libgo/runtime/go-signal.c - gofrontend - Git at Google

 /* go-signal.c -- signal handling for Go.

    Copyright 2009 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 <signal.h>
 #include <stdlib.h>
 #include <unistd.h>
 #include <sys/time.h>
 #include <ucontext.h>

 #include "runtime.h"

 #ifndef SA_RESTART
   #define SA_RESTART 0
 #endif

 #ifdef USING_SPLIT_STACK

 extern void __splitstack_getcontext(void *context[10]);

 extern void __splitstack_setcontext(void *context[10]);

 extern void *__splitstack_find_context(void *context[10], size_t *,
 				       void **, void **, void **);

 #endif

 // The rest of the signal handler, written in Go.

 extern void sigtrampgo(uint32, siginfo_t *, void *)
 	__asm__(GOSYM_PREFIX "runtime.sigtrampgo");

 // The Go signal handler, written in C.  This should be running on the
 // alternate signal stack.  This is responsible for setting up the
 // split stack context so that stack guard checks will work as
 // expected.

 void sigtramp(int, siginfo_t *, void *)
 	__attribute__ ((no_split_stack));

 void sigtramp(int, siginfo_t *, void *)
 	__asm__ (GOSYM_PREFIX "runtime.sigtramp");

 #ifndef USING_SPLIT_STACK

 // When not using split stacks, there are no stack checks, and there
 // is nothing special for this function to do.

 void
 sigtramp(int sig, siginfo_t *info, void *context)
 {
 	sigtrampgo(sig, info, context);
 }

 #else // USING_SPLIT_STACK

 void
 sigtramp(int sig, siginfo_t *info, void *context)
 {
 	G *gp;
 	void *stack_context[10];
 	void *stack;
 	size_t stack_size;
 	void *next_segment;
 	void *next_sp;
 	void *initial_sp;
 	uintptr sp;
 	stack_t st;
 	uintptr stsp;

 	gp = runtime_g();

 	if (gp == nil) {
 		// Let the Go code handle this case.
 		// It should only call nosplit functions in this case.
 		sigtrampgo(sig, info, context);
 		return;
 	}

 	// If this signal is one for which we will panic, we are not
 	// on the alternate signal stack.  It's OK to call split-stack
 	// functions here.
 	if (sig == SIGBUS || sig == SIGFPE || sig == SIGSEGV) {
 		sigtrampgo(sig, info, context);
 		return;
 	}

 	// We are running on the alternate signal stack.

 	__splitstack_getcontext(&stack_context[0]);

 	stack = __splitstack_find_context((void*)(&gp->m->gsignal->stackcontext[0]),
 					  &stack_size, &next_segment,
 					  &next_sp, &initial_sp);

 	// If some non-Go code called sigaltstack, adjust.
 	sp = (uintptr)(&stack_size);
 	if (sp < (uintptr)(stack) || sp >= (uintptr)(stack) + stack_size) {
 		sigaltstack(nil, &st);
 		if ((st.ss_flags & SS_DISABLE) != 0) {
 			runtime_printf("signal %d received on thread with no signal stack\n", (int32)(sig));
 			runtime_throw("non-Go code disabled sigaltstack");
 		}

 		stsp = (uintptr)(st.ss_sp);
 		if (sp < stsp || sp >= stsp + st.ss_size) {
 			runtime_printf("signal %d received but handler not on signal stack\n", (int32)(sig));
 			runtime_throw("non-Go code set up signal handler without SA_ONSTACK flag");
 		}

 		// Unfortunately __splitstack_find_context will return NULL
 		// when it is called on a context that has never been used.
 		// There isn't much we can do but assume all is well.
 		if (stack != NULL) {
 			// Here the gc runtime adjusts the gsignal
 			// stack guard to match the values returned by
 			// sigaltstack.  Unfortunately we have no way
 			// to do that.
 			runtime_printf("signal %d received on unknown signal stack\n", (int32)(sig));
 			runtime_throw("non-Go code changed signal stack");
 		}
 	}

 	// Set the split stack context so that the stack guards are
 	// checked correctly.

