The brief version of my question is:

What's considered "best practice" for deciding when a floating point number

`x`

and`Math.round(x)`

may be considered equal, allowing for loss of precision from floating-point operations?

The long-winded version is:

I often need to decide whether or not a given floating point value `x`

should be "regarded as an integer", or more pedantically, should be "regarded as the floating point representation of an integer".

(For example, if *n* is an integer, the mathematical expression

log

_{10}(10^{n})

is a convoluted way of representing the same integer *n*. This is the thinking that motivates saying that the result of the analogous floating-point computation may be regarded as "the representation of an integer".)

The decision is easy whenever `Math.round(x) == x`

evaluates to `true`

: in this case we can say that `x`

is indeed (the floating point representation of) an integer.

But the test `Math.round(x) == x`

is inconclusive when it evaluates to `false`

. For example,

```
function log10(x) { return Math.log(x)/Math.LN10; }
// -> function()
x = log10(Math.pow(10, -4))
// -> -3.999999999999999
Math.round(x) == x
// -> false
```

EDIT: one "solution" I often see is to pick some arbitrary tolerance, like `ε = 1e-6`

, and test for `Math.abs(Math.round(x) - x) < ε`

. I think such solutions would produce more false positives than I'd find acceptable.