_tmain.cpp

#include <tchar.h>
#include <windows.h>

#ifdef _DEBUG
#include <assert.h>
#endif // _DEBUG

#include "SHA1.hpp"
#include "ecCurveOverGF$2$15$17.hpp"
#include "math_functions/mb_add_x.hpp"
#include "math_functions/mb_sub_x.hpp"
#include "math_functions/mb_mul_x.hpp"
#include "math_functions/mb_div_x.hpp"
#include "math_functions/mb_cmp_x.hpp"

namespace WinRAR {
    struct SignatureData {
        uint64_t r[4];
        uint64_t s[4];
    };

    extern const uint16_t BasePoly = 0x8003;
    extern const GaloisField$2$15<BasePoly> ExtendPoly[18] = { 1, 0, 0, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1 };
    const uint64_t Order[4] = {
        0x5e0d258442bbcd31,
        0x0547840e4bf72d8b,
        0x2314691ced9bbec3,
        0x0001026dd85081b8
    };

    ecCurveOverGF$2$15$17<BasePoly, ExtendPoly> ecCurve(0, 161);
}

template<>
GaloisField$2$15$17<WinRAR::BasePoly, WinRAR::ExtendPoly>&
    GaloisField$2$15$17<WinRAR::BasePoly, WinRAR::ExtendPoly>::operator*=(const GaloisField$2$15$17<WinRAR::BasePoly, WinRAR::ExtendPoly>& other) {

    GaloisField$2$15<WinRAR::BasePoly> temp[33] = { };
    for (int i = 0; i < 17; ++i) {
        for (int j = 0; j < 17; ++j) {
            temp[i + j] += Data[i] * other.Data[j];
        }
    }

    for (int i = 33 - 1; i > 17 - 1; --i) {
        if (temp[i].Value != 0) {
            temp[i - 17] += temp[i];
            temp[i - 17 + 3] += temp[i];
        }
    }

    for (int i = 0; i < 17; ++i)
        Data[i] = temp[i];

    return *this;
}

namespace WinRAR {

    auto G = ecCurve.GetPoint({
        0x38CC, 0x052F, 0x2510, 0x45AA,
        0x1B89, 0x4468, 0x4882, 0x0D67,
        0x4FEB, 0x55CE, 0x0025, 0x4CB7,
        0x0CC2, 0x59DC, 0x289E, 0x65E3,
        0x56FD
    }, {
        0x31A7, 0x65F2, 0x18C4, 0x3412,
        0x7388, 0x54C1, 0x539B, 0x4A02,
        0x4D07, 0x12D6, 0x7911, 0x3B5E,
        0x4F0E, 0x216F, 0x2BF2, 0x1974,
        0x20DA
    });

    uint64_t PrivateKey[4] = {
        0xae9044b7fd61d65e, 0x5fb9f11f467450c1,
        0xbdb95f0105271fa8, 0x59fe6abcca90
    };

    auto Public_ecPoint = ecCurve.GetPoint({
        0x3A1A, 0x1109, 0x268A, 0x12F7,
        0x3734, 0x75F0, 0x576C, 0x2EA4,
        0x4813, 0x3F62, 0x0567, 0x784D,
        0x753D, 0x6D92, 0x366C, 0x1107,
        0x3861
    }, {
        0x6C20, 0x6027, 0x1B22, 0x7A87,
        0x43C4, 0x1908, 0x2449, 0x4675,
        0x7933, 0x2E66, 0x32F5, 0x2A58,
        0x1145, 0x74AC, 0x36D0, 0x2731,
        0x12B6
    });

    uint32_t SBox[8][0x100] = { };

    void InitSBox(uint32_t srcBuffer[8][0x100]) {
        if (srcBuffer[0][1] == 0) {
            for (int i = 0; i < 0x100; ++i) {

                uint32_t result = i;
                for (int j = 0; j < 8; ++j)
                    if (result % 2) {
                        result /= 2;
                        result ^= 0xEDB88320;
                    } else {
                        result /= 2;
                    }

