# nimbus-eth1 # Copyright (c) 2023-2024 Status Research & Development GmbH # Licensed under either of # * Apache License, version 2.0, ([LICENSE-APACHE](LICENSE-APACHE) or # http://www.apache.org/licenses/LICENSE-2.0) # * MIT license ([LICENSE-MIT](LICENSE-MIT) or # http://opensource.org/licenses/MIT) # at your option. This file may not be copied, modified, or distributed # except according to those terms. {.push raises: [].} import eth/common, results, stew/[arrayops, endians2], ./aristo_desc export aristo_desc, results # Allocation-free version short big-endian encoding that skips the leading # zeroes type SbeBuf*[I] = object buf*: array[sizeof(I), byte] len*: byte RVidBuf* = object buf*: array[sizeof(SbeBuf[VertexID]) * 2, byte] len*: byte func significantBytesBE(val: openArray[byte]): byte = for i in 0 ..< val.len: if val[i] != 0: return byte(val.len - i) return 1 func blobify*(v: VertexID|uint64): SbeBuf[typeof(v)] = let b = v.uint64.toBytesBE() SbeBuf[typeof(v)](buf: b, len: significantBytesBE(b)) func blobify*(v: StUint): SbeBuf[typeof(v)] = let b = v.toBytesBE() SbeBuf[typeof(v)](buf: b, len: significantBytesBE(b)) template data*(v: SbeBuf): openArray[byte] = let vv = v vv.buf.toOpenArray(vv.buf.len - int(vv.len), vv.buf.high) func blobify*(rvid: RootedVertexID): RVidBuf = # Length-prefixed root encoding creates a unique and common prefix for all # verticies sharing the same root # TODO evaluate an encoding that colocates short roots (like VertexID(1)) with # the length let root = rvid.root.blobify() result.buf[0] = root.len assign(result.buf.toOpenArray(1, root.len), root.data()) if rvid.root == rvid.vid: result.len = root.len + 1 else: # We can derive the length of the `vid` from the total length let vid = rvid.vid.blobify() assign(result.buf.toOpenArray(root.len + 1, root.len + vid.len), vid.data()) result.len = root.len + 1 + vid.len proc deblobify*[T: uint64|VertexID](data: openArray[byte], _: type T): Result[T,AristoError] = if data.len < 1 or data.len > 8: return err(Deblob64LenUnsupported) var tmp: array[8, byte] discard tmp.toOpenArray(8 - data.len, 7).copyFrom(data) ok T(uint64.fromBytesBE(tmp)) proc deblobify*(data: openArray[byte], _: type UInt256): Result[UInt256,AristoError] = if data.len < 1 or data.len > 32: return err(Deblob256LenUnsupported) ok UInt256.fromBytesBE(data) func deblobify*(data: openArray[byte], T: type RootedVertexID): Result[T, AristoError] = let rlen = int(data[0]) if data.len < 2: return err(DeblobRVidLenUnsupported) if data.len < rlen + 1: return err(DeblobRVidLenUnsupported) let root = ?deblobify(data.toOpenArray(1, rlen), VertexID) vid = if data.len > rlen + 1: ?deblobify(data.toOpenArray(rlen + 1, data.high()), VertexID) else: root ok (root, vid) template data*(v: RVidBuf): openArray[byte] = let vv = v vv.buf.toOpenArray(0, vv.len - 1) # ------------------------------------------------------------------------------ # Private helper # ------------------------------------------------------------------------------ proc load64(data: openArray[byte]; start: var int, len: int): Result[uint64,AristoError] = if data.len < start + len: return err(Deblob256LenUnsupported) let val = ?deblobify(data.toOpenArray(start, start + len - 1), uint64) start += len ok val proc load256(data: openArray[byte]; start: var int, len: int): Result[UInt256,AristoError] = if data.len < start + len: return err(Deblob256LenUnsupported) let val = ?deblobify(data.toOpenArray(start, start + len - 1), UInt256) start += len ok val # ------------------------------------------------------------------------------ # Public functions # ------------------------------------------------------------------------------ proc blobifyTo*(pyl: LeafPayload, data: var Blob) = case pyl.pType of RawData: data &= pyl.rawBlob data &= [0x10.byte] of AccountData: # `lens` holds `len-1` since `mask` filters out the zero-length case (which # allows saving 1 bit per length) var lens: uint16 var mask: byte if 0 < pyl.account.nonce: mask = mask or 0x01 let tmp = pyl.account.nonce.blobify() lens += tmp.len - 1 # 3 bits data &= tmp.data() if 0 < pyl.account.balance: mask = mask or 0x02 let tmp = pyl.account.balance.blobify() lens += uint16(tmp.len - 1) shl 3 # 5 bits data &= tmp.data() if pyl.stoID.isValid: mask = mask or 0x04 let tmp = pyl.stoID.vid.blobify() lens += uint16(tmp.len - 1) shl 8 # 3 bits data &= tmp.data() if pyl.account.codeHash != EMPTY_CODE_HASH: mask = mask or 0x08 data &= pyl.account.codeHash.data data &= lens.toBytesBE() data &= [mask] of StoData: data &= pyl.stoData.blobify().data data &= [0x20.byte] proc blobifyTo*(vtx: VertexRef; data: var Blob): Result[void,AristoError] = ## This function serialises the vertex argument to a database record. ## Contrary to RLP based serialisation, these records aim to align on ## fixed byte boundaries. ## :: ## Branch: ## [VertexID, ...] -- list of up to 16 child vertices lookup keys ## Blob -- hex encoded partial