ref: 88181e1c5c8d19e61c76b93620abcbc7c2e57481
dir: /sys/src/9/xen/trap.c/
#include "u.h" #include "tos.h" #include "../port/lib.h" #include "mem.h" #include "dat.h" #include "fns.h" #include "io.h" #include "ureg.h" #include "../port/error.h" #include <trace.h> #define INTRLOG(a) #define SETUPLOG(a) #define SYSCALLLOG(a) #define FAULTLOG(a) #define FAULTLOGFAST(a) #define POSTNOTELOG(a) #define TRAPLOG(a) int faultpanic = 0; enum { /* trap_info_t flags */ SPL0 = 0, SPL3 = 3, EvDisable = 4, }; void noted(Ureg*, ulong); extern void irqinit(void); extern int irqhandled(Ureg*, int); static void debugbpt(Ureg*, void*); static void fault386(Ureg*, void*); static void safe_fault386(Ureg*, void*); static void doublefault(Ureg*, void*); static void unexpected(Ureg*, void*); static void _dumpstack(Ureg*); /* we started out doing the 'giant bulk init' for all traps. * we're going to do them one-by-one since error analysis is * so much easier that way. */ void trapinit(void) { trap_info_t t[2]; ulong vaddr; int v, flag; HYPERVISOR_set_callbacks( KESEL, (ulong)hypervisor_callback, KESEL, (ulong)failsafe_callback); /* XXX rework as single hypercall once debugged */ t[1].address = 0; vaddr = (ulong)vectortable; for(v = 0; v < 256; v++){ switch(v){ case VectorBPT: case VectorSYSCALL: flag = SPL3 | EvDisable; break; default: flag = SPL0 | EvDisable; break; } t[0] = (trap_info_t){ v, flag, KESEL, vaddr }; if(HYPERVISOR_set_trap_table(t) < 0) panic("trapinit: FAIL: try to set: 0x%x, 0x%x, 0x%x, 0x%ulx\n", t[0].vector, t[0].flags, t[0].cs, t[0].address); vaddr += 6; } irqinit(); /* * Special traps. * Syscall() is called directly without going through trap(). */ trapenable(VectorBPT, debugbpt, 0, "debugpt"); trapenable(VectorPF, fault386, 0, "fault386"); trapenable(Vector2F, doublefault, 0, "doublefault"); trapenable(Vector15, unexpected, 0, "unexpected"); } static char* excname[32] = { "divide error", "debug exception", "nonmaskable interrupt", "breakpoint", "overflow", "bounds check", "invalid opcode", "coprocessor not available", "double fault", "coprocessor segment overrun", "invalid TSS", "segment not present", "stack exception", "general protection violation", "page fault", "15 (reserved)", "coprocessor error", "alignment check", "machine check", "19 (reserved)", "20 (reserved)", "21 (reserved)", "22 (reserved)", "23 (reserved)", "24 (reserved)", "25 (reserved)", "26 (reserved)", "27 (reserved)", "28 (reserved)", "29 (reserved)", "30 (reserved)", "31 (reserved)", }; static int usertrap(int vno) { char buf[ERRMAX]; if(vno < nelem(excname)){ spllo(); sprint(buf, "sys: trap: %s", excname[vno]); postnote(up, 1, buf, NDebug); return 1; } return 0; } /* * All traps come here. It is slower to have all traps call trap() * rather than directly vectoring the handler. However, this avoids a * lot of code duplication and possible bugs. The only exception is * VectorSYSCALL. * Trap is called with interrupts disabled via interrupt-gates. */ void trap(Ureg* ureg) { int vno, user; user = kenter(ureg); vno = ureg->trap; if(!irqhandled(ureg, vno) && (!user || !usertrap(vno))){ if(!user){ /* early fault before trapinit() */ if(vno == VectorPF) fault386(ureg, 0); } dumpregs(ureg); if(!user){ ureg->sp = (ulong)&ureg->sp; _dumpstack(ureg); } if(vno < nelem(excname)) panic("%s", excname[vno]); panic("unknown trap/intr: %d", vno); } splhi(); if(user){ if(up->procctl || up->nnote) notify(ureg); kexit(ureg); } if (ureg->trap == 0xe) { /* * on page fault, we need to restore the old spl * Xen won't do it for us. * XXX verify this. */ if (ureg->flags & 0x200) spllo(); } } void dumpregs2(Ureg* ureg) { if(up) print("cpu%d: registers for %s %lud\n", m->machno, up->text, up->pid); else print("cpu%d: registers for kernel\n", m->machno); print("FLAGS=%luX TRAP=%luX ECODE=%luX PC=%luX", ureg->flags, ureg->trap, ureg->ecode, ureg->pc); print(" SS=%4.4luX USP=%luX\n", ureg->ss & 0xFFFF, ureg->usp); print(" AX %8.8luX BX %8.8luX CX %8.8luX DX %8.8luX\n", ureg->ax, ureg->bx, ureg->cx, ureg->dx); print(" SI %8.8luX DI %8.8luX BP %8.8luX\n", ureg->si, ureg->di, ureg->bp); print(" CS %4.4luX DS %4.4luX ES %4.4luX FS %4.4luX GS %4.4luX\n", ureg->cs & 0xFFFF, ureg->ds & 0xFFFF, ureg->es & 0xFFFF, ureg->fs & 0xFFFF, ureg->gs & 0xFFFF); } void dumpregs(Ureg* ureg) { extern ulong etext; dumpregs2(ureg); /* * Processor control registers. * If machine check exception, time stamp counter, page size extensions * or enhanced virtual 8086 mode extensions are supported, there is a * CR4. If there is a CR4 and machine check extensions, read the machine * check address and machine check type registers if RDMSR supported. */ print("SKIPPING get of crx and other such stuff.\n");/* */ #ifdef NOT print(" CR0 %8.8lux CR2 %8.8lux CR3 %8.8lux", getcr0(), getcr2(), getcr3()); if(m->cpuiddx & 0x9A){ print(" CR4 %8.8lux", getcr4()); if((m->cpuiddx & 0xA0) == 0xA0){ rdmsr(0x00, &mca); rdmsr(0x01, &mct); print("\n MCA %8.8llux MCT %8.8llux", mca, mct); } } #endif print("\n ur %lux up %lux\n", (ulong)ureg, (ulong)up); } /* * Fill in enough of Ureg to get a stack trace, and call a function. * Used by debugging interface rdb. */ void callwithureg(void (*fn)(Ureg*)) { Ureg ureg; ureg.pc = getcallerpc(&fn); ureg.sp = (ulong)&fn; fn(&ureg); } static void _dumpstack(Ureg *ureg) { ulong l, v, i, estack; extern ulong etext; int x; if(getconf("*nodumpstack")){ iprint("dumpstack disabled\n"); return; } iprint("dumpstack\n"); x = 0; x += print("ktrace /kernel/path %.8lux %.8lux <<EOF\n", ureg->pc, ureg->sp); i = 0; if(up && (ulong)&l >= (ulong)up - KSTACK && (ulong)&l <= (ulong)up) estack = (ulong)up; else if((ulong)&l >= (ulong)m->stack && (ulong)&l <= (ulong)m+BY2PG) estack = (ulong)m+MACHSIZE; else return; x += print("estackx %.8lux\n", estack); for(l=(ulong)&l; l<estack; l+=4){ v = *(ulong*)l; if((KTZERO < v && v < (ulong)&etext) || estack-l<32){ /* * we could Pick off general CALL (((uchar*)v)[-5] == 0xE8) * and CALL indirect through AX (((uchar*)v)[-2] == 0xFF && ((uchar*)v)[-2] == 0xD0), * but this is too clever and misses faulting address. */ x += print("%.8lux=%.8lux ", l, v); i++; } if(i == 4){ i = 0; x += print("\n"); } } if(i) print("\n"); print("EOF\n"); } void dumpstack(void) { callwithureg(_dumpstack); } static void debugbpt(Ureg* ureg, void*) { char buf[ERRMAX]; print("debugbpt\n"); if(up == 0) panic("kernel bpt"); /* restore pc to instruction that caused the trap */ ureg->pc--; sprint(buf, "sys: breakpoint"); postnote(up, 1, buf, NDebug); print("debugbpt for proc %lud\n", up->pid); } static void doublefault(Ureg*, void*) { panic("double fault"); } static void unexpected(Ureg* ureg, void*) { print("unexpected trap %lud; ignoring\n", ureg->trap); } static void fault386(Ureg* ureg, void*) { ulong addr; int read, user, n, insyscall; char buf[ERRMAX]; addr = HYPERVISOR_shared_info->vcpu_info[m->machno].arch.cr2; if (faultpanic) { dprint("cr2 is 0x%lx\n", addr); //dumpregs(ureg); dumpstack(); panic("fault386"); exit(1); } user = (ureg->cs & 0xFFFF) == UESEL; if(!user && mmukmapsync(addr)) return; read = !