ab0db651af
The x86-64 doesn't just add two levels to page tables to support 64 bit addresses, but is a different processor. For example, calling conventions, system calls, and segmentation are different from 32-bit x86. Segmentation is basically gone, but gs/fs in combination with MSRs can be used to hold a per-core pointer. In general, x86-64 is more straightforward than 32-bit x86. The port uses code from sv6 and the xv6 "rsc-amd64" branch. A summary of the changes is as follows: - Booting: switch to grub instead of xv6's bootloader (pass -kernel to qemu), because xv6's boot loader doesn't understand 64bit ELF files. And, we don't care anymore about booting. - Makefile: use -m64 instead of -m32 flag for gcc, delete boot loader, xv6.img, bochs, and memfs. For now dont' use -O2, since usertests with -O2 is bigger than MAXFILE! - Update gdb.tmpl to be for i386 or x86-64 - Console/printf: use stdarg.h and treat 64-bit addresses different from ints (32-bit) - Update elfhdr to be 64 bit - entry.S/entryother.S: add code to switch to 64-bit mode: build a simple page table in 32-bit mode before switching to 64-bit mode, share code for entering boot processor and APs, and tweak boot gdt. The boot gdt is the gdt that the kernel proper also uses. (In 64-bit mode, the gdt/segmentation and task state mostly disappear.) - exec.c: fix passing argv (64-bit now instead of 32-bit). - initcode.c: use syscall instead of int. - kernel.ld: load kernel very high, in top terabyte. 64 bits is a lot of address space! - proc.c: initial return is through new syscall path instead of trapret. - proc.h: update struct cpu to have some scratch space since syscall saves less state than int, update struct context to reflect x86-64 calling conventions. - swtch: simplify for x86-64 calling conventions. - syscall: add fetcharg to handle x86-64 calling convetions (6 arguments are passed through registers), and fetchaddr to read a 64-bit value from user space. - sysfile: update to handle pointers from user space (e.g., sys_exec), which are 64 bits. - trap.c: no special trap vector for sys calls, because x86-64 has a different plan for system calls. - trapasm: one plan for syscalls and one plan for traps (interrupt and exceptions). On x86-64, the kernel is responsible for switching user/kernel stacks. To do, xv6 keeps some scratch space in the cpu structure, and uses MSR GS_KERN_BASE to point to the core's cpu structure (using swapgs). - types.h: add uint64, and change pde_t to uint64 - usertests: exit() when fork fails, which helped in tracking down one of the bugs in the switch from 32-bit to 64-bit - vectors: update to make them 64 bits - vm.c: use bootgdt in kernel too, program MSRs for syscalls and core-local state (for swapgs), walk 4 levels in walkpgdir, add DEVSPACETOP, use task segment to set kernel stack for interrupts (but simpler than in 32-bit mode), add an extra argument to freevm (size of user part of address space) to avoid checking all entries till KERNBASE (there are MANY TB before the top 1TB). - x86: update trapframe to have 64-bit entries, which is what the processor pushes on syscalls and traps. simplify lgdt and lidt, using struct desctr, which needs the gcc directives packed and aligned. TODO: - use int32 instead of int? - simplify curproc(). xv6 has per-cpu state again, but this time it must have it. - avoid repetition in walkpgdir - fix validateint() in usertests.c - fix bugs (e.g., observed one a case of entering kernel with invalid gs or proc
316 lines
5.5 KiB
C
316 lines
5.5 KiB
C
// Console input and output.
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// Input is from the keyboard or serial port.
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// Output is written to the screen and serial port.
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#include <stdarg.h>
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#include "types.h"
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#include "defs.h"
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#include "param.h"
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#include "traps.h"
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#include "spinlock.h"
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#include "sleeplock.h"
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#include "fs.h"
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#include "file.h"
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#include "memlayout.h"
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#include "mmu.h"
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#include "proc.h"
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#include "x86.h"
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static void consputc(int);
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static int panicked = 0;
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static struct {
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struct spinlock lock;
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int locking;
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} cons;
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static char digits[] = "0123456789abcdef";
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static void
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printint(int xx, int base, int sign)
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{
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char buf[16];
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int i;
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uint x;
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if(sign && (sign = xx < 0))
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x = -xx;
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else
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x = xx;
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i = 0;
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do{
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buf[i++] = digits[x % base];
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}while((x /= base) != 0);
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if(sign)
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buf[i++] = '-';
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while(--i >= 0)
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consputc(buf[i]);
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}
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static void
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printptr(uint64 x) {
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int i;
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consputc('0');
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consputc('x');
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for (i = 0; i < (sizeof(uint64) * 2); i++, x <<= 4)
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consputc(digits[x >> (sizeof(uint64) * 8 - 4)]);
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}
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//PAGEBREAK: 50
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// Print to the console. only understands %d, %x, %p, %s.
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void
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cprintf(char *fmt, ...)
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{
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va_list ap;
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int i, c, locking;
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char *s;
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locking = cons.locking;
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if(locking)
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acquire(&cons.lock);
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if (fmt == 0)
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panic("null fmt");
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va_start(ap, fmt);
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for(i = 0; (c = fmt[i] & 0xff) != 0; i++){
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if(c != '%'){
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consputc(c);
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continue;
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}
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c = fmt[++i] & 0xff;
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if(c == 0)
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break;
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switch(c){
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case 'd':
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printint(va_arg(ap, int), 10, 1);
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break;
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case 'x':
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printint(va_arg(ap, int), 16, 1);
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break;
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case 'p':
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printptr(va_arg(ap, uint64));
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break;
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case 's':
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if((s = va_arg(ap, char*)) == 0)
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s = "(null)";
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for(; *s; s++)
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consputc(*s);
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break;
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case '%':
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consputc('%');
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break;
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default:
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// Print unknown % sequence to draw attention.
