/*
* Copyright (C) 2016 The Android Open Source Project
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <android_bootloader.h>
#include <android_bootloader_message.h>
#include <android_avb/avb_slot_verify.h>
#include <android_avb/avb_ops_user.h>
#include <android_avb/rk_avb_ops_user.h>
#include <android_image.h>
#include <android_ab.h>
#include <bootm.h>
#include <asm/arch/hotkey.h>
#include <cli.h>
#include <common.h>
#include <dt_table.h>
#include <image-android-dt.h>
#include <malloc.h>
#include <mp_boot.h>
#include <fdt_support.h>
#include <fs.h>
#include <boot_rkimg.h>
#include <attestation_key.h>
#include <keymaster.h>
#include <linux/libfdt_env.h>
#include <optee_include/OpteeClientInterface.h>
#include <bidram.h>
#include <console.h>
#include <sysmem.h>
DECLARE_GLOBAL_DATA_PTR;
int android_bootloader_message_load(
struct blk_desc *dev_desc,
const disk_partition_t *part_info,
struct android_bootloader_message *message)
{
ulong message_blocks = sizeof(struct android_bootloader_message) /
part_info->blksz;
if (message_blocks > part_info->size) {
printf("misc partition too small.\n");
return -1;
}
if (blk_dread(dev_desc, part_info->start + android_bcb_msg_sector_offset(),
message_blocks, message) !=
message_blocks) {
printf("Could not read from misc partition\n");
return -1;
}
debug("ANDROID: Loaded BCB, %lu blocks.\n", message_blocks);
return 0;
}
static int android_bootloader_message_write(
struct blk_desc *dev_desc,
const disk_partition_t *part_info,
struct android_bootloader_message *message)
{
ulong message_blocks = sizeof(struct android_bootloader_message) /
part_info->blksz + android_bcb_msg_sector_offset();
if (message_blocks > part_info->size) {
printf("misc partition too small.\n");
return -1;
}
if (blk_dwrite(dev_desc, part_info->start, message_blocks, message) !=
message_blocks) {
printf("Could not write to misc partition\n");
return -1;
}
debug("ANDROID: Wrote new BCB, %lu blocks.\n", message_blocks);
return 0;
}
static enum android_boot_mode android_bootloader_load_and_clear_mode(
struct blk_desc *dev_desc,
const disk_partition_t *misc_part_info)
{
struct android_bootloader_message bcb;
#ifdef CONFIG_FASTBOOT
char *bootloader_str;
/* Check for message from bootloader stored in RAM from a previous boot.
*/
bootloader_str = (char *)CONFIG_FASTBOOT_BUF_ADDR;
if (!strcmp("reboot-bootloader", bootloader_str)) {
bootloader_str[0] = '\0';
return ANDROID_BOOT_MODE_BOOTLOADER;
}
#endif
/* Check and update the BCB message if needed. */
if (android_bootloader_message_load(dev_desc, misc_part_info, &bcb) <
0) {
printf("WARNING: Unable to load the BCB.\n");
return ANDROID_BOOT_MODE_NORMAL;
}
if (!strcmp("bootonce-bootloader", bcb.command)) {
/* Erase the message in the BCB since this value should be used
* only once.
*/
memset(bcb.command, 0, sizeof(bcb.command));
android_bootloader_message_write(dev_desc, misc_part_info,
&bcb);
return ANDROID_BOOT_MODE_BOOTLOADER;
}
if (!strcmp("boot-recovery", bcb.command))
return ANDROID_BOOT_MODE_RECOVERY;
if (!strcmp("boot-fastboot", bcb.command))
return ANDROID_BOOT_MODE_RECOVERY;
return ANDROID_BOOT_MODE_NORMAL;
}
int android_bcb_write(char *cmd)
{
struct android_bootloader_message message = {0};
disk_partition_t part_info;
struct blk_desc *dev_desc;
int ret;
if (!cmd)
return -ENOMEM;
if (strlen(cmd) >= 32)
return -ENOMEM;
dev_desc = rockchip_get_bootdev();
if (!dev_desc) {
printf("%s: dev_desc is NULL!\n", __func__);
return -ENODEV;
}
ret = part_get_info_by_name(dev_desc, ANDROID_PARTITION_MISC, &part_info);
if (ret < 0) {
printf("%s: Could not found misc partition, just run recovery\n",
__func__);
return -ENODEV;
}
strcpy(message.command, cmd);
return android_bootloader_message_write(dev_desc, &part_info, &message);
}
/**
* Return the reboot reason string for the passed boot mode.
*
* @param mode The Android Boot mode.
* @return a pointer to the reboot reason string for mode.
