Without knowing the implementation of
pow in your stdlib exactly, you cannot be absolutely sure that
floor(pow(n,1.0/k)) or (long long)pow(n,1.0/k)
returns the correct result.
1.0/k introduces a small inaccuracy and that plus the inaccuracy of
pow (unavoidable due to the representation of
doubles) may just move the result of
pow() past the integer threshold if
n is a
kth power or very close to one.
An example using Haskell's
(**), which does the same thing as
math.h, but it might have a different implementation:
Prelude> 3^37-1 :: Int
Prelude> fromIntegral it ** (1.0/37)
It will however always be at least very close to the correct result, so you can use it as the starting point for a quick correction if necessary.
// assumes k > 2
long long r = (long long)pow(n,1.0/k);
while (n/power(r+1,k-k/2) >= power(r+1,k/2)) ++r;
while (n/power(r,k-k/2) < power(r,k/2)) --r;
power(a,b) is an integer power function (could be
round(pow(a,b)) for example, or exponentiation by repeated squaring). By raising
r+1 only to the
k-1th power, overflow is avoided (except possibly if
r is 1, you can deal with that special case easily if necessary by testing
k < 64 && n < (1ull << k)).
Of course the tests for the special cases and the fixup cost time and in almost all cases do nothing above
floor(pow(n,1.0/k)), so it may not be worth it.