src/runtime/os1_netbsd.go - go - Git at Google

 // Copyright 2011 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.

 package runtime

 import "unsafe"

 const (
 	_ESRCH   = 3
 	_ENOTSUP = 91

 	// From NetBSD's <sys/time.h>
 	_CLOCK_REALTIME  = 0
 	_CLOCK_VIRTUAL   = 1
 	_CLOCK_PROF      = 2
 	_CLOCK_MONOTONIC = 3
 )

 var sigset_none = sigset{}
 var sigset_all = sigset{[4]uint32{^uint32(0), ^uint32(0), ^uint32(0), ^uint32(0)}}

 // From NetBSD's <sys/sysctl.h>
 const (
 	_CTL_HW  = 6
 	_HW_NCPU = 3
 )

 func getncpu() int32 {
 	mib := [2]uint32{_CTL_HW, _HW_NCPU}
 	out := uint32(0)
 	nout := unsafe.Sizeof(out)
 	ret := sysctl(&mib[0], 2, (*byte)(unsafe.Pointer(&out)), &nout, nil, 0)
 	if ret >= 0 {
 		return int32(out)
 	}
 	return 1
 }

 //go:nosplit
 func semacreate() uintptr {
 	return 1
 }

 //go:nosplit
 func semasleep(ns int64) int32 {
 	_g_ := getg()

 	// spin-mutex lock
 	for {
 		if xchg(&_g_.m.waitsemalock, 1) == 0 {
 			break
 		}
 		osyield()
 	}

 	for {
 		// lock held
 		if _g_.m.waitsemacount == 0 {
 			// sleep until semaphore != 0 or timeout.
 			// thrsleep unlocks m.waitsemalock.
 			if ns < 0 {
 				// TODO(jsing) - potential deadlock!
 				//
 				// There is a potential deadlock here since we
 				// have to release the waitsemalock mutex
 				// before we call lwp_park() to suspend the
 				// thread. This allows another thread to
 				// release the lock and call lwp_unpark()
 				// before the thread is actually suspended.
 				// If this occurs the current thread will end
 				// up sleeping indefinitely. Unfortunately
 				// the NetBSD kernel does not appear to provide
 				// a mechanism for unlocking the userspace
 				// mutex once the thread is actually parked.
 				atomicstore(&_g_.m.waitsemalock, 0)
 				lwp_park(nil, 0, unsafe.Pointer(&_g_.m.waitsemacount), nil)
 			} else {
 				var ts timespec
 				var nsec int32
 				ns += nanotime()
 				ts.set_sec(timediv(ns, 1000000000, &nsec))
 				ts.set_nsec(nsec)
 				// TODO(jsing) - potential deadlock!
 				// See above for details.
 				atomicstore(&_g_.m.waitsemalock, 0)
 				lwp_park(&ts, 0, unsafe.Pointer(&_g_.m.waitsemacount), nil)
 			}
 			// reacquire lock
 			for {
 				if xchg(&_g_.m.waitsemalock, 1) == 0 {
 					break
 				}
 				osyield()
 			}
 		}

 		// lock held (again)
 		if _g_.m.waitsemacount != 0 {
 			// semaphore is available.
 			_g_.m.waitsemacount--
 			// spin-mutex unlock
 			atomicstore(&_g_.m.waitsemalock, 0)
 			return 0
 		}

 		// semaphore not available.
 		// if there is a timeout, stop now.
 		// otherwise keep trying.
 		if ns >= 0 {
 			break
 		}
 	}

 	// lock held but giving up
 	// spin-mutex unlock
 	atomicstore(&_g_.m.waitsemalock, 0)
 	return -1
 }

 //go:nosplit
 func semawakeup(mp *m) {
 	// spin-mutex lock
 	for {
 		if xchg(&mp.waitsemalock, 1) == 0 {
 			break
 		}
 		osyield()
 	}

 	mp.waitsemacount++
 	// TODO(jsing) - potential deadlock, see semasleep() for details.
 	// Confirm that LWP is parked before unparking...
 	ret := lwp_unpark(int32(mp.procid), unsafe.Pointer(&mp.waitsemacount))
 	if ret != 0 && ret != _ESRCH {
 		// semawakeup can be called on signal stack.
 		systemstack(func() {
 			print("thrwakeup addr=", &mp.waitsemacount, " sem=", mp.waitsemacount, " ret=", ret, "\n")
 		})
 	}

