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cos / mirrors / cros / chromiumos / platform / vboot_reference / refs/heads/stabilize-11316.148.B / . / futility / updater.c
blob: ef66e5915627199419b784a7cfa0ce31752d05b7 [file] [log] [blame]
/*
* Copyright 2018 The Chromium OS Authors. All rights reserved.
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*
* A reference implementation for AP (and supporting images) firmware updater.
*/
#include <assert.h>
#include <ctype.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include "2rsa.h"
#include "crossystem.h"
#include "futility.h"
#include "host_misc.h"
#include "updater.h"
#include "utility.h"
#include "util_misc.h"
#include "vb2_common.h"
#include "vb2_struct.h"
#define COMMAND_BUFFER_SIZE 256
#define RETURN_ON_FAILURE(x) do {int r = (x); if (r) return r;} while (0);
#define FLASHROM_OUTPUT_WP_PATTERN "write protect is "
/* System environment values. */
static const char * const FWACT_A = "A",
* const FWACT_B = "B",
* const STR_REV = "rev",
* const FLASHROM_OUTPUT_WP_ENABLED =
FLASHROM_OUTPUT_WP_PATTERN "enabled",
* const FLASHROM_OUTPUT_WP_DISABLED =
FLASHROM_OUTPUT_WP_PATTERN "disabled";
/* flashrom programmers. */
static const char * const PROG_HOST = "host",
* const PROG_EC = "ec",
* const PROG_PD = "ec:dev=1";
static const char ROOTKEY_HASH_DEV[] =
"b11d74edd286c144e1135b49e7f0bc20cf041f10";
enum wp_state {
WP_DISABLED,
WP_ENABLED,
};
enum target_type {
TARGET_SELF,
TARGET_UPDATE,
};
enum active_slot {
SLOT_UNKNOWN = -1,
SLOT_A = 0,
SLOT_B,
};
enum flashrom_ops {
FLASHROM_READ,
FLASHROM_WRITE,
FLASHROM_WP_STATUS,
};
enum rootkey_compat_result {
ROOTKEY_COMPAT_OK,
ROOTKEY_COMPAT_ERROR,
ROOTKEY_COMPAT_REKEY,
ROOTKEY_COMPAT_REKEY_TO_DEV,
};
/*
* Helper function to create a new temporary file.
* All files created will be removed by updater_remove_all_temp_files().
* Returns the path of new file, or NULL on failure.
*/
const char *updater_create_temp_file(struct updater_config *cfg)
{
struct tempfile *new_temp;
char new_path[] = P_tmpdir "/fwupdater.XXXXXX";
int fd;
fd = mkstemp(new_path);
if (fd < 0) {
ERROR("Failed to create new temp file in %s", new_path);
return NULL;
}
close(fd);
new_temp = (struct tempfile *)malloc(sizeof(*new_temp));
if (new_temp)
new_temp->filepath = strdup(new_path);
if (!new_temp || !new_temp->filepath) {
remove(new_path);
free(new_temp);
ERROR("Failed to allocate buffer for new temp file.");
return NULL;
}
DEBUG("Created new temporary file: %s.", new_path);
new_temp->next = cfg->tempfiles;
cfg->tempfiles = new_temp;
return new_temp->filepath;
}
/*
* Helper function to remove all files created by create_temp_file().
* This is intended to be called only once at end of program execution.
*/
static void updater_remove_all_temp_files(struct updater_config *cfg)
{
struct tempfile *tempfiles = cfg->tempfiles;
while (tempfiles != NULL) {
struct tempfile *target = tempfiles;
DEBUG("Remove temporary file: %s.", target->filepath);
remove(target->filepath);
free(target->filepath);
tempfiles = target->next;
free(target);
}
cfg->tempfiles = NULL;
}
/*
* Strip a string (usually from shell execution output) by removing all the
* trailing characters in pattern. If pattern is NULL, match by space type
* characters (space, new line, tab, ... etc).
*/
static void strip(char *s, const char *pattern)
{
int len;
assert(s);
len = strlen(s);
while (len-- > 0) {
if (pattern) {
if (!strchr(pattern, s[len]))
break;
} else {
if (!isascii(s[len]) || !isspace(s[len]))
break;
}
s[len] = '\0';
}
}
/*
* Executes a command on current host and returns stripped command output.
* If the command has failed (exit code is not zero), returns an empty string.
* The caller is responsible for releasing the returned string.
*/
char *host_shell(const char *command)
{
/* Currently all commands we use do not have large output. */
char buf[COMMAND_BUFFER_SIZE];
int result;
FILE *fp = popen(command, "r");
DEBUG("%s", command);
buf[0] = '\0';
if (!fp) {
DEBUG("Execution error for %s.", command);
return strdup(buf);
}
if (fgets(buf, sizeof(buf), fp))
strip(buf, NULL);
result = pclose(fp);
if (!WIFEXITED(result) || WEXITSTATUS(result) != 0) {
DEBUG("Execution failure with exit code %d: %s",
WEXITSTATUS(result), command);
/*
* Discard all output if command failed, for example command
* syntax failure may lead to garbage in stdout.
*/
buf[0] = '\0';
}
return strdup(buf);
}
/* An helper function to return "mainfw_act" system property. */
static int host_get_mainfw_act()
{
char buf[VB_MAX_STRING_PROPERTY];
if (!VbGetSystemPropertyString("mainfw_act", buf, sizeof(buf)))
return SLOT_UNKNOWN;
if (strcmp(buf, FWACT_A) == 0)
return SLOT_A;
else if (strcmp(buf, FWACT_B) == 0)
return SLOT_B;
return SLOT_UNKNOWN;
}
/* A helper function to return the "tpm_fwver" system property. */
static int host_get_tpm_fwver()
{
return VbGetSystemPropertyInt("tpm_fwver");
}
/* A helper function to return the "hardware write protection" status. */
static int host_get_wp_hw()
{
/* wpsw refers to write protection 'switch', not 'software'. */
int v = VbGetSystemPropertyInt("wpsw_cur");
/* wpsw_cur may be not available, especially in recovery mode. */
if (v < 0)
v = VbGetSystemPropertyInt("wpsw_boot");
return v;
}
/* A helper function to return "fw_vboot2" system property. */
static int host_get_fw_vboot2()
{
return VbGetSystemPropertyInt("fw_vboot2");
}
/* A help function to get $(mosys platform version). */
static int host_get_platform_version()
{
char *result = host_shell("mosys platform version");
int rev = -1;
/* Result should be 'revN' */
if (strncmp(result, STR_REV, strlen(STR_REV)) == 0)
rev = strtol(result + strlen(STR_REV), NULL, 0);
DEBUG("Raw data = [%s], parsed version is %d", result, rev);
free(result);
return rev;
}
/*
* A helper function to invoke flashrom(8) command.
* Returns 0 if success, non-zero if error.
