// Copyright 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. //! Provides the `KadRequestMsg` and `KadResponseMsg` enums of all the possible messages //! transmitted with the Kademlia protocol, and the `KademliaProtocolConfig` connection upgrade. //! //! The upgrade's output a `Sink + Stream` of messages. //! //! The `Stream` component is used to poll the underlying transport, and the `Sink` component is //! used to send messages. use bytes::BytesMut; use futures::{future, sink, stream, Sink, Stream}; use libp2p_core::{InboundUpgrade, Multiaddr, OutboundUpgrade, PeerId, UpgradeInfo}; use multihash::Multihash; use protobuf::{self, Message}; use protobuf_structs; use std::io::{Error as IoError, ErrorKind as IoErrorKind}; use std::iter; use tokio_codec::Framed; use tokio_io::{AsyncRead, AsyncWrite}; use unsigned_varint::codec; /// Status of our connection to a node reported by the Kademlia protocol. #[derive(Copy, Clone, PartialEq, Eq, Debug, Hash)] pub enum KadConnectionType { /// Sender hasn't tried to connect to peer. NotConnected = 0, /// Sender is currently connected to peer. Connected = 1, /// Sender was recently connected to peer. CanConnect = 2, /// Sender tried to connect to peer but failed. CannotConnect = 3, } impl From for KadConnectionType { #[inline] fn from(raw: protobuf_structs::dht::Message_ConnectionType) -> KadConnectionType { use protobuf_structs::dht::Message_ConnectionType::*; match raw { NOT_CONNECTED => KadConnectionType::NotConnected, CONNECTED => KadConnectionType::Connected, CAN_CONNECT => KadConnectionType::CanConnect, CANNOT_CONNECT => KadConnectionType::CannotConnect, } } } impl Into for KadConnectionType { #[inline] fn into(self) -> protobuf_structs::dht::Message_ConnectionType { use protobuf_structs::dht::Message_ConnectionType::*; match self { KadConnectionType::NotConnected => NOT_CONNECTED, KadConnectionType::Connected => CONNECTED, KadConnectionType::CanConnect => CAN_CONNECT, KadConnectionType::CannotConnect => CANNOT_CONNECT, } } } /// Information about a peer, as known by the sender. #[derive(Debug, Clone, PartialEq, Eq)] pub struct KadPeer { /// Identifier of the peer. pub node_id: PeerId, /// The multiaddresses that the sender think can be used in order to reach the peer. pub multiaddrs: Vec, /// How the sender is connected to that remote. pub connection_ty: KadConnectionType, } impl KadPeer { // Builds a `KadPeer` from its raw protobuf equivalent. // TODO: use TryFrom once stable fn from_peer(peer: &mut protobuf_structs::dht::Message_Peer) -> Result { // TODO: this is in fact a CID; not sure if this should be handled in `from_bytes` or // as a special case here let node_id = PeerId::from_bytes(peer.get_id().to_vec()) .map_err(|_| IoError::new(IoErrorKind::InvalidData, "invalid peer id"))?; let mut addrs = Vec::with_capacity(peer.get_addrs().len()); for addr in peer.take_addrs().into_iter() { let as_ma = Multiaddr::from_bytes(addr) .map_err(|err| IoError::new(IoErrorKind::InvalidData, err))?; addrs.push(as_ma); } debug_assert_eq!(addrs.len(), addrs.capacity()); let connection_ty = peer.get_connection().into(); Ok(KadPeer { node_id: node_id, multiaddrs: addrs, connection_ty: connection_ty, }) } } impl Into for KadPeer { fn into(self) -> protobuf_structs::dht::Message_Peer { let mut out = protobuf_structs::dht::Message_Peer::new(); out.set_id(self.node_id.into_bytes()); for addr in self.multiaddrs { out.mut_addrs().push(addr.into_bytes()); } out.set_connection(self.connection_ty.into()); out } } /// Configuration for a Kademlia connection upgrade. When applied to a connection, turns this /// connection into a `Stream + Sink` whose items are of type `KadRequestMsg` and `KadResponseMsg`. // TODO: if, as suspected, we can confirm with Protocol Labs that