*/
static const char *android_boot_mode_str(enum android_boot_mode mode)
{
switch (mode) {
case ANDROID_BOOT_MODE_NORMAL:
return "(none)";
case ANDROID_BOOT_MODE_RECOVERY:
return "recovery";
case ANDROID_BOOT_MODE_BOOTLOADER:
return "bootloader";
}
return NULL;
}
static int android_bootloader_boot_bootloader(void)
{
const char *fastboot_cmd = env_get("fastbootcmd");
if (fastboot_cmd == NULL) {
printf("fastboot_cmd is null, run default fastboot_cmd!\n");
fastboot_cmd = "fastboot usb 0";
}
return run_command(fastboot_cmd, CMD_FLAG_ENV);
}
#ifdef CONFIG_SUPPORT_OEM_DTB
static int android_bootloader_get_fdt(const char *part_name,
const char *load_file_name)
{
struct blk_desc *dev_desc;
disk_partition_t part_info;
char *fdt_addr = NULL;
char dev_part[3] = {0};
loff_t bytes = 0;
loff_t pos = 0;
loff_t len_read;
unsigned long addr = 0;
int part_num = -1;
int ret;
dev_desc = rockchip_get_bootdev();
if (!dev_desc) {
printf("%s: dev_desc is NULL!\n", __func__);
return -1;
}
part_num = part_get_info_by_name(dev_desc, part_name, &part_info);
if (part_num < 0) {
printf("ANDROID: Could not find partition \"%s\"\n", part_name);
return -1;
}
snprintf(dev_part, ARRAY_SIZE(dev_part), ":%x", part_num);
if (fs_set_blk_dev_with_part(dev_desc, part_num))
return -1;
fdt_addr = env_get("fdt_addr_r");
if (!fdt_addr) {
printf("ANDROID: No Found FDT Load Address.\n");
return -1;
}
addr = simple_strtoul(fdt_addr, NULL, 16);
ret = fs_read(load_file_name, addr, pos, bytes, &len_read);
if (ret < 0)
return -1;
return 0;
}
#endif
/*
* Test on RK3308 AARCH64 mode (Cortex A35 816 MHZ) boot with eMMC:
*
* |-------------------------------------------------------------------|
* | Format | Size(Byte) | Ratio | Decomp time(ms) | Boot time(ms) |
* |-------------------------------------------------------------------|
* | Image | 7720968 | | | 488 |
* |-------------------------------------------------------------------|
* | Image.lz4 | 4119448 | 53% | 59 | 455 |
* |-------------------------------------------------------------------|
* | Image.lzo | 3858322 | 49% | 141 | 536 |
* |-------------------------------------------------------------------|
* | Image.gz | 3529108 | 45% | 222 | 609 |
* |-------------------------------------------------------------------|
* | Image.bz2 | 3295914 | 42% | 2940 | |
* |-------------------------------------------------------------------|
* | Image.lzma| 2683750 | 34% | | |
* |-------------------------------------------------------------------|
*/
static int sysmem_alloc_uncomp_kernel(ulong andr_hdr,
ulong uncomp_kaddr, u32 comp)
{
struct andr_img_hdr *hdr = (struct andr_img_hdr *)andr_hdr;
ulong ksize, kaddr;
if (comp != IH_COMP_NONE) {
/* Release compressed sysmem */
kaddr = env_get_hex("kernel_addr_c", 0);
if (!kaddr)
kaddr = env_get_hex("kernel_addr_r", 0);
kaddr -= hdr->page_size;
if (sysmem_free((phys_addr_t)kaddr))
return -EINVAL;
#ifdef CONFIG_SKIP_RELOCATE_UBOOT
sysmem_free(CONFIG_SYS_TEXT_BASE);
#endif
/*
* Use smaller Ratio to get larger estimated uncompress
* kernel size.
*/
if (comp == IH_COMP_ZIMAGE)
ksize = hdr->kernel_size * 100 / 45;
else if (comp == IH_COMP_LZ4)
ksize = hdr->kernel_size * 100 / 50;
else if (comp == IH_COMP_LZO)
ksize = hdr->kernel_size * 100 / 45;
else if (comp == IH_COMP_GZIP)
ksize = hdr->kernel_size * 100 / 40;
else if (comp == IH_COMP_BZIP2)
ksize = hdr->kernel_size * 100 / 40;
else if (comp == IH_COMP_LZMA)
ksize = hdr->kernel_size * 100 / 30;
else
ksize = hdr->kernel_size;
kaddr = uncomp_kaddr;
ksize = ALIGN(ksize, 512);
if (!sysmem_alloc_base(MEM_UNCOMP_KERNEL,
(phys_addr_t)kaddr, ksize))
return -ENOMEM;
}
return 0;
}
int android_bootloader_boot_kernel(unsigned long kernel_address)
{
char *kernel_addr_r = env_get("kernel_addr_r");
char *kernel_addr_c = env_get("kernel_addr_c");
char *fdt_addr = env_get("fdt_addr_r");
char kernel_addr_str[12];
char comp_str[32] = {0};
ulong comp_type;
const char *comp_name[] = {
[IH_COMP_NONE] = "IMAGE",
[IH_COMP_GZIP] = "GZIP",
[IH_COMP_BZIP2] = "BZIP2",
[IH_COMP_LZMA] = "LZMA",
[IH_COMP_LZO] = "LZO",
[IH_COMP_LZ4] = "LZ4",
[IH_COMP_ZIMAGE]= "ZIMAGE",
};
char *bootm_args[] = {
kernel_addr_str, kernel_addr_str, fdt_addr, NULL };
comp_type = env_get_ulong("os_comp", 10, 0);
sprintf(kernel_addr_str, "0x%08lx", kernel_address);
if (comp_type != IH_COMP_NONE) {
if (comp_type == IH_COMP_ZIMAGE &&
kernel_addr_r && !kernel_addr_c) {
kernel_addr_c = kernel_addr_r;
kernel_addr_r = __stringify(CONFIG_SYS_SDRAM_BASE);
}
snprintf(comp_str, 32, "%s%s%s",
"(Uncompress to ", kernel_addr_r, ")");
}
printf("Booting %s kernel at %s%s with fdt at %s...\n\n\n",
comp_name[comp_type],
comp_type != IH_COMP_NONE ? kernel_addr_c : kernel_addr_r,
comp_str, fdt_addr);
hotkey_run(HK_SYSMEM);
/*
* Check whether there is enough space for uncompress kernel,
* Actually, here only gives a sysmem warning message when failed
* but never return -1.
*/
if (sysmem_alloc_uncomp_kernel(kernel_address,
simple_strtoul(kernel_addr_r, NULL, 16),
comp_type))
return -1;
return do_bootm_states(NULL, 0, ARRAY_SIZE(bootm_args), bootm_args,
BOOTM_STATE_START |
BOOTM_STATE_FINDOS | BOOTM_STATE_FINDOTHER |
BOOTM_STATE_LOADOS |
#ifdef CONFIG_SYS_BOOT_RAMDISK_HIGH
BOOTM_STATE_RAMDISK |
#endif
BOOTM_STATE_OS_PREP | BOOTM_STATE_OS_FAKE_GO |
BOOTM_STATE_OS_GO, &images, 1);
}
static char *strjoin(const char **chunks, char separator)
{
int len, joined_len = 0;
char *ret, *current;
const char **p;
for (p = chunks; *p; p++)
joined_len += strlen(*p) + 1;
if (!joined_len) {
ret = malloc(1);
if (ret)
ret[0] = '\0';
return ret;
}
ret = malloc(joined_len);
current = ret;
if (!ret)
return ret;
for (p = chunks; *p; p++) {
len = strlen(*p);
memcpy(current, *p, len);
current += len;
*current = separator;
current++;
}
/* Replace the last separator by a \0. */
current[-1] = '\0';
return ret;
}
/** android_assemble_cmdline - Assemble the command line to pass to the kernel
* @return a newly allocated string
*/
char *android_assemble_cmdline(const char *slot_suffix,
const char *extra_args)
{
const char *cmdline_chunks[16];
const char **current_chunk = cmdline_chunks;
char *env_cmdline, *cmdline, *rootdev_input, *serialno;
char *allocated_suffix = NULL;
char *allocated_serialno = NULL;
char *allocated_rootdev = NULL;
unsigned long rootdev_len;
env_cmdline = env_get("bootargs");
if (env_cmdline)
*(current_chunk++) = env_cmdline;
/* The |slot_suffix| needs to be passed to the kernel to know what
* slot to boot from.
