#include "u.h" #include "../port/lib.h" #include "mem.h" #include "dat.h" #include "fns.h" #include "init.h" #include "arm.h" #include #include #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 BOOTARGS ((char*)CONFADDR) #define BOOTARGSLEN (16*KiB) /* limit in devenv.c */ #define MAXCONF 64 #define MAXCONFLINE 160 enum { Maxmem = 512*MB, /* limited by address ranges */ Minmem = 256*MB, /* conservative default */ /* space for syscall args, return PC, top-of-stack struct */ Ustkheadroom = sizeof(Sargs) + sizeof(uintptr) + sizeof(Tos), }; #define isascii(c) ((uchar)(c) > 0 && (uchar)(c) < 0177) uintptr kseg0 = KZERO; Mach* machaddr[MAXMACH]; /* * Option arguments from the command line. * oargv[0] is the boot file. * Optionsinit() is called from multiboot() * or some other machine-dependent place * to set it all up. */ static int oargc; static char* oargv[20]; static char oargb[128]; static int oargblen; static char oenv[4096]; static uintptr sp; /* XXX - must go - user stack of init proc */ int vflag; char debug[256]; /* store plan9.ini contents here at least until we stash them in #ec */ static char confname[MAXCONF][KNAMELEN]; static char confval[MAXCONF][MAXCONFLINE]; static int nconf; #ifdef CRYPTOSANDBOX uchar sandbox[64*1024+BY2PG]; #endif static int findconf(char *name) { int i; for(i = 0; i < nconf; i++) if(cistrcmp(confname[i], name) == 0) return i; return -1; } char* getconf(char *name) { int i; i = findconf(name); if(i >= 0) return confval[i]; return nil; } void addconf(char *name, char *val) { int i; i = findconf(name); if(i < 0){ if(val == nil || nconf >= MAXCONF) return; i = nconf++; strecpy(confname[i], confname[i]+sizeof(confname[i]), name); } // confval[i] = val; strecpy(confval[i], confval[i]+sizeof(confval[i]), val); } 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"); memmove(BOOTARGS, p, n); poperror(); free(p); } /* * assumes that we have loaded our /cfg/pxe/mac file at 0x1000 with * tftp in u-boot. no longer uses malloc, so can be called early. */ static void plan9iniinit(void) { char *k, *v, *next; k = (char *)CONFADDR; if(!isascii(*k)) return; for(; k && *k != '\0'; k = next) { if (!isascii(*k)) /* sanity check */ break; next = strchr(k, '\n'); if (next) *next++ = '\0'; if (*k == '\0' || *k == '\n' || *k == '#') continue; v = strchr(k, '='); if(v == nil) continue; /* mal-formed line */ *v++ = '\0'; addconf(k, v); } } static void optionsinit(char* s) { char *o; o = strecpy(oargb, oargb+sizeof(oargb), s)+1; if(getenv("bootargs", o, o - oargb) != nil) *(o-1) = ' '; oargblen = strlen(oargb); oargc = tokenize(oargb, oargv, nelem(oargv)-1); oargv[oargc] = nil; } char* getenv(char* name, char* buf, int n) { char *e, *p, *q; p = oenv; while(*p != 0){ if((e = strchr(p, '=')) == nil) break; for(q = name; p < e; p++){ if(*p != *q) break; q++; } if(p == e && *q == 0){ strecpy(buf, buf+n, e+1); return buf; } p += strlen(p)+1; } return nil; } #include "io.h" typedef struct Spiregs Spiregs; struct Spiregs { ulong ictl; /* interface ctl */ ulong icfg; /* interface config */ ulong out; /* data out */ ulong in; /* data in */ ulong ic; /* interrupt cause */ ulong im; /* interrupt mask */ ulong _pad[2]; ulong dwrcfg; /* direct write config */ ulong dwrhdr; /* direct write header */ }; enum { /* ictl bits */ Csnact = 1<<0, /* serial memory activated */ /* icfg bits */ Bytelen = 1<<5, /* 2^(this_bit) bytes per transfer */ Dirrdcmd= 1<<10, /* flag: fast read */ }; static void dumpbytes(uchar *bp, long max) { iprint("%#p: ", bp); for (; max > 0; max--) iprint("%02.2ux ", *bp++); iprint("...\n"); } void archconsole(void); vlong probeaddr(uintptr); static void spiprobe(void) { if (0) { /* generates repeated "spurious irqbridge interrupt: 00000010" on sheevaplug. */ Spiregs *rp = (Spiregs *)soc.spi; if (probeaddr(soc.spi) < 0) return; rp->ictl |= Csnact; coherence(); rp->icfg |= Dirrdcmd | 3<<8; /* fast reads, 4-byte addresses */ rp->icfg &= ~Bytelen; /* one-byte reads */ coherence(); print("spi flash ignored: ctlr %#p, data %#ux", rp, PHYSSPIFLASH); mmuidmap(PHYSSPIFLASH, 1); if (probeaddr(PHYSSPIFLASH) < 0) print(" (no response)"); print(": memory reads enabled\n"); } } /* * entered from l.s with mmu enabled. * * we may have to realign the data segment; apparently 5l -H0 -R4096 * does not pad the text segment. on