# 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 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. # SSZ Serialization (simple serialize) # See https://github.com/ethereum/eth2.0-specs/blob/master/specs/simple-serialize.md # TODO Cannot override push, even though the function is annotated # nim-beacon-chain/beacon_chain/ssz.nim(212, 18) Error: can raise an unlisted exception: IOError #{.push raises: [Defect].} # TODO Many RVO bugs, careful # https://github.com/nim-lang/Nim/issues/14470 # https://github.com/nim-lang/Nim/issues/14126 import options, algorithm, options, strformat, typetraits, stew/[bitops2, byteutils, bitseqs, endians2, objects, varints, ptrops], stew/ranges/ptr_arith, stew/shims/macros, faststreams/[inputs, outputs, buffers], serialization, serialization/testing/tracing, ./spec/[crypto, datatypes, digest], ./ssz/[types, bytes_reader], ../nbench/bench_lab # ################### Helper functions ################################### when hasSerializationTracing: import stew/byteutils export serialization, types, bytes_reader when defined(serialization_tracing): import typetraits const bytesPerChunk = 32 bitsPerChunk = bytesPerChunk * 8 type SszReader* = object stream: InputStream SszWriter* = object stream: OutputStream SszChunksMerkleizer = object combinedChunks: ptr UncheckedArray[Eth2Digest] totalChunks: uint64 topIndex: int SizePrefixed*[T] = distinct T SszMaxSizeExceeded* = object of SerializationError VarSizedWriterCtx = object fixedParts: WriteCursor offset: int FixedSizedWriterCtx = object serializationFormat SSZ, Reader = SszReader, Writer = SszWriter, PreferedOutput = seq[byte] template bytes(x: BitSeq): untyped = seq[byte](x) template sizePrefixed*[TT](x: TT): untyped = type T = TT SizePrefixed[T](x) proc init*(T: type SszReader, stream: InputStream): T {.raises: [Defect].} = T(stream: stream) method formatMsg*( err: ref SszSizeMismatchError, filename: string): string {.gcsafe, raises: [Defect].} = try: &"SSZ size mismatch, element {err.elementSize}, actual {err.actualSszSize}, type {err.deserializedType}, file {filename}" except CatchableError: "SSZ size mismatch" template toSszType*(x: auto): auto = mixin toSszType # Please note that BitArray doesn't need any special treatment here # because it can be considered a regular fixed-size object type. when x is Slot|Epoch|ValidatorIndex|enum: uint64(x) elif x is Eth2Digest: x.data elif x is BlsCurveType: toRaw(x) elif x is ForkDigest|Version: distinctBase(x) else: x proc writeFixedSized(s: var (OutputStream|WriteCursor), x: auto) {.raises: [Defect, IOError].} = mixin toSszType when x is byte: s.write x elif x is bool: s.write byte(ord(x)) elif x is UintN: when cpuEndian == bigEndian: s.write toBytesLE(x) else: s.writeMemCopy x elif x is array: when x[0] is byte: trs "APPENDING FIXED SIZE BYTES", x s.write x else: for elem in x: trs "WRITING FIXED SIZE ARRAY ELEMENT" s.writeFixedSized toSszType(elem) elif x is tuple|object: enumInstanceSerializedFields(x, fieldName, field): trs "WRITING FIXED SIZE FIELD", fieldName s.writeFixedSized toSszType(field) else: unsupported x.type template writeOffset(cursor: var WriteCursor, offset: int) = write cursor, toBytesLE(uint32 offset) template supports*(_: type SSZ, T: type): bool = mixin toSszType anonConst compiles(fixedPortionSize toSszType(declval T)) func init*(T: type SszWriter, stream: OutputStream): T {.raises: [Defect].} = result.stream = stream template enumerateSubFields(holder, fieldVar, body: untyped) = when holder is array|HashArray: for fieldVar in holder: body else: enumInstanceSerializedFields(holder, _{.used.}, fieldVar): body proc writeVarSizeType(w: var SszWriter, value: auto) {.gcsafe.} proc beginRecord*(w: var SszWriter, TT: type): auto {.raises: [Defect].