freebsd-skq/stand/libsa/gpt.c
imp 614ead52a0 Remove the 'mini libstand in libstand' that util.[ch] provided. These
weren't needed, and their existance interfered with things in subtle
ways. One of these subtle ways was that malloc could be different
based on what files were included when (even within the same .c file,
it turns out). Move to a single malloc implementation as well by
adding the calls to setheap() to gptboot.c and zfsboot.c. Once upon a
time, these boot loaders strove to not use libstand. However, with the
proliferation of features, that striving is too hard for too little
gain and lead to stupid mistakes.

This fixes the GELI-enabled (but not even using) boot environment. The
geli routines were calling libstand malloc but zfsboot.c and gptboot.c
were using the mini libstand malloc, so this failed when we tried to
probe for GELI partitions. Subtle changes in build order when moving
to self-contained stand build in r326593 toggled what it used from one
type to another due to odd nesting of the zfs implementation code that
differed subtly between zfsloader and zfsboot.

Sponsored by: Netflix
2017-12-15 23:16:53 +00:00

380 lines
11 KiB
C

/*-
* Copyright (c) 2010 Pawel Jakub Dawidek <pjd@FreeBSD.org>
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHORS AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHORS OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include <sys/param.h>
#include <sys/gpt.h>
#ifndef LITTLE_ENDIAN
#error gpt.c works only for little endian architectures
#endif
#include "stand.h"
#include "crc32.h"
#include "drv.h"
#include "gpt.h"
static struct gpt_hdr hdr_primary, hdr_backup, *gpthdr;
static uint64_t hdr_primary_lba, hdr_backup_lba;
static struct gpt_ent table_primary[MAXTBLENTS], table_backup[MAXTBLENTS];
static struct gpt_ent *gpttable;
static int curent, bootonce;
/*
* Buffer below 64kB passed on gptread(), which can hold at least
* one sector of data (512 bytes).
*/
static char *secbuf;
static void
gptupdate(const char *which, struct dsk *dskp, struct gpt_hdr *hdr,
struct gpt_ent *table)
{
int entries_per_sec, firstent;
daddr_t slba;
/*
* We need to update the following for both primary and backup GPT:
* 1. Sector on disk that contains current partition.
* 2. Partition table checksum.
* 3. Header checksum.
* 4. Header on disk.
*/
entries_per_sec = DEV_BSIZE / hdr->hdr_entsz;
slba = curent / entries_per_sec;
firstent = slba * entries_per_sec;
bcopy(&table[firstent], secbuf, DEV_BSIZE);
slba += hdr->hdr_lba_table;
if (drvwrite(dskp, secbuf, slba, 1)) {
printf("%s: unable to update %s GPT partition table\n",
BOOTPROG, which);
return;
}
hdr->hdr_crc_table = crc32(table, hdr->hdr_entries * hdr->hdr_entsz);
hdr->hdr_crc_self = 0;
hdr->hdr_crc_self = crc32(hdr, hdr->hdr_size);
bzero(secbuf, DEV_BSIZE);
bcopy(hdr, secbuf, hdr->hdr_size);
if (drvwrite(dskp, secbuf, hdr->hdr_lba_self, 1)) {
printf("%s: unable to update %s GPT header\n", BOOTPROG, which);
return;
}
}
int
gptfind(const uuid_t *uuid, struct dsk *dskp, int part)
{
struct gpt_ent *ent;
int firsttry;
if (part >= 0) {
if (part == 0 || part > gpthdr->hdr_entries) {
printf("%s: invalid partition index\n", BOOTPROG);
return (-1);
}
ent = &gpttable[part - 1];
if (bcmp(&ent->ent_type, uuid, sizeof(uuid_t)) != 0) {
printf("%s: specified partition is not UFS\n",
BOOTPROG);
return (-1);
}
curent = part - 1;
goto found;
}
firsttry = (curent == -1);
curent++;
if (curent >= gpthdr->hdr_entries) {
curent = gpthdr->hdr_entries;
return (-1);
}
if (bootonce) {
/*
* First look for partition with both GPT_ENT_ATTR_BOOTME and
* GPT_ENT_ATTR_BOOTONCE flags.
