In general, there is no standard signum function in C/C++, and the lack of such a fundamental function tells you a lot about these languages.

Apart from that, I believe both majority viewpoints about the right approach to define such a function are in a way correct, and the "controversy" about it is actually a non-argument once you take into account two important caveats:

A *signum* function should always return the type of its operand, similarly to an `abs()`

function, because *signum* is usually used for multiplication with an absolute value after the latter has been processed somehow. Therefore, the major use case of *signum* is not comparisons but arithmetic, and the latter shouldn't involve any expensive integer-to/from-floating-point conversions.

Floating point types do not feature a single exact zero value: +0.0 can be interpreted as "infinitesimally above zero", and -0.0 as "infinitesimally below zero". That's the reason why comparisons involving zero must internally check against both values, and an expression like `x == 0.0`

can be dangerous.

Regarding C, I think the best way forward with integral types is indeed to use the `(x > 0) - (x < 0)`

expression, as it should be translated in a branch-free fashion, and requires only three basic operations. Best define inline functions that enforce a return type matching the argument type, and add a C11 `define _Generic`

to map these functions to a common name.

With floating point values, I think inline functions based on C11 `copysignf(1.0f, x)`

, `copysign(1.0, x)`

, and `copysignl(1.0l, x)`

are the way to go, simply because they're also highly likely to be branch-free, and additionally do not require casting the result from integer back into a floating point value. You should probably comment prominently that your floating point implementations of *signum* will not return zero because of the peculiarities of floating point zero values, processing time considerations, and also because it is often very useful in floating point arithmetic to receive the correct -1/+1 sign, even for zero values.

`x==0`

. According to IEEE 754, negative zero and positive zero should compare as equal. – RJFalconer Jun 4 '14 at 11:28