Formatting a number with exactly two decimals in JavaScript

I have this line of code which rounds my numbers to two decimal places. But I get numbers like this: 10.8, 2.4, etc. These are not my idea of two decimal places so how I can improve the following?

``````Math.round(price*Math.pow(10,2))/Math.pow(10,2);
``````

I want numbers like 10.80, 2.40, etc. Use of jQuery is fine with me.

• Your code is exactly what I was looking for(to reduce float precision to 7 decimal places for smaller JSON file) Skipping Math.pow for speed val = Math.round(val * 10000000) / 10000000); Jun 4 '16 at 21:44
• As the currently-accepted answer gives arguably a wrong result for a broad range of values thanks to aggravating imprecision inherent in the numbers (`0.565`, `0.575`, `1.005`), can I suggest looking again at this answer, which gets them correct? Oct 27 '16 at 9:08
• Maybe you want to include an sprintf library for JavaScript stackoverflow.com/questions/610406/… Oct 27 '16 at 9:27
• After correctly rounding with the decimal place shifting and rounding method, you could use the `number.toFixed(x)` method to convert it to a string with the required amount of zeroes. E.g. round `1.34` to `1.3` with the cross-browser method then add 1 zero and convert to string with `1.3.toFixed(2)` (to get `"1.30"`). Nov 19 '16 at 15:26
• It's 2020 and there is no simple native way in JavaScript to simply round a number. wow.
– Sliq
Nov 26 '20 at 1:34

To format a number using fixed-point notation, you can simply use the toFixed method:

``````(10.8).toFixed(2); // "10.80"

var num = 2.4;
``````

Note that `toFixed()` returns a string.

IMPORTANT: Note that toFixed does not round 90% of the time, it will return the rounded value, but for many cases, it doesn't work.

For instance:

`2.005.toFixed(2) === "2.00"`

UPDATE:

Nowadays, you can use the `Intl.NumberFormat` constructor. It's part of the ECMAScript Internationalization API Specification (ECMA402). It has pretty good browser support, including even IE11, and it is fully supported in Node.js.

``````const formatter = new Intl.NumberFormat('en-US', {
minimumFractionDigits: 2,
maximumFractionDigits: 2,
});

console.log(formatter.format(2.005)); // "2.01"
console.log(formatter.format(1.345)); // "1.35"``````

You can alternatively use the `toLocaleString` method, which internally will use the `Intl` API:

``````const format = (num, decimals) => num.toLocaleString('en-US', {
minimumFractionDigits: 2,
maximumFractionDigits: 2,
});

console.log(format(2.005)); // "2.01"
console.log(format(1.345)); // "1.35"``````

This API also provides you a wide variety of options to format, like thousand separators, currency symbols, etc.

• Doesn't work consistently across all browsers, ie `(0.09).toFixed(1);` gives 0.0 in IE8 Oct 10 '11 at 22:55
• fixed doesn't round, you can do it first: (Math.round(0.09)).toFixed(1); Jan 20 '12 at 11:02
• @rekans: This is wrong. `Math.Round(0.09)` will return `0` so this will always give `0.0`... May 11 '12 at 10:33
• This is a bad idea in most situations, it converts the number to a string or float point number in some cases. Jun 20 '12 at 15:19
• Have to agree with @AshBlue here... this is only safe for formatting presentation of values. May break code with further calculations. Otherwise `Math.round(value*100)/100` works better for 2DP. Aug 2 '12 at 6:11

This is an old topic but still top-ranked Google results and the solutions offered share the same floating point decimals issue. Here is the (very generic) function I use, thanks to MDN:

``````function round(value, exp) {
if (typeof exp === 'undefined' || +exp === 0)
return Math.round(value);

value = +value;
exp = +exp;

if (isNaN(value) || !(typeof exp === 'number' && exp % 1 === 0))
return NaN;

// Shift
value = value.toString().split('e');
value = Math.round(+(value[0] + 'e' + (value[1] ? (+value[1] + exp) : exp)));

// Shift back
value = value.toString().split('e');
return +(value[0] + 'e' + (value[1] ? (+value[1] - exp) : -exp));
}
``````

As we can see, we don't get these issues:

``````round(1.275, 2);   // Returns 1.28
round(1.27499, 2); // Returns 1.27
``````

