I have to calculate some floating point variables and my colleague suggest me to use BigDecimal instead of double since it will be more precise. But I want to know what it is and how to make most out of BigDecimal?

up vote 328 down vote accepted

A BigDecimal is an exact way of representing numbers. A Double has a certain precision. Working with doubles of various magnitudes (say d1=1000.0 and d2=0.001) could result in the 0.001 being dropped alltogether when summing as the difference in magnitude is so large. With BigDecimal this would not happen.

The disadvantage of BigDecimal is that it's slower, and it's a bit more difficult to program algorithms that way (due to + - * and / not being overloaded).

If you are dealing with money, or precision is a must, use BigDecimal. Otherwise Doubles tend to be good enough.

I do recommend reading the javadoc of BigDecimal as they do explain things better than I do here :)

  • Yep, I'm calculating the price for stock so I believe BigDecimal is useful in this case. – Truong Ha Aug 5 '10 at 9:51
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    @Truong Ha: When working with prices you want to use BigDecimal. And if you store them in the database you want something similar. – extraneon Aug 5 '10 at 11:46
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    Saying that "BigDecimal is an exact way of representing numbers" is misleading. 1/3 and 1/7 can't be expressed exactly in a base 10 number system (BigDecimal) or in base 2 number system (float or double). 1/3 could be exactly expressed in base 3, base 6, base 9, base 12, etc. and 1/7 could be expressed exactly in base 7, base 14, base 21, etc. BigDecimal advantages are that it is arbitrary precision and that humans are used to the rounding errors you get in base 10. – procrastinate_later Aug 21 '13 at 15:59
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    Good point about it being slower, helps me understand why the Netflix Ribbon load balancer code deals with doubles, and then has lines like this: if (Math.abs(loadPerServer - maxLoadPerServer) < 0.000001d) { – michaelok Oct 11 '17 at 15:24

My English is not good so I'll just write a simple example here.

    double a = 0.02;
    double b = 0.03;
    double c = b - a;

    BigDecimal _a = new BigDecimal("0.02");
    BigDecimal _b = new BigDecimal("0.03");
    BigDecimal _c = _b.subtract(_a);

Program output:


Somebody still want to use double? ;)

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    I surely do. – maaartinus Mar 18 '17 at 7:07
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    i cannot believe that this answer got 50+ votes. initializing a new BigDecimal("0.02") means that you are setting its scale to 2 decimals so BigDecimal will round the result for you. You can do the rounding for the double as well and u can easily get 0.01 that you were expecting. – eldjon May 30 '17 at 14:27
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    @eldjon Thats not true, Look at this example: BigDecimal two = new BigDecimal("2"); BigDecimal eight = new BigDecimal("8"); System.out.println(two.divide(eight)); This prints out 0.25. – Lurr Aug 9 '17 at 8:06
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    doubles forevr :D – vach Mar 28 at 9:53
  • Nonetheless if you use a float instead you get the same precision than BigDecimal in that case but way better performance – EliuX Jul 11 at 14:51

There are two main differences from double:

  • Arbitrary precision, similarly to BigInteger they can contain number of arbitrary precision and size
  • Base 10 instead of Base 2, a BigDecimal is n*10^scale where n is an arbitrary large signed integer and scale can be thought of as the number of digits to move the decimal point left or right

The reason you should use BigDecimal for monetary calculations is not that it can represent any number, but that it can represent all numbers that can be represented in decimal notion and that include virtually all numbers in the monetary world (you never transfer 1/3 $ to someone).

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    This answer truly explains the difference and the reason of using BigDecimal over double. Performance concerns are secondary. – Vortex Oct 4 '16 at 1:39
  • This is not 100% true. You wrote that a BigDecimal is "n*10^scale". Java only does that for negative numbers. So correct would be: "unscaledValue × 10^-scale". For positive numbers the BigDecimal consists of an "arbitrary precision integer unscaled value and a 32-bit integer scale" whereas the scale is the number of digits to the right of the decimal point. – the hand of NOD Oct 2 at 19:15

If you want to write down a value like 1/7 as decimal value you get

1/7 = 0.142857142857142857142857142857142857142857...

with an infinite sequence of 142857. But since you can only write down a finite number of digits you will inevitably introduce a rounding (or truncation) error.

Unfortunately, numbers like 1/10 or 1/100 expressed as binary numbers with a fractional part also have an infinite number of decimals binaries.

1/10 = binary 0.0001100110011001100110011001100110...

Doubles store values as binary numbers and therefore might introduce an error solely by converting a decimal number to a binary number, without even doing any arithmetic.

