nimbus-eth2/beacon_chain/ssz.nim

# beacon_chain
# Copyright (c) 2018 Status Research & Development GmbH
# Licensed and distributed under either of
#   * MIT license (license terms in the root directory or at http://opensource.org/licenses/MIT).
#   * Apache v2 license (license terms in the root directory or at http://www.apache.org/licenses/LICENSE-2.0).
# at your option. This file may not be copied, modified, or distributed except according to those terms.

# SSZ Serialization (simple serialize)
# See https://github.com/ethereum/eth2.0-specs/blob/master/specs/simple-serialize.md

import
  endians, typetraits, options, algorithm,
  eth/common, nimcrypto/blake2,
  ./spec/[crypto, datatypes, digest]

# ################### Helper functions ###################################

# toBytesSSZ convert simple fixed-length types to their SSZ wire representation
func toBytesSSZ(x: SomeInteger): array[sizeof(x), byte] =
  ## Convert directly to bytes the size of the int. (e.g. ``uint16 = 2 bytes``)
  ## All integers are serialized as **little endian**.

  when x.sizeof == 8: littleEndian64(result.addr, x.unsafeAddr)
  elif x.sizeof == 4: littleEndian32(result.addr, x.unsafeAddr)
  elif x.sizeof == 2: littleEndian16(result.addr, x.unsafeAddr)
  elif x.sizeof == 1: copyMem(result.addr, x.unsafeAddr, sizeof(result))
  else: {.fatal: "Unsupported type serialization: " & $(type(x)).name.}

func toBytesSSZ(x: ValidatorIndex): array[3, byte] =
  ## Integers are all encoded as little endian and not padded
  let v = x.uint32
  result[0] = byte(v and 0xff)
  result[1] = byte((v shr 8) and 0xff)
  result[2] = byte((v shr 16) and 0xff)

func toBytesSSZ(x: bool): array[1, byte] =
  [if x: 1'u8 else: 0'u8]

func toBytesSSZ(x: EthAddress): array[sizeof(x), byte] = x
func toBytesSSZ(x: Eth2Digest): array[32, byte] = x.data

# TODO these two are still being debated:
# https://github.com/ethereum/eth2.0-specs/issues/308#issuecomment-447026815
func toBytesSSZ(x: ValidatorPubKey|ValidatorSig): auto = x.getBytes()

type
  TrivialTypes =
    # Types that serialize down to a fixed-length array - most importantly,
    # these values don't carry a length prefix in the final encoding. toBytesSSZ
    # provides the actual nim-type-to-bytes conversion.
    # TODO think about this for a bit - depends where the serialization of
    #      validator keys ends up going..
    # TODO can't put ranges like ValidatorIndex in here:
    #      https://github.com/nim-lang/Nim/issues/10027
    SomeInteger | EthAddress | Eth2Digest | ValidatorPubKey | ValidatorSig |
      bool

func sszLen(v: TrivialTypes): int = toBytesSSZ(v).len
func sszLen(v: ValidatorIndex): int = toBytesSSZ(v).len

func sszLen(v: object | tuple): int =
  result = 4 # Length
  for field in v.fields:
    result += sszLen(type field)

func sszLen(v: seq | array): int =
  result = 4 # Length
  for i in v:
    result += sszLen(i)

# fromBytesSSZUnsafe copy wire representation to a Nim variable, assuming
# there's enough data in the buffer
func fromBytesSSZUnsafe(T: typedesc[SomeInteger], data: pointer): T =
  ## Convert directly to bytes the size of the int. (e.g. ``uint16 = 2 bytes``)
  ## All integers are serialized as **little endian**.
  ## TODO: Assumes data points to a sufficiently large buffer

  # TODO: any better way to get a suitably aligned buffer in nim???
  # see also: https://github.com/nim-lang/Nim/issues/9206
  var tmp: uint64
  var alignedBuf = cast[ptr byte](tmp.addr)
  copyMem(alignedBuf, data, result.sizeof)

  when result.sizeof == 8: littleEndian64(result.addr, alignedBuf)
  elif result.sizeof == 4: littleEndian32(result.addr, alignedBuf)
  elif result.sizeof == 2: littleEndian16(result.addr, alignedBuf)
  elif result.sizeof == 1: copyMem(result.addr, alignedBuf, sizeof(result))
  else: {.fatal: "Unsupported type deserialization: " & $(type(result)).name.}

func fromBytesSSZUnsafe(T: typedesc[bool], data: pointer): T =
  # TODO: spec doesn't say what to do if the value is >1 - we'll use the C
  #       definition for now, but maybe this should be a parse error instead?
  fromBytesSSZUnsafe(uint8, data) != 0

func fromBytesSSZUnsafe(T: typedesc[ValidatorIndex], data: pointer): T =
  ## Integers are all encoded as littleendian and not padded
  var tmp: uint32
  let p = cast[ptr UncheckedArray[byte]](data)
  tmp = tmp or uint32(p[0])
  tmp = tmp or uint32(p[1]) shl 8
  tmp = tmp or uint32(p[2]) shl 16
  result = tmp.ValidatorIndex

