src/pkg/runtime/traceback_x86.c - go - Git at Google

 // 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.

 // +build amd64 386

 #include "runtime.h"
 #include "arch_GOARCH.h"
 #include "malloc.h"

 static uintptr isclosureentry(uintptr);
 void runtime·deferproc(void);
 void runtime·newproc(void);
 void runtime·newstack(void);
 void runtime·morestack(void);
 void runtime·sigpanic(void);

 // This code is also used for the 386 tracebacks.
 // Use uintptr for an appropriate word-sized integer.

 // Generic traceback.  Handles runtime stack prints (pcbuf == nil)
 // as well as the runtime.Callers function (pcbuf != nil).
 // A little clunky to merge the two but avoids duplicating
 // the code and all its subtlety.
 int32
 runtime·gentraceback(byte *pc0, byte *sp, byte *lr0, G *g, int32 skip, uintptr *pcbuf, int32 max)
 {
 	byte *p;
 	int32 i, n, iter, sawnewstack;
 	uintptr pc, lr, tracepc;
 	byte *fp;
 	Stktop *stk;
 	Func *f;
 	bool waspanic;

 	USED(lr0);
 	pc = (uintptr)pc0;
 	lr = 0;
 	fp = nil;
 	waspanic = false;

 	// If the PC is goexit, the goroutine hasn't started yet.
 	if(pc0 == g->sched.pc && sp == g->sched.sp && pc0 == (byte*)runtime·goexit) {
 		fp = sp;
 		lr = pc;
 		pc = (uintptr)g->entry;
 	}

 	// If the PC is zero, it's likely a nil function call.
 	// Start in the caller's frame.
 	if(pc == 0) {
 		pc = lr;
 		lr = 0;
 	}

 	// If the PC is zero, it's likely a nil function call.
 	// Start in the caller's frame.
 	if(pc == 0) {
 		pc = *(uintptr*)sp;
 		sp += sizeof(uintptr);
 	}

 	n = 0;
 	sawnewstack = 0;
 	stk = (Stktop*)g->stackbase;
 	for(iter = 0; iter < 100 && n < max; iter++) {	// iter avoids looping forever
 		// Typically:
 		//	pc is the PC of the running function.
 		//	sp is the stack pointer at that program counter.
 		//	fp is the frame pointer (caller's stack pointer) at that program counter, or nil if unknown.
 		//	stk is the stack containing sp.
 		//	The caller's program counter is lr, unless lr is zero, in which case it is *(uintptr*)sp.

 		if(pc == (uintptr)runtime·lessstack) {
 			// Hit top of stack segment.  Unwind to next segment.
 			pc = (uintptr)stk->gobuf.pc;
 			sp = stk->gobuf.sp;
 			lr = 0;
 			fp = nil;
 			if(pcbuf == nil)
 				runtime·printf("----- stack segment boundary -----\n");
 			stk = (Stktop*)stk->stackbase;
 			continue;
 		}
 		if(pc <= 0x1000 || (f = runtime·findfunc(pc)) == nil) {
 			// Dangerous, but worthwhile: see if this is a closure:
 			//	ADDQ $wwxxyyzz, SP; RET
 			//	[48] 81 c4 zz yy xx ww c3
 			// The 0x48 byte is only on amd64.
 			p = (byte*)pc;
 			// We check p < p+8 to avoid wrapping and faulting if we lose track.
 			if(runtime·mheap.arena_start < p && p < p+8 && p+8 < runtime·mheap.arena_used &&  // pointer in allocated memory
 			   (sizeof(uintptr) != 8 || *p++ == 0x48) &&  // skip 0x48 byte on amd64
 			   p[0] == 0x81 && p[1] == 0xc4 && p[6] == 0xc3) {
 				sp += *(uint32*)(p+2);
 				pc = *(uintptr*)sp;
 				sp += sizeof(uintptr);
 				lr = 0;
 				fp = nil;
 				continue;
 			}

 			// Closure at top of stack, not yet started.
 			if(lr == (uintptr)runtime·goexit && (pc = isclosureentry(pc)) != 0) {
 				fp = sp;
 				continue;
 			}