the other hand, we may have been * loaded by another kernel. * * be careful not to touch the data segment until we know it's aligned. */ void main(Mach* mach) { extern char bdata[], edata[], end[], etext[]; static ulong vfy = 0xcafebabe; m = mach; if (vfy != 0xcafebabe) memmove(bdata, etext, edata - bdata); if (vfy != 0xcafebabe) { wave('?'); panic("misaligned data segment"); } memset(edata, 0, end - edata); /* zero bss */ vfy = 0; wave('9'); machinit(); archreset(); mmuinit(); optionsinit("/boot/boot boot"); quotefmtinstall(); archconsole(); wave(' '); /* want plan9.ini to be able to affect memory sizing in confinit */ plan9iniinit(); /* before we step on plan9.ini in low memory */ /* set memsize before xinit */ confinit(); /* xinit would print if it could */ xinit(); /* * Printinit will cause the first malloc call. * (printinit->qopen->malloc) unless any of the * above (like clockintr) do an irqenable, which * will call malloc. * If the system dies here it's probably due * to malloc(->xalloc) not being initialised * correctly, or the data segment is misaligned * (it's amazing how far you can get with * things like that completely broken). * * (Should be) boilerplate from here on. */ trapinit(); clockinit(); printinit(); uartkirkwoodconsole(); /* only now can we print */ print("from Bell Labs\n\n"); #ifdef CRYPTOSANDBOX print("sandbox: 64K at physical %#lux, mapped to 0xf10b0000\n", PADDR((uintptr)sandbox & ~(BY2PG-1))); #endif archconfinit(); cpuidprint(); timersinit(); procinit0(); initseg(); links(); chandevreset(); /* most devices are discovered here */ spiprobe(); pageinit(); swapinit(); userinit(); schedinit(); panic("schedinit returned"); } void cpuidprint(void) { char name[64]; cputype2name(name, sizeof name); print("cpu%d: %lldMHz ARM %s\n", m->machno, m->cpuhz/1000000, name); } void machinit(void) { memset(m, 0, sizeof(Mach)); m->machno = 0; machaddr[m->machno] = m; m->ticks = 1; m->perf.period = 1; conf.nmach = 1; active.machs = 1; active.exiting = 0; up = nil; } static void shutdown(int ispanic) { int ms, once; lock(&active); if(ispanic) active.ispanic = ispanic; else if(m->machno == 0 && (active.machs & (1<machno)) == 0) active.ispanic = 0; once = active.machs & (1<machno); active.machs &= ~(1<machno); active.exiting = 1; unlock(&active); if(once) iprint("cpu%d: exiting\n", m->machno); spllo(); for(ms = 5*1000; ms > 0; ms -= TK2MS(2)){ delay(TK2MS(2)); if(active.machs == 0 && consactive() == 0) break; } delay(1000); } /* * exit kernel either on a panic or user request */ void exit(int code) { shutdown(code); splhi(); archreboot(); } /* * the new kernel is already loaded at address `code' * of size `size' and entry point `entry'. */ void reboot(void *entry, void *code, ulong size) { void (*f)(ulong, ulong, ulong); iprint("starting reboot..."); writeconf(); shutdown(0); /* * should be the only processor running now */ print("shutting down...\n"); delay(200); /* turn off buffered serial console */ serialoq = nil; /* shutdown devices */ chandevshutdown(); /* call off the dog */ clockshutdown(); splhi(); /* setup reboot trampoline function */ f = (void*)REBOOTADDR; memmove(f, rebootcode, sizeof(rebootcode)); cacheuwbinv(); l2cacheuwb(); print("rebooting..."); iprint("entry %#lux code %#lux size %ld\n", PADDR(entry), PADDR(code), size); delay(100); /* wait for uart to quiesce */ /* off we go - never to return */ cacheuwbinv(); l2cacheuwb(); (*f)(PADDR(entry), PADDR(code), size); iprint("loaded kernel returned!\n"); delay(1000); archreboot(); } /* * starting place for first process */ void init0(void) { int i; char buf[2*KNAMELEN]; assert(up != nil); up->nerrlab = 0; coherence(); 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", "ARM", conffile); ksetenv("terminal", buf, 0); ksetenv("cputype", "arm", 0); if(cpuserver) ksetenv("service", "cpu", 0); else ksetenv("service", "terminal", 0); /* convert plan9.ini variables to #e and #ec */ for(i = 0; i < nconf; i++) { ksetenv(confname[i], confval[i], 0); ksetenv(confname[i], confval[i], 1); } poperror(); } kproc("alarm", alarmkproc, 0); touser(sp); } static void bootargs(uintptr base) { int i; ulong ssize; char **av, *p; /* * Push the boot args onto the stack. * The initial value of the user stack must be such * that the total used is larger than the maximum