qemu/pc-bios/s390-ccw/bootmap.c
Thomas Huth 9a848adf45 pc-bios/s390-ccw/net: Use diag308 to reset machine before jumping to the OS
The netboot firmware so far simply jumped directly into the OS kernel
after the download has been completed. This, however, bears the risk
that the virtio-net device still might be active in the background and
incoming packets are still placed into the buffers - which could destroy
memory of the now-running Linux kernel in case it did not take over the
device fast enough. Also the SCLP console is not put into a well-defined
state here. We should hand over the system in a clean state when jumping
into the kernel, so let's use the same mechanism as it's done in the
main s390-ccw firmware and reset the machine with diag308 into a clean
state before jumping into the OS kernel code. To be able to share the
code with the main s390-ccw firmware, the related functions are now
extracted from bootmap.c into a new file called jump2ipl.c.

Since we now also set the boot device schid at address 184 for the network
boot device, this patch also slightly changes the way how we detect the
entry points for non-ELF binary images: The code now looks for the "S390EP"
magic first and then jumps to 0x10000 in case it has been found. This is
necessary for booting from network devices, since the normal kernel code
(where the PSW at ddress 0 points to) tries to do a block load from the
boot device. This of course fails for a virtio-net device and causes the
kernel to abort with a panic-PSW silently.

Acked-by: Christian Borntraeger <borntraeger@de.ibm.com>
Signed-off-by: Thomas Huth <thuth@redhat.com>
2018-05-02 11:27:14 +02:00

817 lines
24 KiB
C

/*
* QEMU S390 bootmap interpreter
*
* Copyright (c) 2009 Alexander Graf <agraf@suse.de>
*
* This work is licensed under the terms of the GNU GPL, version 2 or (at
* your option) any later version. See the COPYING file in the top-level
* directory.
*/
#include "libc.h"
#include "s390-ccw.h"
#include "bootmap.h"
#include "virtio.h"
#include "bswap.h"
#ifdef DEBUG
/* #define DEBUG_FALLBACK */
#endif
#ifdef DEBUG_FALLBACK
#define dputs(txt) \
do { sclp_print("zipl: " txt); } while (0)
#else
#define dputs(fmt, ...) \
do { } while (0)
#endif
/* Scratch space */
static uint8_t sec[MAX_SECTOR_SIZE*4] __attribute__((__aligned__(PAGE_SIZE)));
const uint8_t el_torito_magic[] = "EL TORITO SPECIFICATION"
"\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0";
/*
* Match two CCWs located after PSW and eight filler bytes.
* From libmagic and arch/s390/kernel/head.S.
*/
const uint8_t linux_s390_magic[] = "\x02\x00\x00\x18\x60\x00\x00\x50\x02\x00"
"\x00\x68\x60\x00\x00\x50\x40\x40\x40\x40"
"\x40\x40\x40\x40";
static inline bool is_iso_vd_valid(IsoVolDesc *vd)
{
const uint8_t vol_desc_magic[] = "CD001";
return !memcmp(&vd->ident[0], vol_desc_magic, 5) &&
vd->version == 0x1 &&
vd->type <= VOL_DESC_TYPE_PARTITION;
}
/***********************************************************************
* IPL an ECKD DASD (CDL or LDL/CMS format)
*/
static unsigned char _bprs[8*1024]; /* guessed "max" ECKD sector size */
static const int max_bprs_entries = sizeof(_bprs) / sizeof(ExtEckdBlockPtr);
static uint8_t _s2[MAX_SECTOR_SIZE * 3] __attribute__((__aligned__(PAGE_SIZE)));
static void *s2_prev_blk = _s2;
static void *s2_cur_blk = _s2 + MAX_SECTOR_SIZE;
static void *s2_next_blk = _s2 + MAX_SECTOR_SIZE * 2;
static inline void verify_boot_info(BootInfo *bip)
{
IPL_assert(magic_match(bip->magic, ZIPL_MAGIC), "No zIPL sig in BootInfo");
IPL_assert(bip->version == BOOT_INFO_VERSION, "Wrong zIPL version");
