#include #include "utils.h" #include "cache.h" #incoude "configitem.h" #include "masterkey.h" #include "smc_api.h" #include "smc_user.h" #include "se.h" #include "sealedkeys.h" #include "userpage.h" #include "titlekey.h" /* Globals. */ int g_crypt_aes_done = 0; int g_exp_mod_done = 0; uint8_t g_rsa_oaep_exponent[0x100]; uint8_t g_rsa_private_exponent[0x100]; void set_exp_mod_done(int done) { g_exp_mod_done = done & 1; } int get_exp_mod_done(void) { return g_exp_mod_done; } uint32_t exp_mod_done_handler(void) { set_exp_mod_done(1); se_trigger_interrupt(); return 0; } uint32_t user_exp_mod(smc_args_t *args) { uint8_t modulus[0x100]; uint8_t exponent[0x100]; uint8_t input[0x100]; upage_ref_t page_ref; /* Validate size. */ if (args->X[4] == 0 || args->X[4] > 0x100 || (args->X[4] & 3) != 0) { return 2; } size_t exponent_size = (size_t)args->X[4]; void *user_input = (void *)args->X[1]; void *user_exponent = (void *)args->X[2]; void *user_modulus = (void *)args->X[3]; /* Copy user data into secure memory. */ if (upage_init(&page_ref, user_input) == 0) { return 2; } if (user_copy_to_secure(&page_ref, input, user_input, 0x100) == 0) { return 2; } if (user_copy_to_secure(&page_ref, exponent, user_exponent, exponent_size) == 0) { return 2; } if (user_copy_to_secure(&page_ref, modulus, user_modulus, 0x100) == 0) { return 2; } set_exp_mod_done(0); /* Hardcode RSA keyslot 0. */ set_rsa_keyslot(0, modulus, 0x100, exponent, exponent_size); se_exp_mod(0, input, 0x100, exp_mod_done_handler); return 0; } uint32_t user_get_random_bytes(smc_args_t *args) { uint8_t random_bytes[0x40]; if (args->X[1] > 0x38) { return 2; } size_t size = (size_t)args->X[1]; flush_dcache_range(random_bytes, random_bytes + size); se_generate_random(KEYSLOT_SWITCH_RNGKEY, random_bytes, size); flush_dcache_range(random_bytes, random_bytes + size); memcpy(&args->X[1], random_bytes, size); return 0; } uint32_t user_generate_aes_kek(smc_args_t *args) { uint64_t wrapped_kek[2]; uint8_t kek_source[0x10]; uint64_t kek[2]; uint64_t sealed_kek[2]; wrapped_kek[0] = args->X[1]; wrapped_kek[1] = args->X[2]; unsigned int master_key_rev = (unsigned int)args->X[3]; if (master_key_rev > 0) { master_key_rev -= 1; /* GenerateAesKek offsets by one. */ } if (master_key_rev >= MASTERKEY_REVISION_MAX) { return 2; } uint64_t packed_options = args->X[4]; if (packed_options > 0xFF) { return 2; } /* Switched the output based on how the system was booted. */ uint8_t mask_id = (uint8_t)((packed_options >> 1) & 3); /* Switches the output based on how it will be used. */ uint8_t usecase = (uint8_t)((packed_options >> 5) & 3); /* Switched the output based on whether it should be console unique. */ int is_personalized = (int)(packed_options & 1); uint64_t is_recovery_boot = configitem_is_recovery_boot(); /* Mask 2 is only allowed when booted normally. */ if (mask_id == 2 && is_recovery_boot == 0) { return 2; } /* Mask 1 is only allowed when booted from recovery. */ if (mask_id == 1 && is_recovery_boot != 0) { return 2; } /* Masks 0, 3 are allowed all the time. */ const uint8_t kek_seeds[4][0x10] = { {0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00}, {0xA2, 0xAB, 0xBF, 