blob: deb0cbdb8f7cf3c9dc556dc95574b5636ad4e32e [file] [log] [blame]
/*
* Copyright (C) 2018 Marvell International Ltd.
*
* SPDX-License-Identifier: BSD-3-Clause
* https://spdx.org/licenses
*/
#include <stdlib.h>
#include <stdio.h>
#include <stdint.h>
#include <stddef.h>
#include <string.h>
#include <unistd.h>
#include <sys/stat.h>
#include <sys/time.h>
#ifdef CONFIG_MVEBU_SECURE_BOOT
#include <libconfig.h> /* for parsing config file */
#if !defined(MBEDTLS_CONFIG_FILE)
#include "mbedtls/config.h"
#else
#include MBEDTLS_CONFIG_FILE
#endif
/* mbedTLS stuff */
#if defined(MBEDTLS_BIGNUM_C) && defined(MBEDTLS_ENTROPY_C) && \
defined(MBEDTLS_SHA256_C) && \
defined(MBEDTLS_PK_PARSE_C) && defined(MBEDTLS_FS_IO) && \
defined(MBEDTLS_CTR_DRBG_C)
#include <mbedtls/error.h>
#include <mbedtls/entropy.h>
#include <mbedtls/ctr_drbg.h>
#include <mbedtls/md.h>
#include <mbedtls/pk.h>
#include <mbedtls/sha256.h>
#include <mbedtls/x509.h>
#else
#error "Bad mbedTLS configuration!"
#endif
#endif /* CONFIG_MVEBU_SECURE_BOOT */
#define MAX_FILENAME 256
#define CSK_ARR_SZ 16
#define CSK_ARR_EMPTY_FILE "*"
#define AES_KEY_BIT_LEN 256
#define AES_KEY_BYTE_LEN (AES_KEY_BIT_LEN >> 3)
#define AES_BLOCK_SZ 16
#define RSA_SIGN_BYTE_LEN 256
#define MAX_RSA_DER_BYTE_LEN 524
/* Number of address pairs in control array */
#define CP_CTRL_EL_ARRAY_SZ 32
#define VERSION_STRING "Marvell(C) doimage utility version 3.3"
/* A8K definitions */
/* Extension header types */
#define EXT_TYPE_SECURITY 0x1
#define EXT_TYPE_BINARY 0x2
#define MAIN_HDR_MAGIC 0xB105B002
/* PROLOG alignment considerations:
* 128B: To allow supporting XMODEM protocol.
* 8KB: To align the boot image to the largest NAND page size, and simplify
* the read operations from NAND.
* We choose the largest page size, in order to use a single image for all
* NAND page sizes.
*/
#define PROLOG_ALIGNMENT (8 << 10)
/* UART argument bitfield */
#define UART_MODE_UNMODIFIED 0x0
#define UART_MODE_DISABLE 0x1
#define UART_MODE_UPDATE 0x2
typedef struct _main_header {
uint32_t magic; /* 0-3 */
uint32_t prolog_size; /* 4-7 */
uint32_t prolog_checksum; /* 8-11 */
uint32_t boot_image_size; /* 12-15 */
uint32_t boot_image_checksum; /* 16-19 */
uint32_t rsrvd0; /* 20-23 */
uint32_t load_addr; /* 24-27 */
uint32_t exec_addr; /* 28-31 */
uint8_t uart_cfg; /* 32 */
uint8_t baudrate; /* 33 */
uint8_t ext_count; /* 34 */
uint8_t aux_flags; /* 35 */
uint32_t io_arg_0; /* 36-39 */
uint32_t io_arg_1; /* 40-43 */
uint32_t io_arg_2; /* 43-47 */
uint32_t io_arg_3; /* 48-51 */
uint32_t rsrvd1; /* 52-55 */
uint32_t rsrvd2; /* 56-59 */
uint32_t rsrvd3; /* 60-63 */
} header_t;
typedef struct _ext_header {
uint8_t type;
uint8_t offset;
uint16_t reserved;
uint32_t size;
} ext_header_t;
typedef struct _sec_entry {
uint8_t kak_key[MAX_RSA_DER_BYTE_LEN];
uint32_t jtag_delay;
uint32_t box_id;
uint32_t flash_id;
uint32_t jtag_en;
uint32_t encrypt_en;
uint32_t efuse_dis;
uint8_t header_sign[RSA_SIGN_BYTE_LEN];
uint8_t image_sign[RSA_SIGN_BYTE_LEN];
uint8_t csk_keys[CSK_ARR_SZ][MAX_RSA_DER_BYTE_LEN];
uint8_t csk_sign[RSA_SIGN_BYTE_LEN];
uint32_t cp_ctrl_arr[CP_CTRL_EL_ARRAY_SZ];
uint32_t cp_efuse_arr[CP_CTRL_EL_ARRAY_SZ];
} sec_entry_t;
/* A8K definitions end */
/* UART argument bitfield */
#define UART_MODE_UNMODIFIED 0x0
#define UART_MODE_DISABLE 0x1
#define UART_MODE_UPDATE 0x2
#define uart_set_mode(arg, mode) (arg |= (mode & 0x3))
typedef struct _sec_options {
#ifdef CONFIG_MVEBU_SECURE_BOOT
char aes_key_file[MAX_FILENAME+1];
char kak_key_file[MAX_FILENAME+1];
char csk_key_file[CSK_ARR_SZ][MAX_FILENAME+1];
uint32_t box_id;
uint32_t flash_id;
uint32_t jtag_delay;
uint8_t csk_index;
uint8_t jtag_enable;
uint8_t efuse_disable;
uint32_t cp_ctrl_arr[CP_CTRL_EL_ARRAY_SZ];
uint32_t cp_efuse_arr[CP_CTRL_EL_ARRAY_SZ];
mbedtls_pk_context kak_pk;
mbedtls_pk_context csk_pk[CSK_ARR_SZ];
uint8_t aes_key[AES_KEY_BYTE_LEN];
uint8_t *encrypted_image;
uint32_t enc_image_sz;
#endif
} sec_options;
typedef struct _options {
char bin_ext_file[MAX_FILENAME+1];
char sec_cfg_file[MAX_FILENAME+1];
sec_options *sec_opts;
uint32_t load_addr;
uint32_t exec_addr;
uint32_t baudrate;
uint8_t disable_print;
int8_t key_index; /* For header signatures verification only */
uint32_t nfc_io_args;
} options_t;
void usage_err(char *msg)
{
fprintf(stderr, "Error: %s\n", msg);
fprintf(stderr, "run 'doimage -h' to get usage information\n");
exit(-1);
}
void usage(void)
{
printf("\n\n%s\n\n", VERSION_STRING);
printf("Usage: doimage [options] <input_file> [output_file]\n");
printf("create bootrom image from u-boot and boot extensions\n\n");
printf("Arguments\n");
printf(" input_file name of boot image file.\n");
printf(" if -p is used, name of the bootrom image file");
printf(" to parse.\n");
printf(" output_file name of output bootrom image file\n");
printf("\nOptions\n");
printf(" -s target SOC name. supports a8020,a7020\n");
printf(" different SOCs may have different boot image\n");
printf(" format so it's mandatory to know the target SOC\n");
printf(" -i boot I/F name. supports nand, spi, nor\n");
printf(" This affects certain parameters coded in the\n");
printf(" image header\n");
printf(" -l boot image load address. default is 0x0\n");
printf(" -e boot image entry address. default is 0x0\n");
printf(" -b binary extension image file.\n");
printf(" This image is executed before the boot image.\n");
printf(" This is typically used to initialize the memory ");
printf(" controller.\n");
printf(" Currently supports only a single file.\n");
#ifdef CONFIG_MVEBU_SECURE_BOOT
printf(" -c Make trusted boot image using parameters\n");
printf(" from the configuration file.\n");
#endif
printf(" -p Parse and display a pre-built boot image\n");
#ifdef CONFIG_MVEBU_SECURE_BOOT
printf(" -k Key index for RSA signatures verification\n");
printf(" when parsing the boot image\n");
#endif
printf(" -m Disable prints of bootrom and binary extension\n");
printf(" -u UART baudrate used for bootrom prints.\n");
printf(" Must be multiple of 1200\n");
printf(" -h Show this help message\n");
printf(" IO-ROM NFC-NAND boot parameters:\n");
printf(" -n NAND device block size in KB [Default is 64KB].\n");
printf(" -t NAND cell technology (SLC [Default] or MLC)\n");
exit(-1);
}
/* globals */
static options_t opts = {
.bin_ext_file = "NA",
.sec_cfg_file = "NA",
.sec_opts = 0,
.load_addr = 0x0,
.exec_addr = 0x0,
.disable_print = 0,
.baudrate = 0,
.key_index = -1,
};
int get_file_size(char *filename)
{
struct stat st;
if (stat(filename, &st) == 0)
return st.st_size;
return -1;
}
uint32_t checksum32(uint32_t *start, int len)
{
uint32_t sum = 0;
uint32_t *startp = start;
do {
sum += *startp;
startp++;
len -= 4;
} while (len > 0);
return sum;
}
/*******************************************************************************
* create_rsa_signature (memory buffer content)
* Create RSASSA-PSS/SHA-256 signature for memory buffer
* using RSA Private Key
* INPUT:
* pk_ctx Private Key context
* input memory buffer
* ilen buffer length
* pers personalization string for seeding the RNG.
