Esempio n. 1
0
// Bootstrap processor starts running C code here.
// Allocate a real stack and switch to it, first
// doing some setup required for memory allocator to work.
int
main(void)
{
  kvmalloc();      // kernel page table
  mpinit();        // collect info about this machine
  lapicinit(mpbcpu());
  seginit();       // set up segments
  cprintf("\ncpu%d: starting xv6\n\n", cpu->id);
  picinit();       // interrupt controller
  ioapicinit();    // another interrupt controller
  consoleinit();   // I/O devices & their interrupts
  uartinit();      // serial port
  pinit();         // process table
  tvinit();        // trap vectors
  binit();         // buffer cache
  fileinit();      // file table
  iinit();         // inode cache
  ideinit();       // disk
  if(!ismp)
    timerinit();   // uniprocessor timer
  startothers();    // start other processors (must come before kinit)
  kinit();         // initialize memory allocator
  userinit();      // first user process  (must come after kinit)
  // Finish setting up this processor in mpmain.
  mpmain();
}
Esempio n. 2
0
// Bootstrap processor starts running C code here.
// Allocate a real stack and switch to it, first
// doing some setup required for memory allocator to work.
int
main(void)
{
  kinit1(end, P2V(4*1024*1024)); // phys page allocator
  kvmalloc();      // kernel page table
  mpinit();        // collect info about this machine
  lapicinit();
  seginit();       // set up segments
  cprintf("\ncpu%d: starting xv6\n\n", cpu->id);
  picinit();       // interrupt controller
  ioapicinit();    // another interrupt controller
  consoleinit();   // I/O devices & their interrupts
  uartinit();      // serial port
  pinit();         // process table
  tvinit();        // trap vectors
  binit();         // buffer cache
  fileinit();      // file table
  ideinit();       // disk
  if(!ismp)
    timerinit();   // uniprocessor timer
  startothers();   // start other processors
  kinit2(P2V(4*1024*1024), P2V(PHYSTOP)); // must come after startothers()
  userinit();      // first user process
  mpmain();
  
}
Esempio n. 3
0
// Bootstrap processor starts running C code here.
// Allocate a real stack and switch to it, first
// doing some setup required for memory allocator to work.
int
main(void)
{
  kinit1(end, P2V(4*1024*1024)); // phys page allocator
  kvmalloc();      // kernel page table
  mpinit();        // detect other processors
  lapicinit();     // interrupt controller
  seginit();       // segment descriptors
  cprintf("\ncpu%d: starting xv6\n\n", cpunum());
  picinit();       // another interrupt controller
  ioapicinit();    // another interrupt controller
  consoleinit();   // console hardware
  uartinit();      // serial port
  pinit();         // process table
  tvinit();        // trap vectors
  binit();         // buffer cache
  fileinit();      // file table
  ideinit();       // disk
  if(!ismp)
    timerinit();   // uniprocessor timer
  startothers();   // start other processors
  kinit2(P2V(4*1024*1024), P2V(PHYSTOP)); // must come after startothers()
  userinit();      // first user process
  mpmain();        // finish this processor's setup
  init_semaphores_on_boot();
}
Esempio n. 4
0
File: main.c Progetto: hosanli/os4
// Bootstrap processor starts running C code here.
int
main(int memsize)
{
  mpinit(); // collect info about this machine
  lapicinit(mpbcpu());
  ksegment();
  picinit();       // interrupt controller
  ioapicinit();    // another interrupt controller
  consoleinit();   // I/O devices & their interrupts
  uartinit();      // serial port
  cprintf("cpus %p cpu %p\n", cpus, cpu);
  cprintf("\ncpu%d: starting xv6\n\n", cpu->id);
  cprintf("mem: %d kb\n", memsize);
  kinit(memsize);         // physical memory allocator
  pinit();         // process table
  tvinit();        // trap vectors
  binit();         // buffer cache
  fileinit();      // file table
  iinit();         // inode cache
  ideinit();       // disk
  if(!ismp)
    timerinit();   // uniprocessor timer
  pageinit();	   // enable paging
  userinit();      // first user process
  bootothers();    // start other processors

