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Java Native Interface (JNI) on Substrate VM

(See also the guide on assisted configuration of JNI and other dynamic features)

JNI is a native API that enables Java code to interact with native code and vice versa. This page gives an overview over the JNI implementation in Substrate VM.

Integration

JNI support is enabled by default and built into Substrate VM images. Individual classes, methods, and fields that should be accessible via JNI must be specified during native image generation in a configuration file (read below).

Linking

Java code can load native code from a shared object with System.loadLibrary(). Alternatively, native code can load the JVM's native library and attach to its Java environment using JNI's invocation API. The Substrate VM JNI implementation supports both approaches.

Reflection

JNI supports looking up classes by their names, and looking up methods and fields by their names and signatures. This requires keeping the necessary metadata for these lookups around. The image build must know beforehand which items will be looked up in case they might not be reachable otherwise and therefore would not be included in the native image. Moreover, the image build must generate call wrapper code ahead of time for any method that can be called via JNI. Therefore, specifying a concise list of items that need to be accessible via JNI guarantees their availability and allows for a smaller footprint. Such a list can be specified with the following image build argument:

-H:JNIConfigurationFiles=/path/to/jniconfig

where jniconfig is a JSON configuration file. The syntax is the same as for reflection configuration files, which are described in the documentation on reflection.

The image build generates JNI reflection metadata for all classes, methods and fields referenced in the configuration file. More than one JNI configuration can be used by specifying multiple paths for JNIConfigurationFiles and separating them with ,. Also, -H:JNIConfigurationResources can be specified to load one or several configuration files from the image build's class path, such as from a JAR file.

Alternatively, a custom Feature implementation can register program elements before and during the analysis phase of the native image build using the JNIRuntimeAccess class. For example:

@AutomaticFeature
class JNIRegistrationFeature implements Feature {
  public void beforeAnalysis(BeforeAnalysisAccess access) {
    try {
      JNIRuntimeAccess.register(String.class);
      JNIRuntimeAccess.register(String.class.getDeclaredField("value"));
      JNIRuntimeAccess.register(String.class.getDeclaredField("hash"));
      JNIRuntimeAccess.register(String.class.getDeclaredConstructor(char[].class));
      JNIRuntimeAccess.register(String.class.getDeclaredMethod("charAt", int.class));
      JNIRuntimeAccess.register(String.class.getDeclaredMethod("format", String.class, Object[].class));
      JNIRuntimeAccess.register(String.CaseInsensitiveComparator.class);
      JNIRuntimeAccess.register(String.CaseInsensitiveComparator.class.getDeclaredMethod("compare", String.class, String.class));
    } catch (NoSuchMethodException | NoSuchFieldException e) { ... }
  }
}

Object handles

JNI does not permit direct access to Java objects. Instead, JNI provides word-sized object handles that can be passed to JNI functions to access objects indirectly. Local handles are only valid for the duration of a native call and only in the caller's thread, while global handles are valid across threads and remain valid until they are destroyed explicitly. The handle 0 represents NULL.

Substrate VM implements local handles with a thread-local, growing array of referenced objects, where the index in the array is the handle value. A "finger" points to where the next handle will be allocated. Native calls can be nested, so before a native method is invoked, the call stub pushes the current finger on a stack, and after it returns, it restores the old finger from the stack and nullifies all object references from the call in the array. Global handles are implemented using a variable number of object arrays in which referenced objects are inserted and nullified using atomic operations. A global handle's value is a negative integer that is determined from the index of the containing array and the index within the array. Therefore, the JNI code can distinguish local and global handles by only looking at their sign. The analysis is not obstructed by object handles because it can observe the entire flow of object references and the handles that are passed to native code are only numeric values.

Java-to-native method calls

Methods declared with the native keyword have a JNI-compliant implementation in native code, but can be called like any other Java method. For example:

// Java declaration
native int[] sort0(int[] array);
// native declaration with JNI name mangling
jintArray JNICALL Java_org_example_sorter_IntSorter_sort0(JNIEnv *env, jobject this, jintArray array) {

When the image build encounters a method that is declared native, it generates a Graal graph with a wrapper that performs the transition to native code and back, adds the JNIEnv* and this arguments, boxes any object arguments in handles and, in case of an object return type, unboxes the returned handle.

The actual native call target address can only be determined at runtime. Therefore, the image build also creates an extra linkage object in the reflection metadata of native-declared methods. When a native method is called, the call wrapper looks up the matching symbol in all loaded libraries and stores the resolved address in the linkage object for future calls. Alternatively, instead of requiring symbols that conform to JNI's name mangling scheme, Substrate VM also supports the RegisterNatives JNI function to explicitly provide code addresses for native methods.

JNI Functions

JNI provides a set of functions that native code can use to interact with Java code. Substrate VM implements these functions using @CEntryPoint, for example:

@CEntryPoint(...) private static void DeleteGlobalRef(JNIEnvironment env, JNIObjectHandle globalRef) { /* setup; */ JNIGlobalHandles.singleton().delete(globalRef); }

JNI specifies that these functions are provided via function pointers in a C struct that is accessible via the JNIEnv* argument. The automatic initialization of this struct is prepared during the image build.