 	__splitstack_setcontext((void*)(&gp->m->gsignal->stackcontext[0]));

 	sigtrampgo(sig, info, context);

 	// We are going to return back to the signal trampoline and
 	// then to whatever we were doing before we got the signal.
 	// Restore the split stack context so that stack guards are
 	// checked correctly.

 	__splitstack_setcontext(&stack_context[0]);
 }

 #endif // USING_SPLIT_STACK

 // C function to return the address of the sigtramp function.
 uintptr getSigtramp(void) __asm__ (GOSYM_PREFIX "runtime.getSigtramp");

 uintptr
 getSigtramp()
 {
   return (uintptr)(void*)sigtramp;
 }

 // C code to manage the sigaction sa_sigaction field, which is
 // typically a union and so hard for mksysinfo.sh to handle.

 uintptr getSigactionHandler(struct sigaction*)
 	__attribute__ ((no_split_stack));

 uintptr getSigactionHandler(struct sigaction*)
 	__asm__ (GOSYM_PREFIX "runtime.getSigactionHandler");

 uintptr
 getSigactionHandler(struct sigaction* sa)
 {
 	return (uintptr)(sa->sa_sigaction);
 }

 void setSigactionHandler(struct sigaction*, uintptr)
 	__attribute__ ((no_split_stack));

 void setSigactionHandler(struct sigaction*, uintptr)
 	__asm__ (GOSYM_PREFIX "runtime.setSigactionHandler");

 void
 setSigactionHandler(struct sigaction* sa, uintptr handler)
 {
 	sa->sa_sigaction = (void*)(handler);
 }

 // C code to fetch values from the siginfo_t and ucontext_t pointers
 // passed to a signal handler.

 uintptr getSiginfoCode(siginfo_t *)
 	__attribute__ ((no_split_stack));

 uintptr getSiginfoCode(siginfo_t *)
 	__asm__ (GOSYM_PREFIX "runtime.getSiginfoCode");

 uintptr
 getSiginfoCode(siginfo_t *info)
 {
 	return (uintptr)(info->si_code);
 }

 struct getSiginfoRet {
 	uintptr sigaddr;
 	uintptr sigpc;
 };

 struct getSiginfoRet getSiginfo(siginfo_t *, void *)
 	__asm__(GOSYM_PREFIX "runtime.getSiginfo");

 struct getSiginfoRet
 getSiginfo(siginfo_t *info, void *context __attribute__((unused)))
 {
 	struct getSiginfoRet ret;
 	Location loc[1];
 	int32 n;

 	if (info == nil) {
 		ret.sigaddr = 0;
 	} else {
 		ret.sigaddr = (uintptr)(info->si_addr);
 	}
 	ret.sigpc = 0;

 	// There doesn't seem to be a portable way to get the PC.
 	// Use unportable code to pull it from context, and if that fails
 	// try a stack backtrace across the signal handler.

 #if defined(__x86_64__) && defined(__linux__)
 	ret.sigpc = ((ucontext_t*)(context))->uc_mcontext.gregs[REG_RIP];
 #elif defined(__i386__) && defined(__linux__)
 	ret.sigpc = ((ucontext_t*)(context))->uc_mcontext.gregs[REG_EIP];
 #elif defined(__alpha__) && defined(__linux__)
 	ret.sigpc = ((ucontext_t*)(context))->uc_mcontext.sc_pc;
 #elif defined(__PPC__) && defined(__linux__)
 	ret.sigpc = ((ucontext_t*)(context))->uc_mcontext.regs->nip;
 #elif defined(__PPC__) && defined(_AIX)
 	ret.sigpc = ((ucontext_t*)(context))->uc_mcontext.jmp_context.iar;
 #elif defined(__aarch64__) && defined(__linux__)
 	ret.sigpc = ((ucontext_t*)(context))->uc_mcontext.pc;
 #elif defined(__NetBSD__)
 	ret.sigpc = _UC_MACHINE_PC(((ucontext_t*)(context)));
 #endif

 	if (ret.sigpc == 0) {
 		// Skip getSiginfo/sighandler/sigtrampgo/sigtramp/handler.
 		n = runtime_callers(5, &loc[0], 1, false);
 		if (n > 0) {
 			ret.sigpc = loc[0].pc;
 		}
 	}

 	return ret;
 }

 // Dump registers when crashing in a signal.
 // There is no portable way to write this,
 // so we just have some CPU/OS specific implementations.

