I've been trying to find out the reason, but I couldn't. Can anybody help me?

Look at the following example.

float f = 125.32f;
System.out.println("value of f = " + f);
double d = (double) 125.32f; 
System.out.println("value of d = " + d);

This is the output:

value of f = 125.32
value of d = 125.31999969482422
  • 1
    Can you provide the specific example(s) that you are seeing this behavior in? It would be better to show a SSCCE: sscce.org Jul 6, 2013 at 16:30
  • 1
    One word: precision. Technically ... the values aren't "changing" ;) Jul 6, 2013 at 16:32
  • 3
    Afaik, that's impossible. Doubles have both more precision and more range, so you lose neither when casting in that direction. It may print differently, though.
    – harold
    Jul 6, 2013 at 16:32

9 Answers 9


The value of a float does not change when converted to a double. There is a difference in the displayed numerals because more digits are required to distinguish a double value from its neighbors, which is required by the Java documentation. That is the documentation for toString, which is referred (through several links) from the documentation for println.

The exact value for 125.32f is 125.31999969482421875. The two neighboring float values are 125.3199920654296875 and 125.32000732421875. Observe that 125.32 is closer to 125.31999969482421875 than to either of the neighbors. Therefore, by displaying “125.32”, Java has displayed enough digits so that conversion back from the decimal numeral to float reproduces the value of the float passed to println.

The two neighboring double values of 125.31999969482421875 are 125.3199996948242045391452847979962825775146484375 and 125.3199996948242329608547152020037174224853515625.
Observe that 125.32 is closer to the latter neighbor than to the original value (125.31999969482421875). Therefore, printing “125.32” does not contain enough digits to distinguish the original value. Java must print more digits in order to ensure that a conversion from the displayed numeral back to double reproduces the value of the double passed to println.

  • in single-precision, the sequence of numbers exactly representable around that number are: 0x42faa3d6, 0x42faa3d7, 0x42faa3d8 (in hex notation, with one bit increments). Anything in-between gets rounded to the closest number. Same can be said for double-precision. btw correct me if I'm wrong but single-precision allows about 9 significant decimal digits precision, so all those extra digits you showed are dropped and ignored
    – Amro
    Jul 7, 2013 at 4:17
  • 2
    @Amro: Extra digits are not dropped or ignored. The arithmetic performed on floating-point objects behaves as if they have exactly the full values, include the values I showed. That is because they do have those full values; the IEEE 754 specification states that they have exactly those values and no others. They are not used by the computer as decimal approximations with a few digits. The computer calculates with them in binary, and they have exactly the values specified. Jul 7, 2013 at 11:51
  • hmm I guess this detail always confused me, can you comment on this please: stackoverflow.com/questions/4227145/… ?
    – Amro
    Jul 7, 2013 at 15:42
  • @Amro: The IEEE 754 standard defines what values are represented by floating-point objects. The standard does not define any notion of significant decimal digits for a binary floating-point format. There simply is no basis for stating that an IEEE-754 binary floating-point object has some number of significant decimal digits. The object has exactly one value that is precisely specified, and it carries no information about significance. It is an exact value. The standard does permit implementations to limit the number of digits they produce when converting the value to a decimal numeral… Jul 8, 2013 at 3:10
  • 1
    @supercat: I do not comment here on whether any particular person ought to use floating-point in any particular way. I simply state that the IEEE 754 standard specifies quite clearly that floating-point value, other than a NaN, represents exactly one value, and the standard specifies that value exactly. Whether you think that is good or bad is of no consequence to the fact that the standard says it, and that results of floating-point operations are defined in terms of these values. Since implementations of IEEE 754 follow these rules, analysis of their behaviors must follow these rules. Nov 26, 2013 at 20:55
  1. When you convert a float into a double, there is no loss of information. Every float can be represented exactly as a double.
  2. On the other hand, neither decimal representation printed by System.out.println is the exact value for the number. An exact decimal representation could require up to about 760 decimal digits. Instead, System.out.println prints exactly the number of decimal digits that allow to parse the decimal representation back into the original float or double. There are more doubles, so when printing one, System.out.println needs to print more digits before the representation becomes unambiguous.
  • There isn't really any double equivalent to the best float representation of 3.5E+38. Comparing such a value to the best float representation of any other value above 3.5E+38 will indicate the values are indistinguishable--not necessarily very informative, but correct. Converting that value to double, on the other hand, will cause it to erroneously compare greater than the best double representation of all values below 1.798E+308--an error of hundreds of orders of magnitude.
    – supercat
    Sep 4, 2013 at 8:02
  • 1
    @supercat This answer is about converting a float to a double. The “best float representation of 3.5E+38” is +inf and the float +inf converts to the double +inf without loss of precision (it's the same inf!). How you interpret that infinity is your problem, not the problem of the conversion. A floating-point value (here, +inf) represents one value only (here, infinity). You could have made the same argument with 1-ulp intervals around 1.0f and the double 1.0, and the argument would be similarly irrelevant. It is a float, i.e. a single value, that is converted to double. Sep 4, 2013 at 8:21
  • @supercat See “Some common misconceptions (2)” in lipforge.ens-lyon.fr/www/crlibm/documents/cern.pdf . De Dinerchin is only talking about finite floating-point values there but the same applies to inf. The floating-point value inf is not “a range of values comprising 3.5E+38”, it is a single value, infinity. The approximation in translating 3.5E38 to +inf has already happened before the conversion to double, and does not prevent the conversion to double from being exact. Sep 4, 2013 at 8:25
  • A floating-point value effectively encapsulates two concepts: what can be said about the computations that produced it, and what should be fed into computations going forward. Given an expression like float2=float1/0.625f, if float1 was 62.5f, then the value of float2 indicates that the arithmetic result of the last operation was between 13421772.5/134217728 and 13421773.5/134217728, and that future uses of float2 will use the exact value 13421773/134217728. If float1 was 3.4E38, the value of float2 will indicate that...
    – supercat
    Sep 4, 2013 at 15:10
  • ...an arithmetic result exceeded 3.4028E38 by an unknown amount, and that future uses of float2 will regard it as infinite. If one wanted to know whether the arithmetic result of a computations that yielded float2 could be definitively regarded as larger than 0.11 or 1.7E+308, casting the second operand of each comparison to float would correctly report that they can't. Casting the float2 to double would suggest that they could.
    – supercat
    Sep 4, 2013 at 15:24

