// Copyright 2017-2018 Parity Technologies (UK) Ltd. // // Permission is hereby granted, free of charge, to any person obtaining a // copy of this software and associated documentation files (the "Software"), // to deal in the Software without restriction, including without limitation // the rights to use, copy, modify, merge, publish, distribute, sublicense, // and/or sell copies of the Software, and to permit persons to whom the // Software is furnished to do so, subject to the following conditions: // // The above copyright notice and this permission notice shall be included in // all copies or substantial portions of the Software. // // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS // OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE // AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING // FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER // DEALINGS IN THE SOFTWARE. //! Transports, upgrades, multiplexing and node handling of *libp2p*. //! //! The main concepts of libp2p-core are: //! //! - A [`PeerId`] is a unique global identifier for a node on the network. //! Each node must have a different `PeerId`. Normally, a `PeerId` is the //! hash of the public key used to negotiate encryption on the //! communication channel, thereby guaranteeing that they cannot be spoofed. //! - The [`Transport`] trait defines how to reach a remote node or listen for //! incoming remote connections. See the `transport` module. //! - The [`StreamMuxer`] trait is implemented on structs that hold a connection //! to a remote and can subdivide this connection into multiple substreams. //! See the `muxing` module. //! - The [`UpgradeInfo`], [`InboundUpgrade`] and [`OutboundUpgrade`] traits //! define how to upgrade each individual substream to use a protocol. //! See the `upgrade` module. mod keys_proto { include!(concat!(env!("OUT_DIR"), "/keys_proto.rs")); } /// Multi-address re-export. pub use multiaddr; pub type Negotiated = futures::compat::Compat01As03>>; use std::{future::Future, pin::Pin}; mod peer_id; mod translation; pub mod either; pub mod identity; pub mod muxing; pub mod nodes; pub mod transport; pub mod upgrade; pub use multiaddr::Multiaddr; pub use muxing::StreamMuxer; pub use peer_id::PeerId; pub use identity::PublicKey; pub use transport::Transport; pub use translation::address_translation; pub use upgrade::{InboundUpgrade, OutboundUpgrade, UpgradeInfo, UpgradeError, ProtocolName}; pub use nodes::ConnectionInfo; #[derive(Debug, Copy, Clone, PartialEq, Eq, Hash)] pub enum Endpoint { /// The socket comes from a dialer. Dialer, /// The socket comes from a listener. Listener, } impl std::ops::Not for Endpoint { type Output = Endpoint; fn not(self) -> Self::Output { match self { Endpoint::Dialer => Endpoint::Listener, Endpoint::Listener => Endpoint::Dialer } } } impl Endpoint { /// Is this endpoint a dialer? pub fn is_dialer(self) -> bool { if let Endpoint::Dialer = self { true } else { false } } /// Is this endpoint a listener? pub fn is_listener(self) -> bool { if let Endpoint::Listener = self { true } else { false } } } /// How we connected to a node. #[derive(Debug, Clone)] pub enum ConnectedPoint { /// We dialed the node. Dialer { /// Multiaddress that was successfully dialed. address: Multiaddr, }, /// We received the node. Listener { /// Local connection address. local_addr: Multiaddr, /// Stack of protocols used to send back data to the remote. send_back_addr: Multiaddr, } } impl From<&'_ ConnectedPoint> for Endpoint { fn from(endpoint: &'_ ConnectedPoint) -> Endpoint { endpoint.to_endpoint() } } impl From for Endpoint { fn from(endpoint: ConnectedPoint) -> Endpoint { endpoint.to_endpoint() } } impl ConnectedPoint { /// Turns the `ConnectedPoint` into the corresponding `Endpoint`. pub fn to_endpoint(&self) -> Endpoint { match self { ConnectedPoint::Dialer { .. } => Endpoint::Dialer, ConnectedPoint::Listener { .. } => Endpoint::Listener } } /// Returns true if we are `Dialer`. pub fn is_dialer(&self) -> bool { match self { ConnectedPoint::Dialer { .. } => true, ConnectedPoint::Listener { .. } => false } } /// Returns true if we are `Listener`. pub fn is_listener(&self) -> bool { match self { ConnectedPoint::Dialer { .. } => false, ConnectedPoint::Listener { .. } => true } } } /// Implemented on objects that can run a `Future` in the background. /// /// > **Note**: While it may be tempting to implement this trait on types such as /// > [`futures::stream::FuturesUnordered`], please note that passing an `Executor` is /// > optional, and that `FuturesUnordered` (or a similar struct) will automatically /// > be used as fallback by libp2p. The `Executor` trait should therefore only be /// > about running `Future`s in the background. pub trait Executor { /// Run the given future in the background until it ends. fn exec(&self, future: Pin + Send>>); } impl<'a, T: ?Sized + Executor> Executor for &'a T { fn exec(&self, f: Pin + Send>>) { T::exec(&**self, f) } } impl<'a, T: ?Sized + Executor> Executor for &'a mut T { fn exec(&self, f: Pin + Send>>) { T::exec(&**self, f) } } impl Executor for Box { fn exec(&self, f: Pin + Send>>) { T::exec(&**self, f) } }