zolfa
/
tendermint


								Secure P2P

								==========


								The Tendermint p2p protocol uses an authenticated encryption scheme

								based on the `Station-to-Station

								Protocol <https://en.wikipedia.org/wiki/Station-to-Station_protocol>`__.

								The implementation uses

								`golang's <https://godoc.org/golang.org/x/crypto/nacl/box>`__ `nacl

								box <http://nacl.cr.yp.to/box.html>`__ for the actual authenticated

								encryption algorithm.


								Each peer generates an ED25519 key-pair to use as a persistent

								(long-term) id.


								When two peers establish a TCP connection, they first each generate an

								ephemeral ED25519 key-pair to use for this session, and send each other

								their respective ephemeral public keys. This happens in the clear.


								They then each compute the shared secret. The shared secret is the

								multiplication of the peer's ephemeral private key by the other peer's

								ephemeral public key. The result is the same for both peers by the magic

								of `elliptic

								curves <https://en.wikipedia.org/wiki/Elliptic_curve_cryptography>`__.

								The shared secret is used as the symmetric key for the encryption

								algorithm.


								The two ephemeral public keys are sorted to establish a canonical order.

								Then a 24-byte nonce is generated by concatenating the public keys and

								hashing them with Ripemd160. Note Ripemd160 produces 20byte hashes, so

								the nonce ends with four 0s.


								The nonce is used to seed the encryption - it is critical that the same

								nonce never be used twice with the same private key. For convenience,

								the last bit of the nonce is flipped, giving us two nonces: one for

								encrypting our own messages, one for decrypting our peer's. Which ever

								peer has the higher public key uses the "bit-flipped" nonce for

								encryption.


								Now, a challenge is generated by concatenating the ephemeral public keys

								and taking the SHA256 hash.


								Each peer signs the challenge with their persistent private key, and

								sends the other peer an AuthSigMsg, containing their persistent public

								key and the signature. On receiving an AuthSigMsg, the peer verifies the

								signature.


								The peers are now authenticated.


								All future communications can now be encrypted using the shared secret

								and the generated nonces, where each nonce is incremented by one each

								time it is used. The communications maintain Perfect Forward Secrecy, as

								the persistent key pair was not used for generating secrets - only for

								authenticating.


								Caveat

								------


								This system is still vulnerable to a Man-In-The-Middle attack if the

								persistent public key of the remote node is not known in advance. The

								only way to mitigate this is with a public key authentication system,

								such as the Web-of-Trust or Certificate Authorities. In our case, we can

								use the blockchain itself as a certificate authority to ensure that we

								are connected to at least one validator.


								Additional Reading

								------------------


								-  `Implementation <https://github.com/tendermint/go-p2p/blob/master/secret_connection.go#L49>`__

								-  `Original STS paper by Whitfield Diffie, Paul C. van Oorschot and

								   Michael J.

								   Wiener <http://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.216.6107&rep=rep1&type=pdf>`__

								-  `Further work on secret

								   handshakes <https://dominictarr.github.io/secret-handshake-paper/shs.pdf>`__