654 lines
23 KiB
Nim
654 lines
23 KiB
Nim
import std/[tables, heapqueue]
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import chronos
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type
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PeerType* = enum
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None, Incoming, Outgoing
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PeerFlags = enum
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Acquired, DeleteOnRelease
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EventType = enum
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NotEmptyEvent, NotFullEvent
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PeerItem[T] = object
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data: T
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peerType: PeerType
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flags: set[PeerFlags]
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index: int
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PeerIndex = object
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data: int
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cmp: proc(a, b: PeerIndex): bool {.closure, gcsafe.}
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PeerScoreCheckCallback*[T] = proc(peer: T): bool {.gcsafe, raises: [Defect].}
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PeerCounterCallback* = proc() {.gcsafe, raises: [Defect].}
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PeerPool*[A, B] = ref object
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incNotEmptyEvent: AsyncEvent
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outNotEmptyEvent: AsyncEvent
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incNotFullEvent: AsyncEvent
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outNotFullEvent: AsyncEvent
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incQueue: HeapQueue[PeerIndex]
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outQueue: HeapQueue[PeerIndex]
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registry: Table[B, PeerIndex]
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storage: seq[PeerItem[A]]
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cmp: proc(a, b: PeerIndex): bool {.closure, gcsafe.}
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scoreCheck: PeerScoreCheckCallback[A]
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peerCounter: PeerCounterCallback
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maxPeersCount: int
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maxIncPeersCount: int
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maxOutPeersCount: int
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curIncPeersCount: int
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curOutPeersCount: int
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acqIncPeersCount: int
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acqOutPeersCount: int
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PeerPoolError* = object of CatchableError
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proc `<`*(a, b: PeerIndex): bool =
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a.cmp(b, a)
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proc fireNotEmptyEvent[A, B](pool: PeerPool[A, B],
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item: PeerItem[A]) {.inline.} =
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if item.peerType == PeerType.Incoming:
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pool.incNotEmptyEvent.fire()
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elif item.peerType == PeerType.Outgoing:
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pool.outNotEmptyEvent.fire()
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proc fireNotFullEvent[A, B](pool: PeerPool[A, B],
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item: PeerItem[A]) {.inline.} =
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if item.peerType == PeerType.Incoming:
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pool.incNotFullEvent.fire()
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elif item.peerType == PeerType.Outgoing:
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pool.outNotFullEvent.fire()
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iterator pairs*[A, B](pool: PeerPool[A, B]): (B, A) =
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for peerId, peerIdx in pool.registry:
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yield (peerId, pool.storage[peerIdx.data].data)
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template incomingEvent(eventType: EventType): AsyncEvent =
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case eventType
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of EventType.NotEmptyEvent:
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pool.incNotEmptyEvent
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of EventType.NotFullEvent:
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pool.incNotFullEvent
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template outgoingEvent(eventType: EventType): AsyncEvent =
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case eventType
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of EventType.NotEmptyEvent:
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pool.outNotEmptyEvent
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of EventType.NotFullEvent:
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pool.outNotFullEvent
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proc waitForEvent[A, B](pool: PeerPool[A, B], eventType: EventType,
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filter: set[PeerType]) {.async.} =
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if filter == {PeerType.Incoming, PeerType.Outgoing} or filter == {}:
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var fut1 = incomingEvent(eventType).wait()
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var fut2 = outgoingEvent(eventType).wait()
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try:
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discard await one(fut1, fut2)
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if fut1.finished:
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if not(fut2.finished):
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fut2.cancel()
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incomingEvent(eventType).clear()
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else:
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if not(fut1.finished):
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fut1.cancel()
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outgoingEvent(eventType).clear()
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except CancelledError as exc:
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if not(fut1.finished):
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fut1.cancel()
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if not(fut2.finished):
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fut2.cancel()
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raise exc
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elif PeerType.Incoming in filter:
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await incomingEvent(eventType).wait()
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incomingEvent(eventType).clear()
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elif PeerType.Outgoing in filter:
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await outgoingEvent(eventType).wait()
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outgoingEvent(eventType).clear()
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proc waitNotEmptyEvent[A, B](pool: PeerPool[A, B],
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filter: set[PeerType]): Future[void] =
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pool.waitForEvent(EventType.NotEmptyEvent, filter)
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proc waitNotFullEvent[A, B](pool: PeerPool[A, B],
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filter: set[PeerType]): Future[void] =
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pool.waitForEvent(EventType.NotFullEvent, filter)
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proc newPeerPool*[A, B](maxPeers = -1, maxIncomingPeers = -1,
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maxOutgoingPeers = -1,
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scoreCheckCb: PeerScoreCheckCallback[A] = nil,
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peerCounterCb: PeerCounterCallback = nil): PeerPool[A, B] =
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## Create new PeerPool.
