libgo/go/runtime/netpoll.go - gofrontend - Git at Google

 // Copyright 2013 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 // +build aix darwin dragonfly freebsd hurd js,wasm linux nacl netbsd openbsd solaris windows

 package runtime

 import (
 	"runtime/internal/atomic"
 	"unsafe"
 )

 // Export temporarily for gccgo's C code to call:
 //go:linkname netpoll runtime.netpoll

 // Integrated network poller (platform-independent part).
 // A particular implementation (epoll/kqueue) must define the following functions:
 // func netpollinit()			// to initialize the poller
 // func netpollopen(fd uintptr, pd *pollDesc) int32	// to arm edge-triggered notifications
 // and associate fd with pd.
 // An implementation must call the following function to denote that the pd is ready.
 // func netpollready(gpp **g, pd *pollDesc, mode int32)

 // pollDesc contains 2 binary semaphores, rg and wg, to park reader and writer
 // goroutines respectively. The semaphore can be in the following states:
 // pdReady - io readiness notification is pending;
 //           a goroutine consumes the notification by changing the state to nil.
 // pdWait - a goroutine prepares to park on the semaphore, but not yet parked;
 //          the goroutine commits to park by changing the state to G pointer,
 //          or, alternatively, concurrent io notification changes the state to READY,
 //          or, alternatively, concurrent timeout/close changes the state to nil.
 // G pointer - the goroutine is blocked on the semaphore;
 //             io notification or timeout/close changes the state to READY or nil respectively
 //             and unparks the goroutine.
 // nil - nothing of the above.
 const (
 	pdReady uintptr = 1
 	pdWait  uintptr = 2
 )

 const pollBlockSize = 4 * 1024

 // Network poller descriptor.
 //
 // No heap pointers.
 //
 //go:notinheap
 type pollDesc struct {
 	link *pollDesc // in pollcache, protected by pollcache.lock

 	// The lock protects pollOpen, pollSetDeadline, pollUnblock and deadlineimpl operations.
 	// This fully covers seq, rt and wt variables. fd is constant throughout the PollDesc lifetime.
 	// pollReset, pollWait, pollWaitCanceled and runtime·netpollready (IO readiness notification)
 	// proceed w/o taking the lock. So closing, rg, rd, wg and wd are manipulated
 	// in a lock-free way by all operations.
 	// NOTE(dvyukov): the following code uses uintptr to store *g (rg/wg),
 	// that will blow up when GC starts moving objects.
 	lock    mutex // protects the following fields
 	fd      uintptr
 	closing bool
 	user    uint32  // user settable cookie
 	rseq    uintptr // protects from stale read timers
 	rg      uintptr // pdReady, pdWait, G waiting for read or nil
 	rt      timer   // read deadline timer (set if rt.f != nil)
 	rd      int64   // read deadline
 	wseq    uintptr // protects from stale write timers
 	wg      uintptr // pdReady, pdWait, G waiting for write or nil
 	wt      timer   // write deadline timer
 	wd      int64   // write deadline
 }

 type pollCache struct {
 	lock  mutex
 	first *pollDesc
 	// PollDesc objects must be type-stable,
 	// because we can get ready notification from epoll/kqueue
 	// after the descriptor is closed/reused.
 	// Stale notifications are detected using seq variable,
 	// seq is incremented when deadlines are changed or descriptor is reused.
 }

 var (
 	netpollInited  uint32
 	pollcache      pollCache
 	netpollWaiters uint32
 )

 //go:linkname poll_runtime_pollServerInit internal..z2fpoll.runtime_pollServerInit
 func poll_runtime_pollServerInit() {
 	netpollinit()
 	atomic.Store(&netpollInited, 1)
 }

 func netpollinited() bool {
 	return atomic.Load(&netpollInited) != 0
 }

 //go:linkname poll_runtime_isPollServerDescriptor internal..z2fpoll.runtime_isPollServerDescriptor

 // poll_runtime_isPollServerDescriptor reports whether fd is a
 // descriptor being used by netpoll.
 func poll_runtime_isPollServerDescriptor(fd uintptr) bool {
 	fds := netpolldescriptor()
 	if GOOS != "aix" && GOOS != "hurd" {
 		return fd == fds
 	} else {
 		// AIX have a pipe in its netpoll implementation.
 		// Therefore, two fd are returned by netpolldescriptor using a mask.
 		return fd == fds&0xFFFF || fd == (fds>>16)&0xFFFF
 	}
 }

