So I have a design which incorporates CRC32C checksums to ensure data hasn't been damaged. I decided to use CRC32C because I can have both a software version and a hardware-accelerated version if the computer the software runs on supports SSE 4.2

I'm going by Intel's developer manual (vol 2A), which seems to provide the algorithm behind the crc32 instruction. However, I'm having little luck. Intel's developer guide says the following:

BIT_REFLECT32: DEST[31-0] = SRC[0-31]
MOD2: Remainder from Polynomial division modulus 2

TEMP1[31-0] <- BIT_REFLECT(SRC[31-0])
TEMP2[31-0] <- BIT_REFLECT(DEST[31-0])
TEMP3[63-0] <- TEMP1[31-0] << 32
TEMP4[63-0] <- TEMP2[31-0] << 32
TEMP5[63-0] <- TEMP3[63-0] XOR TEMP4[63-0]
TEMP6[31-0] <- TEMP5[63-0] MOD2 0x11EDC6F41
DEST[31-0]  <- BIT_REFLECT(TEMP6[31-0])

Now, as far as I can tell, I've done everything up to the line starting TEMP6 correctly, but I think I may be either misunderstanding the polynomial division, or implementing it incorrectly. If my understanding is correct, 1 / 1 mod 2 = 1, 0 / 1 mod 2 = 0, and both divides-by-zero are undefined.

What I don't understand is how binary division with 64-bit and 33-bit operands will work. If SRC is 0x00000000, and DEST is 0xFFFFFFFF, TEMP5[63-32] will be all set bits, while TEMP5[31-0] will be all unset bits.

If I was to use the bits from TEMP5 as the numerator, there would be 30 divisions by zero as the polynomial 11EDC6F41 is only 33 bits long (and so converting it to a 64-bit unsigned integer leaves the top 30 bits unset), and so the denominator is unset for 30 bits.

However, if I was to use the polynomial as the numerator, the bottom 32 bits of TEMP5 are unset, resulting in divides by zero there, and the top 30 bits of the result would be zero, as the top 30 bits of the numerator would be zero, as 0 / 1 mod 2 = 0.

Am I misunderstanding how this works? Just plain missing something? Or has Intel left out some crucial step in their documentation?

The reason I went to Intel's developer guide for what appeared to be the algorithm they used is because they used a 33-bit polynomial, and I wanted to make outputs identical, which didn't happen when I used the 32-bit polynomial 1EDC6F41 (show below).

uint32_t poly = 0x1EDC6F41, sres, crcTable[256], data = 0x00000000;

for (n = 0; n < 256; n++) {
    sres = n;
    for (k = 0; k < 8; k++)
        sres = (sres & 1) == 1 ? poly ^ (sres >> 1) : (sres >> 1);
    crcTable[n] = sres;
}
sres = 0xFFFFFFFF;

for (n = 0; n < 4; n++) {
    sres = crcTable[(sres ^ data) & 0xFF] ^ (sres >> 8);
}

The above code produces 4138093821 as an output, and the crc32 opcode produces 2346497208 using the input 0x00000000.

Sorry if this is badly written or incomprehensible in places, it is rather late for me.

  • 1
    For those using Delphi, I've written some Open Source code using the new crc32 hardware instruction if available, and fast x86 asm or pure pascal code (using pre-computed tables) if SSE 4.2 is not available. Naive rolled version runs at 330 MB/s, optimized unrolled x86 asm performs at 1.7 GB/s, and SSE 4.2 hardware gives an amazing 3.7 GB/s speed (on both Win32 and Win64 platforms). – Arnaud Bouchez May 27 '14 at 6:48
up vote 64 down vote accepted

Here are both software and hardware versions of CRC-32C. The software version is optimized to process eight bytes at a time. The hardware version is optimized to run three crc32q instructions effectively in parallel on a single core, since the throughput of that instruction is one cycle, but the latency is three cycles.