 			// Unknown pc: stop.
 			break;
 		}

 		// Found an actual function.
 		if(fp == nil) {
 			fp = sp;
 			if(pc > f->entry && f->frame >= sizeof(uintptr))
 				fp += f->frame - sizeof(uintptr);
 			if(lr == 0)
 				lr = *(uintptr*)fp;
 			fp += sizeof(uintptr);
 		} else if(lr == 0)
 			lr = *(uintptr*)fp;

 		if(skip > 0)
 			skip--;
 		else if(pcbuf != nil)
 			pcbuf[n++] = pc;
 		else {
 			if(runtime·showframe(f)) {
 				// Print during crash.
 				//	main(0x1, 0x2, 0x3)
 				//		/home/rsc/go/src/runtime/x.go:23 +0xf
 				//
 				tracepc = pc;	// back up to CALL instruction for funcline.
 				if(n > 0 && pc > f->entry && !waspanic)
 					tracepc--;
 				runtime·printf("%S(", f->name);
 				for(i = 0; i < f->args; i++) {
 					if(i != 0)
 						runtime·prints(", ");
 					runtime·printhex(((uintptr*)fp)[i]);
 					if(i >= 4) {
 						runtime·prints(", ...");
 						break;
 					}
 				}
 				runtime·prints(")\n");
 				runtime·printf("\t%S:%d", f->src, runtime·funcline(f, tracepc));
 				if(pc > f->entry)
 					runtime·printf(" +%p", (uintptr)(pc - f->entry));
 				runtime·printf("\n");
 			}
 			n++;
 		}

 		waspanic = f->entry == (uintptr)runtime·sigpanic;

 		if(f->entry == (uintptr)runtime·deferproc || f->entry == (uintptr)runtime·newproc)
 			fp += 2*sizeof(uintptr);

 		if(f->entry == (uintptr)runtime·newstack)
 			sawnewstack = 1;

 		if(pcbuf == nil && f->entry == (uintptr)runtime·morestack && g == m->g0 && sawnewstack) {
 			// The fact that we saw newstack means that morestack
 			// has managed to record its information in m, so we can
 			// use it to keep unwinding the stack.
 			runtime·printf("----- morestack called from goroutine %d -----\n", m->curg->goid);
 			pc = (uintptr)m->morepc;
 			sp = m->morebuf.sp - sizeof(void*);
 			lr = (uintptr)m->morebuf.pc;
 			fp = m->morebuf.sp;
 			sawnewstack = 0;
 			g = m->curg;
 			stk = (Stktop*)g->stackbase;
 			continue;
 		}

 		if(pcbuf == nil && f->entry == (uintptr)runtime·lessstack && g == m->g0) {
 			// Lessstack is running on scheduler stack.  Switch to original goroutine.
 			runtime·printf("----- lessstack called from goroutine %d -----\n", m->curg->goid);
 			g = m->curg;
 			stk = (Stktop*)g->stackbase;
 			sp = stk->gobuf.sp;
 			pc = (uintptr)stk->gobuf.pc;
 			fp = nil;
 			lr = 0;
 			continue;
 		}

 		// Unwind to next frame.
 		pc = lr;
 		lr = 0;
 		sp = fp;
 		fp = nil;
 	}

 	// Show what created goroutine, except main goroutine (goid 1).
 	if(pcbuf == nil && (pc = g->gopc) != 0 && (f = runtime·findfunc(pc)) != nil && g->goid != 1) {
 		runtime·printf("created by %S\n", f->name);
 		tracepc = pc;	// back up to CALL instruction for funcline.
 		if(n > 0 && pc > f->entry)
 			tracepc--;
 		runtime·printf("\t%S:%d", f->src, runtime·funcline(f, tracepc));
 		if(pc > f->entry)
 			runtime·printf(" +%p", (uintptr)(pc - f->entry));
 		runtime·printf("\n");
 	}

 	return n;
 }

 void
 runtime·traceback(byte *pc0, byte *sp, byte*, G *g)
 {
 	runtime·gentraceback(pc0, sp, nil, g, 0, nil, 100);
 }

 int32
 runtime·callers(int32 skip, uintptr *pcbuf, int32 m)
 {
 	byte *pc, *sp;

