#include "u.h" #include "../port/lib.h" #include "mem.h" #include "dat.h" #include "fns.h" #include "io.h" #include "ureg.h" #include "../port/error.h" typedef struct IOMap IOMap; struct IOMap { IOMap *next; int reserved; char tag[13]; ulong start; ulong end; }; static struct { Lock; IOMap *m; IOMap *free; IOMap maps[32]; /* some initial free maps */ QLock ql; /* lock for reading map */ } iomap; enum { Qdir = 0, Qioalloc = 1, Qiob, Qiow, Qiol, Qbase, Qmax = 32, }; enum { /* cpuid standard function codes */ Highstdfunc = 0, /* also returns vendor string */ Procsig, Proctlbcache, Procserial, }; typedef long Rdwrfn(Chan*, void*, long, vlong); static Rdwrfn *readfn[Qmax]; static Rdwrfn *writefn[Qmax]; static Dirtab archdir[Qmax] = { ".", { Qdir, 0, QTDIR }, 0, 0555, "ioalloc", { Qioalloc, 0 }, 0, 0444, "iob", { Qiob, 0 }, 0, 0660, "iow", { Qiow, 0 }, 0, 0660, "iol", { Qiol, 0 }, 0, 0660, }; Lock archwlock; /* the lock is only for changing archdir */ int narchdir = Qbase; int (*_pcmspecial)(char*, ISAConf*); void (*_pcmspecialclose)(int); static int doi8253set = 1; /* * Add a file to the #P listing. Once added, you can't delete it. * You can't add a file with the same name as one already there, * and you get a pointer to the Dirtab entry so you can do things * like change the Qid version. Changing the Qid path is disallowed. */ Dirtab* addarchfile(char *name, int perm, Rdwrfn *rdfn, Rdwrfn *wrfn) { int i; Dirtab d; Dirtab *dp; memset(&d, 0, sizeof d); strcpy(d.name, name); d.perm = perm; lock(&archwlock); if(narchdir >= Qmax){ unlock(&archwlock); return nil; } for(i=0; inext){ m = *l; if (m->start < 0x400) continue; i = m->start - port; if(i > size) break; if(align > 0) port = ((port+align-1)/align)*align; else port = m->end; } if(*l == nil){ unlock(&iomap); return -1; } m = iomap.free; if(m == nil){ print("ioalloc: out of maps"); unlock(&iomap); return port; } iomap.free = m->next; m->next = *l; m->start = port; m->end = port + size; m->reserved = 1; strncpy(m->tag, tag, sizeof(m->tag)); m->tag[sizeof(m->tag)-1] = 0; *l = m; archdir[0].qid.vers++; unlock(&iomap); return m->start; } /* * alloc some io port space and remember who it was * alloced to. if port < 0, find a free region. */ int ioalloc(int port, int size, int align, char *tag) { IOMap *m, **l; int i; lock(&iomap); if(port < 0){ /* find a free port above 0x400 and below 0x1000 */ port = 0x400; for(l = &iomap.m; *l; l = &(*l)->next){ m = *l; if (m->start < 0x400) continue; i = m->start - port; if(i > size) break; if(align > 0) port = ((port+align-1)/align)*align; else port = m->end; } if(*l == nil){ unlock(&iomap); return -1; } } else { /* Only 64KB I/O space on the x86. */ if((port+size) > 0x10000){ unlock(&iomap); return -1; } /* see if the space clashes with previously allocated ports */ for(l = &iomap.m; *l; l = &(*l)->next){ m = *l; if(m->end <= port) continue; if(m->reserved && m->start == port && m->end == port + size) { m->reserved = 0; unlock(&iomap); return m->start; } if(m->start >= port+size) break; unlock(&iomap); return -1; } } m = iomap.free; if(m == nil){ print("ioalloc: out of maps"); unlock(&iomap); return port; } iomap.free = m->next; m->next = *l; m->start = port; m->end = port + size; strncpy(m->tag, tag, sizeof(m->tag)); m->tag[sizeof(m->tag)-1] = 0; *l = m; archdir[0].qid.vers++; unlock(&iomap); return m->start; } void iofree(int port) { IOMap *m, **l; lock(&iomap); for(l = &iomap.m; *l; l = &(*l)->next){ if((*l)->start == port){ m = *l; *l = m->next; m->next = iomap.free; iomap.free = m; break; } if((*l)->start > port) break; } archdir[0].qid.vers++; unlock(&iomap); } int iounused(int start, int end) { IOMap *m; for(m = iomap.m; m; m = m->next){ if(start >= m->start && start < m->end || start <= m->start && end > m->start) return 0; } return 1; } static void checkport(int start, int end) { /* standard vga regs are OK */ if(start >= 0x2b0 && end <= 0x2df+1) return; if(start >= 0x3c0 && end <= 0x3da+1) return; if(iounused(start, end)) return; error(Eperm); } static Chan* archattach(char* spec) { return devattach('P', spec); } Walkqid* archwalk(Chan* c, Chan *nc, char** name, int nname) { return devwalk(c, nc, name, nname, archdir, narchdir, devgen); } static int archstat(Chan* c, uchar* dp, int n) { return devstat(c, dp, n, archdir, narchdir, devgen); } static Chan* archopen(Chan* c, int omode) { return devopen(c, omode, archdir, narchdir, devgen); } static void archclose(Chan*) { } enum { Linelen= 31, }; static long archread(Chan *c, void *a, long n, vlong offset) { char *buf, *p; int port; ushort *sp; ulong *lp; IOMap *m; Rdwrfn *fn; switch((ulong)c->qid.path){ case Qdir: return devdirread(c, a, n, archdir, narchdir, devgen); case Qiob: port = offset; checkport(offset, offset+n); for(p = a; port < offset+n; port++) *p++ = inb(port); return n; case Qiow: if(n & 1) error(Ebadarg); checkport(offset, offset+n); sp = a; for(port = offset; port < offset+n; port += 2) *sp++ = ins(port); return n; case Qiol: if(n & 3) error(Ebadarg); checkport(offset, offset+n); lp = a; for(port = offset; port < offset+n; port += 4) *lp++ = inl(port); return n; case Qioalloc: break; default: if(c->qid.path < narchdir && (fn = readfn[c->qid.path])) return fn(c, a, n, offset); error(Eperm); break; } if((buf = malloc(n)) == nil) error(Enomem); p = buf; n = n/Linelen; offset = offset/Linelen; lock(&iomap); for(m = iomap.m; n > 0 && m != nil; m = m->next){ if(offset-- > 0) continue; sprint(p, "%8lux %8lux %-12.12s\n", m->start, m->end-1, m->tag); p += Linelen; n--; } unlock(&iomap); n = p - buf; memmove(a, buf, n); free(buf); return n; } static long archwrite(Chan *c, void *a, long n, vlong offset) { char *p; int port; ushort *sp; ulong *lp; Rdwrfn *fn; switch((ulong)c->qid.path){ case Qiob: p = a; checkport(offset, offset+n); for(port = offset; port < offset+n; port++) outb(port, *p++); return n; case Qiow: if(n & 1) error(Ebadarg); checkport(offset, offset+n); sp = a; for(port = offset; port < offset+n; port += 2) outs(port, *sp++); return n; case Qiol: if(n & 3) error(Ebadarg); checkport(offset, offset+n); lp = a; for(port = offset; port < offset+n; port += 4) outl(port, *lp++); return n; default: if(c->qid.path < narchdir && (fn = writefn[c->qid.path])) return fn(c, a, n, offset); error(Eperm); break; } return 0; } Dev archdevtab = { 