  // Finish setting up this processor in mpmain.
  mpmain();
}
Esempio n. 5
0
File: main.c Progetto: ismaellc/SOTR
// Bootstrap processor starts running C code here.
// Allocate a real stack and switch to it, first
// doing some setup required for memory allocator to work.
int
main(void)
{
	unsigned char FB[]="MESSAGE WRITTEN THROUGH FRAMEBUFFER!!";
	fb_init();       // initialize framebuffer device (2015.11.02)
	cprintf("\nUsing Framebuffer still presents some problems :(\n\n");
	cprintf("\nSuggestion: review the way it is used in console.c\n\n");
	fb_write(FB, sizeof(FB)); // Framebuffer maybe could be used before this moment (2015.11.02)
	see_mylock(MYLOCK);
  kinit1(end, P2V(4*1024*1024)); // phys page allocator
  kvmalloc();      // kernel page table
  mpinit();        // collect info about this machine
  lapicinit();
  seginit();       // set up segments
  cprintf("\ncpu%d: starting xv6\n\n", cpu->id);
  picinit();       // interrupt controller
  ioapicinit();    // another interrupt controller
  consoleinit();   // I/O devices & their interrupts
  uartinit();      // serial port
  pinit();         // process table
  tvinit();        // trap vectors
  binit();         // buffer cache
  fileinit();      // file table
  ideinit();       // disk
  if(!ismp)
    timerinit();   // uniprocessor timer
  startothers();   // start other processors
  kinit2(P2V(4*1024*1024), P2V(PHYSTOP)); // must come after startothers()
  userinit();      // first user process
  // Finish setting up this processor in mpmain.
  mpmain();
}
Esempio n. 6
0
// Bootstrap processor starts running C code here.
// Allocate a real stack and switch to it, first
// doing some setup required for memory allocator to work.
int
main(void)
{
    monitor_clear ();

    // Print basic system information.
    cprintf ("Ensidia\n\n");
    cprintf ("Copyright (c) 2013-2014 Fotis Koutoulakis\n");
    cprintf ("Based on xv6 by Russ Cox et al, at MIT CSAIL\n");

