xref: /OK3568_Linux_fs/external/rkupdate/CRC.cpp (revision 4882a59341e53eb6f0b4789bf948001014eff981)

#include "DefineHeader.h"
UINT gTable_Crc32[256] =
{
    0x00000000, 0x04c10db7, 0x09821b6e, 0x0d4316d9,
    0x130436dc, 0x17c53b6b, 0x1a862db2, 0x1e472005,
    0x26086db8, 0x22c9600f, 0x2f8a76d6, 0x2b4b7b61,
    0x350c5b64, 0x31cd56d3, 0x3c8e400a, 0x384f4dbd,
    0x4c10db70, 0x48d1d6c7, 0x4592c01e, 0x4153cda9,
    0x5f14edac, 0x5bd5e01b, 0x5696f6c2, 0x5257fb75,
    0x6a18b6c8, 0x6ed9bb7f, 0x639aada6, 0x675ba011,
    0x791c8014, 0x7ddd8da3, 0x709e9b7a, 0x745f96cd,
    0x9821b6e0, 0x9ce0bb57, 0x91a3ad8e, 0x9562a039,
    0x8b25803c, 0x8fe48d8b, 0x82a79b52, 0x866696e5,
    0xbe29db58, 0xbae8d6ef, 0xb7abc036, 0xb36acd81,
    0xad2ded84, 0xa9ece033, 0xa4aff6ea, 0xa06efb5d,
    0xd4316d90, 0xd0f06027, 0xddb376fe, 0xd9727b49,
    0xc7355b4c, 0xc3f456fb, 0xceb74022, 0xca764d95,
    0xf2390028, 0xf6f80d9f, 0xfbbb1b46, 0xff7a16f1,
    0xe13d36f4, 0xe5fc3b43, 0xe8bf2d9a, 0xec7e202d,
    0x34826077, 0x30436dc0, 0x3d007b19, 0x39c176ae,
    0x278656ab, 0x23475b1c, 0x2e044dc5, 0x2ac54072,
    0x128a0dcf, 0x164b0078, 0x1b0816a1, 0x1fc91b16,
    0x018e3b13, 0x054f36a4, 0x080c207d, 0x0ccd2dca,
    0x7892bb07, 0x7c53b6b0, 0x7110a069, 0x75d1adde,
    0x6b968ddb, 0x6f57806c, 0x621496b5, 0x66d59b02,
    0x5e9ad6bf, 0x5a5bdb08, 0x5718cdd1, 0x53d9c066,
    0x4d9ee063, 0x495fedd4, 0x441cfb0d, 0x40ddf6ba,
    0xaca3d697, 0xa862db20, 0xa521cdf9, 0xa1e0c04e,
    0xbfa7e04b, 0xbb66edfc, 0xb625fb25, 0xb2e4f692,
    0x8aabbb2f, 0x8e6ab698, 0x8329a041, 0x87e8adf6,
    0x99af8df3, 0x9d6e8044, 0x902d969d, 0x94ec9b2a,
    0xe0b30de7, 0xe4720050, 0xe9311689, 0xedf01b3e,
    0xf3b73b3b, 0xf776368c, 0xfa352055, 0xfef42de2,
    0xc6bb605f, 0xc27a6de8, 0xcf397b31, 0xcbf87686,
    0xd5bf5683, 0xd17e5b34, 0xdc3d4ded, 0xd8fc405a,
    0x6904c0ee, 0x6dc5cd59, 0x6086db80, 0x6447d637,
    0x7a00f632, 0x7ec1fb85, 0x7382ed5c, 0x7743e0eb,
    0x4f0cad56, 0x4bcda0e1, 0x468eb638, 0x424fbb8f,
    0x5c089b8a, 0x58c9963d, 0x558a80e4, 0x514b8d53,
    0x25141b9e, 0x21d51629, 0x2c9600f0, 0x28570d47,
    0x36102d42, 0x32d120f5, 0x3f92362c, 0x3b533b9b,
    0x031c7626, 0x07dd7b91, 0x0a9e6d48, 0x0e5f60ff,
    0x101840fa, 0x14d94d4d, 0x199a5b94, 0x1d5b5623,
    0xf125760e, 0xf5e47bb9, 0xf8a76d60, 0xfc6660d7,
    0xe22140d2, 0xe6e04d65, 0xeba35bbc, 0xef62560b,
    0xd72d1bb6, 0xd3ec1601, 0xdeaf00d8, 0xda6e0d6f,
    0xc4292d6a, 0xc0e820dd, 0xcdab3604, 0xc96a3bb3,
    0xbd35ad7e, 0xb9f4a0c9, 0xb4b7b610, 0xb076bba7,
    0xae319ba2, 0xaaf09615, 0xa7b380cc, 0xa3728d7b,
    0x9b3dc0c6, 0x9ffccd71, 0x92bfdba8, 0x967ed61f,
    0x8839f61a, 0x8cf8fbad, 0x81bbed74, 0x857ae0c3,
    0x5d86a099, 0x5947ad2e, 0x5404bbf7, 0x50c5b640,
    0x4e829645, 0x4a439bf2, 0x47008d2b, 0x43c1809c,
    0x7b8ecd21, 0x7f4fc096, 0x720cd64f, 0x76cddbf8,
    0x688afbfd, 0x6c4bf64a, 0x6108e093, 0x65c9ed24,
    0x11967be9, 0x1557765e, 0x18146087, 0x1cd56d30,
    0x02924d35, 0x06534082, 0x0b10565b, 0x0fd15bec,
    0x379e1651, 0x335f1be6, 0x3e1c0d3f, 0x3add0088,
    0x249a208d, 0x205b2d3a, 0x2d183be3, 0x29d93654,
    0xc5a71679, 0xc1661bce, 0xcc250d17, 0xc8e400a0,
    0xd6a320a5, 0xd2622d12, 0xdf213bcb, 0xdbe0367c,
    0xe3af7bc1, 0xe76e7676, 0xea2d60af, 0xeeec6d18,
    0xf0ab4d1d, 0xf46a40aa, 0xf9295673, 0xfde85bc4,
    0x89b7cd09, 0x8d76c0be, 0x8035d667, 0x84f4dbd0,
    0x9ab3fbd5, 0x9e72f662, 0x9331e0bb, 0x97f0ed0c,
    0xafbfa0b1, 0xab7ead06, 0xa63dbbdf, 0xa2fcb668,
    0xbcbb966d, 0xb87a9bda, 0xb5398d03, 0xb1f880b4,
};
#define rr_max  104 /* Number of parity checks, rr = deg[g(x)] */
#define parallel 8 //bit count
#define mm 13//limit count
#define nn 8191//code size
#define kk 4120//info length
#define tt 8//correct count

