stand/zbsdmod/zbsdmod.c

1.5  nonaka /*	$NetBSD: zbsdmod.c,v 1.5 2010/12/26 09:03:56 nonaka Exp $	*/
1.1   peter /*	$OpenBSD: zbsdmod.c,v 1.7 2005/05/02 02:45:29 uwe Exp $	*/
1.1   peter
1.1   peter /*
1.1   peter  * Copyright (c) 2005 Uwe Stuehler <uwe (at) bsdx.de>
1.1   peter  *
1.1   peter  * Permission to use, copy, modify, and distribute this software for any
1.1   peter  * purpose with or without fee is hereby granted, provided that the above
1.1   peter  * copyright notice and this permission notice appear in all copies.
1.1   peter  *
1.1   peter  * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
1.1   peter  * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
1.1   peter  * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
1.1   peter  * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
1.1   peter  * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
1.1   peter  * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
1.1   peter  * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
1.1   peter  */
1.1   peter
1.1   peter /*
1.1   peter  * Zaurus NetBSD bootstrap loader.
1.1   peter  */
1.1   peter
1.1   peter #include "compat_linux.h"
1.1   peter
1.1   peter #include <machine/bootinfo.h>
1.1   peter
1.1   peter #define ZBOOTDEV_MAJOR	99
1.1   peter #define ZBOOTDEV_MODE	0222
1.1   peter #define ZBOOTDEV_NAME	"zboot"
1.1   peter #define ZBOOTMOD_NAME	"zbsdmod"
1.1   peter
1.1   peter /* Prototypes */
1.1   peter int	init_module(void);
1.1   peter void	cleanup_module(void);
1.1   peter
1.1   peter static ssize_t	zbsdmod_write(struct file *, const char *, size_t, loff_t *);
1.1   peter static int	zbsdmod_open(struct inode *, struct file *);
1.1   peter static int	zbsdmod_close(struct inode *, struct file *);
1.1   peter
1.1   peter static void	elf32bsdboot(void);
1.1   peter
1.1   peter static struct file_operations fops = {
1.1   peter 	0,			/* struct module *owner */
1.1   peter 	0,			/* lseek */
1.1   peter 	0,			/* read */
1.1   peter 	zbsdmod_write,		/* write */
1.1   peter 	0,			/* readdir */
1.1   peter 	0,			/* poll */
1.1   peter 	0,			/* ioctl */
1.1   peter 	0,			/* mmap */
1.1   peter 	zbsdmod_open,		/* open */
1.1   peter 	0,			/* flush */
1.1   peter 	zbsdmod_close,		/* release */
1.1   peter 	0,			/* sync */
1.1   peter 	0,			/* async */
1.1   peter 	0,			/* check media change */
1.1   peter 	0,			/* revalidate */
1.1   peter 	0,			/* lock */
1.1   peter };
1.1   peter
1.1   peter static int isopen;
1.1   peter static loff_t position;
1.1   peter
1.1   peter /* Outcast local variables to avoid stack usage in elf32bsdboot(). */
1.1   peter static int cpsr;
1.1   peter static unsigned int sz;
1.1   peter static int i;
1.1   peter static vaddr_t minv, maxv, posv;
1.1   peter static vaddr_t elfv, shpv;
1.1   peter static int *addr;
1.1   peter static vaddr_t *esymp;
1.1   peter static Elf_Shdr *shp;
1.1   peter static Elf_Off off;
1.1   peter static int havesyms;
1.1   peter
1.2  nonaka /* The maximum size of a kernel image is restricted to 10MB. */
1.2  nonaka static u_int bsdimage[10485760/sizeof(u_int)];	/* XXX use kmalloc() */
1.1   peter static char bootargs[BOOTARGS_BUFSIZ];
1.1   peter
1.1   peter /*
1.1   peter  * Boot the loaded BSD kernel image, or return if an error is found.
1.1   peter  * Part of this routine is borrowed from sys/lib/libsa/loadfile.c.
1.1   peter  */
1.1   peter static void
1.1   peter elf32bsdboot(void)
1.1   peter {
1.1   peter
1.1   peter #define elf	((Elf32_Ehdr *)bsdimage)
1.1   peter #define phdr	((Elf32_Phdr *)((char *)elf + elf->e_phoff))
1.1   peter
1.1   peter 	if (memcmp(elf->e_ident, ELFMAG, SELFMAG) != 0 ||
1.1   peter 	    elf->e_ident[EI_CLASS] != ELFCLASS32)
1.1   peter 		return;
1.1   peter
1.1   peter 	minv = (vaddr_t)~0;
1.1   peter 	maxv = (vaddr_t)0;
1.1   peter 	posv = (vaddr_t)0;
1.1   peter 	esymp = 0;
1.1   peter
1.1   peter 	/*
1.1   peter 	 * Get min and max addresses used by the loaded kernel.
