# Why not use Double or Float to represent currency?

I've always been told NEVER to represent money in double or float, and this time I pose the question to you: why?

I'm sure there is a very good reason, I simply do not know what it is.

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See this SO question: Rounding Errors? –  adrift Sep 16 '10 at 19:31
Just to be clear, they shouldn't be used for anything that requires accuracy -- not just currency. –  Jeff Sep 16 '10 at 19:59
They shouldn't be used for anything that requires exactness. But double's 53 significant bits (~16 decimal digits) are usually good enough for things that merely require accuracy. –  dan04 Sep 17 '10 at 19:23
Just to be clear, they shouldn't be used for anything that requires exactness -- and neither should decimals. To clarify, doubles can represent all the rational numbers with reasonably-sized numerators and denominators whose denominator is a product of 2. Decimals can represent all the rational numbers with reasonably-sized numerators and denominators whose denominator is a product of powers of 2 and 5. Neither can represent 1/3, for example. –  Brennan Vincent Aug 15 '13 at 17:36
@jeff Your comment completely misrepresents what binary floating-point is good for and what it isn't good for. Read the answer by zneak below, and please delete your misleading comment. –  Pascal Cuoq Aug 3 at 21:08

Because floats and doubles cannot accurately represent the base 10 multiples we use for money. This issue isn't just for Java, it's for any programming language that uses native floating-point types, as it stems from how computers handle floating-point numbers by default.

This is how an IEEE-754 floating-point number works: it dedicates a bit for the sign, a few bits to store an exponent for the base, and the rest for a multiple of that elevated base. This leads to numbers like 10.25 being represented in a form similar to `1025 * 10^-2`; except that instead of the base being 10, for `float`s and `double`s, it's two (so that would be `164 * 2^-4`).

Even in base 10, this notation cannot accurately represent most simple fractions. For instance, you can't represent 1/3 as a multiple of a power of 10: you would need to store an infinite amount of 3's and an infinitely large negative exponent, and you simply can't do that. However, for the purpose of money, in most scenarios all you need is to be able to store multiples of 10-2, so it's not too bad.

Just as some fractions can't be represented exactly as a multiples of a power of ten, some of them can't be represented exactly as a multiple of a power of two, either. In fact, the only fractions of a hundred between 0/100 and 100/100 (which are significant when dealing with money because they're integer cents) that can be represented exactly as an IEEE-754 binary floating-point number are 0, 0.25, 0.5, 0.75 and 1. All the others are off by a small amount.

Representing money as a `double` or `float` will probably look good at first as the software rounds off the tiny errors, but as you perform more additions, subtractions, multiplications and divisions on inexact numbers, you'll lose more and more precision as the errors add up. This makes floats and doubles inadequate for dealing with money, where perfect accuracy for multiples of base 10 powers is required.

A solution that works in just about any language is to use integers instead, and count cents. For instance, 1025 would be \$10.25. Several languages also have built-in types to deal with money. Among others, Java has the `BigDecimal` class, and C# has the `decimal` type.

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Could you please be more specific? –  Fran Fitzpatrick Sep 16 '10 at 19:29
@Fran You will get rounding errors and in some cases where large quantities of currency are being used, interest rate computations can be grossly off –  linuxuser27 Sep 16 '10 at 19:29
...most base 10 fractions, that is. For example, 0.1 has no exact binary floating-point representation. So, `1.0 / 10 * 10` may not be the same as 1.0. –  Chris Jester-Young Sep 16 '10 at 19:30
@linuxuser27 I think Fran was trying to be funny. Anyway, zneak's answer is the best I've seen, better even than the classic version by Bloch. –  Isaac Rabinovitch Oct 8 '12 at 20:28
Of course if you know the precision, you can always round the result and thus avoid the whole issue. This is much faster and simpler than using BigDecimal. Another alternative is to use fixed precision int or long. –  Peter Lawrey Feb 24 '13 at 12:12

From Bloch, J., Effective Java, 2nd ed, Item 48:

The `float` and `double` types are particularly ill-suited for monetary calculations because it is impossible to represent 0.1 (or any other negative power of ten) as a `float` or `double` exactly.

For example, suppose you have \$1.03 and you spend 42c. How much money do you have left?

``````System.out.println(1.03 - .42);
``````

prints out `0.6100000000000001`.