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##
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## ``maxPeers`` - maximum number of peers allowed. All the peers which
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## exceeds this number will be rejected (``addPeer()`` procedure will return
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## ``false``). By default this number is infinite.
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##
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## ``maxIncomingPeers`` - maximum number of incoming peers allowed. All the
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## incoming peers exceeds this number will be rejected. By default this
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## number is infinite.
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##
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## ``maxOutgoingPeers`` - maximum number of outgoing peers allowed. All the
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## outgoing peers exceeds this number will be rejected. By default this
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## number if infinite.
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##
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## ``scoreCheckCb`` - callback which will be called for all released peers.
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## If callback procedure returns ``false`` peer will be removed from
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## PeerPool.
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##
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## ``peerCountCb`` - callback to be called when number of peers in PeerPool
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## has been changed.
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##
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## Please note, that if ``maxPeers`` is positive non-zero value, then equation
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## ``maxPeers >= maxIncomingPeers + maxOutgoingPeers`` must be ``true``.
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var res = PeerPool[A, B]()
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if maxPeers != -1:
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doAssert(maxPeers >= maxIncomingPeers + maxOutgoingPeers)
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res.maxPeersCount = if maxPeers < 0: high(int)
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else: maxPeers
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res.maxIncPeersCount = if maxIncomingPeers < 0: high(int)
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else: maxIncomingPeers
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res.maxOutPeersCount = if maxOutgoingPeers < 0: high(int)
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else: maxOutgoingPeers
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res.incNotEmptyEvent = newAsyncEvent()
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res.outNotEmptyEvent = newAsyncEvent()
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res.incNotFullEvent = newAsyncEvent()
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res.outNotFullEvent = newAsyncEvent()
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res.incQueue = initHeapQueue[PeerIndex]()
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res.outQueue = initHeapQueue[PeerIndex]()
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res.registry = initTable[B, PeerIndex]()
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res.scoreCheck = scoreCheckCb
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res.peerCounter = peerCounterCb
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res.storage = newSeq[PeerItem[A]]()
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proc peerCmp(a, b: PeerIndex): bool {.closure, gcsafe.} =
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let p1 = res.storage[a.data].data
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let p2 = res.storage[b.data].data
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p1 < p2
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res.cmp = peerCmp
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res
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proc len*[A, B](pool: PeerPool[A, B]): int =
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## Returns number of registered peers in PeerPool ``pool``. This number
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## includes all the peers (acquired and available).
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len(pool.registry)
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proc lenAvailable*[A, B](pool: PeerPool[A, B],
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filter = {PeerType.Incoming,
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PeerType.Outgoing}): int {.inline.} =
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## Returns number of available peers in PeerPool ``pool`` which satisfies
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## filter ``filter``.
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(if PeerType.Incoming in filter: len(pool.incQueue) else: 0) +
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(if PeerType.Outgoing in filter: len(pool.outQueue) else: 0)
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proc lenAcquired*[A, B](pool: PeerPool[A, B],
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filter = {PeerType.Incoming,
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PeerType.Outgoing}): int {.inline.} =
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## Returns number of acquired peers in PeerPool ``pool`` which satisifies
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## filter ``filter``.
