#include "types.h" #include "defs.h" #include "param.h" #include "mmu.h" #include "proc.h" #include "x86.h" static void bootothers(void); static void mpmain(void); void jkstack(void) __attribute__((noreturn)); void mainc(void); // Bootstrap processor starts running C code here. int main(void) { mpinit(); // collect info about this machine lapicinit(mpbcpu()); ksegment(); // set up segments picinit(); // interrupt controller ioapicinit(); // another interrupt controller consoleinit(); // I/O devices & their interrupts uartinit(); // serial port pminit(); // discover how much memory there is jkstack(); // call mainc() on a properly-allocated stack } void jkstack(void) { char *kstack = kalloc(PGSIZE); if (!kstack) panic("jkstack\n"); char *top = kstack + PGSIZE; asm volatile("movl %0,%%esp" : : "r" (top)); asm volatile("call mainc"); panic("jkstack"); } void mainc(void) { cprintf("\ncpu%d: starting xv6\n\n", cpu->id); kvmalloc(); // initialize the kernel page table pinit(); // process table tvinit(); // trap vectors binit(); // buffer cache fileinit(); // file table iinit(); // inode cache ideinit(); // disk if(!ismp) timerinit(); // uniprocessor timer userinit(); // first user process bootothers(); // start other processors // Finish setting up this processor in mpmain. mpmain(); } // Common CPU setup code. // Bootstrap CPU comes here from mainc(). // Other CPUs jump here from bootother.S. static void mpmain(void) { if(cpunum() != mpbcpu()) { ksegment(); lapicinit(cpunum()); } vmenable(); // turn on paging cprintf("cpu%d: starting\n", cpu->id); idtinit(); // load idt register xchg(&cpu->booted, 1); scheduler(); // start running processes } static void bootothers(void) { extern uchar _binary_bootother_start[], _binary_bootother_size[]; uchar *code; struct cpu *c; char *stack; // Write bootstrap code to unused memory at 0x7000. The linker has // placed the start of bootother.S there. code = (uchar *) 0x7000; memmove(code, _binary_bootother_start, (uint)_binary_bootother_size); for(c = cpus; c < cpus+ncpu; c++){ if(c == cpus+cpunum()) // We've started already. continue; // Fill in %esp, %eip and start code on cpu. stack = kalloc(KSTACKSIZE); *(void**)(code-4) = stack + KSTACKSIZE; *(void**)(code-8) = mpmain; lapicstartap(c->id, (uint)code); // Wait for cpu to finish mpmain() while(c->booted == 0) ; } }