func fromBytesSSZUnsafe(T: typedesc[EthAddress], data: pointer): T =
  copyMem(result.addr, data, sizeof(result))

func fromBytesSSZUnsafe(T: typedesc[Eth2Digest], data: pointer): T =
  copyMem(result.data.addr, data, sizeof(result.data))

proc deserialize[T: TrivialTypes](
    dest: var T, offset: var int, data: openArray[byte]): bool =
  # TODO proc because milagro is problematic
  if offset + sszLen(dest) > data.len():
    false
  else:
    when T is (ValidatorPubKey|ValidatorSig):
      if dest.init(data[offset..data.len-1]):
        offset += sszLen(dest)
        true
      else:
        false
    else:
      dest = fromBytesSSZUnsafe(T, data[offset].unsafeAddr)
      offset += sszLen(dest)
      true

func deserialize(
    dest: var ValidatorIndex, offset: var int, data: openArray[byte]): bool =
  if offset + sszLen(dest) > data.len():
    false
  else:
    dest = fromBytesSSZUnsafe(ValidatorIndex, data[offset].unsafeAddr)
    offset += sszLen(dest)
    true

func deserialize[T: enum](dest: var T, offset: var int, data: openArray[byte]): bool =
  # TODO er, verify the size here, probably an uint64 but...
  var tmp: uint64
  if not deserialize(tmp, offset, data):
    false
  else:
    # TODO what to do with out-of-range values?? rejecting means breaking
    #      forwards compatibility..
    dest = cast[T](tmp)
    true

proc deserialize[T: not (enum|TrivialTypes|ValidatorIndex)](
    dest: var T, offset: var int, data: openArray[byte]): bool =
  # Length in bytes, followed by each item
  var totalLen: uint32
  if not deserialize(totalLen, offset, data): return false

  if offset + totalLen.int > data.len(): return false

  let itemEnd = offset + totalLen.int
  when T is seq:
    # Items are of homogenous type, but not necessarily homogenous length,
    # cannot pre-allocate item list generically
    while offset < itemEnd:
      dest.setLen dest.len + 1
      if not deserialize(dest[^1], offset, data): return false
  elif T is array:
    var i = 0
    while offset < itemEnd:
      if not deserialize(dest[i], offset, data): return false
      i += 1
      if i > dest.len: return false
  else:
    for field in dest.fields:
      if not deserialize(field, offset, data):  return false
    if offset != itemEnd: return false

  true

func serialize(dest: var seq[byte], src: TrivialTypes) =
  dest.add src.toBytesSSZ()
func serialize(dest: var seq[byte], src: ValidatorIndex) =
  dest.add src.toBytesSSZ()

func serialize(dest: var seq[byte], x: enum) =
  # TODO er, verify the size here, probably an uint64 but...
  serialize dest, uint64(x)

func serialize[T: not enum](dest: var seq[byte], src: T) =
  let lenPos = dest.len()

  # Length is a prefix, so we'll put a dummy 0 here and fill it after
  # serializing
  dest.add toBytesSSZ(0'u32)

  when T is seq|array:
    # If you get an error here that looks like:
    # type mismatch: got <type range 0..8191(uint64)>
    # you just used an unsigned int for an array index thinking you'd get
    # away with it (surprise, surprise: you can't, uints are crippled!)
    # https://github.com/nim-lang/Nim/issues/9984
    for val in src:
      serialize dest, val
  else:
    when defined(debugFieldSizes) and T is (BeaconState | BeaconBlock):
      # for research/serialized_sizes, remove when appropriate
      for name, field in src.fieldPairs:
        let start = dest.len()
        serialize dest, field
        let sz = dest.len() - start
        debugEcho(name, ": ", sz)
    else:
      for field in src.fields:
        serialize dest, field

  # Write size (we only know it once we've serialized the object!)
  var objLen = dest.len() - lenPos - 4
  littleEndian32(dest[lenPos].addr, objLen.addr)

# ################### Core functions ###################################

proc deserialize*(data: openArray[byte],
                  typ: typedesc): auto {.inline.} =
  # TODO: returns Option[typ]: https://github.com/nim-lang/Nim/issues/9195
  var ret: typ
  var offset: int
  if not deserialize(ret, offset, data): none(typ)
  else: some(ret)

func serialize*(value: auto): seq[byte] =
  serialize(result, value)

# ################### Hashing ###################################

# Sample hash_tree_root implementation based on:
# https://github.com/ethereum/eth2.0-specs/blob/a9328157a87451ee4f372df272ece158b386ec41/specs/simple-serialize.md
# TODO Probably wrong - the spec is pretty bare-bones and no test vectors yet

const CHUNK_SIZE = 128

# ################### Hashing helpers ###################################

# TODO varargs openarray, anyone?
template withHash(body: untyped): array[32, byte] =
  let tmp = withEth2Hash: body
  toBytesSSZ tmp

func hash(a: openArray[byte]): array[32, byte] =
  withHash:
    h.update(a)

func hash(a, b: openArray[byte]): array[32, byte] =
  withHash:
    h.update(a)
    h.update(b)