*/
#ifdef CONFIG_ANDROID_AB
if (slot_suffix) {
allocated_suffix = malloc(strlen(ANDROID_ARG_SLOT_SUFFIX) +
strlen(slot_suffix) + 1);
memset(allocated_suffix, 0, strlen(ANDROID_ARG_SLOT_SUFFIX)
+ strlen(slot_suffix) + 1);
strcpy(allocated_suffix, ANDROID_ARG_SLOT_SUFFIX);
strcat(allocated_suffix, slot_suffix);
*(current_chunk++) = allocated_suffix;
}
#endif
serialno = env_get("serial#");
if (serialno) {
allocated_serialno = malloc(strlen(ANDROID_ARG_SERIALNO) +
strlen(serialno) + 1);
memset(allocated_serialno, 0, strlen(ANDROID_ARG_SERIALNO) +
strlen(serialno) + 1);
strcpy(allocated_serialno, ANDROID_ARG_SERIALNO);
strcat(allocated_serialno, serialno);
*(current_chunk++) = allocated_serialno;
}
rootdev_input = env_get("android_rootdev");
if (rootdev_input) {
rootdev_len = strlen(ANDROID_ARG_ROOT) + CONFIG_SYS_CBSIZE + 1;
allocated_rootdev = malloc(rootdev_len);
strcpy(allocated_rootdev, ANDROID_ARG_ROOT);
cli_simple_process_macros(rootdev_input,
allocated_rootdev +
strlen(ANDROID_ARG_ROOT));
/* Make sure that the string is null-terminated since the
* previous could not copy to the end of the input string if it
* is too big.
*/
allocated_rootdev[rootdev_len - 1] = '\0';
*(current_chunk++) = allocated_rootdev;
}
if (extra_args)
*(current_chunk++) = extra_args;
*(current_chunk++) = NULL;
cmdline = strjoin(cmdline_chunks, ' ');
free(allocated_suffix);
free(allocated_rootdev);
return cmdline;
}
#ifdef CONFIG_ANDROID_AVB
static void slot_set_unbootable(AvbABSlotData* slot)
{
slot->priority = 0;
slot->tries_remaining = 0;
slot->successful_boot = 0;
}
static char *join_str(const char *a, const char *b)
{
size_t len = strlen(a) + strlen(b) + 1 /* null term */;
char *ret = (char *)malloc(len);
if (!ret) {
debug("failed to alloc %zu\n", len);
return NULL;
}
strcpy(ret, a);
strcat(ret, b);
return ret;
}
static size_t get_partition_size(AvbOps *ops, char *name,
const char *slot_suffix)
{
char *partition_name = join_str(name, slot_suffix);
uint64_t size = 0;
AvbIOResult res;
if (partition_name == NULL)
goto bail;
res = ops->get_size_of_partition(ops, partition_name, &size);
if (res != AVB_IO_RESULT_OK && res != AVB_IO_RESULT_ERROR_NO_SUCH_PARTITION)
size = 0;
bail:
if (partition_name)
free(partition_name);
return size;
}
static struct AvbOpsData preload_user_data;
static int avb_image_distribute_prepare(AvbSlotVerifyData *slot_data,
AvbOps *ops, char *slot_suffix)
{
struct AvbOpsData *data = (struct AvbOpsData *)(ops->user_data);
size_t vendor_boot_size;
size_t init_boot_size;
size_t resource_size;
size_t boot_size;
void *image_buf;
boot_size = max(get_partition_size(ops, ANDROID_PARTITION_BOOT, slot_suffix),
get_partition_size(ops, ANDROID_PARTITION_RECOVERY, slot_suffix));
init_boot_size = get_partition_size(ops,
ANDROID_PARTITION_INIT_BOOT, slot_suffix);
vendor_boot_size = get_partition_size(ops,
ANDROID_PARTITION_VENDOR_BOOT, slot_suffix);
resource_size = get_partition_size(ops,
ANDROID_PARTITION_RESOURCE, slot_suffix);
image_buf = sysmem_alloc(MEM_AVB_ANDROID,
boot_size + init_boot_size +
vendor_boot_size + resource_size);
if (!image_buf) {
printf("avb: sysmem alloc failed\n");
return -ENOMEM;
}
/* layout: | boot/recovery | vendor_boot | init_boot | resource | */
data->slot_suffix = slot_suffix;
data->boot.addr = image_buf;
data->boot.size = 0;
data->vendor_boot.addr = data->boot.addr + boot_size;
data->vendor_boot.size = 0;
data->init_boot.addr = data->vendor_boot.addr + vendor_boot_size;
data->init_boot.size = 0;
data->resource.addr = data->init_boot.addr + init_boot_size;
data->resource.size = 0;
return 0;
}
static int avb_image_distribute_finish(AvbSlotVerifyData *slot_data,
AvbSlotVerifyFlags flags,
ulong *load_address)
{
struct andr_img_hdr *hdr;
ulong load_addr = *load_address;
void *vendor_boot_hdr = NULL;
void *init_boot_hdr = NULL;
void *boot_hdr = NULL;
char *part_name;
int i, ret;
for (i = 0; i < slot_data->num_loaded_partitions; i++) {
part_name = slot_data->loaded_partitions[i].partition_name;
if (!strncmp(ANDROID_PARTITION_BOOT, part_name, 4) ||
!strncmp(ANDROID_PARTITION_RECOVERY, part_name, 8)) {
boot_hdr = slot_data->loaded_partitions[i].data;
} else if (!strncmp(ANDROID_PARTITION_INIT_BOOT, part_name, 9)) {
init_boot_hdr = slot_data->loaded_partitions[i].data;
} else if (!strncmp(ANDROID_PARTITION_VENDOR_BOOT, part_name, 11)) {
vendor_boot_hdr = slot_data->loaded_partitions[i].data;
}
}
/*
* populate boot_img_hdr_v34
*
* If allow verification error: the images are loaded by
* ops->get_preloaded_partition() which auto populates
* boot_img_hdr_v34.