 	// spin-mutex unlock
 	atomicstore(&mp.waitsemalock, 0)
 }

 func newosproc(mp *m, stk unsafe.Pointer) {
 	if false {
 		print("newosproc stk=", stk, " m=", mp, " g=", mp.g0, " id=", mp.id, "/", int32(mp.tls[0]), " ostk=", &mp, "\n")
 	}

 	mp.tls[0] = uintptr(mp.id) // so 386 asm can find it

 	var uc ucontextt
 	getcontext(unsafe.Pointer(&uc))

 	uc.uc_flags = _UC_SIGMASK | _UC_CPU
 	uc.uc_link = nil
 	uc.uc_sigmask = sigset_all

 	lwp_mcontext_init(&uc.uc_mcontext, stk, mp, mp.g0, funcPC(mstart))

 	ret := lwp_create(unsafe.Pointer(&uc), 0, unsafe.Pointer(&mp.procid))
 	if ret < 0 {
 		print("runtime: failed to create new OS thread (have ", mcount()-1, " already; errno=", -ret, ")\n")
 		throw("runtime.newosproc")
 	}
 }

 func osinit() {
 	ncpu = getncpu()
 }

 var urandom_dev = []byte("/dev/urandom\x00")

 //go:nosplit
 func getRandomData(r []byte) {
 	fd := open(&urandom_dev[0], 0 /* O_RDONLY */, 0)
 	n := read(fd, unsafe.Pointer(&r[0]), int32(len(r)))
 	close(fd)
 	extendRandom(r, int(n))
 }

 func goenvs() {
 	goenvs_unix()
 }

 // Called to initialize a new m (including the bootstrap m).
 // Called on the parent thread (main thread in case of bootstrap), can allocate memory.
 func mpreinit(mp *m) {
 	mp.gsignal = malg(32 * 1024)
 	mp.gsignal.m = mp
 }

 // Called to initialize a new m (including the bootstrap m).
 // Called on the new thread, can not allocate memory.
 func minit() {
 	_g_ := getg()
 	_g_.m.procid = uint64(lwp_self())

 	// Initialize signal handling
 	signalstack((*byte)(unsafe.Pointer(_g_.m.gsignal.stack.lo)), 32*1024)
 	sigprocmask(_SIG_SETMASK, &sigset_none, nil)
 }

 // Called from dropm to undo the effect of an minit.
 func unminit() {
 	signalstack(nil, 0)
 }

 func memlimit() uintptr {
 	return 0
 }

 func sigtramp()

 type sigactiont struct {
 	sa_sigaction uintptr
 	sa_mask      sigset
 	sa_flags     int32
 }

 func setsig(i int32, fn uintptr, restart bool) {
 	var sa sigactiont
 	sa.sa_flags = _SA_SIGINFO | _SA_ONSTACK
 	if restart {
 		sa.sa_flags |= _SA_RESTART
 	}
 	sa.sa_mask = sigset_all
 	if fn == funcPC(sighandler) {
 		fn = funcPC(sigtramp)
 	}
 	sa.sa_sigaction = fn
 	sigaction(i, &sa, nil)
 }

 func setsigstack(i int32) {
 	throw("setsigstack")
 }

 func getsig(i int32) uintptr {
 	var sa sigactiont
 	sigaction(i, nil, &sa)
 	if sa.sa_sigaction == funcPC(sigtramp) {
 		return funcPC(sighandler)
 	}
 	return sa.sa_sigaction
 }

 func signalstack(p *byte, n int32) {
 	var st sigaltstackt

 	st.ss_sp = uintptr(unsafe.Pointer(p))
 	st.ss_size = uintptr(n)
 	st.ss_flags = 0
 	if p == nil {
 		st.ss_flags = _SS_DISABLE
 	}
 	sigaltstack(&st, nil)
 }

 func unblocksignals() {
 	sigprocmask(_SIG_SETMASK, &sigset_none, nil)
 }
	// Copyright 2011 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.

