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EIP-8

devp2p Forward Compatibility Requirements for Homestead

FinalStandards Track: Networking
创建时间: 2015-12-18
Felix Lange <felix@ethdev.com>
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Abstract

This EIP introduces new forward-compatibility requirements for implementations of the devp2p Wire Protocol, the RLPx Discovery Protocol and the RLPx TCP Transport Protocol. Clients which implement EIP-8 behave according to Postel's Law:

Be conservative in what you do, be liberal in what you accept from others.

Specification

Implementations of the devp2p Wire Protocol should ignore the version number of hello packets. When sending the hello packet, the version element should be set to the highest devp2p version supported. Implementations should also ignore any additional list elements at the end of the hello packet.

Similarly, implementations of the RLPx Discovery Protocol should not validate the version number of the ping packet, ignore any additional list elements in any packet, and ignore any data after the first RLP value in any packet. Discovery packets with unknown packet type should be discarded silently. The maximum size of any discovery packet is still 1280 bytes.

Finally, implementations of the RLPx TCP Transport protocol should accept a new encoding for the encrypted key establishment handshake packets. If an EIP-8 style RLPx auth-packet is received, the corresponding ack-packet should be sent using the rules below.

Decoding the RLP data in auth-body and ack-body should ignore mismatches of auth-vsn and ack-vsn, any additional list elements and any trailing data after the list. During the transitioning period (i.e. until the old format has been retired), implementations should pad auth-body with at least 100 bytes of junk data. Adding a random amount in range [100, 300] is recommended to vary the size of the packet.

auth-vsn = 4 auth-size = size of enc-auth-body, encoded as a big-endian 16-bit integer auth-body = rlp.list(sig, initiator-pubk, initiator-nonce, auth-vsn) enc-auth-body = ecies.encrypt(recipient-pubk, auth-body, auth-size) auth-packet = auth-size || enc-auth-body ack-vsn = 4 ack-size = size of enc-ack-body, encoded as a big-endian 16-bit integer ack-body = rlp.list(recipient-ephemeral-pubk, recipient-nonce, ack-vsn) enc-ack-body = ecies.encrypt(initiator-pubk, ack-body, ack-size) ack-packet = ack-size || enc-ack-body where X || Y denotes concatenation of X and Y. X[:N] denotes an N-byte prefix of X. rlp.list(X, Y, Z, ...) denotes recursive encoding of [X, Y, Z, ...] as an RLP list. sha3(MESSAGE) is the Keccak256 hash function as used by Ethereum. ecies.encrypt(PUBKEY, MESSAGE, AUTHDATA) is the asymmetric authenticated encryption function as used by RLPx. AUTHDATA is authenticated data which is not part of the resulting ciphertext, but written to HMAC-256 before generating the message tag.

Motivation

Changes to the devp2p protocols are hard to deploy because clients running an older version will refuse communication if the version number or structure of the hello (discovery ping, RLPx handshake) packet does not match local expectations.

Introducing forward-compatibility requirements as part of the Homestead consensus upgrade will ensure that all client software in use on the Ethereum network can cope with future network protocol upgrades (as long as backwards-compatibility is maintained).

Rationale

The proposed changes address forward compatibility by applying Postel's Law (also known as the Robustness Principle) throughout the protocol stack. The merit and applicability of this approach has been studied repeatedly since its original application in RFC 761. For a recent perspective, see "The Robustness Principle Reconsidered" (Eric Allman, 2011).

Changes to the devp2p Wire Protocol

All clients currently contain statements such as the following:

# pydevp2p/p2p_protocol.py if data['version'] != proto.version: log.debug('incompatible network protocols', peer=proto.peer, expected=proto.version, received=data['version']) return proto.send_disconnect(reason=reasons.incompatibel_p2p_version)

These checks make it impossible to change the version or structure of the hello packet. Dropping them enables switching to a newer protocol version: Clients implementing a newer version simply send a packet with higher version and possibly additional list elements.

  • If such a packet is received by a node with lower version, it will blindly assume that the remote end is backwards-compatible and respond with the old handshake.
  • If the packet is received by a node with equal version, new features of the protocol can be used.
  • If the packet is received by a node with higher version, it can enable backwards-compatibility logic or drop the connection.

Changes to the RLPx Discovery Protocol

The relaxation of discovery packet decoding rules largely codifies current practice. Most existing implementations do not care about the number of list elements (an exception being go-ethereum) and do not reject nodes with mismatching version. This behaviour is not guaranteed by the spec, though.

