The problem isn't really solvable as stated, since floating-point is typically represented in binary, not in decimal. As you say, many (in fact most) decimal numbers are not exactly representable in floating-point.

On the other hand, *all* numbers that are exactly representable in binary floating-point are decimals with a finite number of digits -- but that's not particularly useful if you want a result of 2 for `3.44`

.

When I run your code snippet, it says that `3.44`

has 2 digits after the decimal point -- because `3.44 * 10.0 * 10.0`

just happens to yield exactly `344.0`

. That might not happen for another number like, say, `3.43`

(I haven't tried it).

When I try it with `1.0/3.0`

, it goes into an infinite loop. Adding some `printf`

s shows that `no`

becomes exactly `33333333333333324.0`

after 17 iterations -- but that number is too big to be represented as an `int`

(at least on my system), and converting it to `int`

has undefined behavior.

And for large numbers, repeatedly multiplying by 10 will inevitably give you a floating-point overflow. There are ways to avoid that, but they don't solve the other problems.

If you store the value `3.44`

in a `double`

object, the actual value stored (at least on my system) is exactly `3.439999999999999946709294817992486059665679931640625`

, which has 51 decimal digits in its fractional part. Suppose you really *want* to compute the number of decimal digits after the point in `3.439999999999999946709294817992486059665679931640625`

. Since `3.44`

and `3.439999999999999946709294817992486059665679931640625`

are effectively *the same number*, there's no way for any C function to distinguish between them and know whether it should return 2 or 51 (or 50 if you meant `3.43999999999999994670929481799248605966567993164062`

, or ...).

You could probably detect that the stored value is "close enough" to `3.44`

, but that makes it a much more complex problem -- and it loses the ability to determine the number of decimal digits in the fractional part of `3.439999999999999946709294817992486059665679931640625`

.

The question is meaningful only if the number you're given is stored in some format that can actually represent decimal fractions (such as a string), or if you add some complex requirement for determining which decimal fraction a given binary approximation is meant to represent.

There's probably a reasonable way to do the latter by looking for the unique decimal fraction whose nearest approximation in the given floating-point type is the given binary floating-point number.

shouldit do when you pass a non-ending decimal number to it? Should the program somehow know that`73.486999999999995`

is "actually"`73.487`

? Are you sure the decimal number should be a float, not a string representation? – Juhana Jul 24 '13 at 14:59`2.00000`

(which is exactly representable) is simply 0. And a question isn't stupid just because the answer happens to be "you can't do that". It's a good question if the OP and other readers learn something from it. – Keith Thompson Jul 24 '13 at 15:28