/* Implementation by the Keccak, Keyak and Ketje Teams, namely, Guido Bertoni, Joan Daemen, Michaël Peeters, Gilles Van Assche and Ronny Van Keer, hereby denoted as “the implementer”.
For more information, feedback or questions, please refer to our websites: keccak.noekeon.org/ keyak.noekeon.org/ ketje.noekeon.org/
To the extent possible under law, the implementer has waived all copyright and related or neighboring rights to the source code in this file. creativecommons.org/publicdomain/zero/1.0/ */
define declareABCDE \
UINT64 Aba, Abe, Abi, Abo, Abu; \ UINT64 Aga, Age, Agi, Ago, Agu; \ UINT64 Aka, Ake, Aki, Ako, Aku; \ UINT64 Ama, Ame, Ami, Amo, Amu; \ UINT64 Asa, Ase, Asi, Aso, Asu; \ UINT64 Bba, Bbe, Bbi, Bbo, Bbu; \ UINT64 Bga, Bge, Bgi, Bgo, Bgu; \ UINT64 Bka, Bke, Bki, Bko, Bku; \ UINT64 Bma, Bme, Bmi, Bmo, Bmu; \ UINT64 Bsa, Bse, Bsi, Bso, Bsu; \ UINT64 Ca, Ce, Ci, Co, Cu; \ UINT64 Da, De, Di, Do, Du; \ UINT64 Eba, Ebe, Ebi, Ebo, Ebu; \ UINT64 Ega, Ege, Egi, Ego, Egu; \ UINT64 Eka, Eke, Eki, Eko, Eku; \ UINT64 Ema, Eme, Emi, Emo, Emu; \ UINT64 Esa, Ese, Esi, Eso, Esu; \
define prepareTheta \
Ca = Aba^Aga^Aka^Ama^Asa; \ Ce = Abe^Age^Ake^Ame^Ase; \ Ci = Abi^Agi^Aki^Ami^Asi; \ Co = Abo^Ago^Ako^Amo^Aso; \ Cu = Abu^Agu^Aku^Amu^Asu; \
ifdef UseBebigokimisa // — Code for round, with prepare-theta (lane complementing pattern ‘bebigokimisa’) // — 64-bit lanes mapped to 64-bit words define thetaRhoPiChiIotaPrepareTheta(i, A, E) \
Da = Cu^ROL64(Ce, 1); \ De = Ca^ROL64(Ci, 1); \ Di = Ce^ROL64(Co, 1); \ Do = Ci^ROL64(Cu, 1); \ Du = Co^ROL64(Ca, 1); \
\
A##ba ^= Da; \ Bba = A##ba; \ A##ge ^= De; \ Bbe = ROL64(A##ge, 44); \ A##ki ^= Di; \ Bbi = ROL64(A##ki, 43); \ A##mo ^= Do; \ Bbo = ROL64(A##mo, 21); \ A##su ^= Du; \ Bbu = ROL64(A##su, 14); \ E##ba = Bba ^( Bbe | Bbi ); \ E##ba ^= KeccakF1600RoundConstants[i]; \ Ca = E##ba; \ E##be = Bbe ^((~Bbi)| Bbo ); \ Ce = E##be; \ E##bi = Bbi ^( Bbo & Bbu ); \ Ci = E##bi; \ E##bo = Bbo ^( Bbu | Bba ); \ Co = E##bo; \ E##bu = Bbu ^( Bba & Bbe ); \ Cu = E##bu; \
\
A##bo ^= Do; \ Bga = ROL64(A##bo, 28); \ A##gu ^= Du; \ Bge = ROL64(A##gu, 20); \ A##ka ^= Da; \ Bgi = ROL64(A##ka, 3); \ A##me ^= De; \ Bgo = ROL64(A##me, 45); \ A##si ^= Di; \ Bgu = ROL64(A##si, 61); \ E##ga = Bga ^( Bge | Bgi ); \ Ca ^= E##ga; \ E##ge = Bge ^( Bgi & Bgo ); \ Ce ^= E##ge; \ E##gi = Bgi ^( Bgo |(~Bgu)); \ Ci ^= E##gi; \ E##go = Bgo ^( Bgu | Bga ); \ Co ^= E##go; \ E##gu = Bgu ^( Bga & Bge ); \ Cu ^= E##gu; \
\
A##be ^= De; \ Bka = ROL64(A##be, 1); \ A##gi ^= Di; \ Bke = ROL64(A##gi, 6); \ A##ko ^= Do; \ Bki = ROL64(A##ko, 25); \ A##mu ^= Du; \ Bko = ROL64(A##mu, 8); \ A##sa ^= Da; \ Bku = ROL64(A##sa, 18); \ E##ka = Bka ^( Bke | Bki ); \ Ca ^= E##ka; \ E##ke = Bke ^( Bki & Bko ); \ Ce ^= E##ke; \ E##ki = Bki ^((~Bko)& Bku ); \ Ci ^= E##ki; \ E##ko = (~Bko)^( Bku | Bka ); \ Co ^= E##ko; \ E##ku = Bku ^( Bka & Bke ); \ Cu ^= E##ku; \
\
A##bu ^= Du; \ Bma = ROL64(A##bu, 27); \ A##ga ^= Da; \ Bme = ROL64(A##ga, 36); \ A##ke ^= De; \ Bmi = ROL64(A##ke, 10); \ A##mi ^= Di; \ Bmo = ROL64(A##mi, 15); \ A##so ^= Do; \ Bmu = ROL64(A##so, 56); \ E##ma = Bma ^( Bme & Bmi ); \ Ca ^= E##ma; \ E##me = Bme ^( Bmi | Bmo ); \ Ce ^= E##me; \ E##mi = Bmi ^((~Bmo)| Bmu ); \ Ci ^= E##mi; \ E##mo = (~Bmo)^( Bmu & Bma ); \ Co ^= E##mo; \ E##mu = Bmu ^( Bma | Bme ); \ Cu ^= E##mu; \
\
A##bi ^= Di; \ Bsa = ROL64(A##bi, 62); \ A##go ^= Do; \ Bse = ROL64(A##go, 55); \ A##ku ^= Du; \ Bsi = ROL64(A##ku, 39); \ A##ma ^= Da; \ Bso = ROL64(A##ma, 41); \ A##se ^= De; \ Bsu = ROL64(A##se, 2); \ E##sa = Bsa ^((~Bse)& Bsi ); \ Ca ^= E##sa; \ E##se = (~Bse)^( Bsi | Bso ); \ Ce ^= E##se; \ E##si = Bsi ^( Bso & Bsu ); \ Ci ^= E##si; \ E##so = Bso ^( Bsu | Bsa ); \ Co ^= E##so; \ E##su = Bsu ^( Bsa & Bse ); \ Cu ^= E##su; \
\
// — Code for round (lane complementing pattern ‘bebigokimisa’) // — 64-bit lanes mapped to 64-bit words define thetaRhoPiChiIota(i, A, E) \
Da = Cu^ROL64(Ce, 1); \ De = Ca^ROL64(Ci, 1); \ Di = Ce^ROL64(Co, 1); \ Do = Ci^ROL64(Cu, 1); \ Du = Co^ROL64(Ca, 1); \
\
A##ba ^= Da; \ Bba = A##ba; \ A##ge ^= De; \ Bbe = ROL64(A##ge, 44); \ A##ki ^= Di; \ Bbi = ROL64(A##ki, 43); \ A##mo ^= Do; \ Bbo = ROL64(A##mo, 21); \ A##su ^= Du; \ Bbu = ROL64(A##su, 14); \ E##ba = Bba ^( Bbe | Bbi ); \ E##ba ^= KeccakF1600RoundConstants[i]; \ E##be = Bbe ^((~Bbi)| Bbo ); \ E##bi = Bbi ^( Bbo & Bbu ); \ E##bo = Bbo ^( Bbu | Bba ); \ E##bu = Bbu ^( Bba & Bbe ); \
\
A##bo ^= Do; \ Bga = ROL64(A##bo, 28); \ A##gu ^= Du; \ Bge = ROL64(A##gu, 20); \ A##ka ^= Da; \ Bgi = ROL64(A##ka, 3); \ A##me ^= De; \ Bgo = ROL64(A##me, 45); \ A##si ^= Di; \ Bgu = ROL64(A##si, 61); \ E##ga = Bga ^( Bge | Bgi ); \ E##ge = Bge ^( Bgi & Bgo ); \ E##gi = Bgi ^( Bgo |(~Bgu)); \ E##go = Bgo ^( Bgu | Bga ); \ E##gu = Bgu ^( Bga & Bge ); \
\
A##be ^= De; \ Bka = ROL64(A##be, 1); \ A##gi ^= Di; \ Bke = ROL64(A##gi, 6); \ A##ko ^= Do; \ Bki = ROL64(A##ko, 25); \ A##mu ^= Du; \ Bko = ROL64(A##mu, 8); \ A##sa ^= Da; \ Bku = ROL64(A##sa, 18); \ E##ka = Bka ^( Bke | Bki ); \ E##ke = Bke ^( Bki & Bko ); \ E##ki = Bki ^((~Bko)& Bku ); \ E##ko = (~Bko)^( Bku | Bka ); \ E##ku = Bku ^( Bka & Bke ); \
\
A##bu ^= Du; \ Bma = ROL64(A##bu, 27); \ A##ga ^= Da; \ Bme = ROL64(A##ga, 36); \ A##ke ^= De; \ Bmi = ROL64(A##ke, 10); \ A##mi ^= Di; \ Bmo = ROL64(A##mi, 15); \ A##so ^= Do; \ Bmu = ROL64(A##so, 56); \ E##ma = Bma ^( Bme & Bmi ); \ E##me = Bme ^( Bmi | Bmo ); \ E##mi = Bmi ^((~Bmo)| Bmu ); \ E##mo = (~Bmo)^( Bmu & Bma ); \ E##mu = Bmu ^( Bma | Bme ); \