If adopted, the change makes it possible to deploy protocol changes in a similar manner to the devp2p hello change: simply bump the version and send additional information. Older clients will ignore the additional elements and can continue to operate even when the majority of the network has moved on to a newer protocol.

Changes to the RLPx TCP Handshake

Discussions of the RLPx v5 changes (chunked packets, change to key derivation) have faltered in part because the v4 handshake encoding provides only one in-band way to add a version number: shortening the random portion of the nonce. Even if the RLPx v5 handshake proposal were accepted, future upgrades are hard because the handshake packet is a fixed size ECIES ciphertext with known layout.

I propose the following changes to the handshake packets:

  • Adding the length of the ciphertext as a plaintext header.
  • Encoding the body of the handshake as RLP.
  • Adding a version number to both packets in place of the token flag (unused).
  • Removing the hash of the ephemeral public key (it is redundant).

These changes make it possible to upgrade the RLPx TCP transport protocol in the same manner as described for the other protocols, i.e. by adding list elements and bumping the version. Since this is the first change to the RLPx handshake packet, we can seize the opportunity to remove all currently unused fields.

Additional data is permitted (and in fact required) after the RLP list because the handshake packet needs to grow in order to be distinguishable from the old format. Clients can employ logic such as the following pseudocode to handle both formats simultaneously.

packet = read(307, connection) if decrypt(packet) { // process as old format } else { size = unpack_16bit_big_endian(packet) packet += read(size - 307 + 2, connection) if !decrypt(packet) { // error } // process as new format }

The plain text size prefix is perhaps the most controversial aspect of this document. It has been argued that the prefix aids adversaries that seek to filter and identify RLPx connections on the network level.

This is largely a question of how much effort the adversary is willing to expense. If the recommendation to randomise the lengths is followed, pure pattern-based packet recognition is unlikely to succeed.

  • For typical firewall operators, blocking all connections whose first two bytes form an integer in range [300,600] is probably too invasive. Port-based blocking would be a more effective measure to filter most RLPx traffic.
  • For an attacker who can afford to correlate many criteria, the size prefix would ease recognition because it adds to the indicator set. However, such an attacker could also be expected to read or participate in RLPx Discovery traffic, which would be sufficient to enable blocking of RLPx TCP connections whatever their format is.

Backwards Compatibility

This EIP is backwards-compatible, all valid version 4 packets are still accepted.

Implementation

go-ethereum libweb3core pydevp2p

Test Vectors

devp2p Base Protocol

devp2p hello packet advertising version 22 and containing a few additional list elements:

f87137916b6e6574682f76302e39312f706c616e39cdc5836574683dc6846d6f726b1682270fb840 fda1cff674c90c9a197539fe3dfb53086ace64f83ed7c6eabec741f7f381cc803e52ab2cd55d5569 bce4347107a310dfd5f88a010cd2ffd1005ca406f1842877c883666f6f836261720304

RLPx Discovery Protocol

Implementations should accept the following encoded discovery packets as valid. The packets are signed using the secp256k1 node key

b71c71a67e1177ad4e901695e1b4b9ee17ae16c6668d313eac2f96dbcda3f291

ping packet with version 4, additional list elements:

e9614ccfd9fc3e74360018522d30e1419a143407ffcce748de3e22116b7e8dc92ff74788c0b6663a aa3d67d641936511c8f8d6ad8698b820a7cf9e1be7155e9a241f556658c55428ec0563514365799a 4be2be5a685a80971ddcfa80cb422cdd0101ec04cb847f000001820cfa8215a8d790000000000000 000000000000000000018208ae820d058443b9a3550102

ping packet with version 555, additional list elements and additional random data:

577be4349c4dd26768081f58de4c6f375a7a22f3f7adda654d1428637412c3d7fe917cadc56d4e5e 7ffae1dbe3efffb9849feb71b262de37977e7c7a44e677295680e9e38ab26bee2fcbae207fba3ff3 d74069a50b902a82c9903ed37cc993c50001f83e82022bd79020010db83c4d001500000000abcdef 12820cfa8215a8d79020010db885a308d313198a2e037073488208ae82823a8443b9a355c5010203 040531b9019afde696e582a78fa8d95ea13ce3297d4afb8ba6433e4154caa5ac6431af1b80ba7602 3fa4090c408f6b4bc3701562c031041d4702971d102c9ab7fa5eed4cd6bab8f7af956f7d565ee191 7084a95398b6a21eac920fe3dd1345ec0a7ef39367ee69ddf092cbfe5b93e5e568ebc491983c09c7 6d922dc3

pong packet with additional list elements and additional random data:

09b2428d83348d27cdf7064ad9024f526cebc19e4958f0fdad87c15eb598dd61d08423e0bf66b206 9869e1724125f820d851c136684082774f870e614d95a2855d000f05d1648b2d5945470bc187c2d2 216fbe870f43ed0909009882e176a46b0102f846d79020010db885a308d313198a2e037073488208 ae82823aa0fbc914b16819237dcd8801d7e53f69e9719adecb3cc0e790c57e91ca4461c9548443b9 a355c6010203c2040506a0c969a58f6f9095004c0177a6b47f451530cab38966a25cca5cb58f0555 42124e

findnode packet with additional list elements and additional random data:

c7c44041b9f7c7e41934417ebac9a8e1a4c6298f74553f2fcfdcae6ed6fe53163eb3d2b52e39fe91 831b8a927bf4fc222c3902202027e5e9eb812195f95d20061ef5cd31d502e47ecb61183f74a504fe 04c51e73df81f25c4d506b26db4517490103f84eb840ca634cae0d49acb401d8a4c6b6fe8c55b70d 115bf400769cc1400f3258cd31387574077f301b421bc84df7266c44e9e6d569fc56be0081290476 7bf5ccd1fc7f8443b9a35582999983999999280dc62cc8255c73471e0a61da0c89acdc0e035e260a dd7fc0c04ad9ebf3919644c91cb247affc82b69bd2ca235c71eab8e49737c937a2c396

neighbours packet with additional list elements and additional random data:

c679fc8fe0b8b12f06577f2e802d34f6fa257e6137a995f6f4cbfc9ee50ed3710faf6e66f932c4c8 d81d64343f429651328758b47d3dbc02c4042f0fff6946a50f4a49037a72bb550f3a7872363a83e1 b9ee6469856c24eb4ef80b7535bcf99c0004f9015bf90150f84d846321163782115c82115db84031 55e1427f85f10a5c9a7755877748041af1bcd8d474ec065eb33df57a97babf54bfd2103575fa8291 15d224c523596b401065a97f74010610fce76382c0bf32f84984010203040101b840312c55512422 cf9b8a4097e9a6ad79402e87a15ae909a4bfefa22398f03d20951933beea1e4dfa6f968212385e82 9f04c2d314fc2d4e255e0d3bc08792b069dbf8599020010db83c4d001500000000abcdef12820d05 820d05b84038643200b172dcfef857492156971f0e6aa2c538d8b74010f8e140811d53b98c765dd2 d96126051913f44582e8c199ad7c6d6819e9a56483f637feaac9448aacf8599020010db885a308d3 13198a2e037073488203e78203e8b8408dcab8618c3253b558d459da53bd8fa68935a719aff8b811 197101a4b2b47dd2d47295286fc00cc081bb542d760717d1bdd6bec2c37cd72eca367d6dd3b9df73 8443b9a355010203b525a138aa34383fec3d2719a0

RLPx Handshake

In these test vectors, node A initiates a connection with node B. The values contained in all packets are given below:

Static Key A: 49a7b37aa6f6645917e7b807e9d1c00d4fa71f18343b0d4122a4d2df64dd6fee Static Key B: b71c71a67e1177ad4e901695e1b4b9ee17ae16c6668d313eac2f96dbcda3f291 Ephemeral Key A: 869d6ecf5211f1cc60418a13b9d870b22959d0c16f02bec714c960dd2298a32d Ephemeral Key B: e238eb8e04fee6511ab04c6dd3c89ce097b11f25d584863ac2b6d5b35b1847e4 Nonce A: 7e968bba13b6c50e2c4cd7f241cc0d64d1ac25c7f5952df231ac6a2bda8ee5d6 Nonce B: 559aead08264d5795d3909718cdd05abd49572e84fe55590eef31a88a08fdffd

(Auth₁) RLPx v4 format (sent from A to B):