The conversion from float to double is a widening conversion, as specified by the JLS. A widening conversion is defined as an injective mapping of a smaller set into its superset. Therefore the number being represented does not change after a conversion from float to double.

More information regarding your updated question

In your update you added an example which is supposed to demonstrate that the number has changed. However, it only shows that the string representation of the number has changed, which indeed it has due to the additional precision acquired through the conversion to double. Note that your first output is just a rounding of the second output. As specified by Double.toString,

There must be at least one digit to represent the fractional part, and beyond that as many, but only as many, more digits as are needed to uniquely distinguish the argument value from adjacent values of type double.

Since the adjacent values in the type double are much closer than in float, more digits are needed to comply with that ruling.

  • Please read the original question, to which my original answer is a fully appropriate response, here. The question has been substantially updated since. Jun 4, 2014 at 7:18

The 32bit IEEE-754 floating point number closest to 125.32 is in fact 125.31999969482421875. Pretty close, but not quite there (that's because 0.32 is repeating in binary).

When you cast that to a double, it's the value 125.31999969482421875 that will be made into a double (125.32 is nowhere to be found at this point, the information that it should really end in .32 is completely lost) and of course can be represented exactly by a double. When you print that double, the print routine thinks it has more significant digits than it really has (but of course it can't know that), so it prints to 125.31999969482422, which is the shortest decimal that rounds to that exact double (and of all decimals of that length, it is the closest).

  • So, I made a mistake? What was it?
    – harold
    Jul 7, 2013 at 7:28

The issue of the precision of floating-point numbers is really language-agnostic, so I'll be using MATLAB in my explanation.

The reason you see a difference is that certain numbers are not exactly representable in fixed number of bits. Take 0.1 for example:

>> format hex

>> double(0.1)
ans =

>> double(single(0.1))
ans =

So the error in the approximation of 0.1 in single-precision gets bigger when you cast it as double-precision floating-point number. The result is different from its approximation if you started directly in double-precision.

>> double(single(0.1)) - double(0.1)
ans =
  • these approximations can creep up on you in unexpected ways. For example 0.1*3 == 0.3 evaluates to false. If you need extra accuracy, use arbitrary-precision libraries
    – Amro
    Jul 6, 2013 at 17:26
  • Really cogent explanation. Thanks.
    – Curt
    Jul 6, 2013 at 18:13
  • @Curt: you can find a much better explanation here: mathworks.com/company/newsletters/news_notes/pdf/… (by Cleve Moler, inventor of MATLAB). This page also has some nice examples
    – Amro
    Jul 6, 2013 at 18:31
  • This answer does not explain why printing a float shows a different numeral than printing a double converted from the same value (and which in fact has the same value, because conversion from float to double does not change the value). Jul 7, 2013 at 2:10
  • you are correct, I did not address how println chooses the number of decimal digits to display. The point I was making is that the mathematical value 123.32 cannot be exactly represented in single nor double precision, and that the approximation stored in float when upcasted to double type will not be the same as if the literal number was entered as double to begin with. So everybody is absolutely right in saying that float->double conversion does not loose any precision whatsoever, but the approximation we get for non-exactly-representable numbers are worse if you do the upcasting..
    – Amro
    Jul 7, 2013 at 3:51

As already explained, all floats can be exactly represented as a double and the reason for your issue is that System.out.println performs some rounding when displaying the value of a float or double but the rounding methodology is not the same in both cases.

