Problem is sometimes Sum of field1 and
field2 is value like: 9.5-10.3 and the
result is -0.800000000000001. Could
anybody explain why this happens and
how to solve it?

## Why this happens

The `float`

and `double`

types store numbers in base 2, not in base 10. Sometimes, a number can be exactly represented in a finite number of bits.

```
9.5 → 1001.1
```

And sometimes it can't.

```
10.3 → 1010.0 1001 1001 1001 1001 1001 1001 1001 1001...
```

In the latter case, the number will get rounded to the closest value that *can* be represented as a `double`

:

```
1010.0100110011001100110011001100110011001100110011010 base 2
= 10.300000000000000710542735760100185871124267578125 base 10
```

When the subtraction is done in binary, you get:

```
-0.11001100110011001100110011001100110011001100110100000
= -0.800000000000000710542735760100185871124267578125
```

Output routines will usually hide most of the "noise" digits.

- Python 3.1 rounds it to
`-0.8000000000000007`

- SQLite 3.6 rounds it to
`-0.800000000000001`

.
`printf %g`

rounds it to `-0.8`

.

Note that, even on systems that display the value as -0.8, it's not the same as the best `double`

approximation of -0.8, which is:

```
- 0.11001100110011001100110011001100110011001100110011010
= -0.8000000000000000444089209850062616169452667236328125
```

So, in any programming language using `double`

, the expression `9.5 - 10.3 == -0.8`

will be false.

## The `decimal`

non-solution

With questions like these, the most common answer is "use decimal arithmetic". This does indeed get better output in this particular example. Using Python's `decimal.Decimal`

class:

```
>>> Decimal('9.5') - Decimal('10.3')
Decimal('-0.8')
```

However, you'll still have to deal with

```
>>> Decimal(1) / 3 * 3
Decimal('0.9999999999999999999999999999')
>>> Decimal(2).sqrt() ** 2
Decimal('1.999999999999999999999999999')
```

These may be *more familiar* rounding errors than the ones binary numbers have, but that doesn't make them *less important*.

In fact, binary fractions are *more* accurate than decimal fractions with the same number of bits, because of a combination of:

It's also *much* faster (on PCs) because it has dedicated hardware.

There is nothing special about base ten. It's just an arbitrary choice based on the number of fingers we have.

It would be just as accurate to say that a newborn baby weighs 0x7.5 lb (in more familiar terms, 7 lb 5 oz) as to say that it weighs 7.3 lb. (Yes, there's a 0.2 oz difference between the two, but it's within tolerance.) In general, decimal provides no advantage in representing physical measurements.

### Money is different

Unlike physical quantities which are *measured* to a certain level of precision, money is *counted* and thus an exact quantity. The quirk is that it's counted in multiples of 0.01 instead of multiples of 1 like most other discrete quantities.

If your "10.3" really means $10.30, then you *should* use a decimal number type to represent the value exactly.

(Unless you're working with historical stock prices from the days when they were in 1/16ths of a dollar, in which case binary is adequate anyway ;-) )

### Otherwise, it's just a display issue.

You got an answer correct to 15 significant digits. That's correct for all practical purposes. If you just want to hide the "noise", use the SQL `ROUND`

function.

everyprogrammer must eventually ask this question at some point in their career. :) A good reference is What Every Computer Scientist Should Know About Floating-Point Arithmetic – Adam Paynter Sep 12 '10 at 11:21