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608 lines
24 KiB
Markdown
608 lines
24 KiB
Markdown
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# Extension pipelining
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`websocket-extensions` models the extension negotiation and processing pipeline
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of the WebSocket protocol. Between the driver parsing messages from the TCP
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stream and handing those messages off to the application, there may exist a
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stack of extensions that transform the message somehow.
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In the parlance of this framework, a *session* refers to a single instance of an
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extension, acting on a particular socket on either the server or the client
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side. A session may transform messages both incoming to the application and
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outgoing from the application, for example the `permessage-deflate` extension
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compresses outgoing messages and decompresses incoming messages. Message streams
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in either direction are independent; that is, incoming and outgoing messages
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cannot be assumed to 'pair up' as in a request-response protocol.
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Asynchronous processing of messages poses a number of problems that this
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pipeline construction is intended to solve.
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## Overview
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Logically, we have the following:
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+-------------+ out +---+ +---+ +---+ +--------+
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| |------>| |---->| |---->| |------>| |
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| Application | | A | | B | | C | | Driver |
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| |<------| |<----| |<----| |<------| |
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+-------------+ in +---+ +---+ +---+ +--------+
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\ /
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+----------o----------+
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sessions
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For outgoing messages, the driver receives the result of
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C.outgoing(B.outgoing(A.outgoing(message)))
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or, [A, B, C].reduce(((m, ext) => ext.outgoing(m)), message)
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For incoming messages, the application receives the result of
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A.incoming(B.incoming(C.incoming(message)))
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or, [C, B, A].reduce(((m, ext) => ext.incoming(m)), message)
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A session is of the following type, to borrow notation from pseudo-Haskell:
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type Session = {
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incoming :: Message -> Message
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outgoing :: Message -> Message
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close :: () -> ()
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}
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(That `() -> ()` syntax is intended to mean that `close()` is a nullary void
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method; I apologise to any Haskell readers for not using the right monad.)
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The `incoming()` and `outgoing()` methods perform message transformation in the
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respective directions; `close()` is called when a socket closes so the session
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can release any resources it's holding, for example a DEFLATE de/compression
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context.
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However because this is JavaScript, the `incoming()` and `outgoing()` methods
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may be asynchronous (indeed, `permessage-deflate` is based on `zlib`, whose API
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is stream-based). So their interface is strictly:
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type Session = {
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incoming :: Message -> Callback -> ()
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outgoing :: Message -> Callback -> ()
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close :: () -> ()
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}
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type Callback = Either Error Message -> ()
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This means a message *m2* can be pushed into a session while it's still
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processing the preceding message *m1*. The messages can be processed
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concurrently but they *must* be given to the next session in line (or to the
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application) in the same order they came in. Applications will expect to receive
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messages in the order they arrived over the wire, and sessions require this too.
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So ordering of messages must be preserved throughout the pipeline.
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Consider the following highly simplified extension that deflates messages on the
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wire. `message` is a value conforming the type:
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type Message = {
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rsv1 :: Boolean
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rsv2 :: Boolean
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rsv3 :: Boolean
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opcode :: Number
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data :: Buffer
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}
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Here's the extension:
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```js
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var zlib = require('zlib');
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var deflate = {
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outgoing: function(message, callback) {
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zlib.deflateRaw(message.data, function(error, result) {
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message.rsv1 = true;
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message.data = result;
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callback(error, message);
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});
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},
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incoming: function(message, callback) {
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// decompress inbound messages (elided)
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},
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close: function() {
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// no state to clean up
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}
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};
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```
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We can call it with a large message followed by a small one, and the small one
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will be returned first:
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```js
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var crypto = require('crypto'),
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large = crypto.randomBytes(1 << 14),
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small = new Buffer('hi');
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deflate.outgoing({ data: large }, function() {
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console.log(1, 'large');
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});
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deflate.outgoing({ data: small }, function() {
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console.log(2, 'small');
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});
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/* prints: 2 'small'
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1 'large' */
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```
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So a session that processes messages asynchronously may fail to preserve message
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ordering.
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Now, this extension is stateless, so it can process messages in any order and
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still produce the same output. But some extensions are stateful and require
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message order to be preserved.