/* crc32c.c -- compute CRC-32C using the Intel crc32 instruction
 * Copyright (C) 2013 Mark Adler
 * Version 1.1  1 Aug 2013  Mark Adler
 */

/*
  This software is provided 'as-is', without any express or implied
  warranty.  In no event will the author be held liable for any damages
  arising from the use of this software.

  Permission is granted to anyone to use this software for any purpose,
  including commercial applications, and to alter it and redistribute it
  freely, subject to the following restrictions:

  1. The origin of this software must not be misrepresented; you must not
     claim that you wrote the original software. If you use this software
     in a product, an acknowledgment in the product documentation would be
     appreciated but is not required.
  2. Altered source versions must be plainly marked as such, and must not be
     misrepresented as being the original software.
  3. This notice may not be removed or altered from any source distribution.

  Mark Adler
  madler@alumni.caltech.edu
 */

/* Use hardware CRC instruction on Intel SSE 4.2 processors.  This computes a
   CRC-32C, *not* the CRC-32 used by Ethernet and zip, gzip, etc.  A software
   version is provided as a fall-back, as well as for speed comparisons. */

/* Version history:
   1.0  10 Feb 2013  First version
   1.1   1 Aug 2013  Correct comments on why three crc instructions in parallel
 */

#include <stdio.h>
#include <stdlib.h>
#include <stdint.h>
#include <unistd.h>
#include <pthread.h>

/* CRC-32C (iSCSI) polynomial in reversed bit order. */
#define POLY 0x82f63b78

/* Table for a quadword-at-a-time software crc. */
static pthread_once_t crc32c_once_sw = PTHREAD_ONCE_INIT;
static uint32_t crc32c_table[8][256];

/* Construct table for software CRC-32C calculation. */
static void crc32c_init_sw(void)
{
    uint32_t n, crc, k;

    for (n = 0; n < 256; n++) {
        crc = n;
        crc = crc & 1 ? (crc >> 1) ^ POLY : crc >> 1;
        crc = crc & 1 ? (crc >> 1) ^ POLY : crc >> 1;
        crc = crc & 1 ? (crc >> 1) ^ POLY : crc >> 1;
        crc = crc & 1 ? (crc >> 1) ^ POLY : crc >> 1;
        crc = crc & 1 ? (crc >> 1) ^ POLY : crc >> 1;
        crc = crc & 1 ? (crc >> 1) ^ POLY : crc >> 1;
        crc = crc & 1 ? (crc >> 1) ^ POLY : crc >> 1;
        crc = crc & 1 ? (crc >> 1) ^ POLY : crc >> 1;
        crc32c_table[0][n] = crc;
    }
    for (n = 0; n < 256; n++) {
        crc = crc32c_table[0][n];
        for (k = 1; k < 8; k++) {
            crc = crc32c_table[0][crc & 0xff] ^ (crc >> 8);
            crc32c_table[k][n] = crc;
        }
    }
}

/* Table-driven software version as a fall-back.  This is about 15 times slower
   than using the hardware instructions.  This assumes little-endian integers,
   as is the case on Intel processors that the assembler code here is for. */
static uint32_t crc32c_sw(uint32_t crci, const void *buf, size_t len)
{
    const unsigned char *next = buf;
    uint64_t crc;

    pthread_once(&crc32c_once_sw, crc32c_init_sw);
    crc = crci ^ 0xffffffff;
    while (len && ((uintptr_t)next & 7) != 0) {
        crc = crc32c_table[0][(crc ^ *next++) & 0xff] ^ (crc >> 8);
        len--;
    }
    while (len >= 8) {
        crc ^= *(uint64_t *)next;
        crc = crc32c_table[7][crc & 0xff] ^
              crc32c_table[6][(crc >> 8) & 0xff] ^
              crc32c_table[5][(crc >> 16) & 0xff] ^
              crc32c_table[4][(crc >> 24) & 0xff] ^
              crc32c_table[3][(crc >> 32) & 0xff] ^
              crc32c_table[2][(crc >> 40) & 0xff] ^
              crc32c_table[1][(crc >> 48) & 0xff] ^
              crc32c_table[0][crc >> 56];
        next += 8;
        len -= 8;
    }
    while (len) {
        crc = crc32c_table[0][(crc ^ *next++) & 0xff] ^ (crc >> 8);
        len--;
    }
    return (uint32_t)crc ^ 0xffffffff;
}

