mirror of https://github.com/waku-org/nwaku.git
883 lines
32 KiB
Nim
883 lines
32 KiB
Nim
{.used.}
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import
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testutils/unittests,
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std/random,
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std/tables,
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stew/byteutils,
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libp2p/crypto/chacha20poly1305,
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libp2p/protobuf/minprotobuf,
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stew/endians2
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import
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../../waku/v2/utils/noise as waku_message_utils,
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../../waku/v2/waku_noise/noise_types,
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../../waku/v2/waku_noise/noise_utils,
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../../waku/v2/waku_noise/noise,
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../../waku/v2/waku_noise/noise_handshake_processing,
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../../waku/v2/waku_core,
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./testlib/common
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procSuite "Waku Noise":
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common.randomize()
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test "PKCS#7 Padding/Unpadding":
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# We test padding for different message lengths
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let maxMessageLength = 3 * NoisePaddingBlockSize
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for messageLen in 0..maxMessageLength:
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let
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message = randomSeqByte(rng[], messageLen)
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padded = pkcs7_pad(message, NoisePaddingBlockSize)
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unpadded = pkcs7_unpad(padded, NoisePaddingBlockSize)
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check:
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padded.len != 0
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padded.len mod NoisePaddingBlockSize == 0
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message == unpadded
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test "ChaChaPoly Encryption/Decryption: random byte sequences":
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let cipherState = randomChaChaPolyCipherState(rng[])
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# We encrypt/decrypt random byte sequences
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let
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plaintext: seq[byte] = randomSeqByte(rng[], rand(1..128))
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ciphertext: ChaChaPolyCiphertext = encrypt(cipherState, plaintext)
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decryptedCiphertext: seq[byte] = decrypt(cipherState, ciphertext)
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check:
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plaintext == decryptedCiphertext
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test "ChaChaPoly Encryption/Decryption: random strings":
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let cipherState = randomChaChaPolyCipherState(rng[])
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# We encrypt/decrypt random strings
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var plaintext: string
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for _ in 1..rand(1..128):
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add(plaintext, char(rand(int('A') .. int('z'))))
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let
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ciphertext: ChaChaPolyCiphertext = encrypt(cipherState, plaintext.toBytes())
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decryptedCiphertext: seq[byte] = decrypt(cipherState, ciphertext)
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check:
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plaintext.toBytes() == decryptedCiphertext
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test "Noise public keys: encrypt and decrypt a public key":
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let noisePublicKey: NoisePublicKey = genNoisePublicKey(rng[])
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let
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cs: ChaChaPolyCipherState = randomChaChaPolyCipherState(rng[])
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encryptedPk: NoisePublicKey = encryptNoisePublicKey(cs, noisePublicKey)
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decryptedPk: NoisePublicKey = decryptNoisePublicKey(cs, encryptedPk)
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check:
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noisePublicKey == decryptedPk
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test "Noise public keys: decrypt an unencrypted public key":
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let noisePublicKey: NoisePublicKey = genNoisePublicKey(rng[])
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let
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cs: ChaChaPolyCipherState = randomChaChaPolyCipherState(rng[])
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decryptedPk: NoisePublicKey = decryptNoisePublicKey(cs, noisePublicKey)
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check:
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noisePublicKey == decryptedPk
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test "Noise public keys: encrypt an encrypted public key":
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let noisePublicKey: NoisePublicKey = genNoisePublicKey(rng[])
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let
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cs: ChaChaPolyCipherState = randomChaChaPolyCipherState(rng[])
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encryptedPk: NoisePublicKey = encryptNoisePublicKey(cs, noisePublicKey)
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encryptedPk2: NoisePublicKey = encryptNoisePublicKey(cs, encryptedPk)
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check:
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encryptedPk == encryptedPk2
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test "Noise public keys: encrypt, decrypt and decrypt a public key":
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let noisePublicKey: NoisePublicKey = genNoisePublicKey(rng[])
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let
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cs: ChaChaPolyCipherState = randomChaChaPolyCipherState(rng[])
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encryptedPk: NoisePublicKey = encryptNoisePublicKey(cs, noisePublicKey)
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decryptedPk: NoisePublicKey = decryptNoisePublicKey(cs, encryptedPk)
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decryptedPk2: NoisePublicKey = decryptNoisePublicKey(cs, decryptedPk)
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check:
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decryptedPk == decryptedPk2
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test "Noise public keys: serialize and deserialize an unencrypted public key":
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let
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noisePublicKey: NoisePublicKey = genNoisePublicKey(rng[])
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serializedNoisePublicKey: seq[byte] = serializeNoisePublicKey(noisePublicKey)
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deserializedNoisePublicKey: NoisePublicKey = intoNoisePublicKey(serializedNoisePublicKey)
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check:
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noisePublicKey == deserializedNoisePublicKey
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test "Noise public keys: encrypt, serialize, deserialize and decrypt a public key":
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let noisePublicKey: NoisePublicKey = genNoisePublicKey(rng[])
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let
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cs: ChaChaPolyCipherState = randomChaChaPolyCipherState(rng[])
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encryptedPk: NoisePublicKey = encryptNoisePublicKey(cs, noisePublicKey)
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serializedNoisePublicKey: seq[byte] = serializeNoisePublicKey(encryptedPk)
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deserializedNoisePublicKey: NoisePublicKey = intoNoisePublicKey(serializedNoisePublicKey)