 void dumpregs(siginfo_t *, void *)
 	__asm__(GOSYM_PREFIX "runtime.dumpregs");

 void
 dumpregs(siginfo_t *info __attribute__((unused)), void *context __attribute__((unused)))
 {
 #if defined(__x86_64__) && defined(__linux__)
 	{
 		mcontext_t *m = &((ucontext_t*)(context))->uc_mcontext;

 		runtime_printf("rax    %X\n", m->gregs[REG_RAX]);
 		runtime_printf("rbx    %X\n", m->gregs[REG_RBX]);
 		runtime_printf("rcx    %X\n", m->gregs[REG_RCX]);
 		runtime_printf("rdx    %X\n", m->gregs[REG_RDX]);
 		runtime_printf("rdi    %X\n", m->gregs[REG_RDI]);
 		runtime_printf("rsi    %X\n", m->gregs[REG_RSI]);
 		runtime_printf("rbp    %X\n", m->gregs[REG_RBP]);
 		runtime_printf("rsp    %X\n", m->gregs[REG_RSP]);
 		runtime_printf("r8     %X\n", m->gregs[REG_R8]);
 		runtime_printf("r9     %X\n", m->gregs[REG_R9]);
 		runtime_printf("r10    %X\n", m->gregs[REG_R10]);
 		runtime_printf("r11    %X\n", m->gregs[REG_R11]);
 		runtime_printf("r12    %X\n", m->gregs[REG_R12]);
 		runtime_printf("r13    %X\n", m->gregs[REG_R13]);
 		runtime_printf("r14    %X\n", m->gregs[REG_R14]);
 		runtime_printf("r15    %X\n", m->gregs[REG_R15]);
 		runtime_printf("rip    %X\n", m->gregs[REG_RIP]);
 		runtime_printf("rflags %X\n", m->gregs[REG_EFL]);
 		runtime_printf("cs     %X\n", m->gregs[REG_CSGSFS] & 0xffff);
 		runtime_printf("fs     %X\n", (m->gregs[REG_CSGSFS] >> 16) & 0xffff);
 		runtime_printf("gs     %X\n", (m->gregs[REG_CSGSFS] >> 32) & 0xffff);
 	  }
 #elif defined(__i386__) && defined(__linux__)
 	{
 		mcontext_t *m = &((ucontext_t*)(context))->uc_mcontext;

 		runtime_printf("eax    %x\n", m->gregs[REG_EAX]);
 		runtime_printf("ebx    %x\n", m->gregs[REG_EBX]);
 		runtime_printf("ecx    %x\n", m->gregs[REG_ECX]);
 		runtime_printf("edx    %x\n", m->gregs[REG_EDX]);
 		runtime_printf("edi    %x\n", m->gregs[REG_EDI]);
 		runtime_printf("esi    %x\n", m->gregs[REG_ESI]);
 		runtime_printf("ebp    %x\n", m->gregs[REG_EBP]);
 		runtime_printf("esp    %x\n", m->gregs[REG_ESP]);
 		runtime_printf("eip    %x\n", m->gregs[REG_EIP]);
 		runtime_printf("eflags %x\n", m->gregs[REG_EFL]);
 		runtime_printf("cs     %x\n", m->gregs[REG_CS]);
 		runtime_printf("fs     %x\n", m->gregs[REG_FS]);
 		runtime_printf("gs     %x\n", m->gregs[REG_GS]);
 	  }
 #elif defined(__alpha__) && defined(__linux__)
 	{
 		mcontext_t *m = &((ucontext_t*)(context))->uc_mcontext;

