src/runtime/signal_amd64x.c - go - 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 amd64 amd64p32
 // +build darwin dragonfly freebsd linux nacl netbsd openbsd solaris

 #include "runtime.h"
 #include "defs_GOOS_GOARCH.h"
 #include "os_GOOS.h"
 #include "signal_GOOS_GOARCH.h"
 #include "signals_GOOS.h"

 void
 runtime·dumpregs(Siginfo *info, void *ctxt)
 {
 	USED(info);
 	USED(ctxt);

 	runtime·printf("rax     %X\n", SIG_RAX(info, ctxt));
 	runtime·printf("rbx     %X\n", SIG_RBX(info, ctxt));
 	runtime·printf("rcx     %X\n", SIG_RCX(info, ctxt));
 	runtime·printf("rdx     %X\n", SIG_RDX(info, ctxt));
 	runtime·printf("rdi     %X\n", SIG_RDI(info, ctxt));
 	runtime·printf("rsi     %X\n", SIG_RSI(info, ctxt));
 	runtime·printf("rbp     %X\n", SIG_RBP(info, ctxt));
 	runtime·printf("rsp     %X\n", SIG_RSP(info, ctxt));
 	runtime·printf("r8      %X\n", SIG_R8(info, ctxt) );
 	runtime·printf("r9      %X\n", SIG_R9(info, ctxt) );
 	runtime·printf("r10     %X\n", SIG_R10(info, ctxt));
 	runtime·printf("r11     %X\n", SIG_R11(info, ctxt));
 	runtime·printf("r12     %X\n", SIG_R12(info, ctxt));
 	runtime·printf("r13     %X\n", SIG_R13(info, ctxt));
 	runtime·printf("r14     %X\n", SIG_R14(info, ctxt));
 	runtime·printf("r15     %X\n", SIG_R15(info, ctxt));
 	runtime·printf("rip     %X\n", SIG_RIP(info, ctxt));
 	runtime·printf("rflags  %X\n", SIG_RFLAGS(info, ctxt));
 	runtime·printf("cs      %X\n", SIG_CS(info, ctxt));
 	runtime·printf("fs      %X\n", SIG_FS(info, ctxt));
 	runtime·printf("gs      %X\n", SIG_GS(info, ctxt));
 }

 void
 runtime·sighandler(int32 sig, Siginfo *info, void *ctxt, G *gp)
 {
 	uintptr *sp;
 	SigTab *t;
 	bool crash;

 	if(sig == SIGPROF) {
 		runtime·sigprof((byte*)SIG_RIP(info, ctxt), (byte*)SIG_RSP(info, ctxt), nil, gp, g->m);
 		return;
 	}

 #ifdef GOOS_darwin
 	// x86-64 has 48-bit virtual addresses. The top 16 bits must echo bit 47.
 	// The hardware delivers a different kind of fault for a malformed address
 	// than it does for an attempt to access a valid but unmapped address.
 	// OS X 10.9.2 mishandles the malformed address case, making it look like
 	// a user-generated signal (like someone ran kill -SEGV ourpid).
 	// We pass user-generated signals to os/signal, or else ignore them.
 	// Doing that here - and returning to the faulting code - results in an
 	// infinite loop. It appears the best we can do is rewrite what the kernel
 	// delivers into something more like the truth. The address used below
 	// has very little chance of being the one that caused the fault, but it is
 	// malformed, it is clearly not a real pointer, and if it does get printed
 	// in real life, people will probably search for it and find this code.
 	// There are no Google hits for b01dfacedebac1e or 0xb01dfacedebac1e
 	// as I type this comment.
 	if(sig == SIGSEGV && SIG_CODE0(info, ctxt) == SI_USER) {
 		SIG_CODE0(info, ctxt) = SI_USER+1;
 		info->si_addr = (void*)(uintptr)0xb01dfacedebac1eULL;
 	}
 #endif

 	t = &runtime·sigtab[sig];
 	if(SIG_CODE0(info, ctxt) != SI_USER && (t->flags & SigPanic)) {
 		// Make it look like a call to the signal func.
 		// Have to pass arguments out of band since
 		// augmenting the stack frame would break
 		// the unwinding code.
 		gp->sig = sig;
 		gp->sigcode0 = SIG_CODE0(info, ctxt);
 		gp->sigcode1 = SIG_CODE1(info, ctxt);
 		gp->sigpc = SIG_RIP(info, ctxt);

