Mercurial > hg > orthanc-object-storage
view UnitTestsSources/EncryptionTests.cpp @ 202:bb19f1ed9cd9 2.4.0
2.4.0
author | Sebastien Jodogne <s.jodogne@gmail.com> |
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date | Wed, 26 Jun 2024 13:10:38 +0200 |
parents | 6dd8bb916573 |
children |
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/** * Cloud storage plugins for Orthanc * Copyright (C) 2020-2023 Osimis S.A., Belgium * Copyright (C) 2024-2024 Orthanc Team SRL, Belgium * Copyright (C) 2021-2024 Sebastien Jodogne, ICTEAM UCLouvain, Belgium * * This program is free software: you can redistribute it and/or * modify it under the terms of the GNU Affero General Public License * as published by the Free Software Foundation, either version 3 of * the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Affero General Public License for more details. * * You should have received a copy of the GNU Affero General Public License * along with this program. If not, see <http://www.gnu.org/licenses/>. **/ #include "gtest/gtest.h" #include "../Common/EncryptionHelpers.h" #include <boost/chrono/chrono.hpp> #include <boost/date_time.hpp> TEST(EncryptionHelpers, GenerateKey) { CryptoPP::SecByteBlock key1, key2; EncryptionHelpers::GenerateKey(key1); EncryptionHelpers::GenerateKey(key2); // std::cout << EncryptionHelpers::ToHexString(key1) << std::endl; // std::cout << EncryptionHelpers::ToHexString(key2) << std::endl; ASSERT_NE(key1, key2); ASSERT_EQ(32u, key1.size()); // right now, we work with 256bits key ASSERT_EQ(32u * 2u, EncryptionHelpers::ToHexString(key1).size()); } TEST(EncryptionHelpers, EncryptDecryptSimpleText) { CryptoPP::SecByteBlock masterKey; EncryptionHelpers::GenerateKey(masterKey); EncryptionHelpers crypto; crypto.SetCurrentMasterKey(1, masterKey); std::string plainTextMessage = "Plain text message"; std::string encryptedMessage; crypto.Encrypt(encryptedMessage, plainTextMessage); std::string decryptedMessage; crypto.Decrypt(decryptedMessage, encryptedMessage); ASSERT_EQ(plainTextMessage, decryptedMessage); } TEST(EncryptionHelpers, EncryptDecrypt1byteText) { CryptoPP::SecByteBlock masterKey; EncryptionHelpers::GenerateKey(masterKey); EncryptionHelpers crypto; crypto.SetCurrentMasterKey(1, masterKey); std::string plainTextMessage = "P"; std::string encryptedMessage; crypto.Encrypt(encryptedMessage, plainTextMessage); std::string decryptedMessage; crypto.Decrypt(decryptedMessage, encryptedMessage); ASSERT_EQ(plainTextMessage, decryptedMessage); } TEST(EncryptionHelpers, EncryptDecrypt0byteText) { CryptoPP::SecByteBlock masterKey; EncryptionHelpers::GenerateKey(masterKey); EncryptionHelpers crypto; crypto.SetCurrentMasterKey(1, masterKey); std::string plainTextMessage = ""; std::string encryptedMessage; crypto.Encrypt(encryptedMessage, plainTextMessage); std::string decryptedMessage; crypto.Decrypt(decryptedMessage, encryptedMessage); ASSERT_EQ(plainTextMessage, decryptedMessage); } TEST(EncryptionHelpers, EncryptDecryptTampering) { CryptoPP::SecByteBlock masterKey; EncryptionHelpers::GenerateKey(masterKey); EncryptionHelpers crypto; crypto.SetCurrentMasterKey(1, masterKey); std::string plainTextMessage = "Plain text message"; std::string encryptedMessage; std::string decryptedMessage; crypto.Encrypt(encryptedMessage, plainTextMessage); { std::string tamperedEncryptedMessage = encryptedMessage; // change the header tamperedEncryptedMessage[0] = 'B'; ASSERT_THROW(crypto.Decrypt(decryptedMessage, tamperedEncryptedMessage), EncryptionException); } { std::string tamperedEncryptedMessage = encryptedMessage; // tamper the masterKeyId: tamperedEncryptedMessage[EncryptionHelpers::HEADER_VERSION_SIZE + 2] = 0xAF; ASSERT_THROW(crypto.Decrypt(decryptedMessage, tamperedEncryptedMessage), EncryptionException); } { std::string tamperedEncryptedMessage = encryptedMessage; // tamper the iv: tamperedEncryptedMessage[EncryptionHelpers::HEADER_VERSION_SIZE + EncryptionHelpers::MASTER_KEY_ID_SIZE + 2] = 0; ASSERT_THROW(crypto.Decrypt(decryptedMessage, tamperedEncryptedMessage), EncryptionException); } { std::string tamperedEncryptedMessage = encryptedMessage; // tamper the encrypted text: tamperedEncryptedMessage[EncryptionHelpers::HEADER_VERSION_SIZE + EncryptionHelpers::MASTER_KEY_ID_SIZE + EncryptionHelpers::IV_SIZE + 2] = 0; ASSERT_THROW(crypto.Decrypt(decryptedMessage, tamperedEncryptedMessage), EncryptionException); } { std::string tamperedEncryptedMessage = encryptedMessage; // tamper the mac: tamperedEncryptedMessage[tamperedEncryptedMessage.size() - 2] = 0; ASSERT_THROW(crypto.Decrypt(decryptedMessage, tamperedEncryptedMessage), EncryptionException); } { std::string tamperedEncryptedMessage = encryptedMessage; // extend the file content tamperedEncryptedMessage = tamperedEncryptedMessage + "TAMPER"; ASSERT_THROW(crypto.Decrypt(decryptedMessage, tamperedEncryptedMessage), EncryptionException); } { std::string tamperedEncryptedMessage = encryptedMessage; // reduce the file content tamperedEncryptedMessage = tamperedEncryptedMessage.substr(0, tamperedEncryptedMessage.size() - 5); ASSERT_THROW(crypto.Decrypt(decryptedMessage, tamperedEncryptedMessage), EncryptionException); } } TEST(EncryptionHelpers, EncryptDecrypt2TimesSameText) { CryptoPP::SecByteBlock masterKey; EncryptionHelpers::GenerateKey(masterKey); EncryptionHelpers crypto; crypto.SetCurrentMasterKey(1, masterKey); std::string plainTextMessage = "Plain text message"; std::string encryptedMessage1; std::string encryptedMessage2; crypto.Encrypt(encryptedMessage1, plainTextMessage); crypto.Encrypt(encryptedMessage2, plainTextMessage); ASSERT_NE(encryptedMessage1, encryptedMessage2); std::string decryptedMessage1; std::string decryptedMessage2; crypto.Decrypt(decryptedMessage1, encryptedMessage1); crypto.Decrypt(decryptedMessage2, encryptedMessage2); ASSERT_EQ(plainTextMessage, decryptedMessage1); ASSERT_EQ(plainTextMessage, decryptedMessage2); } TEST(EncryptionHelpers, RotateMasterKeys) { std::string plainTextMessage = "Plain text message"; std::string encryptedMessage1; std::string encryptedMessage2; std::string decryptedMessage; CryptoPP::SecByteBlock masterKey1; CryptoPP::SecByteBlock masterKey2; EncryptionHelpers::GenerateKey(masterKey1); EncryptionHelpers::GenerateKey(masterKey2); { EncryptionHelpers crypto; crypto.SetCurrentMasterKey(1, masterKey1); crypto.Encrypt(encryptedMessage1, plainTextMessage); crypto.SetCurrentMasterKey(2, masterKey2); crypto.AddPreviousMasterKey(1, masterKey1); crypto.Encrypt(encryptedMessage2, plainTextMessage); // ensure that we can decrypt messages encrypted with both master keys crypto.Decrypt(decryptedMessage, encryptedMessage1); ASSERT_EQ(plainTextMessage, decryptedMessage); crypto.Decrypt(decryptedMessage, encryptedMessage2); ASSERT_EQ(plainTextMessage, decryptedMessage); } { // if we don't know the old key, check we can not decrypt the old message EncryptionHelpers crypto; crypto.SetCurrentMasterKey(2, masterKey2); ASSERT_THROW(crypto.Decrypt(decryptedMessage, encryptedMessage1), EncryptionException); } } void MeasurePerformance(size_t sizeInMB, EncryptionHelpers& crypto) { std::string encryptedMessage; std::string decryptedMessage; { const std::string largePlainText(sizeInMB * 1024 * 1024, 'A'); auto start = boost::posix_time::microsec_clock::local_time(); crypto.Encrypt(encryptedMessage, largePlainText); auto end = boost::posix_time::microsec_clock::local_time(); boost::posix_time::time_duration diff = end - start; std::cout << "encryption of " << sizeInMB << " MB file took " << diff.total_milliseconds() << " ms" << std::endl; } { auto start = boost::posix_time::microsec_clock::local_time(); crypto.Decrypt(decryptedMessage, encryptedMessage); auto end = boost::posix_time::microsec_clock::local_time(); boost::posix_time::time_duration diff = end - start; std::cout << "decryption of " << sizeInMB << " MB file took " << diff.total_milliseconds() << " ms" << std::endl; } } TEST(EncryptionHelpers, Performance) { CryptoPP::SecByteBlock masterKey; EncryptionHelpers::GenerateKey(masterKey); EncryptionHelpers crypto; crypto.SetCurrentMasterKey(1, masterKey); MeasurePerformance(1, crypto); MeasurePerformance(10, crypto); // MeasurePerformance(100, crypto); // MeasurePerformance(400, crypto); }