*/
static int host_flashrom(enum flashrom_ops op, const char *image_path,
const char *programmer, int verbose,
const char *section_name)
{
char *command, *result;
const char *op_cmd, *dash_i = "-i", *postfix = "", *ignore_lock = "";
int r;
switch (verbose) {
case 0:
postfix = " >/dev/null 2>&1";
break;
case 1:
break;
case 2:
postfix = "-V";
break;
case 3:
postfix = "-V -V";
break;
default:
postfix = "-V -V -V";
break;
}
if (!section_name || !*section_name) {
dash_i = "";
section_name = "";
}
switch (op) {
case FLASHROM_READ:
op_cmd = "-r";
assert(image_path);
break;
case FLASHROM_WRITE:
op_cmd = "-w";
assert(image_path);
break;
case FLASHROM_WP_STATUS:
op_cmd = "--wp-status";
assert(image_path == NULL);
image_path = "";
/* grep is needed because host_shell only returns 1 line. */
postfix = " 2>/dev/null | grep \"" \
FLASHROM_OUTPUT_WP_PATTERN "\"";
break;
default:
assert(0);
return -1;
}
/* TODO(hungte) In future we should link with flashrom directly. */
ASPRINTF(&command, "flashrom %s %s -p %s %s %s %s %s", op_cmd,
image_path, programmer, dash_i, section_name, ignore_lock,
postfix);
if (verbose)
INFO("Executing: %s", command);
if (op != FLASHROM_WP_STATUS) {
r = system(command);
free(command);
return r;
}
result = host_shell(command);
strip(result, NULL);
free(command);
DEBUG("wp-status: %s", result);
if (strstr(result, FLASHROM_OUTPUT_WP_ENABLED))
r = WP_ENABLED;
else if (strstr(result, FLASHROM_OUTPUT_WP_DISABLED))
r = WP_DISABLED;
else
r = -1;
free(result);
return r;
}
/* Helper function to return write protection status via given programmer. */
static int host_get_wp(const char *programmer)
{
return host_flashrom(FLASHROM_WP_STATUS, NULL, programmer, 0, NULL);
}
/* Helper function to return host software write protection status. */
static int host_get_wp_sw()
{
return host_get_wp(PROG_HOST);
}
/*
* Gets the system property by given type.
* If the property was not loaded yet, invoke the property getter function
* and cache the result.
* Returns the property value.
*/
int get_system_property(enum system_property_type property_type,
struct updater_config *cfg)
{
struct system_property *prop;
assert(property_type < SYS_PROP_MAX);
prop = &cfg->system_properties[property_type];
if (!prop->initialized) {
prop->initialized = 1;
prop->value = prop->getter();
}
return prop->value;
}
static void print_system_properties(struct updater_config *cfg)
{
int i;
/*
* There may be error messages when fetching properties from active
* system, so we want to peek at them first and then print out.
*/
DEBUG("Scanning system properties...");
for (i = 0; i < SYS_PROP_MAX; i++) {
get_system_property((enum system_property_type)i, cfg);
}
printf("System properties: [");
for (i = 0; i < SYS_PROP_MAX; i++) {
printf("%d,",
get_system_property((enum system_property_type)i, cfg));
}
printf("]\n");
}
/*
* Overrides the return value of a system property.
* After invoked, next call to get_system_property(type, cfg) will return
* the given value.
*/
static void override_system_property(enum system_property_type property_type,
struct updater_config *cfg,
int value)
{
struct system_property *prop;
assert(property_type < SYS_PROP_MAX);
prop = &cfg->system_properties[property_type];
prop->initialized = 1;
prop->value = value;
}
/*
* Overrides system properties from a given list.
* The list should be string of integers eliminated by comma and/or space.
* For example, "1 2 3" and "1,2,3" both overrides first 3 properties.
* To skip some properties you have to use comma, for example
* "1, , 3" will only override the first and 3rd properties.
* Invalid characters and fields will be ignored.
*
* The current implementation is only for unit testing.
* In future we may extend this with name=value so users can use it easily on
* actual systems.
*/
static void override_properties_from_list(const char *override_list,
struct updater_config *cfg)
{
const char *s = override_list;
char *e, c;
int i = 0, wait_comma = 0;
long int v;
DEBUG("Input is <%s>", override_list);
for (c = *s; c; c = *++s) {
if (c == ',') {
if (!wait_comma)
i++;
wait_comma = 0;
}
if (!isascii(c) || !(isdigit(c) || c == '-'))
continue;
if (i >= SYS_PROP_MAX) {
ERROR("Too many fields (max is %d): %s.",
SYS_PROP_MAX, override_list);
return;
}
v = strtol(s, &e, 0);
s = e - 1;
DEBUG("property[%d].value = %ld", i, v);
override_system_property((enum system_property_type)i, cfg, v);
wait_comma = 1;
i++;
}
}
/* Gets the value (setting) of specified quirks from updater configuration. */
int get_config_quirk(enum quirk_types quirk, const struct updater_config *cfg)
{
assert(quirk < QUIRK_MAX);
return cfg->quirks[quirk].value;
}
/* Prints the name and description from all supported quirks. */
void updater_list_config_quirks(const struct updater_config *cfg)
{
const struct quirk_entry *entry = cfg->quirks;
int i;
printf("Supported quirks:\n");
for (i = 0; i < QUIRK_MAX; i++, entry++) {
printf(" '%s': %s (default: %d)\n", entry->name,
entry->help ? entry->help : "(no description)",
get_config_quirk((enum quirk_types)i, cfg));
}
}
/*
* Applies a quirk if applicable (the value should be non-zero).
* Returns 0 on success, otherwise failure.
*/
static int try_apply_quirk(enum quirk_types quirk, struct updater_config *cfg)
{
const struct quirk_entry *entry = cfg->quirks + quirk;
assert(quirk < QUIRK_MAX);
if (!entry->value)
return 0;
if (!entry->apply) {
ERROR("<%s> not implemented.", entry->name);
return -1;
}
DEBUG("Applying quirk <%s>.", entry->name);
return entry->apply(cfg);
}
/*
* Initialize the updater_config quirks from a list of settings.
* Returns 0 on success, otherwise failure.
*/
static int setup_config_quirks(const char *quirks, struct updater_config *cfg)
{
/*
* The list should be in NAME[=VALUE],...
* Value defaults to 1 if not specified.
*/
int r = 0;
char *buf = strdup(quirks);
char *token;
token = strtok(buf, ", ");
for (; token; token = strtok(NULL, ", ")) {
const char *name = token;
char *equ = strchr(token, '=');
int i, value = 1;
struct quirk_entry *entry = cfg->quirks;
if (equ) {
*equ = '\0';
value = strtol(equ + 1, NULL, 0);
}
DEBUG("Looking for quirk <%s=%d>.", name, value);
for (i = 0; i < QUIRK_MAX; i++, entry++) {
if (strcmp(name, entry->name))
continue;
entry->value = value;
DEBUG("Set quirk %s to %d.", entry->name, value);
break;
}
if (i >= QUIRK_MAX) {
ERROR("Unknown quirk: %s", name);
r++;
}
}
free(buf);
return r;
}
/*
* Finds a firmware section by given name in the firmware image.
* If successful, return zero and *section argument contains the address and
* size of the section; otherwise failure.
*/
int find_firmware_section(struct firmware_section *section,
const struct firmware_image *image,
const char *section_name)
{
FmapAreaHeader *fah = NULL;
uint8_t *ptr;
section->data = NULL;
section->size = 0;
ptr = fmap_find_by_name(
image->data, image->size, image->fmap_header,
section_name, &fah);
if (!ptr)
return -1;
section->data = (uint8_t *)ptr;
section->size = fah->area_size;
return 0;
}
/*
* Returns true if the given FMAP section exists in the firmware image.
*/
static int firmware_section_exists(const struct firmware_image *image,
const char *section_name)
{
struct firmware_section section;
find_firmware_section(&section, image, section_name);
return section.data != NULL;
}
/*
* Checks if the section is filled with given character.
* If section size is 0, return 0. If section is not empty, return non-zero if
* the section is filled with same character c, otherwise 0.
*/
static int section_is_filled_with(const struct firmware_section *section,
uint8_t c)
{
uint32_t i;
if (!section->size)
return 0;
for (i = 0; i < section->size; i++)
if (section->data[i] != c)
return 0;
return 1;
}
/*
* Loads the firmware information from an FMAP section in loaded firmware image.
* The section should only contain ASCIIZ string as firmware version.
* If successful, the return value is zero and *version points to a newly
* allocated string as firmware version (caller must free it); otherwise
* failure.
*/
static int load_firmware_version(struct firmware_image *image,
const char *section_name,
char **version)
{
struct firmware_section fwid;
find_firmware_section(&fwid, image, section_name);
if (fwid.size) {
*version = strndup((const char*)fwid.data, fwid.size);
/*
* For 'system current' images, the version string may contain
* invalid characters that we do want to strip.