This genericity also provides some cool stuff:

``````round(1234.5678, -2);   // Returns 1200
round(1.2345678e+2, 2); // Returns 123.46
round("123.45");        // Returns 123
``````

Now, to answer the OP's question, one has to type:

``````round(10.8034, 2).toFixed(2); // Returns "10.80"
round(10.8, 2).toFixed(2);    // Returns "10.80"
``````

Or, for a more concise, less generic function:

``````function round2Fixed(value) {
value = +value;

if (isNaN(value))
return NaN;

// Shift
value = value.toString().split('e');
value = Math.round(+(value[0] + 'e' + (value[1] ? (+value[1] + 2) : 2)));

// Shift back
value = value.toString().split('e');
return (+(value[0] + 'e' + (value[1] ? (+value[1] - 2) : -2))).toFixed(2);
}
``````

You can call it with:

``````round2Fixed(10.8034); // Returns "10.80"
round2Fixed(10.8);    // Returns "10.80"
``````

Various examples and tests (thanks to @t-j-crowder!):

``````function round(value, exp) {
if (typeof exp === 'undefined' || +exp === 0)
return Math.round(value);

value = +value;
exp = +exp;

if (isNaN(value) || !(typeof exp === 'number' && exp % 1 === 0))
return NaN;

// Shift
value = value.toString().split('e');
value = Math.round(+(value[0] + 'e' + (value[1] ? (+value[1] + exp) : exp)));

// Shift back
value = value.toString().split('e');
return +(value[0] + 'e' + (value[1] ? (+value[1] - exp) : -exp));
}
function naive(value, exp) {
if (!exp) {
return Math.round(value);
}
var pow = Math.pow(10, exp);
return Math.round(value * pow) / pow;
}
function test(val, places) {
subtest(val, places);
val = typeof val === "string" ? "-" + val : -val;
subtest(val, places);
}
function subtest(val, places) {
var placesOrZero = places || 0;
var naiveResult = naive(val, places);
var roundResult = round(val, places);
if (placesOrZero >= 0) {
naiveResult = naiveResult.toFixed(placesOrZero);
roundResult = roundResult.toFixed(placesOrZero);
} else {
naiveResult = naiveResult.toString();
roundResult = roundResult.toString();
}
\$("<tr>")
.append(\$("<td>").text(JSON.stringify(val)))
.append(\$("<td>").text(placesOrZero))
.append(\$("<td>").text(naiveResult))
.append(\$("<td>").text(roundResult))
.appendTo("#results");
}
test(0.565, 2);
test(0.575, 2);
test(0.585, 2);
test(1.275, 2);
test(1.27499, 2);
test(1234.5678, -2);
test(1.2345678e+2, 2);
test("123.45");
test(10.8034, 2);
test(10.8, 2);
test(1.005, 2);
test(1.0005, 2);``````
``````table {
border-collapse: collapse;
}
table, td, th {
border: 1px solid #ddd;
}
td, th {
}
th {
font-weight: normal;
font-family: sans-serif;
}
td {
font-family: monospace;
}``````
``````<table>
<tr>
<th>Input</th>
<th>Places</th>
<th>Naive</th>
<th>Thorough</th>
</tr>
<tbody id="results">
</tbody>
</table>

• How is there not a simple way to do this? ES6 to the rescue? Jul 12 '17 at 4:11
• Thank you for posting the MDN polyfill. On the linked MDN page the polyfill is no longer there. I wonder why it was removed... Apr 29 '19 at 20:43
• How can I use it to get value upto first decimal place,like 3.0421 shuld return 3.0?
– RIni
Apr 28 at 10:03
• @RIni, you should be able to use `round(3.0421, 1)` to get `3` as a number or `round(3.0421, 1).toFixed(1)` to get `'3.0'` as a string. Apr 28 at 14:23

I usually add this to my personal library, and after some suggestions and using the @TIMINeutron solution too, and making it adaptable for decimal length then, this one fits best:

``````function precise_round(num, decimals) {
var t = Math.pow(10, decimals);
return (Math.round((num * t) + (decimals>0?1:0)*(Math.sign(num) * (10 / Math.pow(100, decimals)))) / t).toFixed(decimals);
}
``````

will work for the exceptions reported.

• precise_round(1.275,2) is 1.27? Mar 14 '13 at 4:25
• @Imre Change the return value to (Math.round(num*Math.pow(10,decimals))/Math.pow(10,decimals)).toFixed(2); and you will no longer have that issue. Aug 7 '13 at 8:26
• where do you declare "sign" and "dec" if your second function is picked up as is shouldn't it have them as undefined? Jan 28 '14 at 18:44
• I've added a workarround for missign sign method in IE: gist.github.com/ArminVieweg/28647e735aa6efaba401 Jan 28 '15 at 14:45
• @Armin Your fix also makes it work in Safari. The original function did not work in Safari.
– Dave
Apr 27 '15 at 19:21

I don't know why can't I add a comment to a previous answer (maybe I'm hopelessly blind, I don't know), but I came up with a solution using @Miguel's answer:

``````function precise_round(num,decimals) {
return Math.round(num*Math.pow(10, decimals)) / Math.pow(10, decimals);
}
``````

And its two comments (from @bighostkim and @Imre):

• Problem with `precise_round(1.275,2)` not returning 1.28
• Problem with `precise_round(6,2)` not returning 6.00 (as he wanted).

My final solution is as follows:

``````function precise_round(num,decimals) {
var sign = num >= 0 ? 1 : -1;
return (Math.round((num*Math.pow(10,decimals)) + (sign*0.001)) / Math.pow(10,decimals)).toFixed(decimals);
}
``````

As you can see I had to add a little bit of "correction" (it's not what it is, but since Math.round is lossy - you can check it on jsfiddle.net - this is the only way I knew how to "fix" it). It adds 0.001 to the already padded number, so it is adding a `1` three `0`s to the right of the decimal value. So it should be safe to use.

After that I added `.toFixed(decimal)` to always output the number in the correct format (with the right amount of decimals).

So that's pretty much it. Use it well ;)

EDIT: added functionality to the "correction" of negative numbers.

• The "correction" is mostly safe, but e.g. `precise_round(1.27499,2)` now also returns 1.28... It's not `Math.round` that is lossy; the way that computers internally store floating point values is. Basically, you're doomed to fail with some values before the data even gets to your function :)
– Imre
Aug 7 '13 at 10:12
• @Imre, you're absolutelly right. That's why I explain what is this 0.001 doing there, in case anyone wants to make it "more precise" or even delete it (if you happen to have a super computer with 2 Mbytes per float, wich I don't think anyone here does ;) Aug 30 '13 at 19:56
• Actually, the language specification is pretty specific about using 64 bits for number values, so having/using a supercomputer wouldn't change anything :)
– Imre
Sep 4 '13 at 7:58
• for the 0.001 you can replace by adding many zeros according to length of the decimals. so.. Oct 26 '13 at 22:13

One way to be 100% sure that you get a number with 2 decimals:

``````(Math.round(num*100)/100).toFixed(2)
``````

If this causes rounding errors, you can use the following as James has explained in his comment:

``````(Math.round((num * 1000)/10)/100).toFixed(2)
``````
• This is the best, simplest way to do it. However, due to floating point math, 1.275 * 100 = 127.49999999999999, which could cause minor errors in the rounding. To fix this, we can multiply by 1000 and divide by 10, as (1.275 * 1000)/10 = 127.5. As follows: `var answer = (Math.round((num * 1000)/10)/100).toFixed(2);` Jun 13 '14 at 19:36
• (Math.round((1.015 * 1000)/10)/100).toFixed(2) still gives 1.01, shouldn't it be 1.02 ? Dec 26 '19 at 5:12
• `(Math.round((99999999999999.9999 * 1000)/10)/100).toFixed(4)` returns `"100000000000000.0000"` Aug 30 at 19:35

toFixed(n) provides n length after the decimal point; toPrecision(x) provides x total length.

Use this method below

``````// Example: toPrecision(4) when the number has 7 digits (3 before, 4 after)
// It will round to the tenths place
num = 500.2349;
result = num.toPrecision(4); // result will equal 500.2
``````

AND if you want the number to be fixed use

``````result = num.toFixed(2);
``````
• it does not work well... for number num = 50.2349 you should write toPrecision(3) to get 50.2 May 14 '14 at 7:51
• its just an example you can change it as per your need @PiotrCzyż May 14 '14 at 11:15

I didn't find an accurate solution for this problem, so I created my own:

``````function inprecise_round(value, decPlaces) {
return Math.round(value*Math.pow(10,decPlaces))/Math.pow(10,decPlaces);
}

function precise_round(value, decPlaces){
var val = value * Math.pow(10, decPlaces);
var fraction = (Math.round((val-parseInt(val))*10)/10);