                srcBuffer[0][i] = result;
            }
        }

        // Expanding
        for (int i = 0; i < 256; ++i) {
            uint32_t temp = srcBuffer[0][i];
            for (int j = 1; j < 8; ++j) {
                temp = (temp >> 8) ^ srcBuffer[0][static_cast<uint8_t>(temp)];
                srcBuffer[j][i] = temp;
            }
        }
    }

    uint32_t Hasher(uint32_t a0, const uint8_t* buffer, size_t length, uint32_t SBox[8][0x100]) {
        uint32_t ret = a0;
        size_t Count = length / 8;
        if (length >= 8) {
            for (size_t i = 0; i < Count; ++i) {
                uint8_t selector[2][4];
                *reinterpret_cast<uint32_t*>(selector[0]) = reinterpret_cast<const uint32_t*>(buffer)[i * 2] ^ ret;
                *reinterpret_cast<uint32_t*>(selector[1]) = reinterpret_cast<const uint32_t*>(buffer)[i * 2 + 1];

                ret = SBox[7][selector[0][0]] ^
                    SBox[6][selector[0][1]] ^
                    SBox[5][selector[0][2]] ^
                    SBox[4][selector[0][3]] ^
                    SBox[3][selector[1][0]] ^
                    SBox[2][selector[1][1]] ^
                    SBox[1][selector[1][2]] ^
                    SBox[0][selector[1][3]];

            }
        }

        for (size_t i = Count * 8; i < length; ++i)
            ret = (ret >> 8) ^ SBox[0][static_cast<uint8_t>(ret) ^ buffer[i]];

        return ret;
    }

    template<size_t length>
    void ConvertToHexString(const uint64_t (&in_data)[length], char (&out_string)[2 * length * sizeof(uint64_t) + 1], bool use_lowercase = true) {
        static const char UppercaseConvertTable[] = { '0', '1', '2', '3', '4', '5', '6', '7', '8', '9', 'A', 'B', 'C', 'D', 'E', 'F' };
        static const char LowercaseConvertTable[] = { '0', '1', '2', '3', '4', '5', '6', '7', '8', '9', 'a', 'b', 'c', 'd', 'e', 'f' };

        const uint8_t* cur_ptr = reinterpret_cast<const uint8_t*>(in_data + length) - 1;
        const char* ConvertTable = use_lowercase ? LowercaseConvertTable : UppercaseConvertTable;

        while (*cur_ptr == 0)
            --cur_ptr;

        out_string[2 * (cur_ptr - reinterpret_cast<const uint8_t*>(in_data) + 1)] = 0;
        for (size_t i = 0; cur_ptr >= reinterpret_cast<const uint8_t*>(in_data); i += 2) {
            out_string[i] = ConvertTable[*cur_ptr >> 4];
            out_string[i + 1] = ConvertTable[*cur_ptr & 0xF];
            --cur_ptr;
        }
    }

    template<size_t length>
    size_t GetByteLength(const uint64_t (&in_data)[length]) {
        const uint8_t* cur_ptr = reinterpret_cast<const uint8_t*>(in_data + length);
        while (*(--cur_ptr) == 0);
        ++cur_ptr;

        return cur_ptr - reinterpret_cast<const uint8_t*>(in_data);
    }

    void InitializeGenerator(uint32_t (&out_Generator)[16], 
                             const uint8_t in_private[], size_t in_private_length, 
                             const uint8_t in_data[], size_t in_data_length) {

        memset(out_Generator, 0, sizeof(out_Generator));

        if (in_private == nullptr) {
            out_Generator[1] = 0xeb3eb781;
            out_Generator[2] = 0x50265329;
            out_Generator[3] = 0xdc5ef4a3;
            out_Generator[4] = 0x6847b9d5;
            out_Generator[5] = 0xcde43b4c;
        } else {
            accel::algorithm::hash::SHA1::Initialize(out_Generator + 1);
            accel::algorithm::hash::SHA1::MainCycle(in_private, in_private_length, out_Generator + 1);
            accel::algorithm::hash::SHA1::Final(in_private, in_private_length, out_Generator + 1);
            for (int i = 1; i < 6; ++i)
                out_Generator[i] = _byteswap_ulong(out_Generator[i]);
        }

