/* * (C) 2014,2015 Jack Lloyd * * Botan is released under the Simplified BSD License (see license.txt) */ #include "tests.h" #include #include #include #include #include #include namespace Botan_Tests { Test::Registration::Registration(const std::string& name, Test* test) { if(Test::global_registry().count(name) == 0) { Test::global_registry().insert(std::make_pair(name, std::unique_ptr(test))); } else { throw Test_Error("Duplicate registration of test '" + name + "'"); } } void Test::Result::merge(const Result& other) { if(who() != other.who()) throw Test_Error("Merging tests from different sources"); m_ns_taken += other.m_ns_taken; m_tests_passed += other.m_tests_passed; m_fail_log.insert(m_fail_log.end(), other.m_fail_log.begin(), other.m_fail_log.end()); m_log.insert(m_log.end(), other.m_log.begin(), other.m_log.end()); } void Test::Result::start_timer() { if(m_started == 0) { m_started = Test::timestamp(); } } void Test::Result::end_timer() { if(m_started > 0) { m_ns_taken += Test::timestamp() - m_started; m_started = 0; } } void Test::Result::test_note(const std::string& note, const char* extra) { if(note != "") { std::ostringstream out; out << who() << " " << note; if(extra) out << ": " << extra; m_log.push_back(out.str()); } } void Test::Result::note_missing(const std::string& whatever) { static std::set s_already_seen; if(s_already_seen.count(whatever) == 0) { test_note("Skipping tests due to missing " + whatever); s_already_seen.insert(whatever); } } bool Test::Result::test_throws(const std::string& what, std::function fn) { try { fn(); return test_failure(what + " failed to throw expected exception"); } catch(std::exception& e) { return test_success(what + " threw exception " + e.what()); } catch(...) { return test_success(what + " threw unknown exception"); } } bool Test::Result::test_throws(const std::string& what, const std::string& expected, std::function fn) { try { fn(); return test_failure(what + " failed to throw expected exception"); } catch(std::exception& e) { if(expected == e.what()) { return test_success(what + " threw exception " + e.what()); } else { return test_failure(what + " failed to throw an exception with the expected text:\n Expected: " + expected + "\n Got: " + e.what()); } } catch(...) { return test_failure(what + " failed to throw an exception with the expected text:\n Expected: " + expected); } } bool Test::Result::test_success(const std::string& note) { if(Test::log_success()) { test_note(note); } ++m_tests_passed; return true; } bool Test::Result::test_failure(const std::string& what, const std::string& error) { return test_failure(who() + " " + what + " with error " + error); } void Test::Result::test_failure(const std::string& what, const uint8_t buf[], size_t buf_len) { test_failure(who() + ": " + what + " buf len " + std::to_string(buf_len) + " value " + Botan::hex_encode(buf, buf_len)); } bool Test::Result::test_failure(const std::string& err) { m_fail_log.push_back(err); return false; } bool Test::Result::test_ne(const std::string& what, const uint8_t produced[], size_t produced_len, const uint8_t expected[], size_t expected_len) { if(produced_len == expected_len && Botan::same_mem(produced, expected, expected_len)) return test_failure(who() + ": " + what + " produced matching"); return test_success(); } bool Test::Result::test_eq(const char* producer, const std::string& what, const uint8_t produced[], size_t produced_size, const uint8_t expected[], size_t expected_size) { if(produced_size == expected_size && Botan::same_mem(produced, expected, expected_size)) return test_success(); std::ostringstream err; err << who(); if(producer) { err << " producer '" << producer << "'"; } err << " unexpected result for " << what; if(produced_size != expected_size) { err << " produced " << produced_size << " bytes expected " << expected_size; } std::vector xor_diff(std::min(produced_size, expected_size)); size_t bits_different = 0; for(size_t