1.1   peter 	 */
1.1   peter 	for (i = 0; i < elf->e_phnum; i++) {
1.1   peter
1.1   peter 		if (phdr[i].p_type != PT_LOAD ||
1.1   peter 		    (phdr[i].p_flags & (PF_W|PF_R|PF_X)) == 0)
1.1   peter 			continue;
1.1   peter
1.1   peter #define IS_TEXT(p)	(p.p_flags & PF_X)
1.1   peter #define IS_DATA(p)	((p.p_flags & PF_X) == 0)
1.1   peter #define IS_BSS(p)	(p.p_filesz < p.p_memsz)
1.1   peter 		/*
1.1   peter 		 * XXX: Assume first address is lowest
1.1   peter 		 */
1.1   peter 		if (IS_TEXT(phdr[i]) || IS_DATA(phdr[i])) {
1.1   peter 			posv = phdr[i].p_vaddr;
1.1   peter 			if (minv > posv)
1.1   peter 				minv = posv;
1.1   peter 			posv += phdr[i].p_filesz;
1.1   peter 			if (maxv < posv)
1.1   peter 				maxv = posv;
1.1   peter 		}
1.1   peter 		if (IS_DATA(phdr[i]) && IS_BSS(phdr[i])) {
1.1   peter 			posv += phdr[i].p_memsz;
1.1   peter 			if (maxv < posv)
1.1   peter 				maxv = posv;
1.1   peter 		}
1.1   peter 		/*
1.1   peter 		 * 'esym' is the first word in the .data section,
1.1   peter 		 * and marks the end of the symbol table.
1.1   peter 		 */
1.1   peter 		if (IS_DATA(phdr[i]) && !IS_BSS(phdr[i]))
1.1   peter 			esymp = (vaddr_t *)phdr[i].p_vaddr;
1.1   peter 	}
1.1   peter
1.1   peter 	__asm volatile ("mrs %0, cpsr_all" : "=r" (cpsr));
1.1   peter 	cpsr |= 0xc0;  /* set FI */
1.1   peter 	__asm volatile ("msr cpsr_all, %0" :: "r" (cpsr));
1.1   peter
1.1   peter 	/*
1.1   peter 	 * Copy the boot arguments.
1.1   peter 	 */
1.1   peter 	sz = BOOTARGS_BUFSIZ;
1.1   peter 	while (sz > 0) {
1.1   peter 		sz--;
1.1   peter 		((char *)minv - BOOTARGS_BUFSIZ)[sz] = bootargs[sz];
1.1   peter 	}
1.1   peter
1.1   peter 	/*
1.1   peter 	 * Set up pointers to copied ELF and section headers.
1.1   peter 	 */
1.1   peter #define roundup(x, y)	((((x)+((y)-1))/(y))*(y))
1.1   peter 	elfv = maxv = roundup(maxv, sizeof(long));
1.1   peter 	maxv += sizeof(Elf_Ehdr);
1.1   peter
1.1   peter 	sz = elf->e_shnum * sizeof(Elf_Shdr);
1.1   peter 	shp = (Elf_Shdr *)((vaddr_t)elf + elf->e_shoff);
1.1   peter 	shpv = maxv;
1.1   peter 	maxv += roundup(sz, sizeof(long));
1.1   peter
1.1   peter 	/*
1.1   peter 	 * Now load the symbol sections themselves.  Make sure the
1.1   peter 	 * sections are aligned, and offsets are relative to the
1.1   peter 	 * copied ELF header.  Don't bother with string tables if
1.1   peter 	 * there are no symbol sections.
1.1   peter 	 */
1.1   peter 	off = roundup((sizeof(Elf_Ehdr) + sz), sizeof(long));
1.1   peter 	for (havesyms = i = 0; i < elf->e_shnum; i++)
1.1   peter 		if (shp[i].sh_type == SHT_SYMTAB)
1.1   peter 			havesyms = 1;
1.1   peter 	for (i = 0; i < elf->e_shnum; i++) {
1.1   peter 		if (shp[i].sh_type == SHT_SYMTAB ||
1.1   peter 		    shp[i].sh_type == SHT_STRTAB) {
1.1   peter 			if (havesyms) {
1.1   peter 				sz = shp[i].sh_size;
1.1   peter 				while (sz > 0) {
1.1   peter 					sz--;
1.1   peter 					((char *)maxv)[sz] =
1.1   peter 					    ((char *)elf +
1.1   peter 						shp[i].sh_offset)[sz];
1.1   peter 				}
1.1   peter 			}
1.1   peter 			maxv += roundup(shp[i].sh_size, sizeof(long));
1.1   peter 			shp[i].sh_offset = off;
1.1   peter 			off += roundup(shp[i].sh_size, sizeof(long));
1.1   peter 		}
1.1   peter 	}
1.1   peter
1.1   peter 	/*
1.1   peter 	 * Copy the ELF and section headers.
