ref: 8043614f797a269cfc9772998a3a1d46c139a1b7
dir: /sys/src/9/pc64/main.c/
#include "u.h" #include "../port/lib.h" #include "mem.h" #include "dat.h" #include "fns.h" #include "io.h" #include "tos.h" #include "ureg.h" #include "init.h" #include "pool.h" #include "reboot.h" /* * Where configuration info is left for the loaded programme. * This will turn into a structure as more is done by the boot loader * (e.g. why parse the .ini file twice?). * There are 3584 bytes available at CONFADDR. */ #define BOOTLINE ((char*)CONFADDR) #define BOOTLINELEN 64 #define BOOTARGS ((char*)(CONFADDR+BOOTLINELEN)) #define BOOTARGSLEN (4096-0x200-BOOTLINELEN) #define MAXCONF 64 Conf conf; char *confname[MAXCONF]; char *confval[MAXCONF]; int nconf; int delaylink; int idle_spin; char *sp; /* user stack of init proc */ extern void (*i8237alloc)(void); extern void bootscreeninit(void); static void multibootargs(void) { extern ulong multibootptr; ulong *multiboot; char *cp, *ep; ulong *m, l; if(multibootptr == 0) return; multiboot = (ulong*)KADDR(multibootptr); /* command line */ if((multiboot[0] & (1<<2)) != 0) strncpy(BOOTLINE, KADDR(multiboot[4]), BOOTLINELEN-1); cp = BOOTARGS; ep = cp + BOOTARGSLEN-1; /* memory map */ if((multiboot[0] & (1<<6)) != 0 && (l = multiboot[11]) >= 24){ cp = seprint(cp, ep, "*e820="); m = KADDR(multiboot[12]); while(m[0] >= 20 && m[0] <= l-4){ uvlong base, size; m++; base = ((uvlong)m[0] | (uvlong)m[1]<<32); size = ((uvlong)m[2] | (uvlong)m[3]<<32); cp = seprint(cp, ep, "%.1lux %.16llux %.16llux ", m[4] & 0xF, base, base+size); l -= m[-1]+4; m = (ulong*)((uintptr)m + m[-1]); } cp[-1] = '\n'; } /* plan9.ini passed as the first module */ if((multiboot[0] & (1<<3)) != 0 && multiboot[5] > 0){ m = KADDR(multiboot[6]); l = m[1] - m[0]; m = KADDR(m[0]); if(cp+l > ep) l = ep - cp; memmove(cp, m, l); cp += l; } *cp = 0; } static void options(void) { long i, n; char *cp, *line[MAXCONF], *p, *q; multibootargs(); /* * parse configuration args from dos file plan9.ini */ cp = BOOTARGS; /* where b.com leaves its config */ cp[BOOTARGSLEN-1] = 0; /* * Strip out '\r', change '\t' -> ' '. */ p = cp; for(q = cp; *q; q++){ if(*q == '\r') continue; if(*q == '\t') *q = ' '; *p++ = *q; } *p = 0; n = getfields(cp, line, MAXCONF, 1, "\n"); for(i = 0; i < n; i++){ if(*line[i] == '#') continue; cp = strchr(line[i], '='); if(cp == nil) continue; *cp++ = '\0'; confname[nconf] = line[i]; confval[nconf] = cp; nconf++; } } char* getconf(char *name) { int i; for(i = 0; i < nconf; i++) if(cistrcmp(confname[i], name) == 0) return confval[i]; return 0; } static void writeconf(void) { char *p, *q; int n; p = getconfenv(); if(waserror()) { free(p); nexterror(); } /* convert to name=value\n format */ for(q=p; *q; q++) { q += strlen(q); *q = '='; q += strlen(q); *q = '\n'; } n = q - p + 1; if(n >= BOOTARGSLEN) error("kernel configuration too large"); memset(BOOTLINE, 0, BOOTLINELEN); memmove(BOOTARGS, p, n); poperror(); free(p); } void confinit(void) { char *p; int i, userpcnt; ulong kpages; if(p = getconf("service")){ if(strcmp(p, "cpu") == 0) cpuserver = 1; else if(strcmp(p,"terminal") == 0) cpuserver = 0; } if(p = getconf("*kernelpercent")) userpcnt = 100 - strtol(p, 0, 0); else userpcnt = 0; conf.npage = 