* For instance a private key file name.
* OUTPUT:
* signature RSA-2048 signature
* RETURN:
* 0 on success
*/
#ifdef CONFIG_MVEBU_SECURE_BOOT
int create_rsa_signature(mbedtls_pk_context *pk_ctx,
const unsigned char *input,
size_t ilen,
const char *pers,
uint8_t *signature)
{
mbedtls_entropy_context entropy;
mbedtls_ctr_drbg_context ctr_drbg;
unsigned char hash[32];
unsigned char buf[MBEDTLS_MPI_MAX_SIZE];
int rval;
/* Not sure this is required,
* but it's safer to start with empty buffers
*/
memset(hash, 0, sizeof(hash));
memset(buf, 0, sizeof(buf));
mbedtls_ctr_drbg_init(&ctr_drbg);
mbedtls_entropy_init(&entropy);
/* Seed the random number generator */
rval = mbedtls_ctr_drbg_seed(&ctr_drbg, mbedtls_entropy_func, &entropy,
(const unsigned char *)pers, strlen(pers));
if (rval != 0) {
fprintf(stderr, " Failed in ctr_drbg_init call (%d)!\n", rval);
goto sign_exit;
}
/* The PK context should be already initialized.
* Set the padding type for this PK context
*/
mbedtls_rsa_set_padding(mbedtls_pk_rsa(*pk_ctx),
MBEDTLS_RSA_PKCS_V21, MBEDTLS_MD_SHA256);
/* First compute the SHA256 hash for the input blob */
mbedtls_sha256_ret(input, ilen, hash, 0);
/* Then calculate the hash signature */
rval = mbedtls_rsa_rsassa_pss_sign(mbedtls_pk_rsa(*pk_ctx),
mbedtls_ctr_drbg_random,
&ctr_drbg,
MBEDTLS_RSA_PRIVATE,
MBEDTLS_MD_SHA256, 0, hash, buf);
if (rval != 0) {
fprintf(stderr,
"Failed to create RSA signature for %s. Error %d\n",
pers, rval);
goto sign_exit;
}
memcpy(signature, buf, 256);
sign_exit:
mbedtls_ctr_drbg_free(&ctr_drbg);
mbedtls_entropy_free(&entropy);
return rval;
} /* end of create_rsa_signature */
/*******************************************************************************
* verify_rsa_signature (memory buffer content)
* Verify RSASSA-PSS/SHA-256 signature for memory buffer
* using RSA Public Key
* INPUT:
* pub_key Public Key buffer
* ilen Public Key buffer length
* input memory buffer
* ilen buffer length
* pers personalization string for seeding the RNG.
* signature RSA-2048 signature
* OUTPUT:
* none
* RETURN:
* 0 on success
*/
int verify_rsa_signature(const unsigned char *pub_key,
size_t klen,
const unsigned char *input,
size_t ilen,
const char *pers,
uint8_t *signature)
{
mbedtls_entropy_context entropy;
mbedtls_ctr_drbg_context ctr_drbg;
mbedtls_pk_context pk_ctx;
unsigned char hash[32];
int rval;
unsigned char *pkey = (unsigned char *)pub_key;
/* Not sure this is required,
* but it's safer to start with empty buffer
*/
memset(hash, 0, sizeof(hash));
mbedtls_pk_init(&pk_ctx);
mbedtls_ctr_drbg_init(&ctr_drbg);
mbedtls_entropy_init(&entropy);
/* Seed the random number generator */
rval = mbedtls_ctr_drbg_seed(&ctr_drbg, mbedtls_entropy_func, &entropy,
(const unsigned char *)pers, strlen(pers));
if (rval != 0) {
fprintf(stderr, " Failed in ctr_drbg_init call (%d)!\n", rval);
goto verify_exit;
}
/* Check ability to read the public key */
rval = mbedtls_pk_parse_subpubkey(&pkey, pub_key + klen, &pk_ctx);
if (rval != 0) {
fprintf(stderr, " Failed in pk_parse_public_key (%#x)!\n",
rval);
goto verify_exit;
}
/* Set the padding type for the new PK context */
mbedtls_rsa_set_padding(mbedtls_pk_rsa(pk_ctx),
MBEDTLS_RSA_PKCS_V21,
MBEDTLS_MD_SHA256);
/* Compute the SHA256 hash for the input buffer */
mbedtls_sha256_ret(input, ilen, hash, 0);
rval = mbedtls_rsa_rsassa_pss_verify(mbedtls_pk_rsa(pk_ctx),
mbedtls_ctr_drbg_random,
&ctr_drbg,
MBEDTLS_RSA_PUBLIC,
MBEDTLS_MD_SHA256, 0,
hash, signature);
if (rval != 0)
fprintf(stderr, "Failed to verify signature (%d)!\n", rval);
verify_exit:
mbedtls_pk_free(&pk_ctx);
mbedtls_ctr_drbg_free(&ctr_drbg);
mbedtls_entropy_free(&entropy);
return rval;
} /* end of verify_rsa_signature */
/*******************************************************************************
* image_encrypt
* Encrypt image buffer using AES-256-CBC scheme.