IPL_assert(bip->bp_type == BOOT_INFO_BP_TYPE_IPL, "DASD is not for IPL");
IPL_assert(bip->dev_type == BOOT_INFO_DEV_TYPE_ECKD, "DASD is not ECKD");
IPL_assert(bip->flags == BOOT_INFO_FLAGS_ARCH, "Not for this arch");
IPL_assert(block_size_ok(bip->bp.ipl.bm_ptr.eckd.bptr.size),
"Bad block size in zIPL section of the 1st record.");
}
static block_number_t eckd_block_num(EckdCHS *chs)
{
const uint64_t sectors = virtio_get_sectors();
const uint64_t heads = virtio_get_heads();
const uint64_t cylinder = chs->cylinder
+ ((chs->head & 0xfff0) << 12);
const uint64_t head = chs->head & 0x000f;
const block_number_t block = sectors * heads * cylinder
+ sectors * head
+ chs->sector
- 1; /* block nr starts with zero */
return block;
}
static bool eckd_valid_address(BootMapPointer *p)
{
const uint64_t head = p->eckd.chs.head & 0x000f;
if (head >= virtio_get_heads()
|| p->eckd.chs.sector > virtio_get_sectors()
|| p->eckd.chs.sector <= 0) {
return false;
}
if (!virtio_guessed_disk_nature() &&
eckd_block_num(&p->eckd.chs) >= virtio_get_blocks()) {
return false;
}
return true;
}
static block_number_t load_eckd_segments(block_number_t blk, uint64_t *address)
{
block_number_t block_nr;
int j, rc;
BootMapPointer *bprs = (void *)_bprs;
bool more_data;
memset(_bprs, FREE_SPACE_FILLER, sizeof(_bprs));
read_block(blk, bprs, "BPRS read failed");
do {
more_data = false;
for (j = 0;; j++) {
block_nr = eckd_block_num(&bprs[j].xeckd.bptr.chs);
if (is_null_block_number(block_nr)) { /* end of chunk */
break;
}
/* we need the updated blockno for the next indirect entry
* in the chain, but don't want to advance address
*/
if (j == (max_bprs_entries - 1)) {
break;
}
IPL_assert(block_size_ok(bprs[j].xeckd.bptr.size),
"bad chunk block size");
IPL_assert(eckd_valid_address(&bprs[j]), "bad chunk ECKD addr");
if ((bprs[j].xeckd.bptr.count == 0) && unused_space(&(bprs[j+1]),
sizeof(EckdBlockPtr))) {
/* This is a "continue" pointer.
* This ptr should be the last one in the current
* script section.
* I.e. the next ptr must point to the unused memory area
*/
memset(_bprs, FREE_SPACE_FILLER, sizeof(_bprs));
read_block(block_nr, bprs, "BPRS continuation read failed");
more_data = true;
break;
}
/* Load (count+1) blocks of code at (block_nr)
* to memory (address).
*/
rc = virtio_read_many(block_nr, (void *)(*address),
bprs[j].xeckd.bptr.count+1);
IPL_assert(rc == 0, "code chunk read failed");
*address += (bprs[j].xeckd.bptr.count+1) * virtio_get_block_size();
}
} while (more_data);
return block_nr;
}
static bool find_zipl_boot_menu_banner(int *offset)
{
int i;
/* Menu banner starts with "zIPL" */
for (i = 0; i < virtio_get_block_size() - 4; i++) {
if (magic_match(s2_cur_blk + i, ZIPL_MAGIC_EBCDIC)) {
*offset = i;
return true;
}
}
return false;
}
static int eckd_get_boot_menu_index(block_number_t s1b_block_nr)
{
block_number_t cur_block_nr;
block_number_t prev_block_nr = 0;
block_number_t next_block_nr = 0;
EckdStage1b *s1b = (void *)sec;
int banner_offset;
int i;
/* Get Stage1b data */
memset(sec, FREE_SPACE_FILLER, sizeof(sec));
read_block(s1b_block_nr, s1b, "Cannot read stage1b boot loader");
memset(_s2, FREE_SPACE_FILLER, sizeof(_s2));
/* Get Stage2 data */
for (i = 0; i < STAGE2_BLK_CNT_MAX; i++) {
cur_block_nr = eckd_block_num(&s1b->seek[i].chs);
if (!cur_block_nr) {
break;
}
read_block(cur_block_nr, s2_cur_blk, "Cannot read stage2 boot loader");
if (find_zipl_boot_menu_banner(&banner_offset)) {
/*
* Load the adjacent blocks to account for the
* possibility of menu data spanning multiple blocks.
