There is no one right value. You need to compute it relative to the magnitude of the numbers involved. What you're basically dealing with is a number of significant digits, not a specific magnitude. If, for example, your numbers are both in the range of 1e-100, and your calculations should maintain roughly 8 significant digits, then your epsilon should be around 1e-108. If you did the same calculations on numbers in the range of 1e+200, then your epsilon would be around 1e+192 (i.e., epsilon ~= magnitude - significant digits).

I'd also note that `isEqual`

is a poor name -- you want something like `isNearlyEQual`

. For one reason, people quite reasonably expect "equal" to be transitive. At the very least, you need to convey the idea that the result is no longer transitive -- i.e., with your definition of `isEqual`

, `isEqual(a, c)`

can be false, even though `isEqual(a, b)`

and `isEqual(b, c)`

are both true.

Edit: (responding to comments): I said "If [...] your calculations should maintain roughly 8 significant digits, then your epsilon should be...". Basically, it comes to looking at what calculations you're doing, and how much precision you're likely to lose in the process, to provide a reasonable guess at how big a difference has to be before it's significant. Without knowing the calculation you're doing, I can't guess that.

As far as the magnitude of epsilon goes: no, it does *not* make sense for it to always be less than or equal to 1. A floating point number can only maintain limited precision. In the case of an IEEE double precision floating point, the *maximum* precision that can be represented is about 20 decimal digits. That means if you start with 1e+200, the absolute smallest difference from that number that the machine can represent *at all* is about 1e+180 (and a double can represent numbers up to ~1e+308, at which point the smallest difference that can be represented is ~1e+288).