Your initial rounding *is* working,^{1} in a sense. The problem is that 8.2 doesn't have a precise internal representation. If you just type `8.2`

into irb or display the results of the `#round(2)`

method call, it *looks* like you have 8.2 but you don't. A number slightly smaller than 8.2 is actually stored.

You end up being defeated by the defaults of the output rounding logic. Once the internal slightly-less-than-8.2 bits are multipled, the error is shifted into the integer part of the number and this part won't be rounded unless you ask for it. You could do this: `(a * 1000000).round`

The problem is that we write the numbers in decimal but store them in binary. This works fine for integers; but it works poorly with fractions.

In fact, *most* of the decimal fractions we write cannot be represented exactly.

Every machine fraction is a rational number of the form x/2^{n}. Now, the constants are decimal and every decimal constant is a rational number of the form x/(2^{n} * 5^{m}). The 5^{m} numbers are odd, so there isn't a 2^{n} factor for any of them. Only when *m == 0* is there a finite representation in both the binary and decimal expansion of the fraction. So, 1.25 is exact because it's 5 / (2^{2} * 5^{0}) but 0.1 is not because it's 1 / (2^{0} * 5^{1}). In fact, in the series 1.01 .. 1.99 only 3 of the numbers are exactly representable: 1.25, 1.50, and 1.75.

Because 8.2 has no exact representation, it repeats in binary forever, never quite adding up to exactly 8.2. It goes on to infinity as 1100110011...

^{1. But note that you might have wanted a.round(1) instead of 2. The parameter to #round is the number of fraction digits you want, not the number of significant digits. In this case, the result was the same and it didn't matter.}