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consputc('%');
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consputc(c);
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break;
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}
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}
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if(locking)
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release(&cons.lock);
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}
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void
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panic(char *s)
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{
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int i;
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uint64 pcs[10];
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cli();
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cons.locking = 0;
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// use lapiccpunum so that we can call panic from mycpu()
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cprintf("lapicid %d: panic: ", lapicid());
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cprintf(s);
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cprintf("\n");
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getcallerpcs(&s, pcs);
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for(i=0; i<10; i++)
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cprintf(" %p", pcs[i]);
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panicked = 1; // freeze other CPU
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for(;;)
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;
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}
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//PAGEBREAK: 50
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#define BACKSPACE 0x100
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#define CRTPORT 0x3d4
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static ushort *crt = (ushort*)P2V(0xb8000); // CGA memory
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static void
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cgaputc(int c)
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{
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int pos;
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// Cursor position: col + 80*row.
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outb(CRTPORT, 14);
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pos = inb(CRTPORT+1) << 8;
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outb(CRTPORT, 15);
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pos |= inb(CRTPORT+1);
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if(c == '\n')
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pos += 80 - pos%80;
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else if(c == BACKSPACE){
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if(pos > 0) --pos;
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} else
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crt[pos++] = (c&0xff) | 0x0700; // black on white
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if(pos < 0 || pos > 25*80)
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panic("pos under/overflow");
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if((pos/80) >= 24){ // Scroll up.
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memmove(crt, crt+80, sizeof(crt[0])*23*80);
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pos -= 80;
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memset(crt+pos, 0, sizeof(crt[0])*(24*80 - pos));
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}
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outb(CRTPORT, 14);
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outb(CRTPORT+1, pos>>8);
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outb(CRTPORT, 15);
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outb(CRTPORT+1, pos);
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crt[pos] = ' ' | 0x0700;
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}
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void
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consputc(int c)
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{
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if(panicked){
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cli();
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for(;;)
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;
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}
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if(c == BACKSPACE){
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uartputc('\b'); uartputc(' '); uartputc('\b');
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} else
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uartputc(c);
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cgaputc(c);
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}
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#define INPUT_BUF 128
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struct {
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char buf[INPUT_BUF];
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uint r; // Read index
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uint w; // Write index
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uint e; // Edit index
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} input;
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#define C(x) ((x)-'@') // Control-x
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void
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consoleintr(int (*getc)(void))
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{
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int c, doprocdump = 0;
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acquire(&cons.lock);
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while((c = getc()) >= 0){
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switch(c){
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case C('P'): // Process listing.
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// procdump() locks cons.lock indirectly; invoke later
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doprocdump = 1;
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break;
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case C('U'): // Kill line.
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while(input.e != input.w &&
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input.buf[(input.e-1) % INPUT_BUF] != '\n'){
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input.e--;
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consputc(BACKSPACE);
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}
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break;
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case C('H'): case '\x7f': // Backspace
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if(input.e != input.w){
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input.e--;
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consputc(BACKSPACE);
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}
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break;
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default:
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if(c != 0 && input.e-input.r < INPUT_BUF){
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c = (c == '\r') ? '\n' : c;
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input.buf[input.e++ % INPUT_BUF] = c;
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consputc(c);
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if(c == '\n' || c == C('D') || input.e == input.r+INPUT_BUF){
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input.w = input.e;
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wakeup(&input.r);
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}
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}
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break;
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}
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}
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release(&cons.lock);
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if(doprocdump) {
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procdump(); // now call procdump() wo. cons.lock held
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}
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}
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int
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consoleread(struct inode *ip, char *dst, int n)
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{
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uint target;
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int c;
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iunlock(ip);
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target = n;
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acquire(&cons.lock);
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while(n > 0){
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while(input.r == input.w){
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if(myproc()->killed){
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release(&cons.lock);
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ilock(ip);
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return -1;
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}
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sleep(&input.r, &cons.lock);
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}
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c = input.buf[input.r++ % INPUT_BUF];
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if(c == C('D')){ // EOF
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if(n < target){
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// Save ^D for next time, to make sure
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// caller gets a 0-byte result.
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input.r--;
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}
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break;
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}
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*dst++ = c;
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--n;
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if(c == '\n')
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break;
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}
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release(&cons.lock);
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ilock(ip);
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return target - n;
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}
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int
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consolewrite(struct inode *ip, char *buf, int n)
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{
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int i;
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iunlock(ip);
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acquire(&cons.lock);
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for(i = 0; i < n; i++)
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consputc(buf[i] & 0xff);
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release(&cons.lock);
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ilock(ip);
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return n;
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}
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void
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consoleinit(void)
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{
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initlock(&cons.lock, "console");
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devsw[CONSOLE].write = consolewrite;
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devsw[CONSOLE].read = consoleread;
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cons.locking = 1;
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ioapicenable(IRQ_KBD, 0);
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}
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