(d,a,b,c); } r_ktr(a,b,c,d,34); r_ktr(b,c,d,a,32); r_ktr(c,d,a,b,30); r_ktr(d,a,b,c,28); r_ktr(a,b,c,d,26); r_ktr(b,c,d,a,24); r_ktr(c,d,a,b,22); r_ktr(d,a,b,c,20); r_ktr(a,d,c,b,18); r_ktr(b,a,d,c,16); r_ktr(c,b,a,d,14); r_ktr(d,c,b,a,12); r_ktr(a,d,c,b,10); r_ktr(b,a,d,c, 8); r_ktr(c,b,a,d, 6); r_ktr(d,c,b,a, 4); for (i = 0; i < 2; i++) { b_mix(a,b,c,d); b_mix(b,c,d,a); c -= b; b_mix(c,d,a,b); d -= a; b_mix(d,a,b,c); } d -= EK[0]; c -= EK[1]; b -= EK[2]; a -= EK[3]; Block::Put(xorBlock, outBlock)(d)(c)(b)(a); } NAMESPACE_END