Native-to-Java method calls

Native code can invoke Java methods by first obtaining a jmethodID for the target method, and then using one of the Call<Type>Method, CallStatic<Type>Method or CallNonvirtual<Type>Method functions for the invocation. Each of these Call... functions is also available in a Call...MethodA and a Call...MethodV variant, which take arguments as an array or as a va_list instead of variadic arguments. For example:

jmethodID intcomparator_compare_method = (*env)->GetMethodID(env, intcomparator_class, "compare", "(II)I");
jint result = (*env)->CallIntMethod(env, this, intcomparator_compare_method, a, b);

The image build generates call wrappers for each method that can be called via JNI according to the provided JNI configuration. The call wrappers conform to the signature of the JNI Call... functions that are appropriate for the method. The wrappers perform the transition to Java code and back, adapt the argument list to the target Java method's signature, unbox any passed object handles, and if necessary, box the return type in an object handle.

Each method that can be called via JNI has a reflection metadata object. The address of this object is used as the method's jmethodID. The metadata object contains the addresses of all of the method's generated call wrappers. Because each call wrapper conforms precisely to the corresponding Call... function signature, the Call... functions themselves are nothing more than an unconditional jump to the appropriate call wrapper based on the passed jmethodID. As another optimization, the call wrappers are able to efficiently restore the current thread's Java context from the JNIEnv* argument.

Object creation

JNI provides two ways of creating Java objects, either by calling AllocObject to allocate memory and then using CallVoidMethod to invoke the constructor, or by using NewObject to create and initialize the object in a single step (or variants NewObjectA or NewObjectV). For example:

jclass calendarClass = (*env)->FindClass(env, "java/util/GregorianCalendar");
jmethodID ctor = (*env)->GetMethodID(env, calendarClass, "<init>", "(IIIIII)V");
jobject firstObject = (*env)->AllocObject(env, calendarClass);
(*env)->CallVoidMethod(env, obj, ctor, year, month, dayOfMonth, hourOfDay, minute, second);
jobject secondObject = (*env)->NewObject(env, calendarClass, ctor, year, month, dayOfMonth, hourOfDay, minute, second);

Substrate VM supports both approaches. The constructor must be included in the JNI configuration with a method name of <init>. Instead of generating additional call wrappers for NewObject, the regular CallVoidMethod wrapper is reused and detects when it is called via NewObject because it is passed the Class object of the target class. In that case, the call wrapper allocates a new instance before invoking the actual constructor.

Field accesses

Native code can access a Java field by obtaining its jfieldID and then using one of the Get<Type>Field, Set<Type>Field, GetStatic<Type>Field or SetStatic<Type>Field functions. For example:

jfieldID intsorter_comparator_field = (*env)->GetFieldID(env, intsorter_class, "comparator", "Lorg/example/sorter/IntComparator;");
jobject value = (*env)->GetObjectField(env, self, intsorter_comparator_field);

For a field that is accessible via JNI, its offset within an object (or within the static field area) is stored in the reflection metadata and is used as its jfieldID. The image build generates accessor methods for for fields of all primitive types and for object fields. These accessor methods perform the transition to Java code and back, and use unsafe loads or stores to directly manipulate the field value. Because the analysis cannot observe assignments of object fields via JNI, it assumes that any subtype of the field's declared type can occur in a field that is accessible via JNI.

JNI also permits writing fields that are declared final, which must be enabled for individual fields with an allowWrite property in the configuration file. However, code accessing final fields might not observe changes of final field values in the same way as for non-final fields because of optimizations.

Exceptions

JNI specifies that exceptions in Java code that are the result of a call from native code must be caught and retained. In Substrate VM, this is done in the native-to-Java call wrappers and in the implementation JNI functions. Native code can then query and clear a pending exception with the ExceptionCheck, ExceptionOccurred, ExceptionDescribe and ExceptionClear functions. Native code can also throw exceptions with Throw, ThrowNew or FatalError. When an exception remains unhandled in native code or the native code itself throws an exception, the Java-to-native call wrapper rethrows that exception upon reentering Java code.

Monitors

JNI declares the functions MonitorEnter and MonitorExit to acquire and release the intrinsic lock of an object. Substrate VM provides implementations of these functions. However, the native image build directly assigns intrinsic locks only to objects of classes which the analysis can observe as being used in Java synchronized statements and with wait(), notify() and notifyAll(). For other objects, synchronization falls back on a slower mechanism which uses a map to store lock associations, which itself needs synchronization. For that reason, it can be beneficial to wrap synchronization in Java code.

java.lang.reflect Support

The JNI functions FromReflectedMethod and ToReflectedMethod can be used to obtain the corresponding jmethodID to a java.lang.reflect.Method, or to a java.lang.reflect.Constructor object, and vice versa. The functions FromReflectedField and ToReflectedField convert between jfieldID and java.lang.reflect.Field. In order to use these functions, reflection support must be enabled and the methods and fields in question must be included in the reflection configuration, which is specified with -H:ReflectionConfigurationFiles=.

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