 //go:linkname poll_runtime_pollOpen internal..z2fpoll.runtime_pollOpen
 func poll_runtime_pollOpen(fd uintptr) (*pollDesc, int) {
 	pd := pollcache.alloc()
 	lock(&pd.lock)
 	if pd.wg != 0 && pd.wg != pdReady {
 		throw("runtime: blocked write on free polldesc")
 	}
 	if pd.rg != 0 && pd.rg != pdReady {
 		throw("runtime: blocked read on free polldesc")
 	}
 	pd.fd = fd
 	pd.closing = false
 	pd.rseq++
 	pd.rg = 0
 	pd.rd = 0
 	pd.wseq++
 	pd.wg = 0
 	pd.wd = 0
 	unlock(&pd.lock)

 	var errno int32
 	errno = netpollopen(fd, pd)
 	return pd, int(errno)
 }

 //go:linkname poll_runtime_pollClose internal..z2fpoll.runtime_pollClose
 func poll_runtime_pollClose(pd *pollDesc) {
 	if !pd.closing {
 		throw("runtime: close polldesc w/o unblock")
 	}
 	if pd.wg != 0 && pd.wg != pdReady {
 		throw("runtime: blocked write on closing polldesc")
 	}
 	if pd.rg != 0 && pd.rg != pdReady {
 		throw("runtime: blocked read on closing polldesc")
 	}
 	netpollclose(pd.fd)
 	pollcache.free(pd)
 }

 func (c *pollCache) free(pd *pollDesc) {
 	lock(&c.lock)
 	pd.link = c.first
 	c.first = pd
 	unlock(&c.lock)
 }

 //go:linkname poll_runtime_pollReset internal..z2fpoll.runtime_pollReset
 func poll_runtime_pollReset(pd *pollDesc, mode int) int {
 	err := netpollcheckerr(pd, int32(mode))
 	if err != 0 {
 		return err
 	}
 	if mode == 'r' {
 		pd.rg = 0
 	} else if mode == 'w' {
 		pd.wg = 0
 	}
 	return 0
 }

 //go:linkname poll_runtime_pollWait internal..z2fpoll.runtime_pollWait
 func poll_runtime_pollWait(pd *pollDesc, mode int) int {
 	err := netpollcheckerr(pd, int32(mode))
 	if err != 0 {
 		return err
 	}
 	// As for now only Solaris, AIX and Hurd use level-triggered IO.
 	if GOOS == "solaris" || GOOS == "aix" || GOOS == "hurd" {
 		netpollarm(pd, mode)
 	}
 	for !netpollblock(pd, int32(mode), false) {
 		err = netpollcheckerr(pd, int32(mode))
 		if err != 0 {
 			return err
 		}
 		// Can happen if timeout has fired and unblocked us,
 		// but before we had a chance to run, timeout has been reset.
 		// Pretend it has not happened and retry.
 	}
 	return 0
 }

 //go:linkname poll_runtime_pollWaitCanceled internal..z2fpoll.runtime_pollWaitCanceled
 func poll_runtime_pollWaitCanceled(pd *pollDesc, mode int) {
 	// This function is used only on windows after a failed attempt to cancel
 	// a pending async IO operation. Wait for ioready, ignore closing or timeouts.
 	for !netpollblock(pd, int32(mode), true) {
 	}
 }

