Literals in Java

Java is an Object-Oriented Program. Literals are a representation of a fixed value by source code. They ‘re explicitly interpreted without any computation in the code. Every primitive form variable can be assigned literal.

Java literal is a syntactic element (i.e. something you find in the source code of a Java program) that represents a value. Examples are 1, 0.333F, false, ‘X’ and “Hello world\n“.

Using underscore to improve readability

Since Java 7 it has been possible to use one or more underscores (_) for separating groups of digits in a primitive number literal to improve their readability.

For instance, these two declarations are equivalent:

Version ≥ Java SE 7
int i1 = 123456;
int i2 = 123_456;
System.out.println(i1 == i2); // true

This can be applied to all primitive number literals as shown below:

Version ≥ Java SE 7
   byte color = 1_2_3;
   short yearsAnnoDomini= 2_016;
   int socialSecurtyNumber = 999_99_9999;
   long creditCardNumber = 1234_5678_9012_3456L;
   float piFourDecimals = 3.14_15F;
   double piTenDecimals = 3.14_15_92_65_35;

This also works using prefixes for binary, octal and hexadecimal bases:

Version ≥ Java SE 7
   short binary= 0b0_1_0_1;
   int octal = 07_7_7_7_7_7_7_7_0;
   long hexBytes = 0xFF_EC_DE_5E;

There are a few rules about underscores which forbid their placement in the following places:

  • At the beginning or end of a number (e.g. 123 or 123 are not valid)
  • Adjacent to a decimal point in a floating-point literal (e.g. 1.23 or 1.23 are not valid)
  • Prior to an F or L suffix (e.g. 1.23_F or 9999999_L are not valid)
  • In positions where a string of digits is expected (e.g. 0_xFFFF is not valid)

Hexadecimal, Octal and Binary literals

A hexadecimal number is a value in base-16. There are 16 digits, 0-9 and the letters A-F (case does not matter). A-F
represent 10-15.

An octal number is a value in base-8, and uses the digits 0-7.

A binary number is a value in base-2, and uses the digits 0 and 1.

All of these numbers result in the same value, 110:
int dec = 110;       // no prefix --> decimal literal
int bin = 0b1101110; // '0b' prefix --> binary literal
int oct = 0156;      // '0' prefix --> octal literal
int hex = 0x6E;      // '0x' prefix --> hexadecimal literal

Note that binary literal syntax was introduced in Java 7.

The octal literal can easily be a trap for semantic errors. If you define a leading ‘0’ to your decimal literals you will get the wrong value:

int a = 0100; // Instead of 100, a == 64

Boolean literals

Boolean literals are the simplest of the literals in the Java programming language. The two possible boolean values are represented by the literals true and false. These are case-sensitive. For example:

boolean flag = true; // using the 'true' literal
flag = false;       // using the 'false' literal

String literals

String literals provide the most convenient way to represent string values in Java source code. A String literal consists of:

  • An opening double-quote (“) character.
  • Zero or more other characters that are neither a double-quote or a line-break character. (A backslash () character alters the meaning of subsequent characters; see Escape sequences in literals.)
  • A closing double-quote character.

Related Article: Strings in Java

For example:

"Hello world"    // A literal denoting an 11 character String
""               // A literal denoting an empty (zero length) String
"\""             // A literal denoting a String consisting of one
                 // double quote character
"1\t2\t3\n"      // Another literal with escape sequences

Note that a single string literal may not span multiple source code lines. It is a compilation error for a line-break (or the end of the source file) to occur before a literal’s closing double-quote. For example

"Jello world // Compilation error (at the end of the line!)

Long strings

If you need a string that is too long to fit on a line, the conventional way to express it is to split it into multiple literals and use the concatenation operator (+) to join the pieces. For example

String typingPractice = "The quick brown fox " +
"jumped over " +
"the lazy dog"

An expression like the above consisting of string literals and + satisfies the requirements to be a Constant Expression. That means that the expression will be evaluated by the compiler and represented at runtime by a
single String object.

Interning of string literals

When a class file containing string literals is loaded by the JVM, the corresponding String objects are interned by the runtime system. This means that a string literal used in multiple classes occupies no more space than if it was used in one class.