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decryptedPk: NoisePublicKey = decryptNoisePublicKey(cs, deserializedNoisePublicKey)
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check:
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noisePublicKey == decryptedPk
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test "PayloadV2: serialize/deserialize PayloadV2 to byte sequence":
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let
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payload2: PayloadV2 = randomPayloadV2(rng[])
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serializedPayload = serializePayloadV2(payload2)
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check:
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serializedPayload.isOk()
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let deserializedPayload = deserializePayloadV2(serializedPayload.get())
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check:
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deserializedPayload.isOk()
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payload2 == deserializedPayload.get()
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test "PayloadV2: Encode/Decode a Waku Message (version 2) to a PayloadV2":
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# We encode to a WakuMessage a random PayloadV2
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let
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payload2 = randomPayloadV2(rng[])
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msg = encodePayloadV2(payload2)
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check:
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msg.isOk()
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# We create ProtoBuffer from WakuMessage
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let pb = msg.get().encode()
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# We decode the WakuMessage from the ProtoBuffer
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let msgFromPb = WakuMessage.decode(pb.buffer)
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check:
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msgFromPb.isOk()
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let decoded = decodePayloadV2(msgFromPb.get())
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check:
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decoded.isOk()
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payload2 == decoded.get()
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test "Noise State Machine: Diffie-Hellman operation":
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#We generate random keypairs
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let
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aliceKey = genKeyPair(rng[])
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bobKey = genKeyPair(rng[])
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# A Diffie-Hellman operation between Alice's private key and Bob's public key must be equal to
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# a Diffie-hellman operation between Alice's public key and Bob's private key
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let
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dh1 = dh(getPrivateKey(aliceKey), getPublicKey(bobKey))
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dh2 = dh(getPrivateKey(bobKey), getPublicKey(aliceKey))
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check:
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dh1 == dh2
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test "Noise State Machine: Cipher State primitives":
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# We generate a random Cipher State, associated data ad and plaintext
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var
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cipherState: CipherState = randomCipherState(rng[])
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nonce: uint64 = uint64(rand(0 .. int.high))
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ad: seq[byte] = randomSeqByte(rng[], rand(1..128))
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plaintext: seq[byte] = randomSeqByte(rng[], rand(1..128))
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# We set the random nonce generated in the cipher state
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setNonce(cipherState, nonce)
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# We perform encryption
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var ciphertext: seq[byte] = encryptWithAd(cipherState, ad, plaintext)
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# After any encryption/decryption operation, the Cipher State's nonce increases by 1
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check:
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getNonce(cipherState) == nonce + 1
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# We set the nonce back to its original value for decryption
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setNonce(cipherState, nonce)
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# We decrypt (using the original nonce)
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var decrypted: seq[byte] = decryptWithAd(cipherState, ad, ciphertext)
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# We check if encryption and decryption are correct and that nonce correctly increased after decryption
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check:
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getNonce(cipherState) == nonce + 1
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plaintext == decrypted
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# If a Cipher State has no key set, encryptWithAd should return the plaintext without increasing the nonce
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setCipherStateKey(cipherState, EmptyKey)
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nonce = getNonce(cipherState)
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plaintext = randomSeqByte(rng[], rand(1..128))
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ciphertext = encryptWithAd(cipherState, ad, plaintext)
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check:
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ciphertext == plaintext
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getNonce(cipherState) == nonce
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# If a Cipher State has no key set, decryptWithAd should return the ciphertext without increasing the nonce
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setCipherStateKey(cipherState, EmptyKey)
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nonce = getNonce(cipherState)
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# Note that we set ciphertext minimum length to 16 to not trigger checks on authentication tag length
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ciphertext = randomSeqByte(rng[], rand(16..128))
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plaintext = decryptWithAd(cipherState, ad, ciphertext)
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check:
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ciphertext == plaintext
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getNonce(cipherState) == nonce
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# A Cipher State cannot have a nonce greater or equal 2^64-1
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# Note that NonceMax is uint64.high - 1 = 2^64-1-1 and that nonce is increased after each encryption and decryption operation
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# We generate a test Cipher State with nonce set to MaxNonce
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cipherState = randomCipherState(rng[])
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setNonce(cipherState, NonceMax)
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plaintext = randomSeqByte(rng[], rand(1..128))
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# We test if encryption fails with a NoiseNonceMaxError error. Any subsequent encryption call over the Cipher State should fail similarly and leave the nonce unchanged
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for _ in [1..5]:
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expect NoiseNonceMaxError:
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ciphertext = encryptWithAd(cipherState, ad, plaintext)
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check:
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getNonce(cipherState) == NonceMax + 1
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# We generate a test Cipher State
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# Since nonce is increased after decryption as well, we need to generate a proper ciphertext in order to test MaxNonceError error handling
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# We cannot call encryptWithAd to encrypt a plaintext using a nonce equal MaxNonce, since this will trigger a MaxNonceError.
