/* * (C) 2009 Jack Lloyd * (C) 2016 René Korthaus, Rohde & Schwarz Cybersecurity * * Botan is released under the Simplified BSD License (see license.txt) */ #include "tests.h" #if defined(BOTAN_HAS_X509_CERTIFICATES) #include #include #include #include #include #include #include #include #include #include #include #endif namespace Botan_Tests { namespace { #if defined(BOTAN_HAS_X509_CERTIFICATES) Botan::X509_Time from_date(const int y, const int m, const int d) { Botan::calendar_point t(y, m, d, 0, 0, 0); return Botan::X509_Time(t.to_std_timepoint()); } /* Return some option sets */ Botan::X509_Cert_Options ca_opts() { Botan::X509_Cert_Options opts("Test CA/US/Botan Project/Testing"); opts.uri = "http://botan.randombit.net"; opts.dns = "botan.randombit.net"; opts.email = "testing@randombit.net"; opts.CA_key(1); return opts; } Botan::X509_Cert_Options req_opts1(const std::string& algo) { Botan::X509_Cert_Options opts("Test User 1/US/Botan Project/Testing"); opts.uri = "http://botan.randombit.net"; opts.dns = "botan.randombit.net"; opts.email = "testing@randombit.net"; opts.not_before("160101200000Z"); opts.not_after("300101200000Z"); if(algo == "RSA") { opts.constraints = Botan::Key_Constraints(Botan::KEY_ENCIPHERMENT); } else if(algo == "DSA" || algo == "ECDSA" || algo == "ECGDSA" || algo == "ECKCDSA") { opts.constraints = Botan::Key_Constraints(Botan::DIGITAL_SIGNATURE); } return opts; } Botan::X509_Cert_Options req_opts2() { Botan::X509_Cert_Options opts("Test User 2/US/Botan Project/Testing"); opts.uri = "http://botan.randombit.net"; opts.dns = "botan.randombit.net"; opts.email = "testing@randombit.net"; opts.add_ex_constraint("PKIX.EmailProtection"); return opts; } std::unique_ptr make_a_private_key(const std::string& algo) { std::string params = ""; // default "" means choose acceptable algo-specific params // Here we override defaults as needed if(algo == "RSA") params = "1024"; if(algo == "GOST-34.10") params = "gost_256A"; if(algo == "ECKCDSA" || algo == "ECGDSA") params = "brainpool256r1"; return Botan::create_private_key(algo, Test::rng(), params); } Test::Result test_cert_status_strings() { Test::Result result("Certificate_Status_Code to_string"); std::set seen; result.test_eq("Same string", Botan::to_string(Botan::Certificate_Status_Code::OK), Botan::to_string(Botan::Certificate_Status_Code::VERIFIED)); const std::vector codes = { Botan::Certificate_Status_Code::OCSP_RESPONSE_GOOD, Botan::Certificate_Status_Code::OCSP_SIGNATURE_OK, Botan::Certificate_Status_Code::VALID_CRL_CHECKED, Botan::Certificate_Status_Code::OCSP_NO_HTTP, Botan::Certificate_Status_Code::SIGNATURE_METHOD_TOO_WEAK, Botan::Certificate_Status_Code::UNTRUSTED_HASH, Botan::Certificate_Status_Code::NO_REVOCATION_DATA, Botan::Certificate_Status_Code::CERT_NOT_YET_VALID, Botan::Certificate_Status_Code::CERT_HAS_EXPIRED, Botan::Certificate_Status_Code::OCSP_NOT_YET_VALID, Botan::Certificate_Status_Code::OCSP_HAS_EXPIRED, Botan::Certificate_Status_Code::CRL_NOT_YET_VALID, Botan::Certificate_Status_Code::CRL_HAS_EXPIRED, Botan::Certificate_Status_Code::CERT_ISSUER_NOT_FOUND, Botan::Certificate_Status_Code::CANNOT_ESTABLISH_TRUST, Botan::Certificate_Status_Code::CERT_CHAIN_LOOP, Botan::Certificate_Status_Code::CHAIN_LACKS_TRUST_ROOT, Botan::Certificate_Status_Code::CHAIN_NAME_MISMATCH, Botan::Certificate_Status_Code::POLICY_ERROR, Botan::Certificate_Status_Code::INVALID_USAGE, Botan::Certificate_Status_Code::CERT_CHAIN_TOO_LONG, Botan::Certificate_Status_Code::CA_CERT_NOT_FOR_CERT_ISSUER, Botan::Certificate_Status_Code::NAME_CONSTRAINT_ERROR, Botan::Certificate_Status_Code::CA_CERT_NOT_FOR_CRL_ISSUER, Botan::Certificate_Status_Code::OCSP_CERT_NOT_LISTED, Botan::Certificate_Status_Code::OCSP_BAD_STATUS, Botan::Certificate_Status_Code::CERT_NAME_NOMATCH, Botan::Certificate_Status_Code::UNKNOWN_CRITICAL_EXTENSION, Botan::Certificate_Status_Code::OCSP_SIGNATURE_ERROR, Botan::Certificate_Status_Code::OCSP_ISSUER_NOT_FOUND, Botan::Certificate_Status_Code::OCSP_RESPONSE_MISSING_KEYUSAGE, Botan::Certificate_Status_Code::OCSP_RESPONSE_INVALID, Botan::Certificate_Status_Code::CERT_IS_REVOKED, Botan::Certificate_Status_Code::CRL_BAD_SIGNATURE, Botan::Certificate_Status_Code::SIGNATURE_ERROR, Botan::Certificate_Status_Code::CERT_PUBKEY_INVALID, }; for(auto