/* * keys.c * * Copyright (c) 2018-2020, SciresM. * Copyright (c) 2019, shchmue. * Copyright (c) 2020-2023, DarkMatterCore . * * This file is part of nxdumptool (https://github.com/DarkMatterCore/nxdumptool). * * nxdumptool is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * nxdumptool is distributed in the hope that 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 . */ #include "nxdt_utils.h" #include "keys.h" #include "nca.h" #include "rsa.h" #include "aes.h" #include "smc.h" #include "key_sources.h" #define ETICKET_RSA_DEVICE_KEY_PUBLIC_EXPONENT 0x10001 /* Type definitions. */ typedef struct { ///< AES-128-ECB key used to derive master KEKs from Erista master KEK sources. ///< Only available in Erista units. Retrieved from the Lockpick_RCM keys file. u8 tsec_root_key[AES_128_KEY_SIZE]; ///< AES-128-ECB key used to derive master KEKs from Mariko master KEK sources. ///< Only available in Mariko units. Retrieved from the Lockpick_RCM keys file -- if available, because it must be manually bruteforced on a PC after running Lockpick_RCM. u8 mariko_kek[AES_128_KEY_SIZE]; ///< AES-128-ECB keys used to decrypt the vast majority of Switch content. ///< Derived at runtime using hardcoded key sources and additional keydata retrieved from the Lockpick_RCM keys file. u8 master_keys[NcaKeyGeneration_Max][AES_128_KEY_SIZE]; ///< AES-128-XTS key needed to handle NCA header crypto. ///< Generated from hardcoded key sources. u8 nca_header_key[AES_128_KEY_SIZE * 2]; ///< AES-128-ECB keys needed to handle key area crypto from NCA headers. ///< Generated from hardcoded key sources and master keys. u8 nca_kaek[NcaKeyAreaEncryptionKeyIndex_Count][NcaKeyGeneration_Max][AES_128_KEY_SIZE]; ///< AES-128-CTR key needed to decrypt the console-specific eTicket RSA device key stored in PRODINFO. ///< Retrieved from the Lockpick_RCM keys file. Verified by decrypting the eTicket RSA device key. ///< The key itself may or may not be console-specific (personalized), based on the eTicket RSA device key generation value. u8 eticket_rsa_kek[AES_128_KEY_SIZE]; ///< AES-128-ECB keys needed to decrypt titlekeys. ///< Generated from a hardcoded key source and master keys. u8 ticket_common_keys[NcaKeyGeneration_Max][AES_128_KEY_SIZE]; ///< AES-128-CBC key needed to decrypt the CardInfo area from gamecard headers. ///< Generated from hardcoded key sources. u8 gc_cardinfo_key[AES_128_KEY_SIZE]; } KeysNxKeyset; /// Used to parse the eTicket RSA device key retrieved from PRODINFO via setcalGetEticketDeviceKey(). /// Everything after the AES CTR is encrypted using the eTicket RSA device key encryption key. typedef struct { u8 ctr[AES_128_KEY_SIZE]; u8 private_exponent[RSA2048_BYTES]; u8 modulus[RSA2048_BYTES]; u32 public_exponent; ///< Stored using big endian byte order. Must match ETICKET_RSA_DEVICE_KEY_PUBLIC_EXPONENT. u8 padding[0x14]; u64 device_id; u8 ghash[0x10]; } EticketRsaDeviceKey; NXDT_ASSERT(EticketRsaDeviceKey, 0x240); /* Function prototypes. */ static bool keysIsKeyEmpty(const void *key); static int keysGetKeyAndValueFromFile(FILE *f, char **line, char **key, char **value); static bool keysParseHexKey(u8 *out, size_t out_size, const char *key, const char *value); static bool keysReadKeysFromFile(void); static bool keysDeriveMasterKeys(void); static bool keysDeriveNcaHeaderKey(void); static bool keysDerivePerGenerationKeys(void); static bool