'P', "arch", devreset, devinit, devshutdown, archattach, archwalk, archstat, archopen, devcreate, archclose, archread, devbread, archwrite, devbwrite, devremove, devwstat, }; /* * the following is a generic version of the * architecture specific stuff */ static int unimplemented(int) { return 0; } static void nop(void) { } static void archreset(void) { i8042reset(); /* * 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. * And sometimes there is no keyboard... * * The reset register (0xcf9) is usually in one of the bridge * chips. The actual location and sequence could be extracted from * ACPI but why bother, this is the end of the line anyway. */ print("Takes a licking and keeps on ticking...\n"); *(ushort*)KADDR(0x472) = 0x1234; /* BIOS warm-boot flag */ outb(0xcf9, 0x02); outb(0xcf9, 0x06); for(;;) idle(); } /* * 386 has no compare-and-swap instruction. * Run it with interrupts turned off instead. */ static int cmpswap386(long *addr, long old, long new) { int r, s; s = splhi(); if(r = (*addr == old)) *addr = new; splx(s); return r; } /* * On a uniprocessor, you'd think that coherence could be nop, * but it can't. We still need a barrier when using coherence() in * device drivers. * * On VMware, it's safe (and a huge win) to set this to nop. * Aux/vmware does this via the #P/archctl file. */ void (*coherence)(void) = nop; int (*cmpswap)(long*, long, long) = cmpswap386; PCArch* arch; extern PCArch* knownarch[]; PCArch archgeneric = { .id= "generic", .ident= 0, .reset= archreset, .serialpower= unimplemented, .modempower= unimplemented, .intrinit= i8259init, .intrenable= i8259enable, .intrdisable= i8259disable, .intron= i8259on, .introff= i8259off, .clockenable= i8253enable, .fastclock= i8253read, .timerset= i8253timerset, }; typedef struct X86type X86type; struct X86type { int family; int model; int aalcycles; char* name; }; static X86type x86intel[] = { { 4, 0, 22, "486DX", }, /* known chips */ { 4, 1, 22, "486DX50", }, { 4, 2, 22, "486SX", }, { 4, 3, 22, "486DX2", }, { 4, 4, 22, "486SL", }, { 4, 5, 22, "486SX2", }, { 4, 7, 22, "DX2WB", }, /* P24D */ { 4, 8, 22, "DX4", }, /* P24C */ { 4, 9, 22, "DX4WB", }, /* P24CT */ { 5, 0, 23, "P5", }, { 5, 1, 23, "P5", }, { 5, 2, 23, "P54C", }, { 5, 3, 23, "P24T", }, { 5, 4, 23, "P55C MMX", }, { 5, 7, 23, "P54C VRT", }, { 6, 1, 16, "PentiumPro", },/* trial and error */ { 6, 3, 16, "PentiumII", }, { 6, 5, 16, "PentiumII/Xeon", }, { 6, 6, 16, "Celeron", }, { 6, 7, 16, "PentiumIII/Xeon", }, { 6, 8, 16, "PentiumIII/Xeon", }, { 6, 0xB, 16, "PentiumIII/Xeon", }, { 6, 0xF, 16, "Xeon5000", }, { 6, 0x16, 16, "ConroeL", }, { 6, 0x17, 16, "Xeon5400", }, { 6, 0x1a, 16, "Xeon3500/i7", }, { 6, 0x1c, 16, "Atom", }, { 6, 0x1d, 16, "Xeon7500", }, { 6, 0x1e, 16, "Xeon3400", }, { 6, 0x25, 16, "Core i5", }, { 6, 0x2a, 16, "Xeon E3", }, { 6, 0x2c, 16, "Xeon[35]600", }, { 0xF, 1, 16, "P4", }, /* P4 */ { 0xF, 2, 16, "PentiumIV/Xeon", }, { 0xF, 6, 16, "PentiumIV/Xeon", }, { 3, -1, 32, "386", }, /* family defaults */ { 4, -1, 22, "486", }, { 5, -1, 23, "P5", }, { 6, -1, 16, "P6", }, { 0xF, -1, 16, "P4", }, /* P4 */ { -1, -1, 16, "unknown", }, /* total default */ }; /* * The AMD processors all implement the CPUID instruction. * The later ones also return the