} = type T = TT when isFixedSize(T): FixedSizedWriterCtx() else: const offset = when T is array|HashArray: len(T) * offsetSize else: fixedPortionSize(T) VarSizedWriterCtx(offset: offset, fixedParts: w.stream.delayFixedSizeWrite(offset)) template writeField*(w: var SszWriter, ctx: var auto, fieldName: string, field: auto) = mixin toSszType when ctx is FixedSizedWriterCtx: writeFixedSized(w.stream, toSszType(field)) else: type FieldType = type toSszType(field) when isFixedSize(FieldType): writeFixedSized(ctx.fixedParts, toSszType(field)) else: trs "WRITING OFFSET ", ctx.offset, " FOR ", fieldName writeOffset(ctx.fixedParts, ctx.offset) let initPos = w.stream.pos trs "WRITING VAR SIZE VALUE OF TYPE ", name(FieldType) when FieldType is BitList: trs "BIT SEQ ", bytes(field) writeVarSizeType(w, toSszType(field)) ctx.offset += w.stream.pos - initPos template endRecord*(w: var SszWriter, ctx: var auto) = when ctx is VarSizedWriterCtx: finalize ctx.fixedParts proc writeSeq[T](w: var SszWriter, value: seq[T]) {.raises: [Defect, IOError].} = # Please note that `writeSeq` exists in order to reduce the code bloat # produced from generic instantiations of the unique `List[N, T]` types. when isFixedSize(T): trs "WRITING LIST WITH FIXED SIZE ELEMENTS" for elem in value: w.stream.writeFixedSized toSszType(elem) trs "DONE" else: trs "WRITING LIST WITH VAR SIZE ELEMENTS" var offset = value.len * offsetSize var cursor = w.stream.delayFixedSizeWrite offset for elem in value: cursor.writeFixedSized uint32(offset) let initPos = w.stream.pos w.writeVarSizeType toSszType(elem) offset += w.stream.pos - initPos finalize cursor trs "DONE" proc writeVarSizeType(w: var SszWriter, value: auto) {.raises: [Defect, IOError].} = trs "STARTING VAR SIZE TYPE" mixin toSszType type T = type toSszType(value) when T is List|HashList: # We reduce code bloat by forwarding all `List` types to a general `seq[T]` proc. writeSeq(w, asSeq value) elif T is BitList: # ATTENTION! We can reuse `writeSeq` only as long as our BitList type is implemented # to internally match the binary representation of SSZ BitLists in memory. writeSeq(w, bytes value) elif T is HashArray: trs "WRITING HASHARRAY" var ctx = beginRecord(w, T.T) enumerateSubFields(value, field): writeField w, ctx, astToStr(field), field.data endRecord w, ctx elif T is object|tuple|array: trs "WRITING OBJECT OR ARRAY" var ctx = beginRecord(w, T) enumerateSubFields(value, field): writeField w, ctx, astToStr(field), field endRecord w, ctx else: unsupported type(value) proc writeValue*(w: var SszWriter, x: auto) {.gcsafe, raises: [Defect, IOError].} = mixin toSszType type T = type toSszType(x) when isFixedSize(T): w.stream.writeFixedSized toSszType(x) else: w.writeVarSizeType toSszType(x) func sszSize*(value: auto): int {.gcsafe, raises: [Defect].} func sszSizeForVarSizeList[T](value: openarray[T]): int = result = len(value) * offsetSize for elem in value: result += sszSize(toSszType elem) func sszSize*(value: auto): int {.gcsafe, raises: [Defect].} = mixin toSszType type T = type toSszType(value) when isFixedSize(T): anonConst fixedPortionSize(T) elif T is array|List|HashList|HashArray: type E = ElemType(T) when isFixedSize(E): len(value) * anonConst(fixedPortionSize(E)) elif T is HashArray: sszSizeForVarSizeList(value.data) elif T is array: sszSizeForVarSizeList(value) else: sszSizeForVarSizeList(asSeq value) elif T is BitList: return len(bytes(value)) elif T is object|tuple: result = anonConst fixedPortionSize(T) enumInstanceSerializedFields(value, _{.used.}, field): type FieldType = type toSszType(field) when not isFixedSize(FieldType): result += sszSize(toSszType field) else: unsupported T proc writeValue*[T](w: var SszWriter, x: SizePrefixed[T]) {.raises: [Defect, IOError].