ref: fcccaf74c54ecd44b7e8bf45a7b0c99572f6a949
dir: /os/pc/mp.c/
#include "u.h" #include "../port/lib.h" #include "mem.h" #include "dat.h" #include "fns.h" #include "io.h" #include "ureg.h" #include "mp.h" #include "apbootstrap.h" static Bus* mpbus; static Bus* mpbuslast; static int mpisabus = -1; static int mpeisabus = -1; extern int i8259elcr; /* mask of level-triggered interrupts */ static Apic mpapic[MaxAPICNO+1]; static int machno2apicno[MaxAPICNO+1]; /* inverse map: machno -> APIC ID */ static Lock mprdthilock; static int mprdthi; static Ref mpvnoref; /* unique vector assignment */ static int mpmachno = 1; static char* buses[] = { "CBUSI ", "CBUSII", "EISA ", "FUTURE", "INTERN", "ISA ", "MBI ", "MBII ", "MCA ", "MPI ", "MPSA ", "NUBUS ", "PCI ", "PCMCIA", "TC ", "VL ", "VME ", "XPRESS", 0, }; static Apic* mkprocessor(PCMPprocessor* p) { Apic *apic; if(!(p->flags & PcmpEN) || p->apicno > MaxAPICNO) return 0; apic = &mpapic[p->apicno]; apic->type = PcmpPROCESSOR; apic->apicno = p->apicno; apic->flags = p->flags; apic->lintr[0] = ApicIMASK; apic->lintr[1] = ApicIMASK; if(p->flags & PcmpBP){ machno2apicno[0] = p->apicno; apic->machno = 0; } else{ machno2apicno[mpmachno] = p->apicno; apic->machno = mpmachno; mpmachno++; } return apic; } static Bus* mkbus(PCMPbus* p) { Bus *bus; int i; for(i = 0; buses[i]; i++){ if(strncmp(buses[i], p->string, sizeof(p->string)) == 0) break; } if(buses[i] == 0) return 0; bus = xalloc(sizeof(Bus)); if(mpbus) mpbuslast->next = bus; else mpbus = bus; mpbuslast = bus; bus->type = i; bus->busno = p->busno; if(bus->type == BusEISA){ bus->po = PcmpLOW; bus->el = PcmpLEVEL; if(mpeisabus != -1) print("mkbus: more than one EISA bus\n"); mpeisabus = bus->busno; } else if(bus->type == BusPCI){ bus->po = PcmpLOW; bus->el = PcmpLEVEL; } else if(bus->type == BusISA){ bus->po = PcmpHIGH; bus->el = PcmpEDGE; if(mpisabus != -1) print("mkbus: more than one ISA bus\n"); mpisabus = bus->busno; } else{ bus->po = PcmpHIGH; bus->el = PcmpEDGE; } return bus; } static Bus* mpgetbus(int busno) { Bus *bus; for(bus = mpbus; bus; bus = bus->next){ if(bus->busno == busno) return bus; } print("mpgetbus: can't find bus %d\n", busno); return 0; } static Apic* mkioapic(PCMPioapic* p) { Apic *apic; if(!(p->flags & PcmpEN) || p->apicno > MaxAPICNO) return 0; /* * Map the I/O APIC. */ if(mmukmap(p->addr, 0, 1024) == 0) return 0; apic = &mpapic[p->apicno]; apic->type = PcmpIOAPIC; apic->apicno = p->apicno; apic->addr = KADDR(p->addr); apic->flags = p->flags; return apic; } static Aintr* mkiointr(PCMPintr* p) { Bus *bus; Aintr *aintr; /* * According to the MultiProcessor Specification, a destination * I/O APIC of 0xFF means the signal is routed to all I/O APICs. * It's unclear how that can possibly be correct so treat it as * an error for now. */ if(p->apicno == 0xFF) return 0; if((bus = mpgetbus(p->busno)) == 0) return 0; aintr = xalloc(sizeof(Aintr)); aintr->intr = p; aintr->apic = &mpapic[p->apicno]; aintr->next = bus->aintr; bus->aintr = aintr; return aintr; } static int mpintrinit(Bus* bus, PCMPintr* intr, int vno, int /*irq*/) { int el, po, v; /* * Parse an I/O or Local APIC interrupt table entry and * return the