i = 0; i != xor_diff.size(); ++i) { xor_diff[i] = produced[i] ^ expected[i]; bits_different += Botan::hamming_weight(xor_diff[i]); } err << "\nProduced: " << Botan::hex_encode(produced, produced_size) << "\nExpected: " << Botan::hex_encode(expected, expected_size); if(bits_different > 0) { err << "\nXOR Diff: " << Botan::hex_encode(xor_diff) << " (" << bits_different << " bits different)"; } return test_failure(err.str()); } bool Test::Result::test_is_nonempty(const std::string& what_is_it, const std::string& to_examine) { if(to_examine.empty()) return test_failure(what_is_it + " was empty"); return test_success(); } bool Test::Result::test_eq(const std::string& what, const std::string& produced, const std::string& expected) { return test_is_eq(what, produced, expected); } bool Test::Result::test_eq(const std::string& what, const char* produced, const char* expected) { return test_is_eq(what, std::string(produced), std::string(expected)); } bool Test::Result::test_eq(const std::string& what, size_t produced, size_t expected) { return test_is_eq(what, produced, expected); } bool Test::Result::test_eq(const std::string& what, OctetString produced, OctetString expected) { std::ostringstream out; out << m_who << " " << what; if(produced == expected) { out << " produced expected result " << produced.as_string(); return test_success(out.str()); } else { out << " produced unexpected result '" << produced.as_string() << "' expected '" << expected.as_string() << "'"; return test_failure(out.str()); } } bool Test::Result::test_lt(const std::string& what, size_t produced, size_t expected) { if(produced >= expected) { std::ostringstream err; err << m_who << " " << what; err << " unexpected result " << produced << " >= " << expected; return test_failure(err.str()); } return test_success(); } bool Test::Result::test_lte(const std::string& what, size_t produced, size_t expected) { if(produced > expected) { std::ostringstream err; err << m_who << " " << what << " unexpected result " << produced << " > " << expected; return test_failure(err.str()); } return test_success(); } bool Test::Result::test_gte(const std::string& what, size_t produced, size_t expected) { if(produced < expected) { std::ostringstream err; err << m_who; err << " " << what; err << " unexpected result " << produced << " < " << expected; return test_failure(err.str()); } return test_success(); } bool Test::Result::test_ne(const std::string& what, const std::string& str1, const std::string& str2) { if(str1 != str2) { return test_success(str1 + " != " + str2); } return test_failure(who() + " " + what + " produced matching strings " + str1); } bool Test::Result::test_ne(const std::string& what, size_t produced, size_t expected) { if(produced != expected) { return test_success(); } std::ostringstream err; err << who() << " " << what << " produced " << produced << " unexpected value"; return test_failure(err.str()); } #if defined(BOTAN_HAS_BIGINT) bool Test::Result::test_eq(const std::string& what, const BigInt& produced, const BigInt& expected) { return test_is_eq(what, produced, expected); } bool Test::Result::test_ne(const std::string& what, const BigInt& produced, const BigInt& expected) { if(produced != expected) return test_success(); std::ostringstream err; err << who() << " " << what << " produced " << produced << " prohibited value"; return test_failure(err.str()); } #endif #if defined(BOTAN_HAS_EC_CURVE_GFP) bool Test::Result::test_eq(const std::string& what, const Botan::PointGFp& a, const Botan::PointGFp& b) { //return test_is_eq(what, a, b); if(a == b) return test_success(); std::ostringstream err; err << who() << " " << what << " a=(" << a.get_affine_x() << "," << a.get_affine_y() << ")" << " b=(" << b.get_affine_x() << "," << b.get_affine_y(); return test_failure(err.str()); } #endif bool Test::Result::test_eq(const std::string& what, bool produced, bool expected) { return test_is_eq(what, produced, expected); } bool