} = var cursor = w.stream.delayVarSizeWrite(10) let initPos = w.stream.pos w.writeValue T(x) let length = uint64(w.stream.pos - initPos) when false: discard # TODO varintBytes is sub-optimal at the moment # cursor.writeAndFinalize length.varintBytes else: var buf: VarintBuffer buf.writeVarint length cursor.finalWrite buf.writtenBytes proc readValue*[T](r: var SszReader, val: var T) {.raises: [Defect, MalformedSszError, SszSizeMismatchError, IOError].} = when isFixedSize(T): const minimalSize = fixedPortionSize(T) if r.stream.readable(minimalSize): readSszValue(r.stream.read(minimalSize), val) else: raise newException(MalformedSszError, "SSZ input of insufficient size") else: # TODO Read the fixed portion first and precisely measure the size of # the dynamic portion to consume the right number of bytes. readSszValue(r.stream.read(r.stream.len.get), val) const zeroChunk = default array[32, byte] func hash(a, b: openArray[byte]): Eth2Digest = result = withEth2Hash: trs "MERGING BRANCHES " trs toHex(a) trs toHex(b) h.update a h.update b trs "HASH RESULT ", result func mergeBranches(existing: Eth2Digest, newData: openarray[byte]): Eth2Digest = result = withEth2Hash: trs "MERGING BRANCHES OPEN ARRAY" trs toHex(existing.data) trs toHex(newData) h.update existing.data h.update newData let paddingBytes = bytesPerChunk - newData.len if paddingBytes > 0: trs "USING ", paddingBytes, " PADDING BYTES" h.update zeroChunk.toOpenArray(0, paddingBytes - 1) trs "HASH RESULT ", result template mergeBranches(a, b: Eth2Digest): Eth2Digest = hash(a.data, b.data) func computeZeroHashes: array[sizeof(Limit) * 8, Eth2Digest] = result[0] = Eth2Digest(data: zeroChunk) for i in 1 .. result.high: result[i] = mergeBranches(result[i - 1], result[i - 1]) const zeroHashes = computeZeroHashes() func addChunk(merkleizer: var SszChunksMerkleizer, data: openarray[byte]) = doAssert data.len > 0 and data.len <= bytesPerChunk if not getBitLE(merkleizer.totalChunks, 0): let chunkStartAddr = addr merkleizer.combinedChunks[0].data[0] copyMem(chunkStartAddr, unsafeAddr data[0], data.len) zeroMem(chunkStartAddr.offset(data.len), bytesPerChunk - data.len) trs "WROTE BASE CHUNK ", merkleizer.combinedChunks[0], " ", data.len else: var hash = mergeBranches(merkleizer.combinedChunks[0], data) for i in 1 .. merkleizer.topIndex: trs "ITERATING" if getBitLE(merkleizer.totalChunks, i): trs "CALLING MERGE BRANCHES" hash = mergeBranches(merkleizer.combinedChunks[i], hash) else: trs "WRITING FRESH CHUNK AT ", i, " = ", hash merkleizer.combinedChunks[i] = hash break inc merkleizer.totalChunks template createMerkleizer(totalElements: static Limit): SszChunksMerkleizer = trs "CREATING A MERKLEIZER FOR ", totalElements const treeHeight = bitWidth nextPow2(uint64 totalElements) var combinedChunks {.noInit.}: array[treeHeight, Eth2Digest] SszChunksMerkleizer( combinedChunks: cast[ptr UncheckedArray[Eth2Digest]](addr combinedChunks), topIndex: treeHeight - 1, totalChunks: 0) func getFinalHash(merkleizer: var SszChunksMerkleizer): Eth2Digest = if merkleizer.totalChunks == 0: return zeroHashes[merkleizer.topIndex] let bottomHashIdx = firstOne(merkleizer.totalChunks) - 1 submittedChunksHeight = bitWidth(merkleizer.totalChunks - 1) topHashIdx = merkleizer.topIndex trs "BOTTOM HASH ", bottomHashIdx trs "SUBMITTED HEIGHT ", submittedChunksHeight trs "TOP HASH IDX ", topHashIdx if bottomHashIdx != submittedChunksHeight: # Our tree is not finished. We must complete the work in progress # branches and then extend the tree to the right height. result = mergeBranches(merkleizer.combinedChunks[bottomHashIdx], zeroHashes[bottomHashIdx]) for i in bottomHashIdx + 1 ..< topHashIdx: if getBitLE(merkleizer.totalChunks, i): result = mergeBranches(merkleizer.combinedChunks[i], result) trs "COMBINED" else: result = mergeBranches(result, zeroHashes[i]) trs "COMBINED WITH ZERO" elif bottomHashIdx == topHashIdx: # We have a perfect tree (chunks == 2**n) at just the right height! result = merkleizer.combinedChunks[bottomHashIdx] else: # We have a perfect tree of user chunks, but we have more work to # do - we must extend it to reach the desired height result = mergeBranches(merkleizer.combinedChunks[bottomHashIdx], zeroHashes[bottomHashIdx]) for i in bottomHashIdx + 1 ..