* The resulting image is saved into opts.sec_opts->encrypted_image
* and the adjusted image size into opts.sec_opts->enc_image_sz
* First AES_BLOCK_SZ bytes of the output image contain IV
* INPUT:
* buf Source buffer to encrypt
* blen Source buffer length
* OUTPUT:
* none
* RETURN:
* 0 on success
*/
int image_encrypt(uint8_t *buf, uint32_t blen)
{
struct timeval tv;
char *ptmp = (char *)&tv;
unsigned char digest[32];
unsigned char IV[AES_BLOCK_SZ];
int i, k;
mbedtls_aes_context aes_ctx;
int rval = -1;
uint8_t *test_img = 0;
if (AES_BLOCK_SZ > 32) {
fprintf(stderr, "Unsupported AES block size %d\n",
AES_BLOCK_SZ);
return rval;
}
mbedtls_aes_init(&aes_ctx);
memset(IV, 0, AES_BLOCK_SZ);
memset(digest, 0, 32);
/* Generate initialization vector and init the AES engine
* Use file name XOR current time and finally SHA-256
* [0...AES_BLOCK_SZ-1]
*/
k = strlen(opts.sec_opts->aes_key_file);
if (k > AES_BLOCK_SZ)
k = AES_BLOCK_SZ;
memcpy(IV, opts.sec_opts->aes_key_file, k);
gettimeofday(&tv, 0);
for (i = 0, k = 0; i < AES_BLOCK_SZ; i++,
k = (k+1) % sizeof(struct timeval))
IV[i] ^= ptmp[k];
/* compute SHA-256 digest of the results
* and use it as the init vector (IV)
*/
mbedtls_sha256_ret(IV, AES_BLOCK_SZ, digest, 0);
memcpy(IV, digest, AES_BLOCK_SZ);
mbedtls_aes_setkey_enc(&aes_ctx, opts.sec_opts->aes_key,
AES_KEY_BIT_LEN);
/* The output image has to include extra space for IV
* and to be aligned to the AES block size.
* The input image buffer has to be already aligned to AES_BLOCK_SZ
* and padded with zeroes
*/
opts.sec_opts->enc_image_sz = (blen + 2 * AES_BLOCK_SZ - 1) &
~(AES_BLOCK_SZ - 1);
opts.sec_opts->encrypted_image = calloc(opts.sec_opts->enc_image_sz, 1);
if (opts.sec_opts->encrypted_image == 0) {
fprintf(stderr, "Failed to allocate encrypted image!\n");
goto encrypt_exit;
}
/* Put IV into the output buffer next to the encrypted image
* Since the IV is modified by the encryption function,
* this should be done now
*/
memcpy(opts.sec_opts->encrypted_image +
opts.sec_opts->enc_image_sz - AES_BLOCK_SZ,
IV, AES_BLOCK_SZ);
rval = mbedtls_aes_crypt_cbc(&aes_ctx, MBEDTLS_AES_ENCRYPT,
opts.sec_opts->enc_image_sz - AES_BLOCK_SZ,
IV, buf, opts.sec_opts->encrypted_image);
if (rval != 0) {
fprintf(stderr, "Failed to encrypt the image! Error %d\n",
rval);
goto encrypt_exit;
}
mbedtls_aes_free(&aes_ctx);
/* Try to decrypt the image and compare it with the original data */
mbedtls_aes_init(&aes_ctx);
mbedtls_aes_setkey_dec(&aes_ctx, opts.sec_opts->aes_key,
AES_KEY_BIT_LEN);
test_img = calloc(opts.sec_opts->enc_image_sz - AES_BLOCK_SZ, 1);
if (test_img == 0) {
fprintf(stderr, "Failed to allocate test image!d\n");
rval = -1;
goto encrypt_exit;
}
memcpy(IV, opts.sec_opts->encrypted_image +
opts.sec_opts->enc_image_sz - AES_BLOCK_SZ,
AES_BLOCK_SZ);
rval = mbedtls_aes_crypt_cbc(&aes_ctx, MBEDTLS_AES_DECRYPT,
opts.sec_opts->enc_image_sz - AES_BLOCK_SZ,
IV, opts.sec_opts->encrypted_image, test_img);
if (rval != 0) {
fprintf(stderr, "Failed to decrypt the image! Error %d\n",
rval);
goto encrypt_exit;
}
for (i = 0; i < blen; i++) {
if (buf[i] != test_img[i]) {
fprintf(stderr, "Failed to compare the image after");
fprintf(stderr, " decryption! Byte count is %d\n", i);
rval = -1;
goto encrypt_exit;
}
}
encrypt_exit:
mbedtls_aes_free(&aes_ctx);
if (test_img)
free(test_img);
return rval;
} /* end of image_encrypt */
/*******************************************************************************
* verify_secure_header_signatures
* Verify CSK array, header and image signatures and print results
* INPUT:
* main_hdr Main header
* sec_ext Secure extension
* OUTPUT:
* none
* RETURN:
* 0 on success
*/
int verify_secure_header_signatures(header_t *main_hdr, sec_entry_t *sec_ext)
{
uint8_t *image = (uint8_t *)main_hdr + main_hdr->prolog_size;
uint8_t signature[RSA_SIGN_BYTE_LEN];
int rval = -1;
/* Save headers signature and reset it in the secure header */
memcpy(signature, sec_ext->header_sign, RSA_SIGN_BYTE_LEN);
memset(sec_ext->header_sign, 0, RSA_SIGN_BYTE_LEN);
fprintf(stdout, "\nCheck RSA Signatures\n");
fprintf(stdout, "#########################\n");
fprintf(stdout, "CSK Block Signature: ");
if (verify_rsa_signature(sec_ext->kak_key,
MAX_RSA_DER_BYTE_LEN,
&sec_ext->csk_keys[0][0],
sizeof(sec_ext->csk_keys),
"CSK Block Signature: ",
sec_ext->csk_sign) != 0) {
fprintf(stdout, "ERROR\n");
goto ver_error;
}
fprintf(stdout, "OK\n");
if (opts.key_index != -1) {
fprintf(stdout, "Image Signature: ");
if (verify_rsa_signature(sec_ext->csk_keys[opts.key_index],
MAX_RSA_DER_BYTE_LEN,
image, main_hdr->boot_image_size,
"Image Signature: ",
sec_ext->image_sign) != 0) {
fprintf(stdout, "ERROR\n");
goto ver_error;
}
fprintf(stdout, "OK\n");
fprintf(stdout, "Header Signature: ");
if (verify_rsa_signature(sec_ext->csk_keys[opts.key_index],
MAX_RSA_DER_BYTE_LEN,
(uint8_t *)main_hdr,
main_hdr->prolog_size,
"Header Signature: ",
signature) != 0) {
fprintf(stdout, "ERROR\n");
goto ver_error;
}
fprintf(stdout, "OK\n");
} else {
fprintf(stdout, "SKIP Image and Header Signatures");
fprintf(stdout, " check (undefined key index)\n");
}
rval = 0;
ver_error:
memcpy(sec_ext->header_sign, signature, RSA_SIGN_BYTE_LEN);
return rval;
}
/*******************************************************************************
* verify_and_copy_file_name_entry
* INPUT:
* element_name
* element
* OUTPUT:
* copy_to
* RETURN:
* 0 on success
*/
int verify_and_copy_file_name_entry(const char *element_name,
const char *element, char *copy_to)
{
int element_length = strlen(element);
