I am trying to vectorize the following function with clang according to this clang reference. It takes a vector of byte array and applies a mask according to this RFC.

static void apply_mask(vector<uint8_t> &payload, uint8_t (&masking_key)[4]) {
  #pragma clang loop vectorize(enable) interleave(enable)
  for (size_t i = 0; i < payload.size(); i++) {
    payload[i] = payload[i] ^ masking_key[i % 4];

The following flags are passed to clang:


However, the vectorization fails with the following error:

In file included from boost/asio/io_service.hpp:767:
In file included from boost/asio/impl/io_service.hpp:19:
In file included from boost/asio/detail/service_registry.hpp:143:
In file included from boost/asio/detail/impl/service_registry.ipp:19:
c++/v1/vector:1498:18: remark: loop not vectorized: could not determine number
      of loop iterations [-Rpass-analysis]
    return this->__begin_[__n];
c++/v1/vector:1498:18: error: loop not vectorized: failed explicitly specified
      loop vectorization [-Werror,-Wpass-failed]

How do I vectorize this for loop?

  • 1
    This loop looks trivial to vectorize. Have you checked whether the compiler does it implicitly with plain -03? – Baum mit Augen May 20 '16 at 16:20
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    I did and checked with -Rpass-analysis=loop-vectorize flag. It does not vectorize implicitly, which is why I added explicit #pragma flags. – rahul May 20 '16 at 16:24
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    I wonder if it's an an aliasing issue - can you try applying restrict (and/or const) to uint8_t (&masking_key)[4] ? – Paul R May 20 '16 at 16:30
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    @PaulR const will probably not help as one can have const& to non const data. restrict is worth a shot though. – Baum mit Augen May 20 '16 at 16:32
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    Using an std::array passed by value for the key would also eliminate all potential aliasing problems. – Baum mit Augen May 20 '16 at 16:37

Thanks to @PaulR and @PeterCordes. Unrolling the loop by a factor of 4 works.

void apply_mask(vector<uint8_t> &payload, const uint8_t (&masking_key)[4]) {
  const size_t size = payload.size();
  const size_t size4 = size / 4;
  size_t i = 0;
  uint8_t *p = &payload[0];
  uint32_t *p32 = reinterpret_cast<uint32_t *>(p);
  const uint32_t m = *reinterpret_cast<const uint32_t *>(&masking_key[0]);

#pragma clang loop vectorize(enable) interleave(enable)
  for (i = 0; i < size4; i++) {
    p32[i] = p32[i] ^ m;

  for (i = (size4*4); i < size; i++) {
    p[i] = p[i] ^ masking_key[i % 4];

gcc.godbolt code

| improve this answer | |
  • 1
    That was Paul's idea actually. :) – Baum mit Augen May 20 '16 at 16:56
  • 2
    Unrolling is the only way to get it vectorized, I tried on all compilers on gcc.godbolt and no one was able to vectorize without unrolling. – CoffeDeveloper May 20 '16 at 16:58
  • Can you link to gcc.godbolt.org with vectorized output? The only "vectorization" I'm ever getting with clang is a bunch of vpaddq(purpose unknown) and 32xvpinsrb / vpxor / 32xvpextrb. This is obviously worse than scalar. Even when avoiding aliasing getting the masking keys and payload.data() into locals, it still doesn't want to autovectorize (but at least avoids the pointer from payload after every byte store). – Peter Cordes May 20 '16 at 17:48
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    That's what I found too; I had to put all 4 keys into a uint32_t. (But I used memcpy instead of a reinterpret cast; either way optimizes away completely on x86.) Your godbolt link doesn't enable optimizations, and has static on the function so we can't see the asm for the function itself. Anyway, here's what you should have posted for a godbolt link. Don't forget to update the code in your answer, since the code in the code block is still useless. – Peter Cordes May 20 '16 at 18:24
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    @rahul: if you have a Haswell or newer, build with -march=native to let it use AVX2. The asm in the link I posted looks pretty much optimal for SSE, and should sustain one 16B vector per clock if the input buffer is 16B-aligned. With -march=haswell, it does the same but with 32B vectors. With -march=sandybridge, it avoids unaligned 32B loads/stores, instead doing them in 16B halves. (The vextractf128 to a register instead of directly to memory looks like a bad idea. Same number of fused-domain uops, but competes for port5 with vxorps :/) – Peter Cordes May 20 '16 at 18:40

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