*/
for (; curent < gpthdr->hdr_entries; curent++) {
ent = &gpttable[curent];
if (bcmp(&ent->ent_type, uuid, sizeof(uuid_t)) != 0)
continue;
if (!(ent->ent_attr & GPT_ENT_ATTR_BOOTME))
continue;
if (!(ent->ent_attr & GPT_ENT_ATTR_BOOTONCE))
continue;
/* Ok, found one. */
goto found;
}
bootonce = 0;
curent = 0;
}
for (; curent < gpthdr->hdr_entries; curent++) {
ent = &gpttable[curent];
if (bcmp(&ent->ent_type, uuid, sizeof(uuid_t)) != 0)
continue;
if (!(ent->ent_attr & GPT_ENT_ATTR_BOOTME))
continue;
if (ent->ent_attr & GPT_ENT_ATTR_BOOTONCE)
continue;
/* Ok, found one. */
goto found;
}
if (firsttry) {
/*
* No partition with BOOTME flag was found, try to boot from
* first UFS partition.
*/
for (curent = 0; curent < gpthdr->hdr_entries; curent++) {
ent = &gpttable[curent];
if (bcmp(&ent->ent_type, uuid, sizeof(uuid_t)) != 0)
continue;
/* Ok, found one. */
goto found;
}
}
return (-1);
found:
dskp->part = curent + 1;
ent = &gpttable[curent];
dskp->start = ent->ent_lba_start;
if (ent->ent_attr & GPT_ENT_ATTR_BOOTONCE) {
/*
* Clear BOOTME, but leave BOOTONCE set before trying to
* boot from this partition.
*/
if (hdr_primary_lba > 0) {
table_primary[curent].ent_attr &= ~GPT_ENT_ATTR_BOOTME;
gptupdate("primary", dskp, &hdr_primary, table_primary);
}
if (hdr_backup_lba > 0) {
table_backup[curent].ent_attr &= ~GPT_ENT_ATTR_BOOTME;
gptupdate("backup", dskp, &hdr_backup, table_backup);
}
}
return (0);
}
static int
gptread_hdr(const char *which, struct dsk *dskp, struct gpt_hdr *hdr,
uint64_t hdrlba)
{
uint32_t crc;
if (drvread(dskp, secbuf, hdrlba, 1)) {
printf("%s: unable to read %s GPT header\n", BOOTPROG, which);
return (-1);
}
bcopy(secbuf, hdr, sizeof(*hdr));
if (bcmp(hdr->hdr_sig, GPT_HDR_SIG, sizeof(hdr->hdr_sig)) != 0 ||
hdr->hdr_lba_self != hdrlba || hdr->hdr_revision < 0x00010000 ||
hdr->hdr_entsz < sizeof(struct gpt_ent) ||
hdr->hdr_entries > MAXTBLENTS || DEV_BSIZE % hdr->hdr_entsz != 0) {
printf("%s: invalid %s GPT header\n", BOOTPROG, which);
return (-1);
}
crc = hdr->hdr_crc_self;
hdr->hdr_crc_self = 0;
if (crc32(hdr, hdr->hdr_size) != crc) {
printf("%s: %s GPT header checksum mismatch\n", BOOTPROG,
which);
return (-1);
}
hdr->hdr_crc_self = crc;
return (0);
}
void
gptbootfailed(struct dsk *dskp)
{
if (!(gpttable[curent].ent_attr & GPT_ENT_ATTR_BOOTONCE))
return;
if (hdr_primary_lba > 0) {
table_primary[curent].ent_attr &= ~GPT_ENT_ATTR_BOOTONCE;
table_primary[curent].ent_attr |= GPT_ENT_ATTR_BOOTFAILED;
gptupdate("primary", dskp, &hdr_primary, table_primary);
}
if (hdr_backup_lba > 0) {
table_backup[curent].ent_attr &= ~GPT_ENT_ATTR_BOOTONCE;
table_backup[curent].ent_attr |= GPT_ENT_ATTR_BOOTFAILED;
gptupdate("backup", dskp, &hdr_backup, table_backup);
}
}
static void
gptbootconv(const char *which, struct dsk *dskp, struct gpt_hdr *hdr,
struct gpt_ent *table)
{
struct gpt_ent *ent;
daddr_t slba;
int table_updated, sector_updated;
int entries_per_sec, nent, part;
table_updated = 0;
entries_per_sec = DEV_BSIZE / hdr->hdr_entsz;
for (nent = 0, slba = hdr->hdr_lba_table;
slba < hdr->hdr_lba_table + hdr->hdr_entries / entries_per_sec;
slba++, nent += entries_per_sec) {
sector_updated = 0;
for (part = 0; part < entries_per_sec; part++) {
ent = &table[nent + part];
if ((ent->ent_attr & (GPT_ENT_ATTR_BOOTME |
GPT_ENT_ATTR_BOOTONCE |