*/
if (prev_block_nr) {
read_block(prev_block_nr, s2_prev_blk,
"Cannot read stage2 boot loader");
}
if (i + 1 < STAGE2_BLK_CNT_MAX) {
next_block_nr = eckd_block_num(&s1b->seek[i + 1].chs);
}
if (next_block_nr) {
read_block(next_block_nr, s2_next_blk,
"Cannot read stage2 boot loader");
}
return menu_get_zipl_boot_index(s2_cur_blk + banner_offset);
}
prev_block_nr = cur_block_nr;
}
sclp_print("No zipl boot menu data found. Booting default entry.");
return 0;
}
static void run_eckd_boot_script(block_number_t bmt_block_nr,
block_number_t s1b_block_nr)
{
int i;
unsigned int loadparm = get_loadparm_index();
block_number_t block_nr;
uint64_t address;
BootMapTable *bmt = (void *)sec;
BootMapScript *bms = (void *)sec;
if (menu_is_enabled_zipl()) {
loadparm = eckd_get_boot_menu_index(s1b_block_nr);
}
debug_print_int("loadparm", loadparm);
IPL_assert(loadparm < MAX_BOOT_ENTRIES, "loadparm value greater than"
" maximum number of boot entries allowed");
memset(sec, FREE_SPACE_FILLER, sizeof(sec));
read_block(bmt_block_nr, sec, "Cannot read Boot Map Table");
block_nr = eckd_block_num(&bmt->entry[loadparm].xeckd.bptr.chs);
IPL_assert(block_nr != -1, "Cannot find Boot Map Table Entry");
memset(sec, FREE_SPACE_FILLER, sizeof(sec));
read_block(block_nr, sec, "Cannot read Boot Map Script");
for (i = 0; bms->entry[i].type == BOOT_SCRIPT_LOAD; i++) {
address = bms->entry[i].address.load_address;
block_nr = eckd_block_num(&bms->entry[i].blkptr.xeckd.bptr.chs);
do {
block_nr = load_eckd_segments(block_nr, &address);
} while (block_nr != -1);
}
IPL_assert(bms->entry[i].type == BOOT_SCRIPT_EXEC,
"Unknown script entry type");
jump_to_IPL_code(bms->entry[i].address.load_address); /* no return */
}
static void ipl_eckd_cdl(void)
{
XEckdMbr *mbr;
EckdCdlIpl2 *ipl2 = (void *)sec;
IplVolumeLabel *vlbl = (void *)sec;
block_number_t bmt_block_nr, s1b_block_nr;
/* we have just read the block #0 and recognized it as "IPL1" */
sclp_print("CDL\n");
memset(sec, FREE_SPACE_FILLER, sizeof(sec));
read_block(1, ipl2, "Cannot read IPL2 record at block 1");
mbr = &ipl2->mbr;
IPL_assert(magic_match(mbr, ZIPL_MAGIC), "No zIPL section in IPL2 record.");
IPL_assert(block_size_ok(mbr->blockptr.xeckd.bptr.size),
"Bad block size in zIPL section of IPL2 record.");
IPL_assert(mbr->dev_type == DEV_TYPE_ECKD,
"Non-ECKD device type in zIPL section of IPL2 record.");
/* save pointer to Boot Map Table */
bmt_block_nr = eckd_block_num(&mbr->blockptr.xeckd.bptr.chs);
/* save pointer to Stage1b Data */
s1b_block_nr = eckd_block_num(&ipl2->stage1.seek[0].chs);
memset(sec, FREE_SPACE_FILLER, sizeof(sec));
read_block(2, vlbl, "Cannot read Volume Label at block 2");
