- # Tendermint Peers
-
- This document explains how Tendermint Peers are identified and how they connect to one another.
-
- For details on peer discovery, see the [peer exchange (PEX) reactor doc](../reactors/pex/pex.md).
-
- ## Peer Identity
-
- Tendermint peers are expected to maintain long-term persistent identities in the form of a public key.
- Each peer has an ID defined as `peer.ID == peer.PubKey.Address()`, where `Address` uses the scheme defined in go-crypto.
-
- A single peer ID can have multiple IP addresses associated with it, but a node
- will only ever connect to one at a time.
-
- When attempting to connect to a peer, we use the PeerURL: `<ID>@<IP>:<PORT>`.
- We will attempt to connect to the peer at IP:PORT, and verify,
- via authenticated encryption, that it is in possession of the private key
- corresponding to `<ID>`. This prevents man-in-the-middle attacks on the peer layer.
-
- If `auth_enc = false`, peers can use an arbitrary ID, but they must always use
- one. Authentication can then happen out-of-band of Tendermint, for instance via VPN.
-
- ## Connections
-
- All p2p connections use TCP.
- Upon establishing a successful TCP connection with a peer,
- two handhsakes are performed: one for authenticated encryption, and one for Tendermint versioning.
- Both handshakes have configurable timeouts (they should complete quickly).
-
- ### Authenticated Encryption Handshake
-
- Tendermint implements the Station-to-Station protocol
- using ED25519 keys for Diffie-Helman key-exchange and NACL SecretBox for encryption.
- It goes as follows:
- - generate an emphemeral ED25519 keypair
- - send the ephemeral public key to the peer
- - wait to receive the peer's ephemeral public key
- - compute the Diffie-Hellman shared secret using the peers ephemeral public key and our ephemeral private key
- - generate two nonces to use for encryption (sending and receiving) as follows:
- - sort the ephemeral public keys in ascending order and concatenate them
- - RIPEMD160 the result
- - append 4 empty bytes (extending the hash to 24-bytes)
- - the result is nonce1
- - flip the last bit of nonce1 to get nonce2
- - if we had the smaller ephemeral pubkey, use nonce1 for receiving, nonce2 for sending;
- else the opposite
- - all communications from now on are encrypted using the shared secret and the nonces, where each nonce
- increments by 2 every time it is used
- - we now have an encrypted channel, but still need to authenticate
- - generate a common challenge to sign:
- - SHA256 of the sorted (lowest first) and concatenated ephemeral pub keys
- - sign the common challenge with our persistent private key
- - send the go-wire encoded persistent pubkey and signature to the peer
- - wait to receive the persistent public key and signature from the peer
- - verify the signature on the challenge using the peer's persistent public key
-
-
- If this is an outgoing connection (we dialed the peer) and we used a peer ID,
- then finally verify that the peer's persistent public key corresponds to the peer ID we dialed,
- ie. `peer.PubKey.Address() == <ID>`.
-
- The connection has now been authenticated. All traffic is encrypted.
-
- Note: only the dialer can authenticate the identity of the peer,
- but this is what we care about since when we join the network we wish to
- ensure we have reached the intended peer (and are not being MITMd).
-
- ### Peer Filter
-
- Before continuing, we check if the new peer has the same ID as ourselves or
- an existing peer. If so, we disconnect.
-
- We also check the peer's address and public key against
- an optional whitelist which can be managed through the ABCI app -
- if the whitelist is enabled and the peer does not qualify, the connection is
- terminated.
-
-
- ### Tendermint Version Handshake
-
- The Tendermint Version Handshake allows the peers to exchange their NodeInfo:
-
- ```golang
- type NodeInfo struct {
- ID p2p.ID
- ListenAddr string
-
- Network string
- Version string
- Channels []int8
-
- Moniker string
- Other []string
- }
- ```
-
- The connection is disconnected if:
- - `peer.NodeInfo.ID` is not equal `peerConn.ID`
- - `peer.NodeInfo.Version` is not formatted as `X.X.X` where X are integers known as Major, Minor, and Revision
- - `peer.NodeInfo.Version` Major is not the same as ours
- - `peer.NodeInfo.Network` is not the same as ours
- - `peer.Channels` does not intersect with our known Channels.
- - `peer.NodeInfo.ListenAddr` is malformed or is a DNS host that cannot be
- resolved
-
-
- At this point, if we have not disconnected, the peer is valid.
- It is added to the switch and hence all reactors via the `AddPeer` method.
- Note that each reactor may handle multiple channels.
-
- ## Connection Activity
-
- Once a peer is added, incoming messages for a given reactor are handled through
- that reactor's `Receive` method, and output messages are sent directly by the Reactors
- on each peer. A typical reactor maintains per-peer go-routine(s) that handle this.
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