The `modf`

function breaks a `double`

argument into integral and fractional parts; for example, given `3.75`

it returns `0.75`

and stores `3.0`

in the object pointed to by its second argument.

The question is, what should happen if you call it with a value that's too big to fit in any integer type?

If it returned an `int`

result, or even a `long long`

or `intmax_t`

result, it would have to deal with overflow somehow, which would likely require adding an extra parameter to distinguish valid results from overflows.

By returning a `double`

result, overflow is not possible; for very large arguments, it can just return the argument value and set the fractional part to `0.0`

. It simplifies the function considerably. (If you want to convert the result to an integer you can do so -- but you should check the result against the bounds of the integer type you're using.)

On modern systems `double`

is typically 64 bits, and can represent integers up to about 2^{53} exactly. If you call `modf`

with a value greater than 2^{53}, then the `double`

value itself can't necessarily hold an exact integer value; having `modf`

return even a 64-bit integer wouldn't provide any extra precision.

A `long double`

, depending on the implementation, might be able to hold a wider range of exact integer values than even the widest integer type; on such a system, making `modfl`

return an integer would lose precision relative to having it return `long double`

.

So having `modf`

(and `modff`

and `modfl`

) return an integer rather than a floating-point value would lose range without any corresponding gain in precision.

`double`

is not inherently less precise than`int`

. In a typical case,`double`

can represent every integer in the range -2e53..2e53 precisely.3more comments