src/runtime/netpoll_solaris.c - go - Git at Google

 // Copyright 2014 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.

 #include "runtime.h"
 #include "arch_GOARCH.h"
 #include "defs_GOOS_GOARCH.h"
 #include "os_GOOS.h"

 // Solaris runtime-integrated network poller.
 //
 // Solaris uses event ports for scalable network I/O. Event
 // ports are level-triggered, unlike epoll and kqueue which
 // can be configured in both level-triggered and edge-triggered
 // mode. Level triggering means we have to keep track of a few things
 // ourselves. After we receive an event for a file descriptor,
 // it's our responsibility to ask again to be notified for future
 // events for that descriptor. When doing this we must keep track of
 // what kind of events the goroutines are currently interested in,
 // for example a fd may be open both for reading and writing.
 //
 // A description of the high level operation of this code
 // follows. Networking code will get a file descriptor by some means
 // and will register it with the netpolling mechanism by a code path
 // that eventually calls runtime·netpollopen. runtime·netpollopen
 // calls port_associate with an empty event set. That means that we
 // will not receive any events at this point. The association needs
 // to be done at this early point because we need to process the I/O
 // readiness notification at some point in the future. If I/O becomes
 // ready when nobody is listening, when we finally care about it,
 // nobody will tell us anymore.
 //
 // Beside calling runtime·netpollopen, the networking code paths
 // will call runtime·netpollarm each time goroutines are interested
 // in doing network I/O. Because now we know what kind of I/O we
 // are interested in (reading/writting), we can call port_associate
 // passing the correct type of event set (POLLIN/POLLOUT). As we made
 // sure to have already associated the file descriptor with the port,
 // when we now call port_associate, we will unblock the main poller
 // loop (in runtime·netpoll) right away if the socket is actually
 // ready for I/O.
 //
 // The main poller loop runs in its own thread waiting for events
 // using port_getn. When an event happens, it will tell the scheduler
 // about it using runtime·netpollready. Besides doing this, it must
 // also re-associate the events that were not part of this current
 // notification with the file descriptor. Failing to do this would
 // mean each notification will prevent concurrent code using the
 // same file descriptor in parallel.
 //
 // The logic dealing with re-associations is encapsulated in
 // runtime·netpollupdate. This function takes care to associate the
 // descriptor only with the subset of events that were previously
 // part of the association, except the one that just happened. We
 // can't re-associate with that right away, because event ports
 // are level triggered so it would cause a busy loop. Instead, that
 // association is effected only by the runtime·netpollarm code path,
 // when Go code actually asks for I/O.
 //
 // The open and arming mechanisms are serialized using the lock
 // inside PollDesc. This is required because the netpoll loop runs
 // asynchonously in respect to other Go code and by the time we get
 // to call port_associate to update the association in the loop, the
 // file descriptor might have been closed and reopened already. The
 // lock allows runtime·netpollupdate to be called synchronously from
 // the loop thread while preventing other threads operating to the
 // same PollDesc, so once we unblock in the main loop, until we loop
 // again we know for sure we are always talking about the same file
 // descriptor and can safely access the data we want (the event set).

 #pragma dynimport libc·fcntl fcntl "libc.so"
 #pragma dynimport libc·port_create port_create "libc.so"
 #pragma dynimport libc·port_associate port_associate "libc.so"
 #pragma dynimport libc·port_dissociate port_dissociate "libc.so"
 #pragma dynimport libc·port_getn port_getn "libc.so"
 extern uintptr libc·fcntl;
 extern uintptr libc·port_create;
 extern uintptr libc·port_associate;
 extern uintptr libc·port_dissociate;
 extern uintptr libc·port_getn;

 #define errno (*g->m->perrno)

 int32
 runtime·fcntl(int32 fd, int32 cmd, uintptr arg)
 {
 	return runtime·sysvicall3(libc·fcntl, (uintptr)fd, (uintptr)cmd, (uintptr)arg);
 }

 int32
 runtime·port_create(void)
 {
 	return runtime·sysvicall0(libc·port_create);
 }

 int32
 runtime·port_associate(int32 port, int32 source, uintptr object, int32 events, uintptr user)
 {
 	return runtime·sysvicall5(libc·port_associate, (uintptr)port, (uintptr)source, object, (uintptr)events, user);
 }

 int32
 runtime·port_dissociate(int32 port, int32 source, uintptr object)
 {
 	return runtime·sysvicall3(libc·port_dissociate, (uintptr)port, (uintptr)source, object);
 }

 int32
 runtime·port_getn(int32 port, PortEvent *evs, uint32 max, uint32 *nget, Timespec *timeout)
 {
 	return runtime·sysvicall5(libc·port_getn, (uintptr)port, (uintptr)evs, (uintptr)max, (uintptr)nget, (uintptr)timeout);
 }