# TODO: er, how is this _actually_ done?
# Mandatory bug: https://github.com/nim-lang/Nim/issues/9825
func empty(T: typedesc): T = discard
const emptyChunk = empty(array[CHUNK_SIZE, byte])

func merkleHash[T](lst: openArray[T]): array[32, byte]

# ################### Hashing interface ###################################

func hash_tree_root*(x: SomeInteger | bool): array[sizeof(x), byte] =
  ## Convert directly to bytes the size of the int. (e.g. ``uint16 = 2 bytes``)
  ## All integers are serialized as **little endian**.
  toBytesSSZ(x)

func hash_tree_root*(x: ValidatorIndex): array[3, byte] =
  ## Convert directly to bytes the size of the int. (e.g. ``uint16 = 2 bytes``)
  ## All integers are serialized as **little endian**.
  toBytesSSZ(x)

func hash_tree_root*(x: EthAddress): array[sizeof(x), byte] =
  ## Addresses copied as-is
  toBytesSSZ(x)

func hash_tree_root*(x: Eth2Digest): array[32, byte] =
  ## Hash32 copied as-is
  toBytesSSZ(x)

func hash_tree_root*(x: openArray[byte]): array[32, byte] =
  ## Blobs are hashed
  hash(x)

func hash_tree_root*[T: seq|array](x: T): array[32, byte] =
  ## Sequences are tree-hashed
  merkleHash(x)

func hash_tree_root*[T: object|tuple](x: T): array[32, byte] =
  ## Containers have their fields recursively hashed, concatenated and hashed
  withHash:
    for field in x.fields:
      h.update hash_tree_root(field)

# #################################
# hash_tree_root not part of official spec
func hash_tree_root*(x: enum): array[8, byte] =
  ## TODO - Warning ⚠️: not part of the spec
  ## as of https://github.com/ethereum/beacon_chain/pull/133/files
  ## This is a "stub" needed for BeaconBlock hashing
  static: assert x.sizeof == 1 # Check that the enum fits in 1 byte
  # TODO We've put enums where the spec uses `uint64` - maybe we should not be
  # using enums?
  hash_tree_root(uint64(x))

func hash_tree_root*(x: ValidatorPubKey): array[32, byte] =
  ## TODO - Warning ⚠️: not part of the spec
  ## as of https://github.com/ethereum/beacon_chain/pull/133/files
  ## This is a "stub" needed for BeaconBlock hashing
  x.getBytes().hash()

func hash_tree_root*(x: ValidatorSig): array[32, byte] =
  ## TODO - Warning ⚠️: not part of the spec
  ## as of https://github.com/ethereum/beacon_chain/pull/133/files
  ## This is a "stub" needed for BeaconBlock hashing
  x.getBytes().hash()

func hash_tree_root_final*(x: object|tuple): Eth2Digest =
  # TODO suggested for spec:
  # https://github.com/ethereum/eth2.0-specs/issues/276
  # only for objects now, else the padding would have to be implemented - not
  # needed yet..
  Eth2Digest(data: hash_tree_root(x))

# ################### Tree hash ###################################

func merkleHash[T](lst: openArray[T]): array[32, byte] =
  ## Merkle tree hash of a list of homogenous, non-empty items

  # TODO: the heap allocations here can be avoided by computing the merkle tree
  #      recursively, but for now keep things simple and aligned with upstream

  # Store length of list (to compensate for non-bijectiveness of padding)
  var dataLen: array[32, byte]
  var lstLen = uint64(len(lst))
  littleEndian64(dataLen[32-8].addr, lstLen.addr)

  # Divide into chunks
  var chunkz: seq[seq[byte]]

  if len(lst) == 0:
    chunkz.add @emptyChunk
  elif sizeof(hash_tree_root(lst[0])) < CHUNK_SIZE:
    # See how many items fit in a chunk
    let itemsPerChunk = CHUNK_SIZE div sizeof(hash_tree_root(lst[0]))

    chunkz.setLen((len(lst) + itemsPerChunk - 1) div itemsPerChunk)

    # Build a list of chunks based on the number of items in the chunk
    for i in 0..<chunkz.len:
      for j in 0..<itemsPerChunk:
        if i == chunkz.len - 1:
          let idx = i * itemsPerChunk + j
          if idx >= lst.len: break # Last chunk may be partial!
        chunkz[i].add hash_tree_root(lst[i * itemsPerChunk + j])
  else:
    # Leave large items alone
    chunkz.setLen(len(lst))
    for i in 0..<len(lst):
      chunkz[i].add hash_tree_root(lst[i])

  while chunkz.len() > 1:
    if chunkz.len() mod 2 == 1:
      chunkz.add @emptyChunk
    for i in 0..<(chunkz.len div 2):
      # As tradition dictates - one feature, at least one nim bug:
      # https://github.com/nim-lang/Nim/issues/9684
      let tmp = @(hash(chunkz[i * 2], chunkz[i * 2 + 1]))
      chunkz[i] = tmp

    chunkz.setLen(chunkz.len div 2)

  hash(chunkz[0], dataLen)