        accel::algorithm::hash::SHA1::Initialize(out_Generator + 6);
        accel::algorithm::hash::SHA1::MainCycle(in_data, in_data_length, out_Generator + 6);
        accel::algorithm::hash::SHA1::Final(in_data, in_data_length, out_Generator + 6);
        accel::algorithm::hash::SHA1::MainCycle(nullptr, 0, out_Generator + 6);
        accel::algorithm::hash::SHA1::Final(nullptr, 0, out_Generator + 11);
        for (int i = 6; i < 16; ++i)
            out_Generator[i] = _byteswap_ulong(out_Generator[i]);
    }

    void GeneratePrivateKey(uint32_t (&in_Generator)[6], uint64_t (&out_PrivateKey)[4]) {
        memset(out_PrivateKey, 0, sizeof(out_PrivateKey));

        uint32_t hash[5];
        for (int i = 0; i < 15; ++i) {
            accel::algorithm::hash::SHA1::Initialize(hash);
            in_Generator[0] = i + 1;
            accel::algorithm::hash::SHA1::MainCycle(reinterpret_cast<const uint8_t*>(in_Generator),
                                                    sizeof(uint32_t) * 6, hash);
            accel::algorithm::hash::SHA1::Final(reinterpret_cast<const uint8_t*>(in_Generator),
                                                sizeof(uint32_t) * 6, hash);
            reinterpret_cast<uint16_t*>(out_PrivateKey)[i] = static_cast<uint16_t>(_byteswap_ulong(hash[0]));
        }
    }

    void GeneratePrivateKey(const uint8_t in_private[], size_t in_private_length, uint64_t(&out_PrivateKey)[4]) {
        uint32_t Generator[6];

        if (in_private == nullptr) {
            Generator[1] = 0xeb3eb781;
            Generator[2] = 0x50265329;
            Generator[3] = 0xdc5ef4a3;
            Generator[4] = 0x6847b9d5;
            Generator[5] = 0xcde43b4c;
        } else {
            accel::algorithm::hash::SHA1::Initialize(Generator + 1);
            accel::algorithm::hash::SHA1::MainCycle(in_private, in_private_length, Generator + 1);
            accel::algorithm::hash::SHA1::Final(in_private, in_private_length, Generator + 1);
            for (int i = 1; i < 6; ++i)
                Generator[i] = _byteswap_ulong(Generator[i]);
        }

        GeneratePrivateKey(Generator, out_PrivateKey);
    }

    void GeneratePublicX(const uint64_t (&in_PrivateKey)[4], uint64_t (&out_PublicX)[4]) {
        auto nP = G.GetNP(in_PrivateKey, 4);
        nP.X.ToDecimal(out_PublicX);
#if defined(_M_X64)
        accel::math::mb_mul_u64(out_PublicX, 4, 2);
        accel::math::mb_add_u64(out_PublicX, 4, (nP.Y / nP.X).Value[0] & 1, 0);
#elif defined(_M_IX86)
        accel::math::mb_mul_u32(reinterpret_cast<uint32_t*>(out_PublicX), 8, 2);
        accel::math::mb_add_u32(reinterpret_cast<uint32_t*>(out_PublicX), 8, (nP.Y / nP.X).Value[0] & 1, 0);
#endif
    }

    void GeneratePublicX(const uint8_t in_private[], size_t in_private_length, uint64_t(&out_PublicX)[4]) {
        uint64_t PrivateKey[4];
        GeneratePrivateKey(in_private, in_private_length, PrivateKey);
        GeneratePublicX(PrivateKey, out_PublicX);
    }

    void GenerateK(uint32_t (&in_Generator)[16], uint64_t (&out_K)[4]) {
        memset(out_K, 0, sizeof(out_K));