 static int32 portfd = -1;

 void
 runtime·netpollinit(void)
 {
 	if((portfd = runtime·port_create()) >= 0) {
 		runtime·fcntl(portfd, F_SETFD, FD_CLOEXEC);
 		return;
 	}

 	runtime·printf("netpollinit: failed to create port (%d)\n", errno);
 	runtime·throw("netpollinit: failed to create port");
 }

 int32
 runtime·netpollopen(uintptr fd, PollDesc *pd)
 {
 	int32 r;

 	runtime·netpolllock(pd);
 	// We don't register for any specific type of events yet, that's
 	// netpollarm's job. We merely ensure we call port_associate before
 	// asynchonous connect/accept completes, so when we actually want
 	// to do any I/O, the call to port_associate (from netpollarm,
 	// with the interested event set) will unblock port_getn right away
 	// because of the I/O readiness notification.
 	*runtime·netpolluser(pd) = 0;
 	r = runtime·port_associate(portfd, PORT_SOURCE_FD, fd, 0, (uintptr)pd);
 	runtime·netpollunlock(pd);
 	return r;
 }

 int32
 runtime·netpollclose(uintptr fd)
 {
 	return runtime·port_dissociate(portfd, PORT_SOURCE_FD, fd);
 }

 // Updates the association with a new set of interested events. After
 // this call, port_getn will return one and only one event for that
 // particular descriptor, so this function needs to be called again.
 void
 runtime·netpollupdate(PollDesc* pd, uint32 set, uint32 clear)
 {
 	uint32 *ep, old, events;
 	uintptr fd = runtime·netpollfd(pd);
 	ep = (uint32*)runtime·netpolluser(pd);

 	if(runtime·netpollclosing(pd))
 		return;

 	old = *ep;
 	events = (old & ~clear) | set;
 	if(old == events)
 		return;

 	if(events && runtime·port_associate(portfd, PORT_SOURCE_FD, fd, events, (uintptr)pd) != 0) {
 		runtime·printf("netpollupdate: failed to associate (%d)\n", errno);
 		runtime·throw("netpollupdate: failed to associate");
 	}
 	*ep = events;
 }

 // subscribe the fd to the port such that port_getn will return one event.
 void
 runtime·netpollarm(PollDesc* pd, int32 mode)
 {
 	runtime·netpolllock(pd);
 	switch(mode) {
 	case 'r':
 		runtime·netpollupdate(pd, POLLIN, 0);
 		break;
 	case 'w':
 		runtime·netpollupdate(pd, POLLOUT, 0);
 		break;
 	default:
 		runtime·throw("netpollarm: bad mode");
 	}
 	runtime·netpollunlock(pd);
 }

 // polls for ready network connections
 // returns list of goroutines that become runnable
 G*
 runtime·netpoll(bool block)
 {
 	static int32 lasterr;
 	PortEvent events[128], *ev;
 	PollDesc *pd;
 	int32 i, mode, clear;
 	uint32 n;
 	Timespec *wait = nil, zero;
 	G *gp;

 	if(portfd == -1)
 		return (nil);

 	if(!block) {
 		zero.tv_sec = 0;
 		zero.tv_nsec = 0;
 		wait = &zero;
 	}

 retry:
 	n = 1;
 	if(runtime·port_getn(portfd, events, nelem(events), &n, wait) < 0) {
 		if(errno != EINTR && errno != lasterr) {
 			lasterr = errno;
 			runtime·printf("runtime: port_getn on fd %d failed with %d\n", portfd, errno);
 		}
 		goto retry;
 	}

 	gp = nil;
 	for(i = 0; i < n; i++) {
 		ev = &events[i];

 		if(ev->portev_events == 0)
 			continue;
 		pd = (PollDesc *)ev->portev_user;

 		mode = 0;
 		clear = 0;
 		if(ev->portev_events & (POLLIN|POLLHUP|POLLERR)) {
 			mode += 'r';
 			clear |= POLLIN;
 		}
 		if(ev->portev_events & (POLLOUT|POLLHUP|POLLERR)) {
 			mode += 'w';
 			clear |= POLLOUT;
 		}
 		// To effect edge-triggered events, we need to be sure to
 		// update our association with whatever events were not
 		// set with the event. For example if we are registered
 		// for POLLIN|POLLOUT, and we get POLLIN, besides waking
 		// the goroutine interested in POLLIN we have to not forget
 		// about the one interested in POLLOUT.
 		if(clear != 0) {
 			runtime·netpolllock(pd);
 			runtime·netpollupdate(pd, 0, clear);
 			runtime·netpollunlock(pd);
 		}

 		if(mode)
 			runtime·netpollready(&gp, pd, mode);
 	}

 	if(block && gp == nil)
 		goto retry;
 	return gp;
 }
	// Copyright 2014 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.