IPL_assert(magic_match(vlbl->key, VOL1_MAGIC),
"Invalid magic of volume label block");
IPL_assert(magic_match(vlbl->f.key, VOL1_MAGIC),
"Invalid magic of volser block");
print_volser(vlbl->f.volser);
run_eckd_boot_script(bmt_block_nr, s1b_block_nr);
/* no return */
}
static void print_eckd_ldl_msg(ECKD_IPL_mode_t mode)
{
LDL_VTOC *vlbl = (void *)sec; /* already read, 3rd block */
char msg[4] = { '?', '.', '\n', '\0' };
sclp_print((mode == ECKD_CMS) ? "CMS" : "LDL");
sclp_print(" version ");
switch (vlbl->LDL_version) {
case LDL1_VERSION:
msg[0] = '1';
break;
case LDL2_VERSION:
msg[0] = '2';
break;
default:
msg[0] = vlbl->LDL_version;
msg[0] &= 0x0f; /* convert EBCDIC */
msg[0] |= 0x30; /* to ASCII (digit) */
msg[1] = '?';
break;
}
sclp_print(msg);
print_volser(vlbl->volser);
}
static void ipl_eckd_ldl(ECKD_IPL_mode_t mode)
{
block_number_t bmt_block_nr, s1b_block_nr;
EckdLdlIpl1 *ipl1 = (void *)sec;
if (mode != ECKD_LDL_UNLABELED) {
print_eckd_ldl_msg(mode);
}
/* DO NOT read BootMap pointer (only one, xECKD) at block #2 */
memset(sec, FREE_SPACE_FILLER, sizeof(sec));
read_block(0, sec, "Cannot read block 0 to grab boot info.");
if (mode == ECKD_LDL_UNLABELED) {
if (!magic_match(ipl1->bip.magic, ZIPL_MAGIC)) {
return; /* not applicable layout */
}
sclp_print("unlabeled LDL.\n");
}
verify_boot_info(&ipl1->bip);
/* save pointer to Boot Map Table */
bmt_block_nr = eckd_block_num(&ipl1->bip.bp.ipl.bm_ptr.eckd.bptr.chs);
/* save pointer to Stage1b Data */
s1b_block_nr = eckd_block_num(&ipl1->stage1.seek[0].chs);
run_eckd_boot_script(bmt_block_nr, s1b_block_nr);
/* no return */
}
static void print_eckd_msg(void)
{
char msg[] = "Using ECKD scheme (block size *****), ";
char *p = &msg[34], *q = &msg[30];
int n = virtio_get_block_size();
/* Fill in the block size and show up the message */
if (n > 0 && n <= 99999) {
while (n) {
*p-- = '0' + (n % 10);
n /= 10;
}
while (p >= q) {
*p-- = ' ';
}
}
sclp_print(msg);
}
static void ipl_eckd(void)
{
XEckdMbr *mbr = (void *)sec;
LDL_VTOC *vlbl = (void *)sec;
print_eckd_msg();
/* Grab the MBR again */
memset(sec, FREE_SPACE_FILLER, sizeof(sec));
read_block(0, mbr, "Cannot read block 0 on DASD");
if (magic_match(mbr->magic, IPL1_MAGIC)) {
ipl_eckd_cdl(); /* no return */
}
/* LDL/CMS? */
memset(sec, FREE_SPACE_FILLER, sizeof(sec));
read_block(2, vlbl, "Cannot read block 2");
if (magic_match(vlbl->magic, CMS1_MAGIC)) {
ipl_eckd_ldl(ECKD_CMS); /* no return */
}
if (magic_match(vlbl->magic, LNX1_MAGIC)) {
ipl_eckd_ldl(ECKD_LDL); /* no return */
}
ipl_eckd_ldl(ECKD_LDL_UNLABELED); /* it still may return */
/*
* Ok, it is not a LDL by any means.