        uint32_t hash[5];
        for (int i = 0; i < 15; ++i) {
            accel::algorithm::hash::SHA1::Initialize(hash);
            ++in_Generator[0];
            accel::algorithm::hash::SHA1::MainCycle(reinterpret_cast<const uint8_t*>(in_Generator),
                                                    sizeof(in_Generator), hash);
            accel::algorithm::hash::SHA1::Final(reinterpret_cast<const uint8_t*>(in_Generator),
                                                sizeof(in_Generator), hash);
            reinterpret_cast<uint16_t*>(out_K)[i] = static_cast<uint16_t>(_byteswap_ulong(hash[0]));
        }
    }

    void Signature(const uint8_t in_data[], size_t in_data_length,
                   const uint8_t in_private[], size_t in_private_length,
                   SignatureData& out_SignData) {

        uint32_t Generator[16];
        InitializeGenerator(Generator, in_private, in_private_length, in_data, in_data_length);

        uint64_t PrivateKey[4];
        uint64_t K[4];
        GeneratePrivateKey(reinterpret_cast<uint32_t (&)[6]>(Generator), PrivateKey);
        GenerateK(Generator, K);
        
        uint64_t Hash[4] = { };
        memcpy_s(Hash, 15 * sizeof(uint16_t), Generator + 6, 15 * sizeof(uint16_t));

        memset(out_SignData.r, 0, sizeof(out_SignData.r));
        G.GetNP(K, 4).X.ToDecimal(out_SignData.r);
#if defined(_M_X64)
        accel::math::mb_add_mb(out_SignData.r, 4, Hash, 4, 0);
        accel::math::mb_div_mb(out_SignData.r, 4, Order, 4, out_SignData.s, 4);

        memset(out_SignData.s, 0, sizeof(out_SignData.s));
        uint64_t PrivateKey_mul_r[8] = { };
        uint64_t temp_quotient[5] = { };
        accel::math::mb_mul_mb(PrivateKey, 4, out_SignData.r, 4, PrivateKey_mul_r, 8);
        accel::math::mb_div_mb(PrivateKey_mul_r, 8, Order, 4, temp_quotient, 5);

        if(accel::math::mb_sub_mb(K, 4, PrivateKey_mul_r, 4, out_SignData.s, 4, 0))
            accel::math::mb_add_mb(out_SignData.s, 4, Order, 4, 0);
#elif defined(_M_IX86)
        accel::math::mb_add_mb(reinterpret_cast<uint32_t*>(out_SignData.r), 8, 
                               reinterpret_cast<uint32_t*>(Hash), 8, 
                               0);
        accel::math::mb_div_mb(reinterpret_cast<uint32_t*>(out_SignData.r), 8, 
                               reinterpret_cast<const uint32_t*>(Order), 8, 
                               reinterpret_cast<uint32_t*>(out_SignData.s), 8);

        memset(out_SignData.s, 0, sizeof(out_SignData.s));
        uint64_t PrivateKey_mul_r[8] = { };
        uint64_t temp_quotient[5] = { };
        accel::math::mb_mul_mb(reinterpret_cast<uint32_t*>(PrivateKey), 8, 
                               reinterpret_cast<uint32_t*>(out_SignData.r), 8, 
                               reinterpret_cast<uint32_t*>(PrivateKey_mul_r), 16);

        accel::math::mb_div_mb(reinterpret_cast<uint32_t*>(PrivateKey_mul_r), 16, 
                               reinterpret_cast<const uint32_t*>(Order), 8, 
                               reinterpret_cast<uint32_t*>(temp_quotient), 10);

        if (accel::math::mb_sub_mb(reinterpret_cast<uint32_t*>(K), 8,
                                   reinterpret_cast<uint32_t*>(PrivateKey_mul_r), 8,
                                   reinterpret_cast<uint32_t*>(out_SignData.s), 8,
                                   0)) {
            accel::math::mb_add_mb(reinterpret_cast<uint32_t*>(out_SignData.s), 8, 
                                   reinterpret_cast<const uint32_t*>(Order), 8, 
                                   0);
        }
#endif
    }