	package runtime

	import "unsafe"

	const (
	_ESRCH = 3
	_ENOTSUP = 91

	// From NetBSD's <sys/time.h>
	_CLOCK_REALTIME = 0
	_CLOCK_VIRTUAL = 1
	_CLOCK_PROF = 2
	_CLOCK_MONOTONIC = 3
	)

	var sigset_none = sigset{}
	var sigset_all = sigset{[4]uint32{^uint32(0), ^uint32(0), ^uint32(0), ^uint32(0)}}

	// From NetBSD's <sys/sysctl.h>
	const (
	_CTL_HW = 6
	_HW_NCPU = 3
	)

	func getncpu() int32 {
	mib := [2]uint32{_CTL_HW, _HW_NCPU}
	out := uint32(0)
	nout := unsafe.Sizeof(out)
	ret := sysctl(&mib[0], 2, (*byte)(unsafe.Pointer(&out)), &nout, nil, 0)
	if ret >= 0 {
	return int32(out)
	}
	return 1
	}

	//go:nosplit
	func semacreate() uintptr {
	return 1
	}

	//go:nosplit
	func semasleep(ns int64) int32 {
	_g_ := getg()

	// spin-mutex lock
	for {
	if xchg(&_g_.m.waitsemalock, 1) == 0 {
	break
	}
	osyield()
	}

	for {
	// lock held
	if _g_.m.waitsemacount == 0 {
	// sleep until semaphore != 0 or timeout.
	// thrsleep unlocks m.waitsemalock.
	if ns < 0 {
	// TODO(jsing) - potential deadlock!
	//
	// There is a potential deadlock here since we
	// have to release the waitsemalock mutex
	// before we call lwp_park() to suspend the
	// thread. This allows another thread to
	// release the lock and call lwp_unpark()
	// before the thread is actually suspended.
	// If this occurs the current thread will end
	// up sleeping indefinitely. Unfortunately
	// the NetBSD kernel does not appear to provide
	// a mechanism for unlocking the userspace
	// mutex once the thread is actually parked.
	atomicstore(&_g_.m.waitsemalock, 0)
	lwp_park(nil, 0, unsafe.Pointer(&_g_.m.waitsemacount), nil)
	} else {
	var ts timespec
	var nsec int32
	ns += nanotime()
	ts.set_sec(timediv(ns, 1000000000, &nsec))
	ts.set_nsec(nsec)
	// TODO(jsing) - potential deadlock!
	// See above for details.
	atomicstore(&_g_.m.waitsemalock, 0)
	lwp_park(&ts, 0, unsafe.Pointer(&_g_.m.waitsemacount), nil)
	}
	// reacquire lock
	for {
	if xchg(&_g_.m.waitsemalock, 1) == 0 {
	break
	}
	osyield()
	}
	}

	// lock held (again)
	if _g_.m.waitsemacount != 0 {
	// semaphore is available.
	_g_.m.waitsemacount--
	// spin-mutex unlock
	atomicstore(&_g_.m.waitsemalock, 0)
	return 0
	}

	// semaphore not available.
	// if there is a timeout, stop now.
	// otherwise keep trying.
	if ns >= 0 {
	break
	}
	}

	// lock held but giving up
	// spin-mutex unlock
	atomicstore(&_g_.m.waitsemalock, 0)
	return -1
	}

	//go:nosplit
	func semawakeup(mp *m) {
	// spin-mutex lock
	for {
	if xchg(&mp.waitsemalock, 1) == 0 {
	break
	}
	osyield()
	}

	mp.waitsemacount++
	// TODO(jsing) - potential deadlock, see semasleep() for details.
	// Confirm that LWP is parked before unparking...
	ret := lwp_unpark(int32(mp.procid), unsafe.Pointer(&mp.waitsemacount))
	if ret != 0 && ret != _ESRCH {
	// semawakeup can be called on signal stack.
	systemstack(func() {
	print("thrwakeup addr=", &mp.waitsemacount, " sem=", mp.waitsemacount, " ret=", ret, "\n")
	})
	}