keysDeriveGcCardInfoKey(void); static bool keysGetDecryptedEticketRsaDeviceKey(void); static bool keysTestEticketRsaDeviceKey(const void *e, const void *d, const void *n); static bool keysGenerateAesKek(const u8 *kek_src, u8 key_generation, SmcGenerateAesKekOption option, u8 *out_kek); static bool keysLoadAesKey(const u8 *kek, const u8 *key_src, u8 *out_key); static bool keysGenerateAesKey(const u8 *kek, const u8 *key_src, u8 *out_key); static bool keysLoadAesKeyFromAesKek(const u8 *kek_src, u8 key_generation, SmcGenerateAesKekOption option, const u8 *key_src, u8 *out_key); static bool keysGenerateAesKeyFromAesKek(const u8 *kek_src, u8 key_generation, SmcGenerateAesKekOption option, const u8 *key_src, u8 *out_key); /* Global variables. */ static bool g_keysetLoaded = false; static Mutex g_keysetMutex = 0; static SetCalRsa2048DeviceKey g_eTicketRsaDeviceKey = {0}; static KeysNxKeyset g_nxKeyset = {0}; static bool g_latestMasterKeyAvailable = false; static bool g_wipedSetCal = false; bool keysLoadKeyset(void) { bool ret = false; SCOPED_LOCK(&g_keysetMutex) { ret = g_keysetLoaded; if (ret) break; /* Get eTicket RSA device key. */ Result rc = setcalGetEticketDeviceKey(&g_eTicketRsaDeviceKey); if (R_FAILED(rc)) { LOG_MSG_ERROR("setcalGetEticketDeviceKey failed! (0x%X).", rc); break; } /* Read data from the Lockpick_RCM keys file. */ if (!keysReadKeysFromFile()) break; /* Derive master keys. */ if (!keysDeriveMasterKeys()) { LOG_MSG_ERROR("Failed to derive master keys!"); break; } /* Derive NCA header key. */ if (!keysDeriveNcaHeaderKey()) break; /* Derive per-generation keys. */ if (!keysDerivePerGenerationKeys()) break; /* Derive gamecard CardInfo key */ if (!keysDeriveGcCardInfoKey()) { LOG_MSG_ERROR("Failed to derive gamecard CardInfo key!"); break; } /* Get decrypted eTicket RSA device key. */ if (!keysGetDecryptedEticketRsaDeviceKey()) break; /* Update flags. */ ret = g_keysetLoaded = true; } #if LOG_LEVEL == LOG_LEVEL_DEBUG LOG_DATA_DEBUG(&g_eTicketRsaDeviceKey, sizeof(SetCalRsa2048DeviceKey), "eTicket RSA device key dump:"); LOG_DATA_DEBUG(&g_nxKeyset, sizeof(KeysNxKeyset), "NX keyset dump:"); #endif return ret; } const u8 *keysGetNcaHeaderKey(void) { const u8 *ret = NULL; SCOPED_LOCK(&g_keysetMutex) { if (g_keysetLoaded) ret = (const u8*)(g_nxKeyset.nca_header_key); } return ret; } const u8 *keysGetNcaKeyAreaEncryptionKey(u8 kaek_index, u8 key_generation) { const u8 *ret = NULL; u8 key_gen_val = (key_generation ? (key_generation - 1) : key_generation); if (kaek_index >= NcaKeyAreaEncryptionKeyIndex_Count) { LOG_MSG_ERROR("Invalid KAEK index! (0x%02X).", kaek_index); goto end; } if (key_generation > NcaKeyGeneration_Max) { LOG_MSG_ERROR("Invalid key generation value! (0x%02X).", key_generation); goto end; } SCOPED_LOCK(&g_keysetMutex) { if (!g_keysetLoaded) break; ret = (const u8*)(g_nxKeyset.nca_kaek[kaek_index][key_gen_val]); if (keysIsKeyEmpty(ret)) { LOG_MSG_ERROR("NCA KAEK for type %u and generation %u unavailable.", kaek_index, key_gen_val); ret = NULL; } } end: return ret; } bool keysDecryptRsaOaepWrappedTitleKey(const void *rsa_wrapped_titlekey, void *out_titlekey) { if (!rsa_wrapped_titlekey || !out_titlekey) { LOG_MSG_ERROR("Invalid parameters!"); return false; } bool ret = false; SCOPED_LOCK(&g_keysetMutex) { if (!g_keysetLoaded || g_wipedSetCal) break; size_t out_keydata_size = 0; u8 out_keydata[RSA2048_BYTES] = {0}; /* Get