0; for(i=0; i<nelem(conf.mem); i++) conf.npage += conf.mem[i].npage; conf.nproc = 100 + ((conf.npage*BY2PG)/MB)*5; if(cpuserver) conf.nproc *= 3; if(conf.nproc > 2000) conf.nproc = 2000; conf.nimage = 200; conf.nswap = conf.nproc*80; conf.nswppo = 4096; if(cpuserver) { if(userpcnt < 10) userpcnt = 70; kpages = conf.npage - (conf.npage*userpcnt)/100; } else { if(userpcnt < 10) { if(conf.npage*BY2PG < 16*MB) userpcnt = 50; else userpcnt = 60; } kpages = conf.npage - (conf.npage*userpcnt)/100; /* * Make sure terminals with low memory get at least * 4MB on the first Image chunk allocation. */ if(conf.npage*BY2PG < 16*MB) imagmem->minarena = 4*MB; } /* * can't go past the end of virtual memory. */ if(kpages > ((uintptr)-KZERO)/BY2PG) kpages = ((uintptr)-KZERO)/BY2PG; conf.upages = conf.npage - kpages; conf.ialloc = (kpages/2)*BY2PG; /* * Guess how much is taken by the large permanent * datastructures. Mntcache and Mntrpc are not accounted for. */ kpages *= BY2PG; kpages -= conf.nproc*sizeof(Proc) + conf.nimage*sizeof(Image) + conf.nswap + conf.nswppo*sizeof(Page*); mainmem->maxsize = kpages; /* * the dynamic allocation will balance the load properly, * hopefully. be careful with 32-bit overflow. */ imagmem->maxsize = kpages - (kpages/10); if(p = getconf("*imagemaxmb")){ imagmem->maxsize = strtol(p, nil, 0)*MB; if(imagmem->maxsize > mainmem->maxsize) imagmem->maxsize = mainmem->maxsize; } } /* * The palloc.pages array can be a large chunk out of the 2GB * window above KZERO, so we allocate the array from * upages and map in the VMAP window before pageinit() */ static void preallocpages(void) { Pallocmem *pm; uintptr va, base, top; vlong size; ulong np; int i; np = 0; for(i=0; i<nelem(palloc.mem); i++){ pm = &palloc.mem[i]; np += pm->npage; } size = (uvlong)np * BY2PG; size += sizeof(Page) + BY2PG; /* round up */ size = (size / (sizeof(Page) + BY2PG)) * sizeof(Page); size = ROUND(size, PGLSZ(1)); for(i=0; i<nelem(palloc.mem); i++){ pm = &palloc.mem[i]; base = ROUND(pm->base, PGLSZ(1)); top = pm->base + (uvlong)pm->npage * BY2PG; if((base + size) <= VMAPSIZE && (vlong)(top - base) >= size){ va = base + VMAP; pmap(m->pml4, base | PTEGLOBAL|PTEWRITE|PTEVALID, va, size); palloc.pages = (Page*)va; pm->base = base + size; pm->npage = (top - pm->base)/BY2PG; break; } } } void machinit(void) { int machno; Segdesc *gdt; uintptr *pml4; machno = m->machno; pml4 = m->pml4; gdt = m->gdt; memset(m, 0, sizeof(Mach)); m->machno = machno; m->pml4 = pml4; m->gdt = gdt; m->perf.period = 1; /* * For polled uart output at boot, need * a default delay constant. 100000 should * be enough for a while. Cpuidentify will * calculate the real value later. */ m->loopconst = 100000; } void mach0init(void) { conf.nmach = 1; MACHP(0) = (Mach*)CPU0MACH; m->machno = 0; m->pml4 = (u64int*)CPU0PML4; m->gdt = (Segdesc*)CPU0GDT; machinit(); active.machs = 1; active.exiting = 0; } void bootargs(void *base) { char *argv[8]; int i, argc; #define UA(ka) ((char*)(ka) + ((uintptr)(USTKTOP - BY2PG) - (uintptr)base)) sp = (char*)base + BY2PG - sizeof(Tos); /* push boot command line onto the stack */ sp -= BOOTLINELEN; sp[BOOTLINELEN-1] = '\0'; memmove(sp, BOOTLINE, BOOTLINELEN-1); /* parse boot command line */ argc = tokenize(sp, argv, nelem(argv)); if(argc < 