The right way to solve this problem is to use `BigDecimal`, `int` or `long` for monetary calculations.

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This actually the best answer i read...... –  Smarty Twiti Nov 27 '13 at 23:54
I'm a little confused by the recommendation to use int or long for monetary calculations. How do you represent 1.03 as an int or long? I've tried "long a = 1.04;" and "long a = 104/100;" to no avail. –  Peter Mar 15 at 10:32
@Peter, you use `long a = 104` and count in cents instead of dollars. –  zneak Mar 17 at 1:49
@zneak, I like the idea of converting everything to cents but I worry that might not carry enough precision. For example, what if you're computing interest (e.g. credit card balance of \$1.03 and an APR of 14.99%), or currency exchange rates (e.g. 1.00 JPY = 0.009868), or a myriad of other financial calculations that require higher precision? In some applications, rounding to the nearest cent is not acceptable. Of course you could use longs and ints to count hundredths or even thousandths of a cent but that's awkward. I'm just not convinced that ints or longs are a good recommendation. –  Peter Mar 17 at 10:19
@Peter that's exactly why BigDecimal exists. It's a safe place to keep your half pennies. int and long are simply a traditional work-around strictly for situations where at every point in the calculation the currency can be modeled with a whole number within a certain upper and lower limit. In ONLY those situations you can avoid the need for the slower types, like BigDecimal, by treating the decimal as simply a display issue and show say 100 as \$1.00 after the calculation. Now, excuse me, I believe you have my stapler: youtube.com/watch?v=GlRG9x0JRMc 2 to 2:30 min –  CandiedOrange Nov 1 at 6:23

This is not a matter of accuracy, nor is it a matter of precision. It is a matter of meeting the expectations of humans who use base 10 for calculations instead of base 2. For example, using doubles for financial calculations does not produce answers that are "wrong" in a mathematical sense, but it can produce answers that are not what is expected in a financial sense.

Even if you round off your results at the last minute before output, you can still occasionally get a result using doubles that does not match expectations.

Using a calculator, or calculating results by hand, 1.40 * 165 = 231 exactly. However, internally using doubles, on my compiler / operating system environment, it is stored as a binary number close to 230.99999... so if you truncate the number, you get 230 instead of 231. You may reason that rounding instead of truncating would have given the desired result of 231. That is true, but rounding always involves truncation. Whatever rounding technique you use, there are still boundary conditions like this one that will round down when you expect it to round up. They are rare enough that they often will not be found through casual testing or observation. You may have to write some code to search for examples that illustrate outcomes that do not behave as expected.

Assume you want to round something to the nearest penny. So you take your final result, multiply by 100, add 0.5, truncate, then divide the result by 100 to get back to pennies. If the internal number you stored was 3.46499999.... instead of 3.465, you are going to get 3.46 instead 3.47 when you round the number to the nearest penny. But your base 10 calculations may have indicated that the answer should be 3.465 exactly, which clearly should round up to 3.47, not down to 3.46. These kinds of things happen occasionally in real life when you use doubles for financial calculations. It is rare, so it often goes unnoticed as an issue, but it happens.

If you use base 10 for your internal calculations instead of doubles, the answers are always exactly what is expected by humans, assuming no other bugs in your code.

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this is a great answer. –  JCasso Jul 2 at 10:44

Floats and doubles are approximate. If you create a BigDecimal and pass a float into the constructor you see what the float actually equals:

``````groovy:000> new BigDecimal(1.0F)
===> 1
groovy:000> new BigDecimal(1.01F)
===> 1.0099999904632568359375
``````

this probably isn't how you want to represent \$1.01.

The problem is that the IEEE spec doesn't have a way to exactly represent all fractions, some of them end up as repeating fractions so you end up with approximation errors. Since accountants like things to come out exactly to the penny, and customers will be annoyed if they pay their bill and after the payment is processed they owe .01 and they get charged a fee or can't close their account, it's better to use exact types like decimal (in C#) or java.math.BigDecimal in Java.

It's not that the error isn't controllable if you round: see this article by Peter Lawrey. It's just easier not to have to round in the first place. Most applications that handle money don't call for a lot of math, the operations consist of adding things or allocating amounts to different buckets. Introducing floating point and rounding just complicates things.