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(if PeerType.Incoming in filter: pool.acqIncPeersCount else: 0) +
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(if PeerType.Outgoing in filter: pool.acqOutPeersCount else: 0)
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proc shortLogAvailable*[A, B](pool: PeerPool[A, B]): string =
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$len(pool.incQueue) & "/" & $len(pool.outQueue)
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proc shortLogAcquired*[A, B](pool: PeerPool[A, B]): string =
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$pool.acqIncPeersCount & "/" & $pool.acqOutPeersCount
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proc checkPeerScore[A, B](pool: PeerPool[A, B], peer: A): bool {.inline.} =
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## Returns ``true`` if peer passing score check.
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if not(isNil(pool.scoreCheck)):
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pool.scoreCheck(peer)
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else:
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true
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proc peerCountChanged[A, B](pool: PeerPool[A, B]) {.inline.} =
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## Call callback when number of peers changed.
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if not(isNil(pool.peerCounter)):
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pool.peerCounter()
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proc deletePeer*[A, B](pool: PeerPool[A, B], peer: A, force = false): bool =
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## Remove ``peer`` from PeerPool ``pool``.
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##
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## Deletion occurs immediately only if peer is available, otherwise it will
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## be deleted only when peer will be released. You can change this behavior
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## with ``force`` option.
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mixin getKey
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let key = getKey(peer)
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if pool.registry.hasKey(key):
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let pindex = pool.registry[key].data
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var item = addr(pool.storage[pindex])
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if (PeerFlags.Acquired in item[].flags):
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if not(force):
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item[].flags.incl(PeerFlags.DeleteOnRelease)
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else:
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if item[].peerType == PeerType.Incoming:
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dec(pool.curIncPeersCount)
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dec(pool.acqIncPeersCount)
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elif item[].peerType == PeerType.Outgoing:
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dec(pool.curOutPeersCount)
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dec(pool.acqOutPeersCount)
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# Indicate that we have an empty space
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pool.fireNotFullEvent(item[])
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# Cleanup storage with default item, and removing key from hashtable.
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pool.storage[pindex] = PeerItem[A]()
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pool.registry.del(key)
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pool.peerCountChanged()
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else:
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if item[].peerType == PeerType.Incoming:
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# If peer is available, then its copy present in heapqueue, so we need
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# to remove it.
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for i in 0 ..< len(pool.incQueue):
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if pool.incQueue[i].data == pindex:
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pool.incQueue.del(i)
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break
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dec(pool.curIncPeersCount)
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elif item[].peerType == PeerType.Outgoing:
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# If peer is available, then its copy present in heapqueue, so we need
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# to remove it.
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for i in 0 ..< len(pool.outQueue):
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if pool.outQueue[i].data == pindex:
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pool.outQueue.del(i)
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break
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dec(pool.curOutPeersCount)
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# Indicate that we have an empty space
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pool.fireNotFullEvent(item[])
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# Cleanup storage with default item, and removing key from hashtable.
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pool.storage[pindex] = PeerItem[A]()
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pool.registry.del(key)
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pool.peerCountChanged()
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true
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else:
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false
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proc addPeerImpl[A, B](pool: PeerPool[A, B], peer: A, peerKey: B,
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peerType: PeerType): PeerIndex =
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proc onPeerClosed(udata: pointer) {.gcsafe.} =
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discard pool.deletePeer(peer)
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var item = PeerItem[A](data: peer, peerType: peerType,
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index: len(pool.storage))
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pool.storage.add(item)
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var pitem = addr(pool.storage[^1])
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let pindex = PeerIndex(data: item.index, cmp: pool.cmp)
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pool.registry[peerKey] = pindex
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pitem[].data.getFuture().addCallback(onPeerClosed)
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pindex
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proc addPeerNoWait*[A, B](pool: PeerPool[A, B],
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peer: A, peerType: PeerType): bool =
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## Add peer ``peer`` of type ``peerType`` to PeerPool ``pool``.
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##
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## Procedure returns ``false`` in case
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## * if ``peer`` is already closed.
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## * if ``pool`` already has peer ``peer`` inside.
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## * if ``pool`` currently has a maximum of peers.
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## * if ``pool`` currently has a maximum of `Incoming` or `Outgoing` peers.
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##
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## Procedure returns ``true`` on success.