encoded vector. */ v = vno; po = intr->flags & PcmpPOMASK; el = intr->flags & PcmpELMASK; switch(intr->intr){ default: /* PcmpINT */ v |= ApicLOWEST; break; case PcmpNMI: v |= ApicNMI; po = PcmpHIGH; el = PcmpEDGE; break; case PcmpSMI: v |= ApicSMI; break; case PcmpExtINT: v |= ApicExtINT; /* * The AMI Goliath doesn't boot successfully with it's LINTR0 * entry which decodes to low+level. The PPro manual says ExtINT * should be level, whereas the Pentium is edge. Setting the * Goliath to edge+high seems to cure the problem. Other PPro * MP tables (e.g. ASUS P/I-P65UP5 have a entry which decodes * to edge+high, so who knows. * Perhaps it would be best just to not set an ExtINT entry at * all, it shouldn't be needed for SMP mode. */ po = PcmpHIGH; el = PcmpEDGE; break; } /* */ if(bus->type == BusEISA && !po && !el /*&& !(i8259elcr & (1<<irq))*/){ po = PcmpHIGH; el = PcmpEDGE; } if(!po) po = bus->po; if(po == PcmpLOW) v |= ApicLOW; else if(po != PcmpHIGH){ print("mpintrinit: bad polarity 0x%uX\n", po); return ApicIMASK; } if(!el) el = bus->el; if(el == PcmpLEVEL) v |= ApicLEVEL; else if(el != PcmpEDGE){ print("mpintrinit: bad trigger 0x%uX\n", el); return ApicIMASK; } return v; } static int mklintr(PCMPintr* p) { Apic *apic; Bus *bus; int intin, v; /* * The offsets of vectors for LINT[01] are known to be * 0 and 1 from the local APIC vector space at VectorLAPIC. */ if((bus = mpgetbus(p->busno)) == 0) return 0; intin = p->intin; /* * Pentium Pros have problems if LINT[01] are set to ExtINT * so just bag it, SMP mode shouldn't need ExtINT anyway. */ if(p->intr == PcmpExtINT || p->intr == PcmpNMI) v = ApicIMASK; else v = mpintrinit(bus, p, VectorLAPIC+intin, p->irq); if(p->apicno == 0xFF){ for(apic = mpapic; apic <= &mpapic[MaxAPICNO]; apic++){ if((apic->flags & PcmpEN) && apic->type == PcmpPROCESSOR) apic->lintr[intin] = v; } } else{ apic = &mpapic[p->apicno]; if((apic->flags & PcmpEN) && apic->type == PcmpPROCESSOR) apic->lintr[intin] = v; } return v; } static void checkmtrr(void) { int i, vcnt; Mach *mach0; /* * If there are MTRR registers, snarf them for validation. */ if(!(m->cpuiddx & 0x1000)) return; rdmsr(0x0FE, &m->mtrrcap); rdmsr(0x2FF, &m->mtrrdef); if(m->mtrrcap & 0x0100){ rdmsr(0x250, &m->mtrrfix[0]); rdmsr(0x258, &m->mtrrfix[1]); rdmsr(0x259, &m->mtrrfix[2]); for(i = 0; i < 8; i++) rdmsr(0x268+i, &m->mtrrfix[(i+3)]); } vcnt = m->mtrrcap & 0x00FF; if(vcnt > nelem(m->mtrrvar)) vcnt = nelem(m->mtrrvar); for(i = 0; i < vcnt; i++) rdmsr(0x200+i, &m->mtrrvar[i]); /* * If not the bootstrap processor, compare. */ if(m->machno == 0) return; mach0 = MACHP(0); if(mach0->mtrrcap != m->mtrrcap) print("mtrrcap%d: %lluX %lluX\n", m->machno, mach0->mtrrcap, m->mtrrcap); if(mach0->mtrrdef != m->mtrrdef) print("mtrrdef%d: %lluX %lluX\n", m->machno, mach0->mtrrdef, m->mtrrdef); for(i = 0; i < 11; i++){ if(mach0->mtrrfix[i] != m->mtrrfix[i]) print("mtrrfix%d: i%d: %lluX %lluX\n", m->machno, i, mach0->mtrrfix[i], m->mtrrfix[i]); } for(i = 0; i < vcnt; i++){ if(mach0->mtrrvar[i] != m->mtrrvar[i]) print("mtrrvar%d: i%d: %lluX %lluX\n", m->machno, i, mach0->mtrrvar[i], m->mtrrvar[i]); } } static void squidboy(Apic* apic) { // iprint("Hello