rename target/linux/generic-2.6 to generic

[openwrt/staging/wigyori.git] / target / linux / generic / files / crypto / ocf / kirkwood / cesa / AES / mvAesAlg.c

/* rijndael-alg-ref.c   v2.0   August '99
 * Reference ANSI C code
 * authors: Paulo Barreto
 *          Vincent Rijmen, K.U.Leuven
 *
 * This code is placed in the public domain.
 */

#include "mvOs.h"

#include "mvAesAlg.h"

#include "mvAesBoxes.dat"


MV_U8 mul1(MV_U8 aa, MV_U8 bb);
void KeyAddition(MV_U8 a[4][MAXBC], MV_U8 rk[4][MAXBC], MV_U8 BC);
void ShiftRow128Enc(MV_U8 a[4][MAXBC]);
void ShiftRow128Dec(MV_U8 a[4][MAXBC]);
void Substitution(MV_U8 a[4][MAXBC], MV_U8 box[256]);
void MixColumn(MV_U8 a[4][MAXBC], MV_U8 rk[4][MAXBC]);
void InvMixColumn(MV_U8 a[4][MAXBC]);


#define mul(aa, bb) (mask[bb] & Alogtable[aa + Logtable[bb]])
                         
MV_U8 mul1(MV_U8 aa, MV_U8 bb)
{
    return mask[bb] & Alogtable[aa + Logtable[bb]];
}


void KeyAddition(MV_U8 a[4][MAXBC], MV_U8 rk[4][MAXBC], MV_U8 BC) 
{
        /* Exor corresponding text input and round key input bytes
         */
    ((MV_U32*)(&(a[0][0])))[0] ^= ((MV_U32*)(&(rk[0][0])))[0];
    ((MV_U32*)(&(a[1][0])))[0] ^= ((MV_U32*)(&(rk[1][0])))[0];
    ((MV_U32*)(&(a[2][0])))[0] ^= ((MV_U32*)(&(rk[2][0])))[0];
    ((MV_U32*)(&(a[3][0])))[0] ^= ((MV_U32*)(&(rk[3][0])))[0];

}

void ShiftRow128Enc(MV_U8 a[4][MAXBC]) {
        /* Row 0 remains unchanged
         * The other three rows are shifted a variable amount
         */
        MV_U8 tmp[MAXBC];
        
    tmp[0] = a[1][1];
    tmp[1] = a[1][2];
    tmp[2] = a[1][3];
    tmp[3] = a[1][0];

    ((MV_U32*)(&(a[1][0])))[0] = ((MV_U32*)(&(tmp[0])))[0];
     /*
    a[1][0] = tmp[0];
    a[1][1] = tmp[1];
    a[1][2] = tmp[2];
    a[1][3] = tmp[3];
       */
    tmp[0] = a[2][2];
    tmp[1] = a[2][3];
    tmp[2] = a[2][0];
    tmp[3] = a[2][1];

    ((MV_U32*)(&(a[2][0])))[0] = ((MV_U32*)(&(tmp[0])))[0];
      /*
    a[2][0] = tmp[0];
    a[2][1] = tmp[1];
    a[2][2] = tmp[2];
    a[2][3] = tmp[3];
    */
    tmp[0] = a[3][3];
    tmp[1] = a[3][0];
    tmp[2] = a[3][1];
    tmp[3] = a[3][2];

    ((MV_U32*)(&(a[3][0])))[0] = ((MV_U32*)(&(tmp[0])))[0];
    /*
    a[3][0] = tmp[0];
    a[3][1] = tmp[1];
    a[3][2] = tmp[2];
    a[3][3] = tmp[3];
    */
}  

void ShiftRow128Dec(MV_U8 a[4][MAXBC]) {
        /* Row 0 remains unchanged
         * The other three rows are shifted a variable amount
         */
        MV_U8 tmp[MAXBC];
        
    tmp[0] = a[1][3];
    tmp[1] = a[1][0];
    tmp[2] = a[1][1];
    tmp[3] = a[1][2];