code : codes) { std::string s = Botan::to_string(code); result.confirm("String is long enough to be informative", s.size() > 12); result.test_eq("No duplicates", seen.count(s), 0); seen.insert(s); } return result; } Test::Result test_x509_dates() { Test::Result result("X509_Time"); Botan::X509_Time time; result.confirm("unset time not set", !time.time_is_set()); time = Botan::X509_Time("080201182200Z", Botan::ASN1_Tag::UTC_TIME); result.confirm("time set after construction", time.time_is_set()); result.test_eq("time readable_string", time.readable_string(), "2008/02/01 18:22:00 UTC"); time = Botan::X509_Time("200305100350Z", Botan::ASN1_Tag::UTC_TIME); result.test_eq("UTC_TIME readable_string", time.readable_string(), "2020/03/05 10:03:50 UTC"); time = Botan::X509_Time("200305100350Z", Botan::ASN1_Tag::UTC_OR_GENERALIZED_TIME); result.test_eq("UTC_OR_GENERALIZED_TIME from UTC_TIME readable_string", time.readable_string(), "2020/03/05 10:03:50 UTC"); time = Botan::X509_Time("20200305100350Z", Botan::ASN1_Tag::UTC_OR_GENERALIZED_TIME); result.test_eq("UTC_OR_GENERALIZED_TIME from GENERALIZED_TIME readable_string", time.readable_string(), "2020/03/05 10:03:50 UTC"); time = Botan::X509_Time("20200305100350Z", Botan::ASN1_Tag::GENERALIZED_TIME); result.test_eq("GENERALIZED_TIME readable_string", time.readable_string(), "2020/03/05 10:03:50 UTC"); // Dates that are valid per X.500 but rejected as unsupported const std::vector valid_but_unsup = { "0802010000-0000", "0802011724+0000", "0406142334-0500", "9906142334+0500", "0006142334-0530", "0006142334+0530", "080201000000-0000", "080201172412+0000", "040614233433-0500", "990614233444+0500", "000614233455-0530", "000614233455+0530", }; // valid length 13 const std::vector valid_utc = { "080201000000Z", "080201172412Z", "040614233433Z", "990614233444Z", "000614233455Z", }; const std::vector invalid_utc = { "", " ", "2008`02-01", "9999-02-01", "2000-02-01 17", "999921", // No seconds "0802010000Z", "0802011724Z", "0406142334Z", "9906142334Z", "0006142334Z", // valid length 13 -> range check "080201000061Z", // seconds too big (61) "080201000060Z", // seconds too big (60, leap seconds not covered by the standard) "0802010000-1Z", // seconds too small (-1) "080201006000Z", // minutes too big (60) "080201240000Z", // hours too big (24:00) // valid length 13 -> invalid numbers "08020123112 Z", "08020123112!Z", "08020123112,Z", "08020123112\nZ", "080201232 33Z", "080201232!33Z", "080201232,33Z", "080201232\n33Z", "0802012 3344Z", "0802012!3344Z", "0802012,3344Z", "08022\n334455Z", "08022 334455Z", "08022!334455Z", "08022,334455Z", "08022\n334455Z", "082 33445511Z", "082!33445511Z", "082,33445511Z", "082\n33445511Z", "2 2211221122Z", "2!2211221122Z", "2,2211221122Z", "2\n2211221122Z", // wrong time zone "080201000000", "080201000000z", // Fractional seconds "170217180154.001Z", // Timezone offset "170217180154+0100", // Extra digits "17021718015400Z", // Non-digits "17021718015aZ", // Trailing garbage "170217180154Zlongtrailinggarbage", // Swapped type "20170217180154Z", }; // valid length 15 const std::vector valid_generalized_time = { "20000305100350Z", }; const std::vector invalid_generalized = { // No trailing Z "20000305100350", // No seconds "200003051003Z", // Fractional seconds "20000305100350.001Z", // Timezone offset "20170217180154+0100", // Extra digits "2017021718015400Z", // Non-digits "2017021718015aZ", // Trailing garbage "20170217180154Zlongtrailinggarbage", // Swapped type "170217180154Z", }; for(auto&& v : valid_but_unsup) { result.test_throws("valid but unsupported", [v]() { Botan::X509_Time t(v, Botan::ASN1_Tag::UTC_TIME); }); } for(auto&& v : valid_utc) { Botan::X509_Time t(v, Botan::ASN1_Tag::UTC_TIME); } for(auto&& v : valid_generalized_time) { Botan::X509_Time