1){ strcpy(sp, "boot"); argc = 0; argv[argc++] = sp; } /* 8 byte word align stack */ sp = (char*)((uintptr)sp & ~7); /* build argv on stack */ sp -= (argc+1)*BY2WD; for(i=0; i<argc; i++) ((char**)sp)[i] = UA(argv[i]); ((char**)sp)[i] = nil; sp = UA(sp); #undef UA sp -= BY2WD; } void init0(void) { int i; char buf[2*KNAMELEN]; up->nerrlab = 0; spllo(); /* * These are o.k. because rootinit is null. * Then early kproc's will have a root and dot. */ up->slash = namec("#/", Atodir, 0, 0); pathclose(up->slash->path); up->slash->path = newpath("/"); up->dot = cclone(up->slash); chandevinit(); if(!waserror()){ snprint(buf, sizeof(buf), "%s %s", arch->id, conffile); ksetenv("terminal", buf, 0); ksetenv("cputype", "amd64", 0); if(cpuserver) ksetenv("service", "cpu", 0); else ksetenv("service", "terminal", 0); for(i = 0; i < nconf; i++){ if(confname[i][0] != '*') ksetenv(confname[i], confval[i], 0); ksetenv(confname[i], confval[i], 1); } poperror(); } kproc("alarm", alarmkproc, 0); touser(sp); } void userinit(void) { void *v; Proc *p; Segment *s; Page *pg; p = newproc(); p->pgrp = newpgrp(); p->egrp = smalloc(sizeof(Egrp)); p->egrp->ref = 1; p->fgrp = dupfgrp(nil); p->rgrp = newrgrp(); p->procmode = 0640; kstrdup(&eve, ""); kstrdup(&p->text, "*init*"); kstrdup(&p->user, eve); procsetup(p); /* * Kernel Stack * * N.B. make sure there's enough space for syscall to check * for valid args and * 8 bytes for gotolabel's return PC */ p->sched.pc = (uintptr)init0; p->sched.sp = (uintptr)p->kstack+KSTACK-(sizeof(Sargs)+BY2WD); /* temporarily set up for kmap() */ up = p; /* * User Stack */ s = newseg(SG_STACK, USTKTOP-USTKSIZE, USTKSIZE/BY2PG); p->seg[SSEG] = s; pg = newpage(0, 0, USTKTOP-BY2PG); v = kmap(pg); memset(v, 0, BY2PG); segpage(s, pg); bootargs(v); kunmap(v); /* * Text */ s = newseg(SG_TEXT, UTZERO, 1); s->flushme++; p->seg[TSEG] = s; pg = newpage(0, 0, UTZERO); pg->txtflush = ~0; segpage(s, pg); v = kmap(pg); memset(v, 0, BY2PG); memmove(v, initcode, sizeof initcode); kunmap(v); /* free kmap */ mmurelease(p); up = nil; ready(p); } void main() { mach0init(); options(); ioinit(); i8250console(); quotefmtinstall(); screeninit(); print("\nPlan 9\n"); trapinit0(); i8253init(); cpuidentify(); meminit(); confinit(); xinit(); archinit(); bootscreeninit(); if(i8237alloc != nil) i8237alloc(); trapinit(); printinit(); cpuidprint(); mmuinit(); if(arch->intrinit) arch->intrinit(); timersinit(); mathinit(); if(arch->clockenable) arch->clockenable(); procinit0(); initseg(); if(delaylink){ bootlinks(); pcimatch(0, 0, 0); }else links(); conf.monitor = 1; chandevreset(); preallocpages(); pageinit(); swapinit(); userinit(); active.thunderbirdsarego = 1; schedinit(); } static void shutdown(int ispanic) { int ms, once; lock(&active); if(ispanic) active.ispanic = ispanic; else if(m->machno == 0 && (active.machs & (1<<m->machno)) == 0) active.ispanic = 0; once = active.machs & (1<<m->machno); /* * setting exiting will make hzclock() on each processor call exit(0), * which calls shutdown(0) and arch->reset(), which on mp systems calls * mpshutdown(), from which there is no return: the processor is idled * or initiates a reboot. clearing our bit in machs avoids calling * exit(0) from hzclock() on this processor. */ active.machs &= ~(1<<m->machno); active.exiting = 1; unlock(&active); if(once) iprint("cpu%d: exiting\n", m->machno); /* wait for any other processors to shutdown */ spllo(); for(ms = 5*1000; ms > 0; ms -= TK2MS(2)){ delay(TK2MS(2)); if(active.machs == 0 && consactive() == 0) break; } if(active.ispanic){ if(!cpuserver) for(;;) halt(); if(getconf("*debug")) delay(5*60*1000); else delay(10000); } } void exit(int ispanic) { shutdown(ispanic); arch->reset(); } void reboot(void *entry, void *code, ulong size) { void (*f)(uintptr, uintptr, ulong); writeconf(); /* * the boot processor is cpu0. execute this function on it * so that the new kernel has the same cpu0. this only matters * because the hardware has a notion of which processor was the * boot processor and we look at it at start up. */ if (m->machno != 0) { procwired(up, 0); sched(); } shutdown(0); iprint("shutting down...\n"); delay(200); splhi(); /* turn off buffered serial console */ serialoq = nil; /* shutdown devices */ chandevshutdown(); arch->introff(); /* * This allows the reboot code to turn off the page mapping */ *mmuwalk(m->pml4, 0, 3, 0) = *mmuwalk(m->pml4, KZERO, 3, 0); *mmuwalk(m->pml4, 0, 2, 0) = *mmuwalk(m->pml4, KZERO, 2, 0); mmuflushtlb(); /* setup reboot trampoline function */ f = (void*)REBOOTADDR; memmove(f, rebootcode, sizeof(rebootcode)); /* off we go - never to return */ coherence(); (*f)((uintptr)entry & ~0xF0000000UL, (uintptr)PADDR(code), size); } /* * SIMD Floating Point. * Assembler support to get at the individual instructions * is in l.s. * There are opportunities to be lazier about saving and * restoring the state and allocating the storage needed. */ extern void _clts(void); extern void _fldcw(u16int); extern void _fnclex(void); extern void _fninit(void); extern void _fxrstor(Fxsave*); extern void _fxsave(Fxsave*); extern void _fwait(void); extern void _ldmxcsr(u32int); extern void _stts(void); /* * not used, AMD64 mandated SSE */ void fpx87save(FPsave*) { } void fpx87restore(FPsave*) { } void fpssesave(FPsave *fps) { Fxsave *fx = (Fxsave*)ROUND(((uintptr)fps), FPalign); _fxsave(fx); _stts(); if(fx != (Fxsave*)fps) memmove((Fxsave*)fps, fx, sizeof(Fxsave)); } void fpsserestore(FPsave *fps) { Fxsave *fx = (Fxsave*)ROUND(((uintptr)fps), FPalign); if(fx != (Fxsave*)fps) memmove(fx, (Fxsave*)fps, sizeof(Fxsave)); _clts(); _fxrstor(fx); } static char* mathmsg[] = { nil, /* handled below */ "denormalized operand", "division by zero", "numeric overflow", "numeric underflow", "precision loss", }; static void mathnote(ulong status, uintptr pc) { char *msg, note[ERRMAX]; int i; /* * Some attention should probably be paid here to the * exception masks and error summary. */ msg = "unknown exception"; for(i = 1; i <= 5; i++){ if(!((1<<i) & status)) continue; msg = mathmsg[i]; break; } if(status & 0x01){ if(status & 0x40){ if(status & 0x200) msg = "stack overflow"; else msg = "stack underflow"; }else msg = "invalid operation"; } snprint(note, sizeof note, "sys: fp: %s fppc=%#p status=0x%lux", msg, pc, status); postnote(up, 1, note, NDebug); } /* * math coprocessor error */ static void matherror(Ureg*, void*) { /* * Save FPU state to check out the error. */ fpsave(&up->fpsave); up->fpstate = FPinactive; mathnote(up->fpsave.fsw, up->fpsave.rip); } /* * SIMD