src/pkg/runtime/thread_freebsd.c - go - Git at Google

 // Use of this source file is governed by a BSD-style
 // license that can be found in the LICENSE file.`

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

 extern SigTab runtime·sigtab[];
 extern int32 runtime·sys_umtx_op(uint32*, int32, uint32, void*, void*);

 // From FreeBSD's <sys/sysctl.h>
 #define	CTL_HW	6
 #define	HW_NCPU	3

 static int32
 getncpu(void)
 {
 	uint32 mib[2];
 	uint32 out;
 	int32 ret;
 	uintptr nout;

 	// Fetch hw.ncpu via sysctl.
 	mib[0] = CTL_HW;
 	mib[1] = HW_NCPU;
 	nout = sizeof out;
 	out = 0;
 	ret = runtime·sysctl(mib, 2, (byte*)&out, &nout, nil, 0);
 	if(ret >= 0)
 		return out;
 	else
 		return 1;
 }

 // FreeBSD's umtx_op syscall is effectively the same as Linux's futex, and
 // thus the code is largely similar. See linux/thread.c and lock_futex.c for comments.

 void
 runtime·futexsleep(uint32 *addr, uint32 val, int64 ns)
 {
 	int32 ret;
 	Timespec ts, *tsp;

 	if(ns < 0)
 		tsp = nil;
 	else {
 		ts.tv_sec = ns / 1000000000LL;
 		ts.tv_nsec = ns % 1000000000LL;
 		tsp = &ts;
 	}

 	ret = runtime·sys_umtx_op(addr, UMTX_OP_WAIT, val, nil, tsp);
 	if(ret >= 0 || ret == -EINTR)
 		return;

 	runtime·printf("umtx_wait addr=%p val=%d ret=%d\n", addr, val, ret);
 	*(int32*)0x1005 = 0x1005;
 }

 void
 runtime·futexwakeup(uint32 *addr, uint32 cnt)
 {
 	int32 ret;

 	ret = runtime·sys_umtx_op(addr, UMTX_OP_WAKE, cnt, nil, nil);
 	if(ret >= 0)
 		return;

 	runtime·printf("umtx_wake addr=%p ret=%d\n", addr, ret);
 	*(int32*)0x1006 = 0x1006;
 }

 void runtime·thr_start(void*);

 void
 runtime·newosproc(M *m, G *g, void *stk, void (*fn)(void))
 {
 	ThrParam param;

 	USED(fn);	// thr_start assumes fn == mstart
 	USED(g);	// thr_start assumes g == m->g0

 	if(0){
 		runtime·printf("newosproc stk=%p m=%p g=%p fn=%p id=%d/%d ostk=%p\n",
 			stk, m, g, fn, m->id, m->tls[0], &m);
 	}

 	runtime·memclr((byte*)&param, sizeof param);

 	param.start_func = runtime·thr_start;
 	param.arg = m;
 	param.stack_base = (int8*)g->stackbase;
 	param.stack_size = (byte*)stk - (byte*)g->stackbase;
 	param.child_tid = (intptr*)&m->procid;
 	param.parent_tid = nil;
 	param.tls_base = (int8*)&m->tls[0];
 	param.tls_size = sizeof m->tls;

 	m->tls[0] = m->id;	// so 386 asm can find it

 	runtime·thr_new(&param, sizeof param);
 }

 void
 runtime·osinit(void)
 {
 	runtime·ncpu = getncpu();
 }

 void
 runtime·goenvs(void)
 {
 	runtime·goenvs_unix();
 }

 // Called to initialize a new m (including the bootstrap m).
 void
 runtime·minit(void)
 {
 	// Initialize signal handling
 	m->gsignal = runtime·malg(32*1024);
 	runtime·signalstack(m->gsignal->stackguard - StackGuard, 32*1024);
 }

 void
 runtime·sigpanic(void)
 {
 	switch(g->sig) {
 	case SIGBUS:
 		if(g->sigcode0 == BUS_ADRERR && g->sigcode1 < 0x1000) {
 			if(g->sigpc == 0)
 				runtime·panicstring("call of nil func value");
 			runtime·panicstring("invalid memory address or nil pointer dereference");
 		}
 		runtime·printf("unexpected fault address %p\n", g->sigcode1);
 		runtime·throw("fault");
 	case SIGSEGV:
 		if((g->sigcode0 == 0 || g->sigcode0 == SEGV_MAPERR || g->sigcode0 == SEGV_ACCERR) && g->sigcode1 < 0x1000) {
 			if(g->sigpc == 0)
 				runtime·panicstring("call of nil func value");
 			runtime·panicstring("invalid memory address or nil pointer dereference");
 		}
 		runtime·printf("unexpected fault address %p\n", g->sigcode1);
 		runtime·throw("fault");
 	case SIGFPE:
 		switch(g->sigcode0) {
 		case FPE_INTDIV:
 			runtime·panicstring("integer divide by zero");
 		case FPE_INTOVF:
 			runtime·panicstring("integer overflow");
 		}
 		runtime·panicstring("floating point error");
 	}
 	runtime·panicstring(runtime·sigtab[g->sig].name);
 }