if (element_length >= MAX_FILENAME) {
fprintf(stderr, "The file name %s for %s is too long (%d). ",
element, element_name, element_length);
fprintf(stderr, "Maximum allowed %d characters!\n",
MAX_FILENAME);
return -1;
} else if (element_length == 0) {
fprintf(stderr, "The file name for %s is empty!\n",
element_name);
return -1;
}
memcpy(copy_to, element, element_length);
return 0;
}
/*******************************************************************************
* parse_sec_config_file
* Read the secure boot configuration from a file
* into internal structures
* INPUT:
* filename File name
* OUTPUT:
* none
* RETURN:
* 0 on success
*/
int parse_sec_config_file(char *filename)
{
config_t sec_cfg;
int array_sz, element, rval = -1;
const char *cfg_string;
int32_t cfg_int32;
const config_setting_t *csk_array, *control_array;
sec_options *sec_opt = 0;
config_init(&sec_cfg);
if (config_read_file(&sec_cfg, filename) != CONFIG_TRUE) {
fprintf(stderr, "Failed to read data from config file ");
fprintf(stderr, "%s\n\t%s at line %d\n",
filename, config_error_text(&sec_cfg),
config_error_line(&sec_cfg));
goto exit_parse;
}
sec_opt = (sec_options *)calloc(sizeof(sec_options), 1);
if (sec_opt == 0) {
fprintf(stderr,
"Cannot allocate memory for secure boot options!\n");
goto exit_parse;
}
/* KAK file name */
if (config_lookup_string(&sec_cfg, "kak_key_file",
&cfg_string) != CONFIG_TRUE) {
fprintf(stderr, "The \"kak_key_file\" undefined!\n");
goto exit_parse;
}
if (verify_and_copy_file_name_entry("kak_key_file",
cfg_string, sec_opt->kak_key_file))
goto exit_parse;
/* AES file name - can be empty/undefined */
if (config_lookup_string(&sec_cfg, "aes_key_file",
&cfg_string) == CONFIG_TRUE) {
if (verify_and_copy_file_name_entry("aes_key_file",
cfg_string,
sec_opt->aes_key_file))
goto exit_parse;
}
/* CSK file names array */
csk_array = config_lookup(&sec_cfg, "csk_key_file");
if (csk_array == NULL) {
fprintf(stderr, "The \"csk_key_file\" undefined!\n");
goto exit_parse;
}
array_sz = config_setting_length(csk_array);
if (array_sz > CSK_ARR_SZ) {
fprintf(stderr, "The \"csk_key_file\" array is too big! ");
fprintf(stderr, "Only first %d elements will be used\n",
CSK_ARR_SZ);
array_sz = CSK_ARR_SZ;
} else if (array_sz == 0) {
fprintf(stderr, "The \"csk_key_file\" array is empty!\n");
goto exit_parse;
}
for (element = 0; element < array_sz; element++) {
cfg_string = config_setting_get_string_elem(csk_array, element);
if (verify_and_copy_file_name_entry(
"csk_key_file", cfg_string,
sec_opt->csk_key_file[element])) {
fprintf(stderr, "Bad csk_key_file[%d] entry!\n",
element);
goto exit_parse;
}
}
/* JTAG options */
if (config_lookup_bool(&sec_cfg, "jtag.enable",
&cfg_int32) != CONFIG_TRUE) {
fprintf(stderr, "Error obtaining \"jtag.enable\" element. ");
fprintf(stderr, "Using default - FALSE\n");
cfg_int32 = 0;
}
sec_opt->jtag_enable = cfg_int32;
if (config_lookup_int(&sec_cfg, "jtag.delay",
&cfg_int32) != CONFIG_TRUE) {
fprintf(stderr, "Error obtaining \"jtag.delay\" element. ");
fprintf(stderr, "Using default - 0us\n");
cfg_int32 = 0;
}
sec_opt->jtag_delay = cfg_int32;
/* eFUSE option */
if (config_lookup_bool(&sec_cfg, "efuse_disable",
&cfg_int32) != CONFIG_TRUE) {
fprintf(stderr, "Error obtaining \"efuse_disable\" element. ");
fprintf(stderr, "Using default - TRUE\n");
cfg_int32 = 1;
}
sec_opt->efuse_disable = cfg_int32;
/* Box ID option */
if (config_lookup_int(&sec_cfg, "box_id", &cfg_int32) != CONFIG_TRUE) {
fprintf(stderr, "Error obtaining \"box_id\" element. ");
fprintf(stderr, "Using default - 0x0\n");
cfg_int32 = 0;
}
sec_opt->box_id = cfg_int32;
/* Flash ID option */
if (config_lookup_int(&sec_cfg, "flash_id",
&cfg_int32) != CONFIG_TRUE) {
fprintf(stderr, "Error obtaining \"flash_id\" element. ");
fprintf(stderr, "Using default - 0x0\n");
cfg_int32 = 0;
}
sec_opt->flash_id = cfg_int32;
/* CSK index option */
if (config_lookup_int(&sec_cfg, "csk_key_index",
&cfg_int32) != CONFIG_TRUE) {
fprintf(stderr, "Error obtaining \"flash_id\" element. ");
fprintf(stderr, "Using default - 0x0\n");
cfg_int32 = 0;
}
sec_opt->csk_index = cfg_int32;
/* Secure boot control array */
control_array = config_lookup(&sec_cfg, "control");
if (control_array != NULL) {
array_sz = config_setting_length(control_array);
if (array_sz == 0)
fprintf(stderr, "The \"control\" array is empty!\n");
} else {
fprintf(stderr, "The \"control\" is undefined!\n");
array_sz = 0;
}
for (element = 0; element < CP_CTRL_EL_ARRAY_SZ; element++) {
sec_opt->cp_ctrl_arr[element] =
config_setting_get_int_elem(control_array, element * 2);
sec_opt->cp_efuse_arr[element] =
config_setting_get_int_elem(control_array,
element * 2 + 1);
}
opts.sec_opts = sec_opt;
rval = 0;
exit_parse:
config_destroy(&sec_cfg);
if (sec_opt && (rval != 0))
free(sec_opt);
return rval;
} /* end of parse_sec_config_file */
int format_sec_ext(char *filename, FILE *out_fd)
{
ext_header_t header;
sec_entry_t sec_ext;
int index;
int written;
#define DER_BUF_SZ 1600
/* First, parse the configuration file */
if (parse_sec_config_file(filename)) {
fprintf(stderr,
"failed parsing configuration file %s\n", filename);
return 1;
}
/* Everything except signatures can be created at this stage */
header.type = EXT_TYPE_SECURITY;
header.offset = 0;
header.size = sizeof(sec_entry_t);
header.reserved = 0;
/* Bring up RSA context and read private keys from their files */
for (index = 0; index < (CSK_ARR_SZ + 1); index++) {
/* for every private key file */
mbedtls_pk_context *pk_ctx = (index == CSK_ARR_SZ) ?