Test::Result::test_rc(const std::string& func, int expected, int rc) { if(expected != rc) { std::ostringstream err; err << m_who; err << " call to " << func << " unexpectedly returned " << rc; err << " but expecting " << expected; return test_failure(err.str()); } return test_success(); } //static std::string Test::format_time(uint64_t ns) { std::ostringstream o; if(ns > 1000000000) { o << std::setprecision(2) << std::fixed << ns/1000000000.0 << " sec"; } else { o << std::setprecision(2) << std::fixed << ns/1000000.0 << " msec"; } return o.str(); } std::string Test::Result::result_string(bool verbose) const { if(tests_run() == 0 && !verbose) return ""; std::ostringstream report; report << who() << " ran "; if(tests_run() == 0) { report << "ZERO"; } else { report << tests_run(); } report << " tests"; if(m_ns_taken > 0) { report << " in " << format_time(m_ns_taken); } if(tests_failed()) { report << " " << tests_failed() << " FAILED"; } else { report << " all ok"; } report << "\n"; for(size_t i = 0; i != m_fail_log.size(); ++i) { report << "Failure " << (i+1) << ": " << m_fail_log[i] << "\n"; } if(m_fail_log.size() > 0 || tests_run() == 0) { for(size_t i = 0; i != m_log.size(); ++i) { report << "Note " << (i+1) << ": " << m_log[i] << "\n"; } } return report.str(); } // static Test:: functions //static std::map>& Test::global_registry() { static std::map> g_test_registry; return g_test_registry; } //static uint64_t Test::timestamp() { auto now = std::chrono::high_resolution_clock::now().time_since_epoch(); return std::chrono::duration_cast(now).count(); } //static std::set Test::registered_tests() { return Botan::map_keys_as_set(Test::global_registry()); } //static Test* Test::get_test(const std::string& test_name) { auto i = Test::global_registry().find(test_name); if(i != Test::global_registry().end()) return i->second.get(); return nullptr; } //static std::vector Test::run_test(const std::string& test_name, bool fail_if_missing) { std::vector results; try { if(Test* test = get_test(test_name)) { std::vector test_results = test->run(); results.insert(results.end(), test_results.begin(), test_results.end()); } else { Test::Result result(test_name); if(fail_if_missing) result.test_failure("Test missing or unavailable"); else result.test_note("Test missing or unavailable"); results.push_back(result); } } catch(std::exception& e) { results.push_back(Test::Result::Failure(test_name, e.what())); } catch(...) { results.push_back(Test::Result::Failure(test_name, "unknown exception")); } return results; } // static member variables of Test Botan::RandomNumberGenerator* Test::m_test_rng = nullptr; std::string Test::m_data_dir; bool Test::m_log_success = false; bool Test::m_run_online_tests = false; bool Test::m_run_long_tests = false; std::string Test::m_pkcs11_lib; //static void Test::setup_tests(bool log_success, bool run_online, bool run_long, const std::string& data_dir, const std::string& pkcs11_lib, Botan::RandomNumberGenerator* rng) { m_data_dir = data_dir; m_log_success = log_success; m_run_online_tests = run_online; m_run_long_tests = run_long; m_test_rng = rng; m_pkcs11_lib = pkcs11_lib; } //static std::string Test::data_file(const std::string& what) { return Test::data_dir() + "/" + what; } //static const std::string& Test::data_dir() { return m_data_dir; } //static bool Test::log_success() { return m_log_success; } //static bool Test::run_online_tests() { return m_run_online_tests; } //static bool Test::run_long_tests() { return m_run_long_tests; } //static std::string Test::pkcs11_lib() { return m_pkcs11_lib; } //static Botan::RandomNumberGenerator& Test::rng() { if(!m_test_rng) throw Test_Error("Test RNG not initialized"); return *m_test_rng; } std::string Test::random_password() { const size_t len = 1 + Test::rng().next_byte() % 32; return Botan::hex_encode(Test::rng().random_vec(len)); } Text_Based_Test::Text_Based_Test(const std::string& data_src, const