stand/boot/boot.c

1.19.10.1      tron /*	$NetBSD: boot.c,v 1.19.10.1 2005/04/28 11:06:03 tron Exp $ */
      1.1       mrg
      1.1       mrg /*-
      1.1       mrg  * Copyright (c) 1982, 1986, 1990, 1993
      1.1       mrg  *	The Regents of the University of California.  All rights reserved.
      1.1       mrg  *
      1.1       mrg  * Redistribution and use in source and binary forms, with or without
      1.1       mrg  * modification, are permitted provided that the following conditions
      1.1       mrg  * are met:
      1.1       mrg  * 1. Redistributions of source code must retain the above copyright
      1.1       mrg  *    notice, this list of conditions and the following disclaimer.
      1.1       mrg  * 2. Redistributions in binary form must reproduce the above copyright
      1.1       mrg  *    notice, this list of conditions and the following disclaimer in the
      1.1       mrg  *    documentation and/or other materials provided with the distribution.
     1.18       agc  * 3. Neither the name of the University nor the names of its contributors
      1.1       mrg  *    may be used to endorse or promote products derived from this software
      1.1       mrg  *    without specific prior written permission.
      1.1       mrg  *
      1.1       mrg  * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
      1.1       mrg  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
      1.1       mrg  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
      1.1       mrg  * ARE DISCLAIMED.  IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
      1.1       mrg  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
      1.1       mrg  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
      1.1       mrg  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
      1.1       mrg  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
      1.1       mrg  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
      1.1       mrg  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
      1.1       mrg  * SUCH DAMAGE.
      1.1       mrg  *
      1.1       mrg  * 	@(#)boot.c	8.1 (Berkeley) 6/10/93
      1.1       mrg  */
      1.1       mrg
      1.1       mrg #include <sys/param.h>
      1.1       mrg #include <sys/reboot.h>
     1.12       uwe #include <sys/boot_flag.h>
      1.9        pk #include <sys/exec.h>
      1.1       mrg
      1.1       mrg #include <lib/libsa/stand.h>
      1.5  christos #include <lib/libsa/loadfile.h>
     1.17       mrg #include <lib/libkern/libkern.h>
      1.1       mrg
      1.4        pk #include <machine/promlib.h>
      1.1       mrg #include <sparc/stand/common/promdev.h>
      1.1       mrg
      1.6  christos #include "bootinfo.h"
      1.6  christos
     1.10       uwe extern void	prom_patch __P((void));	/* prompatch.c */
     1.10       uwe
      1.4        pk static int	bootoptions __P((char *));
      1.4        pk
     1.14        pk int	boothowto;
     1.14        pk int	debug;
     1.14        pk int	netif_debug;
     1.14        pk
     1.14        pk char	fbuf[80], dbuf[128];
     1.15        pk paddr_t bstart, bend;	/* physical start & end address of the boot program */
     1.15        pk
     1.15        pk int	compatmode = 0;		/* For loading older kernels */
     1.15        pk u_long	loadaddrmask = -1UL;
      1.1       mrg
      1.1       mrg extern char bootprog_name[], bootprog_rev[], bootprog_date[], bootprog_maker[];
      1.1       mrg
      1.4        pk int	main __P((void));
      1.1       mrg typedef void (*entry_t)__P((caddr_t, int, int, int, long, long));
      1.1       mrg
      1.3       mrg /*
      1.3       mrg  * Boot device is derived from ROM provided information, or if there is none,
      1.3       mrg  * this list is used in sequence, to find a kernel.
