# Is there a reliable way in JavaScript to obtain the number of decimal places of an arbitrary number?

It's important to note that I'm not looking for a rounding function. I am looking for a function that returns the number of decimal places in an arbitrary number's simplified decimal representation. That is, we have the following:

decimalPlaces(5555.0);     //=> 0
decimalPlaces(5555);       //=> 0
decimalPlaces(555.5);      //=> 1
decimalPlaces(555.50);     //=> 1
decimalPlaces(0.0000005);  //=> 7
decimalPlaces(5e-7);       //=> 7
decimalPlaces(0.00000055); //=> 8
decimalPlaces(5.5e-7);     //=> 8

My first instinct was to use the string representations: split on '.', then on 'e-', and do the math, like so (the example is verbose):

function decimalPlaces(number) {
var parts = number.toString().split('.', 2),
integerPart = parts[0],
decimalPart = parts[1],
exponentPart;

if (integerPart.charAt(0) === '-') {
integerPart = integerPart.substring(1);
}

if (decimalPart !== undefined) {
parts = decimalPart.split('e-', 2);
decimalPart = parts[0];
}
else {
parts = integerPart.split('e-', 2);
integerPart = parts[0];
}
exponentPart = parts[1];

if (exponentPart !== undefined) {
return integerPart.length +
(decimalPart !== undefined ? decimalPart.length : 0) - 1 +
parseInt(exponentPart);
}
else {
return decimalPart !== undefined ? decimalPart.length : 0;
}
}

For my examples above, this function works. However, I'm not satisfied until I've tested every possible value, so I busted out Number.MIN_VALUE.

Number.MIN_VALUE;                      //=> 5e-324
decimalPlaces(Number.MIN_VALUE);       //=> 324

Number.MIN_VALUE * 100;                //=> 4.94e-322
decimalPlaces(Number.MIN_VALUE * 100); //=> 324

This looked reasonable at first, but then on a double take I realized that 5e-324 * 10 should be 5e-323! And then it hit me: I'm dealing with the effects of quantization of very small numbers. Not only are numbers being quantized before storage; additionally, some numbers stored in binary have unreasonably long decimal representations, so their decimal representations are being truncated. This is unfortunate for me, because it means that I can't get at their true decimal precision using their string representations.

So I come to you, StackOverflow community. Does anyone among you know a reliable way to get at a number's true post-decimal-point precision?

The purpose of this function, should anyone ask, is for use in another function that converts a float into a simplified fraction (that is, it returns the relatively coprime integer numerator and nonzero natural denominator). The only missing piece in this outer function is a reliable way to determine the number of decimal places in the float so I can multiply it by the appropriate power of 10. Hopefully I'm overthinking it.

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There are an infinite number of decimal places in any floating-point number. –  Lightness Races in Orbit Mar 2 '12 at 20:19
"the number of decimal places in an arbitrary integer's simplified decimal representation." - that would be zero. –  nnnnnn Mar 2 '12 at 20:19
You may be interested in this: blog.thatscaptaintoyou.com/… –  Dagg Nabbit Mar 2 '12 at 20:20
@LightnessRacesinOrbit: right, well I couldn't include all the details in the title! I do specify in the question, however, that I'm looking for the simplified representation. –  Milosz Mar 2 '12 at 20:29
@nnnnnn: I'm an idiot, fixed, thanks! –  Milosz Mar 2 '12 at 20:29

Based on the definition of Number.prototype.toFixed, the following should work:

function decimalPlaces(number) {
// toFixed produces a fixed representation accurate to 20 decimal places
// without an exponent.
// The ^-?\d*\. strips off any sign, integer portion, and decimal point
// leaving only the decimal fraction.
// The 0+\$ strips off any trailing zeroes.
return ((+number).toFixed(20)).replace(/^-?\d*\.?|0+\$/g, '').length
}

5555.0 => 0
5555 => 0
555.5 => 1
555.50 => 1
0.0000005 => 7
5e-7 => 7
0.00000055 => 8
5.5e-7 => 8