    ((MV_U32*)(&(a[1][0])))[0] = ((MV_U32*)(&(tmp[0])))[0];
    /*
    a[1][0] = tmp[0];
    a[1][1] = tmp[1];
    a[1][2] = tmp[2];
    a[1][3] = tmp[3];
    */

    tmp[0] = a[2][2];
    tmp[1] = a[2][3];
    tmp[2] = a[2][0];
    tmp[3] = a[2][1];

    ((MV_U32*)(&(a[2][0])))[0] = ((MV_U32*)(&(tmp[0])))[0];
    /*
    a[2][0] = tmp[0];
    a[2][1] = tmp[1];
    a[2][2] = tmp[2];
    a[2][3] = tmp[3];
    */

    tmp[0] = a[3][1];
    tmp[1] = a[3][2];
    tmp[2] = a[3][3];
    tmp[3] = a[3][0];

    ((MV_U32*)(&(a[3][0])))[0] = ((MV_U32*)(&(tmp[0])))[0];
    /*
    a[3][0] = tmp[0];
    a[3][1] = tmp[1];
    a[3][2] = tmp[2];
    a[3][3] = tmp[3];
    */
}  

void Substitution(MV_U8 a[4][MAXBC], MV_U8 box[256]) {
        /* Replace every byte of the input by the byte at that place
         * in the nonlinear S-box
         */
        int i, j;
        
        for(i = 0; i < 4; i++)
                for(j = 0; j < 4; j++) a[i][j] = box[a[i][j]] ;
}
   
void MixColumn(MV_U8 a[4][MAXBC], MV_U8 rk[4][MAXBC]) {
        /* Mix the four bytes of every column in a linear way
         */
        MV_U8 b[4][MAXBC];
        int i, j;
                
        for(j = 0; j < 4; j++){
        b[0][j] = mul(25,a[0][j]) ^ mul(1,a[1][j]) ^ a[2][j] ^ a[3][j];
        b[1][j] = mul(25,a[1][j]) ^ mul(1,a[2][j]) ^ a[3][j] ^ a[0][j];
        b[2][j] = mul(25,a[2][j]) ^ mul(1,a[3][j]) ^ a[0][j] ^ a[1][j];
        b[3][j] = mul(25,a[3][j]) ^ mul(1,a[0][j]) ^ a[1][j] ^ a[2][j];
    }
        for(i = 0; i < 4; i++)
                /*for(j = 0; j < BC; j++) a[i][j] = b[i][j];*/
        ((MV_U32*)(&(a[i][0])))[0] = ((MV_U32*)(&(b[i][0])))[0] ^ ((MV_U32*)(&(rk[i][0])))[0];;
}

void InvMixColumn(MV_U8 a[4][MAXBC]) {
        /* Mix the four bytes of every column in a linear way
         * This is the opposite operation of Mixcolumn
         */
        MV_U8 b[4][MAXBC];
        int i, j;
        
        for(j = 0; j < 4; j++){
        b[0][j] = mul(223,a[0][j]) ^ mul(104,a[1][j]) ^ mul(238,a[2][j]) ^ mul(199,a[3][j]);
        b[1][j] = mul(223,a[1][j]) ^ mul(104,a[2][j]) ^ mul(238,a[3][j]) ^ mul(199,a[0][j]);
        b[2][j] = mul(223,a[2][j]) ^ mul(104,a[3][j]) ^ mul(238,a[0][j]) ^ mul(199,a[1][j]);
        b[3][j] = mul(223,a[3][j]) ^ mul(104,a[0][j]) ^ mul(238,a[1][j]) ^ mul(199,a[2][j]);
    }
        for(i = 0; i < 4; i++)
                /*for(j = 0; j < BC; j++) a[i][j] = b[i][j];*/
        ((MV_U32*)(&(a[i][0])))[0] = ((MV_U32*)(&(b[i][0])))[0];
}

int rijndaelKeySched (MV_U8 k[4][MAXKC], int keyBits, int blockBits, MV_U8 W[MAXROUNDS+1][4][MAXBC]) 
{
        /* Calculate the necessary round keys
         * The number of calculations depends on keyBits and blockBits
         */
        int KC, BC, ROUNDS;
        int i, j, t, rconpointer = 0;
        MV_U8 tk[4][MAXKC];   

