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
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
printfs 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 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
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.