New Java programmers are often confused by compilation error messages like:

"incompatible types: possible lossy conversion from double to int"

for this line of code:

int squareRoot = Math.sqrt(i);

In general, what does the "possible lossy conversion" error message mean, and how do you fix it?


First of all, this is a compilation error. If you ever see it in an exception message at runtime, it is because you have have run a program with compilation errors1.

The general form of the message is this:

"incompatible types: possible lossy conversion from <type1> to <type2>"

where <type1> and <type2> are both primitive numeric types; i.e. one of byte, char, short, int, long, float or double.

This error happens when your code attempts to do an implicit conversion from <type1> to <type2> but the conversion could be lossy.

In the example in the question:

  int squareRoot = Math.sqrt(i);

the sqrt method produces a double, but a conversion from double to int is potentially lossy.

What does "potentially lossy" mean?

Well lets look at a couple of examples.

  1. A conversion of a long to an int is a potentially lossy conversion because there are long values that do not have a corresponding int value. For example, any long value that is greater than 2^31 - 1 is too large to be represented as an int. Similarly, any number less than -2^31 is too small.

  2. A conversion of an int to a long is NOT lossy conversion because every int value has a corresponding long value.

  3. A conversion of a float to an long is a potentially lossy conversion because there float values that are too large or too small to represent as long values.

  4. A conversion of an long to a float is NOT lossy conversion because every long value has a corresponding float value. (The converted value may be less precise, but "lossiness" doesn't mean that ... in this context.)

These are all the conversions that are potentially lossy:

  • short to byte or char
  • char to byte or short
  • int to byte, short or char
  • long to byte, short, char or int
  • float to byte, short, char, int or long
  • double to byte, short, char, int, long or float.

How do you fix the error?

The way to make the compilation error go away is to add a typecast. For example;

  int i = 47;
  int squareRoot = Math.sqrt(i);         // compilation error!


  int i = 47;
  int squareRoot = (int) Math.sqrt(i);   // no compilation error

But is that really a fix? Consider that the square root of 47 is 6.8556546004 ... but squareRoot will get the value 6. (The conversion will truncate, not round.)

And what about this?

  byte b = (int) 512;

That results in b getting the value 0. Converting from a larger int type to a smaller int type is done by masking out the high order bits, and the low-order 8 bits of 512 are all zero.

In short, you should not simply add a typecast, because it might not do the correct thing for your application.

Instead, you need to understand why your code needs to do a conversion:

  • Is this happening because you have made some other mistake in your code?
  • Should the <type1> be a different type, so that a lossy conversion isn't needed here?
  • If a conversion is necessary, is the silent lossy conversion that the typecast will do the correct behavior?
  • Or should your code be doing some range checks and dealing with incorrect / unexpected values by throwing an exception?

"Possible lossy conversion" when subscripting.

First example:

for (double d = 0; d < 10.0; d += 1.0) {
    System.out.println(array[d]);  // <<-- possible lossy conversion

The problem here is that array index value must be int. So d has to be converted from double to int. In general, using a floating point value as an index doesn't make sense. Either someone is under the impression that Java arrays work like (say) Python dictionaries, or they have overlooked the fact that floating-point arithmetic is often inexact.

The solution is to rewrite the code to avoid using a floating point value as an array index. (Adding a type cast is probably an incorrect solution.)

Second example:

for (long l = 0; l < 10; l++) {
    System.out.println(array[l]);  // <<-- possible lossy conversion

This is a variation of the previous problem, and the solution is the same. The difference is that the root cause is that Java arrays are limited to 32 bit indexes. If you want an "array like" data structure which has more than 231 - 1 elements, you need to define or find a class to do it.

"Possible lossy conversion" with literals

Consider this:

int a = 21; byte b1 = a; // <<-- possible lossy conversion byte b2 = 21; // OK

What is going on? Why is one version allowed but the other one isn't? (After all they "do" the same thing!)

First of all, the JLS states that 21 is an numeric literal whose type is int. (There are no byte or short literals.) So in both cases we are assigning an int to a byte.

In the first case, the reason for the error is that not all int values will fit into a byte.

In the second case, the compiler knows that 21 is a value that will always fit into a byte.

The technical explanation is that in an assignment context, it is permissible to perform a *primitive narrowing conversionto abyte,charorshortif: - the value is the result of a compile time *constant expression* (which includes literals), and - the type of the expression isbyte,short,charorint`, and - the value is representable (without loss) in the "target" type.

Note that this only applies with assignment statements. Thus:

Byte b4 = new Byte(21); // incorrect

gives a compilation error, though the compiler will not describe this as a "possible lossy conversion". (It will say that there is no matching constructor.)

1 - For instance, the Eclipse IDE has an option which allows you to ignore compilation errors and run the code anyway. If you select this, the IDE's compiler will create a .class file where the method with the error will throw an unchecked exception if it is called. The exception message will mention the compilation error message.

  • Any suggestions for more useful "specific cases"? I'm looking for examples where the root cause is some clearly identifiable misconception about the Java language ... that is not already covered. – Stephen C Aug 12 '18 at 3:11

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