Here would be an example using the Eigen library:

```
#include <Eigen/Core>
std::complex<float> f(const std::complex<float> *x, int n)
{
return Eigen::VectorXcf::Map(x, n).prod();
}
```

If you compile this with clang or g++ and sse or avx enabled (and -O2), you should get fairly decent machine code. It also works for some other architectures like Altivec or NEON. If you know that the first entry of `x`

is aligned, you can use `MapAligned`

instead of `Map`

.

You get even better code, if you happen to know the size of your vector at compile time using this:

```
template<int n>
std::complex<float> f(const std::complex<float> *x)
{
return Eigen::Matrix<std::complex<float>, n, 1> >::MapAligned(x).prod();
}
```

*Note:* The functions above directly correspond to the function `f`

of the OP.
However, as @PeterCordes pointed out, it is generally bad to store complex numbers interleaved, since this will require lots of shuffling for multiplication. Instead, one should store real and imaginary parts in a way that they can be directly loaded one packet at once.

**Edit/Addendum**: To implement a structure-of-arrays like complex multiplication, you can actually write something like:

```
typedef Eigen::Array<float, 8, 1> v8sf; // Eigen::Array allows element-wise standard operations
typedef std::complex<v8sf> complex8;
complex8 prod(const complex8& a, const complex8& b)
{
return a*b;
}
```

Or more generic (using C++11):

```
template<int size, typename Scalar = float> using complexX = std::complex<Eigen::Array<Scalar, size, 1> >;
template<int size>
complexX<size> prod(const complexX<size>& a, const complexX<size>& b)
{
return a*b;
}
```

When compiled with `-mavx -O2`

, this compiles to something like this (using g++-5.4):

```
vmovaps 32(%rsi), %ymm1
movq %rdi, %rax
vmovaps (%rsi), %ymm0
vmovaps 32(%rdi), %ymm3
vmovaps (%rdi), %ymm4
vmulps %ymm0, %ymm3, %ymm2
vmulps %ymm4, %ymm1, %ymm5
vmulps %ymm4, %ymm0, %ymm0
vmulps %ymm3, %ymm1, %ymm1
vaddps %ymm5, %ymm2, %ymm2
vsubps %ymm1, %ymm0, %ymm0
vmovaps %ymm2, 32(%rdi)
vmovaps %ymm0, (%rdi)
vzeroupper
ret
```

For reasons not obvious to me, this is actually hidden in a method which is called by the actual method, which just moves around some memory -- I don't know why Eigen/gcc does not assume that the arguments are already properly aligned. If I compile the same with clang 3.8.0 (and the same arguments), it is compiled to just:

```
vmovaps (%rsi), %ymm0
vmovaps %ymm0, (%rdi)
vmovaps 32(%rsi), %ymm0
vmovaps %ymm0, 32(%rdi)
vmovaps (%rdi), %ymm1
vmovaps (%rdx), %ymm2
vmovaps 32(%rdx), %ymm3
vmulps %ymm2, %ymm1, %ymm4
vmulps %ymm3, %ymm0, %ymm5
vsubps %ymm5, %ymm4, %ymm4
vmulps %ymm3, %ymm1, %ymm1
vmulps %ymm0, %ymm2, %ymm0
vaddps %ymm1, %ymm0, %ymm0
vmovaps %ymm0, 32(%rdi)
vmovaps %ymm4, (%rdi)
movq %rdi, %rax
vzeroupper
retq
```

Again, the memory-movement at the beginning is weird, but at least that is vectorized. For both gcc and clang this get optimized away when called in a loop, however:

```
complex8 f8(complex8 x[], int n) {
if(n==0)
return complex8(v8sf::Ones(),v8sf::Zero()); // I guess you want p = 1 + 0*i at the beginning?
complex8 p = x[0];
for (int i = 1; i < n; i++) p = prod(p, x[i]);
return p;
}
```

The difference here is that clang will unroll that outer loop to 2 multiplications per loop. On the other hand, gcc will use fused-multiply-add instructions when compiled with `-mfma`

.

The `f8`

function can of course also be generalized to arbitrary dimensions:

```
template<int size>
complexX<size> fX(complexX<size> x[], int n) {
using S= typename complexX<size>::value_type;
if(n==0)
return complexX<size>(S::Ones(),S::Zero());
complexX<size> p = x[0];
for (int i = 1; i < n; i++) p *=x[i];
return p;
}
```

And for reducing the `complexX<N>`

to a single `std::complex`

the following function can be used:

```
// only works for powers of two
template<int size> EIGEN_ALWAYS_INLINE
std::complex<float> redux(const complexX<size>& var) {
complexX<size/2> a(var.real().template head<size/2>(), var.imag().template head<size/2>());
complexX<size/2> b(var.real().template tail<size/2>(), var.imag().template tail<size/2>());
return redux(a*b);
}
template<> EIGEN_ALWAYS_INLINE
std::complex<float> redux(const complexX<1>& var) {
return std::complex<float>(var.real()[0], var.imag()[0]);
}
```

However, depending on whether I use clang or g++, I get quite different assembler output. Overall, g++ has a tendency to fail to inline loading the input arguments, and clang fails to use FMA operations (YMMV ...)
Essentially, you need to inspect the generated assembler code anyway. And more importantly, you should benchmark the code (not sure, how much impact this routine has in your overall problem).

Also, I wanted to note that Eigen actually is a linear algebra library. Exploiting it for pure portable SIMD code generation is not really what is designed for.

`float4`

. Either you make the vector types really large, or you write your code to handle variable sized vectors. – Mysticial Jul 27 '17 at 20:49`p`

variables. Like`p0=p1=p2=p3 = {one,one};`

. Then in the loop,`p0 = complex4_mul(p0, x[i+0]);`

`p1 = complex4_mul(p1, x[i+1]);`

, etc. At the end, combine the accumulators together.`p0 = complex4_mul(p0, p1);`

, same for 2 and 3, then the final down to one vector of results. – Peter Cordes Jul 28 '17 at 8:36`float4`

, use`v4sf`

. (And then you can clean up all the`.v`

in the code using it.) – Peter Cordes Jul 31 '17 at 4:07