# Nimbus # Copyright (c) 2021-2023 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. {.push raises: [].} import chronicles, metrics, eth/db/kvstore, eth/db/kvstore_sqlite3, stint, stew/results, ./network/state/state_content, "."/network/wire/[portal_protocol, portal_protocol_config] export kvstore_sqlite3 # This version of content db is the most basic, simple solution where data is # stored no matter what content type or content network in the same kvstore with # the content id as key. The content id is derived from the content key, and the # deriviation is different depending on the content type. As we use content id, # this part is currently out of the scope / API of the ContentDB. # In the future it is likely that that either: # 1. More kvstores are added per network, and thus depending on the network a # different kvstore needs to be selected. # 2. Or more kvstores are added per network and per content type, and thus # content key fields are required to access the data. # 3. Or databases are created per network (and kvstores pre content type) and # thus depending on the network the right db needs to be selected. declareCounter portal_pruning_counter, "Number of pruning event which happened during node lifetime", labels = ["protocol_id"] declareGauge portal_pruning_deleted_elements, "Number of elements delted in last pruning", labels = ["protocol_id"] type RowInfo = tuple contentId: array[32, byte] payloadLength: int64 distance: array[32, byte] ObjInfo* = object contentId*: array[32, byte] payloadLength*: int64 distFrom*: UInt256 ContentDB* = ref object kv: KvStoreRef maxSize: uint32 sizeStmt: SqliteStmt[NoParams, int64] unusedSizeStmt: SqliteStmt[NoParams, int64] vacStmt: SqliteStmt[NoParams, void] contentSizeStmt: SqliteStmt[NoParams, int64] getAllOrderedByDistanceStmt: SqliteStmt[array[32, byte], RowInfo] PutResultType* = enum ContentStored, DbPruned PutResult* = object case kind*: PutResultType of ContentStored: discard of DbPruned: furthestStoredElementDistance*: UInt256 fractionOfDeletedContent*: float64 numOfDeletedElements*: int64 func xorDistance( a: openArray[byte], b: openArray[byte] ): Result[seq[byte], cstring] {.cdecl.} = var s: seq[byte] = newSeq[byte](32) if len(a) != 32 or len(b) != 32: return err("Blobs should have 32 byte length") var i = 0 while i < 32: s[i] = a[i] xor b[i] inc i return ok(s) template expectDb(x: auto): untyped = # There's no meaningful error handling implemented for a corrupt database or # full disk - this requires manual intervention, so we'll panic for now x.expect("working database (disk broken/full?)") proc new*( T: type ContentDB, path: string, maxSize: uint32, inMemory = false): ContentDB = let db = if inMemory: SqStoreRef.init("", "fluffy-test", inMemory = true).expect( "working database (out of memory?)") else: SqStoreRef.init(path, "fluffy").expectDb() db.registerCustomScalarFunction("xorDistance", xorDistance) .expect("Couldn't register custom xor function") let getSizeStmt = db.prepareStmt( "SELECT page_count * page_size as size FROM pragma_page_count(), pragma_page_size();", NoParams, int64).get() let unusedSize = db.prepareStmt( "SELECT freelist_count * page_size as size FROM pragma_freelist_count(), pragma_page_size();", NoParams, int64).get() let vacStmt = db.prepareStmt( "VACUUM;", NoParams, void).get() let kvStore = kvStore db.openKvStore().expectDb() let contentSizeStmt = db.prepareStmt( "SELECT SUM(length(value)) FROM kvstore", NoParams, int64 ).get() let getAllOrderedByDistanceStmt = db.prepareStmt( "SELECT key, length(value), xorDistance(?, key) as distance FROM kvstore ORDER BY distance DESC", array[32, byte], RowInfo ).get() ContentDB( kv: kvStore, maxSize: maxSize, sizeStmt: getSizeStmt, vacStmt: vacStmt, unusedSizeStmt: unusedSize, contentSizeStmt: contentSizeStmt, getAllOrderedByDistanceStmt: getAllOrderedByDistanceStmt ) ## Private KvStoreRef Calls proc get(kv: KvStoreRef, key: openArray[byte]): Opt[seq[byte]] = var res: Opt[seq[byte]] proc onData(data: openArray[byte]) = res = Opt.some(@data) discard kv.get(key, onData).expectDb() return