nim-eth/eth/trie/hexary_proof_verification.nim

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# proof verification
# Copyright (c) 2022-2023 Status Research & Development GmbH
# Licensed and distributed under either of
# * MIT license (license terms in the root directory or at https://opensource.org/licenses/MIT).
# * Apache v2 license (license terms in the root directory or at https://www.apache.org/licenses/LICENSE-2.0).
# at your option. This file may not be copied, modified, or distributed except according to those terms.
{.push raises: [].}
import
std/[tables, options, sequtils],
2024-05-30 12:46:57 +00:00
results,
nimcrypto/[keccak, hash],
".."/rlp,
"."/[trie_defs, nibbles, db]
type
NextNodeKind = enum
EmptyValue, HashNode, ValueNode
NextNodeResult = object
case kind: NextNodeKind
of EmptyValue:
discard
of HashNode:
nextNodeHash: seq[byte]
restOfTheKey: NibblesSeq
of ValueNode:
value: seq[byte]
MptProofVerificationKind* = enum
ValidProof, InvalidProof, MissingKey
MptProofVerificationResult* = object
case kind*: MptProofVerificationKind
of MissingKey:
discard
of InvalidProof:
errorMsg*: string
of ValidProof:
value*: seq[byte]
func missingKey(): MptProofVerificationResult =
return MptProofVerificationResult(kind: MissingKey)
func invalidProof(msg: string): MptProofVerificationResult =
return MptProofVerificationResult(kind: InvalidProof, errorMsg: msg)
func validProof(value: seq[byte]): MptProofVerificationResult =
return MptProofVerificationResult(kind: ValidProof, value: value)
func isValid*(res: MptProofVerificationResult): bool =
return res.kind == ValidProof
func isMissing*(res: MptProofVerificationResult): bool =
return res.kind == MissingKey
proc getListLen(rlp: Rlp): Result[int, string] =
try:
return ok(rlp.listLen)
except RlpError as e:
return err(e.msg)
proc getListElem(rlp: Rlp, idx: int): Result[Rlp, string] =
if not rlp.isList:
return err("rlp element is not a list")
try:
return ok(rlp.listElem(idx))
except RlpError as e:
return err(e.msg)
proc blobBytes(rlp: Rlp): Result[seq[byte], string] =
try:
return ok(rlp.toBytes)
except RlpError as e:
return err(e.msg)
func rawBytesSeq(b: openArray[byte]): seq[byte] =
toSeq(b)
proc getRawRlpBytes(rlp: Rlp): Result[seq[byte], string] =
try :
return ok(rawBytesSeq(rlp.rawData))
except RlpError as e:
return err(e.msg)
proc getNextNode(nodeRlp: Rlp, key: NibblesSeq): Result[NextNodeResult, string] =
var currNode = nodeRlp
var restKey = key
template handleNextRef(nextRef: Rlp, keyLen: int) =
if not nextRef.hasData:
return err("invalid reference")
if nextRef.isList:
let rawBytes = ? nextRef.getRawRlpBytes()
if len(rawBytes) > 32:
return err("Embedded node longer than 32 bytes")
else:
currNode = nextRef
restKey = restKey.slice(keyLen)
else:
let nodeBytes = ? nextRef.blobBytes()
if len(nodeBytes) == 32:
return ok(
NextNodeResult(
kind: HashNode,
nextNodeHash: nodeBytes,
restOfTheKey: restKey.slice(keyLen)
)
)
elif len(nodeBytes) == 0:
return ok(NextNodeResult(kind: EmptyValue))
else:
return err("reference rlp blob should have 0 or 32 bytes")
while true:
let listLen = ? currNode.getListLen()
case listLen
of 2:
let
firstElem = ? currNode.getListElem(0)
blobBytes = ? firstElem.blobBytes()
let (isLeaf, k) = hexPrefixDecode blobBytes
# Paths have diverged, return empty result
if len(restKey) < len(k) or k != restKey.slice(0, len(k)):
return ok(NextNodeResult(kind: EmptyValue))
let nextRef = ? currNode.getListElem(1)
if isLeaf:
let blobBytes = ? nextRef.blobBytes()
return ok(NextNodeResult(kind: ValueNode, value: blobBytes))
handleNextRef(nextRef, len(k))
of 17:
if len(restKey) == 0:
let value = ? currNode.getListElem(16)
if not value.hasData():
return err("expected branch terminator")
if value.isList():
return err("branch value cannot be list")
if value.isEmpty():
return ok(NextNodeResult(kind: EmptyValue))
else:
let bytes = ? value.blobBytes()
return ok(NextNodeResult(kind: ValueNode, value: bytes))
else:
let nextRef = ? currNode.getListElem(restKey[0].int)
handleNextRef(nextRef, 1)
else:
return err("Invalid list node ")
proc verifyProof(
db: TrieDatabaseRef,
rootHash: seq[byte],
key: seq[byte]): Result[Option[seq[byte]], string] =
var currentKey = initNibbleRange(key)
var currentHash = rootHash
while true:
let node = db.get(currentHash)
if len(node) == 0:
return err("missing expected node")
let next = ? getNextNode(rlpFromBytes(node), currentKey)
case next.kind
of EmptyValue:
return ok(none(seq[byte]))
of ValueNode:
return ok(some(next.value))
of HashNode:
currentKey = next.restOfTheKey
currentHash = next.nextNodeHash
proc verifyMptProof*(
branch: seq[seq[byte]],
rootHash: Hash32,
key: seq[byte],
value: seq[byte]): MptProofVerificationResult =
## Verifies provided proof of inclusion (trie branch) against provided trie
## root hash.
## Distinguishes 3 possible results:
## - proof is valid but key is not part of the trie
## - proof is invalid
## - proof is valid
## In case of valid proof, value is extracted from the leaf node and compared
## against provided value
##
## Main difference between this function and hexary.isValidBranch() is that
## this function is meant for dealing with input from untrusted sources so:
## - it should not have hidden assertion
## - it should not have surprising exceptions
## - it parses mpt nodes more strictly
##
## hexary.isValidBranch() is implemented via hexary trie `get` method which
## may contain some checks important for integrity of the trie therefore is
## is not really safe when receiving input from untrusted source.
if len(branch) == 0:
return invalidProof("empty branch")
var db = newMemoryDB()
for node in branch:
if len(node) == 0:
return invalidProof("empty mpt node in proof")
let nodeHash = keccak256(node)
db.put(nodeHash.data, node)
let
hashBytes: seq[byte] = toSeq(rootHash.data)
proofVerificationResult = verifyProof(db, hashBytes, key)
if proofVerificationResult.isErr:
return invalidProof(proofVerificationResult.error)
let maybeProofValue = proofVerificationResult.get()
if maybeProofValue.isNone():
return missingKey()
let proofValue = maybeProofValue.unsafeGet()
if proofValue == value:
return validProof(proofValue)
else:
return invalidProof("proof does not contain expected value")