\
A##bi ^= Di; \ Bsa = ROL64(A##bi, 62); \ A##go ^= Do; \ Bse = ROL64(A##go, 55); \ A##ku ^= Du; \ Bsi = ROL64(A##ku, 39); \ A##ma ^= Da; \ Bso = ROL64(A##ma, 41); \ A##se ^= De; \ Bsu = ROL64(A##se, 2); \ E##sa = Bsa ^((~Bse)& Bsi ); \ E##se = (~Bse)^( Bsi | Bso ); \ E##si = Bsi ^( Bso & Bsu ); \ E##so = Bso ^( Bsu | Bsa ); \ E##su = Bsu ^( Bsa & Bse ); \
\
else // UseBebigokimisa // — Code for round, with prepare-theta // — 64-bit lanes mapped to 64-bit words define thetaRhoPiChiIotaPrepareTheta(i, A, E) \
Da = Cu^ROL64(Ce, 1); \ De = Ca^ROL64(Ci, 1); \ Di = Ce^ROL64(Co, 1); \ Do = Ci^ROL64(Cu, 1); \ Du = Co^ROL64(Ca, 1); \
\
A##ba ^= Da; \ Bba = A##ba; \ A##ge ^= De; \ Bbe = ROL64(A##ge, 44); \ A##ki ^= Di; \ Bbi = ROL64(A##ki, 43); \ A##mo ^= Do; \ Bbo = ROL64(A##mo, 21); \ A##su ^= Du; \ Bbu = ROL64(A##su, 14); \ E##ba = Bba ^((~Bbe)& Bbi ); \ E##ba ^= KeccakF1600RoundConstants[i]; \ Ca = E##ba; \ E##be = Bbe ^((~Bbi)& Bbo ); \ Ce = E##be; \ E##bi = Bbi ^((~Bbo)& Bbu ); \ Ci = E##bi; \ E##bo = Bbo ^((~Bbu)& Bba ); \ Co = E##bo; \ E##bu = Bbu ^((~Bba)& Bbe ); \ Cu = E##bu; \
\
A##bo ^= Do; \ Bga = ROL64(A##bo, 28); \ A##gu ^= Du; \ Bge = ROL64(A##gu, 20); \ A##ka ^= Da; \ Bgi = ROL64(A##ka, 3); \ A##me ^= De; \ Bgo = ROL64(A##me, 45); \ A##si ^= Di; \ Bgu = ROL64(A##si, 61); \ E##ga = Bga ^((~Bge)& Bgi ); \ Ca ^= E##ga; \ E##ge = Bge ^((~Bgi)& Bgo ); \ Ce ^= E##ge; \ E##gi = Bgi ^((~Bgo)& Bgu ); \ Ci ^= E##gi; \ E##go = Bgo ^((~Bgu)& Bga ); \ Co ^= E##go; \ E##gu = Bgu ^((~Bga)& Bge ); \ Cu ^= E##gu; \
\
A##be ^= De; \ Bka = ROL64(A##be, 1); \ A##gi ^= Di; \ Bke = ROL64(A##gi, 6); \ A##ko ^= Do; \ Bki = ROL64(A##ko, 25); \ A##mu ^= Du; \ Bko = ROL64(A##mu, 8); \ A##sa ^= Da; \ Bku = ROL64(A##sa, 18); \ E##ka = Bka ^((~Bke)& Bki ); \ Ca ^= E##ka; \ E##ke = Bke ^((~Bki)& Bko ); \ Ce ^= E##ke; \ E##ki = Bki ^((~Bko)& Bku ); \ Ci ^= E##ki; \ E##ko = Bko ^((~Bku)& Bka ); \ Co ^= E##ko; \ E##ku = Bku ^((~Bka)& Bke ); \ Cu ^= E##ku; \
\
A##bu ^= Du; \ Bma = ROL64(A##bu, 27); \ A##ga ^= Da; \ Bme = ROL64(A##ga, 36); \ A##ke ^= De; \ Bmi = ROL64(A##ke, 10); \ A##mi ^= Di; \ Bmo = ROL64(A##mi, 15); \ A##so ^= Do; \ Bmu = ROL64(A##so, 56); \ E##ma = Bma ^((~Bme)& Bmi ); \ Ca ^= E##ma; \ E##me = Bme ^((~Bmi)& Bmo ); \ Ce ^= E##me; \ E##mi = Bmi ^((~Bmo)& Bmu ); \ Ci ^= E##mi; \ E##mo = Bmo ^((~Bmu)& Bma ); \ Co ^= E##mo; \ E##mu = Bmu ^((~Bma)& Bme ); \ Cu ^= E##mu; \
\
A##bi ^= Di; \ Bsa = ROL64(A##bi, 62); \ A##go ^= Do; \ Bse = ROL64(A##go, 55); \ A##ku ^= Du; \ Bsi = ROL64(A##ku, 39); \ A##ma ^= Da; \ Bso = ROL64(A##ma, 41); \ A##se ^= De; \ Bsu = ROL64(A##se, 2); \ E##sa = Bsa ^((~Bse)& Bsi ); \ Ca ^= E##sa; \ E##se = Bse ^((~Bsi)& Bso ); \ Ce ^= E##se; \ E##si = Bsi ^((~Bso)& Bsu ); \ Ci ^= E##si; \ E##so = Bso ^((~Bsu)& Bsa ); \ Co ^= E##so; \ E##su = Bsu ^((~Bsa)& Bse ); \ Cu ^= E##su; \
\
// — Code for round // — 64-bit lanes mapped to 64-bit words define thetaRhoPiChiIota(i, A, E) \
Da = Cu^ROL64(Ce, 1); \ De = Ca^ROL64(Ci, 1); \ Di = Ce^ROL64(Co, 1); \ Do = Ci^ROL64(Cu, 1); \ Du = Co^ROL64(Ca, 1); \
\
A##ba ^= Da; \ Bba = A##ba; \ A##ge ^= De; \ Bbe = ROL64(A##ge, 44); \ A##ki ^= Di; \ Bbi = ROL64(A##ki, 43); \ A##mo ^= Do; \ Bbo = ROL64(A##mo, 21); \ A##su ^= Du; \ Bbu = ROL64(A##su, 14); \ E##ba = Bba ^((~Bbe)& Bbi ); \ E##ba ^= KeccakF1600RoundConstants[i]; \ E##be = Bbe ^((~Bbi)& Bbo ); \ E##bi = Bbi ^((~Bbo)& Bbu ); \ E##bo = Bbo ^((~Bbu)& Bba ); \ E##bu = Bbu ^((~Bba)& Bbe ); \
\
A##bo ^= Do; \ Bga = ROL64(A##bo, 28); \ A##gu ^= Du; \ Bge = ROL64(A##gu, 20); \ A##ka ^= Da; \ Bgi = ROL64(A##ka, 3); \ A##me ^= De; \ Bgo = ROL64(A##me, 45); \ A##si ^= Di; \ Bgu = ROL64(A##si, 61); \ E##ga = Bga ^((~Bge)& Bgi ); \ E##ge = Bge ^((~Bgi)& Bgo ); \ E##gi = Bgi ^((~Bgo)& Bgu ); \ E##go = Bgo ^((~Bgu)& Bga ); \ E##gu = Bgu ^((~Bga)& Bge ); \
\
A##be ^= De; \ Bka = ROL64(A##be, 1); \ A##gi ^= Di; \ Bke = ROL64(A##gi, 6); \ A##ko ^= Do; \ Bki = ROL64(A##ko, 25); \ A##mu ^= Du; \ Bko = ROL64(A##mu, 8); \ A##sa ^= Da; \ Bku = ROL64(A##sa, 18); \ E##ka = Bka ^((~Bke)& Bki ); \ E##ke = Bke ^((~Bki)& Bko ); \ E##ki = Bki ^((~Bko)& Bku ); \ E##ko = Bko ^((~Bku)& Bka ); \ E##ku = Bku ^((~Bka)& Bke ); \
\
A##bu ^= Du; \ Bma = ROL64(A##bu, 27); \ A##ga ^= Da; \ Bme = ROL64(A##ga, 36); \ A##ke ^= De; \ Bmi = ROL64(A##ke, 10); \ A##mi ^= Di; \ Bmo = ROL64(A##mi, 15); \ A##so ^= Do; \ Bmu = ROL64(A##so, 56); \ E##ma = Bma ^((~Bme)& Bmi ); \ E##me = Bme ^((~Bmi)& Bmo ); \ E##mi = Bmi ^((~Bmo)& Bmu ); \ E##mo = Bmo ^((~Bmu)& Bma ); \ E##mu = Bmu ^((~Bma)& Bme ); \
\
A##bi ^= Di; \ Bsa = ROL64(A##bi, 62); \ A##go ^= Do; \ Bse = ROL64(A##go, 55); \ A##ku ^= Du; \ Bsi = ROL64(A##ku, 39); \ A##ma ^= Da; \ Bso = ROL64(A##ma, 41); \ A##se ^= De; \ Bsu = ROL64(A##se, 2); \ E##sa = Bsa ^((~Bse)& Bsi ); \ E##se = Bse ^((~Bsi)& Bso ); \ E##si = Bsi ^((~Bso)& Bsu ); \ E##so = Bso ^((~Bsu)& Bsa ); \ E##su = Bsu ^((~Bsa)& Bse ); \
\
endif // UseBebigokimisa
define copyFromState(X, state) \
X##ba = state[ 0]; \ X##be = state[ 1]; \ X##bi = state[ 2]; \ X##bo = state[ 3]; \ X##bu = state[ 4]; \ X##ga = state[ 5]; \ X##ge = state[ 6]; \ X##gi = state[ 7]; \ X##go = state[ 8]; \ X##gu = state[ 9]; \ X##ka = state[10]; \ X##ke = state[11]; \ X##ki = state[12]; \ X##ko = state[13]; \ X##ku = state[14]; \ X##ma = state[15]; \ X##me = state[16]; \ X##mi = state[17]; \ X##mo = state[18]; \ X##mu = state[19]; \ X##sa = state[20]; \ X##se = state[21]; \ X##si = state[22]; \ X##so = state[23]; \ X##su = state[24]; \
