nimbus-eth1/nimbus/db/aristo/aristo_transcode.nim

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# nimbus-eth1
# Copyright (c) 2021 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
std/[bitops, sequtils, sets],
eth/[common, rlp, trie/nibbles],
Aristo db api extensions for use as core db backend (#1754) * Update docu * Update Aristo/Kvt constructor prototype why: Previous version used an `enum` value to indicate what backend is to be used. This was replaced by using the backend object type. * Rewrite `hikeUp()` return code into `Result[Hike,(Hike,AristoError)]` why: Better code maintenance. Previously, the `Hike` object was returned. It had an internal error field so partial success was also available on a failure. This error field has been removed. * Use `openArray[byte]` rather than `Blob` in functions prototypes * Provide synchronised multi instance transactions why: The `CoreDB` object was geared towards the legacy DB which used a single transaction for the key-value backend DB. Different state roots are provided by the backend database, so all instances work directly on the same backend. Aristo db instances have different in-memory mappings (aka different state roots) and the transactions are on top of there mappings. So each instance might run different transactions. Multi instance transactions are a compromise to converge towards the legacy behaviour. The synchronised transactions span over all instances available at the time when base transaction was opened. Instances created later are unaffected. * Provide key-value pair database iterator why: Needed in `CoreDB` for `replicate()` emulation also: Some update of internal code * Extend API (i.e. prototype variants) why: Needed for `CoreDB` geared towards the legacy backend which has a more basic API than Aristo.
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results,
stew/endians2,
"."/[aristo_constants, aristo_desc, aristo_get]
type
ResolveVidFn = proc(vid: VertexID): HashKey {.gcsafe, raises: [].}
Aristo db api extensions for use as core db backend (#1754) * Update docu * Update Aristo/Kvt constructor prototype why: Previous version used an `enum` value to indicate what backend is to be used. This was replaced by using the backend object type. * Rewrite `hikeUp()` return code into `Result[Hike,(Hike,AristoError)]` why: Better code maintenance. Previously, the `Hike` object was returned. It had an internal error field so partial success was also available on a failure. This error field has been removed. * Use `openArray[byte]` rather than `Blob` in functions prototypes * Provide synchronised multi instance transactions why: The `CoreDB` object was geared towards the legacy DB which used a single transaction for the key-value backend DB. Different state roots are provided by the backend database, so all instances work directly on the same backend. Aristo db instances have different in-memory mappings (aka different state roots) and the transactions are on top of there mappings. So each instance might run different transactions. Multi instance transactions are a compromise to converge towards the legacy behaviour. The synchronised transactions span over all instances available at the time when base transaction was opened. Instances created later are unaffected. * Provide key-value pair database iterator why: Needed in `CoreDB` for `replicate()` emulation also: Some update of internal code * Extend API (i.e. prototype variants) why: Needed for `CoreDB` geared towards the legacy backend which has a more basic API than Aristo.
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## Resolve storage root vertex ID
# ------------------------------------------------------------------------------
# Private helper
# ------------------------------------------------------------------------------
proc aristoError(error: AristoError): NodeRef =
## Allows returning de
NodeRef(vType: Leaf, error: error)
proc load64(data: Blob; start: var int): Result[uint64,AristoError] =
if data.len < start + 9:
return err(DeblobPayloadTooShortInt64)
let val = uint64.fromBytesBE(data[start ..< start + 8])
start += 8
ok val
proc load256(data: Blob; start: var int): Result[UInt256,AristoError] =
if data.len < start + 33:
return err(DeblobPayloadTooShortInt256)
let val = UInt256.fromBytesBE(data[start ..< start + 32])
start += 32
ok val
Aristo db api extensions for use as core db backend (#1754) * Update docu * Update Aristo/Kvt constructor prototype why: Previous version used an `enum` value to indicate what backend is to be used. This was replaced by using the backend object type. * Rewrite `hikeUp()` return code into `Result[Hike,(Hike,AristoError)]` why: Better code maintenance. Previously, the `Hike` object was returned. It had an internal error field so partial success was also available on a failure. This error field has been removed. * Use `openArray[byte]` rather than `Blob` in functions prototypes * Provide synchronised multi instance transactions why: The `CoreDB` object was geared towards the legacy DB which used a single transaction for the key-value backend DB. Different state roots are provided by the backend database, so all instances work directly on the same backend. Aristo db instances have different in-memory mappings (aka different state roots) and the transactions are on top of there mappings. So each instance might run different transactions. Multi instance transactions are a compromise to converge towards the legacy behaviour. The synchronised transactions span over all instances available at the time when base transaction was opened. Instances created later are unaffected. * Provide key-value pair database iterator why: Needed in `CoreDB` for `replicate()` emulation also: Some update of internal code * Extend API (i.e. prototype variants) why: Needed for `CoreDB` geared towards the legacy backend which has a more basic API than Aristo.
