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//! `netlink-proto` is an asynchronous implementation of the Netlink //! protocol. //! //! # Example: listening for audit events //! //! This example shows how to use `netlink-proto` with the `tokio` //! runtime to print audit events. It requires extra external //! dependencies: //! //! - `futures = "^0.3"` //! - `tokio = "^0.2"` //! - `netlink-packet-audit = "^0.1"` //! //! ```rust,no_run //! use futures::stream::StreamExt; //! use netlink_packet_audit::{ //! NLM_F_ACK, NLM_F_REQUEST, NetlinkMessage, NetlinkPayload, //! AuditMessage, StatusMessage, //! }; //! use std::process; //! //! use netlink_proto::{ //! new_connection, //! sys::{SocketAddr, protocols::NETLINK_AUDIT}, //! }; //! //! const AUDIT_STATUS_ENABLED: u32 = 1; //! const AUDIT_STATUS_PID: u32 = 4; //! //! #[tokio::main] //! async fn main() -> Result<(), String> { //! // Create a netlink socket. Here: //! // //! // - `conn` is a `Connection` that has the netlink socket. It's a //! // `Future` that keeps polling the socket and must be spawned an //! // the event loop. //! // //! // - `handle` is a `Handle` to the `Connection`. We use it to send //! // netlink messages and receive responses to these messages. //! // //! // - `messages` is a channel receiver through which we receive //! // messages that we have not solicited, ie that are not //! // response to a request we made. In this example, we'll receive //! // the audit event through that channel. //! let (conn, mut handle, mut messages) = new_connection(NETLINK_AUDIT) //! .map_err(|e| format!("Failed to create a new netlink connection: {}", e))?; //! //! // Spawn the `Connection` so that it starts polling the netlink //! // socket in the background. //! tokio::spawn(conn); //! //! // Use the `ConnectionHandle` to send a request to the kernel //! // asking it to start multicasting audit event messages. //! tokio::spawn(async move { //! // Craft the packet to enable audit events //! let mut status = StatusMessage::new(); //! status.enabled = 1; //! status.pid = process::id(); //! status.mask = AUDIT_STATUS_ENABLED | AUDIT_STATUS_PID; //! let payload = AuditMessage::SetStatus(status); //! let mut nl_msg = NetlinkMessage::from(payload); //! nl_msg.header.flags = NLM_F_REQUEST | NLM_F_ACK; //! //! // We'll send unicast messages to the kernel. //! let kernel_unicast: SocketAddr = SocketAddr::new(0, 0); //! let mut response = match handle.request(nl_msg, kernel_unicast) { //! Ok(response) => response, //! Err(e) => { //! eprintln!("{}", e); //! return; //! } //! }; //! //! while let Some(message) = response.next().await { //! if let NetlinkPayload::Error(err_message) = message.payload { //! eprintln!("Received an error message: {:?}", err_message); //! return; //! } //! } //! }); //! //! // Finally, start receiving event through the `messages` channel. //! println!("Starting to print audit events... press ^C to interrupt"); //! while let Some((message, _addr)) = messages.next().await { //! if let NetlinkPayload::Error(err_message) = message.payload { //! eprintln!("received an error message: {:?}", err_message); //! } else { //! println!("{:?}", message); //! } //! } //! //! Ok(()) //! } //! ``` //! //! # Example: dumping all the machine's links //! //! This example shows how to use `netlink-proto` with the ROUTE //! protocol. //! //! Here we do not use `netlink_proto::new_connection()`, and instead //! create the socket manually and use call `send()` and `receive()` //! directly. In the previous example, the `NetlinkFramed` was wrapped //! in a `Connection` which was polled automatically by the runtime. //! //! ```rust,no_run //! use futures::StreamExt; //! //! use netlink_packet_route::{ //! NLM_F_DUMP, NLM_F_REQUEST, NetlinkMessage, NetlinkHeader, LinkMessage, RtnlMessage //! }; //! //! use netlink_proto::{ //! new_connection, //! sys::{SocketAddr, protocols::NETLINK_ROUTE}, //! }; //! //! #[tokio::main] //! async fn main() -> Result<(), String> { //! // Create the netlink socket. Here, we won't use the channel that //! // receives unsolicited messages. //! let (conn, mut handle, _) = new_connection(NETLINK_ROUTE) //! .map_err(|e| format!("Failed to create a new netlink connection: {}", e))?; //! //! // Spawn the `Connection` in the background //! tokio::spawn(conn); //! //! // Create the netlink message that requests the links to be dumped //! let msg = NetlinkMessage { //! header: NetlinkHeader { //! sequence_number: 1, //! flags: NLM_F_DUMP | NLM_F_REQUEST, //! ..Default::default() //! }, //! payload: RtnlMessage::GetLink(LinkMessage::default()).into(), //! }; //! //! // Send the request //! let mut response = handle //! .request(msg, SocketAddr::new(0, 0)) //! .map_err(|e| format!("Failed to send request: {}", e))?; //! //! // Print all the messages received in response //! loop { //! if let Some(packet) = response.next().await { //! println!("<<< {:?}", packet); //! } else { //! break; //! } //! } //! //! Ok(()) //! } //! ``` #[macro_use] extern crate futures; #[macro_use] extern crate log; mod codecs; pub use crate::codecs::*; mod framed; pub use crate::framed::*; mod protocol; pub(crate) use self::protocol::{Protocol, Response}; pub(crate) type Request<T> = self::protocol::Request<T, UnboundedSender<crate::packet::NetlinkMessage<T>>>; mod connection; pub use crate::connection::*; mod errors; pub use crate::errors::*; mod handle; pub use crate::handle::*; use futures::channel::mpsc::{unbounded, UnboundedReceiver, UnboundedSender}; use std::{fmt::Debug, io}; pub use netlink_packet_core as packet; pub mod sys { pub use netlink_sys::{protocols, SocketAddr, TokioSocket as Socket}; } /// Create a new Netlink connection for the given Netlink protocol, and returns a handle to that /// connection as well as a stream of unsolicited messages received by that connection (unsolicited /// here means messages that are not a response to a request made by the `Connection`). /// `Connection<T>` wraps a Netlink socket and implements the Netlink protocol. /// /// `protocol` must be one of the [`crate::sys::protocols`][protos] constants. /// /// `T` is the type of netlink messages used for this protocol. For instance, if you're using the /// `NETLINK_AUDIT` protocol with the `netlink-packet-audit` crate, `T` will be /// `netlink_packet_audit::AuditMessage`. More generally, `T` is anything that can be serialized /// and deserialized into a Netlink message. See the `netlink_packet_core` documentation for /// details about the `NetlinkSerializable` and `NetlinkDeserializable` traits. /// /// Most of the time, users will want to spawn the `Connection` on an async runtime, and use the /// handle to send messages. /// /// [protos]: crate::sys::protocols #[allow(clippy::type_complexity)] pub fn new_connection<T>( protocol: isize, ) -> io::Result<( Connection<T>, ConnectionHandle<T>, UnboundedReceiver<(packet::NetlinkMessage<T>, sys::SocketAddr)>, )> where T: Debug + PartialEq + Eq + Clone + packet::NetlinkSerializable<T> + packet::NetlinkDeserializable<T> + Unpin, { let (requests_tx, requests_rx) = unbounded::<Request<T>>(); let (messages_tx, messages_rx) = unbounded::<(packet::NetlinkMessage<T>, sys::SocketAddr)>(); Ok(( Connection::new(requests_rx, messages_tx, protocol)?, ConnectionHandle::new(requests_tx), messages_rx, )) }