 	// our caller's pc, sp.
 	sp = (byte*)&skip;
 	pc = runtime·getcallerpc(&skip);

 	return runtime·gentraceback(pc, sp, nil, g, skip, pcbuf, m);
 }

 static uintptr
 isclosureentry(uintptr pc)
 {
 	byte *p;
 	int32 i, siz;

 	p = (byte*)pc;
 	if(p < runtime·mheap.arena_start || p+32 > runtime·mheap.arena_used)
 		return 0;

 	if(*p == 0xe8) {
 		// CALL fn
 		return pc+5+*(int32*)(p+1);
 	}

 	if(sizeof(uintptr) == 8 && p[0] == 0x48 && p[1] == 0xb9 && p[10] == 0xff && p[11] == 0xd1) {
 		// MOVQ $fn, CX; CALL *CX
 		return *(uintptr*)(p+2);
 	}

 	// SUBQ $siz, SP
 	if((sizeof(uintptr) == 8 && *p++ != 0x48) || *p++ != 0x81 || *p++ != 0xec)
 		return 0;
 	siz = *(uint32*)p;
 	p += 4;

 	// MOVQ $q, SI
 	if((sizeof(uintptr) == 8 && *p++ != 0x48) || *p++ != 0xbe)
 		return 0;
 	p += sizeof(uintptr);

 	// MOVQ SP, DI
 	if((sizeof(uintptr) == 8 && *p++ != 0x48) || *p++ != 0x89 || *p++ != 0xe7)
 		return 0;

 	// CLD on 32-bit
 	if(sizeof(uintptr) == 4 && *p++ != 0xfc)
 		return 0;

 	if(siz <= 4*sizeof(uintptr)) {
 		// MOVSQ...
 		for(i=0; i<siz; i+=sizeof(uintptr))
 			if((sizeof(uintptr) == 8 && *p++ != 0x48) || *p++ != 0xa5)
 				return 0;
 	} else {
 		// MOVQ $(siz/8), CX  [32-bit immediate siz/8]
 		if((sizeof(uintptr) == 8 && *p++ != 0x48) || *p++ != 0xc7 || *p++ != 0xc1)
 			return 0;
 		p += 4;

 		// REP MOVSQ
 		if(*p++ != 0xf3 || (sizeof(uintptr) == 8 && *p++ != 0x48) || *p++ != 0xa5)
 			return 0;
 	}

 	// CALL fn
 	if(*p == 0xe8) {
 		p++;
 		return (uintptr)p+4 + *(int32*)p;
 	}

 	// MOVQ $fn, CX; CALL *CX
 	if(sizeof(uintptr) != 8 || *p++ != 0x48 || *p++ != 0xb9)
 		return 0;

 	pc = *(uintptr*)p;
 	p += 8;

 	if(*p++ != 0xff || *p != 0xd1)
 		return 0;

 	return pc;
 }
	// 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.

	// +build amd64 386

	#include "runtime.h"
	#include "arch_GOARCH.h"
	#include "malloc.h"

	static uintptr isclosureentry(uintptr);
	void runtime·deferproc(void);
	void runtime·newproc(void);
	void runtime·newstack(void);
	void runtime·morestack(void);
	void runtime·sigpanic(void);

	// This code is also used for the 386 tracebacks.
	// Use uintptr for an appropriate word-sized integer.

	// Generic traceback. Handles runtime stack prints (pcbuf == nil)
	// as well as the runtime.Callers function (pcbuf != nil).
	// A little clunky to merge the two but avoids duplicating
	// the code and all its subtlety.
	int32
	runtime·gentraceback(byte pc0, byte sp, byte lr0, G g, int32 skip, uintptr *pcbuf, int32 max)
	{
	byte *p;
	int32 i, n, iter, sawnewstack;
	uintptr pc, lr, tracepc;
	byte *fp;
	Stktop *stk;
	Func *f;
	bool waspanic;

	USED(lr0);
	pc = (uintptr)pc0;
	lr = 0;
	fp = nil;
	waspanic = false;

	// If the PC is goexit, the goroutine hasn't started yet.
	if(pc0 == g->sched.pc && sp == g->sched.sp && pc0 == (byte*)runtime·goexit) {
	fp = sp;
	lr = pc;
	pc = (uintptr)g->entry;
	}

	// If the PC is zero, it's likely a nil function call.
	// Start in the caller's frame.
	if(pc == 0) {
	pc = lr;
	lr = 0;
	}