Decimal numbers (like BigDecimal), on the other hand, store each decimal digit as is. This means that a decimal type is not more precise than a binary floating point or fixed point type in a general sense (e.g. it cannot store 1/7 without loss of precision), but it is more accurate for numbers given with a finite number of decimal digits, as is often the case for money calculations.

Java's BigDecimal has the additional advantage that it can have an arbitrary (but finite) number of digits on both sides of the decimal point, limited only by the available memory.

BigDecimal is Oracle's arbitrary-precision numerical library. BigDecimal is part of the Java language and is useful for a variety of applications ranging from the financial to the scientific (that's where sort of am).

There's nothing wrong with using doubles for certain calculations. Suppose, however, you wanted to calculate Math.Pi * Math.Pi / 6, that is, the value of the Riemann Zeta Function for a real argument of two (a project I'm currently working on). Floating-point division presents you with a painful problem of rounding error.

BigDecimal, on the other hand, includes many options for calculating expressions to arbitrary precision. The add, multiply, and divide methods as described in the Oracle documentation below "take the place" of +, *, and / in BigDecimal Java World:


The compareTo method is especially useful in while and for loops.

Be careful, however, in your use of constructors for BigDecimal. The string constructor is very useful in many cases. For instance, the code

BigDecimal onethird = new BigDecimal("0.33333333333");

utilizes a string representation of 1/3 to represent that infinitely-repeating number to a specified degree of accuracy. The round-off error is most likely somewhere so deep inside the JVM that the round-off errors won't disturb most of your practical calculations. I have, from personal experience, seen round-off creep up, however. The setScale method is important in these regards, as can be seen from the Oracle documentation.

  • BigDecimal is part of Java's arbitrary-precision numerical library. 'In-house' is rather meaningless in this context, especially as it was written by IBM. – user207421 May 13 '16 at 19:38
  • @EJP: I looked into BigDecimal class and learned that only portion of it is written by IBM. Copyright comment below: /* * Portions Copyright IBM Corporation, 2001. All Rights Reserved. */ – realPK Feb 21 '17 at 3:49

If you are dealing with calculation, there are laws on how you should calculate and what precision you should use. If you fail that you will be doing something illegal. The only real reason is that the bit representation of decimal cases are not precise. As Basil simply put, an example is the best explanation. Just to complement his example, here's what happens:

static void theDoubleProblem1() {
    double d1 = 0.3;
    double d2 = 0.2;
    System.out.println("Double:\t 0,3 - 0,2 = " + (d1 - d2));

    float f1 = 0.3f;
    float f2 = 0.2f;
    System.out.println("Float:\t 0,3 - 0,2 = " + (f1 - f2));

    BigDecimal bd1 = new BigDecimal("0.3");
    BigDecimal bd2 = new BigDecimal("0.2");
    System.out.println("BigDec:\t 0,3 - 0,2 = " + (bd1.subtract(bd2)));


Double:  0,3 - 0,2 = 0.09999999999999998
Float:   0,3 - 0,2 = 0.10000001
BigDec:  0,3 - 0,2 = 0.1

Also we have that:

static void theDoubleProblem2() {
    double d1 = 10;
    double d2 = 3;
    System.out.println("Double:\t 10 / 3 = " + (d1 / d2));

    float f1 = 10f;
    float f2 = 3f;
    System.out.println("Float:\t 10 / 3 = " + (f1 / f2));

    // Exception! 
    BigDecimal bd3 = new BigDecimal("10");
    BigDecimal bd4 = new BigDecimal("3");
    System.out.println("BigDec:\t 10 / 3 = " + (bd3.divide(bd4)));

Gives us the output:

Double:  10 / 3 = 3.3333333333333335
Float:   10 / 3 = 3.3333333
Exception in thread "main" java.lang.ArithmeticException: Non-terminating decimal expansion


static void theDoubleProblem2() {
    BigDecimal bd3 = new BigDecimal("10");
    BigDecimal bd4 = new BigDecimal("3");
    System.out.println("BigDec:\t 10 / 3 = " + (bd3.divide(bd4, 4, BigDecimal.ROUND_HALF_UP)));

Has the output:

BigDec:  10 / 3 = 3.3333 
package j2ee.java.math;

 *      Generated from IDL definition of "valuetype "BigDecimal""
 *      TomORB IDL compiler v1.0

public abstract class BigDecimal extends j2ee.java.lang.Number implements org.omg.CORBA.portable.StreamableValue, j2ee.java.lang.Comparable


        private String[] _truncatable_ids = {"RMI:java.math.BigDecimal:11F6D308F5398BBD:54C71557F981284F"};

        protected int scale_;

        protected j2ee.java.math.BigInteger intVal;

