stand/xxboot/main.c

1.1  skrll /*	$NetBSD: main.c,v 1.1 2014/02/24 07:23:43 skrll Exp $	*/
1.1  skrll
1.1  skrll /*
1.1  skrll  * Copyright (c) 2003 ITOH Yasufumi.
1.1  skrll  * All rights reserved.
1.1  skrll  *
1.1  skrll  * Redistribution and use in source and binary forms, with or without
1.1  skrll  * modification, are permitted provided that the following conditions
1.1  skrll  * are met:
1.1  skrll  * 1. Redistributions of source code must retain the above copyright
1.1  skrll  *    notice, this list of conditions and the following disclaimer.
1.1  skrll  * 2. Redistributions in binary forms are unlimited.
1.1  skrll  *
1.1  skrll  * THIS SOFTWARE IS PROVIDED BY THE AUTHORS AND CONTRIBUTORS ``AS IS''
1.1  skrll  * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO,
1.1  skrll  * THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
1.1  skrll  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE AUTHORS OR CONTRIBUTORS
1.1  skrll  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
1.1  skrll  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
1.1  skrll  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
1.1  skrll  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
1.1  skrll  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
1.1  skrll  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF
1.1  skrll  * THE POSSIBILITY OF SUCH DAMAGE.
1.1  skrll  */
1.1  skrll
1.1  skrll #include <sys/types.h>
1.1  skrll #include <sys/param.h>
1.1  skrll #include <ufs/ufs/dinode.h>
1.1  skrll #include <sys/disklabel.h>
1.1  skrll #include <sys/exec_elf.h>
1.1  skrll #include "readufs.h"
1.1  skrll
1.1  skrll #define STACK_SIZE	((unsigned) (64*1024))
1.1  skrll #define LOAD_ALIGN	((unsigned) 2048)
1.1  skrll
1.1  skrll #define PZ_MEM_BOOT	0x3d0
1.1  skrll #define DEV_CLASS	0x2c
1.1  skrll #define DEV_CL_MASK	0xf
1.1  skrll #define DEV_CL_SEQU	0x2	/* sequential record access media */
1.1  skrll
1.1  skrll static char *hexstr(char *, unsigned);
1.1  skrll void ipl_main(unsigned /*interactive*/, unsigned /*sptop*/, unsigned /*psw*/);
1.1  skrll void load_file(const char *, uintptr_t /*loadadr*/, unsigned /*interactive*/,
1.1  skrll     int /*part*/);
1.1  skrll void load_file_ino(ino32_t, const char *, uintptr_t /*loadadr*/,
1.1  skrll     unsigned /*interactive*/, int /*part*/);
1.1  skrll
1.1  skrll struct loadinfo {
1.1  skrll 	void *sec_image;
1.1  skrll 	unsigned sec_size;
1.1  skrll #if 0
1.1  skrll 	unsigned sec_pad;
1.1  skrll #endif
1.1  skrll 	unsigned entry_offset;
1.1  skrll };
1.1  skrll static inline void xi_elf32(struct loadinfo *, Elf32_Ehdr *);
1.1  skrll static inline void xi_elf64(struct loadinfo *, Elf64_Ehdr *);
1.1  skrll int xi_load(struct loadinfo *, void *);
1.1  skrll
1.1  skrll void reboot(void);
1.1  skrll void halt(void);
1.1  skrll void dispatch(unsigned /*interactive*/, unsigned /*top*/,
1.1  skrll     unsigned /*end*/, int /*part*/, unsigned /*entry*/);
1.1  skrll void print(const char *);
1.1  skrll void putch(int);
1.1  skrll int getch(void);
1.1  skrll int boot_input(void *, int /*len*/, int /*pos*/);
1.1  skrll
1.1  skrll /* to make generated code relocatable, do NOT mark them as const */