t(v, Botan::ASN1_Tag::GENERALIZED_TIME); } for(auto&& v : invalid_utc) { result.test_throws("invalid", [v]() { Botan::X509_Time t(v, Botan::ASN1_Tag::UTC_TIME); }); } for (auto&& v : invalid_generalized) { result.test_throws("invalid", [v]() { Botan::X509_Time t(v, Botan::ASN1_Tag::GENERALIZED_TIME); }); } return result; } Test::Result test_x509_cert(const std::string& sig_algo, const std::string& hash_fn = "SHA-256") { Test::Result result("X509 Unit"); /* Create the CA's key and self-signed cert */ std::unique_ptr ca_key(make_a_private_key(sig_algo)); if(!ca_key) { // Failure because X.509 enabled but requested signature algorithm is not present result.test_note("Skipping due to missing signature algorithm: " + sig_algo); return result; } /* Create the self-signed cert */ Botan::X509_Certificate ca_cert = Botan::X509::create_self_signed_cert(ca_opts(), *ca_key, hash_fn, Test::rng()); result.test_eq("ca key usage", (ca_cert.constraints() & Botan::Key_Constraints(Botan::KEY_CERT_SIGN | Botan::CRL_SIGN)) == Botan::Key_Constraints(Botan::KEY_CERT_SIGN | Botan::CRL_SIGN), true); /* Create user #1's key and cert request */ std::unique_ptr user1_key(make_a_private_key(sig_algo)); Botan::PKCS10_Request user1_req = Botan::X509::create_cert_req(req_opts1(sig_algo), *user1_key, hash_fn, Test::rng()); /* Create user #2's key and cert request */ std::unique_ptr user2_key(make_a_private_key(sig_algo)); Botan::PKCS10_Request user2_req = Botan::X509::create_cert_req(req_opts2(), *user2_key, hash_fn, Test::rng()); /* Create the CA object */ Botan::X509_CA ca(ca_cert, *ca_key, hash_fn, Test::rng()); /* Sign the requests to create the certs */ Botan::X509_Certificate user1_cert = ca.sign_request(user1_req, Test::rng(), from_date(2008, 01, 01), from_date(2033, 01, 01)); Botan::X509_Certificate user2_cert = ca.sign_request(user2_req, Test::rng(), from_date(2008, 01, 01), from_date(2033, 01, 01)); // user#1 creates a self-signed cert on the side Botan::X509_Certificate user1_ss_cert = Botan::X509::create_self_signed_cert(req_opts1(sig_algo), *user1_key, hash_fn, Test::rng()); result.test_eq("user1 key usage", (user1_cert.constraints() & req_opts1(sig_algo).constraints) == req_opts1(sig_algo).constraints, true); /* Copy, assign and compare */ Botan::X509_Certificate user1_cert_copy(user1_cert); result.test_eq("certificate copy", user1_cert == user1_cert_copy, true); user1_cert_copy = user2_cert; result.test_eq("certificate assignment", user2_cert == user1_cert_copy, true); Botan::X509_Certificate user1_cert_differ = ca.sign_request(user1_req, Test::rng(), from_date(2008, 01, 01), from_date(2032, 01, 01)); result.test_eq("certificate differs", user1_cert == user1_cert_differ, false); /* Get cert data */ result.test_eq("x509 version", user1_cert.x509_version(), size_t(3)); result.test_eq("issuer info CN", user1_cert.issuer_info("CN").at(0), ca_opts().common_name); result.test_eq("issuer info Country", user1_cert.issuer_info("C").at(0), ca_opts().country); result.test_eq("issuer info Orga", user1_cert.issuer_info("O").at(0), ca_opts().organization); result.test_eq("issuer info OrgaUnit", user1_cert.issuer_info("OU").at(0), ca_opts().org_unit); Botan::X509_CRL crl1 = ca.new_crl(Test::rng()); /* Verify the certs */ Botan::Path_Validation_Restrictions restrictions(false, 80); Botan::Certificate_Store_In_Memory store; // First try with an empty store Botan::Path_Validation_Result result_no_issuer = Botan::x509_path_validate(user1_cert, restrictions, store); result.test_eq("user 1 issuer not found", result_no_issuer.result_string(), Botan::Path_Validation_Result::status_string(Botan::Certificate_Status_Code::CERT_ISSUER_NOT_FOUND)); store.add_certificate(ca.ca_certificate()); Botan::Path_Validation_Result result_u1 = Botan::x509_path_validate(user1_cert, restrictions, store); if(!result.confirm("user 1 validates", result_u1.successful_validation())) { result.test_note("user 1 validation result was " + result_u1.result_string()); } else { const std::set u1_hashes = result_u1.trusted_hashes(); if(result.test_eq("Single