/* * Runtime benchmarking * (C) 2008-2009,2013 Jack Lloyd * * Botan is released under the Simplified BSD License (see license.txt) */ #include #include #include #include #include #include #include #include #include #include namespace Botan { namespace { double time_op(std::chrono::nanoseconds runtime, std::function op) { std::chrono::nanoseconds time_used(0); size_t reps = 0; auto start = std::chrono::high_resolution_clock::now(); while(time_used < runtime) { op(); ++reps; time_used = std::chrono::high_resolution_clock::now() - start; } const u64bit nsec_used = std::chrono::duration_cast(time_used).count(); const double seconds_used = static_cast(nsec_used) / 1000000000; return reps / seconds_used; // ie, return ops per second } std::map time_algorithm_ops(const std::string& name, const std::string& provider, RandomNumberGenerator& rng, std::chrono::nanoseconds runtime, size_t buf_size) { const size_t Mebibyte = 1024*1024; secure_vector buffer(buf_size * 1024); rng.randomize(&buffer[0], buffer.size()); const double mb_mult = buffer.size() / static_cast(Mebibyte); if(BlockCipher* p = get_block_cipher(name, provider)) { std::unique_ptr bc(p); const SymmetricKey key(rng, bc->maximum_keylength()); return std::map({ { "key schedule", time_op(runtime / 8, [&]() { bc->set_key(key); }) }, { "encrypt", mb_mult * time_op(runtime / 2, [&]() { bc->encrypt(buffer); }) }, { "decrypt", mb_mult * time_op(runtime / 2, [&]() { bc->decrypt(buffer); }) }, }); } else if(StreamCipher* p = get_stream_cipher(name, provider)) { std::unique_ptr sc(p); const SymmetricKey key(rng, sc->maximum_keylength()); return std::map({ { "key schedule", time_op(runtime / 8, [&]() { sc->set_key(key); }) }, { "", mb_mult * time_op(runtime, [&]() { sc->encipher(buffer); }) }, }); } else if(HashFunction* p = get_hash_function(name, provider)) { std::unique_ptr h(p); return std::map({ { "", mb_mult * time_op(runtime, [&]() { h->update(buffer); }) }, }); } else if(MessageAuthenticationCode* p = get_mac(name, provider)) { std::unique_ptr mac(p); const SymmetricKey key(rng, mac->maximum_keylength()); return std::map({ { "key schedule", time_op(runtime / 8, [&]() { mac->set_key(key); }) }, { "", mb_mult * time_op(runtime, [&]() { mac->update(buffer); }) }, }); } else { std::unique_ptr enc(get_cipher_mode(name, ENCRYPTION)); std::unique_ptr dec(get_cipher_mode(name, DECRYPTION)); if(enc && dec) { const SymmetricKey key(rng, enc->key_spec().maximum_keylength()); return std::map({ { "key schedule", time_op(runtime / 4, [&]() { enc->set_key(key); dec->set_key(key); }) / 2 }, { "encrypt", mb_mult * time_op(runtime / 2, [&]() { enc->update(buffer, 0); buffer.resize(buf_size*1024); }) }, { "decrypt", mb_mult * time_op(runtime / 2, [&]() { dec->update(buffer, 0); buffer.resize(buf_size*1024); }) }, }); } } return std::map(); } double find_first_in(const std::map& m, const std::vector& keys) { for(auto key : keys) { auto i = m.find(key); if(i != m.end()) return i->second; } throw std::runtime_error("In algo benchmark no usable keys found in result"); } std::set get_all_providers_of(const std::string& algo) { std::set provs; auto add_to_set = [&provs](const std::vector& str) { for(auto&& s : str) { provs.insert(s); } }; add_to_set(get_block_cipher_providers(algo)); add_to_set(get_stream_cipher_providers(algo)); add_to_set(get_hash_function_providers(algo)); add_to_set(get_mac_providers(algo)); return provs; } } std::map algorithm_benchmark(const std::string& name, RandomNumberGenerator& rng, std::chrono::milliseconds milliseconds, size_t buf_size) { //Algorithm_Factory& af = global_state().algorithm_factory(); const auto providers = get_all_providers_of(name); std::map all_results; // provider -> ops/sec if(!providers.empty()) { const std::chrono::nanoseconds ns_per_provider = milliseconds / providers.size(); for(auto provider : providers) { auto results = time_algorithm_ops(name, provider, rng, ns_per_provider, buf_size); all_results[provider] = find_first_in(results, { "", "update", "encrypt" }); } } return all_results; } }