#define tt2 2*tt
UINT s[tt2 + 1]; // Syndrome values

UINT rr;//redundant length      // BCH code parameters


UINT p[mm + 1];
UINT alpha_to[nn + 1], index_of[nn + 1] ; // Galois field
UINT gg[rr_max + 1] ;   // Generator polynomial

UINT ggx1 = 0;
UINT ggx2 = 0;
UINT ggx3 = 0;
UINT ggx4 = 0;
// get crc32 value
UINT CRC_32(unsigned char *pData, UINT ulSize, UINT uiPreviousValue = 0)
{
    UINT i;
    UINT nAccum = uiPreviousValue;

    for (i = 0; i < ulSize; i++)
    {
        nAccum = (nAccum << 8)^gTable_Crc32[(nAccum >> 24) ^ (*pData++)];
    }
    return nAccum;
}
#define CRC16_CCITT         0x1021  //CRC operator
void CRCBuildTable16(unsigned short aPoly, unsigned short *crcTable)
{
    unsigned short i, j;
    unsigned short nData;
    unsigned short nAccum;

    for (i = 0; i < 256; i++)
    {
        nData = (unsigned short)(i << 8);
        nAccum = 0;
        for (j = 0; j < 8; j++)
        {
            if ((nData ^ nAccum) & 0x8000)
            {
                nAccum = (nAccum << 1) ^ aPoly;
            }
            else
            {
                nAccum <<= 1;
            }
            nData <<= 1;
        }
        crcTable[i] = nAccum;
    }
}

unsigned short CRC_16(unsigned char *aData, UINT aSize)
{
    UINT i;
    unsigned short nAccum = 0;
    unsigned short crcTable[256];