//this line is for consistency with .NET Decimal.Round behavior
// -342.055 => -342.06
if(fraction == -0.5) fraction = -0.6;

val = Math.round(parseInt(val) + fraction) / Math.pow(10, decPlaces);
return val;
}
``````

Examples:

``````function inprecise_round(value, decPlaces) {
return Math.round(value * Math.pow(10, decPlaces)) / Math.pow(10, decPlaces);
}

function precise_round(value, decPlaces) {
var val = value * Math.pow(10, decPlaces);
var fraction = (Math.round((val - parseInt(val)) * 10) / 10);

//this line is for consistency with .NET Decimal.Round behavior
// -342.055 => -342.06
if (fraction == -0.5) fraction = -0.6;

val = Math.round(parseInt(val) + fraction) / Math.pow(10, decPlaces);
return val;
}

// This may produce different results depending on the browser environment
console.log("342.055.toFixed(2)         :", 342.055.toFixed(2)); // 342.06 on Chrome & IE10

console.log("inprecise_round(342.055, 2):", inprecise_round(342.055, 2)); // 342.05
console.log("precise_round(342.055, 2)  :", precise_round(342.055, 2));   // 342.06
console.log("precise_round(-342.055, 2) :", precise_round(-342.055, 2));  // -342.06

console.log("inprecise_round(0.565, 2)  :", inprecise_round(0.565, 2));   // 0.56
console.log("precise_round(0.565, 2)    :", precise_round(0.565, 2));     // 0.57``````

• Thanks. Here's a ditty to test this: jsfiddle.net/lamarant/ySXuF. I'm applying toFixed() to the value prior to returning it which appends the correct number of zeroes to the end of the returned value. Jul 7 '13 at 18:27
• not working for value=0,004990845956707237 and inprecise_round(value,8) returns 0,00499085 but it must return 0,00499084 Jan 28 '18 at 13:05
• inprecise_round(9.999, 2) give 10 where it needs to be 9.99 Sep 6 at 4:16

@heridev and I created a small function in jQuery.

You can try next:

HTML

``````<input type="text" name="one" class="two-digits"><br>
<input type="text" name="two" class="two-digits">​
``````

jQuery

``````// apply the two-digits behaviour to elements with 'two-digits' as their class
\$( function() {
\$('.two-digits').keyup(function(){
if(\$(this).val().indexOf('.')!=-1){
if(\$(this).val().split(".")[1].length > 2){
if( isNaN( parseFloat( this.value ) ) ) return;
this.value = parseFloat(this.value).toFixed(2);
}
}
return this; //for chaining
});
});
``````

​ DEMO ONLINE:

http://jsfiddle.net/c4Wqn/

• I can appreciate the contribution, though I think adding DOM elements and jQuery into the mix seems out of the scope of the question. Sep 5 '13 at 11:58
• You shouldn't listen to the keyup event, as it looks verry bad and doesn't activate when you add something with script. I'd rather listen to the `input` event. This doesn't create a flickering effect and also fires when you access the field with JS Nov 26 '15 at 21:29

The trouble with floating point values is that they are trying to represent an infinite amount of (continuous) values with a fixed amount of bits. So naturally, there must be some loss in play, and you're going to be bitten with some values.

When a computer stores 1.275 as a floating point value, it won't actually remember whether it was 1.275 or 1.27499999999999993, or even 1.27500000000000002. These values should give different results after rounding to two decimals, but they won't, since for computer they look exactly the same after storing as floating point values, and there's no way to restore the lost data. Any further calculations will only accumulate such imprecision.

So, if precision matters, you have to avoid floating point values from the start. The simplest options are to

• use a devoted library
• use strings for storing and passing around the values (accompanied by string operations)
• use integers (e.g. you could be passing around the amount of hundredths of your actual value, e.g. amount in cents instead of amount in dollars)

For example, when using integers to store the number of hundredths, the function for finding the actual value is quite simple:

``````function descale(num, decimals) {
var hasMinus = num < 0;
var numString = Math.abs(num).toString();
var precedingZeroes = '';
for (var i = numString.length; i <= decimals; i++) {
precedingZeroes += '0';
}
numString = precedingZeroes + numString;
return (hasMinus ? '-' : '')
+ numString.substr(0, numString.length-decimals)
+ '.'
+ numString.substr(numString.length-decimals);
}