(ureg->ecode & 2); if(up == nil) panic("fault but up is zero; pc 0x%8.8lux addr 0x%8.8lux\n", ureg->pc, addr); insyscall = up->insyscall; up->insyscall = 1; n = fault(addr, ureg->pc, read); if(n < 0){ if(!user){ dumpregs(ureg); panic("fault: 0x%lux\n", addr); } sprint(buf, "sys: trap: fault %s addr=0x%lux", read? "read" : "write", addr); dprint("Posting %s to %lud\n", buf, up->pid); postnote(up, 1, buf, NDebug); } up->insyscall = insyscall; FAULTLOG(dprint("fault386: all done\n");) } /* * system calls */ #include "../port/systab.h" /* * Syscall is called directly from assembler without going through trap(). */ void syscall(Ureg* ureg) { char *e; ulong sp; long ret; int i, s; ulong scallnr; SYSCALLLOG(dprint("%d: syscall ...#%ld(%s)\n", up->pid, ureg->ax, sysctab[ureg->ax]);) if(!kenter(ureg)) panic("syscall: cs 0x%4.4luX\n", ureg->cs); m->syscall++; up->insyscall = 1; up->pc = ureg->pc; if(up->procctl == Proc_tracesyscall){ up->procctl = Proc_stopme; procctl(); } scallnr = ureg->ax; up->scallnr = scallnr; if(scallnr == RFORK && up->fpstate == FPactive){ fpsave(up->fpsave); up->fpstate = FPinactive; } spllo(); sp = ureg->usp; up->nerrlab = 0; ret = -1; if(!waserror()){ if(scallnr >= nsyscall || systab[scallnr] == 0){ pprint("bad sys call number %lud pc %lux\n", scallnr, ureg->pc); postnote(up, 1, "sys: bad sys call", NDebug); error(Ebadarg); } if(sp<(USTKTOP-BY2PG) || sp>(USTKTOP-sizeof(Sargs)-BY2WD)) validaddr(sp, sizeof(Sargs)+BY2WD, 0); up->s = *((Sargs*)(sp+BY2WD)); up->psstate = sysctab[scallnr]; ret = systab[scallnr]((va_list)up->s.args); poperror(); }else{ /* failure: save the error buffer for errstr */ e = up->syserrstr; up->syserrstr = up->errstr; up->errstr = e; if(0 && up->pid == 1) print("syscall %lud error %s\n", scallnr, up->syserrstr); } if(up->nerrlab){ print("bad errstack [%lud]: %d extra\n", scallnr, up->nerrlab); for(i = 0; i < NERR; i++) print("sp=%lux pc=%lux\n", up->errlab[i].sp, up->errlab[i].pc); panic("error stack"); } SYSCALLLOG(dprint("%d: Syscall %d returns %d, ureg %p\n", up->pid, scallnr, ret, ureg);) /* * Put return value in frame. On the x86 the syscall is * just another trap and the return value from syscall is * ignored. On other machines the return value is put into * the results register by caller of syscall. */ ureg->ax = ret; if(up->procctl == Proc_tracesyscall){ s = splhi(); up->procctl = Proc_stopme; procctl(); splx(s); } up->insyscall = 0; up->psstate = 0; INTRLOG(dprint("cleared insyscall\n");) if(scallnr == NOTED) noted(ureg, *(ulong*)(sp+BY2WD)); if(scallnr!