2019-09-01 21:51:39 +00:00
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## Nim-LibP2P
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2019-09-24 17:48:23 +00:00
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## Copyright (c) 2019 Status Research & Development GmbH
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2019-09-01 21:51:39 +00:00
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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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2021-05-21 16:27:01 +00:00
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{.push raises: [Defect].}
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refactor bufferstream to use a queue (#346)
This change modifies how the backpressure algorithm in bufferstream
works - in particular, instead of working byte-by-byte, it will now work
seq-by-seq.
When data arrives, it usually does so in packets - in the current
bufferstream, the packet is read then split into bytes which are fed one
by one to the bufferstream. On the reading side, the bytes are popped of
the bufferstream, again byte by byte, to satisfy `readOnce` requests -
this introduces a lot of synchronization traffic because the checks for
full buffer and for async event handling must be done for every byte.
In this PR, a queue of length 1 is used instead - this means there will
at most exist one "packet" in `pushTo`, one in the queue and one in the
slush buffer that is used to store incomplete reads.
* avoid byte-by-byte copy to buffer, with synchronization in-between
* reuse AsyncQueue synchronization logic instead of rolling own
* avoid writeHandler callback - implement `write` method instead
* simplify EOF signalling by only setting EOF flag in queue reader (and
reset)
* remove BufferStream pipes (unused)
* fixes drainBuffer deadlock when drain is called from within read loop
and thus blocks draining
* fix lpchannel init order
2020-09-10 06:19:13 +00:00
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import std/strformat
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import stew/byteutils
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2020-04-14 13:27:07 +00:00
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import chronos, chronicles, metrics
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2020-06-19 17:29:43 +00:00
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import ../stream/connection
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refactor bufferstream to use a queue (#346)
This change modifies how the backpressure algorithm in bufferstream
works - in particular, instead of working byte-by-byte, it will now work
seq-by-seq.
When data arrives, it usually does so in packets - in the current
bufferstream, the packet is read then split into bytes which are fed one
by one to the bufferstream. On the reading side, the bytes are popped of
the bufferstream, again byte by byte, to satisfy `readOnce` requests -
this introduces a lot of synchronization traffic because the checks for
full buffer and for async event handling must be done for every byte.
In this PR, a queue of length 1 is used instead - this means there will
at most exist one "packet" in `pushTo`, one in the queue and one in the
slush buffer that is used to store incomplete reads.
* avoid byte-by-byte copy to buffer, with synchronization in-between
* reuse AsyncQueue synchronization logic instead of rolling own
* avoid writeHandler callback - implement `write` method instead
* simplify EOF signalling by only setting EOF flag in queue reader (and
reset)
* remove BufferStream pipes (unused)
* fixes drainBuffer deadlock when drain is called from within read loop
and thus blocks draining
* fix lpchannel init order
2020-09-10 06:19:13 +00:00
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import ./streamseq
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2019-09-01 21:51:39 +00:00
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2020-05-23 17:08:39 +00:00
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when chronicles.enabledLogLevel == LogLevel.TRACE:
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import oids
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2020-06-19 17:29:43 +00:00
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export connection
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2020-05-06 16:31:47 +00:00
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2020-05-20 00:14:15 +00:00
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logScope:
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2020-12-01 17:34:27 +00:00
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topics = "libp2p bufferstream"
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2019-09-06 21:28:54 +00:00
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2020-05-20 00:14:15 +00:00
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const
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2020-11-05 03:52:54 +00:00
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BufferStreamTrackerName* = "BufferStream"
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2020-05-20 00:14:15 +00:00
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type
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2020-06-19 17:29:43 +00:00
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BufferStream* = ref object of Connection
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refactor bufferstream to use a queue (#346)
This change modifies how the backpressure algorithm in bufferstream
works - in particular, instead of working byte-by-byte, it will now work
seq-by-seq.
When data arrives, it usually does so in packets - in the current
bufferstream, the packet is read then split into bytes which are fed one
by one to the bufferstream. On the reading side, the bytes are popped of
the bufferstream, again byte by byte, to satisfy `readOnce` requests -
this introduces a lot of synchronization traffic because the checks for
full buffer and for async event handling must be done for every byte.
In this PR, a queue of length 1 is used instead - this means there will
at most exist one "packet" in `pushTo`, one in the queue and one in the
slush buffer that is used to store incomplete reads.