*
* If not allow verification error: the images are full loaded
* by ops->read_from_partition() which doesn't populate
* boot_img_hdr_v34, we need to fix it here for bootm and
*/
hdr = boot_hdr;
if (hdr->header_version >= 3 &&
!(flags & AVB_SLOT_VERIFY_FLAGS_ALLOW_VERIFICATION_ERROR)) {
hdr = malloc(sizeof(struct andr_img_hdr));
if (!hdr)
return -ENOMEM;
ret = populate_boot_info(boot_hdr, vendor_boot_hdr,
init_boot_hdr, hdr, true);
if (ret < 0) {
printf("avb: populate boot info failed, ret=%d\n", ret);
return ret;
}
memcpy(boot_hdr, hdr, sizeof(*hdr));
}
/* distribute ! */
load_addr -= hdr->page_size;
if (android_image_memcpy_separate(boot_hdr, &load_addr)) {
printf("Failed to separate copy android image\n");
return AVB_SLOT_VERIFY_RESULT_ERROR_IO;
}
*load_address = load_addr;
return 0;
}
int android_image_verify_resource(const char *boot_part, ulong *resc_buf)
{
const char *requested_partitions[] = {
NULL,
NULL,
};
struct AvbOpsData *data;
uint8_t unlocked = true;
AvbOps *ops;
AvbSlotVerifyFlags flags;
AvbSlotVerifyData *slot_data = {NULL};
AvbSlotVerifyResult verify_result;
char slot_suffix[3] = {0};
char *part_name;
void *image_buf = NULL;
int retry_no_vbmeta_partition = 1;
int i, ret;
ops = avb_ops_user_new();
if (ops == NULL) {
printf("avb_ops_user_new() failed!\n");
return -AVB_SLOT_VERIFY_RESULT_ERROR_OOM;
}
if (ops->read_is_device_unlocked(ops, (bool *)&unlocked) != AVB_IO_RESULT_OK)
printf("Error determining whether device is unlocked.\n");
printf("Device is: %s\n", (unlocked & LOCK_MASK)? "UNLOCKED" : "LOCKED");
if (unlocked & LOCK_MASK) {
*resc_buf = 0;
return 0;
}
flags = AVB_SLOT_VERIFY_FLAGS_NONE;
if (strcmp(boot_part, ANDROID_PARTITION_RECOVERY) == 0)
flags |= AVB_SLOT_VERIFY_FLAGS_NO_VBMETA_PARTITION;
#ifdef CONFIG_ANDROID_AB
part_name = strdup(boot_part);
*(part_name + strlen(boot_part) - 2) = '\0';
requested_partitions[0] = part_name;
ret = rk_avb_get_current_slot(slot_suffix);
if (ret) {
printf("Failed to get slot suffix, ret=%d\n", ret);
return ret;
}
#else
requested_partitions[0] = boot_part;
#endif
data = (struct AvbOpsData *)(ops->user_data);
ret = avb_image_distribute_prepare(slot_data, ops, slot_suffix);
if (ret) {
printf("avb image distribute prepare failed %d\n", ret);
return ret;
}
retry_verify:
verify_result =
avb_slot_verify(ops,
requested_partitions,
slot_suffix,
flags,
AVB_HASHTREE_ERROR_MODE_RESTART,
&slot_data);
if (verify_result != AVB_SLOT_VERIFY_RESULT_OK &&
verify_result != AVB_SLOT_VERIFY_RESULT_ERROR_PUBLIC_KEY_REJECTED) {
if (retry_no_vbmeta_partition && strcmp(boot_part, ANDROID_PARTITION_RECOVERY) == 0) {
printf("Verify recovery with vbmeta.\n");
flags &= ~AVB_SLOT_VERIFY_FLAGS_NO_VBMETA_PARTITION;
retry_no_vbmeta_partition = 0;
goto retry_verify;
}
}
if (verify_result != AVB_SLOT_VERIFY_RESULT_OK || !slot_data) {
sysmem_free((ulong)data->boot.addr);
return verify_result;
}
for (i = 0; i < slot_data->num_loaded_partitions; i++) {
part_name = slot_data->loaded_partitions[i].partition_name;
if (!strncmp(ANDROID_PARTITION_RESOURCE, part_name, 8)) {
image_buf = slot_data->loaded_partitions[i].data;
break;
} else if (!strncmp(ANDROID_PARTITION_BOOT, part_name, 4) ||
!strncmp(ANDROID_PARTITION_RECOVERY, part_name, 8)) {
struct andr_img_hdr *hdr;
hdr = (void *)slot_data->loaded_partitions[i].data;
if (android_image_check_header(hdr))
continue;
if (hdr->header_version <= 2) {
image_buf = (void *)hdr + hdr->page_size +
ALIGN(hdr->kernel_size, hdr->page_size) +
ALIGN(hdr->ramdisk_size, hdr->page_size);
break;
}
}
}
if (image_buf) {
memcpy((char *)&preload_user_data, (char *)data, sizeof(*data));
*resc_buf = (ulong)image_buf;
}
return 0;
}
/*
* AVB Policy.
*
* == avb with unlock:
* Don't process hash verify.
* Go pre-loaded path: Loading vendor_boot and init_boot
* directly to where they should be, while loading the
* boot/recovery. The boot message tells like:
* ···
* preloaded: distribute image from 'boot_a'
* preloaded: distribute image from 'init_boot_a'
* preloaded: distribute image from 'vendor_boot_a'
* ···
*
* == avb with lock:
* Process hash verify.