< topHashIdx: result = mergeBranches(result, zeroHashes[i]) func mixInLength(root: Eth2Digest, length: int): Eth2Digest = var dataLen: array[32, byte] dataLen[0..<8] = uint64(length).toBytesLE() hash(root.data, dataLen) func hash_tree_root*(x: auto): Eth2Digest {.gcsafe, raises: [Defect].} template merkleizeFields(totalElements: static Limit, body: untyped): Eth2Digest = var merkleizer {.inject.} = createMerkleizer(totalElements) template addField(field) = let hash = hash_tree_root(field) trs "MERKLEIZING FIELD ", astToStr(field), " = ", hash addChunk(merkleizer, hash.data) trs "CHUNK ADDED" body getFinalHash(merkleizer) template writeBytesLE(chunk: var array[bytesPerChunk, byte], atParam: int, val: SomeUnsignedInt) = let at = atParam chunk[at ..< at + sizeof(val)] = toBytesLE(val) func chunkedHashTreeRootForBasicTypes[T](merkleizer: var SszChunksMerkleizer, arr: openarray[T]): Eth2Digest = static: doAssert T is BasicType when T is byte: var remainingBytes = arr.len pos = cast[ptr byte](unsafeAddr arr[0]) while remainingBytes >= bytesPerChunk: merkleizer.addChunk(makeOpenArray(pos, bytesPerChunk)) pos = offset(pos, bytesPerChunk) remainingBytes -= bytesPerChunk if remainingBytes > 0: merkleizer.addChunk(makeOpenArray(pos, remainingBytes)) elif T is bool or cpuEndian == littleEndian: let baseAddr = cast[ptr byte](unsafeAddr arr[0]) len = arr.len * sizeof(T) return chunkedHashTreeRootForBasicTypes(merkleizer, makeOpenArray(baseAddr, len)) else: static: doAssert T is UintN doAssert bytesPerChunk mod sizeof(Т) == 0 const valuesPerChunk = bytesPerChunk div sizeof(Т) var writtenValues = 0 var chunk: array[bytesPerChunk, byte] while writtenValues < arr.len - valuesPerChunk: for i in 0 ..< valuesPerChunk: chunk.writeBytesLE(i * sizeof(T), arr[writtenValues + i]) merkleizer.addChunk chunk inc writtenValues, valuesPerChunk let remainingValues = arr.len - writtenValues if remainingValues > 0: var lastChunk: array[bytesPerChunk, byte] for i in 0 ..< remainingValues: chunk.writeBytesLE(i * sizeof(T), arr[writtenValues + i]) merkleizer.addChunk lastChunk getFinalHash(merkleizer) func bitListHashTreeRoot(merkleizer: var SszChunksMerkleizer, x: BitSeq): Eth2Digest = # TODO: Switch to a simpler BitList representation and # replace this with `chunkedHashTreeRoot` trs "CHUNKIFYING BIT SEQ WITH TOP INDEX ", merkleizer.topIndex var totalBytes = bytes(x).len lastCorrectedByte = bytes(x)[^1] if lastCorrectedByte == byte(1): if totalBytes == 1: # This is an empty bit list. # It should be hashed as a tree containing all zeros: return mergeBranches(zeroHashes[merkleizer.topIndex], zeroHashes[0]) # this is the mixed length totalBytes -= 1 lastCorrectedByte = bytes(x)[^2] else: let markerPos = log2trunc(lastCorrectedByte) lastCorrectedByte.clearBit(markerPos) var bytesInLastChunk = totalBytes mod bytesPerChunk fullChunks = totalBytes div bytesPerChunk if bytesInLastChunk == 0: fullChunks -= 1 bytesInLastChunk = 32 for i in 0 ..< fullChunks: let chunkStartPos = i * bytesPerChunk chunkEndPos = chunkStartPos + bytesPerChunk - 1 merkleizer.addChunk bytes(x).toOpenArray(chunkStartPos, chunkEndPos) var lastChunk: array[bytesPerChunk, byte] chunkStartPos = fullChunks * bytesPerChunk for i in 0 .. bytesInLastChunk - 2: lastChunk[i] = bytes(x)[chunkStartPos + i] lastChunk[bytesInLastChunk - 1] = lastCorrectedByte merkleizer.addChunk lastChunk.toOpenArray(0, bytesInLastChunk - 1) let contentsHash = merkleizer.getFinalHash mixInLength contentsHash, x.len func maxChunksCount(T: type, maxLen: int64): int64 = when T is BitList|BitArray: (maxLen + bitsPerChunk - 1) div bitsPerChunk elif T is array|List: type E = ElemType(T) when E is BasicType: (maxLen * sizeof(E) + bytesPerChunk - 1) div bytesPerChunk else: maxLen else: unsupported T # This should never happen func hashTreeRootAux[T](x: T): Eth2Digest = when T is SignedBeaconBlock: unsupported T # Blocks are identified by htr(BeaconBlock) so we avoid these elif T is bool|char: result.data[0] = byte(x) elif T is SomeUnsignedInt: when cpuEndian == bigEndian: result.data[0..