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proc serialise(pyl: PayloadRef; getKey: ResolveVidFn): Blob =
## Encode the data payload of the argument `pyl` as RLP `Blob` if it is of
## account type, otherwise pass the data as is.
##
case pyl.pType:
of RawData:
result = pyl.rawBlob
of RlpData:
result = pyl.rlpBlob
of AccountData:
Aristo db api extensions for use as core db backend (#1754) * Update docu * Update Aristo/Kvt constructor prototype why: Previous version used an `enum` value to indicate what backend is to be used. This was replaced by using the backend object type. * Rewrite `hikeUp()` return code into `Result[Hike,(Hike,AristoError)]` why: Better code maintenance. Previously, the `Hike` object was returned. It had an internal error field so partial success was also available on a failure. This error field has been removed. * Use `openArray[byte]` rather than `Blob` in functions prototypes * Provide synchronised multi instance transactions why: The `CoreDB` object was geared towards the legacy DB which used a single transaction for the key-value backend DB. Different state roots are provided by the backend database, so all instances work directly on the same backend. Aristo db instances have different in-memory mappings (aka different state roots) and the transactions are on top of there mappings. So each instance might run different transactions. Multi instance transactions are a compromise to converge towards the legacy behaviour. The synchronised transactions span over all instances available at the time when base transaction was opened. Instances created later are unaffected. * Provide key-value pair database iterator why: Needed in `CoreDB` for `replicate()` emulation also: Some update of internal code * Extend API (i.e. prototype variants) why: Needed for `CoreDB` geared towards the legacy backend which has a more basic API than Aristo.
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let
vid = pyl.account.storageID
key = if vid.isValid: vid.getkey else: VOID_HASH_KEY
result = rlp.encode Account(
nonce: pyl.account.nonce,
balance: pyl.account.balance,
storageRoot: key.to(Hash256),
codeHash: pyl.account.codeHash)
# ------------------------------------------------------------------------------
# Public RLP transcoder mixins
# ------------------------------------------------------------------------------
proc read*(
rlp: var Rlp;
T: type NodeRef;
): T {.gcsafe, raises: [RlpError]} =
## Mixin for RLP writer, see `fromRlpRecord()` for an encoder with detailed
## error return code (if needed.) This reader is a jazzed up version which
## reports some particular errors in the `Dummy` type node.
if not rlp.isList:
# Otherwise `rlp.items` would raise a `Defect`
return aristoError(Rlp2Or17ListEntries)
var
blobs = newSeq[Blob](2) # temporary, cache
links: array[16,HashKey] # reconstruct branch node
top = 0 # count entries and positions
# Collect lists of either 2 or 17 blob entries.
for w in rlp.items:
case top
of 0, 1:
if not w.isBlob:
return aristoError(RlpBlobExpected)
blobs[top] = rlp.read(Blob)
of 2 .. 15:
if not links[top].init(rlp.read(Blob)):
return aristoError(RlpBranchLinkExpected)
of 16:
if not w.isBlob:
return aristoError(RlpBlobExpected)
if 0 < rlp.read(Blob).len:
return aristoError(RlpEmptyBlobExpected)
else:
return aristoError(Rlp2Or17ListEntries)
top.inc
# Verify extension data
case top
of 2:
if blobs[0].len == 0:
return aristoError(RlpNonEmptyBlobExpected)
let (isLeaf, pathSegment) = hexPrefixDecode blobs[0]
if isLeaf:
return NodeRef(
vType: Leaf,
lPfx: pathSegment,
lData: PayloadRef(
pType: RawData,
rawBlob: blobs[1]))
else:
var node = NodeRef(
vType: Extension,
ePfx: pathSegment)
if not node.key[0].init(blobs[1]):
return aristoError(RlpExtPathEncoding)
return node
of 17:
for n in [0,1]:
if not links[n].init(blobs[n]):
return aristoError(RlpBranchLinkExpected)
return NodeRef(
vType: Branch,
key: links)
else:
discard
aristoError(Rlp2Or17ListEntries)