* Go pre-loaded path: Loading full vendor_boot, init_boot and
* boot/recovery one by one to verify, and distributing them to
* where they should be by memcpy at last.
*
* The three images share a large memory buffer that allocated
* by sysmem_alloc(), it locate at high memory address that
* just lower than SP bottom. The boot message tells like:
* ···
* preloaded: full image from 'boot_a' at 0xe47f90c0 - 0xe7a4b0c0
* preloaded: full image from 'init_boot_a' at 0xeaff90c0 - 0xeb2950c0
* preloaded: full image from 'vendor_boot_a' at 0xe87f90c0 - 0xe9f6e0c0
* ···
*/
static AvbSlotVerifyResult android_slot_verify(char *boot_partname,
unsigned long *android_load_address,
char *slot_suffix)
{
const char *requested_partitions[] = {
boot_partname,
NULL,
NULL,
NULL,
};
struct AvbOpsData *data;
struct blk_desc *dev_desc;
struct andr_img_hdr *hdr;
disk_partition_t part_info;
uint8_t unlocked = true;
AvbOps *ops;
AvbSlotVerifyFlags flags;
AvbSlotVerifyData *slot_data = {NULL};
AvbSlotVerifyResult verify_result;
AvbABData ab_data, ab_data_orig;
size_t slot_index_to_boot = 0;
char verify_state[38] = {0};
char can_boot = 1;
char retry_no_vbmeta_partition = 1;
unsigned long load_address = *android_load_address;
int ret;
dev_desc = rockchip_get_bootdev();
if (!dev_desc)
return AVB_IO_RESULT_ERROR_IO;
if (part_get_info_by_name(dev_desc, boot_partname, &part_info) < 0) {
printf("Could not find \"%s\" partition\n", boot_partname);
return AVB_IO_RESULT_ERROR_NO_SUCH_PARTITION;
}
hdr = populate_andr_img_hdr(dev_desc, &part_info);
if (!hdr) {
printf("No valid android hdr\n");
return AVB_IO_RESULT_ERROR_NO_SUCH_VALUE;
}
if (hdr->header_version >= 4) {
requested_partitions[1] = ANDROID_PARTITION_VENDOR_BOOT;
if (((hdr->os_version >> 25) & 0x7f) >= 13)
requested_partitions[2] = ANDROID_PARTITION_INIT_BOOT;
}
ops = avb_ops_user_new();
if (ops == NULL) {
printf("avb_ops_user_new() failed!\n");
return AVB_SLOT_VERIFY_RESULT_ERROR_OOM;
}
if (ops->read_is_device_unlocked(ops, (bool *)&unlocked) != AVB_IO_RESULT_OK)
printf("Error determining whether device is unlocked.\n");
printf("read_is_device_unlocked() ops returned that device is %s\n",
(unlocked & LOCK_MASK)? "UNLOCKED" : "LOCKED");
flags = AVB_SLOT_VERIFY_FLAGS_NONE;
if (unlocked & LOCK_MASK)
flags |= AVB_SLOT_VERIFY_FLAGS_ALLOW_VERIFICATION_ERROR;
if (load_metadata(ops->ab_ops, &ab_data, &ab_data_orig)) {
printf("Can not load metadata\n");
return AVB_SLOT_VERIFY_RESULT_ERROR_IO;
}
if (!strncmp(slot_suffix, "_a", 2))
slot_index_to_boot = 0;
else if (!strncmp(slot_suffix, "_b", 2))
slot_index_to_boot = 1;
else
slot_index_to_boot = 0;
if (strcmp(boot_partname, ANDROID_PARTITION_RECOVERY) == 0)
flags |= AVB_SLOT_VERIFY_FLAGS_NO_VBMETA_PARTITION;
#ifdef CONFIG_MP_BOOT
preload_user_data.boot.addr = (void *)mpb_post(1);
preload_user_data.boot.size = (size_t)mpb_post(2);
#endif
/* use preload one if available */
if (preload_user_data.boot.addr) {
data = (struct AvbOpsData *)(ops->user_data);
data->slot_suffix = slot_suffix;
data->boot = preload_user_data.boot;
data->vendor_boot = preload_user_data.vendor_boot;
data->init_boot = preload_user_data.init_boot;
data->resource = preload_user_data.resource;
} else {
ret = avb_image_distribute_prepare(slot_data, ops, slot_suffix);
if (ret < 0) {
printf("avb image distribute prepare failed %d\n", ret);
return AVB_SLOT_VERIFY_RESULT_ERROR_OOM;
}
}
retry_verify:
verify_result =
avb_slot_verify(ops,
requested_partitions,
slot_suffix,
flags,
AVB_HASHTREE_ERROR_MODE_RESTART,
&slot_data);
if (verify_result != AVB_SLOT_VERIFY_RESULT_OK &&
verify_result != AVB_SLOT_VERIFY_RESULT_ERROR_PUBLIC_KEY_REJECTED) {
if (retry_no_vbmeta_partition && strcmp(boot_partname, ANDROID_PARTITION_RECOVERY) == 0) {
printf("Verify recovery with vbmeta.\n");
flags &= ~AVB_SLOT_VERIFY_FLAGS_NO_VBMETA_PARTITION;
retry_no_vbmeta_partition = 0;
goto retry_verify;
}
}
strcat(verify_state, ANDROID_VERIFY_STATE);
switch (verify_result) {
case AVB_SLOT_VERIFY_RESULT_OK:
if (unlocked & LOCK_MASK)
strcat(verify_state, "orange");
else
strcat(verify_state, "green");
break;
case AVB_SLOT_VERIFY_RESULT_ERROR_PUBLIC_KEY_REJECTED:
if (unlocked & LOCK_MASK)
strcat(verify_state, "orange");
else
strcat(verify_state, "yellow");
break;
case AVB_SLOT_VERIFY_RESULT_ERROR_OOM:
case AVB_SLOT_VERIFY_RESULT_ERROR_IO:
case AVB_SLOT_VERIFY_RESULT_ERROR_INVALID_METADATA:
case AVB_SLOT_VERIFY_RESULT_ERROR_UNSUPPORTED_VERSION:
case AVB_SLOT_VERIFY_RESULT_ERROR_VERIFICATION:
case AVB_SLOT_VERIFY_RESULT_ERROR_ROLLBACK_INDEX:
default:
if (unlocked & LOCK_MASK)
strcat(verify_state, "orange");
else
strcat(verify_state, "red");
break;
}
if (!slot_data) {
can_boot = 0;
goto out;
}
if (verify_result == AVB_SLOT_VERIFY_RESULT_OK ||
verify_result == AVB_SLOT_VERIFY_RESULT_ERROR_PUBLIC_KEY_REJECTED ||
(unlocked & LOCK_MASK)) {
int len = 0;
