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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

log10(10n)

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.

share|improve this question
    
(Oops, the [ToInt32] coercsion doesn't work either there. In any case, perhaps there is a way to compute the epsilon for the particular value being checked - it won't be 1e-6 for the entire "integer range" in JavaScript.) – user166390 Feb 3 '13 at 1:46
    
So you want to determine whether a given float is a representation of an integer? It makes sense now. Removed a previous comment. – Fabrício Matté Feb 3 '13 at 1:55
1  
By the way, you can shorten Math.round(x) == x to (x % 1 == 0). That's also much, much faster. – Richard Connamacher Feb 3 '13 at 6:20

As you see in your example x is in fact not an integer at all. This is due to round-off errors earlier in your calculations, and thus you can in fact not know whether x was defined to be a nearly round number or a round number that got jagged up by round-off errors.

If you want to know what numbers is one or the other you will need to use the limit aproach you suggested yourself or use a high enough persicion that your numbers don't get jagged up in the first place. This last approach is not applicable in all cases.

There is also the possibility to track all mathematical operations symbolically, i.e. store 1/3 as 1/3 rather than 0.3333 and evaluate them on demand canceling out factors that can be canceled like you would when evaluating an expression by hand, but this is in almost all cases totally overkill. Not to mention how complex such a system would be. If this is the desired solution you can probably interface with MatLab or Mathematica or something to handle the evaluating, unless you are running this in a browser where it might be somewhat harder to do for browsers try the WolframAlpha API (why did't i think of that the first time?).

Nevertheless; If you can solve this problem by choosing ε in such a way you get a satisfactory result that is probably the best way to do it. If a static ε don't cut it you could try selecting it dynamically based on what type of calculations was done earlier to the number at hand. I.e. Numbers that are multiplied tend to create less of a fraction part than numbers that are divided, and so on. In cases where the number has not been subject to anything else than plus, minus and multiplication (not involving fractions) you can know how many decimal places it maximally can have as well and thus can pick a reasonable ε.

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+1 for "choosing ε in such a way you get a satisfactory result" – user166390 Feb 3 '13 at 1:53

Assuming x is non-zero, I think you should be looking at the ratio Math.abs(x-Math.round(x))/x. That deals with the fact that the floating point types each store a fixed number of significant bits, not a fixed number of digits after the decimal point.

Next, you need to determine the typical rounding error for your calculations. If x is the result of simple calculation that may be easy. If not, consider collecting some statistics from test cases for which you know the exact answer. Ideally, you will find that there is a significant difference between the largest value of the ratio for x integer, and the smallest value for x that should not be treated as an integer. If so, pick an epsilon in that range.

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That's a fun one, so I had to think a bit about it.

Here's a one-line solution, though it involves converting between number and string types so I don't know how optimal it is. But it will be far more accurate than just picking a minimum threshold and checking if the number's within that limit.

JavaScript numbers are double-precision 64-bit format, which has about 16 decimal digits of precision. That's total digits, not just the number of digits to the right of the decimal point.

JavaScript numbers also have a toPrecision() method that converts them to strings, rounded to a given precision (total digits, so good for your use). The following will round any number to the nearest 15 digits of precision, and then convert it back to a float.

function roundToPrecision(number, precision) {
    return parseFloat(number.toPrecision(precision));
}

x = roundToPrecision(x, 15);

Then your example will, in fact, be an integer: -4.

Edit: After some more thinking this will be way faster:

var integerDigits = (""+parseInt(Math.abs(x))).length,
    threshold = 1e-16 * Math.pow(10, integerDigits);

Math.abs(Math.round(x) - x) < threshold

http://jsperf.com/number-precision-rounding

share|improve this answer
    
This seams to me to be exactly what op suggested himself and said was not satisfactory, with the epsilon thing, just implemented in a different way. – Andreas Hagen Feb 3 '13 at 13:48
1  
fwiw, the second approach fails (i.e. produces false) when x = log10(Math.pow(10, -10))... – kjo Feb 3 '13 at 17:27
    
kjo: On my system (Safari 6 on Mac), log10(Math.pow(10, -10)) return exactly -10 so the second approach works. I wonder if the issue here isn't so much the precision of binary floats, but the accuracy of JavaScript log functions? – Richard Connamacher Feb 3 '13 at 21:40
    
Andreas: It does, but since it accounts for the number of integer digits it should produce fewer false positives. There's no way to get it perfectly accurate using floating point arithmetic; you'd have to use a fractional math library as you pointed out and it would be slow. But this should check if a float is "within machine precision" of an integer, which was the kjo's original question. – Richard Connamacher Feb 3 '13 at 21:46

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