skinny-aastha.java

import java.io.*;
import java.util.Random;
public class SKINNY { 

    int versions[][]={{64,64,32},{64,128,36},{64,192,40},{128,128,40},{128,256,48},{128,384,56}};
    char sbox_4[] = {12,6,9,0,1,10,2,11,3,8,5,13,4,14,7,15};
    char sbox_4_inv[] = {3,4,6,8,12,10,1,14,9,2,5,7,0,11,13,15};
    char sbox_8[] = {0x65 , 0x4c , 0x6a , 0x42 , 0x4b , 0x63 , 0x43 , 0x6b , 0x55 , 0x75 , 0x5a , 0x7a , 0x53 , 0x73 , 0x5b , 0x7b ,0x35 , 0x8c , 0x3a , 0x81 , 0x89 , 0x33 , 0x80 , 0x3b , 0x95 , 0x25 , 0x98 , 0x2a , 0x90 , 0x23 , 0x99 , 0x2b ,0xe5 , 0xcc , 0xe8 , 0xc1 , 0xc9 , 0xe0 , 0xc0 , 0xe9 , 0xd5 , 0xf5 , 0xd8 , 0xf8 , 0xd0 , 0xf0 , 0xd9 , 0xf9 ,0xa5 , 0x1c , 0xa8 , 0x12 , 0x1b , 0xa0 , 0x13 , 0xa9 , 0x05 , 0xb5 , 0x0a , 0xb8 , 0x03 , 0xb0 , 0x0b , 0xb9 ,0x32 , 0x88 , 0x3c , 0x85 , 0x8d , 0x34 , 0x84 , 0x3d , 0x91 , 0x22 , 0x9c , 0x2c , 0x94 , 0x24 , 0x9d , 0x2d ,0x62 , 0x4a , 0x6c , 0x45 , 0x4d , 0x64 , 0x44 , 0x6d , 0x52 , 0x72 , 0x5c , 0x7c , 0x54 , 0x74 , 0x5d , 0x7d ,0xa1 , 0x1a , 0xac , 0x15 , 0x1d , 0xa4 , 0x14 , 0xad , 0x02 , 0xb1 , 0x0c , 0xbc , 0x04 , 0xb4 , 0x0d , 0xbd ,0xe1 , 0xc8 , 0xec , 0xc5 , 0xcd , 0xe4 , 0xc4 , 0xed , 0xd1 , 0xf1 , 0xdc , 0xfc , 0xd4 , 0xf4 , 0xdd , 0xfd ,0x36 , 0x8e , 0x38 , 0x82 , 0x8b , 0x30 , 0x83 , 0x39 , 0x96 , 0x26 , 0x9a , 0x28 , 0x93 , 0x20 , 0x9b , 0x29 ,0x66 , 0x4e , 0x68 , 0x41 , 0x49 , 0x60 , 0x40 , 0x69 , 0x56 , 0x76 , 0x58 , 0x78 , 0x50 , 0x70 , 0x59 , 0x79 ,0xa6 , 0x1e , 0xaa , 0x11 , 0x19 , 0xa3 , 0x10 , 0xab , 0x06 , 0xb6 , 0x08 , 0xba , 0x00 , 0xb3 , 0x09 , 0xbb ,0xe6 , 0xce , 0xea , 0xc2 , 0xcb , 0xe3 , 0xc3 , 0xeb , 0xd6 , 0xf6 , 0xda , 0xfa , 0xd3 , 0xf3 , 0xdb , 0xfb ,0x31 , 0x8a , 0x3e , 0x86 , 0x8f , 0x37 , 0x87 , 0x3f , 0x92 , 0x21 , 0x9e , 0x2e , 0x97 , 0x27 , 0x9f , 0x2f ,0x61 , 0x48 , 0x6e , 0x46 , 0x4f , 0x67 , 0x47 , 0x6f , 0x51 , 0x71 , 0x5e , 0x7e , 0x57 , 0x77 , 0x5f , 0x7f ,0xa2 , 0x18 , 0xae , 0x16 , 0x1f , 0xa7 , 0x17 , 0xaf , 0x01 , 0xb2 , 0x0e , 0xbe , 0x07 , 0xb7 , 0x0f , 0xbf ,0xe2 , 0xca , 0xee , 0xc6 , 0xcf , 0xe7 , 0xc7 , 0xef , 0xd2 , 0xf2 , 0xde , 0xfe , 0xd7 , 0xf7 , 0xdf , 0xff};