    kinit1(end, P2V(4*1024*1024)); // phys page allocator
    kvmalloc();      // kernel page table
    mpinit();        // collect info about this machine
    lapicinit();
    seginit();       // set up segments
    cprintf("\ncpu%d: starting xng kernel\n\n", cpu->id);
    picinit();       // interrupt controller
    ioapicinit();    // another interrupt controller
    consoleinit();   // I/O devices & their interrupts
    uartinit();      // serial port
    pinit();         // process table
    tvinit();        // trap vectors
    binit();         // buffer cache
    fileinit();      // file table
    iinit();         // inode cache
    ideinit();       // disk
    if(!ismp)
        timerinit();   // uniprocessor timer
    startothers();   // start other processors
    kinit2(P2V(4*1024*1024), P2V(PHYSTOP)); // must come after startothers()
    userinit();      // first user process
    // Finish setting up this processor in mpmain.
    mpmain();
}
Esempio n. 7
0
/*int main(void){*/
void kmain(void){
//  vga_init();
//  puts((uint8_t*)"Hello kernel world!\n");
  /*do some work here, like initialize timer or paging*/
  kinit1(end, P2V(4*1024*1024)); // phys page allocator
  kvmalloc();      // kernel page table
  mpinit();        // collect info about this machine
  lapicinit();
//  gdt_descriptor();
//  puts((uint8_t*)"GDT initialized...\n");
//  idt_descriptor();
//  puts((uint8_t*)"IDT initialized...\n");
//  cprintf("IDT initialized...\n");
  seginit();       // set up segments
  cprintf("\ncpu%d: starting xv6\n\n", cpu->id);
  picinit();       // interrupt controller
  ioapicinit();    // another interrupt controller
  consoleinit();   // I/O devices & their interrupts
  uartinit();      // serial port
  pinit();         // process table
  tvinit();        // trap vectors
  binit();         // buffer cache
  fileinit();      // file table
  ideinit();       // disk
  if(!ismp)
    timerinit();   // uniprocessor timer
  startothers();   // start other processors
  kinit2(P2V(4*1024*1024), P2V(PHYSTOP)); // must come after startothers()
  userinit();      // first user process
  // Finish setting up this processor in mpmain.
  mpmain();
}
Esempio n. 8
0
File: main.c Progetto: hubert-he/xv6
// Bootstrap processor starts running C code here.
// Allocate a real stack and switch to it, first
// doing some setup required for memory allocator to work.
int
main(void)
{
  kinit1(end, P2V(4*1024*1024)); // phys page allocator  // kmem. freelist added
  cprintf("%x \n", end);
  kvmalloc();      // kernel page table
#ifdef CONFIG_MULTI_PROCESS
  mpinit();        // collect info about this machine
#endif
  lapicinit();
  seginit();       // set up segments
  picinit();       // interrupt controller: Programmable Interrupt Controller
#ifdef CONFIG_MULTI_PROCESS
  ioapicinit();    // another interrupt controller
#endif
  consoleinit();   // I/O devices & their interrupts
  uartinit();      // serial port
  pinit();         // process table
  tvinit();        // trap vectors
  binit();         // buffer cache
  fileinit();      // file table
  iinit();         // inode cache
  ideinit();       // disk
  if(!ismp)
    timerinit();   // uniprocessor timer
#ifdef CONFIG_MULTI_PROCESS
  startothers();   // start other processors
  kinit2(P2V(4*1024*1024), P2V(PHYSTOP)); // must come after startothers()
#endif
  userinit();      // first user process
  // Finish setting up this processor in mpmain.
  mpmain();
}
Esempio n. 9
0
// Bootstrap processor starts running C code here.
// Allocate a real stack and switch to it, first
// doing some setup required for memory allocator to work.
int
main(void)
{
  kinit1(end, P2V(4*1024*1024)); // phys page allocator
  kvmalloc();      // kernel page table
  mpinit();        // collect info about this machine
  lapicinit();
  seginit();       // set up segments
  cprintf("\ncpu%d: starting xv6\n\n", cpu->id);
  picinit();       // interrupt controller
  ioapicinit();    // another interrupt controller
  consoleinit();   // I/O devices & their interrupts
  uartinit();      // serial port
    initGraphMode();
    initDom();
    tryOnce();
    toggleOn();
  pinit();         // process table
    toggleOn();
  tvinit();        // trap vectors
    toggleOn();
  binit();         // buffer cache
    toggleOn();
  fileinit();      // file table
    toggleOn();
  iinit();         // inode cache
    toggleOn();
  ideinit();       // disk
    toggleOn();
  if(!ismp)
    timerinit();   // uniprocessor timer

    toggleOn();
  startothers();   // start other processors
    toggleOn();
  kinit2(P2V(4*1024*1024), P2V(PHYSTOP)); // must come after startothers()
    toggleOn();
	
  txt_initLock();
  mouseEnable();

  initProcessMsgMap();


  userinit();      // first user process
    toggleOn();
    endToggle();
  // Finish setting up this processor in mpmain.
  mpmain();
}
Esempio n. 10
0
void
mpinitcpu(long unit)
{
    cpuinit(unit);
    /* TODO: initialise HPET; enable [rerouted] interrupts */
#if (HPET)
    hpetinit();
#endif
    apicinit();
#if (IOAPIC)
    ioapicinit();
#endif
    tssinit(unit);

