_{This is a follow-up to Testing for floating-point value equality: Is there a standard name for the “precision” constant?.
There is a very similar question Double.Epsilon for equality, greater than, less than, less than or equal to, greater than or equal to.}

It is well known that an equality test for two floating-point values *x* and *y* should look more like this (rather than a straightforward =):

abs(

x-y) <epsilon, whereepsilonis some very small value.

**How to choose a value for epsilon?**

It would obviously be preferable to choose for *epsilon* as small a value as possible, to get the highest-possible precision for the equality check.

As an example, the .NET framework offers a constant `System.Double.Epsilon`

(= 4.94066 × 10^{-324}), which represents the smallest positive `System.Double`

value that is greater than zero.

However, it turns out that this particular value can't be reliably used as *epsilon*, since:

0 +

`System.Double.Epsilon`

≠ 01 +

`System.Double.Epsilon`

= 1 (!)

which is, if I understand correctly, because that constant is less than *machine epsilon*.

~~
→ Is this correct?~~

~~→ Does this also mean that I can reliably use ~~*epsilon := machine epsilon* for equality tests?

_{Removed these two questions, as they are already adequately answered by the second SO question linked-to above.}

The linked-to Wikipedia article says that for 64-bit floating-point numbers (ie. the `double`

type in many languages), machine epsilon is equal to:

2

^{-53}, or approx. 0.000000000000000111 (a number with 15 zeroes after the decimal point)

**→ Does it follow from this that all 64-bit floating point values are guaranteed to be accurate to 14 (if not 15) digits?**