ref: 909323e92a4e694bff5908e500d8655ac1bbd932
dir: /sys/src/9/omap/trap.c/
/* * omap3530 traps, exceptions, interrupts, system calls. */ #include "u.h" #include "../port/lib.h" #include "mem.h" #include "dat.h" #include "fns.h" #include "../port/error.h" #include "ureg.h" #include "arm.h" enum { Nirqs = 96, Nvec = 8, /* # of vectors at start of lexception.s */ Bi2long = BI2BY * sizeof(long), }; extern int notify(Ureg*); extern int ldrexvalid; /* omap35x intc (aka mpu_intc) */ typedef struct Intrregs Intrregs; struct Intrregs { /* * the manual inserts "INTCPS_" before each register name; * we'll just assume the prefix. */ uchar _pad0[4*4]; ulong sysconfig; ulong sysstatus; /* ro */ uchar _pad1[0x40 - 0x18]; ulong sir_irq; /* ro */ ulong sir_fiq; /* ro */ ulong control; ulong protection; ulong idle; uchar _pad2[0x60 - 0x54]; ulong irq_priority; ulong fiq_priority; ulong threshold; uchar _pad3[0x80 - 0x6c]; struct Bits { /* bitmaps */ ulong itr; /* ro: pending intrs (no mask) */ ulong mir; /* interrupt mask: 1 means masked */ ulong mir_clear; /* wo: 1 sets the bit */ ulong mir_set; /* wo: 1 clears the bit */ ulong isr_set; /* software interrupts */ ulong isr_clear; /* wo */ ulong pending_irq; /* ro */ ulong pending_fiq; /* ro */ } bits[3]; /* 3*32 = 96 (Nirqs) */ ulong ilr[Nirqs]; }; enum { /* sysconfig bits */ Softreset = 1<<1, /* sysstatus bits */ Resetdone = 1<<0, /* sir_irq/fiq bits */ Activeirq = MASK(7), /* control bits */ Newirqagr = 1<<0, /* protection bits */ Protection = 1<<0, /* irq/fiq_priority bits */ Irqpriority = MASK(6), /* threshold bits */ Prioritythreshold = MASK(8), /* ilr bits */ Priority = MASK(8) - MASK(2), }; typedef struct Vctl Vctl; typedef struct Vctl { Vctl* next; /* handlers on this vector */ char *name; /* of driver, xallocated */ void (*f)(Ureg*, void*); /* handler to call */ void* a; /* argument to call it with */ } Vctl; static Lock vctllock; static Vctl* vctl[Nirqs]; /* * Layout at virtual address 0. */ typedef struct Vpage0 { void (*vectors[Nvec])(void); u32int vtable[Nvec]; } Vpage0; static Vpage0 *vpage0; uvlong ninterrupt; uvlong ninterruptticks; int irqtooearly = 1; static volatile int probing, trapped; static int irqinuse(uint irq) { Intrregs *ip = (Intrregs *)PHYSINTC; /* * mir registers are odd: a 0 bit means intr unmasked (i.e., * we've unmasked it because it's in use). */ return (ip->bits[irq / Bi2long].mir & (1 << (irq % Bi2long))) == 0; } static void intcmask(uint irq) { Intrregs *ip = (Intrregs *)PHYSINTC; ip->bits[irq / Bi2long].mir_set = 1 << (irq % Bi2long); coherence(); } static void intcunmask(uint irq) { Intrregs *ip = (Intrregs *)PHYSINTC; ip->bits[irq / Bi2long].mir_clear = 1 << (irq % Bi2long); coherence(); } static void intcmaskall(void) { int i; Intrregs *ip = (Intrregs *)PHYSINTC; for (i = 0; i < 3; i++) ip->bits[i].mir_set = ~0; coherence(); } static void intcunmaskall(void) { int i; Intrregs *ip = (Intrregs *)PHYSINTC; for (i = 0; i < 3; i++) ip->bits[i].mir_clear = ~0; coherence(); } static void intcinvertall(void) { int i, s; ulong bits; Intrregs *ip = (Intrregs *)PHYSINTC; s = splhi(); for (i = 0; i < 3; i++) { bits = ip->bits[i].mir; ip->bits[i].mir_set = ~0; /* mask all */ coherence(); /* clearing enables only those intrs. that were disabled */ ip->bits[i].mir_clear = bits; } coherence(); splx(s); } static void intrsave(ulong buf[3]) { int i; Intrregs *ip = (Intrregs *)PHYSINTC; for (i = 0; i < nelem(buf); i++) buf[i] = ip->bits[i].mir; coherence(); } static void intrrestore(ulong buf[3]) { int i, s; Intrregs *ip = (Intrregs *)PHYSINTC; s = splhi(); for (i = 0; i < nelem(buf); i++) { ip->bits[i].mir_clear = ~0; /* unmask all */ coherence(); ip->bits[i].mir_set = buf[i]; /* mask previously disabled */ } coherence(); splx(s); } /* * set up for exceptions */ void trapinit(void) { int i; Intrregs *ip = (Intrregs *)PHYSINTC; /* set up the exception vectors */ vpage0 = (Vpage0*)HVECTORS; memmove(vpage0->vectors, vectors, sizeof(vpage0->vectors)); memmove(vpage0->vtable, vtable, sizeof(vpage0->vtable)); cacheuwbinv(); l2cacheuwbinv(); /* set up the stacks for the interrupt modes */ setr13(PsrMfiq, m->sfiq); setr13(PsrMirq, m->sirq); setr13(PsrMabt, m->sabt); setr13(PsrMund, m->sund); #ifdef HIGH_SECURITY setr13(PsrMmon, m->smon); #endif setr13(PsrMsys, m->ssys); intcmaskall(); ip->control = 0; ip->threshold = Prioritythreshold; /* disable threshold */ for (i = 0; i < Nirqs; i++) ip->ilr[i] = 0<<2 | 0; /* all intrs pri 0 & to irq, not fiq */ irqtooearly = 0; coherence(); } void intrsoff(void) { Intrregs *ip = (Intrregs *)PHYSINTC; intcmaskall(); ip->control = Newirqagr; /* dismiss interrupt */ coherence(); } /* * enable an irq interrupt */ int irqenable(int irq, void (*f)(Ureg*, void*), void* a, char *name) { Vctl *v; if(irq >= nelem(vctl) || irq < 0) panic("irqenable irq %d", irq); if (irqtooearly) { iprint("irqenable for %d %s called too early\n", irq, name); return -1; } if(irqinuse(irq)) print("irqenable: %s: irq %d already in use, chaining\n", name, irq); v = malloc(sizeof(Vctl)); if (v == nil) panic("irqenable: malloc Vctl"); v->f = f; v->a = a; v->name = malloc(strlen(name)+1); if (v->name == nil) panic("irqenable: malloc name"); strcpy(v->name, name); lock(&vctllock); v->next = vctl[irq]; vctl[irq] = v; intcunmask(irq); unlock(&vctllock); return 0; } /* * disable an irq interrupt */ int irqdisable(int irq, void (*f)(Ureg*, void*), void* a, char *name) { Vctl **vp, *v; if(irq >= nelem(vctl) || irq < 0) panic("irqdisable irq %d", irq); lock(&vctllock); for(vp = &vctl[irq]; v = *vp; vp = &v->next) if (v->f == f && v->a == a && strcmp(v->name, name) == 0){ print("irqdisable: remove %s\n", name); *vp = v->next; free(v); break; } if(v == nil) print("irqdisable: irq %d, name %s not enabled\n", irq, name); if(vctl[irq] == nil){ print("irqdisable: clear icmr bit %d\n", irq); intcmask(irq); } unlock(&vctllock); return 0; } /* * called by trap to handle access faults */ static void faultarm(Ureg *ureg, uintptr va, int user, int read) { int n, insyscall; char buf[ERRMAX]; if(up == nil) { dumpregs(ureg); panic("fault: nil up in faultarm, accessing %#p", va); } insyscall = up->insyscall; up->insyscall = 