Why in the world was _mm_crc32_u64(...) defined like this?

unsigned int64 _mm_crc32_u64( unsigned __int64 crc, unsigned __int64 v );

The "crc32" instruction always accumulates a 32-bit CRC, never a 64-bit CRC (It is, after all, CRC32 not CRC64). If the machine instruction CRC32 happens to have a 64-bit destination operand, the upper 32 bits are ignored, and filled with 0's on completion, so there is NO use to EVER have a 64-bit destination. I understand why Intel allowed a 64-bit destination operand on the instruction (for uniformity), but if I want to process data quickly, I want a source operand as large as possible (i.e. 64-bits if I have that much data left, smaller for the tail ends) and always a 32-bit destination operand. But the intrinsics don't allow a 64-bit source and 32-bit destination. Note the other intrinsics:

unsigned int _mm_crc32_u8 ( unsigned int crc, unsigned char v ); 

The type of "crc" is not an 8-bit type, nor is the return type, they are 32-bits. Why is there no

unsigned int _mm_crc32_u64 ( unsigned int crc, unsigned __int64 v );

? The Intel instruction supports this, and that is the intrinsic that makes the most sense.

Does anyone have portable code (Visual Studio and GCC) to implement the latter intrinsic? Thanks. My guess is something like this:

#define CRC32(D32,S) __asm__("crc32 %0, %1" : "+xrm" (D32) : ">xrm" (S))

for GCC, and

#define CRC32(D32,S) __asm { crc32 D32, S }

for VisualStudio. Unfortunately I have little understanding of how constraints work, and little experience with the syntax and semantics of assembly level programming.

Small edit: note the macros I've defined:

#define GET_INT64(P) *(reinterpret_cast<const uint64* &>(P))++
#define GET_INT32(P) *(reinterpret_cast<const uint32* &>(P))++
#define GET_INT16(P) *(reinterpret_cast<const uint16* &>(P))++
#define GET_INT8(P)  *(reinterpret_cast<const uint8 * &>(P))++

#define DO1_HW(CR,P) CR =  _mm_crc32_u8 (CR, GET_INT8 (P))
#define DO2_HW(CR,P) CR =  _mm_crc32_u16(CR, GET_INT16(P))
#define DO4_HW(CR,P) CR =  _mm_crc32_u32(CR, GET_INT32(P))
#define DO8_HW(CR,P) CR = (_mm_crc32_u64((uint64)CR, GET_INT64(P))) & 0xFFFFFFFF;

Notice how different the last macro statement is. The lack of uniformity is certainly and indication that the intrinsic has not been defined sensibly. While it is not necessary to put in the explicit (uint64) cast in the last macro, it is implicit and does happen. Disassembling the generated code shows code for both casts 32->64 and 64->32, both of which are unnecessary.

Put another way, it's _mm_crc32_u64, not _mm_crc64_u64, but they've implemented it as if it were the latter.

If I could get the definition of CRC32 above correct, then I would want to change my macros to

#define DO1_HW(CR,P) CR = CRC32(CR, GET_INT8 (P))
#define DO2_HW(CR,P) CR = CRC32(CR, GET_INT16(P))
#define DO4_HW(CR,P) CR = CRC32(CR, GET_INT32(P))
#define DO8_HW(CR,P) CR = CRC32(CR, GET_INT64(P))
  • Does anyone have portable code (Visual Studio and GCC) to implement the latter intrinsic? Thanks. --> What have you tried??? ... ???????? And note that "8-bits" is not a type. – Sebastian Mach Apr 5 '13 at 18:58
  • And note there is no need to be that rude. If you are more "brilliant" than the "silly" person you are calling out for (as in "Who was the "brilliant" person who defined"): Why don't you try to contact the copyright owner of the code? – Sebastian Mach Apr 5 '13 at 19:03
  • OK, I'll tone it down, but the "owner" of the code is Microsoft, and when was the last time you had success contacting Microsoft? In any event, it's not a question of "trying" something really - the intrinsic works, and the code above works. The issue is that I need maximal performance, and the intrinsic does not allow this, and for no good reason. The question "Why was (itA) defined like this?" is rhetorical - it should have been defined differently. The point of my post was to see if anyone had tested code to do it properly, code that has been tested multi-platform. – David I. McIntosh Apr 5 '13 at 19:11
  • While I can write the code, I cannot test it on all the platforms where people may be using my code, hence I was hoping someone who is better at low-level programming than I had some useful code. – David I. McIntosh Apr 5 '13 at 19:13
  • Actually you asked "Who wrote it", not "Why was it written like that". And I never tried to contact Microsoft, because I don't use any microsoft products for work; however, did you? – Sebastian Mach Apr 5 '13 at 19:22

Does anyone have portable code (Visual Studio and GCC) to implement the latter intrinsic? Thanks.

My friend and I wrote a c++ sse intrinsics wrapper which contains the more preferred usage of the crc32 instruction with 64bit src.