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# To perform such test, we then need to encrypt a test plaintext using directly ChaChaPoly primitive
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cipherState = randomCipherState(rng[])
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setNonce(cipherState, NonceMax)
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plaintext = randomSeqByte(rng[], rand(1..128))
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# We perform encryption using the Cipher State key, NonceMax and ad
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# By Noise specification the nonce is 8 bytes long out of the 12 bytes supported by ChaChaPoly, thus we copy the Little endian conversion of the nonce to a ChaChaPolyNonce
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var
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encNonce: ChaChaPolyNonce
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authorizationTag: ChaChaPolyTag
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encNonce[4..<12] = toBytesLE(NonceMax)
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ChaChaPoly.encrypt(getKey(cipherState), encNonce, authorizationTag, plaintext, ad)
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# The output ciphertext is stored in the plaintext variable after ChaChaPoly.encrypt is called: we copy it along with the authorization tag.
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ciphertext = @[]
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ciphertext.add(plaintext)
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ciphertext.add(authorizationTag)
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# At this point ciphertext is a proper encryption of the original plaintext obtained with nonce equal to NonceMax
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# We can now test if decryption fails with a NoiseNonceMaxError error. Any subsequent decryption call over the Cipher State should fail similarly and leave the nonce unchanged
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# Note that decryptWithAd doesn't fail in decrypting the ciphertext (otherwise a NoiseDecryptTagError would have been triggered)
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for _ in [1..5]:
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expect NoiseNonceMaxError:
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plaintext = decryptWithAd(cipherState, ad, ciphertext)
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check:
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getNonce(cipherState) == NonceMax + 1
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test "Noise State Machine: Symmetric State primitives":
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# We select one supported handshake pattern and we initialize a symmetric state
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var
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hsPattern = NoiseHandshakePatterns["XX"]
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symmetricState: SymmetricState = SymmetricState.init(hsPattern)
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# We get all the Symmetric State field
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# cs : Cipher State
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# ck : chaining key
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# h : handshake hash
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var
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cs = getCipherState(symmetricState)
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ck = getChainingKey(symmetricState)
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h = getHandshakeHash(symmetricState)
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# When a Symmetric state is initialized, handshake hash and chaining key are (byte-wise) equal
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check:
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h.data.intoChaChaPolyKey == ck
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########################################
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# mixHash
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########################################
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# We generate a random byte sequence and execute a mixHash over it
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mixHash(symmetricState, randomSeqByte(rng[], rand(1..128)))
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# mixHash changes only the handshake hash value of the Symmetric state
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check:
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cs == getCipherState(symmetricState)
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ck == getChainingKey(symmetricState)
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h != getHandshakeHash(symmetricState)
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# We update test values
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h = getHandshakeHash(symmetricState)
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########################################
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# mixKey
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########################################
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# We generate random input key material and we execute mixKey
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var inputKeyMaterial = randomSeqByte(rng[], rand(1..128))
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mixKey(symmetricState, inputKeyMaterial)
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# mixKey changes the Symmetric State's chaining key and encryption key of the embedded Cipher State
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# It further sets to 0 the nonce of the embedded Cipher State
