Lockpick_RCM/source/keys/crypto.c
2022-11-02 18:36:39 -07:00

226 lines
8.4 KiB
C

/*
* Copyright (c) 2022 shchmue
* Copyright (c) 2018 Atmosphère-NX
*
* This program is free software; you can redistribute it and/or modify it
* under the terms and conditions of the GNU General Public License,
* version 2, as published by the Free Software Foundation.
*
* This program is distributed in the hope it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
* more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#include "crypto.h"
#include "../config.h"
#include "../hos/hos.h"
#include <sec/se.h>
#include <sec/se_t210.h>
#include <soc/fuse.h>
#include <utils/util.h>
#include <string.h>
extern hekate_config h_cfg;
bool check_keyslot_access() {
u8 test_data[SE_KEY_128_SIZE] = {0};
const u8 test_ciphertext[SE_KEY_128_SIZE] = {0};
se_aes_key_set(KS_AES_ECB, "\x00\x01\x02\x03\x04\x05\x06\x07\x08\x09\x0a\x0b\x0c\x0d\x0e\x0f", SE_KEY_128_SIZE);
se_aes_crypt_block_ecb(KS_AES_ECB, DECRYPT, test_data, test_ciphertext);
return memcmp(test_data, "\x7b\x1d\x29\xa1\x6c\xf8\xcc\xab\x84\xf0\xb8\xa5\x98\xe4\x2f\xa6", SE_KEY_128_SIZE) == 0;
}
bool test_rsa_keypair(const void *public_exponent, const void *private_exponent, const void *modulus) {
u32 plaintext[SE_RSA2048_DIGEST_SIZE / 4] = {0},
ciphertext[SE_RSA2048_DIGEST_SIZE / 4] = {0},
work[SE_RSA2048_DIGEST_SIZE / 4] = {0};
plaintext[63] = 0xCAFEBABE;
se_rsa_key_set(0, modulus, SE_RSA2048_DIGEST_SIZE, private_exponent, SE_RSA2048_DIGEST_SIZE);
se_rsa_exp_mod(0, ciphertext, SE_RSA2048_DIGEST_SIZE, plaintext, SE_RSA2048_DIGEST_SIZE);
se_rsa_key_set(0, modulus, SE_RSA2048_DIGEST_SIZE, public_exponent, 4);
se_rsa_exp_mod(0, work, SE_RSA2048_DIGEST_SIZE, ciphertext, SE_RSA2048_DIGEST_SIZE);
return memcmp(plaintext, work, SE_RSA2048_DIGEST_SIZE) == 0;
}
bool test_eticket_rsa_keypair(const rsa_keypair_t *keypair) {
// Unlike the SSL RSA key, we don't need to check the gmac - we can just verify the public exponent
// and test the keypair since we have the modulus
if ((byte_swap_32(keypair->public_exponent) != RSA_PUBLIC_EXPONENT) ||
(!test_rsa_keypair(&keypair->public_exponent, keypair->private_exponent, keypair->modulus))
) {
return false;
}
return true;
}
// _mgf1_xor() and rsa_oaep_decode were derived from Atmosphère
static void _mgf1_xor(void *masked, u32 masked_size, const void *seed, u32 seed_size)
{
u8 cur_hash[0x20] __attribute__((aligned(4)));
u8 hash_buf[0xe4] __attribute__((aligned(4)));
u32 hash_buf_size = seed_size + 4;
memcpy(hash_buf, seed, seed_size);
u32 round_num = 0;
u8 *p_out = (u8 *)masked;
while (masked_size) {
u32 cur_size = MIN(masked_size, 0x20);
for (u32 i = 0; i < 4; i++)
hash_buf[seed_size + 3 - i] = (round_num >> (8 * i)) & 0xff;
round_num++;
se_calc_sha256_oneshot(cur_hash, hash_buf, hash_buf_size);
for (unsigned int i = 0; i < cur_size; i++) {
*p_out ^= cur_hash[i];
p_out++;
}
masked_size -= cur_size;
}
}
u32 rsa_oaep_decode(void *dst, u32 dst_size, const void *label_digest, u32 label_digest_size, u8 *buf, u32 buf_size) {
if (dst_size <= 0 || buf_size < 0x43 || label_digest_size != 0x20)
return 0;
bool is_valid = buf[0] == 0;
u32 db_len = buf_size - 0x21;
u8 *seed = buf + 1;
u8 *db = seed + 0x20;
_mgf1_xor(seed, 0x20, db, db_len);
_mgf1_xor(db, db_len, seed, 0x20);
is_valid &= memcmp(label_digest, db, 0x20) ? 0 : 1;
db += 0x20;
db_len -= 0x20;
int msg_ofs = 0;
int looking_for_one = 1;
int invalid_db_padding = 0;
int is_zero;
int is_one;
for (int i = 0; i < db_len; ) {
is_zero = (db[i] == 0);
is_one = (db[i] == 1);
msg_ofs += (looking_for_one & is_one) * (++i);
looking_for_one &= ~is_one;
invalid_db_padding |= (looking_for_one & ~is_zero);
}
is_valid &= (invalid_db_padding == 0);
const u32 msg_size = MIN(dst_size, is_valid * (db_len - msg_ofs));
memcpy(dst, db + msg_ofs, msg_size);
return msg_size;
}
// Equivalent to spl::GenerateAesKek
