I am looking for an idiomatic way to optimize this template I wrote.

My main concern is how to correctly define the template parameter n and using it as a return parameter while the user must not overwrite it.

I am also open for other suggestions on how to write this template in an idiomatic C++14 way.

  typename InType=uint32_t,
  typename OutType=float,
  unsigned long bits=8,
  unsigned long n=(sizeof(InType) * 8) / bits
std::array<OutType,n> hash_to_color(InType in) noexcept {    
  InType mask = ~0;
  mask = mask << bits;
  mask = ~mask;
  std::array<OutType,n> out;
  auto out_max = static_cast<OutType>((1 << bits) - 1);
  for (auto i = 0; i < n; i++) {
    auto selected = (in >> (i * bits)) & mask;
    out[i] = static_cast<OutType>(selected) / out_max;
  return out;
  • If you want to ensure that the user doesn't override it, perhaps you can just static_assert that it's the correct value? – Waleed Khan Oct 1 '16 at 6:31

Regarding the n template parameter, you can avoid it by using auto as the return type in C++14. Here's a simpler example of the principle:

template<int N>
auto f()
    constexpr int bar = N * 3;   
    std::array<int, bar> foo;
    return foo;

Naturally the calculation of the array template parameter must be a constant expression.

Another option (compatible with C++11) is trailing-return-type:

template<int N>
auto f() -> std::array<int, N * 3>

This is a wee bit more verbose than taking advantage of C++14's allowing of return type deduction from the return statement.

Note: ~0 in your code is wrong because 0 is an int, it should be ~(InType)0. Also (1 << bits) - 1 has potential overflow issues.

  • Thank you. That's helpful. I removed a few static_assert in the question code which ensure that bits don't overflow by static_assert(bits < sizeof(OutType) * 8) – somnium Oct 1 '16 at 6:51

I think M.M.'s answer is excellent, and, in your case, I'd definitely use one of the two alternatives suggested there.

Suppose you later encounter a situation where the logic is, given n, use not 3 n, but something more complicated, e.g., n2 + 3 n + 1. Alternatively, maybe the logic is not very complicated, but it is subject to change.

(Just to clarify again, I don't think that these are significant problems in the context of your question or M.M.'s answer.)

So, a third option would be to factor out the logic to a constexpr function:

#include <array>

constexpr int arr_size(int n) { return n * n + 3 * n + 1; }

Since it's constexpr, it can be used to instantiate the template:

template<int N>
std::array<int, arr_size(N)> f() {
    return  std::array<int, arr_size(N)>();

Note that now the function has an explicit return type, but the logic of arr_size appears only once.

You could use this as usual:

int main() {
    auto a = f<10>();
    a[0] = 3;

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