* avoid byte-by-byte copy to buffer, with synchronization in-between
* reuse AsyncQueue synchronization logic instead of rolling own
* avoid writeHandler callback - implement `write` method instead
* simplify EOF signalling by only setting EOF flag in queue reader (and
reset)
* remove BufferStream pipes (unused)
* fixes drainBuffer deadlock when drain is called from within read loop
and thus blocks draining
* fix lpchannel init order
2020-09-10 06:19:13 +00:00
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readQueue*: AsyncQueue[seq[byte]] # read queue for managing backpressure
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2020-09-21 17:48:19 +00:00
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readBuf*: StreamSeq # overflow buffer for readOnce
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2020-11-23 15:07:11 +00:00
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pushing*: bool # number of ongoing push operations
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2020-11-17 14:59:25 +00:00
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reading*: bool # is there an ongoing read? (only allow one)
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pushedEof*: bool # eof marker has been put on readQueue
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returnedEof*: bool # 0-byte readOnce has been completed
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2019-12-04 04:44:54 +00:00
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2020-09-06 08:31:47 +00:00
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func shortLog*(s: BufferStream): auto =
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2021-05-21 16:27:01 +00:00
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try:
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if s.isNil: "BufferStream(nil)"
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elif s.peerInfo.isNil: $s.oid
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else: &"{shortLog(s.peerInfo.peerId)}:{s.oid}"
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except ValueError as exc:
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raise newException(Defect, exc.msg)
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2020-09-06 08:31:47 +00:00
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chronicles.formatIt(BufferStream): shortLog(it)
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refactor bufferstream to use a queue (#346)
This change modifies how the backpressure algorithm in bufferstream
works - in particular, instead of working byte-by-byte, it will now work
seq-by-seq.
When data arrives, it usually does so in packets - in the current
bufferstream, the packet is read then split into bytes which are fed one
by one to the bufferstream. On the reading side, the bytes are popped of
the bufferstream, again byte by byte, to satisfy `readOnce` requests -
this introduces a lot of synchronization traffic because the checks for
full buffer and for async event handling must be done for every byte.
In this PR, a queue of length 1 is used instead - this means there will
at most exist one "packet" in `pushTo`, one in the queue and one in the
slush buffer that is used to store incomplete reads.
* avoid byte-by-byte copy to buffer, with synchronization in-between
* reuse AsyncQueue synchronization logic instead of rolling own
* avoid writeHandler callback - implement `write` method instead
* simplify EOF signalling by only setting EOF flag in queue reader (and
reset)
* remove BufferStream pipes (unused)
* fixes drainBuffer deadlock when drain is called from within read loop
and thus blocks draining
* fix lpchannel init order
2020-09-10 06:19:13 +00:00
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proc len*(s: BufferStream): int =
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s.readBuf.len + (if s.readQueue.len > 0: s.readQueue[0].len() else: 0)
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2020-05-23 17:08:39 +00:00
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2020-06-19 17:29:43 +00:00
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method initStream*(s: BufferStream) =
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if s.objName.len == 0:
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s.objName = "BufferStream"
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2020-05-23 17:08:39 +00:00
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2020-06-19 17:29:43 +00:00
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procCall Connection(s).initStream()
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refactor bufferstream to use a queue (#346)
This change modifies how the backpressure algorithm in bufferstream
works - in particular, instead of working byte-by-byte, it will now work
seq-by-seq.
When data arrives, it usually does so in packets - in the current
bufferstream, the packet is read then split into bytes which are fed one
by one to the bufferstream. On the reading side, the bytes are popped of
the bufferstream, again byte by byte, to satisfy `readOnce` requests -
this introduces a lot of synchronization traffic because the checks for
full buffer and for async event handling must be done for every byte.
In this PR, a queue of length 1 is used instead - this means there will
at most exist one "packet" in `pushTo`, one in the queue and one in the
slush buffer that is used to store incomplete reads.
* avoid byte-by-byte copy to buffer, with synchronization in-between
* reuse AsyncQueue synchronization logic instead of rolling own
* avoid writeHandler callback - implement `write` method instead
* simplify EOF signalling by only setting EOF flag in queue reader (and
reset)
* remove BufferStream pipes (unused)
* fixes drainBuffer deadlock when drain is called from within read loop
and thus blocks draining
* fix lpchannel init order
2020-09-10 06:19:13 +00:00
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s.readQueue = newAsyncQueue[seq[byte]](1)
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trace "BufferStream created", s
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2019-09-01 21:51:39 +00:00
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refactor bufferstream to use a queue (#346)
This change modifies how the backpressure algorithm in bufferstream
works - in particular, instead of working byte-by-byte, it will now work
seq-by-seq.
