762 lines
27 KiB
Nim
762 lines
27 KiB
Nim
# beacon_chain
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# Copyright (c) 2018-2024 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: [].}
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import std/[strutils, sequtils, algorithm]
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import stew/[results, base10], chronos, chronicles
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import
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../spec/datatypes/[phase0, altair],
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../spec/eth2_apis/rest_types,
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../spec/[helpers, forks, network],
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../networking/[peer_pool, peer_scores, eth2_network],
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../gossip_processing/block_processor,
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../beacon_clock,
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"."/[sync_protocol, sync_queue]
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export phase0, altair, merge, chronos, chronicles, results,
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helpers, peer_scores, sync_queue, forks, sync_protocol
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logScope:
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topics = "syncman"
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const
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SyncWorkersCount* = 10
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## Number of sync workers to spawn
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StatusUpdateInterval* = chronos.minutes(1)
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## Minimum time between two subsequent calls to update peer's status
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StatusExpirationTime* = chronos.minutes(2)
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## Time time it takes for the peer's status information to expire.
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type
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SyncWorkerStatus* {.pure.} = enum
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Sleeping, WaitingPeer, UpdatingStatus, Requesting, Downloading, Queueing,
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Processing
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SyncManagerFlag* {.pure.} = enum
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NoMonitor
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SyncWorker*[A, B] = object
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future: Future[void].Raising([CancelledError])
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status: SyncWorkerStatus
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SyncManager*[A, B] = ref object
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pool: PeerPool[A, B]
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DENEB_FORK_EPOCH: Epoch
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MIN_EPOCHS_FOR_BLOB_SIDECARS_REQUESTS: uint64
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responseTimeout: chronos.Duration
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maxHeadAge: uint64
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getLocalHeadSlot: GetSlotCallback
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getLocalWallSlot: GetSlotCallback
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getSafeSlot: GetSlotCallback
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getFirstSlot: GetSlotCallback
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getLastSlot: GetSlotCallback
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progressPivot: Slot
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workers: array[SyncWorkersCount, SyncWorker[A, B]]
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notInSyncEvent: AsyncEvent
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rangeAge: uint64
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chunkSize: uint64
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queue: SyncQueue[A]
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syncFut: Future[void]
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blockVerifier: BlockVerifier
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inProgress*: bool
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insSyncSpeed*: float
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avgSyncSpeed*: float
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syncStatus*: string
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direction: SyncQueueKind
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ident*: string
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flags: set[SyncManagerFlag]
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SyncMoment* = object
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stamp*: chronos.Moment
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slots*: uint64
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BeaconBlocksRes =
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NetRes[List[ref ForkedSignedBeaconBlock, Limit MAX_REQUEST_BLOCKS]]
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BlobSidecarsRes = NetRes[List[ref BlobSidecar, Limit(MAX_REQUEST_BLOB_SIDECARS)]]
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proc now*(sm: typedesc[SyncMoment], slots: uint64): SyncMoment {.inline.} =
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SyncMoment(stamp: now(chronos.Moment), slots: slots)
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proc speed*(start, finish: SyncMoment): float {.inline.} =
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## Returns number of slots per second.
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if finish.slots <= start.slots or finish.stamp <= start.stamp:
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0.0 # replays for example
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else:
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let
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slots = float(finish.slots - start.slots)
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dur = toFloatSeconds(finish.stamp - start.stamp)
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slots / dur
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proc initQueue[A, B](man: SyncManager[A, B]) =
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case man.direction
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of SyncQueueKind.Forward:
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man.queue = SyncQueue.init(A, man.direction, man.getFirstSlot(),
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man.getLastSlot(), man.chunkSize,
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man.getSafeSlot, man.blockVerifier,
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1, man.ident)
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of SyncQueueKind.Backward:
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let
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firstSlot = man.getFirstSlot()
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lastSlot = man.getLastSlot()
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startSlot = if firstSlot == lastSlot:
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# This case should never be happened in real life because
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# there is present check `needsBackfill().