res proc getSszDecoded(kv: KvStoreRef, key: openArray[byte], T: type auto): Opt[T] = let res = kv.get(key) if res.isSome(): try: Opt.some(SSZ.decode(res.get(), T)) except SszError: raiseAssert("Stored data should always be serialized correctly") else: Opt.none(T) ## Private ContentDB calls proc get(db: ContentDB, key: openArray[byte]): Opt[seq[byte]] = db.kv.get(key) proc put(db: ContentDB, key, value: openArray[byte]) = db.kv.put(key, value).expectDb() proc contains(db: ContentDB, key: openArray[byte]): bool = db.kv.contains(key).expectDb() proc del(db: ContentDB, key: openArray[byte]) = # TODO: Do we want to return the bool here too? discard db.kv.del(key).expectDb() proc getSszDecoded*( db: ContentDB, key: openArray[byte], T: type auto): Opt[T] = db.kv.getSszDecoded(key, T) proc reclaimSpace*(db: ContentDB): void = ## Runs sqlite VACUUM commands which rebuilds the db, repacking it into a ## minimal amount of disk space. ## Ideal mode of operation, is to run it after several deletes. ## Another option would be to run 'PRAGMA auto_vacuum = FULL;' statement at ## the start of db to leave it up to sqlite to clean up db.vacStmt.exec().expectDb() proc size*(db: ContentDB): int64 = ## Retrun current size of DB as product of sqlite page_count and page_size ## https://www.sqlite.org/pragma.html#pragma_page_count ## https://www.sqlite.org/pragma.html#pragma_page_size ## It returns total size of db i.e both data and metadata used to store content ## also it is worth noting that when deleting content, size may lags behind due ## to the way how deleting works in sqlite. ## Good description can be found in: https://www.sqlite.org/lang_vacuum.html var size: int64 = 0 discard (db.sizeStmt.exec do(res: int64): size = res).expectDb() return size proc unusedSize(db: ContentDB): int64 = ## Returns the total size of the pages which are unused by the database, ## i.e they can be re-used for new content. var size: int64 = 0 discard (db.unusedSizeStmt.exec do(res: int64): size = res).expectDb() return size proc realSize*(db: ContentDB): int64 = db.size() - db.unusedSize() proc contentSize*(db: ContentDB): int64 = ## Returns total size of content stored in DB var size: int64 = 0 discard (db.contentSizeStmt.exec do(res: int64): size = res).expectDb() return size ## Public ContentId based ContentDB calls # TODO: Could also decide to use the ContentKey SSZ bytestring, as this is what # gets send over the network in requests, but that would be a bigger key. Or the # same hashing could be done on it here. # However ContentId itself is already derived through different digests # depending on the content type, and this ContentId typically needs to be # checked with the Radius/distance of the node anyhow. So lets see how we end up # using this mostly in the code. proc get*(db: ContentDB, key: ContentId): Opt[seq[byte]] = # TODO: Here it is unfortunate that ContentId is a uint256 instead of Digest256. db.get(key.toBytesBE()) proc put*(db: ContentDB, key: ContentId, value: openArray[byte]) = db.put(key.toBytesBE(), value) proc contains*(db: ContentDB, key: ContentId): bool = db.contains(key.toBytesBE()) proc del*(db: ContentDB, key: ContentId) = db.del(key.toBytesBE()) proc getSszDecoded*(db: ContentDB, key: ContentId, T: type auto): Opt[T] = db.getSszDecoded(key.toBytesBE(), T) proc deleteContentFraction( db: ContentDB, target: UInt256, fraction: float64): (UInt256, int64, int64, int64) = ## Deletes at most `fraction` percent of content form database. ## First, content furthest from provided `target` is deleted. doAssert( fraction > 0 and fraction < 1, "Deleted fraction should be > 0 and < 1" ) let totalContentSize = db.contentSize() let bytesToDelete = int64(fraction * float64(totalContentSize)) var numOfDeletedElements: int64 = 0 var ri: RowInfo var bytesDeleted: int64 = 0 let targetBytes = target.toBytesBE() for e in db.getAllOrderedByDistanceStmt.exec(targetBytes, ri): if bytesDeleted + ri.payloadLength < bytesToDelete: db.del(ri.contentId) bytesDeleted = bytesDeleted + ri.payloadLength inc numOfDeletedElements