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If account amounts are always rounded off to the nearest penny, and two values that are within half a cent are considered equal, what's the problem? If things aren't always rounded to the penny (so that e.g. an account with \$0.24 in it charged a 2% monthly interest rate would show a visible charge of \$0.01 every other month) one has to deal with rounding issues no matter how one stores the data. –  supercat Sep 16 '10 at 20:47
@supercat: Suppose the number is off by about 1/100 of a cent. You add together 100 such numbers. Now your total is off by a penny. In financial transactions, that's usually not acceptable. Similarly if you, say, multiply a monthly payment amount by 360 to get the total of all payments over the course of a 30-year mortgage. Etc. Also note that a float or double holds a fixed number of digits, total before and after the "decimal point". (It's really a binary point, not decimal.) So the bigger the scale of the number, the less accuracy on the decimal places. –  Jay Sep 16 '10 at 21:00
@Jay: For most applications, even using dollars as units, rounding to the nearest penny would result in an error of well below 1/100 of a cent. And I won't dispute that it's better to use pennies as units even so. There are interesting questions, though, when it comes to things like daily interest. If someone has a \$10 balance on an account which charges 0.049% daily interest, should the interest be rounded to \$0.00 daily, or should the interest show up as \$0.01 every other day? –  supercat Sep 17 '10 at 15:07
@supercat: "rounding to the nearest penny would result in an error of well below 1/100 of a cent". I don't know what you mean. Rounding what to the nearest penny? What is the definition of error here? RE comment about interest: Sure, any calculation on monetary amounts, or anything else where we will eventually round, must define what the rounding rules are. You might well need to carry extra decimal places in intermediate calculations. –  Jay Sep 17 '10 at 17:57

While it's true that floating point type can represent only approximatively decimal data, it's also true that if one rounds numbers to the necessary precision before presenting them, one obtains the correct result. Usually.

Usually because the double type has a precision less than 16 figures. If you require better precision it's not a suitable type. Also approximations can accumulate.

It must be said that even if you use fixed point arithmetic you still have to round numbers, were it not for the fact that BigInteger and BigDecimal give errors if you obtain periodic decimal numbers. So there is an approximation also here.

For example COBOL, historically used for financial calculations, has a maximum precision of 18 figures. So there is often an implicit rounding.

Concluding, in my opinion the double is unsuitable mostly for its 16 digit precision, which can be insufficient, not because it is approximate.