/* Multiply a matrix times a vector over the Galois field of two elements,
   GF(2).  Each element is a bit in an unsigned integer.  mat must have at
   least as many entries as the power of two for most significant one bit in
   vec. */
static inline uint32_t gf2_matrix_times(uint32_t *mat, uint32_t vec)
{
    uint32_t sum;

    sum = 0;
    while (vec) {
        if (vec & 1)
            sum ^= *mat;
        vec >>= 1;
        mat++;
    }
    return sum;
}

/* Multiply a matrix by itself over GF(2).  Both mat and square must have 32
   rows. */
static inline void gf2_matrix_square(uint32_t *square, uint32_t *mat)
{
    int n;

    for (n = 0; n < 32; n++)
        square[n] = gf2_matrix_times(mat, mat[n]);
}

/* Construct an operator to apply len zeros to a crc.  len must be a power of
   two.  If len is not a power of two, then the result is the same as for the
   largest power of two less than len.  The result for len == 0 is the same as
   for len == 1.  A version of this routine could be easily written for any
   len, but that is not needed for this application. */
static void crc32c_zeros_op(uint32_t *even, size_t len)
{
    int n;
    uint32_t row;
    uint32_t odd[32];       /* odd-power-of-two zeros operator */

    /* put operator for one zero bit in odd */
    odd[0] = POLY;              /* CRC-32C polynomial */
    row = 1;
    for (n = 1; n < 32; n++) {
        odd[n] = row;
        row <<= 1;
    }

    /* put operator for two zero bits in even */
    gf2_matrix_square(even, odd);

    /* put operator for four zero bits in odd */
    gf2_matrix_square(odd, even);

    /* first square will put the operator for one zero byte (eight zero bits),
       in even -- next square puts operator for two zero bytes in odd, and so
       on, until len has been rotated down to zero */
    do {
        gf2_matrix_square(even, odd);
        len >>= 1;
        if (len == 0)
            return;
        gf2_matrix_square(odd, even);
        len >>= 1;
    } while (len);

    /* answer ended up in odd -- copy to even */
    for (n = 0; n < 32; n++)
        even[n] = odd[n];
}

/* Take a length and build four lookup tables for applying the zeros operator
   for that length, byte-by-byte on the operand. */
static void crc32c_zeros(uint32_t zeros[][256], size_t len)
{
    uint32_t n;
    uint32_t op[32];

    crc32c_zeros_op(op, len);
    for (n = 0; n < 256; n++) {
        zeros[0][n] = gf2_matrix_times(op, n);
        zeros[1][n] = gf2_matrix_times(op, n << 8);
        zeros[2][n] = gf2_matrix_times(op, n << 16);
        zeros[3][n] = gf2_matrix_times(op, n << 24);
    }
}

/* Apply the zeros operator table to crc. */
static inline uint32_t crc32c_shift(uint32_t zeros[][256], uint32_t crc)
{
    return zeros[0][crc & 0xff] ^ zeros[1][(crc >> 8) & 0xff] ^
           zeros[2][(crc >> 16) & 0xff] ^ zeros[3][crc >> 24];
}

/* Block sizes for three-way parallel crc computation.  LONG and SHORT must
   both be powers of two.  The associated string constants must be set
   accordingly, for use in constructing the assembler instructions. */
#define LONG 8192
#define LONGx1 "8192"
#define LONGx2 "16384"
#define SHORT 256
#define SHORTx1 "256"
#define SHORTx2 "512"

/* Tables for hardware crc that shift a crc by LONG and SHORT zeros. */
static pthread_once_t crc32c_once_hw = PTHREAD_ONCE_INIT;
static uint32_t crc32c_long[4][256];
static uint32_t crc32c_short[4][256];

