Given a floating-point number, I would like to separate it into a sum of parts, each with a given number of bits. For example, given 3.1415926535 and told to separate it into base-10 parts of 4 digits each, it would return 3.141 + 5.926E-4 + 5.350E-8. Actually, I want to separate a double (which has 52 bits of precision) into three parts with 18 bits of precision each, but it was easier to explain with a base-10 example. I am not necessarily averse to tricks that use the internal representation of a standard double-precision IEEE float, but I would really prefer a solution that stays purely in the floating point realm so as to avoid any issues with endian-dependency or non-standard floating point representations.
No, this is not a homework problem, and, yes, this has a practical use. If you want to ensure that floating point multiplications are exact, you need to make sure that any two numbers you multiply will never have more than half the digits that you have space for in your floating point type. Starting from this kind of decomposition, then multiplying all the parts and convolving, is one way to do that. Yes, I could also use an arbitrary-precision floating-point library, but this approach is likely to be faster when only a few parts are involved, and it will definitely be lighter-weight.