048ca79ad18e4b0659fab4853fe5bc58eb83992980f4c9cc147d2aa31532efd29a3d3dc6a3d89eaf 913150cfc777ce0ce4af2758bf4810235f6e6ceccfee1acc6b22c005e9e3a49d6448610a58e98744 ba3ac0399e82692d67c1f58849050b3024e21a52c9d3b01d871ff5f210817912773e610443a9ef14 2e91cdba0bd77b5fdf0769b05671fc35f83d83e4d3b0b000c6b2a1b1bba89e0fc51bf4e460df3105 c444f14be226458940d6061c296350937ffd5e3acaceeaaefd3c6f74be8e23e0f45163cc7ebd7622 0f0128410fd05250273156d548a414444ae2f7dea4dfca2d43c057adb701a715bf59f6fb66b2d1d2 0f2c703f851cbf5ac47396d9ca65b6260bd141ac4d53e2de585a73d1750780db4c9ee4cd4d225173 a4592ee77e2bd94d0be3691f3b406f9bba9b591fc63facc016bfa8

(Auth₂) EIP-8 format with version 4 and no additional list elements (sent from A to B):

01b304ab7578555167be8154d5cc456f567d5ba302662433674222360f08d5f1534499d3678b513b 0fca474f3a514b18e75683032eb63fccb16c156dc6eb2c0b1593f0d84ac74f6e475f1b8d56116b84 9634a8c458705bf83a626ea0384d4d7341aae591fae42ce6bd5c850bfe0b999a694a49bbbaf3ef6c da61110601d3b4c02ab6c30437257a6e0117792631a4b47c1d52fc0f8f89caadeb7d02770bf999cc 147d2df3b62e1ffb2c9d8c125a3984865356266bca11ce7d3a688663a51d82defaa8aad69da39ab6 d5470e81ec5f2a7a47fb865ff7cca21516f9299a07b1bc63ba56c7a1a892112841ca44b6e0034dee 70c9adabc15d76a54f443593fafdc3b27af8059703f88928e199cb122362a4b35f62386da7caad09 c001edaeb5f8a06d2b26fb6cb93c52a9fca51853b68193916982358fe1e5369e249875bb8d0d0ec3 6f917bc5e1eafd5896d46bd61ff23f1a863a8a8dcd54c7b109b771c8e61ec9c8908c733c0263440e 2aa067241aaa433f0bb053c7b31a838504b148f570c0ad62837129e547678c5190341e4f1693956c 3bf7678318e2d5b5340c9e488eefea198576344afbdf66db5f51204a6961a63ce072c8926c

(Auth₃) EIP-8 format with version 56 and 3 additional list elements (sent from A to B):

01b8044c6c312173685d1edd268aa95e1d495474c6959bcdd10067ba4c9013df9e40ff45f5bfd6f7 2471f93a91b493f8e00abc4b80f682973de715d77ba3a005a242eb859f9a211d93a347fa64b597bf 280a6b88e26299cf263b01b8dfdb712278464fd1c25840b995e84d367d743f66c0e54a586725b7bb f12acca27170ae3283c1073adda4b6d79f27656993aefccf16e0d0409fe07db2dc398a1b7e8ee93b cd181485fd332f381d6a050fba4c7641a5112ac1b0b61168d20f01b479e19adf7fdbfa0905f63352 bfc7e23cf3357657455119d879c78d3cf8c8c06375f3f7d4861aa02a122467e069acaf513025ff19 6641f6d2810ce493f51bee9c966b15c5043505350392b57645385a18c78f14669cc4d960446c1757 1b7c5d725021babbcd786957f3d17089c084907bda22c2b2675b4378b114c601d858802a55345a15 116bc61da4193996187ed70d16730e9ae6b3bb8787ebcaea1871d850997ddc08b4f4ea668fbf3740 7ac044b55be0908ecb94d4ed172ece66fd31bfdadf2b97a8bc690163ee11f5b575a4b44e36e2bfb2 f0fce91676fd64c7773bac6a003f481fddd0bae0a1f31aa27504e2a533af4cef3b623f4791b2cca6 d490

(Ack₁) RLPx v4 format (sent from B to A):

049f8abcfa9c0dc65b982e98af921bc0ba6e4243169348a236abe9df5f93aa69d99cadddaa387662 b0ff2c08e9006d5a11a278b1b3331e5aaabf0a32f01281b6f4ede0e09a2d5f585b26513cb794d963 5a57563921c04a9090b4f14ee42be1a5461049af4ea7a7f49bf4c97a352d39c8d02ee4acc416388c 1c66cec761d2bc1c72da6ba143477f049c9d2dde846c252c111b904f630ac98e51609b3b1f58168d dca6505b7196532e5f85b259a20c45e1979491683fee108e9660edbf38f3add489ae73e3dda2c71b d1497113d5c755e942d1