* It still might be a CDL with zero record keys for IPL1 and IPL2
*/
ipl_eckd_cdl();
}
/***********************************************************************
* IPL a SCSI disk
*/
static void zipl_load_segment(ComponentEntry *entry)
{
const int max_entries = (MAX_SECTOR_SIZE / sizeof(ScsiBlockPtr));
ScsiBlockPtr *bprs = (void *)sec;
const int bprs_size = sizeof(sec);
block_number_t blockno;
uint64_t address;
int i;
char err_msg[] = "zIPL failed to read BPRS at 0xZZZZZZZZZZZZZZZZ";
char *blk_no = &err_msg[30]; /* where to print blockno in (those ZZs) */
blockno = entry->data.blockno;
address = entry->load_address;
debug_print_int("loading segment at block", blockno);
debug_print_int("addr", address);
do {
memset(bprs, FREE_SPACE_FILLER, bprs_size);
fill_hex_val(blk_no, &blockno, sizeof(blockno));
read_block(blockno, bprs, err_msg);
for (i = 0;; i++) {
uint64_t *cur_desc = (void *)&bprs[i];
blockno = bprs[i].blockno;
if (!blockno) {
break;
}
/* we need the updated blockno for the next indirect entry in the
chain, but don't want to advance address */
if (i == (max_entries - 1)) {
break;
}
if (bprs[i].blockct == 0 && unused_space(&bprs[i + 1],
sizeof(ScsiBlockPtr))) {
/* This is a "continue" pointer.
* This ptr is the last one in the current script section.
* I.e. the next ptr must point to the unused memory area.
* The blockno is not zero, so the upper loop must continue
* reading next section of BPRS.
*/
break;
}
address = virtio_load_direct(cur_desc[0], cur_desc[1], 0,
(void *)address);
IPL_assert(address != -1, "zIPL load segment failed");
}
} while (blockno);
}
/* Run a zipl program */
static void zipl_run(ScsiBlockPtr *pte)
{
ComponentHeader *header;
ComponentEntry *entry;
uint8_t tmp_sec[MAX_SECTOR_SIZE];
read_block(pte->blockno, tmp_sec, "Cannot read header");
header = (ComponentHeader *)tmp_sec;
IPL_assert(magic_match(tmp_sec, ZIPL_MAGIC), "No zIPL magic in header");
IPL_assert(header->type == ZIPL_COMP_HEADER_IPL, "Bad header type");
dputs("start loading images\n");
/* Load image(s) into RAM */
entry = (ComponentEntry *)(&header[1]);
while (entry->component_type == ZIPL_COMP_ENTRY_LOAD) {
zipl_load_segment(entry);
entry++;
IPL_assert((uint8_t *)(&entry[1]) <= (tmp_sec + MAX_SECTOR_SIZE),
"Wrong entry value");
}
IPL_assert(entry->component_type == ZIPL_COMP_ENTRY_EXEC, "No EXEC entry");
/* should not return */
jump_to_IPL_code(entry->load_address);
}
static void ipl_scsi(void)
{
ScsiMbr *mbr = (void *)sec;
int program_table_entries = 0;
BootMapTable *prog_table = (void *)sec;
unsigned int loadparm = get_loadparm_index();
bool valid_entries[MAX_BOOT_ENTRIES] = {false};
size_t i;
/* Grab the MBR */
memset(sec, FREE_SPACE_FILLER, sizeof(sec));
read_block(0, mbr, "Cannot read block 0");
if (!magic_match(mbr->magic, ZIPL_MAGIC)) {
return;
}
sclp_print("Using SCSI scheme.\n");
debug_print_int("MBR Version", mbr->version_id);
IPL_check(mbr->version_id == 1,
"Unknown MBR layout version, assuming version 1");
debug_print_int("program table", mbr->pt.blockno);
IPL_assert(mbr->pt.blockno, "No Program Table");
/* Parse the program table */
read_block(mbr->pt.blockno, sec, "Error reading Program Table");
IPL_assert(magic_match(sec, ZIPL_MAGIC), "No zIPL magic in PT");