	// If the PC is zero, it's likely a nil function call.
	// Start in the caller's frame.
	if(pc == 0) {
	pc = (uintptr)sp;
	sp += sizeof(uintptr);
	}

	n = 0;
	sawnewstack = 0;
	stk = (Stktop*)g->stackbase;
	for(iter = 0; iter < 100 && n < max; iter++) { // iter avoids looping forever
	// Typically:
	// pc is the PC of the running function.
	// sp is the stack pointer at that program counter.
	// fp is the frame pointer (caller's stack pointer) at that program counter, or nil if unknown.
	// stk is the stack containing sp.
	// The caller's program counter is lr, unless lr is zero, in which case it is (uintptr)sp.

	if(pc == (uintptr)runtime·lessstack) {
	// Hit top of stack segment. Unwind to next segment.
	pc = (uintptr)stk->gobuf.pc;
	sp = stk->gobuf.sp;
	lr = 0;
	fp = nil;
	if(pcbuf == nil)
	runtime·printf("----- stack segment boundary -----\n");
	stk = (Stktop*)stk->stackbase;
	continue;
	}
	if(pc <= 0x1000 \|\| (f = runtime·findfunc(pc)) == nil) {
	// Dangerous, but worthwhile: see if this is a closure:
	// ADDQ $wwxxyyzz, SP; RET
	// [48] 81 c4 zz yy xx ww c3
	// The 0x48 byte is only on amd64.
	p = (byte*)pc;
	// We check p < p+8 to avoid wrapping and faulting if we lose track.
	if(runtime·mheap.arena_start < p && p < p+8 && p+8 < runtime·mheap.arena_used && // pointer in allocated memory
	(sizeof(uintptr) != 8 \|\| *p++ == 0x48) && // skip 0x48 byte on amd64
	p[0] == 0x81 && p[1] == 0xc4 && p[6] == 0xc3) {
	sp += (uint32)(p+2);
	pc = (uintptr)sp;
	sp += sizeof(uintptr);
	lr = 0;
	fp = nil;
	continue;
	}

	// Closure at top of stack, not yet started.
	if(lr == (uintptr)runtime·goexit && (pc = isclosureentry(pc)) != 0) {
	fp = sp;
	continue;
	}

	// Unknown pc: stop.
	break;
	}

	// Found an actual function.
	if(fp == nil) {
	fp = sp;
	if(pc > f->entry && f->frame >= sizeof(uintptr))
	fp += f->frame - sizeof(uintptr);
	if(lr == 0)
	lr = (uintptr)fp;
	fp += sizeof(uintptr);
	} else if(lr == 0)
	lr = (uintptr)fp;

	if(skip > 0)
	skip--;
	else if(pcbuf != nil)
	pcbuf[n++] = pc;
	else {
	if(runtime·showframe(f)) {
	// Print during crash.
	// main(0x1, 0x2, 0x3)
	// /home/rsc/go/src/runtime/x.go:23 +0xf
	//
	tracepc = pc; // back up to CALL instruction for funcline.
	if(n > 0 && pc > f->entry && !waspanic)
	tracepc--;
	runtime·printf("%S(", f->name);
	for(i = 0; i < f->args; i++) {
	if(i != 0)
	runtime·prints(", ");
	runtime·printhex(((uintptr*)fp)[i]);
	if(i >= 4) {
	runtime·prints(", ...");
	break;
	}
	}
	runtime·prints(")\n");
	runtime·printf("\t%S:%d", f->src, runtime·funcline(f, tracepc));
	if(pc > f->entry)
	runtime·printf(" +%p", (uintptr)(pc - f->entry));
	runtime·printf("\n");
	}
	n++;
	}

	waspanic = f->entry == (uintptr)runtime·sigpanic;

	if(f->entry == (uintptr)runtime·deferproc \|\| f->entry == (uintptr)runtime·newproc)
	fp += 2*sizeof(uintptr);

	if(f->entry == (uintptr)runtime·newstack)
	sawnewstack = 1;

	if(pcbuf == nil && f->entry == (uintptr)runtime·morestack && g == m->g0 && sawnewstack) {
	// The fact that we saw newstack means that morestack
	// has managed to record its information in m, so we can
	// use it to keep unwinding the stack.
	runtime·printf("----- morestack called from goroutine %d -----\n", m->curg->goid);
	pc = (uintptr)m->morepc;
	sp = m->morebuf.sp - sizeof(void*);
	lr = (uintptr)m->morebuf.pc;
	fp = m->morebuf.sp;
	sawnewstack = 0;
	g = m->curg;
	stk = (Stktop*)g->stackbase;
	continue;
	}

	if(pcbuf == nil && f->entry == (uintptr)runtime·lessstack && g == m->g0) {
	// Lessstack is running on scheduler stack. Switch to original goroutine.
	runtime·printf("----- lessstack called from goroutine %d -----\n", m->curg->goid);
	g = m->curg;
	stk = (Stktop*)g->stackbase;
	sp = stk->gobuf.sp;
	pc = (uintptr)stk->gobuf.pc;
	fp = nil;
	lr = 0;
	continue;
	}