If you want something that maps 0.1e-100 to 101, then you can try something like

function decimalPlaces(n) {
// Make sure it is a number and use the builtin number -> string.
var s = "" + (+n);
// Pull out the fraction and the exponent.
var match = /(?:\.(\d+))?(?:[eE]([+\-]?\d+))?\$/.exec(s);
// NaN or Infinity or integer.
// We arbitrarily decide that Infinity is integral.
if (!match) { return 0; }
// Count the number of digits in the fraction and subtract the
// exponent to simulate moving the decimal point left by exponent places.
// 1.234e+2 has 1 fraction digit and '234'.length -  2 == 1
// 1.234e-2 has 5 fraction digit and '234'.length - -2 == 5
return Math.max(
0,  // lower limit.
(match[1] == '0' ? 0 : (match[1] || '').length)  // fraction length
- (match[2] || 0));  // exponent
}

According to the spec, any solution based on the builtin number->string conversion can only be accurate to 21 places beyond the exponent.

9.8.1 ToString Applied to the Number Type

1. Otherwise, let n, k, and s be integers such that k ≥ 1, 10k−1 ≤ s < 10k, the Number value for s × 10n−k is m, and k is as small as possible. Note that k is the number of digits in the decimal representation of s, that s is not divisible by 10, and that the least significant digit of s is not necessarily uniquely determined by these criteria.
2. If k ≤ n ≤ 21, return the String consisting of the k digits of the decimal representation of s (in order, with no leading zeroes), followed by n−k occurrences of the character ‘0’.
3. If 0 < n ≤ 21, return the String consisting of the most significant n digits of the decimal representation of s, followed by a decimal point ‘.’, followed by the remaining k−n digits of the decimal representation of s.
4. If −6 < n ≤ 0, return the String consisting of the character ‘0’, followed by a decimal point ‘.’, followed by −n occurrences of the character ‘0’, followed by the k digits of the decimal representation of s.
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Very informative, thank you. I think I might end up using toFixed(20) for simplicity's sake and ignore the really really small numbers. The quantization line has to be drawn somewhere, and 20 isn't low enough to be annoying for most purposes. –  Milosz Mar 2 '12 at 20:53
@Milosz, Yeah. If I was writing a library, I would go with the second approach, but for specific applications, the first may be sufficient. One thing to note though is that the first doesn't deal as well with NaN and ±Infinity. –  Mike Samuel Mar 2 '12 at 22:19
This isn't working for me in Google Chrome version 30. Input of 555.50 results in an output of 1, but 555.20 results in an output of 20. –  user1 Oct 9 at 20:20

this works for numbers smaller than e-17 :

function decimalPlaces(n){
var a;
return (a=(n.toString().charAt(0)=='-'?n-1:n+1).toString().replace(/^-?[0-9]+\.?([0-9]+)\$/,'\$1').length)>=1?a:0;
}
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This reminds me that I forgot to include checking for minus signs at the beginning of the number. Thanks! I also enjoy how concise this function is. Pushing the number past 1 in absolute value to avoid the negative exponent is clever (though I don't understand why JavaScript switches to exponent notation so much later for positive exponents). If nothing that works past e-17 comes along, this is probably what I'll go with. –  Milosz Mar 2 '12 at 20:22
Incorrectly returns 0 for 1.2 –  serg Apr 1 at 0:12

Not only are numbers being quantized before storage; additionally, some numbers stored in binary have unreasonably long decimal representations, so their decimal representations are being truncated.

JavaScript represents numbers using IEEE-754 double-precision (64 bit) format. As I understand it this gives you 53 bits precision, or fifteen to sixteen decimal digits.

So for any number with more digits you just get an approximation. There are some libraries around to handle large numbers with more precision, including those mentioned in this thread.

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Well, I use a solution based on the fact that if you multiply a floating point number by the right power of 10, you get an integer.

For instance, if you multiply 3.14 * 10 ^ 2, you get 314 (an integer). The exponent represents then the number of integers the floating point number has.

So, I thought that if I gradually multiply a floating point by increasing powers of 10, you eventually arrive at the solution.

var decimalPlaces = function(){
function isInt(n){
return typeof n === 'number' &&
parseFloat(n) == parseInt(n, 10) && !isNaN(n);
}
return function(n){
var a = Math.abs(n);
var c = a, count = 1;
while(!isInt(c) && isFinite(c)){
c = a * Math.pow(10,count++);
}
return count-1;
};
}();

If I do:

console.log(decimalPlaces(3.14)); //yields 2
console.log(decimalPlaces(2.e-14)); //yields 14
console.log(decimalPlaces(-3.14e-21)); //yields 23
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