    char sbox_8_inv[] = {0xac , 0xe8 , 0x68 , 0x3c , 0x6c , 0x38 , 0xa8 , 0xec , 0xaa , 0xae , 0x3a , 0x3e , 0x6a , 0x6e , 0xea , 0xee ,0xa6 , 0xa3 , 0x33 , 0x36 , 0x66 , 0x63 , 0xe3 , 0xe6 , 0xe1 , 0xa4 , 0x61 , 0x34 , 0x31 , 0x64 , 0xa1 , 0xe4 ,0x8d , 0xc9 , 0x49 , 0x1d , 0x4d , 0x19 , 0x89 , 0xcd , 0x8b , 0x8f , 0x1b , 0x1f , 0x4b , 0x4f , 0xcb , 0xcf ,0x85 , 0xc0 , 0x40 , 0x15 , 0x45 , 0x10 , 0x80 , 0xc5 , 0x82 , 0x87 , 0x12 , 0x17 , 0x42 , 0x47 , 0xc2 , 0xc7 ,0x96 , 0x93 , 0x03 , 0x06 , 0x56 , 0x53 , 0xd3 , 0xd6 , 0xd1 , 0x94 , 0x51 , 0x04 , 0x01 , 0x54 , 0x91 , 0xd4 ,0x9c , 0xd8 , 0x58 , 0x0c , 0x5c , 0x08 , 0x98 , 0xdc , 0x9a , 0x9e , 0x0a , 0x0e , 0x5a , 0x5e , 0xda , 0xde ,0x95 , 0xd0 , 0x50 , 0x05 , 0x55 , 0x00 , 0x90 , 0xd5 , 0x92 , 0x97 , 0x02 , 0x07 , 0x52 , 0x57 , 0xd2 , 0xd7 ,0x9d , 0xd9 , 0x59 , 0x0d , 0x5d , 0x09 , 0x99 , 0xdd , 0x9b , 0x9f , 0x0b , 0x0f , 0x5b , 0x5f , 0xdb , 0xdf ,0x16 , 0x13 , 0x83 , 0x86 , 0x46 , 0x43 , 0xc3 , 0xc6 , 0x41 , 0x14 , 0xc1 , 0x84 , 0x11 , 0x44 , 0x81 , 0xc4 ,0x1c , 0x48 , 0xc8 , 0x8c , 0x4c , 0x18 , 0x88 , 0xcc , 0x1a , 0x1e , 0x8a , 0x8e , 0x4a , 0x4e , 0xca , 0xce ,0x35 , 0x60 , 0xe0 , 0xa5 , 0x65 , 0x30 , 0xa0 , 0xe5 , 0x32 , 0x37 , 0xa2 , 0xa7 , 0x62 , 0x67 , 0xe2 , 0xe7 ,0x3d , 0x69 , 0xe9 , 0xad , 0x6d , 0x39 , 0xa9 , 0xed , 0x3b , 0x3f , 0xab , 0xaf , 0x6b , 0x6f , 0xeb , 0xef ,0x26 , 0x23 , 0xb3 , 0xb6 , 0x76 , 0x73 , 0xf3 , 0xf6 , 0x71 , 0x24 , 0xf1 , 0xb4 , 0x21 , 0x74 , 0xb1 , 0xf4 ,0x2c , 0x78 , 0xf8 , 0xbc , 0x7c , 0x28 , 0xb8 , 0xfc , 0x2a , 0x2e , 0xba , 0xbe , 0x7a , 0x7e , 0xfa , 0xfe ,0x25 , 0x70 , 0xf0 , 0xb5 , 0x75 , 0x20 , 0xb0 , 0xf5 , 0x22 , 0x27 , 0xb2 , 0xb7 , 0x72 , 0x77 , 0xf2 , 0xf7 ,0x2d , 0x79 , 0xf9 , 0xbd , 0x7d , 0x29 , 0xb9 , 0xfd , 0x2b , 0x2f , 0xbb , 0xbf , 0x7b , 0x7f , 0xfb , 0xff};
    char P[] = {0,1,2,3,7,4,5,6,10,11,8,9,13,14,15,12};
    char P_inv[] = {0,1,2,3,5,6,7,4,10,11,8,9,15,12,13,14};
    char TWEAKEY_P[] = {9,15,8,13,10,14,12,11,0,1,2,3,4,5,6,7};
    char TWEAKEY_P_inv[] = {8,9,10,11,12,13,14,15,2,0,4,7,6,3,5,1};