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For example, when using `permessage-deflate` without `no_context_takeover` set,
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the session retains a DEFLATE de/compression context between messages, which
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accumulates state as it consumes data (later messages can refer to sections of
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previous ones to improve compression). Reordering parts of the DEFLATE stream
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will result in a failed decompression. Messages must be decompressed in the same
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order they were compressed by the peer in order for the DEFLATE protocol to
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work.
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Finally, there is the problem of closing a socket. When a WebSocket is closed by
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the application, or receives a closing request from the other peer, there may be
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messages outgoing from the application and incoming from the peer in the
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pipeline. If we close the socket and pipeline immediately, two problems arise:
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* We may send our own closing frame to the peer before all prior messages we
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sent have been written to the socket, and before we have finished processing
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all prior messages from the peer
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* The session may be instructed to close its resources (e.g. its de/compression
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context) while it's in the middle of processing a message, or before it has
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received messages that are upstream of it in the pipeline
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Essentially, we must defer closing the sessions and sending a closing frame
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until after all prior messages have exited the pipeline.
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## Design goals
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* Message order must be preserved between the protocol driver, the extension
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sessions, and the application
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* Messages should be handed off to sessions and endpoints as soon as possible,
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to maximise throughput of stateless sessions
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* The closing procedure should block any further messages from entering the
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pipeline, and should allow all existing messages to drain
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* Sessions should be closed as soon as possible to prevent them holding memory
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and other resources when they have no more messages to handle
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* The closing API should allow the caller to detect when the pipeline is empty
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and it is safe to continue the WebSocket closing procedure
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* Individual extensions should remain as simple as possible to facilitate
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modularity and independent authorship
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The final point about modularity is an important one: this framework is designed
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to facilitate extensions existing as plugins, by decoupling the protocol driver,
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extensions, and application. In an ideal world, plugins should only need to
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contain code for their specific functionality, and not solve these problems that
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apply to all sessions. Also, solving some of these problems requires
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consideration of all active sessions collectively, which an individual session
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is incapable of doing.
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For example, it is entirely possible to take the simple `deflate` extension
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above and wrap its `incoming()` and `outgoing()` methods in two `Transform`
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streams, producing this type:
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type Session = {
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incoming :: TransformStream
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outtoing :: TransformStream
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close :: () -> ()
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}
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The `Transform` class makes it easy to wrap an async function such that message
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order is preserved:
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```js
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var stream = require('stream'),
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session = new stream.Transform({ objectMode: true });
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session._transform = function(message, _, callback) {
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var self = this;
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deflate.outgoing(message, function(error, result) {
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self.push(result);
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callback();
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});
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};
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```
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However, this has a negative impact on throughput: it works by deferring
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`callback()` until the async function has 'returned', which blocks `Transform`
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from passing further input into the `_transform()` method until the current
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message is dealt with completely. This would prevent sessions from processing
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messages concurrently, and would unnecessarily reduce the throughput of
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stateless extensions.
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So, input should be handed off to sessions as soon as possible, and all we need
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is a mechanism to reorder the output so that message order is preserved for the
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next session in line.
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## Solution
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We now describe the model implemented here and how it meets the above design
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goals. The above diagram where a stack of extensions sit between the driver and
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application describes the data flow, but not the object graph. That looks like
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this:
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+--------+
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| Driver |
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+---o----+
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V
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+------------+ +----------+
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| Extensions o----->| Pipeline |
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+------------+ +-----o----+
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+---------------+---------------+
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+-----o----+ +-----o----+ +-----o----+
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| Cell [A] | | Cell [B] | | Cell [C] |
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+----------+ +----------+ +----------+
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A driver using this framework holds an instance of the `Extensions` class, which
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it uses to register extension plugins, negotiate headers and transform messages.
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The `Extensions` instance itself holds a `Pipeline`, which contains an array of
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`Cell` objects, each of which wraps one of the sessions.
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### Message processing
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Both the `Pipeline` and `Cell` classes have `incoming()` and `outgoing()`
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methods; the `Pipeline` interface pushes messages into the pipe, delegates the
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message to each `Cell` in turn, then returns it back to the driver. Outgoing
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messages pass through `A` then `B` then `C`, and incoming messages in the
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reverse order.
