/* * (C) 2014,2015,2018,2019 Jack Lloyd * * Botan is released under the Simplified BSD License (see license.txt) */ #include "tests.h" #if defined(BOTAN_HAS_HASH) #include #endif namespace Botan_Tests { #if defined(BOTAN_HAS_HASH) namespace { class Invalid_Hash_Name_Tests final : public Test { public: std::vector run() override { Test::Result result("Invalid HashFunction names"); test_invalid_name(result, "NonExistentHash"); test_invalid_name(result, "Blake2b(9)", "Bad output bits size for BLAKE2b"); test_invalid_name(result, "Comb4P(MD5,MD5)", "Comb4P: Must use two distinct hashes"); test_invalid_name(result, "Comb4P(MD5,SHA-256)", "Comb4P: Incompatible hashes MD5 and SHA-256"); test_invalid_name(result, "Keccak-1600(160)", "Keccak_1600: Invalid output length 160"); test_invalid_name(result, "SHA-3(160)", "SHA_3: Invalid output length 160"); return {result}; } private: void test_invalid_name(Result& result, const std::string& name, const std::string& expected_msg = "") const { try { auto hash = Botan::HashFunction::create_or_throw(name); result.test_failure("Was successfully able to create " + name); } catch(Botan::Invalid_Argument& e) { const std::string msg = e.what(); const std::string full_msg = "" + expected_msg; result.test_eq("expected error message", msg, full_msg); } catch(Botan::Lookup_Error& e) { const std::string algo_not_found_msg = "Unavailable Hash " + name; const std::string msg = e.what(); result.test_eq("expected error message", msg, algo_not_found_msg); } catch(std::exception& e) { result.test_failure("some unknown exception", e.what()); } catch(...) { result.test_failure("some unknown exception"); } } }; BOTAN_REGISTER_TEST("hash", "invalid_name_hash", Invalid_Hash_Name_Tests); class Hash_Function_Tests final : public Text_Based_Test { public: Hash_Function_Tests() : Text_Based_Test("hash", "In,Out") {} std::vector possible_providers(const std::string& algo) override { return provider_filter(Botan::HashFunction::providers(algo)); } Test::Result run_one_test(const std::string& algo, const VarMap& vars) override { const std::vector input = vars.get_req_bin("In"); const std::vector expected = vars.get_req_bin("Out"); Test::Result result(algo); const std::vector providers = possible_providers(algo); if(providers.empty()) { result.note_missing("hash " + algo); return result; } for(auto const& provider_ask : providers) { std::unique_ptr hash(Botan::HashFunction::create(algo, provider_ask)); if(!hash) { result.test_failure("Hash " + algo + " supported by " + provider_ask + " but not found"); continue; } std::unique_ptr clone(hash->clone()); const std::string provider(hash->provider()); result.test_is_nonempty("provider", provider); result.test_eq(provider, hash->name(), algo); result.test_eq(provider, hash->name(), clone->name()); hash->update(input); result.test_eq(provider, "hashing", hash->final(), expected); clone->update(input); result.test_eq(provider, "hashing (clone)", clone->final(), expected); // Test to make sure clear() resets what we need it to hash->update("some discarded input"); hash->clear(); hash->update(nullptr, 0); // this should be effectively ignored hash->update(input); result.test_eq(provider, "hashing after clear", hash->final(), expected); // Test that misaligned inputs work if(input.size() > 0) { std::vector misaligned = input; const size_t current_alignment = reinterpret_cast(misaligned.data()) % 16; const size_t bytes_to_misalign = 15 - current_alignment; for(size_t i = 0; i != bytes_to_misalign; ++i) misaligned.insert(misaligned.begin(), 0x23); hash->update(&misaligned[bytes_to_misalign], input.size()); result.test_eq(provider, "hashing misaligned data", hash->final(), expected); } if(input.size() > 5) { hash->update(input[0]); std::unique_ptr fork = hash->copy_state(); // verify fork copy doesn't affect original computation fork->update(&input[1], input.size() - 2); size_t so_far = 1; while(so_far < input.size()) { size_t take = Test::rng().next_byte() % (input.size() - so_far); if(input.size() - so_far == 1) take = 1; hash->update(&input[so_far], take); so_far += take; } result.test_eq(provider, "hashing split", hash->final(), expected); fork->update(&input[input.size() - 1], 1); result.test_eq(provider, "hashing split", fork->final(), expected); } if(hash->hash_block_size() > 0) { // GOST-34.11 uses 32 byte block result.test_gte("If hash_block_size is set, it is large", hash->hash_block_size(), 32); } } return result; } }; BOTAN_REGISTER_TEST("hash", "hash", Hash_Function_Tests); class Hash_NIST_MonteCarlo_Tests final : public Text_Based_Test { public: Hash_NIST_MonteCarlo_Tests() : Text_Based_Test("hash_mc.vec", "Seed,Count,Output") {} std::vector possible_providers(const std::string& algo) override { return provider_filter(Botan::HashFunction::providers(algo)); } Test::Result run_one_test(const std::string& algo, const VarMap& vars) override { const std::vector seed = vars.get_req_bin("Seed"); const size_t count = vars.get_req_sz("Count"); const std::vector expected = vars.get_req_bin("Output"); Test::Result result("NIST Monte Carlo " + algo); const std::vector providers = possible_providers(algo); if(providers.empty()) { result.note_missing("hash " + algo); return result; } for(auto const& provider_ask : providers) { std::unique_ptr hash(Botan::HashFunction::create(algo, provider_ask)); if(!hash) { result.test_failure("Hash " + algo + " supported by " + provider_ask + " but not found"); continue; } std::vector> input; input.push_back(seed); input.push_back(seed); input.push_back(seed); std::vector buf(hash->output_length()); for(size_t j = 0; j <= count; ++j) { for(size_t i = 3; i != 1003; ++i) { hash->update(input[0]); hash->update(input[1]); hash->update(input[2]); hash->final(input[0].data()); input[0].swap(input[1]); input[1].swap(input[2]); } if(j < count) { input[0] = input[2]; input[1] = input[2]; } } result.test_eq("Output is expected", input[2], expected); } return result; } }; BOTAN_REGISTER_TEST("hash", "hash_nist_mc", Hash_NIST_MonteCarlo_Tests); class Hash_LongRepeat_Tests final : public Text_Based_Test { public: Hash_LongRepeat_Tests() : Text_Based_Test("hash_rep.vec", "Input,TotalLength,Digest") {} std::vector possible_providers(const std::string& algo) override { return provider_filter(Botan::HashFunction::providers(algo)); } // repeating the output several times reduces buffering overhead during processing static std::vector expand_input(const std::vector& input, size_t min_len) { std::vector output; output.reserve(min_len); while(output.size() < min_len) output.insert(output.end(), input.begin(), input.end()); return output; } Test::Result run_one_test(const std::string& algo, const VarMap& vars) override { const std::vector input = expand_input(vars.get_req_bin("Input"), 256); const size_t total_len = vars.get_req_sz("TotalLength"); const std::vector expected = vars.get_req_bin("Digest"); Test::Result result("Long input " + algo); const std::vector providers = possible_providers(algo); if(total_len > 1000000 && Test::run_long_tests() == false) { return result; } if(providers.empty()) { result.note_missing("hash " + algo); return result; } for(auto const& provider_ask : providers) { std::unique_ptr hash(Botan::HashFunction::create(algo, provider_ask)); if(!hash) { result.test_failure("Hash " + algo + " supported by " + provider_ask + " but not found"); continue; } const size_t full_inputs = total_len / input.size(); const size_t leftover = total_len % input.size(); for(size_t i = 0; i != full_inputs; ++i) hash->update(input); if(leftover > 0) hash->update(input.data(), leftover); std::vector output(hash->output_length()); hash->final(output.data()); result.test_eq("Output is expected", output, expected); } return result; } }; BOTAN_REGISTER_TEST("hash", "hash_rep", Hash_LongRepeat_Tests); } #endif }