What is an efficient way to compute pq, where q is an integer?


Exponentiation by squaring uses only O(lg q) multiplications.

template <typename T>
T expt(T p, unsigned q)
    T r(1);

    while (q != 0) {
        if (q % 2 == 1) {    // q is odd
            r *= p;
        p *= p;
        q /= 2;

    return r;

This should work on any monoid (T, operator*) where a T constructed from 1 is the identity element. That includes all numeric types.

Extending this to signed q is easy: just divide one by the result of the above for the absolute value of q (but as usual, be careful when computing the absolute value).

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    I -1d this because it is not a complete answer; exponentiation by squaring is a good algorithm, but there are other concerns as well. – user79758 Apr 11 '11 at 18:18
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    @Joe: the OP was asking for a suggestion, not a complete solution or a proof of correctness. – Fred Foo Apr 11 '11 at 18:19
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    Generally, I assume someone asking a question wants a complete solution. Rarely are questions asked expecting half-answers. – user79758 Apr 11 '11 at 18:21
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    Do downvotes really hurt that much? Is 98 rep out of a three word Wikipedia link really so little you must be upset, or upset on someone else's behalf? – user79758 Apr 11 '11 at 18:44
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    @Joe Wreschnig: The usual standard for votes (as revealed by hovering on the voting arrows) is "is this answer useful", not "is this answer as complete as it is possible to be". See also meta.stackexchange.com/questions/2451/… – wnoise Apr 12 '11 at 15:24

Assuming that ^ means exponentiation and that q is runtime variable, use std::pow(double, int).

EDIT: For completeness due to the comments on this answer: I asked the question Why was std::pow(double, int) removed from C++11? about the missing function and in fact pow(double, int) wasn't removed in C++0x, just the language was changed. However, it appears that libraries may not actually optimize it due to result accuracy concerns.

Even given that I would still use pow until measurement showed me that it needed to be optimized.

  • And assuming p can be coerced to a double. – user79758 Apr 11 '11 at 18:09
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    @downvoter: What's the problem with this solution? The standard library is likely to have a highly optimized pow function when runtime variability is needed. – Mark B Apr 11 '11 at 18:10
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    Actually, I just checked my C++0x draft, and std::pow(double,int) is not defined. std::pow(double,double) and std::pow(float,float), and some more complex overloads, are. I think that means 1) any library offering std::pow(double,int) is non-standard, and 2) if they do special-case integer-valued doubles at runtime, that would be sigificant overhead. So although I was not the downvoter, I am also going to -1 this. – user79758 Apr 11 '11 at 18:23
  • @Joe Wreschnig I spotted it in C++98 26.5/6 and assumed they wouldn't remove functionality in 0x. Did they remove it in C++0x (I don't have a handy copy of that standard)? – Mark B Apr 11 '11 at 18:32
  • @Mark B: I actually cannot find a C++98 PDF on Google quickly, but in my C++0x PDF, the only mention of pow on primitive types is via C99 transclusion in 26.8, and it only defines pow for float,float, double,double, and long double,long double. – user79758 Apr 11 '11 at 18:38

I assume by ^ you mean power function, and not bitwise xor.

The development of an efficient power function for any type of p and any positive integral q is the subject of an entire section, 3.2, in Stepanov's and McJones's book Elements of Programming. The language in the book is not C++, but is very easily translated into C++.

It covers several optimizations, including exponentiation by squaring, conversion to tail recursion then iteration, and accumulation-variable elimination, and relates the optimizations to the notions of type regularity and associative operations to prove it works for all such types.


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