&opts.sec_opts->kak_pk :
&opts.sec_opts->csk_pk[index];
char *fname = (index == CSK_ARR_SZ) ?
opts.sec_opts->kak_key_file :
opts.sec_opts->csk_key_file[index];
uint8_t *out_der_key = (index == CSK_ARR_SZ) ?
sec_ext.kak_key :
sec_ext.csk_keys[index];
size_t output_len;
unsigned char output_buf[DER_BUF_SZ];
unsigned char *der_buf_start;
/* Handle invalid/reserved file names */
if (strncmp(CSK_ARR_EMPTY_FILE, fname,
strlen(CSK_ARR_EMPTY_FILE)) == 0) {
if (opts.sec_opts->csk_index == index) {
fprintf(stderr,
"CSK file with index %d cannot be %s\n",
index, CSK_ARR_EMPTY_FILE);
return 1;
} else if (index == CSK_ARR_SZ) {
fprintf(stderr, "KAK file name cannot be %s\n",
CSK_ARR_EMPTY_FILE);
return 1;
}
/* this key will be empty in CSK array */
continue;
}
mbedtls_pk_init(pk_ctx);
/* Read the private RSA key into the context
* and verify it (no password)
*/
if (mbedtls_pk_parse_keyfile(pk_ctx, fname, "") != 0) {
fprintf(stderr,
"Cannot read RSA private key file %s\n", fname);
return 1;
}
/* Create a public key out of private one
* and store it in DER format
*/
output_len = mbedtls_pk_write_pubkey_der(pk_ctx,
output_buf,
DER_BUF_SZ);
if (output_len < 0) {
fprintf(stderr,
"Failed to create DER coded PUB key (%s)\n",
fname);
return 1;
}
/* Data in the output buffer is aligned to the buffer end */
der_buf_start = output_buf + sizeof(output_buf) - output_len;
/* In the header DER data is aligned
* to the start of appropriate field
*/
bzero(out_der_key, MAX_RSA_DER_BYTE_LEN);
memcpy(out_der_key, der_buf_start, output_len);
} /* for every private key file */
/* The CSK block signature can be created here */
if (create_rsa_signature(&opts.sec_opts->kak_pk,
&sec_ext.csk_keys[0][0],
sizeof(sec_ext.csk_keys),
opts.sec_opts->csk_key_file[
opts.sec_opts->csk_index],
sec_ext.csk_sign) != 0) {
fprintf(stderr, "Failed to sign CSK keys block!\n");
return 1;
}
/* Check that everything is correct */
if (verify_rsa_signature(sec_ext.kak_key,
MAX_RSA_DER_BYTE_LEN,
&sec_ext.csk_keys[0][0],
sizeof(sec_ext.csk_keys),
opts.sec_opts->kak_key_file,
sec_ext.csk_sign) != 0) {
fprintf(stderr, "Failed to verify CSK keys block signature!\n");
return 1;
}
/* AES encryption stuff */
if (strlen(opts.sec_opts->aes_key_file) != 0) {
FILE *in_fd;
in_fd = fopen(opts.sec_opts->aes_key_file, "rb");
if (in_fd == NULL) {
fprintf(stderr, "Failed to open AES key file %s\n",
opts.sec_opts->aes_key_file);
return 1;
}
/* Read the AES key in ASCII format byte by byte */
for (index = 0; index < AES_KEY_BYTE_LEN; index++) {
if (fscanf(in_fd, "%02hhx",
opts.sec_opts->aes_key + index) != 1) {
fprintf(stderr,
"Failed to read AES key byte %d ",
index);
fprintf(stderr,
"from file %s\n",
opts.sec_opts->aes_key_file);
fclose(in_fd);
return 1;
}
}
fclose(in_fd);
sec_ext.encrypt_en = 1;
} else {
sec_ext.encrypt_en = 0;
}
/* Fill the rest of the trusted boot extension fields */
sec_ext.box_id = opts.sec_opts->box_id;
sec_ext.flash_id = opts.sec_opts->flash_id;
sec_ext.efuse_dis = opts.sec_opts->efuse_disable;
sec_ext.jtag_delay = opts.sec_opts->jtag_delay;
sec_ext.jtag_en = opts.sec_opts->jtag_enable;
memcpy(sec_ext.cp_ctrl_arr,
opts.sec_opts->cp_ctrl_arr,
sizeof(uint32_t) * CP_CTRL_EL_ARRAY_SZ);
memcpy(sec_ext.cp_efuse_arr,
opts.sec_opts->cp_efuse_arr,
sizeof(uint32_t) * CP_CTRL_EL_ARRAY_SZ);
/* Write the resulting extension to file
* (image and header signature fields are still empty)
*/
/* Write extension header */
written = fwrite(&header, sizeof(ext_header_t), 1, out_fd);
if (written != 1) {
fprintf(stderr,
"Failed to write SEC extension header to the file\n");
return 1;
}
/* Write extension body */
written = fwrite(&sec_ext, sizeof(sec_entry_t), 1, out_fd);
if (written != 1) {
fprintf(stderr,
"Failed to write SEC extension body to the file\n");
return 1;
}
return 0;
}
/*******************************************************************************
* finalize_secure_ext
* Make final changes to secure extension - calculate image and header
* signatures and encrypt the image if needed.
* The main header checksum and image size fields updated accordingly
* INPUT:
* header Main header
* prolog_buf the entire prolog buffer
* prolog_size prolog buffer length
* image_buf buffer containing the input binary image
* image_size image buffer size.
* OUTPUT:
* none
* RETURN:
* 0 on success
*/
int finalize_secure_ext(header_t *header,
uint8_t *prolog_buf, uint32_t prolog_size,
uint8_t *image_buf, int image_size)
{
int cur_ext, offset;
uint8_t *final_image = image_buf;
uint32_t final_image_sz = image_size;
uint8_t hdr_sign[RSA_SIGN_BYTE_LEN];
sec_entry_t *sec_ext = 0;
/* Find the Trusted Boot Header between available extensions */
for (cur_ext = 0, offset = sizeof(header_t);
cur_ext < header->ext_count; cur_ext++) {
ext_header_t *ext_hdr = (ext_header_t *)(prolog_buf + offset);
if (ext_hdr->type == EXT_TYPE_SECURITY) {
sec_ext = (sec_entry_t *)(prolog_buf + offset +
sizeof(ext_header_t) + ext_hdr->offset);
break;
}
offset += sizeof(ext_header_t);
/* If offset is Zero, the extension follows its header */
if (ext_hdr->offset == 0)
offset += ext_hdr->size;
}
if (sec_ext == 0) {
fprintf(stderr, "Error: No Trusted Boot extension found!\n");
return -1;
}
if (sec_ext->encrypt_en) {
/* Encrypt the image if needed */
fprintf(stdout, "Encrypting the image...\n");
if (image_encrypt(image_buf, image_size) != 0) {
fprintf(stderr, "Failed to encrypt the image!\n");
return -1;
}
/* Image size and checksum should be updated after encryption.
* This way the image could be verified by the BootROM
* before decryption.