	#include "runtime.h"
	#include "arch_GOARCH.h"
	#include "defs_GOOS_GOARCH.h"
	#include "os_GOOS.h"

	// Solaris runtime-integrated network poller.
	//
	// Solaris uses event ports for scalable network I/O. Event
	// ports are level-triggered, unlike epoll and kqueue which
	// can be configured in both level-triggered and edge-triggered
	// mode. Level triggering means we have to keep track of a few things
	// ourselves. After we receive an event for a file descriptor,
	// it's our responsibility to ask again to be notified for future
	// events for that descriptor. When doing this we must keep track of
	// what kind of events the goroutines are currently interested in,
	// for example a fd may be open both for reading and writing.
	//
	// A description of the high level operation of this code
	// follows. Networking code will get a file descriptor by some means
	// and will register it with the netpolling mechanism by a code path
	// that eventually calls runtime·netpollopen. runtime·netpollopen
	// calls port_associate with an empty event set. That means that we
	// will not receive any events at this point. The association needs
	// to be done at this early point because we need to process the I/O
	// readiness notification at some point in the future. If I/O becomes
	// ready when nobody is listening, when we finally care about it,
	// nobody will tell us anymore.
	//
	// Beside calling runtime·netpollopen, the networking code paths
	// will call runtime·netpollarm each time goroutines are interested
	// in doing network I/O. Because now we know what kind of I/O we
	// are interested in (reading/writting), we can call port_associate
	// passing the correct type of event set (POLLIN/POLLOUT). As we made
	// sure to have already associated the file descriptor with the port,
	// when we now call port_associate, we will unblock the main poller
	// loop (in runtime·netpoll) right away if the socket is actually
	// ready for I/O.
	//
	// The main poller loop runs in its own thread waiting for events
	// using port_getn. When an event happens, it will tell the scheduler
	// about it using runtime·netpollready. Besides doing this, it must
	// also re-associate the events that were not part of this current
	// notification with the file descriptor. Failing to do this would
	// mean each notification will prevent concurrent code using the
	// same file descriptor in parallel.
	//
	// The logic dealing with re-associations is encapsulated in
	// runtime·netpollupdate. This function takes care to associate the
	// descriptor only with the subset of events that were previously
	// part of the association, except the one that just happened. We
	// can't re-associate with that right away, because event ports
	// are level triggered so it would cause a busy loop. Instead, that
	// association is effected only by the runtime·netpollarm code path,
	// when Go code actually asks for I/O.
	//
	// The open and arming mechanisms are serialized using the lock
	// inside PollDesc. This is required because the netpoll loop runs
	// asynchonously in respect to other Go code and by the time we get
	// to call port_associate to update the association in the loop, the
	// file descriptor might have been closed and reopened already. The
	// lock allows runtime·netpollupdate to be called synchronously from
	// the loop thread while preventing other threads operating to the
	// same PollDesc, so once we unblock in the main loop, until we loop
	// again we know for sure we are always talking about the same file
	// descriptor and can safely access the data we want (the event set).

	#pragma dynimport libc·fcntl fcntl "libc.so"
	#pragma dynimport libc·port_create port_create "libc.so"
	#pragma dynimport libc·port_associate port_associate "libc.so"
	#pragma dynimport libc·port_dissociate port_dissociate "libc.so"
	#pragma dynimport libc·port_getn port_getn "libc.so"
	extern uintptr libc·fcntl;
	extern uintptr libc·port_create;
	extern uintptr libc·port_associate;
	extern uintptr libc·port_dissociate;
	extern uintptr libc·port_getn;

	#define errno (*g->m->perrno)

	int32
	runtime·fcntl(int32 fd, int32 cmd, uintptr arg)
	{
	return runtime·sysvicall3(libc·fcntl, (uintptr)fd, (uintptr)cmd, (uintptr)arg);
	}

	int32
	runtime·port_create(void)
	{
	return runtime·sysvicall0(libc·port_create);
	}

	int32
	runtime·port_associate(int32 port, int32 source, uintptr object, int32 events, uintptr user)
	{
	return runtime·sysvicall5(libc·port_associate, (uintptr)port, (uintptr)source, object, (uintptr)events, user);
	}

	int32
	runtime·port_dissociate(int32 port, int32 source, uintptr object)
	{
	return runtime·sysvicall3(libc·port_dissociate, (uintptr)port, (uintptr)source, object);
	}

