I want to load 4 doubles into a 256 bit register and pad with 0's if the array size is less than 4.

register __m256d c = _mm256_loadu_pd(C);

Now suppose C had just three elements in it, I want to pad the last "entry" in register c to 0. How can I do this efficiently?

  • 2
    There's always vmaskmovpd which can even do fault-suppression if that last element happens to be in an unmapped page. Do you need that? See also Intel store instructions on delibrately overlapping memory regions for some info about efficiency of vmaskmov (mostly for stores, but it is efficient for loads on AMD, unlike for stores). – Peter Cordes Jan 22 '20 at 3:30
  • @PeterCordes that would require me to specify a mask.. looking for a simpler option – midi Jan 22 '20 at 5:39
  • 1
    Yes, you'd need a mask, which you could get from a load from a sliding window onto an array of -1, -1, -1, 0,0,0. Vectorizing with unaligned buffers: using VMASKMOVPS: generating a mask from a misalignment count? Or not using that insn at all. Or you could maybe generate it on the fly from the length, like (1ULL<<(n*8)) - 1 and vmovd to an XMM + vpmovsxbq ymm, xmm. You don't have a lot of good options, unfortunately, especially if you can't pad the source data to guarantee that it's at least save to load 32 bytes from the pointer C. – Peter Cordes Jan 22 '20 at 5:47
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    Until AVX512 makes masking a first-class operation (and probably even then), you're definitely going to want to peel out handling the tail of a big array, or the whole small array, separate from your main loop. For tail handling in larger arrays, it can work to do a load that ends at the last element (potentially overlapping with earlier loads if the array size isn't a multiple of the vector width). For vertical SIMD copying into a dst array you can just let the store overlap, but for a horizontal sum or something yeah you need to avoid double-counting the overlap so this way doesn't work. – Peter Cordes Jan 22 '20 at 5:50
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    Correction: VPERM2F128 takes a 256bit memory operand, so you'll actually need a separate 128 bit load. And in that case you can also do VINSERTF128 to combine both halves. This is what _mm256_set[r]_m128d will generate for you: godbolt.org/z/yifEK_ – chtz Jan 22 '20 at 10:04

Here’s one method. Unlike _mm256_maskload_pd, the function below doesn’t need to load or create the mask.

// Load 3 doubles from memory, zero out the 4-th one.
inline __m256d load3( const double* source )
    const __m128d low = _mm_loadu_pd( source );
    const __m128d high = _mm_load_sd( source + 2 );
    return _mm256_set_m128d( high, low );   // vinsertf128

For completeness, here’s 2 other variants.

// Zero out the high 2 double lanes.
inline __m256d zeroupper( __m128d low2 )
    const __m256d low = _mm256_castpd128_pd256( low2 ); // no instruction
    const __m256d zero = _mm256_setzero_pd();   // vxorpd
    // vblendpd is 4-5 times faster than vinsertf128
    return _mm256_blend_pd( zero, low, 3 ); // vblendpd
// Load 2 doubles from memory, zero out other 2
inline __m256d load2( const double* source )
    return zeroupper( _mm_loadu_pd( source ) );
// Load 1 double from memory, zero out the other 3
inline __m256d load1( const double* source )
    return zeroupper( _mm_load_sd( source ) );
  • 1
    vblendpd is 4-5 times faster than vinsertf128 uh, what? On Zen 1, vinsertf128 is actually faster. On Intel, both are single uop but vinsertf128 is a lane-crossing shuffle (3c latency, 1c throughput on HSW/SKL) while vblendpd is 1c latency, 0.333c throughput on Haswell/Skylake). If you were trying to benchmark these intrinsics, then hopefully a good compiler would optimize away the _mm256_blend_pd entirely and just use vmovupd xmm, [mem] to zero-extend to 256 bits. But some compilers (like MSVC and ICC) won't optimize away intrinsics. – Peter Cordes Jan 24 '20 at 1:28
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    In practice, clang optimizes away the blend-with-zero for the case where it's actually loading (not using a value that was already in a register). But GCC9.2 doesn't. godbolt.org/z/5ZXsR7. Use _mm256_set_pd(0,0,0, *source); to get efficient asm from gcc and clang: just a vmovsd or vmovq load. But MSVC still faceplants on that, using a stupid vshufpd + vinsertf128 after a zero-extending load instruction. godbolt.org/z/ww4uLL – Peter Cordes Jan 24 '20 at 1:32
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    @PeterCordes Indeed, just using _mm256_set[r]_pd already generates the most efficient code on clang/gcc, for all sizes from 1-3: godbolt.org/z/qEYrex – chtz Jan 24 '20 at 10:05

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