14

I want to calculate a 32-bit CRC lookup table. One way I tried is by using the following code from this website:

#include <iostream>
#include <stdint.h>

void make_crc_table()
{
    unsigned long POLYNOMIAL = 0x04c11db7;
    unsigned long WIDTH = 8 * sizeof(unsigned long);
    unsigned long TOPBIT = 1 << (WIDTH - 1);
    unsigned long crcTable[256];
    unsigned long remainder;
    // Compute the remainder of each possible dividend
    for (int dividend = 0; dividend < 256; ++dividend)
    {
        // Start with the dividend followed by zeros
        remainder = dividend << (WIDTH - 8);

        // Perform modulo-2 division, a bit at a time
        for (unsigned long bit = 8; bit > 0; --bit)
        {
            // Try to divide the current data bit
            if (remainder & TOPBIT)
            {
                remainder = (remainder << 1) ^ POLYNOMIAL;
            }
            else
            {
                remainder = (remainder << 1);
            }
        }
        crcTable[dividend] = remainder;
    }

    // Print the CRC table
    for (int i = 0; i < 256; i++)
    {
        if (i % 4 == 0)
        {
            std::cout <<"\n";
        }
        std::cout << std::hex << crcTable[i];
        std::cout << ", ";
    }
}

int main()
{
    make_crc_table();
    return 0;
}

Another way I tried is by using the following code that I found from this StackOverflow question, and the code can be downloaded from here in a file called CRC Calculator.zip

#include <iostream>
#include <stdint.h>

#define POLYNOMIAL      0x04C11DB7
uint32_t A_crcLookupTable[256] = {0};
#define WIDTH    (8 * sizeof(uint32_t))
#define TOPBIT   (((uint32_t)1) << (WIDTH - 1))

#define FP_reflect_DATA(_DATO)                      (_DATO)
#define FP_reflect_CRCTableValue(_CRCTableValue)    (_CRCTableValue)

uint32_t F_CRC_ObtenValorDeTabla(uint8_t VP_Pos_Tabla)
{
    uint32_t VP_CRCTableValue = 0;
    uint8_t VP_Pos_bit = 0;

    VP_CRCTableValue = ((uint32_t) FP_reflect_DATA(VP_Pos_Tabla)) << (WIDTH - 8);

    for (VP_Pos_bit = 0; VP_Pos_bit < 8; VP_Pos_bit++)
    {
        if (VP_CRCTableValue & TOPBIT)
        {
            VP_CRCTableValue = (VP_CRCTableValue << 1) ^ POLYNOMIAL;
        }
        else
        {
            VP_CRCTableValue = (VP_CRCTableValue << 1);
        }
    }
    return (FP_reflect_CRCTableValue(VP_CRCTableValue));
}

void F_CRC_InicializaTabla(void)
{
    uint16_t VP_Pos_Array = 0;

    for (VP_Pos_Array = 0; VP_Pos_Array < 256; VP_Pos_Array++)
    {
        A_crcLookupTable[VP_Pos_Array] = F_CRC_ObtenValorDeTabla((uint8_t)(VP_Pos_Array &0xFF));

    }

}


void make_crc_table()
{
    F_CRC_InicializaTabla();

    // Print the CRC table
    for (int i = 0; i < 256; i++)
    {
        if (i % 4 == 0)
        {
            std::cout <<"\n";
        }
        std::cout << std::hex << A_crcLookupTable[i];
        std::cout << ", ";
    }
}

int main()
{
    make_crc_table();
    return 0;
}

Here is what the correct final table should be, based on this link:

// The constants here are for the CRC-32 generator 
// polynomial, as defined in the Microsoft 
// Systems Journal, March 1995, pp. 107-108
CONST
  table: ARRAY[0..255] OF DWORD =
 ($00000000, $77073096, $EE0E612C, $990951BA,
  $076DC419, $706AF48F, $E963A535, $9E6495A3,
  $0EDB8832, $79DCB8A4, $E0D5E91E, $97D2D988,
  $09B64C2B, $7EB17CBD, $E7B82D07, $90BF1D91,
  $1DB71064, $6AB020F2, $F3B97148, $84BE41DE,
  $1ADAD47D, $6DDDE4EB, $F4D4B551, $83D385C7,
  $136C9856, $646BA8C0, $FD62F97A, $8A65C9EC,
  $14015C4F, $63066CD9, $FA0F3D63, $8D080DF5,
  $3B6E20C8, $4C69105E, $D56041E4, $A2677172,
  $3C03E4D1, $4B04D447, $D20D85FD, $A50AB56B,
  $35B5A8FA, $42B2986C, $DBBBC9D6, $ACBCF940,
  $32D86CE3, $45DF5C75, $DCD60DCF, $ABD13D59,
  $26D930AC, $51DE003A, $C8D75180, $BFD06116,
  $21B4F4B5, $56B3C423, $CFBA9599, $B8BDA50F,
  $2802B89E, $5F058808, $C60CD9B2, $B10BE924,
  $2F6F7C87, $58684C11, $C1611DAB, $B6662D3D,

