mirror of https://github.com/status-im/nim-eth.git
257 lines
9.1 KiB
Nim
257 lines
9.1 KiB
Nim
#
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# Ethereum P2P
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# (c) Copyright 2018
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# Status Research & Development GmbH
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#
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# Licensed under either of
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# Apache License, version 2.0, (LICENSE-APACHEv2)
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# MIT license (LICENSE-MIT)
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#
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## This module implements RLPx cryptography
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{.push raises: [Defect].}
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import
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nimcrypto/[bcmode, keccak, rijndael, utils], stew/results
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from auth import ConnectionSecret
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export results
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const
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RlpHeaderLength* = 16
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RlpMacLength* = 16
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maxUInt24 = (not uint32(0)) shl 8
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type
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SecretState* = object
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## Object represents current encryption/decryption context.
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aesenc*: CTR[aes256]
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aesdec*: CTR[aes256]
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macenc*: ECB[aes256]
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emac*: keccak256
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imac*: keccak256
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RlpxError* = enum
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IncorrectMac = "rlpx: MAC verification failed"
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BufferOverrun = "rlpx: buffer overrun"
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IncompleteError = "rlpx: data incomplete"
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IncorrectArgs = "rlpx: incorrect arguments"
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RlpxHeader* = array[16, byte]
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RlpxResult*[T] = Result[T, RlpxError]
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proc roundup16*(x: int): int {.inline.} =
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## Procedure aligns `x` to
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let rem = x and 15
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if rem != 0:
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result = x + 16 - rem
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else:
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result = x
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template toa(a, b, c: untyped): untyped =
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toOpenArray((a), (b), (b) + (c) - 1)
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proc sxor[T](a: var openArray[T], b: openArray[T]) {.inline.} =
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doAssert(len(a) == len(b))
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for i in 0 ..< len(a):
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a[i] = a[i] xor b[i]
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proc initSecretState*(secrets: ConnectionSecret, context: var SecretState) =
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## Initialized `context` with values from `secrets`.
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# FIXME: Yes, the encryption is insecure,
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# see: https://github.com/ethereum/devp2p/issues/32
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# https://github.com/ethereum/py-evm/blob/master/p2p/peer.py#L159-L160
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var iv: array[context.aesenc.sizeBlock, byte]
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context.aesenc.init(secrets.aesKey, iv)
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context.aesdec = context.aesenc
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context.macenc.init(secrets.macKey)
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context.emac = secrets.egressMac
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context.imac = secrets.ingressMac
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template encryptedLength*(size: int): int =
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## Returns the number of bytes used by the entire frame of a
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## message with size `size`:
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RlpHeaderLength + roundup16(size) + 2 * RlpMacLength
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template decryptedLength*(size: int): int =
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## Returns size of decrypted message for body with length `size`.
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roundup16(size)
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proc encrypt*(c: var SecretState, header: openArray[byte],
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frame: openArray[byte],
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output: var openArray[byte]): RlpxResult[void] =
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## Encrypts `header` and `frame` using SecretState `c` context and store
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## result into `output`.
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##
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## `header` must be exactly `RlpHeaderLength` length.
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## `frame` must not be zero length.
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## `output` must be at least `encryptedLength(len(frame))` length.
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var
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tmpmac: keccak256
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aes: array[RlpHeaderLength, byte]
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let length = encryptedLength(len(frame))
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let frameLength = roundup16(len(frame))
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let headerMacPos = RlpHeaderLength
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let framePos = RlpHeaderLength + RlpMacLength
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let frameMacPos = RlpHeaderLength * 2 + frameLength
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if len(header) != RlpHeaderLength or len(frame) == 0 or length != len(output):
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return err(IncorrectArgs)
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# header_ciphertext = self.aes_enc.update(header)
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c.aesenc.encrypt(header, toa(output, 0, RlpHeaderLength))
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# mac_secret = self.egress_mac.digest()[:HEADER_LEN]
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tmpmac = c.emac
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var macsec = tmpmac.finish()
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# self.egress_mac.update(sxor(self.mac_enc(mac_secret), header_ciphertext))
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c.macenc.encrypt(toa(macsec.data, 0, RlpHeaderLength), aes)
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sxor(aes, toa(output, 0, RlpHeaderLength))
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c.emac.update(aes)
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burnMem(aes)
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# header_mac = self.egress_mac.digest()[:HEADER_LEN]
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tmpmac = c.emac
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var headerMac = tmpmac.finish()
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# frame_ciphertext = self.aes_enc.update(frame)
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copyMem(addr output[framePos], unsafeAddr frame[0], len(frame))
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c.aesenc.encrypt(toa(output, 32, frameLength), toa(output, 32, frameLength))
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# self.egress_mac.update(frame_ciphertext)
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c.emac.update(toa(output, 32, frameLength))
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# fmac_seed = self.egress_mac.digest()[:HEADER_LEN]
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tmpmac = c.emac
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var seed = tmpmac.finish()
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# mac_secret = self.egress_mac.digest()[:HEADER_LEN]
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macsec = seed
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# self.egress_mac.update(sxor(self.mac_enc(mac_secret), fmac_seed))
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c.macenc.encrypt(toa(macsec.data, 0, RlpHeaderLength), aes)
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sxor(aes, toa(seed.data, 0, RlpHeaderLength))
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c.emac.update(aes)
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burnMem(aes)
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# frame_mac = self.egress_mac.digest()[:HEADER_LEN]
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tmpmac = c.emac
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var frameMac = tmpmac.finish()
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tmpmac.clear()
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# return header_ciphertext + header_mac + frame_ciphertext + frame_mac
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copyMem(addr output[headerMacPos], addr headerMac.data[0], RlpHeaderLength)
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copyMem(addr output[frameMacPos], addr frameMac.data[0], RlpHeaderLength)
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ok()
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proc encryptMsg*(msg: openArray[byte], secrets: var SecretState): seq[byte] =
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var header: RlpxHeader
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if uint32(msg.len) > maxUInt24:
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raise newException(OverflowError, "RLPx message size exceeds limit")
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# write the frame size in the first 3 bytes of the header
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header[0] = byte((msg.len shr 16) and 0xFF)
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header[1] = byte((msg.len shr 8) and 0xFF)
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header[2] = byte(msg.len and 0xFF)
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# This is the [capability-id, context-id] in header-data
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# While not really used, this is checked in the Parity client.
