openethereum/ipc/nano/src/lib.rs

// Copyright 2015, 2016 Ethcore (UK) Ltd.
// This file is part of Parity.

// Parity is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.

// Parity is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
// GNU General Public License for more details.

// You should have received a copy of the GNU General Public License
// along with Parity.  If not, see <http://www.gnu.org/licenses/>.

//! IPC over nanomsg transport

extern crate ethcore_ipc as ipc;
extern crate nanomsg;
#[macro_use] extern crate log;

pub use ipc::*;

use std::sync::*;
use nanomsg::{Socket, Protocol, Error, Endpoint, PollRequest, PollFd, PollInOut};

const POLL_TIMEOUT: isize = 100;

pub struct Worker<S> where S: IpcInterface<S> {
	service: Arc<S>,
	sockets: Vec<(Socket, Endpoint)>,
	polls: Vec<PollFd>,
	buf: Vec<u8>,
}

#[derive(Debug)]
pub enum SocketError {
	DuplexLink
}

impl<S> Worker<S> where S: IpcInterface<S> {
	pub fn new(service: Arc<S>) -> Worker<S> {
		Worker::<S> {
			service: service.clone(),
			sockets: Vec::new(),
			polls: Vec::new(),
			buf: Vec::new(),
		}
	}

	pub fn poll(&mut self) {
		let mut request = PollRequest::new(&mut self.polls[..]);
 		let _result_guard = Socket::poll(&mut request, POLL_TIMEOUT);

		for (fd_index, fd) in request.get_fds().iter().enumerate() {
			if fd.can_read() {
				let (ref mut socket, _) = self.sockets[fd_index];
				unsafe { self.buf.set_len(0); }
				match socket.nb_read_to_end(&mut self.buf) {
					Ok(method_sign_len) => {
						if method_sign_len >= 2 {
							// method_num
							let method_num = self.buf[1] as u16 * 256 + self.buf[0] as u16;
							// payload
							let payload = &self.buf[2..];

							// dispatching for ipc interface
							let result = self.service.dispatch_buf(method_num, payload);

							if let Err(e) = socket.nb_write(&result) {
								warn!(target: "ipc", "Failed to write response: {:?}", e);
							}
						}
						else {
							warn!(target: "ipc", "Failed to read method signature from socket: unexpected message length({})", method_sign_len);
						}
					},
					Err(Error::TryAgain) => {
					},
					Err(x) => {
						warn!(target: "ipc", "Error polling connections {:?}", x);
						panic!();
					}
				}
			}
		}
	}

	fn rebuild_poll_request(&mut self) {
		self.polls = self.sockets.iter()
			.map(|&(ref socket, _)| socket.new_pollfd(PollInOut::In))
			.collect::<Vec<PollFd>>();
	}

	pub fn add_duplex(&mut self, addr: &str) -> Result<(), SocketError>  {
		let mut socket = try!(Socket::new(Protocol::Pair).map_err(|e| {
			warn!(target: "ipc", "Failed to create ipc socket: {:?}", e);
			SocketError::DuplexLink
		}));

		let endpoint = try!(socket.bind(addr).map_err(|e| {
			warn!(target: "ipc", "Failed to bind socket to address '{}': {:?}", addr, e);
			SocketError::DuplexLink
		}));

		self.sockets.push((socket, endpoint));

		self.rebuild_poll_request();

		Ok(())
	}
}

#[cfg(test)]
mod tests {

	use super::Worker;
	use ipc::*;
	use std::io::{Read, Write};
	use std::sync::{Arc, RwLock};
	use nanomsg::{Socket, Protocol, Endpoint};

	struct TestInvoke {
		method_num: u16,
		params: Vec<u8>,
	}

	struct DummyService {
		methods_stack: RwLock<Vec<TestInvoke>>,
	}

	impl DummyService {
		fn new() -> DummyService {
			DummyService { methods_stack: RwLock::new(Vec::new()) }
		}
	}

	impl IpcInterface<DummyService> for DummyService {
		fn dispatch<R>(&self, _r: &mut R) -> Vec<u8> where R: Read {
			vec![]
		}
		fn dispatch_buf(&self, method_num: u16, buf: &[u8]) -> Vec<u8> {
			self.methods_stack.write().unwrap().push(
				TestInvoke {
					method_num: method_num,
					params: buf.to_vec(),
				});
			vec![]
		}
	}

	fn dummy_write(addr: &str, buf: &[u8]) -> (Socket, Endpoint) {
		let mut socket = Socket::new(Protocol::Pair).unwrap();
		let endpoint = socket.connect(addr).unwrap();
		//thread::sleep_ms(10);
		socket.write(buf).unwrap();
		(socket, endpoint)
	}

	#[test]
	fn can_create_worker() {
		let worker = Worker::<DummyService>::new(Arc::new(DummyService::new()));
		assert_eq!(0, worker.sockets.len());
	}

	#[test]
	fn can_add_duplex_socket_to_worker() {
		let mut worker = Worker::<DummyService>::new(Arc::new(DummyService::new()));
		worker.add_duplex("ipc:///tmp/parity-test10.ipc").unwrap();
		assert_eq!(1, worker.sockets.len());
	}

	#[test]
	fn worker_can_poll_empty() {
		let service = Arc::new(DummyService::new());
		let mut worker = Worker::<DummyService>::new(service.clone());
		worker.add_duplex("ipc:///tmp/parity-test20.ipc").unwrap();
		worker.poll();
		assert_eq!(0, service.methods_stack.read().unwrap().len());
	}

	#[test]
	fn worker_can_poll() {
		let url = "ipc:///tmp/parity-test30.ipc";

		let mut worker = Worker::<DummyService>::new(Arc::new(DummyService::new()));
		worker.add_duplex(url).unwrap();

		let (_socket, _endpoint) = dummy_write(url, &vec![0, 0, 7, 7, 6, 6]);
		worker.poll();

		assert_eq!(1, worker.service.methods_stack.read().unwrap().len());
		assert_eq!(0, worker.service.methods_stack.read().unwrap()[0].method_num);
		assert_eq!([7, 7, 6, 6], worker.service.methods_stack.read().unwrap()[0].params[..]);
	}

	#[test]
	fn worker_can_poll_long() {
		let url = "ipc:///tmp/parity-test40.ipc";

		let mut worker = Worker::<DummyService>::new(Arc::new(DummyService::new()));
		worker.add_duplex(url).unwrap();

		let message = [0u8; 1024*1024];

		let (_socket, _endpoint) = dummy_write(url, &message);
		worker.poll();

		assert_eq!(1, worker.service.methods_stack.read().unwrap().len());
		assert_eq!(0, worker.service.methods_stack.read().unwrap()[0].method_num);
		assert_eq!(vec![0u8; 1024*1024-2], worker.service.methods_stack.read().unwrap()[0].params);
	}
}