Consider the following output of the subsequent program. It shows that after rounding double give the same result as BigDecimal up to precision 16.

``````Precision 14
------------------------------------------------------
BigDecimalNoRound             : 56789.012345 / 1111111111 = Non-terminating decimal expansion; no exact representable decimal result.
DoubleNoRound                 : 56789.012345 / 1111111111 = 5.111011111561101E-5
BigDecimal                    : 56789.012345 / 1111111111 = 0.000051110111115611
Double                        : 56789.012345 / 1111111111 = 0.000051110111115611

Precision 15
------------------------------------------------------
BigDecimalNoRound             : 56789.012345 / 1111111111 = Non-terminating decimal expansion; no exact representable decimal result.
DoubleNoRound                 : 56789.012345 / 1111111111 = 5.111011111561101E-5
BigDecimal                    : 56789.012345 / 1111111111 = 0.0000511101111156110
Double                        : 56789.012345 / 1111111111 = 0.0000511101111156110

Precision 16
------------------------------------------------------
BigDecimalNoRound             : 56789.012345 / 1111111111 = Non-terminating decimal expansion; no exact representable decimal result.
DoubleNoRound                 : 56789.012345 / 1111111111 = 5.111011111561101E-5
BigDecimal                    : 56789.012345 / 1111111111 = 0.00005111011111561101
Double                        : 56789.012345 / 1111111111 = 0.00005111011111561101

Precision 17
------------------------------------------------------
BigDecimalNoRound             : 56789.012345 / 1111111111 = Non-terminating decimal expansion; no exact representable decimal result.
DoubleNoRound                 : 56789.012345 / 1111111111 = 5.111011111561101E-5
BigDecimal                    : 56789.012345 / 1111111111 = 0.000051110111115611011
Double                        : 56789.012345 / 1111111111 = 0.000051110111115611013

Precision 18
------------------------------------------------------
BigDecimalNoRound             : 56789.012345 / 1111111111 = Non-terminating decimal expansion; no exact representable decimal result.
DoubleNoRound                 : 56789.012345 / 1111111111 = 5.111011111561101E-5
BigDecimal                    : 56789.012345 / 1111111111 = 0.0000511101111156110111
Double                        : 56789.012345 / 1111111111 = 0.0000511101111156110125

Precision 19
------------------------------------------------------
BigDecimalNoRound             : 56789.012345 / 1111111111 = Non-terminating decimal expansion; no exact representable decimal result.
DoubleNoRound                 : 56789.012345 / 1111111111 = 5.111011111561101E-5
BigDecimal                    : 56789.012345 / 1111111111 = 0.00005111011111561101111
Double                        : 56789.012345 / 1111111111 = 0.00005111011111561101252

import java.lang.reflect.InvocationTargetException;
import java.lang.reflect.Method;
import java.math.BigDecimal;
import java.math.MathContext;

public class Exercise {
public static void main(String[] args) throws IllegalArgumentException,
SecurityException, IllegalAccessException,
InvocationTargetException, NoSuchMethodException {
String amount = "56789.012345";
String quantity = "1111111111";
int [] precisions = new int [] {14, 15, 16, 17, 18, 19};
for (int i = 0; i < precisions.length; i++) {
int precision = precisions[i];
System.out.println(String.format("Precision %d", precision));
System.out.println("------------------------------------------------------");
execute("BigDecimalNoRound", amount, quantity, precision);
execute("DoubleNoRound", amount, quantity, precision);
execute("BigDecimal", amount, quantity, precision);
execute("Double", amount, quantity, precision);
System.out.println();
}
}

private static void execute(String test, String amount, String quantity,
int precision) throws IllegalArgumentException, SecurityException,
IllegalAccessException, InvocationTargetException,
NoSuchMethodException {
Method impl = Exercise.class.getMethod("divideUsing" + test, String.class,
String.class, int.class);
String price;
try {
price = (String) impl.invoke(null, amount, quantity, precision);
} catch (InvocationTargetException e) {
price = e.getTargetException().getMessage();
}
System.out.println(String.format("%-30s: %s / %s = %s", test, amount,
quantity, price));
}

public static String divideUsingDoubleNoRound(String amount,
String quantity, int precision) {
// acceptance
double amount0 = Double.parseDouble(amount);
double quantity0 = Double.parseDouble(quantity);

//calculation
double price0 = amount0 / quantity0;

// presentation
String price = Double.toString(price0);
return price;
}

public static String divideUsingDouble(String amount, String quantity,
int precision) {
// acceptance
double amount0 = Double.parseDouble(amount);
double quantity0 = Double.parseDouble(quantity);

//calculation
double price0 = amount0 / quantity0;

// presentation
MathContext precision0 = new MathContext(precision);
String price = new BigDecimal(price0, precision0)
.toString();
return price;
}

public static String divideUsingBigDecimal(String amount, String quantity,
int precision) {
// acceptance
BigDecimal amount0 = new BigDecimal(amount);
BigDecimal quantity0 = new BigDecimal(quantity);
MathContext precision0 = new MathContext(precision);

//calculation
BigDecimal price0 = amount0.divide(quantity0, precision0);

// presentation
String price = price0.toString();
return price;
}

public static String divideUsingBigDecimalNoRound(String amount, String quantity,
int precision) {
// acceptance
BigDecimal amount0 = new BigDecimal(amount);
BigDecimal quantity0 = new BigDecimal(quantity);

//calculation
BigDecimal price0 = amount0.divide(quantity0);

// presentation
String price = price0.toString();
return price;
}
}
``````
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If one scales ones currency properly (e.g. so a value of \$1.23 is represented as 123 pennies), `double` will be adequate in most situations provided one is mindful of exactly when things are rounded. Further, even types like `Decimal` will be unsuitable unless one is mindful of how things are rounded. For example, if things are priced at 3/\$1, three of them which are registered as being the same price won't total exactly a dollar; the code necessary to handle that can work just as well with `double` as with `Decimal`. –  supercat Nov 18 '12 at 15:21

I'm troubled by some of these responses. I think doubles and floats have a place in financial calculations. Certainly, when adding and subtracting non-fractional monetary amounts there will be no loss of precision when using integer classes or BigDecimal classes. But when performing more complex operations, you often end up with results that go out several or many decimal places, no matter how you store the numbers. The issue is how you present the result.

