c70ff9f9be
The gc compiler has started permitting go:linkname comments with a single argument to mean that a function should be externally visible outside the package. Implement this in the Go frontend. Change the libgo runtime package to use it, rather than repeating the name just to export a function. Remove a couple of unnecessary go:linkname comments on declarations. Reviewed-on: https://go-review.googlesource.com/c/gofrontend/+/192197 From-SVN: r275239
249 lines
5.3 KiB
Go
249 lines
5.3 KiB
Go
// Copyright 2011 The Go Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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// +build dragonfly freebsd linux
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package runtime
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import (
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"runtime/internal/atomic"
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"unsafe"
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)
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// For gccgo, while we still have C runtime code, use go:linkname to
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// export some functions.
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//
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//go:linkname lock
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//go:linkname unlock
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//go:linkname noteclear
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//go:linkname notewakeup
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//go:linkname notesleep
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//go:linkname notetsleep
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//go:linkname notetsleepg
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// This implementation depends on OS-specific implementations of
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//
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// futexsleep(addr *uint32, val uint32, ns int64)
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// Atomically,
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// if *addr == val { sleep }
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// Might be woken up spuriously; that's allowed.
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// Don't sleep longer than ns; ns < 0 means forever.
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//
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// futexwakeup(addr *uint32, cnt uint32)
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// If any procs are sleeping on addr, wake up at most cnt.
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const (
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mutex_unlocked = 0
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mutex_locked = 1
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mutex_sleeping = 2
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active_spin = 4
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active_spin_cnt = 30
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passive_spin = 1
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)
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// Possible lock states are mutex_unlocked, mutex_locked and mutex_sleeping.
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// mutex_sleeping means that there is presumably at least one sleeping thread.
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// Note that there can be spinning threads during all states - they do not
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// affect mutex's state.
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// We use the uintptr mutex.key and note.key as a uint32.
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//go:nosplit
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func key32(p *uintptr) *uint32 {
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return (*uint32)(unsafe.Pointer(p))
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}
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func lock(l *mutex) {
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gp := getg()
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if gp.m.locks < 0 {
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throw("runtime·lock: lock count")
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}
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gp.m.locks++
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// Speculative grab for lock.
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v := atomic.Xchg(key32(&l.key), mutex_locked)
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if v == mutex_unlocked {
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return
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}
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// wait is either MUTEX_LOCKED or MUTEX_SLEEPING
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// depending on whether there is a thread sleeping
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// on this mutex. If we ever change l->key from
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// MUTEX_SLEEPING to some other value, we must be
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// careful to change it back to MUTEX_SLEEPING before
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// returning, to ensure that the sleeping thread gets
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// its wakeup call.
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wait := v
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// On uniprocessors, no point spinning.
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// On multiprocessors, spin for ACTIVE_SPIN attempts.
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spin := 0
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if ncpu > 1 {
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spin = active_spin
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}
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for {
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// Try for lock, spinning.
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for i := 0; i < spin; i++ {
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for l.key == mutex_unlocked {
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if atomic.Cas(key32(&l.key), mutex_unlocked, wait) {
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return
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}
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}
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procyield(active_spin_cnt)
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}
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// Try for lock, rescheduling.
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for i := 0; i < passive_spin; i++ {
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for l.key == mutex_unlocked {
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if atomic.Cas(key32(&l.key), mutex_unlocked, wait) {
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return
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}
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}
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osyield()
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}
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// Sleep.
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v = atomic.Xchg(key32(&l.key), mutex_sleeping)
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if v == mutex_unlocked {
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return
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}
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wait = mutex_sleeping
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futexsleep(key32(&l.key), mutex_sleeping, -1)
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}
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}
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func unlock(l *mutex) {
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v := atomic.Xchg(key32(&l.key), mutex_unlocked)
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if v == mutex_unlocked {
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throw("unlock of unlocked lock")
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}
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if v == mutex_sleeping {
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futexwakeup(key32(&l.key), 1)
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}
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gp := getg()
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gp.m.locks--
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if gp.m.locks < 0 {
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throw("runtime·unlock: lock count")
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}
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// if gp.m.locks == 0 && gp.preempt { // restore the preemption request in case we've cleared it in newstack
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// gp.stackguard0 = stackPreempt
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// }
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}
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// One-time notifications.
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func noteclear(n *note) {
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n.key = 0
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}
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func notewakeup(n *note) {
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old := atomic.Xchg(key32(&n.key), 1)
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if old != 0 {
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print("notewakeup - double wakeup (", old, ")\n")
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throw("notewakeup - double wakeup")
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}
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futexwakeup(key32(&n.key), 1)
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}
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func notesleep(n *note) {
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gp := getg()
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if gp != gp.m.g0 {
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throw("notesleep not on g0")
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}
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ns := int64(-1)
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if *cgo_yield != nil {
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// Sleep for an arbitrary-but-moderate interval to poll libc interceptors.
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ns = 10e6
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}
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for atomic.Load(key32(&n.key)) == 0 {
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gp.m.blocked = true
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futexsleep(key32(&n.key), 0, ns)
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if *cgo_yield != nil {
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asmcgocall(*cgo_yield, nil)
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}
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gp.m.blocked = false
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}
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}
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// May run with m.p==nil if called from notetsleep, so write barriers
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// are not allowed.
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//
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//go:nosplit
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//go:nowritebarrier
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func notetsleep_internal(n *note, ns int64) bool {
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gp := getg()
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if ns < 0 {
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if *cgo_yield != nil {
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// Sleep for an arbitrary-but-moderate interval to poll libc interceptors.
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ns = 10e6
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}
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for atomic.Load(key32(&n.key)) == 0 {
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gp.m.blocked = true
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futexsleep(key32(&n.key), 0, ns)
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if *cgo_yield != nil {
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asmcgocall(*cgo_yield, nil)
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}
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gp.m.blocked = false
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}
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return true
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}
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if atomic.Load(key32(&n.key)) != 0 {
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return true
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}
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deadline := nanotime() + ns
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for {
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if *cgo_yield != nil && ns > 10e6 {
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ns = 10e6
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}
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gp.m.blocked = true
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futexsleep(key32(&n.key), 0, ns)
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if *cgo_yield != nil {
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asmcgocall(*cgo_yield, nil)
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}
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gp.m.blocked = false
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if atomic.Load(key32(&n.key)) != 0 {
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break
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}
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now := nanotime()
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if now >= deadline {
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break
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}
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ns = deadline - now
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}
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return atomic.Load(key32(&n.key)) != 0
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}
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func notetsleep(n *note, ns int64) bool {
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gp := getg()
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if gp != gp.m.g0 && gp.m.preemptoff != "" {
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throw("notetsleep not on g0")
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}
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return notetsleep_internal(n, ns)
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}
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// same as runtime·notetsleep, but called on user g (not g0)
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// calls only nosplit functions between entersyscallblock/exitsyscall
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func notetsleepg(n *note, ns int64) bool {
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gp := getg()
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if gp == gp.m.g0 {
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throw("notetsleepg on g0")
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}
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entersyscallblock()
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ok := notetsleep_internal(n, ns)
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exitsyscall()
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return ok
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}
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func beforeIdle() bool {
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return false
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}
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func checkTimeouts() {}
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