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firstSlot
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else:
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Slot(firstSlot - 1'u64)
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man.queue = SyncQueue.init(A, man.direction, startSlot, lastSlot,
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man.chunkSize, man.getSafeSlot,
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man.blockVerifier, 1, man.ident)
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proc newSyncManager*[A, B](pool: PeerPool[A, B],
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denebEpoch: Epoch,
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minEpochsForBlobSidecarsRequests: uint64,
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direction: SyncQueueKind,
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getLocalHeadSlotCb: GetSlotCallback,
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getLocalWallSlotCb: GetSlotCallback,
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getFinalizedSlotCb: GetSlotCallback,
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getBackfillSlotCb: GetSlotCallback,
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getFrontfillSlotCb: GetSlotCallback,
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progressPivot: Slot,
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blockVerifier: BlockVerifier,
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maxHeadAge = uint64(SLOTS_PER_EPOCH * 1),
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chunkSize = uint64(SLOTS_PER_EPOCH),
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flags: set[SyncManagerFlag] = {},
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ident = "main"
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): SyncManager[A, B] =
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let (getFirstSlot, getLastSlot, getSafeSlot) = case direction
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of SyncQueueKind.Forward:
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(getLocalHeadSlotCb, getLocalWallSlotCb, getFinalizedSlotCb)
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of SyncQueueKind.Backward:
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(getBackfillSlotCb, getFrontfillSlotCb, getBackfillSlotCb)
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var res = SyncManager[A, B](
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pool: pool,
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DENEB_FORK_EPOCH: denebEpoch,
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MIN_EPOCHS_FOR_BLOB_SIDECARS_REQUESTS: minEpochsForBlobSidecarsRequests,
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getLocalHeadSlot: getLocalHeadSlotCb,
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getLocalWallSlot: getLocalWallSlotCb,
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getSafeSlot: getSafeSlot,
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getFirstSlot: getFirstSlot,
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getLastSlot: getLastSlot,
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progressPivot: progressPivot,
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maxHeadAge: maxHeadAge,
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chunkSize: chunkSize,
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blockVerifier: blockVerifier,
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notInSyncEvent: newAsyncEvent(),
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direction: direction,
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ident: ident,
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flags: flags
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)
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res.initQueue()
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res
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proc getBlocks[A, B](man: SyncManager[A, B], peer: A,
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req: SyncRequest): Future[BeaconBlocksRes] {.
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async: (raises: [CancelledError], raw: true).} =
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mixin getScore, `==`
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logScope:
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peer_score = peer.getScore()
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peer_speed = peer.netKbps()
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sync_ident = man.ident
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direction = man.direction
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topics = "syncman"
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doAssert(not(req.isEmpty()), "Request must not be empty!")
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debug "Requesting blocks from peer", request = req
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beaconBlocksByRange_v2(peer, req.slot, req.count, 1'u64)
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proc shouldGetBlobs[A, B](man: SyncManager[A, B], e: Epoch): bool =
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let wallEpoch = man.getLocalWallSlot().epoch
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e >= man.DENEB_FORK_EPOCH and
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(wallEpoch < man.MIN_EPOCHS_FOR_BLOB_SIDECARS_REQUESTS or
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e >= wallEpoch - man.MIN_EPOCHS_FOR_BLOB_SIDECARS_REQUESTS)
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proc getBlobSidecars[A, B](man: SyncManager[A, B], peer: A,
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req: SyncRequest): Future[BlobSidecarsRes]
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{.async: (raises: [CancelledError], raw: true).} =
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mixin getScore, `==`
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logScope:
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peer_score = peer.getScore()
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peer_speed = peer.netKbps()
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sync_ident = man.ident
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direction = man.direction
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topics = "syncman"
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doAssert(not(req.isEmpty()), "Request must not be empty!")