1.1   peter 	 */
1.1   peter 	sz = sizeof(Elf_Ehdr);
1.1   peter 	while (sz > 0) {
1.1   peter 		sz--;
1.1   peter 		((char *)elfv)[sz] = ((char *)elf)[sz];
1.1   peter 	}
1.1   peter 	sz = elf->e_shnum * sizeof(Elf_Shdr);
1.1   peter 	while (sz > 0) {
1.1   peter 		sz--;
1.1   peter 		((char *)shpv)[sz] = ((char *)shp)[sz];
1.1   peter 	}
1.1   peter
1.1   peter 	/*
1.1   peter 	 * Frob the copied ELF header to give information relative
1.1   peter 	 * to elfv.
1.1   peter 	 */
1.1   peter 	((Elf_Ehdr *)elfv)->e_phoff = 0;
1.1   peter 	((Elf_Ehdr *)elfv)->e_shoff = sizeof(Elf_Ehdr);
1.1   peter 	((Elf_Ehdr *)elfv)->e_phentsize = 0;
1.1   peter 	((Elf_Ehdr *)elfv)->e_phnum = 0;
1.1   peter
1.1   peter 	/*
1.1   peter 	 * Tell locore.S where the symbol table ends, and arrange
1.1   peter 	 * to skip esym when loading the data section.
1.1   peter 	 */
1.1   peter 	if (esymp != 0)
1.1   peter 		*esymp = (vaddr_t)maxv;
1.1   peter 	for (i = 0; esymp != 0 && i < elf->e_phnum; i++) {
1.1   peter 		if (phdr[i].p_type != PT_LOAD ||
1.1   peter 		    (phdr[i].p_flags & (PF_W|PF_R|PF_X)) == 0)
1.1   peter 			continue;
1.1   peter 		if (phdr[i].p_vaddr == (vaddr_t)esymp) {
1.1   peter 			phdr[i].p_vaddr = (vaddr_t)((char *)phdr[i].p_vaddr + sizeof(long));
1.1   peter 			phdr[i].p_offset = (vaddr_t)((char *)phdr[i].p_offset + sizeof(long));
1.1   peter 			phdr[i].p_filesz -= sizeof(long);
1.1   peter 			break;
1.1   peter 		}
1.1   peter 	}
1.1   peter
1.1   peter 	/*
1.1   peter 	 * Load text and data.
1.1   peter 	 */
1.1   peter 	for (i = 0; i < elf->e_phnum; i++) {
1.1   peter 		if (phdr[i].p_type != PT_LOAD ||
1.1   peter 		    (phdr[i].p_flags & (PF_W|PF_R|PF_X)) == 0)
1.1   peter 			continue;
1.1   peter
1.1   peter 		if (IS_TEXT(phdr[i]) || IS_DATA(phdr[i])) {
1.1   peter 			sz = phdr[i].p_filesz;
1.1   peter 			while (sz > 0) {
1.1   peter 				sz--;
1.1   peter 				((char *)phdr[i].p_vaddr)[sz] =
1.1   peter 				    (((char *)elf) + phdr[i].p_offset)[sz];
1.1   peter 			}
1.1   peter 		}
1.1   peter 	}
1.1   peter
1.1   peter 	addr = (int *)(elf->e_entry);
1.1   peter 	__asm volatile (
1.1   peter 		"mov	r0, %0;"
1.1   peter 		"mov	r2, #0;"
1.1   peter 		"mcr	p15, 0, r2, c7, c7, 0;"
1.1   peter 		"mov	r2, r2;"
1.1   peter 		"sub	pc, pc, #4;"
1.1   peter 		"mov	r1, #(0x00000010 | 0x00000020);"
1.1   peter 		"mcr	p15, 0, r1, c1, c0, 0;"
1.1   peter 		"mcr	p15, 0, r2, c8, c7, 0;"
1.1   peter 		"mov	r2, r2;"
1.1   peter 		"sub	pc, pc, #4;"
1.1   peter 		"mov	pc, r0" :: "r"(addr) : "r0","r1","r2");
1.1   peter }
1.1   peter
1.1   peter /*
1.3      ad  * Initialize the module.