1.1  skrll extern char str_seekseq[], str_bit_firmware[];
1.1  skrll extern char str_crlf[], str_space[], str_rubout[];
1.1  skrll extern char str_bootpart[], str_booting_part[];
1.1  skrll extern char str_warn_2GB[], str_warn_unused[], str_nolabel[];
1.1  skrll extern char str_filesystem[], str_nofs[];
1.1  skrll extern char str_lookup[], str_loading[], str_at[], str_dddot[], str_done[];
1.1  skrll extern char str_boot1[], str_boot2[], str_boot3[];
1.1  skrll extern char str_noboot[];
1.1  skrll extern char str_ukfmt[];
1.1  skrll
1.1  skrll #ifdef __GNUC__
1.1  skrll #define memcpy(d, s, n)	__builtin_memcpy(d, s, n)
1.1  skrll #else
1.1  skrll void *memcpy(void *, const void *, size_t);
1.1  skrll #endif
1.1  skrll void *memmove(void *, const void *, size_t);
1.1  skrll
1.1  skrll /* disklabel */
1.1  skrll union {
1.1  skrll 	char dklsec[512];
1.1  skrll 	struct disklabel dkl;	/* to ensure alignment */
1.1  skrll } labelsector;
1.1  skrll #define dklabel	(*(struct disklabel *)(labelsector.dklsec + LABELOFFSET))
1.1  skrll
1.1  skrll unsigned offset_raw_read;
1.1  skrll
1.1  skrll extern char diskbuf[2048];
1.1  skrll #define BLK_PER_READ	4
1.1  skrll #define MASK_BLK_PER_READ	(BLK_PER_READ - 1)
1.1  skrll
1.1  skrll void
1.1  skrll RAW_READ(void *buf, daddr_t blkpos, size_t bytelen)
1.1  skrll {
1.1  skrll 	char *b = buf;
1.1  skrll 	size_t off, readlen;
1.1  skrll 	int devoff;
1.1  skrll 	static int prvdevoff = -dbtob(BLK_PER_READ);
1.1  skrll 	int pos;
1.1  skrll
1.1  skrll 	for ( ; bytelen > 0; b += readlen, bytelen -= readlen) {
1.1  skrll 		/*
1.1  skrll 		 * read 2KB, avoiding unneeded read
1.1  skrll 		 */
1.1  skrll 		devoff = dbtob(blkpos & ~MASK_BLK_PER_READ) + offset_raw_read;
1.1  skrll 		if (prvdevoff != devoff) {
1.1  skrll #if 1	/* supports sequential media */
1.1  skrll 			if ((*(unsigned *)(PZ_MEM_BOOT+DEV_CLASS) & DEV_CL_MASK)
1.1  skrll 				== DEV_CL_SEQU) {
1.1  skrll 				/*
1.1  skrll 				 * sequential media
1.1  skrll 				 * -- read sequentially or rewind
1.1  skrll 				 */
1.1  skrll 				pos = prvdevoff + dbtob(BLK_PER_READ);
1.1  skrll 				if (devoff < pos)
1.1  skrll 					pos = 0;	/* rewind */
1.1  skrll
1.1  skrll 				/* "repositioning media...\r\n" */
1.1  skrll 				if (devoff - pos > 512 * 1024)
1.1  skrll 					print(str_seekseq);
1.1  skrll
1.1  skrll 				for (; pos < devoff; pos += dbtob(BLK_PER_READ))
1.1  skrll 					boot_input(diskbuf,
1.1  skrll 					    dbtob(BLK_PER_READ), pos);
1.1  skrll 			}
1.1  skrll #endif
1.1  skrll 			prvdevoff = devoff;
1.1  skrll 			boot_input(diskbuf, dbtob(BLK_PER_READ), devoff);
1.1  skrll 		}
1.1  skrll 		/*
1.1  skrll 		 * copy specified size to the destination
1.1  skrll 		 */
1.1  skrll 		off = dbtob(blkpos & MASK_BLK_PER_READ),
1.1  skrll 		readlen = dbtob(BLK_PER_READ) - off;
1.1  skrll 		if (readlen > bytelen)
1.1  skrll 			readlen = bytelen;
1.1  skrll 		memcpy(b, diskbuf + off, readlen);
1.1  skrll 		blkpos = (blkpos & ~MASK_BLK_PER_READ) + BLK_PER_READ;
1.1  skrll 	}
1.1  skrll }
1.1  skrll
1.1  skrll /*
1.1  skrll  * convert number to hex string
1.1  skrll  * buf must have enough space
1.1  skrll  */
1.1  skrll static char *
1.1  skrll hexstr(char *buf, unsigned val)