 //go:linkname poll_runtime_pollSetDeadline internal..z2fpoll.runtime_pollSetDeadline
 func poll_runtime_pollSetDeadline(pd *pollDesc, d int64, mode int) {
 	lock(&pd.lock)
 	if pd.closing {
 		unlock(&pd.lock)
 		return
 	}
 	rd0, wd0 := pd.rd, pd.wd
 	combo0 := rd0 > 0 && rd0 == wd0
 	if d > 0 {
 		d += nanotime()
 		if d <= 0 {
 			// If the user has a deadline in the future, but the delay calculation
 			// overflows, then set the deadline to the maximum possible value.
 			d = 1<<63 - 1
 		}
 	}
 	if mode == 'r' || mode == 'r'+'w' {
 		pd.rd = d
 	}
 	if mode == 'w' || mode == 'r'+'w' {
 		pd.wd = d
 	}
 	combo := pd.rd > 0 && pd.rd == pd.wd
 	rtf := netpollReadDeadline
 	if combo {
 		rtf = netpollDeadline
 	}
 	if pd.rt.f == nil {
 		if pd.rd > 0 {
 			pd.rt.f = rtf
 			pd.rt.when = pd.rd
 			// Copy current seq into the timer arg.
 			// Timer func will check the seq against current descriptor seq,
 			// if they differ the descriptor was reused or timers were reset.
 			pd.rt.arg = pd
 			pd.rt.seq = pd.rseq
 			addtimer(&pd.rt)
 		}
 	} else if pd.rd != rd0 || combo != combo0 {
 		pd.rseq++ // invalidate current timers
 		if pd.rd > 0 {
 			modtimer(&pd.rt, pd.rd, 0, rtf, pd, pd.rseq)
 		} else {
 			deltimer(&pd.rt)
 			pd.rt.f = nil
 		}
 	}
 	if pd.wt.f == nil {
 		if pd.wd > 0 && !combo {
 			pd.wt.f = netpollWriteDeadline
 			pd.wt.when = pd.wd
 			pd.wt.arg = pd
 			pd.wt.seq = pd.wseq
 			addtimer(&pd.wt)
 		}
 	} else if pd.wd != wd0 || combo != combo0 {
 		pd.wseq++ // invalidate current timers
 		if pd.wd > 0 && !combo {
 			modtimer(&pd.wt, pd.wd, 0, netpollWriteDeadline, pd, pd.wseq)
 		} else {
 			deltimer(&pd.wt)
 			pd.wt.f = nil
 		}
 	}
 	// If we set the new deadline in the past, unblock currently pending IO if any.
 	var rg, wg *g
 	if pd.rd < 0 || pd.wd < 0 {
 		atomic.StorepNoWB(noescape(unsafe.Pointer(&wg)), nil) // full memory barrier between stores to rd/wd and load of rg/wg in netpollunblock
 		if pd.rd < 0 {
 			rg = netpollunblock(pd, 'r', false)
 		}
 		if pd.wd < 0 {
 			wg = netpollunblock(pd, 'w', false)
 		}
 	}
 	unlock(&pd.lock)
 	if rg != nil {
 		netpollgoready(rg, 3)
 	}
 	if wg != nil {
 		netpollgoready(wg, 3)
 	}
 }

 //go:linkname poll_runtime_pollUnblock internal..z2fpoll.runtime_pollUnblock
 func poll_runtime_pollUnblock(pd *pollDesc) {
 	lock(&pd.lock)
 	if pd.closing {
 		throw("runtime: unblock on closing polldesc")
 	}
 	pd.closing = true
 	pd.rseq++
 	pd.wseq++
 	var rg, wg *g
 	atomic.StorepNoWB(noescape(unsafe.Pointer(&rg)), nil) // full memory barrier between store to closing and read of rg/wg in netpollunblock
 	rg = netpollunblock(pd, 'r', false)
 	wg = netpollunblock(pd, 'w', false)
 	if pd.rt.f != nil {
 		deltimer(&pd.rt)
 		pd.rt.f = nil
 	}
 	if pd.wt.f != nil {
 		deltimer(&pd.wt)
 		pd.wt.f = nil
 	}
 	unlock(&pd.lock)
 	if rg != nil {
 		netpollgoready(rg, 3)
 	}
 	if wg != nil {
 		netpollgoready(wg, 3)
 	}
 }

 // make pd ready, newly runnable goroutines (if any) are added to toRun.
 // May run during STW, so write barriers are not allowed.
 //go:nowritebarrier
 func netpollready(toRun *gList, pd *pollDesc, mode int32) {
 	var rg, wg *g
 	if mode == 'r' || mode == 'r'+'w' {
 		rg = netpollunblock(pd, 'r', true)
 	}
 	if mode == 'w' || mode == 'r'+'w' {
 		wg = netpollunblock(pd, 'w', true)
 	}
 	if rg != nil {
 		toRun.push(rg)
 	}
 	if wg != nil {
 		toRun.push(wg)
 	}
 }

 func netpollcheckerr(pd *pollDesc, mode int32) int {
 	if pd.closing {
 		return 1 // errClosing
 	}
 	if (mode == 'r' && pd.rd < 0) || (mode == 'w' && pd.wd < 0) {
 		return 2 // errTimeout
 	}
 	return 0
 }

 func netpollblockcommit(gp *g, gpp unsafe.Pointer) bool {
 	r := atomic.Casuintptr((*uintptr)(gpp), pdWait, uintptr(unsafe.Pointer(gp)))
 	if r {
 		// Bump the count of goroutines waiting for the poller.
 		// The scheduler uses this to decide whether to block
 		// waiting for the poller if there is nothing else to do.
 		atomic.Xadd(&netpollWaiters, 1)
 	}
 	return r
 }

 func netpollgoready(gp *g, traceskip int) {
 	atomic.Xadd(&netpollWaiters, -1)
 	goready(gp, traceskip+1)
 }

