You can do this and I'll point you towards a solution (which compiles and runs). You are looking to get rid of the loop, preferably by inlining it in hopes the compiler will optimize things for you.
In practice I have found it sufficient to specify the dimensions needed, i.e. N = 3, 4, 5 because this allows finer grained control over what the compiler does than doing what you asked for. However you can use recursion and partial template specialization to implement your operators. I have illustrated addition.
So instead of this:
template<typename T, int N>
vector<T, N> operator+(vector<T, N> lhs, vector<T, N> rhs) {
vector<T, N> result;
for (int i = 0; i < N; i++) {
result[i] = lhs[i] + rhs[i];
}
return result;
}
You want code that effectively does this:
template<typename T, int N>
vector<T, N> operator+(vector<T, N> lhs, vector<T, N> rhs) {
vector<T, N> result;
result[0] = lhs[0] + rhs[0];
result[1] = lhs[1] + rhs[1];
...
result[N-1] = lhs[N-1] + rhs[N-1];
return result;
}
if N is 1, it is pretty easy you just want this...
template
vector operator+(vector lhs, vector rhs) {
vector result;
result[0] = lhs[0] + rhs[0];
return result;
}
and if N is 2, it is pretty easy you just want this...
template
vector operator+(vector lhs, vector rhs) {
vector result;
result[0] = lhs[0] + rhs[0];
result[1] = lhs[1] + rhs[1];
return result;
}
The easiest way is to simply define this up to as many N as you expect to use and not the answer you are looking for because you probably don't need more than N=5 or N=6 in practice right?
However, you can also use partial template specialization and recursion to get there. Consider this struct, which recursively calls itself and then assigns the index:
template<typename T, int N, int IDX>
struct Plus
{
void operator()(vector<T,N>& lhs, vector<T,N>& rhs, vector<T,N>& result)
{
Plus<T,N,IDX-1>()(lhs,rhs,result);
result.data[IDX] = lhs.data[IDX] + rhs.data[IDX];
}
};
and this partial specialization which appears to do nothing, but handles the case when the index is 0 and ends the recursion:
template<typename T, int N>
struct Plus<T,N,-1>
{
void operator()(vector<T,N>& lhs, vector<T,N>& rhs, vector<T,N>& result)
{
//noop
}
};
and finally this implementation of operator+ which instantiates Plus and calls it:
template<typename T, int N>
vector<T, N> operator+(vector<T, N> lhs, vector<T, N> rhs) {
vector<T, N> result;
Plus<T,N,N-1>()(lhs,rhs,result);
return result;
}
You'll need to turn this into an operator to make it more general purpose but you get the idea. However this is mean to the compiler and it may take awhile in big projects even if it is super cool. In practice I have found that hand typing the overloads you want or writing script code to generate the C++ results in a more debuggable experience and code that in the end is simpler to read and easier for the compiler to optimize. More specifically if you write a script to generate the C++ you can include the SIMD intrinsics in the first place and not leave things to chance.