 #ifdef GOOS_darwin
 		// Work around Leopard bug that doesn't set FPE_INTDIV.
 		// Look at instruction to see if it is a divide.
 		// Not necessary in Snow Leopard (si_code will be != 0).
 		if(sig == SIGFPE && gp->sigcode0 == 0) {
 			byte *pc;
 			pc = (byte*)gp->sigpc;
 			if((pc[0]&0xF0) == 0x40)	// 64-bit REX prefix
 				pc++;
 			else if(pc[0] == 0x66)	// 16-bit instruction prefix
 				pc++;
 			if(pc[0] == 0xF6 || pc[0] == 0xF7)
 				gp->sigcode0 = FPE_INTDIV;
 		}
 #endif

 		// Only push runtime·sigpanic if rip != 0.
 		// If rip == 0, probably panicked because of a
 		// call to a nil func.  Not pushing that onto sp will
 		// make the trace look like a call to runtime·sigpanic instead.
 		// (Otherwise the trace will end at runtime·sigpanic and we
 		// won't get to see who faulted.)
 		if(SIG_RIP(info, ctxt) != 0) {
 			sp = (uintptr*)SIG_RSP(info, ctxt);
 			if(sizeof(uintreg) > sizeof(uintptr))
 				*--sp = 0;
 			*--sp = SIG_RIP(info, ctxt);
 			SIG_RSP(info, ctxt) = (uintptr)sp;
 		}
 		SIG_RIP(info, ctxt) = (uintptr)runtime·sigpanic;
 		return;
 	}

 	if(SIG_CODE0(info, ctxt) == SI_USER || (t->flags & SigNotify))
 		if(runtime·sigsend(sig))
 			return;
 	if(t->flags & SigKill)
 		runtime·exit(2);
 	if(!(t->flags & SigThrow))
 		return;

 	g->m->throwing = 1;
 	g->m->caughtsig = gp;
 	runtime·startpanic();

 	if(sig < 0 || sig >= NSIG)
 		runtime·printf("Signal %d\n", sig);
 	else
 		runtime·printf("%s\n", runtime·sigtab[sig].name);

 	runtime·printf("PC=%X\n", SIG_RIP(info, ctxt));
 	if(g->m->lockedg != nil && g->m->ncgo > 0 && gp == g->m->g0) {
 		runtime·printf("signal arrived during cgo execution\n");
 		gp = g->m->lockedg;
 	}
 	runtime·printf("\n");

 	if(runtime·gotraceback(&crash)){
 		runtime·goroutineheader(gp);
 		runtime·tracebacktrap(SIG_RIP(info, ctxt), SIG_RSP(info, ctxt), 0, gp);
 		runtime·tracebackothers(gp);
 		runtime·printf("\n");
 		runtime·dumpregs(info, ctxt);
 	}

 	if(crash)
 		runtime·crash();

 	runtime·exit(2);
 }
	// 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 amd64 amd64p32
	// +build darwin dragonfly freebsd linux nacl netbsd openbsd solaris

	#include "runtime.h"
	#include "defs_GOOS_GOARCH.h"
	#include "os_GOOS.h"
	#include "signal_GOOS_GOARCH.h"
	#include "signals_GOOS.h"

	void
	runtime·dumpregs(Siginfo info, void ctxt)
	{
	USED(info);
	USED(ctxt);

	runtime·printf("rax %X\n", SIG_RAX(info, ctxt));
	runtime·printf("rbx %X\n", SIG_RBX(info, ctxt));
	runtime·printf("rcx %X\n", SIG_RCX(info, ctxt));
	runtime·printf("rdx %X\n", SIG_RDX(info, ctxt));
	runtime·printf("rdi %X\n", SIG_RDI(info, ctxt));
	runtime·printf("rsi %X\n", SIG_RSI(info, ctxt));
	runtime·printf("rbp %X\n", SIG_RBP(info, ctxt));
	runtime·printf("rsp %X\n", SIG_RSP(info, ctxt));
	runtime·printf("r8 %X\n", SIG_R8(info, ctxt) );
	runtime·printf("r9 %X\n", SIG_R9(info, ctxt) );
	runtime·printf("r10 %X\n", SIG_R10(info, ctxt));
	runtime·printf("r11 %X\n", SIG_R11(info, ctxt));
	runtime·printf("r12 %X\n", SIG_R12(info, ctxt));
	runtime·printf("r13 %X\n", SIG_R13(info, ctxt));
	runtime·printf("r14 %X\n", SIG_R14(info, ctxt));
	runtime·printf("r15 %X\n", SIG_R15(info, ctxt));
	runtime·printf("rip %X\n", SIG_RIP(info, ctxt));
	runtime·printf("rflags %X\n", SIG_RFLAGS(info, ctxt));
	runtime·printf("cs %X\n", SIG_CS(info, ctxt));
	runtime·printf("fs %X\n", SIG_FS(info, ctxt));
	runtime·printf("gs %X\n", SIG_GS(info, ctxt));
	}

	void
	runtime·sighandler(int32 sig, Siginfo info, void ctxt, G *gp)
	{
	uintptr *sp;
	SigTab *t;
	bool crash;

	if(sig == SIGPROF) {
	runtime·sigprof((byte)SIG_RIP(info, ctxt), (byte)SIG_RSP(info, ctxt), nil, gp, g->m);
	return;
	}

