2022-05-19 19:56:03 +00:00
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## Nim-Codex
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2021-02-26 00:23:22 +00:00
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## Copyright (c) 2021 Status Research & Development GmbH
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## Licensed under either of
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## * Apache License, version 2.0, ([LICENSE-APACHE](LICENSE-APACHE))
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## * MIT license ([LICENSE-MIT](LICENSE-MIT))
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## at your option.
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## This file may not be copied, modified, or distributed except according to
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## those terms.
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import std/sequtils
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import pkg/chronos
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import pkg/stew/results
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# Based on chronos AsyncHeapQueue and std/heapqueue
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type
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QueueType* {.pure.} = enum
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Min, Max
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AsyncHeapQueue*[T] = ref object of RootRef
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## A priority queue
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##
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## If ``maxsize`` is less than or equal to zero, the queue size is
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## infinite. If it is an integer greater than ``0``, then "await put()"
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## will block when the queue reaches ``maxsize``, until an item is
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## removed by "await get()".
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queueType: QueueType
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getters: seq[Future[void]]
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putters: seq[Future[void]]
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queue: seq[T]
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maxsize: int
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AsyncHQErrors* {.pure.} = enum
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Empty, Full
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proc newAsyncHeapQueue*[T](
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maxsize: int = 0,
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queueType: QueueType = QueueType.Min): AsyncHeapQueue[T] =
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## Creates a new asynchronous queue ``AsyncHeapQueue``.
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##
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AsyncHeapQueue[T](
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getters: newSeq[Future[void]](),
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putters: newSeq[Future[void]](),
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queue: newSeqOfCap[T](maxsize),
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maxsize: maxsize,
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queueType: queueType,
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)
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proc wakeupNext(waiters: var seq[Future[void]]) {.inline.} =
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var i = 0
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while i < len(waiters):
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var waiter = waiters[i]
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inc(i)
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if not(waiter.finished()):
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waiter.complete()
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break
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if i > 0:
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waiters.delete(0, i - 1)
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proc heapCmp[T](x, y: T, max: bool = false): bool {.inline.} =
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if max:
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return (y < x)
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else:
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return (x < y)
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proc siftdown[T](heap: AsyncHeapQueue[T], startpos, p: int) =
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## 'heap' is a heap at all indices >= startpos, except
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## possibly for pos. pos is the index of a leaf with a
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## possibly out-of-order value. Restore the heap invariant.
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##
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var pos = p
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var newitem = heap[pos]
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# Follow the path to the root, moving parents down until
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# finding a place newitem fits.
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while pos > startpos:
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let parentpos = (pos - 1) shr 1
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let parent = heap[parentpos]
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if heapCmp(newitem, parent, heap.queueType == QueueType.Max):
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heap.queue[pos] = parent
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pos = parentpos
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else:
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break
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heap.queue[pos] = newitem
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proc siftup[T](heap: AsyncHeapQueue[T], p: int) =
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let endpos = len(heap)
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var pos = p
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let startpos = pos
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let newitem = heap[pos]
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# Bubble up the smaller child until hitting a leaf.
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var childpos = 2*pos + 1 # leftmost child position
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while childpos < endpos:
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# Set childpos to index of smaller child.
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let rightpos = childpos + 1
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if rightpos < endpos and
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not heapCmp(heap[childpos], heap[rightpos], heap.queueType == QueueType.Max):
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childpos = rightpos
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# Move the smaller child up.
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heap.queue[pos] = heap[childpos]
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pos = childpos
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childpos = 2*pos + 1
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# The leaf at pos is empty now. Put newitem there, and bubble it up
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# to its final resting place (by sifting its parents down).
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heap.queue[pos] = newitem
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siftdown(heap, startpos, pos)
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proc full*[T](heap: AsyncHeapQueue[T]): bool {.inline.} =
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## Return ``true`` if there are ``maxsize`` items in the queue.
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##
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## Note: If the ``heap`` was initialized with ``maxsize = 0`` (default),
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## then ``full()`` is never ``true``.
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if heap.maxsize <= 0:
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false
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else:
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(len(heap.queue) >= heap.maxsize)
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proc empty*[T](heap: AsyncHeapQueue[T]): bool {.inline.} =
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## Return ``true`` if the queue is empty, ``false`` otherwise.
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(len(heap.queue) == 0)
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proc pushNoWait*[T](heap: AsyncHeapQueue[T], item: T): Result[void, AsyncHQErrors] =
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## Push `item` onto heap, maintaining the heap invariant.
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##
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if heap.full():
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return err(AsyncHQErrors.Full)
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heap.queue.add(item)
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siftdown(heap, 0, len(heap)-1)
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heap.getters.wakeupNext()
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return ok()
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proc push*[T](heap: AsyncHeapQueue[T], item: T) {.async, gcsafe.} =
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## Push item into the queue, awaiting for an available slot
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## when it's full
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##
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while heap.full():
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var putter = newFuture[void]("AsyncHeapQueue.push")
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heap.putters.add(putter)
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try:
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await putter
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except CatchableError as exc:
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if not(heap.full()) and not(putter.cancelled()):
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heap.putters.wakeupNext()
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raise exc
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heap.pushNoWait(item).tryGet()
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proc popNoWait*[T](heap: AsyncHeapQueue[T]): Result[T, AsyncHQErrors] =
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## Pop and return the smallest item from `heap`,
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## maintaining the heap invariant.
