This library offers a futures based API over the lapin-async library. It leverages the tokio-io and futures library, so you can use it with tokio-core, futures-cpupool or any other reactor.
The library is designed so it does not own the socket, so you can use any TCP, TLS or unix socket based stream.
Calls to the underlying stream are guarded by a mutex, so you could use one connection from multiple threads.
There's an example available using tokio-core.
```rust
extern crate amqprotocol; extern crate futures; extern crate tokiocore; extern crate lapin_futures as lapin;
use amqprotocol::types::FieldTable; use futures::Stream; use futures::future::Future; use tokiocore::reactor::Core; use tokio_core::net::TcpStream; use lapin::client::ConnectionOptions; use lapin::channel::{BasicPublishOptions,QueueDeclareOptions, BasicProperties};
fn main() {
// create the reactor let mut core = Core::new().unwrap(); let handle = core.handle(); let addr = "127.0.0.1:5672".parse().unwrap();
core.run(
TcpStream::connect(&addr, &handle).and_then(|stream| {
// connect() returns a future of an AMQP Client
// that resolves once the handshake is done
lapin::client::Client::connect(stream, &ConnectionOptions::default())
}).and_then(|client| {
// create_channel returns a future that is resolved
// once the channel is successfully created
client.create_channel()
}).and_then(|channel| {
let id = channel.id;
info!("created channel with id: {}", id);
// we using a "move" closure to reuse the channel
// once the queue is declared. We could also clone
// the channel
channel.queue_declare("hello", &QueueDeclareOptions::default(), FieldTable::new()).and_then(move |_| {
info!("channel {} declared queue {}", id, "hello");
channel.basic_publish("hello", b"hello from tokio", &BasicPublishOptions::default(),
BasicProperties::default())
})
})
).unwrap(); } ```
```rust
extern crate amqprotocol; extern crate futures; extern crate tokiocore; extern crate lapin_futures as lapin;
use amqprotocol::types::FieldTable; use futures::Stream; use futures::future::Future; use tokiocore::reactor::Core; use tokio_core::net::TcpStream; use lapin::client::ConnectionOptions; use lapin::channel::{BasicConsumeOptions,BasicPublishOptions,QueueDeclareOptions}; fn main() {
// create the reactor let mut core = Core::new().unwrap(); let handle = core.handle(); let addr = "127.0.0.1:5672".parse().unwrap();
core.run(
TcpStream::connect(&addr, &handle).and_then(|stream| {
// connect() returns a future of an AMQP Client
// that resolves once the handshake is done
lapin::client::Client::connect(stream, &ConnectionOptions::default())
}).and_then(|client| {
// create_channel returns a future that is resolved
// once the channel is successfully created
client.create_channel()
}).and_then(|channel| {
let id = channel.id;
info!("created channel with id: {}", id);
let ch = channel.clone();
channel.queue_declare("hello", &QueueDeclareOptions::default(), FieldTable::new()).and_then(move |_| {
info!("channel {} declared queue {}", id, "hello");
// basic_consume returns a future of a message
// stream. Any time a message arrives for this consumer,
// the for_each method would be called
channel.basic_consume("hello", "my_consumer", &BasicConsumeOptions::default())
}).and_then(|stream| {
info!("got consumer stream");
stream.for_each(move|message| {
debug!("got message: {:?}", message);
info!("decoded message: {:?}", std::str::from_utf8(&message.data).unwrap());
ch.basic_ack(message.delivery_tag);
Ok(())
})
})
})
).unwrap(); } ```