I need to replicate a 6-byte integer value into a memory region, starting with its beginning and as quickly as possible. If such an operation is supported in hardware, I'd like to use it (I'm on x64 processors now, compiler is GCC 4.6.3).

The memset doesn't suit the job, because it can replicate bytes only. The std::fill isn't good either, because I even can't define an iterator, jumping between 6 byte-width positions in the memory region.

So, I'd like to have a function:

void myMemset(void* ptr, uint64_t value, uint8_t width, size_t num)

This looks like memset, but there is an additional argument width to define how much bytes from the value to replicate. If something like that could be expressed in C++, that would be even better.

I already know about obvious myMemset implementation, which would call the memcpy in loop with last argument (bytes to copy) equal to the width. Also I know, that I can define a temporary memory region with size 6 * 8 = 48 bytes, fill it up with 6-byte integers and then memcpy it to the destination area.

Can we do better?

  • 2
    I think that your last approach is the best we can get. Fill a small region of n bytes manually, then memcpy it once to double, then memcpy the doubled region of 2 n bytes to get 4 n bytes and so forth. Finally, memcpy the last portion (which, in general, will not be a power of two) to complete the task. You'll only have a logarithmic number of function calls. – 5gon12eder Feb 16 '15 at 22:16
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    I don't understand what memset() and std:fill can do for you, since you say you want to replicate a number, not clear it. memcpy(&destination,&source,6) is the best, what do you think could be improved? – Mike Nakis Feb 16 '15 at 22:16
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    You can expand on your last idea and go even larger than 48 bytes. For that matter you can make it recursive; fill the first 6 bytes manually, then use memcpy to expand it to 12 bytes, expand to 24 bytes, 48 bytes, etc. – Mark Ransom Feb 16 '15 at 22:20
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    I'm curious as to why you're using 6-byte integers. If it's to conserve space, I'd recommend you reconsider. The speedup by using naturally-aligned 8-byte integers will probably outweigh the space savings, even if you don't use SSE instructions on your data. But you haven't really told us what you're doing. – Jonathon Reinhart Feb 16 '15 at 22:43
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    The most C++ way would be an iterator and std::copy: coliru.stacked-crooked.com/a/7a521244b39e3567 Why do you need something faster? – Mooing Duck Feb 17 '15 at 0:21

Write 8 bytes at a time.

Being on a 64-bit machine, certainly the generated code can operate well with 8-byte writes. After dealing with some set-up issues, in a tight loop, write 8-bytes per write about num times. Assumptions apply - see code.

// assume little endian
void myMemset(void* ptr, uint64_t value, uint8_t width, size_t num) {
  assert(width > 0 && width <= 8);

  uint64_t *ptr64 = (uint64_t *) ptr;
  // # to stop early to prevent writing past array end
  static const unsigned stop_early[8 + 1] = { 0, 8, 3, 2, 1, 1, 1, 1, 0 };
  size_t se = stop_early[width];
  if (num > se) {
    num -= se;

    // assume no bus-fault with 64-bit write @ `ptr64, ptr64+1, ... ptr64+7`
    while (num > 0) { // tight loop
      *ptr64 = value;
      ptr64 = (uint64_t *) ((char *) ptr64 + width);

    ptr = ptr64;
    num = se;
  // Cope with last few writes
  while (num-- > 0) {
    memcpy(ptr, &value, width);
    ptr = (char *) ptr + width;

Further optimization includes writing 2 blocks at a time width == 3 or 4, 4 blocks at a time when width == 2 and 8 blocks at a time width == 1.

  • Are you saying that this code is faster than the code in your previous answer (with multibyte copying)? – HEKTO Feb 17 '15 at 20:44
  • Also i'm afraid it will overwrite previosly written bytes – HEKTO Feb 17 '15 at 20:48
  • @HEKTO Faster depends of the compiler, allowable compiler settings, platform and data set. (you have provide 2 of those 4) This is just another candidate for the horse race. Yes is does overwrite previously written bytes, that is not the issue as the bytes overwritten need to be overwritten. The issues is does it get the correct job done fastest? Why care if ti over-writes some bytes? What is nice here is the tight loop does not need to read the source data repeatedly. Once source is in value, likely kept in a register for optimized code. – chux - Reinstate Monica Feb 17 '15 at 21:04
  • Probably your idea (for width = 6) is to copy two lowest bytes of the value to its highest bytes - then the overwriting won't be destructive, but I don't see that in your code – HEKTO Feb 17 '15 at 21:39
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    Got it - it'll overwrite unused highest bytes – HEKTO Feb 17 '15 at 22:50