See the i_crc32() instruction. (sadly there are even more flaws with intel's sse intrinsic specifications on other instructions, see this page for more examples of flawed intrinsic design)

  • Thanks very much. This is exactly the sort of thing I was looking for! I will look and see if it give me what I need. Thanks again. – David I. McIntosh Apr 16 '13 at 17:39
  • Your header file has the comment "(and yes, the 64-bit CRC32 generates an effective 32-bit result)". Are you saying the declaration unsigned __int64 _mm_crc32_u64( unsigned __int64 crc, unsigned __int64 v ); in the VisualStudio header files is incorrect and/or misleading? Because I notice your USE of the _mm_crc32_u64 intrinsic is as if it had been declared as I was claiming it should have been, i.e. as if it were unsigned __int32 _mm_crc32_u64( unsigned __int32 crc, unsigned __int64 v );. thanks. – David I. McIntosh Apr 16 '13 at 20:07
  • Hey David, sorry for the late reply. Yes you're correct. – cottonvibes Jun 26 '13 at 19:06
  • 2
    Basically the x64 crc32 instruction which uses the 64bit gpr registers as operands leave the upper 32bits as 0 for the result, and only the lower 32bits contain the legit data. The return type was made "__int64" in the intrinsic because the result is returned in a 64bit gpr in the real asm instruction. – cottonvibes Jun 26 '13 at 19:13
  • The code is no longer available for casual browsing because Google Code is effectively shutdown. Perhaps you can add the relevant portions to your answer. – jww Apr 24 '16 at 12:59

The 4 intrinsic functions provided really do allow all possible uses of the Intel defined CRC32 instruction. The instruction output always 32-bits because the instruction is hard-coded to use a specific 32-bit CRC polynomial. However, the instruction allows your code to feed input data to it 8, 16, 32, or 64 bits at a time. Processing 64-bits at a time should maximize throughput. Processing 32-bits at a time is the best you can do if restricted to 32-bit build. Processing 8 or 16 bits at a time could simplify your code logic if the input byte count is odd or or not a multiple of 4/8.

#include <stdio.h>
#include <stdint.h>
#include <intrin.h>

int main (int argc, char *argv [])
    int index;
    uint8_t *data8;
    uint16_t *data16;
    uint32_t *data32;
    uint64_t *data64;
    uint32_t total1, total2, total3;
    uint64_t total4;
    uint64_t input [] = {0x1122334455667788, 0x1111222233334444};

    total1 = total2 = total3 = total4 = 0;
    data8  = (void *) input;
    data16 = (void *) input;
    data32 = (void *) input;
    data64 = (void *) input;

    for (index = 0; index < sizeof input / sizeof *data8; index++)
        total1 = _mm_crc32_u8 (total1, *data8++);

    for (index = 0; index < sizeof input / sizeof *data16; index++)
        total2 = _mm_crc32_u16 (total2, *data16++);

    for (index = 0; index < sizeof input / sizeof *data32; index++)
        total3 = _mm_crc32_u32 (total3, *data32++);

    for (index = 0; index < sizeof input / sizeof *data64; index++)
        total4 = _mm_crc32_u64 (total4, *data64++);

    printf ("CRC32 result using 8-bit chunks: %08X\n", total1);
    printf ("CRC32 result using 16-bit chunks: %08X\n", total2);
    printf ("CRC32 result using 32-bit chunks: %08X\n", total3);
    printf ("CRC32 result using 64-bit chunks: %08X\n", total4);
    return 0;
  • 1
    Nope. Notice your declaration for total4 differs from the declaration for total1, total2 and total3. If we are to make mixed use of _mm_crc32_u64, _mm_crc32_u32, _mm_crc32_u16 and _mm_crc32_u8, we need to do data type conversions between use of _mm_crc32_u64 and all the others. Admittedly they are trivial, but they are also completely unnecessary - as I said, there is NO point in using a 64-bit destination data type. – David I. McIntosh Apr 3 '13 at 16:37
  • To be more specific, given const uint8_t *data; unsigned long total = 0xFFFFFFFFUL; int nSize = sizeof input data;, I can do this: //Align memory on 4-byte boundary for(; nSize>0 && (data&3)!=0; --nSize) total = _mm_crc32_u8(total, *data++); for( ; nSize>=4; nSize -= 4 ) total = _mm_crc32_u32(total, *(reinterpret_cast<const uint32_t* &>(data))++); if( nSize>=2 ) { total = _mm_crc32_u16(total, *(reinterpret_cast<const uint16_t* &>(data))++); nSize -=2; } if( nSize>0 ) total = _mm_crc32_u8(total, *data++); – David I. McIntosh Apr 3 '13 at 16:57
  • But I can't do this: for(; nSize>0 && (data&3)!=0; --nSize) total = _mm_crc32_u8 (total, *data++); for( ; nSize>=8; nSize -= 8 ) total = _mm_crc32_u64(total, *(reinterpret_cast<const uint64_t* &>(data))++); if( nSize>=4 ) { total = _mm_crc32_u32(total, *(reinterpret_cast<const uint32_t* &>(data))++); nSize -= 4; } if( nSize>=2 ) { total = _mm_crc32_u16(total, *(reinterpret_cast<const uint16_t* &>(data))++); nSize -=2; } if( nSize>0 ) total = _mm_crc32_u8(total, *data++); – David I. McIntosh Apr 4 '13 at 15:12
  • without incurring a cost before the first for-loop of transforming my 32-bit "total" to a 64-bit "total64", which is completely unnecessary and silly. I.e. the 64-bit loop needs to be: for( ; nSize>=8; nSize -= 8 ) total = _mm_crc32_u64(total, *(reinterpret_cast<const uint64_t* &>(data))++)&0xFFFFFFFF; and there is also an implicit conversion of the first parameter to _mm_crc32_u64 from 32 bit to 64 bit. – David I. McIntosh Apr 4 '13 at 15:14
  • @DavidI.McIntosh: Why do you think that case would have any cost at all? x86-64 zero-extends for free, so unless your compiler sucks at optimizing there's no real cost to a 64-bit type for the accumulator / retval. (The compiler might not "know" that the high 32 bits are zero., but that only matters if you explicitly wrote 1 + (uint64_t)(uint32_t)retval, it might spend an instruction zero-extending. Normally would just invert the result to post-process and then store it to memory. – Peter Cordes Jun 18 '18 at 1:20

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