    CRCBuildTable16(CRC16_CCITT, crcTable);
    for (i = 0; i < aSize; i++)
    {
        nAccum = (nAccum << 8) ^ crcTable[(nAccum >> 8) ^ *aData++];
    }

    return nAccum;
}

void P_RC4(unsigned char *buf, unsigned short len)
{
    unsigned char S[256], K[256], temp;
    unsigned short i, j, t, x;
    unsigned char key[16] = {124, 78, 3, 4, 85, 5, 9, 7, 45, 44, 123, 56, 23, 13, 23, 17};

    j = 0;
    for (i = 0; i < 256; i++)
    {
        S[i] = (unsigned char)i;
        j &= 0x0f;
        K[i] = key[j];
        j++;
    }

    j = 0;
    for (i = 0; i < 256; i++)
    {
        j = (j + S[i] + K[i]) % 256;
        temp = S[i];
        S[i] = S[j];
        S[j] = temp;
    }

    i = j = 0;
    for (x = 0; x < len; x++)
    {
        i = (i + 1) % 256;
        j = (j + S[i]) % 256;
        temp = S[i];
        S[i] = S[j];
        S[j] = temp;
        t = (S[i] + (S[j] % 256)) % 256;
        buf[x] = buf[x] ^ S[t];
    }
}

void bch_encode(unsigned char *encode_in, unsigned char *encode_out)
{
    UINT i, j;
    bool feed_back;
    UINT bch1 = 0;
    UINT bch2 = 0;
    UINT bch3 = 0;
    UINT bch4 = 0;

    for (i = 0; i < 515; i++)
    {
        for (j = 0; j < 8; j++)
        {
            feed_back = (bch1 & 1) ^ ((encode_in[i] >> j) & 1);

            bch1 = ((bch1 >> 1) | ((bch2 & 1) * 0x80000000)) ^ (ggx1 * feed_back);
            bch2 = ((bch2 >> 1) | ((bch3 & 1) * 0x80000000)) ^ (ggx2 * feed_back);
            bch3 = ((bch3 >> 1) | ((bch4 & 1) * 0x80000000)) ^ (ggx3 * feed_back);
            bch4 = (((bch4 >> 1) ^ (ggx4 * feed_back))) | (feed_back * 0x80);
        }
    }

    //********Handle FF***********************
    bch1 = ~(bch1 ^ 0xad6273b1);
    bch2 = ~(bch2 ^ 0x348393d2);
    bch3 = ~(bch3 ^ 0xe6ebed3c);
    bch4 = ~(bch4 ^ 0xc8);
    //*********************************************

    for (i = 0; i < 515; i++)
    {
        encode_out[i] = encode_in[i];
    }
    encode_out[515] = bch1 & 0x000000ff;
    encode_out[516] = (bch1 & 0x0000ff00) >> 8;
    encode_out[517] = (bch1 & 0x00ff0000) >> 16;
    encode_out[518] = (bch1 & 0xff000000) >> 24;
    encode_out[519] = bch2 & 0x000000ff;
    encode_out[520] = (bch2 & 0x0000ff00) >> 8;
    encode_out[521] = (bch2 & 0x00ff0000) >> 16;
    encode_out[522] = (bch2 & 0xff000000) >> 24;
    encode_out[523] = bch3 & 0x000000ff;
    encode_out[524] = (bch3 & 0x0000ff00) >> 8;
    encode_out[525] = (bch3 & 0x00ff0000) >> 16;
    encode_out[526] = (bch3 & 0xff000000) >> 24;
    encode_out[527] = bch4 & 0x000000ff;
}

