#include "STDInclude.hpp" /// http://www.opensource.apple.com/source/CommonCrypto/CommonCrypto-55010/Source/libtomcrypt/doc/libTomCryptDoc.pdf namespace Utils { namespace Cryptography { void Initialize() { DES3::Initialize(); Rand::Initialize(); } #pragma region Rand prng_state Rand::State; uint32_t Rand::GenerateInt() { uint32_t number = 0; fortuna_read(reinterpret_cast(&number), sizeof(number), &Rand::State); return number; } void Rand::Initialize() { ltc_mp = ltm_desc; register_prng(&fortuna_desc); rng_make_prng(128, find_prng("fortuna"), &Rand::State, NULL); } #pragma endregion #pragma region ECC ECC::Key ECC::GenerateKey(int bits) { ECC::Key key; register_prng(&sprng_desc); ltc_mp = ltm_desc; ecc_make_key(NULL, find_prng("sprng"), bits / 8, key.getKeyPtr()); return key; } std::string ECC::SignMessage(Key key, std::string message) { if (!key.isValid()) return ""; uint8_t buffer[512]; DWORD length = sizeof(buffer); register_prng(&sprng_desc); ltc_mp = ltm_desc; ecc_sign_hash(reinterpret_cast(message.data()), message.size(), buffer, &length, NULL, find_prng("sprng"), key.getKeyPtr()); return std::string(reinterpret_cast(buffer), length); } bool ECC::VerifyMessage(Key key, std::string message, std::string signature) { if (!key.isValid()) return false; ltc_mp = ltm_desc; int result = 0; return (ecc_verify_hash(reinterpret_cast(signature.data()), signature.size(), reinterpret_cast(message.data()), message.size(), &result, key.getKeyPtr()) == CRYPT_OK && result != 0); } #pragma endregion #pragma region RSA RSA::Key RSA::GenerateKey(int bits) { RSA::Key key; register_prng(&sprng_desc); register_hash(&sha1_desc); ltc_mp = ltm_desc; rsa_make_key(NULL, find_prng("sprng"), bits / 8, 65537, key.getKeyPtr()); return key; } std::string RSA::SignMessage(RSA::Key key, std::string message) { if (!key.isValid()) return ""; uint8_t buffer[512]; DWORD length = sizeof(buffer); register_prng(&sprng_desc); register_hash(&sha1_desc); ltc_mp = ltm_desc; rsa_sign_hash(reinterpret_cast(message.data()), message.size(), buffer, &length, NULL, find_prng("sprng"), find_hash("sha1"), 0, key.getKeyPtr()); return std::string(reinterpret_cast(buffer), length); } bool RSA::VerifyMessage(Key key, std::string message, std::string signature) { if (!key.isValid()) return false; register_hash(&sha1_desc); ltc_mp = ltm_desc; int result = 0; return (rsa_verify_hash(reinterpret_cast(signature.data()), signature.size(), reinterpret_cast(message.data()), message.size(), find_hash("sha1"), 0, &result, key.getKeyPtr()) == CRYPT_OK && result != 0); } #pragma endregion #pragma region DES3 void DES3::Initialize() { register_cipher(&des3_desc); } std::string DES3::Encrypt(std::string text, std::string iv, std::string key) { std::string encData; encData.resize(text.size()); symmetric_CBC cbc; int des3 = find_cipher("3des"); cbc_start(des3, reinterpret_cast(iv.data()), reinterpret_cast(key.data()), key.size(), 0, &cbc); cbc_encrypt(reinterpret_cast(text.data()), reinterpret_cast(const_cast(encData.data())), text.size(), &cbc); cbc_done(&cbc); return encData; } std::string DES3::Decrpyt(std::string data, std::string iv, std::string key) { std::string decData; decData.resize(data.size()); symmetric_CBC cbc; int des3 = find_cipher("3des"); cbc_start(des3, reinterpret_cast(iv.data()), reinterpret_cast(key.data()), key.size(), 0, &cbc); cbc_decrypt(reinterpret_cast(data.data()), reinterpret_cast(const_cast(decData.data())), data.size(), &cbc); cbc_done(&cbc); return decData; } #pragma endregion #pragma region Tiger std::string Tiger::Compute(std::string data, bool hex) { return Tiger::Compute(reinterpret_cast(data.data()), data.size(), hex); } std::string Tiger::Compute(const uint8_t* data, size_t length, bool hex) { uint8_t buffer[24] = { 0 }; hash_state state; tiger_init(&state); tiger_process(&state, data, length); tiger_done(&state, buffer); std::string hash(reinterpret_cast(buffer), sizeof(buffer)); if (!hex) return hash; return Utils::String::DumpHex(hash, ""); } #pragma endregion #pragma region SHA1 std::string SHA1::Compute(std::string data, bool hex) { return SHA1::Compute(reinterpret_cast(data.data()), data.size(), hex); } std::string SHA1::Compute(const uint8_t* data, size_t length, bool hex) { uint8_t buffer[20] = { 0 }; hash_state state; sha1_init(&state); sha1_process(&state, data, length); sha1_done(&state, buffer); std::string hash(reinterpret_cast(buffer), sizeof(buffer)); if (!hex) return hash; return Utils::String::DumpHex(hash, ""); } #pragma endregion #pragma region SHA256 std::string SHA256::Compute(std::string data, bool hex) { return SHA256::Compute(reinterpret_cast(data.data()), data.size(), hex); } std::string SHA256::Compute(const uint8_t* data, size_t length, bool hex) { uint8_t buffer[32] = { 0 }; hash_state state; sha256_init(&state); sha256_process(&state, data, length); sha256_done(&state, buffer); std::string hash(reinterpret_cast(buffer), sizeof(buffer)); if (!hex) return hash; return Utils::String::DumpHex(hash, ""); } #pragma endregion #pragma region SHA512 std::string SHA512::Compute(std::string data, bool hex) { return SHA512::Compute(reinterpret_cast(data.data()), data.size(), hex); } std::string SHA512::Compute(const uint8_t* data, size_t length, bool hex) { uint8_t buffer[64] = { 0 }; hash_state state; sha512_init(&state); sha512_process(&state, data, length); sha512_done(&state, buffer); std::string hash(reinterpret_cast(buffer), sizeof(buffer)); if (!hex) return hash; return Utils::String::DumpHex(hash, ""); } #pragma endregion #pragma region JenkinsOneAtATime unsigned int JenkinsOneAtATime::Compute(std::string data) { return JenkinsOneAtATime::Compute(data.data(), data.size()); } unsigned int JenkinsOneAtATime::Compute(const char *key, size_t len) { unsigned int hash, i; for (hash = i = 0; i < len; ++i) { hash += key[i]; hash += (hash << 10); hash ^= (hash >> 6); } hash += (hash << 3); hash ^= (hash >> 11); hash += (hash << 15); return hash; } #pragma endregion } }