/* Initialize tables for shifting crcs. */
static void crc32c_init_hw(void)
{
    crc32c_zeros(crc32c_long, LONG);
    crc32c_zeros(crc32c_short, SHORT);
}

/* Compute CRC-32C using the Intel hardware instruction. */
static uint32_t crc32c_hw(uint32_t crc, const void *buf, size_t len)
{
    const unsigned char *next = buf;
    const unsigned char *end;
    uint64_t crc0, crc1, crc2;      /* need to be 64 bits for crc32q */

    /* populate shift tables the first time through */
    pthread_once(&crc32c_once_hw, crc32c_init_hw);

    /* pre-process the crc */
    crc0 = crc ^ 0xffffffff;

    /* compute the crc for up to seven leading bytes to bring the data pointer
       to an eight-byte boundary */
    while (len && ((uintptr_t)next & 7) != 0) {
        __asm__("crc32b\t" "(%1), %0"
                : "=r"(crc0)
                : "r"(next), "0"(crc0));
        next++;
        len--;
    }

    /* compute the crc on sets of LONG*3 bytes, executing three independent crc
       instructions, each on LONG bytes -- this is optimized for the Nehalem,
       Westmere, Sandy Bridge, and Ivy Bridge architectures, which have a
       throughput of one crc per cycle, but a latency of three cycles */
    while (len >= LONG*3) {
        crc1 = 0;
        crc2 = 0;
        end = next + LONG;
        do {
            __asm__("crc32q\t" "(%3), %0\n\t"
                    "crc32q\t" LONGx1 "(%3), %1\n\t"
                    "crc32q\t" LONGx2 "(%3), %2"
                    : "=r"(crc0), "=r"(crc1), "=r"(crc2)
                    : "r"(next), "0"(crc0), "1"(crc1), "2"(crc2));
            next += 8;
        } while (next < end);
        crc0 = crc32c_shift(crc32c_long, crc0) ^ crc1;
        crc0 = crc32c_shift(crc32c_long, crc0) ^ crc2;
        next += LONG*2;
        len -= LONG*3;
    }

    /* do the same thing, but now on SHORT*3 blocks for the remaining data less
       than a LONG*3 block */
    while (len >= SHORT*3) {
        crc1 = 0;
        crc2 = 0;
        end = next + SHORT;
        do {
            __asm__("crc32q\t" "(%3), %0\n\t"
                    "crc32q\t" SHORTx1 "(%3), %1\n\t"
                    "crc32q\t" SHORTx2 "(%3), %2"
                    : "=r"(crc0), "=r"(crc1), "=r"(crc2)
                    : "r"(next), "0"(crc0), "1"(crc1), "2"(crc2));
            next += 8;
        } while (next < end);
        crc0 = crc32c_shift(crc32c_short, crc0) ^ crc1;
        crc0 = crc32c_shift(crc32c_short, crc0) ^ crc2;
        next += SHORT*2;
        len -= SHORT*3;
    }

    /* compute the crc on the remaining eight-byte units less than a SHORT*3
       block */
    end = next + (len - (len & 7));
    while (next < end) {
        __asm__("crc32q\t" "(%1), %0"
                : "=r"(crc0)
                : "r"(next), "0"(crc0));
        next += 8;
    }
    len &= 7;

    /* compute the crc for up to seven trailing bytes */
    while (len) {
        __asm__("crc32b\t" "(%1), %0"
                : "=r"(crc0)
                : "r"(next), "0"(crc0));
        next++;
        len--;
    }

    /* return a post-processed crc */
    return (uint32_t)crc0 ^ 0xffffffff;
}

/* Check for SSE 4.2.  SSE 4.2 was first supported in Nehalem processors
   introduced in November, 2008.  This does not check for the existence of the
   cpuid instruction itself, which was introduced on the 486SL in 1992, so this
   will fail on earlier x86 processors.  cpuid works on all Pentium and later
   processors. */
#define SSE42(have) \
    do { \
        uint32_t eax, ecx; \
        eax = 1; \
        __asm__("cpuid" \
                : "=c"(ecx) \
                : "a"(eax) \
                : "%ebx", "%edx"); \
        (have) = (ecx >> 20) & 1; \
    } while (0)