 		runtime_printf("v0  %X\n", m->sc_regs[0]);
 		runtime_printf("t0  %X\n", m->sc_regs[1]);
 		runtime_printf("t1  %X\n", m->sc_regs[2]);
 		runtime_printf("t2  %X\n", m->sc_regs[3]);
 		runtime_printf("t3  %X\n", m->sc_regs[4]);
 		runtime_printf("t4  %X\n", m->sc_regs[5]);
 		runtime_printf("t5  %X\n", m->sc_regs[6]);
 		runtime_printf("t6  %X\n", m->sc_regs[7]);
 		runtime_printf("t7  %X\n", m->sc_regs[8]);
 		runtime_printf("s0  %X\n", m->sc_regs[9]);
 		runtime_printf("s1  %X\n", m->sc_regs[10]);
 		runtime_printf("s2  %X\n", m->sc_regs[11]);
 		runtime_printf("s3  %X\n", m->sc_regs[12]);
 		runtime_printf("s4  %X\n", m->sc_regs[13]);
 		runtime_printf("s5  %X\n", m->sc_regs[14]);
 		runtime_printf("fp  %X\n", m->sc_regs[15]);
 		runtime_printf("a0  %X\n", m->sc_regs[16]);
 		runtime_printf("a1  %X\n", m->sc_regs[17]);
 		runtime_printf("a2  %X\n", m->sc_regs[18]);
 		runtime_printf("a3  %X\n", m->sc_regs[19]);
 		runtime_printf("a4  %X\n", m->sc_regs[20]);
 		runtime_printf("a5  %X\n", m->sc_regs[21]);
 		runtime_printf("t8  %X\n", m->sc_regs[22]);
 		runtime_printf("t9  %X\n", m->sc_regs[23]);
 		runtime_printf("t10 %X\n", m->sc_regs[24]);
 		runtime_printf("t11 %X\n", m->sc_regs[25]);
 		runtime_printf("ra  %X\n", m->sc_regs[26]);
 		runtime_printf("t12 %X\n", m->sc_regs[27]);
 		runtime_printf("at  %X\n", m->sc_regs[28]);
 		runtime_printf("gp  %X\n", m->sc_regs[29]);
 		runtime_printf("sp  %X\n", m->sc_regs[30]);
 		runtime_printf("pc  %X\n", m->sc_pc);
 	  }
 #elif defined(__PPC__) && defined(__LITTLE_ENDIAN__) && defined(__linux__)
 	  {
 		mcontext_t *m = &((ucontext_t*)(context))->uc_mcontext;
 		int i;

 		for (i = 0; i < 32; i++)
 			runtime_printf("r%d %X\n", i, m->regs->gpr[i]);
 		runtime_printf("pc  %X\n", m->regs->nip);
 		runtime_printf("msr %X\n", m->regs->msr);
 		runtime_printf("cr  %X\n", m->regs->ccr);
 		runtime_printf("lr  %X\n", m->regs->link);
 		runtime_printf("ctr %X\n", m->regs->ctr);
 		runtime_printf("xer %X\n", m->regs->xer);
 	  }
 #elif defined(__PPC__) && defined(_AIX)
 	  {
 		mcontext_t *m = &((ucontext_t*)(context))->uc_mcontext;
 		int i;

 		for (i = 0; i < 32; i++)
 			runtime_printf("r%d %p\n", i, m->jmp_context.gpr[i]);
 		runtime_printf("pc  %p\n", m->jmp_context.iar);
 		runtime_printf("msr %p\n", m->jmp_context.msr);
 		runtime_printf("cr  %x\n", m->jmp_context.cr);
 		runtime_printf("lr  %p\n", m->jmp_context.lr);
 		runtime_printf("ctr %p\n", m->jmp_context.ctr);
 		runtime_printf("xer %x\n", m->jmp_context.xer);
 	  }
 #elif defined(__aarch64__) && defined(__linux__)
 	  {
 		mcontext_t *m = &((ucontext_t*)(context))->uc_mcontext;
 		int i;

 		for (i = 0; i < 31; i++)
 			runtime_printf("x%d    %X\n", i, m->regs[i]);
 		runtime_printf("sp     %X\n", m->sp);
 		runtime_printf("pc     %X\n", m->pc);
 		runtime_printf("pstate %X\n", m->pstate);
 	  }
 #endif
 }
	/* go-signal.c -- signal handling for Go.