Something along @Mark Ransom comment:

Copy 6 bytes, then 6, 12, 24, 48, 96, etc.

void memcpy6(void *dest, const void *src, size_t n /* number of 6 byte blocks */) {
  if (n-- == 0) {
  memcpy(dest, src, 6);
  size_t width = 1;
  while (n >= width) {
    memcpy(&((char *) dest)[width * 6], dest, width * 6);
    n -= width;
    width <<= 1; // double w
  if (n > 0) {
    memcpy(&((char *) dest)[width * 6], dest, n * 6);

Optimization: scale n and width by 6.

Corrected destination @SchighSchagh
Added cast (char *)

  • This got me thinking: dividing the amount of memory to fill by 6 gives you a bit set indicating 'what to do'. However, a head cold is wreaking havoc with my math skills and so I cannot deduce what 'what' is supposed to be. (Doubling the copy size? Incrementing the copy-to pointer? Both?) – usr2564301 Feb 16 '15 at 22:32
  • @Jongware Yes, double the width of the copy per each iteration, copying the initial portion of the destination as the source to the the next ever increasing offset offset in the destination. – chux - Reinstate Monica Feb 16 '15 at 22:39
  • It takes a bit of extra processing inside the supposedly tight inner loop, but on the other hand, your current way stops at 64 if it has to fill 127 sextuples, and reverts to 'dumb' copying after that. – usr2564301 Feb 16 '15 at 22:42
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    @Jongware For 127 blocks, first memcpy() of 1 block, then loop copies, 1,2,4,8,16,32,64 blocks. Last memcpy() copies 31 blocks. – chux - Reinstate Monica Feb 16 '15 at 22:52
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    A true function call to memcpy() is actually quite expensive. The majority of the code in memcpy() deals with memory alignment issues. Not to mention that a true call to memcpy() will always read in order to write; if you can avoid the reading and only write the contents of registers, then you have a clear winner. – Mike Nakis Feb 16 '15 at 22:58

Determine the most efficient write size that the CPU supports; then find the smallest number that can be evenly divided by both 6 and that write size and call that "block size".

Now split the memory region up into blocks of that size. Each block will be identical and all writes will be correctly aligned (assuming the memory region itself is correctly aligned).

For example, if the most efficient write size that the CPU supports is 4 bytes (e.g. ancient 80486) then the "size of block" would be 12 bytes. You'd set 3 general purpose registers and do 3 stores per block.

For another example, if the most efficient write size that the CPU supports is 16 bytes (e.g. SSE) then the "size of block" would be 48 bytes. You'd set 3 SSE registers and do 3 stores per block.

Also, I'd recommend rounding the size of the memory region up to ensure it is a multiple of the block size (with some "not strictly necessary" padding). A few unnecessary writes are less expensive than code to fill a "partial block".

The second most efficient method might be to use a memory copy (but not memcpy() or memmove()). In this case you'd write the initial 6 bytes (or 12 bytes or 48 bytes or whatever), then copy from (e.g.) &area[0] to &area[6] (working from lowest to highest) until you reach the end. For this memmove() will not work because it will notice the area is overlapping and work from highest to lowest instead; and memcpy() will not work because it assumes the source and destination do not overlap; so you'd have to create your own memory copy to suit. The main problem with this is that you double the number of memory accesses - "reading and writing" is slower than "writing alone".


If your Num is large enough, you can try using the AVX vector instructions that will handle 32 bytes at a time (_mm256_load_si256/_mm256_store_si256 or their unaligned variants).

As 32 is not a multiple of 6, you will have to first replicate the 6 bytes pattern 16 times using short memcpy's or 32/64 bits moves.


You will also finish with a short memcpy.


Try the __movsq intrinsic (x64 only; in assembly, rep movsq) that will move 8 bytes at a time, with a suitable repetition factor, and setting the destination address 6 bytes after the source. Check that overlapping addresses are handled smartly.

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