char *bootargs, *newbootargs;
#ifdef CONFIG_ANDROID_AVB_ROLLBACK_INDEX
if (rk_avb_update_stored_rollback_indexes_for_slot(ops, slot_data))
printf("Fail to update the rollback indexes.\n");
#endif
if (slot_data->cmdline) {
debug("Kernel command line: %s\n", slot_data->cmdline);
len += strlen(slot_data->cmdline);
}
bootargs = env_get("bootargs");
if (bootargs)
len += strlen(bootargs);
newbootargs = malloc(len + 2);
if (!newbootargs) {
puts("Error: malloc in android_slot_verify failed!\n");
return AVB_SLOT_VERIFY_RESULT_ERROR_OOM;
}
*newbootargs = '\0';
if (bootargs) {
strcpy(newbootargs, bootargs);
strcat(newbootargs, " ");
}
if (slot_data->cmdline)
strcat(newbootargs, slot_data->cmdline);
env_set("bootargs", newbootargs);
/* if need, distribute full image to where they should be */
ret = avb_image_distribute_finish(slot_data, flags, &load_address);
if (ret) {
printf("avb image distribute finish failed %d\n", ret);
return ret;
}
*android_load_address = load_address;
} else {
slot_set_unbootable(&ab_data.slots[slot_index_to_boot]);
}
out:
env_update("bootargs", verify_state);
if (save_metadata_if_changed(ops->ab_ops, &ab_data, &ab_data_orig)) {
printf("Can not save metadata\n");
verify_result = AVB_SLOT_VERIFY_RESULT_ERROR_IO;
}
if (slot_data != NULL)
avb_slot_verify_data_free(slot_data);
if ((unlocked & LOCK_MASK) && can_boot)
return 0;
else
return verify_result;
}
#endif
#if defined(CONFIG_CMD_DTIMG) && defined(CONFIG_OF_LIBFDT_OVERLAY)
/*
* Default return index 0.
*/
__weak int board_select_fdt_index(ulong dt_table_hdr, struct blk_desc *dev_desc)
{
/*
* User can use "dt_for_each_entry(entry, hdr, idx)" to iterate
* over all dt entry of DT image and pick up which they want.
*
* Example:
* struct dt_table_entry *entry;
* int index;
*
* dt_for_each_entry(entry, dt_table_hdr, index) {
*
* .... (use entry)
* }
*
* return index;
*/
return 0;
}
static int android_get_dtbo(ulong *fdt_dtbo,
const struct andr_img_hdr *hdr,
int *index, const char *part_dtbo)
{
struct dt_table_header *dt_hdr = NULL;
struct blk_desc *dev_desc;
disk_partition_t part_info;
u32 blk_offset, blk_cnt;
void *buf;
ulong e_addr;
u32 e_size;
int e_idx;
int ret;
/* Get partition info */
dev_desc = rockchip_get_bootdev();
if (!dev_desc)
return -ENODEV;
ret = part_get_info_by_name(dev_desc, part_dtbo, &part_info);
if (ret < 0) {
printf("No %s partition, ret=%d\n", part_dtbo, ret);
return ret;
}
/* Check dt table header */
if (hdr && !strcmp(part_dtbo, PART_RECOVERY))
blk_offset = part_info.start +
(hdr->recovery_dtbo_offset / part_info.blksz);
else
blk_offset = part_info.start;
dt_hdr = memalign(ARCH_DMA_MINALIGN, part_info.blksz);
if (!dt_hdr)
return -ENOMEM;
ret = blk_dread(dev_desc, blk_offset, 1, dt_hdr);
if (ret != 1)
goto out1;
if (!android_dt_check_header((ulong)dt_hdr)) {
printf("DTBO: invalid dt table header: 0x%x\n", dt_hdr->magic);
ret = -EINVAL;
goto out1;
}
#ifdef DEBUG
android_dt_print_contents((ulong)dt_hdr);
#endif
blk_cnt = DIV_ROUND_UP(fdt32_to_cpu(dt_hdr->total_size),
part_info.blksz);
/* Read all DT Image */
buf = memalign(ARCH_DMA_MINALIGN, part_info.blksz * blk_cnt);
if (!buf) {
ret = -ENOMEM;
goto out1;
}
ret = blk_dread(dev_desc, blk_offset, blk_cnt, buf);
if (ret != blk_cnt)
goto out2;
e_idx = board_select_fdt_index((ulong)buf, dev_desc);
if (e_idx < 0) {
printf("%s: failed to select board fdt index\n", __func__);
ret = -EINVAL;
goto out2;
}
ret = android_dt_get_fdt_by_index((ulong)buf, e_idx, &e_addr, &e_size);
if (!ret) {
printf("%s: failed to get fdt, index=%d\n", __func__, e_idx);
ret = -EINVAL;
goto out2;
}
if (fdt_dtbo)
*fdt_dtbo = e_addr;
if (index)
*index = e_idx;
free(dt_hdr);
debug("ANDROID: Loading dt entry to 0x%lx size 0x%x idx %d from \"%s\" part\n",
e_addr, e_size, e_idx, part_dtbo);
return 0;
out2:
free(buf);
out1:
free(dt_hdr);
return ret;
}
int android_fdt_overlay_apply(void *fdt_addr)
{
struct andr_img_hdr *hdr;
struct blk_desc *dev_desc;
const char *part_boot = PART_BOOT;
disk_partition_t part_info;
char *fdt_backup;
char *part_dtbo = PART_DTBO;
char buf[32] = {0};
ulong fdt_dtbo = -1;
u32 totalsize;
int index = -1;
int ret;
if (rockchip_get_boot_mode() == BOOT_MODE_RECOVERY) {
#ifdef CONFIG_ANDROID_AB
bool can_find_recovery;
can_find_recovery = ab_can_find_recovery_part();
part_boot = can_find_recovery ? PART_RECOVERY : PART_BOOT;
part_dtbo = can_find_recovery ? PART_RECOVERY : PART_DTBO;
#else
part_boot = PART_RECOVERY;
part_dtbo = PART_RECOVERY;
#endif
}
dev_desc = rockchip_get_bootdev();
if (!dev_desc)
return -ENODEV;
ret = part_get_info_by_name(dev_desc, part_boot, &part_info);
if (ret < 0)
return ret;
hdr = populate_andr_img_hdr(dev_desc, &part_info);
if (hdr) {
#ifdef DEBUG
android_print_contents(hdr);
#endif
/*
* Google requires a/b system mandory from Android Header v3 for
* google authentication, that means there is not recovery.