When data arrives, it usually does so in packets - in the current
bufferstream, the packet is read then split into bytes which are fed one
by one to the bufferstream. On the reading side, the bytes are popped of
the bufferstream, again byte by byte, to satisfy `readOnce` requests -
this introduces a lot of synchronization traffic because the checks for
full buffer and for async event handling must be done for every byte.
In this PR, a queue of length 1 is used instead - this means there will
at most exist one "packet" in `pushTo`, one in the queue and one in the
slush buffer that is used to store incomplete reads.
* avoid byte-by-byte copy to buffer, with synchronization in-between
* reuse AsyncQueue synchronization logic instead of rolling own
* avoid writeHandler callback - implement `write` method instead
* simplify EOF signalling by only setting EOF flag in queue reader (and
reset)
* remove BufferStream pipes (unused)
* fixes drainBuffer deadlock when drain is called from within read loop
and thus blocks draining
* fix lpchannel init order
2020-09-10 06:19:13 +00:00
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proc newBufferStream*(timeout: Duration = DefaultConnectionTimeout): BufferStream =
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2019-09-01 21:51:39 +00:00
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new result
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2020-08-10 22:17:11 +00:00
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result.timeout = timeout
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refactor bufferstream to use a queue (#346)
This change modifies how the backpressure algorithm in bufferstream
works - in particular, instead of working byte-by-byte, it will now work
seq-by-seq.
When data arrives, it usually does so in packets - in the current
bufferstream, the packet is read then split into bytes which are fed one
by one to the bufferstream. On the reading side, the bytes are popped of
the bufferstream, again byte by byte, to satisfy `readOnce` requests -
this introduces a lot of synchronization traffic because the checks for
full buffer and for async event handling must be done for every byte.
In this PR, a queue of length 1 is used instead - this means there will
at most exist one "packet" in `pushTo`, one in the queue and one in the
slush buffer that is used to store incomplete reads.
* avoid byte-by-byte copy to buffer, with synchronization in-between
* reuse AsyncQueue synchronization logic instead of rolling own
* avoid writeHandler callback - implement `write` method instead
* simplify EOF signalling by only setting EOF flag in queue reader (and
reset)
* remove BufferStream pipes (unused)
* fixes drainBuffer deadlock when drain is called from within read loop
and thus blocks draining
* fix lpchannel init order
2020-09-10 06:19:13 +00:00
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result.initStream()
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2019-09-01 21:51:39 +00:00
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2020-09-21 17:48:19 +00:00
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method pushData*(s: BufferStream, data: seq[byte]) {.base, async.} =
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2020-01-07 08:02:37 +00:00
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## Write bytes to internal read buffer, use this to fill up the
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2019-09-01 21:51:39 +00:00
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## buffer with data.
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##
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refactor bufferstream to use a queue (#346)
This change modifies how the backpressure algorithm in bufferstream
works - in particular, instead of working byte-by-byte, it will now work
seq-by-seq.
When data arrives, it usually does so in packets - in the current
bufferstream, the packet is read then split into bytes which are fed one
by one to the bufferstream. On the reading side, the bytes are popped of
the bufferstream, again byte by byte, to satisfy `readOnce` requests -
this introduces a lot of synchronization traffic because the checks for
full buffer and for async event handling must be done for every byte.
In this PR, a queue of length 1 is used instead - this means there will
at most exist one "packet" in `pushTo`, one in the queue and one in the
slush buffer that is used to store incomplete reads.
* avoid byte-by-byte copy to buffer, with synchronization in-between
* reuse AsyncQueue synchronization logic instead of rolling own
* avoid writeHandler callback - implement `write` method instead
* simplify EOF signalling by only setting EOF flag in queue reader (and
reset)
* remove BufferStream pipes (unused)
* fixes drainBuffer deadlock when drain is called from within read loop
and thus blocks draining
* fix lpchannel init order
2020-09-10 06:19:13 +00:00
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## `pushTo` will block if the queue is full, thus maintaining backpressure.
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2019-12-04 04:44:54 +00:00
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##
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2020-11-23 15:07:11 +00:00
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2020-12-03 01:24:48 +00:00
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doAssert(not s.pushing,
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&"Only one concurrent push allowed for stream {s.shortLog()}")
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2020-09-21 17:48:19 +00:00
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if s.isClosed or s.pushedEof:
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2020-05-20 00:14:15 +00:00
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raise newLPStreamEOFError()
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2020-04-14 13:21:16 +00:00
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refactor bufferstream to use a queue (#346)
This change modifies how the backpressure algorithm in bufferstream
works - in particular, instead of working byte-by-byte, it will now work
seq-by-seq.