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debug "Requesting blobs sidecars from peer", request = req
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blobSidecarsByRange(peer, req.slot, req.count)
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proc remainingSlots(man: SyncManager): uint64 =
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let
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first = man.getFirstSlot()
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last = man.getLastSlot()
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if man.direction == SyncQueueKind.Forward:
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if last > first:
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man.getLastSlot() - man.getFirstSlot()
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else:
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0'u64
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else:
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if first > last:
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man.getFirstSlot() - man.getLastSlot()
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else:
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0'u64
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func groupBlobs*[T](req: SyncRequest[T],
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blocks: seq[ref ForkedSignedBeaconBlock],
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blobs: seq[ref BlobSidecar]):
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Result[seq[BlobSidecars], string] =
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var
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grouped = newSeq[BlobSidecars](len(blocks))
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blob_cursor = 0
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for block_idx, blck in blocks:
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withBlck(blck[]):
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when consensusFork >= ConsensusFork.Deneb:
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template kzgs: untyped = forkyBlck.message.body.blob_kzg_commitments
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if kzgs.len == 0:
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continue
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# Clients MUST include all blob sidecars of each block from which they include blob sidecars.
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# The following blob sidecars, where they exist, MUST be sent in consecutive (slot, index) order.
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# https://github.com/ethereum/consensus-specs/blob/v1.4.0-beta.5/specs/deneb/p2p-interface.md#blobsidecarsbyrange-v1
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let header = forkyBlck.toSignedBeaconBlockHeader()
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for blob_idx, kzg_commitment in kzgs:
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if blob_cursor >= blobs.len:
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return err("BlobSidecar: response too short")
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let blob_sidecar = blobs[blob_cursor]
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if blob_sidecar.index != BlobIndex blob_idx:
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return err("BlobSidecar: unexpected index")
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if blob_sidecar.kzg_commitment != kzg_commitment:
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return err("BlobSidecar: unexpected kzg_commitment")
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if blob_sidecar.signed_block_header != header:
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return err("BlobSidecar: unexpected signed_block_header")
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grouped[block_idx].add(blob_sidecar)
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inc blob_cursor
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if blob_cursor != len(blobs):
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# we reached end of blocks without consuming all blobs so either
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# the peer we got too few blocks in the paired request, or the
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# peer is sending us spurious blobs.
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Result[seq[BlobSidecars], string].err "invalid block or blob sequence"
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else:
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Result[seq[BlobSidecars], string].ok grouped
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func checkBlobs(blobs: seq[BlobSidecars]): Result[void, string] =
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for blob_sidecars in blobs:
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for blob_sidecar in blob_sidecars:
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? blob_sidecar[].verify_blob_sidecar_inclusion_proof()
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ok()
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proc syncStep[A, B](man: SyncManager[A, B], index: int, peer: A)
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{.async: (raises: [CancelledError]).} =
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logScope:
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peer_score = peer.getScore()
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peer_speed = peer.netKbps()
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index = index
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sync_ident = man.ident
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topics = "syncman"
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var
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headSlot = man.getLocalHeadSlot()
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wallSlot = man.getLocalWallSlot()
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peerSlot = peer.getHeadSlot()
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block: # Check that peer status is recent and relevant
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logScope:
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peer = peer
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direction = man.direction
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debug "Peer's syncing status", wall_clock_slot = wallSlot,
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remote_head_slot = peerSlot, local_head_slot = headSlot
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let
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peerStatusAge = Moment.now() - peer.getStatusLastTime()
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needsUpdate =
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# Latest status we got is old
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peerStatusAge >= StatusExpirationTime or
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# The point we need to sync is close to where the peer is
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man.getFirstSlot() >= peerSlot
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if needsUpdate:
