Java class file

Java class file
Developed by Sun Microsystems

A Java class file is a file (with the .class filename extension) containing Java bytecode that can be executed on the Java Virtual Machine (JVM). A Java class file is produced by a Java compiler from Java programming language source files (.java files) containing Java classes. If a source file has more than one class, each class is compiled into a separate class file.

JVMs are available for many platforms, and a class file compiled on one platform will execute on a JVM of another platform. This makes Java applications platform-independent.

History

On 11 December 2006, the class file format was modified under Java Specification Request (JSR) 202.[1]

File layout and structure

Sections

There are 10 basic sections to the Java Class File structure:

Magic Number

Class files are identified by the following 4 byte header (in hexadecimal): CA FE BA BE (the first 4 entries in the table below). The history of this magic number was explained by James Gosling referring to a restaurant in Palo Alto:[2]

"We used to go to lunch at a place called St Michael's Alley. According to local legend, in the deep dark past, the Grateful Dead used to perform there before they made it big. It was a pretty funky place that was definitely a Grateful Dead Kinda Place. When Jerry died, they even put up a little Buddhist-esque shrine. When we used to go there, we referred to the place as Cafe Dead. Somewhere along the line it was noticed that this was a HEX number. I was re-vamping some file format code and needed a couple of magic numbers: one for the persistent object file, and one for classes. I used CAFEDEAD for the object file format, and in grepping for 4 character hex words that fit after "CAFE" (it seemed to be a good theme) I hit on BABE and decided to use it. At that time, it didn't seem terribly important or destined to go anywhere but the trash-can of history. So CAFEBABE became the class file format, and CAFEDEAD was the persistent object format. But the persistent object facility went away, and along with it went the use of CAFEDEAD - it was eventually replaced by RMI.

General layout

Because the class file contains variable-sized items and does not also contain embedded file offsets (or pointers), it is typically parsed sequentially, from the first byte toward the end. At the lowest level the file format is described in terms of a few fundamental data types:

Some of these fundamental types are then re-interpreted as higher-level values (such as strings or floating-point numbers), depending on context. There is no enforcement of word alignment, and so no padding bytes are ever used. The overall layout of the class file is as shown in the following table.

byte offset size type or value description
0 4 bytes u1 =
0xCA hex
magic number (CAFEBABE) used to identify file as conforming to the class file format
1 u1 =
0xFE hex
2 u1 =
0xBA hex
3 u1 =
0xBE hex
4 2 bytes u2 minor version number of the class file format being used
5
6 2 bytes u2 major version number of the class file format being used.

Java SE 9 = 53 (0x35 hex),[3]
Java SE 8 = 52 (0x34 hex),
Java SE 7 = 51 (0x33 hex),
Java SE 6.0 = 50 (0x32 hex),
Java SE 5.0 = 49 (0x31 hex),
JDK 1.4 = 48 (0x30 hex),
JDK 1.3 = 47 (0x2F hex),
JDK 1.2 = 46 (0x2E hex),
JDK 1.1 = 45 (0x2D hex).
For details of earlier version numbers see footnote 1 at The JavaTM Virtual Machine Specification 2nd edition

7
8 2 bytes u2 constant pool count, number of entries in the following constant pool table. This count is at least one greater than the actual number of entries; see following discussion.
9
10 cpsize (variable) table constant pool table, an array of variable-sized constant pool entries, containing items such as literal numbers, strings, and references to classes or methods. Indexed starting at 1, containing (constant pool count - 1) number of entries in total (see note).
...
...
...
10+cpsize 2 bytes u2 access flags, a bitmask
11+cpsize
12+cpsize 2 bytes u2 identifies this class, index into the constant pool to a "Class"-type entry
13+cpsize
14+cpsize 2 bytes u2 identifies super class, index into the constant pool to a "Class"-type entry
15+cpsize
16+cpsize 2 bytes u2 interface count, number of entries in the following interface table
17+cpsize
18+cpsize isize (variable) table interface table, an array of variable-sized interfaces
...
...
...
18+cpsize+isize 2 bytes u2 field count, number of entries in the following field table
19+cpsize+isize
20+cpsize+isize fsize (variable) table field table, variable length array of fields
...
...
...
20+cpsize+isize+fsize 2 bytes u2 method count, number of entries in the following method table
21+cpsize+isize+fsize
22+cpsize+isize+fsize msize (variable) table method table, variable length array of methods
...
...
...
22+cpsize+isize+fsize+msize 2 bytes u2 attribute count, number of entries in the following attribute table
23+cpsize+isize+fsize+msize
24+cpsize+isize+fsize+msize asize (variable) table attribute table, variable length array of attributes
...
...
...