When data arrives, it usually does so in packets - in the current
bufferstream, the packet is read then split into bytes which are fed one
by one to the bufferstream. On the reading side, the bytes are popped of
the bufferstream, again byte by byte, to satisfy `readOnce` requests -
this introduces a lot of synchronization traffic because the checks for
full buffer and for async event handling must be done for every byte.
In this PR, a queue of length 1 is used instead - this means there will
at most exist one "packet" in `pushTo`, one in the queue and one in the
slush buffer that is used to store incomplete reads.
* avoid byte-by-byte copy to buffer, with synchronization in-between
* reuse AsyncQueue synchronization logic instead of rolling own
* avoid writeHandler callback - implement `write` method instead
* simplify EOF signalling by only setting EOF flag in queue reader (and
reset)
* remove BufferStream pipes (unused)
* fixes drainBuffer deadlock when drain is called from within read loop
and thus blocks draining
* fix lpchannel init order
2020-09-10 06:19:13 +00:00
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if data.len == 0:
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return # Don't push 0-length buffers, these signal EOF
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2020-07-12 16:37:10 +00:00
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refactor bufferstream to use a queue (#346)
This change modifies how the backpressure algorithm in bufferstream
works - in particular, instead of working byte-by-byte, it will now work
seq-by-seq.
When data arrives, it usually does so in packets - in the current
bufferstream, the packet is read then split into bytes which are fed one
by one to the bufferstream. On the reading side, the bytes are popped of
the bufferstream, again byte by byte, to satisfy `readOnce` requests -
this introduces a lot of synchronization traffic because the checks for
full buffer and for async event handling must be done for every byte.
In this PR, a queue of length 1 is used instead - this means there will
at most exist one "packet" in `pushTo`, one in the queue and one in the
slush buffer that is used to store incomplete reads.
* avoid byte-by-byte copy to buffer, with synchronization in-between
* reuse AsyncQueue synchronization logic instead of rolling own
* avoid writeHandler callback - implement `write` method instead
* simplify EOF signalling by only setting EOF flag in queue reader (and
reset)
* remove BufferStream pipes (unused)
* fixes drainBuffer deadlock when drain is called from within read loop
and thus blocks draining
* fix lpchannel init order
2020-09-10 06:19:13 +00:00
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# We will block here if there is already data queued, until it has been
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# processed
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2020-09-21 17:48:19 +00:00
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try:
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2020-11-23 15:07:11 +00:00
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s.pushing = true
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2020-09-21 17:48:19 +00:00
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trace "Pushing data", s, data = data.len
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await s.readQueue.addLast(data)
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finally:
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2020-11-23 15:07:11 +00:00
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s.pushing = false
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2020-09-21 17:48:19 +00:00
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method pushEof*(s: BufferStream) {.base, async.} =
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if s.pushedEof:
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return
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2020-11-23 15:07:11 +00:00
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2020-12-03 01:24:48 +00:00
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doAssert(not s.pushing,
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&"Only one concurrent push allowed for stream {s.shortLog()}")
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2020-11-23 15:07:11 +00:00
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2020-09-21 17:48:19 +00:00
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s.pushedEof = true
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# We will block here if there is already data queued, until it has been
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# processed
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try:
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2020-11-23 15:07:11 +00:00
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s.pushing = true
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2020-09-21 17:48:19 +00:00
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trace "Pushing EOF", s
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2020-11-23 15:07:11 +00:00
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await s.readQueue.addLast(Eof)
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2020-09-21 17:48:19 +00:00
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finally:
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2020-11-23 15:07:11 +00:00
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s.pushing = false
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2020-07-12 16:37:10 +00:00
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2021-03-09 12:22:52 +00:00
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method atEof*(s: BufferStream): bool {.raises: [Defect].} =
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2020-11-17 14:59:25 +00:00
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s.isEof and s.readBuf.len == 0
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2019-09-04 06:40:53 +00:00
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method readOnce*(s: BufferStream,
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pbytes: pointer,
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nbytes: int):
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2019-12-04 04:44:54 +00:00
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Future[int] {.async.} =
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2020-09-16 09:55:25 +00:00
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doAssert(nbytes > 0, "nbytes must be positive integer")
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2020-12-03 01:24:48 +00:00
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doAssert(not s.reading,
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&"Only one concurrent read allowed for stream {s.shortLog()}")
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2020-11-17 14:59:25 +00:00
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if s.returnedEof:
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2020-05-20 00:14:15 +00:00
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raise newLPStreamEOFError()
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refactor bufferstream to use a queue (#346)
This change modifies how the backpressure algorithm in bufferstream
works - in particular, instead of working byte-by-byte, it will now work
seq-by-seq.