/* Compute a CRC-32C.  If the crc32 instruction is available, use the hardware
   version.  Otherwise, use the software version. */
uint32_t crc32c(uint32_t crc, const void *buf, size_t len)
{
    int sse42;

    SSE42(sse42);
    return sse42 ? crc32c_hw(crc, buf, len) : crc32c_sw(crc, buf, len);
}

#ifdef TEST

#define SIZE (262144*3)
#define CHUNK SIZE

int main(int argc, char **argv)
{
    char *buf;
    ssize_t got;
    size_t off, n;
    uint32_t crc;

    (void)argv;
    crc = 0;
    buf = malloc(SIZE);
    if (buf == NULL) {
        fputs("out of memory", stderr);
        return 1;
    }
    while ((got = read(0, buf, SIZE)) > 0) {
        off = 0;
        do {
            n = (size_t)got - off;
            if (n > CHUNK)
                n = CHUNK;
            crc = argc > 1 ? crc32c_sw(crc, buf + off, n) :
                             crc32c(crc, buf + off, n);
            off += n;
        } while (off < (size_t)got);
    }
    free(buf);
    if (got == -1) {
        fputs("read error\n", stderr);
        return 1;
    }
    printf("%08x\n", crc);
    return 0;
}

#endif /* TEST */
  • 6
    That was written for the GNU compiler (gcc), which uses the AT&T syntax for assembler instructions, as opposed to the Intel syntax. The AT&T syntax is much more clear about what instruction is generated, since it doesn't depend on argument typing for that (e.g. dword ptr, etc.). Your assembler probably uses the Intel syntax, where the crc32 "instruction" can actually generate one of six different instructions. Which one has to be determined by the assembler, as well as by a human attempting to read the code, based on the nature of the arguments. – Mark Adler Jul 16 '13 at 14:46
  • 4
    The reason to process 3 buffers in parallel is that the CRC32C instruction is pipelined and has a 3 cycle latency with 1 cycle throughput - you can get one CRC32C instruction retiring every clock cycle provided the result isn't used as input to another CRC32C instruction for 3 cycles... there is only one ALU capable of executing CRC32C - instructions dispatch to it through port 1, this ALU does "complex/slow" integer instructions. The other ALUs cannot handle CRC32C. intel.com/content/dam/www/public/us/en/documents/manuals/… – amdn Aug 1 '13 at 20:10
  • 2
    Thanks! I misconstrued why doing four CRC instructions in parallel doesn't help. I will fix the comments. – Mark Adler Aug 2 '13 at 0:11
  • 2
    I have wrapped the code in a library for Windows and added .NET wrapper and NuGet packages. I've also speeded up the software fallback by 50%. – Robert Važan Feb 19 '14 at 22:07
  • 1
    Nice answer, but note that C++ constexpr initialization of lookup tables may be faster than this C version since you may pay a little cost on every call because of that pthread_once_t – NoSenseEtAl Jun 17 at 21:26

Mark Adler's answer is correct and complete, but those seeking quick and easy way to integrate CRC-32C in their application might find it a little difficult to adapt the code, especially if they are using Windows and .NET.

I've created a library that implements CRC-32C using either hardware or software method depending on available hardware. It's available as a NuGet package for C++ and .NET. It's opensource of course.

Besides packaging Mark Adler's code above, I've found a simple way to improve throughput of the software fallback by 50%. On my computer, the library now achieves 2 GB/s in software and over 20 GB/s in hardware. For those curious, here's the optimized software implementation:

static uint32_t append_table(uint32_t crci, buffer input, size_t length)
{
    buffer next = input;
#ifdef _M_X64
    uint64_t crc;
#else
    uint32_t crc;
#endif