    // round constants
    char RC[] = {
            0x01, 0x03, 0x07, 0x0F, 0x1F, 0x3E, 0x3D, 0x3B, 0x37, 0x2F,
            0x1E, 0x3C, 0x39, 0x33, 0x27, 0x0E, 0x1D, 0x3A, 0x35, 0x2B,
            0x16, 0x2C, 0x18, 0x30, 0x21, 0x02, 0x05, 0x0B, 0x17, 0x2E,
            0x1C, 0x38, 0x31, 0x23, 0x06, 0x0D, 0x1B, 0x36, 0x2D, 0x1A,
            0x34, 0x29, 0x12, 0x24, 0x08, 0x11, 0x22, 0x04, 0x09, 0x13,
            0x26, 0x0c, 0x19, 0x32, 0x25, 0x0a, 0x15, 0x2a, 0x14, 0x28,
            0x10, 0x20 };

    void display_matrix(char state[][], int ver)
    {
        int i;
        char input[];
    
        if (versions[ver][0]==64)
        {
            for(i = 0; i < 8; i++) input[i] = ((state[(2*i)>>2][(2*i)&0x3] & 0xF) << 4) | (state[(2*i+1)>>2][(2*i+1)&0x3] & 0xF);
                for(i = 0; i < 8; i++) System.out.printf("%02x", input[i]);
        }
        else if (versions[ver][0]==128)
        {
            for(i = 0; i < 16; i++) input[i] = state[i>>2][i&0x3] & 0xFF;
            for(i = 0; i < 16; i++) System.out.printf("%02x", input[i]);
        }
    
    }

    void display_cipher_state(char state[][], char keyCells[][][], int ver)
    {
        int k;

        System.out.printf("S = ");
        display_matrix(state,ver);
        for(k = 0; k <(int)(versions[ver][1]/versions[ver][0]); k++)
        {
            System.out.printf(" - TK%i = ",k+1); 
            display_matrix(keyCells[k],ver);
        }
    }

        // Extract and apply the subtweakey to the internal state (must be the two top rows XORed together), then update the tweakey state
    void AddKey(char state[][], char keyCells[][][], int ver)
    {
        int i, j, k;
        char pos;
        char keyCells_tmp[][][];

        // apply the subtweakey to the internal state
        for(i = 0; i <= 1; i++)
        {
            for(j = 0; j < 4; j++)
            {
                state[i][j] ^= keyCells[0][i][j];
                if (2*versions[ver][0]==versions[ver][1])
                    state[i][j] ^= keyCells[1][i][j];
                else if (3*versions[ver][0]==versions[ver][1])
                state[i][j] ^= keyCells[1][i][j] ^ keyCells[2][i][j];
            }
        }

        // update the subtweakey states with the permutation
        for(k = 0; k <(int)(versions[ver][1]/versions[ver][0]); k++){
            for(i = 0; i < 4; i++){
                for(j = 0; j < 4; j++){
                    //application of the TWEAKEY permutation
                    pos=TWEAKEY_P[j+4*i];
                    keyCells_tmp[k][i][j]=keyCells[k][pos>>2][pos&0x3];
                }
            }
        }

