ref: 1e9bb75854a336de2a63f9a4fb4d67dd75d682f1
dir: /sys/src/9/pc/devarch.c/
#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" enum { Qdir = 0, Qiob, Qiow, Qiol, Qmsr, Qbase, Qmax = 32, }; enum { /* cpuid standard function codes */ Highstdfunc = 0, /* also returns vendor string */ Procsig, Proctlbcache, Procserial, Highextfunc = 0x80000000, Procextfeat, }; typedef long Rdwrfn(Chan*, void*, long, vlong); static Rdwrfn *readfn[Qmax]; static Rdwrfn *writefn[Qmax]; static Dirtab archdir[Qmax] = { ".", { Qdir, 0, QTDIR }, 0, 0555, "iob", { Qiob, 0 }, 0, 0660, "iow", { Qiow, 0 }, 0, 0660, "iol", { Qiol, 0 }, 0, 0660, "msr", { Qmsr, 0 }, 0, 0660, }; Lock archwlock; /* the lock is only for changing archdir */ int narchdir = Qbase; int (*_pcmspecial)(char*, ISAConf*); void (*_pcmspecialclose)(int); /* * 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); print("addarchfile: out of entries for %s\n", name); return nil; } for(i=0; i<narchdir; i++) if(strcmp(archdir[i].name, name) == 0){ unlock(&archwlock); return nil; } d.qid.path = narchdir; archdir[narchdir] = d; readfn[narchdir] = rdfn; writefn[narchdir] = wrfn; dp = &archdir[narchdir++]; unlock(&archwlock); return dp; } void ioinit(void) { char *excluded; iomapinit(0xffff); /* * This is necessary to make the IBM X20 boot. * Have not tracked down the reason. * i82557 is at 0x1000, the dummy entry is needed for swappable devs. */ ioalloc(0x0fff, 1, 0, "dummy"); if ((excluded = getconf("ioexclude")) != nil) { char *s; s = excluded; while (s && *s != '\0' && *s != '\n') { char *ends; int io_s, io_e; io_s = (int)strtol(s, &ends, 0); if (ends == nil || ends == s || *ends != '-') { print("ioinit: cannot parse option string\n"); break; } s = ++ends; io_e = (int)strtol(s, &ends, 0); if (ends && *ends == ',') *ends++ = '\0'; s = ends; ioalloc(io_s, io_e - io_s + 1, 0, "pre-allocated"); } } } static void checkport(ulong start, ulong end) { if(end < start || end > 0x10000) error(Ebadarg); /* 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*) { } static long archread(Chan *c, void *a, long n, vlong offset) { ulong port, end; uchar *cp; ushort *sp; ulong *lp; vlong *vp; Rdwrfn *fn; port = offset; end = port+n; switch((ulong)c->qid.path){ case Qdir: return devdirread(c, a, n, archdir, narchdir, devgen); case Qiob: checkport(port, end); for(cp = a; port < end; port++) *cp++ = inb(port); return n; case Qiow: if(n & 1) error(Ebadarg); checkport(port, end); for(sp = a; port < end; port += 2) *sp++ = ins(port); return n; case Qiol: if(n & 3) error(Ebadarg); checkport(port, end); for(lp = a; port < end; port += 4) *lp++ = inl(port); return n; case Qmsr: if(n & 7) error(Ebadarg); if((ulong)n/8 > -port) error(Ebadarg); end = port+(n/8); for(vp = a; port != end; port++) if(rdmsr(port, vp++) < 0) error(Ebadarg); return n; default: if(c->qid.path < narchdir && (fn = readfn[c->qid.path])) return fn(c, a, n, offset); error(Eperm); return 0; } } static long archwrite(Chan *c, void *a, long n, vlong offset) { ulong port, end; uchar *cp; ushort *sp; ulong *lp; vlong *vp; Rdwrfn *fn; port = offset; end = port+n; switch((ulong)c->qid.path){ case Qiob: checkport(port, end); for(cp = a; port < end; port++) outb(port, *cp++); return n; case Qiow: if(n & 1) error(Ebadarg); checkport(port, end); for(sp = a; port < end; port += 2) outs(port, *sp++); return n; case Qiol: if(n & 3) error(Ebadarg); checkport(port, end); for(lp = a; port < end; port += 4) outl(port, *lp++); return n; case Qmsr: if(n & 7) error(Ebadarg); if((ulong)n/8 > -port) error(Ebadarg); end = port+(n/8); for(vp = a; port != end; port++) if(wrmsr(port, *vp++) < 0) error(Ebadarg); return n; default: if(c->qid.path < narchdir && (fn = writefn[c->qid.path]) != nil) 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) { } /* * 