Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I'm trying to write an optimized dot product for an ARM A8 processor using Neon intrinsics but I'm having a little trouble. First of all, is there any library that already implements this? My code seems to work, but causes some quiet failures during run-time - my best guess is because there is a slight loss of precision compared to the unoptimized code. Is there a better way to accomplish what I'm trying to do? I would be very grateful for any help or suggestions. Thanks in advance.

This particualar dot product is a 32 bit float * 32 bit float complex.

Here is the unoptimized code:

    double sum_re = 0.0;
    double sum_im = 0.0;
    for(int i=0; i<len; i++, src1++, src2++)
    {
            sum_re += *src1 * src2->re;
            sum_im += *src1 * src2->im;
    }

Here is my optimized version:

    float sum_re = 0.0;
    float sum_im = 0.0;

    float to_sum_re[4] = {0,0,0,0};
    float to_sum_im[4] = {0,0,0,0};

    float32x4_t tmp_sum_re, tmp_sum_im, source1;
    float32x4x2_t source2;
    tmp_sum_re = vld1q_f32(to_sum_re);
    tmp_sum_im = vld1q_f32(to_sum_im);

    int i = 0;

    while (i < (len & ~3)) {
            source1 = vld1q_f32(&src1[i]);
            source2 = vld2q_f32((const float32_t*)&src2[i]);

            tmp_sum_re = vmlaq_f32(tmp_sum_re, source1, source2.val[0]);
            tmp_sum_im = vmlaq_f32(tmp_sum_im, source1, source2.val[1]);

            i += 4;
    }
    if (len & ~3) {
            vst1q_f32(to_sum_re, tmp_sum_re);
            vst1q_f32(to_sum_im, tmp_sum_im);

            sum_re += to_sum_re[0] + to_sum_re[1] + to_sum_re[2] + to_sum_re[3];
            sum_im += to_sum_im[0] + to_sum_im[1] + to_sum_im[2] + to_sum_im[3];
    }

    while (i < len)
    {
            sum_re += src1[i] * src2[i].re;
            sum_im += src1[i] * src2[i].im;
            i++;
    }
share|improve this question
    
Did you write the outputs and checked if they are different and by how much? –  Dani Jul 11 '12 at 16:10
    
This may not be a representative example, but the first time the function is called: - - - - WITH NEON: {re = 54.041008, im = 29.197485} WITHOUT NEON: {re = 54.0410004, im = 29.1974678} –  Tan Man Jul 11 '12 at 16:56
    
What platform/OS ? –  Paul R Jul 11 '12 at 17:25
    
Ettus e110 (similar to a beagleboard) running Angstrom –  Tan Man Jul 11 '12 at 17:39

3 Answers 3

If you are using iOS, use vDSP_zrdotpr in the Accelerate framework. (vDSP_zrdotpr returns the dot product of a real vector with a complex vector. There are other variants, such as for real-to-real or complex-to-complex.)

Of course there is a loss of precision; your unoptimized code accumulates double-precision sums, while the NEON code accumulates single-precision sums.

Even without a precision change, the results would be expected to differ because doing floating-point operations in different orders produces different rounding errors. (This is true for integers too; if you calculate 7/3*5, you get 10, but 5*7/3 is 11.)

There are algorithms for doing floating-point arithmetic with reduced error. However, for doing a high-performance dot product, you are generally stuck with what you get.

One option would be to do the arithmetic with double-precision NEON instructions. This will not be as fast a single-precision NEON, of course, but it will be faster than scalar (non-NEON) code.

share|improve this answer
1  
Two notes: Even though you accumulate double-precision sums in the scalar code, the multiplication is in single-precision, so the final errors are typical of that rather than what double-precision throughout would produce. And, while vDSP_zrdotpr can multiply by an interleaved complex vector (stride of two), I suspect it is not optimized for that case. You could file a bug report requesting it at bugreport.apple.com. –  Eric Postpischil Jul 11 '12 at 17:24

As for other implementations, there is the NEON OpenMAX DL implementation from ARM. Linked to from http://www.arm.com/community/multimedia/standards-apis.php.

Downloading requires registration, and the format is RVCT assembler, but for looking at a set of examples of how to use NEON (including a dot product implementation), it's pretty good.

share|improve this answer

Here is something that I did and currently in a commercial product. Hopefully, it helps. The only requirement is that the two multiplicands (src1, srcs->re) must be multiples of four.

float dotProduct4 (const float *a, const float *b, int n) {
float net1D=0.0f;
assert(n%4==0);     // required floats 'a' & 'b' to be multiple of 4
#ifdef __ARM_NEON__
asm volatile (
              "vmov.f32 q8, #0.0          \n\t" // zero out q8 register
              "1:                         \n\t"
              "subs %3, %3, #4            \n\t" // we load 4 floats into q0, and q2 register
              "vld1.f32 {d0,d1}, [%1]!    \n\t" // loads q0, update pointer *a
              "vld1.f32 {d4,d5}, [%2]!    \n\t" // loads q2, update pointer *b
              "vmla.f32 q8, q0, q2        \n\t" // store four partial sums in q8
              "bgt 1b                     \n\t"   // loops to label 1 until n==0
              "vpadd.f32 d0, d16, d17     \n\t"   // pairwise add 4 partial sums in q8, store in d0
              "vadd.f32 %0, s0, s1        \n\t"   // add 2 partial sums in d0, store result in return variable net1D
              : "=w"(net1D)                 // output
              : "r"(a), "r"(b), "r"(n)      // input
              : "q0", "q2", "q8");          // clobber list
#else
for (int k=0; k < n; k++) {
    net1D += a[k] * b[k];
}
#endif
return net1D;
}  
share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.