eTicket RSA device key. */ EticketRsaDeviceKey *eticket_rsa_key = (EticketRsaDeviceKey*)g_eTicketRsaDeviceKey.key; /* Perform a RSA-OAEP unwrap operation to get the encrypted titlekey. */ /* ES uses a NULL string as the label. */ ret = (rsa2048OaepDecrypt(out_keydata, sizeof(out_keydata), rsa_wrapped_titlekey, eticket_rsa_key->modulus, &(eticket_rsa_key->public_exponent), sizeof(eticket_rsa_key->public_exponent), \ eticket_rsa_key->private_exponent, sizeof(eticket_rsa_key->private_exponent), NULL, 0, &out_keydata_size) && out_keydata_size >= AES_128_KEY_SIZE); if (ret) { /* Copy RSA-OAEP unwrapped titlekey. */ memcpy(out_titlekey, out_keydata, AES_128_KEY_SIZE); } else { LOG_MSG_ERROR("RSA-OAEP titlekey decryption failed!"); } } return ret; } const u8 *keysGetTicketCommonKey(u8 key_generation) { const u8 *ret = NULL; u8 key_gen_val = (key_generation ? (key_generation - 1) : key_generation); if (key_generation > NcaKeyGeneration_Max) { LOG_MSG_ERROR("Invalid key generation value! (0x%02X).", key_generation); goto end; } SCOPED_LOCK(&g_keysetMutex) { if (!g_keysetLoaded) break; ret = (const u8*)(g_nxKeyset.ticket_common_keys[key_gen_val]); if (keysIsKeyEmpty(ret)) { LOG_MSG_ERROR("Ticket common key for generation %u unavailable.", key_gen_val); ret = NULL; } } end: return ret; } const u8 *keysGetGameCardInfoKey(void) { const u8 *ret = NULL; SCOPED_LOCK(&g_keysetMutex) { if (g_keysetLoaded) ret = (const u8*)(g_nxKeyset.gc_cardinfo_key); } return ret; } static bool keysIsKeyEmpty(const void *key) { const u8 null_key[AES_128_KEY_SIZE] = {0}; return (memcmp(key, null_key, AES_128_KEY_SIZE) == 0); } /** * Reads a line from file f and parses out the key and value from it. * The format of a line must match /^[ \t]*\w+[ \t]*[,=][ \t]*(?:[A-Fa-f0-9]{2})+[ \t]*$/. * If a line ends in \r, the final \r is stripped. * The input file is assumed to have been opened with the 'b' flag. * The input file is assumed to contain only ASCII. * * On success, *line will point to a dynamically allocated buffer that holds * the read line, whilst *key and *value will be set to point to the key and * value strings within *line, respectively. *line must be freed by the caller. * On failure, *line, *key and *value will all be set to NULL. * Empty lines and end of file are both considered failures. * * This function is thread-safe. * * Both key and value strings will be converted to lowercase. * Empty key and/or value strings are both considered a parse error. * Furthermore, a parse error will also be returned if the value string length * is not a multiple of 2. * * This function assumes that the file can be trusted not to contain any NUL in * the contents. * * Whitespace (' ', ASCII 0x20, as well as '\t', ASCII 0x09) at the beginning of * the line, at the end of the line as well as around = (or ,) will be ignored. * * @param f the file to read * @param line pointer to change to point to the read line * @param key pointer to change to point to the key * @param value pointer to change to point to the value * @return 0 on success, * 1 on end of file, * -1 on parse error (line malformed, empty line) * -2 on I/O error */ static int keysGetKeyAndValueFromFile(FILE *f, char **line, char **key, char **value) { if (!f || !line || !key || !value) { LOG_MSG_ERROR("Invalid parameters!"); return -2; } int ret = -1; size_t n = 0; ssize_t read = 0; char *l = NULL, *k = NULL, *v = NULL, *p = NULL, *e = NULL; /* Clear inputs beforehand. */ if (*line) free(*line); *line = *key = *value = NULL; errno = 0; /* Read line. */ read = __getline(line, &n, f); if (errno != 0 || read <= 0) { ret = ((errno == 0 && (read == 0 || feof(f))) ? 