In the interest of creating crossplatform code, I'd like to develop a simple financial application in JavaScript. The calculations required involve compound interest and relatively long decimal numbers. I'd like to know what mistakes to avoid when using JavaScript to do this type of math—if it is possible at all!
9 Answers
You should probably scale your decimal values by 100, and represent all the monetary values in whole cents. This is to avoid problems with floatingpoint logic and arithmetic. There is no decimal data type in JavaScript  the only numeric data type is floatingpoint. Therefore it is generally recommended to handle money as 2550
cents instead of 25.50
dollars.
Consider that in JavaScript:
var result = 1.0 + 2.0; // (result === 3.0) returns true
But:
var result = 0.1 + 0.2; // (result === 0.3) returns false
The expression 0.1 + 0.2 === 0.3
returns false
, but fortunately integer arithmetic in floatingpoint is exact, so decimal representation errors can be avoided by scaling^{1}.
Note that while the set of real numbers is infinite, only a finite number of them (18,437,736,874,454,810,627 to be exact) can be represented exactly by the JavaScript floatingpoint format. Therefore the representation of the other numbers will be an approximation of the actual number^{2}.
^{1} Douglas Crockford: JavaScript: The Good Parts: Appendix A  Awful Parts (page 105).
^{2} David Flanagan: JavaScript: The Definitive Guide, Fourth Edition: 3.1.3 FloatingPoint Literals (page 31).

6And as a reminder, always round calculations to the cent, and do so in the least beneficial way to the consumer, I.E. If you're calculating tax, round up. If you're calculating interest earned, truncate.– JoshMay 20, 2010 at 18:20

6@Cirrostratus: You may want to check stackoverflow.com/questions/744099. If you go ahead with the scaling method, in general you would want to scale your value by the number of decimal digits you wish to retain precision. If you need 2 decimal places, scale by 100, if you need 4, scale by 10000. May 20, 2010 at 21:10

2... Regarding the 3000.57 value, yes, if you store that value in JavaScript variables, and you intend to do arithmetic on it, you might want to store it scaled to 300057 (number of cents). Because
3000.57 + 0.11 === 3000.68
returnsfalse
. May 20, 2010 at 21:17 
12Counting pennies instead of dollars will not help. When counting pennies, you loose the ability to add 1 to an integer at about 10^16. When counting dollars you lose the ability to add .01 to a number at 10^14. It's the same either way. Nov 1, 2012 at 0:12

7@slashingweapon, anyone feel free to correct me if I'm wrong but 10^16 cents is a hundred trillion dollars. For MOST circumstances this isn't going to be an issue. 0.1 + 0.2 will crop up WAY before you are dealing with more than a hundred trillion dollars.– DaveJul 29, 2017 at 15:18
Scaling every value by 100 is the solution. Doing it by hand is probably useless, since you can find libraries that do that for you. I recommend moneysafe, which offers a functional API well suited for ES6 applications:
const { in$, $ } = require('moneysafe');
console.log(in$($(10.5) + $(.3)); // 10.8
https://github.com/ericelliott/moneysafe
Works both in Node.js and the browser.

4Upvoted. The "scale by 100" point is already covered in the accepted answer, however it's good that you added a software package option with modern JavaScript syntax. FWIW the
in$, $
value names are ambiguous to someone who's not used the package before. I know it was Eric's choice to name things that way, but I still feel it's enough of a mistake that I'd probably rename them in the import/destructured require statement. Sep 12, 2017 at 21:18 
18Scaling by 100 only helps until you start wanting to do something like calculate percentages (perform division, essentially).– PointyMay 8, 2018 at 13:05

4I wish I could upvote a comment multiple times. Scaling by 100 just isn't sufficient. The only numeric datatype in JavaScript is still a floating point data type, and you're still going to end up with significant rounding errors. Feb 16, 2019 at 22:42