define copyToState(state, X) \
state[ 0] = X##ba; \ state[ 1] = X##be; \ state[ 2] = X##bi; \ state[ 3] = X##bo; \ state[ 4] = X##bu; \ state[ 5] = X##ga; \ state[ 6] = X##ge; \ state[ 7] = X##gi; \ state[ 8] = X##go; \ state[ 9] = X##gu; \ state[10] = X##ka; \ state[11] = X##ke; \ state[12] = X##ki; \ state[13] = X##ko; \ state[14] = X##ku; \ state[15] = X##ma; \ state[16] = X##me; \ state[17] = X##mi; \ state[18] = X##mo; \ state[19] = X##mu; \ state[20] = X##sa; \ state[21] = X##se; \ state[22] = X##si; \ state[23] = X##so; \ state[24] = X##su; \
define copyStateVariables(X, Y) \
X##ba = Y##ba; \ X##be = Y##be; \ X##bi = Y##bi; \ X##bo = Y##bo; \ X##bu = Y##bu; \ X##ga = Y##ga; \ X##ge = Y##ge; \ X##gi = Y##gi; \ X##go = Y##go; \ X##gu = Y##gu; \ X##ka = Y##ka; \ X##ke = Y##ke; \ X##ki = Y##ki; \ X##ko = Y##ko; \ X##ku = Y##ku; \ X##ma = Y##ma; \ X##me = Y##me; \ X##mi = Y##mi; \ X##mo = Y##mo; \ X##mu = Y##mu; \ X##sa = Y##sa; \ X##se = Y##se; \ X##si = Y##si; \ X##so = Y##so; \ X##su = Y##su; \
define copyFromStateAndXOR(X, state, input, laneCount) \
if (laneCount < 16) { \
if (laneCount < 8) { \
if (laneCount < 4) { \
if (laneCount < 2) { \
if (laneCount < 1) { \
X##ba = state[ 0]; \
} \
else { \
X##ba = state[ 0]^input[ 0]; \
} \
X##be = state[ 1]; \
X##bi = state[ 2]; \
} \
else { \
X##ba = state[ 0]^input[ 0]; \
X##be = state[ 1]^input[ 1]; \
if (laneCount < 3) { \
X##bi = state[ 2]; \
} \
else { \
X##bi = state[ 2]^input[ 2]; \
} \
} \
X##bo = state[ 3]; \
X##bu = state[ 4]; \
X##ga = state[ 5]; \
X##ge = state[ 6]; \
} \
else { \
X##ba = state[ 0]^input[ 0]; \
X##be = state[ 1]^input[ 1]; \
X##bi = state[ 2]^input[ 2]; \
X##bo = state[ 3]^input[ 3]; \
if (laneCount < 6) { \
if (laneCount < 5) { \
X##bu = state[ 4]; \
} \
else { \
X##bu = state[ 4]^input[ 4]; \
} \
X##ga = state[ 5]; \
X##ge = state[ 6]; \
} \
else { \
X##bu = state[ 4]^input[ 4]; \
X##ga = state[ 5]^input[ 5]; \
if (laneCount < 7) { \
X##ge = state[ 6]; \
} \
else { \
X##ge = state[ 6]^input[ 6]; \
} \
} \
} \
X##gi = state[ 7]; \
X##go = state[ 8]; \
X##gu = state[ 9]; \
X##ka = state[10]; \
X##ke = state[11]; \
X##ki = state[12]; \
X##ko = state[13]; \
X##ku = state[14]; \
} \
else { \
X##ba = state[ 0]^input[ 0]; \
X##be = state[ 1]^input[ 1]; \
X##bi = state[ 2]^input[ 2]; \
X##bo = state[ 3]^input[ 3]; \
X##bu = state[ 4]^input[ 4]; \
X##ga = state[ 5]^input[ 5]; \
X##ge = state[ 6]^input[ 6]; \
X##gi = state[ 7]^input[ 7]; \
if (laneCount < 12) { \
if (laneCount < 10) { \
if (laneCount < 9) { \
X##go = state[ 8]; \
} \
else { \
X##go = state[ 8]^input[ 8]; \
} \
X##gu = state[ 9]; \
X##ka = state[10]; \
} \
else { \
X##go = state[ 8]^input[ 8]; \
X##gu = state[ 9]^input[ 9]; \
if (laneCount < 11) { \
X##ka = state[10]; \
} \
else { \
X##ka = state[10]^input[10]; \
} \
} \
X##ke = state[11]; \
X##ki = state[12]; \
X##ko = state[13]; \
X##ku = state[14]; \
} \
else { \
X##go = state[ 8]^input[ 8]; \
X##gu = state[ 9]^input[ 9]; \
X##ka = state[10]^input[10]; \
X##ke = state[11]^input[11]; \
if (laneCount < 14) { \
if (laneCount < 13) { \
X##ki = state[12]; \
} \
else { \
X##ki = state[12]^input[12]; \
} \
X##ko = state[13]; \
X##ku = state[14]; \
} \
else { \
X##ki = state[12]^input[12]; \
X##ko = state[13]^input[13]; \
if (laneCount < 15) { \
X##ku = state[14]; \
} \
else { \
X##ku = state[14]^input[14]; \
} \
} \
} \
} \
X##ma = state[15]; \
X##me = state[16]; \
X##mi = state[17]; \
X##mo = state[18]; \
X##mu = state[19]; \
X##sa = state[20]; \
X##se = state[21]; \
X##si = state[22]; \
X##so = state[23]; \
X##su = state[24]; \
} \
else { \
X##ba = state[ 0]^input[ 0]; \
X##be = state[ 1]^input[ 1]; \
X##bi = state[ 2]^input[ 2]; \
X##bo = state[ 3]^input[ 3]; \
X##bu = state[ 4]^input[ 4]; \
X##ga = state[ 5]^input[ 5]; \
X##ge = state[ 6]^input[ 6]; \
X##gi = state[ 7]^input[ 7]; \
X##go = state[ 8]^input[ 8]; \
X##gu = state[ 9]^input[ 9]; \
X##ka = state[10]^input[10]; \
X##ke = state[11]^input[11]; \
X##ki = state[12]^input[12]; \
X##ko = state[13]^input[13]; \
X##ku = state[14]^input[14]; \
X##ma = state[15]^input[15]; \
if (laneCount < 24) { \
if (laneCount < 20) { \
if (laneCount < 18) { \
if (laneCount < 17) { \
X##me = state[16]; \
} \
else { \
X##me = state[16]^input[16]; \
} \
X##mi = state[17]; \
X##mo = state[18]; \
} \
else { \
X##me = state[16]^input[16]; \
X##mi = state[17]^input[17]; \
if (laneCount < 19) { \
X##mo = state[18]; \
} \
else { \
X##mo = state[18]^input[18]; \
} \
} \
X##mu = state[19]; \
X##sa = state[20]; \
X##se = state[21]; \
X##si = state[22]; \
} \
else { \
X##me = state[16]^input[16]; \
X##mi = state[17]^input[17]; \
X##mo = state[18]^input[18]; \
X##mu = state[19]^input[19]; \
if (laneCount < 22) { \
if (laneCount < 21) { \
X##sa = state[20]; \
} \
else { \
X##sa = state[20]^input[20]; \
} \
X##se = state[21]; \
X##si = state[22]; \
} \
else { \
X##sa = state[20]^input[20]; \
X##se = state[21]^input[21]; \
if (laneCount < 23) { \
X##si = state[22]; \
} \
else { \
X##si = state[22]^input[22]; \
} \
} \
} \
X##so = state[23]; \
X##su = state[24]; \
} \
else { \
X##me = state[16]^input[16]; \
X##mi = state[17]^input[17]; \
X##mo = state[18]^input[18]; \
X##mu = state[19]^input[19]; \
X##sa = state[20]^input[20]; \
X##se = state[21]^input[21]; \
X##si = state[22]^input[22]; \
X##so = state[23]^input[23]; \
if (laneCount < 25) { \
X##su = state[24]; \
} \
else { \
X##su = state[24]^input[24]; \
} \
} \
}