1 : -2); if (ret != 1) LOG_MSG_ERROR("__getline failed! (0x%lX, %ld, %d, %d).", ftell(f), read, errno, ret); goto end; } n = (ftell(f) - (size_t)read); /* Check if we're dealing with an empty line. */ l = *line; if (*l == '\n' || *l == '\r' || *l == '\0') { LOG_MSG_WARNING("Empty line detected! (0x%lX, 0x%lX).", n, read); goto end; } /* Not finding '\r' or '\n' is not a problem. */ /* It's possible that the last line of a file isn't actually a line (i.e., does not end in '\n'). */ /* We do want to handle those. */ if ((p = strchr(l, '\r')) != NULL || (p = strchr(l, '\n')) != NULL) { e = p; *p = '\0'; } else { e = (l + read + 1); } #define SKIP_SPACE(p) do { \ for(; (*p == ' ' || *p == '\t'); ++p); \ } while(0); /* Skip leading whitespace before the key name string. */ p = l; SKIP_SPACE(p); k = p; /* Validate key name string. */ for(; *p != ' ' && *p != '\t' && *p != ',' && *p != '='; ++p) { /* Bail out if we reached the end of string. */ if (*p == '\0') { LOG_MSG_ERROR("End of string reached while validating key name string! (#1) (0x%lX, 0x%lX, 0x%lX).", n, read, (size_t)(p - l)); goto end; } /* Convert uppercase characters to lowercase. */ if (*p >= 'A' && *p <= 'Z') { *p = ('a' + (*p - 'A')); continue; } /* Handle unsupported characters. */ if (*p != '_' && (*p < '0' || *p > '9') && (*p < 'a' || *p > 'z')) { LOG_MSG_ERROR("Unsupported character detected in key name string! (0x%lX, 0x%lX, 0x%lX, 0x%02X).", n, read, (size_t)(p - l), *p); goto end; } } /* Bail if the final ++p put us at the end of string. */ if (*p == '\0') { LOG_MSG_ERROR("End of string reached while validating key name string! (#2) (0x%lX, 0x%lX, 0x%lX).", n, read, (size_t)(p - l)); goto end; } /* We should be at the end of the key name string now and either whitespace or [,=] follows. */ if (*p == '=' || *p == ',') { *p++ = '\0'; } else { /* Skip leading whitespace before [,=]. */ *p++ = '\0'; SKIP_SPACE(p); if (*p != '=' && *p != ',') { LOG_MSG_ERROR("Unable to find expected [,=]! (0x%lX, 0x%lX, 0x%lX).", n, read, (size_t)(p - l)); goto end; } *p++ = '\0'; } /* Empty key name string is an error. */ if (*k == '\0') { LOG_MSG_ERROR("Key name string empty! (0x%lX, 0x%lX).", n, read); goto end; } /* Skip trailing whitespace after [,=]. */ SKIP_SPACE(p); v = p; #undef SKIP_SPACE /* Validate value string. */ for(; p < e && *p != ' ' && *p != '\t'; ++p) { /* Bail out if we reached the end of string. */ if (*p == '\0') { LOG_MSG_ERROR("End of string reached while validating value string! (0x%lX, 0x%lX, 0x%lX, %s).", n, read, (size_t)(p - l), k); goto end; } /* Convert uppercase characters to lowercase. */ if (*p >= 'A' && *p <= 'F') { *p = ('a' + (*p - 'A')); continue; } /* Handle unsupported characters. */ if ((*p < '0' || *p > '9') && (*p < 'a' || *p > 'f')) { LOG_MSG_ERROR("Unsupported character detected in value string! (0x%lX, 0x%lX, 0x%lX, 0x%02X, %s).", n, read, (size_t)(p - l), *p, k); goto end; } } /* We should be at the end of the value string now and whitespace may optionally follow. */ l = p; if (p < e) { /* Skip trailing whitespace after the value string. */ /* Make sure there's no additional data after