    return;
}
Esempio n. 11
0
ASMLINK
void
mpmain(struct m_cpu *cpu)
{
//    gdtinit();
    seginit(cpu->id);
    idtset();
    m_xchgl(&cpu->started, 1L);
    /* TODO: initialise HPET; enable [rerouted] interrupts */
#if (HPET)
    hpetinit();
    apicinitcpu(cpu->id);
    ioapicinit(cpu->id);
    tssinit(cpu->id);
#endif
    while (1) {
        k_waitint();
    }
}
Esempio n. 12
0
// Os procedimentos de inicialização começam a executar o 
// código .C a partir daqui.
// Aloca uma pilha real e troca para ela, primeiro fazendo
// algumas configurações necessárias par o alocador de memória funcionar.
int main(void) {
  kinit1(end, P2V(4*1024*1024)); // alocador de páginas de memória física
  kvmalloc();      // tabela de páginas do kernel
  mpinit();        // detecta outros processadores
  lapicinit();     // controlador de interrupções
  seginit();       // descritores de segmentos
  picinit();       // desabilita pic
  ioapicinit();    // outro controlador de interrupções
  consoleinit();   // console hardware
  uartinit();      // porta serial
  pinit();         // tabela de processos
  tvinit();        // vetores trap
  binit();         // buffer cache
  fileinit();      // tabela de arquivo
  ideinit();       // disco 
  startothers();   // inicia outros processadores
  kinit2(P2V(4*1024*1024), P2V(PHYSTOP)); // deve vir após startothers()
  userinit();      // primeiro processo no modo usuário
  mpmain();        // encerra esta configuração de processadores
}
Esempio n. 13
0
void
mpstart(void)
{
//    volatile static int    first = 1;
    volatile struct m_cpu *cpu;
    volatile struct m_cpu *lim;
    uint32_t              *mpentrystk = (uint32_t *)MPENTRYSTK;

    lim = &mpcputab[0] + mpncpu;
#if 0
    if (first) {
        kmemcpy((void *)MPENTRY,
                mpentry, (uint8_t *)&mpend - (uint8_t *)&mpentry);
        first = 0;
    }
#endif
    for (cpu = &mpcputab[0] ; cpu < lim ; cpu++) {
        if (cpu == mpbootcpu) {
            /* started already */
            
            continue;
        }
        kprintf("starting CPU %ld @ 0x%lx\n", cpu->id, MPENTRY);
        cpuinit((struct m_cpu *)cpu);
#if 0
        apicinit(cpu->id);
        ioapicinit(cpu->id);
#endif
        *--mpentrystk = (uint32_t)cpu;
        *--mpentrystk = MPENTRYSTK - cpu->id * MPSTKSIZE;
        *--mpentrystk = (uint32_t)&kernpagedir;
        apicstart(cpu->id, MPENTRY);
        while (!cpu->started) {
            ;
        }
    }

    return;
}
Esempio n. 14
0
// Bootstrap processor starts running C code here.
// Allocate a real stack and switch to it, first
// doing some setup required for memory allocator to work.
int
main(void)
{
  kinit1(end, P2V(4*1024*1024)); // phys page allocator
  kvmalloc();      // kernel page table
  mpinit();        // detect other processors
  lapicinit();     // interrupt controller
  seginit();       // segment descriptors
  picinit();       // disable pic
  ioapicinit();    // another interrupt controller
  consoleinit();   // console hardware
  uartinit();      // serial port
  pinit();         // process table
  shminit();       // shared memory
  tvinit();        // trap vectors
  binit();         // buffer cache
  fileinit();      // file table
  ideinit();       // disk 
  startothers();   // start other processors
  kinit2(P2V(4*1024*1024), P2V(PHYSTOP)); // must come after startothers()
  userinit();      // first user process
  mpmain();        // finish this processor's setup
}
Esempio n. 15
0
// Bootstrap processor starts running C code here.
// Allocate a real stack and switch to it, first
// doing some setup required for memory allocator to work.
int
main(void)
{
	monitor_clear();
	xylos_logo();