=RFORK && (up->procctl || up->nnote)){ splhi(); notify(ureg); } /* if we delayed sched because we held a lock, sched now */ if(up->delaysched) sched(); INTRLOG(dprint("before kexit\n");) kexit(ureg); } /* * Call user, if necessary, with note. * Pass user the Ureg struct and the note on his stack. */ int notify(Ureg* ureg) { ulong s, sp; char *msg; if(up->procctl) procctl(); if(up->nnote == 0) return 0; if(up->fpstate == FPactive){ fpsave(up->fpsave); up->fpstate = FPinactive; } up->fpstate |= FPillegal; s = spllo(); qlock(&up->debug); msg = popnote(ureg); if(msg == nil){ qunlock(&up->debug); splhi(); return 0; } sp = ureg->usp; sp -= sizeof(Ureg); if(!okaddr((ulong)up->notify, 1, 0) || !okaddr(sp-ERRMAX-4*BY2WD, sizeof(Ureg)+ERRMAX+4*BY2WD, 1)){ qunlock(&up->debug); pprint("suicide: bad address in notify\n"); pexit("Suicide", 0); } up->ureg = (void*)sp; memmove((Ureg*)sp, ureg, sizeof(Ureg)); *(Ureg**)(sp-BY2WD) = up->ureg; /* word under Ureg is old up->ureg */ up->ureg = (void*)sp; sp -= BY2WD+ERRMAX; memmove((char*)sp, msg, ERRMAX); sp -= 3*BY2WD; *(ulong*)(sp+2*BY2WD) = sp+3*BY2WD; /* arg 2 is string */ *(ulong*)(sp+1*BY2WD) = (ulong)up->ureg; /* arg 1 is ureg* */ *(ulong*)(sp+0*BY2WD) = 0; /* arg 0 is pc */ ureg->usp = sp; ureg->pc = (ulong)up->notify; qunlock(&up->debug); splx(s); return 1; } /* * Return user to state before notify() */ void noted(Ureg* ureg, ulong arg0) { Ureg *nureg; ulong oureg, sp; qlock(&up->debug); if(arg0!=NRSTR && !up->notified) { qunlock(&up->debug); pprint("call to noted() when not notified\n"); pexit("Suicide", 0); } up->notified = 0; nureg = up->ureg; /* pointer to user returned Ureg struct */ up->fpstate &= ~FPillegal; /* sanity clause */ oureg = (ulong)nureg; if(!okaddr((ulong)oureg-BY2WD, BY2WD+sizeof(Ureg), 0)){ pprint("bad ureg in noted or call to noted when not notified\n"); qunlock(&up->debug); pexit("Suicide", 0); } /* * Check the segment selectors are all valid, otherwise * a fault will be taken on attempting to return to the * user process. * Take care with the comparisons as different processor * generations push segment descriptors in different ways. */ if((nureg->cs & 0xFFFF) != UESEL || (nureg->ss & 0xFFFF) != UDSEL || (nureg->ds & 0xFFFF) != UDSEL || (nureg->es & 0xFFFF) != UDSEL || (nureg->fs & 0xFFFF) != UDSEL || (nureg->gs & 0xFFFF) != UDSEL){ pprint("bad segment selector in noted\n"); pprint("cs is %#lux, wanted %#ux\n", nureg->cs, UESEL); pprint("ds is %#lux, wanted %#ux\n", nureg->ds, UDSEL); pprint("es is %#lux, fs is %#lux, gs %#lux, wanted %#ux\n", ureg->es, ureg->fs, ureg->gs, UDSEL); pprint("ss is %#lux, wanted %#ux\n", nureg->ss, UDSEL); qunlock(&up->debug); pexit("Suicide", 0); } /* don't let user change system flags */ nureg->flags = (ureg->flags & ~0xCD5) | (nureg->flags & 0xCD5); memmove(ureg, nureg, sizeof(Ureg)); switch(arg0){ case NCONT: case NRSTR: if(!okaddr(nureg->pc, 1, 0) || !okaddr(nureg->usp, BY2WD, 0)){ qunlock(&up->debug); pprint("suicide: trap in noted\n"); pexit("Suicide", 0); } up->ureg = (Ureg*)(*(ulong*)(oureg-BY2WD)); qunlock(&up->debug); break; case NSAVE: if(!okaddr(nureg->pc, BY2WD, 0) || !okaddr(nureg->usp, BY2WD, 0)){ qunlock(&up->debug); pprint("suicide: trap in noted\n"); pexit("Suicide", 0); } qunlock(&up->debug); sp = oureg-4*BY2WD-ERRMAX; splhi(); ureg->sp = sp; ((ulong*)sp)[1] = oureg; /* arg 1 0(FP) is ureg* */ ((ulong*)sp)[0] = 0; /* arg 0 is pc */ break; default: pprint("unknown noted arg 0x%lux\n", arg0); up->lastnote->flag = NDebug; /* fall through */ case NDFLT: qunlock(&up->debug); if(up->lastnote->flag == NDebug) pprint("suicide: %s\n", up->lastnote->msg); pexit(up->lastnote->msg, up->lastnote->flag!