/* * Copyright Amazon.com, Inc. or its affiliates. All Rights Reserved. * * Licensed under the Apache License, Version 2.0 (the "License"). * You may not use this file except in compliance with the License. * A copy of the License is located at * * http://aws.amazon.com/apache2.0 * * or in the "license" file accompanying this file. This file is distributed * on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either * express or implied. See the License for the specific language governing * permissions and limitations under the License. */ #include #include #include "crypto/s2n_cipher.h" #include "crypto/s2n_openssl.h" #include "crypto/s2n_pq.h" #include "error/s2n_errno.h" #include "tls/s2n_auth_selection.h" #include "tls/s2n_kex.h" #include "tls/s2n_psk.h" #include "tls/s2n_security_policies.h" #include "tls/s2n_tls.h" #include "tls/s2n_tls13.h" #include "utils/s2n_safety.h" /************************* * S2n Record Algorithms * *************************/ const struct s2n_record_algorithm s2n_record_alg_null = { .cipher = &s2n_null_cipher, .hmac_alg = S2N_HMAC_NONE, .flags = 0, .encryption_limit = UINT64_MAX, }; const struct s2n_record_algorithm s2n_record_alg_rc4_md5 = { .cipher = &s2n_rc4, .hmac_alg = S2N_HMAC_MD5, .flags = 0, .encryption_limit = UINT64_MAX, }; const struct s2n_record_algorithm s2n_record_alg_rc4_sslv3_md5 = { .cipher = &s2n_rc4, .hmac_alg = S2N_HMAC_SSLv3_MD5, .flags = 0, .encryption_limit = UINT64_MAX, }; const struct s2n_record_algorithm s2n_record_alg_rc4_sha = { .cipher = &s2n_rc4, .hmac_alg = S2N_HMAC_SHA1, .flags = 0, .encryption_limit = UINT64_MAX, }; const struct s2n_record_algorithm s2n_record_alg_rc4_sslv3_sha = { .cipher = &s2n_rc4, .hmac_alg = S2N_HMAC_SSLv3_SHA1, .flags = 0, .encryption_limit = UINT64_MAX, }; const struct s2n_record_algorithm s2n_record_alg_3des_sha = { .cipher = &s2n_3des, .hmac_alg = S2N_HMAC_SHA1, .flags = 0, .encryption_limit = UINT64_MAX, }; const struct s2n_record_algorithm s2n_record_alg_3des_sslv3_sha = { .cipher = &s2n_3des, .hmac_alg = S2N_HMAC_SSLv3_SHA1, .flags = 0, .encryption_limit = UINT64_MAX, }; const struct s2n_record_algorithm s2n_record_alg_aes128_sha = { .cipher = &s2n_aes128, .hmac_alg = S2N_HMAC_SHA1, .flags = 0, .encryption_limit = UINT64_MAX, }; const struct s2n_record_algorithm s2n_record_alg_aes128_sslv3_sha = { .cipher = &s2n_aes128, .hmac_alg = S2N_HMAC_SSLv3_SHA1, .flags = 0, .encryption_limit = UINT64_MAX, }; const struct s2n_record_algorithm s2n_record_alg_aes128_sha_composite = { .cipher = &s2n_aes128_sha, .hmac_alg = S2N_HMAC_NONE, .flags = 0, .encryption_limit = UINT64_MAX, }; const struct s2n_record_algorithm s2n_record_alg_aes128_sha256 = { .cipher = &s2n_aes128, .hmac_alg = S2N_HMAC_SHA256, .flags = 0, .encryption_limit = UINT64_MAX, }; const struct s2n_record_algorithm s2n_record_alg_aes128_sha256_composite = { .cipher = &s2n_aes128_sha256, .hmac_alg = S2N_HMAC_NONE, .encryption_limit = UINT64_MAX, }; const struct s2n_record_algorithm s2n_record_alg_aes256_sha = { .cipher = &s2n_aes256, .hmac_alg = S2N_HMAC_SHA1, .flags = 0, .encryption_limit = UINT64_MAX, }; const struct s2n_record_algorithm s2n_record_alg_aes256_sslv3_sha = { .cipher = &s2n_aes256, .hmac_alg = S2N_HMAC_SSLv3_SHA1, .flags = 0, .encryption_limit = UINT64_MAX, }; const struct s2n_record_algorithm s2n_record_alg_aes256_sha_composite = { .cipher = &s2n_aes256_sha, .hmac_alg = S2N_HMAC_NONE, .flags = 0, .encryption_limit = UINT64_MAX, }; const struct s2n_record_algorithm s2n_record_alg_aes256_sha256 = { .cipher = &s2n_aes256, .hmac_alg = S2N_HMAC_SHA256, .flags = 0, .encryption_limit = UINT64_MAX, }; const struct s2n_record_algorithm s2n_record_alg_aes256_sha256_composite = { .cipher = &s2n_aes256_sha256, .hmac_alg = S2N_HMAC_NONE, .encryption_limit = UINT64_MAX, }; const struct s2n_record_algorithm s2n_record_alg_aes256_sha384 = { .cipher = &s2n_aes256, .hmac_alg = S2N_HMAC_SHA384, .flags = 0, .encryption_limit = UINT64_MAX, }; const struct s2n_record_algorithm s2n_record_alg_aes128_gcm = { .cipher = &s2n_aes128_gcm, .hmac_alg = S2N_HMAC_NONE, .flags = S2N_TLS12_AES_GCM_AEAD_NONCE, .encryption_limit = UINT64_MAX, }; const struct s2n_record_algorithm s2n_record_alg_aes256_gcm = { .cipher = &s2n_aes256_gcm, .hmac_alg = S2N_HMAC_NONE, .flags = S2N_TLS12_AES_GCM_AEAD_NONCE, .encryption_limit = UINT64_MAX, }; const struct s2n_record_algorithm s2n_record_alg_chacha20_poly1305 = { .cipher = &s2n_chacha20_poly1305, .hmac_alg = S2N_HMAC_NONE, /* Per RFC 7905, ChaCha20-Poly1305 will use a nonce construction expected to be used in TLS1.3. * Give it a distinct 1.2 nonce value in case this changes. */ .flags = S2N_TLS12_CHACHA_POLY_AEAD_NONCE, .encryption_limit = UINT64_MAX, }; /* TLS 1.3 Record Algorithms */ const struct s2n_record_algorithm s2n_tls13_record_alg_aes128_gcm = { .cipher = &s2n_tls13_aes128_gcm, .hmac_alg = S2N_HMAC_NONE, /* previously used in 1.2 prf, we do not need this */ .flags = S2N_TLS13_RECORD_AEAD_NONCE, .encryption_limit = S2N_TLS13_AES_GCM_MAXIMUM_RECORD_NUMBER, }; const struct s2n_record_algorithm s2n_tls13_record_alg_aes256_gcm = { .cipher = &s2n_tls13_aes256_gcm, .hmac_alg = S2N_HMAC_NONE, .flags = S2N_TLS13_RECORD_AEAD_NONCE, .encryption_limit = S2N_TLS13_AES_GCM_MAXIMUM_RECORD_NUMBER, }; const struct s2n_record_algorithm s2n_tls13_record_alg_chacha20_poly1305 = { .cipher = &s2n_chacha20_poly1305, .hmac_alg = S2N_HMAC_NONE, /* this mirrors s2n_record_alg_chacha20_poly1305 with the exception of TLS 1.3 nonce flag */ .flags = S2N_TLS13_RECORD_AEAD_NONCE, .encryption_limit = UINT64_MAX, }; /********************* * S2n Cipher Suites * *********************/ /* This is the initial cipher suite, but is never negotiated */ struct s2n_cipher_suite s2n_null_cipher_suite = { .available = 1, .name = "TLS_NULL_WITH_NULL_NULL", .iana_name = "TLS_NULL_WITH_NULL_NULL", .iana_value = { TLS_NULL_WITH_NULL_NULL }, .key_exchange_alg = &s2n_rsa, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = &s2n_record_alg_null, }; struct s2n_cipher_suite s2n_rsa_with_rc4_128_md5 = /* 0x00,0x04 */ { .available = 0, .name = "RC4-MD5", .iana_name = "TLS_RSA_WITH_RC4_128_MD5", .iana_value = { TLS_RSA_WITH_RC4_128_MD5 }, .key_exchange_alg = &s2n_rsa, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_rc4_md5 }, .num_record_algs = 1, .sslv3_record_alg = &s2n_record_alg_rc4_sslv3_md5, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_SSLv3, }; struct s2n_cipher_suite s2n_rsa_with_rc4_128_sha = /* 0x00,0x05 */ { .available = 0, .name = "RC4-SHA", .iana_name = "TLS_RSA_WITH_RC4_128_SHA", .iana_value = { TLS_RSA_WITH_RC4_128_SHA }, .key_exchange_alg = &s2n_rsa, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_rc4_sha }, .num_record_algs = 1, .sslv3_record_alg = &s2n_record_alg_rc4_sslv3_sha, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_SSLv3, }; struct s2n_cipher_suite s2n_rsa_with_3des_ede_cbc_sha = /* 0x00,0x0A */ { .available = 0, .name = "DES-CBC3-SHA", .iana_name = "TLS_RSA_WITH_3DES_EDE_CBC_SHA", .iana_value = { TLS_RSA_WITH_3DES_EDE_CBC_SHA }, .key_exchange_alg = &s2n_rsa, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_3des_sha }, .num_record_algs = 1, .sslv3_record_alg = &s2n_record_alg_3des_sslv3_sha, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_SSLv3, }; struct s2n_cipher_suite s2n_dhe_rsa_with_3des_ede_cbc_sha = /* 0x00,0x16 */ { .available = 0, .name = "DHE-RSA-DES-CBC3-SHA", .iana_name = "TLS_DHE_RSA_WITH_3DES_EDE_CBC_SHA", .iana_value = { TLS_DHE_RSA_WITH_3DES_EDE_CBC_SHA }, .key_exchange_alg = &s2n_dhe, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_3des_sha }, .num_record_algs = 1, .sslv3_record_alg = &s2n_record_alg_3des_sslv3_sha, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_SSLv3, }; struct s2n_cipher_suite s2n_rsa_with_aes_128_cbc_sha = /* 0x00,0x2F */ { .available = 0, .name = "AES128-SHA", .iana_name = "TLS_RSA_WITH_AES_128_CBC_SHA", .iana_value = { TLS_RSA_WITH_AES_128_CBC_SHA }, .key_exchange_alg = &s2n_rsa, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_aes128_sha_composite, &s2n_record_alg_aes128_sha }, .num_record_algs = 2, .sslv3_record_alg = &s2n_record_alg_aes128_sslv3_sha, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_SSLv3, }; struct s2n_cipher_suite s2n_dhe_rsa_with_aes_128_cbc_sha = /* 0x00,0x33 */ { .available = 0, .name = "DHE-RSA-AES128-SHA", .iana_name = "TLS_DHE_RSA_WITH_AES_128_CBC_SHA", .iana_value = { TLS_DHE_RSA_WITH_AES_128_CBC_SHA }, .key_exchange_alg = &s2n_dhe, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_aes128_sha_composite, &s2n_record_alg_aes128_sha }, .num_record_algs = 2, .sslv3_record_alg = &s2n_record_alg_aes128_sslv3_sha, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_SSLv3, }; struct s2n_cipher_suite s2n_rsa_with_aes_256_cbc_sha = /* 0x00,0x35 */ { .available = 0, .name = "AES256-SHA", .iana_name = "TLS_RSA_WITH_AES_256_CBC_SHA", .iana_value = { TLS_RSA_WITH_AES_256_CBC_SHA }, .key_exchange_alg = &s2n_rsa, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_aes256_sha_composite, &s2n_record_alg_aes256_sha }, .num_record_algs = 2, .sslv3_record_alg = &s2n_record_alg_aes256_sslv3_sha, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_SSLv3, }; struct s2n_cipher_suite s2n_dhe_rsa_with_aes_256_cbc_sha = /* 0x00,0x39 */ { .available = 0, .name = "DHE-RSA-AES256-SHA", .iana_name = "TLS_DHE_RSA_WITH_AES_256_CBC_SHA", .iana_value = { TLS_DHE_RSA_WITH_AES_256_CBC_SHA }, .key_exchange_alg = &s2n_dhe, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_aes256_sha_composite, &s2n_record_alg_aes256_sha }, .num_record_algs = 2, .sslv3_record_alg = &s2n_record_alg_aes256_sslv3_sha, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_SSLv3, }; struct s2n_cipher_suite s2n_rsa_with_aes_128_cbc_sha256 = /* 0x00,0x3C */ { .available = 0, .name = "AES128-SHA256", .iana_name = "TLS_RSA_WITH_AES_128_CBC_SHA256", .iana_value = { TLS_RSA_WITH_AES_128_CBC_SHA256 }, .key_exchange_alg = &s2n_rsa, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_aes128_sha256_composite, &s2n_record_alg_aes128_sha256 }, .num_record_algs = 2, .sslv3_record_alg = NULL, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_TLS12, }; struct s2n_cipher_suite s2n_rsa_with_aes_256_cbc_sha256 = /* 0x00,0x3D */ { .available = 0, .name = "AES256-SHA256", .iana_name = "TLS_RSA_WITH_AES_256_CBC_SHA256", .iana_value = { TLS_RSA_WITH_AES_256_CBC_SHA256 }, .key_exchange_alg = &s2n_rsa, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_aes256_sha256_composite, &s2n_record_alg_aes256_sha256 }, .num_record_algs = 2, .sslv3_record_alg = NULL, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_TLS12, }; struct s2n_cipher_suite s2n_dhe_rsa_with_aes_128_cbc_sha256 = /* 0x00,0x67 */ { .available = 0, .name = "DHE-RSA-AES128-SHA256", .iana_name = "TLS_DHE_RSA_WITH_AES_128_CBC_SHA256", .iana_value = { TLS_DHE_RSA_WITH_AES_128_CBC_SHA256 }, .key_exchange_alg = &s2n_dhe, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_aes128_sha256_composite, &s2n_record_alg_aes128_sha256 }, .num_record_algs = 2, .sslv3_record_alg = NULL, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_TLS12, }; struct s2n_cipher_suite s2n_dhe_rsa_with_aes_256_cbc_sha256 = /* 0x00,0x6B */ { .available = 0, .name = "DHE-RSA-AES256-SHA256", .iana_name = "TLS_DHE_RSA_WITH_AES_256_CBC_SHA256", .iana_value = { TLS_DHE_RSA_WITH_AES_256_CBC_SHA256 }, .key_exchange_alg = &s2n_dhe, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_aes256_sha256_composite, &s2n_record_alg_aes256_sha256 }, .num_record_algs = 2, .sslv3_record_alg = NULL, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_TLS12, }; struct s2n_cipher_suite s2n_rsa_with_aes_128_gcm_sha256 = /* 0x00,0x9C */ { .available = 0, .name = "AES128-GCM-SHA256", .iana_name = "TLS_RSA_WITH_AES_128_GCM_SHA256", .iana_value = { TLS_RSA_WITH_AES_128_GCM_SHA256 }, .key_exchange_alg = &s2n_rsa, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_aes128_gcm }, .num_record_algs = 1, .sslv3_record_alg = NULL, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_TLS12, }; struct s2n_cipher_suite s2n_rsa_with_aes_256_gcm_sha384 = /* 0x00,0x9D */ { .available = 0, .name = "AES256-GCM-SHA384", .iana_name = "TLS_RSA_WITH_AES_256_GCM_SHA384", .iana_value = { TLS_RSA_WITH_AES_256_GCM_SHA384 }, .key_exchange_alg = &s2n_rsa, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_aes256_gcm }, .num_record_algs = 1, .sslv3_record_alg = NULL, .prf_alg = S2N_HMAC_SHA384, .minimum_required_tls_version = S2N_TLS12, }; struct s2n_cipher_suite s2n_dhe_rsa_with_aes_128_gcm_sha256 = /* 0x00,0x9E */ { .available = 0, .name = "DHE-RSA-AES128-GCM-SHA256", .iana_name = "TLS_DHE_RSA_WITH_AES_128_GCM_SHA256", .iana_value = { TLS_DHE_RSA_WITH_AES_128_GCM_SHA256 }, .key_exchange_alg = &s2n_dhe, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_aes128_gcm }, .num_record_algs = 1, .sslv3_record_alg = NULL, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_TLS12, }; struct s2n_cipher_suite s2n_dhe_rsa_with_aes_256_gcm_sha384 = /* 0x00,0x9F */ { .available = 0, .name = "DHE-RSA-AES256-GCM-SHA384", .iana_name = "TLS_DHE_RSA_WITH_AES_256_GCM_SHA384", .iana_value = { TLS_DHE_RSA_WITH_AES_256_GCM_SHA384 }, .key_exchange_alg = &s2n_dhe, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_aes256_gcm }, .num_record_algs = 1, .sslv3_record_alg = NULL, .prf_alg = S2N_HMAC_SHA384, .minimum_required_tls_version = S2N_TLS12, }; struct s2n_cipher_suite s2n_ecdhe_ecdsa_with_aes_128_cbc_sha = /* 0xC0,0x09 */ { .available = 0, .name = "ECDHE-ECDSA-AES128-SHA", .iana_name = "TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA", .iana_value = { TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA }, .key_exchange_alg = &s2n_ecdhe, .auth_method = S2N_AUTHENTICATION_ECDSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_aes128_sha_composite, &s2n_record_alg_aes128_sha }, .num_record_algs = 2, .sslv3_record_alg = &s2n_record_alg_aes128_sslv3_sha, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_SSLv3, }; struct s2n_cipher_suite s2n_ecdhe_ecdsa_with_aes_256_cbc_sha = /* 0xC0,0x0A */ { .available = 0, .name = "ECDHE-ECDSA-AES256-SHA", .iana_name = "TLS_ECDHE_ECDSA_WITH_AES_256_CBC_SHA", .iana_value = { TLS_ECDHE_ECDSA_WITH_AES_256_CBC_SHA }, .key_exchange_alg = &s2n_ecdhe, .auth_method = S2N_AUTHENTICATION_ECDSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_aes256_sha_composite, &s2n_record_alg_aes256_sha }, .num_record_algs = 2, .sslv3_record_alg = &s2n_record_alg_aes256_sslv3_sha, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_SSLv3, }; struct s2n_cipher_suite s2n_ecdhe_rsa_with_rc4_128_sha = /* 0xC0,0x11 */ { .available = 0, .name = "ECDHE-RSA-RC4-SHA", .iana_name = "TLS_ECDHE_RSA_WITH_RC4_128_SHA", .iana_value = { TLS_ECDHE_RSA_WITH_RC4_128_SHA }, .key_exchange_alg = &s2n_ecdhe, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_rc4_sha }, .num_record_algs = 1, .sslv3_record_alg = &s2n_record_alg_rc4_sslv3_sha, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_SSLv3, }; struct s2n_cipher_suite s2n_ecdhe_rsa_with_3des_ede_cbc_sha = /* 0xC0,0x12 */ { .available = 0, .name = "ECDHE-RSA-DES-CBC3-SHA", .iana_name = "TLS_ECDHE_RSA_WITH_3DES_EDE_CBC_SHA", .iana_value = { TLS_ECDHE_RSA_WITH_3DES_EDE_CBC_SHA }, .key_exchange_alg = &s2n_ecdhe, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_3des_sha }, .num_record_algs = 1, .sslv3_record_alg = &s2n_record_alg_3des_sslv3_sha, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_SSLv3, }; struct s2n_cipher_suite s2n_ecdhe_rsa_with_aes_128_cbc_sha = /* 0xC0,0x13 */ { .available = 0, .name = "ECDHE-RSA-AES128-SHA", .iana_name = "TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA", .iana_value = { TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA }, .key_exchange_alg = &s2n_ecdhe, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_aes128_sha_composite, &s2n_record_alg_aes128_sha }, .num_record_algs = 2, .sslv3_record_alg = &s2n_record_alg_aes128_sslv3_sha, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_SSLv3, }; struct s2n_cipher_suite s2n_ecdhe_rsa_with_aes_256_cbc_sha = /* 0xC0,0x14 */ { .available = 0, .name = "ECDHE-RSA-AES256-SHA", .iana_name = "TLS_ECDHE_RSA_WITH_AES_256_CBC_SHA", .iana_value = { TLS_ECDHE_RSA_WITH_AES_256_CBC_SHA }, .key_exchange_alg = &s2n_ecdhe, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_aes256_sha_composite, &s2n_record_alg_aes256_sha }, .num_record_algs = 2, .sslv3_record_alg = &s2n_record_alg_aes256_sslv3_sha, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_SSLv3, }; struct s2n_cipher_suite s2n_ecdhe_ecdsa_with_aes_128_cbc_sha256 = /* 0xC0,0x23 */ { .available = 0, .name = "ECDHE-ECDSA-AES128-SHA256", .iana_name = "TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA256", .iana_value = { TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA256 }, .key_exchange_alg = &s2n_ecdhe, .auth_method = S2N_AUTHENTICATION_ECDSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_aes128_sha256_composite, &s2n_record_alg_aes128_sha256 }, .num_record_algs = 2, .sslv3_record_alg = NULL, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_TLS12, }; struct s2n_cipher_suite s2n_ecdhe_ecdsa_with_aes_256_cbc_sha384 = /* 0xC0,0x24 */ { .available = 0, .name = "ECDHE-ECDSA-AES256-SHA384", .iana_name = "TLS_ECDHE_ECDSA_WITH_AES_256_CBC_SHA384", .iana_value = { TLS_ECDHE_ECDSA_WITH_AES_256_CBC_SHA384 }, .key_exchange_alg = &s2n_ecdhe, .auth_method = S2N_AUTHENTICATION_ECDSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_aes256_sha384 }, .num_record_algs = 1, .sslv3_record_alg = NULL, .prf_alg = S2N_HMAC_SHA384, .minimum_required_tls_version = S2N_TLS12, }; struct s2n_cipher_suite s2n_ecdhe_rsa_with_aes_128_cbc_sha256 = /* 0xC0,0x27 */ { .available = 0, .name = "ECDHE-RSA-AES128-SHA256", .iana_name = "TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA256", .iana_value = { TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA256 }, .key_exchange_alg = &s2n_ecdhe, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_aes128_sha256_composite, &s2n_record_alg_aes128_sha256 }, .num_record_algs = 2, .sslv3_record_alg = NULL, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_TLS12, }; struct s2n_cipher_suite s2n_ecdhe_rsa_with_aes_256_cbc_sha384 = /* 0xC0,0x28 */ { .available = 0, .name = "ECDHE-RSA-AES256-SHA384", .iana_name = "TLS_ECDHE_RSA_WITH_AES_256_CBC_SHA384", .iana_value = { TLS_ECDHE_RSA_WITH_AES_256_CBC_SHA384 }, .key_exchange_alg = &s2n_ecdhe, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_aes256_sha384 }, .num_record_algs = 1, .sslv3_record_alg = NULL, .prf_alg = S2N_HMAC_SHA384, .minimum_required_tls_version = S2N_TLS12, }; struct s2n_cipher_suite s2n_ecdhe_ecdsa_with_aes_128_gcm_sha256 = /* 0xC0,0x2B */ { .available = 0, .name = "ECDHE-ECDSA-AES128-GCM-SHA256", .iana_name = "TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256", .iana_value = { TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256 }, .key_exchange_alg = &s2n_ecdhe, .auth_method = S2N_AUTHENTICATION_ECDSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_aes128_gcm }, .num_record_algs = 1, .sslv3_record_alg = NULL, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_TLS12, }; struct s2n_cipher_suite s2n_ecdhe_ecdsa_with_aes_256_gcm_sha384 = /* 0xC0,0x2C */ { .available = 0, .name = "ECDHE-ECDSA-AES256-GCM-SHA384", .iana_name = "TLS_ECDHE_ECDSA_WITH_AES_256_GCM_SHA384", .iana_value = { TLS_ECDHE_ECDSA_WITH_AES_256_GCM_SHA384 }, .key_exchange_alg = &s2n_ecdhe, .auth_method = S2N_AUTHENTICATION_ECDSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_aes256_gcm }, .num_record_algs = 1, .sslv3_record_alg = NULL, .prf_alg = S2N_HMAC_SHA384, .minimum_required_tls_version = S2N_TLS12, }; struct s2n_cipher_suite s2n_ecdhe_rsa_with_aes_128_gcm_sha256 = /* 0xC0,0x2F */ { .available = 0, .name = "ECDHE-RSA-AES128-GCM-SHA256", .iana_name = "TLS_ECDHE_RSA_WITH_AES_128_GCM_SHA256", .iana_value = { TLS_ECDHE_RSA_WITH_AES_128_GCM_SHA256 }, .key_exchange_alg = &s2n_ecdhe, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_aes128_gcm }, .num_record_algs = 1, .sslv3_record_alg = NULL, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_TLS12, }; struct s2n_cipher_suite s2n_ecdhe_rsa_with_aes_256_gcm_sha384 = /* 0xC0,0x30 */ { .available = 0, .name = "ECDHE-RSA-AES256-GCM-SHA384", .iana_name = "TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384", .iana_value = { TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384 }, .key_exchange_alg = &s2n_ecdhe, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_aes256_gcm }, .num_record_algs = 1, .sslv3_record_alg = NULL, .prf_alg = S2N_HMAC_SHA384, .minimum_required_tls_version = S2N_TLS12, }; struct s2n_cipher_suite s2n_ecdhe_rsa_with_chacha20_poly1305_sha256 = /* 0xCC,0xA8 */ { .available = 0, .name = "ECDHE-RSA-CHACHA20-POLY1305", .iana_name = "TLS_ECDHE_RSA_WITH_CHACHA20_POLY1305_SHA256", .iana_value = { TLS_ECDHE_RSA_WITH_CHACHA20_POLY1305_SHA256 }, .key_exchange_alg = &s2n_ecdhe, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_chacha20_poly1305 }, .num_record_algs = 1, .sslv3_record_alg = NULL, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_TLS12, }; struct s2n_cipher_suite s2n_ecdhe_ecdsa_with_chacha20_poly1305_sha256 = /* 0xCC,0xA9 */ { .available = 0, .name = "ECDHE-ECDSA-CHACHA20-POLY1305", .iana_name = "TLS_ECDHE_ECDSA_WITH_CHACHA20_POLY1305_SHA256", .iana_value = { TLS_ECDHE_ECDSA_WITH_CHACHA20_POLY1305_SHA256 }, .key_exchange_alg = &s2n_ecdhe, .auth_method = S2N_AUTHENTICATION_ECDSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_chacha20_poly1305 }, .num_record_algs = 1, .sslv3_record_alg = NULL, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_TLS12, }; struct s2n_cipher_suite s2n_dhe_rsa_with_chacha20_poly1305_sha256 = /* 0xCC,0xAA */ { .available = 0, .name = "DHE-RSA-CHACHA20-POLY1305", .iana_name = "TLS_DHE_RSA_WITH_CHACHA20_POLY1305_SHA256", .iana_value = { TLS_DHE_RSA_WITH_CHACHA20_POLY1305_SHA256 }, .key_exchange_alg = &s2n_dhe, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_chacha20_poly1305 }, .num_record_algs = 1, .sslv3_record_alg = NULL, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_TLS12, }; /* From https://tools.ietf.org/html/draft-campagna-tls-bike-sike-hybrid */ struct s2n_cipher_suite s2n_ecdhe_kyber_rsa_with_aes_256_gcm_sha384 = /* 0xFF, 0x0C */ { .available = 0, .name = "ECDHE-KYBER-RSA-AES256-GCM-SHA384", .iana_name = "TLS_ECDHE_KYBER_RSA_WITH_AES_256_GCM_SHA384", .iana_value = { TLS_ECDHE_KYBER_RSA_WITH_AES_256_GCM_SHA384 }, .key_exchange_alg = &s2n_hybrid_ecdhe_kem, .auth_method = S2N_AUTHENTICATION_RSA, .record_alg = NULL, .all_record_algs = { &s2n_record_alg_aes256_gcm }, .num_record_algs = 1, .sslv3_record_alg = NULL, .prf_alg = S2N_HMAC_SHA384, .minimum_required_tls_version = S2N_TLS12, }; struct s2n_cipher_suite s2n_tls13_aes_128_gcm_sha256 = { .available = 0, .name = "TLS_AES_128_GCM_SHA256", .iana_name = "TLS_AES_128_GCM_SHA256", .iana_value = { TLS_AES_128_GCM_SHA256 }, .key_exchange_alg = &s2n_tls13_kex, .auth_method = S2N_AUTHENTICATION_METHOD_TLS13, .record_alg = NULL, .all_record_algs = { &s2n_tls13_record_alg_aes128_gcm }, .num_record_algs = 1, .sslv3_record_alg = NULL, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_TLS13, }; struct s2n_cipher_suite s2n_tls13_aes_256_gcm_sha384 = { .available = 0, .name = "TLS_AES_256_GCM_SHA384", .iana_name = "TLS_AES_256_GCM_SHA384", .iana_value = { TLS_AES_256_GCM_SHA384 }, .key_exchange_alg = &s2n_tls13_kex, .auth_method = S2N_AUTHENTICATION_METHOD_TLS13, .record_alg = NULL, .all_record_algs = { &s2n_tls13_record_alg_aes256_gcm }, .num_record_algs = 1, .sslv3_record_alg = NULL, .prf_alg = S2N_HMAC_SHA384, .minimum_required_tls_version = S2N_TLS13, }; struct s2n_cipher_suite s2n_tls13_chacha20_poly1305_sha256 = { .available = 0, .name = "TLS_CHACHA20_POLY1305_SHA256", .iana_name = "TLS_CHACHA20_POLY1305_SHA256", .iana_value = { TLS_CHACHA20_POLY1305_SHA256 }, .key_exchange_alg = &s2n_tls13_kex, .auth_method = S2N_AUTHENTICATION_METHOD_TLS13, .record_alg = NULL, .all_record_algs = { &s2n_tls13_record_alg_chacha20_poly1305 }, .num_record_algs = 1, .sslv3_record_alg = NULL, .prf_alg = S2N_HMAC_SHA256, .minimum_required_tls_version = S2N_TLS13, }; /* All of the cipher suites that s2n negotiates in order of IANA value. * New