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check:
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getKey(cs) != getKey(getCipherState(symmetricState))
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getNonce(getCipherState(symmetricState)) == 0.uint64
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cs != getCipherState(symmetricState)
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ck != getChainingKey(symmetricState)
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h == getHandshakeHash(symmetricState)
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# We update test values
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cs = getCipherState(symmetricState)
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ck = getChainingKey(symmetricState)
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########################################
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# mixKeyAndHash
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########################################
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# We generate random input key material and we execute mixKeyAndHash
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inputKeyMaterial = randomSeqByte(rng[], rand(1..128))
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mixKeyAndHash(symmetricState, inputKeyMaterial)
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# mixKeyAndHash executes a mixKey and a mixHash using the input key material
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# All Symmetric State's fields are updated
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check:
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cs != getCipherState(symmetricState)
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ck != getChainingKey(symmetricState)
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h != getHandshakeHash(symmetricState)
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# We update test values
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cs = getCipherState(symmetricState)
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ck = getChainingKey(symmetricState)
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h = getHandshakeHash(symmetricState)
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########################################
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# encryptAndHash and decryptAndHash
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########################################
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# We store the initial symmetricState in order to correctly perform decryption
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var initialSymmetricState = symmetricState
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# We generate random plaintext and we execute encryptAndHash
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var plaintext = randomChaChaPolyKey(rng[])
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var nonce = getNonce(getCipherState(symmetricState))
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var ciphertext = encryptAndHash(symmetricState, plaintext)
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# encryptAndHash combines encryptWithAd and mixHash over the ciphertext (encryption increases the nonce of the embedded Cipher State but does not change its key)
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# We check if only the handshake hash value and the Symmetric State changed accordingly
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check:
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cs != getCipherState(symmetricState)
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getKey(cs) == getKey(getCipherState(symmetricState))
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getNonce(getCipherState(symmetricState)) == nonce + 1
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ck == getChainingKey(symmetricState)
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h != getHandshakeHash(symmetricState)
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# We restore the symmetric State to its initial value to test decryption
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symmetricState = initialSymmetricState
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# We execute decryptAndHash over the ciphertext
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var decrypted = decryptAndHash(symmetricState, ciphertext)
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# decryptAndHash combines decryptWithAd and mixHash over the ciphertext (encryption increases the nonce of the embedded Cipher State but does not change its key)
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# We check if only the handshake hash value and the Symmetric State changed accordingly
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# We further check if decryption corresponds to the original plaintext
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check:
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cs != getCipherState(symmetricState)
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getKey(cs) == getKey(getCipherState(symmetricState))
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getNonce(getCipherState(symmetricState)) == nonce + 1
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ck == getChainingKey(symmetricState)
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h != getHandshakeHash(symmetricState)
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decrypted == plaintext
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########################################
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# split
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########################################
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# If at least one mixKey is executed (as above), ck is non-empty