GPT_ENT_ATTR_BOOTFAILED)) !=
GPT_ENT_ATTR_BOOTONCE) {
continue;
}
ent->ent_attr &= ~GPT_ENT_ATTR_BOOTONCE;
ent->ent_attr |= GPT_ENT_ATTR_BOOTFAILED;
table_updated = 1;
sector_updated = 1;
}
if (!sector_updated)
continue;
bcopy(&table[nent], secbuf, DEV_BSIZE);
if (drvwrite(dskp, secbuf, slba, 1)) {
printf("%s: unable to update %s GPT partition table\n",
BOOTPROG, which);
}
}
if (!table_updated)
return;
hdr->hdr_crc_table = crc32(table, hdr->hdr_entries * hdr->hdr_entsz);
hdr->hdr_crc_self = 0;
hdr->hdr_crc_self = crc32(hdr, hdr->hdr_size);
bzero(secbuf, DEV_BSIZE);
bcopy(hdr, secbuf, hdr->hdr_size);
if (drvwrite(dskp, secbuf, hdr->hdr_lba_self, 1))
printf("%s: unable to update %s GPT header\n", BOOTPROG, which);
}
static int
gptread_table(const char *which, const uuid_t *uuid, struct dsk *dskp,
struct gpt_hdr *hdr, struct gpt_ent *table)
{
struct gpt_ent *ent;
int entries_per_sec;
int part, nent;
daddr_t slba;
if (hdr->hdr_entries == 0)
return (0);
entries_per_sec = DEV_BSIZE / hdr->hdr_entsz;
slba = hdr->hdr_lba_table;
nent = 0;
for (;;) {
if (drvread(dskp, secbuf, slba, 1)) {
printf("%s: unable to read %s GPT partition table\n",
BOOTPROG, which);
return (-1);
}
ent = (struct gpt_ent *)secbuf;
for (part = 0; part < entries_per_sec; part++, ent++) {
bcopy(ent, &table[nent], sizeof(table[nent]));
if (++nent >= hdr->hdr_entries)
break;
}
if (nent >= hdr->hdr_entries)
break;
slba++;
}
if (crc32(table, nent * hdr->hdr_entsz) != hdr->hdr_crc_table) {
printf("%s: %s GPT table checksum mismatch\n", BOOTPROG, which);
return (-1);
}
return (0);
}
int
gptread(const uuid_t *uuid, struct dsk *dskp, char *buf)
{
uint64_t altlba;
/*
* Read and verify both GPT headers: primary and backup.
*/
secbuf = buf;
hdr_primary_lba = hdr_backup_lba = 0;
curent = -1;
bootonce = 1;
dskp->start = 0;
if (gptread_hdr("primary", dskp, &hdr_primary, 1) == 0 &&
gptread_table("primary", uuid, dskp, &hdr_primary,
table_primary) == 0) {
hdr_primary_lba = hdr_primary.hdr_lba_self;
gpthdr = &hdr_primary;
gpttable = table_primary;
}
if (hdr_primary_lba > 0) {
/*
* If primary header is valid, we can get backup
* header location from there.
*/
altlba = hdr_primary.hdr_lba_alt;
} else {
altlba = drvsize(dskp);
if (altlba > 0)
altlba--;
}
if (altlba == 0)
printf("%s: unable to locate backup GPT header\n", BOOTPROG);
else if (gptread_hdr("backup", dskp, &hdr_backup, altlba) == 0 &&
gptread_table("backup", uuid, dskp, &hdr_backup,
table_backup) == 0) {
hdr_backup_lba = hdr_backup.hdr_lba_self;
if (hdr_primary_lba == 0) {
gpthdr = &hdr_backup;
gpttable = table_backup;
printf("%s: using backup GPT\n", BOOTPROG);
}
}
/*
* Convert all BOOTONCE without BOOTME flags into BOOTFAILED.
* BOOTONCE without BOOTME means that we tried to boot from it,
* but failed after leaving gptboot and machine was rebooted.
* We don't want to leave partitions marked as BOOTONCE only,
* because when we boot successfully start-up scripts should
* find at most one partition with only BOOTONCE flag and this
* will mean that we booted from that partition.
*/
if (hdr_primary_lba != 0)
gptbootconv("primary", dskp, &hdr_primary, table_primary);
if (hdr_backup_lba != 0)
gptbootconv("backup", dskp, &hdr_backup, table_backup);
if (hdr_primary_lba == 0 && hdr_backup_lba == 0)
return (-1);
return (0);
}