Java Native Interface (JNI) is a programming framework that
enables Java code running in a
Java Virtual Machine
1 Objectives 2 Design 3 Mapping types 4 Performance 5 Alternatives 6 See also 7 References 8 Bibliography 9 External links
JNI enables programmers to write native methods to handle situations
when an application cannot be written entirely in the Java programming
language, e.g. when the standard Java class library does not support
the platform-specific features or program library. It is also used to
modify an existing application (written in another programming
language) to be accessible to Java applications. Many of the standard
library classes depend on JNI to provide functionality to the
developer and the user, e.g. file I/O and sound capabilities.
Including performance- and platform-sensitive API implementations in
the standard library allows all Java applications to access this
functionality in a safe and platform-independent manner.
The JNI framework lets a native method use Java objects in the same
way that Java code uses these objects. A native method can create Java
objects and then inspect and use these objects to perform its tasks. A
native method can also inspect and use objects created by Java
Only applications and signed applets can invoke JNI.
An application that relies on JNI loses the platform portability Java
offers (a partial workaround is to write a separate implementation of
JNI code for each platform and have Java detect the operating system
and load the correct one at runtime).
Not only can native code interface with Java, it can also draw on a
Java Canvas, which is possible with the Java AWT Native Interface. The
process is almost the same, with just a few changes. The Java AWT
Native Interface is only available since J2SE 1.3.
JNI also allows direct access to assembly code, without even going
through a C bridge. Accessing Java applications from assembly is
also possible in the same way.
In the JNI framework, native functions are implemented in separate .c
or .cpp files. (
extern "C" JNIEXPORT void JNICALL Java_ClassName_MethodName (JNIEnv *env, jobject obj, jstring javaString)
const char *nativeString = env->GetStringUTFChars(javaString, 0);
//Do something with the nativeString
The env pointer is a structure that contains the interface to the JVM. It includes all of the functions necessary to interact with the JVM and to work with Java objects. Example JNI functions are converting native arrays to/from Java arrays, converting native strings to/from Java strings, instantiating objects, throwing exceptions, etc. Basically, anything that Java code can do can be done using JNIEnv, albeit with considerably less ease. The argument obj is a reference to the Java object inside which this native method has been declared. Native data types can be mapped to/from Java data types. For compound types such as objects, arrays and strings the native code must explicitly convert the data by calling methods in the JNIEnv. A JNI environment pointer (JNIEnv*) is passed as an argument for each native function mapped to a Java method, allowing for interaction with the JNI environment within the native method. This JNI interface pointer can be stored, but remains valid only in the current thread. Other threads must first call AttachCurrentThread() to attach themselves to the VM and obtain a JNI interface pointer. Once attached, a native thread works like a regular Java thread running within a native method. The native thread remains attached to the VM until it calls DetachCurrentThread() to detach itself. The JNI framework does not provide any automatic garbage collection for non-JVM memory resources allocated by code executing on the native side. Consequently, native side code (such as assembly language) assumes the responsibility for explicitly releasing any such memory resources that the native code acquires. On Linux and Solaris platforms, if the native code registers itself as a signal handler, it could intercept signals intended for the JVM. A chain of responsibility can be used to allow native code to better inter-operate with the JVM. On Windows platforms, Structured Exception Handling (SEH) may be employed to wrap native code in SEH try/catch blocks so as to capture machine (CPU/FPU) generated software interrupts (such as NULL pointer access violations and divide-by-zero operations), and to handle these situations before the interrupt is propagated back up into the JVM (i.e. Java side code), in all likelihood resulting in an unhandled exception.[original research?] The encoding used for the NewStringUTF, GetStringUTFLength, GetStringUTFChars, ReleaseStringUTFChars and GetStringUTFRegion functions is "modified UTF-8", which is not valid UTF-8 for all inputs, but a different encoding really. The null character (U+0000) and codepoints not on the Basic Multilingual Plane (greater than or equal to U+10000, i.e. those represented as surrogate pairs in UTF-16) are encoded differently in modified UTF-8. Many programs actually use these functions incorrectly and treat the UTF-8 strings returned or passed into the functions as standard UTF-8 strings instead of modified UTF-8 strings. Programs should use the NewString, GetStringLength, GetStringChars, ReleaseStringChars, GetStringRegion, GetStringCritical and ReleaseStringCritical functions, which use UTF-16LE encoding on little-endian architectures and UTF-16BE on big-endian architectures, and then use a UTF-16 to UTF-8 conversion routine.[original research?] Mapping types The following table shows the mapping of types between Java (JNI) and native code.