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[]; 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-series", }, { 6, 0x16, 16, "Celeron", }, { 6, 0x17, 16, "Core 2/Xeon", }, { 6, 0x1A, 16, "Core i7/Xeon", }, { 6, 0x1C, 16, "Atom", }, { 6, 0x1D, 16, "Xeon MP", }, { 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 */ { 6, 1, 11, "AMD-Athlon", },/* trial and error */ { 6, 2, 11, "AMD-Athlon", },/* trial and error */ { 0x1F, 9, 11, "AMD-K10 Opteron G34", },/* guesswork */ { 4, -1, 22, "Am486", }, /* guesswork */ { 5, -1, 23, "AMD-K5/K6", }, /* guesswork */ { 6, -1, 11, "AMD-Athlon", },/* guesswork */ { 0xF, -1, 11, "AMD-K8", }, /* guesswork */ { 0x1F, -1, 11, "AMD-K10", }, /* guesswork */ { 23, 1, 13, "AMD Ryzen" }, { -1, -1, 11, "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",}, {6, 0xd, 23, "Via C7 Eden",}, { -1, -1, 23, "unknown", }, /* total default */ }; /* * SiS 55x */ static X86type x86sis[] = { {5, 0, 23, "SiS 55x",}, /* guesswork */ { -1, -1, 23, "unknown", }, /* total default */ }; static void simplecycles(uvlong*); void (*cycles)(uvlong*) = simplecycles; void _cycles(uvlong*); /* in l.s */ static void simplecycles(uvlong*x) { *x = m->ticks; } void cpuidprint(void) { print("cpu%d: %dMHz %s %s (AX %8.8uX CX %8.8uX DX %8.8uX)\n", m->machno, m->cpumhz, m->cpuidid, m->cpuidtype, m->cpuidax, m->cpuidcx, m->cpuiddx); } /* * 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) * - detect PAT feature and add write-combining entry * - detect MTRR support and synchronize state with cpu0 * - detect NX support and enable it for AMD64 * - detect watchpoint support * - detect FPU features and enable the FPU */ int cpuidentify(void) { int family, model; X86type *t, *tab; ulong regs[4]; uintptr cr4; cpuid(Highstdfunc, 0, regs); memmove(m->cpuidid, ®s[1], BY2WD); /* bx */ memmove(m->cpuidid+4, ®s[3], BY2WD); /* dx */ memmove(m->cpuidid+8, ®s[2], BY2WD); /* cx */ m->cpuidid[12] = '\0'; cpuid(Procsig, 0, regs); m->cpuidax = regs[0]; m->cpuidcx = regs[2]; m->cpuiddx = regs[3]; m->cpuidfamily = m->cpuidax >> 8 & 0xf; m->cpuidmodel = m->cpuidax >> 4 & 0xf; m->cpuidstepping = m->cpuidax & 0xf; switch(m->cpuidfamily){ case 15: m->cpuidfamily += m->cpuidax >> 20 & 0xff; m->cpuidmodel += m->cpuidax >> 16 & 0xf; break; case 6: m->cpuidmodel += m->cpuidax >> 16 & 0xf; break; } 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 = m->cpuidfamily; model = m->cpuidmodel; for(t=tab; t->name; t++) if((t->family == family && t->model == model) || (t->family == family && t->model == -1) || (t->family == -1)) break; m->aalcycles = t->aalcycles; 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); } /* * 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|Pse)){ vlong mca, mct; cr4 = getcr4(); if(m->cpuiddx & Pse) cr4 |= 0x10; /* page size extensions */ if((m->cpuiddx & Mce) != 0 && getconf("*nomce") == nil){ if((m->cpuiddx & Mca) != 0){ vlong cap; int bank; cap = 0; rdmsr(0x179, &cap); if(cap & 0x100) wrmsr(0x17B, ~0ULL); /* enable all mca features */ bank = cap & 0xFF; if(bank > 64) bank = 64; /* init MCi .. MC1 (except MC0) */ while(--bank > 0){ wrmsr(0x400 + bank*4, ~0ULL); wrmsr(0x401 + bank*4, 0); } if(family != 6 || model >= 0x1A) wrmsr(0x400, ~0ULL); wrmsr(0x401, 0); } else if(family == 5){ rdmsr(0x00, &mca); rdmsr(0x01, &mct); } cr4 |= 0x40; /* machine check enable */ } /* * 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 & (Mca|Mce)) == Mce) rdmsr(0x01, &mct); } #ifdef PATWC /* IA32_PAT write combining */ if((m->cpuiddx & Pat) != 0){ vlong pat; if(rdmsr(0x277, &pat) != -1){ pat &= ~(255LL<<(PATWC*8)); pat |= 1LL<<(PATWC*8); /* WC */ wrmsr(0x277, pat); } } #endif if((m->cpuiddx & Mtrr) != 0 && getconf("*nomtrr") == nil) mtrrsync(); if(strcmp(m->cpuidid, "GenuineIntel") == 