  $76DC4190, $01DB7106, $98D220BC, $EFD5102A,
  $71B18589, $06B6B51F, $9FBFE4A5, $E8B8D433,
  $7807C9A2, $0F00F934, $9609A88E, $E10E9818,
  $7F6A0DBB, $086D3D2D, $91646C97, $E6635C01,
  $6B6B51F4, $1C6C6162, $856530D8, $F262004E,
  $6C0695ED, $1B01A57B, $8208F4C1, $F50FC457,
  $65B0D9C6, $12B7E950, $8BBEB8EA, $FCB9887C,
  $62DD1DDF, $15DA2D49, $8CD37CF3, $FBD44C65,
  $4DB26158, $3AB551CE, $A3BC0074, $D4BB30E2,
  $4ADFA541, $3DD895D7, $A4D1C46D, $D3D6F4FB,
  $4369E96A, $346ED9FC, $AD678846, $DA60B8D0,
  $44042D73, $33031DE5, $AA0A4C5F, $DD0D7CC9,
  $5005713C, $270241AA, $BE0B1010, $C90C2086,
  $5768B525, $206F85B3, $B966D409, $CE61E49F,
  $5EDEF90E, $29D9C998, $B0D09822, $C7D7A8B4,
  $59B33D17, $2EB40D81, $B7BD5C3B, $C0BA6CAD,

  $EDB88320, $9ABFB3B6, $03B6E20C, $74B1D29A,
  $EAD54739, $9DD277AF, $04DB2615, $73DC1683,
  $E3630B12, $94643B84, $0D6D6A3E, $7A6A5AA8,
  $E40ECF0B, $9309FF9D, $0A00AE27, $7D079EB1,
  $F00F9344, $8708A3D2, $1E01F268, $6906C2FE,
  $F762575D, $806567CB, $196C3671, $6E6B06E7,
  $FED41B76, $89D32BE0, $10DA7A5A, $67DD4ACC,
  $F9B9DF6F, $8EBEEFF9, $17B7BE43, $60B08ED5,
  $D6D6A3E8, $A1D1937E, $38D8C2C4, $4FDFF252,
  $D1BB67F1, $A6BC5767, $3FB506DD, $48B2364B,
  $D80D2BDA, $AF0A1B4C, $36034AF6, $41047A60,
  $DF60EFC3, $A867DF55, $316E8EEF, $4669BE79,
  $CB61B38C, $BC66831A, $256FD2A0, $5268E236,
  $CC0C7795, $BB0B4703, $220216B9, $5505262F,
  $C5BA3BBE, $B2BD0B28, $2BB45A92, $5CB36A04,
  $C2D7FFA7, $B5D0CF31, $2CD99E8B, $5BDEAE1D,

  $9B64C2B0, $EC63F226, $756AA39C, $026D930A,
  $9C0906A9, $EB0E363F, $72076785, $05005713,
  $95BF4A82, $E2B87A14, $7BB12BAE, $0CB61B38,
  $92D28E9B, $E5D5BE0D, $7CDCEFB7, $0BDBDF21,
  $86D3D2D4, $F1D4E242, $68DDB3F8, $1FDA836E,
  $81BE16CD, $F6B9265B, $6FB077E1, $18B74777,
  $88085AE6, $FF0F6A70, $66063BCA, $11010B5C,
  $8F659EFF, $F862AE69, $616BFFD3, $166CCF45,
  $A00AE278, $D70DD2EE, $4E048354, $3903B3C2,
  $A7672661, $D06016F7, $4969474D, $3E6E77DB,
  $AED16A4A, $D9D65ADC, $40DF0B66, $37D83BF0,
  $A9BCAE53, $DEBB9EC5, $47B2CF7F, $30B5FFE9,
  $BDBDF21C, $CABAC28A, $53B39330, $24B4A3A6,
  $BAD03605, $CDD70693, $54DE5729, $23D967BF,
  $B3667A2E, $C4614AB8, $5D681B02, $2A6F2B94,
  $B40BBE37, $C30C8EA1, $5A05DF1B, $2D02EF8D);

However, this is what my output is from both programs (I diffed the output, and it's the same for both of them), and it's incorrect:

0, 4c11db7, 9823b6e, d4326d9, 
130476dc, 17c56b6b, 1a864db2, 1e475005, 
2608edb8, 22c9f00f, 2f8ad6d6, 2b4bcb61, 
350c9b64, 31cd86d3, 3c8ea00a, 384fbdbd, 
4c11db70, 48d0c6c7, 4593e01e, 4152fda9, 
5f15adac, 5bd4b01b, 569796c2, 52568b75, 
6a1936c8, 6ed82b7f, 639b0da6, 675a1011, 
791d4014, 7ddc5da3, 709f7b7a, 745e66cd, 
9823b6e0, 9ce2ab57, 91a18d8e, 95609039, 
8b27c03c, 8fe6dd8b, 82a5fb52, 8664e6e5, 
be2b5b58, baea46ef, b7a96036, b3687d81, 
ad2f2d84, a9ee3033, a4ad16ea, a06c0b5d, 
d4326d90, d0f37027, ddb056fe, d9714b49, 
c7361b4c, c3f706fb, ceb42022, ca753d95, 
f23a8028, f6fb9d9f, fbb8bb46, ff79a6f1, 
e13ef6f4, e5ffeb43, e8bccd9a, ec7dd02d, 
34867077, 30476dc0, 3d044b19, 39c556ae, 
278206ab, 23431b1c, 2e003dc5, 2ac12072, 
128e9dcf, 164f8078, 1b0ca6a1, 1fcdbb16, 
18aeb13, 54bf6a4, 808d07d, cc9cdca, 
7897ab07, 7c56b6b0, 71159069, 75d48dde, 
6b93dddb, 6f52c06c, 6211e6b5, 66d0fb02, 
5e9f46bf, 5a5e5b08, 571d7dd1, 53dc6066, 
4d9b3063, 495a2dd4, 44190b0d, 40d816ba, 
aca5c697, a864db20, a527fdf9, a1e6e04e, 
bfa1b04b, bb60adfc, b6238b25, b2e29692, 
8aad2b2f, 8e6c3698, 832f1041, 87ee0df6, 
99a95df3, 9d684044, 902b669d, 94ea7b2a, 
e0b41de7, e4750050, e9362689, edf73b3e, 
f3b06b3b, f771768c, fa325055, fef34de2, 
c6bcf05f, c27dede8, cf3ecb31, cbffd686, 
d5b88683, d1799b34, dc3abded, d8fba05a, 
690ce0ee, 6dcdfd59, 608edb80, 644fc637, 
7a089632, 7ec98b85, 738aad5c, 774bb0eb, 
4f040d56, 4bc510e1, 46863638, 42472b8f, 
5c007b8a, 58c1663d, 558240e4, 51435d53, 
251d3b9e, 21dc2629, 2c9f00f0, 285e1d47, 
36194d42, 32d850f5, 3f9b762c, 3b5a6b9b, 
315d626, 7d4cb91, a97ed48, e56f0ff, 
1011a0fa, 14d0bd4d, 19939b94, 1d528623, 
f12f560e, f5ee4bb9, f8ad6d60, fc6c70d7, 
e22b20d2, e6ea3d65, eba91bbc, ef68060b, 
d727bbb6, d3e6a601, dea580d8, da649d6f, 
c423cd6a, c0e2d0dd, cda1f604, c960ebb3, 
bd3e8d7e, b9ff90c9, b4bcb610, b07daba7, 
ae3afba2, aafbe615, a7b8c0cc, a379dd7b, 
9b3660c6, 9ff77d71, 92b45ba8, 9675461f, 
8832161a, 8cf30bad, 81b02d74, 857130c3, 
5d8a9099, 594b8d2e, 5408abf7, 50c9b640, 
4e8ee645, 4a4ffbf2, 470cdd2b, 43cdc09c, 
7b827d21, 7f436096, 7200464f, 76c15bf8, 
68860bfd, 6c47164a, 61043093, 65c52d24, 
119b4be9, 155a565e, 18197087, 1cd86d30, 
29f3d35, 65e2082, b1d065b, fdc1bec, 
3793a651, 3352bbe6, 3e119d3f, 3ad08088, 
2497d08d, 2056cd3a, 2d15ebe3, 29d4f654, 
c5a92679, c1683bce, cc2b1d17, c8ea00a0, 
d6ad50a5, d26c4d12, df2f6bcb, dbee767c, 
e3a1cbc1, e760d676, ea23f0af, eee2ed18, 
f0a5bd1d, f464a0aa, f9278673, fde69bc4, 
89b8fd09, 8d79e0be, 803ac667, 84fbdbd0, 
9abc8bd5, 9e7d9662, 933eb0bb, 97ffad0c, 
afb010b1, ab710d06, a6322bdf, a2f33668, 
bcb4666d, b8757bda, b5365d03, b1f740b4,
6
  • 1
    Are you using the same generator polynomial as the people you're checking your table against? – genisage Sep 25 '14 at 22:42
  • @genisage Yes, I am. I am using the CRC-32 polynomial that's used for Ethernet. Here it is, listed from the website where I got the output from: x32 + x26 + x23 + x22 + x16 + x12 + x11 + x10 + x8 + x7 + x5 + x4 + x2 + x1 + 1 – Programmer_D Sep 25 '14 at 22:51
  • Printing five columns of output makes it really hard to find the interesting coefficients. Please use a power of two. – Ben Voigt Sep 25 '14 at 22:51
  • 1
    Is it possible that they represented it with the highest power as the most significant bit and you did it with the highest power as the least significant bit? – genisage Sep 25 '14 at 22:53
  • @genisage: I think that's the difference, both in the bit-order of the CRC values, and the bit-order of the array indexes. Can't construct one table from the other, though, because the bit shifts are effectively performed in the wrong direction as well. – Ben Voigt Sep 25 '14 at 22:54
20