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mixin getKey, getFuture
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if not(pool.checkPeerScore(peer)):
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return false
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let peerKey = getKey(peer)
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if not(pool.registry.hasKey(peerKey)) and not(peer.getFuture().finished):
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if len(pool.registry) < pool.maxPeersCount:
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if peerType == PeerType.Incoming:
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if pool.curIncPeersCount < pool.maxIncPeersCount:
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let pindex = pool.addPeerImpl(peer, peerKey, peerType)
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inc(pool.curIncPeersCount)
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pool.incQueue.push(pindex)
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pool.incNotEmptyEvent.fire()
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pool.peerCountChanged()
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return true
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elif peerType == PeerType.Outgoing:
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if pool.curOutPeersCount < pool.maxOutPeersCount:
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let pindex = pool.addPeerImpl(peer, peerKey, peerType)
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inc(pool.curOutPeersCount)
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pool.outQueue.push(pindex)
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pool.outNotEmptyEvent.fire()
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pool.peerCountChanged()
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return true
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return false
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proc addPeer*[A, B](pool: PeerPool[A, B],
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peer: A, peerType: PeerType): Future[bool] {.async.} =
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## Add peer ``peer`` of type ``peerType`` to PeerPool ``pool``.
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##
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## This procedure will wait for an empty space in PeerPool ``pool``, if
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## PeerPool ``pool`` is full.
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##
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## Procedure returns ``false`` in case:
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## * if ``peer`` is already closed.
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## * if ``pool`` already has peer ``peer`` inside.
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##
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## Procedure returns ``true`` on success.
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mixin getKey, getFuture
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if not(pool.checkPeerScore(peer)):
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return false
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let peerKey = getKey(peer)
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if not(pool.registry.hasKey(peerKey)) and not(peer.getFuture().finished):
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while len(pool.registry) >= pool.maxPeersCount:
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await pool.waitNotFullEvent({PeerType.Incoming, PeerType.Outgoing})
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if peerType == PeerType.Incoming:
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while pool.curIncPeersCount >= pool.maxIncPeersCount:
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await pool.waitNotFullEvent({peerType})
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let pindex = pool.addPeerImpl(peer, peerKey, peerType)
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inc(pool.curIncPeersCount)
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pool.incQueue.push(pindex)
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pool.incNotEmptyEvent.fire()
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pool.peerCountChanged()
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return true
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elif peerType == PeerType.Outgoing:
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while pool.curOutPeersCount >= pool.maxOutPeersCount:
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await pool.waitNotFullEvent({peerType})
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let pindex = pool.addPeerImpl(peer, peerKey, peerType)
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inc(pool.curOutPeersCount)
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pool.outQueue.push(pindex)
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pool.outNotEmptyEvent.fire()
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pool.peerCountChanged()
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return true
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else:
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return false
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proc addIncomingPeerNoWait*[A, B](pool: PeerPool[A, B],
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peer: A): bool {.inline.} =
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## Add incoming peer ``peer`` to PeerPool ``pool``.
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##
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## Returns ``true`` on success.
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pool.addPeerNoWait(peer, PeerType.Incoming)
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proc addOutgoingPeerNoWait*[A, B](pool: PeerPool[A, B],
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peer: A): bool {.inline.} =
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## Add outgoing peer ``peer`` to PeerPool ``pool``.
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##
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## Returns ``true`` on success.
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pool.addPeerNoWait(peer, PeerType.Outgoing)
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proc addIncomingPeer*[A, B](pool: PeerPool[A, B],
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peer: A): Future[bool] {.inline.} =
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## Add incoming peer ``peer`` to PeerPool ``pool``.
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##
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## Returns ``true`` on success.
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pool.addPeer(peer, PeerType.Incoming)
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proc addOutgoingPeer*[A, B](pool: PeerPool[A, B],
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peer: A): Future[bool] {.inline.} =
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## Add outgoing peer ``peer`` to PeerPool ``pool``.
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##
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## Returns ``true`` on success.
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pool.addPeer(peer, PeerType.Outgoing)
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proc acquireItemImpl[A, B](pool: PeerPool[A, B],
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filter: set[PeerType]): A {.inline.} =
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doAssert(filter != {})
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doAssert((len(pool.outQueue) > 0) or (len(pool.incQueue) > 0))
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let pindex =
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if filter == {PeerType.Incoming, PeerType.Outgoing}:
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if len(pool.outQueue) > 0 and len(pool.incQueue) > 0:
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# Don't think `<` is actually `<` here.
