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I have created a function which does 64-bit * 64-bit to 128-bit using SIMD. Currently I have implemented it using SSE2 (acutally SSE4.1). This means it does two 64b*64b to 128b products at the same time. The same idea could be extended to AVX2 or AVX512 giving four or eight 64b*64 to 128b products at the same time. I based my algorithm on http://www.hackersdelight.org/hdcodetxt/muldws.c.txt

That algorithm does one unsigned multiplication, one signed multiplication, and two signed * unsigned multiplications. The signed * signed and unsigned * unsigned operations are easy to do using _mm_mul_epi32 and _mm_mul_epu32. But the mixed signed and unsigned products caused me trouble. Consider for example.

int32_t x = 0x80000000;
uint32_t y = 0x7fffffff;
int64_t z = (int64_t)x*y;

The double word product should be 0xc000000080000000. But how can you get this if you assume your compiler does know how to handle mixed types? This is what I came up with:

int64_t sign = x<0; sign*=-1;        //get the sign and make it all ones
uint32_t t = abs(x);                 //if x<0 take two's complement again
uint64_t prod = (uint64_t)t*y;       //unsigned product
int64_t z = (prod ^ sign) - sign;    //take two's complement based on the sign

Using SSE this can be done like this

__m128i xh;    //(xl2, xh2, xl1, xh1) high is signed, low unsigned
__m128i yl;    //(yh2, yl2, yh2, yl2)
__m128i xs     = _mm_cmpgt_epi32(_mm_setzero_si128(), xh); // get sign
        xs     = _mm_shuffle_epi32(xs, 0xA0);              // extend sign
__m128i t      = _mm_sign_epi32(xh,xh);                    // abs(xh)
__m128i prod   = _mm_mul_epu32(t, yl);                     // unsigned (xh2*yl2,xh1*yl1)
__m128i inv    = _mm_xor_si128(prod,xs);                   // invert bits if negative
__m128i z      = _mm_sub_epi64(inv,xs);                    // add 1 if negative

This gives the correct result. But I have to do this twice (once when squaring) and it's now a significant fraction of my function. Is there a more efficient way of doing this with SSE4.2, AVX2 (four 128bit products), or even AVX512 (eight 128bit products)?

Maybe there are more efficient ways of doing this than with SIMD? It's a lot of calculations to get the upper word.

Edit: based on the comment by @ElderBug it looks like the way to do this is not with SIMD but with the mul instruction. For what it's worth, in case anyone want's to see how complicated this is, here is the full working function (I just got it working so I have not optimized it but I don't think it's worth it).

void muldws1_sse(__m128i x, __m128i y, __m128i *lo, __m128i *hi) {
    __m128i lomask = _mm_set1_epi64x(0xffffffff);

    __m128i xh     = _mm_shuffle_epi32(x, 0xB1);    // x0l, x0h, x1l, x1h
    __m128i yh     = _mm_shuffle_epi32(y, 0xB1);    // y0l, y0h, y1l, y1h

    __m128i xs     = _mm_cmpgt_epi32(_mm_setzero_si128(), xh);
    __m128i ys     = _mm_cmpgt_epi32(_mm_setzero_si128(), yh);
            xs     = _mm_shuffle_epi32(xs, 0xA0);
            ys     = _mm_shuffle_epi32(ys, 0xA0);

    __m128i w0     = _mm_mul_epu32(x,  y);          // x0l*y0l, y0l*y0h
    __m128i w3     = _mm_mul_epi32(xh, yh);         // x0h*y0h, x1h*y1h
            xh     = _mm_sign_epi32(xh,xh);
            yh     = _mm_sign_epi32(yh,yh);

    __m128i w1     = _mm_mul_epu32(x,  yh);         // x0l*y0h, x1l*y1h
    __m128i w2     = _mm_mul_epu32(xh, y);          // x0h*y0l, x1h*y0l