0 && (m->cpuidcx & Rdrnd) != 0) hwrandbuf = rdrandbuf; else hwrandbuf = nil; if(sizeof(uintptr) == 8) { /* 8-byte watchpoints are supported in Long Mode */ m->havewatchpt8 = 1; /* check and enable NX bit */ cpuid(Highextfunc, 0, regs); if(regs[0] >= Procextfeat){ cpuid(Procextfeat, 0, regs); if((regs[3] & (1<<20)) != 0){ vlong efer; /* enable no-execute feature */ if(rdmsr(Efer, &efer) != -1){ efer |= 1ull<<11; if(wrmsr(Efer, efer) != -1) m->havenx = 1; } } } } else if(strcmp(m->cpuidid, "GenuineIntel") == 0){ /* some random CPUs that support 8-byte watchpoints */ if(family == 15 && (model == 3 || model == 4 || model == 6) || family == 6 && (model == 15 || model == 23 || model == 28)) m->havewatchpt8 = 1; /* Intel SDM claims amd64 support implies 8-byte watchpoint support */ cpuid(Highextfunc, 0, regs); if(regs[0] >= Procextfeat){ cpuid(Procextfeat, 0, regs); if((regs[3] & 1<<29) != 0) m->havewatchpt8 = 1; } } fpuinit(); return t->family; } static long cputyperead(Chan*, void *a, long n, vlong offset) { char str[32]; snprint(str, sizeof(str), "%s %d\n", m->cpuidtype, m->cpumhz); return readstr(offset, a, n, str); } static long archctlread(Chan*, void *a, long nn, vlong offset) { int n; char *buf, *p, *ep; p = buf = smalloc(READSTR); ep = p + READSTR; p = seprint(p, ep, "cpu %s %d%s\n", m->cpuidtype, m->cpumhz, 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, "arch %s\n", arch->id); n = p - buf; n += mtrrprint(p, ep - p); buf[n] = '\0'; n = readstr(offset, a, nn, buf); free(buf); return n; } enum { CMpge, CMcoherence, CMcache, }; static Cmdtab archctlmsg[] = { CMpge, "pge", 2, CMcoherence, "coherence", 2, CMcache, "cache", 4, }; static long archctlwrite(Chan*, void *a, long n, vlong) { uvlong base, size; Cmdbuf *cb; Cmdtab *ct; char *ep; 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(m->cpuidfamily < 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 CMcache: base = strtoull(cb->f[1], &ep, 0); if(*ep) error("cache: parse error: base not a number?"); size = strtoull(cb->f[2], &ep, 0); if(*ep) error("cache: parse error: size not a number?"); ep = mtrr(base, size, cb->f[3]); if(ep != nil) error(ep); break; } free(cb); poperror(); return n; } static long rmemrw(int isr, void *a, long n, vlong off) { uintptr addr = off; if(off < 0 || n < 0) error("bad offset/count"); if(isr){ if(addr >= MB) return 0; if(addr+n > MB) n = MB - addr; memmove(a, KADDR(addr), n); }else{ /* allow vga framebuf's write access */ if(addr >= MB || addr+n > MB || (addr < 0xA0000 || addr+n > 0xB0000+0x10000)) error("bad offset/count in write"); memmove(KADDR(addr), a, n); } return n; } static long rmemread(Chan*, void *a, long n, vlong off) { return rmemrw(1, a, n, off); } static long rmemwrite(Chan*, void *a, long n, vlong off) { return rmemrw(0, a, n, off); } void archinit(void) { PCArch **p; arch = knownarch[0]; for(p = knownarch; *p != nil; p++){ if((*p)->ident != nil && (*p)->ident() == 0){ arch = *p; break; } } if(arch != knownarch[0]){ if(arch->id == nil) arch->id = knownarch[0]->id; if(arch->reset == nil) arch->reset = knownarch[0]->reset; if(arch->intrinit == nil) arch->intrinit = knownarch[0]->intrinit; if(arch->intrassign == nil) arch->intrassign = knownarch[0]->intrassign; if(arch->clockinit == nil) arch->clockinit = knownarch[0]->clockinit; } /* * Decide whether to use copy-on-reference (386 and mp). * We get another chance to set it in mpinit() for a * multiprocessor. */ if(m->cpuidfamily == 3) conf.copymode = 1; if(m->cpuidfamily >= 4) cmpswap = cmpswap486; if(m->cpuidfamily >= 5) coherence = mb586; if(m->cpuiddx & Sse2) coherence = mfence; addarchfile("cputype", 0444, cputyperead, nil); addarchfile("archctl", 0664, archctlread, archctlwrite); addarchfile("realmodemem", 