        // update the subtweakey states with the LFSRs
        for(k = 0; k <(int)(versions[ver][1]/versions[ver][0]); k++){
            for(i = 0; i <= 1; i++){
                for(j = 0; j < 4; j++){
                    //application of LFSRs for TK updates
                    if (k==1)
                    {
                        if (versions[ver][0]==64)
                            keyCells_tmp[k][i][j]=((keyCells_tmp[k][i][j]<<1)&0xE)^((keyCells_tmp[k][i][j]>>3)&0x1)^((keyCells_tmp[k][i][j]>>2)&0x1);
                        else
                            keyCells_tmp[k][i][j]=((keyCells_tmp[k][i][j]<<1)&0xFE)^((keyCells_tmp[k][i][j]>>7)&0x01)^((keyCells_tmp[k][i][j]>>5)&0x01);
                    }
                    else if (k==2)
                    {
                        if (versions[ver][0]==64)
                            keyCells_tmp[k][i][j]=((keyCells_tmp[k][i][j]>>1)&0x7)^((keyCells_tmp[k][i][j])&0x8)^((keyCells_tmp[k][i][j]<<3)&0x8);
                        else
                            keyCells_tmp[k][i][j]=((keyCells_tmp[k][i][j]>>1)&0x7F)^((keyCells_tmp[k][i][j]<<7)&0x80)^((keyCells_tmp[k][i][j]<<1)&0x80);
                    }
                }
            }
        }

        for(k = 0; k <(int)(versions[ver][1]/versions[ver][0]); k++){
            for(i = 0; i < 4; i++){
                for(j = 0; j < 4; j++){
                    keyCells[k][i][j]=keyCells_tmp[k][i][j];
                }
            }
        }
    }


    // Extract and apply the subtweakey to the internal state (must be the two top rows XORed together), then update the tweakey state (inverse function}
    void AddKey_inv(char state[][], char keyCells[][][], int ver)
    {
        int i, j, k;
        char pos;
        char keyCells_tmp[][][];

        // update the subtweakey states with the permutation
        for(k = 0; k <(int)(versions[ver][1]/versions[ver][0]); k++){
            for(i = 0; i < 4; i++){
                for(j = 0; j < 4; j++){
                    //application of the inverse TWEAKEY permutation
                    pos=TWEAKEY_P_inv[j+4*i];
                    keyCells_tmp[k][i][j]=keyCells[k][pos>>2][pos&0x3];
                }
            }
        }

        // update the subtweakey states with the LFSRs
        for(k = 0; k <(int)(versions[ver][1]/versions[ver][0]); k++){
            for(i = 2; i <= 3; i++){
                for(j = 0; j < 4; j++){
                    //application of inverse LFSRs for TK updates
                    if (k==1)
                    {
                        if (versions[ver][0]==64)
                            keyCells_tmp[k][i][j]=((keyCells_tmp[k][i][j]>>1)&0x7)^((keyCells_tmp[k][i][j]<<3)&0x8)^((keyCells_tmp[k][i][j])&0x8);
                        else
                            keyCells_tmp[k][i][j]=((keyCells_tmp[k][i][j]>>1)&0x7F)^((keyCells_tmp[k][i][j]<<7)&0x80)^((keyCells_tmp[k][i][j]<<1)&0x80);
                    }
                    else if (k==2)
                    {
                        if (versions[ver][0]==64)
                            keyCells_tmp[k][i][j]=((keyCells_tmp[k][i][j]<<1)&0xE)^((keyCells_tmp[k][i][j]>>3)&0x1)^((keyCells_tmp[k][i][j]>>2)&0x1);
                        else
                            keyCells_tmp[k][i][j]=((keyCells_tmp[k][i][j]<<1)&0xFE)^((keyCells_tmp[k][i][j]>>7)&0x01)^((keyCells_tmp[k][i][j]>>5)&0x01);
                    }
                }
            }
        }

        for(k = 0; k <(int)(versions[ver][1]/versions[ver][0]); k++){
            for(i = 0; i < 4; i++){
                for(j = 0; j < 4; j++){
                    keyCells[k][i][j]=keyCells_tmp[k][i][j];
                }
            }
        }


