# # Ethereum P2P # (c) Copyright 2018 # Status Research & Development GmbH # # See the file "LICENSE", included in this # distribution, for details about the copyright. # import unittest import eth/keys, nimcrypto/[utils, sysrand, keccak] import eth/p2p/[auth, rlpxcrypt] const data = [ ("initiator_private_key", "5e173f6ac3c669587538e7727cf19b782a4f2fda07c1eaa662c593e5e85e3051"), ("receiver_private_key", "c45f950382d542169ea207959ee0220ec1491755abe405cd7498d6b16adb6df8"), ("initiator_ephemeral_private_key", "19c2185f4f40634926ebed3af09070ca9e029f2edd5fae6253074896205f5f6c"), ("receiver_ephemeral_private_key", "d25688cf0ab10afa1a0e2dba7853ed5f1e5bf1c631757ed4e103b593ff3f5620"), ("auth_plaintext", """884c36f7ae6b406637c1f61b2f57e1d2cab813d24c6559aaf843c3f48962f32f 46662c066d39669b7b2e3ba14781477417600e7728399278b1b5d801a519aa57 0034fdb5419558137e0d44cd13d319afe5629eeccb47fd9dfe55cc6089426e46 cc762dd8a0636e07a54b31169eba0c7a20a1ac1ef68596f1f283b5c676bae406 4abfcce24799d09f67e392632d3ffdc12e3d6430dcb0ea19c318343ffa7aae74 d4cd26fecb93657d1cd9e9eaf4f8be720b56dd1d39f190c4e1c6b7ec66f077bb 1100"""), ("authresp_plaintext", """802b052f8b066640bba94a4fc39d63815c377fced6fcb84d27f791c9921ddf3e 9bf0108e298f490812847109cbd778fae393e80323fd643209841a3b7f110397 f37ec61d84cea03dcc5e8385db93248584e8af4b4d1c832d8c7453c0089687a7 00"""), ("auth_ciphertext", """04a0274c5951e32132e7f088c9bdfdc76c9d91f0dc6078e848f8e3361193dbdc 43b94351ea3d89e4ff33ddcefbc80070498824857f499656c4f79bbd97b6c51a 514251d69fd1785ef8764bd1d262a883f780964cce6a14ff206daf1206aa073a 2d35ce2697ebf3514225bef186631b2fd2316a4b7bcdefec8d75a1025ba2c540 4a34e7795e1dd4bc01c6113ece07b0df13b69d3ba654a36e35e69ff9d482d88d 2f0228e7d96fe11dccbb465a1831c7d4ad3a026924b182fc2bdfe016a6944312 021da5cc459713b13b86a686cf34d6fe6615020e4acf26bf0d5b7579ba813e77 23eb95b3cef9942f01a58bd61baee7c9bdd438956b426a4ffe238e61746a8c93 d5e10680617c82e48d706ac4953f5e1c4c4f7d013c87d34a06626f498f34576d c017fdd3d581e83cfd26cf125b6d2bda1f1d56"""), ("authresp_ciphertext", """049934a7b2d7f9af8fd9db941d9da281ac9381b5740e1f64f7092f3588d4f87f 5ce55191a6653e5e80c1c5dd538169aa123e70dc6ffc5af1827e546c0e958e42 dad355bcc1fcb9cdf2cf47ff524d2ad98cbf275e661bf4cf00960e74b5956b79 9771334f426df007350b46049adb21a6e78ab1408d5e6ccde6fb5e69f0f4c92b b9c725c02f99fa72b9cdc8dd53cff089e0e73317f61cc5abf6152513cb7d833f 09d2851603919bf0fbe44d79a09245c6e8338eb502083dc84b846f2fee1cc310 d2cc8b1b9334728f97220bb799376233e113"""), ("ecdhe_shared_secret", "e3f407f83fc012470c26a93fdff534100f2c6f736439ce0ca90e9914f7d1c381"), ("initiator_nonce", "cd26fecb93657d1cd9e9eaf4f8be720b56dd1d39f190c4e1c6b7ec66f077bb11"), ("receiver_nonce", "f37ec61d84cea03dcc5e8385db93248584e8af4b4d1c832d8c7453c0089687a7"), ("aes_secret", "c0458fa97a5230830e05f4f20b7c755c1d4e54b1ce5cf43260bb191eef4e418d"), ("mac_secret", "48c938884d5067a1598272fcddaa4b833cd5e7d92e8228c0ecdfabbe68aef7f1"), ("token", "3f9ec2592d1554852b1f54d228f042ed0a9310ea86d038dc2b401ba8cd7fdac4"), ("initial_egress_MAC", "09771e93b1a6109e97074cbe2d2b0cf3d3878efafe68f53c41bb60c0ec49097e"), ("initial_ingress_MAC", "75823d96e23136c89666ee025fb21a432be906512b3dd4a3049e898adb433847"), ("initiator_hello_packet", """6ef23fcf1cec7312df623f9ae701e63b550cdb8517fefd8dd398fc2acd1d935e 