When data arrives, it usually does so in packets - in the current
bufferstream, the packet is read then split into bytes which are fed one
by one to the bufferstream. On the reading side, the bytes are popped of
the bufferstream, again byte by byte, to satisfy `readOnce` requests -
this introduces a lot of synchronization traffic because the checks for
full buffer and for async event handling must be done for every byte.
In this PR, a queue of length 1 is used instead - this means there will
at most exist one "packet" in `pushTo`, one in the queue and one in the
slush buffer that is used to store incomplete reads.
* avoid byte-by-byte copy to buffer, with synchronization in-between
* reuse AsyncQueue synchronization logic instead of rolling own
* avoid writeHandler callback - implement `write` method instead
* simplify EOF signalling by only setting EOF flag in queue reader (and
reset)
* remove BufferStream pipes (unused)
* fixes drainBuffer deadlock when drain is called from within read loop
and thus blocks draining
* fix lpchannel init order
2020-09-10 06:19:13 +00:00
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var
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p = cast[ptr UncheckedArray[byte]](pbytes)
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2019-12-04 04:44:54 +00:00
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refactor bufferstream to use a queue (#346)
This change modifies how the backpressure algorithm in bufferstream
works - in particular, instead of working byte-by-byte, it will now work
seq-by-seq.
When data arrives, it usually does so in packets - in the current
bufferstream, the packet is read then split into bytes which are fed one
by one to the bufferstream. On the reading side, the bytes are popped of
the bufferstream, again byte by byte, to satisfy `readOnce` requests -
this introduces a lot of synchronization traffic because the checks for
full buffer and for async event handling must be done for every byte.
In this PR, a queue of length 1 is used instead - this means there will
at most exist one "packet" in `pushTo`, one in the queue and one in the
slush buffer that is used to store incomplete reads.
* avoid byte-by-byte copy to buffer, with synchronization in-between
* reuse AsyncQueue synchronization logic instead of rolling own
* avoid writeHandler callback - implement `write` method instead
* simplify EOF signalling by only setting EOF flag in queue reader (and
reset)
* remove BufferStream pipes (unused)
* fixes drainBuffer deadlock when drain is called from within read loop
and thus blocks draining
* fix lpchannel init order
2020-09-10 06:19:13 +00:00
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# First consume leftovers from previous read
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var rbytes = s.readBuf.consumeTo(toOpenArray(p, 0, nbytes - 1))
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2020-08-04 13:22:05 +00:00
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2020-11-17 14:59:25 +00:00
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if rbytes < nbytes and not s.isEof:
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refactor bufferstream to use a queue (#346)
This change modifies how the backpressure algorithm in bufferstream
works - in particular, instead of working byte-by-byte, it will now work
seq-by-seq.
When data arrives, it usually does so in packets - in the current
bufferstream, the packet is read then split into bytes which are fed one
by one to the bufferstream. On the reading side, the bytes are popped of
the bufferstream, again byte by byte, to satisfy `readOnce` requests -
this introduces a lot of synchronization traffic because the checks for
full buffer and for async event handling must be done for every byte.
In this PR, a queue of length 1 is used instead - this means there will
at most exist one "packet" in `pushTo`, one in the queue and one in the
slush buffer that is used to store incomplete reads.
* avoid byte-by-byte copy to buffer, with synchronization in-between
* reuse AsyncQueue synchronization logic instead of rolling own
* avoid writeHandler callback - implement `write` method instead
* simplify EOF signalling by only setting EOF flag in queue reader (and
reset)
* remove BufferStream pipes (unused)
* fixes drainBuffer deadlock when drain is called from within read loop
and thus blocks draining
* fix lpchannel init order
2020-09-10 06:19:13 +00:00
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# There's space in the buffer - consume some data from the read queue
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2020-11-17 14:59:25 +00:00
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s.reading = true
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|
|
|
let buf =
|
|
|
|
try:
|
|
|
|
await s.readQueue.popFirst()
|
|
|
|
except CatchableError as exc:
|
|
|
|
# When an exception happens here, the Bufferstream is effectively
|
|
|
|
# broken and no more reads will be valid - for now, return EOF if it's
|
|
|
|
# called again, though this is not completely true - EOF represents an
|
|
|
|
# "orderly" shutdown and that's not what happened here..
|
|
|
|
s.returnedEof = true
|
|
|
|
raise exc
|
|
|
|
finally:
|
|
|
|
s.reading = false
|
|
|
|
|
|
|
|
if buf.len == 0:
|
refactor bufferstream to use a queue (#346)
This change modifies how the backpressure algorithm in bufferstream
works - in particular, instead of working byte-by-byte, it will now work
seq-by-seq.
