rust-libp2p/core/src/upgrade/mod.rs

// Copyright 2018 Parity Technologies (UK) Ltd.
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//! Contains everything related to upgrading a connection or a substream to use a protocol.
//!
//! After a connection with a remote has been successfully established or a substream successfully
//! opened, the next step is to *upgrade* this connection or substream to use a protocol.
//!
//! This is where the `UpgradeInfo`, `InboundUpgrade` and `OutboundUpgrade` traits come into play.
//! The `InboundUpgrade` and `OutboundUpgrade` traits are implemented on types that represent a
//! collection of one or more possible protocols for respectively an ingoing or outgoing
//! connection or substream.
//!
//! > **Note**: Multiple versions of the same protocol are treated as different protocols.
//! >           For example, `/foo/1.0.0` and `/foo/1.1.0` are totally unrelated as far as
//! >           upgrading is concerned.
//!
//! # Upgrade process
//!
//! An upgrade is performed in two steps:
//!
//! - A protocol negotiation step. The `UpgradeInfo::protocol_names` method is called to determine
//!   which protocols are supported by the trait implementation. The `multistream-select` protocol
//!   is used in order to agree on which protocol to use amongst the ones supported.
//!
//! - A handshake. After a successful negotiation, the `InboundUpgrade::upgrade_inbound` or
//!   `OutboundUpgrade::upgrade_outbound` method is called. This method will return a `Future` that
//!   performs a handshake. This handshake is considered mandatory, however in practice it is
//!   possible for the trait implementation to return a dummy `Future` that doesn't perform any
//!   action and immediately succeeds.
//!
//! After an upgrade is successful, an object of type `InboundUpgrade::Output` or
//! `OutboundUpgrade::Output` is returned. The actual object depends on the implementation and
//! there is no constraint on the traits that it should implement, however it is expected that it
//! can be used by the user to control the behaviour of the protocol.
//!
//! > **Note**: You can use the `apply_inbound` or `apply_outbound` methods to try upgrade a
//!             connection or substream. However if you use the recommended `Swarm` or
//!             `ProtocolsHandler` APIs, the upgrade is automatically handled for you and you don't
//!             need to use these methods.
//!

mod apply;
mod denied;
mod error;
mod map;
mod or;
mod toggleable;

use bytes::Bytes;
use futures::future::Future;

pub use self::{
    apply::{apply_inbound, apply_outbound, InboundUpgradeApply, OutboundUpgradeApply},
    denied::DeniedUpgrade,
    error::UpgradeError,
    map::{MapInboundUpgrade, MapOutboundUpgrade, MapUpgradeErr},
    or::OrUpgrade,
    toggleable::{toggleable, Toggleable}
};

/// Common trait for upgrades that can be applied on inbound substreams, outbound substreams,
/// or both.
pub trait UpgradeInfo {
    /// Opaque type representing a negotiable protocol.
    type UpgradeId;
    /// Iterator returned by `protocol_names`.
    type NamesIter: Iterator<Item = (Bytes, Self::UpgradeId)>;

    /// Returns the list of protocols that are supported. Used during the negotiation process.
    ///
    /// Each item returned by the iterator is a pair of a protocol name and an opaque identifier.
    fn protocol_names(&self) -> Self::NamesIter;
}

/// Possible upgrade on an inbound connection or substream.
pub trait InboundUpgrade<C>: UpgradeInfo {
    /// Output after the upgrade has been successfully negotiated and the handshake performed.
    type Output;
    /// Possible error during the handshake.
    type Error;
    /// Future that performs the handshake with the remote.
    type Future: Future<Item = Self::Output, Error = Self::Error>;

    /// After we have determined that the remote supports one of the protocols we support, this
    /// method is called to start the handshake.
    ///
    /// The `id` is the identifier of the protocol, as produced by `protocol_names()`.
    fn upgrade_inbound(self, socket: C, id: Self::UpgradeId) -> Self::Future;
}

/// Extension trait for `InboundUpgrade`. Automatically implemented on all types that implement
/// `InboundUpgrade`.
pub trait InboundUpgradeExt<C>: InboundUpgrade<C> {
    /// Returns a new object that wraps around `Self` and applies a closure to the `Output`.
    fn map_inbound<F, T>(self, f: F) -> MapInboundUpgrade<Self, F>
    where
        Self: Sized,
        F: FnOnce(Self::Output) -> T
    {
        MapInboundUpgrade::new(self, f)
    }

    /// Returns a new object that wraps around `Self` and applies a closure to the `Error`.
    fn map_inbound_err<F, T>(self, f: F) -> MapUpgradeErr<Self, F>
    where
        Self: Sized,
        F: FnOnce(Self::Error) -> T
    {
        MapUpgradeErr::new(self, f)
    }

    /// Returns a new object that combines `Self` and another upgrade to support both at the same
    /// time.
    fn or_inbound<U>(self, upgrade: U) -> OrUpgrade<Self, U>
    where
        Self: Sized,
        U: InboundUpgrade<C, Output = Self::Output, Error = Self::Error>
    {
        OrUpgrade::new(self, upgrade)
    }
}

impl<C, U: InboundUpgrade<C>> InboundUpgradeExt<C> for U {}

/// Possible upgrade on an outbound connection or substream.
pub trait OutboundUpgrade<C>: UpgradeInfo {
    /// Output after the upgrade has been successfully negotiated and the handshake performed.
    type Output;
    /// Possible error during the handshake.
    type Error;
    /// Future that performs the handshake with the remote.
    type Future: Future<Item = Self::Output, Error = Self::Error>;

    /// After we have determined that the remote supports one of the protocols we support, this
    /// method is called to start the handshake.
    ///
    /// The `id` is the identifier of the protocol, as produced by `protocol_names()`.
    fn upgrade_outbound(self, socket: C, id: Self::UpgradeId) -> Self::Future;
}

/// Extention trait for `OutboundUpgrade`. Automatically implemented on all types that implement
/// `OutboundUpgrade`.
pub trait OutboundUpgradeExt<C>: OutboundUpgrade<C> {
    /// Returns a new object that wraps around `Self` and applies a closure to the `Output`.
    fn map_outbound<F, T>(self, f: F) -> MapOutboundUpgrade<Self, F>
    where
        Self: Sized,
        F: FnOnce(Self::Output) -> T
    {
        MapOutboundUpgrade::new(self, f)
    }

    /// Returns a new object that wraps around `Self` and applies a closure to the `Error`.
    fn map_outbound_err<F, T>(self, f: F) -> MapUpgradeErr<Self, F>
    where
        Self: Sized,
        F: FnOnce(Self::Error) -> T
    {
        MapUpgradeErr::new(self, f)
    }

    /// Returns a new object that combines `Self` and another upgrade to support both at the same
    /// time.
    fn or_outbound<U>(self, upgrade: U) -> OrUpgrade<Self, U>
    where
        Self: Sized,
        U: OutboundUpgrade<C, Output = Self::Output, Error = Self::Error>
    {
        OrUpgrade::new(self, upgrade)
    }
}

impl<C, U: OutboundUpgrade<C>> OutboundUpgradeExt<C> for U {}