 // returns true if IO is ready, or false if timedout or closed
 // waitio - wait only for completed IO, ignore errors
 func netpollblock(pd *pollDesc, mode int32, waitio bool) bool {
 	gpp := &pd.rg
 	if mode == 'w' {
 		gpp = &pd.wg
 	}

 	// set the gpp semaphore to WAIT
 	for {
 		old := *gpp
 		if old == pdReady {
 			*gpp = 0
 			return true
 		}
 		if old != 0 {
 			throw("runtime: double wait")
 		}
 		if atomic.Casuintptr(gpp, 0, pdWait) {
 			break
 		}
 	}

 	// need to recheck error states after setting gpp to WAIT
 	// this is necessary because runtime_pollUnblock/runtime_pollSetDeadline/deadlineimpl
 	// do the opposite: store to closing/rd/wd, membarrier, load of rg/wg
 	if waitio || netpollcheckerr(pd, mode) == 0 {
 		gopark(netpollblockcommit, unsafe.Pointer(gpp), waitReasonIOWait, traceEvGoBlockNet, 5)
 	}
 	// be careful to not lose concurrent READY notification
 	old := atomic.Xchguintptr(gpp, 0)
 	if old > pdWait {
 		throw("runtime: corrupted polldesc")
 	}
 	return old == pdReady
 }

 func netpollunblock(pd *pollDesc, mode int32, ioready bool) *g {
 	gpp := &pd.rg
 	if mode == 'w' {
 		gpp = &pd.wg
 	}

 	for {
 		old := *gpp
 		if old == pdReady {
 			return nil
 		}
 		if old == 0 && !ioready {
 			// Only set READY for ioready. runtime_pollWait
 			// will check for timeout/cancel before waiting.
 			return nil
 		}
 		var new uintptr
 		if ioready {
 			new = pdReady
 		}
 		if atomic.Casuintptr(gpp, old, new) {
 			if old == pdReady || old == pdWait {
 				old = 0
 			}
 			return (*g)(unsafe.Pointer(old))
 		}
 	}
 }

 func netpolldeadlineimpl(pd *pollDesc, seq uintptr, read, write bool) {
 	lock(&pd.lock)
 	// Seq arg is seq when the timer was set.
 	// If it's stale, ignore the timer event.
 	currentSeq := pd.rseq
 	if !read {
 		currentSeq = pd.wseq
 	}
 	if seq != currentSeq {
 		// The descriptor was reused or timers were reset.
 		unlock(&pd.lock)
 		return
 	}
 	var rg *g
 	if read {
 		if pd.rd <= 0 || pd.rt.f == nil {
 			throw("runtime: inconsistent read deadline")
 		}
 		pd.rd = -1
 		atomic.StorepNoWB(unsafe.Pointer(&pd.rt.f), nil) // full memory barrier between store to rd and load of rg in netpollunblock
 		rg = netpollunblock(pd, 'r', false)
 	}
 	var wg *g
 	if write {
 		if pd.wd <= 0 || pd.wt.f == nil && !read {
 			throw("runtime: inconsistent write deadline")
 		}
 		pd.wd = -1
 		atomic.StorepNoWB(unsafe.Pointer(&pd.wt.f), nil) // full memory barrier between store to wd and load of wg in netpollunblock
 		wg = netpollunblock(pd, 'w', false)
 	}
 	unlock(&pd.lock)
 	if rg != nil {
 		netpollgoready(rg, 0)
 	}
 	if wg != nil {
 		netpollgoready(wg, 0)
 	}
 }

 func netpollDeadline(arg interface{}, seq uintptr) {
 	netpolldeadlineimpl(arg.(*pollDesc), seq, true, true)
 }

 func netpollReadDeadline(arg interface{}, seq uintptr) {
 	netpolldeadlineimpl(arg.(*pollDesc), seq, true, false)
 }

 func netpollWriteDeadline(arg interface{}, seq uintptr) {
 	netpolldeadlineimpl(arg.(*pollDesc), seq, false, true)
 }

