280 lines
9.7 KiB
Nim
280 lines
9.7 KiB
Nim
# Nimbus
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# Copyright (c) 2021-2022 Status Research & Development GmbH
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# Licensed and distributed under either of
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# * MIT license (license terms in the root directory or at https://opensource.org/licenses/MIT).
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# * Apache v2 license (license terms in the root directory or at https://www.apache.org/licenses/LICENSE-2.0).
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# at your option. This file may not be copied, modified, or distributed except according to those terms.
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{.push raises: [Defect].}
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import
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std/[options, heapqueue],
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eth/db/kvstore,
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eth/db/kvstore_sqlite3,
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stint,
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./network/state/state_content
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export kvstore_sqlite3
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# This version of content db is the most basic, simple solution where data is
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# stored no matter what content type or content network in the same kvstore with
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# the content id as key. The content id is derived from the content key, and the
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# deriviation is different depending on the content type. As we use content id,
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# this part is currently out of the scope / API of the ContentDB.
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# In the future it is likely that that either:
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# 1. More kvstores are added per network, and thus depending on the network a
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# different kvstore needs to be selected.
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# 2. Or more kvstores are added per network and per content type, and thus
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# content key fields are required to access the data.
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# 3. Or databases are created per network (and kvstores pre content type) and
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# thus depending on the network the right db needs to be selected.
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const
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# Maximal number of ObjInfo objects held in memory per database scan. 100k
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# objects should result in memory usage of around 7mb which should be
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# appropriate for even low resource devices
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maxObjPerScan = 100000
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type
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RowInfo = tuple
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contentId: array[32, byte]
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payloadLength: int64
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ObjInfo* = object
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contentId*: array[32, byte]
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payloadLength*: int64
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distFrom*: UInt256
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ContentDB* = ref object
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kv: KvStoreRef
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maxSize: uint32
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sizeStmt: SqliteStmt[NoParams, int64]
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vacStmt: SqliteStmt[NoParams, void]
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getAll: SqliteStmt[NoParams, RowInfo]
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PutResultType* = enum
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ContentStored, DbPruned
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PutResult* = object
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case kind*: PutResultType
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of ContentStored:
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discard
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of DbPruned:
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furthestStoredElementDistance*: UInt256
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fractionOfDeletedContent*: float64
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numOfDeletedElements*: int64
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# Objects must be sorted from largest to closest distance
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proc `<`(a, b: ObjInfo): bool =
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return a.distFrom < b.distFrom
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template expectDb(x: auto): untyped =
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# There's no meaningful error handling implemented for a corrupt database or
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# full disk - this requires manual intervention, so we'll panic for now
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x.expect("working database (disk broken/full?)")
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proc new*(T: type ContentDB, path: string, maxSize: uint32, inMemory = false): ContentDB =
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let db =
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if inMemory:
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SqStoreRef.init("", "fluffy-test", inMemory = true).expect(
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"working database (out of memory?)")
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else:
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SqStoreRef.init(path, "fluffy").expectDb()
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let getSizeStmt = db.prepareStmt(
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"SELECT page_count * page_size as size FROM pragma_page_count(), pragma_page_size();",
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NoParams, int64).get()
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let vacStmt = db.prepareStmt(
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"VACUUM;",
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NoParams, void).get()
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let kvStore = kvStore db.openKvStore().expectDb()
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# This needs to go after `openKvStore`, as it checks whether the table name
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# kvstore already exists.
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let getKeysStmt = db.prepareStmt(
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"SELECT key, length(value) FROM kvstore",
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NoParams, RowInfo
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).get()
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ContentDB(
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kv: kvStore, maxSize: maxSize, sizeStmt: getSizeStmt, vacStmt: vacStmt, getAll: getKeysStmt)
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proc getNFurthestElements*(
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db: ContentDB, target: UInt256, n: uint64): (seq[ObjInfo], int64) =
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## Get at most n furthest elements from db in order from furthest to closest.
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## Payload lengths are also returned so the caller can decide how many of
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## those elements need to be deleted.
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##
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## Currently it uses xor metric
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##
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## Currently works by querying for all elements in database and doing all
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## necessary work on program level. This is mainly due to two facts:
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## - sqlite does not have build xor function, also it does not handle bitwise
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## operations on blobs as expected
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## - our nim wrapper for sqlite does not support create_function api of sqlite
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## so we cannot create custom function comparing blobs at sql level. If that
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## would be possible we may be able to all this work by one sql query
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if n == 0:
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return (newSeq[ObjInfo](), 0'i64)
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var heap = initHeapQueue[ObjInfo]()
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var totalContentSize: int64 = 0
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var ri: RowInfo
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for e in db.getAll.exec(ri):
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let contentId = UInt256.fromBytesBE(ri.contentId)
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# TODO: Currently it assumes xor distance, but when we start testing
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# networks with other distance functions this needs to be adjusted to the
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# custom distance function
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let dist = contentId xor target
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let obj = ObjInfo(
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contentId: ri.contentId, payloadLength: ri.payloadLength, distFrom: dist)
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if (uint64(len(heap)) < n):
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heap.push(obj)
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else:
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if obj > heap[0]:
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discard heap.replace(obj)
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totalContentSize = totalContentSize + ri.payloadLength
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var res: seq[ObjInfo] = newSeq[ObjInfo](heap.len())
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var i = heap.len() - 1
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while heap.len() > 0:
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res[i] = heap.pop()
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dec i
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return (res, totalContentSize)
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proc reclaimSpace*(db: ContentDB): void =
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## Runs sqlite VACUUM commands which rebuilds the db, repacking it into a
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## minimal amount of disk space.