When data arrives, it usually does so in packets - in the current
bufferstream, the packet is read then split into bytes which are fed one
by one to the bufferstream. On the reading side, the bytes are popped of
the bufferstream, again byte by byte, to satisfy `readOnce` requests -
this introduces a lot of synchronization traffic because the checks for
full buffer and for async event handling must be done for every byte.
In this PR, a queue of length 1 is used instead - this means there will
at most exist one "packet" in `pushTo`, one in the queue and one in the
slush buffer that is used to store incomplete reads.
* avoid byte-by-byte copy to buffer, with synchronization in-between
* reuse AsyncQueue synchronization logic instead of rolling own
* avoid writeHandler callback - implement `write` method instead
* simplify EOF signalling by only setting EOF flag in queue reader (and
reset)
* remove BufferStream pipes (unused)
* fixes drainBuffer deadlock when drain is called from within read loop
and thus blocks draining
* fix lpchannel init order
2020-09-10 06:19:13 +00:00
|
|
|
# No more data will arrive on read queue
|
2020-09-24 16:43:20 +00:00
|
|
|
trace "EOF", s
|
refactor bufferstream to use a queue (#346)
This change modifies how the backpressure algorithm in bufferstream
works - in particular, instead of working byte-by-byte, it will now work
seq-by-seq.
When data arrives, it usually does so in packets - in the current
bufferstream, the packet is read then split into bytes which are fed one
by one to the bufferstream. On the reading side, the bytes are popped of
the bufferstream, again byte by byte, to satisfy `readOnce` requests -
this introduces a lot of synchronization traffic because the checks for
full buffer and for async event handling must be done for every byte.
In this PR, a queue of length 1 is used instead - this means there will
at most exist one "packet" in `pushTo`, one in the queue and one in the
slush buffer that is used to store incomplete reads.
* avoid byte-by-byte copy to buffer, with synchronization in-between
* reuse AsyncQueue synchronization logic instead of rolling own
* avoid writeHandler callback - implement `write` method instead
* simplify EOF signalling by only setting EOF flag in queue reader (and
reset)
* remove BufferStream pipes (unused)
* fixes drainBuffer deadlock when drain is called from within read loop
and thus blocks draining
* fix lpchannel init order
2020-09-10 06:19:13 +00:00
|
|
|
s.isEof = true
|
|
|
|
else:
|
|
|
|
let remaining = min(buf.len, nbytes - rbytes)
|
|
|
|
toOpenArray(p, rbytes, nbytes - 1)[0..<remaining] =
|
|
|
|
buf.toOpenArray(0, remaining - 1)
|
|
|
|
rbytes += remaining
|
2019-09-01 21:51:39 +00:00
|
|
|
|
refactor bufferstream to use a queue (#346)
This change modifies how the backpressure algorithm in bufferstream
works - in particular, instead of working byte-by-byte, it will now work
seq-by-seq.
When data arrives, it usually does so in packets - in the current
bufferstream, the packet is read then split into bytes which are fed one
by one to the bufferstream. On the reading side, the bytes are popped of
the bufferstream, again byte by byte, to satisfy `readOnce` requests -
this introduces a lot of synchronization traffic because the checks for
full buffer and for async event handling must be done for every byte.
In this PR, a queue of length 1 is used instead - this means there will
at most exist one "packet" in `pushTo`, one in the queue and one in the
slush buffer that is used to store incomplete reads.
* avoid byte-by-byte copy to buffer, with synchronization in-between
* reuse AsyncQueue synchronization logic instead of rolling own
* avoid writeHandler callback - implement `write` method instead
* simplify EOF signalling by only setting EOF flag in queue reader (and
reset)
* remove BufferStream pipes (unused)
* fixes drainBuffer deadlock when drain is called from within read loop
and thus blocks draining
* fix lpchannel init order
2020-09-10 06:19:13 +00:00
|
|
|
if remaining < buf.len:
|
|
|
|
trace "add leftovers", s, len = buf.len - remaining
|
|
|
|
s.readBuf.add(buf.toOpenArray(remaining, buf.high))
|
2020-05-20 00:14:15 +00:00
|
|
|
|
refactor bufferstream to use a queue (#346)
This change modifies how the backpressure algorithm in bufferstream
works - in particular, instead of working byte-by-byte, it will now work
seq-by-seq.