1; n = fault(va, ureg->pc, read); if(n < 0){ if(!user){ dumpregs(ureg); panic("fault: kernel accessing %#p", va); } /* don't dump registers; programs suicide all the time */ snprint(buf, sizeof buf, "sys: trap: fault %s va=%#p", read? "read": "write", va); postnote(up, 1, buf, NDebug); } up->insyscall = insyscall; } /* * called by trap to handle interrupts. * returns true iff a clock interrupt, thus maybe reschedule. */ static int irq(Ureg* ureg) { int clockintr; uint irqno, handled, t, ticks = perfticks(); Intrregs *ip = (Intrregs *)PHYSINTC; Vctl *v; static int nesting, lastirq = -1; handled = 0; irqno = ip->sir_irq & Activeirq; if (irqno >= 37 && irqno <= 47) /* this is a clock intr? */ m->inclockintr++; /* yes, count nesting */ lastirq = irqno; if (irqno >= nelem(vctl)) { iprint("trap: irq %d >= # vectors (%d)\n", irqno, nelem(vctl)); ip->control = Newirqagr; /* dismiss interrupt */ return 0; } ++nesting; for(v = vctl[irqno]; v != nil; v = v->next) if (v->f) { if (islo()) panic("trap: pl0 before trap handler for %s", v->name); v->f(ureg, v->a); if (islo()) panic("trap: %s lowered pl", v->name); // splhi(); /* in case v->f lowered pl */ handled++; } if(!handled) { iprint("unexpected interrupt: irq %d", irqno); switch (irqno) { case 56: case 57: iprint(" (IC)"); break; case 83: case 86: case 94: iprint(" (MMC)"); break; } if(irqno < nelem(vctl)) { intcmask(irqno); iprint(", now masked"); } iprint("\n"); } t = perfticks(); ninterrupt++; if(t < ticks) ninterruptticks += ticks-t; else ninterruptticks += t-ticks; ip->control = Newirqagr; /* dismiss interrupt */ coherence(); --nesting; clockintr = m->inclockintr == 1; if (irqno >= 37 && irqno <= 47) m->inclockintr--; return clockintr; } /* * returns 1 if the instruction writes memory, 0 otherwise */ int writetomem(ulong inst) { /* swap always write memory */ if((inst & 0x0FC00000) == 0x01000000) return 1; /* loads and stores are distinguished by bit 20 */ if(inst & (1<<20)) return 0; return 1; } void prgpmcerrs(void); /* * here on all exceptions other than syscall (SWI) */ void trap(Ureg *ureg) { int clockintr, user, x, rv, rem; ulong inst, fsr; uintptr va; char buf[ERRMAX]; splhi(); /* paranoia */ if(up != nil) rem = ((char*)ureg)-up->kstack; else rem = ((char*)ureg)-((char*)m+sizeof(Mach)); if(rem < 1024) { iprint("trap: %d stack bytes left, up %#p ureg %#p at pc %#lux\n", rem, up, ureg, ureg->pc); delay(1000); dumpstack(); panic("trap: %d stack bytes left, up %#p ureg %#p at pc %#lux", rem, up, ureg, ureg->pc); } user = kenter(ureg); /* * All interrupts/exceptions should be resumed at ureg->pc-4, * except for Data Abort which resumes at ureg->pc-8. */ if(ureg->type == (PsrMabt+1)) ureg->pc -= 8; else ureg->pc -= 4; clockintr = 0; /* if set, may call sched() before return */ switch(ureg->type){ default: panic("unknown trap; type %#lux, psr mode %#lux", ureg->type, ureg->psr & PsrMask); break; case PsrMirq: ldrexvalid = 0; clockintr = irq(ureg); m->intr++; break; case PsrMabt: /* prefetch fault */ ldrexvalid = 0; x = ifsrget(); fsr = (x>>7) & 0x8 | x & 0x7; switch(fsr){ case 0x02: /* instruction debug event (BKPT) */ if(user){ snprint(buf, sizeof buf, "sys: breakpoint"); postnote(up, 1, buf, NDebug); }else{ iprint("kernel bkpt: pc %#lux inst %#ux\n", ureg->pc, *(u32int*)ureg->pc); panic("kernel bkpt"); } break; default: faultarm(ureg, ureg->pc, user, 1); break; } break; case PsrMabt+1: /* data fault */ ldrexvalid = 0; va = farget(); inst = *(ulong*)(ureg->pc); /* bits 12 and 10 have to be concatenated with status */ x = fsrget(); fsr = (x>>7) & 0x20 | (x>>6) & 0x10 | x & 0xf; if (probing && !user) { if (trapped++ > 0) panic("trap: recursive probe %#lux", va); ureg->pc += 4; /* continue at next instruction */ break; } switch(fsr){ default: case 0xa: /* ? was under external abort */ panic("unknown data fault, 6b fsr %#lux", fsr); break; case 0x0: panic("vector exception at %#lux", ureg->pc); break; case 0x1: /* alignment fault */ case 0x3: /* access flag fault (section) */ if(user){ snprint(buf, sizeof buf, "sys: alignment: pc %#lux va %#p\n", ureg->pc, va); postnote(up, 1, buf, NDebug); } else panic("kernel alignment: pc %#lux va %#p", ureg->pc, va); break; case 0x2: panic("terminal exception at %#lux", ureg->pc); break; case 0x4: /* icache maint fault */ case 0x6: /* access flag fault (page) */ case 0x8: /* precise external abort, non-xlat'n */ case 0x28: case 0xc: /* l1 translation, precise ext. abort */ case 0x2c: case 0xe: /* l2 translation, precise ext. abort */ case 0x2e: case 0x16: /* imprecise ext. abort, non-xlt'n */ case 0x36: panic("external abort %#lux pc %#lux addr %#p", fsr, ureg->pc, va); break; case 0x1c: /* l1 translation, precise parity err */ case 0x1e: /* l2 translation, precise parity err */ case 0x18: /* imprecise parity or ecc err */ panic("translation parity error %#lux pc %#lux addr %#p", fsr, ureg->pc, va); break; case 0x5: /* translation fault, no section entry */ case 0x7: /* translation fault, no page entry */ faultarm(ureg, va, user, !writetomem(inst)); break; case 0x9: case 0xb: /* domain fault, accessing something we shouldn't */ if(user){ snprint(buf, sizeof buf, "sys: access violation: pc %#lux va %#p\n", ureg->pc, va); postnote(up, 1, buf, NDebug); } else panic("kernel access violation: pc %#lux va %#p", ureg->pc, va); break; case 0xd: case 0xf: /* permission error, copy on write or real permission error */ faultarm(ureg, va, user, !writetomem(inst)); break; } break; case PsrMund: /* undefined instruction */ if(user){ if(seg(up, ureg->pc, 0) != nil && *(u32int*)ureg->pc == 0xD1200070){ snprint(buf, sizeof buf, "sys: breakpoint"); postnote(up, 1, buf, NDebug); }else{ /* look for floating point instructions to interpret */ x = spllo(); rv = fpiarm(ureg); splx(x); if(rv == 0){ ldrexvalid = 0; snprint(buf, sizeof buf, "undefined instruction: pc %#lux\n", ureg->pc); postnote(up, 1, buf, NDebug); } } }else{ if (ureg->pc & 3) { iprint("rounding fault pc %#lux down to word\n", ureg->pc); ureg->pc &= ~3; } iprint("undefined instruction: pc %#lux inst %#ux\n", ureg->pc, ((u32int*)ureg->pc)[-2]); panic("undefined instruction"); } break; } splhi(); /* delaysched set because we held a