    __m128i yinv   = _mm_xor_si128(w1,ys);          // invert bits if negative
            w1     = _mm_sub_epi64(yinv,ys);         // add 1
    __m128i xinv   = _mm_xor_si128(w2,xs);          // invert bits if negative
            w2     = _mm_sub_epi64(xinv,xs);         // add 1

    __m128i w0l    = _mm_and_si128(w0, lomask);
    __m128i w0h    = _mm_srli_epi64(w0, 32);

    __m128i s1     = _mm_add_epi64(w1, w0h);         // xl*yh + w0h;
    __m128i s1l    = _mm_and_si128(s1, lomask);      // lo(wl*yh + w0h);
    __m128i s1h    = _mm_srai_epi64(s1, 32);

    __m128i s2     = _mm_add_epi64(w2, s1l);         //xh*yl + s1l
    __m128i s2l    = _mm_slli_epi64(s2, 32);
    __m128i s2h    = _mm_srai_epi64(s2, 32);           //arithmetic shift right

    __m128i hi1    = _mm_add_epi64(w3, s1h);
            hi1    = _mm_add_epi64(hi1, s2h);

    __m128i lo1    = _mm_add_epi64(w0l, s2l);
    *hi = hi1;
    *lo = lo1;
}

It gets worse. There is no _mm_srai_epi64 instrinsic/instruction until AVX512 so I had to make my own.

static inline __m128i _mm_srai_epi64(__m128i a, int b) {
    __m128i sra = _mm_srai_epi32(a,32);
    __m128i srl = _mm_srli_epi64(a,32);
    __m128i mask = _mm_set_epi32(-1,0,-1,0);
    __m128i out = _mm_blendv_epi8(srl, sra, mask);
}

My implementation of _mm_srai_epi64 above is incomplete. I think I was using Agner Fog's Vector Class Library. If you look in the file vectori128.h you find

static inline Vec2q operator >> (Vec2q const & a, int32_t b) {
    // instruction does not exist. Split into 32-bit shifts
    if (b <= 32) {
        __m128i bb   = _mm_cvtsi32_si128(b);               // b
        __m128i sra  = _mm_sra_epi32(a,bb);                // a >> b signed dwords
        __m128i srl  = _mm_srl_epi64(a,bb);                // a >> b unsigned qwords
        __m128i mask = _mm_setr_epi32(0,-1,0,-1);          // mask for signed high part
        return  selectb(mask,sra,srl);
    }
    else {  // b > 32
        __m128i bm32 = _mm_cvtsi32_si128(b-32);            // b - 32
        __m128i sign = _mm_srai_epi32(a,31);               // sign of a
        __m128i sra2 = _mm_sra_epi32(a,bm32);              // a >> (b-32) signed dwords
        __m128i sra3 = _mm_srli_epi64(sra2,32);            // a >> (b-32) >> 32 (second shift unsigned qword)
        __m128i mask = _mm_setr_epi32(0,-1,0,-1);          // mask for high part containing only sign
        return  selectb(mask,sign,sra3);
    }
}
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    Can't you just use the assembly mul instruction ? It already does 64*64 = 128 multiplication, and it's a single instruction. – ElderBug Mar 2 '15 at 11:03
  • @ElderBug, yeah, I just learned that it does this. Maybe I'm wasting my time with this. With AVX512 I could do eight 128 products at once. I don't know if that will beat mul eight times. AVX512 has _mm512_mullo_epi64 but sadly no _mm512_mul_epi64. – Z boson Mar 2 '15 at 11:37
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    This is about multiplication so I don't think Intel ADX will work here, but MULX in BMI2 may improve performance a bit. Since you want to increase the precision of the calculations maybe you'll be interested in double-double arithmetics. It has wider dynamic range and is easier to vectorize because you don't need to carry from the low part anymore, and multiplications may also be easier. The downside is that the precision is limited to 106/107 bits – phuclv Mar 2 '15 at 12:29
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    @Zboson: double-double is extremely easy to implement in SIMD (and pretty fast) on Haswell and beyond (thanks to FMA), if you are willing to take a relaxed attitude about edge cases. If you need to handle NaNs and inf correctly, it's a little bit more painful. You'll definitely want to keep the high and low parts in separate registers, not interleaved. – Stephen Canon Mar 2 '15 at 13:22
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    C (with some ppc inline asm) implementations of double-double: opensource.apple.com/source/gcc/gcc-5646/gcc/config/rs6000/… – Stephen Canon Mar 2 '15 at 13:29
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The right way to think about the throughput limits of integer multiplication using various instructions is in terms of how many "product bits" you can compute per cycle.