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man.workers[index].status = SyncWorkerStatus.UpdatingStatus
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# Avoid a stampede of requests, but make them more frequent in case the
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# peer is "close" to the slot range of interest
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if peerStatusAge < StatusExpirationTime div 2:
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await sleepAsync(StatusExpirationTime div 2 - peerStatusAge)
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trace "Updating peer's status information", wall_clock_slot = wallSlot,
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remote_head_slot = peerSlot, local_head_slot = headSlot
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if not await peer.updateStatus():
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peer.updateScore(PeerScoreNoStatus)
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debug "Failed to get remote peer's status, exiting",
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peer_head_slot = peerSlot
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return
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let newPeerSlot = peer.getHeadSlot()
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if peerSlot >= newPeerSlot:
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peer.updateScore(PeerScoreStaleStatus)
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debug "Peer's status information is stale",
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wall_clock_slot = wallSlot, remote_old_head_slot = peerSlot,
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local_head_slot = headSlot, remote_new_head_slot = newPeerSlot
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else:
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debug "Peer's status information updated", wall_clock_slot = wallSlot,
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remote_old_head_slot = peerSlot, local_head_slot = headSlot,
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remote_new_head_slot = newPeerSlot
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peer.updateScore(PeerScoreGoodStatus)
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peerSlot = newPeerSlot
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# Time passed - enough to move slots, if sleep happened
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headSlot = man.getLocalHeadSlot()
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wallSlot = man.getLocalWallSlot()
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if man.remainingSlots() <= man.maxHeadAge:
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logScope:
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peer = peer
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direction = man.direction
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case man.direction
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of SyncQueueKind.Forward:
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info "We are in sync with network", wall_clock_slot = wallSlot,
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remote_head_slot = peerSlot, local_head_slot = headSlot
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of SyncQueueKind.Backward:
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info "Backfill complete", wall_clock_slot = wallSlot,
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remote_head_slot = peerSlot, local_head_slot = headSlot
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# We clear SyncManager's `notInSyncEvent` so all the workers will become
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# sleeping soon.
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man.notInSyncEvent.clear()
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return
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# Find out if the peer potentially can give useful blocks - in the case of
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# forward sync, they can be useful if they have blocks newer than our head -
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# in the case of backwards sync, they're useful if they have blocks newer than
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# the backfill point
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if man.getFirstSlot() >= peerSlot:
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# This is not very good solution because we should not discriminate and/or
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# penalize peers which are in sync process too, but their latest head is
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# lower then our latest head. We should keep connections with such peers
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# (so this peers are able to get in sync using our data), but we should
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# not use this peers for syncing because this peers are useless for us.
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# Right now we decreasing peer's score a bit, so it will not be
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# disconnected due to low peer's score, but new fresh peers could replace
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# peers with low latest head.
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debug "Peer's head slot is lower then local head slot", peer = peer,
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wall_clock_slot = wallSlot, remote_head_slot = peerSlot,
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local_last_slot = man.getLastSlot(),
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local_first_slot = man.getFirstSlot(),
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direction = man.direction
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peer.updateScore(PeerScoreUseless)
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return
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# Wall clock keeps ticking, so we need to update the queue
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man.queue.updateLastSlot(man.getLastSlot())
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man.workers[index].status = SyncWorkerStatus.Requesting
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let req = man.queue.pop(peerSlot, peer)
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if req.isEmpty():
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# SyncQueue could return empty request in 2 cases:
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# 1. There no more slots in SyncQueue to download (we are synced, but
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# our ``notInSyncEvent`` is not yet cleared).
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# 2. Current peer's known head slot is too low to satisfy request.
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#
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# To avoid endless loop we going to wait for RESP_TIMEOUT time here.
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# This time is enough for all pending requests to finish and it is also
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# enough for main sync loop to clear ``notInSyncEvent``.