	#ifdef GOOS_darwin
	// x86-64 has 48-bit virtual addresses. The top 16 bits must echo bit 47.
	// The hardware delivers a different kind of fault for a malformed address
	// than it does for an attempt to access a valid but unmapped address.
	// OS X 10.9.2 mishandles the malformed address case, making it look like
	// a user-generated signal (like someone ran kill -SEGV ourpid).
	// We pass user-generated signals to os/signal, or else ignore them.
	// Doing that here - and returning to the faulting code - results in an
	// infinite loop. It appears the best we can do is rewrite what the kernel
	// delivers into something more like the truth. The address used below
	// has very little chance of being the one that caused the fault, but it is
	// malformed, it is clearly not a real pointer, and if it does get printed
	// in real life, people will probably search for it and find this code.
	// There are no Google hits for b01dfacedebac1e or 0xb01dfacedebac1e
	// as I type this comment.
	if(sig == SIGSEGV && SIG_CODE0(info, ctxt) == SI_USER) {
	SIG_CODE0(info, ctxt) = SI_USER+1;
	info->si_addr = (void*)(uintptr)0xb01dfacedebac1eULL;
	}
	#endif

	t = &runtime·sigtab[sig];
	if(SIG_CODE0(info, ctxt) != SI_USER && (t->flags & SigPanic)) {
	// Make it look like a call to the signal func.
	// Have to pass arguments out of band since
	// augmenting the stack frame would break
	// the unwinding code.
	gp->sig = sig;
	gp->sigcode0 = SIG_CODE0(info, ctxt);
	gp->sigcode1 = SIG_CODE1(info, ctxt);
	gp->sigpc = SIG_RIP(info, ctxt);

	#ifdef GOOS_darwin
	// Work around Leopard bug that doesn't set FPE_INTDIV.
	// Look at instruction to see if it is a divide.
	// Not necessary in Snow Leopard (si_code will be != 0).
	if(sig == SIGFPE && gp->sigcode0 == 0) {
	byte *pc;
	pc = (byte*)gp->sigpc;
	if((pc[0]&0xF0) == 0x40) // 64-bit REX prefix
	pc++;
	else if(pc[0] == 0x66) // 16-bit instruction prefix
	pc++;
	if(pc[0] == 0xF6 \|\| pc[0] == 0xF7)
	gp->sigcode0 = FPE_INTDIV;
	}
	#endif

	// Only push runtime·sigpanic if rip != 0.
	// If rip == 0, probably panicked because of a
	// call to a nil func. Not pushing that onto sp will
	// make the trace look like a call to runtime·sigpanic instead.
	// (Otherwise the trace will end at runtime·sigpanic and we
	// won't get to see who faulted.)
	if(SIG_RIP(info, ctxt) != 0) {
	sp = (uintptr*)SIG_RSP(info, ctxt);
	if(sizeof(uintreg) > sizeof(uintptr))
	*--sp = 0;
	*--sp = SIG_RIP(info, ctxt);
	SIG_RSP(info, ctxt) = (uintptr)sp;
	}
	SIG_RIP(info, ctxt) = (uintptr)runtime·sigpanic;
	return;
	}

	if(SIG_CODE0(info, ctxt) == SI_USER \|\| (t->flags & SigNotify))
	if(runtime·sigsend(sig))
	return;
	if(t->flags & SigKill)
	runtime·exit(2);
	if(!(t->flags & SigThrow))
	return;

	g->m->throwing = 1;
	g->m->caughtsig = gp;
	runtime·startpanic();

	if(sig < 0 \|\| sig >= NSIG)
	runtime·printf("Signal %d\n", sig);
	else
	runtime·printf("%s\n", runtime·sigtab[sig].name);

	runtime·printf("PC=%X\n", SIG_RIP(info, ctxt));
	if(g->m->lockedg != nil && g->m->ncgo > 0 && gp == g->m->g0) {
	runtime·printf("signal arrived during cgo execution\n");
	gp = g->m->lockedg;
	}
	runtime·printf("\n");

	if(runtime·gotraceback(&crash)){
	runtime·goroutineheader(gp);
	runtime·tracebacktrap(SIG_RIP(info, ctxt), SIG_RSP(info, ctxt), 0, gp);
	runtime·tracebackothers(gp);
	runtime·printf("\n");
	runtime·dumpregs(info, ctxt);
	}

	if(crash)
	runtime·crash();

	runtime·exit(2);
	}