*
* But for the products that don't care about google authentication,
* it's not mandory to use a/b system. So that we use the solution:
* boot.img(v3+) with recovery(v2).
*
* [recovery_dtbo fields]
* recovery.img with boot_img_hdr_v1,2: supported
* recovery.img with boot_img_hdr_v0,3+: illegal
*/
if ((hdr->header_version == 0) ||
(hdr->header_version >= 3 && !strcmp(part_boot, PART_RECOVERY)))
goto out;
}
#ifdef CONFIG_VENDOR_FRIENDLYELEC
if (part_get_info_by_name(dev_desc, PART_DTBO, &part_info) > 0) {
part_dtbo = PART_DTBO;
} else {
printf("No %s partition\n", PART_DTBO);
}
#endif
ret = android_get_dtbo(&fdt_dtbo, (void *)hdr, &index, part_dtbo);
if (!ret) {
phys_size_t fdt_size;
/* Must incease size before overlay */
fdt_size = fdt_totalsize((void *)fdt_addr) +
fdt_totalsize((void *)fdt_dtbo);
if (sysmem_free((phys_addr_t)fdt_addr))
goto out;
if (!sysmem_alloc_base(MEM_FDT_DTBO,
(phys_addr_t)fdt_addr,
fdt_size + CONFIG_SYS_FDT_PAD))
goto out;
/*
* Backup main fdt in case of being destroyed by
* fdt_overlay_apply() when it overlys failed.
*/
totalsize = fdt_totalsize(fdt_addr);
fdt_backup = malloc(totalsize);
if (!fdt_backup)
goto out;
memcpy(fdt_backup, fdt_addr, totalsize);
fdt_increase_size(fdt_addr, fdt_totalsize((void *)fdt_dtbo));
ret = fdt_overlay_apply(fdt_addr, (void *)fdt_dtbo);
if (!ret) {
snprintf(buf, 32, "%s%d", "androidboot.dtbo_idx=", index);
env_update("bootargs", buf);
printf("ANDROID: fdt overlay OK\n");
} else {
memcpy(fdt_addr, fdt_backup, totalsize);
printf("ANDROID: fdt overlay failed, ret=%d\n", ret);
}
free(fdt_backup);
}
out:
if (hdr)
free(hdr);
return 0;
}
#endif
int android_image_load_by_partname(struct blk_desc *dev_desc,
const char *boot_partname,
unsigned long *load_address)
{
disk_partition_t boot_part;
int ret, part_num;
part_num = part_get_info_by_name(dev_desc, boot_partname, &boot_part);
if (part_num < 0) {
printf("%s: Can't find part: %s\n", __func__, boot_partname);
return -1;
}
debug("ANDROID: Loading kernel from \"%s\", partition %d.\n",
boot_part.name, part_num);
ret = android_image_load(dev_desc, &boot_part, *load_address, -1UL);
if (ret < 0) {
debug("%s: %s part load fail, ret=%d\n",
__func__, boot_part.name, ret);
return ret;
}
*load_address = ret;
return 0;
}
int android_bootloader_boot_flow(struct blk_desc *dev_desc,
unsigned long load_address)
{
enum android_boot_mode mode = ANDROID_BOOT_MODE_NORMAL;
disk_partition_t misc_part_info;
int part_num;
char *command_line;
char slot_suffix[3] = {0};
const char *mode_cmdline = NULL;
char *boot_partname = ANDROID_PARTITION_BOOT;
/*
* 1. Load MISC partition and determine the boot mode
* clear its value for the next boot if needed.
*/
part_num = part_get_info_by_name(dev_desc, ANDROID_PARTITION_MISC,
&misc_part_info);
if (part_num < 0) {
printf("Could not find misc partition\n");
} else {
#ifdef CONFIG_ANDROID_KEYMASTER_CA
/* load attestation key from misc partition. */
load_attestation_key(dev_desc, &misc_part_info);
#endif
mode = android_bootloader_load_and_clear_mode(dev_desc,
&misc_part_info);
#ifdef CONFIG_RKIMG_BOOTLOADER
if (mode == ANDROID_BOOT_MODE_NORMAL) {
if (rockchip_get_boot_mode() == BOOT_MODE_RECOVERY)
mode = ANDROID_BOOT_MODE_RECOVERY;
}
#endif
}
printf("ANDROID: reboot reason: \"%s\"\n", android_boot_mode_str(mode));
#ifdef CONFIG_ANDROID_AB
/* Get current slot_suffix */
if (ab_get_slot_suffix(slot_suffix))
return -1;
#endif
switch (mode) {
case ANDROID_BOOT_MODE_NORMAL:
/* In normal mode, we load the kernel from "boot" but append
* "skip_initramfs" to the cmdline to make it ignore the
* recovery initramfs in the boot partition.
*/
#ifdef CONFIG_ANDROID_AB
/* In A/B, the recovery image is built as boot.img, containing the
* recovery's ramdisk. Previously, bootloader used the skip_initramfs
* kernel command line parameter to decide which mode to boot into.