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debug "Empty request received from queue, exiting", peer = peer,
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local_head_slot = headSlot, remote_head_slot = peerSlot,
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queue_input_slot = man.queue.inpSlot,
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queue_output_slot = man.queue.outSlot,
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queue_last_slot = man.queue.finalSlot, direction = man.direction
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await sleepAsync(RESP_TIMEOUT_DUR)
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return
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debug "Creating new request for peer", wall_clock_slot = wallSlot,
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remote_head_slot = peerSlot, local_head_slot = headSlot,
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request = req
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man.workers[index].status = SyncWorkerStatus.Downloading
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let blocks = (await man.getBlocks(peer, req)).valueOr:
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peer.updateScore(PeerScoreNoValues)
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man.queue.push(req)
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debug "Failed to receive blocks on request", request = req
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return
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let blockSmap = getShortMap(req, blocks.asSeq())
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debug "Received blocks on request", blocks_count = len(blocks),
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blocks_map = blockSmap, request = req
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let slots = mapIt(blocks, it[].slot)
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if not(checkResponse(req, slots)):
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peer.updateScore(PeerScoreBadResponse)
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man.queue.push(req)
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warn "Received blocks sequence is not in requested range",
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blocks_count = len(blocks), blocks_map = blockSmap,
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request = req
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return
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func combine(acc: seq[Slot], cur: Slot): seq[Slot] =
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var copy = acc
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if copy[copy.len-1] != cur:
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copy.add(cur)
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copy
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let blobData =
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if man.shouldGetBlobs(req.slot.epoch):
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let blobs = (await man.getBlobSidecars(peer, req)).valueOr:
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peer.updateScore(PeerScoreNoValues)
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man.queue.push(req)
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debug "Failed to receive blobs on request", request = req
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return
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let blobSmap = getShortMap(req, blobs.asSeq())
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debug "Received blobs on request", blobs_count = len(blobs),
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blobs_map = blobSmap, request = req
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if len(blobs) > 0:
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let slots = mapIt(blobs, it[].signed_block_header.message.slot)
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let uniqueSlots = foldl(slots, combine(a, b), @[slots[0]])
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if not(checkResponse(req, uniqueSlots)):
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peer.updateScore(PeerScoreBadResponse)
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man.queue.push(req)
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warn "Received blobs sequence is not in requested range",
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blobs_count = len(blobs), blobs_map = blobSmap,
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request = req
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return
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let groupedBlobs = groupBlobs(req, blocks.asSeq(), blobs.asSeq())
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if groupedBlobs.isErr():
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peer.updateScore(PeerScoreNoValues)
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man.queue.push(req)
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info "Received blobs sequence is inconsistent",
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blobs_map = blobSmap, request = req, msg=groupedBlobs.error()
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return
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if (let checkRes = groupedBlobs.get.checkBlobs(); checkRes.isErr):
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peer.updateScore(PeerScoreBadResponse)
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man.queue.push(req)
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warn "Received blobs sequence is invalid",
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blobs_map = blobSmap, request = req, msg=groupedBlobs.error()
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return
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Opt.some(groupedBlobs.get())
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else:
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Opt.none(seq[BlobSidecars])
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if len(blocks) == 0 and man.direction == SyncQueueKind.Backward and
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req.contains(man.getSafeSlot()):
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# The sync protocol does not distinguish between:
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# - All requested slots are empty
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# - Peer does not have data available about requested range
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#
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# However, we include the `backfill` slot in backward sync requests.
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# If we receive an empty response to a request covering that slot,
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# we know that the response is incomplete and can descore.
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peer.updateScore(PeerScoreNoValues)
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man.queue.push(req)
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debug "Response does not include known-to-exist block", request = req
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return
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# Scoring will happen in `syncUpdate`.