When data arrives, it usually does so in packets - in the current
bufferstream, the packet is read then split into bytes which are fed one
by one to the bufferstream. On the reading side, the bytes are popped of
the bufferstream, again byte by byte, to satisfy `readOnce` requests -
this introduces a lot of synchronization traffic because the checks for
full buffer and for async event handling must be done for every byte.
In this PR, a queue of length 1 is used instead - this means there will
at most exist one "packet" in `pushTo`, one in the queue and one in the
slush buffer that is used to store incomplete reads.
* avoid byte-by-byte copy to buffer, with synchronization in-between
* reuse AsyncQueue synchronization logic instead of rolling own
* avoid writeHandler callback - implement `write` method instead
* simplify EOF signalling by only setting EOF flag in queue reader (and
reset)
* remove BufferStream pipes (unused)
* fixes drainBuffer deadlock when drain is called from within read loop
and thus blocks draining
* fix lpchannel init order
2020-09-10 06:19:13 +00:00
|
|
|
if s.isEof and s.readBuf.len() == 0:
|
|
|
|
# We can clear the readBuf memory since it won't be used any more
|
|
|
|
s.readBuf = StreamSeq()
|
2020-05-20 00:14:15 +00:00
|
|
|
|
refactor bufferstream to use a queue (#346)
This change modifies how the backpressure algorithm in bufferstream
works - in particular, instead of working byte-by-byte, it will now work
seq-by-seq.
When data arrives, it usually does so in packets - in the current
bufferstream, the packet is read then split into bytes which are fed one
by one to the bufferstream. On the reading side, the bytes are popped of
the bufferstream, again byte by byte, to satisfy `readOnce` requests -
this introduces a lot of synchronization traffic because the checks for
full buffer and for async event handling must be done for every byte.
In this PR, a queue of length 1 is used instead - this means there will
at most exist one "packet" in `pushTo`, one in the queue and one in the
slush buffer that is used to store incomplete reads.
* avoid byte-by-byte copy to buffer, with synchronization in-between
* reuse AsyncQueue synchronization logic instead of rolling own
* avoid writeHandler callback - implement `write` method instead
* simplify EOF signalling by only setting EOF flag in queue reader (and
reset)
* remove BufferStream pipes (unused)
* fixes drainBuffer deadlock when drain is called from within read loop
and thus blocks draining
* fix lpchannel init order
2020-09-10 06:19:13 +00:00
|
|
|
s.activity = true
|
2020-03-04 19:45:14 +00:00
|
|
|
|
2020-11-17 14:59:25 +00:00
|
|
|
# We want to return 0 exactly once - after that, we'll start raising instead -
|
|
|
|
# this is a bit nuts in a mixed exception / return value world, but allows the
|
|
|
|
# consumer of the stream to rely on the 0-byte read as a "regular" EOF marker
|
|
|
|
# (instead of _sometimes_ getting an exception).
|
|
|
|
s.returnedEof = rbytes == 0
|
|
|
|
|
refactor bufferstream to use a queue (#346)
This change modifies how the backpressure algorithm in bufferstream
works - in particular, instead of working byte-by-byte, it will now work
seq-by-seq.
When data arrives, it usually does so in packets - in the current
bufferstream, the packet is read then split into bytes which are fed one
by one to the bufferstream. On the reading side, the bytes are popped of
the bufferstream, again byte by byte, to satisfy `readOnce` requests -
this introduces a lot of synchronization traffic because the checks for
full buffer and for async event handling must be done for every byte.
In this PR, a queue of length 1 is used instead - this means there will
at most exist one "packet" in `pushTo`, one in the queue and one in the
slush buffer that is used to store incomplete reads.
* avoid byte-by-byte copy to buffer, with synchronization in-between
* reuse AsyncQueue synchronization logic instead of rolling own
* avoid writeHandler callback - implement `write` method instead
* simplify EOF signalling by only setting EOF flag in queue reader (and
reset)
* remove BufferStream pipes (unused)
* fixes drainBuffer deadlock when drain is called from within read loop
and thus blocks draining
* fix lpchannel init order
2020-09-10 06:19:13 +00:00
|
|
|
return rbytes
|
2019-12-04 04:44:54 +00:00
|
|
|
|
2020-09-21 17:48:19 +00:00
|
|
|
method closeImpl*(s: BufferStream): Future[void] =
|
refactor bufferstream to use a queue (#346)
This change modifies how the backpressure algorithm in bufferstream
works - in particular, instead of working byte-by-byte, it will now work
seq-by-seq.
