e00baa9f5d
simplify
178 lines
3.9 KiB
C
178 lines
3.9 KiB
C
#include "types.h"
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#include "param.h"
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#include "mmu.h"
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#include "proc.h"
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#include "defs.h"
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#include "x86.h"
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#include "traps.h"
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#include "syscall.h"
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#include "elf.h"
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#include "param.h"
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#include "spinlock.h"
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extern char edata[], end[];
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extern uchar _binary_init_start[], _binary_init_size[];
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void process0();
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// CPU 0 starts running C code here.
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// This is called main0 not main so that it can have
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// a void return type. Gcc can't handle functions named
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// main that don't return int. Really.
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void
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main0(void)
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{
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int i;
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struct proc *p;
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// clear BSS
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memset(edata, 0, end - edata);
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// switch to cpu0's cpu stack
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asm volatile("movl %0, %%esp" : : "r" (cpus[0].mpstack + MPSTACK - 32));
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asm volatile("movl %0, %%ebp" : : "r" (cpus[0].mpstack + MPSTACK));
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// Prevent release() from enabling interrupts.
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for(i=0; i<NCPU; i++)
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cpus[i].nlock = 1;
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mp_init(); // collect info about this machine
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lapic_init(mp_bcpu());
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cprintf("\ncpu%d: starting xv6\n\n", cpu());
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pinit(); // process table
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binit(); // buffer cache
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pic_init();
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ioapic_init();
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kinit(); // physical memory allocator
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tvinit(); // trap vectors
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idtinit(); // this CPU's interrupt descriptor table
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fileinit();
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iinit(); // i-node table
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// initialize process 0
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p = &proc[0];
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p->state = RUNNABLE;
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p->kstack = kalloc(KSTACKSIZE);
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// cause proc[0] to start in kernel at process0
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p->jmpbuf.eip = (uint) process0;
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p->jmpbuf.esp = (uint) (p->kstack + KSTACKSIZE - 4);
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// make sure there's a TSS
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setupsegs(0);
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// initialize I/O devices, let them enable interrupts
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console_init();
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ide_init();
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// start other CPUs
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mp_startthem();
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// turn on timer
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if (ismp) lapic_timerinit();
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else pit8253_timerinit();
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// enable interrupts on the local APIC
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lapic_enableintr();
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// enable interrupts on this processor.
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cpus[cpu()].nlock--;
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sti();
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scheduler();
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}
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// Additional processors start here.
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void
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mpmain(void)
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{
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cprintf("cpu%d: starting\n", cpu());
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idtinit(); // CPU's idt
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if(cpu() == 0)
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panic("mpmain on cpu 0");
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lapic_init(cpu());
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lapic_timerinit();
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lapic_enableintr();
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// make sure there's a TSS
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setupsegs(0);
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cpuid(0, 0, 0, 0, 0); // memory barrier
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cpus[cpu()].booted = 1;
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// Enable interrupts on this processor.
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cpus[cpu()].nlock--;
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sti();
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scheduler();
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}
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// proc[0] starts here, called by scheduler() in the ordinary way.
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void
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process0()
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{
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struct proc *p0 = &proc[0];
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struct proc *p1;
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extern struct spinlock proc_table_lock;
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struct trapframe tf;
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release(&proc_table_lock);
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p0->cwd = iget(rootdev, 1);
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iunlock(p0->cwd);
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// dummy user memory to make copyproc() happy
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p0->sz = 4 * PAGE;
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p0->mem = kalloc(p0->sz);
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// fake a trap frame as if a user process had made a system
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// call, so that copyproc will have a place for the new
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// process to return to.
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p0->tf = &tf;
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memset(p0->tf, 0, sizeof(struct trapframe));
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p0->tf->es = p0->tf->ds = p0->tf->ss = (SEG_UDATA << 3) | 3;
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p0->tf->cs = (SEG_UCODE << 3) | 3;
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p0->tf->eflags = FL_IF;
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p0->tf->esp = p0->sz;
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p1 = copyproc(p0);
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load_icode(p1, _binary_init_start, (uint) _binary_init_size);
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p1->state = RUNNABLE;
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proc_wait();
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panic("init exited");
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}
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void
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load_icode(struct proc *p, uchar *binary, uint size)
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{
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int i;
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struct elfhdr *elf;
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struct proghdr *ph;
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elf = (struct elfhdr*) binary;
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if(elf->magic != ELF_MAGIC)
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panic("load_icode: not an ELF binary");
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p->tf->eip = elf->entry;
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// Map and load segments as directed.
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ph = (struct proghdr*) (binary + elf->phoff);
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for(i = 0; i < elf->phnum; i++, ph++) {
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if(ph->type != ELF_PROG_LOAD)
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continue;
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if(ph->va + ph->memsz < ph->va)
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panic("load_icode: overflow in elf header segment");
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if(ph->va + ph->memsz >= p->sz)
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panic("load_icode: icode wants to be above UTOP");
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// Load/clear the segment
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memmove(p->mem + ph->va, binary + ph->offset, ph->filesz);
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memset(p->mem + ph->va + ph->filesz, 0, ph->memsz - ph->filesz);
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}
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}
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