= byteLen: zeroHashes[1] else: let nbytes = min(byteLen - byteIdx, 64) padding = 64 - nbytes hash( toOpenArray(bytes, int(byteIdx), int(byteIdx + nbytes - 1)), toOpenArray(zero64, 0, int(padding - 1))) else: if chunkIdx + 1 > x.data.len(): zeroHashes[x.maxDepth] elif chunkIdx + 1 == x.data.len(): mergeBranches( hash_tree_root(x.data[chunkIdx]), Eth2Digest()) else: mergeBranches( hash_tree_root(x.data[chunkIdx]), hash_tree_root(x.data[chunkIdx + 1])) func cachedHash*(x: HashList, vIdx: int64): Eth2Digest = doAssert vIdx >= 1 let layer = layer(vIdx) idxInLayer = vIdx - (1'i64 shl layer) layerIdx = idxInlayer + x.indices[layer] doAssert layer < x.maxDepth trs "GETTING ", vIdx, " ", layerIdx, " ", layer, " ", x.indices.len if layerIdx >= x.indices[layer + 1]: trs "ZERO ", x.indices[layer], " ", x.indices[layer + 1] zeroHashes[x.maxDepth - layer] else: if true or not isCached(x.hashes[layerIdx]): # TODO oops. so much for maintaining non-mutability. let px = unsafeAddr x trs "REFRESHING ", vIdx, " ", layerIdx, " ", layer px[].hashes[layerIdx] = if layer == x.maxDepth - 1: let dataIdx = vIdx * 2 - 1'i64 shl (x.maxDepth) mergedDataHash(x, dataIdx) else: mergeBranches( cachedHash(x, vIdx * 2), cachedHash(x, vIdx * 2 + 1)) else: trs "CACHED ", layerIdx x.hashes[layerIdx] func cachedHash*(x: HashArray, i: int): Eth2Digest = doAssert i > 0, "Only valid for flat merkle tree indices" if not isCached(x.hashes[i]): # TODO oops. so much for maintaining non-mutability. let px = unsafeAddr x px[].hashes[i] = if i * 2 >= x.hashes.len(): let dataIdx = i * 2 - x.hashes.len() mergedDataHash(x, dataIdx) else: mergeBranches( cachedHash(x, i * 2), cachedHash(x, i * 2 + 1)) return x.hashes[i] func hash_tree_root*(x: auto): Eth2Digest {.raises: [Defect], nbench.} = trs "STARTING HASH TREE ROOT FOR TYPE ", name(type(x)) mixin toSszType result = when x is HashArray: cachedHash(x, 1) elif x is HashList: if x.hashes.len < 2: mixInLength(zeroHashes[x.maxDepth], x.data.len()) else: if not isCached(x.hashes[0]): # TODO oops. so much for maintaining non-mutability. let px = unsafeAddr x px[].hashes[0] = mixInLength(cachedHash(x, 1), x.data.len) x.hashes[0] elif x is List|BitList: const maxLen = static(x.maxLen) type T = type(x) const limit = maxChunksCount(T, maxLen) var merkleizer = createMerkleizer(limit) when x is BitList: merkleizer.bitListHashTreeRoot(BitSeq x) else: type E = ElemType(T) let contentsHash = when E is BasicType: chunkedHashTreeRootForBasicTypes(merkleizer, asSeq x) else: for elem in x: let elemHash = hash_tree_root(elem) merkleizer.addChunk(elemHash.data) merkleizer.getFinalHash() mixInLength(contentsHash, x.len) else: hashTreeRootAux toSszType(x) trs "HASH TREE ROOT FOR ", name(type x), " = ", "0x", $result iterator hash_tree_roots_prefix*[T](lst: openarray[T], limit: static Limit): Eth2Digest = # This is a particular type's instantiation of a general fold, reduce, # accumulation, prefix sums, etc family of operations. As long as that # Eth1 deposit case is the only notable example -- the usual uses of a # list involve, at some point, tree-hashing it -- finalized hashes are # the only abstraction that escapes from this module this way. var merkleizer = createMerkleizer(limit) for i, elem in lst: merkleizer.addChunk(hash_tree_root(elem).data) yield mixInLength(merkleizer.getFinalHash(), i + 1)