trusted hash", u1_hashes.size(), 1)) { result.test_eq("Hash matches test", *u1_hashes.begin(), hash_fn); } } Botan::Path_Validation_Result result_u2 = Botan::x509_path_validate(user2_cert, restrictions, store); if(!result.confirm("user 2 validates", result_u2.successful_validation())) { result.test_note("user 2 validation result was " + result_u2.result_string()); } Botan::Path_Validation_Result result_self_signed = Botan::x509_path_validate(user1_ss_cert, restrictions, store); result.test_eq("user 1 issuer not found", result_no_issuer.result_string(), Botan::Path_Validation_Result::status_string(Botan::Certificate_Status_Code::CERT_ISSUER_NOT_FOUND)); store.add_crl(crl1); std::vector revoked; revoked.push_back(Botan::CRL_Entry(user1_cert, Botan::CESSATION_OF_OPERATION)); revoked.push_back(user2_cert); Botan::X509_CRL crl2 = ca.update_crl(crl1, revoked, Test::rng()); store.add_crl(crl2); const std::string revoked_str = Botan::Path_Validation_Result::status_string(Botan::Certificate_Status_Code::CERT_IS_REVOKED); result_u1 = Botan::x509_path_validate(user1_cert, restrictions, store); result.test_eq("user 1 revoked", result_u1.result_string(), revoked_str); result_u2 = Botan::x509_path_validate(user2_cert, restrictions, store); result.test_eq("user 1 revoked", result_u2.result_string(), revoked_str); revoked.clear(); revoked.push_back(Botan::CRL_Entry(user1_cert, Botan::REMOVE_FROM_CRL)); Botan::X509_CRL crl3 = ca.update_crl(crl2, revoked, Test::rng()); store.add_crl(crl3); result_u1 = Botan::x509_path_validate(user1_cert, restrictions, store); if(!result.confirm("user 1 validates", result_u1.successful_validation())) { result.test_note("user 1 validation result was " + result_u1.result_string()); } result_u2 = Botan::x509_path_validate(user2_cert, restrictions, store); result.test_eq("user 2 still revoked", result_u2.result_string(), revoked_str); return result; } Test::Result test_usage(const std::string& sig_algo, const std::string& hash_fn = "SHA-256") { using Botan::Key_Constraints; Test::Result result("X509 Usage"); /* Create the CA's key and self-signed cert */ std::unique_ptr ca_key(make_a_private_key(sig_algo)); if(!ca_key) { // Failure because X.509 enabled but requested signature algorithm is not present result.test_note("Skipping due to missing signature algorithm: " + sig_algo); return result; } /* Create the self-signed cert */ Botan::X509_Certificate ca_cert = Botan::X509::create_self_signed_cert(ca_opts(), *ca_key, hash_fn, Test::rng()); /* Create the CA object */ Botan::X509_CA ca(ca_cert, *ca_key, hash_fn, Test::rng()); std::unique_ptr user1_key(make_a_private_key(sig_algo)); Botan::X509_Cert_Options opts("Test User 1/US/Botan Project/Testing"); opts.constraints = Key_Constraints::DIGITAL_SIGNATURE; Botan::PKCS10_Request user1_req = Botan::X509::create_cert_req(opts, *user1_key, hash_fn, Test::rng()); Botan::X509_Certificate user1_cert = ca.sign_request(user1_req, Test::rng(), from_date(2008, 01, 01), from_date(2033, 01, 01)); // cert only allows digitalSignature, but we check for both digitalSignature and cRLSign result.test_eq("key usage cRLSign not allowed", user1_cert.allowed_usage(Key_Constraints(Key_Constraints::DIGITAL_SIGNATURE | Key_Constraints::CRL_SIGN)), false); // cert only allows digitalSignature, so checking for only that should be ok result.confirm("key usage digitalSignature allowed", user1_cert.allowed_usage(Key_Constraints::DIGITAL_SIGNATURE)); opts.constraints = Key_Constraints(Key_Constraints::DIGITAL_SIGNATURE | Key_Constraints::CRL_SIGN); Botan::PKCS10_Request mult_usage_req = Botan::X509::create_cert_req(opts, *user1_key, hash_fn, Test::rng()); Botan::X509_Certificate mult_usage_cert = ca.sign_request(mult_usage_req, Test::rng(), from_date(2008, 01, 01), from_date(2033, 01, 01)); // cert allows multiple usages, so each one of them as well as both together should be allowed result.confirm("key usage multiple digitalSignature allowed", mult_usage_cert.allowed_usage(Key_Constraints::DIGITAL_SIGNATURE)); result.confirm("key usage multiple