else: return ( UInt256.fromBytesBE(ri.distance), bytesDeleted, totalContentSize, numOfDeletedElements ) proc put*( db: ContentDB, key: ContentId, value: openArray[byte], target: UInt256): PutResult = db.put(key, value) # We use real size for our pruning threshold, which means that database file # will reach size specified in db.maxSize, and will stay that size thorough # node life time, as after content deletion free pages will be re used. # TODO: # 1. Devise vacuum strategy - after few pruning cycles database can become # fragmented which may impact performance, so at some point in time `VACUUM` # will need to be run to defragment the db. # 2. Deal with the edge case where a user configures max db size lower than # current db.size(). With such config the database would try to prune itself # with each addition. let dbSize = db.realSize() if dbSize < int64(db.maxSize): return PutResult(kind: ContentStored) else: # TODO Add some configuration for this magic number let ( furthestNonDeletedElement, deletedBytes, totalContentSize, deletedElements ) = db.deleteContentFraction(target, 0.25) let deletedFraction = float64(deletedBytes) / float64(totalContentSize) return PutResult( kind: DbPruned, furthestStoredElementDistance: furthestNonDeletedElement, fractionOfDeletedContent: deletedFraction, numOfDeletedElements: deletedElements) proc adjustRadius( p: PortalProtocol, fractionOfDeletedContent: float64, furthestElementInDbDistance: UInt256) = if fractionOfDeletedContent == 0.0: # even though pruning was triggered no content was deleted, it could happen # in pathological case of really small database with really big values. # log it as error as it should not happenn error "Database pruning attempt resulted in no content deleted" return # we need to invert fraction as our Uin256 implementation does not support # multiplication by float let invertedFractionAsInt = int64(1.0 / fractionOfDeletedContent) let scaledRadius = p.dataRadius div u256(invertedFractionAsInt) # Chose larger value to avoid situation, where furthestElementInDbDistance # is super close to local id, so local radius would end up too small # to accept any more data to local database # If scaledRadius radius will be larger it will still contain all elements let newRadius = max(scaledRadius, furthestElementInDbDistance) debug "Database pruned", oldRadius = p.dataRadius, newRadius = newRadius, furthestDistanceInDb = furthestElementInDbDistance, fractionOfDeletedContent = fractionOfDeletedContent # both scaledRadius and furthestElementInDbDistance are smaller than current # dataRadius, so the radius will constantly decrease through the node # life time p.dataRadius = newRadius proc createGetHandler*(db: ContentDB): DbGetHandler = return ( proc(contentKey: ByteList, contentId: ContentId): Opt[seq[byte]] = let content = db.get(contentId).valueOr: return Opt.none(seq[byte]) ok(content) ) proc createStoreHandler*( db: ContentDB, cfg: RadiusConfig, p: PortalProtocol): DbStoreHandler = return (proc( contentKey: ByteList, contentId: ContentId, content: seq[byte]) {.raises: [], gcsafe.} = # always re-check that the key is in the node range to make sure only # content in range is stored. # TODO: current silent assumption is that both ContentDB and PortalProtocol # are using the same xor distance function if p.inRange(contentId): case cfg.kind: of Dynamic: # In case of dynamic radius setting we obey storage limits and adjust # radius to store network fraction corresponding to those storage limits. let res = db.put(contentId, content, p.baseProtocol.localNode.id) if res.kind == DbPruned: portal_pruning_counter.inc(labelValues = [$p.protocolId]) portal_pruning_deleted_elements.set( res.numOfDeletedElements.int64, labelValues = [$p.protocolId] ) p.adjustRadius( res.fractionOfDeletedContent, res.furthestStoredElementDistance ) of Static: # If the config is set statically, radius is not adjusted, and is kept # constant thorugh node life time, also database max size is disabled # so we will effectivly store fraction of the network db.put(contentId, content) )