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if pool.incQueue[0] < pool.outQueue[0]:
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inc(pool.acqIncPeersCount)
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let item = pool.incQueue.pop()
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item.data
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else:
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inc(pool.acqOutPeersCount)
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let item = pool.outQueue.pop()
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item.data
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else:
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if len(pool.outQueue) > 0:
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inc(pool.acqOutPeersCount)
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let item = pool.outQueue.pop()
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item.data
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else:
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inc(pool.acqIncPeersCount)
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let item = pool.incQueue.pop()
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item.data
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else:
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if PeerType.Outgoing in filter:
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inc(pool.acqOutPeersCount)
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let item = pool.outQueue.pop()
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item.data
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else:
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inc(pool.acqIncPeersCount)
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let item = pool.incQueue.pop()
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item.data
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var pitem = addr(pool.storage[pindex])
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doAssert(PeerFlags.Acquired notin pitem[].flags)
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pitem[].flags.incl(PeerFlags.Acquired)
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pitem[].data
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proc acquire*[A, B](pool: PeerPool[A, B],
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filter = {PeerType.Incoming,
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PeerType.Outgoing}): Future[A] {.async.} =
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## Acquire peer from PeerPool ``pool``, which match the filter ``filter``.
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mixin getKey
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doAssert(filter != {}, "Filter must not be empty")
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while true:
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if pool.lenAvailable(filter) == 0:
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await pool.waitNotEmptyEvent(filter)
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else:
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return pool.acquireItemImpl(filter)
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proc acquireNoWait*[A, B](pool: PeerPool[A, B],
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filter = {PeerType.Incoming,
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PeerType.Outgoing}): A =
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doAssert(filter != {}, "Filter must not be empty")
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if pool.lenAvailable(filter) < 1:
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raise newException(PeerPoolError, "Not enough peers in pool")
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pool.acquireItemImpl(filter)
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proc release*[A, B](pool: PeerPool[A, B], peer: A) =
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## Release peer ``peer`` back to PeerPool ``pool``
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mixin getKey
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let key = getKey(peer)
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var titem = pool.registry.getOrDefault(key, PeerIndex(data: -1))
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if titem.data >= 0:
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let pindex = titem.data
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var item = addr(pool.storage[pindex])
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if PeerFlags.Acquired in item[].flags:
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if not(pool.checkPeerScore(peer)):
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item[].flags.incl(DeleteOnRelease)
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if PeerFlags.DeleteOnRelease in item[].flags:
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# We do not care about result here because peer is present in registry
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# and has all proper flags set.
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discard pool.deletePeer(peer, force = true)
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else:
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item[].flags.excl(PeerFlags.Acquired)
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if item[].peerType == PeerType.Incoming:
|
|
pool.incQueue.push(titem)
|
|
dec(pool.acqIncPeersCount)
|
|
elif item[].peerType == PeerType.Outgoing:
|
|
pool.outQueue.push(titem)
|
|
dec(pool.acqOutPeersCount)
|
|
pool.fireNotEmptyEvent(item[])
|
|
|
|
proc release*[A, B](pool: PeerPool[A, B], peers: openarray[A]) {.inline.} =
|
|
## Release array of peers ``peers`` back to PeerPool ``pool``.
|
|
for item in peers:
|
|
pool.release(item)