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Internally, a `Cell` contains two `Functor` objects. A `Functor` wraps an async
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function and makes sure its output messages maintain the order of its input
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messages. This name is due to [@fronx](https://github.com/fronx), on the basis
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that, by preserving message order, the abstraction preserves the *mapping*
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between input and output messages. To use our simple `deflate` extension from
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above:
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```js
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var functor = new Functor(deflate, 'outgoing');
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functor.call({ data: large }, function() {
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console.log(1, 'large');
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});
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functor.call({ data: small }, function() {
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console.log(2, 'small');
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});
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/* -> 1 'large'
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2 'small' */
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```
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A `Cell` contains two of these, one for each direction:
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+-----------------------+
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+---->| Functor [A, incoming] |
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+----------+ | +-----------------------+
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| Cell [A] o------+
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+----------+ | +-----------------------+
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+---->| Functor [A, outgoing] |
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+-----------------------+
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This satisfies the message transformation requirements: the `Pipeline` simply
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loops over the cells in the appropriate direction to transform each message.
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Because each `Cell` will preserve message order, we can pass a message to the
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next `Cell` in line as soon as the current `Cell` returns it. This gives each
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`Cell` all the messages in order while maximising throughput.
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### Session closing
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We want to close each session as soon as possible, after all existing messages
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have drained. To do this, each `Cell` begins with a pending message counter in
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each direction, labelled `in` and `out` below.
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+----------+
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| Pipeline |
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+-----o----+
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+---------------+---------------+
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+-----o----+ +-----o----+ +-----o----+
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| Cell [A] | | Cell [B] | | Cell [C] |
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+----------+ +----------+ +----------+
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in: 0 in: 0 in: 0
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out: 0 out: 0 out: 0
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When a message *m1* enters the pipeline, say in the `outgoing` direction, we
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increment the `pending.out` counter on all cells immediately.
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+----------+
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m1 => | Pipeline |
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+-----o----+
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+---------------+---------------+
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+-----o----+ +-----o----+ +-----o----+
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| Cell [A] | | Cell [B] | | Cell [C] |
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+----------+ +----------+ +----------+
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in: 0 in: 0 in: 0
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out: 1 out: 1 out: 1
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*m1* is handed off to `A`, meanwhile a second message `m2` arrives in the same
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direction. All `pending.out` counters are again incremented.
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+----------+
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m2 => | Pipeline |
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+-----o----+
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+---------------+---------------+
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m1 | | |
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+-----o----+ +-----o----+ +-----o----+
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| Cell [A] | | Cell [B] | | Cell [C] |
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+----------+ +----------+ +----------+
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in: 0 in: 0 in: 0
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out: 2 out: 2 out: 2
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When the first cell's `A.outgoing` functor finishes processing *m1*, the first
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`pending.out` counter is decremented and *m1* is handed off to cell `B`.
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+----------+
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| Pipeline |
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+-----o----+
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+---------------+---------------+
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m2 | m1 | |
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+-----o----+ +-----o----+ +-----o----+
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| Cell [A] | | Cell [B] | | Cell [C] |
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+----------+ +----------+ +----------+
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in: 0 in: 0 in: 0
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out: 1 out: 2 out: 2
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As `B` finishes with *m1*, and as `A` finishes with *m2*, the `pending.out`
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counters continue to decrement.
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+----------+
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| Pipeline |
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+-----o----+
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+---------------+---------------+
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| m2 | m1 |
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+-----o----+ +-----o----+ +-----o----+
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| Cell [A] | | Cell [B] | | Cell [C] |
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+----------+ +----------+ +----------+
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in: 0 in: 0 in: 0
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out: 0 out: 1 out: 2
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Say `C` is a little slow, and begins processing *m2* while still processing
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*m1*. That's fine, the `Functor` mechanism will keep *m1* ahead of *m2* in the
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output.
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+----------+
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| Pipeline |
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+-----o----+
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+---------------+---------------+
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| | m2 | m1
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+-----o----+ +-----o----+ +-----o----+
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| Cell [A] | | Cell [B] | | Cell [C] |
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+----------+ +----------+ +----------+
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in: 0 in: 0 in: 0
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out: 0 out: 0 out: 2
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Once all messages are dealt with, the counters return to `0`.
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+----------+
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| Pipeline |
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+-----o----+
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+---------------+---------------+
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+-----o----+ +-----o----+ +-----o----+
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| Cell [A] | | Cell [B] | | Cell [C] |
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+----------+ +----------+ +----------+
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in: 0 in: 0 in: 0
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out: 0 out: 0 out: 0
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The same process applies in the `incoming` direction, the only difference being
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that messages are passed to `C` first.