cipher suites MUST be added here, IN ORDER, or they will not be * properly initialized. */ static struct s2n_cipher_suite *s2n_all_cipher_suites[] = { &s2n_rsa_with_rc4_128_md5, /* 0x00,0x04 */ &s2n_rsa_with_rc4_128_sha, /* 0x00,0x05 */ &s2n_rsa_with_3des_ede_cbc_sha, /* 0x00,0x0A */ &s2n_dhe_rsa_with_3des_ede_cbc_sha, /* 0x00,0x16 */ &s2n_rsa_with_aes_128_cbc_sha, /* 0x00,0x2F */ &s2n_dhe_rsa_with_aes_128_cbc_sha, /* 0x00,0x33 */ &s2n_rsa_with_aes_256_cbc_sha, /* 0x00,0x35 */ &s2n_dhe_rsa_with_aes_256_cbc_sha, /* 0x00,0x39 */ &s2n_rsa_with_aes_128_cbc_sha256, /* 0x00,0x3C */ &s2n_rsa_with_aes_256_cbc_sha256, /* 0x00,0x3D */ &s2n_dhe_rsa_with_aes_128_cbc_sha256, /* 0x00,0x67 */ &s2n_dhe_rsa_with_aes_256_cbc_sha256, /* 0x00,0x6B */ &s2n_rsa_with_aes_128_gcm_sha256, /* 0x00,0x9C */ &s2n_rsa_with_aes_256_gcm_sha384, /* 0x00,0x9D */ &s2n_dhe_rsa_with_aes_128_gcm_sha256, /* 0x00,0x9E */ &s2n_dhe_rsa_with_aes_256_gcm_sha384, /* 0x00,0x9F */ &s2n_tls13_aes_128_gcm_sha256, /* 0x13,0x01 */ &s2n_tls13_aes_256_gcm_sha384, /* 0x13,0x02 */ &s2n_tls13_chacha20_poly1305_sha256, /* 0x13,0x03 */ &s2n_ecdhe_ecdsa_with_aes_128_cbc_sha, /* 0xC0,0x09 */ &s2n_ecdhe_ecdsa_with_aes_256_cbc_sha, /* 0xC0,0x0A */ &s2n_ecdhe_rsa_with_rc4_128_sha, /* 0xC0,0x11 */ &s2n_ecdhe_rsa_with_3des_ede_cbc_sha, /* 0xC0,0x12 */ &s2n_ecdhe_rsa_with_aes_128_cbc_sha, /* 0xC0,0x13 */ &s2n_ecdhe_rsa_with_aes_256_cbc_sha, /* 0xC0,0x14 */ &s2n_ecdhe_ecdsa_with_aes_128_cbc_sha256, /* 0xC0,0x23 */ &s2n_ecdhe_ecdsa_with_aes_256_cbc_sha384, /* 0xC0,0x24 */ &s2n_ecdhe_rsa_with_aes_128_cbc_sha256, /* 0xC0,0x27 */ &s2n_ecdhe_rsa_with_aes_256_cbc_sha384, /* 0xC0,0x28 */ &s2n_ecdhe_ecdsa_with_aes_128_gcm_sha256, /* 0xC0,0x2B */ &s2n_ecdhe_ecdsa_with_aes_256_gcm_sha384, /* 0xC0,0x2C */ &s2n_ecdhe_rsa_with_aes_128_gcm_sha256, /* 0xC0,0x2F */ &s2n_ecdhe_rsa_with_aes_256_gcm_sha384, /* 0xC0,0x30 */ &s2n_ecdhe_rsa_with_chacha20_poly1305_sha256, /* 0xCC,0xA8 */ &s2n_ecdhe_ecdsa_with_chacha20_poly1305_sha256, /* 0xCC,0xA9 */ &s2n_dhe_rsa_with_chacha20_poly1305_sha256, /* 0xCC,0xAA */ &s2n_ecdhe_kyber_rsa_with_aes_256_gcm_sha384, /* 0xFF,0x0C */ }; /* All supported ciphers. Exposed for integration testing. */ const struct s2n_cipher_preferences cipher_preferences_test_all = { .count = s2n_array_len(s2n_all_cipher_suites), .suites = s2n_all_cipher_suites, }; /* All TLS12 Cipher Suites */ static struct s2n_cipher_suite *s2n_all_tls12_cipher_suites[] = { &s2n_rsa_with_rc4_128_md5, /* 0x00,0x04 */ &s2n_rsa_with_rc4_128_sha, /* 0x00,0x05 */ &s2n_rsa_with_3des_ede_cbc_sha, /* 0x00,0x0A */ &s2n_dhe_rsa_with_3des_ede_cbc_sha, /* 0x00,0x16 */ &s2n_rsa_with_aes_128_cbc_sha, /* 0x00,0x2F */ &s2n_dhe_rsa_with_aes_128_cbc_sha, /* 0x00,0x33 */ &s2n_rsa_with_aes_256_cbc_sha, /* 0x00,0x35 */ &s2n_dhe_rsa_with_aes_256_cbc_sha, /* 0x00,0x39 */ &s2n_rsa_with_aes_128_cbc_sha256, /* 0x00,0x3C */ &s2n_rsa_with_aes_256_cbc_sha256, /* 0x00,0x3D */ &s2n_dhe_rsa_with_aes_128_cbc_sha256, /* 0x00,0x67 */ &s2n_dhe_rsa_with_aes_256_cbc_sha256, /* 0x00,0x6B */ &s2n_rsa_with_aes_128_gcm_sha256, /* 0x00,0x9C */ &s2n_rsa_with_aes_256_gcm_sha384, /* 0x00,0x9D */ &s2n_dhe_rsa_with_aes_128_gcm_sha256, /* 0x00,0x9E */ &s2n_dhe_rsa_with_aes_256_gcm_sha384, /* 0x00,0x9F */ &s2n_ecdhe_ecdsa_with_aes_128_cbc_sha, /* 0xC0,0x09 */ &s2n_ecdhe_ecdsa_with_aes_256_cbc_sha, /* 0xC0,0x0A */ &s2n_ecdhe_rsa_with_rc4_128_sha, /* 0xC0,0x11 */ &s2n_ecdhe_rsa_with_3des_ede_cbc_sha, /* 0xC0,0x12 */ &s2n_ecdhe_rsa_with_aes_128_cbc_sha, /* 0xC0,0x13 */ &s2n_ecdhe_rsa_with_aes_256_cbc_sha, /* 0xC0,0x14 */ &s2n_ecdhe_ecdsa_with_aes_128_cbc_sha256, /* 0xC0,0x23 */ &s2n_ecdhe_ecdsa_with_aes_256_cbc_sha384, /* 0xC0,0x24 */ &s2n_ecdhe_rsa_with_aes_128_cbc_sha256, /* 0xC0,0x27 */ &s2n_ecdhe_rsa_with_aes_256_cbc_sha384, /* 0xC0,0x28 */ &s2n_ecdhe_ecdsa_with_aes_128_gcm_sha256, /* 0xC0,0x2B */ &s2n_ecdhe_ecdsa_with_aes_256_gcm_sha384, /* 0xC0,0x2C */ &s2n_ecdhe_rsa_with_aes_128_gcm_sha256, /* 0xC0,0x2F */ &s2n_ecdhe_rsa_with_aes_256_gcm_sha384, /* 0xC0,0x30 */ &s2n_ecdhe_rsa_with_chacha20_poly1305_sha256, /* 0xCC,0xA8 */ &s2n_ecdhe_ecdsa_with_chacha20_poly1305_sha256, /* 0xCC,0xA9 */ &s2n_dhe_rsa_with_chacha20_poly1305_sha256, /* 0xCC,0xAA */ &s2n_ecdhe_kyber_rsa_with_aes_256_gcm_sha384, /* 0xFF,0x0C */ }; const struct s2n_cipher_preferences cipher_preferences_test_all_tls12 = { .count = s2n_array_len(s2n_all_tls12_cipher_suites), .suites = s2n_all_tls12_cipher_suites, }; /* All of the cipher suites that s2n can negotiate when in FIPS mode, * in order of IANA value. Exposed for the "test_all_fips" cipher preference list. */ static struct s2n_cipher_suite *s2n_all_fips_cipher_suites[] = { &s2n_dhe_rsa_with_aes_128_cbc_sha, /* 0x00,0x33 */ &s2n_dhe_rsa_with_aes_256_cbc_sha, /* 0x00,0x39 */ &s2n_dhe_rsa_with_aes_128_cbc_sha256, /* 0x00,0x67 */ &s2n_dhe_rsa_with_aes_256_cbc_sha256, /* 0x00,0x6B */ &s2n_dhe_rsa_with_aes_128_gcm_sha256, /* 0x00,0x9E */ &s2n_dhe_rsa_with_aes_256_gcm_sha384, /* 0x00,0x9F */ &s2n_tls13_aes_128_gcm_sha256, /* 0x13,0x01 */ &s2n_tls13_aes_256_gcm_sha384, /* 0x13,0x02 */ &s2n_ecdhe_ecdsa_with_aes_128_cbc_sha, /* 0xC0,0x09 */ &s2n_ecdhe_ecdsa_with_aes_256_cbc_sha, /* 0xC0,0x0A */ &s2n_ecdhe_rsa_with_aes_128_cbc_sha, /* 0xC0,0x13 */ &s2n_ecdhe_rsa_with_aes_256_cbc_sha, /* 0xC0,0x14 */ &s2n_ecdhe_ecdsa_with_aes_128_cbc_sha256, /* 0xC0,0x23 */ &s2n_ecdhe_ecdsa_with_aes_256_cbc_sha384, /* 0xC0,0x24 */ &s2n_ecdhe_rsa_with_aes_128_cbc_sha256, /* 0xC0,0x27 */ &s2n_ecdhe_rsa_with_aes_256_cbc_sha384, /* 0xC0,0x28 */ &s2n_ecdhe_ecdsa_with_aes_128_gcm_sha256, /* 0xC0,0x2B */ &s2n_ecdhe_ecdsa_with_aes_256_gcm_sha384, /* 0xC0,0x2C */ &s2n_ecdhe_rsa_with_aes_128_gcm_sha256, /* 0xC0,0x2F */ &s2n_ecdhe_rsa_with_aes_256_gcm_sha384, /* 0xC0,0x30 */ }; /* All supported FIPS ciphers. Exposed for integration testing. */ const struct s2n_cipher_preferences cipher_preferences_test_all_fips = { .count = s2n_array_len(s2n_all_fips_cipher_suites), .suites = s2n_all_fips_cipher_suites, }; /* All of the ECDSA cipher suites that s2n can negotiate, in order of IANA * value. Exposed for the "test_all_ecdsa" cipher preference list. */ static struct s2n_cipher_suite *s2n_all_ecdsa_cipher_suites[] = { &s2n_ecdhe_ecdsa_with_aes_128_cbc_sha, /* 0xC0,0x09 */ &s2n_ecdhe_ecdsa_with_aes_256_cbc_sha, /* 0xC0,0x0A */ &s2n_ecdhe_ecdsa_with_aes_128_cbc_sha256, /* 0xC0,0x23 */ &s2n_ecdhe_ecdsa_with_aes_256_cbc_sha384, /* 0xC0,0x24 */ &s2n_ecdhe_ecdsa_with_aes_128_gcm_sha256, /* 0xC0,0x2B */ &s2n_ecdhe_ecdsa_with_aes_256_gcm_sha384, /* 0xC0,0x2C */ &s2n_ecdhe_ecdsa_with_chacha20_poly1305_sha256, /* 0xCC,0xA9 */ }; /* All supported ECDSA cipher suites. Exposed for integration testing. */ const struct s2n_cipher_preferences cipher_preferences_test_all_ecdsa = { .count = s2n_array_len(s2n_all_ecdsa_cipher_suites), .suites = s2n_all_ecdsa_cipher_suites, }; /* All cipher suites that uses RSA key exchange. Exposed for unit or integration tests. */ static struct s2n_cipher_suite *s2n_all_rsa_kex_cipher_suites[] = { &s2n_rsa_with_aes_128_cbc_sha, /* 0x00,0x2F */ &s2n_rsa_with_rc4_128_md5, /* 0x00,0x04 */ &s2n_rsa_with_rc4_128_sha, /* 0x00,0x05 */ &s2n_rsa_with_3des_ede_cbc_sha, /* 0x00,0x0A */ &s2n_rsa_with_aes_128_cbc_sha, /* 0x00,0x2F */ &s2n_rsa_with_aes_256_cbc_sha, /* 0x00,0x35 */ &s2n_rsa_with_aes_128_cbc_sha256, /* 0x00,0x3C */ &s2n_rsa_with_aes_256_cbc_sha256, /* 0x00,0x3D */ &s2n_rsa_with_aes_128_gcm_sha256, /* 0x00,0x9C */ &s2n_rsa_with_aes_256_gcm_sha384, /* 0x00,0x9D */ }; /* Cipher preferences with rsa key exchange. Exposed for unit and integration tests. */ const struct s2n_cipher_preferences cipher_preferences_test_all_rsa_kex = { .count = s2n_array_len(s2n_all_rsa_kex_cipher_suites), .suites = s2n_all_rsa_kex_cipher_suites, }; /* All ECDSA cipher suites first, then the rest of the supported ciphers that s2n can negotiate. * Exposed for the "test_ecdsa_priority" cipher preference list. */ static struct s2n_cipher_suite *s2n_ecdsa_priority_cipher_suites[] = { &s2n_ecdhe_ecdsa_with_aes_128_cbc_sha, /* 0xC0,0x09 */ &s2n_ecdhe_ecdsa_with_aes_256_cbc_sha, /* 0xC0,0x0A */ &s2n_ecdhe_ecdsa_with_aes_128_cbc_sha256, /* 0xC0,0x23 */ &s2n_ecdhe_ecdsa_with_aes_256_cbc_sha384, /* 0xC0,0x24 */ &s2n_ecdhe_ecdsa_with_aes_128_gcm_sha256, /* 0xC0,0x2B */ &s2n_ecdhe_ecdsa_with_aes_256_gcm_sha384, /* 0xC0,0x2C */ &s2n_ecdhe_ecdsa_with_chacha20_poly1305_sha256, /* 0xCC,0xA9 */ &s2n_rsa_with_rc4_128_md5, /* 0x00,0x04 */ &s2n_rsa_with_rc4_128_sha, /* 0x00,0x05 */ &s2n_rsa_with_3des_ede_cbc_sha, /* 0x00,0x0A */ &s2n_dhe_rsa_with_3des_ede_cbc_sha, /* 0x00,0x16 */ &s2n_rsa_with_aes_128_cbc_sha, /* 0x00,0x2F */ &s2n_dhe_rsa_with_aes_128_cbc_sha, /* 0x00,0x33 */ &s2n_rsa_with_aes_256_cbc_sha, /* 0x00,0x35 */ &s2n_dhe_rsa_with_aes_256_cbc_sha, /* 0x00,0x39 */ &s2n_rsa_with_aes_128_cbc_sha256, /* 0x00,0x3C */ &s2n_rsa_with_aes_256_cbc_sha256, /* 0x00,0x3D */ &s2n_dhe_rsa_with_aes_128_cbc_sha256, /* 0x00,0x67 */ &s2n_dhe_rsa_with_aes_256_cbc_sha256, /* 0x00,0x6B */ &s2n_rsa_with_aes_128_gcm_sha256, /* 0x00,0x9C */ &s2n_rsa_with_aes_256_gcm_sha384, /* 0x00,0x9D */ &s2n_dhe_rsa_with_aes_128_gcm_sha256, /* 0x00,0x9E */ &s2n_dhe_rsa_with_aes_256_gcm_sha384, /* 0x00,0x9F */ &s2n_ecdhe_rsa_with_rc4_128_sha, /* 0xC0,0x11 */ &s2n_ecdhe_rsa_with_3des_ede_cbc_sha, /* 0xC0,0x12 */ &s2n_ecdhe_rsa_with_aes_128_cbc_sha, /* 0xC0,0x13 */ &s2n_ecdhe_rsa_with_aes_256_cbc_sha, /* 0xC0,0x14 */ &s2n_ecdhe_rsa_with_aes_128_cbc_sha256, /* 0xC0,0x27 */ &s2n_ecdhe_rsa_with_aes_256_cbc_sha384, /* 0xC0,0x28 */ &s2n_ecdhe_rsa_with_aes_128_gcm_sha256, /* 0xC0,0x2F */ &s2n_ecdhe_rsa_with_aes_256_gcm_sha384, /* 0xC0,0x30 */ &s2n_ecdhe_rsa_with_chacha20_poly1305_sha256, /* 0xCC,0xA8 */ &s2n_dhe_rsa_with_chacha20_poly1305_sha256, /* 0xCC,0xAA */ }; /* All cipher suites, but with ECDSA priority. Exposed for integration testing. */ const struct s2n_cipher_preferences cipher_preferences_test_ecdsa_priority = { .count = s2n_array_len(s2n_ecdsa_priority_cipher_suites), .suites = s2n_ecdsa_priority_cipher_suites, }; static struct s2n_cipher_suite *s2n_all_tls13_cipher_suites[] = { &s2n_tls13_aes_128_gcm_sha256, /* 0x13,0x01 */ &s2n_tls13_aes_256_gcm_sha384, /* 0x13,0x02 */ &s2n_tls13_chacha20_poly1305_sha256, /* 0x13,0x03 */ }; const struct s2n_cipher_preferences cipher_preferences_test_all_tls13 = { .count = s2n_array_len(s2n_all_tls13_cipher_suites), .suites = s2n_all_tls13_cipher_suites, }; static bool should_init_crypto = true; static bool crypto_initialized = false; int s2n_crypto_disable_init(void) { POSIX_ENSURE(!crypto_initialized, S2N_ERR_INITIALIZED); should_init_crypto = false; return S2N_SUCCESS; } /* Determines cipher suite availability and selects record algorithms */ int s2n_cipher_suites_init(void) { const int num_cipher_suites = s2n_array_len(s2n_all_cipher_suites); for (int i = 0; i < num_cipher_suites; i++) { struct s2n_cipher_suite *cur_suite = s2n_all_cipher_suites[i]; cur_suite->available = 0; cur_suite->record_alg = NULL; /* Find the highest priority supported record algorithm */ for (int j = 0; j < cur_suite->num_record_algs; j++) { /* Can we use the record algorithm's cipher? Won't be available if the system CPU architecture * doesn't support it or if the libcrypto lacks the feature. All hmac_algs are supported. */ if (cur_suite->all_record_algs[j]->cipher->is_available()) { /* Found a supported record algorithm. Use it. */ cur_suite->available = 1; cur_suite->record_alg = cur_suite->all_record_algs[j]; break; } } /* Mark PQ cipher suites as unavailable if PQ is disabled */ if (s2n_kex_includes(cur_suite->key_exchange_alg, &s2n_kem) && !s2n_pq_is_enabled()) { cur_suite->available = 0; cur_suite->record_alg = NULL; } /* Initialize SSLv3 cipher suite if SSLv3 utilizes a different record algorithm */ if (cur_suite->sslv3_record_alg && cur_suite->sslv3_record_alg->cipher->is_available()) { struct s2n_blob cur_suite_mem = { 0 }; POSIX_GUARD(s2n_blob_init(&cur_suite_mem, (uint8_t *) cur_suite, sizeof(struct s2n_cipher_suite))); struct s2n_blob new_suite_mem = { 0 }; POSIX_GUARD(s2n_dup(&cur_suite_mem, &new_suite_mem)); struct s2n_cipher_suite *new_suite = (struct s2n_cipher_suite *) (void *) new_suite_mem.data; new_suite->available = 1; new_suite->record_alg = cur_suite->sslv3_record_alg; cur_suite->sslv3_cipher_suite = new_suite; } else { cur_suite->sslv3_cipher_suite = cur_suite; } } if (should_init_crypto) { #if !S2N_OPENSSL_VERSION_AT_LEAST(1, 1, 0) /*https://wiki.openssl.org/index.php/Manual:OpenSSL_add_all_algorithms(3)*/ OpenSSL_add_all_algorithms(); #else OPENSSL_init_crypto(OPENSSL_INIT_LOAD_CRYPTO_STRINGS | OPENSSL_INIT_ADD_ALL_CIPHERS | OPENSSL_INIT_ADD_ALL_DIGESTS, NULL); #endif } crypto_initialized = true; return S2N_SUCCESS; } /* Reset any selected record algorithms */ S2N_RESULT s2n_cipher_suites_cleanup(void) { const int num_cipher_suites = s2n_array_len(s2n_all_cipher_suites); for (int i = 0; i < num_cipher_suites; i++) { struct s2n_cipher_suite *cur_suite = s2n_all_cipher_suites[i]; cur_suite->available = 0; cur_suite->record_alg = NULL; /* Release custom SSLv3 cipher suites */ if (cur_suite->sslv3_cipher_suite != cur_suite) { RESULT_GUARD_POSIX(s2n_free_object((uint8_t **) &cur_suite->sslv3_cipher_suite, sizeof(struct s2n_cipher_suite))); } cur_suite->sslv3_cipher_suite = NULL; } if (should_init_crypto) { #if !S2N_OPENSSL_VERSION_AT_LEAST(1, 1, 0) /*https://wiki.openssl.org/index.php/Manual:OpenSSL_add_all_algorithms(3)*/ EVP_cleanup(); /* per the reqs here https://www.openssl.org/docs/man1.1.0/crypto/OPENSSL_init_crypto.html we don't explicitly call * cleanup in later versions */ #endif } return S2N_RESULT_OK; } S2N_RESULT s2n_cipher_suite_from_iana(const uint8_t *iana, size_t iana_len, struct s2n_cipher_suite **cipher_suite) { RESULT_ENSURE_REF(cipher_suite); *cipher_suite = NULL; RESULT_ENSURE_REF(iana); RESULT_ENSURE_EQ(iana_len, S2N_TLS_CIPHER_SUITE_LEN); int low = 0; int top = s2n_array_len(s2n_all_cipher_suites) - 1; /* Perform a textbook binary search */ while (low <= top) { /* Check in the middle */ size_t mid = low + ((top - low) / 2); int m = memcmp(s2n_all_cipher_suites[mid]->iana_value, iana, S2N_TLS_CIPHER_SUITE_LEN); if (m == 0) { *cipher_suite = s2n_all_cipher_suites[mid]; return S2N_RESULT_OK; } else if (m > 0) { top = mid - 1; } else if (m < 0) { low = mid + 1; } } RESULT_BAIL(S2N_ERR_CIPHER_NOT_SUPPORTED); } int s2n_set_cipher_as_client(struct s2n_connection *conn, uint8_t wire[S2N_TLS_CIPHER_SUITE_LEN]) { POSIX_ENSURE_REF(conn); POSIX_ENSURE_REF(conn->secure); POSIX_ENSURE_REF(conn->secure->cipher_suite); const struct s2n_security_policy *security_policy = NULL; POSIX_GUARD(s2n_connection_get_security_policy(conn, &security_policy)); POSIX_ENSURE_REF(security_policy); /** * Ensure that the wire cipher suite is contained in the security * policy, and thus was offered by the client. * *= https://www.rfc-editor.org/rfc/rfc8446#4.1.3 *# A client which receives a *# cipher suite that was not offered MUST abort the handshake with an *# "illegal_parameter" alert. * *= https://www.rfc-editor.org/rfc/rfc8446#4.1.4 *# A client which receives a cipher suite that was not offered MUST *# abort the handshake. * *= https://www.rfc-editor.org/rfc/rfc8446#4.1.4 *# Upon receipt of a HelloRetryRequest, the client MUST check the *# legacy_version, legacy_session_id_echo, cipher_suite **/ struct s2n_cipher_suite *cipher_suite = NULL; for (size_t i = 0; i < security_policy->cipher_preferences->count; i++) { const uint8_t *ours = security_policy->cipher_preferences->suites[i]->iana_value; if (s2n_constant_time_equals(wire, ours, S2N_TLS_CIPHER_SUITE_LEN)) { cipher_suite = security_policy->cipher_preferences->suites[i]; break; } } POSIX_ENSURE(cipher_suite != NULL, S2N_ERR_CIPHER_NOT_SUPPORTED); POSIX_ENSURE(cipher_suite->available, S2N_ERR_CIPHER_NOT_SUPPORTED); /** Clients MUST verify *= https://www.rfc-editor.org/rfc/rfc8446#section-4.2.11 *# that the server selected a cipher suite *# indicating a Hash associated with the PSK **/ if (conn->psk_params.chosen_psk) { POSIX_ENSURE(cipher_suite->prf_alg == conn->psk_params.chosen_psk->hmac_alg, S2N_ERR_CIPHER_NOT_SUPPORTED); } /** *= https://www.rfc-editor.org/rfc/rfc8446#4.1.4 *# Upon receiving *# the ServerHello, clients MUST check that the cipher suite supplied in *# the ServerHello is the same as that in the HelloRetryRequest and *# otherwise abort the handshake with an "illegal_parameter" alert. **/ if (s2n_is_hello_retry_handshake(conn) && !s2n_is_hello_retry_message(conn)) { POSIX_ENSURE(conn->secure->cipher_suite->iana_value == cipher_suite->iana_value, S2N_ERR_CIPHER_NOT_SUPPORTED); return S2N_SUCCESS; } conn->secure->cipher_suite = cipher_suite; /* For SSLv3 use SSLv3-specific ciphers */ if (conn->actual_protocol_version == S2N_SSLv3) { conn->secure->cipher_suite = conn->secure->cipher_suite->sslv3_cipher_suite; POSIX_ENSURE_REF(conn->secure->cipher_suite); } return 0; } static int s2n_wire_ciphers_contain(const uint8_t *match, const uint8_t *wire, uint32_t count, uint32_t cipher_suite_len) { for (size_t i = 0; i < count; i++) { const uint8_t *theirs = wire + (i * cipher_suite_len) + (cipher_suite_len - S2N_TLS_CIPHER_SUITE_LEN); if (s2n_constant_time_equals(match, theirs, S2N_TLS_CIPHER_SUITE_LEN)) { return 1; } } return 0; } bool s2n_cipher_suite_uses_chacha20_alg(struct s2n_cipher_suite *cipher_suite) { return cipher_suite && cipher_suite->record_alg && cipher_suite->record_alg->cipher == &s2n_chacha20_poly1305; } /* Iff the server has enabled allow_chacha20_boosting and the client has a chacha20 cipher suite as its most * preferred cipher suite, then we have mutual chacha20 boosting support. */ static S2N_RESULT s2n_validate_chacha20_boosting(const struct s2n_cipher_preferences *cipher_preferences, const uint8_t *wire, uint32_t cipher_suite_len) { RESULT_ENSURE_REF(cipher_preferences); RESULT_ENSURE_REF(wire); RESULT_ENSURE_EQ(cipher_preferences->allow_chacha20_boosting, true); const uint8_t *clients_first_cipher_iana = wire + cipher_suite_len - S2N_TLS_CIPHER_SUITE_LEN; struct s2n_cipher_suite *client_first_cipher_suite = NULL; RESULT_GUARD(s2n_cipher_suite_from_iana(clients_first_cipher_iana, S2N_TLS_CIPHER_SUITE_LEN, &client_first_cipher_suite)); RESULT_ENSURE_REF(client_first_cipher_suite); RESULT_ENSURE_EQ(s2n_cipher_suite_uses_chacha20_alg(client_first_cipher_suite), true); return