``````

With strings, you'll need rounding, but it's still manageable:

``````function precise_round(num, decimals) {
var parts = num.split('.');
var hasMinus = parts.length > 0 && parts[0].length > 0 && parts[0].charAt(0) == '-';
var integralPart = parts.length == 0 ? '0' : (hasMinus ? parts[0].substr(1) : parts[0]);
var decimalPart = parts.length > 1 ? parts[1] : '';
if (decimalPart.length > decimals) {
var roundOffNumber = decimalPart.charAt(decimals);
decimalPart = decimalPart.substr(0, decimals);
if ('56789'.indexOf(roundOffNumber) > -1) {
var numbers = integralPart + decimalPart;
var i = numbers.length;
var trailingZeroes = '';
var justOneAndTrailingZeroes = true;
do {
i--;
var roundedNumber = '1234567890'.charAt(parseInt(numbers.charAt(i)));
if (roundedNumber === '0') {
trailingZeroes += '0';
} else {
numbers = numbers.substr(0, i) + roundedNumber + trailingZeroes;
justOneAndTrailingZeroes = false;
break;
}
} while (i > 0);
if (justOneAndTrailingZeroes) {
numbers = '1' + trailingZeroes;
}
integralPart = numbers.substr(0, numbers.length - decimals);
decimalPart = numbers.substr(numbers.length - decimals);
}
} else {
for (var i = decimalPart.length; i < decimals; i++) {
decimalPart += '0';
}
}
return (hasMinus ? '-' : '') + integralPart + (decimals > 0 ? '.' + decimalPart : '');
}

``````

Note that this function rounds to nearest, ties away from zero, while IEEE 754 recommends rounding to nearest, ties to even as the default behavior for floating point operations. Such modifications are left as an exercise for the reader :)

• `precise_round("999999999999999999.9999", 2)` returns `"1000000000000000000.00"` Aug 30 at 19:46
• I want it to be `999999999999999999.99` Aug 30 at 19:46
• @FaizanHussainRabbani 1000000000000000000.00 is the correct result for this rounding - 9.9999 is much closer to 10.00 than 9.99. Rounding is a function defined in mathematics and standardized for computing in IEEE 754. If you want a different result, you need a different function. Write the tests to specify what results you need for various inputs, and write code that would satisfy those tests.
– Imre
Aug 31 at 5:58

Here's a simple one

``````function roundFloat(num,dec){
var d = 1;
for (var i=0; i<dec; i++){
d += "0";
}
return Math.round(num * d) / d;
}
``````

Use like `alert(roundFloat(1.79209243929,4));`

Jsfiddle

Round down

``````function round_down(value, decPlaces) {
return Math.floor(value * Math.pow(10, decPlaces)) / Math.pow(10, decPlaces);
}
``````

Round up

``````function round_up(value, decPlaces) {
return Math.ceil(value * Math.pow(10, decPlaces)) / Math.pow(10, decPlaces);
}
``````

Round nearest

``````function round_nearest(value, decPlaces) {
return Math.round(value * Math.pow(10, decPlaces)) / Math.pow(10, decPlaces);
}
``````

FAST AND EASY

``````parseFloat(number.toFixed(2))
``````

Example

``````let number = 2.55435930

let roundedString = number.toFixed(2)    // "2.55"

let twoDecimalsNumber = parseFloat(roundedString)    // 2.55

let directly = parseFloat(number.toFixed(2))    // 2.55
``````
• after searching for some time, finally this worked with me, simple and easy
– Omar
Mar 16 at 16:43
• Yes, with caveats mentioned above about toFixed, which can return inaccurate roundings for stuff like 1.005. You SHOULD mention those caveats in your answer. Aug 19 at 20:35
• parseFloat(13.99999).toFixed(2) > "14.00" parseFloat(parseFloat(13.99999).toFixed(2)) > 14 Sep 8 at 6:55

Round your decimal value, then use `toFixed(x)` for your expected digit(s).

``````function parseDecimalRoundAndFixed(num,dec){
var d =  Math.pow(10,dec);
return (Math.round(num * d) / d).toFixed(dec);
}
``````

Call

parseDecimalRoundAndFixed(10.800243929,4) => 10.80 parseDecimalRoundAndFixed(10.807243929,2) => 10.81

``````Number(Math.round(1.005+'e2')+'e-2'); // 1.01
``````