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This makes closing the sessions quite simple. When the driver wants to close the
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socket, it calls `Pipeline.close()`. This *immediately* calls `close()` on all
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the cells. If a cell has `in == out == 0`, then it immediately calls
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`session.close()`. Otherwise, it stores the closing call and defers it until
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`in` and `out` have both ticked down to zero. The pipeline will not accept new
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messages after `close()` has been called, so we know the pending counts will not
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increase after this point.
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This means each session is closed as soon as possible: `A` can close while the
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slow `C` session is still working, because it knows there are no more messages
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on the way. Similarly, `C` will defer closing if `close()` is called while *m1*
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is still in `B`, and *m2* in `A`, because its pending count means it knows it
|
||
|
has work yet to do, even if it's not received those messages yet. This concern
|
||
|
cannot be addressed by extensions acting only on their own local state, unless
|
||
|
we pollute individual extensions by making them all implement this same
|
||
|
mechanism.
|
||
|
|
||
|
The actual closing API at each level is slightly different:
|
||
|
|
||
|
type Session = {
|
||
|
close :: () -> ()
|
||
|
}
|
||
|
|
||
|
type Cell = {
|
||
|
close :: () -> Promise ()
|
||
|
}
|
||
|
|
||
|
type Pipeline = {
|
||
|
close :: Callback -> ()
|
||
|
}
|
||
|
|
||
|
This might appear inconsistent so it's worth explaining. Remember that a
|
||
|
`Pipeline` holds a list of `Cell` objects, each wrapping a `Session`. The driver
|
||
|
talks (via the `Extensions` API) to the `Pipeline` interface, and it wants
|
||
|
`Pipeline.close()` to do two things: close all the sessions, and tell me when
|
||
|
it's safe to start the closing procedure (i.e. when all messages have drained
|
||
|
from the pipe and been handed off to the application or socket). A callback API
|
||
|
works well for that.
|
||
|
|
||
|
At the other end of the stack, `Session.close()` is a nullary void method with
|
||
|
no callback or promise API because we don't care what it does, and whatever it
|
||
|
does do will not block the WebSocket protocol; we're not going to hold off
|
||
|
processing messages while a session closes its de/compression context. We just
|
||
|
tell it to close itself, and don't want to wait while it does that.
|
||
|
|
||
|
In the middle, `Cell.close()` returns a promise rather than using a callback.
|
||
|
This is for two reasons. First, `Cell.close()` might not do anything
|
||
|
immediately, it might have to defer its effect while messages drain. So, if
|
||
|
given a callback, it would have to store it in a queue for later execution.
|
||
|
Callbacks work fine if your method does something and can then invoke the
|
||
|
callback itself, but if you need to store callbacks somewhere so another method
|
||
|
can execute them, a promise is a better fit. Second, it better serves the
|
||
|
purposes of `Pipeline.close()`: it wants to call `close()` on each of a list of
|
||
|
cells, and wait for all of them to finish. This is simple and idiomatic using
|
||
|
promises:
|
||
|
|
||
|
```js
|
||
|
var closed = cells.map((cell) => cell.close());
|
||
|
Promise.all(closed).then(callback);
|
||
|
```
|
||
|
|
||
|
(We don't actually use a full *Promises/A+* compatible promise here, we use a
|
||
|
much simplified construction that acts as a callback aggregater and resolves
|
||
|
synchronously and does not support chaining, but the principle is the same.)
|
||
|
|
||
|
|
||
|
### Error handling
|
||
|
|
||
|
We've not mentioned error handling so far but it bears some explanation. The
|
||
|
above counter system still applies, but behaves slightly differently in the
|
||
|
presence of errors.