	kinit1(end, P2V(4 * 1024 * 1024)); // phys page allocator, 16MB for kernel
	kvmalloc();      // kernel page table
	mpinit();        // collect info about this machine
	lapicinit();
	seginit();       // set up segments

	cprintf("Initializing interrupts...             ");
	init_generic_irq_table();
	picinit();       // interrupt controller
	ioapicinit();    // another interrupt controller
	cprintf_color(COLOR_BLACK, COLOR_LIGHT_GREEN, false, "done\n");

	cprintf("Initializing console and serial...     ");
	consoleinit();   // I/O devices & their interrupts
	uartinit();      // serial port
	cprintf_color(COLOR_BLACK, COLOR_LIGHT_GREEN, false, "done\n");

	cprintf("Setting up swap space disk...          ");
	swapinit();
	cprintf_color(COLOR_BLACK, COLOR_LIGHT_GREEN, false, "done\n");

	cprintf("Initializing tasking...                ");
	pinit();         // process table
	tvinit();        // trap vectors
	binit();         // buffer cache
	cprintf_color(COLOR_BLACK, COLOR_LIGHT_GREEN, false, "done\n");

	cprintf("Initializing pipe IPC...               ");
	init_pipe_ipc_system();
	if(pipe_ipc_sanitycheck() == 0) {
		cprintf_color(COLOR_BLACK, COLOR_LIGHT_GREEN, false, "done\n");
	}

	cprintf("Initializing direct IPC...             ");
	init_direct_ipc_table();
	if(direct_ipc_sanitycheck() == 0) {
		cprintf_color(COLOR_BLACK, COLOR_LIGHT_GREEN, false, "done\n");
	}

	cprintf("Mounting root filesystem...            ");
	fileinit();      // file table
	ideinit();       // disk
	cprintf_color(COLOR_BLACK, COLOR_LIGHT_GREEN, false, "done\n");

	if(!ismp) {
		cprintf("Starting up uniprocessor CPU...        ");
		timerinit();   // uniprocessor timer
		cprintf_color(COLOR_BLACK, COLOR_LIGHT_GREEN, false, "done\n");
	}

	if(ismp) {
		if(ncpu > 1) {
			cprintf("Starting up %d CPU cores...             ", ncpu);
		} else {
			cprintf("Starting up %d CPU core...              ", ncpu);
		}
	}

	startothers();   // start other processors
	kinit2(P2V(4 * 1024 * 1024), P2V(PHYSTOP)); // 16MB to PHYSTOP [234MB]

	if(ismp) {
		cprintf_color(COLOR_BLACK, COLOR_LIGHT_GREEN, false, "done\n");
	}

	// detects and starts km drivers
	auto_enable_nic();

	// first user process
	userinit();

	// Finish setting up this processor in mpmain.
	mpmain();


}
Esempio n. 16
0
static void
pcmpinit(void)
{
	uchar *p, *e;
	Apic *apic;
	void *va;

	/*
	 * Map the local APIC.
	 */
	va = vmap(pcmp->lapicbase, 1024);

	print("LAPIC: %.8lux %#p\n", pcmp->lapicbase, va);
	if(va == nil)
		panic("pcmpinit: cannot map lapic %.8lux", pcmp->lapicbase);

	p = ((uchar*)pcmp)+PCMPsz;
	e = ((uchar*)pcmp)+pcmp->length;
	if(getconf("*dumpmp") != nil)
		dumpmp(p, e);
	if(getconf("*mp") != nil)
		mpoverride(&p, &e);

