* While executing a {@literal @}{@code FastNative} method, the garbage collection cannot * suspend the thread for essential work and may become blocked. Use with caution. Do not use * this annotation for long-running methods, including usually-fast, but generally unbounded, * methods. In particular, the code should not perform significant I/O operations or acquire * native locks that can be held for a long time. (Some logging or native allocations, which * internally acquire native locks for a short time, are generally OK. However, as the cost * of several such operations adds up, the {@literal @}{@code FastNative} performance gain * can become insignificant and overshadowed by potential GC delays.) * Acquiring managed locks is OK as it internally allows thread suspension. *
* ** For performance critical methods that need this annotation, it is strongly recommended * to explicitly register the method(s) with JNI {@code RegisterNatives} instead of relying * on the built-in dynamic JNI linking. *
* ** The {@literal @}{@code FastNative} optimization was implemented for system use since * Android 8 and became CTS-tested public API in Android 14. Developers aiming for maximum * compatibility should avoid calling {@literal @}{@code FastNative} methods on Android 13-. * The optimization is likely to work also on Android 8-13 devices (after all, it was used * in the system, albeit without the strong CTS guarantees), especially those that use * unmodified versions of ART, such as Android 12+ devices with the official ART Module. * The built-in dynamic JNI linking is working only in Android 12+, the explicit registration * with JNI {@code RegisterNatives} is strictly required for running on Android versions 8-11. * The annotation is ignored on Android 7-. *
* ** Deadlock Warning: As a rule of thumb, any native locks acquired in a * {@literal @}{@link FastNative} call (despite the above warning that this is an unbounded * operation that can block GC for a long time) must be released before returning to managed code. *
* *
* Say some code does:
*
*
* fast_jni_call_to_grab_a_lock();
* does_some_java_work();
* fast_jni_call_to_release_a_lock();
*
*
*
* This code can lead to deadlocks. Say thread 1 just finishes * {@code fast_jni_call_to_grab_a_lock()} and is in {@code does_some_java_work()}. * GC kicks in and suspends thread 1. Thread 2 now is in {@code fast_jni_call_to_grab_a_lock()} * but is blocked on grabbing the native lock since it's held by thread 1. * Now thread suspension can't finish since thread 2 can't be suspended since it's doing * FastNative JNI. *
* ** Normal JNI doesn't have the issue since once it's in native code, * it is considered suspended from java's point of view. * FastNative JNI however doesn't do the state transition done by JNI. *
* ** Note that even in FastNative methods you are allowed to * allocate objects and make upcalls into Java code. A call from Java to * a FastNative function and back to Java is equivalent to a call from one Java * method to another. What's forbidden in a FastNative method is blocking * the calling thread in some non-Java code and thereby preventing the thread * from responding to requests from the garbage collector to enter the suspended * state. *
* ** Has no effect when used with non-native methods. *
*/ @Retention(RetentionPolicy.CLASS) // Save memory, don't instantiate as an object at runtime. @Target(ElementType.METHOD) public @interface FastNative {}