Files
lbmk/util/nvmutil/nvmutil.c
T
Leah Rowe a7cc8143a7 util/nvmutil: cmd copy/swap: use word/setWord
this means that we make use of the boundary checks. it's just
a safer way of handling these functions.

Signed-off-by: Leah Rowe <leah@libreboot.org>
2026-03-03 01:18:23 +00:00

463 lines
9.7 KiB
C

/* SPDX-License-Identifier: MIT */
/* Copyright (c) 2022-2026 Leah Rowe <leah@libreboot.org> */
/* Copyright (c) 2023 Riku Viitanen <riku.viitanen@protonmail.com> */
#include <sys/stat.h>
#include <dirent.h>
#include <err.h>
#include <errno.h>
#include <fcntl.h>
#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
void cmd_setchecksum(void), cmd_brick(void), swap(int partnum), writeGbe(void),
cmd_dump(void), cmd_setmac(void), readGbe(void),
checkdir(const char *path), macf(int partnum), hexdump(int partnum),
parseMacString(const char *strMac, uint16_t *mac), cmd_swap(void),
openFiles(void), cmd_copy(void), writeGbe_part(int),
readGbe_part(int), usage(char*), set_io_flags(int, char **),
set_cmd(int, char **), setWord(int, int, uint16_t), check_bounds(int, int),
xopen (int *, const char *, int p, struct stat *);
int goodChecksum(int partnum);
uint8_t hextonum(char chs), rhex(void);
uint16_t word(int, int);
#define COMMAND argv[2]
#define MAC_ADDRESS argv[3]
#define PARTN argv[3]
#define NVM_CHECKSUM 0xBABA
#define NVM_CHECKSUM_WORD 0x3F
#define NVM_SIZE 128
#define SIZE_4KB 0x1000
#define SIZE_8KB 0x2000
#define SIZE_16KB 0x4000
#define SIZE_128KB 0x20000
uint8_t buf[SIZE_8KB];
uint16_t mac[3] = {0, 0, 0};
size_t partsize;
uint8_t *gbe[2];
int flags, rfd, fd, part, e = 1;
const char *strMac = NULL, *strRMac = "xx:xx:xx:xx:xx:xx", *fname = NULL;
typedef struct op {
char *str;
void (*cmd)(void);
int args;
} op_t;
op_t op[] = {
{ .str = "dump", .cmd = cmd_dump, .args = 3 },
{ .str = "setmac", .cmd = cmd_setmac, .args = 3 },
{ .str = "swap", .cmd = cmd_swap, .args = 3 },
{ .str = "copy", .cmd = cmd_copy, .args = 4 },
{ .str = "brick", .cmd = cmd_brick, .args = 4 },
{ .str = "setchecksum", .cmd = cmd_setchecksum, .args = 4 },
};
void (*cmd)(void) = NULL;
#define set_err(x) errno = errno ? errno : x
#define err_if(x) if (x) err(set_err(ECANCELED), "%s", fname)
int
main(int argc, char *argv[])
{
#ifdef __OpenBSD__
err_if(pledge("stdio rpath wpath unveil", NULL) == -1);
err_if(unveil("/dev/urandom", "r") == -1);
#endif
set_cmd(argc, argv);
fname = argv[1];
set_io_flags(argc, argv);
#ifdef __OpenBSD__
if (flags == O_RDONLY) {
err_if(unveil(fname, "r") == -1);
err_if(unveil(NULL, NULL) == -1);
err_if(pledge("stdio rpath", NULL) == -1);
} else {
err_if(unveil(fname, "rw") == -1);
err_if(unveil(NULL, NULL) == -1);
err_if(pledge("stdio rpath wpath", NULL) == -1);
}
#endif
openFiles();
#ifdef __OpenBSD__
err_if(pledge("stdio", NULL) == -1);
#endif
readGbe();
(*cmd)();
writeGbe();
err_if((errno != 0) && (cmd != cmd_dump));
return errno;
}
void
set_cmd(int argc, char *argv[])
{
if (argc < 2) {
usage(argv[0]);
} else if (argc > 2) {
for (int i = 0; (i < 6) && (cmd == NULL); i++) {
if (strcmp(COMMAND, op[i].str) != 0)
continue;
if (argc >= op[i].args) {
cmd = op[i].cmd;
break;
}
err(set_err(EINVAL), "Too few args on command '%s'",
op[i].str);
}
} else { /* argc == 2 */
cmd = cmd_setmac;