(Ack₂) EIP-8 format with version 4 and no additional list elements (sent from B to A):

01ea0451958701280a56482929d3b0757da8f7fbe5286784beead59d95089c217c9b917788989470 b0e330cc6e4fb383c0340ed85fab836ec9fb8a49672712aeabbdfd1e837c1ff4cace34311cd7f4de 05d59279e3524ab26ef753a0095637ac88f2b499b9914b5f64e143eae548a1066e14cd2f4bd7f814 c4652f11b254f8a2d0191e2f5546fae6055694aed14d906df79ad3b407d94692694e259191cde171 ad542fc588fa2b7333313d82a9f887332f1dfc36cea03f831cb9a23fea05b33deb999e85489e645f 6aab1872475d488d7bd6c7c120caf28dbfc5d6833888155ed69d34dbdc39c1f299be1057810f34fb e754d021bfca14dc989753d61c413d261934e1a9c67ee060a25eefb54e81a4d14baff922180c395d 3f998d70f46f6b58306f969627ae364497e73fc27f6d17ae45a413d322cb8814276be6ddd13b885b 201b943213656cde498fa0e9ddc8e0b8f8a53824fbd82254f3e2c17e8eaea009c38b4aa0a3f306e8 797db43c25d68e86f262e564086f59a2fc60511c42abfb3057c247a8a8fe4fb3ccbadde17514b7ac 8000cdb6a912778426260c47f38919a91f25f4b5ffb455d6aaaf150f7e5529c100ce62d6d92826a7 1778d809bdf60232ae21ce8a437eca8223f45ac37f6487452ce626f549b3b5fdee26afd2072e4bc7 5833c2464c805246155289f4

(Ack₃) EIP-8 format with version 57 and 3 additional list elements (sent from B to A):

01f004076e58aae772bb101ab1a8e64e01ee96e64857ce82b1113817c6cdd52c09d26f7b90981cd7 ae835aeac72e1573b8a0225dd56d157a010846d888dac7464baf53f2ad4e3d584531fa203658fab0 3a06c9fd5e35737e417bc28c1cbf5e5dfc666de7090f69c3b29754725f84f75382891c561040ea1d dc0d8f381ed1b9d0d4ad2a0ec021421d847820d6fa0ba66eaf58175f1b235e851c7e2124069fbc20 2888ddb3ac4d56bcbd1b9b7eab59e78f2e2d400905050f4a92dec1c4bdf797b3fc9b2f8e84a482f3 d800386186712dae00d5c386ec9387a5e9c9a1aca5a573ca91082c7d68421f388e79127a5177d4f8 590237364fd348c9611fa39f78dcdceee3f390f07991b7b47e1daa3ebcb6ccc9607811cb17ce51f1 c8c2c5098dbdd28fca547b3f58c01a424ac05f869f49c6a34672ea2cbbc558428aa1fe48bbfd6115 8b1b735a65d99f21e70dbc020bfdface9f724a0d1fb5895db971cc81aa7608baa0920abb0a565c9c 436e2fd13323428296c86385f2384e408a31e104670df0791d93e743a3a5194ee6b076fb6323ca59 3011b7348c16cf58f66b9633906ba54a2ee803187344b394f75dd2e663a57b956cb830dd7a908d4f 39a2336a61ef9fda549180d4ccde21514d117b6c6fd07a9102b5efe710a32af4eeacae2cb3b1dec0 35b9593b48b9d3ca4c13d245d5f04169b0b1

Node B derives the connection secrets for (Auth₂, Ack₂) as follows:

aes-secret = 80e8632c05fed6fc2a13b0f8d31a3cf645366239170ea067065aba8e28bac487 mac-secret = 2ea74ec5dae199227dff1af715362700e989d889d7a493cb0639691efb8e5f98

Running B's ingress-mac keccak state on the string "foo" yields the hash

ingress-mac("foo") = 0c7ec6340062cc46f5e9f1e3cf86f8c8c403c5a0964f5df0ebd34a75ddc86db5

Copyright and related rights waived via CC0.

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