lock or because our quantum ended */ if(up && up->delaysched && clockintr){ ldrexvalid = 0; sched(); /* can cause more traps */ splhi(); } if(user){ if(up->procctl || up->nnote) notify(ureg); kexit(ureg); } } /* * 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 = (uintptr)&fn; fn(&ureg); } static void dumpstackwithureg(Ureg *ureg) { int x; uintptr l, v, i, estack; char *s; dumpregs(ureg); if((s = getconf("*nodumpstack")) != nil && strcmp(s, "0") != 0){ iprint("dumpstack disabled\n"); return; } iprint("dumpstack\n"); x = 0; x += iprint("ktrace /kernel/path %#.8lux %#.8lux %#.8lux # pc, sp, link\n", ureg->pc, ureg->sp, ureg->r14); delay(20); i = 0; if(up && (uintptr)&l >= (uintptr)up->kstack && (uintptr)&l <= (uintptr)up->kstack+KSTACK) estack = (uintptr)up->kstack+KSTACK; else if((uintptr)&l >= (uintptr)m->stack && (uintptr)&l <= (uintptr)m+MACHSIZE) estack = (uintptr)m+MACHSIZE; else return; x += iprint("estackx %p\n", estack); for(l = (uintptr)&l; l < estack; l += sizeof(uintptr)){ v = *(uintptr*)l; if((KTZERO < v && v < (uintptr)etext) || estack-l < 32){ x += iprint("%.8p ", v); delay(20); i++; } if(i == 8){ i = 0; x += iprint("\n"); delay(20); } } if(i) iprint("\n"); } void dumpstack(void) { callwithureg(dumpstackwithureg); } /* * dump system control coprocessor registers */ static void dumpscr(void) { iprint("0:\t%#8.8ux id\n", cpidget()); iprint("\t%8.8#ux ct\n", cpctget()); iprint("1:\t%#8.8ux control\n", controlget()); iprint("2:\t%#8.8ux ttb\n", ttbget()); iprint("3:\t%#8.8ux dac\n", dacget()); iprint("4:\t(reserved)\n"); iprint("5:\t%#8.8ux fsr\n", fsrget()); iprint("6:\t%#8.8ux far\n", farget()); iprint("7:\twrite-only cache\n"); iprint("8:\twrite-only tlb\n"); iprint("13:\t%#8.8ux pid\n", pidget()); delay(10); } /* * dump general registers */ static void dumpgpr(Ureg* ureg) { if(up != nil) iprint("cpu%d: registers for %s %lud\n", m->machno, up->text, up->pid); else iprint("cpu%d: registers for kernel\n", m->machno); delay(20); iprint("%#8.8lux\tr0\n", ureg->r0); iprint("%#8.8lux\tr1\n", ureg->r1); iprint("%#8.8lux\tr2\n", ureg->r2); delay(20); iprint("%#8.8lux\tr3\n", ureg->r3); iprint("%#8.8lux\tr4\n", ureg->r4); iprint("%#8.8lux\tr5\n", ureg->r5); delay(20); iprint("%#8.8lux\tr6\n", ureg->r6); iprint("%#8.8lux\tr7\n", ureg->r7); iprint("%#8.8lux\tr8\n", ureg->r8); delay(20); iprint("%#8.8lux\tr9 (up)\n", ureg->r9); iprint("%#8.8lux\tr10 (m)\n", ureg->r10); iprint("%#8.8lux\tr11 (loader temporary)\n", ureg->r11); iprint("%#8.8lux\tr12 (SB)\n", ureg->r12); delay(20); iprint("%#8.8lux\tr13 (sp)\n", ureg->r13); iprint("%#8.8lux\tr14 (link)\n", ureg->r14); iprint("%#8.8lux\tr15 (pc)\n", ureg->pc); delay(20); iprint("%10.10lud\ttype\n", ureg->type); iprint("%#8.8lux\tpsr\n", ureg->psr); delay(20); } void dumpregs(Ureg* ureg) { dumpgpr(ureg); dumpscr(); } vlong probeaddr(uintptr addr) { vlong v; static Lock fltlck; ilock(&fltlck); trapped = 0; probing = 1; coherence(); v = *(ulong *)addr; /* this may cause a fault */ USED(probing); coherence(); probing = 0; coherence(); if (trapped) v = -1; iunlock(&fltlck); return v; }