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check:
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getChainingKey(symmetricState) != EmptyKey
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# When a Symmetric State's ck is non-empty, we can execute split, which creates two distinct Cipher States cs1 and cs2
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# with non-empty encryption keys and nonce set to 0
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var (cs1, cs2) = split(symmetricState)
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check:
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getKey(cs1) != EmptyKey
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getKey(cs2) != EmptyKey
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getNonce(cs1) == 0.uint64
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getNonce(cs2) == 0.uint64
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getKey(cs1) != getKey(cs2)
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test "Noise XX Handhshake and message encryption (extended test)":
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let hsPattern = NoiseHandshakePatterns["XX"]
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# We initialize Alice's and Bob's Handshake State
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let aliceStaticKey = genKeyPair(rng[])
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var aliceHS = initialize(hsPattern = hsPattern, staticKey = aliceStaticKey, initiator = true)
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let bobStaticKey = genKeyPair(rng[])
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var bobHS = initialize(hsPattern = hsPattern, staticKey = bobStaticKey)
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var
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sentTransportMessage: seq[byte]
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aliceStep, bobStep: HandshakeStepResult
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# Here the handshake starts
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# Write and read calls alternate between Alice and Bob: the handhshake progresses by alternatively calling stepHandshake for each user
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###############
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# 1st step
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###############
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# We generate a random transport message
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sentTransportMessage = randomSeqByte(rng[], 32)
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# By being the handshake initiator, Alice writes a Waku2 payload v2 containing her handshake message
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# and the (encrypted) transport message
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aliceStep = stepHandshake(rng[], aliceHS, transportMessage = sentTransportMessage).get()
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# Bob reads Alice's payloads, and returns the (decrypted) transport message Alice sent to him
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bobStep = stepHandshake(rng[], bobHS, readPayloadV2 = aliceStep.payload2).get()
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check:
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bobStep.transportMessage == sentTransportMessage
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###############
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# 2nd step
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###############
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# We generate a random transport message
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sentTransportMessage = randomSeqByte(rng[], 32)
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# At this step, Bob writes and returns a payload
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bobStep = stepHandshake(rng[], bobHS, transportMessage = sentTransportMessage).get()
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# While Alice reads and returns the (decrypted) transport message
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aliceStep = stepHandshake(rng[], aliceHS, readPayloadV2 = bobStep.payload2).get()
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check:
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aliceStep.transportMessage == sentTransportMessage
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###############
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# 3rd step
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###############
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# We generate a random transport message
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sentTransportMessage = randomSeqByte(rng[], 32)
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# Similarly as in first step, Alice writes a Waku2 payload containing the handshake message and the (encrypted) transport message
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aliceStep = stepHandshake(rng[], aliceHS, transportMessage = sentTransportMessage).get()
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# Bob reads Alice's payloads, and returns the (decrypted) transport message Alice sent to him
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bobStep = stepHandshake(rng[], bobHS, readPayloadV2 = aliceStep.payload2).get()
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check:
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|
bobStep.transportMessage == sentTransportMessage
|
|
|
|
# Note that for this handshake pattern, no more message patterns are left for processing
|
|
# Another call to stepHandshake would return an empty HandshakeStepResult
|
|
# We test that extra calls to stepHandshake do not affect parties' handshake states
|