Squidboy\n"); machinit(); mmuinit(); cpuidentify(); cpuidprint(); checkmtrr(); lock(&mprdthilock); mprdthi |= (1<<apic->apicno)<<24; unlock(&mprdthilock); lapicinit(apic); lapiconline(); syncclock(); timersinit(); fpoff(); lock(&active); active.machs |= 1<<m->machno; unlock(&active); while(!active.thunderbirdsarego) microdelay(100); schedinit(); } static void mpstartap(Apic* apic) { ulong *apbootp, *pdb, *pte; Mach *mach, *mach0; int i, machno; uchar *p; mach0 = MACHP(0); /* * Initialise the AP page-tables and Mach structure. The page-tables * are the same as for the bootstrap processor with the exception of * the PTE for the Mach structure. * Xspanalloc will panic if an allocation can't be made. */ p = xspanalloc(4*BY2PG, BY2PG, 0); pdb = (ulong*)p; memmove(pdb, mach0->pdb, BY2PG); p += BY2PG; if((pte = mmuwalk(pdb, MACHADDR, 1, 0)) == nil) return; memmove(p, KADDR(PPN(*pte)), BY2PG); *pte = PADDR(p)|PTEWRITE|PTEVALID; if(mach0->havepge) *pte |= PTEGLOBAL; p += BY2PG; mach = (Mach*)p; if((pte = mmuwalk(pdb, MACHADDR, 2, 0)) == nil) return; *pte = PADDR(mach)|PTEWRITE|PTEVALID; if(mach0->havepge) *pte |= PTEGLOBAL; p += BY2PG; machno = apic->machno; MACHP(machno) = mach; mach->machno = machno; mach->pdb = pdb; mach->gdt = (Segdesc*)p; /* filled by mmuinit */ /* * Tell the AP where its kernel vector and pdb are. * The offsets are known in the AP bootstrap code. */ apbootp = (ulong*)(APBOOTSTRAP+0x08); *apbootp++ = (ulong)squidboy; *apbootp++ = PADDR(pdb); *apbootp = (ulong)apic; /* * Universal Startup Algorithm. */ p = KADDR(0x467); *p++ = PADDR(APBOOTSTRAP); *p++ = PADDR(APBOOTSTRAP)>>8; i = (PADDR(APBOOTSTRAP) & ~0xFFFF)/16; *p++ = i; *p = i>>8; nvramwrite(0x0F, 0x0A); lapicstartap(apic, PADDR(APBOOTSTRAP)); for(i = 0; i < 1000; i++){ lock(&mprdthilock); if(mprdthi & ((1<<apic->apicno)<<24)){ unlock(&mprdthilock); break; } unlock(&mprdthilock); delay(10); } nvramwrite(0x0F, 0x00); } void mpinit(void) { int ncpu; char *cp; PCMP *pcmp; uchar *e, *p; Apic *apic, *bpapic; i8259init(); syncclock(); if(_mp_ == 0) return; pcmp = KADDR(_mp_->physaddr); /* * Map the local APIC. */ if(mmukmap(pcmp->lapicbase, 0, 1024) == 0) return; bpapic = nil; /* * Run through the table saving information needed for starting * application processors and initialising any I/O APICs. The table * is guaranteed to be in order such that only one pass is necessary. */ p = ((uchar*)pcmp)+sizeof(PCMP); e = ((uchar*)pcmp)+pcmp->length; while(p < e) switch(*p){ default: print("mpinit: unknown PCMP type 0x%uX (e-p 0x%luX)\n", *p, e-p); while(p < e){ print("%uX ", *p); p++; } break; case PcmpPROCESSOR: if(apic = mkprocessor((PCMPprocessor*)p)){ /* * Must take a note of bootstrap processor APIC * now as it will be needed in order to start the * application processors later and there's no * guarantee that the bootstrap processor appears * first in the table before the others. */ apic->addr = KADDR(pcmp->lapicbase); if(apic->flags & PcmpBP) bpapic = apic; } p += sizeof(PCMPprocessor); continue; case PcmpBUS: mkbus((PCMPbus*)p); p += sizeof(PCMPbus); continue; case PcmpIOAPIC: if(apic = mkioapic((PCMPioapic*)p)) ioapicinit(apic, ((PCMPioapic*)p)->apicno); p += sizeof(PCMPioapic); continue; case PcmpIOINTR: mkiointr((PCMPintr*)p); p += sizeof(PCMPintr); continue; case PcmpLINTR: mklintr((PCMPintr*)p); p += sizeof(PCMPintr); continue; } /* * No bootstrap processor, no need to go further. */ if(bpapic == 0) return; lapicinit(bpapic); lock(&mprdthilock); mprdthi |= (1<<bpapic->apicno)<<24; unlock(&mprdthilock); /* * These interrupts are local to the processor * and do not appear in the I/O APIC so it is OK * to set them now. */ intrenable(IrqTIMER, lapicclock, 0, BUSUNKNOWN, "clock"); intrenable(IrqERROR, lapicerror, 0, BUSUNKNOWN, "lapicerror"); intrenable(IrqSPURIOUS, lapicspurious, 0, BUSUNKNOWN, "lapicspurious"); lapiconline(); checkmtrr(); /* * Initialise the application processors. */ if(cp = getconf("*ncpu")){ ncpu = strtol(cp, 0, 0); if(ncpu < 1) ncpu = 1; } else ncpu = MaxAPICNO; memmove((void*)APBOOTSTRAP, apbootstrap, sizeof(apbootstrap)); for(apic = mpapic; apic <= &mpapic[MaxAPICNO]; apic++){ if(ncpu <= 1) break; if((apic->flags & (PcmpBP|PcmpEN)) == PcmpEN && apic->type == PcmpPROCESSOR){ mpstartap(apic); conf.nmach++; ncpu--; } } /* * we don't really know the number of processors till * here. * * set conf.copymode here if nmach > 1. * Should look for an ExtINT line and enable it. */ if(X86FAMILY(m->cpuidax) == 3 || conf.nmach > 1) conf.copymode = 1; } static int mpintrenablex(Vctl* v, int tbdf) { Bus *bus; Aintr *aintr; Apic *apic; Pcidev *pcidev; int bno, dno, irq, lo, n, type, vno; /* * Find the bus. */ type = BUSTYPE(tbdf); bno = BUSBNO(tbdf); dno = BUSDNO(tbdf); n = 0; for(bus = mpbus; bus != nil; bus = bus->next){ if(bus->type != type) continue; if(n == bno) break; n++; } if(bus == nil){ print("ioapicirq: can't find bus type %d\n", type); return -1; } /* * For PCI devices the interrupt pin (INT[ABCD]) and device * number are encoded into the entry irq field, so create something * to match on. The interrupt pin used by the device has to be * obtained from the PCI config space. */ if(bus->type == BusPCI){ pcidev = pcimatchtbdf(tbdf); if(pcidev != nil && (n = pcicfgr8(pcidev, PciINTP)) != 0) irq = (dno<<2)|(n-1); else irq = -1; //print("pcidev %uX: irq %uX v->irq %uX\n", tbdf, irq, v->irq); } else irq = v->irq; /* * Find a matching interrupt entry from the list of interrupts * attached to this bus. */ for(aintr = bus->aintr; aintr; aintr = aintr->next){ if(aintr->intr->irq != irq) continue; /* * Check if already enabled. Multifunction devices may share * INT[A-D]# so, if already enabled, check the polarity matches * and the trigger is level. * * Should check the devices differ only in the function number, * but that can wait for the planned enable/disable rewrite. * The RDT read here is safe for now as currently interrupts * are never disabled once enabled. */ apic = aintr->apic; ioapicrdtr(apic, aintr->intr->intin, 0, &lo); if(!(lo & ApicIMASK)){ vno = lo & 0xFF; n = mpintrinit(bus, aintr->intr, vno, v->irq); n |= ApicLOGICAL; if(n != lo || !