        // apply the subtweakey to the internal state
        for(i = 0; i <= 1; i++)
        {
            for(j = 0; j < 4; j++)
            {
                state[i][j] ^= keyCells[0][i][j];
                if (2*versions[ver][0]==versions[ver][1])
                    state[i][j] ^= keyCells[1][i][j];
                else if (3*versions[ver][0]==versions[ver][1])
                    state[i][j] ^= keyCells[1][i][j] ^ keyCells[2][i][j];
            }
        }
    }

    // Apply the constants: using a LFSR counter on 6 bits, we XOR the 6 bits to the first 6 bits of the internal state
    void AddConstants(char state[][], int r)
    {
        state[0][0] ^= (RC[r] & 0xf);
        state[1][0] ^= ((RC[r]>>4) & 0x3);
        state[2][0] ^= 0x2;
    }

    // apply the 4-bit Sbox
    void SubCell4(char state[][])
    {
        int i,j;
        for(i = 0; i < 4; i++)
            for(j = 0; j <  4; j++)
                state[i][j] = sbox_4[state[i][j]];
    }

    // apply the 4-bit inverse Sbox
    void SubCell4_inv(char state[][])
    {
        int i,j;
        for(i = 0; i < 4; i++)
            for(j = 0; j <  4; j++)
                state[i][j] = sbox_4_inv[state[i][j]];
    }

    // apply the 8-bit Sbox
    void SubCell8(char state[4][4])
    {
        int i,j;
        for(i = 0; i < 4; i++)
            for(j = 0; j <  4; j++)
                state[i][j] = sbox_8[state[i][j]];
    }

    // apply the 8-bit inverse Sbox
    void SubCell8_inv(char state[][])
    {
        int i,j;
        for(i = 0; i < 4; i++)
            for(j = 0; j <  4; j++)
                state[i][j] = sbox_8_inv[state[i][j]];
    }

    // Apply the ShiftRows function
    void ShiftRows(char state[][])
    {
        int i, j, pos;

        char state_tmp[][];
        for(i = 0; i < 4; i++)
        {
            for(j = 0; j < 4; j++)
            {
                //application of the ShiftRows permutation
                pos=P[j+4*i];
                state_tmp[i][j]=state[pos>>2][pos&0x3];
            }
        }

        for(i = 0; i < 4; i++)
        {
            for(j = 0; j < 4; j++)
            {
                state[i][j]=state_tmp[i][j];
            }
        }
    }
    // Apply the inverse ShiftRows function
    void ShiftRows_inv(char state[][])
    {
        int i, j, pos;

        char state_tmp[][];
        for(i = 0; i < 4; i++)
        {
            for(j = 0; j < 4; j++)
            {
                //application of the inverse ShiftRows permutation
                pos=P_inv[j+4*i];
                state_tmp[i][j]=state[pos>>2][pos&0x3];
            }
        }

        for(i = 0; i < 4; i++)
        {
            for(j = 0; j < 4; j++)
            {
                state[i][j]=state_tmp[i][j];
            }
        }
    }

    // Apply the linear diffusion matrix
//M =
//1 0 1 1
//1 0 0 0
//0 1 1 0
//1 0 1 0
void MixColumn(char state[][])
{
	int j;
    char temp;

	for(j = 0; j < 4; j++){
        state[1][j]^=state[2][j];
        state[2][j]^=state[0][j];
        state[3][j]^=state[2][j];

        temp=state[3][j];
        state[3][j]=state[2][j];
        state[2][j]=state[1][j];
        state[1][j]=state[0][j];
        state[0][j]=temp;
	}
}