S2N_RESULT_OK; } static int s2n_set_cipher_as_server(struct s2n_connection *conn, uint8_t *wire, uint32_t count, uint32_t cipher_suite_len) { POSIX_ENSURE_REF(conn); POSIX_ENSURE_REF(conn->secure); uint8_t renegotiation_info_scsv[S2N_TLS_CIPHER_SUITE_LEN] = { TLS_EMPTY_RENEGOTIATION_INFO_SCSV }; struct s2n_cipher_suite *higher_vers_match = NULL; struct s2n_cipher_suite *non_chacha20_match = NULL; /* RFC 7507 - If client is attempting to negotiate a TLS Version that is lower than the highest supported server * version, and the client cipher list contains TLS_FALLBACK_SCSV, then the server must abort the connection since * TLS_FALLBACK_SCSV should only be present when the client previously failed to negotiate a higher TLS version. */ if (conn->client_protocol_version < conn->server_protocol_version) { uint8_t fallback_scsv[S2N_TLS_CIPHER_SUITE_LEN] = { TLS_FALLBACK_SCSV }; if (s2n_wire_ciphers_contain(fallback_scsv, wire, count, cipher_suite_len)) { POSIX_BAIL(S2N_ERR_FALLBACK_DETECTED); } } if (s2n_wire_ciphers_contain(renegotiation_info_scsv, wire, count, cipher_suite_len)) { /** For renegotiation handshakes: *= https://www.rfc-editor.org/rfc/rfc5746#3.7 *# o When a ClientHello is received, the server MUST verify that it *# does not contain the TLS_EMPTY_RENEGOTIATION_INFO_SCSV SCSV. If *# the SCSV is present, the server MUST abort the handshake. */ POSIX_ENSURE(!s2n_handshake_is_renegotiation(conn), S2N_ERR_BAD_MESSAGE); /** For initial handshakes: *= https://www.rfc-editor.org/rfc/rfc5746#3.6 *# o When a ClientHello is received, the server MUST check if it *# includes the TLS_EMPTY_RENEGOTIATION_INFO_SCSV SCSV. If it does, *# set the secure_renegotiation flag to TRUE. */ conn->secure_renegotiation = 1; } const struct s2n_security_policy *security_policy = NULL; POSIX_GUARD(s2n_connection_get_security_policy(conn, &security_policy)); const struct s2n_cipher_preferences *cipher_preferences = security_policy->cipher_preferences; POSIX_ENSURE_REF(cipher_preferences); bool try_chacha20_boosting = s2n_result_is_ok(s2n_validate_chacha20_boosting(cipher_preferences, wire, cipher_suite_len)); /* * s2n only respects server preference order and chooses the server's * most preferred mutually supported cipher suite. * * If chacha20 boosting is enabled, we prefer chacha20 cipher suites over all * other cipher suites. * * If no mutually supported cipher suites are found, we choose one with a version * too high for the current connection (higher_vers_match). */ for (size_t i = 0; i < cipher_preferences->count; i++) { const uint8_t *ours = cipher_preferences->suites[i]->iana_value; if (s2n_wire_ciphers_contain(ours, wire, count, cipher_suite_len)) { /* We have a match */ struct s2n_cipher_suite *match = cipher_preferences->suites[i]; /* Never use TLS1.3 ciphers on a pre-TLS1.3 connection, and vice versa */ if ((conn->actual_protocol_version >= S2N_TLS13) != (match->minimum_required_tls_version >= S2N_TLS13)) { continue; } /* If connection is for SSLv3, use SSLv3 version of suites */ if (conn->actual_protocol_version == S2N_SSLv3) { match = match->sslv3_cipher_suite; } /* Skip the suite if we don't have an available implementation */ if (!match->available) { continue; } /* Make sure the cipher is valid for available certs */ if (s2n_is_cipher_suite_valid_for_auth(conn, match) != S2N_SUCCESS) { continue; } /* If the kex is not supported continue to the next candidate */ bool kex_supported = false; POSIX_GUARD_RESULT(s2n_kex_supported(match, conn, &kex_supported)); if (!kex_supported) { continue; } /* If the kex is not configured correctly continue to the next candidate */ if (s2n_result_is_error(s2n_configure_kex(match, conn))) { continue; } /** *= https://www.rfc-editor.org/rfc/rfc8446#section-4.2.11 *# The server MUST ensure that it selects a compatible PSK *# (if any) and cipher suite. **/ if (conn->psk_params.chosen_psk != NULL) { if (match->prf_alg != conn->psk_params.chosen_psk->hmac_alg) { continue; } } /* Don't immediately choose a cipher the connection shouldn't be able to support */ if (conn->actual_protocol_version < match->minimum_required_tls_version) { if (!higher_vers_match) { higher_vers_match = match; } continue; } /* The server and client have chacha20 boosting support enabled AND the server identified a negotiable match */ if (try_chacha20_boosting) { if (s2n_cipher_suite_uses_chacha20_alg(match)) { conn->secure->cipher_suite = match; return S2N_SUCCESS; } /* Save the valid non-chacha20 match in case no valid chacha20 match is found */ if (!non_chacha20_match) { non_chacha20_match = match; } continue; } conn->secure->cipher_suite = match; return S2N_SUCCESS; } } if (non_chacha20_match) { conn->secure->cipher_suite = non_chacha20_match; return S2N_SUCCESS; } /* Settle for a cipher with a higher required proto version, if it was set */ if (higher_vers_match) { conn->secure->cipher_suite = higher_vers_match; return S2N_SUCCESS; } POSIX_BAIL(S2N_ERR_CIPHER_NOT_SUPPORTED); } int s2n_set_cipher_as_sslv2_server(struct s2n_connection *conn, uint8_t *wire, uint16_t count) { return s2n_set_cipher_as_server(conn, wire, count, S2N_SSLv2_CIPHER_SUITE_LEN); } int s2n_set_cipher_as_tls_server(struct s2n_connection *conn, uint8_t *wire, uint16_t count) { return s2n_set_cipher_as_server(conn, wire, count, S2N_TLS_CIPHER_SUITE_LEN); } bool s2n_cipher_suite_requires_ecc_extension(struct s2n_cipher_suite *cipher) { if (!cipher) { return false; } /* TLS1.3 does not include key exchange algorithms in its cipher suites, * but the elliptic curves extension is always required. */ if (cipher->minimum_required_tls_version >= S2N_TLS13) { return true; } if (s2n_kex_includes(cipher->key_exchange_alg, &s2n_ecdhe)) { return true; } return false; } bool s2n_cipher_suite_requires_pq_extension(struct s2n_cipher_suite *cipher) { if (!cipher) { return false; } if (s2n_kex_includes(cipher->key_exchange_alg, &s2n_kem)) { return true; } return false; }