third_party/gofrontend/libgo/runtime/panic.c - llvm-project/llgo - Git at Google

 // Copyright 2012 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 "malloc.h"
 #include "go-defer.h"
 #include "go-panic.h"

 // Code related to defer, panic and recover.

 uint32 runtime_panicking;
 static Lock paniclk;

 // Allocate a Defer, usually using per-P pool.
 // Each defer must be released with freedefer.
 Defer*
 runtime_newdefer()
 {
 	Defer *d;
 	P *p;

 	d = nil;
 	p = runtime_m()->p;
 	d = p->deferpool;
 	if(d)
 		p->deferpool = d->__next;
 	if(d == nil) {
 		// deferpool is empty
 		d = runtime_malloc(sizeof(Defer));
 	}
 	return d;
 }

 // Free the given defer.
 // The defer cannot be used after this call.
 void
 runtime_freedefer(Defer *d)
 {
 	P *p;

 	if(d->__special)
 		return;
 	p = runtime_m()->p;
 	d->__next = p->deferpool;
 	p->deferpool = d;
 	// No need to wipe out pointers in argp/pc/fn/args,
 	// because we empty the pool before GC.
 }

 // Run all deferred functions for the current goroutine.
 // This is noinline for go_can_recover.
 static void __go_rundefer (void) __attribute__ ((noinline));
 static void
 __go_rundefer(void)
 {
 	G *g;
 	Defer *d;

 	g = runtime_g();
 	while((d = g->defer) != nil) {
 		void (*pfn)(void*);

 		g->defer = d->__next;
 		pfn = d->__pfn;
 		d->__pfn = nil;
 		if (pfn != nil)
 			(*pfn)(d->__arg);
 		runtime_freedefer(d);
 	}
 }

 void
 runtime_startpanic(void)
 {
 	M *m;

 	m = runtime_m();
 	if(runtime_mheap.cachealloc.size == 0) { // very early
 		runtime_printf("runtime: panic before malloc heap initialized\n");
 		m->mallocing = 1; // tell rest of panic not to try to malloc
 	} else if(m->mcache == nil) // can happen if called from signal handler or throw
 		m->mcache = runtime_allocmcache();
 	switch(m->dying) {
 	case 0:
 		m->dying = 1;
 		if(runtime_g() != nil)
 			runtime_g()->writebuf = nil;
 		runtime_xadd(&runtime_panicking, 1);
 		runtime_lock(&paniclk);
 		if(runtime_debug.schedtrace > 0 || runtime_debug.scheddetail > 0)
 			runtime_schedtrace(true);
 		runtime_freezetheworld();
 		return;
 	case 1:
 		// Something failed while panicing, probably the print of the
 		// argument to panic().  Just print a stack trace and exit.
 		m->dying = 2;
 		runtime_printf("panic during panic\n");
 		runtime_dopanic(0);
 		runtime_exit(3);
 	case 2:
 		// This is a genuine bug in the runtime, we couldn't even
 		// print the stack trace successfully.
 		m->dying = 3;
 		runtime_printf("stack trace unavailable\n");
 		runtime_exit(4);
 	default:
 		// Can't even print!  Just exit.
 		runtime_exit(5);
 	}
 }

 void
 runtime_dopanic(int32 unused __attribute__ ((unused)))
 {
 	G *g;
 	static bool didothers;
 	bool crash;
 	int32 t;

 	g = runtime_g();
 	if(g->sig != 0)
 		runtime_printf("[signal %x code=%p addr=%p]\n",
 			       g->sig, (void*)g->sigcode0, (void*)g->sigcode1);

 	if((t = runtime_gotraceback(&crash)) > 0){
 		if(g != runtime_m()->g0) {
 			runtime_printf("\n");
 			runtime_goroutineheader(g);
 			runtime_traceback();
 			runtime_printcreatedby(g);
 		} else if(t >= 2 || runtime_m()->throwing > 0) {
 			runtime_printf("\nruntime stack:\n");
 			runtime_traceback();
 		}
 		if(!didothers) {
 			didothers = true;
 			runtime_tracebackothers(g);
 		}
 	}
 	runtime_unlock(&paniclk);
 	if(runtime_xadd(&runtime_panicking, -1) != 0) {
 		// Some other m is panicking too.
 		// Let it print what it needs to print.
 		// Wait forever without chewing up cpu.
 		// It will exit when it's done.
 		static Lock deadlock;
 		runtime_lock(&deadlock);
 		runtime_lock(&deadlock);
 	}

 	if(crash)
 		runtime_crash();

 	runtime_exit(2);
 }

 bool
 runtime_canpanic(G *gp)
 {
 	M *m = runtime_m();
 	byte g;