*/
strip(*version, "\xff");
return 0;
}
*version = strdup("");
return -1;
}
/*
* Loads a firmware image from file.
* If archive is provided and file_name is a relative path, read the file from
* archive.
* Returns 0 on success, otherwise failure.
*/
int load_firmware_image(struct firmware_image *image, const char *file_name,
struct archive *archive)
{
DEBUG("Load image file from %s...", file_name);
if (!archive_has_entry(archive, file_name)) {
ERROR("Does not exist: %s", file_name);
return -1;
}
if (archive_read_file(archive, file_name, &image->data, &image->size) !=
VB2_SUCCESS) {
ERROR("Failed to load %s", file_name);
return -1;
}
DEBUG("Image size: %d", image->size);
assert(image->data);
image->file_name = strdup(file_name);
image->fmap_header = fmap_find(image->data, image->size);
if (!image->fmap_header) {
ERROR("Invalid image file (missing FMAP): %s", file_name);
return -1;
}
if (!firmware_section_exists(image, FMAP_RO_FRID)) {
ERROR("Does not look like VBoot firmware image: %s", file_name);
return -1;
}
load_firmware_version(image, FMAP_RO_FRID, &image->ro_version);
if (firmware_section_exists(image, FMAP_RW_FWID_A)) {
char **a = &image->rw_version_a, **b = &image->rw_version_b;
load_firmware_version(image, FMAP_RW_FWID_A, a);
load_firmware_version(image, FMAP_RW_FWID_B, b);
} else if (firmware_section_exists(image, FMAP_RW_FWID)) {
char **a = &image->rw_version_a, **b = &image->rw_version_b;
load_firmware_version(image, FMAP_RW_FWID, a);
load_firmware_version(image, FMAP_RW_FWID, b);
} else {
ERROR("Unsupported VBoot firmware (no RW ID): %s", file_name);
}
return 0;
}
/*
* Loads the active system firmware image (usually from SPI flash chip).
* Returns 0 if success, non-zero if error.
*/
int load_system_firmware(struct updater_config *cfg,
struct firmware_image *image)
{
const char *tmp_file = updater_create_temp_file(cfg);
if (!tmp_file)
return -1;
RETURN_ON_FAILURE(host_flashrom(
FLASHROM_READ, tmp_file, image->programmer,
cfg->verbosity, NULL));
return load_firmware_image(image, tmp_file, NULL);
}
/*
* Frees the allocated resource from a firmware image object.
*/
void free_firmware_image(struct firmware_image *image)
{
/*
* The programmer is not allocated by load_firmware_image and must be
* preserved explicitly.
*/
const char *programmer = image->programmer;
free(image->data);
free(image->file_name);
free(image->ro_version);
free(image->rw_version_a);
free(image->rw_version_b);
memset(image, 0, sizeof(*image));
image->programmer = programmer;
}
/*
* Decides which target in RW firmware to manipulate.
* The `target` argument specifies if we want to know "the section to be
* update" (TARGET_UPDATE), or "the (active) section * to check" (TARGET_SELF).
* Returns the section name if success, otherwise NULL.
*/
static const char *decide_rw_target(struct updater_config *cfg,
enum target_type target,
int is_vboot2)
{
const char *a = FMAP_RW_SECTION_A, *b = FMAP_RW_SECTION_B;
int slot = get_system_property(SYS_PROP_MAINFW_ACT, cfg);
/* In vboot1, always update B and check content with A. */
if (!is_vboot2)
return target == TARGET_UPDATE ? b : a;
switch (slot) {
case SLOT_A:
return target == TARGET_UPDATE ? b : a;
case SLOT_B:
return target == TARGET_UPDATE ? a : b;
}
return NULL;
}
/*
* Sets any needed system properties to indicate system should try the new
* firmware on next boot.
* The `target` argument is an FMAP section name indicating which to try.
* Returns 0 if success, non-zero if error.
*/
static int set_try_cookies(struct updater_config *cfg, const char *target,
int is_vboot2)
{
int tries = 6;
const char *slot;
/* EC Software Sync needs few more reboots. */
if (cfg->ec_image.data)
tries += 2;
/* Find new slot according to target (section) name. */
if (strcmp(target, FMAP_RW_SECTION_A) == 0)
slot = FWACT_A;
else if (strcmp(target, FMAP_RW_SECTION_B) == 0)
slot = FWACT_B;
else {
ERROR("Unknown target: %s", target);
return -1;
}
if (cfg->emulation) {
INFO("(emulation) Setting try_next to %s, try_count to %d.",
slot, tries);
return 0;
}
if (is_vboot2 && VbSetSystemPropertyString("fw_try_next", slot)) {
ERROR("Failed to set fw_try_next to %s.", slot);
return -1;
}
if (VbSetSystemPropertyInt("fw_try_count", tries)) {
ERROR("Failed to set fw_try_count to %d.", tries);
return -1;
}
return 0;
}
/*
* Emulates writing to firmware.
* Returns 0 if success, non-zero if error.
*/
static int emulate_write_firmware(const char *filename,
const struct firmware_image *image,
const char *section_name)
{
struct firmware_image to_image = {0};
struct firmware_section from, to;
int errorcnt = 0;
from.data = image->data;
from.size = image->size;
if (load_firmware_image(&to_image, filename, NULL)) {
ERROR("Cannot load image from %s.", filename);
return -1;
}
if (section_name) {
find_firmware_section(&from, image, section_name);
if (!from.data) {
ERROR("No section %s in source image %s.",
section_name, image->file_name);
errorcnt++;
}
find_firmware_section(&to, &to_image, section_name);
if (!to.data) {
ERROR("No section %s in destination image %s.",
section_name, filename);
errorcnt++;
}
} else if (image->size != to_image.size) {
ERROR("Image size is different (%s:%d != %s:%d)",
image->file_name, image->size, to_image.file_name,
to_image.size);
errorcnt++;
} else {
to.data = to_image.data;
to.size = to_image.size;
}
if (!errorcnt) {
size_t to_write = Min(to.size, from.size);
assert(from.data && to.data);
DEBUG("Writing %zu bytes", to_write);
memcpy(to.data, from.data, to_write);
}
if (!errorcnt && vb2_write_file(
filename, to_image.data, to_image.size)) {
ERROR("Failed writing to file: %s", filename);
errorcnt++;
}
free_firmware_image(&to_image);
return errorcnt;
}
/*
* Writes a section from given firmware image to system firmware.
* If section_name is NULL, write whole image.
* Returns 0 if success, non-zero if error.
*/
static int write_firmware(struct updater_config *cfg,
const struct firmware_image *image,
const char *section_name)
{
const char *tmp_file = updater_create_temp_file(cfg);
const char *programmer = image->programmer;
if (!tmp_file)
return -1;
if (cfg->emulation) {
INFO("%s: (emulation) Writing %s from %s to %s (emu=%s).",
__FUNCTION__,
section_name ? section_name : "whole image",
image->file_name, programmer, cfg->emulation);
return emulate_write_firmware(
cfg->emulation, image, section_name);
}
if (vb2_write_file(tmp_file, image->data, image->size) != VB2_SUCCESS) {
ERROR("Cannot write temporary file for output: %s", tmp_file);
return -1;
}
return host_flashrom(FLASHROM_WRITE, tmp_file, programmer,
cfg->verbosity + 1, section_name);
}
/*
* Write a section from given firmware image to system firmware if possible.
* If section_name is NULL, write whole image. If the image has no data or if
* the section does not exist, ignore and return success.
* Returns 0 if success, non-zero if error.
*/
static int write_optional_firmware(struct updater_config *cfg,
const struct firmware_image *image,
const char *section_name,
int check_programmer_wp)
{
if (!image->data) {
DEBUG("No data in <%s> image.", image->programmer);
return 0;
}
if (section_name && !firmware_section_exists(image, section_name)) {
DEBUG("Image %s<%s> does not have section %s.",
image->file_name, image->programmer, section_name);
return 0;
}
/*
* EC & PD may have different WP settings and we want to write
* only if it is OK.