	// spin-mutex unlock
	atomicstore(&mp.waitsemalock, 0)
	}

	func newosproc(mp *m, stk unsafe.Pointer) {
	if false {
	print("newosproc stk=", stk, " m=", mp, " g=", mp.g0, " id=", mp.id, "/", int32(mp.tls[0]), " ostk=", &mp, "\n")
	}

	mp.tls[0] = uintptr(mp.id) // so 386 asm can find it

	var uc ucontextt
	getcontext(unsafe.Pointer(&uc))

	uc.uc_flags = _UC_SIGMASK \| _UC_CPU
	uc.uc_link = nil
	uc.uc_sigmask = sigset_all

	lwp_mcontext_init(&uc.uc_mcontext, stk, mp, mp.g0, funcPC(mstart))

	ret := lwp_create(unsafe.Pointer(&uc), 0, unsafe.Pointer(&mp.procid))
	if ret < 0 {
	print("runtime: failed to create new OS thread (have ", mcount()-1, " already; errno=", -ret, ")\n")
	throw("runtime.newosproc")
	}
	}

	func osinit() {
	ncpu = getncpu()
	}

	var urandom_dev = []byte("/dev/urandom\x00")

	//go:nosplit
	func getRandomData(r []byte) {
	fd := open(&urandom_dev[0], 0 /* O_RDONLY */, 0)
	n := read(fd, unsafe.Pointer(&r[0]), int32(len(r)))
	close(fd)
	extendRandom(r, int(n))
	}

	func goenvs() {
	goenvs_unix()
	}

	// Called to initialize a new m (including the bootstrap m).
	// Called on the parent thread (main thread in case of bootstrap), can allocate memory.
	func mpreinit(mp *m) {
	mp.gsignal = malg(32 * 1024)
	mp.gsignal.m = mp
	}

	// Called to initialize a new m (including the bootstrap m).
	// Called on the new thread, can not allocate memory.
	func minit() {
	_g_ := getg()
	_g_.m.procid = uint64(lwp_self())

	// Initialize signal handling
	signalstack((byte)(unsafe.Pointer(_g_.m.gsignal.stack.lo)), 321024)
	sigprocmask(_SIG_SETMASK, &sigset_none, nil)
	}

	// Called from dropm to undo the effect of an minit.
	func unminit() {
	signalstack(nil, 0)
	}

	func memlimit() uintptr {
	return 0
	}

	func sigtramp()

	type sigactiont struct {
	sa_sigaction uintptr
	sa_mask sigset
	sa_flags int32
	}

	func setsig(i int32, fn uintptr, restart bool) {
	var sa sigactiont
	sa.sa_flags = _SA_SIGINFO \| _SA_ONSTACK
	if restart {
	sa.sa_flags \|= _SA_RESTART
	}
	sa.sa_mask = sigset_all
	if fn == funcPC(sighandler) {
	fn = funcPC(sigtramp)
	}
	sa.sa_sigaction = fn
	sigaction(i, &sa, nil)
	}

	func setsigstack(i int32) {
	throw("setsigstack")
	}

	func getsig(i int32) uintptr {
	var sa sigactiont
	sigaction(i, nil, &sa)
	if sa.sa_sigaction == funcPC(sigtramp) {
	return funcPC(sighandler)
	}
	return sa.sa_sigaction
	}

	func signalstack(p *byte, n int32) {
	var st sigaltstackt

	st.ss_sp = uintptr(unsafe.Pointer(p))
	st.ss_size = uintptr(n)
	st.ss_flags = 0
	if p == nil {
	st.ss_flags = _SS_DISABLE
	}
	sigaltstack(&st, nil)
	}

	func unblocksignals() {
	sigprocmask(_SIG_SETMASK, &sigset_none, nil)
	}