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# Same as rlp.encode((0, 0))
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header[3] = 0xc2
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header[4] = 0x80
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header[5] = 0x80
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# XXX:
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# This would be safer if we use a thread-local sequ for the temporary buffer
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result = newSeq[byte](encryptedLength(msg.len))
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let s = encrypt(secrets, header, msg, result)
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s.expect("always succeeds because we call with correct buffer")
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proc getBodySize*(a: RlpxHeader): int =
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(int(a[0]) shl 16) or (int(a[1]) shl 8) or int(a[2])
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proc decryptHeader*(c: var SecretState, data: openArray[byte],
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output: var openArray[byte]): RlpxResult[void] =
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## Decrypts header `data` using SecretState `c` context and store
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## result into `output`.
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##
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## `header` must be exactly `RlpHeaderLength + RlpMacLength` length.
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## `output` must be at least `RlpHeaderLength` length.
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var
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tmpmac: keccak256
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aes: array[RlpHeaderLength, byte]
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if len(data) != RlpHeaderLength + RlpMacLength:
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return err(IncompleteError)
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if len(output) < RlpHeaderLength:
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return err(IncorrectArgs)
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# mac_secret = self.ingress_mac.digest()[:HEADER_LEN]
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tmpmac = c.imac
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var macsec = tmpmac.finish()
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# aes = self.mac_enc(mac_secret)[:HEADER_LEN]
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c.macenc.encrypt(toa(macsec.data, 0, RlpHeaderLength), aes)
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# self.ingress_mac.update(sxor(aes, header_ciphertext))
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sxor(aes, toa(data, 0, RlpHeaderLength))
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c.imac.update(aes)
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burnMem(aes)
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# expected_header_mac = self.ingress_mac.digest()[:HEADER_LEN]
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tmpmac = c.imac
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var expectMac = tmpmac.finish()
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# if not bytes_eq(expected_header_mac, header_mac):
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let headerMacPos = RlpHeaderLength
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if not equalMem(cast[pointer](unsafeAddr data[headerMacPos]),
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cast[pointer](addr expectMac.data[0]), RlpMacLength):
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result = err(IncorrectMac)
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else:
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# return self.aes_dec.update(header_ciphertext)
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c.aesdec.decrypt(toa(data, 0, RlpHeaderLength), output)
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result = ok()
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proc decryptHeaderAndGetMsgSize*(c: var SecretState,
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encryptedHeader: openArray[byte],
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outSize: var int,
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outHeader: var RlpxHeader): RlpxResult[void] =
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result = decryptHeader(c, encryptedHeader, outHeader)
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if result.isOk():
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outSize = outHeader.getBodySize
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proc decryptHeaderAndGetMsgSize*(c: var SecretState,
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encryptedHeader: openArray[byte],
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outSize: var int): RlpxResult[void] =
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var decryptedHeader: RlpxHeader
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result = decryptHeader(c, encryptedHeader, decryptedHeader)
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if result.isOk():
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outSize = decryptedHeader.getBodySize
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proc decryptBody*(c: var SecretState, data: openArray[byte], bodysize: int,
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output: var openArray[byte], outlen: var int): RlpxResult[void] =
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## Decrypts body `data` using SecretState `c` context and store
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## result into `output`.
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##
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## `data` must be at least `roundup16(bodysize) + RlpMacLength` length.
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## `output` must be at least `roundup16(bodysize)` length.
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##
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## On success completion `outlen` will hold actual size of decrypted body.
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var
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tmpmac: keccak256
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aes: array[RlpHeaderLength, byte]
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outlen = 0
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let rsize = roundup16(bodysize)
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if len(data) < rsize + RlpMacLength:
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return err(IncompleteError)
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if len(output) < rsize:
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return err(IncorrectArgs)
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# self.ingress_mac.update(frame_ciphertext)
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c.imac.update(toa(data, 0, rsize))
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tmpmac = c.imac
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# fmac_seed = self.ingress_mac.digest()[:MAC_LEN]
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var seed = tmpmac.finish()
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# self.ingress_mac.update(sxor(self.mac_enc(fmac_seed), fmac_seed))
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c.macenc.encrypt(toa(seed.data, 0, RlpHeaderLength), aes)
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sxor(aes, toa(seed.data, 0, RlpHeaderLength))
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c.imac.update(aes)
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# expected_frame_mac = self.ingress_mac.digest()[:MAC_LEN]
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tmpmac = c.imac
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var expectMac = tmpmac.finish()
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let bodyMacPos = rsize
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if not equalMem(cast[pointer](unsafeAddr data[bodyMacPos]),
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cast[pointer](addr expectMac.data[0]), RlpMacLength):
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result = err(IncorrectMac)
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else:
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c.aesdec.decrypt(toa(data, 0, rsize), output)
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outlen = bodysize
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result = ok()
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