To see the exact value of the float, you can use a BigDecimal:

float f = 125.32f;
System.out.println("value of f = " + new BigDecimal(f));
double d = (double) 125.32f;
System.out.println("value of d = " + new BigDecimal(d));

which outputs:

value of f = 125.31999969482421875
value of d = 125.31999969482421875

it won`t work in java because in java by default it will take real values as double and if we declare a float value without float representation like 123.45f by default it will take it as double and it will cause an error as loss of precision


The representation of the values changes due to contracts of the methods that convert numerical values to a String, correspondingly java.lang.Float#toString(float) and java.lang.Double#toString(double), while the actual value remains the same. There is a common part in Javadoc of both aforementioned methods that elaborates requirements to values' String representation:

There must be at least one digit to represent the fractional part, and beyond that as many, but only as many, more digits as are needed to uniquely distinguish the argument value from adjacent values

To illustrate the similarity of significant parts for values of both types, the following snippet can be run:

package com.my.sandbox.numbers;

public class FloatToDoubleConversion {

    public static void main(String[] args) {
        float f = 125.32f;
        double d = (double) f;

    private static void floatToBits(float floatValue) {
        System.out.println("String representation of float: " + floatValue);
        int bits = Float.floatToIntBits(floatValue);
        int sign = bits >>> 31;
        int exponent = (bits >>> 23 & ((1 << 8) - 1)) - ((1 << 7) - 1);
        int mantissa = bits & ((1 << 23) - 1);
        System.out.println("Bytes: " + Long.toBinaryString(Float.floatToIntBits(floatValue)));
        System.out.println("Sign: " + Long.toBinaryString(sign));
        System.out.println("Exponent: " + Long.toBinaryString(exponent));
        System.out.println("Mantissa: " + Long.toBinaryString(mantissa));
        System.out.println("Back from parts: " + Float.intBitsToFloat((sign << 31) | (exponent + ((1 << 7) - 1)) << 23 | mantissa));

    private static void doubleToBits(double doubleValue) {
        System.out.println("String representation of double: " + doubleValue);
        long bits = Double.doubleToLongBits(doubleValue);
        long sign = bits >>> 63;
        long exponent = (bits >>> 52 & ((1 << 11) - 1)) - ((1 << 10) - 1);
        long mantissa = bits & ((1L << 52) - 1);
        System.out.println("Bytes: " + Long.toBinaryString(Double.doubleToLongBits(doubleValue)));
        System.out.println("Sign: " + Long.toBinaryString(sign));
        System.out.println("Exponent: " + Long.toBinaryString(exponent));
        System.out.println("Mantissa: " + Long.toBinaryString(mantissa));
        System.out.println("Back from parts: " + Double.longBitsToDouble((sign << 63) | (exponent + ((1 << 10) - 1)) << 52 | mantissa));

In my environment, the output is:

String representation of float: 125.32
Bytes: 1000010111110101010001111010111
Sign: 0
Exponent: 110
Mantissa: 11110101010001111010111
Back from parts: 125.32

String representation of double: 125.31999969482422
Bytes: 100000001011111010101000111101011100000000000000000000000000000
Sign: 0
Exponent: 110
Mantissa: 1111010101000111101011100000000000000000000000000000
Back from parts: 125.31999969482422

This way, you can see that values' sign, exponent are the same, while its mantissa was extended retained its significant part (11110101010001111010111) exactly the same.

The used extraction logic of floating point number parts: 1 and 2.


Both are what Microsoft refers to as "approximate number data types."

There's a reason. A float has a precision of 7 digits, and a double 15. But I have seen it happen many times that 8.0 - 1.0 - 6.999999999. This is because they are not guaranteed to represent a decimal number fraction exactly.

If you need absolute, invariable precision, go with a decimal, or integral type.

  • 1
    "approximate" is quite an awkward way to describe what an IEEE floating point number is, since it exactly represents a very precisely defined set of numbers. Jul 6, 2013 at 16:38
  • 1
    This doesn't address the question at all.
    – Zong
    Jul 6, 2013 at 16:39
  • "Approximate-number data type" is precisely what Microsoft calls float and real: msdn.microsoft.com/en-us/library/ms173773.aspx
    – Curt
    Jul 6, 2013 at 16:43
  • @Curt If one starts calling a floating-point type “real”, then the first thing one needs to mention is that it is approximate: as a datatype to store real numbers in, it certainly is. I don't think that documentation from Microsoft about floating-point types in SQL should be considered appropriate reference material for discussion of floating-point either in itself or in Java. Jul 7, 2013 at 12:06
  • 2
    @MarkoTopolnik: From the standpoint of the code which performs low-level computations, IEEE floats are precisely-defined types. From the standpoint of consumer code, however, if a program reads two float values (say x=1.0 and y=10.0) and computes float z=x/y;, it is far more likely that the programmer regards z as holding an imperfect representation of value of the entered fraction, than a precise representation of the fraction 13421773/134217728.
    – supercat
    Sep 4, 2013 at 7:54

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