mulx produces one 64x64 -> 128 result every cycle; that's 64x64 = 4096 "product bits per cycle"

If you piece together a multiplier on SIMD out of instructions that do 32x32 -> 64 bit multiplies, you need to be able to get four results every cycle to match mulx (4x32x32 = 4096). If there was no arithmetic other than the multiplies, you'd just break even on AVX2. Unfortunately, as you've noticed, there's lots of arithmetic other than the multiplies, so this is a total non-starter on current generation hardware.

  • What got me started on this was _mm512_mullo_epi64. I thought I could use this to get the upper word quickly. But it turns out that getting the upper world given the lower word is hardly easier (it's a lot of work determining a carry of 0, 1, or 2 not to mention the sign*unsigned terms). I'm really surprised by this. Because Intel did not create _mm512_mul_epi64 an extension of a 16-bit scalar instruction from the 80s trumps the best vector instruction from 2015. – Z boson Mar 2 '15 at 15:01
  • @Zboson I wouldn't count on _mm512_mullo_epi64 being a fast instruction. The fact that Intel added IFMA52 instructions (probably for Cannonlake based on their emulator) suggests that Intel has no intention to put a 64-bit multiplier in their SIMD any time soon. – Mysticial Mar 2 '15 at 19:32
  • @Zboson Also, getting the upper half of an unsigned 64x64 multiply is much easier. I have an implementation of this with AVX2. In the context of my particular application, it works out to be about 40% faster than pulling them out into scalar mulx and repacking them. – Mysticial Mar 2 '15 at 19:53
  • @Mysticial, I posted an answer to my question which uses a much simpler unsigned 64x64 to 128 to construct a signed product. I think it's much better than what I had before. Is my unsigned function muldwu1_sse similar to your AVX2 version? – Z boson Mar 3 '15 at 8:25
  • @Mysticial, it turns out that the signed version should take the same number of instructions as the unsigned version if there is an instruction which can do 64x64 to 64. So on AVX512 the signed version could be implemented using only 16 instructions like I did with the unsigned version. However, as you said the 64x64 to 64 instruction might be much slower than the 32x32 to 64 instruction so doing it three times in the signed version might be much slower than using unsigned and than correcting. – Z boson Mar 5 '15 at 12:12
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I found a SIMD solution which is much simpler and does not need signed*unsigned products. I'm no longer convinced that SIMD (at least with AVX2 and AV512) can't compete with mulx. In some cases SIMD can compete with mulx. The only case I'm aware of is in FFT based multiplication of large numbers.

The trick was to do unsigned multiplication first and then correct. I learned how to do this from this answer 32-bit-signed-multiplication-without-using-64-bit-data-type. The correction is simple for (hi,lo) = x*y do unsigned multiplication first and then correct hi like this:

hi -= ((x<0) ? y : 0)  + ((y<0) ? x : 0)

This can be done with with the SSE4.2 intrinsic _mm_cmpgt_epi64

void muldws1_sse(__m128i x, __m128i y, __m128i *lo, __m128i *hi) {    
    muldwu1_sse(x,y,lo,hi);    
    //hi -= ((x<0) ? y : 0)  + ((y<0) ? x : 0);
    __m128i xs = _mm_cmpgt_epi64(_mm_setzero_si128(), x);
    __m128i ys = _mm_cmpgt_epi64(_mm_setzero_si128(), y);           
    __m128i t1 = _mm_and_si128(y,xs);
    __m128i t2 = _mm_and_si128(x,ys);
           *hi = _mm_sub_epi64(*hi,t1);
           *hi = _mm_sub_epi64(*hi,t2);
}

