Very similar to iavr, but sorting in place (benchmarked against iavr's solution with g++ -O3 and takes about 2020ms compared to iavr's 1780ms), enjoying a regular interface and resuable code. The problem with Iavr's implementation is that its logic only works with containers of strings, and is not easily extensible to other types. Obviously his specialized version is more efficient, but it might be worth it to sacrifice some performance for regularity.
You can find the rest of the code at radix sort implementation
General Radix sort:
template <typename T>
using Iter_value = std::iterator_traits<T>::value_type;
// intermediate struct to get partial template specialization
template<typename Iter, typename T, size_t range = 256>
struct rdx_impl {
static void rdx_sort(Iter begin, Iter end, int bits) {
// bits is # bits to consider up to if a max val is known ahead of time
// most efficent (theoretically) when digits are base n, having lg(n) bits
constexpr size_t digit_bits {8}; // # bits in digit, 8 works well for 32 and 64 bit vals
size_t d {0}; // current digit #
for (long long mask = (1 << digit_bits) - 1;
d * digit_bits < bits;) {// ex. 0x000000ff for setting lower 8 bits on 32 bit num
cnt_sort(begin, end, range, Digit_cmp<T>(mask, digit_bits*d));
++d;
}
}
};
// specialization of rdx_sort for strings
struct Shorter {
template <typename Seq>
bool operator()(const Seq& a, const Seq& b) { return a.size() < b.size(); }
};
template <typename Iter>
struct rdx_impl<Iter, std::string> { // enough to hold ASCII char range
static void rdx_sort(Iter begin, Iter end, int) {
// ignore additional int argument
int len_max = std::max_element(begin, end, Shorter())->size();
for (int d = len_max - 1; d >= 0; --d)
cnt_sort(begin, end, 128, Digit_cmp<std::string>(d));
}
};
// generic call interface for all iterators
template <typename Iter> // use intermediate struct for partial specialization
void rdx_sort(Iter begin, Iter end, int bits) {
rdx_impl<Iter, Iter_value<Iter>>::rdx_sort(begin, end, bits);
}
Counting sort to sort on each digit (in place):
template <typename Iter, typename Op>
void cnt_sort(Iter begin, Iter end, size_t range, Op op) {
using T = typename Iter::value_type;
std::vector<int> counts(range); // init to 0
for (auto i = begin; i != end; ++i) // count # elems == i
++counts[op(*i)];
for (size_t i = 1; i < range; ++i)
counts[i] += counts[i-1]; // turn into # elems <= i
std::vector<T> res(end - begin);
for (auto j = end;;) {
--j;
res[--counts[op(*j)]] = *j;
if (j == begin) break;
}
// ~18% of time is spent on copying
std::copy(res.begin(), res.end(), begin);
}
Extract value of digit:
template <typename T> // overload digit_cmp for non-integral types top provide radix sort with digits
class Digit_cmp { // functor for comparing a "digit" (particular bits)
const long long mask; // 0..63 bitfield to test against
const size_t to_shift;
public:
Digit_cmp(long long m, size_t ts) : mask{m}, to_shift{ts} {}
// by default assumes integral, just shifts
size_t operator()(T n) const { // char assuming r = 8
return (n >> to_shift) & mask; // shift then mask for unit digit
}
};
// specialization for strings
template <>
class Digit_cmp<std::string> {
const size_t digit;
public:
Digit_cmp(size_t d) : digit{d} {}
size_t operator()(const std::string& str) {
// 0 indicates past the end of the string
return str.size() > digit ? str[digit] : 0;
}
};