*/
final_image = opts.sec_opts->encrypted_image;
final_image_sz = opts.sec_opts->enc_image_sz;
header->boot_image_size = final_image_sz;
header->boot_image_checksum =
checksum32((uint32_t *)final_image, final_image_sz);
} /* AES encryption */
/* Create the image signature first, since it will be later
* signed along with the header signature
*/
if (create_rsa_signature(&opts.sec_opts->csk_pk[
opts.sec_opts->csk_index],
final_image, final_image_sz,
opts.sec_opts->csk_key_file[
opts.sec_opts->csk_index],
sec_ext->image_sign) != 0) {
fprintf(stderr, "Failed to sign image!\n");
return -1;
}
/* Check that the image signature is correct */
if (verify_rsa_signature(sec_ext->csk_keys[opts.sec_opts->csk_index],
MAX_RSA_DER_BYTE_LEN,
final_image, final_image_sz,
opts.sec_opts->csk_key_file[
opts.sec_opts->csk_index],
sec_ext->image_sign) != 0) {
fprintf(stderr, "Failed to verify image signature!\n");
return -1;
}
/* Sign the headers and all the extensions block
* when the header signature field is empty
*/
if (create_rsa_signature(&opts.sec_opts->csk_pk[
opts.sec_opts->csk_index],
prolog_buf, prolog_size,
opts.sec_opts->csk_key_file[
opts.sec_opts->csk_index],
hdr_sign) != 0) {
fprintf(stderr, "Failed to sign header!\n");
return -1;
}
/* Check that the header signature is correct */
if (verify_rsa_signature(sec_ext->csk_keys[opts.sec_opts->csk_index],
MAX_RSA_DER_BYTE_LEN,
prolog_buf, prolog_size,
opts.sec_opts->csk_key_file[
opts.sec_opts->csk_index],
hdr_sign) != 0) {
fprintf(stderr, "Failed to verify header signature!\n");
return -1;
}
/* Finally, copy the header signature into the trusted boot extension */
memcpy(sec_ext->header_sign, hdr_sign, RSA_SIGN_BYTE_LEN);
return 0;
}
#endif /* CONFIG_MVEBU_SECURE_BOOT */
#define FMT_HEX 0
#define FMT_DEC 1
#define FMT_BIN 2
#define FMT_NONE 3
void do_print_field(unsigned int value, char *name,
int start, int size, int format)
{
fprintf(stdout, "[0x%05x : 0x%05x] %-26s",
start, start + size - 1, name);
switch (format) {
case FMT_HEX:
printf("0x%x\n", value);
break;
case FMT_DEC:
printf("%d\n", value);
break;
default:
printf("\n");
break;
}
}
#define print_field(st, type, field, hex, base) \
do_print_field((int)st->field, #field, \
base + offsetof(type, field), sizeof(st->field), hex)
int print_header(uint8_t *buf, int base)
{
header_t *main_hdr;
main_hdr = (header_t *)buf;
fprintf(stdout, "########### Header ##############\n");
print_field(main_hdr, header_t, magic, FMT_HEX, base);
print_field(main_hdr, header_t, prolog_size, FMT_DEC, base);
print_field(main_hdr, header_t, prolog_checksum, FMT_HEX, base);
print_field(main_hdr, header_t, boot_image_size, FMT_DEC, base);
print_field(main_hdr, header_t, boot_image_checksum, FMT_HEX, base);
print_field(main_hdr, header_t, rsrvd0, FMT_HEX, base);
print_field(main_hdr, header_t, load_addr, FMT_HEX, base);
print_field(main_hdr, header_t, exec_addr, FMT_HEX, base);
print_field(main_hdr, header_t, uart_cfg, FMT_HEX, base);
print_field(main_hdr, header_t, baudrate, FMT_HEX, base);
print_field(main_hdr, header_t, ext_count, FMT_DEC, base);
print_field(main_hdr, header_t, aux_flags, FMT_HEX, base);
print_field(main_hdr, header_t, io_arg_0, FMT_HEX, base);
print_field(main_hdr, header_t, io_arg_1, FMT_HEX, base);
print_field(main_hdr, header_t, io_arg_2, FMT_HEX, base);
print_field(main_hdr, header_t, io_arg_3, FMT_HEX, base);
print_field(main_hdr, header_t, rsrvd1, FMT_HEX, base);
print_field(main_hdr, header_t, rsrvd2, FMT_HEX, base);
print_field(main_hdr, header_t, rsrvd3, FMT_HEX, base);
return sizeof(header_t);
}
int print_ext_hdr(ext_header_t *ext_hdr, int base)
{
print_field(ext_hdr, ext_header_t, type, FMT_HEX, base);
print_field(ext_hdr, ext_header_t, offset, FMT_HEX, base);
print_field(ext_hdr, ext_header_t, reserved, FMT_HEX, base);
print_field(ext_hdr, ext_header_t, size, FMT_DEC, base);
return base + sizeof(ext_header_t);
}
void print_sec_ext(ext_header_t *ext_hdr, int base)
{
sec_entry_t *sec_entry;
uint32_t new_base;
fprintf(stdout, "\n########### Secure extension ###########\n");
new_base = print_ext_hdr(ext_hdr, base);
sec_entry = (sec_entry_t *)(ext_hdr + 1);
do_print_field(0, "KAK key", new_base, MAX_RSA_DER_BYTE_LEN, FMT_NONE);
new_base += MAX_RSA_DER_BYTE_LEN;
print_field(sec_entry, sec_entry_t, jtag_delay, FMT_DEC, base);
print_field(sec_entry, sec_entry_t, box_id, FMT_HEX, base);
print_field(sec_entry, sec_entry_t, flash_id, FMT_HEX, base);
print_field(sec_entry, sec_entry_t, encrypt_en, FMT_DEC, base);
print_field(sec_entry, sec_entry_t, efuse_dis, FMT_DEC, base);
new_base += 6 * sizeof(uint32_t);
do_print_field(0, "header signature",
new_base, RSA_SIGN_BYTE_LEN, FMT_NONE);
new_base += RSA_SIGN_BYTE_LEN;
do_print_field(0, "image signature",
new_base, RSA_SIGN_BYTE_LEN, FMT_NONE);
new_base += RSA_SIGN_BYTE_LEN;
do_print_field(0, "CSK keys", new_base,
CSK_ARR_SZ * MAX_RSA_DER_BYTE_LEN, FMT_NONE);
new_base += CSK_ARR_SZ * MAX_RSA_DER_BYTE_LEN;
do_print_field(0, "CSK block signature",
new_base, RSA_SIGN_BYTE_LEN, FMT_NONE);
new_base += RSA_SIGN_BYTE_LEN;
do_print_field(0, "control", new_base,
CP_CTRL_EL_ARRAY_SZ * 2, FMT_NONE);
}
void print_bin_ext(ext_header_t *ext_hdr, int base)
{
fprintf(stdout, "\n########### Binary extension ###########\n");
base = print_ext_hdr(ext_hdr, base);
do_print_field(0, "binary image", base, ext_hdr->size, FMT_NONE);