 func (c *pollCache) alloc() *pollDesc {
 	lock(&c.lock)
 	if c.first == nil {
 		const pdSize = unsafe.Sizeof(pollDesc{})
 		n := pollBlockSize / pdSize
 		if n == 0 {
 			n = 1
 		}
 		// Must be in non-GC memory because can be referenced
 		// only from epoll/kqueue internals.
 		mem := persistentalloc(n*pdSize, 0, &memstats.other_sys)
 		for i := uintptr(0); i < n; i++ {
 			pd := (*pollDesc)(add(mem, i*pdSize))
 			pd.link = c.first
 			c.first = pd
 		}
 	}
 	pd := c.first
 	c.first = pd.link
 	unlock(&c.lock)
 	return pd
 }
	// Copyright 2013 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	// +build aix darwin dragonfly freebsd hurd js,wasm linux nacl netbsd openbsd solaris windows

	package runtime

	import (
	"runtime/internal/atomic"
	"unsafe"
	)

	// Export temporarily for gccgo's C code to call:
	//go:linkname netpoll runtime.netpoll

	// Integrated network poller (platform-independent part).
	// A particular implementation (epoll/kqueue) must define the following functions:
	// func netpollinit() // to initialize the poller
	// func netpollopen(fd uintptr, pd *pollDesc) int32 // to arm edge-triggered notifications
	// and associate fd with pd.
	// An implementation must call the following function to denote that the pd is ready.
	// func netpollready(gpp *g, pd pollDesc, mode int32)

	// pollDesc contains 2 binary semaphores, rg and wg, to park reader and writer
	// goroutines respectively. The semaphore can be in the following states:
	// pdReady - io readiness notification is pending;
	// a goroutine consumes the notification by changing the state to nil.
	// pdWait - a goroutine prepares to park on the semaphore, but not yet parked;
	// the goroutine commits to park by changing the state to G pointer,
	// or, alternatively, concurrent io notification changes the state to READY,
	// or, alternatively, concurrent timeout/close changes the state to nil.
	// G pointer - the goroutine is blocked on the semaphore;
	// io notification or timeout/close changes the state to READY or nil respectively
	// and unparks the goroutine.
	// nil - nothing of the above.
	const (
	pdReady uintptr = 1
	pdWait uintptr = 2
	)

	const pollBlockSize = 4 * 1024

	// Network poller descriptor.
	//
	// No heap pointers.
	//
	//go:notinheap
	type pollDesc struct {
	link *pollDesc // in pollcache, protected by pollcache.lock

	// The lock protects pollOpen, pollSetDeadline, pollUnblock and deadlineimpl operations.
	// This fully covers seq, rt and wt variables. fd is constant throughout the PollDesc lifetime.
	// pollReset, pollWait, pollWaitCanceled and runtime·netpollready (IO readiness notification)
	// proceed w/o taking the lock. So closing, rg, rd, wg and wd are manipulated
	// in a lock-free way by all operations.
	// NOTE(dvyukov): the following code uses uintptr to store *g (rg/wg),
	// that will blow up when GC starts moving objects.
	lock mutex // protects the following fields
	fd uintptr
	closing bool
	user uint32 // user settable cookie
	rseq uintptr // protects from stale read timers
	rg uintptr // pdReady, pdWait, G waiting for read or nil
	rt timer // read deadline timer (set if rt.f != nil)
	rd int64 // read deadline
	wseq uintptr // protects from stale write timers
	wg uintptr // pdReady, pdWait, G waiting for write or nil
	wt timer // write deadline timer
	wd int64 // write deadline
	}

	type pollCache struct {
	lock mutex
	first *pollDesc
	// PollDesc objects must be type-stable,
	// because we can get ready notification from epoll/kqueue
	// after the descriptor is closed/reused.
	// Stale notifications are detected using seq variable,
	// seq is incremented when deadlines are changed or descriptor is reused.
	}

	var (
	netpollInited uint32
	pollcache pollCache
	netpollWaiters uint32
	)

	//go:linkname poll_runtime_pollServerInit internal..z2fpoll.runtime_pollServerInit
	func poll_runtime_pollServerInit() {
	netpollinit()
	atomic.Store(&netpollInited, 1)
	}

	func netpollinited() bool {
	return atomic.Load(&netpollInited) != 0
	}

	//go:linkname poll_runtime_isPollServerDescriptor internal..z2fpoll.runtime_isPollServerDescriptor

	// poll_runtime_isPollServerDescriptor reports whether fd is a
	// descriptor being used by netpoll.
	func poll_runtime_isPollServerDescriptor(fd uintptr) bool {
	fds := netpolldescriptor()
	if GOOS != "aix" && GOOS != "hurd" {
	return fd == fds
	} else {
	// AIX have a pipe in its netpoll implementation.
	// Therefore, two fd are returned by netpolldescriptor using a mask.
	return fd == fds&0xFFFF \|\| fd == (fds>>16)&0xFFFF
	}
	}