	int32
	runtime·port_getn(int32 port, PortEvent evs, uint32 max, uint32 nget, Timespec *timeout)
	{
	return runtime·sysvicall5(libc·port_getn, (uintptr)port, (uintptr)evs, (uintptr)max, (uintptr)nget, (uintptr)timeout);
	}

	static int32 portfd = -1;

	void
	runtime·netpollinit(void)
	{
	if((portfd = runtime·port_create()) >= 0) {
	runtime·fcntl(portfd, F_SETFD, FD_CLOEXEC);
	return;
	}

	runtime·printf("netpollinit: failed to create port (%d)\n", errno);
	runtime·throw("netpollinit: failed to create port");
	}

	int32
	runtime·netpollopen(uintptr fd, PollDesc *pd)
	{
	int32 r;

	runtime·netpolllock(pd);
	// We don't register for any specific type of events yet, that's
	// netpollarm's job. We merely ensure we call port_associate before
	// asynchonous connect/accept completes, so when we actually want
	// to do any I/O, the call to port_associate (from netpollarm,
	// with the interested event set) will unblock port_getn right away
	// because of the I/O readiness notification.
	*runtime·netpolluser(pd) = 0;
	r = runtime·port_associate(portfd, PORT_SOURCE_FD, fd, 0, (uintptr)pd);
	runtime·netpollunlock(pd);
	return r;
	}

	int32
	runtime·netpollclose(uintptr fd)
	{
	return runtime·port_dissociate(portfd, PORT_SOURCE_FD, fd);
	}

	// Updates the association with a new set of interested events. After
	// this call, port_getn will return one and only one event for that
	// particular descriptor, so this function needs to be called again.
	void
	runtime·netpollupdate(PollDesc* pd, uint32 set, uint32 clear)
	{
	uint32 *ep, old, events;
	uintptr fd = runtime·netpollfd(pd);
	ep = (uint32*)runtime·netpolluser(pd);

	if(runtime·netpollclosing(pd))
	return;

	old = *ep;
	events = (old & ~clear) \| set;
	if(old == events)
	return;

	if(events && runtime·port_associate(portfd, PORT_SOURCE_FD, fd, events, (uintptr)pd) != 0) {
	runtime·printf("netpollupdate: failed to associate (%d)\n", errno);
	runtime·throw("netpollupdate: failed to associate");
	}
	*ep = events;
	}

	// subscribe the fd to the port such that port_getn will return one event.
	void
	runtime·netpollarm(PollDesc* pd, int32 mode)
	{
	runtime·netpolllock(pd);
	switch(mode) {
	case 'r':
	runtime·netpollupdate(pd, POLLIN, 0);
	break;
	case 'w':
	runtime·netpollupdate(pd, POLLOUT, 0);
	break;
	default:
	runtime·throw("netpollarm: bad mode");
	}
	runtime·netpollunlock(pd);
	}

	// polls for ready network connections
	// returns list of goroutines that become runnable
	G*
	runtime·netpoll(bool block)
	{
	static int32 lasterr;
	PortEvent events[128], *ev;
	PollDesc *pd;
	int32 i, mode, clear;
	uint32 n;
	Timespec *wait = nil, zero;
	G *gp;

	if(portfd == -1)
	return (nil);

	if(!block) {
	zero.tv_sec = 0;
	zero.tv_nsec = 0;
	wait = &zero;
	}

	retry:
	n = 1;
	if(runtime·port_getn(portfd, events, nelem(events), &n, wait) < 0) {
	if(errno != EINTR && errno != lasterr) {
	lasterr = errno;
	runtime·printf("runtime: port_getn on fd %d failed with %d\n", portfd, errno);
	}
	goto retry;
	}

	gp = nil;
	for(i = 0; i < n; i++) {
	ev = &events[i];

	if(ev->portev_events == 0)
	continue;
	pd = (PollDesc *)ev->portev_user;

	mode = 0;
	clear = 0;
	if(ev->portev_events & (POLLIN\|POLLHUP\|POLLERR)) {
	mode += 'r';
	clear \|= POLLIN;
	}
	if(ev->portev_events & (POLLOUT\|POLLHUP\|POLLERR)) {
	mode += 'w';
	clear \|= POLLOUT;
	}
	// To effect edge-triggered events, we need to be sure to
	// update our association with whatever events were not
	// set with the event. For example if we are registered
	// for POLLIN\|POLLOUT, and we get POLLIN, besides waking
	// the goroutine interested in POLLIN we have to not forget
	// about the one interested in POLLOUT.
	if(clear != 0) {
	runtime·netpolllock(pd);
	runtime·netpollupdate(pd, 0, clear);
	runtime·netpollunlock(pd);
	}

	if(mode)
	runtime·netpollready(&gp, pd, mode);
	}

	if(block && gp == nil)
	goto retry;
	return gp;
	}