This worked for me: Rounding Decimals in JavaScript

With these examples you will still get an error when trying to round the number 1.005 the solution is to either use a library like Math.js or this function:

``````function round(value: number, decimals: number) {
return Number(Math.round(value + 'e' + decimals) + 'e-' + decimals);
}
``````

Here is my 1-line solution: `Number((yourNumericValueHere).toFixed(2));`

Here's what happens:

1) First, you apply `.toFixed(2)` onto the number that you want to round off the decimal places of. Note that this will convert the value to a string from number. So if you are using Typescript, it will throw an error like this:

"Type 'string' is not assignable to type 'number'"

2) To get back the numeric value or to convert the string to numeric value, simply apply the `Number()` function on that so-called 'string' value.

For clarification, look at the example below:

EXAMPLE: I have an amount that has upto 5 digits in the decimal places and I would like to shorten it to upto 2 decimal places. I do it like so:

``````var price = 0.26453;
var priceRounded = Number((price).toFixed(2));
console.log('Original Price: ' + price);
console.log('Price Rounded: ' + priceRounded);``````

In general, decimal rounding is done by scaling: `round(num * p) / p`

Naive implementation

Using the following function with halfway numbers, you will get either the upper rounded value as expected, or the lower rounded value sometimes depending on the input.

This `inconsistency` in rounding may introduce hard to detect bugs in the client code.

``````function naiveRound(num, decimalPlaces) {
var p = Math.pow(10, decimalPlaces);
return Math.round(num * p) / p;
}

console.log( naiveRound(1.245, 2) );  // 1.25 correct (rounded as expected)
console.log( naiveRound(1.255, 2) );  // 1.25 incorrect (should be 1.26)``````

Better implementations

By converting the number to a string in the exponential notation, positive numbers are rounded as expected. But, be aware that negative numbers round differently than positive numbers.

In fact, it performs what is basically equivalent to "round half up" as the rule, you will see that `round(-1.005, 2)` evaluates to `-1` even though `round(1.005, 2)` evaluates to `1.01`. The lodash _.round method uses this technique.

``````/**
* Round half up ('round half towards positive infinity')
* Uses exponential notation to avoid floating-point issues.
* Negative numbers round differently than positive numbers.
*/
function round(num, decimalPlaces) {
num = Math.round(num + "e" + decimalPlaces);
return Number(num + "e" + -decimalPlaces);
}

// test rounding of half
console.log( round(0.5, 0) );  // 1
console.log( round(-0.5, 0) ); // 0

// testing edge cases
console.log( round(1.005, 2) );   // 1.01
console.log( round(2.175, 2) );   // 2.18
console.log( round(5.015, 2) );   // 5.02

console.log( round(-1.005, 2) );  // -1
console.log( round(-2.175, 2) );  // -2.17
console.log( round(-5.015, 2) );  // -5.01``````

If you want the usual behavior when rounding negative numbers, you would need to convert negative numbers to positive before calling Math.round(), and then convert them back to negative numbers before returning.

``````// Round half away from zero
function round(num, decimalPlaces) {
num = Math.round(Math.abs(num) + "e" + decimalPlaces) * Math.sign(num);
return Number(num + "e" + -decimalPlaces);
}
``````

There is a different purely mathematical technique to perform round-to-nearest (using "round half away from zero"), in which epsilon correction is applied before calling the rounding function.

Simply, we add the smallest possible float value (= 1.0 ulp; unit in the last place) to the number before rounding. This moves to the next representable value after the number, away from zero.

``````/**
* Round half away from zero ('commercial' rounding)
* Uses correction to offset floating-point inaccuracies.
* Works symmetrically for positive and negative numbers.
*/
function round(num, decimalPlaces) {
var p = Math.pow(10, decimalPlaces);
var e = Number.EPSILON * num * p;
return Math.round((num * p) + e) / p;
}

// test rounding of half
console.log( round(0.5, 0) );  // 1
console.log( round(-0.5, 0) ); // -1

// testing edge cases
console.log( round(1.005, 2) );  // 1.01
console.log( round(2.175, 2) );  // 2.18
console.log( round(5.015, 2) );  // 5.02

console.log( round(-1.005, 2) ); // -1.01
console.log( round(-2.175, 2) ); // -2.18
console.log( round(-5.015, 2) ); // -5.02``````

This is needed to offset the implicit round-off error that may occur during encoding of decimal numbers, particularly those having "5" in the last decimal position, like 1.005, 2.675 and 16.235. Actually, `1.005` in decimal system is encoded to `1.0049999999999999` in 64-bit binary float; while, `1234567.005` in decimal system is encoded to `1234567.0049999998882413` in 64-bit binary float.