this. */ *p++ = '\0'; for(; p < e && (*p == ' ' || *p == '\t'); ++p); if (p < e) { LOG_MSG_ERROR("Additional data detected after value string and before line end! (0x%lX, 0x%lX, 0x%lX, %s).", n, read, (size_t)(p - *line), k); goto end; } } /* Empty value string and value string length not being a multiple of 2 are both errors. */ if (*v == '\0' || ((l - v) % 2) != 0) { LOG_MSG_ERROR("Invalid value string length! (0x%lX, 0x%lX, 0x%lX, %s).", n, read, (size_t)(l - v), k); goto end; } /* Update pointers. */ *key = k; *value = v; /* Update return value. */ ret = 0; end: if (ret != 0) { if (*line) free(*line); *line = *key = *value = NULL; } return ret; } static bool keysParseHexKey(u8 *out, size_t out_size, const char *key, const char *value) { if (!out || !out_size || !key || !*key || !value || !*value) { LOG_MSG_ERROR("Invalid parameters!"); return false; } bool success = utilsParseHexString(out, out_size, value, 0); if (!success) LOG_MSG_ERROR("Failed to parse key \"%s\"!", key); return success; } static bool keysReadKeysFromFile(void) { int ret = 0; u32 key_count = 0; FILE *keys_file = NULL; char *line = NULL, *key = NULL, *value = NULL; char test_name[0x40] = {0}; const char *keys_file_path = (utilsIsDevelopmentUnit() ? DEV_KEYS_FILE_PATH : PROD_KEYS_FILE_PATH); bool is_mariko = utilsIsMarikoUnit(); bool tsec_root_key_available = false, mariko_kek_available = false; bool use_personalized_eticket_rsa_kek = (g_eTicketRsaDeviceKey.generation > 0), eticket_rsa_kek_available = false; keys_file = fopen(keys_file_path, "rb"); if (!keys_file) { LOG_MSG_ERROR("Unable to open \"%s\" to retrieve keys!", keys_file_path); return false; } #define PARSE_HEX_KEY(name, out, decl) \ if (!strcasecmp(key, name) && keysParseHexKey(out, sizeof(out), key, value)) { \ key_count++; \ decl; \ } #define PARSE_HEX_KEY_WITH_INDEX(name, idx, out, decl) \ snprintf(test_name, sizeof(test_name), "%s_%02x", name, idx); \ PARSE_HEX_KEY(test_name, out, decl); while(true) { /* Get key and value strings from the current line. */ /* Break from the while loop if EOF is reached or if an I/O error occurs. */ ret = keysGetKeyAndValueFromFile(keys_file, &line, &key, &value); if (ret == 1 || ret == -2) break; /* Ignore malformed or empty lines. */ if (ret != 0 || !key || !value) continue; if (is_mariko) { /* Parse Mariko KEK. */ /* This will only appear on Mariko units. */ if (!mariko_kek_available) { PARSE_HEX_KEY("mariko_kek", g_nxKeyset.mariko_kek, mariko_kek_available = true; continue); } } else { /* Parse TSEC root key. */ /* This will only appear on Erista units. */ if (!tsec_root_key_available) { PARSE_HEX_KEY_WITH_INDEX("tsec_root_key", TSEC_ROOT_KEY_VERSION, g_nxKeyset.tsec_root_key, tsec_root_key_available = true; continue); } } /* Parse eTicket RSA device KEK. */ /* The personalized entry only appears on consoles that use the new PRODINFO key generation scheme. */ if (!eticket_rsa_kek_available) { PARSE_HEX_KEY(use_personalized_eticket_rsa_kek ? "eticket_rsa_kek_personalized" : "eticket_rsa_kek", g_nxKeyset.eticket_rsa_kek, eticket_rsa_kek_available = true; continue); } /* Parse master keys, starting with the last known one. */ for(u8 i = NcaKeyGeneration_Current; i <= NcaKeyGeneration_Max; i++) { u8 key_gen_val = (i - 1); PARSE_HEX_KEY_WITH_INDEX("master_key", key_gen_val, g_nxKeyset.master_keys[key_gen_val], break); } } #undef PARSE_HEX_KEY_WITH_INDEX #undef