proc append*(writer: var RlpWriter; node: NodeRef) =
## Mixin for RLP writer. Note that a `Dummy` node is encoded as an empty
## list.
proc addHashKey(writer: var RlpWriter; key: HashKey) =
if not key.isValid:
writer.append EmptyBlob
else:
writer.append key.to(Hash256)
Aristo db api extensions for use as core db backend (#1754) * Update docu * Update Aristo/Kvt constructor prototype why: Previous version used an `enum` value to indicate what backend is to be used. This was replaced by using the backend object type. * Rewrite `hikeUp()` return code into `Result[Hike,(Hike,AristoError)]` why: Better code maintenance. Previously, the `Hike` object was returned. It had an internal error field so partial success was also available on a failure. This error field has been removed. * Use `openArray[byte]` rather than `Blob` in functions prototypes * Provide synchronised multi instance transactions why: The `CoreDB` object was geared towards the legacy DB which used a single transaction for the key-value backend DB. Different state roots are provided by the backend database, so all instances work directly on the same backend. Aristo db instances have different in-memory mappings (aka different state roots) and the transactions are on top of there mappings. So each instance might run different transactions. Multi instance transactions are a compromise to converge towards the legacy behaviour. The synchronised transactions span over all instances available at the time when base transaction was opened. Instances created later are unaffected. * Provide key-value pair database iterator why: Needed in `CoreDB` for `replicate()` emulation also: Some update of internal code * Extend API (i.e. prototype variants) why: Needed for `CoreDB` geared towards the legacy backend which has a more basic API than Aristo.
2023-09-15 15:23:53 +00:00
proc getKeyFn(key: HashKey): ResolveVidFn =
result = proc(vid: VertexID): HashKey = key
if node.error != AristoError(0):
writer.startList(0)
else:
case node.vType:
of Branch:
writer.startList(17)
for n in 0..15:
writer.addHashKey node.key[n]
writer.append EmptyBlob
of Extension:
writer.startList(2)
writer.append node.ePfx.hexPrefixEncode(isleaf = false)
writer.addHashKey node.key[0]
of Leaf:
writer.startList(2)
writer.append node.lPfx.hexPrefixEncode(isleaf = true)
Aristo db api extensions for use as core db backend (#1754) * Update docu * Update Aristo/Kvt constructor prototype why: Previous version used an `enum` value to indicate what backend is to be used. This was replaced by using the backend object type. * Rewrite `hikeUp()` return code into `Result[Hike,(Hike,AristoError)]` why: Better code maintenance. Previously, the `Hike` object was returned. It had an internal error field so partial success was also available on a failure. This error field has been removed. * Use `openArray[byte]` rather than `Blob` in functions prototypes * Provide synchronised multi instance transactions why: The `CoreDB` object was geared towards the legacy DB which used a single transaction for the key-value backend DB. Different state roots are provided by the backend database, so all instances work directly on the same backend. Aristo db instances have different in-memory mappings (aka different state roots) and the transactions are on top of there mappings. So each instance might run different transactions. Multi instance transactions are a compromise to converge towards the legacy behaviour. The synchronised transactions span over all instances available at the time when base transaction was opened. Instances created later are unaffected. * Provide key-value pair database iterator why: Needed in `CoreDB` for `replicate()` emulation also: Some update of internal code * Extend API (i.e. prototype variants) why: Needed for `CoreDB` geared towards the legacy backend which has a more basic API than Aristo.
2023-09-15 15:23:53 +00:00
writer.append node.lData.serialise node.key[0].getKeyFn
# ---------------------
proc to*(node: NodeRef; T: type HashKey): T =
## Convert the argument `node` to the corresponding Merkle hash key
node.encode.digestTo T
Aristo db api extensions for use as core db backend (#1754) * Update docu * Update Aristo/Kvt constructor prototype why: Previous version used an `enum` value to indicate what backend is to be used. This was replaced by using the backend object type. * Rewrite `hikeUp()` return code into `Result[Hike,(Hike,AristoError)]` why: Better code maintenance. Previously, the `Hike` object was returned. It had an internal error field so partial success was also available on a failure. This error field has been removed. * Use `openArray[byte]` rather than `Blob` in functions prototypes * Provide synchronised multi instance transactions why: The `CoreDB` object was geared towards the legacy DB which used a single transaction for the key-value backend DB. Different state roots are provided by the backend database, so all instances work directly on the same backend. Aristo db instances have different in-memory mappings (aka different state roots) and the transactions are on top of there mappings. So each instance might run different transactions. Multi instance transactions are a compromise to converge towards the legacy behaviour. The synchronised transactions span over all instances available at the time when base transaction was opened. Instances created later are unaffected. * Provide key-value pair database iterator why: Needed in `CoreDB` for `replicate()` emulation also: Some update of internal code * Extend API (i.e. prototype variants) why: Needed for `CoreDB` geared towards the legacy backend which has a more basic API than Aristo.