For more information on interning and the string pool, refer to the String pool and heap storage example in the Strings topic.

The Null literal

The Null literal (written as null) represents the one and only value of the null type. Here are some examples

MyClass object = null;
MyClass[] objects = new MyClass[]{new MyClass(), null, new MyClass()};
myMethod(null);
if (objects != null) {
   // Do something
}

The null type is rather unusual. It has no name, so you cannot express it in Java source code. (And it has no runtime
representation either.)

The sole purpose of the null type is to be the type of null. It is assignment compatible with all reference types and can be typecast to any reference type. (In the latter case, the cast does not entail a runtime type check.)

Finally, null has the property that null instance of will evaluate to false, no matter what the type is.

Escape sequences in literals

String and character literals provide an escape mechanism that allows express character codes that would otherwise not be allowed in the literal. An escape sequence consists of a backslash character () followed by one
or more other characters. The same sequences are valid in both characters a string literals.

The complete set of escape sequences is as follows:

Escape sequenceMeaning
\\Denotes an backslash () character
\’Denotes a single-quote (‘) character
\”Denotes a double-quote (“) character
\nDenotes a line feed (LF) character
\rDenotes a carriage return (CR) character
\tDenotes a horizontal tab (HT) character
\fDenotes a form feed (FF) character
\bDenotes a backspace (BS) character
\<octal>Denotes a character code in the range 0 to 255.

The in the above consists of one, two, or three octal digits (‘0’ through ‘7’) which represent a number between 0 and 255 (decimal).

Note that a backslash followed by any other character is an invalid escape sequence. Invalid escape sequences are treated as compilation errors by the JLS.

Unicode escapes

In addition to the string and character escape sequences described above, Java has a more general Unicode escaping mechanism, as defined in JLS 3.3. Unicode Escapes. A Unicode escape has the following syntax:

'\' 'u'
where is one of '0', '1', '2', '3', '4', '5', '6', '7', '8', '9', 'a', 'b', 'c', 'd', 'e', 'f', 'A', 'B', 'C',
'D', 'E', 'F'.

A Unicode escape is mapped by the Java compiler to a character (strictly speaking a 16-bit Unicode code unit) and can be used anywhere in the source code where the mapped character is valid. It is commonly used in character and string literals when you need to represent a non-ASCII character in a literal.

Escaping in regexe

TBD

Character literals

Character literals provide the most convenient way to express char values in Java source code. A character literal consists of:

  • An opening single-quote (‘) character.
  • A representation of a character. This representation cannot be a single-quote or a line-break character, but it
  • can be an escape sequence introduced by a backslash () character; see Escape sequences in literals.
  • A closing single-quote (‘) character.

For example:

char a = 'a';
char doubleQuote = '"';
char singleQuote = '\'';

A line-break in a character literal is a compilation error:

char newline = '
// Compilation error in previous line
char newLine = '\n'; // Correct
Decimal Integer literals

Integer literals provide values that can be used where you need a byte, short, int, long, or char instance. (This the example focuses on the simple decimal forms. Other examples explain how to literals in octal, hexadecimal and binary, and the use of underscores to improve readability.)

Ordinary integer literals

The simplest and most common form of integer literal is a decimal integer literal. For example:

0     // The decimal number zero (type 'int')
1     // The decimal number one (type 'int')
42    // The decimal number forty two (type 'int')

You need to be careful with leading zeros. A leading zero causes an integer literal to be interpreted as octal, not decimal.

077 // This literal actually means 7 x 8 + 7 … or 63 decimal!

Integer literals are unsigned. If you see something like -10 or +10, these are actually expressions using the unary – and unary + operators.

The range of integer literals of this form has an intrinsic type of int and must fall in the range zero to 231 or 2,147,483,648.

