In a digital filtering C++ application, I use `std::inner_product`

(with `std::vector<double>`

and `std::deque<double>`

) to compute the dot product between the filter coefficients and the input data, for each data sample. After profiling my application, I figured out that no less than 85% of the execution time is spent in `std::inner_product`

!

To what extend is `std::inner_product`

optimized, in GCC for example?
Does it uses SIMD instructions? Does it performs loop unrolling? How to make sure of that?
Based on this, would it worth it to implement custom dot product function(s) (especially if the number of coefficient is low)? (but I would like to keep the function as generic as possible)

More specifically, this is the piece of code I use to apply a filter:

```
std::deque<double> in(filterNum.size(), 0.0);
std::deque<double> out(filterDenom.size() - 1, 0.0);
const double gain = filterDenom.back();
for (unsigned int s = 0, size = data.size(); s < size; ++s) {
in.pop_front();
in.push_back(data[s] / gain);
data[s] = inner_product(in.begin(), in.end(), filterNum.begin(),
-inner_product(out.begin(), out.end(), filterDenom.begin(), 0.0));
out.pop_front();
out.push_back(data[s]);
}
```

Typically, I use second order bandpass IIR filters, which means that the size of `filterNum`

and `filterDenom`

(numerator and denominator coefficients of the filter) is 5. `data`

is the vector containing the input samples.