 	USED(&g);  // don't use global g, it points to gsignal

 	// Is it okay for gp to panic instead of crashing the program?
 	// Yes, as long as it is running Go code, not runtime code,
 	// and not stuck in a system call.
 	if(gp == nil || gp != m->curg)
 		return false;
 	if(m->locks-m->softfloat != 0 || m->mallocing != 0 || m->throwing != 0 || m->gcing != 0 || m->dying != 0)
 		return false;
 	if(gp->status != Grunning)
 		return false;
 #ifdef GOOS_windows
 	if(m->libcallsp != 0)
 		return false;
 #endif
 	return true;
 }

 void
 runtime_throw(const char *s)
 {
 	M *mp;

 	mp = runtime_m();
 	if(mp->throwing == 0)
 		mp->throwing = 1;
 	runtime_startpanic();
 	runtime_printf("fatal error: %s\n", s);
 	runtime_dopanic(0);
 	*(int32*)0 = 0;	// not reached
 	runtime_exit(1);	// even more not reached
 }

 void
 runtime_panicstring(const char *s)
 {
 	Eface err;

 	if(runtime_m()->mallocing) {
 		runtime_printf("panic: %s\n", s);
 		runtime_throw("panic during malloc");
 	}
 	if(runtime_m()->gcing) {
 		runtime_printf("panic: %s\n", s);
 		runtime_throw("panic during gc");
 	}
 	if(runtime_m()->locks) {
 		runtime_printf("panic: %s\n", s);
 		runtime_throw("panic holding locks");
 	}
 	runtime_newErrorCString(s, &err);
 	runtime_panic(err);
 }

 void runtime_Goexit (void) __asm__ (GOSYM_PREFIX "runtime.Goexit");

 void
 runtime_Goexit(void)
 {
 	__go_rundefer();
 	runtime_goexit();
 }

 void
 runtime_panicdivide(void)
 {
 	runtime_panicstring("integer divide by zero");
 }
	// Copyright 2012 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 "malloc.h"
	#include "go-defer.h"
	#include "go-panic.h"

	// Code related to defer, panic and recover.

	uint32 runtime_panicking;
	static Lock paniclk;

	// Allocate a Defer, usually using per-P pool.
	// Each defer must be released with freedefer.
	Defer*
	runtime_newdefer()
	{
	Defer *d;
	P *p;

	d = nil;
	p = runtime_m()->p;
	d = p->deferpool;
	if(d)
	p->deferpool = d->__next;
	if(d == nil) {
	// deferpool is empty
	d = runtime_malloc(sizeof(Defer));
	}
	return d;
	}

	// Free the given defer.
	// The defer cannot be used after this call.
	void
	runtime_freedefer(Defer *d)
	{
	P *p;

	if(d->__special)
	return;
	p = runtime_m()->p;
	d->__next = p->deferpool;
	p->deferpool = d;
	// No need to wipe out pointers in argp/pc/fn/args,
	// because we empty the pool before GC.
	}

	// Run all deferred functions for the current goroutine.
	// This is noinline for go_can_recover.
	static void __go_rundefer (void) __attribute__ ((noinline));
	static void
	__go_rundefer(void)
	{
	G *g;
	Defer *d;

	g = runtime_g();
	while((d = g->defer) != nil) {
	void (pfn)(void);

	g->defer = d->__next;
	pfn = d->__pfn;
	d->__pfn = nil;
	if (pfn != nil)
	(*pfn)(d->__arg);
	runtime_freedefer(d);
	}
	}

	void
	runtime_startpanic(void)
	{
	M *m;