        switch (keyBits) {
        case 128: KC = 4; break;
        case 192: KC = 6; break;
        case 256: KC = 8; break;
        default : return (-1);
        }

        switch (blockBits) {
        case 128: BC = 4; break;
        case 192: BC = 6; break;
        case 256: BC = 8; break;
        default : return (-2);
        }

        switch (keyBits >= blockBits ? keyBits : blockBits) {
        case 128: ROUNDS = 10; break;
        case 192: ROUNDS = 12; break;
        case 256: ROUNDS = 14; break;
        default : return (-3); /* this cannot happen */
        }

        
        for(j = 0; j < KC; j++)
                for(i = 0; i < 4; i++)
                        tk[i][j] = k[i][j];
        t = 0;
        /* copy values into round key array */
        for(j = 0; (j < KC) && (t < (ROUNDS+1)*BC); j++, t++)
                for(i = 0; i < 4; i++) W[t / BC][i][t % BC] = tk[i][j];
                
        while (t < (ROUNDS+1)*BC) { /* while not enough round key material calculated */
                /* calculate new values */
                for(i = 0; i < 4; i++)
                        tk[i][0] ^= S[tk[(i+1)%4][KC-1]];
                tk[0][0] ^= rcon[rconpointer++];

                if (KC != 8)
                        for(j = 1; j < KC; j++)
                                for(i = 0; i < 4; i++) tk[i][j] ^= tk[i][j-1];
                else {
                        for(j = 1; j < KC/2; j++)
                                for(i = 0; i < 4; i++) tk[i][j] ^= tk[i][j-1];
                        for(i = 0; i < 4; i++) tk[i][KC/2] ^= S[tk[i][KC/2 - 1]];
                        for(j = KC/2 + 1; j < KC; j++)
                                for(i = 0; i < 4; i++) tk[i][j] ^= tk[i][j-1];
        }
        /* copy values into round key array */
        for(j = 0; (j < KC) && (t < (ROUNDS+1)*BC); j++, t++)
                for(i = 0; i < 4; i++) W[t / BC][i][t % BC] = tk[i][j];
        }               

        return 0;
}
      
        

int rijndaelEncrypt128(MV_U8 a[4][MAXBC], MV_U8 rk[MAXROUNDS+1][4][MAXBC], int rounds)
{
        /* Encryption of one block. 
         */
        int r, BC, ROUNDS;

    BC = 4;
    ROUNDS = rounds;

        /* begin with a key addition
         */

        KeyAddition(a,rk[0],BC); 

    /* ROUNDS-1 ordinary rounds
         */
        for(r = 1; r < ROUNDS; r++) {
                Substitution(a,S);
                ShiftRow128Enc(a);
                MixColumn(a, rk[r]);
                /*KeyAddition(a,rk[r],BC);*/
        }
        
        /* Last round is special: there is no MixColumn
         */
        Substitution(a,S);
        ShiftRow128Enc(a);
        KeyAddition(a,rk[ROUNDS],BC);

        return 0;
}   


int rijndaelDecrypt128(MV_U8 a[4][MAXBC], MV_U8 rk[MAXROUNDS+1][4][MAXBC], int rounds)
{
        int r, BC, ROUNDS;
        
    BC = 4;
    ROUNDS = rounds;

        /* To decrypt: apply the inverse operations of the encrypt routine,
         *             in opposite order
         * 
         * (KeyAddition is an involution: it 's equal to its inverse)
         * (the inverse of Substitution with table S is Substitution with the inverse table of S)
         * (the inverse of Shiftrow is Shiftrow over a suitable distance)
         */

        /* First the special round:
         *   without InvMixColumn
         *   with extra KeyAddition
         */
        KeyAddition(a,rk[ROUNDS],BC);
    ShiftRow128Dec(a);               
        Substitution(a,Si);
        
        /* ROUNDS-1 ordinary rounds
         */
        for(r = ROUNDS-1; r > 0; r--) {
                KeyAddition(a,rk[r],BC);
                InvMixColumn(a);      
                ShiftRow128Dec(a);               
                Substitution(a,Si);

        }
        
        /* End with the extra key addition
         */
        
        KeyAddition(a,rk[0],BC);    

        return 0;
}