	/*
	 * 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.
	 */
	while(p < e) switch(*p){
	default:
		print("pcmpinit: 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)){
			apic->addr = va;
			apic->paddr = pcmp->lapicbase;
		}
		p += PCMPprocessorsz;
		continue;

	case PcmpBUS:
		mkbus((PCMPbus*)p);
		p += PCMPbussz;
		continue;

	case PcmpIOAPIC:
		if(apic = mkioapic((PCMPioapic*)p))
			ioapicinit(apic, apic->apicno);
		p += PCMPioapicsz;
		continue;

	case PcmpIOINTR:
		mkiointr((PCMPintr*)p);
		p += PCMPintrsz;
		continue;

	case PcmpLINTR:
		mklintr((PCMPintr*)p);
		p += PCMPintrsz;
		continue;
	}

	/*
	 * Ininitalize local APIC and start application processors.
	 */
	mpinit();
}
Esempio n. 17
0
File: mp.c Progetto: 8l/inferno
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;
}
Esempio n. 18
0
int mpacpi(int ncleft)
{
	char *already;
	int np, bp;
	Apic *apic;
	Apicst *st;
	Madt *mt;

	/* If we don't have an mpisabusno yet, it's because the MP tables failed to
	 * parse.  So we'll just take the last one available.  I think we're
	 * supposed to parse the ACPI shit with the AML to figure out the buses and
	 * find a clear one, but f**k that.  Note this busno is just for our own
	 * RDT/Rbus bookkeeping. */
	if (mpisabusno == -1)
		mpisabusno = Nbus - 1;

	if (apics == nil)
		return ncleft;
	mt = apics->tbl;
	if (mt == nil)
		return ncleft;

	print("APIC lapic paddr %#.8llx, flags %#.8x\n",
		   mt->lapicpa, mt->pcat);
	np = 0;
	//print("apics->st %p\n", apics->st);
	for (int i = 0; i < apics->nchildren; i++) {
		st = apics->children[i]->tbl;
		already = "";
		switch (st->type) {
			case ASlapic:
				print("ASlapic %d\n", st->lapic.id);
				/* this table is supposed to have all of them if it exists */
				if (st->lapic.id > Napic)
					break;
				apic = xlapic + st->lapic.id;
				bp = (np++ == 0);
				if (apic->useable) {
					already = "(mp)";
				} else if (ncleft != 0) {
					ncleft--;
					apicinit(st->lapic.id, mt->lapicpa, bp);
				} else
					already = "(off)";

				print("apic proc %d/%d apicid %d %s\n", np - 1, apic->Lapic.machno,
					   st->lapic.id, already);
				break;
			case ASioapic:
				print("ASioapic %d\n", st->ioapic.id);
				if (st->ioapic.id > Napic){
					print("ASioapic: %d is > %d, ignoring\n", st->ioapic.id, Napic);
					break;
				}
				apic = xioapic + st->ioapic.id;
				if (apic->useable) {
					already = "(mp)";
					goto pr1;
				}
				ioapicinit(st->ioapic.id, st->ioapic.ibase, st->ioapic.addr);
pr1:
				apic->Ioapic.gsib = st->ioapic.ibase;
				print("ioapic %d ", st->ioapic.id);
				print("addr %p ibase %d %s\n", st->ioapic.addr, st->ioapic.ibase,
					   already);
				break;
		}
	}
	return ncleft;
}
Esempio n. 19
0
int mpacpi(int ncleft)
{
	char *already;
	int np, bp;
	struct apic *apic;
	struct Apicst *st;

	/* If we don't have an mpisabusno yet, it's because the MP tables failed to
	 * parse.  So we'll just take the last one available.  I think we're
	 * supposed to parse the ACPI shit with the AML to figure out the buses and
	 * find a clear one, but f**k that.  Note this busno is just for our own
	 * RDT/Rbus bookkeeping. */
	if (mpisabusno == -1)
		mpisabusno = Nbus - 1;

	if (apics == NULL)
		return ncleft;