define XORinputAndTrailingBits(X, input, laneCount, trailingBits) \
if (laneCount < 16) { \
if (laneCount < 8) { \
if (laneCount < 4) { \
if (laneCount < 2) { \
if (laneCount < 1) { \
X##ba ^= trailingBits; \
} \
else { \
X##ba ^= input[ 0]; \
X##be ^= trailingBits; \
} \
} \
else { \
X##ba ^= input[ 0]; \
X##be ^= input[ 1]; \
if (laneCount < 3) { \
X##bi ^= trailingBits; \
} \
else { \
X##bi ^= input[ 2]; \
X##bo ^= trailingBits; \
} \
} \
} \
else { \
X##ba ^= input[ 0]; \
X##be ^= input[ 1]; \
X##bi ^= input[ 2]; \
X##bo ^= input[ 3]; \
if (laneCount < 6) { \
if (laneCount < 5) { \
X##bu ^= trailingBits; \
} \
else { \
X##bu ^= input[ 4]; \
X##ga ^= trailingBits; \
} \
} \
else { \
X##bu ^= input[ 4]; \
X##ga ^= input[ 5]; \
if (laneCount < 7) { \
X##ge ^= trailingBits; \
} \
else { \
X##ge ^= input[ 6]; \
X##gi ^= trailingBits; \
} \
} \
} \
} \
else { \
X##ba ^= input[ 0]; \
X##be ^= input[ 1]; \
X##bi ^= input[ 2]; \
X##bo ^= input[ 3]; \
X##bu ^= input[ 4]; \
X##ga ^= input[ 5]; \
X##ge ^= input[ 6]; \
X##gi ^= input[ 7]; \
if (laneCount < 12) { \
if (laneCount < 10) { \
if (laneCount < 9) { \
X##go ^= trailingBits; \
} \
else { \
X##go ^= input[ 8]; \
X##gu ^= trailingBits ; \
} \
} \
else { \
X##go ^= input[ 8]; \
X##gu ^= input[ 9]; \
if (laneCount < 11) { \
X##ka ^= trailingBits; \
} \
else { \
X##ka ^= input[10]; \
X##ke ^= trailingBits; \
} \
} \
} \
else { \
X##go ^= input[ 8]; \
X##gu ^= input[ 9]; \
X##ka ^= input[10]; \
X##ke ^= input[11]; \
if (laneCount < 14) { \
if (laneCount < 13) { \
X##ki ^= trailingBits; \
} \
else { \
X##ki ^= input[12]; \
X##ko ^= trailingBits; \
} \
} \
else { \
X##ki ^= input[12]; \
X##ko ^= input[13]; \
if (laneCount < 15) { \
X##ku ^= trailingBits; \
} \
else { \
X##ku ^= input[14]; \
X##ma ^= trailingBits; \
} \
} \
} \
} \
} \
else { \
X##ba ^= input[ 0]; \
X##be ^= input[ 1]; \
X##bi ^= input[ 2]; \
X##bo ^= input[ 3]; \
X##bu ^= input[ 4]; \
X##ga ^= input[ 5]; \
X##ge ^= input[ 6]; \
X##gi ^= input[ 7]; \
X##go ^= input[ 8]; \
X##gu ^= input[ 9]; \
X##ka ^= input[10]; \
X##ke ^= input[11]; \
X##ki ^= input[12]; \
X##ko ^= input[13]; \
X##ku ^= input[14]; \
X##ma ^= input[15]; \
if (laneCount < 24) { \
if (laneCount < 20) { \
if (laneCount < 18) { \
if (laneCount < 17) { \
X##me ^= trailingBits; \
} \
else { \
X##me ^= input[16]; \
X##mi ^= trailingBits; \
} \
} \
else { \
X##me ^= input[16]; \
X##mi ^= input[17]; \
if (laneCount < 19) { \
X##mo ^= trailingBits; \
} \
else { \
X##mo ^= input[18]; \
X##mu ^= trailingBits; \
} \
} \
} \
else { \
X##me ^= input[16]; \
X##mi ^= input[17]; \
X##mo ^= input[18]; \
X##mu ^= input[19]; \
if (laneCount < 22) { \
if (laneCount < 21) { \
X##sa ^= trailingBits; \
} \
else { \
X##sa ^= input[20]; \
X##se ^= trailingBits; \
} \
} \
else { \
X##sa ^= input[20]; \
X##se ^= input[21]; \
if (laneCount < 23) { \
X##si ^= trailingBits; \
} \
else { \
X##si ^= input[22]; \
X##so ^= trailingBits; \
} \
} \
} \
} \
else { \
X##me ^= input[16]; \
X##mi ^= input[17]; \
X##mo ^= input[18]; \
X##mu ^= input[19]; \
X##sa ^= input[20]; \
X##se ^= input[21]; \
X##si ^= input[22]; \
X##so ^= input[23]; \
if (laneCount < 25) { \
X##su ^= trailingBits; \
} \
else { \
X##su ^= input[24]; \
} \
} \
}
ifdef UseBebigokimisa
define copyToStateAndOutput(X, state, output, laneCount) \
if (laneCount < 16) { \
if (laneCount < 8) { \
if (laneCount < 4) { \
if (laneCount < 2) { \
state[ 0] = X##ba; \
if (laneCount >= 1) { \
output[ 0] = X##ba; \
} \
state[ 1] = X##be; \
state[ 2] = X##bi; \
} \
else { \
state[ 0] = X##ba; \
output[ 0] = X##ba; \
state[ 1] = X##be; \
output[ 1] = ~X##be; \
state[ 2] = X##bi; \
if (laneCount >= 3) { \
output[ 2] = ~X##bi; \
} \
} \
state[ 3] = X##bo; \
state[ 4] = X##bu; \
state[ 5] = X##ga; \
state[ 6] = X##ge; \
} \
else { \
state[ 0] = X##ba; \
output[ 0] = X##ba; \
state[ 1] = X##be; \
output[ 1] = ~X##be; \
state[ 2] = X##bi; \
output[ 2] = ~X##bi; \
state[ 3] = X##bo; \
output[ 3] = X##bo; \
if (laneCount < 6) { \
state[ 4] = X##bu; \
if (laneCount >= 5) { \
output[ 4] = X##bu; \
} \
state[ 5] = X##ga; \
state[ 6] = X##ge; \
} \
else { \
state[ 4] = X##bu; \
output[ 4] = X##bu; \
state[ 5] = X##ga; \
output[ 5] = X##ga; \
state[ 6] = X##ge; \
if (laneCount >= 7) { \
output[ 6] = X##ge; \
} \
} \
} \
state[ 7] = X##gi; \
state[ 8] = X##go; \
state[ 9] = X##gu; \
state[10] = X##ka; \
state[11] = X##ke; \
state[12] = X##ki; \
state[13] = X##ko; \
state[14] = X##ku; \
} \
else { \
state[ 0] = X##ba; \
output[ 0] = X##ba; \
state[ 1] = X##be; \
output[ 1] = ~X##be; \
state[ 2] = X##bi; \
output[ 2] = ~X##bi; \
state[ 3] = X##bo; \
output[ 3] = X##bo; \
state[ 4] = X##bu; \
output[ 4] = X##bu; \
state[ 5] = X##ga; \
output[ 5] = X##ga; \
state[ 6] = X##ge; \
output[ 6] = X##ge; \
state[ 7] = X##gi; \
output[ 7] = X##gi; \
if (laneCount < 12) { \
if (laneCount < 10) { \
state[ 8] = X##go; \
if (laneCount >= 9) { \
output[ 8] = ~X##go; \
} \
state[ 9] = X##gu; \
state[10] = X##ka; \
} \
else { \
state[ 8] = X##go; \
output[ 8] = ~X##go; \
state[ 9] = X##gu; \
output[ 9] = X##gu; \
state[10] = X##ka; \
if (laneCount >= 11) { \
output[10] = X##ka; \
} \
} \
state[11] = X##ke; \
state[12] = X##ki; \
state[13] = X##ko; \
state[14] = X##ku; \
} \
else { \
state[ 8] = X##go; \
output[ 8] = ~X##go; \
state[ 9] = X##gu; \
output[ 9] = X##gu; \
state[10] = X##ka; \
output[10] = X##ka; \
state[11] = X##ke; \
output[11] = X##ke; \
if (laneCount < 14) { \
state[12] = X##ki; \
if (laneCount >= 13) { \
