The cardinal rule of numerical computing is to avoid subtracting nearly equal numbers. Multiplication and division are always accurate: you lose at most one bit of precision in performing a multiply or divide. But if two numbers agree to n bits, you can lose up to n bits of precision in their subtraction.

There are all kinds of tricks for avoiding such subtractions. For example, suppose you need to calculate exp(x) - 1 for small values of x. (This is something you might do in an interest calculation.) If x is so small that exp(x) equals 1 to all the precision of the computer, then the subtraction will give exactly 0, and the resulting relative error will be 100%. But if you use the Taylor approximation exp(x) - 1 = x + x^2/2 + ... you could get a more accurate answer. For example, exp(10^-17) - 1 will be completely inaccurate, but 10^-17, the one-term Taylor approximation, would be very accurate. This is how functions like `expm1`

work. See the explanation of `log1p`

and `expm1`

here.

If you're concerned about numerical accuracy, you need to understand the anatomy of floating point numbers in order to know what is safe and what is not.