	m = runtime_m();
	if(runtime_mheap.cachealloc.size == 0) { // very early
	runtime_printf("runtime: panic before malloc heap initialized\n");
	m->mallocing = 1; // tell rest of panic not to try to malloc
	} else if(m->mcache == nil) // can happen if called from signal handler or throw
	m->mcache = runtime_allocmcache();
	switch(m->dying) {
	case 0:
	m->dying = 1;
	if(runtime_g() != nil)
	runtime_g()->writebuf = nil;
	runtime_xadd(&runtime_panicking, 1);
	runtime_lock(&paniclk);
	if(runtime_debug.schedtrace > 0 \|\| runtime_debug.scheddetail > 0)
	runtime_schedtrace(true);
	runtime_freezetheworld();
	return;
	case 1:
	// Something failed while panicing, probably the print of the
	// argument to panic(). Just print a stack trace and exit.
	m->dying = 2;
	runtime_printf("panic during panic\n");
	runtime_dopanic(0);
	runtime_exit(3);
	case 2:
	// This is a genuine bug in the runtime, we couldn't even
	// print the stack trace successfully.
	m->dying = 3;
	runtime_printf("stack trace unavailable\n");
	runtime_exit(4);
	default:
	// Can't even print! Just exit.
	runtime_exit(5);
	}
	}

	void
	runtime_dopanic(int32 unused __attribute__ ((unused)))
	{
	G *g;
	static bool didothers;
	bool crash;
	int32 t;

	g = runtime_g();
	if(g->sig != 0)
	runtime_printf("[signal %x code=%p addr=%p]\n",
	g->sig, (void)g->sigcode0, (void)g->sigcode1);

	if((t = runtime_gotraceback(&crash)) > 0){
	if(g != runtime_m()->g0) {
	runtime_printf("\n");
	runtime_goroutineheader(g);
	runtime_traceback();
	runtime_printcreatedby(g);
	} else if(t >= 2 \|\| runtime_m()->throwing > 0) {
	runtime_printf("\nruntime stack:\n");
	runtime_traceback();
	}
	if(!didothers) {
	didothers = true;
	runtime_tracebackothers(g);
	}
	}
	runtime_unlock(&paniclk);
	if(runtime_xadd(&runtime_panicking, -1) != 0) {
	// Some other m is panicking too.
	// Let it print what it needs to print.
	// Wait forever without chewing up cpu.
	// It will exit when it's done.
	static Lock deadlock;
	runtime_lock(&deadlock);
	runtime_lock(&deadlock);
	}

	if(crash)
	runtime_crash();

	runtime_exit(2);
	}

	bool
	runtime_canpanic(G *gp)
	{
	M *m = runtime_m();
	byte g;

	USED(&g); // don't use global g, it points to gsignal

	// Is it okay for gp to panic instead of crashing the program?
	// Yes, as long as it is running Go code, not runtime code,
	// and not stuck in a system call.
	if(gp == nil \|\| gp != m->curg)
	return false;
	if(m->locks-m->softfloat != 0 \|\| m->mallocing != 0 \|\| m->throwing != 0 \|\| m->gcing != 0 \|\| m->dying != 0)
	return false;
	if(gp->status != Grunning)
	return false;
	#ifdef GOOS_windows
	if(m->libcallsp != 0)
	return false;
	#endif
	return true;
	}

	void
	runtime_throw(const char *s)
	{
	M *mp;

	mp = runtime_m();
	if(mp->throwing == 0)
	mp->throwing = 1;
	runtime_startpanic();
	runtime_printf("fatal error: %s\n", s);
	runtime_dopanic(0);
	(int32)0 = 0; // not reached
	runtime_exit(1); // even more not reached
	}

	void
	runtime_panicstring(const char *s)
	{
	Eface err;

	if(runtime_m()->mallocing) {
	runtime_printf("panic: %s\n", s);
	runtime_throw("panic during malloc");
	}
	if(runtime_m()->gcing) {
	runtime_printf("panic: %s\n", s);
	runtime_throw("panic during gc");
	}
	if(runtime_m()->locks) {
	runtime_printf("panic: %s\n", s);
	runtime_throw("panic holding locks");
	}
	runtime_newErrorCString(s, &err);
	runtime_panic(err);
	}

	void runtime_Goexit (void) __asm__ (GOSYM_PREFIX "runtime.Goexit");

	void
	runtime_Goexit(void)
	{
	__go_rundefer();
	runtime_goexit();
	}

	void
	runtime_panicdivide(void)
	{
	runtime_panicstring("integer divide by zero");
	}