*/
if (check_programmer_wp &&
get_system_property(SYS_PROP_WP_HW, cfg) == WP_ENABLED &&
host_get_wp(image->programmer) == WP_ENABLED) {
ERROR("Target %s has write protection enabled, skip updating.",
image->programmer);
return 0;
}
return write_firmware(cfg, image, section_name);
}
/*
* Preserves (copies) the given section (by name) from image_from to image_to.
* The offset may be different, and the section data will be directly copied.
* If the section does not exist on either images, return as failure.
* If the source section is larger, contents on destination be truncated.
* If the source section is smaller, the remaining area is not modified.
* Returns 0 if success, non-zero if error.
*/
int preserve_firmware_section(const struct firmware_image *image_from,
struct firmware_image *image_to,
const char *section_name)
{
struct firmware_section from, to;
find_firmware_section(&from, image_from, section_name);
find_firmware_section(&to, image_to, section_name);
if (!from.data || !to.data) {
DEBUG("Cannot find section %s: from=%p, to=%p", section_name,
from.data, to.data);
return -1;
}
if (from.size > to.size) {
WARN("%s: Section %s is truncated after updated.",
__FUNCTION__, section_name);
}
/* Use memmove in case if we need to deal with sections that overlap. */
memmove(to.data, from.data, Min(from.size, to.size));
return 0;
}
/*
* Finds the GBB (Google Binary Block) header on a given firmware image.
* Returns a pointer to valid GBB header, or NULL on not found.
*/
const struct vb2_gbb_header *find_gbb(const struct firmware_image *image)
{
struct firmware_section section;
struct vb2_gbb_header *gbb_header;
find_firmware_section(&section, image, FMAP_RO_GBB);
gbb_header = (struct vb2_gbb_header *)section.data;
/*
* futil_valid_gbb_header needs v1 header (GoogleBinaryBlockHeader)
* but that should be compatible with vb2_gbb_header
*/
if (!futil_valid_gbb_header((GoogleBinaryBlockHeader *)gbb_header,
section.size, NULL)) {
ERROR("Cannot find GBB in image: %s.", image->file_name);
return NULL;
}
return gbb_header;
}
/*
* Preserve the GBB contents from image_from to image_to.
* HWID is always preserved, and flags are preserved only if preserve_flags set.
* Returns 0 if success, otherwise -1 if GBB header can't be found or if HWID is
* too large.
*/
static int preserve_gbb(const struct firmware_image *image_from,
struct firmware_image *image_to,
int preserve_flags)
{
const struct vb2_gbb_header *gbb_from;
struct vb2_gbb_header *gbb_to;
gbb_from = find_gbb(image_from);
/* We do want to change GBB contents later. */
gbb_to = (struct vb2_gbb_header *)find_gbb(image_to);
if (!gbb_from || !gbb_to)
return -1;
/* Preserve flags (for non-factory mode). */
if (preserve_flags)
gbb_to->flags = gbb_from->flags;
/* Preserve HWID. */
return futil_set_gbb_hwid(
gbb_to, (const char *)gbb_from + gbb_from->hwid_offset);
}
/*
* Preserves the regions locked by Intel management engine.
*/
static int preserve_management_engine(struct updater_config *cfg,
const struct firmware_image *image_from,
struct firmware_image *image_to)
{
struct firmware_section section;
find_firmware_section(&section, image_from, FMAP_SI_ME);
if (!section.data) {
DEBUG("Skipped because no section %s.", FMAP_SI_ME);
return 0;
}
if (section_is_filled_with(&section, 0xFF)) {
DEBUG("ME is probably locked - preserving %s.", FMAP_SI_DESC);
return preserve_firmware_section(
image_from, image_to, FMAP_SI_DESC);
}
return try_apply_quirk(QUIRK_UNLOCK_ME_FOR_UPDATE, cfg);
}
/*
* Preserves the critical sections from the current (active) firmware.
* Currently preserved sections: GBB (HWID and flags), x86 ME, {RO,RW}_PRESERVE,
* {RO,RW}_VPD, RW_NVRAM.
* Returns 0 if success, non-zero if error.
*/
static int preserve_images(struct updater_config *cfg)
{
int errcnt = 0, i;
struct firmware_image *from = &cfg->image_current, *to = &cfg->image;
const char * const optional_sections[] = {
FMAP_RO_PRESERVE,
FMAP_RW_PRESERVE,
FMAP_RW_NVRAM,
FMAP_RW_ELOG,
FMAP_RW_SMMSTORE,
/*
* TODO(hungte): b/116326638: Remove RO_FSG after the migration
* is finished.
*/
"RO_FSG",
};
errcnt += preserve_gbb(from, to, !cfg->factory_update);
errcnt += preserve_management_engine(cfg, from, to);
errcnt += preserve_firmware_section(from, to, FMAP_RO_VPD);
errcnt += preserve_firmware_section(from, to, FMAP_RW_VPD);
for (i = 0; i < ARRAY_SIZE(optional_sections); i++) {
if (!firmware_section_exists(from, optional_sections[i]))
continue;
errcnt += preserve_firmware_section(
from, to, optional_sections[i]);
}
return errcnt;
}
/*
* Compares if two sections have same size and data.
* Returns 0 if given sections are the same, otherwise non-zero.
*/
static int compare_section(const struct firmware_section *a,
const struct firmware_section *b)
{
if (a->size != b->size)
return a->size - b->size;
return memcmp(a->data, b->data, a->size);
}
/*
* Returns if the images are different (should be updated) in given section.
* If the section contents are the same or if the section does not exist on both
* images, return value is 0 (no need to update). Otherwise the return value is
* non-zero, indicating an update should be performed.
* If section_name is NULL, compare whole images.
*/
static int section_needs_update(const struct firmware_image *image_from,
const struct firmware_image *image_to,
const char *section_name)
{
struct firmware_section from, to;
if (!section_name) {
if (image_from->size != image_to->size)
return -1;
return memcmp(image_from->data, image_to->data, image_to->size);
}
find_firmware_section(&from, image_from, section_name);
find_firmware_section(&to, image_to, section_name);
return compare_section(&from, &to);
}
/*
* Returns true if the write protection is enabled on current system.
*/
static int is_write_protection_enabled(struct updater_config *cfg)
{
/* Default to enabled. */
int wp = get_system_property(SYS_PROP_WP_HW, cfg);
if (wp == WP_DISABLED)
return wp;
/* For error or enabled, check WP SW. */
wp = get_system_property(SYS_PROP_WP_SW, cfg);
/* Consider all errors as enabled. */
if (wp != WP_DISABLED)
return WP_ENABLED;
return wp;
}
/*
* Checks if the given firmware images are compatible with current platform.
* In current implementation (following Chrome OS style), we assume the platform
* is identical to the name before a dot (.) in firmware version.
* Returns 0 for success, otherwise failure.
*/
static int check_compatible_platform(struct updater_config *cfg)
{
int len;
struct firmware_image *image_from = &cfg->image_current,
*image_to = &cfg->image;
const char *from_dot = strchr(image_from->ro_version, '.'),
*to_dot = strchr(image_to->ro_version, '.');
if (!from_dot || !to_dot) {
DEBUG("Missing dot (from=%p, to=%p)", from_dot, to_dot);
return -1;
}
len = from_dot - image_from->ro_version + 1;
DEBUG("Platform: %*.*s", len, len, image_from->ro_version);
return strncmp(image_from->ro_version, image_to->ro_version, len);
}
/*
* Returns a valid root key from GBB header, or NULL on failure.
*/
static const struct vb2_packed_key *get_rootkey(
const struct vb2_gbb_header *gbb)
{
struct vb2_packed_key *key = NULL;
key = (struct vb2_packed_key *)((uint8_t *)gbb + gbb->rootkey_offset);
if (!packed_key_looks_ok(key, gbb->rootkey_size)) {
ERROR("Invalid root key.");
return NULL;
}
return key;
}
/*
* Returns a key block key from given image section, or NULL on failure.
