@jatan

Thanks for you answer. It makes sense. Can you please explain me MathContext in the context of BigDecimal#round method.

There's nothing special about `BigDecimal.round()`

*vs.* any other `BigDecimal`

method. In all cases, the `MathContext`

specifies the number of significant digits and the rounding technique. Basically, there are two parts of every `MathContext`

. There's a precision, and there's also a `RoundingMode`

.

The precision again specifies the number of significant digits. So if you specify `123`

as a number, and ask for 2 significant digits, you're going to get `120`

. It might be clearer if you think in terms of scientific notation.

`123`

would be `1.23e2`

in scientific notation. If you only keep 2 significant digits, then you get `1.2e2`

, or `120`

. By reducing the number of significant digits, we reduce the precision with which we can specify a number.

The `RoundingMode`

part specifies how we should handle the loss of precision. To reuse the example, if you use `123`

as the number, and ask for 2 significant digits, you've reduced your precision. With a `RoundingMode`

of `HALF_UP`

(the default mode), `123`

will become `120`

. With a `RoundingMode`

of `CEILING`

, you'll get `130`

.

For example:

```
System.out.println(new BigDecimal("123.4",
new MathContext(4,RoundingMode.HALF_UP)));
System.out.println(new BigDecimal("123.4",
new MathContext(2,RoundingMode.HALF_UP)));
System.out.println(new BigDecimal("123.4",
new MathContext(2,RoundingMode.CEILING)));
System.out.println(new BigDecimal("123.4",
new MathContext(1,RoundingMode.CEILING)));
```

Outputs:

```
123.4
1.2E+2
1.3E+2
2E+2
```

You can see that both the precision and the rounding mode affect the output.