	printd("APIC lapic paddr %#.8llux, flags %#.8ux\n",
		   apics->lapicpa, apics->pcat);
	np = 0;
	printd("apics->st %p\n", apics->st);
	for (st = apics->st; st != NULL; st = st->next) {
		already = "";
		switch (st->type) {
			case ASlapic:
				printd("ASlapic %d\n", st->lapic.id);
				/* this table is supposed to have all of them if it exists */
				if (st->lapic.id > MaxAPICNO)
					break;
				apic = xlapic + st->lapic.id;
				bp = (np++ == 0);
				if (apic->useable) {
					already = "(mp)";
				} else if (ncleft != 0) {
					ncleft--;
					apicinit(st->lapic.id, apics->lapicpa, bp);
				} else
					already = "(off)";

				printd("apic proc %d/%d apicid %d %s\n", np - 1, apic->machno,
					   st->lapic.id, already);
				break;
			case ASioapic:
				printd("ASioapic %d\n", st->ioapic.id);
				if (st->ioapic.id > Napic)
					break;
				apic = xioapic + st->ioapic.id;
				if (apic->useable) {
					apic->ibase = st->ioapic.ibase;	/* gnarly */
					already = "(mp)";
					goto pr1;
				}
				ioapicinit(st->ioapic.id, st->ioapic.ibase, st->ioapic.addr);
pr1:
				printd("ioapic %d ", st->ioapic.id);
				printd("addr %p base %d %s\n", apic->paddr, apic->ibase,
					   already);
				break;
		}
	}
	return ncleft;
}
Esempio n. 20
0
void
kinitlong(unsigned long pmemsz)
{
#if (NEWTMR)
    uint32_t tmrcnt = 0;
#endif

/* initialise interrupt management */
#if (VBE)
    trapinitprot();
#endif
    /* initialise virtual memory */
    vminitlong((uint64_t *)kernpagemapl4tab);
#if 0
    /* FIXME: map possible device memory */
    vmmapseg((uint32_t *)&_pagetab, DEVMEMBASE, DEVMEMBASE, 0xffffffffU,
             PAGEPRES | PAGEWRITE | PAGENOCACHE);
#endif
//    schedinit();
    /* zero kernel BSS segment */
    kbzero(&_bssvirt, (uint32_t)&_ebssvirt - (uint32_t)&_bssvirt);
    /* set kernel I/O permission bitmap to all 1-bits */
    kmemset(&kerniomap, 0xff, sizeof(kerniomap));
    /* INITIALIZE CONSOLES AND SCREEN */
#if (VBE)
    vbeinitscr();
#endif
#if (VBE) && (NEWFONT)
    consinit(768 / vbefontw, 1024 / vbefonth);
#elif (VBE)
    consinit(768 >> 3, 1024 >> 3);
#endif
    /* TODO: use memory map from GRUB? */
//    vminitphys((uintptr_t)&_epagetab, pmemsz);
    vminitphys((uintptr_t)&_epagetab, pmemsz);
    meminit(pmemsz);
    tssinit(0);
#if (VBE) && (NEWFONT)
//    consinit(768 / vbefontw, 1024 / vbefonth);
#elif (VBE)
    consinit(768 >> 3, 1024 >> 3);
#endif
#if (SMBIOS)
    smbiosinit();
#endif
#if (PS2DRV)
    ps2init();
#endif
#if (VBE) && (PLASMA)
    plasmaloop();
#endif
#if (VBE)
    vbeprintinfo();
#endif
    logoprint();
//    vminitphys((uintptr_t)&_ebss, pmemsz - (unsigned long)&_ebss);
    /* HID devices */
#if (PCI)
    /* initialise PCI bus driver */
    pciinit();
#endif
#if (ATA)
    /* initialise ATA driver */
    atainit();
#endif
#if (SB16)
    /* initialise Soundblaster 16 driver */
    sb16init();
#endif
#if (ACPI)
    /* initialise ACPI subsystem */
    acpiinit();
#endif
    /* initialise block I/O buffer cache */
    if (!bufinit()) {
        kprintf("failed to allocate buffer cache\n");