    // Apply the inverse linear diffusion matrix
    void MixColumn_inv(char state[][])
    {
        int j;
        char temp;

        for(j = 0; j < 4; j++){
            temp=state[3][j];
            state[3][j]=state[0][j];
            state[0][j]=state[1][j];
            state[1][j]=state[2][j];
            state[2][j]=temp;

            state[3][j]^=state[2][j];
            state[2][j]^=state[0][j];
            state[1][j]^=state[2][j];
        }
    }
// encryption function of Skinny
public static void dec(byte[] input_U, byte[] userkey_U, int ver) {
    byte[][] state_U = new byte[4][4];
    byte[][] dummy_U = new byte[4][4];
    String8 keyCells_U = new String8(3, 4, 4);
	keyCells_U.fill(0, 48, (byte)0);


    for(int i = 0; i < 16; i++) {
        if(versions[ver][0] == 64) {
            if((i & 1) != 0) {
                state_U[i >> 2][i & 0x3] = (byte)(Byte.toUnsignedInt(input_U[i >> 1]) & 0xF);
                keyCells_U[0][i >> 2][i & 0x3] = (byte)(Byte.toUnsignedInt(userkey_U[i >> 1]) & 0xF);
                if(versions[ver][1] >= 128) {
                    keyCells_U[1][i >> 2][i & 0x3] = (byte)(Byte.toUnsignedInt(userkey_U[i + 16 >> 1]) & 0xF);
                }
                if(versions[ver][1] >= 192) {
                    keyCells_U[2][i >> 2][i & 0x3] = (byte)(Byte.toUnsignedInt(userkey_U[i + 32 >> 1]) & 0xF);
                }
            }

            else {
                state_U[i >> 2][i & 0x3] = (byte)(Byte.toUnsignedInt(input_U[i >> 1]) >> 4 & 0xF);
                keyCells_U[0][i >> 2][i & 0x3] = (byte)(Byte.toUnsignedInt(userkey_U[i >> 1]) >> 4 & 0xF);
                if(versions[ver][1] >= 128) {
                    keyCells_U[1][i >> 2][i & 0x3] = (byte)(Byte.toUnsignedInt(userkey_U[i + 16 >> 1]) >> 4 & 0xF);
                }
                if(versions[ver][1] >= 192) {
                    keyCells_U[2][i >> 2][i & 0x3] = (byte)(Byte.toUnsignedInt(userkey_U[i + 32 >> 1]) >> 4 & 0xF);
                }
            }
        }

            else if(versions[ver][0] == 128) {
                state_U[i >> 2][i & 0x3] = (byte)(Byte.toUnsignedInt(input_U[i]) & 0xFF);

                keyCells_U[0][i >> 2][i & 0x3] = (byte)(Byte.toUnsignedInt(userkey_U[i]) & 0xFF);
                if(versions[ver][1] >= 256) {
                    keyCells_U[1][i >> 2][i & 0x3] = (byte)(Byte.toUnsignedInt(userkey_U[i + 16]) & 0xFF);
                }
                if(versions[ver][1] >= 384) {
                    keyCells_U[2][i >> 2][i & 0x3] = (byte)(Byte.toUnsignedInt(userkey_U[i + 32]) & 0xFF);
                }
            }
        }

            for(i = versions[ver][2]-1; i >=0 ; i--){
                AddKey(dummy, keyCells, ver);
            }
            
            System.out.printf("DEC - initial state:                     ");
            display_cipher_state(state,keyCells,ver);
            System.out.printf("\n");

            for(i = versions[ver][2]-1; i >=0 ; i--){
                MixColumn_inv(state);
                    //#ifdef DEBUG
                    System.out.printf("DEC - round %.2i - after MixColumn_inv:    ",i);
                    display_cipher_state(state,keyCells,ver);
                    printf("\n");
                    //#endif
                ShiftRows_inv(state);
                    //#ifdef DEBUG
                    System.out.printf("DEC - round %.2i - after ShiftRows_inv:    ",i);
                    display_cipher_state(state,keyCells,ver);
                    System.out.printf("\n");
                    //#endif
                AddKey_inv(state, keyCells, ver);
                    //#ifdef DEBUG
                    System.out.printf("DEC - round %.2i - after AddKey_inv:       ",i);
                    display_cipher_state(state,keyCells,ver);
                    System.out.printf("\n");
                    //#endif
                AddConstants(state, i);
                    //#ifdef DEBUG
                    System.out.printf("DEC - round %.2i - after AddConstants_inv: ",i);
                    display_cipher_state(state,keyCells,ver);
                    System.out.printf("\n");
                    //#endif
                if (versions[ver][0]==64)
                    SubCell4_inv(state);
                else
                    SubCell8_inv(state);
                    //#ifdef DEBUG
                    System.out.printf("DEC - round %.2i - after SubCell_inv:      ",i);
                    display_cipher_state(state,keyCells,ver);
                    System.out.printf("\n");
                    //#endif
            }
           // #ifdef DEBUG
            System.out.printf("DEC - final state:                       ");
            display_cipher_state(state,keyCells,ver);
            System.out.printf("\n");
           // #endif