*/
static const struct vb2_keyblock *get_keyblock(
const struct firmware_image *image,
const char *section_name)
{
struct firmware_section section;
find_firmware_section(&section, image, section_name);
/* A keyblock must be followed by a vb2_fw_preamble. */
if (section.size < sizeof(struct vb2_keyblock) +
sizeof(struct vb2_fw_preamble)) {
ERROR("Invalid section: %s", section_name);
return NULL;
}
return (const struct vb2_keyblock *)section.data;
}
/*
* Duplicates a key block and returns the duplicated block.
* The caller must free the returned key block after being used.
*/
static struct vb2_keyblock *dupe_keyblock(const struct vb2_keyblock *block)
{
struct vb2_keyblock *new_block;
new_block = (struct vb2_keyblock *)malloc(block->keyblock_size);
assert(new_block);
memcpy(new_block, block, block->keyblock_size);
return new_block;
}
/*
* Verifies if keyblock is signed with given key.
* Returns 0 on success, otherwise failure.
*/
static int verify_keyblock(const struct vb2_keyblock *block,
const struct vb2_packed_key *sign_key) {
int r;
uint8_t workbuf[VB2_WORKBUF_RECOMMENDED_SIZE];
struct vb2_workbuf wb;
struct vb2_public_key key;
struct vb2_keyblock *new_block;
if (block->keyblock_signature.sig_size == 0) {
ERROR("Keyblock is not signed.");
return -1;
}
vb2_workbuf_init(&wb, workbuf, sizeof(workbuf));
if (VB2_SUCCESS != vb2_unpack_key(&key, sign_key)) {
ERROR("Invalid signing key,");
return -1;
}
/*
* vb2_verify_keyblock will destroy the signature inside keyblock
* so we have to verify with a local copy.
*/
new_block = dupe_keyblock(block);
r = vb2_verify_keyblock(new_block, new_block->keyblock_size, &key, &wb);
free(new_block);
if (r != VB2_SUCCESS) {
ERROR("Failed verifying key block.");
return -1;
}
return 0;
}
/*
* Gets the data key and firmware version from a section on firmware image.
* The section should contain a vb2_keyblock and a vb2_fw_preamble immediately
* after key block so we can decode and save the data key and firmware version
* into argument `data_key_version` and `firmware_version`.
* Returns 0 for success, otherwise failure.
*/
static int get_key_versions(const struct firmware_image *image,
const char *section_name,
unsigned int *data_key_version,
unsigned int *firmware_version)
{
const struct vb2_keyblock *keyblock = get_keyblock(image, section_name);
const struct vb2_fw_preamble *pre;
if (!keyblock)
return -1;
*data_key_version = keyblock->data_key.key_version;
pre = (struct vb2_fw_preamble *)((uint8_t*)keyblock +
keyblock->keyblock_size);
*firmware_version = pre->firmware_version;
DEBUG("%s: data key version = %d, firmware version = %d",
image->file_name, *data_key_version, *firmware_version);
return 0;
}
/*
* Checks if the root key in ro_image can verify vblocks in rw_image.
* Returns 0 for success, otherwise failure.
*/
static enum rootkey_compat_result check_compatible_root_key(
const struct firmware_image *ro_image,
const struct firmware_image *rw_image)
{
const struct vb2_gbb_header *gbb = find_gbb(ro_image);
const struct vb2_packed_key *rootkey;
const struct vb2_keyblock *keyblock;
if (!gbb)
return ROOTKEY_COMPAT_ERROR;
rootkey = get_rootkey(gbb);
if (!rootkey)
return ROOTKEY_COMPAT_ERROR;
/* Assume VBLOCK_A and VBLOCK_B are signed in same way. */
keyblock = get_keyblock(rw_image, FMAP_RW_VBLOCK_A);
if (!keyblock)
return ROOTKEY_COMPAT_ERROR;
if (verify_keyblock(keyblock, rootkey) != 0) {
const struct vb2_gbb_header *gbb_rw = find_gbb(rw_image);
const struct vb2_packed_key *rootkey_rw = NULL;
int is_same_key = 0, to_dev = 0;
/*
* Try harder to provide more info.
* packed_key_sha1_string uses static buffer so don't call
* it twice in args list of one expression.
*/
if (gbb_rw)
rootkey_rw = get_rootkey(gbb_rw);
if (rootkey_rw) {
if (rootkey->key_offset == rootkey_rw->key_offset &&
rootkey->key_size == rootkey_rw->key_size &&
memcmp(rootkey, rootkey_rw, rootkey->key_size +
rootkey->key_offset) == 0)
is_same_key = 1;
if (strcmp(packed_key_sha1_string(rootkey_rw),
ROOTKEY_HASH_DEV) == 0)
to_dev = 1;
}
INFO("Current (RO) firmware image has root key: %s",
packed_key_sha1_string(rootkey));
if (is_same_key) {
ERROR("Rootkey is same as target (RW) image. "
"Maybe RW corrupted?");
return ROOTKEY_COMPAT_ERROR;
}
WARN("Target (RW) image is signed by rootkey: %s.",
rootkey_rw ? packed_key_sha1_string(rootkey_rw) :
"<invalid>");
return to_dev ? ROOTKEY_COMPAT_REKEY_TO_DEV :
ROOTKEY_COMPAT_REKEY;
}
return ROOTKEY_COMPAT_OK;
}
/*
* Returns 1 if a given file (cbfs_entry_name) exists inside a particular CBFS
* section of an image file, otherwise 0.
*/
static int cbfs_file_exists(const char *image_file,
const char *section_name,
const char *cbfs_entry_name)
{
char *cmd;
int r;
ASPRINTF(&cmd,
"cbfstool '%s' print -r %s 2>/dev/null | grep -q '^%s '",
image_file, section_name, cbfs_entry_name);
r = system(cmd);
free(cmd);
return !r;
}
/*
* Returns non-zero if the RW_LEGACY needs to be updated, otherwise 0.
*/
static int legacy_needs_update(struct updater_config *cfg)
{
int has_from, has_to;
const char * const tag = "cros_allow_auto_update";
const char *section = FMAP_RW_LEGACY;
const char *tmp_path = updater_create_temp_file(cfg);
DEBUG("Checking %s contents...", FMAP_RW_LEGACY);
if (!tmp_path ||
vb2_write_file(tmp_path, cfg->image.data, cfg->image.size)) {
ERROR("Failed to create temporary file for image contents.");
return 0;
}
has_to = cbfs_file_exists(tmp_path, section, tag);
has_from = cbfs_file_exists(tmp_path, section, tag);
if (!has_from || !has_to) {
DEBUG("Current legacy firmware has%s updater tag (%s) "
"and target firmware has%s updater tag, won't update.",
has_from ? "" : " no", tag, has_to ? "" : " no");
return 0;
}
return section_needs_update(
&cfg->image_current, &cfg->image, FMAP_RW_LEGACY);
}
/*
* Checks if the given firmware image is signed with a key that won't be
* blocked by TPM's anti-rollback detection.
* Returns 0 for success, otherwise failure.
*/
static int do_check_compatible_tpm_keys(struct updater_config *cfg,
const struct firmware_image *rw_image)
{
unsigned int data_key_version = 0, firmware_version = 0,
tpm_data_key_version = 0, tpm_firmware_version = 0;
int tpm_fwver = 0;
/* Fail if the given image does not look good. */
if (get_key_versions(rw_image, FMAP_RW_VBLOCK_A, &data_key_version,
&firmware_version) != 0)
return -1;
/* The stored tpm_fwver can be 0 (b/116298359#comment3). */
tpm_fwver = get_system_property(SYS_PROP_TPM_FWVER, cfg);
if (tpm_fwver < 0) {
ERROR("Invalid tpm_fwver: %d.", tpm_fwver);
return -1;
}
tpm_data_key_version = tpm_fwver >> 16;
tpm_firmware_version = tpm_fwver & 0xffff;
DEBUG("TPM: data_key_version = %d, firmware_version = %d",
tpm_data_key_version, tpm_firmware_version);
if (tpm_data_key_version > data_key_version) {
ERROR("Data key version rollback detected (%d->%d).",
tpm_data_key_version, data_key_version);
return -1;
}
if (tpm_firmware_version > firmware_version) {
ERROR("Firmware version rollback detected (%d->%d).",
tpm_firmware_version, firmware_version);
return -1;
}
return 0;
}
/*
* Wrapper for do_check_compatible_tpm_keys.