4And another heads up from the readme:
Money$afe has not yet been tested in production at scale.
. Just pointing that out so anyone can then consider if that's appropriate for their use case– AurelioOct 17, 2019 at 7:59
Unfortunately all of the answers so far ignore the fact that not all currencies have 100 subunits (e.g., the cent is the subunit of the US dollar (USD)). Currencies like the Iraqi Dinar (IQD) have 1000 subunits: an Iraqi Dinar has 1000 fils. The Japanese Yen (JPY) has no subunits. So "multiply by 100 to do integer arithmetic" isn't always the correct answer.
Additionally for monetary calculations you also need to keep track of the currency. You can't add a US Dollar (USD) to an Indian Rupee (INR) (without first converting one to the other).
There are also limitations on the maximum amount that can be represented by JavaScript's integer data type.
In monetary calculations you also have to keep in mind that money has finite precision (typically 03 decimal points) & rounding needs to be done in particular ways (e.g., "normal" rounding vs. banker's rounding). The type of rounding to be performed might also vary by jurisdiction/currency.
How to handle money in javascript has a very good discussion of the relevant points.
In my searches I found the dinero.js library that addresses many of the issues wrt monetary calculations. Haven't used it yet in a production system so can't give an informed opinion on it.
There's no such thing as "precise" financial calculation because of just two decimal fraction digits but that's a more general problem.
In JavaScript, you can scale every value by 100 and use Math.round()
everytime a fraction can occur.
You could use an object to store the numbers and include the rounding in its prototypes valueOf()
method. Like this:
sys = require('sys');
var Money = function(amount) {
this.amount = amount;
}
Money.prototype.valueOf = function() {
return Math.round(this.amount*100)/100;
}
var m = new Money(50.42355446);
var n = new Money(30.342141);
sys.puts(m.amount + n.amount); //80.76569546
sys.puts(m+n); //80.76
That way, everytime you use a Moneyobject, it will be represented as rounded to two decimals. The unrounded value is still accessible via m.amount
.
You can build in your own rounding algorithm into Money.prototype.valueOf()
, if you like.

I like this objectoriented approach, the fact that the Money object holds both values is very useful. It's the exact type of functionality I like to create in my custom ObjectiveC classes. May 20, 2010 at 21:08

4

3Shouldn't sys.puts(m+n); //80.76 actually read sys.puts(m+n); //80.77? I believe you forgot to round the .5 up.– Dave LAug 18, 2015 at 16:16

2This kind of approach has a number of subtle issues that can crop up. For instance, you haven't implemented safe methods of addition, subtraction, multiplication and so on, so you are likely to run into rounding errors when combining money amounts Sep 30, 2015 at 21:41

2The problem here is that e.g.
Money(0.1)
means that the JavaScript lexer reads the string "0.1" from the source and then converts it to a binary floating point and then you already did an unintended rounding. The problem is about representation (binary vs decimal) not about precision.– mgdNov 20, 2015 at 15:08
use decimaljs ... It a very good library that solves a harsh part of the problem ...
just use it in all your operation.
Your problem stems from inaccuracy in floating point calculations. If you're just using rounding to solve this you'll have greater error when you're multiplying and dividing.
The solution is below, an explanation follows:
You'll need to think about mathematics behind this to understand it. Real numbers like 1/3 cannot be represented in math with decimal values since they're endless (e.g.  .333333333333333 ...). Some numbers in decimal cannot be represented in binary correctly. For example, 0.1 cannot be represented in binary correctly with a limited number of digits.
For more detailed description look here: http://docs.oracle.com/cd/E1995701/8063568/ncg_goldberg.html
Take a look at the solution implementation: http://floatingpointgui.de/languages/javascript/
Due to the binary nature of their encoding, some decimal numbers cannot be represented with perfect accuracy. For example
var money = 600.90;
var price = 200.30;
var total = price * 3;
// Outputs: false
console.log(money >= total);
// Outputs: 600.9000000000001
console.log(total);
If you need to use pure javascript then you have need to think about solution for every calculation. For above code we can convert decimals to whole integers.
var money = 60090;
var price = 20030;
var total = price * 3;
// Outputs: true
console.log(money >= total);
// Outputs: 60090
console.log(total);
Avoiding Problems with Decimal Math in JavaScript
There is a dedicated library for financial calculations with great documentation. Finance.js
Use this code for currency calculation and round numbers in two digits.
<!DOCTYPE html>
<html>
<body>
<h1>JavaScript Variables</h1>
<p id="test1"></p>
<p id="test2"></p>
<p id="test3"></p>
<script>
function setDecimalPoint(num) {
if (isNaN(parseFloat(num)))
return 0;
else {
var Number = parseFloat(num);
var multiplicator = Math.pow(10, 2);
Number = parseFloat((Number * multiplicator).toFixed(2));
return (Math.round(Number) / multiplicator);
}
}
document.getElementById("test1").innerHTML = "Without our method O/P is: " + (655.93 * 9)/100;
document.getElementById("test2").innerHTML = "Calculator O/P: 59.0337, Our value is: " + setDecimalPoint((655.93 * 9)/100);
document.getElementById("test3").innerHTML = "Calculator O/P: 32.888.175, Our value is: " + setDecimalPoint(756.05 * 43.5);
</script>
</body>
</html>
Here we are using JavaScript and Node.js to trade real money in financial markets. We came up with a custom Decimal class representing immutable decimal numbers and providing logic for calculations.
import { decimal, } from "@reiryoku/mida";
0.1 + 0.2; //= 0.30000000000000004
decimal(0.1).add(0.2); //= 0.3
decimal("0.1").add("0.2"); //= 0.3
If you are curious you can see the definition here https://github.com/ReiryokuTechnologies/Mida/blob/master/src/core/decimals/MidaDecimal.ts
The package is available for anyone on npm.