=NDebug); } } uintptr execregs(uintptr entry, ulong ssize, ulong nargs) { ulong *sp; Ureg *ureg; up->fpstate = FPinit; fpoff(); sp = (ulong*)(USTKTOP - ssize); *--sp = nargs; ureg = up->dbgreg; ureg->usp = (ulong)sp; ureg->pc = entry; // print("execregs returns 0x%x\n", USTKTOP-sizeof(Tos)); return USTKTOP-sizeof(Tos); /* address of kernel/user shared data */ } /* * return the userpc the last exception happened at */ ulong userpc(void) { Ureg *ureg; ureg = (Ureg*)up->dbgreg; return ureg->pc; } /* This routine must save the values of registers the user is not permitted * to write from devproc and then restore the saved values before returning. */ void setregisters(Ureg* ureg, char* pureg, char* uva, int n) { ulong flags; ulong cs; ulong ss; flags = ureg->flags; cs = ureg->cs; ss = ureg->ss; memmove(pureg, uva, n); ureg->flags = (ureg->flags & 0x00FF) | (flags & 0xFF00); ureg->cs = cs; ureg->ss = ss; } void kprocchild(Proc *p, void (*entry)(void)) { /* * gotolabel() needs a word on the stack in * which to place the return PC used to jump * to linkproc(). */ p->sched.pc = (ulong)entry; p->sched.sp = (ulong)p - BY2WD; } void forkchild(Proc *p, Ureg *ureg) { Ureg *cureg; /* * Add 2*BY2WD to the stack to account for * - the return PC * - trap's argument (ur) */ p->sched.sp = (ulong)p - (sizeof(Ureg)+2*BY2WD); p->sched.pc = (ulong)forkret; cureg = (Ureg*)(p->sched.sp+2*BY2WD); memmove(cureg, ureg, sizeof(Ureg)); /* return value of syscall in child */ cureg->ax = 0; } /* Give enough context in the ureg to produce a kernel stack for * a sleeping process */ void setkernur(Ureg* ureg, Proc* p) { ureg->pc = p->sched.pc; ureg->sp = p->sched.sp+4; } ulong dbgpc(Proc *p) { Ureg *ureg; ureg = p->dbgreg; if(ureg == 0) return 0; return ureg->pc; } /* * install_safe_pf_handler / install_normal_pf_handler: * * These are used within the failsafe_callback handler in entry.S to avoid * taking a full page fault when reloading FS and GS. This is because FS and * GS could be invalid at pretty much any point while Xenolinux executes (we * don't set them to safe values on entry to the kernel). At *any* point Xen * may be entered due to a hardware interrupt --- on exit from Xen an invalid * FS/GS will cause our failsafe_callback to be executed. This could occur, * for example, while the mmu_update_queue is in an inconsistent state. This * is disastrous because the normal page-fault handler touches the update * queue! * * Fortunately, within the failsafe handler it is safe to force DS/ES/FS/GS * to zero if they cannot be reloaded -- at this point executing a normal * page fault would not change this effect. The safe page-fault handler * ensures this end result (blow away the selector value) without the dangers * of the normal page-fault handler. * * NB. Perhaps this can all go away after we have implemented writeable * page tables. :-) */ static void safe_fault386(Ureg* , void* ) { panic("DO SAFE PAGE FAULT!\n"); } unsigned long install_safe_pf_handler(void) { dprint("called from failsafe callback\n"); trapenable(VectorPF, safe_fault386, 0, "safe_fault386"); return 0; } void install_normal_pf_handler(unsigned long) { trapenable(VectorPF, fault386, 0, "fault386"); }