If your result is on the borderline between being rounded up and rounded down, and that last penny really matters, you should be probably be telling the viewer that the answer is nearly in the middle - by displaying more decimal places.

The problem with doubles, and more so with floats, is when they are used to combine large numbers and small numbers. In java,

``````System.out.println(1000000.0f + 1.2f - 1000000.0f);
``````

results in

``````1.1875
``````
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THIS!!!! I was searching all answers to find this RELEVANT FACT!!! In normal calculations nobody cares if you are of by some fraction of a cent, but here with high numbers easily some dollars get lost per transaction! –  Falco Oct 8 at 12:05
And now imagine someone getting daily revenue of 0.01% on his 1 Million dollars - he would get nothing each day - and after a year he has not gotten 1000 Dollars, THIS WILL MATTER –  Falco Oct 8 at 12:06

The result of floating point number is not exact, which makes them unsuitable for any financial calculation which requires exact result and not approximation. float and double are designed for engineering and scientific calculation and many times doesn’t produce exact result also result of floating point calculation may vary from JVM to JVM. Look at below example of BigDecimal and double primitive which is used to represent money value, its quite clear that floating point calculation may not be exact and one should use BigDecimal for financial calculations.

``````    // floating point calculation
final double amount1 = 2.0;
final double amount2 = 1.1;
System.out.println("difference between 2.0 and 1.1 using double is: " + (amount1 - amount2));

// Use BigDecimal for financial calculation
final BigDecimal amount3 = new BigDecimal("2.0");
final BigDecimal amount4 = new BigDecimal("1.1");
System.out.println("difference between 2.0 and 1.1 using BigDecimal is: " + (amount3.subtract(amount4)));
``````

Output: difference between 2.0 and 1.1 using double is: 0.8999999999999999 difference between 2.0 and 1.1 using BigDecimal is: 0.9

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I prefer using Integer or Long to represent currency. BigDecimal junks up the source code too much.

You just have to know that all your values are in cents. Or the lowest value of whatever currency you're using.

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What if you are charging for electricity at 0.1 cent per unit? What about when you calculate taxes and have sub-cent values? For example add 1.2c + 1.9c and now you a missing a cent. –  Desmond Zhou Mar 19 '13 at 18:33
Then I would use an Integer or Long in .1 cent units, so 1 = one tenth of a cent, and 10 would be a cent. –  Tony Ennis Mar 20 '13 at 0:43
How would you handle forex calculations using Longs? –  Darren Jun 11 '13 at 11:58

I've reached to a pretty nice precision just dealing with cents.

Here is the class:

``````public class Money implements Comparable<Money> {

private static Locale CURRENT_LOCALE = new Locale("pt", "br");

private Long amount = 0L;

public Money() { }

public Money(long cents) {
super();
this.setAmount(cents);
}

public Money(float cents) {
super();
this.setAmount(cents);
}

public Money(double cents) {
super();
this.setAmount(cents);
}

public void setAmount(Long cents) {
this.amount = cents;
}

public void setAmount(Float amount) {
this.amount = new Long(Math.round(amount * 100));
}

public void setAmount(Double amount) {
this.amount = Math.round(amount * 100);
}

public Double amount() {
return ((double) this.amount/100);
}

if (amount != null) {
this.amount += portion.amount;
}
return this;
}

public Money subtract(Money portion) {
if (amount != null) {
this.amount -= portion.amount;
}
return this;
}

public Money multiplyBy(double times) {
this.amount = Math.round(this.amount * times);
return this;
}

public Money divideBy(double divisor) {
this.amount = Math.round(this.amount / divisor);
return this;
}

@Override
public String toString() {
return NumberFormat.getCurrencyInstance(currentLocale()).format(amount());
}

@Override
public int compareTo(Money value) {
return (int) (amount - value.amount);
}

protected static void currentLocale(Locale locale) {
CURRENT_LOCALE = locale;
}

protected static Locale currentLocale() {
return CURRENT_LOCALE;
}
``````

}

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## protected by BoltClock♦Dec 28 '13 at 6:15

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