	Copyright 2009 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 <signal.h>
	#include <stdlib.h>
	#include <unistd.h>
	#include <sys/time.h>
	#include <ucontext.h>

	#include "runtime.h"

	#ifndef SA_RESTART
	#define SA_RESTART 0
	#endif

	#ifdef USING_SPLIT_STACK

	extern void __splitstack_getcontext(void *context[10]);

	extern void __splitstack_setcontext(void *context[10]);

	extern void __splitstack_find_context(void context[10], size_t *,
	void , void , void **);

	#endif

	// The rest of the signal handler, written in Go.

	extern void sigtrampgo(uint32, siginfo_t , void )
	__asm__(GOSYM_PREFIX "runtime.sigtrampgo");

	// The Go signal handler, written in C. This should be running on the
	// alternate signal stack. This is responsible for setting up the
	// split stack context so that stack guard checks will work as
	// expected.

	void sigtramp(int, siginfo_t , void )
	__attribute__ ((no_split_stack));

	void sigtramp(int, siginfo_t , void )
	__asm__ (GOSYM_PREFIX "runtime.sigtramp");

	#ifndef USING_SPLIT_STACK

	// When not using split stacks, there are no stack checks, and there
	// is nothing special for this function to do.

	void
	sigtramp(int sig, siginfo_t info, void context)
	{
	sigtrampgo(sig, info, context);
	}

	#else // USING_SPLIT_STACK

	void
	sigtramp(int sig, siginfo_t info, void context)
	{
	G *gp;
	void *stack_context[10];
	void *stack;
	size_t stack_size;
	void *next_segment;
	void *next_sp;
	void *initial_sp;
	uintptr sp;
	stack_t st;
	uintptr stsp;

	gp = runtime_g();

	if (gp == nil) {
	// Let the Go code handle this case.
	// It should only call nosplit functions in this case.
	sigtrampgo(sig, info, context);
	return;
	}

	// If this signal is one for which we will panic, we are not
	// on the alternate signal stack. It's OK to call split-stack
	// functions here.
	if (sig == SIGBUS \|\| sig == SIGFPE \|\| sig == SIGSEGV) {
	sigtrampgo(sig, info, context);
	return;
	}

	// We are running on the alternate signal stack.

	__splitstack_getcontext(&stack_context[0]);

	stack = __splitstack_find_context((void*)(&gp->m->gsignal->stackcontext[0]),
	&stack_size, &next_segment,
	&next_sp, &initial_sp);

	// If some non-Go code called sigaltstack, adjust.
	sp = (uintptr)(&stack_size);
	if (sp < (uintptr)(stack) \|\| sp >= (uintptr)(stack) + stack_size) {
	sigaltstack(nil, &st);
	if ((st.ss_flags & SS_DISABLE) != 0) {
	runtime_printf("signal %d received on thread with no signal stack\n", (int32)(sig));
	runtime_throw("non-Go code disabled sigaltstack");
	}

	stsp = (uintptr)(st.ss_sp);
	if (sp < stsp \|\| sp >= stsp + st.ss_size) {
	runtime_printf("signal %d received but handler not on signal stack\n", (int32)(sig));
	runtime_throw("non-Go code set up signal handler without SA_ONSTACK flag");
	}

	// Unfortunately __splitstack_find_context will return NULL
	// when it is called on a context that has never been used.
	// There isn't much we can do but assume all is well.
	if (stack != NULL) {
	// Here the gc runtime adjusts the gsignal
	// stack guard to match the values returned by
	// sigaltstack. Unfortunately we have no way
	// to do that.
	runtime_printf("signal %d received on unknown signal stack\n", (int32)(sig));
	runtime_throw("non-Go code changed signal stack");
	}
	}

	// Set the split stack context so that the stack guards are
	// checked correctly.