    crc = crci ^ 0xffffffff;
#ifdef _M_X64
    while (length && ((uintptr_t)next & 7) != 0)
    {
        crc = table[0][(crc ^ *next++) & 0xff] ^ (crc >> 8);
        --length;
    }
    while (length >= 16)
    {
        crc ^= *(uint64_t *)next;
        uint64_t high = *(uint64_t *)(next + 8);
        crc = table[15][crc & 0xff]
            ^ table[14][(crc >> 8) & 0xff]
            ^ table[13][(crc >> 16) & 0xff]
            ^ table[12][(crc >> 24) & 0xff]
            ^ table[11][(crc >> 32) & 0xff]
            ^ table[10][(crc >> 40) & 0xff]
            ^ table[9][(crc >> 48) & 0xff]
            ^ table[8][crc >> 56]
            ^ table[7][high & 0xff]
            ^ table[6][(high >> 8) & 0xff]
            ^ table[5][(high >> 16) & 0xff]
            ^ table[4][(high >> 24) & 0xff]
            ^ table[3][(high >> 32) & 0xff]
            ^ table[2][(high >> 40) & 0xff]
            ^ table[1][(high >> 48) & 0xff]
            ^ table[0][high >> 56];
        next += 16;
        length -= 16;
    }
#else
    while (length && ((uintptr_t)next & 3) != 0)
    {
        crc = table[0][(crc ^ *next++) & 0xff] ^ (crc >> 8);
        --length;
    }
    while (length >= 12)
    {
        crc ^= *(uint32_t *)next;
        uint32_t high = *(uint32_t *)(next + 4);
        uint32_t high2 = *(uint32_t *)(next + 8);
        crc = table[11][crc & 0xff]
            ^ table[10][(crc >> 8) & 0xff]
            ^ table[9][(crc >> 16) & 0xff]
            ^ table[8][crc >> 24]
            ^ table[7][high & 0xff]
            ^ table[6][(high >> 8) & 0xff]
            ^ table[5][(high >> 16) & 0xff]
            ^ table[4][high >> 24]
            ^ table[3][high2 & 0xff]
            ^ table[2][(high2 >> 8) & 0xff]
            ^ table[1][(high2 >> 16) & 0xff]
            ^ table[0][high2 >> 24];
        next += 12;
        length -= 12;
    }
#endif
    while (length)
    {
        crc = table[0][(crc ^ *next++) & 0xff] ^ (crc >> 8);
        --length;
    }
    return (uint32_t)crc ^ 0xffffffff;
}

As you can see, it merely crunches larger block at a time. It needs larger lookup table, but it's still cache-friendly. The table is generated the same way, only with more rows.

One extra thing I explored is the use of PCLMULQDQ instruction to get hardware acceleration on AMD processors. I've managed to port Intel's CRC patch for zlib (also available on GitHub) to CRC-32C polynomial except the magic constant 0x9db42487. If anyone is able to decipher that one, please let me know. After supersaw7's excellent explanation on reddit, I have ported also the elusive 0x9db42487 constant and I just need to find some time to polish and test it.

  • +1 Thanks for sharing your code. It helps me a lot when porting it to Delphi. – Arnaud Bouchez May 27 '14 at 6:49
  • I fixed the link to the patch and added some additional links. Did you progress on this issue, Robert? – Janus Troelsen Mar 22 '15 at 13:36
  • it seems that cloudflare's zlib with PCLMULQDQ support does not use the constant... maybe that is useful to you? – Janus Troelsen Mar 22 '15 at 16:14
  • PCLMULQDQ is no longer a mystery. See updated answer. – Robert Važan Mar 26 '15 at 11:42

I compare various algorithms here: https://github.com/htot/crc32c

The fastest algorithm has been taken from Intels crc_iscsi_v_pcl.asm assembly code (which is available in a modified form in the linux kernel) and using a C wrapper (crcintelasm.cc) included into this project.

To be able to run this code on 32 bit platforms first it has been ported to C (crc32intelc) where possible, a small amount of inline assembly is required. Certain parts of the code depend on the bitness, crc32q is not available on 32 bits and neither is movq, these are put in macro's (crc32intel.h) with alternative code for 32 bit platforms.

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