}
int print_extension(void *buf, int base, int count, int ext_size)
{
ext_header_t *ext_hdr = buf;
int pad = ext_size;
int curr_size;
while (count--) {
if (ext_hdr->type == EXT_TYPE_BINARY)
print_bin_ext(ext_hdr, base);
else if (ext_hdr->type == EXT_TYPE_SECURITY)
print_sec_ext(ext_hdr, base);
curr_size = sizeof(ext_header_t) + ext_hdr->size;
base += curr_size;
pad -= curr_size;
ext_hdr = (ext_header_t *)((uintptr_t)ext_hdr + curr_size);
}
if (pad)
do_print_field(0, "padding", base, pad, FMT_NONE);
return ext_size;
}
int parse_image(uint8_t *buf, int size)
{
int base = 0;
int ret = 1;
header_t *main_hdr;
uint32_t checksum, prolog_checksum;
fprintf(stdout,
"################### Prolog Start ######################\n\n");
main_hdr = (header_t *)buf;
base += print_header(buf, base);
if (main_hdr->ext_count)
base += print_extension(buf + base, base,
main_hdr->ext_count,
main_hdr->prolog_size -
sizeof(header_t));
if (base < main_hdr->prolog_size) {
fprintf(stdout, "\n########### Padding ##############\n");
do_print_field(0, "prolog padding",
base, main_hdr->prolog_size - base, FMT_HEX);
base = main_hdr->prolog_size;
}
fprintf(stdout,
"\n################### Prolog End ######################\n");
fprintf(stdout,
"\n################### Boot image ######################\n");
do_print_field(0, "boot image", base, size - base - 4, FMT_NONE);
fprintf(stdout,
"################### Image end ########################\n");
/* Check sanity for certain values */
printf("\nChecking values:\n");
if (main_hdr->magic == MAIN_HDR_MAGIC) {
fprintf(stdout, "Headers magic: OK!\n");
} else {
fprintf(stderr,
"\n****** ERROR: HEADER MAGIC 0x%08x != 0x%08x\n",
main_hdr->magic, MAIN_HDR_MAGIC);
goto error;
}
/* headers checksum */
/* clear the checksum field in header to calculate checksum */
prolog_checksum = main_hdr->prolog_checksum;
main_hdr->prolog_checksum = 0;
checksum = checksum32((uint32_t *)buf, main_hdr->prolog_size);
if (checksum == prolog_checksum) {
fprintf(stdout, "Headers checksum: OK!\n");
} else {
fprintf(stderr,
"\n***** ERROR: BAD HEADER CHECKSUM 0x%08x != 0x%08x\n",
checksum, prolog_checksum);
goto error;
}
/* boot image checksum */
checksum = checksum32((uint32_t *)(buf + main_hdr->prolog_size),
main_hdr->boot_image_size);
if (checksum == main_hdr->boot_image_checksum) {
fprintf(stdout, "Image checksum: OK!\n");
} else {
fprintf(stderr,
"\n****** ERROR: BAD IMAGE CHECKSUM 0x%08x != 0x%08x\n",
checksum, main_hdr->boot_image_checksum);
goto error;
}
#ifdef CONFIG_MVEBU_SECURE_BOOT
/* RSA signatures */
if (main_hdr->ext_count) {
uint8_t ext_num = main_hdr->ext_count;
ext_header_t *ext_hdr = (ext_header_t *)(main_hdr + 1);
unsigned char hash[32];
int i;
while (ext_num--) {
if (ext_hdr->type == EXT_TYPE_SECURITY) {
sec_entry_t *sec_entry =
(sec_entry_t *)(ext_hdr + 1);
ret = verify_secure_header_signatures(
main_hdr, sec_entry);
if (ret != 0) {
fprintf(stderr,
"\n****** FAILED TO VERIFY ");
fprintf(stderr,
"RSA SIGNATURES ********\n");
goto error;
}
mbedtls_sha256_ret(sec_entry->kak_key,
MAX_RSA_DER_BYTE_LEN, hash, 0);
fprintf(stdout,
">>>>>>>>>> KAK KEY HASH >>>>>>>>>>\n");
fprintf(stdout, "SHA256: ");
for (i = 0; i < 32; i++)
fprintf(stdout, "%02X", hash[i]);
fprintf(stdout,
"\n<<<<<<<<< KAK KEY HASH <<<<<<<<<\n");
break;
}
ext_hdr =
(ext_header_t *)((uint8_t *)(ext_hdr + 1) +
ext_hdr->size);
}
}
#endif
ret = 0;
error:
return ret;
}
int format_bin_ext(char *filename, FILE *out_fd)
{
ext_header_t header;
FILE *in_fd;
int size, written;
int aligned_size, pad_bytes;
char c;
in_fd = fopen(filename, "rb");
if (in_fd == NULL) {
fprintf(stderr, "failed to open bin extension file %s\n",
filename);
return 1;
}
size = get_file_size(filename);
if (size <= 0) {
fprintf(stderr, "bin extension file size is bad\n");
return 1;
}
/* Align extension size to 8 bytes */
aligned_size = (size + 7) & (~7);
pad_bytes = aligned_size - size;
header.type = EXT_TYPE_BINARY;
header.offset = 0;
header.size = aligned_size;
header.reserved = 0;
/* Write header */
written = fwrite(&header, sizeof(ext_header_t), 1, out_fd);
if (written != 1) {
fprintf(stderr, "failed writing header to extension file\n");
return 1;
}
/* Write image */
while (size--) {
c = getc(in_fd);
fputc(c, out_fd);
}
while (pad_bytes--)
fputc(0, out_fd);
fclose(in_fd);
return 0;
}
/* ****************************************
*
* Write all extensions (binary, secure
* extensions) to file
*
* ****************************************/
int format_extensions(char *ext_filename)
{
FILE *out_fd;
int ret = 0;
out_fd = fopen(ext_filename, "wb");
if (out_fd == NULL) {
fprintf(stderr, "failed to open extension output file %s",
ext_filename);
return 1;
}
if (strncmp(opts.bin_ext_file, "NA", MAX_FILENAME)) {
if (format_bin_ext(opts.bin_ext_file, out_fd)) {
ret = 1;
goto error;
}
}
#ifdef CONFIG_MVEBU_SECURE_BOOT
if (strncmp(opts.sec_cfg_file, "NA", MAX_FILENAME)) {
if (format_sec_ext(opts.sec_cfg_file, out_fd)) {
ret = 1;
goto error;
}
}
#endif
error:
fflush(out_fd);
fclose(out_fd);
return ret;
}
void update_uart(header_t *header)
{
header->uart_cfg = 0;
header->baudrate = 0;
if (opts.disable_print)
uart_set_mode(header->uart_cfg, UART_MODE_DISABLE);
if (opts.baudrate)
header->baudrate = (opts.baudrate / 1200);
}
/* ****************************************
*
* Write the image prolog, i.e.