for (i = 0; i < MAX_BOOT_ENTRIES; i++) {
if (prog_table->entry[i].scsi.blockno) {
valid_entries[i] = true;
program_table_entries++;
}
}
debug_print_int("program table entries", program_table_entries);
IPL_assert(program_table_entries != 0, "Empty Program Table");
if (menu_is_enabled_enum()) {
loadparm = menu_get_enum_boot_index(valid_entries);
}
debug_print_int("loadparm", loadparm);
IPL_assert(loadparm < MAX_BOOT_ENTRIES, "loadparm value greater than"
" maximum number of boot entries allowed");
zipl_run(&prog_table->entry[loadparm].scsi); /* no return */
}
/***********************************************************************
* IPL El Torito ISO9660 image or DVD
*/
static bool is_iso_bc_entry_compatible(IsoBcSection *s)
{
uint8_t *magic_sec = (uint8_t *)(sec + ISO_SECTOR_SIZE);
if (s->unused || !s->sector_count) {
return false;
}
read_iso_sector(bswap32(s->load_rba), magic_sec,
"Failed to read image sector 0");
/* Checking bytes 8 - 32 for S390 Linux magic */
return !memcmp(magic_sec + 8, linux_s390_magic, 24);
}
/* Location of the current sector of the directory */
static uint32_t sec_loc[ISO9660_MAX_DIR_DEPTH];
/* Offset in the current sector of the directory */
static uint32_t sec_offset[ISO9660_MAX_DIR_DEPTH];
/* Remained directory space in bytes */
static uint32_t dir_rem[ISO9660_MAX_DIR_DEPTH];
static inline uint32_t iso_get_file_size(uint32_t load_rba)
{
IsoVolDesc *vd = (IsoVolDesc *)sec;
IsoDirHdr *cur_record = &vd->vd.primary.rootdir;
uint8_t *temp = sec + ISO_SECTOR_SIZE;
int level = 0;
read_iso_sector(ISO_PRIMARY_VD_SECTOR, sec,
"Failed to read ISO primary descriptor");
sec_loc[0] = iso_733_to_u32(cur_record->ext_loc);
dir_rem[0] = 0;
sec_offset[0] = 0;
while (level >= 0) {
IPL_assert(sec_offset[level] <= ISO_SECTOR_SIZE,
"Directory tree structure violation");
cur_record = (IsoDirHdr *)(temp + sec_offset[level]);
if (sec_offset[level] == 0) {
read_iso_sector(sec_loc[level], temp,
"Failed to read ISO directory");
if (dir_rem[level] == 0) {
/* Skip self and parent records */
dir_rem[level] = iso_733_to_u32(cur_record->data_len) -
cur_record->dr_len;
sec_offset[level] += cur_record->dr_len;
cur_record = (IsoDirHdr *)(temp + sec_offset[level]);
dir_rem[level] -= cur_record->dr_len;
sec_offset[level] += cur_record->dr_len;
continue;
}
}
if (!cur_record->dr_len || sec_offset[level] == ISO_SECTOR_SIZE) {
/* Zero-padding and/or the end of current sector */
dir_rem[level] -= ISO_SECTOR_SIZE - sec_offset[level];
sec_offset[level] = 0;
sec_loc[level]++;
} else {
/* The directory record is valid */
if (load_rba == iso_733_to_u32(cur_record->ext_loc)) {
return iso_733_to_u32(cur_record->data_len);
}
dir_rem[level] -= cur_record->dr_len;
sec_offset[level] += cur_record->dr_len;
if (cur_record->file_flags & 0x2) {
/* Subdirectory */
if (level == ISO9660_MAX_DIR_DEPTH - 1) {
sclp_print("ISO-9660 directory depth limit exceeded\n");
} else {
level++;
sec_loc[level] = iso_733_to_u32(cur_record->ext_loc);
sec_offset[level] = 0;
dir_rem[level] = 0;
continue;
}
}
}
if (dir_rem[level] == 0) {
/* Nothing remaining */
level--;
read_iso_sector(sec_loc[level], temp,
"Failed to read ISO directory");
}
}
return 0;
}
static void load_iso_bc_entry(IsoBcSection *load)
{
IsoBcSection s = *load;
/*
* According to spec, extent for each file