      1.3       mrg  */
      1.3       mrg char *kernels[] = {
      1.3       mrg 	"netbsd",
      1.3       mrg 	"netbsd.gz",
      1.3       mrg 	"netbsd.old",
      1.3       mrg 	"netbsd.old.gz",
      1.3       mrg 	"onetbsd",
      1.3       mrg 	"onetbsd.gz",
      1.3       mrg 	"vmunix",
      1.3       mrg #ifdef notyet
      1.3       mrg 	"netbsd.pl",
      1.3       mrg 	"netbsd.pl.gz",
      1.3       mrg 	"netbsd.el",
      1.3       mrg 	"netbsd.el.gz",
      1.3       mrg #endif
      1.3       mrg 	NULL
      1.3       mrg };
      1.3       mrg
      1.4        pk int
      1.4        pk bootoptions(ap)
      1.4        pk 	char *ap;
      1.4        pk {
      1.4        pk 	int v = 0;
      1.4        pk 	if (ap == NULL || *ap++ != '-')
      1.4        pk 		return (0);
      1.4        pk
      1.4        pk 	while (*ap != '\0' && *ap != ' ' && *ap != '\t' && *ap != '\n') {
     1.12       uwe 		BOOT_FLAG(*ap, v);
     1.16        pk 		if (*ap == 'C')
     1.16        pk 			compatmode = 1;
      1.4        pk 		ap++;
      1.4        pk 	}
     1.12       uwe
     1.12       uwe 	if ((v & RB_KDB) != 0)
     1.12       uwe 		debug = 1;
      1.4        pk
      1.4        pk 	return (v);
      1.4        pk }
      1.4        pk
     1.15        pk static paddr_t getphysmem(u_long size)
     1.15        pk {
     1.15        pk 	struct	memarr *pmemarr;	/* physical memory regions */
     1.15        pk 	int	npmemarr;		/* number of entries in pmemarr */
     1.15        pk 	struct memarr *mp;
     1.15        pk 	int i;
     1.15        pk 	extern char start[];	/* top of stack (see srt0.S) */
     1.15        pk
     1.15        pk 	/*
     1.15        pk 	 * Find the physical memory area that's in use by the boot loader.
     1.15        pk 	 * Our stack grows down from label `start'; assume we need no more
     1.15        pk 	 * than 16K of stack space.
     1.15        pk 	 * The top of the boot loader is the next 4MB boundary.
     1.15        pk 	 */
     1.15        pk 	if (pmap_extract((vaddr_t)start - (16*1024), &bstart) != 0)
     1.15        pk 		return ((paddr_t)-1);
     1.15        pk
     1.15        pk 	bend = roundup(bstart, 0x400000);
     1.15        pk
     1.15        pk 	/*
     1.15        pk 	 * Get available physical memory from the prom.
     1.15        pk 	 */
     1.15        pk 	npmemarr = prom_makememarr(NULL, 0, MEMARR_AVAILPHYS);
     1.15        pk 	pmemarr = alloc(npmemarr*sizeof(struct memarr));
     1.15        pk 	if (pmemarr == NULL)
     1.15        pk 		return ((paddr_t)-1);
     1.15        pk 	npmemarr = prom_makememarr(pmemarr, npmemarr, MEMARR_AVAILPHYS);
     1.15        pk
     1.15        pk 	/*
     1.15        pk 	 * Find a suitable loading address.
     1.15        pk 	 */
     1.15        pk 	for (mp = pmemarr, i = npmemarr; --i >= 0; mp++) {
     1.15        pk 		paddr_t pa = (paddr_t)pmemarr[i].addr;
     1.15        pk 		u_long len = (u_long)pmemarr[i].len;
     1.15        pk
     1.15        pk 		/* Check whether it will fit in front of us */
     1.15        pk 		if (pa < bstart && len >= size && (bstart - pa) >= size)
     1.15        pk 			return (pa);
     1.15        pk
     1.15        pk 		/* Skip the boot program memory */
     1.15        pk 		if (pa < bend) {
     1.15        pk 			if (len < bend - pa)
     1.15        pk 				/* Not large enough */
     1.15        pk 				continue;
     1.15        pk
     1.15        pk 			/* Shrink this segment */
     1.15        pk 			len -=  bend - pa;
     1.15        pk 			pa = bend;
     1.15        pk 		}
     1.15        pk
     1.15        pk 		/* Does it fit in the remainder of this segment? */
     1.15        pk 		if (len >= size)
     1.15        pk 			return (pa);
     1.15        pk 	}
     1.15        pk 	return ((paddr_t)-1);
     1.15        pk }
     1.15        pk
     1.14        pk static int
     1.14        pk loadk(char *kernel, u_long *marks)
     1.14        pk {
     1.14        pk 	int fd, error;
     1.15        pk 	vaddr_t va;
     1.15        pk 	paddr_t pa;
     1.14        pk 	u_long size;
     1.14        pk
     1.14        pk 	if ((fd = open(kernel, 0)) < 0)
     1.14        pk 		return (errno ? errno : ENOENT);
     1.14        pk
     1.14        pk 	marks[MARK_START] = 0;
     1.14        pk 	if ((error = fdloadfile(fd, marks, COUNT_KERNEL)) != 0)
     1.14        pk 		goto out;
     1.14        pk
     1.14        pk 	size = marks[MARK_END] - marks[MARK_START];
     1.15        pk
     1.16        pk 	/* We want that leading 16K in front of the kernel image */
     1.15        pk 	size += PROM_LOADADDR;
     1.15        pk 	va = marks[MARK_START] - PROM_LOADADDR;
     1.15        pk
     1.16        pk 	/*
     1.16        pk 	 * Extra space for bootinfo and kernel bootstrap.