 // TODO: fill this in properly.
 void
 runtime·osyield(void)
 {
 }
	// Use of this source file is governed by a BSD-style
	// license that can be found in the LICENSE file.`

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

	extern SigTab runtime·sigtab[];
	extern int32 runtime·sys_umtx_op(uint32, int32, uint32, void, void*);

	// From FreeBSD's <sys/sysctl.h>
	#define CTL_HW 6
	#define HW_NCPU 3

	static int32
	getncpu(void)
	{
	uint32 mib[2];
	uint32 out;
	int32 ret;
	uintptr nout;

	// Fetch hw.ncpu via sysctl.
	mib[0] = CTL_HW;
	mib[1] = HW_NCPU;
	nout = sizeof out;
	out = 0;
	ret = runtime·sysctl(mib, 2, (byte*)&out, &nout, nil, 0);
	if(ret >= 0)
	return out;
	else
	return 1;
	}

	// FreeBSD's umtx_op syscall is effectively the same as Linux's futex, and
	// thus the code is largely similar. See linux/thread.c and lock_futex.c for comments.

	void
	runtime·futexsleep(uint32 *addr, uint32 val, int64 ns)
	{
	int32 ret;
	Timespec ts, *tsp;

	if(ns < 0)
	tsp = nil;
	else {
	ts.tv_sec = ns / 1000000000LL;
	ts.tv_nsec = ns % 1000000000LL;
	tsp = &ts;
	}

	ret = runtime·sys_umtx_op(addr, UMTX_OP_WAIT, val, nil, tsp);
	if(ret >= 0 \|\| ret == -EINTR)
	return;

	runtime·printf("umtx_wait addr=%p val=%d ret=%d\n", addr, val, ret);
	(int32)0x1005 = 0x1005;
	}

	void
	runtime·futexwakeup(uint32 *addr, uint32 cnt)
	{
	int32 ret;

	ret = runtime·sys_umtx_op(addr, UMTX_OP_WAKE, cnt, nil, nil);
	if(ret >= 0)
	return;

	runtime·printf("umtx_wake addr=%p ret=%d\n", addr, ret);
	(int32)0x1006 = 0x1006;
	}

	void runtime·thr_start(void*);

	void
	runtime·newosproc(M m, G g, void stk, void (fn)(void))
	{
	ThrParam param;

	USED(fn); // thr_start assumes fn == mstart
	USED(g); // thr_start assumes g == m->g0

	if(0){
	runtime·printf("newosproc stk=%p m=%p g=%p fn=%p id=%d/%d ostk=%p\n",
	stk, m, g, fn, m->id, m->tls[0], &m);
	}

	runtime·memclr((byte*)&param, sizeof param);

	param.start_func = runtime·thr_start;
	param.arg = m;
	param.stack_base = (int8*)g->stackbase;
	param.stack_size = (byte)stk - (byte)g->stackbase;
	param.child_tid = (intptr*)&m->procid;
	param.parent_tid = nil;
	param.tls_base = (int8*)&m->tls[0];
	param.tls_size = sizeof m->tls;

	m->tls[0] = m->id; // so 386 asm can find it

	runtime·thr_new(&param, sizeof param);
	}

	void
	runtime·osinit(void)
	{
	runtime·ncpu = getncpu();
	}

	void
	runtime·goenvs(void)
	{
	runtime·goenvs_unix();
	}

	// Called to initialize a new m (including the bootstrap m).
	void
	runtime·minit(void)
	{
	// Initialize signal handling
	m->gsignal = runtime·malg(32*1024);
	runtime·signalstack(m->gsignal->stackguard - StackGuard, 32*1024);
	}

	void
	runtime·sigpanic(void)
	{
	switch(g->sig) {
	case SIGBUS:
	if(g->sigcode0 == BUS_ADRERR && g->sigcode1 < 0x1000) {
	if(g->sigpc == 0)
	runtime·panicstring("call of nil func value");
	runtime·panicstring("invalid memory address or nil pointer dereference");
	}
	runtime·printf("unexpected fault address %p\n", g->sigcode1);
	runtime·throw("fault");
	case SIGSEGV:
	if((g->sigcode0 == 0 \|\| g->sigcode0 == SEGV_MAPERR \|\| g->sigcode0 == SEGV_ACCERR) && g->sigcode1 < 0x1000) {
	if(g->sigpc == 0)
	runtime·panicstring("call of nil func value");
	runtime·panicstring("invalid memory address or nil pointer dereference");
	}
	runtime·printf("unexpected fault address %p\n", g->sigcode1);
	runtime·throw("fault");
	case SIGFPE:
	switch(g->sigcode0) {
	case FPE_INTDIV:
	runtime·panicstring("integer divide by zero");
	case FPE_INTOVF:
	runtime·panicstring("integer overflow");
	}
	runtime·panicstring("floating point error");
	}
	runtime·panicstring(runtime·sigtab[g->sig].name);
	}

	// TODO: fill this in properly.
	void
	runtime·osyield(void)
	{
	}