           if(versions[ver][0] == 64) {
			for(int i = 0; i < 8; i++) {
				input_U[i] = (byte)((Byte.toUnsignedInt(state_U[2 * i >> 2][2 * i & 0x3]) & 0xF) << 4 | Byte.toUnsignedInt(state_U[2 * i + 1 >> 2][2 * i + 1 & 0x3]) & 0xF);
			    }
            } 
            else if(versions[ver][0] == 128) {
			    for(int i = 0; i < 16; i++) {
				input_U[i] = (byte)(Byte.toUnsignedInt(state_U[i >> 2][i & 0x3]) & 0xFF);
			    }
		    }
        }

public static void enc(byte[] input_U, byte[] userkey_U, int ver) {
    byte[][] state_U = new byte[4][4];
    byte[][][] keyCells_U = new byte[3][4][4];


    for(int i = 0; i < 16; i++) {
        if(versions[ver][0] == 64) {
            if((i & 1) != 0) {
                state_U[i >> 2][i & 0x3] = (byte)(Byte.toUnsignedInt(input_U[i >> 1]) & 0xF);
                keyCells_U[0][i >> 2][i & 0x3] = (byte)(Byte.toUnsignedInt(userkey_U[i >> 1]) & 0xF);
                if(versions[ver][1] >= 128) {
                    keyCells_U[1][i >> 2][i & 0x3] = (byte)(Byte.toUnsignedInt(userkey_U[i + 16 >> 1]) & 0xF);
                }
                if(versions[ver][1] >= 192) {
                    keyCells_U[2][i >> 2][i & 0x3] = (byte)(Byte.toUnsignedInt(userkey_U[i + 32 >> 1]) & 0xF);
                }
            }
        
            else
            {
                state_U[i >> 2][i & 0x3] = (byte)(Byte.toUnsignedInt(input_U[i >> 1]) >> 4 & 0xF);
				keyCells_U[0][i >> 2][i & 0x3] = (byte)(Byte.toUnsignedInt(userkey_U[i >> 1]) >> 4 & 0xF);
					if(versions[ver][1] >= 128) {
						keyCells_U[1][i >> 2][i & 0x3] = (byte)(Byte.toUnsignedInt(userkey_U[i + 16 >> 1]) >> 4 & 0xF);
					}
					if(versions[ver][1] >= 192) {
						keyCells_U[2][i >> 2][i & 0x3] = (byte)(Byte.toUnsignedInt(userkey_U[i + 32 >> 1]) >> 4 & 0xF);
					}
            }
        }

        else if (versions[ver][0]==128){
        state_U[i >> 2][i & 0x3] = (byte)(Byte.toUnsignedInt(input_U[i]) & 0xFF);
        keyCells_U[0][i >> 2][i & 0x3] = (byte)(Byte.toUnsignedInt(userkey_U[i]) & 0xFF);

            if(versions[ver][1] >= 256) {
                keyCells_U[1][i >> 2][i & 0x3] = (byte)(Byte.toUnsignedInt(userkey_U[i + 16]) & 0xFF);
            }

            if(versions[ver][1] >= 384) {
                keyCells_U[2][i >> 2][i & 0x3] = (byte)(Byte.toUnsignedInt(userkey_U[i + 32]) & 0xFF);
            }
        }
    }
    //#ifdef DEBUG
    System.out.printf("ENC - initial state:                 ");
    display_cipher_state(state,keyCells,ver);
    System.out.printf("\n");
    //#endif