The code for the unsigned multiplication is simpler since it does not need mixed signed*unsigned products. Additionally, since it's unsigned it does not need arithmetic shift right which only has an instruction for AVX512. In fact the following function only needs SSE2:

void muldwu1_sse(__m128i x, __m128i y, __m128i *lo, __m128i *hi) {    
    __m128i lomask = _mm_set1_epi64x(0xffffffff);

    __m128i xh     = _mm_shuffle_epi32(x, 0xB1);    // x0l, x0h, x1l, x1h
    __m128i yh     = _mm_shuffle_epi32(y, 0xB1);    // y0l, y0h, y1l, y1h

    __m128i w0     = _mm_mul_epu32(x,  y);          // x0l*y0l, x1l*y1l
    __m128i w1     = _mm_mul_epu32(x,  yh);         // x0l*y0h, x1l*y1h
    __m128i w2     = _mm_mul_epu32(xh, y);          // x0h*y0l, x1h*y0l
    __m128i w3     = _mm_mul_epu32(xh, yh);         // x0h*y0h, x1h*y1h

    __m128i w0l    = _mm_and_si128(w0, lomask);     //(*)
    __m128i w0h    = _mm_srli_epi64(w0, 32);

    __m128i s1     = _mm_add_epi64(w1, w0h);
    __m128i s1l    = _mm_and_si128(s1, lomask);
    __m128i s1h    = _mm_srli_epi64(s1, 32);

    __m128i s2     = _mm_add_epi64(w2, s1l);
    __m128i s2l    = _mm_slli_epi64(s2, 32);        //(*)
    __m128i s2h    = _mm_srli_epi64(s2, 32);

    __m128i hi1    = _mm_add_epi64(w3, s1h);
            hi1    = _mm_add_epi64(hi1, s2h);

    __m128i lo1    = _mm_add_epi64(w0l, s2l);       //(*)
    //__m128i lo1    = _mm_mullo_epi64(x,y);          //alternative

    *hi = hi1;
    *lo = lo1;
}

This uses

4x mul_epu32
5x add_epi64
2x shuffle_epi32
2x and
2x srli_epi64
1x slli_epi64
****************
16 instructions

AVX512 has the _mm_mullo_epi64 intrinsic which can calculate lo with one instruction. In this case the alternative can be used (comment the lines with the (*) comment and uncomment the alternative line):

5x mul_epu32
4x add_epi64
2x shuffle_epi32
1x and
2x srli_epi64
****************
14 instructions

To change the code for full width AVX2 replace _mm with _mm256 , si128 with si256, and __m128i with __m256i for AVX512 replace them with _mm512, si512, and __m512i.

  • 2
    Yeah, your unsigned 64x64 multiply is similar to mine. My SSE4.1/AVX2 version is 19 instructions, but it trades away the shifts for shuffles since shifts use the same port as the multiplier. – Mysticial Mar 3 '15 at 8:37
  • And my AVX512 version is 15 instructions. – Mysticial Mar 3 '15 at 8:43
  • @Mysticial, that's good to know. I'm on the right track then. I have not tried to optimize the function (I have not even compiled with optimization yet - mostly been unit testing). I should run it through IACA. Why are you interested in the multi-word products? Is this for pi calculations? – Z boson Mar 3 '15 at 8:49
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    I haven't tried, but I'm not sure it will be helpful at all. It takes two IFMA instructions to get a full 104-bit product. And you'll still need 4 of those to get up to 128-bit. Not to mention the extra masking and shifting that will be needed. – Mysticial Mar 4 '15 at 8:11
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    It's pretty obvious that it exposes the double-precision circuitry. And it's also the reason why I believe that _mm512_mullo_epi64() is not going to be a fast instruction. At least not through Skylake/Cannonlake. – Mysticial Mar 4 '15 at 8:18

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