}

#ifdef _DEBUG
void StartTest() {
    GaloisField$2$15$17<WinRAR::BasePoly, WinRAR::ExtendPoly> a0({
        0x4CAB, 0x7F00, 0x409B, 0x784F, 
        0x6105, 0x2D19, 0x4699, 0x4D0F, 
        0x5420, 0x5625, 0x7342, 0x2D0D, 
        0x1DCE, 0x1052, 0x3450, 0x0595, 
        0x6CCD 
    });

    GaloisField$2$15$17<WinRAR::BasePoly, WinRAR::ExtendPoly> b0({
        0x5AA7, 0x7315, 0x2132, 0x12D1,
        0x1DD3, 0x1540, 0x71BF, 0x42C6,
        0x3BAE, 0x3F1C, 0x3A14, 0x2619,
        0x63E7, 0x6936, 0x2919, 0x76ED,
        0x1D9B 
    });

    GaloisField$2$15$17<WinRAR::BasePoly, WinRAR::ExtendPoly> c0({
        0x65C2, 0x677A, 0x0931, 0x5067,
        0x1FDA, 0x0E0C, 0x1801, 0x779D,
        0x0918, 0x6F18, 0x3A36, 0x688F,
        0x78EF, 0x17E0, 0x27C7, 0x7F67,
        0x10DB 
    });

    assert(a0 * b0 == c0);
    _tprintf_s(TEXT("Test 1 passed.\n"));

    GaloisField$2$15$17<WinRAR::BasePoly, WinRAR::ExtendPoly> a1({
        0x7CEC, 0x3646, 0x2C52, 0x1363,
        0x7A87, 0x4666, 0x083E, 0x2B1E,
        0x088B, 0x5142, 0x1D95, 0x0BAD,
        0x31A0, 0x6EB6, 0x2116, 0x5818,
        0x0147 
    });

    GaloisField$2$15$17<WinRAR::BasePoly, WinRAR::ExtendPoly> b1({
        0x5AA7, 0x7315, 0x2132, 0x12D1,
        0x1DD3, 0x1540, 0x71BF, 0x42C6,
        0x3BAE, 0x3F1C, 0x3A14, 0x2619,
        0x63E7, 0x6936, 0x2919, 0x76ED,
        0x1D9B 
    });

    assert(a1.Inverse() == b1);
    _tprintf_s(TEXT("Test 2 passed.\n"));

    ecCurveOverGF$2$15$17<WinRAR::BasePoly, WinRAR::ExtendPoly> ecCurve(0, 161);

    auto a2 = ecCurve.GetPoint({ 
        0x655E, 0x4AEC, 0x5EC4, 0x280E,
        0x2D9C, 0x018A, 0x6CE6, 0x6446,
        0x4F96, 0x64E4, 0x5A48, 0x36AB,
        0x79E3, 0x7854, 0x785A, 0x6CB9,
        0x5E76 
    }, { 
        0x5243, 0x4418, 0x0E66, 0x5BC2,
        0x7474, 0x6F88, 0x18F1, 0x66FC,
        0x70AC, 0x21D0, 0x32C8, 0x3048,
        0x3670, 0x5494, 0x645F, 0x2000,
        0x02E0 
    });

    auto b2 = ecCurve.GetPoint({
        0x16C8, 0x6E22, 0x6C50, 0x4047,
        0x21C2, 0x0076, 0x4E69, 0x0713,
        0x5BB9, 0x1876, 0x53E3, 0x4D6A,
        0x4E1C, 0x3C95, 0x0849, 0x2C91,
        0x4CB3 
    }, { 
        0x4079, 0x498C, 0x48CC, 0x2623,
        0x4BAD, 0x5660, 0x6E3E, 0x5C7B,
        0x1E5C, 0x5CD6, 0x3C60, 0x42C7,
        0x0285, 0x3C96, 0x282C, 0x291A,
        0x3D9B 
    });