#define poly16_CCITT    0x1021          /* crc-ccitt mask */

unsigned short CRC_Calculate(unsigned short crc, unsigned char ch)
{
    UINT i;
    for (i = 0x80; i != 0; i >>= 1)
    {
        if ((crc & 0x8000) != 0)
        {
            crc <<= 1;
            crc ^= poly16_CCITT;
        }
        else
        {
            crc <<= 1;
        }

        if ((ch & i) != 0)
        {
            crc ^= poly16_CCITT;
        }
    }
    return crc;
}
unsigned short CRC_CCITT(unsigned char *p, UINT CalculateNumber)
{
    unsigned short crc = 0xffff;
    while (CalculateNumber--)
    {
        crc = CRC_Calculate(crc, *p);
        p++;
    }
    return crc;
}

void gen_poly()
{
    UINT gen_roots[nn + 1], gen_roots_true[nn + 1] ;    // Roots of generator polynomial
    UINT i, j, Temp ;

    // Initialization of gen_roots
    for (i = 0; i <= nn; i++)
    {
        gen_roots_true[i] = 0;
        gen_roots[i] = 0;
    }

    // Cyclotomic cosets of gen_roots
    for (i = 1; i <= 2 * tt ; i++)
    {
        for (j = 0; j < mm; j++)
        {
            Temp = ((1 << j) * i) % nn;
            gen_roots_true[Temp] = 1;
        }
    }
    rr = 0;     // Count thenumber of parity check bits
    for (i = 0; i < nn; i++)
    {
        if (gen_roots_true[i] == 1)
        {
            rr++;
            gen_roots[rr] = i;
        }
    }
    // Compute generator polynomial based on its roots
    gg[0] = 2 ; // g(x) = (X + alpha) initially
    gg[1] = 1 ;
    for (i = 2; i <= rr; i++)
    {
        gg[i] = 1 ;
        for (j = i - 1; j > 0; j--)
            if (gg[j] != 0)
            {
                gg[j] = gg[j - 1] ^ alpha_to[(index_of[gg[j]] + index_of[alpha_to[gen_roots[i]]]) % nn] ;
            }
            else
            {
                gg[j] = gg[j - 1] ;
            }
        gg[0] = alpha_to[(index_of[gg[0]] + index_of[alpha_to[gen_roots[i]]]) % nn] ;
    }

    ggx1 = gg[103] | (gg[102] << 1) | (gg[101] << 2) | (gg[100] << 3) | (gg[99] << 4) | (gg[98] << 5) | (gg[97] << 6) | (gg[96] << 7)
           | (gg[95] << 8) | (gg[94] << 9) | (gg[93] << 10) | (gg[92] << 11) | (gg[91] << 12) | (gg[90] << 13) | (gg[89] << 14) |
           (gg[88] << 15)
           | (gg[87] << 16) | (gg[86] << 17) | (gg[85] << 18) | (gg[84] << 19) | (gg[83] << 20) | (gg[82] << 21) | (gg[81] << 22) |
           (gg[80] << 23)
           | (gg[79] << 24) | (gg[78] << 25) | (gg[77] << 26) | (gg[76] << 27) | (gg[75] << 28) | (gg[74] << 29) | (gg[73] << 30) |
           (gg[72] << 31);
    ggx2 = gg[71] | (gg[70] << 1) | (gg[69] << 2) | (gg[68] << 3) | (gg[67] << 4) | (gg[66] << 5) | (gg[65] << 6) | (gg[64] << 7)
           | (gg[63] << 8) | (gg[62] << 9) | (gg[61] << 10) | (gg[60] << 11) | (gg[59] << 12) | (gg[58] << 13) | (gg[57] << 14) |
           (gg[56] << 15)
           | (gg[55] << 16) | (gg[54] << 17) | (gg[53] << 18) | (gg[52] << 19) | (gg[51] << 20) | (gg[50] << 21) | (gg[49] << 22) |
           (gg[48] << 23)
           | (gg[47] << 24) | (gg[46] << 25) | (gg[45] << 26) | (gg[44] << 27) | (gg[43] << 28) | (gg[42] << 29) | (gg[41] << 30) |
           (gg[40] << 31);
    ggx3 = gg[39] | (gg[38] << 1) | (gg[37] << 2) | (gg[36] << 3) | (gg[35] << 4) | (gg[34] << 5) | (gg[33] << 6) | (gg[32] << 7)
           | (gg[31] << 8) | (gg[30] << 9) | (gg[29] << 10) | (gg[28] << 11) | (gg[27] << 12) | (gg[26] << 13) | (gg[25] << 14) |
           (gg[24] << 15)
           | (gg[23] << 16) | (gg[22] << 17) | (gg[21] << 18) | (gg[20] << 19) | (gg[19] << 20) | (gg[18] << 21) | (gg[17] << 22) |
           (gg[16] << 23)
           | (gg[15] << 24) | (gg[14] << 25) | (gg[13] << 26) | (gg[12] << 27) | (gg[11] << 28) | (gg[10] << 29) | (gg[9] << 30) |
           (gg[8] << 31);
    ggx4 = gg[7] | (gg[6] << 1) | (gg[5] << 2) | (gg[4] << 3) | (gg[3] << 4) | (gg[2] << 5) | (gg[1] << 6);