	
	for(i = 0; i < versions[ver][2]; i++){
        if (versions[ver][0]==64)
            SubCell4(state);
        else
            SubCell8(state);
            //#ifdef DEBUG
            System.out.printf("ENC - round %.2i - after SubCell:      ",i);
            display_cipher_state(state,keyCells,ver);
            System.out.printf("\n");
            //#endif
        AddConstants(state, i);
           // #ifdef DEBUG
           System.out.printf("ENC - round %.2i - after AddConstants: ",i);
           display_cipher_state(state,keyCells,ver);
           System.out.printf("\n");
           // #endif
        AddKey(state, keyCells, ver);
           // #ifdef DEBUG
           System.out.printf("ENC - round %.2i - after AddKey:       ",i);
           display_cipher_state(state,keyCells,ver);
           System.out.printf("\n");
            //#endif
        ShiftRows(state);
           // #ifdef DEBUG
           System.out.printf("ENC - round %.2i - after ShiftRows:    ",i);
           display_cipher_state(state,keyCells,ver);
           System.out.printf("\n");
           // #endif
        MixColumn(state);
            //#ifdef DEBUG
            System.out.printf("ENC - round %.2i - after MixColumn:    ",i);
            display_cipher_state(state,keyCells,ver);
            System.out.printf("\n");
           // #endif
	}  //The last subtweakey should not be added
	//#ifdef DEBUG
    System.out.printf("ENC - final state:                   ");
    display_cipher_state(state,keyCells,ver);
    System.out.printf("\n");
    //#endif

    if(versions[ver][0] == 64) {
        for(i = 0; i < 8; i++) {
            input_U[i] = (byte)((Byte.toUnsignedInt(state_U[2 * i >> 2][2 * i & 0x3]) & 0xF) << 4 | Byte.toUnsignedInt(state_U[2 * i + 1 >> 2][2 * i + 1 & 0x3]) & 0xF);
        }
    } 
    else if(versions[ver][0] == 128) {
        for(i = 0; i < 16; i++) {
            input_U[i] = (byte)(Byte.toUnsignedInt(state_U[i >> 2][i & 0x3]) & 0xFF);
        }
    }
}

        // generate test vectors for all the versions of Skinny
    void TestVectors(int ver)
    {
        char p[];
        char c[];
        char k[];
        int n;

        int i;
        for(i = 0; i < (versions[ver][0]>>3); i++) c[i] = p[i] = (char)Math.random() & 0xff;
        for(i = 0; i < (versions[ver][1]>>3); i++) k[i] = (char)Math.random() & 0xff;
        System.out.printf("TK = "); for(i = 0; i < (versions[ver][1]>>3); i++) System.out.printf("%02x", k[i]); System.out.printf("\n");
        System.out.printf("P =  "); for(i = 0; i < (versions[ver][0]>>3); i++) System.out.printf("%02x", p[i]); System.out.printf("\n");
        enc(c,k,ver);
        System.out.printf("C =  "); for(i = 0; i < (versions[ver][0]>>3); i++) System.out.printf("%02x", c[i]); System.out.printf("\n");
        // dec(c,k,ver);
        // printf("P' = "); for(i = 0; i < (versions[ver][0]>>3); i++) printf("%02x", c[i]); printf("\n\n");
    }

    int main() {
        int i;
        char name[];

        RANDOM.setSeed(Integer.toUnsignedLong((int)(System.currentTimeMillis() / 1_000)));

        System.out.printf("Enter the SKINNY Variant to test\n");
        for(i = 0; Long.compareUnsigned(i, versions.length) < 0; i++) {
			System.out.println((i + 1) + ": SKINNY-" + versions[i][0] + "-" + versions[i][1]);
		}
        int ver;
		ver = STDIN_SCANNER.nextInt();
		System.out.println("Running Skinny-" + versions[ver - 1][0] + "-" + versions[ver - 1][1]);
        TestVectors(ver);
    }

    public final static Random RANDOM = new Random(1);
    public final static Scanner STDIN_SCANNER = new Scanner(System.in);

}