    auto c2 = ecCurve.GetPoint({ 
        0x20BE, 0x22A6, 0x3969, 0x7EF6,
        0x72E3, 0x2EB7, 0x59B0, 0x254D,
        0x3E78, 0x43C1, 0x6209, 0x0D70,
        0x1BA0, 0x1BB0, 0x765E, 0x094F,
        0x2A88 
    }, { 
        0x19B7, 0x235B, 0x1E4D, 0x33A4,
        0x07A3, 0x73E5, 0x793A, 0x698E,
        0x4E2E, 0x4966, 0x3FF9, 0x4004,
        0x0AAF, 0x1692, 0x7900, 0x27B5,
        0x16EA 
    });

    assert(a2 + b2 == c2);
    _tprintf_s(TEXT("Test 3 passed.\n"));

    auto a3 = ecCurve.GetPoint({ 
        0x38CC, 0x052F, 0x2510, 0x45AA,
        0x1B89, 0x4468, 0x4882, 0x0D67,
        0x4FEB, 0x55CE, 0x0025, 0x4CB7,
        0x0CC2, 0x59DC, 0x289E, 0x65E3,
        0x56FD 
    }, { 
        0x31A7, 0x65F2, 0x18C4, 0x3412,
        0x7388, 0x54C1, 0x539B, 0x4A02,
        0x4D07, 0x12D6, 0x7911, 0x3B5E,
        0x4F0E, 0x216F, 0x2BF2, 0x1974,
        0x20DA 
    });

    uint64_t b3[4] = { 
        0x5b634cf28190bdf4, 0x8519aa87488bf38f, 
        0xc5c62f0238f183d2, 0x35c6ab9048e2
    };

    auto c3 = ecCurve.GetPoint({
        0x651C, 0x1207, 0x331A, 0x5769, 
        0x76BD, 0x690D, 0x5159, 0x672C, 
        0x10C7, 0x559C, 0x004C, 0x5F04, 
        0x4476, 0x7DDB, 0x6912, 0x2E81, 
        0x5FA6 
    }, { 
        0x1DD9, 0x38CE, 0x6F31, 0x24A9, 
        0x66D6, 0x4E59, 0x0301, 0x08C6, 
        0x1759, 0x39EE, 0x2B52, 0x1839, 
        0x6F5A, 0x7FBC, 0x59A3, 0x30F8, 
        0x66E0 
    });

    assert(a3.GetNP(b3, 4) == c3);
    _tprintf_s(TEXT("Test 4 passed.\n"));
}
#endif // _DEBUG

bool GenerateRegisterData(const char* UserName, const char* LicenseType, char (&RegisterData)[4][512], char(&UID)[512]) {
    memset(RegisterData, 0, sizeof(RegisterData));

    uint64_t temp_value[4];
    char temp_string[2][sizeof(temp_value) * 2 + 1];
    WinRAR::GeneratePublicX(reinterpret_cast<const uint8_t*>(UserName), strlen(UserName), temp_value);
    WinRAR::ConvertToHexString(temp_value, temp_string[0]);
    if (_stprintf_s(RegisterData[3], TEXT("%zd%.48s"), strlen(temp_string[0]) - 4, temp_string) == -1)
        return false;

    WinRAR::GeneratePublicX(reinterpret_cast<const uint8_t*>(RegisterData[3]), strlen(RegisterData[3]), temp_value);
    WinRAR::ConvertToHexString(temp_value, temp_string[1]);
    if (_stprintf_s(RegisterData[0], TEXT("%s"), temp_string[1]) == -1)
        return false;

    if (_stprintf_s(UID, TEXT("UID=%.16s%.4s"), temp_string[0] + 48, temp_string[1]) == -1)
        return false;

    WinRAR::SignatureData LicenseType_Signature;
    WinRAR::Signature(reinterpret_cast<const uint8_t*>(LicenseType), strlen(LicenseType), nullptr, 0, LicenseType_Signature);
    WinRAR::ConvertToHexString(LicenseType_Signature.r, temp_string[0]);
    WinRAR::ConvertToHexString(LicenseType_Signature.s, temp_string[1]);
    if (_stprintf_s(RegisterData[1], TEXT("60%060s%060s"), temp_string[1], temp_string[0]) == -1)
        return false;