	__splitstack_setcontext((void*)(&gp->m->gsignal->stackcontext[0]));

	sigtrampgo(sig, info, context);

	// We are going to return back to the signal trampoline and
	// then to whatever we were doing before we got the signal.
	// Restore the split stack context so that stack guards are
	// checked correctly.

	__splitstack_setcontext(&stack_context[0]);
	}

	#endif // USING_SPLIT_STACK

	// C function to return the address of the sigtramp function.
	uintptr getSigtramp(void) __asm__ (GOSYM_PREFIX "runtime.getSigtramp");

	uintptr
	getSigtramp()
	{
	return (uintptr)(void*)sigtramp;
	}

	// C code to manage the sigaction sa_sigaction field, which is
	// typically a union and so hard for mksysinfo.sh to handle.

	uintptr getSigactionHandler(struct sigaction*)
	__attribute__ ((no_split_stack));

	uintptr getSigactionHandler(struct sigaction*)
	__asm__ (GOSYM_PREFIX "runtime.getSigactionHandler");

	uintptr
	getSigactionHandler(struct sigaction* sa)
	{
	return (uintptr)(sa->sa_sigaction);
	}

	void setSigactionHandler(struct sigaction*, uintptr)
	__attribute__ ((no_split_stack));

	void setSigactionHandler(struct sigaction*, uintptr)
	__asm__ (GOSYM_PREFIX "runtime.setSigactionHandler");

	void
	setSigactionHandler(struct sigaction* sa, uintptr handler)
	{
	sa->sa_sigaction = (void*)(handler);
	}

	// C code to fetch values from the siginfo_t and ucontext_t pointers
	// passed to a signal handler.

	uintptr getSiginfoCode(siginfo_t *)
	__attribute__ ((no_split_stack));

	uintptr getSiginfoCode(siginfo_t *)
	__asm__ (GOSYM_PREFIX "runtime.getSiginfoCode");

	uintptr
	getSiginfoCode(siginfo_t *info)
	{
	return (uintptr)(info->si_code);
	}

	struct getSiginfoRet {
	uintptr sigaddr;
	uintptr sigpc;
	};

	struct getSiginfoRet getSiginfo(siginfo_t , void )
	__asm__(GOSYM_PREFIX "runtime.getSiginfo");

	struct getSiginfoRet
	getSiginfo(siginfo_t info, void context __attribute__((unused)))
	{
	struct getSiginfoRet ret;
	Location loc[1];
	int32 n;

	if (info == nil) {
	ret.sigaddr = 0;
	} else {
	ret.sigaddr = (uintptr)(info->si_addr);
	}
	ret.sigpc = 0;

	// There doesn't seem to be a portable way to get the PC.
	// Use unportable code to pull it from context, and if that fails
	// try a stack backtrace across the signal handler.

	#if defined(__x86_64__) && defined(__linux__)
	ret.sigpc = ((ucontext_t*)(context))->uc_mcontext.gregs[REG_RIP];
	#elif defined(__i386__) && defined(__linux__)
	ret.sigpc = ((ucontext_t*)(context))->uc_mcontext.gregs[REG_EIP];
	#elif defined(__alpha__) && defined(__linux__)
	ret.sigpc = ((ucontext_t*)(context))->uc_mcontext.sc_pc;
	#elif defined(__PPC__) && defined(__linux__)
	ret.sigpc = ((ucontext_t*)(context))->uc_mcontext.regs->nip;
	#elif defined(__PPC__) && defined(_AIX)
	ret.sigpc = ((ucontext_t*)(context))->uc_mcontext.jmp_context.iar;
	#elif defined(__aarch64__) && defined(__linux__)
	ret.sigpc = ((ucontext_t*)(context))->uc_mcontext.pc;
	#elif defined(__NetBSD__)
	ret.sigpc = _UC_MACHINE_PC(((ucontext_t*)(context)));
	#endif

	if (ret.sigpc == 0) {
	// Skip getSiginfo/sighandler/sigtrampgo/sigtramp/handler.
	n = runtime_callers(5, &loc[0], 1, false);
	if (n > 0) {
	ret.sigpc = loc[0].pc;
	}
	}

	return ret;
	}

	// Dump registers when crashing in a signal.
	// There is no portable way to write this,
	// so we just have some CPU/OS specific implementations.