|
||
|
|
||
|
Say we push three messages into the pipe in the outgoing direction:
|
||
|
|
||
|
|
||
|
+----------+
|
||
|
m3, m2, m1 => | Pipeline |
|
||
|
+-----o----+
|
||
|
|
|
||
|
+---------------+---------------+
|
||
|
| | |
|
||
|
+-----o----+ +-----o----+ +-----o----+
|
||
|
| Cell [A] | | Cell [B] | | Cell [C] |
|
||
|
+----------+ +----------+ +----------+
|
||
|
in: 0 in: 0 in: 0
|
||
|
out: 3 out: 3 out: 3
|
||
|
|
||
|
|
||
|
They pass through the cells successfully up to this point:
|
||
|
|
||
|
|
||
|
+----------+
|
||
|
| Pipeline |
|
||
|
+-----o----+
|
||
|
|
|
||
|
+---------------+---------------+
|
||
|
m3 | m2 | m1 |
|
||
|
+-----o----+ +-----o----+ +-----o----+
|
||
|
| Cell [A] | | Cell [B] | | Cell [C] |
|
||
|
+----------+ +----------+ +----------+
|
||
|
in: 0 in: 0 in: 0
|
||
|
out: 1 out: 2 out: 3
|
||
|
|
||
|
|
||
|
At this point, session `B` produces an error while processing *m2*, that is *m2*
|
||
|
becomes *e2*. *m1* is still in the pipeline, and *m3* is queued behind *m2*.
|
||
|
What ought to happen is that *m1* is handed off to the socket, then *m2* is
|
||
|
released to the driver, which will detect the error and begin closing the
|
||
|
socket. No further processing should be done on *m3* and it should not be
|
||
|
released to the driver after the error is emitted.
|
||
|
|
||
|
To handle this, we allow errors to pass down the pipeline just like messages do,
|
||
|
to maintain ordering. But, once a cell sees its session produce an error, or it
|
||
|
receives an error from upstream, it should refuse to accept any further
|
||
|
messages. Session `B` might have begun processing *m3* by the time it produces
|
||
|
the error *e2*, but `C` will have been given *e2* before it receives *m3*, and
|
||
|
can simply drop *m3*.
|
||
|
|
||
|
Now, say *e2* reaches the slow session `C` while *m1* is still present,
|
||
|
meanwhile *m3* has been dropped. `C` will never receive *m3* since it will have
|
||
|
been dropped upstream. Under the present model, its `out` counter will be `3`
|
||
|
but it is only going to emit two more values: *m1* and *e2*. In order for
|
||
|
closing to work, we need to decrement `out` to reflect this. The situation
|
||
|
should look like this:
|
||
|
|
||
|
|
||
|
+----------+
|
||
|
| Pipeline |
|
||
|
+-----o----+
|
||
|
|
|
||
|
+---------------+---------------+
|
||
|
| | e2 | m1
|
||
|
+-----o----+ +-----o----+ +-----o----+
|
||
|
| Cell [A] | | Cell [B] | | Cell [C] |
|
||
|
+----------+ +----------+ +----------+
|
||
|
in: 0 in: 0 in: 0
|
||
|
out: 0 out: 0 out: 2
|
||
|
|
||
|
|
||
|
When a cell sees its session emit an error, or when it receives an error from
|
||
|
upstream, it sets its pending count in the appropriate direction to equal the
|
||
|
number of messages it is *currently* processing. It will not accept any messages
|
||
|
after it sees the error, so this will allow the counter to reach zero.
|
||
|
|
||
|
Note that while *e2* is in the pipeline, `Pipeline` should drop any further
|
||
|
messages in the outgoing direction, but should continue to accept incoming
|
||
|
messages. Until *e2* makes it out of the pipe to the driver, behind previous
|
||
|
successful messages, the driver does not know an error has happened, and a
|
||
|
message may arrive over the socket and make it all the way through the incoming
|
||
|
pipe in the meantime. We only halt processing in the affected direction to avoid
|
||
|
doing unnecessary work since messages arriving after an error should not be
|
||
|
processed.
|
||
|
|
||
|
Some unnecessary work may happen, for example any messages already in the
|
||
|
pipeline following *m2* will be processed by `A`, since it's upstream of the
|
||
|
error. Those messages will be dropped by `B`.
|
||
|
|
||
|
|
||
|
## Alternative ideas
|
||
|
|
||
|
I am considering implementing `Functor` as an object-mode transform stream
|
||
|
rather than what is essentially an async function. Being object-mode, a stream
|
||
|
would preserve message boundaries and would also possibly help address
|
||
|
back-pressure. I'm not sure whether this would require external API changes so
|
||
|
that such streams could be connected to the downstream driver's streams.
|
||
|
|
||
|
|
||
|
## Acknowledgements
|
||
|
|
||
|
Credit is due to [@mnowster](https://github.com/mnowster) for helping with the
|
||
|
design and to [@fronx](https://github.com/fronx) for helping name things.
|