output[12] = ~X##ki; \
} \
state[13] = X##ko; \
state[14] = X##ku; \
} \
else { \
state[12] = X##ki; \
output[12] = ~X##ki; \
state[13] = X##ko; \
output[13] = X##ko; \
state[14] = X##ku; \
if (laneCount >= 15) { \
output[14] = X##ku; \
} \
} \
} \
} \
state[15] = X##ma; \
state[16] = X##me; \
state[17] = X##mi; \
state[18] = X##mo; \
state[19] = X##mu; \
state[20] = X##sa; \
state[21] = X##se; \
state[22] = X##si; \
state[23] = X##so; \
state[24] = X##su; \
} \
else { \
state[ 0] = X##ba; \
output[ 0] = X##ba; \
state[ 1] = X##be; \
output[ 1] = ~X##be; \
state[ 2] = X##bi; \
output[ 2] = ~X##bi; \
state[ 3] = X##bo; \
output[ 3] = X##bo; \
state[ 4] = X##bu; \
output[ 4] = X##bu; \
state[ 5] = X##ga; \
output[ 5] = X##ga; \
state[ 6] = X##ge; \
output[ 6] = X##ge; \
state[ 7] = X##gi; \
output[ 7] = X##gi; \
state[ 8] = X##go; \
output[ 8] = ~X##go; \
state[ 9] = X##gu; \
output[ 9] = X##gu; \
state[10] = X##ka; \
output[10] = X##ka; \
state[11] = X##ke; \
output[11] = X##ke; \
state[12] = X##ki; \
output[12] = ~X##ki; \
state[13] = X##ko; \
output[13] = X##ko; \
state[14] = X##ku; \
output[14] = X##ku; \
state[15] = X##ma; \
output[15] = X##ma; \
if (laneCount < 24) { \
if (laneCount < 20) { \
if (laneCount < 18) { \
state[16] = X##me; \
if (laneCount >= 17) { \
output[16] = X##me; \
} \
state[17] = X##mi; \
state[18] = X##mo; \
} \
else { \
state[16] = X##me; \
output[16] = X##me; \
state[17] = X##mi; \
output[17] = ~X##mi; \
state[18] = X##mo; \
if (laneCount >= 19) { \
output[18] = X##mo; \
} \
} \
state[19] = X##mu; \
state[20] = X##sa; \
state[21] = X##se; \
state[22] = X##si; \
} \
else { \
state[16] = X##me; \
output[16] = X##me; \
state[17] = X##mi; \
output[17] = ~X##mi; \
state[18] = X##mo; \
output[18] = X##mo; \
state[19] = X##mu; \
output[19] = X##mu; \
if (laneCount < 22) { \
state[20] = X##sa; \
if (laneCount >= 21) { \
output[20] = ~X##sa; \
} \
state[21] = X##se; \
state[22] = X##si; \
} \
else { \
state[20] = X##sa; \
output[20] = ~X##sa; \
state[21] = X##se; \
output[21] = X##se; \
state[22] = X##si; \
if (laneCount >= 23) { \
output[22] = X##si; \
} \
} \
} \
state[23] = X##so; \
state[24] = X##su; \
} \
else { \
state[16] = X##me; \
output[16] = X##me; \
state[17] = X##mi; \
output[17] = ~X##mi; \
state[18] = X##mo; \
output[18] = X##mo; \
state[19] = X##mu; \
output[19] = X##mu; \
state[20] = X##sa; \
output[20] = ~X##sa; \
state[21] = X##se; \
output[21] = X##se; \
state[22] = X##si; \
output[22] = X##si; \
state[23] = X##so; \
output[23] = X##so; \
state[24] = X##su; \
if (laneCount >= 25) { \
output[24] = X##su; \
} \
} \
}
define output(X, output, laneCount) \
if (laneCount < 16) { \
if (laneCount < 8) { \
if (laneCount < 4) { \
if (laneCount < 2) { \
if (laneCount >= 1) { \
output[ 0] = X##ba; \
} \
} \
else { \
output[ 0] = X##ba; \
output[ 1] = ~X##be; \
if (laneCount >= 3) { \
output[ 2] = ~X##bi; \
} \
} \
} \
else { \
output[ 0] = X##ba; \
output[ 1] = ~X##be; \
output[ 2] = ~X##bi; \
output[ 3] = X##bo; \
if (laneCount < 6) { \
if (laneCount >= 5) { \
output[ 4] = X##bu; \
} \
} \
else { \
output[ 4] = X##bu; \
output[ 5] = X##ga; \
if (laneCount >= 7) { \
output[ 6] = X##ge; \
} \
} \
} \
} \
else { \
output[ 0] = X##ba; \
output[ 1] = ~X##be; \
output[ 2] = ~X##bi; \
output[ 3] = X##bo; \
output[ 4] = X##bu; \
output[ 5] = X##ga; \
output[ 6] = X##ge; \
output[ 7] = X##gi; \
if (laneCount < 12) { \
if (laneCount < 10) { \
if (laneCount >= 9) { \
output[ 8] = ~X##go; \
} \
} \
else { \
output[ 8] = ~X##go; \
output[ 9] = X##gu; \
if (laneCount >= 11) { \
output[10] = X##ka; \
} \
} \
} \
else { \
output[ 8] = ~X##go; \
output[ 9] = X##gu; \
output[10] = X##ka; \
output[11] = X##ke; \
if (laneCount < 14) { \
if (laneCount >= 13) { \
output[12] = ~X##ki; \
} \
} \
else { \
output[12] = ~X##ki; \
output[13] = X##ko; \
if (laneCount >= 15) { \
output[14] = X##ku; \
} \
} \
} \
} \
} \
else { \
output[ 0] = X##ba; \
output[ 1] = ~X##be; \
output[ 2] = ~X##bi; \
output[ 3] = X##bo; \
output[ 4] = X##bu; \
output[ 5] = X##ga; \
output[ 6] = X##ge; \
output[ 7] = X##gi; \
output[ 8] = ~X##go; \
output[ 9] = X##gu; \
output[10] = X##ka; \
output[11] = X##ke; \
output[12] = ~X##ki; \
output[13] = X##ko; \
output[14] = X##ku; \
output[15] = X##ma; \
if (laneCount < 24) { \
if (laneCount < 20) { \
if (laneCount < 18) { \
if (laneCount >= 17) { \
output[16] = X##me; \
} \
} \
else { \
output[16] = X##me; \
output[17] = ~X##mi; \
if (laneCount >= 19) { \
output[18] = X##mo; \
} \
} \
} \
else { \
output[16] = X##me; \
output[17] = ~X##mi; \
output[18] = X##mo; \
output[19] = X##mu; \
if (laneCount < 22) { \
if (laneCount >= 21) { \
output[20] = ~X##sa; \
} \
} \
else { \
output[20] = ~X##sa; \
output[21] = X##se; \
if (laneCount >= 23) { \
output[22] = X##si; \
} \
} \
} \
} \
else { \
output[16] = X##me; \
output[17] = ~X##mi; \
output[18] = X##mo; \
output[19] = X##mu; \
output[20] = ~X##sa; \
output[21] = X##se; \
output[22] = X##si; \
output[23] = X##so; \
if (laneCount >= 25) { \
output[24] = X##su; \
} \
} \
}
define wrapOne(X, input, output, index, name) \
X##name ^= input[index]; \ output[index] = X##name;
define wrapOneInvert(X, input, output, index, name) \
X##name ^= input[index]; \ output[index] = ~X##name;
define unwrapOne(X, input, output, index, name) \
output[index] = input[index] ^ X##name; \ X##name ^= output[index];
define unwrapOneInvert(X, input, output, index, name) \
output[index] = ~(input[index] ^ X##name); \ X##name ^= output[index]; \