cRLSign allowed", mult_usage_cert.allowed_usage(Key_Constraints::CRL_SIGN)); result.confirm("key usage multiple digitalSignature and cRLSign allowed", mult_usage_cert.allowed_usage( Key_Constraints(Key_Constraints::DIGITAL_SIGNATURE | Key_Constraints::CRL_SIGN))); opts.constraints = Key_Constraints::NO_CONSTRAINTS; Botan::PKCS10_Request no_usage_req = Botan::X509::create_cert_req(opts, *user1_key, hash_fn, Test::rng()); Botan::X509_Certificate no_usage_cert = ca.sign_request(no_usage_req, Test::rng(), from_date(2008, 01, 01), from_date(2033, 01, 01)); // cert allows every usage result.confirm("key usage digitalSignature allowed", no_usage_cert.allowed_usage(Key_Constraints::DIGITAL_SIGNATURE)); result.confirm("key usage cRLSign allowed", no_usage_cert.allowed_usage(Key_Constraints::CRL_SIGN)); return result; } Test::Result test_self_issued(const std::string& sig_algo, const std::string& hash_fn = "SHA-256") { using Botan::Key_Constraints; Test::Result result("X509 Self Issued"); // create the CA's key and self-signed cert std::unique_ptr ca_key(make_a_private_key(sig_algo)); if(!ca_key) { // Failure because X.509 enabled but requested signature algorithm is not present result.test_note("Skipping due to missing signature algorithm: " + sig_algo); return result; } // create the self-signed cert Botan::X509_Certificate ca_cert = Botan::X509::create_self_signed_cert(ca_opts(), *ca_key, hash_fn, Test::rng()); /* Create the CA object */ Botan::X509_CA ca(ca_cert, *ca_key, hash_fn, Test::rng()); std::unique_ptr user_key(make_a_private_key(sig_algo)); // create a self-issued certificate, that is, a certificate with subject dn == issuer dn, // but signed by a CA, not signed by it's own private key Botan::X509_Cert_Options opts = ca_opts(); opts.constraints = Key_Constraints::DIGITAL_SIGNATURE; Botan::PKCS10_Request self_issued_req = Botan::X509::create_cert_req(opts, *user_key, hash_fn, Test::rng()); Botan::X509_Certificate self_issued_cert = ca.sign_request(self_issued_req, Test::rng(), from_date(2008, 01, 01), from_date(2033, 01, 01)); // check that this chain can can be verified successfully Botan::Certificate_Store_In_Memory trusted(ca.ca_certificate()); Botan::Path_Validation_Restrictions restrictions(false, 80); Botan::Path_Validation_Result validation_result = Botan::x509_path_validate(self_issued_cert, restrictions, trusted); result.confirm("chain with self-issued cert validates", validation_result.successful_validation()); return result; } using Botan::Key_Constraints; /** * @brief Some typical key usage scenarios (taken from RFC 5280, sec. 4.2.1.3) */ struct typical_usage_constraints { // ALL constraints are not typical at all, but we use them for a negative test Key_Constraints all = Key_Constraints( Key_Constraints::DIGITAL_SIGNATURE | Key_Constraints::NON_REPUDIATION | Key_Constraints::KEY_ENCIPHERMENT | Key_Constraints::DATA_ENCIPHERMENT | Key_Constraints::KEY_AGREEMENT | Key_Constraints::KEY_CERT_SIGN | Key_Constraints::CRL_SIGN | Key_Constraints::ENCIPHER_ONLY | Key_Constraints::DECIPHER_ONLY); Key_Constraints ca = Key_Constraints(Key_Constraints::KEY_CERT_SIGN); Key_Constraints sign_data = Key_Constraints(Key_Constraints::DIGITAL_SIGNATURE); Key_Constraints non_repudiation = Key_Constraints(Key_Constraints::NON_REPUDIATION | Key_Constraints::DIGITAL_SIGNATURE); Key_Constraints key_encipherment = Key_Constraints(Key_Constraints::KEY_ENCIPHERMENT); Key_Constraints data_encipherment = Key_Constraints(Key_Constraints::DATA_ENCIPHERMENT); Key_Constraints key_agreement = Key_Constraints(Key_Constraints::KEY_AGREEMENT); Key_Constraints key_agreement_encipher_only = Key_Constraints(Key_Constraints::KEY_AGREEMENT | Key_Constraints::ENCIPHER_ONLY); Key_Constraints key_agreement_decipher_only = Key_Constraints(Key_Constraints::KEY_AGREEMENT | Key_Constraints::DECIPHER_ONLY); Key_Constraints crl_sign = Key_Constraints(Key_Constraints::CRL_SIGN); Key_Constraints sign_everything = Key_Constraints(Key_Constraints::DIGITAL_SIGNATURE | Key_Constraints::KEY_CERT_SIGN | Key_Constraints::CRL_SIGN); }; Test::Result test_valid_constraints(const std::string& pk_algo) { Test::Result result("X509 Valid Constraints"); std::unique_ptr key(make_a_private_key(pk_algo)); if(!key) { // Failure because X.509 enabled but requested algorithm is not present result.test_note("Skipping due to missing signature algorithm: " + pk_algo); return result; } // should not throw on empty constraints verify_cert_constraints_valid_for_key_type(*key, Key_Constraints(Key_Constraints::NO_CONSTRAINTS)); // now check some typical usage scenarios for the given key type typical_usage_constraints typical_usage; if(pk_algo == "DH" || pk_algo == "ECDH") { // DH and ECDH only for key agreement result.test_throws("all constraints not permitted", [&key, &typical_usage]() { verify_cert_constraints_valid_for_key_type(*key, typical_usage.all); }); result.test_throws("cert sign not permitted", [&key, &typical_usage]() { verify_cert_constraints_valid_for_key_type(*key, typical_usage.ca); }); result.test_throws("signature not permitted", [&key, &typical_usage]() { verify_cert_constraints_valid_for_key_type(*key, typical_usage.sign_data); }); result.test_throws("non repudiation not permitted", [&key, &typical_usage]() { verify_cert_constraints_valid_for_key_type(*key, typical_usage.non_repudiation); }); result.test_throws("key encipherment not permitted", [&key, &typical_usage]() { verify_cert_constraints_valid_for_key_type(*key, typical_usage.key_encipherment); }); result.test_throws("data encipherment not permitted", [&key, &typical_usage]() { verify_cert_constraints_valid_for_key_type(*key, typical_usage.data_encipherment); }); verify_cert_constraints_valid_for_key_type(*key, typical_usage.key_agreement); verify_cert_constraints_valid_for_key_type(*key, typical_usage.key_agreement_encipher_only); verify_cert_constraints_valid_for_key_type(*key, typical_usage.key_agreement_decipher_only); result.test_throws("crl sign not permitted", [&key, &typical_usage]() { verify_cert_constraints_valid_for_key_type(*key, typical_usage.crl_sign); }); result.test_throws("sign, cert sign, crl sign not permitted", [&key, &typical_usage]() { verify_cert_constraints_valid_for_key_type(*key, typical_usage.sign_everything); }); } else if(pk_algo == "RSA") { // RSA can do everything except key agreement result.test_throws("all constraints not permitted", [&key, &typical_usage]() { verify_cert_constraints_valid_for_key_type(*key, typical_usage.all); }); verify_cert_constraints_valid_for_key_type(*key, typical_usage.ca); verify_cert_constraints_valid_for_key_type(*key, typical_usage.sign_data); verify_cert_constraints_valid_for_key_type(*key, typical_usage.non_repudiation); verify_cert_constraints_valid_for_key_type(*key, typical_usage.key_encipherment); verify_cert_constraints_valid_for_key_type(*key, typical_usage.data_encipherment); result.test_throws("key agreement not permitted", [&key, &typical_usage]() { verify_cert_constraints_valid_for_key_type(*key, typical_usage.key_agreement); }); result.test_throws("key agreement, encipher only not permitted", [&key, &typical_usage]() { verify_cert_constraints_valid_for_key_type(*key, typical_usage.key_agreement_encipher_only); }); result.test_throws("key agreement, decipher only not permitted", [&key, &typical_usage]() { verify_cert_constraints_valid_for_key_type(*key, typical_usage.key_agreement_decipher_only); }); verify_cert_constraints_valid_for_key_type(*key, typical_usage.crl_sign); verify_cert_constraints_valid_for_key_type(*key, typical_usage.sign_everything); } else if(pk_algo == "ElGamal") { // only ElGamal encryption is currently implemented result.test_throws("all constraints not permitted", [&key, &typical_usage]() { verify_cert_constraints_valid_for_key_type(*key, typical_usage.all); }); result.test_throws("cert sign not permitted", [&key, &typical_usage]() { verify_cert_constraints_valid_for_key_type(*key, typical_usage.ca); }); verify_cert_constraints_valid_for_key_type(*key, typical_usage.data_encipherment); verify_cert_constraints_valid_for_key_type(*key, typical_usage.key_encipherment); result.test_throws("key