/* * (C) 2016 Jack Lloyd * * Botan is released under the Simplified BSD License (see license.txt) */ #include "tests.h" #if defined(BOTAN_HAS_PK_PADDING) #include #endif #if defined(BOTAN_HAS_EME_PKCS1v15) #include #endif namespace Botan_Tests { #if defined(BOTAN_HAS_EME_PKCS1v15) class EME_PKCS1v15_Decoding_Tests final : public Text_Based_Test { public: EME_PKCS1v15_Decoding_Tests() : Text_Based_Test( "pk_pad_eme/pkcs1.vec", "RawCiphertext", "Plaintext") {} Test::Result run_one_test(const std::string& hdr, const VarMap& vars) override { const bool is_valid = (hdr == "valid"); Test::Result result("PKCSv15 Decoding"); Botan::EME_PKCS1v15 pkcs; const std::vector ciphertext = vars.get_req_bin("RawCiphertext"); const std::vector plaintext = vars.get_opt_bin("Plaintext"); if(is_valid == false) { result.test_eq("Plaintext value should be empty for invalid EME inputs", plaintext.size(), 0); } uint8_t valid_mask = 0; Botan::secure_vector decoded = pkcs.unpad(valid_mask, ciphertext.data(), ciphertext.size()); result.confirm("EME valid_mask has expected value", valid_mask == 0x00 || valid_mask == 0xFF); result.test_eq("EME decoding valid/invalid matches", valid_mask == 0xFF, is_valid); if(valid_mask == 0xFF) { result.test_eq("EME decoded plaintext correct", decoded, plaintext); } else { bool all_zeros = true; for(size_t i = 0; i != decoded.size(); ++i) if(decoded[i] != 0) all_zeros = false; result.confirm("On invalid padding output is all zero", all_zeros); } // TODO: also test that encoding is accepted return result; } }; BOTAN_REGISTER_TEST("eme_pkcs1v15", EME_PKCS1v15_Decoding_Tests); class EMSA_unit_tests final : public Test { public: std::vector run() override { Test::Result name_tests("EMSA_name_tests"); std::vector pads_need_hash = { #if BOTAN_HAS_EMSA1 "EMSA1", #endif #if BOTAN_HAS_EMSA_X931 "EMSA2", #endif #if BOTAN_HAS_EMSA_PKCS1 "EMSA3", #endif #if BOTAN_HAS_EMSA_PSSR "EMSA4", "PSSR_Raw", #endif #if BOTAN_HAS_ISO_9796 "ISO_9796_DS2", "ISO_9796_DS3", #endif }; std::vector pads_no_hash = { #if BOTAN_HAS_EMSA_RAW "Raw", #endif #if BOTAN_HAS_EMSA_PKCS1 "EMSA3(Raw)", "EMSA3(Raw,SHA-512)", #endif }; for(auto pad : pads_need_hash) { try { std::unique_ptr emsa_1( Botan::get_emsa(pad + "(" + Botan::hash_for_emsa(pad) + ")")); std::unique_ptr emsa_2(Botan::get_emsa(emsa_1->name())); name_tests.test_eq("EMSA_name_test for " + pad, emsa_1->name(), emsa_2->name()); } catch(const std::exception& e) { name_tests.test_failure("EMSA_name_test for " + pad + ": " + e.what()); } } for(auto pad : pads_need_hash) { std::string algo_name = pad + "(YYZ)"; try { std::unique_ptr emsa( Botan::get_emsa(algo_name)); name_tests.test_failure("EMSA_name_test for " + pad + ": " + "Could create EMSA with fantasy hash YYZ"); } catch(const std::exception& e) { name_tests.test_eq("EMSA_name_test for " + pad, e.what(), "Could not find any algorithm named \"" + algo_name + "\""); } } for(auto pad : pads_no_hash) { try { std::unique_ptr emsa_1(Botan::get_emsa(pad)); std::unique_ptr emsa_2(Botan::get_emsa(emsa_1->name())); name_tests.test_eq("EMSA_name_test for " + pad, emsa_1->name(), emsa_2->name()); } catch(const std::exception& e) { name_tests.test_failure("EMSA_name_test for " + pad + ": " + e.what()); } } return { name_tests }; } }; BOTAN_REGISTER_TEST("pk_pad_emsa_unit", EMSA_unit_tests); #endif }