In C++11 is std::sqrt defined as constexpr, i.e. can it legally be used from other constexpr functions or in compile-time contexts like array sizes or template arguments? g++ seems to allow it (using -std=c++0x), but I'm not sure I can take that as authoritative given that c++0x/c++11 support is still incomplete. The fact that I can't seem to find anything on the Internet makes me unsure.

It seems like this should be something one could easily find out using Google, but I've tried (for 40 minutes now...) and couldn't find anything. I could find several proposals for adding constexpr to various parts of the standard library (like for example this one), but nothing about sqrt or other math functions.

up vote 23 down vote accepted

std::sqrt is not defined as constexpr, according to section 26.8 of N3291: the C++11 FDIS (and I doubt they added it to the final standard after that). One could possibly write such a version, but the standard library version is not constexpr.

  • 2
    Is this stated there explicitly? 26.8 C library makes no reference to constexpr. An implementation would surely still be conformant if it provided constexpr function implementations in addition to those mandated without. – user2023370 May 16 '12 at 22:44
  • 7
    @user643722: A standard library implementation could define a constexpr version. But it is not required to do so, and therefore you can't really rely upon it. – Nicol Bolas May 16 '12 at 23:35

Just in case anyone is interested in a meta integer square root function, here is one I wrote while a ago:

constexpr std::size_t isqrt_impl
    (std::size_t sq, std::size_t dlt, std::size_t value){
    return sq <= value ?
        isqrt_impl(sq+dlt, dlt+2, value) : (dlt >> 1) - 1;

constexpr std::size_t isqrt(std::size_t value){
    return isqrt_impl(1, 3, value);
  • Umm, that seems to have linear complexity , i.e. Theta(value), rather than logarithmic, which is quite achievable, e.g. in @Linoliumz 's answer. – einpoklum Feb 10 '16 at 11:57

Below is a constexpr square root implementation that uses binary search. It works correctly up to 2^64 with gcc and clang, other simpler versions often fail for numbers > 2^32 because compilers limit the recursion depth to e.g. 200.

// C++11 compile time square root using binary search

#define MID ((lo + hi + 1) / 2)

constexpr uint64_t sqrt_helper(uint64_t x, uint64_t lo, uint64_t hi)
  return lo == hi ? lo : ((x / MID < MID)
      ? sqrt_helper(x, lo, MID - 1) : sqrt_helper(x, MID, hi));

constexpr uint64_t ct_sqrt(uint64_t x)
  return sqrt_helper(x, 0, x / 2 + 1);

Below is a nicer version (for integer constants) which requires C++14, it is similar to the one presented in Baptiste Wicht's blog post. C++14 constexpr functions are allowed to use local variables and if statements.

// C++14 compile time square root using binary search

template <typename T>
constexpr T sqrt_helper(T x, T lo, T hi)
  if (lo == hi)
    return lo;

  const T mid = (lo + hi + 1) / 2;

  if (x / mid < mid)
    return sqrt_helper<T>(x, lo, mid - 1);
    return sqrt_helper(x, mid, hi);

template <typename T>
constexpr T ct_sqrt(T x)
  return sqrt_helper<T>(x, 0, x / 2 + 1);
  • Why is MID a macro? – dyp Dec 30 '14 at 16:51
  • Because in C++11 static const variables inside constexpr functions are not allowed. – Linoliumz Dec 30 '14 at 18:17
  • Is this for show, or do people really use something that takes over 200 recursions to compile? – Mikhail Dec 30 '14 at 19:01
  • @Mikhail: This version doesn't take 200 recursions. AraK's does. This version just takes about log_2(x) iterations, which is pretty reasonable. – Cornstalks Dec 30 '14 at 19:24
  • 2
    It is even possible to use up only one more level of recursion and make mid a function: – dyp Dec 30 '14 at 20:06

Here is a fast and efficient constexpr implementation for double floating point numbers. You may adapt it to float too, if needed:

#include <limits>   

namespace Detail
    double constexpr sqrtNewtonRaphson(double x, double curr, double prev)
        return curr == prev
            ? curr
            : sqrtNewtonRaphson(x, 0.5 * (curr + x / curr), curr);

* Constexpr version of the square root
* Return value:
*   - For a finite and non-negative value of "x", returns an approximation for the square root of "x"
*   - Otherwise, returns NaN
double constexpr sqrt(double x)
    return x >= 0 && x < std::numeric_limits<double>::infinity()
        ? Detail::sqrtNewtonRaphson(x, x, 0)
        : std::numeric_limits<double>::quiet_NaN();

If we look at the closest draft standard to C++11 N3337 we can see that sqrt is not marked constexpr, from section 26.8 c.math:

The contents of these headers are the same as the Standard C library headers and respectively, with the following changes:

none of the changes include adding constexpr to sqrt.

We can see from the question Is gcc considering builtins of non-constant expression functions to be constant expressions, that gcc marks many math functions as constexpr as an extension. This extension is a non-conforming extension, as I note in my answer to the linked question when gcc implemented this it looked like it would be a conforming extension but this changed and gcc is likely to fix this this extension to be conforming.

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