	//go:linkname poll_runtime_pollOpen internal..z2fpoll.runtime_pollOpen
	func poll_runtime_pollOpen(fd uintptr) (*pollDesc, int) {
	pd := pollcache.alloc()
	lock(&pd.lock)
	if pd.wg != 0 && pd.wg != pdReady {
	throw("runtime: blocked write on free polldesc")
	}
	if pd.rg != 0 && pd.rg != pdReady {
	throw("runtime: blocked read on free polldesc")
	}
	pd.fd = fd
	pd.closing = false
	pd.rseq++
	pd.rg = 0
	pd.rd = 0
	pd.wseq++
	pd.wg = 0
	pd.wd = 0
	unlock(&pd.lock)

	var errno int32
	errno = netpollopen(fd, pd)
	return pd, int(errno)
	}

	//go:linkname poll_runtime_pollClose internal..z2fpoll.runtime_pollClose
	func poll_runtime_pollClose(pd *pollDesc) {
	if !pd.closing {
	throw("runtime: close polldesc w/o unblock")
	}
	if pd.wg != 0 && pd.wg != pdReady {
	throw("runtime: blocked write on closing polldesc")
	}
	if pd.rg != 0 && pd.rg != pdReady {
	throw("runtime: blocked read on closing polldesc")
	}
	netpollclose(pd.fd)
	pollcache.free(pd)
	}

	func (c pollCache) free(pd pollDesc) {
	lock(&c.lock)
	pd.link = c.first
	c.first = pd
	unlock(&c.lock)
	}

	//go:linkname poll_runtime_pollReset internal..z2fpoll.runtime_pollReset
	func poll_runtime_pollReset(pd *pollDesc, mode int) int {
	err := netpollcheckerr(pd, int32(mode))
	if err != 0 {
	return err
	}
	if mode == 'r' {
	pd.rg = 0
	} else if mode == 'w' {
	pd.wg = 0
	}
	return 0
	}

	//go:linkname poll_runtime_pollWait internal..z2fpoll.runtime_pollWait
	func poll_runtime_pollWait(pd *pollDesc, mode int) int {
	err := netpollcheckerr(pd, int32(mode))
	if err != 0 {
	return err
	}
	// As for now only Solaris, AIX and Hurd use level-triggered IO.
	if GOOS == "solaris" \|\| GOOS == "aix" \|\| GOOS == "hurd" {
	netpollarm(pd, mode)
	}
	for !netpollblock(pd, int32(mode), false) {
	err = netpollcheckerr(pd, int32(mode))
	if err != 0 {
	return err
	}
	// Can happen if timeout has fired and unblocked us,
	// but before we had a chance to run, timeout has been reset.
	// Pretend it has not happened and retry.
	}
	return 0
	}

	//go:linkname poll_runtime_pollWaitCanceled internal..z2fpoll.runtime_pollWaitCanceled
	func poll_runtime_pollWaitCanceled(pd *pollDesc, mode int) {
	// This function is used only on windows after a failed attempt to cancel
	// a pending async IO operation. Wait for ioready, ignore closing or timeouts.
	for !netpollblock(pd, int32(mode), true) {
	}
	}