agreement not permitted", [&key, &typical_usage]() { verify_cert_constraints_valid_for_key_type(*key, typical_usage.key_agreement); }); result.test_throws("key agreement, encipher only not permitted", [&key, &typical_usage]() { verify_cert_constraints_valid_for_key_type(*key, typical_usage.key_agreement_encipher_only); }); result.test_throws("key agreement, decipher only not permitted", [&key, &typical_usage]() { verify_cert_constraints_valid_for_key_type(*key, typical_usage.key_agreement_decipher_only); }); result.test_throws("crl sign not permitted", [&key, &typical_usage]() { verify_cert_constraints_valid_for_key_type(*key, typical_usage.crl_sign); }); result.test_throws("sign, cert sign, crl sign not permitted not permitted", [&key, &typical_usage]() { verify_cert_constraints_valid_for_key_type(*key, typical_usage.sign_everything); }); } else if(pk_algo == "DSA" || pk_algo == "ECDSA" || pk_algo == "ECGDSA" || pk_algo == "ECKCDSA" || pk_algo == "GOST-34.10") { // these are signature algorithms only result.test_throws("all constraints not permitted", [&key, &typical_usage]() { verify_cert_constraints_valid_for_key_type(*key, typical_usage.all); }); verify_cert_constraints_valid_for_key_type(*key, typical_usage.ca); verify_cert_constraints_valid_for_key_type(*key, typical_usage.sign_data); verify_cert_constraints_valid_for_key_type(*key, typical_usage.non_repudiation); result.test_throws("key encipherment not permitted", [&key, &typical_usage]() { verify_cert_constraints_valid_for_key_type(*key, typical_usage.key_encipherment); }); result.test_throws("data encipherment not permitted", [&key, &typical_usage]() { verify_cert_constraints_valid_for_key_type(*key, typical_usage.data_encipherment); }); result.test_throws("key agreement not permitted", [&key, &typical_usage]() { verify_cert_constraints_valid_for_key_type(*key, typical_usage.key_agreement); }); result.test_throws("key agreement, encipher only not permitted", [&key, &typical_usage]() { verify_cert_constraints_valid_for_key_type(*key, typical_usage.key_agreement_encipher_only); }); result.test_throws("key agreement, decipher only not permitted", [&key, &typical_usage]() { verify_cert_constraints_valid_for_key_type(*key, typical_usage.key_agreement_decipher_only); }); verify_cert_constraints_valid_for_key_type(*key, typical_usage.crl_sign); verify_cert_constraints_valid_for_key_type(*key, typical_usage.sign_everything); } return result; } /** * @brief X.509v3 extension that encodes a given string */ class String_Extension : public Botan::Certificate_Extension { public: String_Extension() = default; String_Extension(const std::string& val) : m_contents(val) {} std::string value() const { return m_contents; } String_Extension* copy() const override { return new String_Extension(m_contents); } Botan::OID oid_of() const override { return m_oid; } std::string oid_name() const override { return "String Extension"; } void contents_to(Botan::Data_Store&, Botan::Data_Store&) const override {} std::vector encode_inner() const override { return Botan::DER_Encoder().encode(Botan::ASN1_String(m_contents, Botan::UTF8_STRING)).get_contents_unlocked(); } void decode_inner(const std::vector& in) override { Botan::ASN1_String str; Botan::BER_Decoder(in).decode(str, Botan::UTF8_STRING).verify_end(); m_contents = str.value(); } private: Botan::OID m_oid {"1.2.3.4.5.6.7.8.9.1"}; std::string m_contents; }; Test::Result test_x509_extensions(const std::string& sig_algo, const std::string& hash_fn = "SHA-256") { using Botan::Key_Constraints; Test::Result result("X509 Extensions"); /* Create the CA's key and self-signed cert */ std::unique_ptr ca_key(make_a_private_key(sig_algo)); if(!ca_key) { // Failure because X.509 enabled but requested signature algorithm is not present result.test_note("Skipping due to missing signature algorithm: " + sig_algo); return result; } /* Create the self-signed cert */ Botan::X509_Certificate ca_cert = Botan::X509::create_self_signed_cert(ca_opts(), *ca_key, hash_fn, Test::rng()); /* Create