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|
man.workers[index].status = SyncWorkerStatus.Queueing
|
|
let
|
|
peerFinalized = peer.getFinalizedEpoch().start_slot()
|
|
lastSlot = req.slot + req.count
|
|
# The peer claims the block is finalized - our own block processing will
|
|
# verify this point down the line
|
|
# TODO descore peers that lie
|
|
maybeFinalized = lastSlot < peerFinalized
|
|
|
|
await man.queue.push(req, blocks.asSeq(), blobData, maybeFinalized, proc() =
|
|
man.workers[index].status = SyncWorkerStatus.Processing)
|
|
|
|
proc syncWorker[A, B](man: SyncManager[A, B], index: int) {.async: (raises: [CancelledError]).} =
|
|
mixin getKey, getScore, getHeadSlot
|
|
|
|
logScope:
|
|
index = index
|
|
sync_ident = man.ident
|
|
direction = man.direction
|
|
topics = "syncman"
|
|
|
|
debug "Starting syncing worker"
|
|
|
|
var peer: A = nil
|
|
|
|
try:
|
|
while true:
|
|
man.workers[index].status = SyncWorkerStatus.Sleeping
|
|
# This event is going to be set until we are not in sync with network
|
|
await man.notInSyncEvent.wait()
|
|
man.workers[index].status = SyncWorkerStatus.WaitingPeer
|
|
peer = await man.pool.acquire()
|
|
await man.syncStep(index, peer)
|
|
man.pool.release(peer)
|
|
peer = nil
|
|
finally:
|
|
if not(isNil(peer)):
|
|
man.pool.release(peer)
|
|
|
|
debug "Sync worker stopped"
|
|
|
|
proc getWorkersStats[A, B](man: SyncManager[A, B]): tuple[map: string,
|
|
sleeping: int,
|
|
waiting: int,
|
|
pending: int] =
|
|
var map = newString(len(man.workers))
|
|
var sleeping, waiting, pending: int
|
|
for i in 0 ..< len(man.workers):
|
|
var ch: char
|
|
case man.workers[i].status
|
|
of SyncWorkerStatus.Sleeping:
|
|
ch = 's'
|
|
inc(sleeping)
|
|
of SyncWorkerStatus.WaitingPeer:
|
|
ch = 'w'
|
|
inc(waiting)
|
|
of SyncWorkerStatus.UpdatingStatus:
|
|
ch = 'U'
|
|
inc(pending)
|
|
of SyncWorkerStatus.Requesting:
|
|
ch = 'R'
|
|
inc(pending)
|
|
of SyncWorkerStatus.Downloading:
|
|
ch = 'D'
|
|
inc(pending)
|
|
of SyncWorkerStatus.Queueing:
|
|
ch = 'Q'
|
|
inc(pending)
|
|
of SyncWorkerStatus.Processing:
|
|
ch = 'P'
|
|
inc(pending)
|
|
map[i] = ch
|
|
(map, sleeping, waiting, pending)
|
|
|
|
proc startWorkers[A, B](man: SyncManager[A, B]) =
|
|
# Starting all the synchronization workers.
|
|
for i in 0 ..< len(man.workers):
|
|
man.workers[i].future = syncWorker[A, B](man, i)
|
|
|
|
proc toTimeLeftString*(d: Duration): string =
|
|
if d == InfiniteDuration:
|
|
"--h--m"
|
|
else:
|
|
var v = d
|
|
var res = ""
|
|
let ndays = chronos.days(v)
|
|
if ndays > 0:
|
|
res = res & (if ndays < 10: "0" & $ndays else: $ndays) & "d"
|
|
v = v - chronos.days(ndays)
|
|
|
|
let nhours = chronos.hours(v)
|
|
if nhours > 0:
|
|
res = res & (if nhours < 10: "0" & $nhours else: $nhours) & "h"
|
|
v = v - chronos.hours(nhours)
|
|
else:
|
|
res = res & "00h"
|
|
|
|
let nmins = chronos.minutes(v)
|
|
if nmins > 0:
|
|
res = res & (if nmins < 10: "0" & $nmins else: $nmins) & "m"
|
|
v = v - chronos.minutes(nmins)
|
|
else:
|
|
res = res & "00m"
|
|
res
|
|
|
|
proc syncClose[A, B](man: SyncManager[A, B],
|
|
speedTaskFut: Future[void]) {.async.} =
|
|
var pending: seq[FutureBase]
|
|
if not(speedTaskFut.finished()):
|
|
pending.add(speedTaskFut.cancelAndWait())