	//go:linkname poll_runtime_pollSetDeadline internal..z2fpoll.runtime_pollSetDeadline
	func poll_runtime_pollSetDeadline(pd *pollDesc, d int64, mode int) {
	lock(&pd.lock)
	if pd.closing {
	unlock(&pd.lock)
	return
	}
	rd0, wd0 := pd.rd, pd.wd
	combo0 := rd0 > 0 && rd0 == wd0
	if d > 0 {
	d += nanotime()
	if d <= 0 {
	// If the user has a deadline in the future, but the delay calculation
	// overflows, then set the deadline to the maximum possible value.
	d = 1<<63 - 1
	}
	}
	if mode == 'r' \|\| mode == 'r'+'w' {
	pd.rd = d
	}
	if mode == 'w' \|\| mode == 'r'+'w' {
	pd.wd = d
	}
	combo := pd.rd > 0 && pd.rd == pd.wd
	rtf := netpollReadDeadline
	if combo {
	rtf = netpollDeadline
	}
	if pd.rt.f == nil {
	if pd.rd > 0 {
	pd.rt.f = rtf
	pd.rt.when = pd.rd
	// Copy current seq into the timer arg.
	// Timer func will check the seq against current descriptor seq,
	// if they differ the descriptor was reused or timers were reset.
	pd.rt.arg = pd
	pd.rt.seq = pd.rseq
	addtimer(&pd.rt)
	}
	} else if pd.rd != rd0 \|\| combo != combo0 {
	pd.rseq++ // invalidate current timers
	if pd.rd > 0 {
	modtimer(&pd.rt, pd.rd, 0, rtf, pd, pd.rseq)
	} else {
	deltimer(&pd.rt)
	pd.rt.f = nil
	}
	}
	if pd.wt.f == nil {
	if pd.wd > 0 && !combo {
	pd.wt.f = netpollWriteDeadline
	pd.wt.when = pd.wd
	pd.wt.arg = pd
	pd.wt.seq = pd.wseq
	addtimer(&pd.wt)
	}
	} else if pd.wd != wd0 \|\| combo != combo0 {
	pd.wseq++ // invalidate current timers
	if pd.wd > 0 && !combo {
	modtimer(&pd.wt, pd.wd, 0, netpollWriteDeadline, pd, pd.wseq)
	} else {
	deltimer(&pd.wt)
	pd.wt.f = nil
	}
	}
	// If we set the new deadline in the past, unblock currently pending IO if any.
	var rg, wg *g
	if pd.rd < 0 \|\| pd.wd < 0 {
	atomic.StorepNoWB(noescape(unsafe.Pointer(&wg)), nil) // full memory barrier between stores to rd/wd and load of rg/wg in netpollunblock
	if pd.rd < 0 {
	rg = netpollunblock(pd, 'r', false)
	}
	if pd.wd < 0 {
	wg = netpollunblock(pd, 'w', false)
	}
	}
	unlock(&pd.lock)
	if rg != nil {
	netpollgoready(rg, 3)
	}
	if wg != nil {
	netpollgoready(wg, 3)
	}
	}

	//go:linkname poll_runtime_pollUnblock internal..z2fpoll.runtime_pollUnblock
	func poll_runtime_pollUnblock(pd *pollDesc) {
	lock(&pd.lock)
	if pd.closing {
	throw("runtime: unblock on closing polldesc")
	}
	pd.closing = true
	pd.rseq++
	pd.wseq++
	var rg, wg *g
	atomic.StorepNoWB(noescape(unsafe.Pointer(&rg)), nil) // full memory barrier between store to closing and read of rg/wg in netpollunblock
	rg = netpollunblock(pd, 'r', false)
	wg = netpollunblock(pd, 'w', false)
	if pd.rt.f != nil {
	deltimer(&pd.rt)
	pd.rt.f = nil
	}
	if pd.wt.f != nil {
	deltimer(&pd.wt)
	pd.wt.f = nil
	}
	unlock(&pd.lock)
	if rg != nil {
	netpollgoready(rg, 3)
	}
	if wg != nil {
	netpollgoready(wg, 3)
	}
	}

	// make pd ready, newly runnable goroutines (if any) are added to toRun.
	// May run during STW, so write barriers are not allowed.
	//go:nowritebarrier
	func netpollready(toRun gList, pd pollDesc, mode int32) {
	var rg, wg *g
	if mode == 'r' \|\| mode == 'r'+'w' {
	rg = netpollunblock(pd, 'r', true)
	}
	if mode == 'w' \|\| mode == 'r'+'w' {
	wg = netpollunblock(pd, 'w', true)
	}
	if rg != nil {
	toRun.push(rg)
	}
	if wg != nil {
	toRun.push(wg)
	}
	}

	func netpollcheckerr(pd *pollDesc, mode int32) int {
	if pd.closing {
	return 1 // errClosing
	}
	if (mode == 'r' && pd.rd < 0) \|\| (mode == 'w' && pd.wd < 0) {
	return 2 // errTimeout
	}
	return 0
	}

	func netpollblockcommit(gp *g, gpp unsafe.Pointer) bool {
	r := atomic.Casuintptr((*uintptr)(gpp), pdWait, uintptr(unsafe.Pointer(gp)))
	if r {
	// Bump the count of goroutines waiting for the poller.
	// The scheduler uses this to decide whether to block
	// waiting for the poller if there is nothing else to do.
	atomic.Xadd(&netpollWaiters, 1)
	}
	return r
	}

	func netpollgoready(gp *g, traceskip int) {
	atomic.Xadd(&netpollWaiters, -1)
	goready(gp, traceskip+1)
	}