    WinRAR::SignatureData UserName_Signature;
    if (_stprintf_s(RegisterData[2], TEXT("%s%s"), UserName, RegisterData[0]) == -1)
        return false;
    WinRAR::Signature(reinterpret_cast<const uint8_t*>(RegisterData[2]), strlen(RegisterData[2]),
                      nullptr, 0, 
                      UserName_Signature);
    WinRAR::ConvertToHexString(UserName_Signature.r, temp_string[0]);
    WinRAR::ConvertToHexString(UserName_Signature.s, temp_string[1]);
    if (_stprintf_s(RegisterData[2], TEXT("60%060s%060s"), temp_string[1], temp_string[0]) == -1)
        return false;

    return true;
}

uint32_t GenerateChecksum(const char* UserName, const char* LicenseType, char(&RegisterData)[4][512]) {
    uint32_t result = WinRAR::Hasher(0xffffffff, 
                                     reinterpret_cast<const uint8_t*>(LicenseType), 
                                     strlen(LicenseType), 
                                     WinRAR::SBox);
    result = WinRAR::Hasher(result, reinterpret_cast<const uint8_t*>(UserName),
                            strlen(UserName),
                            WinRAR::SBox);

    result = WinRAR::Hasher(result, reinterpret_cast<const uint8_t*>(RegisterData[0]),
                            strlen(RegisterData[0]),
                            WinRAR::SBox);
    result = WinRAR::Hasher(result, reinterpret_cast<const uint8_t*>(RegisterData[1]),
                            strlen(RegisterData[1]),
                            WinRAR::SBox);
    result = WinRAR::Hasher(result, reinterpret_cast<const uint8_t*>(RegisterData[2]),
                            strlen(RegisterData[2]),
                            WinRAR::SBox);
    result = WinRAR::Hasher(result, reinterpret_cast<const uint8_t*>(RegisterData[3]),
                            strlen(RegisterData[3]),
                            WinRAR::SBox);
    return result;
}

int _tmain(int argc, TCHAR* argv[]) {

    if (argc != 3) {
        _tprintf_s(TEXT("Usage:\n"));
        _tprintf_s(TEXT("        winrar-keygen.exe <your name> <license type>\n\n"));
        _tprintf_s(TEXT("Example:\n\n"));
        _tprintf_s(TEXT("        winrar-keygen.exe \"Rebecca Morrison\" \"Single PC usage license\"\n"));
        _tprintf_s(TEXT(" or:\n"));
        _tprintf_s(TEXT("        winrar-keygen.exe \"Rebecca Morrison\" \"Single PC usage license\" >> rarreg.key\n\n"));
        return 0;
    }

    GaloisField$2$15<WinRAR::BasePoly>::InitTable();
    WinRAR::InitSBox(WinRAR::SBox);

    char* UserName = argv[1];
    char* LicenseType = argv[2];

    char RegisterData[4][512];
    char UID[512];
    if (GenerateRegisterData(UserName, LicenseType, RegisterData, UID) == false)
        throw std::overflow_error("buffer is too small.");

    uint32_t checksum = GenerateChecksum(UserName, LicenseType, RegisterData);

    _tprintf_s(TEXT("RAR registration data\n%s\n%s\n%s\n"), 
               UserName,
               LicenseType,
               UID);

    _stprintf_s(UID, TEXT("%zd%zd%zd%zd%s%s%s%s%lu"),
                strlen(RegisterData[0]),
                strlen(RegisterData[1]),
                strlen(RegisterData[2]),
                strlen(RegisterData[3]),
                RegisterData[0],
                RegisterData[1],
                RegisterData[2],
                RegisterData[3], 
                checksum);

    for (int i = 0; i < 8; ++i)
        _tprintf_s(TEXT("%.54s\n"), UID + i * 54);

	return 0;
}