The bits are reversed. Note that the table entry for array[0x80] (0x80 is 0x01 reversed) = 0xEDB88320, which is 0x04C11DB7 reversed.

Example code:

#include <iostream>
#include <iomanip>

void make_crc_table(unsigned long crcTable[]) {
    unsigned long POLYNOMIAL = 0xEDB88320;
    unsigned long remainder;
    unsigned char b = 0;
    do {
        // Start with the data byte
        remainder = b;
        for (unsigned long bit = 8; bit > 0; --bit) {
            if (remainder & 1)
                remainder = (remainder >> 1) ^ POLYNOMIAL;
            else
                remainder = (remainder >> 1);
        }
        crcTable[(size_t)b] = remainder;
    } while(0 != ++b);
}

unsigned long gen_crc(unsigned char *p, size_t n, unsigned long crcTable[]) {
    unsigned long crc = 0xfffffffful;
    size_t i;
    for(i = 0; i < n; i++)
        crc = crcTable[*p++ ^ (crc&0xff)] ^ (crc>>8);
    return(~crc);
}

int main() {
    unsigned long crcTable[256];
    make_crc_table(crcTable);
    // Print the CRC table
    for (size_t i = 0; i < 256; i++) {
        std::cout << std::setfill('0') << std::setw(8) << std::hex << crcTable[i];
        if (i % 4 == 3)
            std::cout << std::endl;
        else
            std::cout << ", ";
    }
    return 0;
}
14
  • 2
    @TypeKazt - in this case, the order of operations doesn't matter, since p is a pointer to a byte (unsigned char). In either case, ((CRC ^ byte)&0xff) or (byte ^ (CRC&0xff)), the result is the same, an 8 bit index that is promoted to a 32 bit index with leading zero bits since it is used as an index to the table (the xor operation also promotes to a 32 bit index with leading zero bits in the second case) – rcgldr Jan 25 '18 at 2:50
  • 1
    @Arash - depends on the amount of data and the probability of bit errors. There is a 32 bit CRC guaranteed to detect up to 5 error bits with 32767 bits of data + crc. There is a 64 bit CRC guaranteed to detect up to 5 error bits with 65535 bits of data + crc. Finding a 64 bit CRC that handles 5 or more error bits takes a long time, so there aren't a lot of 64 bit CRC. If the data is larger, like 128k + bits, then it doesn't matter, the probability of not detecting an error is about 1 in 2^64 using two 32 bit CRC's or one 64 bit CRC. – rcgldr Jan 14 at 0:50
  • 1
    @Arash - for a processor with 64 bit registers, then a typical CRC calculation would be faster with one 64 bit CRC than two 32 bit CRCs. – rcgldr Jan 15 at 15:23
  • 1
    @Arash - Here is a collection of 16, 32, and 64 bit CRC examples. Look at the ??????c.cpp source files for typical CRC implementations. The assembly (.asm) files are versions of github Intel CRC examples modified to run with Visual Studio, with comments added for the RK?? constants (the Intel files are missing some comments). The ??????g.cpp source files are used to generate the RK?? constants. – rcgldr Jan 15 at 20:16
  • 1
    @Arash - the assembly files implementation is explained in Intel - CRC using PCLMULQDQ pdf . Note that my assembly examples do not include the variations with ZMM registers, as those are only available on some Intel processors with AVX512, which I don't have. – rcgldr Jan 15 at 20:28
3

If there is not enough Flash and RAM (embedded software), you can use this function:

uint32_t CRC32_function(uint8_t *buf, uint32_t len){

    uint32_t val, crc;
    uint8_t i;

    crc = 0xFFFFFFFF;
    while(len--){
        val=(crc^*buf++)&0xFF;
        for(i=0; i<8; i++){
            val = val & 1 ? (val>>1)^0xEDB88320 : val>>1;
        }
        crc = val^crc>>8;
    }
    return crc^0xFFFFFFFF;
}

But CRC calculation takes more time.

1
  • can you explain the code? val = val & 1 ? (val>>1)^0xEDB88320 : val>>1; – Arash Jan 8 at 5:23

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