2023-09-15 15:23:53 +00:00
proc serialise*(db: AristoDbRef; pyl: PayloadRef): Blob =
## Encode the data payload of the argument `pyl` as RLP `Blob` if it is of
## account type, otherwise pass the data as is.
##
proc getKey(vid: VertexID): HashKey = db.getKey vid
pyl.serialise getKey
# ------------------------------------------------------------------------------
Aristo db api extensions for use as core db backend (#1754) * Update docu * Update Aristo/Kvt constructor prototype why: Previous version used an `enum` value to indicate what backend is to be used. This was replaced by using the backend object type. * Rewrite `hikeUp()` return code into `Result[Hike,(Hike,AristoError)]` why: Better code maintenance. Previously, the `Hike` object was returned. It had an internal error field so partial success was also available on a failure. This error field has been removed. * Use `openArray[byte]` rather than `Blob` in functions prototypes * Provide synchronised multi instance transactions why: The `CoreDB` object was geared towards the legacy DB which used a single transaction for the key-value backend DB. Different state roots are provided by the backend database, so all instances work directly on the same backend. Aristo db instances have different in-memory mappings (aka different state roots) and the transactions are on top of there mappings. So each instance might run different transactions. Multi instance transactions are a compromise to converge towards the legacy behaviour. The synchronised transactions span over all instances available at the time when base transaction was opened. Instances created later are unaffected. * Provide key-value pair database iterator why: Needed in `CoreDB` for `replicate()` emulation also: Some update of internal code * Extend API (i.e. prototype variants) why: Needed for `CoreDB` geared towards the legacy backend which has a more basic API than Aristo.
2023-09-15 15:23:53 +00:00
# Public functions
# ------------------------------------------------------------------------------
proc blobify*(pyl: PayloadRef): Blob =
if pyl.isNil:
return
case pyl.pType
of RawData:
result = pyl.rawBlob & @[0x6b.byte]
of RlpData:
result = pyl.rlpBlob & @[0x6a.byte]
of AccountData:
var mask: byte
if 0 < pyl.account.nonce:
mask = mask or 0x01
result &= pyl.account.nonce.uint64.toBytesBE.toSeq
if high(uint64).u256 < pyl.account.balance:
mask = mask or 0x08
result &= pyl.account.balance.UInt256.toBytesBE.toSeq
elif 0 < pyl.account.balance:
mask = mask or 0x04
result &= pyl.account.balance.truncate(uint64).uint64.toBytesBE.toSeq
if VertexID(0) < pyl.account.storageID:
mask = mask or 0x10
result &= pyl.account.storageID.uint64.toBytesBE.toSeq
if pyl.account.codeHash != VOID_CODE_HASH:
mask = mask or 0x80
result &= pyl.account.codeHash.data.toSeq
result &= @[mask]
proc blobify*(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:
## uint64, ... -- list of up to 16 child vertices lookup keys
## uint16 -- index bitmap
## 0x08 -- marker(8)
##
## Extension:
## uint64 -- child vertex lookup key
## Blob -- hex encoded partial path (at least one byte)
## 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
top = 0u64
access = 0u16
refs: Blob
keys: Blob
for n in 0..15:
if vtx.bVid[n].isValid:
access = access or (1u16 shl n)
refs &= vtx.bVid[n].uint64.toBytesBE.toSeq
if refs.len < 16:
return err(BlobifyBranchMissingRefs)
data = refs & access.toBytesBE.toSeq & @[0x08u8]
of Extension:
let
pSegm = vtx.ePfx.hexPrefixEncode(isleaf = false)
psLen = pSegm.len.byte
if psLen == 0 or 33 < pslen:
return err(BlobifyExtPathOverflow)
if not vtx.eVid.isValid:
return err(BlobifyExtMissingRefs)
data = vtx.eVid.uint64.toBytesBE.toSeq & pSegm & @[0x80u8 or psLen]
of Leaf:
let
pSegm = vtx.lPfx.hexPrefixEncode(isleaf = true)
psLen = pSegm.len.byte
if psLen == 0 or 33 < psLen:
return err(BlobifyLeafPathOverflow)
data = vtx.lData.blobify & pSegm & @[0xC0u8 or psLen]
ok()
proc blobify*(vtx: VertexRef): Result[Blob, AristoError] =
## Variant of `blobify()`
var data: Blob
? vtx.blobify data
ok(data)