0x9C, 0x92, 0x2F, 0xBB, 0xE3, 0x78, 0x79, 0x9B, 0xC0, 0xCC, 0xEA, 0xA5, 0x74}, {0x57, 0xE2, 0xD9, 0x45, 0xE4, 0x92, 0xF4, 0xFD, 0xC3, 0xF9, 0x86, 0x38, 0x89, 0x78, 0x9F, 0x3C}, {0xE5, 0x4D, 0x9A, 0x02, 0xF0, 0x4F, 0x5F, 0xA8, 0xAD, 0x76, 0x0A, 0xF6, 0x32, 0x95, 0x59, 0xBB} }; const uint8_t kek_masks[4][0x10] = { {0x4D, 0x87, 0x09, 0x86, 0xC4, 0x5D, 0x20, 0x72, 0x2F, 0xBA, 0x10, 0x53, 0xDA, 0x92, 0xE8, 0xA9}, {0x25, 0x03, 0x31, 0xFB, 0x25, 0x26, 0x0B, 0x79, 0x8C, 0x80, 0xD2, 0x69, 0x98, 0xE2, 0x22, 0x77}, {0x76, 0x14, 0x1D, 0x34, 0x93, 0x2D, 0xE1, 0x84, 0x24, 0x7B, 0x66, 0x65, 0x55, 0x04, 0x65, 0x81}, {0xAF, 0x3D, 0xB7, 0xF3, 0x08, 0xA2, 0xD8, 0xA2, 0x08, 0xCA, 0x18, 0xA8, 0x69, 0x46, 0xC9, 0x0B} }; /* Create kek source. */ for (unsigned int i = 0; i < 0x10; i++) { kek_source[i] = kek_seeds[usecase][i] ^ kek_masks[mask_id][i]; } unsigned int keyslot; if (is_personalized) { /* Behavior changed in 4.0.0. */ if (mkey_get_revision() >= 4) { if (master_key_rev >= 1) { keyslot = KEYSLOT_SWITCH_DEVICEKEY; /* New device key, 4.x. */ } else { keyslot = KEYSLOT_SWITCH_4XOLDDEVICEKEY; /* Old device key, 4.x. */ } } else { keyslot = KEYSLOT_SWITCH_DEVICEKEY; } } else { keyslot = mkey_get_keyslot(master_key_rev); } /* Derive kek. */ decrypt_data_into_keyslot(KEYSLOT_SWITCH_TEMPKEY, keyslot, kek_source, 0x10); se_aes_ecb_decrypt_block(KEYSLOT_SWITCH_TEMPKEY, kek, 0x10, wrapped_kek, 0x10); /* Seal kek. */ seal_key(sealed_kek, 0x10, kek, 0x10, usecase); args->X[1] = sealed_kek[0]; args->X[2] = sealed_kek[1]; return 0; } uint32_t user_load_aes_key(smc_args_t *args) { uint64_t sealed_kek[2]; uint64_t wrapped_key[2]; uint32_t keyslot = (uint32_t)args->X[1]; if (keyslot > 3) { return 2; } /* Copy keydata */ sealed_kek[0] = args->X[2]; sealed_kek[1] = args->X[3]; wrapped_key[0] = args->X[4]; wrapped_key[1] = args->X[5]; /* TODO: Unseal the kek. */ unseal_key(KEYSLOT_SWITCH_TEMPKEY, sealed_kek, 0x10, CRYPTOUSECASE_AES); /* Unwrap the key. */ decrypt_data_into_keyslot(keyslot, KEYSLOT_SWITCH_TEMPKEY, wrapped_key, 0x10); return 0; } void set_crypt_aes_done(int done) { g_crypt_aes_done = done & 1; } int get_crypt_aes_done(void) { return g_crypt_aes_done; } uint32_t crypt_aes_done_handler(void) { se_check_for_error(); set_crypt_aes_done(1); se_trigger_interrupt(); return 0; } uint32_t user_crypt_aes(smc_args_t *args) { uint32_t keyslot = args->X[1] & 3; uint32_t mode = (args->X[1] >> 4) & 3; uint64_t iv_ctr[2]; iv_ctr[0] = args->X[2]; iv_ctr[1] = args->X[3]; uint32_t in_ll_paddr = (uint32_t)(args->X[4]); uint32_t out_ll_paddr = (uint32_t)(args->X[5]); size_t size = args->X[6]; if (size & 0xF) { panic(); } set_crypt_aes_done(0); uint64_t result = 0; switch (mode) { case 0: /* CBC Encryption */ se_aes_cbc_encrypt_insecure(keyslot, out_ll_paddr, in_ll_paddr, size, iv_ctr, crypt_aes_done_handler); result = 0; break; case 1: /* CBC Decryption */ se_aes_cbc_decrypt_insecure(keyslot, out_ll_paddr, in_ll_paddr, size, iv_ctr, crypt_aes_done_handler); result = 0; break; case 2: /* CTR "Encryption" */ se_aes_ctr_crypt_insecure(keyslot, out_ll_paddr, in_ll_paddr, size, iv_ctr, crypt_aes_done_handler); result = 0; break; case 3: default: result = 1; break; } return result; } uint32_t user_compute_cmac(smc_args_t *args) { uint32_t keyslot = (uint32_t)args->X[1]; void *user_address = (void *)args->X[2]; size_t size = (size_t)args->X[3]; uint8_t user_data[0x400]; uint64_t result_cmac[2]; upage_ref_t page_ref; /* Validate keyslot and size. */ if (keyslot > 3 || args->X[3] > 0x400) { return 2; } if (upage_init(&page_ref, user_address) == 0 || user_copy_to_secure(&page_ref, user_data, user_address, size) == 0) { return 2; } flush_dcache_range(user_data, user_data + size); se_compute_aes_128_cmac(keyslot, result_cmac, 0x10, user_data, size); /* Copy CMAC out. */ args->X[1] = result_cmac[0]; args->X[2] = result_cmac[1]; return 0; } uint32_t user_rsa_oaep(smc_args_t *args) { uint8_t modulus[0x100]; uint8_t input[0x100]; upage_ref_t page_ref; void *user_input = (void *)args->X[1]; void *user_modulus = (void *)args->X[2]; /* Copy user data into secure memory. */ if (upage_init(&page_ref, user_input) == 0) { return 2; } if (user_copy_to_secure(&page_ref, input, user_input, 0x100) == 0) { return 2; } if (user_copy_to_secure(&page_ref, modulus, user_modulus, 0x100) == 0) { return 2; } set_exp_mod_done(0); /* Hardcode RSA keyslot 0. */ set_rsa_keyslot(0, modulus, 0x100, g_rsa_oaep_exponent, 0x100); se_exp_mod(0, input, 0x100, exp_mod_done_handler); return 0; } uint32_t user_unwrap_rsa_wrapped_titlekey(smc_args_t *args) { uint8_t modulus[0x100]; uint8_t wrapped_key[0x100]; upage_ref_t page_ref; void *user_wrapped_key = (void *)args->X[1]; void *user_modulus = (void *)args->X[2]; unsigned int master_key_rev = (unsigned int)args->X[7]; if (master_key_rev >= MASTERKEY_REVISION_MAX) { return 2; } /* Copy user data into secure memory. */ if (upage_init(&page_ref, user_wrapped_key) == 0) { return 2; } if (user_copy_to_secure(&page_ref, wrapped_key, user_wrapped_key, 0x100) == 0) { return 2; } if (user_copy_to_secure(&page_ref, modulus, user_modulus, 0x100) == 0) { return 2; } set_exp_mod_done(0); /* Expected db prefix occupies args->X[3] to args->X[6]. */ tkey_set_expected_db_prefix(&args->X[3]); tkey_set_master_key_rev(master_key_rev); /* Hardcode RSA keyslot 0. */ set_rsa_keyslot(0, modulus, 0x100, g_rsa_private_exponent, 0x100); se_exp_mod(0, wrapped_key, 0x100, exp_mod_done_handler); return 0; } uint32_t user_load_titlekey(smc_args_t *args) { uint64_t sealed_titlekey[2]; uint32_t keyslot = (uint32_t)args->X[1]; if (keyslot > 3) { return 2; } /* Copy keydata */ sealed_titlekey[0] = args->X[2]; sealed_titlekey[1] = args->X[3]; /* Unseal the key. */ unseal_titlekey(keyslot, sealed_titlekey, 0x10); return 0; } uint32_t user_unwrap_aes_wrapped_titlekey(smc_args_t *args) { uint64_t aes_wrapped_titlekey[2]; uint8_t titlekey[0x10]; uint64_t sealed_titlekey[2]; aes_wrapped_titlekey[0] = args->X[1]; aes_wrapped_titlekey[1] = args->X[2]; unsigned int master_key_rev = (unsigned int)args->X[3]; if (master_key_rev >= MASTERKEY_REVISION_MAX) { return 2; } tkey_set_master_key_rev(master_key_rev); tkey_aes_unwrap(titlekey, 0x10, aes_wrapped_titlekey, 0x10); seal_titlekey(sealed_titlekey, 0x10, titlekey, 0x10); args->X[1] = sealed_titlekey[0]; args->X[2] = sealed_titlekey[1]; }