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I want to calculate [n^(1/k)] where n is long long and 2 <= k <= lg(n); k is integer.

I thought may be I could use this:

long long d = pow(n,1.0/k)-1;
while(power(d,k) < n)
    d++;
d--;

but it may overflow long long at the last step.

Is it guaranteed that d will be pow(n,1.0/k) rounded down if I write:

long long d = long long(pow(n,1.0/k));

If not, what is an easy & safe way to calculate floor(pow(n,1.0/k))

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4  
If you want to calculate floor(pow(n,1.0/k)) why dont you use floor(pow(n,1.0/k)) for it? –  PlasmaHH Feb 21 '12 at 16:41
    
k <= lg(k) ?? –  Karoly Horvath Feb 21 '12 at 16:41
    
@yi_H: k <= log(k) I think. –  Evan Mulawski Feb 21 '12 at 16:42
    
@Evan Mulawski: that doesn't make any sense. –  Karoly Horvath Feb 21 '12 at 16:43
    
@PlasmaHH : I thought maybe the real value is 4-eps for example, and the goal is 3 therefore. but floor(pow(n,1.0/k)) may give 4. can't? –  a-z Feb 21 '12 at 16:47

3 Answers 3

up vote 1 down vote accepted

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 pow() from math.h, but it might have a different implementation:

Prelude> 3^37-1 :: Int
450283905890997362
Prelude> fromIntegral it ** (1.0/37)
3.0000000000000004

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;

where power(a,b) is an integer power function (could be round(pow(a,b)) for example, or exponentiation by repeated squaring). By raising r resp 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.

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I think power() in your code may overflow yet. –  a-z Feb 21 '12 at 17:39
    
Correct, in a few cases it could, fixed now. –  Daniel Fischer Feb 21 '12 at 18:52

You're asking for guarantees. Unfortunately, there are very few guarantees when it comes to types in C/C++. An exact size for these datatypes is not defined, though you'll find that long long is normally 64 bits. However, I believe that 1.0 will by default be a float, which normally has 32 bits. There are both float pow(float base, float exponent) and double pow(double base, double exponent) and I'm not certain that C++ will understand which one you want to use unless you specify it. Thus, you might lose precision when you convert. Oh, and by the way, even double might be less precise than a long long, since it stores the exponent as well.

Another problem is that floating point conversion might be inexact even when you think that it shouldn't be. I've had cases where I've read an integer into a floating point variable from stdin, and then immediately converted it back to an int, and found out that it was rounded down from one integer value to the one below! To avoid this, you should add a small epsilon prior to the typecast. The size of the epsilon should be determined based on the precision of the variables and the size of the numbers you're working with.

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pow() returns a double, i think that's what you've missed

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