	void dumpregs(siginfo_t , void )
	__asm__(GOSYM_PREFIX "runtime.dumpregs");

	void
	dumpregs(siginfo_t info __attribute__((unused)), void context __attribute__((unused)))
	{
	#if defined(__x86_64__) && defined(__linux__)
	{
	mcontext_t m = &((ucontext_t)(context))->uc_mcontext;

	runtime_printf("rax %X\n", m->gregs[REG_RAX]);
	runtime_printf("rbx %X\n", m->gregs[REG_RBX]);
	runtime_printf("rcx %X\n", m->gregs[REG_RCX]);
	runtime_printf("rdx %X\n", m->gregs[REG_RDX]);
	runtime_printf("rdi %X\n", m->gregs[REG_RDI]);
	runtime_printf("rsi %X\n", m->gregs[REG_RSI]);
	runtime_printf("rbp %X\n", m->gregs[REG_RBP]);
	runtime_printf("rsp %X\n", m->gregs[REG_RSP]);
	runtime_printf("r8 %X\n", m->gregs[REG_R8]);
	runtime_printf("r9 %X\n", m->gregs[REG_R9]);
	runtime_printf("r10 %X\n", m->gregs[REG_R10]);
	runtime_printf("r11 %X\n", m->gregs[REG_R11]);
	runtime_printf("r12 %X\n", m->gregs[REG_R12]);
	runtime_printf("r13 %X\n", m->gregs[REG_R13]);
	runtime_printf("r14 %X\n", m->gregs[REG_R14]);
	runtime_printf("r15 %X\n", m->gregs[REG_R15]);
	runtime_printf("rip %X\n", m->gregs[REG_RIP]);
	runtime_printf("rflags %X\n", m->gregs[REG_EFL]);
	runtime_printf("cs %X\n", m->gregs[REG_CSGSFS] & 0xffff);
	runtime_printf("fs %X\n", (m->gregs[REG_CSGSFS] >> 16) & 0xffff);
	runtime_printf("gs %X\n", (m->gregs[REG_CSGSFS] >> 32) & 0xffff);
	}
	#elif defined(__i386__) && defined(__linux__)
	{
	mcontext_t m = &((ucontext_t)(context))->uc_mcontext;

	runtime_printf("eax %x\n", m->gregs[REG_EAX]);
	runtime_printf("ebx %x\n", m->gregs[REG_EBX]);
	runtime_printf("ecx %x\n", m->gregs[REG_ECX]);
	runtime_printf("edx %x\n", m->gregs[REG_EDX]);
	runtime_printf("edi %x\n", m->gregs[REG_EDI]);
	runtime_printf("esi %x\n", m->gregs[REG_ESI]);
	runtime_printf("ebp %x\n", m->gregs[REG_EBP]);
	runtime_printf("esp %x\n", m->gregs[REG_ESP]);
	runtime_printf("eip %x\n", m->gregs[REG_EIP]);
	runtime_printf("eflags %x\n", m->gregs[REG_EFL]);
	runtime_printf("cs %x\n", m->gregs[REG_CS]);
	runtime_printf("fs %x\n", m->gregs[REG_FS]);
	runtime_printf("gs %x\n", m->gregs[REG_GS]);
	}
	#elif defined(__alpha__) && defined(__linux__)
	{
	mcontext_t m = &((ucontext_t)(context))->uc_mcontext;