}
if ((cmd == NULL) && (argc > 2)) { /* nvm gbe [MAC] */
strMac = COMMAND;
cmd = cmd_setmac;
} else if (cmd == cmd_setmac) { /* nvm gbe setmac [MAC] */
strMac = strRMac; /* random MAC */
if (argc > 3)
strMac = MAC_ADDRESS;
} else if ((cmd != NULL) && (argc > 3)) { /* user-supplied partnum */
err_if((errno = (!((part = PARTN[0] - '0') == 0 || part == 1))
|| PARTN[1] ? EINVAL : errno)); /* only allow '0' or '1' */
}
err_if((errno = (cmd == NULL) ? EINVAL : errno));
}
void
set_io_flags(int argc, char *argv[])
{
flags = O_RDWR;
if (argc > 2)
if (strcmp(COMMAND, "dump") == 0)
flags = O_RDONLY;
}
void
checkdir(const char *path)
{
if (opendir(path) != NULL)
err(set_err(EISDIR), "%s", path);
if (errno == ENOTDIR)
errno = 0;
err_if(errno);
}
void
openFiles(void)
{
struct stat st;
checkdir("/dev/urandom");
checkdir(fname);
xopen(&rfd, "/dev/urandom", O_RDONLY, &st);
xopen(&fd, fname, flags, &st);
switch(st.st_size) {
case SIZE_8KB:
case SIZE_16KB:
case SIZE_128KB:
partsize = st.st_size >> 1;
break;
default:
err(set_err(ECANCELED), "Invalid file size (not 8/16/128KiB)");
break;
}
}
void
xopen(int *f, const char *l, int p, struct stat *st)
{
if ((*f = open(l, p)) == -1) \
err(set_err(ECANCELED), "%s", l); \
if (fstat(*f, st) == -1) \
err(set_err(ECANCELED), "%s", l);
}
void
readGbe(void)
{
gbe[0] = buf;
gbe[1] = buf + SIZE_4KB;
for (int p = 0; p < 2; p++)
readGbe_part(p);
}
void
readGbe_part(int p)
{
if (pread(fd, (uint8_t *) gbe[p], SIZE_4KB, p * partsize) != SIZE_4KB)
err(set_err(ECANCELED),
"Can't read %d b from '%s' p%d", SIZE_4KB, fname, p);
swap(p); /* handle big-endian host CPU */
}
void
cmd_setmac(void)
{
int mac_updated = 0;
parseMacString(strMac, mac);
printf("MAC address to be written: %s\n", strMac);
for (int partnum = 0; partnum < 2; partnum++) {
if (!goodChecksum(part = partnum))
continue;
for (int w = 0; w < 3; w++)
setWord(w, partnum, mac[w]);
printf("Wrote MAC address to part %d: ", partnum);
macf(partnum);
cmd_setchecksum();
mac_updated = 1;
}
if (mac_updated)
errno = 0;
}
void
parseMacString(const char *strMac, uint16_t *mac)
{
uint64_t total = 0;
if (strnlen(strMac, 20) != 17)
err(set_err(EINVAL), "Invalid MAC address string length");
for (uint8_t h, i = 0; i < 16; i += 3) {
if (i != 15)
if (strMac[i + 2] != ':')
err(set_err(EINVAL),
"Invalid MAC address separator '%c'",
strMac[i + 2]);
int byte = i / 3;
for (int nib = 0; nib < 2; nib++, total += h) {
if ((h = hextonum(strMac[i + nib])) > 15)
err(set_err(EINVAL), "Invalid character '%c'",
strMac[i + nib]);
/* If random, ensure that local/unicast bits are set */
if ((byte == 0) && (nib == 1))
if ((strMac[i + nib] == '?') ||
(strMac[i + nib] == 'x') ||
(strMac[i + nib] == 'X')) /* random */
h = (h & 0xE) | 2; /* local, unicast */
mac[byte >> 1] |= ((uint16_t ) h)
<< ((8 * (byte % 2)) + (4 * (nib ^ 1)));
}
}
if (total == 0)
err(set_err(EINVAL), "Invalid MAC (all-zero MAC address)");
if (mac[0] & 1)
err(set_err(EINVAL), "Invalid MAC (multicast bit set)");
}
uint8_t
hextonum(char ch)
{
if ((ch >= '0') && (ch <= '9'))
return ch - '0';
else if ((ch >= 'A') && (ch <= 'F'))
return ch - 'A' + 10;
else if ((ch >= 'a') && (ch <= 'f'))
return ch - 'a' + 10;
else if ((ch == '?') || (ch == 'x') || (ch == 'X'))
