This chapter discusses how the JNI maps Java types to native C types.
This chapter covers the following topics:
- Primitive Types
- Reference Types
- Field and Method IDs
- The Value Type
- Type Signatures
- Modified UTF-8 Strings
Primitive Types
The following table describes Java primitive types and their machine-dependent native equivalents.
Java Type | Native Type | Description |
---|---|---|
boolean | jboolean | unsigned 8 bits |
byte | jbyte | signed 8 bits |
char | jchar | unsigned 16 bits |
short | jshort | signed 16 bits |
int | jint | signed 32 bits |
long | jlong | signed 64 bits |
float | jfloat | 32 bits |
double | jdouble | 64 bits |
void | void | not applicable |
The following definition is provided for convenience.
#define JNI_FALSE 0
#define JNI_TRUE 1
The jsize
integer type is used to describe cardinal
indices and sizes:
typedef jint jsize;
Reference Types
The JNI includes a number of reference types that correspond to different kinds of Java objects. JNI reference types are organized in the following hierarchy:
jobject
jclass
(java.lang.Class
objects)jstring
(java.lang.String
objects)jarray
(arrays)jobjectArray
(object arrays)jbooleanArray
(boolean
arrays)jbyteArray
(byte
arrays)jcharArray
(char
arrays)jshortArray
(short
arrays)jintArray
(int
arrays)jlongArray
(long
arrays)jfloatArray
(float
arrays)jdoubleArray
(double
arrays)
jthrowable
(java.lang.Throwable
objects)
In C, all other JNI reference types are defined to be the same as jobject. For example:
typedef jobject jclass;
In C++, JNI introduces a set of dummy classes to enforce the subtyping relationship. For example:
class _jobject {};
class _jclass : public _jobject {};
// ...
typedef _jobject *jobject;
typedef _jclass *jclass;
Field and Method IDs
Method and field IDs are regular C pointer types:
struct _jfieldID; /* opaque structure */
typedef struct _jfieldID *jfieldID; /* field IDs */
struct _jmethodID; /* opaque structure */
typedef struct _jmethodID *jmethodID; /* method IDs */
The Value Type
The jvalue
union type is used as the element type in
argument arrays. It is declared as follows:
typedef union jvalue {
jboolean z;
jbyte b;
jchar c;
jshort s;
jint i;
jlong j;
jfloat f;
jdouble d;
jobject l;
} jvalue;
Type Signatures
The JNI uses the Java VM’s representation of type signatures. The following table shows these type signatures.
Type Signature | Java Type |
---|---|
Z |
boolean |
B |
byte |
C |
char |
S |
short |
I |
int |
J |
long |
F |
float |
D |
double |
L fully-qualified-class
; |
fully-qualified-class |
[ type |
type[] |
( arg-types )
ret-type |
method type |
For example, the Java method:
long f (int n, String s, int[] arr);
has the following type signature:
(ILjava/lang/String;[I)J
Modified UTF-8 Strings
The JNI uses modified UTF-8 strings to represent various string types. Modified UTF-8 strings are the same as those used by the Java VM. Modified UTF-8 strings are encoded so that character sequences that contain only non-null ASCII characters can be represented using only one byte per character, but all Unicode characters can be represented.
All characters in the range \u0001 to \u007F are represented by a single byte, as follows:
0xxxxxxx
The seven bits of data in the byte give the value of the character represented.
The null character ('\u0000'
) and characters in the
range '\u0080'
to '\u07FF'
are represented by
a pair of bytes x and y:
- x:
110xxxxx
- y:
10yyyyyy
The bytes represent the character with the value ((x &
0x1f
) << 6
) + (y &
0x3f
).
Characters in the range '\u0800'
to
'\uFFFF'
are represented by 3 bytes x, y, and z:
- x:
1110xxxx
- y:
10yyyyyy
- z:
10zzzzzz
The character with the value ((x & 0xf
) <<
12
) + ((y & 0x3f
) << 6
)
+ (z & 0x3f
) is represented by the bytes.
Characters with code points above U+FFFF (so-called supplementary characters) are represented by separately encoding the two surrogate code units of their UTF-16 representation. Each of the surrogate code units is represented by three bytes. This means, supplementary characters are represented by six bytes, u, v, w, x, y, and z:
- u:
11101101
- v:
1010vvvv
- w:
10wwwwww
- x:
11101101
- y:
1011yyyy
- z:
10zzzzzz
The character with the value 0x10000+((v&0x0f)<<16)+((w&0x3f)<<10)+(y&0x0f)<<6)+(z&0x3f) is represented by the six bytes.
The bytes of multibyte characters are stored in the
class
file in big-endian (high byte first) order.
There are two differences between this format and the standard UTF-8
format. First, the null character (char)0
is encoded using
the two-byte format rather than the one-byte format. This means that
modified UTF-8 strings never have embedded nulls. Second, only the
one-byte, two-byte, and three-byte formats of standard UTF-8 are used.
The Java VM does not recognize the four-byte format of standard UTF-8;
it uses its own two-times-three-byte format instead.
For more information regarding the standard UTF-8 format, see section 3.9 Unicode Encoding Forms of The Unicode Standard, Version 4.0.