Representation in a C-like programming language

Since C doesn't support multiple variable length arrays within a struct, the code below won't compile and only serves as a demonstration.

struct Class_File_Format {
   u4 magic_number;

   u2 minor_version;   
   u2 major_version;

   u2 constant_pool_count;   
  
   cp_info constant_pool[constant_pool_count - 1];

   u2 access_flags;

   u2 this_class;
   u2 super_class;

   u2 interfaces_count;   
   
   u2 interfaces[interfaces_count];

   u2 fields_count;   
   field_info fields[fields_count];

   u2 methods_count;
   method_info methods[methods_count];

   u2 attributes_count;   
   attribute_info attributes[attributes_count];
}

The constant pool

The constant pool table is where most of the literal constant values are stored. This includes values such as numbers of all sorts, strings, identifier names, references to classes and methods, and type descriptors. All indexes, or references, to specific constants in the constant pool table are given by 16-bit (type u2) numbers, where index value 1 refers to the first constant in the table (index value 0 is invalid).

Due to historic choices made during the file format development, the number of constants in the constant pool table is not actually the same as the constant pool count which precedes the table. First, the table is indexed starting at 1 (rather than 0), but the count should actually be interpreted as the maximum index plus one.[4] Additionally, two types of constants (longs and doubles) take up two consecutive slots in the table, although the second such slot is a phantom index that is never directly used.

The type of each item (constant) in the constant pool is identified by an initial byte tag. The number of bytes following this tag and their interpretation are then dependent upon the tag value. The valid constant types and their tag values are:

Tag byte Additional bytes Description of constant
1 2+x bytes
(variable)
UTF-8 (Unicode) string: a character string prefixed by a 16-bit number (type u2) indicating the number of bytes in the encoded string which immediately follows (which may be different than the number of characters). Note that the encoding used is not actually UTF-8, but involves a slight modification of the Unicode standard encoding form.
3 4 bytes Integer: a signed 32-bit two's complement number in big-endian format
4 4 bytes Float: a 32-bit single-precision IEEE 754 floating-point number
5 8 bytes Long: a signed 64-bit two's complement number in big-endian format (takes two slots in the constant pool table)
6 8 bytes Double: a 64-bit double-precision IEEE 754 floating-point number (takes two slots in the constant pool table)
7 2 bytes Class reference: an index within the constant pool to a UTF-8 string containing the fully qualified class name (in internal format) (big-endian)
8 2 bytes String reference: an index within the constant pool to a UTF-8 string (big-endian too)
9 4 bytes Field reference: two indexes within the constant pool, the first pointing to a Class reference, the second to a Name and Type descriptor. (big-endian)
10 4 bytes Method reference: two indexes within the constant pool, the first pointing to a Class reference, the second to a Name and Type descriptor. (big-endian)
11 4 bytes Interface method reference: two indexes within the constant pool, the first pointing to a Class reference, the second to a Name and Type descriptor. (big-endian)
12 4 bytes Name and type descriptor: two indexes to UTF-8 strings within the constant pool, the first representing a name (identifier) and the second a specially encoded type descriptor.
15 3 bytes Method handle: this structure is used to represent a method handle and consists of one byte of type descriptor, followed by an index within the constant pool.[4]
16 2 bytes Method type: this structure is used to represent a method type, and consists of an index within the constant pool.[4]
18 4 bytes InvokeDynamic: this is used by an invokedynamic instruction to specify a bootstrap method, the dynamic invocation name, the argument and return types of the call, and optionally, a sequence of additional constants called static arguments to the bootstrap method.[4]

There are only two integral constant types, integer and long. Other integral types appearing in the high-level language, such as boolean, byte, and short must be represented as an integer constant.

Class names in Java, when fully qualified, are traditionally dot-separated, such as "java.lang.Object". However within the low-level Class reference constants, an internal form appears which uses slashes instead, such as "java/lang/Object".

The Unicode strings, despite the moniker "UTF-8 string", are not actually encoded according to the Unicode standard, although it is similar. There are two differences (see UTF-8 for a complete discussion). The first is that the codepoint U+0000 is encoded as the two-byte sequence C0 80 (in hex) instead of the standard single-byte encoding 00. The second difference is that supplementary characters (those outside the BMP at U+10000 and above) are encoded using a surrogate-pair construction similar to UTF-16 rather than being directly encoded using UTF-8. In this case each of the two surrogates is encoded separately in UTF-8. For example, U+1D11E is encoded as the 6-byte sequence ED A0 B4 ED B4 9E, rather than the correct 4-byte UTF-8 encoding of F0 9D 84 9E.

See also

References

Further reading

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