0660, rmemread, rmemwrite); } /* * 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) { (*arch->timerset)(x); } /* * put the processor in the halt state if we've no processes to run. * an interrupt will get us going again. * * halting in an smp system can result in a startup latency for * processes that become ready. * if idle_spin is zero, we care more about saving energy * than reducing this latency. * * the performance loss with idle_spin == 0 seems to be slight * and it reduces lock contention (thus system time and real time) * on many-core systems with large values of NPROC. */ void idlehands(void) { extern int nrdy, idle_spin; if(conf.nmach == 1) halt(); else if(m->cpuidcx & Monitor) mwait(&nrdy); else if(idle_spin == 0) halt(); } int isaconfig(char *class, int ctlrno, ISAConf *isa) { char cc[32], *p, *x; int i; snprint(cc, sizeof cc, "%s%d", class, ctlrno); p = getconf(cc); if(p == nil) return 0; x = nil; kstrdup(&x, p); p = x; isa->type = ""; isa->nopt = tokenize(p, isa->opt, NISAOPT); for(i = 0; i < isa->nopt; i++){ p = isa->opt[i]; if(cistrncmp(p, "type=", 5) == 0) isa->type = p + 5; else if(cistrncmp(p, "port=", 5) == 0) isa->port = strtoull(p+5, &p, 0); else if(cistrncmp(p, "irq=", 4) == 0) isa->irq = strtoul(p+4, &p, 0); else if(cistrncmp(p, "dma=", 4) == 0) isa->dma = strtoul(p+4, &p, 0); else if(cistrncmp(p, "mem=", 4) == 0) isa->mem = strtoul(p+4, &p, 0); else if(cistrncmp(p, "size=", 5) == 0) isa->size = strtoul(p+5, &p, 0); else if(cistrncmp(p, "freq=", 5) == 0) isa->freq = strtoul(p+5, &p, 0); } return 1; } void dumpmcregs(void) { vlong v, w; int bank; if((m->cpuiddx & (Mce|Cpumsr)) != (Mce|Cpumsr)) return; if((m->cpuiddx & Mca) == 0){ rdmsr(0x00, &v); rdmsr(0x01, &w); iprint("MCA %8.8llux MCT %8.8llux\n", v, w); return; } rdmsr(0x179, &v); rdmsr(0x17A, &w); iprint("MCG CAP %.16llux STATUS %.16llux\n", v, w); bank = v & 0xFF; if(bank > 64) bank = 64; while(--bank >= 0){ rdmsr(0x401 + bank*4, &v); if((v & (1ull << 63)) == 0) continue; iprint("MC%d STATUS %.16llux", bank, v); if(v & (1ull << 58)){ rdmsr(0x402 + bank*4, &w); iprint(" ADDR %.16llux", w); } if(v & (1ull << 59)){ rdmsr(0x403 + bank*4, &w); iprint(" MISC %.16llux", w); } iprint("\n"); } } static void nmihandler(Ureg *ureg, void*) { iprint("cpu%d: nmi PC %#p, status %ux\n", m->machno, ureg->pc, inb(0x61)); while(m->machno != 0) ; } void nmienable(void) { int x; trapenable(VectorNMI, nmihandler, nil, "nmi"); /* * Hack: should be locked with NVRAM access. */ outb(0x70, 0x80); /* NMI latch clear */ outb(0x70, 0); x = inb(0x61) & 0x07; /* Enable NMI */ outb(0x61, 0x0C|x); outb(0x61, x); } void setupwatchpts(Proc *pr, Watchpt *wp, int nwp) { int i; u8int cfg; Watchpt *p; if(nwp > 4) error("there are four watchpoints."); if(nwp == 0){ memset(pr->dr, 0, sizeof(pr->dr)); return; } for(p = wp; p < wp + nwp; p++){ switch(p->type){ case WATCHRD|WATCHWR: case WATCHWR: break; case WATCHEX: if(p->len != 1) error("length must be 1 on breakpoints"); break; default: error("type must be rw-, -w- or --x"); } switch(p->len){ case 1: case 2: case 4: break; case 8: if(m->havewatchpt8) break; default: error(m->havewatchpt8 ? "length must be 1,2,4,8" : "length must be 1,2,4"); } if((p->addr & p->len - 1) != 0) error("address must be aligned according to length"); } memset(pr->dr, 0, sizeof(pr->dr)); pr->dr[6] = 0xffff8ff0; for(i = 0; i < nwp; i++){ pr->dr[i] = wp[i].addr; switch(wp[i].type){ case WATCHRD|WATCHWR: cfg = 3; break; case WATCHWR: cfg = 1; break; case WATCHEX: cfg = 0; break; default: continue; } switch(wp[i].len){ case 1: break; case 2: cfg |= 4; break; case 4: cfg |= 12; break; case 8: cfg |= 8; break; default: continue; } pr->dr[7] |= cfg << 16 + 4 * i; pr->dr[7] |= 1 << 2 * i + 1; } }