6e0434a2b96769078477637347b7b01924fff9ff1c06df2f804df3b0402bbb9f 87365b3c6856b45e1e2b6470986813c3816a71bff9d69dd297a5dbd935ab578f 6e5d7e93e4506a44f307c332d95e8a4b102585fd8ef9fc9e3e055537a5cec2e9"""), ("receiver_hello_packet", """6ef23fcf1cec7312df623f9ae701e63be36a1cdd1b19179146019984f3625d4a 6e0434a2b96769050577657247b7b02bc6c314470eca7e3ef650b98c83e9d7dd 4830b3f718ff562349aead2530a8d28a8484604f92e5fced2c6183f304344ab0 e7c301a0c05559f4c25db65e36820b4b909a226171a60ac6cb7beea09376d6d8""") ] proc testValue(s: string): string = for item in data: if item[0] == s: result = item[1] break suite "Ethereum RLPx encryption/decryption test suite": proc newTestHandshake(flags: set[HandshakeFlag]): Handshake = if Initiator in flags: let pk = PrivateKey.fromHex(testValue("initiator_private_key"))[] let kp = KeyPair(seckey: pk, pubkey: pk.toPublicKey()[]) result = Handshake.tryInit(kp, flags)[] let epki = testValue("initiator_ephemeral_private_key") result.ephemeral.seckey = PrivateKey.fromHex(epki)[] result.ephemeral.pubkey = result.ephemeral.seckey.toPublicKey()[] let nonce = fromHex(stripSpaces(testValue("initiator_nonce"))) result.initiatorNonce[0..^1] = nonce[0..^1] elif Responder in flags: let pk = PrivateKey.fromHex(testValue("receiver_private_key"))[] let kp = KeyPair(seckey: pk, pubkey: pk.toPublicKey()[]) result = Handshake.tryInit(kp, flags)[] let epkr = testValue("receiver_ephemeral_private_key") result.ephemeral.seckey = PrivateKey.fromHex(epkr)[] result.ephemeral.pubkey = result.ephemeral.seckey.toPublicKey()[] let nonce = fromHex(stripSpaces(testValue("receiver_nonce"))) result.responderNonce[0..^1] = nonce[0..^1] test "Encrypt/Decrypt Hello packet test vectors": var initiator = newTestHandshake({Initiator}) var responder = newTestHandshake({Responder}) var authm = fromHex(stripSpaces(testValue("auth_ciphertext"))) var ackm = fromHex(stripSpaces(testValue("authresp_ciphertext"))) var stateInitiator0, stateInitiator1: SecretState var stateResponder0, stateResponder1: SecretState responder.decodeAuthMessage(authm).expect("success") initiator.decodeAckMessage(ackm).expect("success") var csecInitiator = initiator.getSecrets(authm, ackm)[] var csecResponder = responder.getSecrets(authm, ackm)[] initSecretState(csecInitiator, stateInitiator0) initSecretState(csecResponder, stateResponder0) initSecretState(csecInitiator, stateInitiator1) initSecretState(csecResponder, stateResponder1) var packet0 = testValue("initiator_hello_packet") var initiatorHello = fromHex(stripSpaces(packet0)) var packet1 = testValue("receiver_hello_packet") var responderHello = fromHex(stripSpaces(packet1)) var header: array[RlpHeaderLength, byte] block: check stateResponder0.decryptHeader(toOpenArray(initiatorHello, 0, 31), header).isOk() let bodysize = getBodySize(header) check bodysize == 79 # we need body size to be rounded to 16 bytes boundary to properly # encrypt/decrypt it. var body = newSeq[byte](decryptedLength(bodysize)) var decrsize = 0 check: stateResponder0.decryptBody( toOpenArray(initiatorHello, 32, len(initiatorHello) - 1), getBodySize(header), body, decrsize).isOk() decrsize == 79 body.setLen(decrsize) var hello = newSeq[byte](encryptedLength(bodysize)) check: stateInitiator1.encrypt(header, body, hello).isOk() hello == initiatorHello block: check stateInitiator0.decryptHeader(toOpenArray(responderHello, 0, 31), header).isOk() let bodysize = getBodySize(header) check bodysize == 79 # we need body size to be rounded to 16 bytes boundary to properly # encrypt/decrypt it. var body = newSeq[byte](decryptedLength(bodysize)) var decrsize = 0 check: stateInitiator0.decryptBody( toOpenArray(responderHello, 32, len(initiatorHello) - 1), getBodySize(header), body, decrsize).isOk() decrsize == 79 body.setLen(decrsize) var hello = newSeq[byte](encryptedLength(bodysize)) check: stateResponder1.encrypt(header, body, hello).isOk() hello == responderHello test "Continuous stream of different lengths (1000 times)": var initiator = newTestHandshake({Initiator}) var responder = newTestHandshake({Responder}) var m0 = newSeq[byte](initiator.authSize()) var k0 = 0 var k1 = 0 check initiator.authMessage(responder.host.pubkey, m0, k0).isOk m0.setLen(k0) check responder.decodeAuthMessage(m0).isOk var m1 = newSeq[byte](responder.ackSize()) check responder.ackMessage(m1, k1).isOk m1.setLen(k1) check initiator.decodeAckMessage(m1).isOk var csecInitiator = initiator.getSecrets(m0, m1)[] var csecResponder = responder.getSecrets(m0, m1)[] var stateInitiator: SecretState var stateResponder: SecretState var iheader, rheader: array[16, byte] initSecretState(csecInitiator, stateInitiator) initSecretState(csecResponder, stateResponder) burnMem(iheader) burnMem(rheader) for i in 1..1000: # initiator -> responder block: var ibody = newSeq[byte](i) var encrypted = newSeq[byte](encryptedLength(len(ibody))) iheader[0] = byte((len(ibody) shr 16) and 0xFF) iheader[1] = byte((len(ibody) shr 8) and 0xFF) iheader[2] = byte(len(ibody) and 0xFF) check: randomBytes(ibody) == len(ibody) stateInitiator.encrypt(iheader, ibody, encrypted).isOk() stateResponder.decryptHeader(toOpenArray(encrypted, 0, 31), rheader).isOk() var length = getBodySize(rheader) check length == len(ibody) var rbody = newSeq[byte](decryptedLength(length)) var decrsize = 0 check: stateResponder.decryptBody( toOpenArray(encrypted, 32, len(encrypted) - 1), length, rbody, decrsize).isOk() decrsize == length rbody.setLen(decrsize) check: iheader == rheader ibody == rbody burnMem(iheader) burnMem(rheader) # responder -> initiator block: var ibody = newSeq[byte](i * 3) var encrypted = newSeq[byte](encryptedLength(len(ibody))) iheader[0] = byte((len(ibody) shr 16) and 0xFF) iheader[1] = byte((len(ibody) shr 8) and 0xFF) iheader[2] = byte(len(ibody) and 0xFF) check: randomBytes(ibody) == len(ibody) stateResponder.encrypt(iheader, ibody, encrypted).isOk() stateInitiator.decryptHeader(toOpenArray(encrypted, 0, 31), rheader).isOk() var length = getBodySize(rheader) check length == len(ibody) var rbody = newSeq[byte](decryptedLength(length)) var decrsize = 0 check: stateInitiator.decryptBody( toOpenArray(encrypted, 32, len(encrypted) - 1), length, rbody, decrsize).isOk() decrsize == length rbody.setLen(length) check: iheader == rheader ibody == rbody burnMem(iheader) burnMem(rheader)