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## Ideal mode of operation, is to run it after several deletes.
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## Another options would be to run 'PRAGMA auto_vacuum = FULL;' statement at
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## the start of db to leave it up to sqlite to clean up
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db.vacStmt.exec().expectDb()
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proc size*(db: ContentDB): int64 =
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## Retrun current size of DB as product of sqlite page_count and page_size
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## https://www.sqlite.org/pragma.html#pragma_page_count
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## https://www.sqlite.org/pragma.html#pragma_page_size
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## It returns total size of db i.e both data and metadata used to store content
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## also it is worth noting that when deleting content, size may lags behind due
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## to the way how deleting works in sqlite.
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## Good description can be found in: https://www.sqlite.org/lang_vacuum.html
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var size: int64 = 0
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discard (db.sizeStmt.exec do(res: int64):
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size = res).expectDb()
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return size
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proc get*(db: ContentDB, key: openArray[byte]): Option[seq[byte]] =
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var res: Option[seq[byte]]
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proc onData(data: openArray[byte]) = res = some(@data)
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discard db.kv.get(key, onData).expectDb()
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return res
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proc put(db: ContentDB, key, value: openArray[byte]) =
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db.kv.put(key, value).expectDb()
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proc contains*(db: ContentDB, key: openArray[byte]): bool =
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db.kv.contains(key).expectDb()
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proc del*(db: ContentDB, key: openArray[byte]) =
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db.kv.del(key).expectDb()
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# TODO: Could also decide to use the ContentKey SSZ bytestring, as this is what
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# gets send over the network in requests, but that would be a bigger key. Or the
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# same hashing could be done on it here.
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# However ContentId itself is already derived through different digests
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# depending on the content type, and this ContentId typically needs to be
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# checked with the Radius/distance of the node anyhow. So lets see how we end up
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# using this mostly in the code.
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proc get*(db: ContentDB, key: ContentId): Option[seq[byte]] =
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# TODO: Here it is unfortunate that ContentId is a uint256 instead of Digest256.
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db.get(key.toByteArrayBE())
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proc put*(db: ContentDB, key: ContentId, value: openArray[byte]) =
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db.put(key.toByteArrayBE(), value)
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proc contains*(db: ContentDB, key: ContentId): bool =
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db.contains(key.toByteArrayBE())
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proc del*(db: ContentDB, key: ContentId) =
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db.del(key.toByteArrayBE())
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proc deleteFractionOfContent(
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db: ContentDB,
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target: Uint256,
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targetFraction: float64): (UInt256, int64, int64, int64) =
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## Procedure which tries to delete fraction of database by scanning maxObjPerScan
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## furthest elements.
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## If the maxObjPerScan furthest elements, is not enough to attain required fraction
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## procedure deletes all but one element and report how many bytes have been
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## deleted
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## Procedure do not call reclaim space, it is left to the caller.
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let (furthestElements, totalContentSize) = db.getNFurthestElements(target, maxObjPerScan)
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var bytesDeleted: int64 = 0
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let bytesToDelete = int64(targetFraction * float64(totalContentSize))
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let numOfElements = len(furthestElements)
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var numOfDeletedElements: int64 = 0
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if numOfElements == 0:
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# no elements in database, return some zero value
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return (UInt256.zero, 0'i64, 0'i64, 0'i64)
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let lastIdx = len(furthestElements) - 1
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for i, elem in furthestElements:
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if i == lastIdx:
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# this is our last element, do not delete it and report it as last non deleted
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# element
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return (elem.distFrom, bytesDeleted, totalContentSize, numOfDeletedElements)
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if bytesDeleted + elem.payloadLength < bytesToDelete:
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db.del(elem.contentId)
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bytesDeleted = bytesDeleted + elem.payloadLength
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inc numOfDeletedElements
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else:
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return (elem.distFrom, bytesDeleted, totalContentSize, numOfDeletedElements)
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proc put*(
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db: ContentDB,
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key: ContentId,
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value: openArray[byte],
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target: UInt256): PutResult =
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db.put(key, value)
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let dbSize = db.size()
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if dbSize < int64(db.maxSize):
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return PutResult(kind: ContentStored)
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else:
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# TODO Add some configuration for this magic number
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let (
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furthestNonDeletedElement,
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deletedBytes,
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totalContentSize,
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deletedElements
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) =
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db.deleteFractionOfContent(target, 0.25)
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let deletedFraction = float64(deletedBytes) / float64(totalContentSize)
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db.reclaimSpace()
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return PutResult(
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kind: DbPruned,
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furthestStoredElementDistance: furthestNonDeletedElement,
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fractionOfDeletedContent: deletedFraction,
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numOfDeletedElements: deletedElements)
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