|
|
for worker in man.workers:
|
|
doAssert(worker.status in {Sleeping, WaitingPeer})
|
|
pending.add(worker.future.cancelAndWait())
|
|
await noCancel allFutures(pending)
|
|
|
|
proc syncLoop[A, B](man: SyncManager[A, B]) {.async.} =
|
|
logScope:
|
|
sync_ident = man.ident
|
|
direction = man.direction
|
|
topics = "syncman"
|
|
|
|
mixin getKey, getScore
|
|
var pauseTime = 0
|
|
|
|
man.startWorkers()
|
|
|
|
debug "Synchronization loop started"
|
|
|
|
proc averageSpeedTask() {.async: (raises: [CancelledError]).} =
|
|
while true:
|
|
# Reset sync speeds between each loss-of-sync event
|
|
man.avgSyncSpeed = 0
|
|
man.insSyncSpeed = 0
|
|
|
|
await man.notInSyncEvent.wait()
|
|
|
|
# Give the node time to connect to peers and get the sync process started
|
|
await sleepAsync(seconds(SECONDS_PER_SLOT.int64))
|
|
|
|
var
|
|
stamp = SyncMoment.now(man.queue.progress())
|
|
syncCount = 0
|
|
|
|
while man.inProgress:
|
|
await sleepAsync(seconds(SECONDS_PER_SLOT.int64))
|
|
|
|
let
|
|
newStamp = SyncMoment.now(man.queue.progress())
|
|
slotsPerSec = speed(stamp, newStamp)
|
|
|
|
syncCount += 1
|
|
|
|
man.insSyncSpeed = slotsPerSec
|
|
man.avgSyncSpeed =
|
|
man.avgSyncSpeed + (slotsPerSec - man.avgSyncSpeed) / float(syncCount)
|
|
|
|
stamp = newStamp
|
|
|
|
let averageSpeedTaskFut = averageSpeedTask()
|
|
|
|
while true:
|
|
let wallSlot = man.getLocalWallSlot()
|
|
let headSlot = man.getLocalHeadSlot()
|
|
|
|
let (map, sleeping, waiting, pending) = man.getWorkersStats()
|
|
|
|
debug "Current syncing state", workers_map = map,
|
|
sleeping_workers_count = sleeping,
|
|
waiting_workers_count = waiting,
|
|
pending_workers_count = pending,
|
|
wall_head_slot = wallSlot, local_head_slot = headSlot,
|
|
pause_time = $chronos.seconds(pauseTime),
|
|
avg_sync_speed = man.avgSyncSpeed, ins_sync_speed = man.insSyncSpeed
|
|
|
|
let
|
|
pivot = man.progressPivot
|
|
progress =
|
|
case man.queue.kind
|
|
of SyncQueueKind.Forward:
|
|
if man.queue.outSlot >= pivot:
|
|
man.queue.outSlot - pivot
|
|
else:
|
|
0'u64
|
|
of SyncQueueKind.Backward:
|
|
if pivot >= man.queue.outSlot:
|
|
pivot - man.queue.outSlot
|
|
else:
|
|
0'u64
|
|
total =
|
|
case man.queue.kind
|
|
of SyncQueueKind.Forward:
|
|
if man.queue.finalSlot >= pivot:
|
|
man.queue.finalSlot + 1'u64 - pivot
|
|
else:
|
|
0'u64
|
|
of SyncQueueKind.Backward:
|
|
if pivot >= man.queue.finalSlot:
|
|
pivot + 1'u64 - man.queue.finalSlot
|
|
else:
|
|
0'u64
|
|
remaining = total - progress
|
|
done =
|
|
if total > 0:
|
|
progress.float / total.float
|
|
else:
|
|
1.0
|
|
timeleft =
|
|
if man.avgSyncSpeed >= 0.001:
|
|
Duration.fromFloatSeconds(remaining.float / man.avgSyncSpeed)
|
|
else:
|
|
InfiniteDuration
|
|
currentSlot = Base10.toString(
|
|
if man.queue.kind == SyncQueueKind.Forward:
|
|
max(uint64(man.queue.outSlot), 1'u64) - 1'u64
|
|
else:
|
|
uint64(man.queue.outSlot) + 1'u64
|
|
)
|
|
|
|
# Update status string
|
|
man.syncStatus = timeleft.toTimeLeftString() & " (" &
|
|
(done * 100).formatBiggestFloat(ffDecimal, 2) & "%) " &
|
|
man.avgSyncSpeed.formatBiggestFloat(ffDecimal, 4) &
|
|
"slots/s (" & map & ":" & currentSlot & ")"
|
|
|
|
if man.remainingSlots() <= man.maxHeadAge:
|
|
man.notInSyncEvent.clear()