error */ static void simderror(Ureg *ureg, void*) { fpsave(&up->fpsave); up->fpstate = FPinactive; mathnote(up->fpsave.mxcsr & 0x3f, ureg->pc); } /* * math coprocessor emulation fault */ static void mathemu(Ureg *ureg, void*) { ulong status, control; if(up->fpstate & FPillegal){ /* someone did floating point in a note handler */ postnote(up, 1, "sys: floating point in note handler", NDebug); return; } switch(up->fpstate){ case FPinit: /* * A process tries to use the FPU for the * first time and generates a 'device not available' * exception. * Turn the FPU on and initialise it for use. * Set the precision and mask the exceptions * we don't care about from the generic Mach value. */ _clts(); _fninit(); _fwait(); _fldcw(0x0232); _ldmxcsr(0x1900); up->fpstate = FPactive; break; case FPinactive: /* * Before restoring the state, check for any pending * exceptions, there's no way to restore the state without * generating an unmasked exception. * More attention should probably be paid here to the * exception masks and error summary. */ status = up->fpsave.fsw; control = up->fpsave.fcw; if((status & ~control) & 0x07F){ mathnote(status, up->fpsave.rip); break; } fprestore(&up->fpsave); up->fpstate = FPactive; break; case FPactive: panic("math emu pid %ld %s pc %#p", up->pid, up->text, ureg->pc); break; } } /* * math coprocessor segment overrun */ static void mathover(Ureg*, void*) { pexit("math overrun", 0); } void mathinit(void) { trapenable(VectorCERR, matherror, 0, "matherror"); if(X86FAMILY(m->cpuidax) == 3) intrenable(IrqIRQ13, matherror, 0, BUSUNKNOWN, "matherror"); trapenable(VectorCNA, mathemu, 0, "mathemu"); trapenable(VectorCSO, mathover, 0, "mathover"); trapenable(VectorSIMD, simderror, 0, "simderror"); } void procsetup(Proc *p) { p->fpstate = FPinit; _stts(); cycles(&p->kentry); p->pcycles = -p->kentry; } void procfork(Proc *p) { int s; p->kentry = up->kentry; p->pcycles = -p->kentry; /* save floating point state */ s = splhi(); switch(up->fpstate & ~FPillegal){ case FPactive: fpsave(&up->fpsave); up->fpstate = FPinactive; case FPinactive: p->fpsave = up->fpsave; p->fpstate = FPinactive; } splx(s); } void procrestore(Proc *p) { uvlong t; if(p->kp) return; cycles(&t); p->kentry += t; p->pcycles -= t; } void procsave(Proc *p) { uvlong t; cycles(&t); p->kentry -= t; p->pcycles += t; if(p->fpstate == FPactive){ if(p->state == Moribund){ _clts(); _fnclex(); _stts(); } else{ /* * Fpsave() stores without handling pending * unmasked exeptions. Postnote() can't be called * here as sleep() already has up->rlock, so * the handling of pending exceptions is delayed * until the process runs again and generates an * emulation fault to activate the FPU. */ fpsave(&p->fpsave); } p->fpstate = FPinactive; } /* * While this processor is in the scheduler, the process could run * on another processor and exit, returning the page tables to * the free list where they could be reallocated and overwritten. * When this processor eventually has to get an entry from the * trashed page tables it will crash. * * If there's only one processor, this can't happen. * You might think it would be a win not to do this in that case, * especially on VMware, but it turns out not to matter. */ mmuflushtlb(); }