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##
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if heap.empty():
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return err(AsyncHQErrors.Empty)
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let lastelt = heap.queue.pop()
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if heap.len > 0:
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result = ok(heap[0])
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heap.queue[0] = lastelt
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siftup(heap, 0)
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else:
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result = ok(lastelt)
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heap.putters.wakeupNext()
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proc pop*[T](heap: AsyncHeapQueue[T]): Future[T] {.async.} =
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## Remove and return an ``item`` from the beginning of the queue ``heap``.
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## If the queue is empty, wait until an item is available.
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while heap.empty():
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var getter = newFuture[void]("AsyncHeapQueue.pop")
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heap.getters.add(getter)
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try:
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await getter
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except CatchableError as exc:
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if not(heap.empty()) and not(getter.cancelled()):
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heap.getters.wakeupNext()
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raise exc
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return heap.popNoWait().tryGet()
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proc del*[T](heap: AsyncHeapQueue[T], index: Natural) =
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## Removes the element at `index` from `heap`,
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## maintaining the heap invariant.
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##
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if heap.empty():
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return
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swap(heap.queue[^1], heap.queue[index])
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let newLen = heap.len - 1
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heap.queue.setLen(newLen)
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if index < newLen:
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heap.siftup(index)
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heap.putters.wakeupNext()
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proc delete*[T](heap: AsyncHeapQueue[T], item: T) =
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## Find and delete an `item` from the `heap`
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##
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let index = heap.find(item)
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if index > -1:
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heap.del(index)
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proc update*[T](heap: AsyncHeapQueue[T], item: T): bool =
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## Update an entry in the heap by reshufling its
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## possition, maintaining the heap invariant.
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##
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let index = heap.find(item)
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if index > -1:
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# replace item with new one in case it's a copy
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heap.queue[index] = item
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# re-establish heap order
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# TODO: don't start at 0 to avoid reshuffling
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# entire heap
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heap.siftup(0)
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return true
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proc pushOrUpdateNoWait*[T](heap: AsyncHeapQueue[T], item: T): Result[void, AsyncHQErrors] =
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## Update an item if it exists or push a new one
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##
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if heap.update(item):
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return ok()
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return heap.pushNoWait(item)
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proc pushOrUpdate*[T](heap: AsyncHeapQueue[T], item: T) {.async.} =
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## Update an item if it exists or push a new one
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## awaiting until a slot becomes available
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##
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if not heap.update(item):
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await heap.push(item)
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proc replace*[T](heap: AsyncHeapQueue[T], item: T): Result[T, AsyncHQErrors] =
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## Pop and return the current smallest value, and add the new item.
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## This is more efficient than pop() followed by push(), and can be
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## more appropriate when using a fixed-size heap. Note that the value
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## returned may be larger than item! That constrains reasonable uses of
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## this routine unless written as part of a conditional replacement:
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##
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## .. code-block:: nim
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## if item > heap[0]:
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## item = replace(heap, item)
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##
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if heap.empty():
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error(AsyncHQErrors.Empty)
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result = heap[0]
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heap.queue[0] = item
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siftup(heap, 0)
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proc pushPopNoWait*[T](heap: AsyncHeapQueue[T], item: T): Result[T, AsyncHQErrors] =
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## Fast version of a push followed by a pop.
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##
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if heap.empty():
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err(AsyncHQErrors.Empty)
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if heap.len > 0 and heapCmp(heap[0], item, heap.queueType == QueueType.Max):
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swap(item, heap[0])
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siftup(heap, 0)
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return item
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proc clear*[T](heap: AsyncHeapQueue[T]) {.inline.} =
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## Clears all elements of queue ``heap``.
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heap.queue.setLen(0)
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proc len*[T](heap: AsyncHeapQueue[T]): int {.inline.} =
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## Return the number of elements in ``heap``.
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len(heap.queue)
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proc size*[T](heap: AsyncHeapQueue[T]): int {.inline.} =
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## Return the maximum number of elements in ``heap``.
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len(heap.maxsize)
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proc `[]`*[T](heap: AsyncHeapQueue[T], i: Natural) : T {.inline.} =
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## Access the i-th element of ``heap`` by order from first to last.
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## ``heap[0]`` is the first element, ``heap[^1]`` is the last element.
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heap.queue[i]
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proc `[]`*[T](heap: AsyncHeapQueue[T], i: BackwardsIndex) : T {.inline.} =
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## Access the i-th element of ``heap`` by order from first to last.
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## ``heap[0]`` is the first element, ``heap[^1]`` is the last element.
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heap.queue[len(heap.queue) - int(i)]
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iterator items*[T](heap: AsyncHeapQueue[T]): T {.inline.} =
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## Yield every element of ``heap``.
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for item in heap.queue.items():
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yield item
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iterator mitems*[T](heap: AsyncHeapQueue[T]): var T {.inline.} =
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## Yield every element of ``heap``.
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for mitem in heap.queue.mitems():
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yield mitem
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iterator pairs*[T](heap: AsyncHeapQueue[T]): tuple[key: int, val: T] {.inline.} =
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## Yield every (position, value) of ``heap``.
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for pair in heap.queue.pairs():
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yield pair
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proc contains*[T](heap: AsyncHeapQueue[T], item: T): bool {.inline.} =
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## Return true if ``item`` is in ``heap`` or false if not found. Usually used
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## via the ``in`` operator.
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for e in heap.queue.items():
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if e == item: return true
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return false
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proc `$`*[T](heap: AsyncHeapQueue[T]): string =
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## Turn an async queue ``heap`` into its string representation.
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var res = "["
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for item in heap.queue.items():
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if len(res) > 1: res.add(", ")
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res.addQuoted(item)
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res.add("]")
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res
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