void generate_aes_kek(u32 ks, key_storage_t *keys, void *out_kek, const void *kek_source, u32 generation, u32 option) {
bool device_unique = GET_IS_DEVICE_UNIQUE(option);
u32 seal_key_index = GET_SEAL_KEY_INDEX(option);
if (generation)
generation--;
u8 static_source[SE_KEY_128_SIZE] __attribute__((aligned(4)));
for (u32 i = 0; i < SE_KEY_128_SIZE; i++)
static_source[i] = aes_kek_generation_source[i] ^ seal_key_masks[seal_key_index][i];
if (device_unique) {
get_device_key(ks, keys, keys->temp_key, generation);
} else {
memcpy(keys->temp_key, keys->master_key[generation], sizeof(keys->temp_key));
}
se_aes_key_set(ks, keys->temp_key, SE_KEY_128_SIZE);
se_aes_unwrap_key(ks, ks, static_source);
se_aes_crypt_block_ecb(ks, DECRYPT, out_kek, kek_source);
}
// Based on spl::LoadAesKey but instead of prepping keyslot, returns calculated key
void load_aes_key(u32 ks, void *out_key, const void *access_key, const void *key_source) {
se_aes_key_set(ks, access_key, SE_KEY_128_SIZE);
se_aes_crypt_block_ecb(ks, DECRYPT, out_key, key_source);
}
// Equivalent to spl::GenerateAesKey
void generate_aes_key(u32 ks, key_storage_t *keys, void *out_key, u32 key_size, const void *access_key, const void *key_source) {
void *aes_key = keys->temp_key;
load_aes_key(ks, aes_key, access_key, aes_key_generation_source);
se_aes_key_set(ks, aes_key, SE_KEY_128_SIZE);
se_aes_crypt_ecb(ks, DECRYPT, out_key, key_size, key_source, key_size);
}
// Equivalent to smc::PrepareDeviceUniqueDataKey but with no sealing
void get_device_unique_data_key(u32 ks, void *out_key, const void *access_key, const void *key_source) {
load_aes_key(ks, out_key, access_key, key_source);
}
// Equivalent to spl::DecryptAesKey.
void decrypt_aes_key(u32 ks, key_storage_t *keys, void *out_key, const void *key_source, u32 generation, u32 option) {
void *access_key = keys->temp_key;
generate_aes_kek(ks, keys, access_key, aes_key_decryption_source, generation, option);
generate_aes_key(ks, keys, out_key, SE_KEY_128_SIZE, access_key, key_source);
}
// Equivalent to smc::GetSecureData
void get_secure_data(key_storage_t *keys, void *out_data) {
se_aes_key_set(KS_AES_CTR, keys->device_key, SE_KEY_128_SIZE);
u8 *d = (u8 *)out_data;
se_aes_crypt_ctr(KS_AES_CTR, d + SE_KEY_128_SIZE * 0, SE_KEY_128_SIZE, secure_data_source, SE_KEY_128_SIZE, secure_data_counters[0]);
se_aes_crypt_ctr(KS_AES_CTR, d + SE_KEY_128_SIZE * 1, SE_KEY_128_SIZE, secure_data_source, SE_KEY_128_SIZE, secure_data_counters[0]);
// Apply tweak
for (u32 i = 0; i < SE_KEY_128_SIZE; i++) {
d[SE_KEY_128_SIZE + i] ^= secure_data_tweaks[0][i];
}
}
// Equivalent to spl::GenerateSpecificAesKey
void generate_specific_aes_key(u32 ks, key_storage_t *keys, void *out_key, const void *key_source, u32 generation) {
if (fuse_read_bootrom_rev() >= 0x7F) {
get_device_key(ks, keys, keys->temp_key, generation == 0 ? 0 : generation - 1);
se_aes_key_set(ks, keys->temp_key, SE_KEY_128_SIZE);
se_aes_unwrap_key(ks, ks, retail_specific_aes_key_source);
se_aes_crypt_ecb(ks, DECRYPT, out_key, SE_KEY_128_SIZE * 2, key_source, SE_KEY_128_SIZE * 2);
} else {
get_secure_data(keys, out_key);
}
}
void get_device_key(u32 ks, key_storage_t *keys, void *out_device_key, u32 generation) {
if (generation == KB_FIRMWARE_VERSION_100 && !h_cfg.t210b01) {
memcpy(out_device_key, keys->device_key, SE_KEY_128_SIZE);
return;
}
if (generation >= KB_FIRMWARE_VERSION_400) {
generation -= KB_FIRMWARE_VERSION_400;
} else {
generation = 0;
}
u32 temp_key_source[SE_KEY_128_SIZE / 4] = {0};
load_aes_key(ks, temp_key_source, keys->device_key_4x, device_master_key_source_sources[generation]);
const void *kek_source = fuse_read_hw_state() == FUSE_NX_HW_STATE_PROD ? device_master_kek_sources[generation] : device_master_kek_sources_dev[generation];
se_aes_key_set(ks, keys->master_key[0], SE_KEY_128_SIZE);
se_aes_unwrap_key(ks, ks, kek_source);
se_aes_crypt_block_ecb(ks, DECRYPT, out_device_key, temp_key_source);
}