PARSE_HEX_KEY if (line) free(line); fclose(keys_file); /* Bail out if we didn't retrieve a single key. */ if (key_count) { LOG_MSG_INFO("Loaded %u key(s) from \"%s\".", key_count, keys_file_path); } else { LOG_MSG_ERROR("Unable to parse keys from \"%s\"! (keys file empty?).", keys_file_path); return false; } /* Check if the latest master key was retrieved. */ g_latestMasterKeyAvailable = !keysIsKeyEmpty(g_nxKeyset.master_keys[NcaKeyGeneration_Current - 1]); if (!g_latestMasterKeyAvailable) { LOG_MSG_WARNING("Latest known master key (%02X) unavailable in \"%s\". Latest master key derivation will be carried out.", NcaKeyGeneration_Current - 1, keys_file_path); /* Make sure we have what we need to derive the latest master key. */ if (is_mariko) { if (!mariko_kek_available) { LOG_MSG_ERROR("Mariko KEK unavailable in \"%s\"!", keys_file_path); return false; } } else { if (!tsec_root_key_available) { LOG_MSG_ERROR("TSEC root key unavailable in \"%s\"!", keys_file_path); return false; } } } if (!eticket_rsa_kek_available) { LOG_MSG_ERROR("eTicket RSA KEK unavailable in \"%s\"!", keys_file_path); return false; } return true; } static bool keysDeriveMasterKeys(void) { u8 tmp[AES_128_KEY_SIZE] = {0}; u8 latest_mkey_index = (NcaKeyGeneration_Current - 1); bool is_dev = utilsIsDevelopmentUnit(); /* Only derive the latest master key if it hasn't been populated already. */ if (!g_latestMasterKeyAvailable) { if (utilsIsMarikoUnit()) { /* Derive the latest master KEK using the hardcoded Mariko master KEK source and the Mariko KEK. */ aes128EcbCrypt(tmp, is_dev ? g_marikoMasterKekSourceDev : g_marikoMasterKekSourceProd, g_nxKeyset.mariko_kek, false); } else { /* Derive the latest master KEK using the hardcoded Erista master KEK source and the TSEC root key. */ aes128EcbCrypt(tmp, g_eristaMasterKekSource, g_nxKeyset.tsec_root_key, false); } /* Derive the latest master key using the hardcoded master key source and the latest master KEK. */ aes128EcbCrypt(g_nxKeyset.master_keys[latest_mkey_index], g_masterKeySource, tmp, false); } /* Derive all lower master keys using the latest master key and the master key vectors. */ for(u8 i = latest_mkey_index; i > NcaKeyGeneration_Since100NUP; i--) aes128EcbCrypt(g_nxKeyset.master_keys[i - 1], is_dev ? g_masterKeyVectorsDev[i] : g_masterKeyVectorsProd[i], \ g_nxKeyset.master_keys[i], false); /* Check if we derived the right keys. */ aes128EcbCrypt(tmp, is_dev ? g_masterKeyVectorsDev[NcaKeyGeneration_Since100NUP] : g_masterKeyVectorsProd[NcaKeyGeneration_Since100NUP], \ g_nxKeyset.master_keys[NcaKeyGeneration_Since100NUP], false); return keysIsKeyEmpty(tmp); } static bool keysDeriveNcaHeaderKey(void) { u8 nca_header_kek[AES_128_KEY_SIZE] = {0}; SmcGenerateAesKekOption option = {0}; smcPrepareGenerateAesKekOption(false, SmcKeyType_Default, SmcSealKey_LoadAesKey, &option); /* Derive nca_header_kek using g_ncaHeaderKekSource and master key 00. */ if (!keysGenerateAesKek(g_ncaHeaderKekSource, NcaKeyGeneration_Since100NUP, option, nca_header_kek)) { LOG_MSG_ERROR("Failed to derive NCA header KEK!"); return false; } /* Derive nca_header_key (first half) from nca_header_kek and g_ncaHeaderKeySource. */ if (!keysGenerateAesKey(nca_header_kek, g_ncaHeaderKeySource, g_nxKeyset.nca_header_key)) { LOG_MSG_ERROR("Failed to derive NCA header key! (#1)."); return false; } /* Derive nca_header_key (second half) from nca_header_kek