|
|
# We are marking SyncManager as not working only when we are in sync and
|
|
# all sync workers are in `Sleeping` state.
|
|
if pending > 0:
|
|
debug "Synchronization loop waits for workers completion",
|
|
wall_head_slot = wallSlot, local_head_slot = headSlot,
|
|
difference = (wallSlot - headSlot), max_head_age = man.maxHeadAge,
|
|
sleeping_workers_count = sleeping,
|
|
waiting_workers_count = waiting, pending_workers_count = pending
|
|
# We already synced, so we should reset all the pending workers from
|
|
# any state they have.
|
|
man.queue.clearAndWakeup()
|
|
man.inProgress = true
|
|
else:
|
|
case man.direction
|
|
of SyncQueueKind.Forward:
|
|
if man.inProgress:
|
|
if SyncManagerFlag.NoMonitor in man.flags:
|
|
await man.syncClose(averageSpeedTaskFut)
|
|
man.inProgress = false
|
|
debug "Forward synchronization process finished, exiting",
|
|
wall_head_slot = wallSlot, local_head_slot = headSlot,
|
|
difference = (wallSlot - headSlot),
|
|
max_head_age = man.maxHeadAge
|
|
break
|
|
else:
|
|
man.inProgress = false
|
|
debug "Forward synchronization process finished, sleeping",
|
|
wall_head_slot = wallSlot, local_head_slot = headSlot,
|
|
difference = (wallSlot - headSlot),
|
|
max_head_age = man.maxHeadAge
|
|
else:
|
|
debug "Synchronization loop sleeping", wall_head_slot = wallSlot,
|
|
local_head_slot = headSlot,
|
|
difference = (wallSlot - headSlot),
|
|
max_head_age = man.maxHeadAge
|
|
of SyncQueueKind.Backward:
|
|
# Backward syncing is going to be executed only once, so we exit loop
|
|
# and stop all pending tasks which belongs to this instance (sync
|
|
# workers, speed calculation task).
|
|
await man.syncClose(averageSpeedTaskFut)
|
|
man.inProgress = false
|
|
debug "Backward synchronization process finished, exiting",
|
|
wall_head_slot = wallSlot, local_head_slot = headSlot,
|
|
backfill_slot = man.getLastSlot(),
|
|
max_head_age = man.maxHeadAge
|
|
break
|
|
else:
|
|
if not(man.notInSyncEvent.isSet()):
|
|
# We get here only if we lost sync for more then `maxHeadAge` period.
|
|
if pending == 0:
|
|
man.initQueue()
|
|
man.notInSyncEvent.fire()
|
|
man.inProgress = true
|
|
debug "Node lost sync for more then preset period",
|
|
period = man.maxHeadAge, wall_head_slot = wallSlot,
|
|
local_head_slot = headSlot,
|
|
missing_slots = man.remainingSlots(),
|
|
progress = float(man.queue.progress())
|
|
else:
|
|
man.notInSyncEvent.fire()
|
|
man.inProgress = true
|
|
|
|
await sleepAsync(chronos.seconds(2))
|
|
|
|
proc start*[A, B](man: SyncManager[A, B]) =
|
|
## Starts SyncManager's main loop.
|
|
man.syncFut = man.syncLoop()
|