When data arrives, it usually does so in packets - in the current
bufferstream, the packet is read then split into bytes which are fed one
by one to the bufferstream. On the reading side, the bytes are popped of
the bufferstream, again byte by byte, to satisfy `readOnce` requests -
this introduces a lot of synchronization traffic because the checks for
full buffer and for async event handling must be done for every byte.
In this PR, a queue of length 1 is used instead - this means there will
at most exist one "packet" in `pushTo`, one in the queue and one in the
slush buffer that is used to store incomplete reads.
* avoid byte-by-byte copy to buffer, with synchronization in-between
* reuse AsyncQueue synchronization logic instead of rolling own
* avoid writeHandler callback - implement `write` method instead
* simplify EOF signalling by only setting EOF flag in queue reader (and
reset)
* remove BufferStream pipes (unused)
* fixes drainBuffer deadlock when drain is called from within read loop
and thus blocks draining
* fix lpchannel init order
2020-09-10 06:19:13 +00:00
|
|
|
## close the stream and clear the buffer
|
2020-09-21 17:48:19 +00:00
|
|
|
trace "Closing BufferStream", s, len = s.len
|
2019-12-04 04:44:54 +00:00
|
|
|
|
2020-11-23 15:07:11 +00:00
|
|
|
# First, make sure any new calls to `readOnce` and `pushData` etc will fail -
|
|
|
|
# there may already be such calls in the event queue however
|
|
|
|
s.isEof = true
|
|
|
|
s.readBuf = StreamSeq()
|
|
|
|
s.pushedEof = true
|
|
|
|
|
|
|
|
# Essentially we need to handle the following cases
|
|
|
|
#
|
|
|
|
# - If a push was in progress but no reader is
|
|
|
|
# attached we need to pop the queue
|
|
|
|
# - If a read was in progress without without a
|
|
|
|
# push/data we need to push the Eof marker to
|
|
|
|
# notify the reader that the channel closed
|
|
|
|
#
|
|
|
|
# In all other cases, there should be a data to complete
|
|
|
|
# a read or enough room in the queue/buffer to complete a
|
|
|
|
# push.
|
|
|
|
#
|
|
|
|
# State | Q Empty | Q Full
|
|
|
|
# ------------|----------|-------
|
|
|
|
# Reading | Push Eof | Na
|
|
|
|
# Pushing | Na | Pop
|
2021-05-21 16:27:01 +00:00
|
|
|
try:
|
|
|
|
if not(s.reading and s.pushing):
|
|
|
|
if s.reading:
|
|
|
|
if s.readQueue.empty():
|
|
|
|
# There is an active reader
|
|
|
|
s.readQueue.addLastNoWait(Eof)
|
|
|
|
elif s.pushing:
|
|
|
|
if not s.readQueue.empty():
|
|
|
|
discard s.readQueue.popFirstNoWait()
|
|
|
|
except AsyncQueueFullError, AsyncQueueEmptyError:
|
|
|
|
raise newException(Defect, getCurrentExceptionMsg())
|
refactor bufferstream to use a queue (#346)
This change modifies how the backpressure algorithm in bufferstream
works - in particular, instead of working byte-by-byte, it will now work
seq-by-seq.
When data arrives, it usually does so in packets - in the current
bufferstream, the packet is read then split into bytes which are fed one
by one to the bufferstream. On the reading side, the bytes are popped of
the bufferstream, again byte by byte, to satisfy `readOnce` requests -
this introduces a lot of synchronization traffic because the checks for
full buffer and for async event handling must be done for every byte.
In this PR, a queue of length 1 is used instead - this means there will
at most exist one "packet" in `pushTo`, one in the queue and one in the
slush buffer that is used to store incomplete reads.
* avoid byte-by-byte copy to buffer, with synchronization in-between
* reuse AsyncQueue synchronization logic instead of rolling own
* avoid writeHandler callback - implement `write` method instead
* simplify EOF signalling by only setting EOF flag in queue reader (and
reset)
* remove BufferStream pipes (unused)
* fixes drainBuffer deadlock when drain is called from within read loop
and thus blocks draining
* fix lpchannel init order
2020-09-10 06:19:13 +00:00
|
|
|
|
|
|
|
trace "Closed BufferStream", s
|
2020-09-21 17:48:19 +00:00
|
|
|
|
|
|
|
procCall Connection(s).closeImpl() # noraises, nocancels
|