std::string& required_keys_str, const std::string& optional_keys_str) : m_data_src(data_src) { if(required_keys_str.empty()) throw Test_Error("Invalid test spec"); std::vector required_keys = Botan::split_on(required_keys_str, ','); std::vector optional_keys = Botan::split_on(optional_keys_str, ','); m_required_keys.insert(required_keys.begin(), required_keys.end()); m_optional_keys.insert(optional_keys.begin(), optional_keys.end()); m_output_key = required_keys.at(required_keys.size() - 1); } std::vector Text_Based_Test::get_req_bin(const VarMap& vars, const std::string& key) const { auto i = vars.find(key); if(i == vars.end()) throw Test_Error("Test missing variable " + key); try { return Botan::hex_decode(i->second); } catch(std::exception&) { throw Test_Error("Test invalid hex input '" + i->second + "'" + + " for key " + key); } } std::string Text_Based_Test::get_opt_str(const VarMap& vars, const std::string& key, const std::string& def_value) const { auto i = vars.find(key); if(i == vars.end()) return def_value; return i->second; } bool Text_Based_Test::get_req_bool(const VarMap& vars, const std::string& key) const { auto i = vars.find(key); if(i == vars.end()) throw Test_Error("Test missing variable " + key); if(i->second == "true") return true; else if(i->second == "false") return false; else throw Test_Error("Invalid boolean for key '" + key + "' value '" + i->second + "'"); } size_t Text_Based_Test::get_req_sz(const VarMap& vars, const std::string& key) const { auto i = vars.find(key); if(i == vars.end()) throw Test_Error("Test missing variable " + key); return Botan::to_u32bit(i->second); } size_t Text_Based_Test::get_opt_sz(const VarMap& vars, const std::string& key, const size_t def_value) const { auto i = vars.find(key); if(i == vars.end()) return def_value; return Botan::to_u32bit(i->second); } std::vector Text_Based_Test::get_opt_bin(const VarMap& vars, const std::string& key) const { auto i = vars.find(key); if(i == vars.end()) return std::vector(); try { return Botan::hex_decode(i->second); } catch(std::exception&) { throw Test_Error("Test invalid hex input '" + i->second + "'" + + " for key " + key); } } std::string Text_Based_Test::get_req_str(const VarMap& vars, const std::string& key) const { auto i = vars.find(key); if(i == vars.end()) throw Test_Error("Test missing variable " + key); return i->second; } #if defined(BOTAN_HAS_BIGINT) Botan::BigInt Text_Based_Test::get_req_bn(const VarMap& vars, const std::string& key) const { auto i = vars.find(key); if(i == vars.end()) throw Test_Error("Test missing variable " + key); try { return Botan::BigInt(i->second); } catch(std::exception&) { throw Test_Error("Test invalid bigint input '" + i->second + "' for key " + key); } } Botan::BigInt Text_Based_Test::get_opt_bn(const VarMap& vars, const std::string& key, const Botan::BigInt& def_value) const { auto i = vars.find(key); if(i == vars.end()) { return def_value; } try { return Botan::BigInt(i->second); } catch(std::exception&) { throw Test_Error("Test invalid bigint input '" + i->second + "' for key " + key); } } #endif std::string Text_Based_Test::get_next_line() { while(true) { if(m_cur == nullptr || m_cur->good() == false) { if(m_srcs.empty()) { if(m_first) { const std::string full_path = Test::data_dir() + "/" + m_data_src; if(full_path.find(".vec") != std::string::npos) { m_srcs.push_back(full_path); } else { const auto fs = Botan::get_files_recursive(full_path); m_srcs.assign(fs.begin(), fs.end()); if(m_srcs.empty()) throw Test_Error("Error reading test data dir " + full_path); } m_first = false; } else { return ""; // done } } m_cur.reset(new std::ifstream(m_srcs[0])); m_cur_src_name = m_srcs[0]; // Reinit cpuid on new file if needed if(m_cpu_flags.empty() == false) { m_cpu_flags.clear(); Botan::CPUID::initialize(); } if(!m_cur->good()) throw Test_Error("Could not open input file '" + m_cur_src_name); m_srcs.pop_front(); } while(m_cur->good()) { std::string