(n & ApicLEVEL)){ print("mpintrenable: multiple botch irq%d, tbdf %uX, lo %8.8uX, n %8.8uX\n", v->irq, tbdf, lo, n); return -1; } v->isr = lapicisr; v->eoi = lapiceoi; return vno; } /* * With the APIC a unique vector can be assigned to each * request to enable an interrupt. There are two reasons this * is a good idea: * 1) to prevent lost interrupts, no more than 2 interrupts * should be assigned per block of 16 vectors (there is an * in-service entry and a holding entry for each priority * level and there is one priority level per block of 16 * interrupts). * 2) each input pin on the IOAPIC will receive a different * vector regardless of whether the devices on that pin use * the same IRQ as devices on another pin. */ vno = VectorAPIC + (incref(&mpvnoref)-1)*8; if(vno > MaxVectorAPIC){ print("mpintrenable: vno %d, irq %d, tbdf %uX\n", vno, v->irq, tbdf); return -1; } lo = mpintrinit(bus, aintr->intr, vno, v->irq); //print("lo 0x%uX: busno %d intr %d vno %d irq %d elcr 0x%uX\n", // lo, bus->busno, aintr->intr->irq, vno, // v->irq, i8259elcr); if(lo & ApicIMASK) return -1; lo |= ApicLOGICAL; if((apic->flags & PcmpEN) && apic->type == PcmpIOAPIC){ lock(&mprdthilock); ioapicrdtw(apic, aintr->intr->intin, mprdthi, lo); unlock(&mprdthilock); } //else // print("lo not enabled 0x%uX %d\n", // apic->flags, apic->type); v->isr = lapicisr; v->eoi = lapiceoi; return vno; } return -1; } int mpintrenable(Vctl* v) { int irq, tbdf, vno; /* * If the bus is known, try it. * BUSUNKNOWN is given both by [E]ISA devices and by * interrupts local to the processor (local APIC, coprocessor * breakpoint and page-fault). */ tbdf = v->tbdf; if(tbdf != BUSUNKNOWN && (vno = mpintrenablex(v, tbdf)) != -1) return vno; irq = v->irq; if(irq >= IrqLINT0 && irq <= MaxIrqLAPIC){ if(irq != IrqSPURIOUS) v->isr = lapiceoi; return VectorPIC+irq; } if(irq < 0 || irq > MaxIrqPIC){ print("mpintrenable: irq %d out of range\n", irq); return -1; } /* * Either didn't find it or have to try the default buses * (ISA and EISA). This hack is due to either over-zealousness * or laziness on the part of some manufacturers. * * The MP configuration table on some older systems * (e.g. ASUS PCI/E-P54NP4) has an entry for the EISA bus * but none for ISA. It also has the interrupt type and * polarity set to 'default for this bus' which wouldn't * be compatible with ISA. */ if(mpeisabus != -1){ vno = mpintrenablex(v, MKBUS(BusEISA, 0, 0, 0)); if(vno != -1) return vno; } if(mpisabus != -1){ vno = mpintrenablex(v, MKBUS(BusISA, 0, 0, 0)); if(vno != -1) return vno; } return -1; } static Lock mpshutdownlock; void mpshutdown(void) { /* * To be done... */ if(!canlock(&mpshutdownlock)){ /* * If this processor received the CTRL-ALT-DEL from * the keyboard, acknowledge it. Send an INIT to self. */ #ifdef FIXTHIS if(lapicisr(VectorKBD)) lapiceoi(VectorKBD); #endif /* FIX THIS */ idle(); } print("apshutdown: active = 0x%2.2uX\n", active.machs); delay(1000); splhi(); /* * INIT all excluding self. */ lapicicrw(0, 0x000C0000|ApicINIT); #ifdef notdef /* * Often the BIOS hangs during restart if a conventional 8042 * warm-boot sequence is tried. The following is Intel specific and * seems to perform a cold-boot, but at least it comes back. */ *(ushort*)KADDR(0x472) = 0x1234; /* BIOS warm-boot flag */ outb(0xCF9, 0x02); outb(0xCF9, 0x06); #else pcireset(); i8042reset(); #endif /* notdef */ }