|
|
|
|
proc acquire*[A, B](pool: PeerPool[A, B],
|
|
number: int,
|
|
filter = {PeerType.Incoming,
|
|
PeerType.Outgoing}): Future[seq[A]] {.async.} =
|
|
## Acquire ``number`` number of peers from PeerPool ``pool``, which match the
|
|
## filter ``filter``.
|
|
doAssert(filter != {}, "Filter must not be empty")
|
|
var peers = newSeq[A]()
|
|
try:
|
|
if number > 0:
|
|
while true:
|
|
if len(peers) >= number:
|
|
break
|
|
if pool.lenAvailable(filter) == 0:
|
|
await pool.waitNotEmptyEvent(filter)
|
|
else:
|
|
peers.add(pool.acquireItemImpl(filter))
|
|
except CancelledError as exc:
|
|
# If we got cancelled, we need to return all the acquired peers back to
|
|
# pool.
|
|
for item in peers:
|
|
pool.release(item)
|
|
peers.setLen(0)
|
|
raise exc
|
|
return peers
|
|
|
|
proc acquireNoWait*[A, B](pool: PeerPool[A, B],
|
|
number: int,
|
|
filter = {PeerType.Incoming,
|
|
PeerType.Outgoing}): seq[A] =
|
|
## Acquire ``number`` number of peers from PeerPool ``pool``, which match the
|
|
## filter ``filter``.
|
|
doAssert(filter != {}, "Filter must not be empty")
|
|
var peers = newSeq[A]()
|
|
if pool.lenAvailable(filter) < number:
|
|
raise newException(PeerPoolError, "Not enough peers in pool")
|
|
for i in 0 ..< number:
|
|
peers.add(pool.acquireItemImpl(filter))
|
|
return peers
|
|
|
|
proc acquireIncomingPeer*[A, B](pool: PeerPool[A, B]): Future[A] {.inline.} =
|
|
## Acquire single incoming peer from PeerPool ``pool``.
|
|
pool.acquire({PeerType.Incoming})
|
|
|
|
proc acquireOutgoingPeer*[A, B](pool: PeerPool[A, B]): Future[A] {.inline.} =
|
|
## Acquire single outgoing peer from PeerPool ``pool``.
|
|
pool.acquire({PeerType.Outgoing})
|
|
|
|
proc acquireIncomingPeers*[A, B](pool: PeerPool[A, B],
|
|
number: int): Future[seq[A]] {.inline.} =
|
|
## Acquire ``number`` number of incoming peers from PeerPool ``pool``.
|
|
pool.acquire(number, {PeerType.Incoming})
|
|
|
|
proc acquireOutgoingPeers*[A, B](pool: PeerPool[A, B],
|
|
number: int): Future[seq[A]] {.inline.} =
|
|
## Acquire ``number`` number of outgoing peers from PeerPool ``pool``.
|
|
pool.acquire(number, {PeerType.Outgoing})
|
|
|
|
iterator peers*[A, B](pool: PeerPool[A, B],
|
|
filter = {PeerType.Incoming,
|
|
PeerType.Outgoing}): A =
|
|
## Iterate over sorted list of peers.
|
|
##
|
|
## All peers will be sorted by equation `>`(Peer1, Peer2), so biggest values
|
|
## will be first.
|
|
var sorted = initHeapQueue[PeerIndex]()
|
|
for i in 0 ..< len(pool.storage):
|
|
if pool.storage[i].peerType in filter:
|
|
sorted.push(PeerIndex(data: i, cmp: pool.cmp))
|
|
while len(sorted) > 0:
|
|
let pindex = sorted.pop().data
|
|
yield pool.storage[pindex].data
|
|
|
|
iterator availablePeers*[A, B](pool: PeerPool[A, B],
|
|
filter = {PeerType.Incoming,
|
|
PeerType.Outgoing}): A =
|
|
## Iterate over sorted list of available peers.
|
|
##
|
|
## All peers will be sorted by equation `>`(Peer1, Peer2), so biggest values
|
|
## will be first.
|
|
var sorted = initHeapQueue[PeerIndex]()
|
|
for i in 0 ..< len(pool.storage):
|
|
if (PeerFlags.Acquired notin pool.storage[i].flags) and
|
|
(pool.storage[i].peerType in filter):
|
|
sorted.push(PeerIndex(data: i, cmp: pool.cmp))
|
|
while len(sorted) > 0:
|
|
let pindex = sorted.pop().data
|
|
yield pool.storage[pindex].data
|
|
|
|
iterator acquiredPeers*[A, B](pool: PeerPool[A, B],
|
|
filter = {PeerType.Incoming,
|
|
PeerType.Outgoing}): A =
|
|
## Iterate over sorted list of acquired (non-available) peers.
|
|
##
|
|
## All peers will be sorted by equation `>`(Peer1, Peer2), so biggest values
|
|
## will be first.
|
|
var sorted = initHeapQueue[PeerIndex]()
|
|
for i in 0 ..< len(pool.storage):
|
|
if (PeerFlags.Acquired in pool.storage[i].flags) and
|
|
(pool.storage[i].peerType in filter):
|
|
sorted.push(PeerIndex(data: i, cmp: pool.cmp))
|
|
while len(sorted) > 0:
|
|
let pindex = sorted.pop().data
|
|
yield pool.storage[pindex].data
|
|
|
|
proc `[]`*[A, B](pool: PeerPool[A, B], key: B): A {.inline.} =
|
|
## Retrieve peer with key ``key`` from PeerPool ``pool``.
|
|
let pindex = pool.registry[key]
|
|
pool.storage[pindex.data]
|
|
|
|
proc `[]`*[A, B](pool: var PeerPool[A, B], key: B): var A {.inline.} =
|
|
## Retrieve peer with key ``key`` from PeerPool ``pool``.
|
|
let pindex = pool.registry[key]
|
|
pool.storage[pindex.data].data
|
|
|
|
proc hasPeer*[A, B](pool: PeerPool[A, B], key: B): bool {.inline.} =
|
|
## Returns ``true`` if peer with ``key`` present in PeerPool ``pool``.
|
|
pool.registry.hasKey(key)
|
|
|
|
proc getOrDefault*[A, B](pool: PeerPool[A, B], key: B): A {.inline.} =
|
|
## Retrieves the peer from PeerPool ``pool`` using key ``key``. If peer is
|
|
## not present, default initialization value for type ``A`` is returned
|
|
## (e.g. 0 for any integer type).
|
|
let pindex = pool.registry.getOrDefault(key, PeerIndex(data: -1))
|
|
if pindex.data >= 0:
|
|
pool.storage[pindex.data].data
|
|
else:
|
|
A()
|
|
|
|
proc getOrDefault*[A, B](pool: PeerPool[A, B], key: B,
|
|
default: A): A {.inline.} =
|
|
## Retrieves the peer from PeerPool ``pool`` using key ``key``. If peer is
|
|
## not present, default value ``default`` is returned.
|
|
let pindex = pool.registry.getOrDefault(key, PeerIndex(data: -1))
|
|
if pindex.data >= 0:
|
|
pool.storage[pindex.data].data
|
|
else:
|
|
default
|
|
|
|
proc clear*[A, B](pool: PeerPool[A, B]) =
|
|
## Performs PeerPool's ``pool`` storage and counters reset.
|
|
pool.incQueue.clear()
|
|
pool.outQueue.clear()
|
|
pool.registry.clear()
|
|
for i in 0 ..< len(pool.storage):
|
|
pool.storage[i] = PeerItem[A]()
|
|
pool.storage.setLen(0)
|
|
pool.curIncPeersCount = 0
|
|
pool.curOutPeersCount = 0
|
|
pool.acqIncPeersCount = 0
|
|
pool.acqOutPeersCount = 0
|
|
|
|
proc clearSafe*[A, B](pool: PeerPool[A, B]) {.async.} =
|
|
## Performs "safe" clear. Safe means that it first acquires all the peers
|
|
## in PeerPool, and only after that it will reset storage.
|
|
var acquired = newSeq[A]()
|
|
while len(pool.registry) > len(acquired):
|
|
var peers = await pool.acquire(len(pool.registry) - len(acquired))
|
|
for item in peers:
|
|
acquired.add(item)
|
|
pool.clear()
|
|
|
|
proc setScoreCheck*[A, B](pool: PeerPool[A, B],
|
|
scoreCheckCb: PeerScoreCheckCallback[A]) =
|
|
## Add ScoreCheck callback.
|
|
pool.scoreCheck = scoreCheckCb
|
|
|
|
proc setPeerCounter*[A, B](pool: PeerPool[A, B],
|
|
peerCounterCb: PeerCounterCallback) =
|
|
pool.peerCounter = peerCounterCb
|