and g_ncaHeaderKeySource. */ if (!keysGenerateAesKey(nca_header_kek, g_ncaHeaderKeySource + AES_128_KEY_SIZE, g_nxKeyset.nca_header_key + AES_128_KEY_SIZE)) { LOG_MSG_ERROR("Failed to derive NCA header key! (#2)."); return false; } return true; } static bool keysDerivePerGenerationKeys(void) { SmcGenerateAesKekOption option = {0}; smcPrepareGenerateAesKekOption(false, SmcKeyType_Default, SmcSealKey_LoadAesKey, &option); bool success = true; for(u8 i = 1; i <= NcaKeyGeneration_Max; i++) { u8 key_gen_val = (i - 1); /* Make sure we're not dealing with an unpopulated master key entry. */ if (i > NcaKeyGeneration_Current && keysIsKeyEmpty(g_nxKeyset.master_keys[key_gen_val])) { //LOG_MSG_DEBUG("Master key %02X unavailable.", key_gen_val); continue; } /* Derive NCA key area keys for this generation. */ for(u8 j = 0; j < NcaKeyAreaEncryptionKeyIndex_Count; j++) { if (!keysLoadAesKeyFromAesKek(g_ncaKeyAreaEncryptionKeySources[j], i, option, g_aesKeyGenerationSource, g_nxKeyset.nca_kaek[j][key_gen_val])) { LOG_MSG_DEBUG("Failed to derive NCA KAEK for type %u and generation %u!", j, key_gen_val); success = false; break; } } if (!success) break; /* Derive ticket common key for this generation. */ aes128EcbCrypt(g_nxKeyset.ticket_common_keys[key_gen_val], g_ticketCommonKeySource, g_nxKeyset.master_keys[key_gen_val], false); } return success; } static bool keysDeriveGcCardInfoKey(void) { SmcGenerateAesKekOption option = {0}; const u8 *key_src = (utilsIsDevelopmentUnit() ? g_gcCardInfoKeySourceDev : g_gcCardInfoKeySourceProd); smcPrepareGenerateAesKekOption(false, SmcKeyType_Default, SmcSealKey_LoadAesKey, &option); return keysGenerateAesKeyFromAesKek(g_gcCardInfoKekSource, NcaKeyGeneration_Since100NUP, option, key_src, g_nxKeyset.gc_cardinfo_key); } static bool keysGetDecryptedEticketRsaDeviceKey(void) { u32 public_exponent = 0; Aes128CtrContext eticket_aes_ctx = {0}; EticketRsaDeviceKey *eticket_rsa_key = (EticketRsaDeviceKey*)g_eTicketRsaDeviceKey.key; bool success = false; /* Decrypt eTicket RSA device key. */ aes128CtrContextCreate(&eticket_aes_ctx, g_nxKeyset.eticket_rsa_kek, eticket_rsa_key->ctr); aes128CtrCrypt(&eticket_aes_ctx, &(eticket_rsa_key->private_exponent), &(eticket_rsa_key->private_exponent), sizeof(EticketRsaDeviceKey) - sizeof(eticket_rsa_key->ctr)); /* Public exponent value must be 0x10001. */ /* It is stored using big endian byte order. */ public_exponent = __builtin_bswap32(eticket_rsa_key->public_exponent); if (public_exponent != ETICKET_RSA_DEVICE_KEY_PUBLIC_EXPONENT) { if (public_exponent == 0) { /* Bail out if we're dealing with a wiped calibration area. */ LOG_MSG_ERROR("eTicket RSA device key is empty! Personalized titlekey crypto won't be handled. Restore an eMMC backup or disable set:cal blanking options."); success = g_wipedSetCal = true; } else { LOG_MSG_ERROR("Invalid public exponent for decrypted eTicket RSA device key! Wrong keys? (0x%X).", public_exponent); } goto end; } /* Test RSA key pair. */ success = keysTestEticketRsaDeviceKey(&(eticket_rsa_key->public_exponent), eticket_rsa_key->private_exponent, eticket_rsa_key->modulus); if (!success) LOG_MSG_ERROR("eTicket RSA device key test failed! Wrong keys?"); end: return success; } static bool keysTestEticketRsaDeviceKey(const void *e, const void *d, const void *n) { if (!e || !d || !n) { LOG_MSG_ERROR("Invalid parameters!"); return false; } Result rc = 0; u8 