Crate jni[−][src]
Expand description
Safe JNI Bindings in Rust
This crate provides a (mostly) safe way to implement methods in Java using the JNI. Because who wants to actually write Java?
Getting Started
Naturally, any ffi-related project is going to require some code in both languages that we’re trying to make communicate. Java requires all native methods to adhere to the Java Native Interface (JNI), so we first have to define our function signature from Java, and then we can write Rust that will adhere to it.
The Java side
First, you need a Java class definition. HelloWorld.java
:
class HelloWorld { // This declares that the static `hello` method will be provided // a native library. private static native String hello(String input); static { // This actually loads the shared object that we'll be creating. // The actual location of the .so or .dll may differ based on your // platform. System.loadLibrary("mylib"); } // The rest is just regular ol' Java! public static void main(String[] args) { String output = HelloWorld.hello("josh"); System.out.println(output); } }
Compile this to a class file with javac HelloWorld.java
.
Trying to run it now will give us the error Exception in thread "main" java.lang.UnsatisfiedLinkError: no mylib in java.library.path
since we
haven’t written our native code yet.
To do that, first we need the name and type signature that our Rust function
needs to adhere to. Luckily, the Java compiler can generate that for you!
Run javac -h . HelloWorld
and you’ll get a HelloWorld.h
output to your
directory. It should look something like this:
/* DO NOT EDIT THIS FILE - it is machine generated */ #include <jni.h> /* Header for class HelloWorld */ #ifndef _Included_HelloWorld #define _Included_HelloWorld #ifdef __cplusplus extern "C" { #endif /* * Class: HelloWorld * Method: hello * Signature: (Ljava/lang/String;)Ljava/lang/String; */ JNIEXPORT jstring JNICALL Java_HelloWorld_hello (JNIEnv *, jclass, jstring); #ifdef __cplusplus } #endif #endif
It’s a C header, but luckily for us, the types will mostly match up. Let’s make our crate that’s going to compile to our native library.
The Rust side
Create your crate with cargo new mylib
. This will create a directory
mylib
that has everything needed to build an basic crate with cargo
. We
need to make a couple of changes to Cargo.toml
before we do anything else.
- Under
[dependencies]
, addjni = "0.19.0"
- Add a new
[lib]
section and under it,crate_type = ["cdylib"]
.
Now, if you run cargo build
from inside the crate directory, you should
see a libmylib.so
(if you’re on linux) or a libmylib.dylib
(if you are on OSX) in the target/debug
directory.
The last thing we need to do is to define our exported method. Add this to
your crate’s src/lib.rs
:
// This is the interface to the JVM that we'll call the majority of our // methods on. use jni::JNIEnv; // These objects are what you should use as arguments to your native // function. They carry extra lifetime information to prevent them escaping // this context and getting used after being GC'd. use jni::objects::{JClass, JString}; // This is just a pointer. We'll be returning it from our function. We // can't return one of the objects with lifetime information because the // lifetime checker won't let us. use jni::sys::jstring; // This keeps Rust from "mangling" the name and making it unique for this // crate. #[no_mangle] pub extern "system" fn Java_HelloWorld_hello(env: JNIEnv, // This is the class that owns our static method. It's not going to be used, // but still must be present to match the expected signature of a static // native method. class: JClass, input: JString) -> jstring { // First, we have to get the string out of Java. Check out the `strings` // module for more info on how this works. let input: String = env.get_string(input).expect("Couldn't get java string!").into(); // Then we have to create a new Java string to return. Again, more info // in the `strings` module. let output = env.new_string(format!("Hello, {}!", input)) .expect("Couldn't create java string!"); // Finally, extract the raw pointer to return. output.into_inner() }
Note that the type signature for our function is almost identical to the one from the generated header, aside from our lifetime-carrying arguments.
Final steps
That’s it! Build your crate and try to run your Java class again.
… Same error as before you say? Well that’s because JVM is looking for
mylib
in all the wrong places. This will differ by platform thanks to
different linker/loader semantics, but on Linux, you can simply export LD_LIBRARY_PATH=/path/to/mylib/target/debug
. Now, you should get the
expected output Hello, josh!
from your Java class.
Launching JVM from Rust
It is possible to launch a JVM from a native process using the Invocation API, provided
by JavaVM
.
See Also
Examples
JNI Documentation
- Java Native Interface Specification
- JNI tips — general tips on JNI development and some Android-specific
Open-Source Users
- The Servo browser engine Android port
- The Exonum framework Java Binding
- MaidSafe Java Binding
Other Projects Simplifying Java and Rust Communication
- Consider JNR if you just need to use a native library with C interface
- Watch OpenJDK Project Panama which aims to enable using native libraries with no JNI code
- Consider GraalVM — a recently released VM that gives zero-cost interoperability between various languages (including Java and Rust compiled into LLVM-bitcode)
Modules
Descriptors for classes and method IDs.
Errors. Do you really need more explanation?
Wrappers for object pointers returned from the JVM.
Parser for java type signatures.
String types for going to/from java strings.
jni-sys
re-exports
Structs
A RAII implementation of scoped guard which detaches the current thread
when dropped. The attached JNIEnv
can be accessed through this guard
via its Deref
implementation.
Thread attachment manager. It allows to execute closures in attached threads with automatic
local references management done with with_local_frame
. It combines the performance benefits
of permanent attaches whilst removing the risk of local references leaks if used consistently.
JavaVM InitArgs.
Builder for JavaVM InitArgs.
FFI-compatible JNIEnv struct. You can safely use this as the JNIEnv argument to exported methods that will be called by java. This is where most of the magic happens. All methods on this object are wrappers around JNI functions, so the documentation on their behavior is still pretty applicable.
The Java VM, providing Invocation API support.
Guard for a lock on a java object. This gets returned from the lock_obj
method.
Native method descriptor.
Enums
Constants
The capacity of local frames, allocated for attached threads by default. Same as the default value Hotspot uses when calling native Java methods.