|
# and that the intermediate HandshakeStepResult are empty
|
|
let prevAliceHS = aliceHS
|
|
let prevBobHS = bobHS
|
|
|
|
let bobStep1 = stepHandshake(rng[], bobHS, transportMessage = sentTransportMessage).get()
|
|
let aliceStep1 = stepHandshake(rng[], aliceHS, readPayloadV2 = bobStep1.payload2).get()
|
|
let aliceStep2 = stepHandshake(rng[], aliceHS, transportMessage = sentTransportMessage).get()
|
|
let bobStep2 = stepHandshake(rng[], bobHS, readPayloadV2 = aliceStep2.payload2).get()
|
|
|
|
check:
|
|
aliceStep1 == default(HandshakeStepResult)
|
|
aliceStep2 == default(HandshakeStepResult)
|
|
bobStep1 == default(HandshakeStepResult)
|
|
bobStep2 == default(HandshakeStepResult)
|
|
aliceHS == prevAliceHS
|
|
bobHS == prevBobHS
|
|
|
|
#########################
|
|
# After Handshake
|
|
#########################
|
|
|
|
# We finalize the handshake to retrieve the Inbound/Outbound symmetric states
|
|
var aliceHSResult, bobHSResult: HandshakeResult
|
|
|
|
aliceHSResult = finalizeHandshake(aliceHS)
|
|
bobHSResult = finalizeHandshake(bobHS)
|
|
|
|
# We test read/write of random messages exchanged between Alice and Bob
|
|
var
|
|
payload2: PayloadV2
|
|
message: seq[byte]
|
|
readMessage: seq[byte]
|
|
defaultMessageNametagBuffer: MessageNametagBuffer
|
|
|
|
for _ in 0..10:
|
|
|
|
# Alice writes to Bob
|
|
message = randomSeqByte(rng[], 32)
|
|
payload2 = writeMessage(aliceHSResult, message, defaultMessageNametagBuffer)
|
|
readMessage = readMessage(bobHSResult, payload2, defaultMessageNametagBuffer).get()
|
|
|
|
check:
|
|
message == readMessage
|
|
|
|
# Bob writes to Alice
|
|
message = randomSeqByte(rng[], 32)
|
|
payload2 = writeMessage(bobHSResult, message, defaultMessageNametagBuffer)
|
|
readMessage = readMessage(aliceHSResult, payload2, defaultMessageNametagBuffer).get()
|
|
|
|
check:
|
|
message == readMessage
|
|
|
|
test "Noise XXpsk0 Handhshake and message encryption (short test)":
|
|
|
|
let hsPattern = NoiseHandshakePatterns["XXpsk0"]
|
|
|
|
# We generate a random psk
|
|
let psk = randomSeqByte(rng[], 32)
|
|
|
|
# We initialize Alice's and Bob's Handshake State
|
|
let aliceStaticKey = genKeyPair(rng[])
|
|
var aliceHS = initialize(hsPattern = hsPattern, staticKey = aliceStaticKey, psk = psk, initiator = true)
|
|
|
|
let bobStaticKey = genKeyPair(rng[])
|
|
var bobHS = initialize(hsPattern = hsPattern, staticKey = bobStaticKey, psk = psk)
|
|
|
|
var
|
|
sentTransportMessage: seq[byte]
|
|
aliceStep, bobStep: HandshakeStepResult
|
|
|
|
# Here the handshake starts
|
|
# Write and read calls alternate between Alice and Bob: the handhshake progresses by alternatively calling stepHandshake for each user
|
|
|
|
###############
|
|
# 1st step
|
|
###############
|
|
|
|
# We generate a random transport message
|
|
sentTransportMessage = randomSeqByte(rng[], 32)
|
|
|
|
# By being the handshake initiator, Alice writes a Waku2 payload v2 containing her handshake message
|
|
# and the (encrypted) transport message
|
|
aliceStep = stepHandshake(rng[], aliceHS, transportMessage = sentTransportMessage).get()
|
|
|
|
# Bob reads Alice's payloads, and returns the (decrypted) transport message Alice sent to him
|
|
bobStep = stepHandshake(rng[], bobHS, readPayloadV2 = aliceStep.payload2).get()
|
|
|
|
check:
|
|
bobStep.transportMessage == sentTransportMessage
|
|
|
|
###############
|
|
# 2nd step
|
|
###############
|
|
|
|
# We generate a random transport message
|
|
sentTransportMessage = randomSeqByte(rng[], 32)
|
|
|
|
# At this step, Bob writes and returns a payload
|
|
bobStep = stepHandshake(rng[], bobHS, transportMessage = sentTransportMessage).get()
|
|
|
|
# While Alice reads and returns the (decrypted) transport message
|
|
aliceStep = stepHandshake(rng[], aliceHS, readPayloadV2 = bobStep.payload2).get()
|
|
|
|
check:
|
|
aliceStep.transportMessage == sentTransportMessage
|
|
|
|
###############
|
|
# 3rd step
|
|
###############
|
|
|
|
# We generate a random transport message
|
|
sentTransportMessage = randomSeqByte(rng[], 32)
|
|
|
|
# Similarly as in first step, Alice writes a Waku2 payload containing the handshake message and the (encrypted) transport message
|
|
aliceStep = stepHandshake(rng[], aliceHS, transportMessage = sentTransportMessage).get()
|
|
|
|
# Bob reads Alice's payloads, and returns the (decrypted) transportMessage alice sent to him
|
|
bobStep = stepHandshake(rng[], bobHS, readPayloadV2 = aliceStep.payload2).get()
|
|
|
|
check:
|
|
bobStep.transportMessage == sentTransportMessage
|
|
|
|
# Note that for this handshake pattern, no more message patterns are left for processing
|
|
|
|
#########################
|
|
# After Handshake
|
|
#########################
|
|
|
|
# We finalize the handshake to retrieve the Inbound/Outbound Symmetric States
|
|
var aliceHSResult, bobHSResult: HandshakeResult
|
|
|
|
aliceHSResult = finalizeHandshake(aliceHS)
|
|
bobHSResult = finalizeHandshake(bobHS)
|
|
|
|
# We test read/write of random messages exchanged between Alice and Bob
|
|
var
|
|
payload2: PayloadV2
|
|
message: seq[byte]
|
|
readMessage: seq[byte]
|
|
defaultMessageNametagBuffer: MessageNametagBuffer
|
|
|
|
for _ in 0..10:
|
|
|
|
# Alice writes to Bob
|
|
message = randomSeqByte(rng[], 32)
|
|
payload2 = writeMessage(aliceHSResult, message, defaultMessageNametagBuffer)
|
|
readMessage = readMessage(bobHSResult, payload2, defaultMessageNametagBuffer).get()
|
|
|
|
check:
|
|
message == readMessage
|
|
|
|
# Bob writes to Alice
|
|
message = randomSeqByte(rng[], 32)
|
|
payload2 = writeMessage(bobHSResult, message, defaultMessageNametagBuffer)
|
|
readMessage = readMessage(aliceHSResult, payload2, defaultMessageNametagBuffer).get()
|
|
|
|
check:
|
|
message == readMessage
|
|
|
|
test "Noise K1K1 Handhshake and message encryption (short test)":
|
|
|
|
let hsPattern = NoiseHandshakePatterns["K1K1"]
|
|
|
|
# We initialize Alice's and Bob's Handshake State
|
|
let aliceStaticKey = genKeyPair(rng[])
|
|
let bobStaticKey = genKeyPair(rng[])