processor name via functions * 0x80000002, 0x80000003 and 0x80000004 in registers AX, BX, CX * and DX: * K5 "AMD-K5(tm) Processor" * K6 "AMD-K6tm w/ multimedia extensions" * K6 3D "AMD-K6(tm) 3D processor" * K6 3D+ ? */ static X86type x86amd[] = { { 5, 0, 23, "AMD-K5", }, /* guesswork */ { 5, 1, 23, "AMD-K5", }, /* guesswork */ { 5, 2, 23, "AMD-K5", }, /* guesswork */ { 5, 3, 23, "AMD-K5", }, /* guesswork */ { 5, 4, 23, "AMD Geode GX1", }, /* guesswork */ { 5, 5, 23, "AMD Geode GX2", }, /* guesswork */ { 5, 6, 11, "AMD-K6", }, /* trial and error */ { 5, 7, 11, "AMD-K6", }, /* trial and error */ { 5, 8, 11, "AMD-K6-2", }, /* trial and error */ { 5, 9, 11, "AMD-K6-III", },/* trial and error */ { 5, 0xa, 23, "AMD Geode LX", }, /* guesswork */ { 0x1F, 9, 11, "AMD-K10 Opteron G34", },/* guesswork */ { 6, 1, 11, "AMD-Athlon", },/* trial and error */ { 6, 2, 11, "AMD-Athlon", },/* trial and error */ { 4, -1, 22, "Am486", }, /* guesswork */ { 5, -1, 23, "AMD-K5/K6", }, /* guesswork */ { 6, -1, 11, "AMD-Athlon", },/* guesswork */ { 0xF, -1, 11, "AMD64", }, /* guesswork */ { 0x1f, 2, 11, "AMD64-K10 AM2", }, /* guesswork */ { 0x1f, 4, 11, "AMD64-K10 AM2", }, /* guesswork */ { 0x1f, 6, 11, "AMD64-K10 AM3", }, /* guesswork */ { 0x1f, 8, 11, "AMD64-K10 x6", }, /* guesswork */ { 0x1f, -1, 11, "AMD64-K10", }, { -1, -1, 11, "AMD unknown", }, /* total default */ }; /* * WinChip 240MHz */ static X86type x86winchip[] = { {5, 4, 23, "Winchip",}, /* guesswork */ {6, 7, 23, "Via C3 Samuel 2 or Ezra",}, {6, 8, 23, "Via C3 Ezra-T",}, {6, 9, 23, "Via C3 Eden-N",}, { -1, -1, 23, "unknown", }, /* total default */ }; /* * SiS 55x */ static X86type x86sis[] = { {5, 0, 23, "SiS 55x",}, /* guesswork */ { -1, -1, 23, "unknown", }, /* total default */ }; static X86type *cputype; static void simplecycles(uvlong*); void (*cycles)(uvlong*) = simplecycles; void _cycles(uvlong*); /* in l.s */ #pragma profile 0 static void simplecycles(uvlong*x) { *x = m->ticks; } #pragma profile 1 void cpuidprint(void) { int i; char buf[128]; i = sprint(buf, "cpu%d: %dMHz ", m->machno, m->cpumhz); if(m->cpuidid[0]) i += sprint(buf+i, "%12.12s ", m->cpuidid); seprint(buf+i, buf + sizeof buf - 1, "%s (cpuid: AX 0x%4.4uX DX 0x%4.4uX)\n", m->cpuidtype, m->cpuidax, m->cpuiddx); print(buf); } /* * figure out: * - cpu type * - whether or not we have a TSC (cycle counter) * - whether or not it supports page size extensions * (if so turn it on) * - whether or not it supports machine check exceptions * (if so turn it on) * - whether or not it supports the page global flag * (if so turn it on) */ int cpuidentify(void) { char *p; int family, model, nomce; X86type *t, *tab; ulong cr4; Cpuidreg regs; vlong mca, mct; cpuid(Highstdfunc, ®s); memmove(m->cpuidid, ®s.bx, BY2WD); /* bx */ memmove(m->cpuidid+4, ®s.dx, BY2WD); /* dx */ memmove(m->cpuidid+8, ®s.cx, BY2WD); /* cx */ m->cpuidid[12] = '\0'; cpuid(Procsig, ®s); m->cpuidax = regs.ax; m->cpuiddx = regs.dx; if(strncmp(m->cpuidid, "AuthenticAMD", 12) == 0 || strncmp(m->cpuidid, "Geode by NSC", 12) == 0) tab = x86amd; else if(strncmp(m->cpuidid, "CentaurHauls", 12) == 0) tab = x86winchip; else if(strncmp(m->cpuidid, "SiS SiS SiS ", 12) == 0) tab = x86sis; else tab = x86intel; family = X86FAMILY(m->cpuidax); model = X86MODEL(m->cpuidax); for(t=tab; t->name; t++) if((t->family == family && t->model == model) || (t->family == family && t->model == -1) || (t->family == -1)) break; m->cpuidtype = t->name; /* * if there is one, set tsc to a known value */ if(m->cpuiddx & Tsc){ m->havetsc = 1; cycles = _cycles; if(m->cpuiddx & Cpumsr) wrmsr(0x10, 0); } /* * use i8253 to guess our cpu speed */ guesscpuhz(t->aalcycles); /* * If machine check exception, page size extensions or page global bit * are supported enable them in CR4 and clear any other set extensions. * If machine check was enabled clear out any lingering status. */ if(m->cpuiddx & (Pge|Mce|0x8)){ cr4 = 0; if(0 && m->cpuiddx & Pae) cr4 |= getcr4() & 1<<5; if(m->cpuiddx & 0x08) cr4 |= 0x10; /* page size extensions */ if(p = getconf("*nomce")) nomce = strtoul(p, 0, 0); else nomce = 0; if((m->cpuiddx & Mce) && !nomce){ cr4 |= 0x40; /* machine check enable */ if(family == 5){ rdmsr(0x00, &mca); rdmsr(0x01, &mct); } } /* * Detect whether the chip supports the global bit * in page directory and page table entries. When set * in a particular entry, it means ``don't bother removing * this from the TLB when CR3 changes.'' * * We flag all kernel pages with this bit. Doing so lessens the * overhead of switching processes on bare hardware, * even more so on VMware. See mmu.c:/^memglobal. * * For future reference, should we ever need to do a * full TLB flush, it can be accomplished by clearing * the PGE bit in CR4, writing to CR3, and then * restoring the PGE bit. */ if(m->cpuiddx & Pge){ cr4 |= 0x80; /* page global enable bit */ m->havepge = 1; } putcr4(cr4); if(m->cpuiddx & Mce) rdmsr(0x01, &mct); } cputype = t; return t->family; } static long cputyperead(Chan*, void *a, long n, vlong offset) { char str[32]; ulong mhz; mhz = (m->cpuhz+999999)/1000000; snprint(str, sizeof(str), "%s %lud\n", cputype->name, mhz); return readstr(offset, a, n, str); } static int intelcputempok(void) { Cpuidreg r; if(m->cpuiddx & Acpif) if(strcmp(m->cpuidid, "GenuineIntel") == 0){ cpuid(6, &r); return r.ax & 1; } return 0; } static char Notemp[] = "-1 -1 unsupported\n"; static long cputemprd0(Chan*, void *a, long n, vlong offset) { char buf[32], *s; ulong msr, t, res, d; vlong emsr; Cpuidreg r; static ulong tj; cpuid(6, &r); if((r.ax & 1) == 0) return readstr(offset, a, n, Notemp); if(tj == 0){ /* * magic undocumented msr. tj(max) is 100 or 85. */ tj = 100; d = X86MODEL(m->cpuidax); d |= (m->cpuidax>>12) & 0xf0; if((d == 0xf && (m->cpuidax & 0xf)>1) || d == 0xe){ rdmsr(0xee, &emsr); msr = emsr; if(msr & 1<<30) tj = 85; } } rdmsr(0x19c, &emsr); msr = emsr; t = -1; if(msr & 1<<31){ t = (msr>>16) & 127; t = tj - t; } res = (msr>>27) & 15; s = ""; if((msr & 0x30) == 0x30) s = " alarm"; snprint(buf, sizeof buf, "%ld %lud%s\n", t, res, s); return readstr(offset, a, n, buf); } static long intelcputemprd(Chan *c, void *va, long n, vlong offset) { char *a; long i, r, t; Mach *w; w = up->wired; a = va; t = 0; for(i = 0; i < conf.nmach; i++){ procwired(up, i); sched(); r = cputemprd0(c, a, n, offset); if(r == 0) break; offset -= r; if(offset < 0) offset = 