     1.16        pk 	 * In compat mode, we get to re-use the space occupied by the
     1.16        pk 	 * boot program. Traditionally, we've silently assumed that
     1.16        pk 	 * is enough for the kernel to work with.
     1.16        pk 	 */
     1.16        pk 	size += BOOTINFO_SIZE;
     1.16        pk 	if (!compatmode)
     1.16        pk 		size += 512 * 1024;
     1.15        pk
     1.15        pk 	/* Get a physical load address */
     1.15        pk 	pa = getphysmem(size);
     1.15        pk 	if (pa == (paddr_t)-1) {
     1.14        pk 		error = EFBIG;
     1.14        pk 		goto out;
     1.14        pk 	}
     1.14        pk
     1.15        pk 	if (boothowto & AB_VERBOSE)
     1.15        pk 		printf("Loading at physical address %lx\n", pa);
     1.15        pk 	if (pmap_map(va, pa, size) != 0) {
     1.15        pk 		error = EFAULT;
     1.15        pk 		goto out;
     1.15        pk 	}
     1.15        pk
     1.15        pk 	/* XXX - to do: inspect kernel image and set compat mode */
     1.15        pk 	if (compatmode) {
     1.16        pk 		/* Double-map at VA 0 for compatibility */
     1.16        pk 		if (pa + size >= bstart) {
     1.16        pk 			printf("%s: too large for compat mode\n", kernel);
     1.16        pk 			error = EFBIG;
     1.16        pk 			goto out;
     1.16        pk 		}
     1.16        pk
     1.19        pk 		if (pa != 0 && pmap_map(0, pa, size) != 0) {
     1.16        pk 			error = EFAULT;
     1.16        pk 			goto out;
     1.16        pk 		}
     1.15        pk 		loadaddrmask = 0x07ffffffUL;
     1.15        pk 	}
     1.15        pk
     1.14        pk 	marks[MARK_START] = 0;
     1.14        pk 	error = fdloadfile(fd, marks, LOAD_KERNEL);
     1.14        pk out:
     1.14        pk 	close(fd);
     1.14        pk 	return (error);
     1.14        pk }
     1.14        pk
      1.4        pk int
      1.1       mrg main()
      1.1       mrg {
     1.14        pk 	int	error, i;
1.19.10.1      tron 	char	kernel[MAX_PROM_PATH], *k;
      1.6  christos 	u_long	marks[MARK_MAX], bootinfo;
      1.6  christos 	struct btinfo_symtab bi_sym;
      1.5  christos 	void	*arg;
      1.1       mrg
      1.8        pk #ifdef HEAP_VARIABLE
      1.8        pk 	{
      1.8        pk 		extern char end[];
      1.8        pk 		setheap((void *)ALIGN(end), (void *)0xffffffff);
      1.8        pk 	}
      1.8        pk #endif
      1.1       mrg 	prom_init();
     1.15        pk 	mmu_init();
      1.1       mrg
      1.1       mrg 	printf(">> %s, Revision %s\n", bootprog_name, bootprog_rev);
      1.1       mrg 	printf(">> (%s, %s)\n", bootprog_maker, bootprog_date);
     1.10       uwe
     1.10       uwe 	/* massage machine prom */
     1.10       uwe 	prom_patch();
      1.1       mrg
      1.3       mrg 	/*
      1.3       mrg 	 * get default kernel.
      1.3       mrg 	 */
1.19.10.1      tron 	k = prom_getbootfile();
1.19.10.1      tron 	if (k != NULL && *k != '\0') {
      1.3       mrg 		i = -1;	/* not using the kernels */
1.19.10.1      tron 		strcpy(kernel, k);
      1.3       mrg 	} else {
      1.3       mrg 		i = 0;
1.19.10.1      tron 		strcpy(kernel, kernels[i]);
      1.3       mrg 	}
      1.1       mrg
1.19.10.1      tron 	k = prom_getbootpath();
1.19.10.1      tron 	if (k && *k)
1.19.10.1      tron 		strcpy(prom_bootdevice, k);
1.19.10.1      tron 	boothowto = bootoptions(prom_getbootargs());
1.19.10.1      tron
      1.1       mrg 	for (;;) {
      1.3       mrg 		/*
      1.3       mrg 		 * ask for a kernel first ..