return rhex(); /* random hex value */
return 16; /* error: invalid character */
}
uint8_t
rhex(void)
{
static uint8_t n = 0, rnum[16];
if (!n)
err_if(pread(rfd, (uint8_t *) &rnum, (n = 15) + 1, 0) == -1);
return rnum[n--] & 0xf;
}
void
cmd_dump(void)
{
for (int partnum = 0, numInvalid = 0; partnum < 2; partnum++) {
if (!goodChecksum(partnum))
++numInvalid;
printf("MAC (part %d): ", partnum);
macf(partnum);
hexdump(partnum);
if ((numInvalid < 2) && (partnum))
errno = 0;
}
}
void
macf(int partnum)
{
for (int c = 0; c < 3; c++) {
uint16_t val16 = word(c, partnum);
printf("%02x:%02x", val16 & 0xff, val16 >> 8);
if (c == 2)
printf("\n");
else
printf(":");
}
}
void
hexdump(int partnum)
{
for (int row = 0; row < 8; row++) {
printf("%08x ", row << 4);
for (int c = 0; c < 8; c++) {
uint16_t val16 = word((row << 3) + c, partnum);
if (c == 4)
printf(" ");
printf(" %02x %02x", val16 & 0xff, val16 >> 8);
}
printf("\n");
}
}
void
cmd_setchecksum(void)
{
uint16_t val16 = 0;
for (int c = 0; c < NVM_CHECKSUM_WORD; c++)
val16 += word(c, part);
setWord(NVM_CHECKSUM_WORD, part, NVM_CHECKSUM - val16);
}
void
cmd_brick(void)
{
if (goodChecksum(part))
setWord(NVM_CHECKSUM_WORD, part,
((word(NVM_CHECKSUM_WORD, part)) ^ 0xFF));
}
void
cmd_copy(void)
{
err_if(!goodChecksum(part));
for (int c = 0; c < (SIZE_4KB >> 1); c++)
setWord(c, part ^ 1, word(c, part));
}
void
cmd_swap(void) {
err_if(!(goodChecksum(0) || goodChecksum(1)));
errno = 0;
for (int c = 0; c < (SIZE_4KB >> 1); c++) {
uint16_t chg = word(c, 0);
setWord(c, 0, word(c, 1));
setWord(c, 1, chg);
}
}
int
goodChecksum(int partnum)
{
uint16_t total = 0;
for(int w = 0; w <= NVM_CHECKSUM_WORD; w++)
total += word(w, partnum);
if (total == NVM_CHECKSUM)
return 1;
fprintf(stderr, "WARNING: BAD checksum in part %d\n", partnum);
set_err(ECANCELED);
return 0;
}
uint16_t
word(int pos16, int p)
{
check_bounds(pos16, p);
return ((uint16_t *) gbe[p])[pos16];
}
void
setWord(int pos16, int p, uint16_t val16)
{
check_bounds(pos16, p);
((uint16_t *) gbe[p])[pos16] = val16;
}
void
check_bounds(int c, int p)
{
if ((p != 0) && (p != 1))
err(set_err(EINVAL), "check_bounds: invalid partnum %d", p);
if ((c < 0) || (c >= (SIZE_4KB >> 1)))
err(set_err(EINVAL), "check_bounds: out of bounds %d", c);
}
void
writeGbe(void)
{
if (flags != O_RDONLY)
for (int p = 0; p < 2; p++)
writeGbe_part(p);
err_if(close(fd) == -1);
}
void
writeGbe_part(int p)
{
swap(p); /* swap bytes on big-endian host CPUs */
if(pwrite(fd, (uint8_t *) gbe[p], SIZE_4KB, p * partsize) != SIZE_4KB)
err(set_err(ECANCELED),
"Can't write %d b to '%s' p%d", SIZE_4KB, fname, p);
}
void
swap(int partnum)
{
uint8_t *n = gbe[partnum];
for (size_t w = NVM_SIZE * ((uint8_t *) &e)[0], x = 1;
w < NVM_SIZE; w += 2, x += 2) {
uint8_t chg = n[w];
n[w] ^= n[x];
n[x] ^= chg;
}
}
void
usage(char *util)
{
#ifdef __OpenBSD__
err_if(pledge("stdio", NULL) == -1);
#endif
fprintf(stderr,
"Modify Intel GbE NVM images e.g. set MAC\n"
"USAGE:\n"
"%s FILE dump\n"
" %s FILE\n # same as setmac without arg\n"
" %s FILE setmac [MAC]\n"
" %s FILE swap\n"
" %s FILE copy 0|1\n"
" %s FILE brick 0|1\n"
" %s FILE setchecksum 0|1\n",
util, util, util, util, util, util, util);
err(set_err(ECANCELED), "Too few arguments");
}