1.1  skrll {
1.1  skrll 	unsigned v;
1.1  skrll 	char rev[16];
1.1  skrll 	char *r = rev, *b = buf;
1.1  skrll
1.1  skrll 	/* inverse order */
1.1  skrll 	do {
1.1  skrll 		v = val & 0xf;
1.1  skrll 		*r++ = (v <= 9) ? '0' + v : 'a' - 10 + v;
1.1  skrll 		val >>= 4;
1.1  skrll 	} while (val);
1.1  skrll
1.1  skrll 	/* reverse string */
1.1  skrll 	while (r > rev)
1.1  skrll 		*b++ = *--r;
1.1  skrll
1.1  skrll 	*b = '\0';
1.1  skrll 	return buf;
1.1  skrll }
1.1  skrll
1.1  skrll void
1.1  skrll ipl_main(unsigned interactive, unsigned sptop, unsigned psw)
1.1  skrll 	/* interactive:		 parameters from PDC */
1.1  skrll 	/* sptop:			 value of sp on function entry */
1.1  skrll 	/* psw:			 PSW on startup */
1.1  skrll {
1.1  skrll 	char buf[32];
1.1  skrll 	int part = 0;		/* default partition "a" */
1.1  skrll 	unsigned secsz, partoff, partsz;
1.1  skrll 	int c, c1;
1.1  skrll 	uintptr_t loadadr;
1.1  skrll
1.1  skrll #if 0
1.1  skrll 	print(hexstr(buf, interactive));
1.1  skrll 	print(str_crlf);
1.1  skrll 	print(hexstr(buf, sptop));
1.1  skrll 	print(str_crlf);
1.1  skrll 	print(hexstr(buf, psw));
1.1  skrll 	print(str_crlf);
1.1  skrll #endif
1.1  skrll
1.1  skrll 	print(hexstr(buf, (psw & 0x08000000) ? (unsigned) 0x64 : 0x32));
1.1  skrll 	print(str_bit_firmware);	/* "bit firmware\r\n" */
1.1  skrll
1.1  skrll 	/*
1.1  skrll 	 * check disklabel
1.1  skrll 	 * (dklabel has disklabel on startup)
1.1  skrll 	 */
1.1  skrll 	if (dklabel.d_magic == DISKMAGIC && (secsz = dklabel.d_secsize) != 0) {
1.1  skrll 		/*
1.1  skrll 		 * select boot partition
1.1  skrll 		 */
1.1  skrll 		if (interactive) {
1.1  skrll 		select_partition:
1.1  skrll 			/* "boot partition (a-p, ! to reboot) [a]:" */
1.1  skrll 			print(str_bootpart);
1.1  skrll 			part = 0;		/* default partition "a" */
1.1  skrll 			c1 = 0;
1.1  skrll 			while ((c = getch()) >= 0) {
1.1  skrll 				switch (c) {
1.1  skrll 				case '\n':
1.1  skrll 				case '\r':
1.1  skrll 					goto break_while;
1.1  skrll 				case '\b':
1.1  skrll 				case '\177':
1.1  skrll 					if (c1) {
1.1  skrll 						print(str_rubout);
1.1  skrll 						part = c1 = 0;
1.1  skrll 					}
1.1  skrll 					break;
1.1  skrll 				case '!':	/* reset */
1.1  skrll 					if (c1 == 0) {
1.1  skrll 						part = -1;
1.1  skrll 						goto echoback;
1.1  skrll 					}
1.1  skrll 					break;
1.1  skrll 				default:
1.1  skrll 					if (c1 == 0 && c >= 'a' && c <= 'p') {
1.1  skrll 						part = c - 'a';
1.1  skrll 					echoback:
1.1  skrll 						putch(c);
1.1  skrll 						c1 = 1;
1.1  skrll 					}
1.1  skrll 					break;
1.1  skrll 				}
1.1  skrll 			}
1.1  skrll 		break_while:
1.1  skrll 			if (part == -1)
1.1  skrll 				return;		/* reset */
1.1  skrll 		}
1.1  skrll
1.1  skrll 		/*
1.1  skrll 		 * "\r\nbooting from partition _\r\n"
1.1  skrll 		 */
1.1  skrll 		str_booting_part[25] = 'a' + part;
1.1  skrll 		print(str_booting_part);
1.1  skrll
1.1  skrll 		partoff = dklabel.d_partitions[part].p_offset;
1.1  skrll 		partsz  = dklabel.d_partitions[part].p_size;
1.1  skrll
1.1  skrll 		if (part >= (int) dklabel.d_npartitions || partsz == 0) {
1.1  skrll 			print(str_warn_unused);	/* "unused partition\r\n" */
1.1  skrll 			goto select_partition;