|
|
|
|
# This handshake has the following pre-message pattern:
|
|
# -> s
|
|
# <- s
|
|
# ...
|
|
# So we define accordingly the sequence of the pre-message public keys
|
|
let preMessagePKs: seq[NoisePublicKey] = @[toNoisePublicKey(getPublicKey(aliceStaticKey)), toNoisePublicKey(getPublicKey(bobStaticKey))]
|
|
|
|
var aliceHS = initialize(hsPattern = hsPattern, staticKey = aliceStaticKey, preMessagePKs = preMessagePKs, initiator = true)
|
|
var bobHS = initialize(hsPattern = hsPattern, staticKey = bobStaticKey, preMessagePKs = preMessagePKs)
|
|
|
|
var
|
|
sentTransportMessage: seq[byte]
|
|
aliceStep, bobStep: HandshakeStepResult
|
|
|
|
# Here the handshake starts
|
|
# Write and read calls alternate between Alice and Bob: the handhshake progresses by alternatively calling stepHandshake for each user
|
|
|
|
###############
|
|
# 1st step
|
|
###############
|
|
|
|
# We generate a random transport message
|
|
sentTransportMessage = randomSeqByte(rng[], 32)
|
|
|
|
# By being the handshake initiator, Alice writes a Waku2 payload v2 containing her handshake message
|
|
# and the (encrypted) transport message
|
|
aliceStep = stepHandshake(rng[], aliceHS, transportMessage = sentTransportMessage).get()
|
|
|
|
# Bob reads Alice's payloads, and returns the (decrypted) transport message Alice sent to him
|
|
bobStep = stepHandshake(rng[], bobHS, readPayloadV2 = aliceStep.payload2).get()
|
|
|
|
check:
|
|
bobStep.transportMessage == sentTransportMessage
|
|
|
|
###############
|
|
# 2nd step
|
|
###############
|
|
|
|
# We generate a random transport message
|
|
sentTransportMessage = randomSeqByte(rng[], 32)
|
|
|
|
# At this step, Bob writes and returns a payload
|
|
bobStep = stepHandshake(rng[], bobHS, transportMessage = sentTransportMessage).get()
|
|
|
|
# While Alice reads and returns the (decrypted) transport message
|
|
aliceStep = stepHandshake(rng[], aliceHS, readPayloadV2 = bobStep.payload2).get()
|
|
|
|
check:
|
|
aliceStep.transportMessage == sentTransportMessage
|
|
|
|
###############
|
|
# 3rd step
|
|
###############
|
|
|
|
# We generate a random transport message
|
|
sentTransportMessage = randomSeqByte(rng[], 32)
|
|
|
|
# Similarly as in first step, Alice writes a Waku2 payload containing the handshake_message and the (encrypted) transportMessage
|
|
aliceStep = stepHandshake(rng[], aliceHS, transportMessage = sentTransportMessage).get()
|
|
|
|
# Bob reads Alice's payloads, and returns the (decrypted) transportMessage alice sent to him
|
|
bobStep = stepHandshake(rng[], bobHS, readPayloadV2 = aliceStep.payload2).get()
|
|
|
|
check:
|
|
bobStep.transportMessage == sentTransportMessage
|
|
|
|
# Note that for this handshake pattern, no more message patterns are left for processing
|
|
|
|
#########################
|
|
# After Handshake
|
|
#########################
|
|
|
|
# We finalize the handshake to retrieve the Inbound/Outbound Symmetric States
|
|
var aliceHSResult, bobHSResult: HandshakeResult
|
|
|
|
aliceHSResult = finalizeHandshake(aliceHS)
|
|
bobHSResult = finalizeHandshake(bobHS)
|
|
|
|
# We test read/write of random messages between Alice and Bob
|
|
var
|
|
payload2: PayloadV2
|
|
message: seq[byte]
|
|
readMessage: seq[byte]
|
|
defaultMessageNametagBuffer: MessageNametagBuffer
|
|
|
|
for _ in 0..10:
|
|
|
|
# Alice writes to Bob
|
|
message = randomSeqByte(rng[], 32)
|
|
payload2 = writeMessage(aliceHSResult, message, defaultMessageNametagBuffer)
|
|
readMessage = readMessage(bobHSResult, payload2, defaultMessageNametagBuffer).get()
|
|
|
|
check:
|
|
message == readMessage
|
|
|
|
# Bob writes to Alice
|
|
message = randomSeqByte(rng[], 32)
|
|
payload2 = writeMessage(bobHSResult, message, defaultMessageNametagBuffer)
|
|
readMessage = readMessage(aliceHSResult, payload2, defaultMessageNametagBuffer).get()
|
|
|
|
check:
|
|
message == readMessage
|
|
|
|
|
|
test "Noise XK1 Handhshake and message encryption (short test)":
|
|
|
|
let hsPattern = NoiseHandshakePatterns["XK1"]
|
|
|
|
# We initialize Alice's and Bob's Handshake State
|
|
let aliceStaticKey = genKeyPair(rng[])
|
|
let bobStaticKey = genKeyPair(rng[])