proc blobify*(vGen: openArray[VertexID]; data: var Blob) =
## This function serialises a list of vertex IDs.
## ::
## uint64, ... -- list of IDs
## 0x7c -- marker(8)
##
data.setLen(0)
for w in vGen:
data &= w.uint64.toBytesBE.toSeq
data.add 0x7Cu8
proc blobify*(vGen: openArray[VertexID]): Blob =
## Variant of `blobify()`
vGen.blobify result
proc blobify*(filter: FilterRef; data: var Blob): Result[void,AristoError] =
## This function serialises an Aristo DB filter object
## ::
## uint64 -- filter ID
## Uint256 -- source key
## Uint256 -- target key
## uint32 -- number of vertex IDs (vertex ID generator state)
## uint32 -- number of (id,key,vertex) triplets
##
## uint64, ... -- list of vertex IDs (vertex ID generator state)
##
## uint32 -- flag(3) + vtxLen(29), first triplet
## uint64 -- vertex ID
## Uint256 -- optional key
## Blob -- optional vertex
##
## ... -- more triplets
## 0x7d -- marker(8)
##
if not filter.isValid:
return err(BlobifyNilFilter)
data.setLen(0)
data &= filter.fid.uint64.toBytesBE.toSeq
data &= filter.src.ByteArray32.toSeq
data &= filter.trg.ByteArray32.toSeq
data &= filter.vGen.len.uint32.toBytesBE.toSeq
data &= newSeq[byte](4) # place holder
# Store vertex ID generator state
for w in filter.vGen:
data &= w.uint64.toBytesBE.toSeq
var
n = 0
leftOver = filter.kMap.keys.toSeq.toHashSet
# Loop over vertex table
for (vid,vtx) in filter.sTab.pairs:
n.inc
leftOver.excl vid
var
keyMode = 0u # present and usable
vtxMode = 0u # present and usable
keyBlob: Blob
vtxBlob: Blob
let key = filter.kMap.getOrVoid vid
if key.isValid:
keyBlob = key.ByteArray32.toSeq
elif filter.kMap.hasKey vid:
keyMode = 1u # void hash key => considered deleted
else:
keyMode = 2u # ignore that hash key
if vtx.isValid:
? vtx.blobify vtxBlob
else:
vtxMode = 1u # nil vertex => considered deleted
if (vtxBlob.len and not 0x1fffffff) != 0:
return err(BlobifyFilterRecordOverflow)
let pfx = ((keyMode * 3 + vtxMode) shl 29) or vtxBlob.len.uint
data &=
pfx.uint32.toBytesBE.toSeq &
vid.uint64.toBytesBE.toSeq &
keyBlob &
vtxBlob
# Loop over remaining data from key table
for vid in leftOver:
n.inc
var
mode = 2u # key present and usable, ignore vtx
keyBlob: Blob
let key = filter.kMap.getOrVoid vid
if key.isValid:
keyBlob = key.ByteArray32.toSeq
else:
mode = 5u # 1 * 3 + 2: void key, ignore vtx
let pfx = (mode shl 29)
data &=
pfx.uint32.toBytesBE.toSeq &
vid.uint64.toBytesBE.toSeq &
keyBlob
data[76 ..< 80] = n.uint32.toBytesBE.toSeq
data.add 0x7Du8
ok()