the CA object */ Botan::X509_CA ca(ca_cert, *ca_key, hash_fn, Test::rng()); std::unique_ptr user_key(make_a_private_key(sig_algo)); Botan::X509_Cert_Options opts("Test User 1/US/Botan Project/Testing"); opts.constraints = Key_Constraints::DIGITAL_SIGNATURE; // include a custom extension in the request Botan::Extensions req_extensions; Botan::OID oid("1.2.3.4.5.6.7.8.9.1"); req_extensions.add(new String_Extension("1Test"), false); opts.extensions = req_extensions; /* Create a self-signed certificate */ Botan::X509_Certificate self_signed_cert = Botan::X509::create_self_signed_cert(opts, *user_key, hash_fn, Test::rng()); // check if known Key_Usage extension is present in self-signed cert auto key_usage_ext = self_signed_cert.v3_extensions().get(Botan::OIDS::lookup("X509v3.KeyUsage")); if(result.confirm("Key_Usage extension present in self-signed certificate", key_usage_ext != nullptr)) { result.confirm("Key_Usage extension value matches in self-signed certificate", dynamic_cast(*key_usage_ext).get_constraints() == opts.constraints); } // check if custom extension is present in self-signed cert auto string_ext = self_signed_cert.v3_extensions().get_raw(oid); if(result.confirm("Custom extension present in self-signed certificate", string_ext != nullptr)) { result.test_eq("Custom extension value matches in self-signed certificate", string_ext->value(), "1Test"); } Botan::PKCS10_Request user_req = Botan::X509::create_cert_req(opts, *user_key, hash_fn, Test::rng()); /* Create a CA-signed certificate */ Botan::X509_Certificate user_cert = ca.sign_request(user_req, Test::rng(), from_date(2008, 01, 01), from_date(2033, 01, 01)); // check if known Key_Usage extension is present in CA-signed cert key_usage_ext = self_signed_cert.v3_extensions().get(Botan::OIDS::lookup("X509v3.KeyUsage")); if(result.confirm("Key_Usage extension present in user certificate", key_usage_ext != nullptr)) { result.confirm("Key_Usage extension value matches in user certificate", dynamic_cast(*key_usage_ext).get_constraints() == Botan::DIGITAL_SIGNATURE); } // check if custom extension is present in CA-signed cert string_ext = user_cert.v3_extensions().get_raw(oid); if(result.confirm("Custom extension present in user certificate", string_ext != nullptr)) { result.test_eq("Custom extension value matches in user certificate", string_ext->value(), "1Test"); } return result; } class X509_Cert_Unit_Tests : public Test { public: std::vector run() override { std::vector results; const std::vector sig_algos { "RSA", "DSA", "ECDSA", "ECGDSA", "ECKCDSA", "GOST-34.10" }; Test::Result cert_result("X509 Unit"); Test::Result usage_result("X509 Usage"); Test::Result self_issued_result("X509 Self Issued"); Test::Result extensions_result("X509 Extensions"); for(const auto& algo : sig_algos) { try { cert_result.merge(test_x509_cert(algo)); } catch(std::exception& e) { cert_result.test_failure("test_x509_cert " + algo, e.what()); } try { usage_result.merge(test_usage(algo)); } catch(std::exception& e) { usage_result.test_failure("test_usage " + algo, e.what()); } try { self_issued_result.merge(test_self_issued(algo)); } catch(std::exception& e) { self_issued_result.test_failure("test_self_issued " + algo, e.what()); } try { extensions_result.merge(test_x509_extensions(algo)); } catch(std::exception& e) { extensions_result.test_failure("test_extensions " + algo, e.what()); } } results.push_back(cert_result); results.push_back(usage_result); results.push_back(self_issued_result); results.push_back(extensions_result); const std::vector pk_algos { "DH", "ECDH", "RSA", "ElGamal", "GOST-34.10", "DSA", "ECDSA", "ECGDSA", "ECKCDSA" }; Test::Result valid_constraints_result("X509 Valid Constraints"); for(const auto& algo : pk_algos) { valid_constraints_result.merge(test_valid_constraints(algo)); } results.push_back(valid_constraints_result); results.push_back(test_x509_dates()); results.push_back(test_cert_status_strings()); return results; } }; BOTAN_REGISTER_TEST("x509_unit", X509_Cert_Unit_Tests); #endif } }