* Will return 0 if do_check_compatible_tpm_keys success or if cfg.force_update
* is set; otherwise non-zero.
*/
static int check_compatible_tpm_keys(struct updater_config *cfg,
const struct firmware_image *rw_image)
{
int r = do_check_compatible_tpm_keys(cfg, rw_image);
if (!r)
return r;
if (!cfg->force_update) {
ERROR("Add --force if you want to waive TPM checks.");
return r;
}
WARN("TPM KEYS CHECK IS WAIVED BY --force. YOU ARE ON YOUR OWN.");
return 0;
}
const char * const updater_error_messages[] = {
[UPDATE_ERR_DONE] = "Done (no error)",
[UPDATE_ERR_NEED_RO_UPDATE] = "RO changed and no WP. Need full update.",
[UPDATE_ERR_NO_IMAGE] = "No image to update; try specify with -i.",
[UPDATE_ERR_SYSTEM_IMAGE] = "Cannot load system active firmware.",
[UPDATE_ERR_INVALID_IMAGE] = "The given firmware image is not valid.",
[UPDATE_ERR_SET_COOKIES] = "Failed writing system flags to try update.",
[UPDATE_ERR_WRITE_FIRMWARE] = "Failed writing firmware.",
[UPDATE_ERR_PLATFORM] = "Your system platform is not compatible.",
[UPDATE_ERR_TARGET] = "No valid RW target to update. Abort.",
[UPDATE_ERR_ROOT_KEY] = "RW not signed by same RO root key",
[UPDATE_ERR_TPM_ROLLBACK] = "RW not usable due to TPM anti-rollback.",
[UPDATE_ERR_UNKNOWN] = "Unknown error.",
};
/*
* The main updater for "Try-RW update", to update only one RW section
* and try if it can boot properly on reboot.
* This was also known as --mode=autoupdate,--wp=1 in legacy updater.
* Returns UPDATE_ERR_DONE if success, otherwise error.
*/
static enum updater_error_codes update_try_rw_firmware(
struct updater_config *cfg,
struct firmware_image *image_from,
struct firmware_image *image_to,
int wp_enabled)
{
const char *target;
int has_update = 1;
int is_vboot2 = get_system_property(SYS_PROP_FW_VBOOT2, cfg);
preserve_gbb(image_from, image_to, 1);
if (!wp_enabled && section_needs_update(
image_from, image_to, FMAP_RO_SECTION))
return UPDATE_ERR_NEED_RO_UPDATE;
INFO("Checking compatibility...");
if (check_compatible_root_key(image_from, image_to))
return UPDATE_ERR_ROOT_KEY;
if (check_compatible_tpm_keys(cfg, image_to))
return UPDATE_ERR_TPM_ROLLBACK;
DEBUG("Firmware %s vboot2.", is_vboot2 ? "is" : "is NOT");
target = decide_rw_target(cfg, TARGET_SELF, is_vboot2);
if (target == NULL) {
ERROR("TRY-RW update needs system to boot in RW firmware.");
return UPDATE_ERR_TARGET;
}
INFO("Checking %s contents...", target);
if (!firmware_section_exists(image_to, target)) {
ERROR("Cannot find section '%s' on firmware image: %s",
target, image_to->file_name);
return UPDATE_ERR_INVALID_IMAGE;
}
if (!cfg->force_update)
has_update = section_needs_update(image_from, image_to, target);
if (has_update) {
target = decide_rw_target(cfg, TARGET_UPDATE, is_vboot2);
STATUS("TRY-RW UPDATE: Updating %s to try on reboot.", target);
if (write_firmware(cfg, image_to, target))
return UPDATE_ERR_WRITE_FIRMWARE;
if (set_try_cookies(cfg, target, is_vboot2))
return UPDATE_ERR_SET_COOKIES;
} else {
/* Clear trial cookies for vboot1. */
if (!is_vboot2 && !cfg->emulation)
VbSetSystemPropertyInt("fwb_tries", 0);
}
/* Do not fail on updating legacy. */
if (legacy_needs_update(cfg)) {
has_update = 1;
STATUS("LEGACY UPDATE: Updating %s.", FMAP_RW_LEGACY);
write_firmware(cfg, image_to, FMAP_RW_LEGACY);
}
if (!has_update)
STATUS("NO UPDATE: No need to update.");
return UPDATE_ERR_DONE;
}
/*
* The main updater for "RW update".
* This was also known as --mode=recovery, --wp=1 in legacy updater.
* Returns UPDATE_ERR_DONE if success, otherwise error.
*/
static enum updater_error_codes update_rw_firmrware(
struct updater_config *cfg,
struct firmware_image *image_from,
struct firmware_image *image_to)
{
STATUS("RW UPDATE: Updating RW sections (%s, %s, %s, and %s).",
FMAP_RW_SECTION_A, FMAP_RW_SECTION_B, FMAP_RW_SHARED,
FMAP_RW_LEGACY);
INFO("Checking compatibility...");
if (check_compatible_root_key(image_from, image_to))
return UPDATE_ERR_ROOT_KEY;
if (check_compatible_tpm_keys(cfg, image_to))
return UPDATE_ERR_TPM_ROLLBACK;
/*
* TODO(hungte) Speed up by flashing multiple sections in one
* command, or provide diff file.
*/
if (write_firmware(cfg, image_to, FMAP_RW_SECTION_A) ||
write_firmware(cfg, image_to, FMAP_RW_SECTION_B) ||
write_firmware(cfg, image_to, FMAP_RW_SHARED) ||
write_optional_firmware(cfg, image_to, FMAP_RW_LEGACY, 0))
return UPDATE_ERR_WRITE_FIRMWARE;
return UPDATE_ERR_DONE;
}
/*
* The main updater for "Legacy update".
* This is equivalent to --mode=legacy.
* Returns UPDATE_ERR_DONE if success, otherwise error.
*/
static enum updater_error_codes update_legacy_firmware(
struct updater_config *cfg,
struct firmware_image *image_to)
{
STATUS("LEGACY UPDATE: Updating firmware %s.", FMAP_RW_LEGACY);
if (write_firmware(cfg, image_to, FMAP_RW_LEGACY))
return UPDATE_ERR_WRITE_FIRMWARE;
return UPDATE_ERR_DONE;
}
/*
* The main updater for "Full update".
* This was also known as "--mode=factory" or "--mode=recovery, --wp=0" in
* legacy updater.
* Returns UPDATE_ERR_DONE if success, otherwise error.
*/
static enum updater_error_codes update_whole_firmware(
struct updater_config *cfg,
struct firmware_image *image_to)
{
STATUS("FULL UPDATE: Updating whole firmware image(s), RO+RW.");
if (preserve_images(cfg))
DEBUG("Failed to preserve some sections - ignore.");
INFO("Checking compatibility...");
if (check_compatible_tpm_keys(cfg, image_to))
return UPDATE_ERR_TPM_ROLLBACK;
if (!cfg->force_update) {
enum rootkey_compat_result r = check_compatible_root_key(
&cfg->image_current, image_to);
/* We only allow re-key to non-dev keys. */
switch (r) {
case ROOTKEY_COMPAT_OK:
break;
case ROOTKEY_COMPAT_REKEY:
INFO("Will change firmware signing key.");
break;
case ROOTKEY_COMPAT_REKEY_TO_DEV:
ERROR("Re-key to DEV is not allowed. "
"Add --force if you really want to do that.");
return UPDATE_ERR_ROOT_KEY;
default:
return UPDATE_ERR_ROOT_KEY;
}
}
/* FMAP may be different so we should just update all. */
if (write_firmware(cfg, image_to, NULL) ||
write_optional_firmware(cfg, &cfg->ec_image, NULL, 1) ||
write_optional_firmware(cfg, &cfg->pd_image, NULL, 1))
return UPDATE_ERR_WRITE_FIRMWARE;
return UPDATE_ERR_DONE;
}
/*
* The main updater to update system firmware using the configuration parameter.