	runtime_printf("v0 %X\n", m->sc_regs[0]);
	runtime_printf("t0 %X\n", m->sc_regs[1]);
	runtime_printf("t1 %X\n", m->sc_regs[2]);
	runtime_printf("t2 %X\n", m->sc_regs[3]);
	runtime_printf("t3 %X\n", m->sc_regs[4]);
	runtime_printf("t4 %X\n", m->sc_regs[5]);
	runtime_printf("t5 %X\n", m->sc_regs[6]);
	runtime_printf("t6 %X\n", m->sc_regs[7]);
	runtime_printf("t7 %X\n", m->sc_regs[8]);
	runtime_printf("s0 %X\n", m->sc_regs[9]);
	runtime_printf("s1 %X\n", m->sc_regs[10]);
	runtime_printf("s2 %X\n", m->sc_regs[11]);
	runtime_printf("s3 %X\n", m->sc_regs[12]);
	runtime_printf("s4 %X\n", m->sc_regs[13]);
	runtime_printf("s5 %X\n", m->sc_regs[14]);
	runtime_printf("fp %X\n", m->sc_regs[15]);
	runtime_printf("a0 %X\n", m->sc_regs[16]);
	runtime_printf("a1 %X\n", m->sc_regs[17]);
	runtime_printf("a2 %X\n", m->sc_regs[18]);
	runtime_printf("a3 %X\n", m->sc_regs[19]);
	runtime_printf("a4 %X\n", m->sc_regs[20]);
	runtime_printf("a5 %X\n", m->sc_regs[21]);
	runtime_printf("t8 %X\n", m->sc_regs[22]);
	runtime_printf("t9 %X\n", m->sc_regs[23]);
	runtime_printf("t10 %X\n", m->sc_regs[24]);
	runtime_printf("t11 %X\n", m->sc_regs[25]);
	runtime_printf("ra %X\n", m->sc_regs[26]);
	runtime_printf("t12 %X\n", m->sc_regs[27]);
	runtime_printf("at %X\n", m->sc_regs[28]);
	runtime_printf("gp %X\n", m->sc_regs[29]);
	runtime_printf("sp %X\n", m->sc_regs[30]);
	runtime_printf("pc %X\n", m->sc_pc);
	}
	#elif defined(__PPC__) && defined(__LITTLE_ENDIAN__) && defined(__linux__)
	{
	mcontext_t m = &((ucontext_t)(context))->uc_mcontext;
	int i;

	for (i = 0; i < 32; i++)
	runtime_printf("r%d %X\n", i, m->regs->gpr[i]);
	runtime_printf("pc %X\n", m->regs->nip);
	runtime_printf("msr %X\n", m->regs->msr);
	runtime_printf("cr %X\n", m->regs->ccr);
	runtime_printf("lr %X\n", m->regs->link);
	runtime_printf("ctr %X\n", m->regs->ctr);
	runtime_printf("xer %X\n", m->regs->xer);
	}
	#elif defined(__PPC__) && defined(_AIX)
	{
	mcontext_t m = &((ucontext_t)(context))->uc_mcontext;
	int i;

	for (i = 0; i < 32; i++)
	runtime_printf("r%d %p\n", i, m->jmp_context.gpr[i]);
	runtime_printf("pc %p\n", m->jmp_context.iar);
	runtime_printf("msr %p\n", m->jmp_context.msr);
	runtime_printf("cr %x\n", m->jmp_context.cr);
	runtime_printf("lr %p\n", m->jmp_context.lr);
	runtime_printf("ctr %p\n", m->jmp_context.ctr);
	runtime_printf("xer %x\n", m->jmp_context.xer);
	}
	#elif defined(__aarch64__) && defined(__linux__)
	{
	mcontext_t m = &((ucontext_t)(context))->uc_mcontext;
	int i;

	for (i = 0; i < 31; i++)
	runtime_printf("x%d %X\n", i, m->regs[i]);
	runtime_printf("sp %X\n", m->sp);
	runtime_printf("pc %X\n", m->pc);
	runtime_printf("pstate %X\n", m->pstate);
	}
	#endif
	}