else // UseBebigokimisa
define copyToStateAndOutput(X, state, output, laneCount) \
if (laneCount < 16) { \
if (laneCount < 8) { \
if (laneCount < 4) { \
if (laneCount < 2) { \
state[ 0] = X##ba; \
if (laneCount >= 1) { \
output[ 0] = X##ba; \
} \
state[ 1] = X##be; \
state[ 2] = X##bi; \
} \
else { \
state[ 0] = X##ba; \
output[ 0] = X##ba; \
state[ 1] = X##be; \
output[ 1] = X##be; \
state[ 2] = X##bi; \
if (laneCount >= 3) { \
output[ 2] = X##bi; \
} \
} \
state[ 3] = X##bo; \
state[ 4] = X##bu; \
state[ 5] = X##ga; \
state[ 6] = X##ge; \
} \
else { \
state[ 0] = X##ba; \
output[ 0] = X##ba; \
state[ 1] = X##be; \
output[ 1] = X##be; \
state[ 2] = X##bi; \
output[ 2] = X##bi; \
state[ 3] = X##bo; \
output[ 3] = X##bo; \
if (laneCount < 6) { \
state[ 4] = X##bu; \
if (laneCount >= 5) { \
output[ 4] = X##bu; \
} \
state[ 5] = X##ga; \
state[ 6] = X##ge; \
} \
else { \
state[ 4] = X##bu; \
output[ 4] = X##bu; \
state[ 5] = X##ga; \
output[ 5] = X##ga; \
state[ 6] = X##ge; \
if (laneCount >= 7) { \
output[ 6] = X##ge; \
} \
} \
} \
state[ 7] = X##gi; \
state[ 8] = X##go; \
state[ 9] = X##gu; \
state[10] = X##ka; \
state[11] = X##ke; \
state[12] = X##ki; \
state[13] = X##ko; \
state[14] = X##ku; \
} \
else { \
state[ 0] = X##ba; \
output[ 0] = X##ba; \
state[ 1] = X##be; \
output[ 1] = X##be; \
state[ 2] = X##bi; \
output[ 2] = X##bi; \
state[ 3] = X##bo; \
output[ 3] = X##bo; \
state[ 4] = X##bu; \
output[ 4] = X##bu; \
state[ 5] = X##ga; \
output[ 5] = X##ga; \
state[ 6] = X##ge; \
output[ 6] = X##ge; \
state[ 7] = X##gi; \
output[ 7] = X##gi; \
if (laneCount < 12) { \
if (laneCount < 10) { \
state[ 8] = X##go; \
if (laneCount >= 9) { \
output[ 8] = X##go; \
} \
state[ 9] = X##gu; \
state[10] = X##ka; \
} \
else { \
state[ 8] = X##go; \
output[ 8] = X##go; \
state[ 9] = X##gu; \
output[ 9] = X##gu; \
state[10] = X##ka; \
if (laneCount >= 11) { \
output[10] = X##ka; \
} \
} \
state[11] = X##ke; \
state[12] = X##ki; \
state[13] = X##ko; \
state[14] = X##ku; \
} \
else { \
state[ 8] = X##go; \
output[ 8] = X##go; \
state[ 9] = X##gu; \
output[ 9] = X##gu; \
state[10] = X##ka; \
output[10] = X##ka; \
state[11] = X##ke; \
output[11] = X##ke; \
if (laneCount < 14) { \
state[12] = X##ki; \
if (laneCount >= 13) { \
output[12]= X##ki; \
} \
state[13] = X##ko; \
state[14] = X##ku; \
} \
else { \
state[12] = X##ki; \
output[12]= X##ki; \
state[13] = X##ko; \
output[13] = X##ko; \
state[14] = X##ku; \
if (laneCount >= 15) { \
output[14] = X##ku; \
} \
} \
} \
} \
state[15] = X##ma; \
state[16] = X##me; \
state[17] = X##mi; \
state[18] = X##mo; \
state[19] = X##mu; \
state[20] = X##sa; \
state[21] = X##se; \
state[22] = X##si; \
state[23] = X##so; \
state[24] = X##su; \
} \
else { \
state[ 0] = X##ba; \
output[ 0] = X##ba; \
state[ 1] = X##be; \
output[ 1] = X##be; \
state[ 2] = X##bi; \
output[ 2] = X##bi; \
state[ 3] = X##bo; \
output[ 3] = X##bo; \
state[ 4] = X##bu; \
output[ 4] = X##bu; \
state[ 5] = X##ga; \
output[ 5] = X##ga; \
state[ 6] = X##ge; \
output[ 6] = X##ge; \
state[ 7] = X##gi; \
output[ 7] = X##gi; \
state[ 8] = X##go; \
output[ 8] = X##go; \
state[ 9] = X##gu; \
output[ 9] = X##gu; \
state[10] = X##ka; \
output[10] = X##ka; \
state[11] = X##ke; \
output[11] = X##ke; \
state[12] = X##ki; \
output[12]= X##ki; \
state[13] = X##ko; \
output[13] = X##ko; \
state[14] = X##ku; \
output[14] = X##ku; \
state[15] = X##ma; \
output[15] = X##ma; \
if (laneCount < 24) { \
if (laneCount < 20) { \
if (laneCount < 18) { \
state[16] = X##me; \
if (laneCount >= 17) { \
output[16] = X##me; \
} \
state[17] = X##mi; \
state[18] = X##mo; \
} \
else { \
state[16] = X##me; \
output[16] = X##me; \
state[17] = X##mi; \
output[17] = X##mi; \
state[18] = X##mo; \
if (laneCount >= 19) { \
output[18] = X##mo; \
} \
} \
state[19] = X##mu; \
state[20] = X##sa; \
state[21] = X##se; \
state[22] = X##si; \
} \
else { \
state[16] = X##me; \
output[16] = X##me; \
state[17] = X##mi; \
output[17] = X##mi; \
state[18] = X##mo; \
output[18] = X##mo; \
state[19] = X##mu; \
output[19] = X##mu; \
if (laneCount < 22) { \
state[20] = X##sa; \
if (laneCount >= 21) { \
output[20] = X##sa; \
} \
state[21] = X##se; \
state[22] = X##si; \
} \
else { \
state[20] = X##sa; \
output[20] = X##sa; \
state[21] = X##se; \
output[21] = X##se; \
state[22] = X##si; \
if (laneCount >= 23) { \
output[22] = X##si; \
} \
} \
} \
state[23] = X##so; \
state[24] = X##su; \
} \
else { \
state[16] = X##me; \
output[16] = X##me; \
state[17] = X##mi; \
output[17] = X##mi; \
state[18] = X##mo; \
output[18] = X##mo; \
state[19] = X##mu; \
output[19] = X##mu; \
state[20] = X##sa; \
output[20] = X##sa; \
state[21] = X##se; \
output[21] = X##se; \
state[22] = X##si; \
output[22] = X##si; \
state[23] = X##so; \
output[23] = X##so; \
state[24] = X##su; \
if (laneCount >= 25) { \
output[24] = X##su; \
} \
} \
}
define output(X, output, laneCount) \
if (laneCount < 16) { \
if (laneCount < 8) { \
if (laneCount < 4) { \
if (laneCount < 2) { \
if (laneCount >= 1) { \
output[ 0] = X##ba; \
} \
} \
else { \
output[ 0] = X##ba; \
output[ 1] = X##be; \
if (laneCount >= 3) { \
output[ 2] = X##bi; \
} \
} \
} \
else { \
output[ 0] = X##ba; \
output[ 1] = X##be; \
output[ 2] = X##bi; \
output[ 3] = X##bo; \
if (laneCount < 6) { \
if (laneCount >= 5) { \
output[ 4] = X##bu; \
} \
} \
else { \
output[ 4] = X##bu; \
output[ 5] = X##ga; \
if (laneCount >= 7) { \
output[ 6] = X##ge; \
} \
} \
} \
} \
else { \
output[ 0] = X##ba; \