1.1   peter  */
1.1   peter int
1.1   peter init_module(void)
1.1   peter {
1.1   peter 	struct proc_dir_entry *entry;
1.1   peter 	int rc;
1.1   peter
1.1   peter 	rc = register_chrdev(ZBOOTDEV_MAJOR, ZBOOTDEV_NAME, &fops);
1.1   peter 	if (rc != 0) {
1.1   peter 		printk("%s: register_chrdev(%d, ...): error %d\n",
1.5  nonaka 		    ZBOOTMOD_NAME, ZBOOTDEV_MAJOR, -rc);
1.1   peter 		return 1;
1.1   peter 	}
1.1   peter
1.1   peter 	entry = proc_mknod(ZBOOTDEV_NAME, ZBOOTDEV_MODE | S_IFCHR,
1.1   peter 	    &proc_root, MKDEV(ZBOOTDEV_MAJOR, 0));
1.1   peter 	if (entry == (struct proc_dir_entry *)0) {
1.1   peter 		(void)unregister_chrdev(ZBOOTDEV_MAJOR, ZBOOTDEV_NAME);
1.1   peter 		return 1;
1.1   peter 	}
1.1   peter
1.1   peter 	printk("%s: NetBSD/" MACHINE " bootstrap device is %d,0\n",
1.1   peter 	    ZBOOTMOD_NAME, ZBOOTDEV_MAJOR);
1.1   peter
1.1   peter 	return 0;
1.1   peter }
1.1   peter
1.1   peter /*
1.1   peter  * Cleanup - undo whatever init_module did.
1.1   peter  */
1.1   peter void
1.1   peter cleanup_module(void)
1.1   peter {
1.1   peter
1.1   peter 	(void)unregister_chrdev(ZBOOTDEV_MAJOR, ZBOOTDEV_NAME);
1.1   peter 	remove_proc_entry(ZBOOTDEV_NAME, &proc_root);
1.1   peter
1.1   peter 	printk("%s: NetBSD/" MACHINE " bootstrap device unloaded\n",
1.1   peter 	    ZBOOTMOD_NAME);
1.1   peter }
1.1   peter
1.1   peter static ssize_t
1.1   peter zbsdmod_write(struct file *f, const char *buf, size_t len, loff_t *offp)
1.1   peter {
1.1   peter
1.1   peter 	if (len < 1)
1.1   peter 		return 0;
1.1   peter
1.1   peter 	if (*offp + len >= sizeof(bsdimage))
1.1   peter 		return EFBIG;
1.1   peter
1.1   peter 	memcpy(((char *)bsdimage) + *offp, buf, len);
1.1   peter
1.1   peter 	*offp += len;
1.1   peter 	if (*offp > position)
1.1   peter 		position = *offp;
1.1   peter
1.1   peter 	return len;
1.1   peter }
1.1   peter
1.1   peter static int
1.1   peter zbsdmod_open(struct inode *ino, struct file *f)
1.1   peter {
1.1   peter
1.1   peter 	/* XXX superuser check */
1.1   peter
1.1   peter 	if (isopen)
1.1   peter 		return -EBUSY;
1.1   peter
1.1   peter 	isopen = 1;
1.1   peter 	position = 0;
1.1   peter
1.1   peter 	return 0;
1.1   peter }
1.1   peter
1.1   peter static int
1.1   peter zbsdmod_close(struct inode *ino, struct file *f)
1.1   peter {
1.1   peter
1.1   peter 	if (!isopen)
1.1   peter 		return -EBUSY;
1.1   peter
1.1   peter 	if (position > 0) {
1.5  nonaka 		printk("%s: loaded %ld bytes\n", ZBOOTDEV_NAME,
1.1   peter 		    position);
1.1   peter
1.4  nonaka 		if (position < BOOTINFO_MAXSIZE) {
1.1   peter 			*(u_int *)bootargs = BOOTARGS_MAGIC;
1.4  nonaka 			memcpy(bootargs + sizeof(u_int), bsdimage, position);
1.1   peter 		} else {
1.1   peter 			elf32bsdboot();
1.4  nonaka 			printk("%s: boot failed\n", ZBOOTDEV_NAME);
1.1   peter 		}
1.1   peter 	}
1.1   peter 	isopen = 0;
1.1   peter
1.1   peter 	return 0;
1.1   peter }