1.1  skrll 		}
1.1  skrll
1.1  skrll 		/* boot partition must be below 2GB */
1.1  skrll 		if (partoff + partsz > ((unsigned)2*1024*1024*1024) / secsz) {
1.1  skrll 			/* "boot partition exceeds 2GB boundary\r\n" */
1.1  skrll 			print(str_warn_2GB);
1.1  skrll 			goto select_partition;
1.1  skrll 		}
1.1  skrll
1.1  skrll 		/*
1.1  skrll 		 * following device accesses are only in the partition
1.1  skrll 		 */
1.1  skrll 		offset_raw_read = partoff * secsz;
1.1  skrll 	} else {
1.1  skrll 		/*
1.1  skrll 		 * no disklabel --- assume the whole of the device
1.1  skrll 		 * is a filesystem
1.1  skrll 		 */
1.1  skrll 		print(str_nolabel);	/* "no disklabel\r\n" */
1.1  skrll 	}
1.1  skrll
1.1  skrll 	if (ufs_init()) {
1.1  skrll 		print(str_nofs);	/* "no filesystem found\r\n" */
1.1  skrll 		return;
1.1  skrll 	}
1.1  skrll 	str_filesystem[12] = (ufs_info.fstype == UFSTYPE_FFS) ? 'F' : 'L';
1.1  skrll 	print(str_filesystem);		/* "filesystem: _FS\r\n" */
1.1  skrll
1.1  skrll 	loadadr = (sptop + STACK_SIZE + LOAD_ALIGN - 1) & (-LOAD_ALIGN);
1.1  skrll 	load_file(str_boot1, loadadr, interactive, part); /* "boot.hp700" */
1.1  skrll 	load_file(str_boot2, loadadr, interactive, part); /* "boot" */
1.1  skrll 	load_file(str_boot3, loadadr, interactive, part); /* "usr/mdec/boot" */
1.1  skrll
1.1  skrll 	print(str_noboot);		/* "no secondary boot found\r\n" */
1.1  skrll }
1.1  skrll
1.1  skrll void
1.1  skrll load_file(const char *path, uintptr_t loadadr, unsigned interactive, int part)
1.1  skrll {
1.1  skrll
1.1  skrll 	/* look-up the file */
1.1  skrll 	print(str_lookup);	/* "looking up " */
1.1  skrll 	print(path);
1.1  skrll 	print(str_crlf);
1.1  skrll 	load_file_ino(ufs_lookup_path(path), path, loadadr, interactive, part);
1.1  skrll }
1.1  skrll
1.1  skrll void
1.1  skrll load_file_ino(ino32_t ino, const char *fn, uintptr_t loadadr, unsigned interactive, int part)
1.1  skrll 	/* fn:		 for message only */
1.1  skrll {
1.1  skrll 	union ufs_dinode dinode;
1.1  skrll 	size_t sz;
1.1  skrll 	struct loadinfo inf;
1.1  skrll 	char buf[32];
1.1  skrll
1.1  skrll 	if (ino == 0 || ufs_get_inode(ino, &dinode))
1.1  skrll 		return;		/* not found */
1.1  skrll
1.1  skrll 	print(str_loading);		/* "loading " */
1.1  skrll 	print(fn);
1.1  skrll 	print(str_at);			/* " at 0x" */
1.1  skrll 	print(hexstr(buf, loadadr));
1.1  skrll 	print(str_dddot);		/* "..." */
1.1  skrll
1.1  skrll 	sz = DI_SIZE(&dinode);
1.1  skrll 	ufs_read(&dinode, (void *) loadadr, 0, sz);
1.1  skrll
1.1  skrll 	print(str_done);		/* "done\r\n" */
1.1  skrll
1.1  skrll 	/* digest executable format */
1.1  skrll 	inf.sec_size = sz;
1.1  skrll 	inf.entry_offset = 0;
1.1  skrll 	if (xi_load(&inf, (void *) loadadr)) {
1.1  skrll 		print(fn);
1.1  skrll 		print(str_ukfmt); /* ": unknown format -- exec from top\r\n" */
1.1  skrll 	}
1.1  skrll
1.1  skrll 	/* pass control to the secondary boot */
1.1  skrll 	dispatch(interactive, loadadr, loadadr + inf.sec_size, part,
1.1  skrll 	    loadadr + inf.entry_offset);
1.1  skrll }
1.1  skrll
1.1  skrll /*
1.1  skrll  * fill in loading information from an ELF executable
1.1  skrll  */
1.1  skrll static inline void
1.1  skrll xi_elf32(struct loadinfo *inf, Elf32_Ehdr *hdr)
