/* ----------------------------------------------------------------------- * code extracted from 3GPP TS 35.231, annex E for Keccak core functions * https://portal.3gpp.org/desktopmodules/Specifications/SpecificationDetails.aspx?specificationId=2402 *-----------------------------------------------------------------------*/ /* This code may be freely used or adapted. */ #include "KeccakP-1600-3gpp.h" const uint8_t Rho[25] = {0,1,62,28,27,36,44,6,55,20,3,10,43,25,39,41,45, 15,21,8,18,2,61,56,14}; const uint8_t Pi[25] = {0,6,12,18,24,3,9,10,16,22,1,7,13,19,20,4,5,11,17, 23,2,8,14,15,21}; const uint8_t Iota[24] = {1,146,218,112,155,33,241,89,138,136,57,42,187,203, 217,83,82,192,26,106,241,208,33,120}; #define ROTATE64(value, n) \ ((((uint64_t)(value))<<(n)) | (((uint64_t)(value))>>(64-(n)))) /* --------------------------------------------------------------------- 64-bit version of Keccak_f(1600) --------------------------------------------------------------------- */ void Keccak_f_64(uint64_t s[25]) { uint64_t t[5]; uint8_t i, j, round; for(round=0; round<24; ++round) { /* Theta function */ for(i=0; i<5; ++i) t[i] = s[i] ^ s[5+i] ^ s[10+i] ^ s[15+i] ^ s[20+i]; for(i=0; i<5; ++i, s+=5) { s[0] ^= t[4] ^ ROTATE64(t[1], 1); s[1] ^= t[0] ^ ROTATE64(t[2], 1); s[2] ^= t[1] ^ ROTATE64(t[3], 1); s[3] ^= t[2] ^ ROTATE64(t[4], 1); s[4] ^= t[3] ^ ROTATE64(t[0], 1); } s -= 25; /* Rho function */ for(i=1; i<25; ++i) s[i] = ROTATE64(s[i], Rho[i]); /* Pi function */ for(t[1] = s[i=1]; (j=Pi[i]) > 1; s[i]=s[j], i=j); s[i] = t[1]; /* Chi function */ for(i=0; i<5; ++i, s += 5) { t[0] = (~s[1]) & s[2]; t[1] = (~s[2]) & s[3]; t[2] = (~s[3]) & s[4]; t[3] = (~s[4]) & s[0]; t[4] = (~s[0]) & s[1]; for(j=0; j<5; ++j) s[j] ^= t[j]; } s -= 25; /* Iota function */ t[0] = Iota[round]; *s ^= (t[0] | (t[0]<<11) | (t[0]<<26) | (t[0]<<57)) & 0x800000008000808BULL; /* set & mask bits 0,1,3,7,15,31,63 */ } } /* --------------------------------------------------------------------- 8-bit version of Keccak_f(1600) --------------------------------------------------------------------- */ void Keccak_f_8(uint8_t s[200]) { uint8_t t[40], i, j, k, round; for(round=0; round<24; ++round) { /* Theta function */ for(i=0; i<40; ++i) t[i]=s[i]^s[40+i]^s[80+i]^s[120+i]^s[160+i]; for(i=0; i<200; i+=8) for(j = (i+32)%40, k=0; k<8; ++k) s[i+k] ^= t[j+k]; for(i=0; i<40; t[i] = (t[i]<<1)|j, i+=8) for(j = t[i+7]>>7, k=7; k; --k) t[i+k] = (t[i+k]<<1)|(t[i+k-1]>>7); for(i=0; i<200; i+=8) for(j = (i+8)%40, k=0; k<8; ++k) s[i+k] ^= t[j+k]; /* Rho function */ for(i=8; i<200; i+=8) { for(j = Rho[i>>3]>>3, k=0; k<8; ++k) /* j:=bytes to shift, s->t */ t[(k+j)&7] = s[i+k]; for(j = Rho[i>>3]&7, k=7; k; --k) /* j:=bits to shift, t->s */ s[i+k] = (t[k]<>(8-j)); s[i] = (t[0]<>(8-j)); } /* Pi function */ for(k=8; k<16; ++k) t[k] = s[k]; /* =memcpy(t+8, s+8, 8) */ for(i=1; (j=Pi[i])>1; i=j) for(k=0; k<8; ++k) /* =memcpy(s+(i<<3), s+(j<<3), 8) */ s[(i<<3)|k] = s[(j<<3)|k]; for(k=0; k<8; ++k) /* =memcpy(s+(i<<3), t+8, 8) */ s[(i<<3)|k] = t[k+8]; /* Chi function */ for(i=0; i<200; i+=40) { for(j=0; j<40; ++j) t[j]=(~s[i+(j+8)%40]) & s[i+(j+16)%40]; for(j=0; j<40; ++j) s[i+j]^=t[j]; } /* Iota function */ k = Iota[round]; s[0] ^= k & 0x8B; /* bits 0, 1, 3, 7 */ s[1] ^= (k<<3)&0x80; /* bit 15 */ s[3] ^= (k<<2)&0x80; /* bit 31 */ s[7] ^= (k<<1)&0x80; /* bit 63 */ } } /* --------------------------------------------------------------------- 32-bit version of Keccak_f(1600) --------------------------------------------------------------------- */ void Keccak_f_32(uint32_t s[50]) { uint32_t t[10]; uint8_t i, j, round, k; for(round=0; round<24; ++round) { /* Theta function */ for(i=0; i<10; ++i) t[i] = s[i] ^ s[10+i] ^ s[20+i] ^ s[30+i] ^ s[40+i]; for(i=0; i<5; ++i) for(j=8, k=2; ; j%=10, k=(k+2)%10) { *s++ ^= t[j++] ^ ((t[k]<<1)|(t[k+1]>>31)); *s++ ^= t[j++] ^ ((t[k+1]<<1)|(t[k]>>31)); if(j==8) break; } s -= 50; /* Rho function */ for(i=2; i<50; i+=2) { k = Rho[i>>1] & 0x1f; t[0] = (s[i+1] << k) | (s[i] >> (32-k)); t[1] = (s[i] << k) | (s[i+1] >> (32-k)); k = Rho[i>>1] >> 5; s[i] = t[1-k], s[i+1] = t[k]; } /* Pi function */ for(i=2, t[0]=s[2], t[1]=s[3]; (j=(Pi[i>>1]<<1))>2; i=j) s[i]=s[j], s[i+1]=s[j+1]; s[i]=t[0], s[i+1]=t[1]; /* Chi function */ for(i=0; i<5; ++i, s+=10) { for(j=0; j<10; ++j) t[j] = (~s[(j+2)%10]) & s[(j+4)%10]; for(j=0; j<10; ++j) s[j] ^= t[j]; } s -= 50; /* Iota function */ t[0] = Iota[round]; s[0] ^= (t[0] | (t[0]<<11) | (t[0]<<26)) & 0x8000808B; s[1] ^= (t[0]<<25) & 0x80000000; } }