Native Type Java Language Type Description Type signature
unsigned char jboolean unsigned 8 bits Z
signed char jbyte signed 8 bits B
unsigned short jchar unsigned 16 bits C
short jshort signed 16 bits S
long jint signed 32 bits I
long long __int64
jlong signed 64 bits J
float jfloat 32 bits F
double jdouble 64 bits D
In addition, the signature "L fully-qualified-class ;" would mean the class uniquely specified by that name; e.g., the signature "Ljava/lang/String;" refers to the class java.lang.String. Also, prefixing [ to the signature makes the array of that type; for example, [I means the int array type. Finally, a void signature uses the V code. These types are interchangeable. One can use jint where you normally use an int, and vice versa, without any typecasting required. However, mapping between Java Strings and arrays to native strings and arrays is different. If a jstring is used where a char * would be, the code could crash the JVM.[original research?] Performance JNI incurs considerable overhead and performance loss under certain circumstances:
Function calls to JNI methods are expensive, especially when calling a method repeatedly. Native methods are not inlined by the JVM, nor can the method be JIT compiled, as the method is already compiled. A Java array may be copied for access in native code, and later copied back. The cost can be linear in the size of the array. If the method is passed an object, or needs to make a callback, then the native method will likely be making its own calls to the JVM. Accessing Java fields, methods and types from the native code requires something similar to reflection. Signatures are specified in strings and queried from the JVM. This is both slow and error-prone. Java Strings are objects, have length and are encoded. Accessing or creating a string may require an O(n) copy.
Alternatives Microsoft's proprietary implementation of a Java Virtual Machine (Visual J++) has a similar mechanism for calling native code from Java, called the Raw Native Interface (RNI). In addition, it has an easy way to call existing native code that isn't itself aware of Java, such as (but not limited to) the Windows API, called J/Direct. However, following the Sun - Microsoft litigation about this implementation, Visual J++ is no longer maintained. RNI was less clumsy to use than JNI, because no bookkeeping with a Java environment pointer was needed. Instead, all Java objects could be accessed directly. To facilitate this, a tool was used that generated header files from Java classes. Similarly, J/Direct was easier to use than using the necessary intermediate native library and JNI, although at present JNA is an alternative.[original research?] See also
GIWS (software) Gluegen Java AWT Native Interface Java Native Access Platform Invocation Services SWIG
^ "Role of the JNI". The Java Native Interface Programmer's Guide and Specification. Retrieved 2008-02-27. ^ "Invoking Assembly Language Programs from Java". Java.net. 2006-10-19. Archived from the original on 2008-03-30. Retrieved 2007-10-06. ^ "Launch Java Applications from Assembly Language Programs". Java.net. 2006-10-19. Archived from the original on 2007-10-11. Retrieved 2007-10-04. ^ The Invocation API. Sun Microsystems. http://java.sun.com/j2se/1.5.0/docs/guide/jni/spec/invocation.html ^ "JNI Types and Data Structures". ^ "java — What makes JNI calls slow? - Stack Overflow".
Gordon, Rob (March 1998). Essential Jni: Java Native Interface (1st ed.). Prentice Hall. p. 498. ISBN 0-13-679895-0. Liang, Sheng (June 20, 1999). Java(TM) Native Interface: Programmer's Guide and Specification (1st ed.). Prentice Hall. p. 320. ISBN 0-201-32577-2.
Oracle's JNI 6.0 API Specification Java Native Interface: Programmer's Guide and Specification JNI in XCode from Apple Excepti