line; std::getline(*m_cur, line); if(line.empty()) continue; if(line[0] == '#') { if(line.compare(0, 6, "#test ") == 0) return line; else continue; } return line; } } } namespace { // strips leading and trailing but not internal whitespace std::string strip_ws(const std::string& in) { const char* whitespace = " "; const auto first_c = in.find_first_not_of(whitespace); if(first_c == std::string::npos) return ""; const auto last_c = in.find_last_not_of(whitespace); return in.substr(first_c, last_c - first_c + 1); } std::vector map_cpuid_string(const std::string& tok) { #if defined(BOTAN_TARGET_CPU_IS_X86_FAMILY) if(tok == "sse2" || tok == "simd") return {Botan::CPUID::CPUID_SSE2_BIT}; if(tok == "ssse3") return {Botan::CPUID::CPUID_SSSE3_BIT}; if(tok == "aesni") return {Botan::CPUID::CPUID_AESNI_BIT}; if(tok == "clmul") return {Botan::CPUID::CPUID_CLMUL_BIT}; if(tok == "avx2") return {Botan::CPUID::CPUID_AVX2_BIT}; #endif #if defined(BOTAN_TARGET_CPU_IS_PPC_FAMILY) if(tok == "altivec" || tok == "simd") return {Botan::CPUID::CPUID_ALTIVEC_BIT}; #endif return {}; } std::vector parse_cpuid_bits(const std::vector& tok) { std::vector bits; for(size_t i = 1; i < tok.size(); ++i) { const std::vector more = map_cpuid_string(tok[i]); bits.insert(bits.end(), more.begin(), more.end()); } return bits; } } bool Text_Based_Test::skip_this_test(const std::string& /*header*/, const VarMap& /*vars*/) { return false; } std::vector Text_Based_Test::run() { std::vector results; std::string header, header_or_name = m_data_src; VarMap vars; size_t test_cnt = 0; while(true) { const std::string line = get_next_line(); if(line.empty()) // EOF break; if(line.compare(0, 6, "#test ") == 0) { std::vector pragma_tokens = Botan::split_on(line.substr(6), ' '); if(pragma_tokens.empty()) throw Test_Error("Empty pragma found in " + m_cur_src_name); if(pragma_tokens[0] != "cpuid") throw Test_Error("Unknown test pragma '" + line + "' in " + m_cur_src_name); m_cpu_flags = parse_cpuid_bits(pragma_tokens); continue; } else if(line[0] == '#') { throw Test_Error("Unknown test pragma '" + line + "' in " + m_cur_src_name); } if(line[0] == '[' && line[line.size()-1] == ']') { header = line.substr(1, line.size() - 2); header_or_name = header; test_cnt = 0; continue; } const std::string test_id = "test " + std::to_string(test_cnt); auto equal_i = line.find_first_of('='); if(equal_i == std::string::npos) { results.push_back(Test::Result::Failure(header_or_name, "invalid input '" + line + "'")); continue; } std::string key = strip_ws(std::string(line.begin(), line.begin() + equal_i - 1)); std::string val = strip_ws(std::string(line.begin() + equal_i + 1, line.end())); if(m_required_keys.count(key) == 0 && m_optional_keys.count(key) == 0) results.push_back(Test::Result::Failure(header_or_name, test_id + " failed unknown key " + key)); vars[key] = val; if(key == m_output_key) { try { if(skip_this_test(header, vars)) { continue; } ++test_cnt; uint64_t start = Test::timestamp(); Test::Result result = run_one_test(header, vars); if(m_cpu_flags.size() > 0) { for(auto&& cpuid_bit : m_cpu_flags) { if(Botan::CPUID::has_cpuid_bit(cpuid_bit)) { Botan::CPUID::clear_cpuid_bit(cpuid_bit); // now re-run the test result.merge(run_one_test(header, vars)); } } Botan::CPUID::initialize(); } result.set_ns_consumed(Test::timestamp() - start); if(result.tests_failed()) result.test_note("Test #" + std::to_string(test_cnt) + " failed"); results.push_back(result); } catch(std::exception& e) { results.push_back(Test::Result::Failure(header_or_name, "test " + std::to_string(test_cnt) + " failed with exception '" + e.what() + "'")); } if(clear_between_callbacks()) { vars.clear(); } } } try { std::vector final_tests = run_final_tests(); results.insert(results.end(), final_tests.begin(), final_tests.end()); } catch(std::exception& e) { results.push_back(Test::Result::Failure(header_or_name, "run_final_tests exception " + std::string(e.what()))); } return results; } }