each open Kademlia substream does // only one request, then we can change the output of the `InboundUpgrade` and // `OutboundUpgrade` to be just a single message #[derive(Debug, Default, Copy, Clone)] pub struct KademliaProtocolConfig; impl UpgradeInfo for KademliaProtocolConfig { type Info = &'static [u8]; type InfoIter = iter::Once; #[inline] fn protocol_info(&self) -> Self::InfoIter { iter::once(b"/ipfs/kad/1.0.0") } } impl InboundUpgrade for KademliaProtocolConfig where C: AsyncRead + AsyncWrite, { type Output = KadInStreamSink; type Future = future::FutureResult; type Error = IoError; #[inline] fn upgrade_inbound(self, incoming: C, _: Self::Info) -> Self::Future { future::ok( Framed::new(incoming, codec::UviBytes::default()) .from_err::() .with::<_, fn(_) -> _, _>(|response| -> Result<_, IoError> { let proto_struct = resp_msg_to_proto(response); proto_struct.write_to_bytes() .map_err(|err| IoError::new(IoErrorKind::InvalidData, err.to_string())) }) .and_then:: _, _>(|bytes: BytesMut| { let request = protobuf::parse_from_bytes(&bytes)?; proto_to_req_msg(request) }), ) } } impl OutboundUpgrade for KademliaProtocolConfig where C: AsyncRead + AsyncWrite, { type Output = KadOutStreamSink; type Future = future::FutureResult; type Error = IoError; #[inline] fn upgrade_outbound(self, incoming: C, _: Self::Info) -> Self::Future { future::ok( Framed::new(incoming, codec::UviBytes::default()) .from_err::() .with::<_, fn(_) -> _, _>(|request| -> Result<_, IoError> { let proto_struct = req_msg_to_proto(request); match proto_struct.write_to_bytes() { Ok(msg) => Ok(msg), Err(err) => Err(IoError::new(IoErrorKind::Other, err.to_string())), } }) .and_then:: _, _>(|bytes: BytesMut| { let response = protobuf::parse_from_bytes(&bytes)?; proto_to_resp_msg(response) }), ) } } /// Sink of responses and stream of requests. pub type KadInStreamSink = stream::AndThen< sink::With< stream::FromErr>>, IoError>, KadResponseMsg, fn(KadResponseMsg) -> Result, IoError>, Result, IoError>, >, fn(BytesMut) -> Result, Result, >; /// Sink of requests and stream of responses. pub type KadOutStreamSink = stream::AndThen< sink::With< stream::FromErr>>, IoError>, KadRequestMsg, fn(KadRequestMsg) -> Result, IoError>, Result, IoError>, >, fn(BytesMut) -> Result, Result, >; /// Request that we can send to a peer or that we received from a peer. #[derive(Debug, Clone, PartialEq, Eq)] pub enum KadRequestMsg { /// Ping request. Ping, /// Request for the list of nodes whose IDs are the closest to `key`. The number of nodes /// returned is not specified, but should be around 20. FindNode { /// Identifier of the node. key: PeerId, }, /// Same as `FindNode`, but should also return the entries of the local providers list for /// this key. GetProviders { /// Identifier being searched. key: Multihash, }, /// Indicates that this list of providers is known for this key. AddProvider { /// Key for which we should add providers. key: Multihash, /// Known provider for this key. provider_peer: KadPeer, }, } /// Response that we can send to a peer or that we received from a peer. #[derive(Debug, Clone, PartialEq, Eq)] pub enum KadResponseMsg { /// Ping response. Pong, /// Response to a `FindNode`. FindNode { /// Results of the request. closer_peers: Vec, }, /// Response to a `GetProviders`. GetProviders { /// Nodes closest to the key. closer_peers: Vec, /// Known providers for this key. provider_peers: Vec, }, } // Turns a type-safe Kadmelia message into the corresponding raw protobuf message. fn req_msg_to_proto(kad_msg: KadRequestMsg) -> protobuf_structs::dht::Message { match kad_msg { KadRequestMsg::Ping => { let mut msg = protobuf_structs::dht::Message::new(); msg.set_field_type(protobuf_structs::dht::Message_MessageType::PING); msg } KadRequestMsg::FindNode { key } => { let mut msg = protobuf_structs::dht::Message::new(); msg.set_field_type(protobuf_structs::dht::Message_MessageType::FIND_NODE); msg.set_key(key.into_bytes()); msg.set_clusterLevelRaw(10); msg } KadRequestMsg::GetProviders { key } => { let mut msg = protobuf_structs::dht::Message::new(); msg.set_field_type(protobuf_structs::dht::Message_MessageType::GET_PROVIDERS); msg.set_key(key.into_bytes()); msg.set_clusterLevelRaw(10); msg } KadRequestMsg::AddProvider { key, provider_peer } => { let mut msg = protobuf_structs::dht::Message::new(); msg.set_field_type(protobuf_structs::dht::Message_MessageType::ADD_PROVIDER); msg.set_clusterLevelRaw(10); msg.set_key(key.into_bytes()); msg.mut_providerPeers().push(provider_peer.into()); msg } } } // Turns a type-safe Kadmelia message into the corresponding raw protobuf message. fn resp_msg_to_proto(kad_msg: KadResponseMsg) -> protobuf_structs::dht::Message { match kad_msg { KadResponseMsg::Pong => { let mut msg = protobuf_structs::dht::Message::new(); msg.set_field_type(protobuf_structs::dht::Message_MessageType::PING); msg } KadResponseMsg::FindNode { closer_peers } => { let mut msg = protobuf_structs::dht::Message::new(); msg.set_field_type(protobuf_structs::dht::Message_MessageType::FIND_NODE); msg.set_clusterLevelRaw(9); for peer in closer_peers { msg.mut_closerPeers().push(peer.into()); } msg } KadResponseMsg::GetProviders { closer_peers, provider_peers, } => { let mut msg = protobuf_structs::dht::Message::new(); msg.set_field_type(protobuf_structs::dht::Message_MessageType::GET_PROVIDERS); msg.set_clusterLevelRaw(9); for peer in closer_peers { msg.mut_closerPeers().push(peer.into()); } for peer in provider_peers { msg.mut_providerPeers().push(peer.into()); } msg } } } /// Turns a raw Kademlia message into a type-safe message. fn proto_to_req_msg(mut message: protobuf_structs::dht::Message) -> Result { match message.get_field_type() { protobuf_structs::dht::Message_MessageType::PING => Ok(KadRequestMsg::Ping), protobuf_structs::dht::Message_MessageType::PUT_VALUE => { Err(IoError::new( IoErrorKind::InvalidData, "received a PUT_VALUE message, but this is not supported by rust-libp2p yet", )) } protobuf_structs::dht::Message_MessageType::GET_VALUE => { Err(IoError::new( IoErrorKind::InvalidData, "received a GET_VALUE message, but this is not supported by rust-libp2p yet", )) } protobuf_structs::dht::Message_MessageType::FIND_NODE => { let key = PeerId::from_bytes(message.take_key()).map_err(|_| { IoError::new(IoErrorKind::InvalidData, "invalid peer id in FIND_NODE") })?; Ok(KadRequestMsg::FindNode { key }) } protobuf_structs::dht::Message_MessageType::GET_PROVIDERS => { let key = Multihash::from_bytes(message.take_key()) .map_err(|err| IoError::new(IoErrorKind::InvalidData, err))?; Ok(KadRequestMsg::GetProviders { key }) } protobuf_structs::dht::Message_MessageType::ADD_PROVIDER => { // TODO: for now we don't parse the peer properly, so it is possible that we get // parsing errors for peers even when they are valid; we ignore these // errors for now, but ultimately we should just error altogether let provider_peer = message .mut_providerPeers() .iter_mut() .filter_map(|peer| KadPeer::from_peer(peer).ok()) .next(); if let Some(provider_peer) = provider_peer { let key = Multihash::from_bytes(message.take_key()) .map_err(|err| IoError::new(IoErrorKind::InvalidData, err))?; Ok(KadRequestMsg::AddProvider { key, provider_peer }) } else { Err(IoError::new( IoErrorKind::InvalidData, "received an ADD_PROVIDER message with no valid peer", )) } } } } /// Turns a raw Kademlia message into a type-safe message. fn proto_to_resp_msg( mut message: protobuf_structs::dht::Message, ) -> Result { match message.get_field_type() { protobuf_structs::dht::Message_MessageType::PING => Ok(KadResponseMsg::Pong), protobuf_structs::dht::Message_MessageType::GET_VALUE => { Err(IoError::new( IoErrorKind::InvalidData, "received a GET_VALUE message, but this is not supported by rust-libp2p yet", )) } protobuf_structs::dht::Message_MessageType::FIND_NODE => { let closer_peers = message .mut_closerPeers() .iter_mut() .filter_map(|peer| KadPeer::from_peer(peer).ok()) .collect::>(); Ok(KadResponseMsg::FindNode { closer_peers }) } protobuf_structs::dht::Message_MessageType::GET_PROVIDERS => { let closer_peers = message .mut_closerPeers() .iter_mut() .filter_map(|peer| KadPeer::from_peer(peer).ok()) .collect::>(); let provider_peers = message .mut_providerPeers() .iter_mut() .filter_map(|peer| KadPeer::from_peer(peer).ok()) .collect::>(); Ok(KadResponseMsg::GetProviders { closer_peers, provider_peers, }) } protobuf_structs::dht::Message_MessageType::PUT_VALUE => Err(IoError::new( IoErrorKind::InvalidData, "received an unexpected PUT_VALUE message", )), protobuf_structs::dht::Message_MessageType::ADD_PROVIDER => Err(IoError::new( IoErrorKind::InvalidData, "received an unexpected ADD_PROVIDER message", )), } } #[cfg(test)] mod tests { extern crate libp2p_tcp; extern crate tokio; /*// TODO: restore use self::libp2p_tcp::TcpConfig; use self::tokio::runtime::current_thread::Runtime; use futures::{Future, Sink, Stream}; use libp2p_core::{PeerId, PublicKey, Transport}; use multihash::{encode, Hash}; use protocol::{KadConnectionType, KadPeer, KademliaProtocolConfig}; use std::sync::mpsc; use std::thread; #[test] fn correct_transfer() { // We open a server and a client, send a message between the two, and check that they were // successfully received. test_one(KadMsg::Ping); test_one(KadMsg::FindNodeReq { key: PeerId::random(), }); test_one(KadMsg::FindNodeRes { closer_peers: vec![KadPeer { node_id: PeerId::random(), multiaddrs: vec!["/ip4/100.101.102.103/tcp/20105".parse().unwrap()], connection_ty: KadConnectionType::Connected, }], }); test_one(KadMsg::GetProvidersReq { key: encode(Hash::SHA2256, &[9, 12, 0, 245, 245, 201, 28, 95]).unwrap(), }); test_one(KadMsg::GetProvidersRes { closer_peers: vec![KadPeer { node_id: PeerId::random(), multiaddrs: vec!["/ip4/100.101.102.103/tcp/20105".parse().unwrap()], connection_ty: KadConnectionType::Connected, }], provider_peers: vec![KadPeer { node_id: PeerId::random(), multiaddrs: vec!["/ip4/200.201.202.203/tcp/1999".parse().unwrap()], connection_ty: KadConnectionType::NotConnected, }], }); test_one(KadMsg::AddProvider { key: encode(Hash::SHA2256, &[9, 12, 0, 245, 245, 201, 28, 95]).unwrap(), provider_peer: KadPeer { node_id: PeerId::random(), multiaddrs: vec!["/ip4/9.1.2.3/udp/23".parse().unwrap()], connection_ty: KadConnectionType::Connected, }, }); // TODO: all messages fn test_one(msg_server: KadMsg) { let msg_client = msg_server.clone(); let (tx, rx) = mpsc::channel(); let bg_thread = thread::spawn(move || { let transport = TcpConfig::new().with_upgrade(KademliaProtocolConfig); let (listener, addr) = transport .listen_on("/ip4/127.0.0.1/tcp/0".parse().unwrap()) .unwrap(); tx.send(addr).unwrap(); let future = listener .into_future() .map_err(|(err, _)| err) .and_then(|(client, _)| client.unwrap().0) .and_then(|proto| proto.into_future().map_err(|(err, _)| err).map(|(v, _)| v)) .map(|recv_msg| { assert_eq!(recv_msg.unwrap(), msg_server); () }); let mut rt = Runtime::new().unwrap(); let _ = rt.block_on(future).unwrap(); }); let transport = TcpConfig::new().with_upgrade(KademliaProtocolConfig); let future = transport .dial(rx.recv().unwrap()) .unwrap_or_else(|_| panic!()) .and_then(|proto| proto.send(msg_client)) .map(|_| ()); let mut rt = Runtime::new().unwrap(); let _ = rt.block_on(future).unwrap(); bg_thread.join().unwrap(); } }*/ }