1.1  skrll {
1.1  skrll 	char *top = (void *) hdr;
1.1  skrll 	Elf32_Phdr *ph;
1.1  skrll
1.1  skrll 	/* text + data, bss */
1.1  skrll 	ph = (void *) (top + hdr->e_phoff);
1.1  skrll 	inf->sec_image = top + ph->p_offset;
1.1  skrll 	inf->sec_size = ph->p_filesz;
1.1  skrll #if 0
1.1  skrll 	inf->sec_pad = ph->p_memsz - ph->p_filesz;
1.1  skrll #endif
1.1  skrll 	/* entry */
1.1  skrll 	inf->entry_offset = hdr->e_entry - ph->p_vaddr;
1.1  skrll }
1.1  skrll
1.1  skrll static inline void
1.1  skrll xi_elf64(struct loadinfo *inf, Elf64_Ehdr *hdr)
1.1  skrll {
1.1  skrll 	char *top = (void *) hdr;
1.1  skrll 	Elf64_Phdr *ph;
1.1  skrll
1.1  skrll 	/*
1.1  skrll 	 * secondary boot is not so large, so 32bit (unsigned) arithmetic
1.1  skrll 	 * is enough
1.1  skrll 	 */
1.1  skrll 	/* text + data, bss */
1.1  skrll 	ph = (void *) (top + (unsigned) hdr->e_phoff);
1.1  skrll 	inf->sec_image = top + (unsigned) ph->p_offset;
1.1  skrll 	inf->sec_size = (unsigned) ph->p_filesz;
1.1  skrll #if 0
1.1  skrll 	inf->sec_pad = (unsigned) ph->p_memsz - (unsigned) ph->p_filesz;
1.1  skrll #endif
1.1  skrll 	/* entry */
1.1  skrll 	inf->entry_offset = (unsigned) hdr->e_entry - (unsigned) ph->p_vaddr;
1.1  skrll }
1.1  skrll
1.1  skrll int
1.1  skrll xi_load(struct loadinfo *inf, void *buf)
1.1  skrll {
1.1  skrll 	Elf32_Ehdr *e32hdr = buf;
1.1  skrll 	Elf64_Ehdr *e64hdr = buf;
1.1  skrll 	uint16_t class_data;
1.1  skrll
1.1  skrll 	/*
1.1  skrll 	 * check ELF header
1.1  skrll 	 * (optimized assuming big endian byte order)
1.1  skrll 	 */
1.1  skrll 	/* ELF magic */
1.1  skrll 	if (*(uint32_t *)&e32hdr->e_ident[EI_MAG0] !=
1.1  skrll 		(ELFMAG0 << 24 | ELFMAG1 << 16 | ELFMAG2 << 8 | ELFMAG3) ||
1.1  skrll 	    e32hdr->e_ident[EI_VERSION] != EV_CURRENT)
1.1  skrll 		return 1;	/* Not an ELF */
1.1  skrll
1.1  skrll 	/* file and machine type */
1.1  skrll 	if (*(uint32_t *)&e32hdr->e_type != (ET_EXEC << 16 | EM_PARISC))
1.1  skrll 		return 1;	/* Not an executable / Wrong architecture */
1.1  skrll
1.1  skrll 	if ((class_data = *(uint16_t *)&e32hdr->e_ident[EI_CLASS]) ==
1.1  skrll 	    (ELFCLASS32 << 8 | ELFDATA2MSB)) {
1.1  skrll
1.1  skrll 		/* support one section executable (ld -N) only */
1.1  skrll 		if (e32hdr->e_phnum != 1)
1.1  skrll 			return 1;	/* Wrong number of loading sections */
1.1  skrll
1.1  skrll 		/* fill in loading information */
1.1  skrll 		xi_elf32(inf, e32hdr);
1.1  skrll
1.1  skrll 	} else if (class_data == (ELFCLASS64 << 8 | ELFDATA2MSB)) {
1.1  skrll
1.1  skrll 		/* support one section executable (ld -N) only */
1.1  skrll 		if (e64hdr->e_phnum != 1)
1.1  skrll 			return 1;	/* Wrong number of loading sections */
1.1  skrll
1.1  skrll 		/* fill in loading information */
1.1  skrll 		xi_elf64(inf, e64hdr);
1.1  skrll
1.1  skrll 	} else
1.1  skrll 		return 1;	/* Not a 32bit or 64bit ELF */
1.1  skrll
1.1  skrll 	/* move text + data to the top address */
1.1  skrll 	memmove(buf, inf->sec_image, inf->sec_size);
1.1  skrll
1.1  skrll #if 0	/* XXX bss clear is done by the secondary boot itself */
1.1  skrll 	memset((char *) buf + inf->sec_size, 0, inf->sec_pad);
1.1  skrll #endif
1.1  skrll
1.1  skrll 	return 0;
1.1  skrll }