127 lines
6.2 KiB
Plaintext
127 lines
6.2 KiB
Plaintext
= Netty Incubator Buffer API
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This repository is incubating a new buffer API proposed for Netty 5.
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See the xref:RATIONALE.adoc[RATIONALE] document for more background.
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== Building and Testing
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Short version: just run `make`.
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The project currently relies on snapshot versions of the https://github.com/openjdk/panama-foreign[Panama Foreign] fork of OpenJDK.
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This allows us to test out the most recent version of the `jdk.incubator.foreign` APIs, but also make building, and local development more involved.
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To simplify things, we have a Docker based build, controlled via a Makefile with the following commands:
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* `image` – build the docker image.This includes building a snapshot of OpenJDK, and download all relevant Maven dependencies.
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* `test` – run all tests in a docker container.This implies `image`.The container is automatically deleted afterwards.
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* `dbg` – drop into a shell in the build container, without running the build itself.The debugging container is not deleted afterwards.
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* `clean` – remove the leftover containers created by `dbg`, `test`, and `build`.
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* `build` – build binaries and run all tests in a container, and copy the `target` directory out of the container afterwards.This is the default build target.
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== Example: Echo Client and Server
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Making use of this new buffer API on the client side is quite easy.
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Even though Netty 5 does not have native support for these buffers, it is able to convert them to the old `ByteBuf` API as needed.
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This means we are able to send incubator buffers through a Netty pipeline, and have it work as if we were sending `ByteBuf` instances.
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[source,java]
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----
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public final class Client {
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public static void main(String[] args) throws Exception {
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EventLoopGroup group = new MultithreadEventLoopGroup(NioHandler.newFactory());
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try (BufferAllocator allocator = BufferAllocator.pooledDirect()) { // <1>
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Bootstrap b = new Bootstrap();
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b.group(group)
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.channel(NioSocketChannel.class)
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.option(ChannelOption.TCP_NODELAY, true)
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.handler(new ChannelInitializer<SocketChannel>() {
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@Override
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public void initChannel(SocketChannel ch) throws Exception {
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ch.pipeline().addLast(new ChannelHandlerAdapter() {
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@Override
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public void channelActive(ChannelHandlerContext ctx) {
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Buffer message = allocator.allocate(256); // <2>
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for (int i = 0; i < message.capacity(); i++) {
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message.writeByte((byte) i);
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}
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ctx.writeAndFlush(message); // <3>
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}
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});
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}
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});
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// Start the client.
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ChannelFuture f = b.connect("127.0.0.1", 8007).sync();
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// Wait until the connection is closed.
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f.channel().closeFuture().sync();
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} finally {
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// Shut down the event loop to terminate all threads.
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group.shutdownGracefully();
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}
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}
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}
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----
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<1> A life-cycled allocator is created to wrap the scope of our application.
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<2> Buffers are allocated with one of the `allocate` methods.
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<3> The buffer can then be sent down the pipeline, and will be written to the socket just like a `ByteBuf` would.
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[NOTE]
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--
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The same is not the case for `BufferHolder`.
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It is not treated the same as a `ByteBufHolder`.
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--
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On the server size, things are more complicated because Netty itself will be allocating the buffers, and the `ByteBufAllocator` API is only capable of returning `ByteBuf` instances.
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The `ByteBufAllocatorAdaptor` will allocate `ByteBuf` instances that are backed by the new buffers.
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The buffers can then we extracted from the `ByteBuf` instances with the `ByteBufAdaptor.extract` method.
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We can tell a Netty server how to allocate buffers by setting the `ALLOCATOR` child-channel option:
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[source,java]
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----
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ByteBufAllocatorAdaptor allocator = new ByteBufAllocatorAdaptor(); // <1>
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ServerBootstrap server = new ServerBootstrap();
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server.group(bossGroup, workerGroup)
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.channel(NioServerSocketChannel.class)
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.childOption(ChannelOption.ALLOCATOR, allocator) // <2>
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.handler(new EchoServerHandler());
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----
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<1> The `ByteBufAllocatorAdaptor` implements `ByteBufAllocator`, and directly allocates `ByteBuf` instances that are backed by buffers that use the new API.
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<2> To make Netty use a given allocator when allocating buffers for receiving data, we set the allocator as a child option.
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With the above, we just changed how the buffers are allocated, but we haven't changed the API we use for interacting with the buffers.
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The buffers are still allocated at `ByteBuf` instances, and flow through the pipeline as such.
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If we want to use the new buffer API in our server handlers, we have to extract the buffers from the `ByteBuf` instances that are passed down:
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[source,java]
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----
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import io.netty.buffer.ByteBuf;
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import io.netty.buffer.api.Buffer;
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import io.netty.buffer.api.adaptor.ByteBufAdaptor;
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@Sharable
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public class EchoServerHandler implements ChannelHandler {
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@Override
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public void channelRead(ChannelHandlerContext ctx, Object msg) { // <1>
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if (msg instanceof ByteBuf) { // <2>
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// For this example, we only echo back buffers that are using the new buffer API.
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Buffer buf = ByteBufAdaptor.extract((ByteBuf) msg); // <3>
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ctx.write(buf); // <4>
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}
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}
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@Override
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public void channelReadComplete(ChannelHandlerContext ctx) {
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ctx.flush();
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}
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}
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----
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<1> Netty pipelines are defined as transferring `Object` instances as messages.
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<2> When we receive data directly from a socket, these messages will be `ByteBuf` instances with the received data.
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<3> Since we set the allocator to create `ByteBuf` instances that are backed by buffers with the new API, we will be able to extract the backing `Buffer` instances.
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<4> We can then operate on the extracted `Buffer` instances directly.
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The `Buffer` and `ByteBuf` instances mirror each other exactly.
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In this case, we just write them back to the client that sent the data to us.
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The files in `src/test/java/io/netty/buffer/api/examples/echo` for the full source code to this example. |