|
|
|
|
# This handshake has the following pre-message pattern:
|
|
# <- s
|
|
# ...
|
|
# So we define accordingly the sequence of the pre-message public keys
|
|
let preMessagePKs: seq[NoisePublicKey] = @[toNoisePublicKey(getPublicKey(bobStaticKey))]
|
|
|
|
var aliceHS = initialize(hsPattern = hsPattern, staticKey = aliceStaticKey, preMessagePKs = preMessagePKs, initiator = true)
|
|
var bobHS = initialize(hsPattern = hsPattern, staticKey = bobStaticKey, preMessagePKs = preMessagePKs)
|
|
|
|
var
|
|
sentTransportMessage: seq[byte]
|
|
aliceStep, bobStep: HandshakeStepResult
|
|
|
|
# Here the handshake starts
|
|
# Write and read calls alternate between Alice and Bob: the handhshake progresses by alternatively calling stepHandshake for each user
|
|
|
|
###############
|
|
# 1st step
|
|
###############
|
|
|
|
# We generate a random transport message
|
|
sentTransportMessage = randomSeqByte(rng[], 32)
|
|
|
|
# By being the handshake initiator, Alice writes a Waku2 payload v2 containing her handshake message
|
|
# and the (encrypted) transport message
|
|
aliceStep = stepHandshake(rng[], aliceHS, transportMessage = sentTransportMessage).get()
|
|
|
|
# Bob reads Alice's payloads, and returns the (decrypted) transport message Alice sent to him
|
|
bobStep = stepHandshake(rng[], bobHS, readPayloadV2 = aliceStep.payload2).get()
|
|
|
|
check:
|
|
bobStep.transportMessage == sentTransportMessage
|
|
|
|
###############
|
|
# 2nd step
|
|
###############
|
|
|
|
# We generate a random transport message
|
|
sentTransportMessage = randomSeqByte(rng[], 32)
|
|
|
|
# At this step, Bob writes and returns a payload
|
|
bobStep = stepHandshake(rng[], bobHS, transportMessage = sentTransportMessage).get()
|
|
|
|
# While Alice reads and returns the (decrypted) transport message
|
|
aliceStep = stepHandshake(rng[], aliceHS, readPayloadV2 = bobStep.payload2).get()
|
|
|
|
check:
|
|
aliceStep.transportMessage == sentTransportMessage
|
|
|
|
###############
|
|
# 3rd step
|
|
###############
|
|
|
|
# We generate a random transport message
|
|
sentTransportMessage = randomSeqByte(rng[], 32)
|
|
|
|
# Similarly as in first step, Alice writes a Waku2 payload containing the handshake message and the (encrypted) transport message
|
|
aliceStep = stepHandshake(rng[], aliceHS, transportMessage = sentTransportMessage).get()
|
|
|
|
# Bob reads Alice's payloads, and returns the (decrypted) transport message Alice sent to him
|
|
bobStep = stepHandshake(rng[], bobHS, readPayloadV2 = aliceStep.payload2).get()
|
|
|
|
check:
|
|
bobStep.transportMessage == sentTransportMessage
|
|
|
|
# Note that for this handshake pattern, no more message patterns are left for processing
|
|
|
|
#########################
|
|
# After Handshake
|
|
#########################
|
|
|
|
# We finalize the handshake to retrieve the Inbound/Outbound Symmetric States
|
|
var aliceHSResult, bobHSResult: HandshakeResult
|
|
|
|
aliceHSResult = finalizeHandshake(aliceHS)
|
|
bobHSResult = finalizeHandshake(bobHS)
|
|
|
|
# We test read/write of random messages exchanged between Alice and Bob
|
|
var
|
|
payload2: PayloadV2
|
|
message: seq[byte]
|
|
readMessage: seq[byte]
|
|
defaultMessageNametagBuffer: MessageNametagBuffer
|
|
|
|
for _ in 0..10:
|
|
|
|
# Alice writes to Bob
|
|
message = randomSeqByte(rng[], 32)
|
|
payload2 = writeMessage(aliceHSResult, message, defaultMessageNametagBuffer)
|
|
readMessage = readMessage(bobHSResult, payload2, defaultMessageNametagBuffer).get()
|
|
|
|
check:
|
|
message == readMessage
|
|
|
|
# Bob writes to Alice
|
|
message = randomSeqByte(rng[], 32)
|
|
payload2 = writeMessage(bobHSResult, message, defaultMessageNametagBuffer)
|
|
readMessage = readMessage(aliceHSResult, payload2, defaultMessageNametagBuffer).get()
|
|
|
|
check:
|
|
message == readMessage
|