        /* constants */

        int ROUND_UP = 0;

        int ROUND_DOWN = 1;

        int ROUND_CEILING = 2;

        int ROUND_FLOOR = 3;

        int ROUND_HALF_UP = 4;

        int ROUND_HALF_DOWN = 5;

        int ROUND_HALF_EVEN = 6;

        int ROUND_UNNECESSARY = 7;

        public abstract int _hashCode();

        public abstract int scale();

        public abstract int signum();

        public abstract boolean _equals(org.omg.CORBA.Any arg0);

        public abstract java.lang.String _toString();

        public abstract j2ee.java.math.BigDecimal abs();

        public abstract j2ee.java.math.BigDecimal negate();

        public abstract j2ee.java.math.BigDecimal movePointLeft(int arg0);

        public abstract j2ee.java.math.BigDecimal movePointRight(int arg0);

        public abstract j2ee.java.math.BigDecimal setScale(int arg0);

        public abstract j2ee.java.math.BigDecimal setScale(int arg0, int arg1);

        public abstract j2ee.java.math.BigDecimal valueOf(long arg0);

        public abstract j2ee.java.math.BigDecimal valueOf(long arg0, int arg1);

        public abstract int compareTo(j2ee.java.math.BigDecimal arg0);

        public abstract j2ee.java.math.BigInteger toBigInteger();

        public abstract j2ee.java.math.BigInteger unscaledValue();

        public abstract j2ee.javax.rmi.CORBA.ClassDesc classU0024(java.lang.String arg0);

        public abstract j2ee.java.math.BigDecimal add(j2ee.java.math.BigDecimal arg0);

        public abstract j2ee.java.math.BigDecimal max(j2ee.java.math.BigDecimal arg0);

        public abstract j2ee.java.math.BigDecimal min(j2ee.java.math.BigDecimal arg0);

        public abstract j2ee.java.math.BigDecimal multiply(j2ee.java.math.BigDecimal arg0);

        public abstract j2ee.java.math.BigDecimal subtract(j2ee.java.math.BigDecimal arg0);

        public abstract j2ee.java.math.BigDecimal divide(j2ee.java.math.BigDecimal arg0, int arg1);

        public abstract j2ee.java.math.BigDecimal divide(j2ee.java.math.BigDecimal arg0, int arg1, int arg2);

        public void _write (org.omg.CORBA.portable.OutputStream os)


               super._write( os );


         ((org.omg.CORBA_2_3.portable.OutputStream)os).write_value( new java.lang.String("intVal") );


        public void _read (final org.omg.CORBA.portable.InputStream os)
               super._read( os );


         intVal=(j2ee.java.math.BigInteger)((org.omg.CORBA_2_3.portable.InputStream)os).read_value ( "RMI:java.math.BigInteger:E2F79B6E7A470003:8CFC9F1FA93BFB1D".toString() );

        public String[] _truncatable_ids()
               return _truncatable_ids;

        public org.omg.CORBA.TypeCode _type()
               return j2ee.java.math.BigDecimalHelper.type();

Primitive numeric types are useful for storing single values in memory. But when dealing with calculation using double and float types, there is a problems with the rounding.It happens because memory representation doesn't map exactly to the value. For example, a double value is supposed to take 64 bits but Java doesn't use all 64 bits.It only stores what it thinks the important parts of the number. So you can arrive to the wrong values when you adding values together of the float or double type. May be this video https://youtu.be/EXxUSz9x7BM will explain more

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    Are you the author of that video? If you aren't, you have chosen one of the worst explanations to copy-paste verbatim as an answer. If you are, you should spend more time investigating how double works before making videos. – Pascal Cuoq Mar 1 '16 at 16:28
  • I am the author. What do you think id wrong with the answer ? – Gregory Nozik Mar 1 '16 at 16:31
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    “Java doesn't use all 64 bits. It only stores what it thinks the important parts of the number.” is nonsense. Java always uses 64 bits, and it stores values in the IEEE 754 binary64 format, not what it thinks is important. – Pascal Cuoq Mar 1 '16 at 16:35
  • Have a look at this article drdobbs.com/jvm/javas-floating-point-imprecision/240168744 – Gregory Nozik Mar 1 '16 at 16:44
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    He's completely wrong, and so are you. Java uses every bit available, but there are only 53 bits available for the significand, eleven for the exponent. This is defined by IEEE-754, not by Java. Java doesn't add or subtract anything to or from IEEE-754. You can't cite Dr Dobbs as an authoritative source. – user207421 Mar 10 '16 at 0:03

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