* main header and extensions, to file
*
* ****************************************/
int write_prolog(int ext_cnt, char *ext_filename,
uint8_t *image_buf, int image_size, FILE *out_fd)
{
header_t *header;
int main_hdr_size = sizeof(header_t);
int prolog_size = main_hdr_size;
FILE *ext_fd;
char *buf;
int written, read;
int ret = 1;
if (ext_cnt)
prolog_size += get_file_size(ext_filename);
prolog_size = ((prolog_size + PROLOG_ALIGNMENT) &
(~(PROLOG_ALIGNMENT-1)));
/* Allocate a zeroed buffer to zero the padding bytes */
buf = calloc(prolog_size, 1);
if (buf == NULL) {
fprintf(stderr, "Error: failed allocating checksum buffer\n");
return 1;
}
header = (header_t *)buf;
header->magic = MAIN_HDR_MAGIC;
header->prolog_size = prolog_size;
header->load_addr = opts.load_addr;
header->exec_addr = opts.exec_addr;
header->io_arg_0 = opts.nfc_io_args;
header->ext_count = ext_cnt;
header->aux_flags = 0;
header->boot_image_size = (image_size + 3) & (~0x3);
header->boot_image_checksum = checksum32((uint32_t *)image_buf,
image_size);
update_uart(header);
/* Populate buffer with main header and extensions */
if (ext_cnt) {
ext_fd = fopen(ext_filename, "rb");
if (ext_fd == NULL) {
fprintf(stderr,
"Error: failed to open extensions file\n");
goto error;
}
read = fread(&buf[main_hdr_size],
get_file_size(ext_filename), 1, ext_fd);
if (read != 1) {
fprintf(stderr,
"Error: failed to open extensions file\n");
goto error;
}
#ifdef CONFIG_MVEBU_SECURE_BOOT
/* Secure boot mode? */
if (opts.sec_opts != 0) {
ret = finalize_secure_ext(header, (uint8_t *)buf,
prolog_size, image_buf,
image_size);
if (ret != 0) {
fprintf(stderr, "Error: failed to handle ");
fprintf(stderr, "secure extension!\n");
goto error;
}
} /* secure boot mode */
#endif
}
/* Update the total prolog checksum */
header->prolog_checksum = checksum32((uint32_t *)buf, prolog_size);
/* Now spill everything to output file */
written = fwrite(buf, prolog_size, 1, out_fd);
if (written != 1) {
fprintf(stderr,
"Error: failed to write prolog to output file\n");
goto error;
}
ret = 0;
error:
free(buf);
return ret;
}
int write_boot_image(uint8_t *buf, uint32_t image_size, FILE *out_fd)
{
int aligned_size;
int written;
/* Image size must be aligned to 4 bytes */
aligned_size = (image_size + 3) & (~0x3);
written = fwrite(buf, aligned_size, 1, out_fd);
if (written != 1) {
fprintf(stderr, "Error: Failed to write boot image\n");
goto error;
}
return 0;
error:
return 1;
}
int main(int argc, char *argv[])
{
char in_file[MAX_FILENAME+1] = { 0 };
char out_file[MAX_FILENAME+1] = { 0 };
char ext_file[MAX_FILENAME+1] = { 0 };
FILE *in_fd = NULL;
FILE *out_fd = NULL;
int parse = 0;
int ext_cnt = 0;
int opt;
int ret = 0;
int image_size;
uint8_t *image_buf = NULL;
int read;
size_t len;
uint32_t nand_block_size_kb, mlc_nand;
/* Create temporary file for building extensions
* Use process ID for allowing multiple parallel runs
*/
snprintf(ext_file, MAX_FILENAME, "/tmp/ext_file-%x", getpid());
while ((opt = getopt(argc, argv, "hpms:i:l:e:a:b:u:n:t:c:k:")) != -1) {
switch (opt) {
case 'h':
usage();
break;
case 'l':
opts.load_addr = strtoul(optarg, NULL, 0);
break;
case 'e':
opts.exec_addr = strtoul(optarg, NULL, 0);
break;
case 'm':
opts.disable_print = 1;
break;
case 'u':
opts.baudrate = strtoul(optarg, NULL, 0);
break;
case 'b':
strncpy(opts.bin_ext_file, optarg, MAX_FILENAME);
ext_cnt++;
break;
case 'p':
parse = 1;
break;
case 'n':
nand_block_size_kb = strtoul(optarg, NULL, 0);
opts.nfc_io_args |= (nand_block_size_kb / 64);
break;
case 't':
mlc_nand = 0;
if (!strncmp("MLC", optarg, 3))
mlc_nand = 1;
opts.nfc_io_args |= (mlc_nand << 8);
break;
#ifdef CONFIG_MVEBU_SECURE_BOOT
case 'c': /* SEC extension */
strncpy(opts.sec_cfg_file, optarg, MAX_FILENAME);
ext_cnt++;
break;
case 'k':
opts.key_index = strtoul(optarg, NULL, 0);
break;
#endif
default: /* '?' */
usage_err("Unknown argument");
exit(EXIT_FAILURE);
}
}
/* Check validity of inputes */
if (opts.load_addr % 8)
usage_err("Load address must be 8 bytes aligned");
if (opts.baudrate % 1200)
usage_err("Baudrate must be a multiple of 1200");
/* The remaining arguments are the input
* and potentially output file
*/
/* Input file must exist so exit if not */
if (optind >= argc)
usage_err("missing input file name");
len = strlen(argv[optind]);
if (len > MAX_FILENAME)
usage_err("file name too long");
memcpy(in_file, argv[optind], len);
optind++;
/* Output file must exist in non parse mode */
if (optind < argc) {
len = strlen(argv[optind]);
if (len > MAX_FILENAME)
usage_err("file name too long");
memcpy(out_file, argv[optind], len);
} else if (!parse)
usage_err("missing output file name");
/* open the input file */
in_fd = fopen(in_file, "rb");
if (in_fd == NULL) {
printf("Error: Failed to open input file %s\n", in_file);
goto main_exit;
}
/* Read the input file to buffer */
image_size = get_file_size(in_file);
image_buf = calloc((image_size + AES_BLOCK_SZ - 1) &
~(AES_BLOCK_SZ - 1), 1);
if (image_buf == NULL) {
fprintf(stderr, "Error: failed allocating input buffer\n");
return 1;
}
read = fread(image_buf, image_size, 1, in_fd);
if (read != 1) {
fprintf(stderr, "Error: failed to read input file\n");
goto main_exit;
}
/* Parse the input image and leave */
if (parse) {
if (opts.key_index >= CSK_ARR_SZ) {
fprintf(stderr,
"Wrong key IDX value. Valid values 0 - %d\n",
CSK_ARR_SZ - 1);
goto main_exit;
}
ret = parse_image(image_buf, image_size);
goto main_exit;
}
/* Create a blob file from all extensions */
if (ext_cnt) {
ret = format_extensions(ext_file);
if (ret)
goto main_exit;
}
out_fd = fopen(out_file, "wb");
if (out_fd == NULL) {
fprintf(stderr,
"Error: Failed to open output file %s\n", out_file);
goto main_exit;
}
ret = write_prolog(ext_cnt, ext_file, image_buf, image_size, out_fd);
if (ret)
goto main_exit;
#ifdef CONFIG_MVEBU_SECURE_BOOT
if (opts.sec_opts && (opts.sec_opts->encrypted_image != 0) &&
(opts.sec_opts->enc_image_sz != 0)) {
ret = write_boot_image(opts.sec_opts->encrypted_image,
opts.sec_opts->enc_image_sz, out_fd);
} else
#endif
ret = write_boot_image(image_buf, image_size, out_fd);
if (ret)
goto main_exit;
main_exit:
if (in_fd)
fclose(in_fd);
if (out_fd)
fclose(out_fd);
if (image_buf)
free(image_buf);
unlink(ext_file);
#ifdef CONFIG_MVEBU_SECURE_BOOT
if (opts.sec_opts) {
if (opts.sec_opts->encrypted_image)
free(opts.sec_opts->encrypted_image);
free(opts.sec_opts);
}
#endif
exit(ret);
}