proc blobify*(filter: FilterRef): Result[Blob, AristoError] =
## ...
var data: Blob
? filter.blobify data
ok data
proc blobify*(vFqs: openArray[(QueueID,QueueID)]; data: var Blob) =
## This function serialises a list of filter queue IDs.
## ::
## uint64, ... -- list of IDs
## 0x7e -- marker(8)
##
data.setLen(0)
for w in vFqs:
data &= w[0].uint64.toBytesBE.toSeq
data &= w[1].uint64.toBytesBE.toSeq
data.add 0x7Eu8
proc blobify*(vFqs: openArray[(QueueID,QueueID)]): Blob =
## Variant of `blobify()`
vFqs.blobify result
# -------------
proc deblobify(data: Blob; pyl: var PayloadRef): Result[void,AristoError] =
if data.len == 0:
pyl = PayloadRef(pType: RawData)
return ok()
let mask = data[^1]
if mask == 0x6b: # unstructured payload
pyl = PayloadRef(pType: RawData, rawBlob: data[0 .. ^2])
return ok()
if mask == 0x6a: # RLP encoded payload
pyl = PayloadRef(pType: RlpData, rlpBlob: data[0 .. ^2])
return ok()
var
pAcc = PayloadRef(pType: AccountData)
start = 0
case mask and 0x03:
of 0x00:
discard
of 0x01:
pAcc.account.nonce = (? data.load64 start).AccountNonce
else:
return err(DeblobNonceLenUnsupported)
case mask and 0x0c:
of 0x00:
discard
of 0x04:
pAcc.account.balance = (? data.load64 start).u256
of 0x08:
pAcc.account.balance = (? data.load256 start)
else:
return err(DeblobBalanceLenUnsupported)
case mask and 0x30:
of 0x00:
discard
of 0x10:
pAcc.account.storageID = (? data.load64 start).VertexID
else:
return err(DeblobStorageLenUnsupported)
case mask and 0xc0:
of 0x00:
pAcc.account.codeHash = VOID_CODE_HASH
of 0x80:
if data.len < start + 33:
return err(DeblobPayloadTooShortInt256)
(addr pAcc.account.codeHash.data[0]).copyMem(unsafeAddr data[start], 32)
else:
return err(DeblobCodeLenUnsupported)
pyl = pacc
ok()
proc deblobify*(record: Blob; vtx: var VertexRef): Result[void,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(DeblobTooShort)
case record[^1] shr 6:
of 0: # `Branch` vertex
if record[^1] != 0x08u8:
return err(DeblobUnknown)
if record.len < 19: # at least two edges
return err(DeblobBranchTooShort)
if (record.len mod 8) != 3:
return err(DeblobBranchSizeGarbled)
let
maxOffset = record.len - 11
aInx = record.len - 3
aIny = record.len - 2
var
offs = 0
access = uint16.fromBytesBE record[aInx..aIny] # bitmap
vtxList: array[16,VertexID]
while access != 0:
if maxOffset < offs:
return err(DeblobBranchInxOutOfRange)
let n = access.firstSetBit - 1
access.clearBit n
vtxList[n] = (uint64.fromBytesBE record[offs ..< offs+8]).VertexID
offs += 8
# End `while`
vtx = VertexRef(
vType: Branch,
bVid: vtxList)
of 2: # `Extension` vertex
let
sLen = record[^1].int and 0x3f # length of path segment
rlen = record.len - 1 # `vertexID` + path segm
if record.len < 10:
return err(DeblobExtTooShort)
if 8 + sLen != rlen: # => slen is at least 1
return err(DeblobExtSizeGarbled)
let (isLeaf, pathSegment) = hexPrefixDecode record[8 ..< rLen]
if isLeaf:
return err(DeblobExtGotLeafPrefix)
vtx = VertexRef(
vType: Extension,
eVid: (uint64.fromBytesBE record[0 ..< 8]).VertexID,
ePfx: pathSegment)
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:
return err(DeblobLeafSizeGarbled)
let (isLeaf, pathSegment) = hexPrefixDecode record[pLen ..< rLen]
if not isLeaf:
return err(DeblobLeafGotExtPrefix)
var pyl: PayloadRef
? record[0 ..< plen].deblobify(pyl)
vtx = VertexRef(
vType: Leaf,
lPfx: pathSegment,
lData: pyl)
else:
return err(DeblobUnknown)
ok()