* For Android >=10 and with dynamic partition support, the bootloader
* MUST NOT pass skip_initramfs to the kernel command-line.
* Instead, bootloader should pass androidboot.force_normal_boot=1
* and then Android's first-stage init in ramdisk
* will skip recovery and boot normal Android.
*/
if (ab_is_support_dynamic_partition(dev_desc)) {
mode_cmdline = "androidboot.force_normal_boot=1";
} else {
mode_cmdline = "skip_initramfs";
}
#endif
break;
case ANDROID_BOOT_MODE_RECOVERY:
/*
* In recovery mode, if have recovery partition, we still boot the
* kernel from "recovery". If not, don't skip the initramfs so it
* boots to recovery from image in partition "boot".
*/
#ifdef CONFIG_ANDROID_AB
boot_partname = ab_can_find_recovery_part() ?
ANDROID_PARTITION_RECOVERY : ANDROID_PARTITION_BOOT;
#else
boot_partname = ANDROID_PARTITION_RECOVERY;
#endif
break;
case ANDROID_BOOT_MODE_BOOTLOADER:
/* Bootloader mode enters fastboot. If this operation fails we
* simply return since we can't recover from this situation by
* switching to another slot.
*/
return android_bootloader_boot_bootloader();
}
#ifdef CONFIG_ANDROID_AVB
uint8_t vboot_flag = 0;
disk_partition_t vbmeta_part_info;
#ifdef CONFIG_OPTEE_CLIENT
if (trusty_read_vbootkey_enable_flag(&vboot_flag)) {
printf("Can't read vboot flag\n");
return -1;
}
#endif
if (vboot_flag) {
printf("Vboot=1, SecureBoot enabled, AVB verify\n");
if (android_slot_verify(boot_partname, &load_address,
slot_suffix)) {
printf("AVB verify failed\n");
return -1;
}
} else {
part_num = part_get_info_by_name(dev_desc,
ANDROID_PARTITION_VBMETA,
&vbmeta_part_info);
if (part_num < 0) {
printf("Not AVB images, AVB skip\n");
env_update("bootargs",
"androidboot.verifiedbootstate=orange");
if (android_image_load_by_partname(dev_desc,
boot_partname,
&load_address)) {
printf("Android image load failed\n");
return -1;
}
} else {
printf("Vboot=0, AVB images, AVB verify\n");
if (android_slot_verify(boot_partname, &load_address,
slot_suffix)) {
printf("AVB verify failed\n");
return -1;
}
}
}
#else
/*
* 2. Load the boot/recovery from the desired "boot" partition.
* Determine if this is an AOSP image.
*/
if (android_image_load_by_partname(dev_desc,
boot_partname,
&load_address)) {
printf("Android image load failed\n");
return -1;
}
#endif
/* Set Android root variables. */
env_set_ulong("android_root_devnum", dev_desc->devnum);
env_set("android_slotsufix", slot_suffix);
#ifdef CONFIG_FASTBOOT_OEM_UNLOCK
/* read oem unlock status and attach to bootargs */
uint8_t unlock = 0;
TEEC_Result result;
char oem_unlock[OEM_UNLOCK_ARG_SIZE] = {0};
result = trusty_read_oem_unlock(&unlock);
if (result) {
printf("read oem unlock status with error : 0x%x\n", result);
} else {
snprintf(oem_unlock, OEM_UNLOCK_ARG_SIZE, "androidboot.oem_unlocked=%d", unlock);
env_update("bootargs", oem_unlock);
}
#endif
/* Assemble the command line */
command_line = android_assemble_cmdline(slot_suffix, mode_cmdline);
env_update("bootargs", command_line);
debug("ANDROID: bootargs: \"%s\"\n", command_line);
#ifdef CONFIG_SUPPORT_OEM_DTB
if (android_bootloader_get_fdt(ANDROID_PARTITION_OEM,
ANDROID_ARG_FDT_FILENAME)) {
printf("Can not get the fdt data from oem!\n");
}
#endif
#ifdef CONFIG_OPTEE_CLIENT
if (trusty_notify_optee_uboot_end())
printf("Close optee client failed!\n");
#endif
#ifdef CONFIG_AMP
return android_bootloader_boot_kernel(load_address);
#else
android_bootloader_boot_kernel(load_address);
/* TODO: If the kernel doesn't boot mark the selected slot as bad. */
return -1;
#endif
}
int android_avb_boot_flow(unsigned long kernel_address)
{
struct blk_desc *dev_desc;
disk_partition_t boot_part_info;
int ret;
dev_desc = rockchip_get_bootdev();
if (!dev_desc) {
printf("%s: dev_desc is NULL!\n", __func__);
return -1;
}
/* Load the kernel from the desired "boot" partition. */
ret = part_get_info_by_name(dev_desc, ANDROID_PARTITION_BOOT,
&boot_part_info);
if (ret < 0) {
printf("%s: failed to get boot part\n", __func__);
return ret;
}
ret = android_image_load(dev_desc, &boot_part_info,
kernel_address, -1UL);
if (ret < 0) {
printf("Android avb boot failed, error %d.\n", ret);
return ret;
}
android_bootloader_boot_kernel(kernel_address);
/* TODO: If the kernel doesn't boot mark the selected slot as bad. */
return -1;
}
int android_boot_flow(unsigned long kernel_address)
{
struct blk_desc *dev_desc;
disk_partition_t boot_part_info;
int ret;
dev_desc = rockchip_get_bootdev();
if (!dev_desc) {
printf("%s: dev_desc is NULL!\n", __func__);
return -1;
}
/* Load the kernel from the desired "boot" partition. */
ret = part_get_info_by_name(dev_desc, ANDROID_PARTITION_BOOT,
&boot_part_info);
if (ret < 0) {
printf("%s: failed to get boot part\n", __func__);
return ret;
}
ret = android_image_load(dev_desc, &boot_part_info, kernel_address,
-1UL);
if (ret < 0)
return ret;
android_bootloader_boot_kernel(kernel_address);
/* TODO: If the kernel doesn't boot mark the selected slot as bad. */
return -1;
}