output[ 1] = X##be; \
output[ 2] = X##bi; \
output[ 3] = X##bo; \
output[ 4] = X##bu; \
output[ 5] = X##ga; \
output[ 6] = X##ge; \
output[ 7] = X##gi; \
if (laneCount < 12) { \
if (laneCount < 10) { \
if (laneCount >= 9) { \
output[ 8] = X##go; \
} \
} \
else { \
output[ 8] = X##go; \
output[ 9] = X##gu; \
if (laneCount >= 11) { \
output[10] = X##ka; \
} \
} \
} \
else { \
output[ 8] = X##go; \
output[ 9] = X##gu; \
output[10] = X##ka; \
output[11] = X##ke; \
if (laneCount < 14) { \
if (laneCount >= 13) { \
output[12] = X##ki; \
} \
} \
else { \
output[12] = X##ki; \
output[13] = X##ko; \
if (laneCount >= 15) { \
output[14] = X##ku; \
} \
} \
} \
} \
} \
else { \
output[ 0] = X##ba; \
output[ 1] = X##be; \
output[ 2] = X##bi; \
output[ 3] = X##bo; \
output[ 4] = X##bu; \
output[ 5] = X##ga; \
output[ 6] = X##ge; \
output[ 7] = X##gi; \
output[ 8] = X##go; \
output[ 9] = X##gu; \
output[10] = X##ka; \
output[11] = X##ke; \
output[12] = X##ki; \
output[13] = X##ko; \
output[14] = X##ku; \
output[15] = X##ma; \
if (laneCount < 24) { \
if (laneCount < 20) { \
if (laneCount < 18) { \
if (laneCount >= 17) { \
output[16] = X##me; \
} \
} \
else { \
output[16] = X##me; \
output[17] = X##mi; \
if (laneCount >= 19) { \
output[18] = X##mo; \
} \
} \
} \
else { \
output[16] = X##me; \
output[17] = X##mi; \
output[18] = X##mo; \
output[19] = X##mu; \
if (laneCount < 22) { \
if (laneCount >= 21) { \
output[20] = X##sa; \
} \
} \
else { \
output[20] = X##sa; \
output[21] = X##se; \
if (laneCount >= 23) { \
output[22] = X##si; \
} \
} \
} \
} \
else { \
output[16] = X##me; \
output[17] = X##mi; \
output[18] = X##mo; \
output[19] = X##mu; \
output[20] = X##sa; \
output[21] = X##se; \
output[22] = X##si; \
output[23] = X##so; \
if (laneCount >= 25) { \
output[24] = X##su; \
} \
} \
}
define wrapOne(X, input, output, index, name) \
X##name ^= input[index]; \ output[index] = X##name;
define wrapOneInvert(X, input, output, index, name) \
X##name ^= input[index]; \ output[index] = X##name;
define unwrapOne(X, input, output, index, name) \
output[index] = input[index] ^ X##name; \ X##name ^= output[index];
define unwrapOneInvert(X, input, output, index, name) \
output[index] = input[index] ^ X##name; \ X##name ^= output[index];
endif
define wrap(X, input, output, laneCount, trailingBits) \
if (laneCount < 16) { \
if (laneCount < 8) { \
if (laneCount < 4) { \
if (laneCount < 2) { \
if (laneCount < 1) { \
X##ba ^= trailingBits; \
} \
else { \
wrapOne(X, input, output, 0, ba) \
X##be ^= trailingBits; \
} \
} \
else { \
wrapOne(X, input, output, 0, ba) \
wrapOneInvert(X, input, output, 1, be) \
if (laneCount < 3) { \
X##bi ^= trailingBits; \
} \
else { \
wrapOneInvert(X, input, output, 2, bi) \
X##bo ^= trailingBits; \
} \
} \
} \
else { \
wrapOne(X, input, output, 0, ba) \
wrapOneInvert(X, input, output, 1, be) \
wrapOneInvert(X, input, output, 2, bi) \
wrapOne(X, input, output, 3, bo) \
if (laneCount < 6) { \
if (laneCount < 5) { \
X##bu ^= trailingBits; \
} \
else { \
wrapOne(X, input, output, 4, bu) \
X##ga ^= trailingBits; \
} \
} \
else { \
wrapOne(X, input, output, 4, bu) \
wrapOne(X, input, output, 5, ga) \
if (laneCount < 7) { \
X##ge ^= trailingBits; \
} \
else { \
wrapOne(X, input, output, 6, ge) \
X##gi ^= trailingBits; \
} \
} \
} \
} \
else { \
wrapOne(X, input, output, 0, ba) \
wrapOneInvert(X, input, output, 1, be) \
wrapOneInvert(X, input, output, 2, bi) \
wrapOne(X, input, output, 3, bo) \
wrapOne(X, input, output, 4, bu) \
wrapOne(X, input, output, 5, ga) \
wrapOne(X, input, output, 6, ge) \
wrapOne(X, input, output, 7, gi) \
if (laneCount < 12) { \
if (laneCount < 10) { \
if (laneCount < 9) { \
X##go ^= trailingBits; \
} \
else { \
wrapOneInvert(X, input, output, 8, go) \
X##gu ^= trailingBits; \
} \
} \
else { \
wrapOneInvert(X, input, output, 8, go) \
wrapOne(X, input, output, 9, gu) \
if (laneCount < 11) { \
X##ka ^= trailingBits; \
} \
else { \
wrapOne(X, input, output, 10, ka) \
X##ke ^= trailingBits; \
} \
} \
} \
else { \
wrapOneInvert(X, input, output, 8, go) \
wrapOne(X, input, output, 9, gu) \
wrapOne(X, input, output, 10, ka) \
wrapOne(X, input, output, 11, ke) \
if (laneCount < 14) { \
if (laneCount < 13) { \
X##ki ^= trailingBits; \
} \
else { \
wrapOneInvert(X, input, output, 12, ki) \
X##ko ^= trailingBits; \
} \
} \
else { \
wrapOneInvert(X, input, output, 12, ki) \
wrapOne(X, input, output, 13, ko) \
if (laneCount < 15) { \
X##ku ^= trailingBits; \
} \
else { \
wrapOne(X, input, output, 14, ku) \
X##ma ^= trailingBits; \
} \
} \
} \
} \
} \
else { \
wrapOne(X, input, output, 0, ba) \
wrapOneInvert(X, input, output, 1, be) \
wrapOneInvert(X, input, output, 2, bi) \
wrapOne(X, input, output, 3, bo) \
wrapOne(X, input, output, 4, bu) \
wrapOne(X, input, output, 5, ga) \
wrapOne(X, input, output, 6, ge) \
wrapOne(X, input, output, 7, gi) \
wrapOneInvert(X, input, output, 8, go) \
wrapOne(X, input, output, 9, gu) \
wrapOne(X, input, output, 10, ka) \
wrapOne(X, input, output, 11, ke) \
wrapOneInvert(X, input, output, 12, ki) \
wrapOne(X, input, output, 13, ko) \
wrapOne(X, input, output, 14, ku) \
wrapOne(X, input, output, 15, ma) \
if (laneCount < 24) { \
if (laneCount < 20) { \
if (laneCount < 18) { \
if (laneCount < 17) { \
X##me ^= trailingBits; \
} \
else { \
wrapOne(X, input, output, 16, me) \
X##mi ^= trailingBits; \
} \
} \
else { \
wrapOne(X, input, output, 16, me) \
wrapOneInvert(X, input, output, 17, mi) \
if (laneCount < 19) { \
X##mo ^= trailingBits; \