path (non-empty for extension nodes) ## uint64 -- lengths of each child vertex, each taking 4 bits ## 0x80 + xx -- marker(2) + pathSegmentLen(6) ## ## Leaf: ## Blob -- opaque leaf data payload (might be zero length) ## Blob -- hex encoded partial path (at least one byte) ## 0xc0 + yy -- marker(2) + partialPathLen(6) ## ## For a branch record, the bytes of the `access` array indicate the position ## of the Patricia Trie vertex reference. So the `vertexID` with index `n` has ## :: ## 8 * n * ((access shr (n * 4)) and 15) ## if not vtx.isValid: return err(BlobifyNilVertex) case vtx.vType: of Branch: var lens = 0u64 pos = data.len for n in 0..15: if vtx.bVid[n].isValid: let tmp = vtx.bVid[n].blobify() lens += uint64(tmp.len) shl (n * 4) data &= tmp.data() if data.len == pos: return err(BlobifyBranchMissingRefs) let pSegm = if vtx.ePfx.len > 0: vtx.ePfx.toHexPrefix(isleaf = false) else: default(HexPrefixBuf) psLen = pSegm.len.byte if 33 < psLen: return err(BlobifyExtPathOverflow) data &= pSegm.data() data &= lens.toBytesBE data &= [0x80u8 or psLen] of Leaf: let pSegm = vtx.lPfx.toHexPrefix(isleaf = true) psLen = pSegm.len.byte if psLen == 0 or 33 < psLen: return err(BlobifyLeafPathOverflow) vtx.lData.blobifyTo(data) data &= pSegm.data() data &= [0xC0u8 or psLen] ok() proc blobify*(vtx: VertexRef): Blob = ## Variant of `blobify()` result = newSeqOfCap[byte](128) if vtx.blobifyTo(result).isErr: result.setLen(0) # blobify only fails on invalid verticies proc blobifyTo*(lSst: SavedState; data: var Blob): Result[void,AristoError] = ## Serialise a last saved state record data.add lSst.key.data data.add lSst.serial.toBytesBE data.add @[0x7fu8] ok() proc blobify*(lSst: SavedState): Result[Blob,AristoError] = ## Variant of `blobify()` var data: Blob ? lSst.blobifyTo data ok(move(data)) # ------------- proc deblobify( data: openArray[byte]; pyl: var LeafPayload; ): Result[void,AristoError] = if data.len == 0: pyl = LeafPayload(pType: RawData) return ok() let mask = data[^1] if (mask and 0x10) > 0: # unstructured payload pyl = LeafPayload(pType: RawData, rawBlob: data[0 .. ^2]) return ok() if (mask and 0x20) > 0: # Slot storage data pyl = LeafPayload( pType: StoData, stoData: ?deblobify(data.toOpenArray(0, data.len - 2), UInt256)) return ok() pyl = LeafPayload(pType: AccountData) var start = 0 lens = uint16.fromBytesBE(data.toOpenArray(data.len - 3, data.len - 2)) if (mask and 0x01) > 0: let len = lens and 0b111 pyl.account.nonce = ? load64(data, start, int(len + 1)) if (mask and 0x02) > 0: let len = (lens shr 3) and 0b11111 pyl.account.balance = ? load256(data, start, int(len + 1)) if (mask and 0x04) > 0: let len = (lens shr 8) and 0b111 pyl.stoID = (true, VertexID(? load64(data, start, int(len + 1)))) if (mask and 0x08) > 0: if data.len() < start + 32: return err(DeblobCodeLenUnsupported) discard pyl.account.codeHash.data.copyFrom(data.toOpenArray(start, start + 31)) else: pyl.account.codeHash = EMPTY_CODE_HASH ok() proc deblobify*( record: openArray[byte]; T: type VertexRef; ): Result[T,AristoError] = ## De-serialise a data record encoded with `blobify()`. The second ## argument `vtx` can be `nil`. if record.len < 3: # minimum `Leaf` record return err(DeblobVtxTooShort) ok case record[^1] shr 6: of 2: # `Branch` vertex if record.len < 11: # at least two edges return err(DeblobBranchTooShort) let aInx = record.len - 9 aIny = record.len - 2 var offs = 0 lens = uint64.fromBytesBE record.toOpenArray(aInx, aIny) # bitmap vtxList: array[16,VertexID] n = 0 while lens != 0: let len = lens and 0b1111 if len > 0: vtxList[n] = VertexID(? load64(record, offs, int(len))) inc n lens = lens shr 4 let (isLeaf, pathSegment) = NibblesBuf.fromHexPrefix record.toOpenArray(offs, aInx - 1) if isLeaf: return err(DeblobBranchGotLeafPrefix) # End `while` VertexRef( vType: Branch, ePfx: pathSegment, bVid: vtxList) of 3: # `Leaf` vertex let sLen = record[^1].int and 0x3f # length of path segment rLen = record.len - 1 # payload + path segment pLen = rLen - sLen # payload length if rLen < sLen or pLen < 1: return err(DeblobLeafSizeGarbled) let (isLeaf, pathSegment) = NibblesBuf.fromHexPrefix record.toOpenArray(pLen, rLen-1) if not isLeaf: return err(DeblobLeafGotExtPrefix) let vtx = VertexRef( vType: Leaf, lPfx: pathSegment) ? record.toOpenArray(0, pLen - 1).deblobify(vtx.lData) vtx else: return err(DeblobUnknown) proc deblobify*( data: openArray[byte]; T: type SavedState; ): Result[SavedState,AristoError] = ## De-serialise the last saved state data record previously encoded with ## `blobify()`. if data.len != 41: return err(DeblobWrongSize) if data[^1] != 0x7f: return err(DeblobWrongType) ok(SavedState( key: Hash256(data: array[32, byte].initCopyFrom(data.toOpenArray(0, 31))), serial: uint64.fromBytesBE data.toOpenArray(32, 39))) # ------------------------------------------------------------------------------ # End # ------------------------------------------------------------------------------