0; n -= r; a = a + r; t += r; } up->wired = w; sched(); return t; } static long amd0ftemprd(Chan*, void *a, long n, vlong offset) { char *s, *e, buf[64]; long i, t, j, max; Pcidev *p; p = pcimatch(0, 0x1022, 0x1103); if(p == nil) return readstr(offset, a, n, Notemp); max = 2; if(max > conf.nmach) max = conf.nmach; s = buf; e = buf + sizeof buf; for(j = 0; j < max; j++){ pcicfgw32(p, 0xe4, pcicfgr32(p, 0xe4) & ~4 | j<<2); i = pcicfgr32(p, 0xe4); if(X86STEPPING(m->cpuidax) == 2) t = i>>16 & 0xff; else{ t = i>>14 & 0x3ff; t *= 3; t /= 4; } t += -49; s = seprint(s, e, "%ld %lud%s\n", t, 1l, ""); } return readstr(offset, a, n, buf); } static long amd10temprd(Chan*, void *a, long n, vlong offset) { char *s, *e, *r, *buf; long i, t, c, nb, cores[MAXMACH]; Pcidev *p; nb = 0; for(p = 0; p = pcimatch(p, 0x1022, 0x1203); ){ cores[nb++] = 1 + ((pcicfgr32(p, 0xe8) & 0x3000)>>12); if(nb == nelem(cores)) break; } if(nb == 0) return readstr(offset, a, n, Notemp); buf = smalloc(MAXMACH*4*32); s = buf; e = buf + MAXMACH*4*32; nb = 0; c = 0; for(p = 0; p = pcimatch(p, 0x1022, 0x1203); nb++){ i = pcicfgr32(p, 0xa4) & 0x7fffffff; i >>= 21; t = i/8; r = ".0"; if(i % 8 >= 4) r = "0.5"; /* * only one value per nb; repeat per core */ while(c++ < conf.nmach && cores[nb]--) s = seprint(s, e, "%ld%s 0.5%s\n", t, r, ""); } i = readstr(offset, a, n, buf); free(buf); return i; } static long archctlread(Chan*, void *a, long nn, vlong offset) { int n; char *buf, *p, *ep; p = buf = malloc(READSTR); ep = p + READSTR; p = seprint(p, ep, "cpu %s %lud%s\n", cputype->name, (ulong)(m->cpuhz+999999)/1000000, m->havepge ? " pge" : ""); p = seprint(p, ep, "pge %s\n", getcr4()&0x80 ? "on" : "off"); p = seprint(p, ep, "coherence "); if(coherence == mb386) p = seprint(p, ep, "mb386\n"); else if(coherence == mb586) p = seprint(p, ep, "mb586\n"); else if(coherence == mfence) p = seprint(p, ep, "mfence\n"); else if(coherence == nop) p = seprint(p, ep, "nop\n"); else p = seprint(p, ep, "0x%p\n", coherence); p = seprint(p, ep, "cmpswap "); if(cmpswap == cmpswap386) p = seprint(p, ep, "cmpswap386\n"); else if(cmpswap == cmpswap486) p = seprint(p, ep, "cmpswap486\n"); else p = seprint(p, ep, "0x%p\n", cmpswap); p = seprint(p, ep, "i8253set %s\n", doi8253set ? "on" : "off"); seprint(p, ep, "tsc %s\n", m->havetsc ? "on" : "off"); n = readstr(offset, a, nn, buf); free(buf); return n; } enum { CMpge, CMcoherence, CMi8253set, }; static Cmdtab archctlmsg[] = { CMpge, "pge", 2, CMcoherence, "coherence", 2, CMi8253set, "i8253set", 2, }; static long archctlwrite(Chan*, void *a, long n, vlong) { Cmdbuf *cb; Cmdtab *ct; cb = parsecmd(a, n); if(waserror()){ free(cb); nexterror(); } ct = lookupcmd(cb, archctlmsg, nelem(archctlmsg)); switch(ct->index){ case CMpge: if(!m->havepge) error("processor does not support pge"); if(strcmp(cb->f[1], "on") == 0) putcr4(getcr4() | 0x80); else if(strcmp(cb->f[1], "off") == 0) putcr4(getcr4() & ~0x80); else cmderror(cb, "invalid pge ctl"); break; case CMcoherence: if(strcmp(cb->f[1], "mb386") == 0) coherence = mb386; else if(strcmp(cb->f[1], "mb586") == 0){ if(X86FAMILY(m->cpuidax) < 5) error("invalid coherence ctl on this cpu family"); coherence = mb586; }else if(strcmp(cb->f[1], "mfence") == 0){ if((m->cpuiddx & Sse2) == 0) error("invalid coherence ctl on this cpu family"); coherence = mfence; }else if(strcmp(cb->f[1], "nop") == 0){ /* only safe on vmware */ if(conf.nmach > 1) error("cannot disable coherence on a multiprocessor"); coherence = nop; }else cmderror(cb, "invalid coherence ctl"); break; case CMi8253set: if(strcmp(cb->f[1], "on") == 0) doi8253set = 1; else if(strcmp(cb->f[1], "off") == 0){ doi8253set = 0; (*arch->timerset)(0); }else cmderror(cb, "invalid i2853set ctl"); break; } free(cb); poperror(); return n; } static long msrwr(Chan *c, void *va, long n, vlong) { char buf[32]; u32int msr; if(n>sizeof buf - 1) error(Etoobig); memmove(buf, va, n); buf[n] = 0; msr = strtoul(buf, nil, 0); c->aux = (void*)(uintptr)msr; return n; } static long msrrd(Chan *c, void *va, long n, vlong offset) { char *a, buf[64]; long i, t, r; u32int msr; vlong v; /* sic */ Mach *w; w = up->wired; a = va; t = 0; msr = (u32int)(uintptr)c->aux; for(i = 0; i < conf.nmach; i++){ procwired(up, i); sched(); rdmsr(msr, &v); snprint(buf, sizeof buf, "%ld %.16llux\n", i, v); r = readstr(offset, a, n, buf); if(r == 0) break; offset -= r; if(offset < 0) offset = 0; n -= r; a = a + r; t += r; } up->wired = w; sched(); return t; } void archinit(void) { PCArch **p; arch = 0; for(p = knownarch; *p; p++){ if((*p)->ident && (*p)->ident() == 0){ arch = *p; break; } } if(arch == 0) arch = &archgeneric; else{ if(arch->id == 0) arch->id = archgeneric.id; if(arch->reset == 0) arch->reset = archgeneric.reset; if(arch->serialpower == 0) arch->serialpower = archgeneric.serialpower; if(arch->modempower == 0) arch->modempower = archgeneric.modempower; if(arch->intrinit == 0) arch->intrinit = archgeneric.intrinit; if(arch->intrenable == 0) arch->intrenable = archgeneric.intrenable; } /* * Decide whether to use copy-on-reference (386 and mp). * We get another chance to set it in mpinit() for a * multiprocessor. */ if(X86FAMILY(m->cpuidax) == 3) conf.copymode = 1; if(X86FAMILY(m->cpuidax) >= 4) cmpswap = cmpswap486; if(X86FAMILY(m->cpuidax) >= 5) coherence = mb586; if(m->cpuiddx & Sse2) coherence = mfence; if(intelcputempok()) addarchfile("cputemp", 0444, intelcputemprd, nil); if(strcmp(m->cpuidid, "AuthenticAMD") == 0) switch(X86FAMILY(m->cpuidax)){ case 0xf: addarchfile("cputemp", 0444, amd0ftemprd, nil); break; case 0x10: case 0x1f: addarchfile("cputemp", 0444, amd10temprd, nil); break; } addarchfile("cputype", 0444, cputyperead, nil); addarchfile("archctl", 0664, archctlread, archctlwrite); addarchfile("msr", 0664, msrrd, msrwr); } /* * call either the pcmcia or pccard device setup */ int pcmspecial(char *idstr, ISAConf *isa) { return (_pcmspecial != nil)? _pcmspecial(idstr, isa): -1; } /* * call either the pcmcia or pccard device teardown */ void pcmspecialclose(int a) { if (_pcmspecialclose != nil) _pcmspecialclose(a); } /* * return value and speed of timer set in arch->clockenable */ uvlong fastticks(uvlong *hz) { return (*arch->fastclock)(hz); } ulong µs(void) { return fastticks2us((*arch->fastclock)(nil)); } /* * set next timer interrupt */ void timerset(Tval x) { if(doi8253set) (*arch->timerset)(x); }