* Returns UPDATE_ERR_DONE if success, otherwise failure.
*/
enum updater_error_codes update_firmware(struct updater_config *cfg)
{
int wp_enabled;
struct firmware_image *image_from = &cfg->image_current,
*image_to = &cfg->image;
if (!image_to->data)
return UPDATE_ERR_NO_IMAGE;
if (try_apply_quirk(QUIRK_DAISY_SNOW_DUAL_MODEL, cfg))
return UPDATE_ERR_PLATFORM;
STATUS("Target image: %s (RO:%s, RW/A:%s, RW/B:%s).",
image_to->file_name, image_to->ro_version,
image_to->rw_version_a, image_to->rw_version_b);
if (try_apply_quirk(QUIRK_MIN_PLATFORM_VERSION, cfg))
return UPDATE_ERR_PLATFORM;
if (!image_from->data) {
/*
* TODO(hungte) Read only RO_SECTION, VBLOCK_A, VBLOCK_B,
* RO_VPD, RW_VPD, RW_NVRAM, RW_LEGACY.
*/
INFO("Loading current system firmware...");
if (load_system_firmware(cfg, image_from) != 0)
return UPDATE_ERR_SYSTEM_IMAGE;
}
STATUS("Current system: %s (RO:%s, RW/A:%s, RW/B:%s).",
image_from->file_name, image_from->ro_version,
image_from->rw_version_a, image_from->rw_version_b);
if (cfg->check_platform && check_compatible_platform(cfg))
return UPDATE_ERR_PLATFORM;
wp_enabled = is_write_protection_enabled(cfg);
STATUS("Write protection: %d (%s; HW=%d, SW=%d).", wp_enabled,
wp_enabled ? "enabled" : "disabled",
get_system_property(SYS_PROP_WP_HW, cfg),
get_system_property(SYS_PROP_WP_SW, cfg));
if (try_apply_quirk(QUIRK_ENLARGE_IMAGE, cfg))
return UPDATE_ERR_SYSTEM_IMAGE;
if (try_apply_quirk(QUIRK_EVE_SMM_STORE, cfg))
return UPDATE_ERR_INVALID_IMAGE;
if (debugging_enabled)
print_system_properties(cfg);
if (cfg->legacy_update)
return update_legacy_firmware(cfg, image_to);
if (cfg->try_update) {
enum updater_error_codes r;
r = update_try_rw_firmware(cfg, image_from, image_to,
wp_enabled);
if (r != UPDATE_ERR_NEED_RO_UPDATE)
return r;
WARN("%s", updater_error_messages[r]);
}
if (wp_enabled)
return update_rw_firmrware(cfg, image_from, image_to);
else
return update_whole_firmware(cfg, image_to);
}
/*
* Allocates and initializes a updater_config object with default values.
* Returns the newly allocated object, or NULL on error.
*/
struct updater_config *updater_new_config()
{
struct system_property *props;
struct updater_config *cfg = (struct updater_config *)calloc(
1, sizeof(struct updater_config));
if (!cfg)
return cfg;
cfg->image.programmer = PROG_HOST;
cfg->image_current.programmer = PROG_HOST;
cfg->ec_image.programmer = PROG_EC;
cfg->pd_image.programmer = PROG_PD;
cfg->check_platform = 1;
props = cfg->system_properties;
props[SYS_PROP_MAINFW_ACT].getter = host_get_mainfw_act;
props[SYS_PROP_TPM_FWVER].getter = host_get_tpm_fwver;
props[SYS_PROP_FW_VBOOT2].getter = host_get_fw_vboot2;
props[SYS_PROP_PLATFORM_VER].getter = host_get_platform_version;
props[SYS_PROP_WP_HW].getter = host_get_wp_hw;
props[SYS_PROP_WP_SW].getter = host_get_wp_sw;
updater_register_quirks(cfg);
return cfg;
}
/*
* Saves everything from stdin to given output file.
* Returns 0 on success, otherwise failure.
*/
static int save_from_stdin(const char *output)
{
FILE *in = stdin, *out = fopen(output, "wb");
char buffer[4096];
size_t sz;
assert(in);
if (!out)
return -1;
while (!feof(in)) {
sz = fread(buffer, 1, sizeof(buffer), in);
fwrite(buffer, 1, sz, out);
}
fclose(out);
return 0;
}
/*
* Setup quirks for updating current image.
*
* Quirks must be loaded after image loaded because we use image contents to
* decide default quirks to load. Also, we have to load default quirks first so
* user can override them using command line.
*
* Returns 0 on success, otherwise number of failures.
*/
static int updater_setup_quirks(struct updater_config *cfg,
const struct updater_config_arguments *arg)
{
int errorcnt = 0;
const char *quirks = updater_get_default_quirks(cfg);
if (quirks)
errorcnt += !!setup_config_quirks(quirks, cfg);
if (arg->quirks)
errorcnt += !!setup_config_quirks(arg->quirks, cfg);
return errorcnt;
}
/*
* Loads images into updater configuration.
* Returns 0 on success, otherwise number of failures.
*/
static int updater_load_images(struct updater_config *cfg,
const struct updater_config_arguments *arg,
const char *image,
const char *ec_image,
const char *pd_image)
{
int errorcnt = 0;
struct archive *ar = cfg->archive;
if (!cfg->image.data && image) {
if (image && strcmp(image, "-") == 0) {
INFO("Reading image from stdin...");
image = updater_create_temp_file(cfg);
if (image)
errorcnt += !!save_from_stdin(image);
}
errorcnt += !!load_firmware_image(&cfg->image, image, ar);
if (!errorcnt)
errorcnt += updater_setup_quirks(cfg, arg);
}
if (cfg->emulation || arg->host_only)
return errorcnt;
if (!cfg->ec_image.data && ec_image)
errorcnt += !!load_firmware_image(&cfg->ec_image, ec_image, ar);
if (!cfg->pd_image.data && pd_image)
errorcnt += !!load_firmware_image(&cfg->pd_image, pd_image, ar);
return errorcnt;
}
/*
* Writes a firmware image to specified file.
* Returns 0 on success, otherwise failure.
*/
static int updater_output_image(const struct firmware_image *image,
const char *fname, const char *root)
{
int r = 0;
char *fpath;
if (!image->data)
return 0;
ASPRINTF(&fpath, "%s/%s", root, fname);
r = vb2_write_file(fpath, image->data, image->size);
if (r)
ERROR("Failed writing firmware image to: %s", fpath);
else
printf("Firmware image saved in: %s\n", fpath);
free(fpath);
return !!r;
}
/*
* Applies white label information to an existing model config.
* Returns 0 on success, otherwise failure.
*/
static int updater_apply_white_label(struct updater_config *cfg,
struct model_config *model,
const char *signature_id)
{
const char *tmp_image = NULL;
assert(model->is_white_label);
if (!signature_id) {
if (cfg->image_current.data) {
tmp_image = updater_create_temp_file(cfg);
if (!tmp_image)
return 1;
if (vb2_write_file(tmp_image, cfg->image_current.data,
cfg->image_current.size)) {
ERROR("Failed writing temporary image file.");
return 1;
}
} else {
INFO("Loading system firmware for white label...");
load_system_firmware(cfg, &cfg->image_current);
tmp_image = cfg->image_current.file_name;
}
if (!tmp_image) {
ERROR("Failed to get system current firmware");
return 1;
}
}
return !!model_apply_white_label(
model, cfg->archive, signature_id, tmp_image);
}
/*
* Setup what the updater has to do against an archive.