proc deblobify*(data: Blob; T: type VertexRef): Result[T,AristoError] =
## Variant of `deblobify()` for vertex deserialisation.
var vtx = T(nil) # will be auto-initialised
? data.deblobify vtx
ok vtx
proc deblobify*(data: Blob; vGen: var seq[VertexID]): Result[void,AristoError] =
## De-serialise the data record encoded with `blobify()` into the vertex ID
## generator argument `vGen`.
if data.len == 0:
vGen = @[]
else:
if (data.len mod 8) != 1:
return err(DeblobSizeGarbled)
if data[^1] != 0x7c:
return err(DeblobWrongType)
for n in 0 ..< (data.len div 8):
let w = n * 8
vGen.add (uint64.fromBytesBE data[w ..< w + 8]).VertexID
ok()
proc deblobify*(data: Blob; T: type seq[VertexID]): Result[T,AristoError] =
## Variant of `deblobify()` for deserialising the vertex ID generator state
var vGen: seq[VertexID]
? data.deblobify vGen
ok vGen
proc deblobify*(data: Blob; filter: var FilterRef): Result[void,AristoError] =
## De-serialise an Aristo DB filter object
if data.len < 80: # minumum length 80 for an empty filter
return err(DeblobFilterTooShort)
if data[^1] != 0x7d:
return err(DeblobWrongType)
let f = FilterRef()
f.fid = (uint64.fromBytesBE data[0 ..< 8]).FilterID
(addr f.src.ByteArray32[0]).copyMem(unsafeAddr data[8], 32)
(addr f.trg.ByteArray32[0]).copyMem(unsafeAddr data[40], 32)
let
nVids = uint32.fromBytesBE data[72 ..< 76]
nTriplets = uint32.fromBytesBE data[76 ..< 80]
nTrplStart = (80 + nVids * 8).int
if data.len < nTrplStart:
return err(DeblobFilterGenTooShort)
for n in 0 ..< nVids:
let w = 80 + n * 8
f.vGen.add (uint64.fromBytesBE data[w ..< w + 8]).VertexID
var offs = nTrplStart
for n in 0 ..< nTriplets:
if data.len < offs + 12:
return err(DeblobFilterTrpTooShort)
let
flag = data[offs] shr 5 # double triplets: {0,1,2} x {0,1,2}
vLen = ((uint32.fromBytesBE data[offs ..< offs + 4]) and 0x1fffffff).int
if (vLen == 0) != ((flag mod 3) > 0):
return err(DeblobFilterTrpVtxSizeGarbled) # contadiction
offs = offs + 4
let vid = (uint64.fromBytesBE data[offs ..< offs + 8]).VertexID
offs = offs + 8
if data.len < offs + (flag < 3).ord * 32 + vLen:
return err(DeblobFilterTrpTooShort)
if flag < 3: # {0} x {0,1,2}
var key: HashKey
(addr key.ByteArray32[0]).copyMem(unsafeAddr data[offs], 32)
f.kMap[vid] = key
offs = offs + 32
elif flag < 6: # {0,1} x {0,1,2}
f.kMap[vid] = VOID_HASH_KEY
if 0 < vLen:
var vtx: VertexRef
? data[offs ..< offs + vLen].deblobify vtx
f.sTab[vid] = vtx
offs = offs + vLen
elif (flag mod 3) == 1: # {0,1,2} x {1}
f.sTab[vid] = VertexRef(nil)
if data.len != offs + 1:
return err(DeblobFilterSizeGarbled)
filter = f
ok()
proc deblobify*(data: Blob; T: type FilterRef): Result[T,AristoError] =
## Variant of `deblobify()` for deserialising an Aristo DB filter object
var filter: T
? data.deblobify filter
ok filter
proc deblobify*(
data: Blob;
vFqs: var seq[(QueueID,QueueID)];
): Result[void,AristoError] =
## De-serialise the data record encoded with `blobify()` into a filter queue
## ID argument liet `vFqs`.
if data.len == 0:
vFqs = @[]
else:
if (data.len mod 16) != 1:
return err(DeblobSizeGarbled)
if data[^1] != 0x7e:
return err(DeblobWrongType)
for n in 0 ..< (data.len div 16):
let
w = n * 16
a = (uint64.fromBytesBE data[w + 0 ..< w + 8]).QueueID
b = (uint64.fromBytesBE data[w + 8 ..< w + 16]).QueueID
vFqs.add (a,b)
ok()
proc deblobify*(
data: Blob;
T: type seq[(QueueID,QueueID)];
): Result[T,AristoError] =
## Variant of `deblobify()` for deserialising the vertex ID generator state
var vFqs: seq[(QueueID,QueueID)]
? data.deblobify vFqs
ok vFqs
# ------------------------------------------------------------------------------
# End
# ------------------------------------------------------------------------------