size * of the argument list checked in syscall. */ i = oargblen+1; p = UINT2PTR(STACKALIGN(base + BY2PG - Ustkheadroom - i)); memmove(p, oargb, i); /* * Now push argc and the argv pointers. * This isn't strictly correct as the code jumped to by * touser in init9.s calls startboot (port/initcode.c) which * expects arguments * startboot(char *argv0, char **argv) * not the usual (int argc, char* argv[]), but argv0 is * unused so it doesn't matter (at the moment...). */ av = (char**)(p - (oargc+2)*sizeof(char*)); ssize = base + BY2PG - PTR2UINT(av); *av++ = (char*)oargc; for(i = 0; i < oargc; i++) *av++ = (oargv[i] - oargb) + (p - base) + (USTKTOP - BY2PG); *av = nil; /* * Leave space for the return PC of the * caller of initcode. */ sp = USTKTOP - ssize - sizeof(void*); } /* * create the first process */ void userinit(void) { Proc *p; Segment *s; KMap *k; Page *pg; /* no processes yet */ up = nil; 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); /* * Kernel Stack */ p->sched.pc = PTR2UINT(init0); p->sched.sp = PTR2UINT(p->kstack+KSTACK-sizeof(up->s.args)-sizeof(uintptr)); p->sched.sp = STACKALIGN(p->sched.sp); /* * User Stack * * Technically, newpage can't be called here because it * should only be called when in a user context as it may * try to sleep if there are no pages available, but that * shouldn't be the case here. */ s = newseg(SG_STACK, USTKTOP-USTKSIZE, USTKSIZE/BY2PG); p->seg[SSEG] = s; pg = newpage(1, 0, USTKTOP-BY2PG); segpage(s, pg); k = kmap(pg); bootargs(VA(k)); kunmap(k); /* * Text */ s = newseg(SG_TEXT, UTZERO, 1); s->flushme++; p->seg[TSEG] = s; pg = newpage(1, 0, UTZERO); memset(pg->cachectl, PG_TXTFLUSH, sizeof(pg->cachectl)); segpage(s, pg); k = kmap(s->map[0]->pages[0]); memmove(UINT2PTR(VA(k)), initcode, sizeof initcode); kunmap(k); ready(p); } Conf conf; /* XXX - must go - gag */ Confmem sheevamem[nelem(conf.mem)] = { /* * Memory available to Plan 9: * the 8K is reserved for ethernet dma access violations to scribble on. */ { .base = PHYSDRAM, .limit = PHYSDRAM + Maxmem - 8*1024, }, }; ulong memsize = Maxmem; static int gotmem(uintptr sz) { uintptr addr; addr = PHYSDRAM + sz - MB; mmuidmap(addr, 1); if (probeaddr(addr) >= 0) { memsize = sz; return 0; } return -1; } void confinit(void) { int i; ulong kpages; uintptr pa; char *p; /* * Copy the physical memory configuration to Conf.mem. */ if(nelem(sheevamem) > nelem(conf.mem)){ iprint("memory configuration botch\n"); exit(1); } if((p = getconf("*maxmem")) != nil) { memsize = strtoul(p, 0, 0) - PHYSDRAM; if (memsize < 16*MB) /* sanity */ memsize = 16*MB; } /* * see if all that memory exists; if not, find out how much does. * trapinit must have been called first. */ if (gotmem(memsize) < 0 && gotmem(256*MB) < 0 && gotmem(128*MB) < 0) { iprint("can't find any memory, assuming %dMB\n", Minmem / MB); memsize = Minmem; } sheevamem[0].limit = PHYSDRAM + memsize - 8*1024; memmove(conf.mem, sheevamem, sizeof(sheevamem)); conf.npage = 0; pa = PADDR(PGROUND(PTR2UINT(end))); /* * we assume that the kernel is at the beginning of one of the * contiguous chunks of memory and fits therein. */ for(i=0; i conf.mem[i].base && pa < conf.mem[i].limit) conf.mem[i].base = pa; conf.mem[i].npage = (conf.mem[i].limit - conf.mem[i].base)/BY2PG; conf.npage += conf.mem[i].npage; } conf.upages = (conf.npage*90)/100; conf.ialloc = ((conf.npage-conf.upages)/2)*BY2PG; /* only one processor */ conf.nmach = 1; /* set up other configuration parameters */ conf.nproc = 100 + ((conf.npage*BY2PG)/MB)*5; if(cpuserver) conf.nproc *= 3; if(conf.nproc > 2000) conf.nproc = 2000; conf.nswap = conf.npage*3; conf.nswppo = 4096; conf.nimage = 200; conf.copymode = 0; /* copy on write */ /* * Guess how much is taken by the large permanent * datastructures. Mntcache and Mntrpc are not accounted for * (probably ~300KB). */ kpages = conf.npage - conf.upages; kpages *= BY2PG; kpages -= conf.upages*sizeof(Page) + conf.nproc*sizeof(Proc) + conf.nimage*sizeof(Image) + conf.nswap + conf.nswppo*sizeof(Page); mainmem->maxsize = kpages; if(!cpuserver) /* * give terminals lots of image memory, too; the dynamic * allocation will balance the load properly, hopefully. * be careful with 32-bit overflow. */ imagmem->maxsize = kpages; } int cmpswap(long *addr, long old, long new) { return cas32(addr, old, new); }