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runtime: clarify which work needs spinning coordination
The overview comments discuss readying goroutines, which is the most common source of work, but timers and idle-priority GC work also require the same synchronization w.r.t. spinning Ms. This CL should have no functional changes. For #43997 Updates #44313 Change-Id: I7910a7f93764dde07c3ed63666277eb832bf8299 Reviewed-on: https://go-review.googlesource.com/c/go/+/307912 Trust: Michael Pratt <mpratt@google.com> Run-TryBot: Michael Pratt <mpratt@google.com> TryBot-Result: Go Bot <gobot@golang.org> Reviewed-by: Michael Knyszek <mknyszek@google.com>
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@ -50,33 +50,64 @@ var modinfo string
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// any work to do.
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//
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// The current approach:
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// We unpark an additional thread when we ready a goroutine if (1) there is an
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// idle P and there are no "spinning" worker threads. A worker thread is considered
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// spinning if it is out of local work and did not find work in global run queue/
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// netpoller; the spinning state is denoted in m.spinning and in sched.nmspinning.
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// Threads unparked this way are also considered spinning; we don't do goroutine
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// handoff so such threads are out of work initially. Spinning threads do some
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// spinning looking for work in per-P run queues before parking. If a spinning
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// thread finds work it takes itself out of the spinning state and proceeds to
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// execution. If it does not find work it takes itself out of the spinning state
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// and then parks.
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// If there is at least one spinning thread (sched.nmspinning>1), we don't unpark
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// new threads when readying goroutines. To compensate for that, if the last spinning
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// thread finds work and stops spinning, it must unpark a new spinning thread.
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// This approach smooths out unjustified spikes of thread unparking,
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// but at the same time guarantees eventual maximal CPU parallelism utilization.
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//
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// The main implementation complication is that we need to be very careful during
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// spinning->non-spinning thread transition. This transition can race with submission
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// of a new goroutine, and either one part or another needs to unpark another worker
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// thread. If they both fail to do that, we can end up with semi-persistent CPU
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// underutilization. The general pattern for goroutine readying is: submit a goroutine
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// to local work queue, #StoreLoad-style memory barrier, check sched.nmspinning.
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// The general pattern for spinning->non-spinning transition is: decrement nmspinning,
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// #StoreLoad-style memory barrier, check all per-P work queues for new work.
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// Note that all this complexity does not apply to global run queue as we are not
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// sloppy about thread unparking when submitting to global queue. Also see comments
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// for nmspinning manipulation.
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// This approach applies to three primary sources of potential work: readying a
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// goroutine, new/modified-earlier timers, and idle-priority GC. See below for
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// additional details.
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//
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// We unpark an additional thread when we submit work if (this is wakep()):
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// 1. There is an idle P, and
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// 2. There are no "spinning" worker threads.
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//
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// A worker thread is considered spinning if it is out of local work and did
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// not find work in the global run queue or netpoller; the spinning state is
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// denoted in m.spinning and in sched.nmspinning. Threads unparked this way are
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// also considered spinning; we don't do goroutine handoff so such threads are
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// out of work initially. Spinning threads spin on looking for work in per-P
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// run queues and timer heaps or from the GC before parking. If a spinning
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// thread finds work it takes itself out of the spinning state and proceeds to
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// execution. If it does not find work it takes itself out of the spinning
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// state and then parks.
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//
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// If there is at least one spinning thread (sched.nmspinning>1), we don't
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// unpark new threads when submitting work. To compensate for that, if the last
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// spinning thread finds work and stops spinning, it must unpark a new spinning
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// thread. This approach smooths out unjustified spikes of thread unparking,
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// but at the same time guarantees eventual maximal CPU parallelism
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// utilization.
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//
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// The main implementation complication is that we need to be very careful
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// during spinning->non-spinning thread transition. This transition can race
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// with submission of new work, and either one part or another needs to unpark
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// another worker thread. If they both fail to do that, we can end up with
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// semi-persistent CPU underutilization.
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//
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// The general pattern for submission is:
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// 1. Submit work to the local run queue, timer heap, or GC state.
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// 2. #StoreLoad-style memory barrier.
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// 3. Check sched.nmspinning.
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//
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// The general pattern for spinning->non-spinning transition is:
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// 1. Decrement nmspinning.
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// 2. #StoreLoad-style memory barrier.
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// 3. Check all per-P work queues and GC for new work.
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//
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// Note that all this complexity does not apply to global run queue as we are
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// not sloppy about thread unparking when submitting to global queue. Also see
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// comments for nmspinning manipulation.
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//
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// How these different sources of work behave varies, though it doesn't affect
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// the synchronization approach:
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// * Ready goroutine: this is an obvious source of work; the goroutine is
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// immediately ready and must run on some thread eventually.
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// * New/modified-earlier timer: The current timer implementation (see time.go)
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// uses netpoll in a thread with no work available to wait for the soonest
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// timer. If there is no thread waiting, we want a new spinning thread to go
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// wait.
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// * Idle-priority GC: The GC wakes a stopped idle thread to contribute to
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// background GC work (note: currently disabled per golang.org/issue/19112).
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// Also see golang.org/issue/44313, as this should be extended to all GC
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// workers.
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var (
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m0 m
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@ -2785,18 +2816,25 @@ stop:
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pidleput(_p_)
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unlock(&sched.lock)
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// Delicate dance: thread transitions from spinning to non-spinning state,
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// potentially concurrently with submission of new goroutines. We must
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// drop nmspinning first and then check all per-P queues again (with
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// #StoreLoad memory barrier in between). If we do it the other way around,
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// another thread can submit a goroutine after we've checked all run queues
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// but before we drop nmspinning; as a result nobody will unpark a thread
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// to run the goroutine.
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// Delicate dance: thread transitions from spinning to non-spinning
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// state, potentially concurrently with submission of new work. We must
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// drop nmspinning first and then check all sources again (with
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// #StoreLoad memory barrier in between). If we do it the other way
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// around, another thread can submit work after we've checked all
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// sources but before we drop nmspinning; as a result nobody will
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// unpark a thread to run the work.
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//
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// This applies to the following sources of work:
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//
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// * Goroutines added to a per-P run queue.
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// * New/modified-earlier timers on a per-P timer heap.
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// * Idle-priority GC work (barring golang.org/issue/19112).
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//
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// If we discover new work below, we need to restore m.spinning as a signal
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// for resetspinning to unpark a new worker thread (because there can be more
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// than one starving goroutine). However, if after discovering new work
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// we also observe no idle Ps, it is OK to just park the current thread:
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// the system is fully loaded so no spinning threads are required.
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// we also observe no idle Ps it is OK to skip unparking a new worker
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// thread: the system is fully loaded so no spinning threads are required.
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// Also see "Worker thread parking/unparking" comment at the top of the file.
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wasSpinning := _g_.m.spinning
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if _g_.m.spinning {
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