* Returns number of failures, or 0 on success.
*/
static int updater_setup_archive(
struct updater_config *cfg,
const struct updater_config_arguments *arg,
struct manifest *manifest,
int is_factory)
{
int errorcnt = 0;
struct archive *ar = cfg->archive;
const struct model_config *model;
if (arg->do_manifest) {
assert(!arg->image);
print_json_manifest(manifest);
/* No additional error. */
return errorcnt;
}
model = manifest_find_model(manifest, arg->model);
if (!model)
return ++errorcnt;
/* Load images now so we can get quirks in WL checks. */
errorcnt += updater_load_images(
cfg, arg, model->image, model->ec_image,
model->pd_image);
if (model->is_white_label && !manifest->has_keyset) {
/*
* Developers running unsigned updaters (usually local build)
* won't be able match any white label tags.
*/
WARN("No keysets found - this is probably a local build of "
"unsigned firmware updater. Skip applying white label.");
} else if (model->is_white_label) {
/*
* It is fine to fail in updater_apply_white_label for factory
* mode so we are not checking the return value; instead we
* verify if the patches do contain new root key.
*/
updater_apply_white_label(cfg, (struct model_config *)model,
arg->signature_id);
if (!model->patches.rootkey) {
if (is_factory ||
is_write_protection_enabled(cfg) ||
get_config_quirk(QUIRK_ALLOW_EMPTY_WLTAG, cfg)) {
WARN("No VPD for white label.");
} else {
ERROR("Need VPD set for white label.");
return ++errorcnt;
}
}
}
errorcnt += patch_image_by_model(&cfg->image, model, ar);
return errorcnt;
}
/*
* Helper function to setup an allocated updater_config object.
* Returns number of failures, or 0 on success.
*/
int updater_setup_config(struct updater_config *cfg,
const struct updater_config_arguments *arg,
int *do_update)
{
int errorcnt = 0;
int check_single_image = 0, check_wp_disabled = 0;
int do_output = 0;
const char *archive_path = arg->archive;
/* Setup values that may change output or decision of other argument. */
cfg->verbosity = arg->verbosity;
cfg->factory_update = arg->is_factory;
if (arg->force_update)
cfg->force_update = 1;
/* Check incompatible options and return early. */
if (arg->do_manifest) {
if (!!arg->archive == !!arg->image) {
ERROR("--manifest needs either -a or -i");
return ++errorcnt;
}
if (arg->archive && (arg->ec_image || arg->pd_image)) {
ERROR("--manifest for archive (-a) does not accept "
"additional images (--ec_image, --pd_image).");
return ++errorcnt;
}
*do_update = 0;
}
if (arg->repack || arg->unpack) {
if (!arg->archive) {
ERROR("--{re,un}pack needs --archive.");
return ++errorcnt;
}
*do_update = 0;
}
/* Setup update mode. */
if (arg->try_update)
cfg->try_update = 1;
if (arg->mode) {
if (strcmp(arg->mode, "autoupdate") == 0) {
cfg->try_update = 1;
} else if (strcmp(arg->mode, "recovery") == 0) {
cfg->try_update = 0;
} else if (strcmp(arg->mode, "legacy") == 0) {
cfg->legacy_update = 1;
} else if (strcmp(arg->mode, "factory") == 0 ||
strcmp(arg->mode, "factory_install") == 0) {
cfg->factory_update = 1;
} else if (strcmp(arg->mode, "output") == 0) {
do_output = 1;
} else {
errorcnt++;
ERROR("Invalid mode: %s", arg->mode);
}
}
if (cfg->factory_update) {
/* factory_update must be processed after arg->mode. */
check_wp_disabled = 1;
cfg->try_update = 0;
}
/* Setup properties and fields that do not have external dependency. */
if (arg->programmer) {
check_single_image = 1;
cfg->image.programmer = arg->programmer;
cfg->image_current.programmer = arg->programmer;
DEBUG("AP (host) programmer changed to %s.", arg->programmer);
}
if (arg->sys_props)
override_properties_from_list(arg->sys_props, cfg);
if (arg->write_protection) {
/* arg->write_protection must be done after arg->sys_props. */
int r = strtol(arg->write_protection, NULL, 0);
override_system_property(SYS_PROP_WP_HW, cfg, r);
override_system_property(SYS_PROP_WP_SW, cfg, r);
}
/* Set up archive and load images. */
if (arg->emulation) {
/* Process emulation file first. */
check_single_image = 1;
cfg->emulation = arg->emulation;
DEBUG("Using file %s for emulation.", arg->emulation);
errorcnt += !!load_firmware_image(
&cfg->image_current, arg->emulation, NULL);
}
/* Always load images specified from command line directly. */
errorcnt += updater_load_images(
cfg, arg, arg->image, arg->ec_image, arg->pd_image);
if (!archive_path)
archive_path = ".";
cfg->archive = archive_open(archive_path);
if (!cfg->archive) {
ERROR("Failed to open archive: %s", archive_path);
return ++errorcnt;
}
/* Process archives which may not have valid contents. */
if (arg->repack || arg->unpack) {
const char *work_name = arg->repack ? arg->repack : arg->unpack;
struct archive *from, *to, *work;
work = archive_open(work_name);
if (arg->repack) {
from = work;
to = cfg->archive;
} else {
to = work;
from = cfg->archive;
}
if (!work) {
ERROR("Failed to open: %s", work_name);
return ++errorcnt;
}
errorcnt += !!archive_copy(from, to);
/* TODO(hungte) Update manifest after copied. */
archive_close(work);
return errorcnt;
}
/* Load images from archive. */
if (arg->archive) {
struct manifest *m = new_manifest_from_archive(cfg->archive);
if (m) {
errorcnt += updater_setup_archive(
cfg, arg, m, cfg->factory_update);
delete_manifest(m);
} else {
ERROR("Failure in archive: %s", arg->archive);
++errorcnt;
}
} else if (arg->do_manifest) {
char name[] = "default";
struct model_config model = {
.name = name,
.image = arg->image,
.ec_image = arg->ec_image,
.pd_image = arg->pd_image,
};
struct manifest manifest = {
.num = 1,
.models = &model,
};
assert(model.image);
print_json_manifest(&manifest);
}
/*
* Images should be loaded now (either in first updater_load_images or
* second call from updater_setup_archive) and quirks should be loaded.
* For invocation without image, we want to get quirks now.
*/
if (!cfg->image.data && arg->quirks)
errorcnt += !!setup_config_quirks(arg->quirks, cfg);
/* Additional checks. */
if (check_single_image && (cfg->ec_image.data || cfg->pd_image.data)) {
errorcnt++;
ERROR("EC/PD images are not supported in current mode.");
}
if (check_wp_disabled && is_write_protection_enabled(cfg)) {
errorcnt++;
ERROR("Factory mode needs WP disabled.");
}
if (!errorcnt && do_output) {
const char *r = arg->output_dir;
if (!r)
r = ".";
errorcnt += updater_output_image(&cfg->image, "bios.bin", r);
errorcnt += updater_output_image(&cfg->ec_image, "ec.bin", r);
errorcnt += updater_output_image(&cfg->pd_image, "pd.bin", r);
*do_update = 0;
}
return errorcnt;
}
/*
* Releases all resources in an updater configuration object.
*/
void updater_delete_config(struct updater_config *cfg)
{
assert(cfg);
free_firmware_image(&cfg->image);
free_firmware_image(&cfg->image_current);
free_firmware_image(&cfg->ec_image);
free_firmware_image(&cfg->pd_image);
updater_remove_all_temp_files(cfg);
if (cfg->archive)
archive_close(cfg->archive);
free(cfg);
}