} \
else { \
wrapOne(X, input, output, 18, mo) \
X##mu ^= trailingBits; \
} \
} \
} \
else { \
wrapOne(X, input, output, 16, me) \
wrapOneInvert(X, input, output, 17, mi) \
wrapOne(X, input, output, 18, mo) \
wrapOne(X, input, output, 19, mu) \
if (laneCount < 22) { \
if (laneCount < 21) { \
X##sa ^= trailingBits; \
} \
else { \
wrapOneInvert(X, input, output, 20, sa) \
X##se ^= trailingBits; \
} \
} \
else { \
wrapOneInvert(X, input, output, 20, sa) \
wrapOne(X, input, output, 21, se) \
if (laneCount < 23) { \
X##si ^= trailingBits; \
} \
else { \
wrapOne(X, input, output, 22, si) \
X##so ^= trailingBits; \
} \
} \
} \
} \
else { \
wrapOne(X, input, output, 16, me) \
wrapOneInvert(X, input, output, 17, mi) \
wrapOne(X, input, output, 18, mo) \
wrapOne(X, input, output, 19, mu) \
wrapOneInvert(X, input, output, 20, sa) \
wrapOne(X, input, output, 21, se) \
wrapOne(X, input, output, 22, si) \
wrapOne(X, input, output, 23, so) \
if (laneCount < 25) { \
X##su ^= trailingBits; \
} \
else { \
wrapOne(X, input, output, 24, su) \
} \
} \
}
define unwrap(X, input, output, laneCount, trailingBits) \
if (laneCount < 16) { \
if (laneCount < 8) { \
if (laneCount < 4) { \
if (laneCount < 2) { \
if (laneCount < 1) { \
X##ba ^= trailingBits; \
} \
else { \
unwrapOne(X, input, output, 0, ba) \
X##be ^= trailingBits; \
} \
} \
else { \
unwrapOne(X, input, output, 0, ba) \
unwrapOneInvert(X, input, output, 1, be) \
if (laneCount < 3) { \
X##bi ^= trailingBits; \
} \
else { \
unwrapOneInvert(X, input, output, 2, bi) \
X##bo ^= trailingBits; \
} \
} \
} \
else { \
unwrapOne(X, input, output, 0, ba) \
unwrapOneInvert(X, input, output, 1, be) \
unwrapOneInvert(X, input, output, 2, bi) \
unwrapOne(X, input, output, 3, bo) \
if (laneCount < 6) { \
if (laneCount < 5) { \
X##bu ^= trailingBits; \
} \
else { \
unwrapOne(X, input, output, 4, bu) \
X##ga ^= trailingBits; \
} \
} \
else { \
unwrapOne(X, input, output, 4, bu) \
unwrapOne(X, input, output, 5, ga) \
if (laneCount < 7) { \
X##ge ^= trailingBits; \
} \
else { \
unwrapOne(X, input, output, 6, ge) \
X##gi ^= trailingBits; \
} \
} \
} \
} \
else { \
unwrapOne(X, input, output, 0, ba) \
unwrapOneInvert(X, input, output, 1, be) \
unwrapOneInvert(X, input, output, 2, bi) \
unwrapOne(X, input, output, 3, bo) \
unwrapOne(X, input, output, 4, bu) \
unwrapOne(X, input, output, 5, ga) \
unwrapOne(X, input, output, 6, ge) \
unwrapOne(X, input, output, 7, gi) \
if (laneCount < 12) { \
if (laneCount < 10) { \
if (laneCount < 9) { \
X##go ^= trailingBits; \
} \
else { \
unwrapOneInvert(X, input, output, 8, go) \
X##gu ^= trailingBits; \
} \
} \
else { \
unwrapOneInvert(X, input, output, 8, go) \
unwrapOne(X, input, output, 9, gu) \
if (laneCount < 11) { \
X##ka ^= trailingBits; \
} \
else { \
unwrapOne(X, input, output, 10, ka) \
X##ke ^= trailingBits; \
} \
} \
} \
else { \
unwrapOneInvert(X, input, output, 8, go) \
unwrapOne(X, input, output, 9, gu) \
unwrapOne(X, input, output, 10, ka) \
unwrapOne(X, input, output, 11, ke) \
if (laneCount < 14) { \
if (laneCount < 13) { \
X##ki ^= trailingBits; \
} \
else { \
unwrapOneInvert(X, input, output, 12, ki) \
X##ko ^= trailingBits; \
} \
} \
else { \
unwrapOneInvert(X, input, output, 12, ki) \
unwrapOne(X, input, output, 13, ko) \
if (laneCount < 15) { \
X##ku ^= trailingBits; \
} \
else { \
unwrapOne(X, input, output, 14, ku) \
X##ma ^= trailingBits; \
} \
} \
} \
} \
} \
else { \
unwrapOne(X, input, output, 0, ba) \
unwrapOneInvert(X, input, output, 1, be) \
unwrapOneInvert(X, input, output, 2, bi) \
unwrapOne(X, input, output, 3, bo) \
unwrapOne(X, input, output, 4, bu) \
unwrapOne(X, input, output, 5, ga) \
unwrapOne(X, input, output, 6, ge) \
unwrapOne(X, input, output, 7, gi) \
unwrapOneInvert(X, input, output, 8, go) \
unwrapOne(X, input, output, 9, gu) \
unwrapOne(X, input, output, 10, ka) \
unwrapOne(X, input, output, 11, ke) \
unwrapOneInvert(X, input, output, 12, ki) \
unwrapOne(X, input, output, 13, ko) \
unwrapOne(X, input, output, 14, ku) \
unwrapOne(X, input, output, 15, ma) \
if (laneCount < 24) { \
if (laneCount < 20) { \
if (laneCount < 18) { \
if (laneCount < 17) { \
X##me ^= trailingBits; \
} \
else { \
unwrapOne(X, input, output, 16, me) \
X##mi ^= trailingBits; \
} \
} \
else { \
unwrapOne(X, input, output, 16, me) \
unwrapOneInvert(X, input, output, 17, mi) \
if (laneCount < 19) { \
X##mo ^= trailingBits; \
} \
else { \
unwrapOne(X, input, output, 18, mo) \
X##mu ^= trailingBits; \
} \
} \
} \
else { \
unwrapOne(X, input, output, 16, me) \
unwrapOneInvert(X, input, output, 17, mi) \
unwrapOne(X, input, output, 18, mo) \
unwrapOne(X, input, output, 19, mu) \
if (laneCount < 22) { \
if (laneCount < 21) { \
X##sa ^= trailingBits; \
} \
else { \
unwrapOneInvert(X, input, output, 20, sa) \
X##se ^= trailingBits; \
} \
} \
else { \
unwrapOneInvert(X, input, output, 20, sa) \
unwrapOne(X, input, output, 21, se) \
if (laneCount < 23) { \
X##si ^= trailingBits; \
} \
else { \
unwrapOne(X, input, output, 22, si) \
X##so ^= trailingBits; \
} \
} \
} \
} \
else { \
unwrapOne(X, input, output, 16, me) \
unwrapOneInvert(X, input, output, 17, mi) \
unwrapOne(X, input, output, 18, mo) \
unwrapOne(X, input, output, 19, mu) \
unwrapOneInvert(X, input, output, 20, sa) \
unwrapOne(X, input, output, 21, se) \
unwrapOne(X, input, output, 22, si) \
unwrapOne(X, input, output, 23, so) \
if (laneCount < 25) { \
X##su ^= trailingBits; \
} \
else { \
unwrapOne(X, input, output, 24, su) \
} \
} \
}