Note that 231 is 1 greater than Integer.MAX_VALUE. Literals from 0 through to 2147483647 can be used anywhere, but it is a compilation error to use 2147483648 without a preceding unary – operator. (In other words, it is reserved for expressing the value of Integer.MIN_VALUE.)

int max = 2147483647;     // OK
int min = -2147483648;    // OK
int tooBig = 2147483648;  // ERROR

Long integer literals

Literals of type long are expressed by adding an L suffix. For example:

0L // The decimal number zero (type 'long')
1L // The decimal number one (type 'long')
2147483648L // The value of Integer.MAX_VALUE + 1
long big = 2147483648; // ERROR
long big2 = 2147483648L; // OK

Note that the distinction between int and long literals is significant in other places. For example

int i = 2147483647;
long l = i + 1; // Produces a negative value because the operation is
// performed using 32 bit arithmetic, and the
// addition overflows
long l2 = i + 1L; // Produces the (intuitively) correct value.
Floating-point literals

Floating-point literals provide values that can be used where you need a float or double instance. There are three kinds of floating-point literal.

  • Simple decimal forms
  • Scaled decimal forms
  • Hexadecimal forms

(The JLS syntax rules combine the two decimal forms into a single form. We treat them separately for ease of explanation.)

There are distinct literal types for float and double literals expressed using suffixes. The various forms use letters to express different things. These letters are case insensitive.

Simple decimal forms

The simplest form of floating-point literal consists of one or more decimal digits and a decimal point (.) and an optional suffix (f, F, d, or D). The optional suffix allows you to specify that the literal is a float (f or F) or double (d or D) value. The default (when no suffix is specified) is double.

For example

0.0           // this denotes zero
.0 // this also denotes zero
0. // this also denotes zero
3.14159 // this denotes Pi, accurate to (approximately!) 5 decimal places.
1.0F // a float literal
1.0D // a double literal. (double is the default if no suffix is given)

In fact, decimal digits followed by a suffix is also a floating point literal.

1F // means the same thing as 1.0F

The meaning of a decimal literal is the IEEE floating-point number that is closest to the infinite precision mathematical Real number denoted by the decimal floating-point form. This conceptual value is converted to the IEEE
binary floating-point representation using round to nearest. (The precise semantics of decimal conversion are specified in the javadocs for Double.valueOf(String) and Float.valueOf(String), bearing in mind that there are differences in the number syntaxes.)

Scaled decimal forms

Scaled decimal forms consist of simple decimal with an exponent part introduced by an E or e, and followed by a signed integer. The exponent part is a shorthand for multiplying the decimal form by a power of ten, as shown in the examples below. There is also an optional suffix to distinguish float and double literals. Here are some examples:

1.0E1   // this means 1.0 x 10^1 … or 10.0 (double)
1E-1D   // this means 1.0 x 10^(-1) … or 0.1 (double)
1.0e10f // this means 1.0 x 10^(10) … or 10000000000.0 (float)

The size of a literal is limited by the representation (float or double). It is a compilation error if the scale factor results in a value that is too large or too small.

Hexadecimal forms

Starting with Java 6, it is possible to express floating-point literals in hexadecimal. The hexadecimal form has an analogous syntax to the simple and scaled decimal forms with the following differences:

  1. Every hexadecimal floating-point literal starts with a zero (0) and then an x or X.
  2. The digits of the number (but not the exponent part!) also include the hexadecimal digits a through f and their uppercase equivalents.
  3. The exponent is mandatory and is introduced by the letter p (or P) instead of an e or E. The exponent represents a scaling factor that is a power of 2 instead of a power of 10.

Here are some examples:

0x0.0p0f    // this is zero expressed in hexadecimal form (float)
0xff.0p19   // this is 255.0 x 2^19 (double)

Advice: since hexadecimal floating-point forms are unfamiliar to most Java programmers, it is advisable to use them sparingly.

Underscores

Starting with Java 7, underscores are permitted within the digit strings in all three forms of floating point literal. This applies to the “exponent” parts as well. See Using underscores to improve readability.

Special cases

It is a compilation error if a floating-point literal denotes a number that is too large or too small to represent in the selected representation; i.e. if the number would overflow to +INF or -INF, or underflow to 0.0. However, it is legal for a literal to represent a non-zero denormalized number.

The floating-point literal syntax does not provide literal representations for IEEE 754 special values such as the INF and NaN values. If you need to express them in source code, the recommended way is to use the constants defined by the java.lang.Float and java.lang.Double; e.g. Float.NaN, Float.NEGATIVE_INFINITY and Float.POSITIVE_INFINITY.

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