        while (1) {
            ;
        }
    }
    /* allocate unused device regions (in 3.5G..4G) */
//    pageaddzone(DEVMEMBASE, &vmshmq, 0xffffffffU - DEVMEMBASE + 1);
#if (SMP) || (APIC)
//#if (SMP)
    /* multiprocessor initialisation */
//    mpinit();
//#endif
    if (mpncpu == 1) {
        kprintf("found %ld processor\n", mpncpu);
    } else {
        kprintf("found %ld processors\n", mpncpu);
    }
#if (HPET)
    /* initialise high precision event timers */
    hpetinit();
#endif
#if (NEWTMR)
    tmrcnt = apicinitcpu(0);
#else
    apicinitcpu(0);
#endif
#if (IOAPIC)
    ioapicinit(0);
#endif
#endif /* SMP || APIC */
#if (SMP)
    if (mpmultiproc) {
        mpstart();
    }
#endif
    /* CPU interface */
    taskinit();
//    tssinit(0);
//    machinit();
    /* execution environment */
    procinit(PROCKERN);
//    k_curtask = &k_curproc->task;
//    sysinit();
    kprintf("DMA buffers (%ul x %ul kilobytes) @ 0x%p\n",
            DMANCHAN, DMACHANBUFSIZE >> 10, DMABUFBASE);
    kprintf("VM page tables @ 0x%p\n", (unsigned long)&_pagetab);
//    kprintf("%ld kilobytes physical memory\n", pmemsz >> 10);
    kprintf("%ld kilobytes kernel memory\n", (uint32_t)&_ebss >> 10);
    kprintf("%ld kilobytes allocated physical memory (%ld wired, %ld total)\n",
            (vmpagestat.nwired + vmpagestat.nmapped + vmpagestat.nbuf) << (PAGESIZELOG2 - 10),
            vmpagestat.nwired << (PAGESIZELOG2 - 10),
            vmpagestat.nphys << (PAGESIZELOG2 - 10));
    k_curcpu = &cputab[0];
    cpuinit(k_curcpu);
    schedinit();
#if (APIC)
    apicstarttmr(tmrcnt);
#else
    pitinit();
#endif
    schedloop();

    /* NOTREACHED */
}
Esempio n. 21
0
File: mp.c Progetto: Earnestly/plan9
void
mpinit(void)
{
	int ncpu, cpuson;
	char *cp;
	PCMP *pcmp;
	uchar *e, *p;
	Apic *apic, *bpapic;
	void *va;

	mpdebug = getconf("*debugmp") != nil;
	i8259init();
	syncclock();

	bpapic = nil;
	cpuson = 0;

	if(_mp_ == 0) {
		/*
		 * We can easily get processor info from ACPI, but
		 * interrupt routing, etc. would require interpreting AML.
		 */
		print("mpinit: no mp table found, assuming uniprocessor\n");
		archrevert();
		return;
	}
	pcmp = KADDR(_mp_->physaddr);

	/*
	 * Map the local APIC.
	 */
	if((va = vmap(pcmp->lapicbase, 1024)) == nil)
		return;
	mppcmp = pcmp;
	print("LAPIC: %#lux %#lux\n", pcmp->lapicbase, (ulong)va);

	/*
	 * 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 = va;
			apic->paddr = pcmp->lapicbase;
			if(apic->flags & PcmpBP)
				bpapic = apic;
			cpuson++;
		}
		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;
	}

	dprint("mpinit: mp table describes %d cpus\n", cpuson);

	/* For now, always scan ACPI's MADT for processors that MP missed. */
	trympacpi();

	if (bpapic == nil)
		bpapic = bootapic;

	/*
	 * No bootstrap processor, no need to go further.
	 */
	if(bpapic == 0)
		return;
	bpapic->online = 1;

	lapicinit(bpapic);

	/*
	 * 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 if(ncpu > MAXMACH)
			ncpu = MAXMACH;
	}
	else
		ncpu = MAXMACH;
	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;
}