This question already has an answer here:

- Is floating point math broken? 26 answers
- Rounding oddity - what is special about “100”? 2 answers

As I understand this, some numbers can't be represented with exactitude in binary, and that's why floating-point arithmetic sometimes gives us unexpected results; like 4.35 * 100 = 434.99999999999994. Something similar to what happens with 1/3 in decimal.

That makes sense, but this induces another question. Seems that in binary both 4.35 and 435 can be represented with exactitude. That's when it stops making sense to me. Why does 4.35 * 100 evaluates to 434.99999999999994? 435 and 4.35 have an exact representation in the double type dynamics:

```
double number1 = 4.35;
double number2 = 435;
double number3 = 100;
System.out.println(number1); // 4.35
System.out.println(number2); // 435.0
System.out.println(number3); // 100.0
// So far so good. Everything ok.
System.out.println(number1 * number3); // 434.99999999999994 !!!
// But 4.35 * 100 evaluates to 434.99999999999994
```

Why?

Edit: this question was marked as duplicate, and it is not. As you can see in the accepted answer, my confusion was regarding the discrepancy between the actual value and the printed value.

`double`

value to`4.35`

is`4.3499999999999996447286321199499070644378662109375`

. Multiplying by 100 produces`434.99999999999994315658113919198513031005859375`

. – Daniel Fischer Aug 22 '13 at 19:49a prioriquite likely that`4.35 * 100`

would have computed as`435`

. By the way, fractional floating-point numbers have either .5 or a sequence of digits that end in 25 or in 75 as fractional part. – Pascal Cuoq Aug 22 '13 at 20:01`4.35 * 100`

would not compute as 435. – Pascal Cuoq Aug 22 '13 at 20:05