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123 lines
6.7 KiB
Markdown
123 lines
6.7 KiB
Markdown
## Userspace Context Switching
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The `ircd::ctx` subsystem is a userspace threading library meant to regress
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the asynchronous callback pattern back to synchronous suspensions. These are
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stackful coroutines which provide developers with more intuitive control in
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environments which conduct frequent I/O which would otherwise break up a single
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asynchronous stack into callback-hell.
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### Motivation
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Userspace threads are an alternative to using posix kernel threads as a way
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to develop intuitively-stackful programs in applications which are primarily
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I/O-bound rather than CPU-bound. This is born out of a recognition that a
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single CPU core has enough capacity to compute the entirety of all requests for
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an efficiently-written network daemon if I/O were instantaneous; if one
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*could* use a single thread it is advantageous to do so right up until the
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compute-bound is reached, rather than introducing more threads for any other
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reason. The limits to single-threading and scaling beyond a single CPU is then
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pushed to higher-level application logic: either message-passing between
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multiple processes (or machines in a cluster), and/or threads which have
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extremely low interference.
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`ircd::ctx` allows for a very large number of contexts to exist, on the order
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of thousands or more, and still efficiently make progress without the overhead
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of kernel context switches. As an anecdotal example, a kernel context switch
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from a contended mutex could realistically be five to ten times more costly
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than a userspace context switch if not significantly more, and with effects
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that are less predictable. Contexts will accomplish as much work as possible
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in a "straight line" before yielding to the kernel to wait for the completion
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of any I/O event.
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> There is no preemptive interleaving of contexts. This makes every sequence
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of instructions executed a natural transaction requiring no other method of
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exclusion. It also allows for introspective conditions, i.e: check if context
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switch occurred: if so, refresh value; if not, the old value is good. This is
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impossible in a preemptive environment as the result may have changed at
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instruction boundaries rather than at cooperative boundaries.
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### Foundation
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This library is based in `boost::coroutine / boost::context` which wraps
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the register save/restores in a cross-platform way in addition to providing
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properly `mmap(NOEXEC)'ed` etc memory appropriate for stacks on each platform.
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`boost::asio` has then added its own comprehensive integration with the above
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libraries eliminating the need for us to worry about a lot of boilerplate to
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de-async the asio networking calls. See: [boost::asio::spawn](http://www.boost.org/doc/libs/1_65_1/boost/asio/spawn.hpp).
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This is a nice boost, but that's as far as it goes. The rest is on us here to
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actually make a threading library.
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### Interface
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We mimic the standard library `std::thread` suite as much as possible (which
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mimics the `boost::thread` library) and offer alternative threading primitives
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for these userspace contexts rather than those for operating system threads in
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`std::` such as `ctx::mutex` and `ctx::condition_variable` and `ctx::future`
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among others.
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* The primary user object is `ircd::context` (or `ircd::ctx::context`) which has
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an `std::thread`-like interface. By default the lifetime of this instance has
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significance, and when `context` goes out of scope, a termination is sent to
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the child context and the parent yields until it has joined (see DETACH and
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WAIT_JOIN flags to change this behavior). Take note that this means by default
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a child context may never be able to complete (or even be entered at all!)
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if the parent constructs and then desctructs `context` without either any flags
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or any strategy by the parent to wait for completion.
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### Context Switching
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A context switch has the overhead of a heavy function call -- a function with
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a bunch of arguments (i.e the registers being saved and restored). We consider
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this _fast_ and our philosophy is to not think about the context switch
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_itself_ as a bad thing to be avoided for its own sake.
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This system is also fully integrated both with the IRCd core
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`boost::asio::io_service` event loop and networking systems. There are actually
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several types of context switches going on here built on two primitives:
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* Direct jump: This is the fastest switch. Context `A` can yield to context `B`
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directly if `A` knows about `B` and if it knows that `B` is in a state ready to
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resume from a direct jump _and_ that `A` will also be further resumed somehow.
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This is not always suitable in practice so other techniques may be used instead.
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* Queued wakeup: This is the common default and safe switch. This is where
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the context system integrates with the `boost::asio::io_service` event loop.
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The execution of a "slice" as we'll call a yield-to-yield run of non-stop
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computation is analogous to a function posted to the `io_service` in the
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asynchronous pattern. Context `A` can enqueue context `B` if it knows about `B`
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and then choose whether to yield or not to yield. In any case the `io_service`
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queue will simply continue to the next task which isn't guaranteed to be `B`.
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The most common context switching encountered and wielded by developers is the
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`ctx::dock`, a non-locking condition variable. The power of the dock is in its:
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1. Lightweight. It's just a ctx::list; two pointers for a list head, where the
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nodes are the contexts themselves participating in the list.
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2. Cooperative-condition optimized. When a context is waiting on a condition
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it provides, the ctx system can run the function itself to test the condition
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without waking up the context.
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#### When does Context Switching (yielding) occur?
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Bottom line is that this is simply not javascript. There are no
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stack-clairvoyant keywords like `await` which explicitly indicate to everyone
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everywhere that the overall state of the program before and after any totally
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benign-looking function call will be different. This is indeed multi-threaded
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programming but in a very PG-13 rated way. You have to assume that if you
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aren't sure some function has a "deep yield" somewhere way up the stack that
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there is a potential for yielding in that function. Unlike real concurrent
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threading everything beyond this is much easier.
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* Anything directly on your stack is safe (same with real MT anyway).
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* `static` and global assets are safe if you can assert no yielding. Such
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an assertion can be made with an instance of `ircd::ctx::critical_assertion`.
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Note that we try to use `thread_local` rather than `static` to still respect
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any real multi-threading that may occur now or in the future.
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* Calls which may yield and do IO may be marked with `[GET]` and `[SET]`
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conventional labels but they may not be. Some reasoning about obvious yields
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and a zen-like awareness is always recommended.
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