Every `constexpr`

function is pure, but not every pure function can or should be `constexpr`

.

[Examples involving `constexpr`

function templates are misleading, since function templates are not functions, they're patterns by which the compiler can generate functions. The outcome of function templates, their specialisations, *are* functions and they *will* be `constexpr`

iff possible.]

A pure function is one that only depends on its arguments, or other constant state. That's pretty much what a `constexpr`

function is. In addition, `constexpr`

functions must be defined (not only declared) prior to their first use (recursion seems to be allowed, though), and must consist of only the return statement. That's enough to make the allowed subset Turing-complete, but the result is not necessarily the most efficient form at runtime.

Which brings us to the mathematical functions. You can probably implement `constexpr`

`sqrt()`

or `sin()`

, but they would have to use a recursive implementation that the compiler can evaluate at compile-time, whereas at runtime, these would be better implemented in one assembler operation. Since `constexpr`

uses of `sqrt()`

and `sin()`

are few and far apart, its better to maximise runtime performance instead, which requires a form that isn't `constexpr`

able.

You may wonder why you can't write one `constexpr`

version of a function and one that's used at runtime, and I'd agree that would be nice to have, but the standard says you can't overload on `constexpr`

ness. Maybe in C++17...

`constexpr`

requirements,`<cmath>`

functions can't be`constexpr`

because they modify the global variable`errno`

– Ryan Haining Oct 10 '14 at 4:15