As noted in other answers, rounding to an arbitrary number of decimal digits is closely related to printing the float. As algorithms which do round correctly are rather complex, the simplest way to do it right is using printf itself.
Note that you don't necessarily have to provide an arbitrary number of digits, an alternative is to use the shortest decimal that would be transformed back unchanged in base 2. Such algorithms are used for printing float in Scheme, Java, Python, Squeak/Pharo, etc ... Unfortunately, neither libm printf nor any standard C library are compliant.
Scheme is even better because it prints * where digits are not significant when you impose a fixed number of digits (* means that any digit would result in same float when converting back in base 2).
In this issue http://code.google.com/p/pharo/issues/detail?id=4957 there is an attachment named Float-asMinimalDecimalFraction.st containing an implementation in Smalltalk of similar algorithm for printing than Scheme but that outputs a fraction (the ratio of two arbitrary length integers) rather than an ASCII string.
So, for example, despite 14.2f is represented internally exactly as 14.19999980926513671875 it's not too late, you could retrieve that the shortest decimal fraction which correctly rounds to it is (142/10).
Using such code in Smalltalk, the solution to your problem would trivially be:
nanos := (floatingPointSeconds asMinimalDecimalFraction * 1e9) rounded.
But above code is using exact arithmetic (
1e9 is an integer) and arbitrary length integers under the hood.
Note that performing the multiplication in float would be bad:
nanos := (aFloat * 1e9) asMinimalDecimalFraction rounded.
Indeed, though 1e9 asFloat conversion is exact, its significand spans 21 bits, so the float multiplication would most probably cumulate round off errors and worsen the problem of retrieving a short fraction.
Though responding somehow technically to the question, I would personnaly consider above algorithm as pragmatically inappropriate for these reasons:
doing it with low level C/C++ instructions without the help of arbitrary precision arithmetic library is not the fastest path to the result
it's very limited since it would not apply to the result of computations with several rounding errors (they statistically require many digits)
it's overkill if you can simply avoid using a Float at all and work with nanos int
Nonetheless, it's always nice to know that it exists...