x[RSA2048_BYTES] = {0}, y[RSA2048_BYTES] = {0}, z[RSA2048_BYTES] = {0}; /* 0xCAFEBABE. */ x[0xFC] = 0xCA; x[0xFD] = 0xFE; x[0xFE] = 0xBA; x[0xFF] = 0xBE; rc = splUserExpMod(x, n, d, RSA2048_BYTES, y); if (R_FAILED(rc)) { LOG_MSG_ERROR("splUserExpMod failed! (#1) (0x%X).", rc); return false; } rc = splUserExpMod(y, n, e, 4, z); if (R_FAILED(rc)) { LOG_MSG_ERROR("splUserExpMod failed! (#2) (0x%X).", rc); return false; } if (memcmp(x, z, RSA2048_BYTES) != 0) { LOG_MSG_ERROR("Invalid RSA key pair!"); return false; } return true; } /* Based on splCryptoGenerateAesKek(). Excludes key sealing and device-unique shenanigans. */ static bool keysGenerateAesKek(const u8 *kek_src, u8 key_generation, SmcGenerateAesKekOption option, u8 *out_kek) { bool is_device_unique = (option.fields.is_device_unique == 1); u8 key_type_idx = option.fields.key_type_idx; u8 seal_key_idx = option.fields.seal_key_idx; if (!kek_src || key_generation > NcaKeyGeneration_Max || is_device_unique || key_type_idx >= SmcKeyType_Count || seal_key_idx >= SmcSealKey_Count || \ option.fields.reserved != 0 || !out_kek) { LOG_MSG_ERROR("Invalid parameters!"); return false; } if (key_generation) key_generation--; u8 kekek_src[AES_128_KEY_SIZE] = {0}, kekek[AES_128_KEY_SIZE] = {0}; const u8 *mkey = g_nxKeyset.master_keys[key_generation]; /* Make sure this master key is available. */ if (keysIsKeyEmpty(mkey)) { LOG_MSG_ERROR("Master key %02X unavailable!", key_generation); return false; } /* Derive the KEKEK source using hardcoded data. */ for(u8 i = 0; i < AES_128_KEY_SIZE; i++) kekek_src[i] = (g_smcKeyTypeSources[key_type_idx][i] ^ g_smcSealKeyMasks[seal_key_idx][i]); /* Derive the KEKEK using the KEKEK source and the master key. */ aes128EcbCrypt(kekek, kekek_src, mkey, false); /* Derive the KEK using the provided KEK source and the derived KEKEK. */ aes128EcbCrypt(out_kek, kek_src, kekek, false); return true; } /* Based on splCryptoLoadAesKey(). Excludes key sealing shenanigans. */ static bool keysLoadAesKey(const u8 *kek, const u8 *key_src, u8 *out_key) { if (!kek || !key_src || !out_key) { LOG_MSG_ERROR("Invalid parameters!"); return false; } aes128EcbCrypt(out_key, key_src, kek, false); return true; } /* Based on splCryptoGenerateAesKey(). Excludes key sealing shenanigans. */ static bool keysGenerateAesKey(const u8 *kek, const u8 *key_src, u8 *out_key) { if (!kek || !key_src || !out_key) { LOG_MSG_ERROR("Invalid parameters!"); return false; } u8 aes_key[AES_128_KEY_SIZE] = {0}; keysLoadAesKey(kek, g_aesKeyGenerationSource, aes_key); aes128EcbCrypt(out_key, key_src, aes_key, false); return true; } /* Wrapper for keysGenerateAesKek() + keysLoadAesKey() to generate a single usable AES key in one shot. */ static bool keysLoadAesKeyFromAesKek(const u8 *kek_src, u8 key_generation, SmcGenerateAesKekOption option, const u8 *key_src, u8 *out_key) { u8 kek[AES_128_KEY_SIZE] = {0}; return (keysGenerateAesKek(kek_src, key_generation, option, kek) && keysLoadAesKey(kek, key_src, out_key)); } /* Wrapper for keysGenerateAesKek() + keysGenerateAesKey() to generate a single usable AES key in one shot. */ static bool keysGenerateAesKeyFromAesKek(const u8 *kek_src, u8 key_generation, SmcGenerateAesKekOption option, const u8 *key_src, u8 *out_key) { u8 kek[AES_128_KEY_SIZE] = {0}; return (keysGenerateAesKek(kek_src, key_generation, option, kek) && keysGenerateAesKey(kek, key_src, out_key)); }