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I was writing a matrix-vector-multiplication in both SSE and AVX using the following:

for(size_t i=0;i<M;i++) {
    size_t index = i*N;
    __m128 a, x, r1;
    __m128 sum = _mm_setzero_ps();
    for(size_t j=0;j<N;j+=4,index+=4) {
         a = _mm_load_ps(&A[index]);
         x = _mm_load_ps(&X[j]);
         r1 = _mm_mul_ps(a,x);
         sum = _mm_add_ps(r1,sum);
    sum = _mm_hadd_ps(sum,sum);
    sum = _mm_hadd_ps(sum,sum);

I used a similar method for AVX, however at the end, since AVX doesn't have an equivalent instruction to _mm_store_ss(), I used:


The SSE code gives me a speedup of 3.7 over the serial code. However, the AVX code gives me a speedup of only 4.3 over the serial code.

I know that using SSE with AVX can cause problems but I compiled it with the -mavx' flag using g++ which should remove the SSE opcodes.

I could have also used: _mm256_storeu_ps(&C[i],sum) to do the same thing, but the speedup is the same.

Any insights as to what else I could be doing to improve performance? Can it be related to : performance_memory_bound, though I didn't understand the answer on that thread clearly.

Also, I am not able to use the _mm_fmadd_ps() instruction even by including "immintrin.h" header file. I have both FMA and AVX enabled.

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It could be that the CPU is just idling while waiting for memory IO. This means that it actually does its computations way faster, but is then stuck waiting for the next chunk of data for a longer time too. –  Marc Claesen Nov 6 '13 at 7:25
_mm_store_ss(&C[i],_mm256_castps256_ps128(sum)); is the equivalent instruction in AVX. SSE instructions just operate on the lower 128 bits of the 256 bit AVX register. The cast is only to make the compiler happy and does not use an instruction. –  Z boson Nov 6 '13 at 8:01
You should try unrolling your loop at least once. –  Z boson Nov 6 '13 at 8:13
"I used a similar method for AVX" - Just to be sure, I assume this similar method to have all 4s appropriately changed to 8s. Just in case. –  Christian Rau Nov 6 '13 at 9:43
Well I was doing matrixmatrix not just matrixvector. I did several things. Loop unrolling, loop tiling, AVX, OpenMP. It's actually quite difficult to get more than 50% of the peak flops. I got up to 70% I think eventually which was still lower than MKL but faster than Eigen. –  Z boson Nov 7 '13 at 13:59

3 Answers 3

I suggest you reconsider your algorithm. See the discussion Efficient 4x4 matrix vector multiplication with SSE: horizontal add and dot product - what's the point?

You're doing one long dot product and using _mm_hadd_ps per iteration. Instead you should do four dot products at once with SSE (eight with AVX) and only use vertical operators.

You need addition, multiplication, and a broadcast. This can all be done in SSE with _mm_add_ps, _mm_mul_ps, and _mm_shuffle_ps (for the broadcast).

If you already have the transpose of the matrix this is really simple.

But whether you have the transpose or not you need to make your code more cache friendly. To fix this I suggest loop tiling of the matrix. See this discussion What is the fastest way to transpose a matrix in C++? to get an idea on how to do loop tiling.

I would try and get the loop tiling right first before even trying SSE/AVX. The biggest boost I got in my matrix multiplication was not from SIMD or threading it was from loop tiling. I think if you get the cache usage right your AVX code will perform more linear compared to SSE as well.

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Once again, if you want to build your own matrix multiplication algorithm, please stop. I remember from Intel's AVX forum, one of their engineer confessed that it took them a very long time to write AVX assemblies to reach AVX theoretical throughput for multiplying two matrices (especially small matrices), because AVX load and store instructions are quite slow at the moment, and not to mention the difficulty to overcome the thread overhead for the parallel version.

Please install Intel Math Kernel Library, spend half an hour reading the manual and code 1 lines to call the library, DONE!

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As somebody already suggested, add -funroll-loops

Curiously this is not set by default.

Use __restrict for the definition of any float pointers. Use const for constant array references. I don't know if the compiler is smart enough to recognize that the 3 intermediate values inside the loop don't need to be kept alive from iteration to iteration. I would just remove these 3 variables or at least make them local inside the loop (a, x, r1). Index can be declared, where j is declared in order to make it more local. Make certain that M and N are declared as const and if their values are compile-time constants, let the compiler see them.

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