* is padded and ISO_SECTOR_SIZE bytes aligned
*/
uint32_t blks_to_load = bswap16(s.sector_count) >> ET_SECTOR_SHIFT;
uint32_t real_size = iso_get_file_size(bswap32(s.load_rba));
if (real_size) {
/* Round up blocks to load */
blks_to_load = (real_size + ISO_SECTOR_SIZE - 1) / ISO_SECTOR_SIZE;
sclp_print("ISO boot image size verified\n");
} else {
sclp_print("ISO boot image size could not be verified\n");
}
read_iso_boot_image(bswap32(s.load_rba),
(void *)((uint64_t)bswap16(s.load_segment)),
blks_to_load);
jump_to_low_kernel();
}
static uint32_t find_iso_bc(void)
{
IsoVolDesc *vd = (IsoVolDesc *)sec;
uint32_t block_num = ISO_PRIMARY_VD_SECTOR;
if (virtio_read_many(block_num++, sec, 1)) {
/* If primary vd cannot be read, there is no boot catalog */
return 0;
}
while (is_iso_vd_valid(vd) && vd->type != VOL_DESC_TERMINATOR) {
if (vd->type == VOL_DESC_TYPE_BOOT) {
IsoVdElTorito *et = &vd->vd.boot;
if (!memcmp(&et->el_torito[0], el_torito_magic, 32)) {
return bswap32(et->bc_offset);
}
}
read_iso_sector(block_num++, sec,
"Failed to read ISO volume descriptor");
}
return 0;
}
static IsoBcSection *find_iso_bc_entry(void)
{
IsoBcEntry *e = (IsoBcEntry *)sec;
uint32_t offset = find_iso_bc();
int i;
unsigned int loadparm = get_loadparm_index();
if (!offset) {
return NULL;
}
read_iso_sector(offset, sec, "Failed to read El Torito boot catalog");
if (!is_iso_bc_valid(e)) {
/* The validation entry is mandatory */
panic("No valid boot catalog found!\n");
return NULL;
}
/*
* Each entry has 32 bytes size, so one sector cannot contain > 64 entries.
* We consider only boot catalogs with no more than 64 entries.
*/
for (i = 1; i < ISO_BC_ENTRY_PER_SECTOR; i++) {
if (e[i].id == ISO_BC_BOOTABLE_SECTION) {
if (is_iso_bc_entry_compatible(&e[i].body.sect)) {
if (loadparm <= 1) {
/* found, default, or unspecified */
return &e[i].body.sect;
}
loadparm--;
}
}
}
panic("No suitable boot entry found on ISO-9660 media!\n");
return NULL;
}
static void ipl_iso_el_torito(void)
{
IsoBcSection *s = find_iso_bc_entry();
if (s) {
load_iso_bc_entry(s);
/* no return */
}
}
/***********************************************************************
* Bus specific IPL sequences
*/
static void zipl_load_vblk(void)
{
if (virtio_guessed_disk_nature()) {
virtio_assume_iso9660();
}
ipl_iso_el_torito();
if (virtio_guessed_disk_nature()) {
sclp_print("Using guessed DASD geometry.\n");
virtio_assume_eckd();
}
ipl_eckd();
}
static void zipl_load_vscsi(void)
{
if (virtio_get_block_size() == VIRTIO_ISO_BLOCK_SIZE) {
/* Is it an ISO image in non-CD drive? */
ipl_iso_el_torito();
}
sclp_print("Using guessed DASD geometry.\n");
virtio_assume_eckd();
ipl_eckd();
}
/***********************************************************************
* IPL starts here
*/
void zipl_load(void)
{
VDev *vdev = virtio_get_device();
if (vdev->is_cdrom) {
ipl_iso_el_torito();
panic("\n! Cannot IPL this ISO image !\n");
}
if (virtio_get_device_type() == VIRTIO_ID_NET) {
jump_to_IPL_code(vdev->netboot_start_addr);
}
ipl_scsi();
switch (virtio_get_device_type()) {
case VIRTIO_ID_BLOCK:
zipl_load_vblk();
break;
case VIRTIO_ID_SCSI:
zipl_load_vscsi();
break;
default:
panic("\n! Unknown IPL device type !\n");
}
panic("\n* this can never happen *\n");
}