	// returns true if IO is ready, or false if timedout or closed
	// waitio - wait only for completed IO, ignore errors
	func netpollblock(pd *pollDesc, mode int32, waitio bool) bool {
	gpp := &pd.rg
	if mode == 'w' {
	gpp = &pd.wg
	}

	// set the gpp semaphore to WAIT
	for {
	old := *gpp
	if old == pdReady {
	*gpp = 0
	return true
	}
	if old != 0 {
	throw("runtime: double wait")
	}
	if atomic.Casuintptr(gpp, 0, pdWait) {
	break
	}
	}

	// need to recheck error states after setting gpp to WAIT
	// this is necessary because runtime_pollUnblock/runtime_pollSetDeadline/deadlineimpl
	// do the opposite: store to closing/rd/wd, membarrier, load of rg/wg
	if waitio \|\| netpollcheckerr(pd, mode) == 0 {
	gopark(netpollblockcommit, unsafe.Pointer(gpp), waitReasonIOWait, traceEvGoBlockNet, 5)
	}
	// be careful to not lose concurrent READY notification
	old := atomic.Xchguintptr(gpp, 0)
	if old > pdWait {
	throw("runtime: corrupted polldesc")
	}
	return old == pdReady
	}

	func netpollunblock(pd pollDesc, mode int32, ioready bool) g {
	gpp := &pd.rg
	if mode == 'w' {
	gpp = &pd.wg
	}

	for {
	old := *gpp
	if old == pdReady {
	return nil
	}
	if old == 0 && !ioready {
	// Only set READY for ioready. runtime_pollWait
	// will check for timeout/cancel before waiting.
	return nil
	}
	var new uintptr
	if ioready {
	new = pdReady
	}
	if atomic.Casuintptr(gpp, old, new) {
	if old == pdReady \|\| old == pdWait {
	old = 0
	}
	return (*g)(unsafe.Pointer(old))
	}
	}
	}

	func netpolldeadlineimpl(pd *pollDesc, seq uintptr, read, write bool) {
	lock(&pd.lock)
	// Seq arg is seq when the timer was set.
	// If it's stale, ignore the timer event.
	currentSeq := pd.rseq
	if !read {
	currentSeq = pd.wseq
	}
	if seq != currentSeq {
	// The descriptor was reused or timers were reset.
	unlock(&pd.lock)
	return
	}
	var rg *g
	if read {
	if pd.rd <= 0 \|\| pd.rt.f == nil {
	throw("runtime: inconsistent read deadline")
	}
	pd.rd = -1
	atomic.StorepNoWB(unsafe.Pointer(&pd.rt.f), nil) // full memory barrier between store to rd and load of rg in netpollunblock
	rg = netpollunblock(pd, 'r', false)
	}
	var wg *g
	if write {
	if pd.wd <= 0 \|\| pd.wt.f == nil && !read {
	throw("runtime: inconsistent write deadline")
	}
	pd.wd = -1
	atomic.StorepNoWB(unsafe.Pointer(&pd.wt.f), nil) // full memory barrier between store to wd and load of wg in netpollunblock
	wg = netpollunblock(pd, 'w', false)
	}
	unlock(&pd.lock)
	if rg != nil {
	netpollgoready(rg, 0)
	}
	if wg != nil {
	netpollgoready(wg, 0)
	}
	}

	func netpollDeadline(arg interface{}, seq uintptr) {
	netpolldeadlineimpl(arg.(*pollDesc), seq, true, true)
	}

	func netpollReadDeadline(arg interface{}, seq uintptr) {
	netpolldeadlineimpl(arg.(*pollDesc), seq, true, false)
	}

	func netpollWriteDeadline(arg interface{}, seq uintptr) {
	netpolldeadlineimpl(arg.(*pollDesc), seq, false, true)
	}

	func (c pollCache) alloc() pollDesc {
	lock(&c.lock)
	if c.first == nil {
	const pdSize = unsafe.Sizeof(pollDesc{})
	n := pollBlockSize / pdSize
	if n == 0 {
	n = 1
	}
	// Must be in non-GC memory because can be referenced
	// only from epoll/kqueue internals.
	mem := persistentalloc(n*pdSize, 0, &memstats.other_sys)
	for i := uintptr(0); i < n; i++ {
	pd := (pollDesc)(add(mem, ipdSize))
	pd.link = c.first
	c.first = pd
	}
	}
	pd := c.first
	c.first = pd.link
	unlock(&c.lock)
	return pd
	}