It is worth noting that the maximum binary `round-off error` is dependent upon (1) the magnitude of the number and (2) the relative machine epsilon (2^-52).

Put the following in some global scope:

``````Number.prototype.getDecimals = function ( decDigCount ) {
return this.toFixed(decDigCount);
}
``````

and then try:

``````var a = 56.23232323;
a.getDecimals(2); // will return 56.23
``````

Update

Note that `toFixed()` can only work for the number of decimals between `0-20` i.e. `a.getDecimals(25)` may generate a javascript error, so to accomodate that you may add some additional check i.e.

``````Number.prototype.getDecimals = function ( decDigCount ) {
return ( decDigCount > 20 ) ? this : this.toFixed(decDigCount);
}
``````
``````Number(((Math.random() * 100) + 1).toFixed(2))
``````

this will return a random number from 1 to 100 rounded to 2 decimal places.

Using this response by reference: https://stackoverflow.com/a/21029698/454827

I build a function to get dynamic numbers of decimals:

``````function toDec(num, dec)
{
if(typeof dec=='undefined' || dec<0)
dec = 2;

var tmp = dec + 1;
for(var i=1; i<=tmp; i++)
num = num * 10;

num = num / 10;
num = Math.round(num);
for(var i=1; i<=dec; i++)
num = num / 10;

num = num.toFixed(dec);

return num;
}
``````

here working example: https://jsfiddle.net/wpxLduLc/

``````parse = function (data) {
data = Math.round(data*Math.pow(10,2))/Math.pow(10,2);
if (data != null) {
var lastone = data.toString().split('').pop();
if (lastone != '.') {
data = parseFloat(data);
}
}
return data;
};

\$('#result').html(parse(200)); // output 200
\$('#result1').html(parse(200.1)); // output 200.1
\$('#result2').html(parse(200.10)); // output 200.1
\$('#result3').html(parse(200.109)); // output 200.11``````
``````<script src="https://ajax.googleapis.com/ajax/libs/jquery/2.0.0/jquery.min.js"></script>
<div id="result"></div>
<div id="result1"></div>
<div id="result2"></div>
<div id="result3"></div>``````

I got some ideas from this post a few months back, but none of the answers here, nor answers from other posts/blogs could handle all the scenarios (e.g. negative numbers and some "lucky numbers" our tester found). In the end, our tester did not find any problem with this method below. Pasting a snippet of my code:

``````fixPrecision: function (value) {
var me = this,
nan = isNaN(value),
precision = me.decimalPrecision;

if (nan || !value) {
return nan ? '' : value;
} else if (!me.allowDecimals || precision <= 0) {
precision = 0;
}

//[1]
//return parseFloat(Ext.Number.toFixed(parseFloat(value), precision));
precision = precision || 0;
var negMultiplier = value < 0 ? -1 : 1;

//[2]
var numWithExp = parseFloat(value + "e" + precision);
var roundedNum = parseFloat(Math.round(Math.abs(numWithExp)) + 'e-' + precision) * negMultiplier;
return parseFloat(roundedNum.toFixed(precision));
},
``````

I also have code comments (sorry i forgot all the details already)...I'm posting my answer here for future reference:

``````9.995 * 100 = 999.4999999999999
Whereas 9.995e2 = 999.5
This discrepancy causes Math.round(9.995 * 100) = 999 instead of 1000.
Use e notation instead of multiplying /dividing by Math.Pow(10,precision).
``````

Building on top of Christian C. Salvadó's answer, doing the following will output a `Number` type, and also seems to be dealing with rounding well:

``````const roundNumberToTwoDecimalPlaces = (num) => Number(new Intl.NumberFormat('en-US', {
minimumFractionDigits: 2,
maximumFractionDigits: 2,
}).format(num));

roundNumberToTwoDecimalPlaces(1.344); // => 1.34
roundNumberToTwoDecimalPlaces(1.345); // => 1.35
``````

The difference between the above and what has already been mentioned is that you don't need the `.format()` chaining when you're using it[, and that it outputs a `Number` type].