      1.3       mrg 		 */
     1.14        pk 		if (boothowto & RB_ASKNAME) {
      1.3       mrg 			printf("device[%s] (\"halt\" to halt): ",
      1.4        pk 					prom_bootdevice);
      1.1       mrg 			gets(dbuf);
      1.3       mrg 			if (strcmp(dbuf, "halt") == 0)
      1.3       mrg 				_rtt();
      1.1       mrg 			if (dbuf[0])
1.19.10.1      tron 				strcpy(prom_bootdevice, dbuf);
      1.3       mrg 			printf("boot (press RETURN to try default list): ");
      1.1       mrg 			gets(fbuf);
      1.1       mrg 			if (fbuf[0])
1.19.10.1      tron 				strcpy(kernel, fbuf);
      1.3       mrg 			else {
     1.14        pk 				boothowto &= ~RB_ASKNAME;
      1.3       mrg 				i = 0;
1.19.10.1      tron 				strcpy(kernel, kernels[i]);
      1.3       mrg 			}
      1.1       mrg 		}
      1.3       mrg
      1.5  christos 		printf("Booting %s\n", kernel);
     1.14        pk 		if ((error = loadk(kernel, marks)) == 0)
     1.14        pk 			break;
     1.14        pk
     1.14        pk 		if (error != ENOENT) {
     1.14        pk 			printf("Cannot load %s: error=%d\n", kernel, error);
     1.14        pk 			boothowto |= RB_ASKNAME;
     1.13        pk 		}
     1.13        pk
      1.3       mrg 		/*
      1.3       mrg 		 * if we have are not in askname mode, and we aren't using the
      1.3       mrg 		 * prom bootfile, try the next one (if it exits).  otherwise,
      1.3       mrg 		 * go into askname mode.
      1.3       mrg 		 */
     1.14        pk 		if ((boothowto & RB_ASKNAME) == 0 &&
      1.3       mrg 		    i != -1 && kernels[++i]) {
1.19.10.1      tron 			strcpy(kernel, kernels[i]);
      1.3       mrg 			printf(": trying %s...\n", kernel);
      1.3       mrg 		} else {
      1.3       mrg 			printf("\n");
     1.14        pk 			boothowto |= RB_ASKNAME;
      1.3       mrg 		}
      1.1       mrg 	}
      1.1       mrg
     1.15        pk 	marks[MARK_END] = (((u_long)marks[MARK_END] + sizeof(u_long) - 1)) &
     1.15        pk 	    (-sizeof(u_long));
      1.7  christos 	arg = (prom_version() == PROM_OLDMON) ? (caddr_t)PROM_LOADADDR : romp;
     1.14        pk
     1.15        pk 	/* Setup boot info structure at the end of the kernel image */
     1.15        pk 	bootinfo = bi_init(marks[MARK_END] & loadaddrmask);
     1.11        pk
     1.15        pk 	/* Add kernel symbols to bootinfo */
     1.15        pk 	bi_sym.nsym = marks[MARK_NSYM] & loadaddrmask;
     1.15        pk 	bi_sym.ssym = marks[MARK_SYM] & loadaddrmask;
     1.15        pk 	bi_sym.esym = marks[MARK_END] & loadaddrmask;
      1.6  christos 	bi_add(&bi_sym, BTINFO_SYMTAB, sizeof(bi_sym));
     1.11        pk
     1.15        pk 	/* Add kernel path to bootinfo */
     1.11        pk 	i = sizeof(struct btinfo_common) + strlen(kernel) + 1;
     1.11        pk 	/* Impose limit (somewhat arbitrary) */
     1.11        pk 	if (i < BOOTINFO_SIZE / 2) {
     1.11        pk 		union {
     1.11        pk 			struct btinfo_kernelfile bi_file;
     1.11        pk 			char x[i];
     1.11        pk 		} U;
     1.11        pk 		strcpy(U.bi_file.name, kernel);
     1.11        pk 		bi_add(&U.bi_file, BTINFO_KERNELFILE, i);
     1.11        pk 	}
     1.11        pk
      1.6  christos 	(*(entry_t)marks[MARK_ENTRY])(arg, 0, 0, 0, bootinfo, DDB_MAGIC2);
      1.1       mrg 	_rtt();
      1.1       mrg }