nim-eth/eth/trie/sparse_proofs.nim

import
  stew/ranges/[typedranges, bitranges],
  trie_defs, db, trie_utils

const
  treeHeight* = 160
  pathByteLen* = treeHeight div 8
  emptyLeafNodeHash* = blankStringHash

proc makeInitialEmptyTreeHash(H: static[int]): array[H, ByteRange] =
  result[^1] = @(emptyLeafNodeHash.data).toRange
  for i in countdown(H-1, 1):
    result[i - 1] = keccakHash(result[i], result[i])

# cannot yet turn this into compile time constant
let emptyNodeHashes* = makeInitialEmptyTreeHash(treeHeight)

# VerifyProof verifies a Merkle proof.
proc verifyProofAux*(proof: seq[ByteRange], root, key, value: ByteRange): bool =
  doAssert(root.len == 32)
  doAssert(key.len == pathByteLen)
  var
    path = MutByteRange(key).bits
    curHash = keccakHash(value)

  if proof.len != treeHeight: return false

  for i in countdown(treeHeight - 1, 0):
    var node = proof[i]
    if node.len != 32: return false
    if path[i]: # right
      # reuse curHash without more alloc
      curHash.keccakHash(node, curHash)
    else:
      curHash.keccakHash(curHash, node)

  result = curHash == root

template verifyProof*(proof: seq[ByteRange], root, key, value: distinct BytesContainer): bool =
  verifyProofAux(proof, root.toRange, key.toRange, value.toRange)

proc count(b: BitRange, val: bool): int =
  for c in b:
    if c == val: inc result

# CompactProof compacts a proof, to reduce its size.
proc compactProof*(proof: seq[ByteRange]): seq[ByteRange] =
  if proof.len != treeHeight: return

  var
    data = newRange[byte](pathByteLen)
    bits = MutByteRange(data).bits

  result = @[]
  result.add data
  for i in 0 ..< treeHeight:
    var node = proof[i]
    if node == emptyNodeHashes[i]:
      bits[i] = true
    else:
      result.add node

# decompactProof decompacts a proof, so that it can be used for VerifyProof.
proc decompactProof*(proof: seq[ByteRange]): seq[ByteRange] =
  if proof.len == 0: return
  if proof[0].len != pathByteLen: return
  var bits = MutByteRange(proof[0]).bits
  if proof.len != bits.count(false) + 1: return
  result = newSeq[ByteRange](treeHeight)

  var pos = 1 # skip bits
  for i in 0 ..< treeHeight:
    if bits[i]:
      result[i] = emptyNodeHashes[i]
    else:
      result[i] = proof[pos]
      inc pos

# verifyCompactProof verifies a compacted Merkle proof.
proc verifyCompactProofAux*(proof: seq[ByteRange], root, key, value: ByteRange): bool =
  var decompactedProof = decompactProof(proof)
  if decompactedProof.len == 0: return false
  verifyProofAux(decompactedProof, root, key, value)

template verifyCompactProof*(proof: seq[ByteRange], root, key, value: distinct BytesContainer): bool =
  verifyCompactProofAux(proof, root.toRange, key.toRange, value.toRange)
Moved rlp and trie to eth 2019-02-05 12:01:10 +00:00			`import`
std_shims -> stew 2019-07-07 09:55:17 +00:00			`stew/ranges/[typedranges, bitranges],`
Moved rlp and trie to eth 2019-02-05 12:01:10 +00:00			`trie_defs, db, trie_utils`

			`const`
			`treeHeight* = 160`
			`pathByteLen* = treeHeight div 8`
			`emptyLeafNodeHash* = blankStringHash`

			`proc makeInitialEmptyTreeHash(H: static[int]): array[H, ByteRange] =`
			`result[^1] = @(emptyLeafNodeHash.data).toRange`
			`for i in countdown(H-1, 1):`
			`result[i - 1] = keccakHash(result[i], result[i])`

			`# cannot yet turn this into compile time constant`
			`let emptyNodeHashes* = makeInitialEmptyTreeHash(treeHeight)`

			`# VerifyProof verifies a Merkle proof.`
			`proc verifyProofAux*(proof: seq[ByteRange], root, key, value: ByteRange): bool =`
assert() -> doAssert() 2019-03-13 22:15:26 +00:00			`doAssert(root.len == 32)`
			`doAssert(key.len == pathByteLen)`
Moved rlp and trie to eth 2019-02-05 12:01:10 +00:00			`var`
			`path = MutByteRange(key).bits`
			`curHash = keccakHash(value)`

			`if proof.len != treeHeight: return false`

			`for i in countdown(treeHeight - 1, 0):`
			`var node = proof[i]`
			`if node.len != 32: return false`
			`if path[i]: # right`
			`# reuse curHash without more alloc`
			`curHash.keccakHash(node, curHash)`
			`else:`
			`curHash.keccakHash(curHash, node)`

			`result = curHash == root`

			`template verifyProof*(proof: seq[ByteRange], root, key, value: distinct BytesContainer): bool =`
			`verifyProofAux(proof, root.toRange, key.toRange, value.toRange)`

			`proc count(b: BitRange, val: bool): int =`
			`for c in b:`
			`if c == val: inc result`

			`# CompactProof compacts a proof, to reduce its size.`
			`proc compactProof*(proof: seq[ByteRange]): seq[ByteRange] =`
			`if proof.len != treeHeight: return`

			`var`
			`data = newRange[byte](pathByteLen)`
			`bits = MutByteRange(data).bits`

			`result = @[]`
			`result.add data`
			`for i in 0 ..< treeHeight:`
			`var node = proof[i]`
			`if node == emptyNodeHashes[i]:`
			`bits[i] = true`
			`else:`
			`result.add node`

			`# decompactProof decompacts a proof, so that it can be used for VerifyProof.`
			`proc decompactProof*(proof: seq[ByteRange]): seq[ByteRange] =`
			`if proof.len == 0: return`
			`if proof[0].len != pathByteLen: return`
			`var bits = MutByteRange(proof[0]).bits`
			`if proof.len != bits.count(false) + 1: return`
			`result = newSeq[ByteRange](treeHeight)`

			`var pos = 1 # skip bits`
			`for i in 0 ..< treeHeight:`
			`if bits[i]:`
			`result[i] = emptyNodeHashes[i]`
			`else:`
			`result[i] = proof[pos]`
			`inc pos`

			`# verifyCompactProof verifies a compacted Merkle proof.`
			`proc verifyCompactProofAux*(proof: seq[ByteRange], root, key, value: ByteRange): bool =`
			`var decompactedProof = decompactProof(proof)`
			`if decompactedProof.len == 0: return false`
			`verifyProofAux(decompactedProof, root, key, value)`

			`template verifyCompactProof*(proof: seq[ByteRange], root, key, value: distinct BytesContainer): bool =`
			`verifyCompactProofAux(proof, root.toRange, key.toRange, value.toRange)`