I'm fix the problem the modifier. Support 2 decimal only.

``````\$(function(){
//input number only.
convertNumberFloatZero(22); // output : 22.00
convertNumberFloatZero(22.5); // output : 22.50
convertNumberFloatZero(22.55); // output : 22.55
convertNumberFloatZero(22.556); // output : 22.56
convertNumberFloatZero(22.555); // output : 22.55
convertNumberFloatZero(22.5541); // output : 22.54
convertNumberFloatZero(22222.5541); // output : 22,222.54

function convertNumberFloatZero(number){
if(!\$.isNumeric(number)){
return 'NaN';
}
var numberFloat = number.toFixed(3);
var splitNumber = numberFloat.split(".");
var cNumberFloat = number.toFixed(2);
var cNsplitNumber = cNumberFloat.split(".");
var lastChar = splitNumber[1].substr(splitNumber[1].length - 1);
if(lastChar > 0 && lastChar < 5){
cNsplitNumber[1]--;
}
return Number(splitNumber[0]).toLocaleString('en').concat('.').concat(cNsplitNumber[1]);
};
});``````
``<script src="https://ajax.googleapis.com/ajax/libs/jquery/1.9.1/jquery.min.js"></script>``

``````(Math.round((10.2)*100)/100).toFixed(2)
``````

That should yield: `10.20`

``````(Math.round((.05)*100)/100).toFixed(2)
``````

That should yield: `0.05`

``````(Math.round((4.04)*100)/100).toFixed(2)
``````

That should yield: `4.04`

etc.

``````/*Due to all told stuff. You may do 2 things for different purposes:
YourRebelNumber.toFixed(2)*/

var aNumber=9242.16;
var YourRebelNumber=aNumber-9000;

/*and when comparing use:
Number(YourRebelNumber.toFixed(2))*/

/*Number will behave as you want in that moment. After that, it'll return to its defiance.
*/``````

This is very simple and works just as well as any of the others:

``````function parseNumber(val, decimalPlaces) {
if (decimalPlaces == null) decimalPlaces = 0
var ret = Number(val).toFixed(decimalPlaces)
return Number(ret)
}
``````

Since toFixed() can only be called on numbers, and unfortunately returns a string, this does all the parsing for you in both directions. You can pass a string or a number, and you get a number back every time! Calling parseNumber(1.49) will give you 1, and parseNumber(1.49,2) will give you 1.50. Just like the best of 'em!

You could also use the `.toPrecision()` method and some custom code, and always round up to the nth decimal digit regardless the length of int part.

``````function glbfrmt (number, decimals, seperator) {
return typeof number !== 'number' ? number : number.toPrecision( number.toString().split(seperator)[0].length + decimals);
}
``````

You could also make it a plugin for a better use.

Here's a TypeScript implementation of https://stackoverflow.com/a/21323330/916734. It also dries things up with functions, and allows for a optional digit offset.

``````export function round(rawValue: number | string, precision = 0, fractionDigitOffset = 0): number | string {
const value = Number(rawValue);
if (isNaN(value)) return rawValue;

precision = Number(precision);
if (precision % 1 !== 0) return NaN;

let [ stringValue, exponent ] = scientificNotationToParts(value);

let shiftExponent = exponentForPrecision(exponent, precision, Shift.Right);
const enlargedValue = toScientificNotation(stringValue, shiftExponent);
const roundedValue = Math.round(enlargedValue);

[ stringValue, exponent ] = scientificNotationToParts(roundedValue);
const precisionWithOffset = precision + fractionDigitOffset;
shiftExponent = exponentForPrecision(exponent, precisionWithOffset, Shift.Left);

}

enum Shift {
Left = -1,
Right = 1,
}

function scientificNotationToParts(value: number): Array<string> {
const [ stringValue, exponent ] = value.toString().split('e');
return [ stringValue, exponent ];
}

function exponentForPrecision(exponent: string, precision: number, shift: Shift): number {
precision = shift * precision;
return exponent ? (Number(exponent) + precision) : precision;
}

function toScientificNotation(value: string, exponent: number): number {
return Number(`\${value}e\${exponent}`);
}
``````

I found a very simple way that solved this problem for me and can be used or adapted:

``````td[row].innerHTML = price.toPrecision(price.toFixed(decimals).length
``````