	// Unwind to next frame.
	pc = lr;
	lr = 0;
	sp = fp;
	fp = nil;
	}

	// Show what created goroutine, except main goroutine (goid 1).
	if(pcbuf == nil && (pc = g->gopc) != 0 && (f = runtime·findfunc(pc)) != nil && g->goid != 1) {
	runtime·printf("created by %S\n", f->name);
	tracepc = pc; // back up to CALL instruction for funcline.
	if(n > 0 && pc > f->entry)
	tracepc--;
	runtime·printf("\t%S:%d", f->src, runtime·funcline(f, tracepc));
	if(pc > f->entry)
	runtime·printf(" +%p", (uintptr)(pc - f->entry));
	runtime·printf("\n");
	}

	return n;
	}

	void
	runtime·traceback(byte pc0, byte sp, byte, G g)
	{
	runtime·gentraceback(pc0, sp, nil, g, 0, nil, 100);
	}

	int32
	runtime·callers(int32 skip, uintptr *pcbuf, int32 m)
	{
	byte pc, sp;

	// our caller's pc, sp.
	sp = (byte*)&skip;
	pc = runtime·getcallerpc(&skip);

	return runtime·gentraceback(pc, sp, nil, g, skip, pcbuf, m);
	}

	static uintptr
	isclosureentry(uintptr pc)
	{
	byte *p;
	int32 i, siz;

	p = (byte*)pc;
	if(p < runtime·mheap.arena_start \|\| p+32 > runtime·mheap.arena_used)
	return 0;

	if(*p == 0xe8) {
	// CALL fn
	return pc+5+(int32)(p+1);
	}

	if(sizeof(uintptr) == 8 && p[0] == 0x48 && p[1] == 0xb9 && p[10] == 0xff && p[11] == 0xd1) {
	// MOVQ $fn, CX; CALL *CX
	return (uintptr)(p+2);
	}

	// SUBQ $siz, SP
	if((sizeof(uintptr) == 8 && p++ != 0x48) \|\| p++ != 0x81 \|\| *p++ != 0xec)
	return 0;
	siz = (uint32)p;
	p += 4;

	// MOVQ $q, SI
	if((sizeof(uintptr) == 8 && p++ != 0x48) \|\| p++ != 0xbe)
	return 0;
	p += sizeof(uintptr);

	// MOVQ SP, DI
	if((sizeof(uintptr) == 8 && p++ != 0x48) \|\| p++ != 0x89 \|\| *p++ != 0xe7)
	return 0;

	// CLD on 32-bit
	if(sizeof(uintptr) == 4 && *p++ != 0xfc)
	return 0;

	if(siz <= 4*sizeof(uintptr)) {
	// MOVSQ...
	for(i=0; i<siz; i+=sizeof(uintptr))
	if((sizeof(uintptr) == 8 && p++ != 0x48) \|\| p++ != 0xa5)
	return 0;
	} else {
	// MOVQ $(siz/8), CX [32-bit immediate siz/8]
	if((sizeof(uintptr) == 8 && p++ != 0x48) \|\| p++ != 0xc7 \|\| *p++ != 0xc1)
	return 0;
	p += 4;

	// REP MOVSQ
	if(p++ != 0xf3 \|\| (sizeof(uintptr) == 8 && p++ != 0x48) \|\| *p++ != 0xa5)
	return 0;
	}

	// CALL fn
	if(*p == 0xe8) {
	p++;
	return (uintptr)p+4 + (int32)p;
	}

	// MOVQ $fn, CX; CALL *CX
	if(sizeof(uintptr) != 8 \|\| p++ != 0x48 \|\| p++ != 0xb9)
	return 0;

	pc = (uintptr)p;
	p += 8;

	if(p++ != 0xff \|\| p != 0xd1)
	return 0;

	return pc;
	}