Is floating point precision mutable or invariant, and why?

Typically, given any numbers in the same power-of-2 range, the floating point precision is invariant - a fixed value. The absolute precision changes with each power-of-2 step. Over the entire FP range, the precision is approximately relative to the magnitude. Relating this relative binary precision in terms of a decimal precision incurs a *wobble* varying between `DBL_DIG`

and `DBL_DECIMAL_DIG`

decimal digits - Typically 15 to 17.

What is precision? With FP, it makes most sense to discuss *relative* precision.

Floating point numbers have the form of:

Sign * Significand * pow(base,exponent)

They have a logarithmic distribution. There are *about* as many different floating point numbers between 100.0 and 3000.0 ( a range of 30x) as there are between 2.0 and 60.0. This is true regardless of the underlying storage representation.

`1.23456789e100`

has about the same *relative* precision as `1.23456789e-100`

.

Most computers implemment `double`

as binary64. This format has 53 bits of *binary* precision.

The `n`

numbers between 1.0 and 2.0 have the same absolute precision of 1 part in ((2.0-1.0)/pow(2,52).

Numbers between 64.0 and 128.0, also `n`

, have the same absolute precision of 1 part in ((128.0-64.0)/pow(2,52).

Even group of numbers between powers of 2, have the same absolute precision.

Over the entire normal range of FP numbers, this approximates a uniform relative precision.

When these numbers are represented as decimal, the precision *wobbles*: Numbers 1.0 to 2.0 have 1 more bit of absolute precision than numbers 2.0 to 4.0. 2 more bits than 4.0 to 8.0, etc.

C provides `DBL_DIG`

, `DBL_DECIMAL_DIG`

, and their `float`

and `long double`

counterparts. `DBL_DIG`

indicates the minimum *relative* decimal precision. `DBL_DECIMAL_DIG`

can be thought of as the maximum *relative* decimal precision.

Typically this means given `double`

will have at 15 to 17 decimal digits of precision.

Consider `1.0`

and its next representable `double`

, the digits do not change until the 17th significant decimal digit. Each next `double`

is `pow(2,-52)`

or about `2.2204e-16`

apart.

```
/*
1 234567890123456789 */
1.000000000000000000...
1.000000000000000222...
```

Now consider `"8.521812787393891"`

and its next representable number as a decimal string using 16 significant decimal digits. Both of these strings, converted to `double`

are the *same* `8.521812787393891142073699...`

even though they differ in the 16th digit. Saying this `double`

had 16 digits of precision was over-stated.

```
/*
1 234567890123456789 */
8.521812787393891
8.521812787393891142073699...
8.521812787393892
```

aboutis due to the conversion from significantbitsto significantdigits. – Degustaf May 29 '15 at 19:21integermath. Fixed-point (though somewhat easier predictable than floating) is still just an approximation to the reals/rationals which are what you really want to express, in almost all interesting applications. And it's typically a worse approximation than floating-point! – leftaroundabout May 30 '15 at 9:53