}

void generate_gf()
{
    UINT i;
    UINT mask ; // Register states

    // Primitive polynomials
    for (i = 1; i < mm; i++)
    {
        p[i] = 0;
    }
    p[0] = p[mm] = 1;
    if (mm == 2)
    {
        p[1] = 1;
    }
    else if (mm == 3)
    {
        p[1] = 1;
    }
    else if (mm == 4)
    {
        p[1] = 1;
    }
    else if (mm == 5)
    {
        p[2] = 1;
    }
    else if (mm == 6)
    {
        p[1] = 1;
    }
    else if (mm == 7)
    {
        p[1] = 1;
    }
    else if (mm == 8)
    {
        p[4] = p[5] = p[6] = 1;
    }
    else if (mm == 9)
    {
        p[4] = 1;
    }
    else if (mm == 10)
    {
        p[3] = 1;
    }
    else if (mm == 11)
    {
        p[2] = 1;
    }
    else if (mm == 12)
    {
        p[3] = p[4] = p[7] = 1;
    }
    else if (mm == 13)
    {
        p[1] = p[2] = p[3] = p[5] = p[7] = p[8] = p[10] = 1;    // 25AF
    }
    else if (mm == 14)
    {
        p[2] = p[4] = p[6] = p[7] = p[8] = 1;    // 41D5
    }
    else if (mm == 15)
    {
        p[1] = 1;
    }
    else if (mm == 16)
    {
        p[2] = p[3] = p[5] = 1;
    }
    else if (mm == 17)
    {
        p[3] = 1;
    }
    else if (mm == 18)
    {
        p[7] = 1;
    }
    else if (mm == 19)
    {
        p[1] = p[5] = p[6] = 1;
    }
    else if (mm == 20)
    {
        p[3] = 1;
    }
    // Galois field implementation with shift registers
    // Ref: L&C, Chapter 6.7, pp. 217
    mask = 1 ;
    alpha_to[mm] = 0 ;
    for (i = 0; i < mm; i++)
    {
        alpha_to[i] = mask ;
        index_of[alpha_to[i]] = i ;
        if (p[i] != 0)
        {
            alpha_to[mm] ^= mask ;
        }
        mask <<= 1 ;
    }

    index_of[alpha_to[mm]] = mm ;
    mask >>= 1 ;
    for (i = mm + 1; i < nn; i++)
    {
        if (alpha_to[i - 1] >= mask)
        {
            alpha_to[i] = alpha_to[mm] ^ ((alpha_to[i - 1] ^ mask) << 1) ;
        }
        else
        {
            alpha_to[i] = alpha_to[i - 1] << 1 ;
        }

        index_of[alpha_to[i]] = i ;
    }
    index_of[0] = -1 ;
}