#if !BESTHTTP_DISABLE_ALTERNATE_SSL && (!UNITY_WEBGL || UNITY_EDITOR) #pragma warning disable using System; using BestHTTP.SecureProtocol.Org.BouncyCastle.Crypto.Parameters; using BestHTTP.SecureProtocol.Org.BouncyCastle.Crypto.Utilities; using BestHTTP.SecureProtocol.Org.BouncyCastle.Utilities; namespace BestHTTP.SecureProtocol.Org.BouncyCastle.Crypto.Engines { /** * A Noekeon engine, using direct-key mode. */ public class NoekeonEngine : IBlockCipher { // Block and key size, as well as the amount of rounds. private const int Size = 16; private static readonly byte[] RoundConstants = { 0x80, 0x1b, 0x36, 0x6c, 0xd8, 0xab, 0x4d, 0x9a, 0x2f, 0x5e, 0xbc, 0x63, 0xc6, 0x97, 0x35, 0x6a, 0xd4 }; private readonly uint[] k = new uint[4]; private bool _initialised, _forEncryption; /** * Create an instance of the Noekeon encryption algorithm * and set some defaults */ public NoekeonEngine() { _initialised = false; } public virtual string AlgorithmName { get { return "Noekeon"; } } public virtual bool IsPartialBlockOkay { get { return false; } } public virtual int GetBlockSize() { return Size; } /** * initialise * * @param forEncryption whether or not we are for encryption. * @param params the parameters required to set up the cipher. * @exception ArgumentException if the params argument is * inappropriate. */ public virtual void Init(bool forEncryption, ICipherParameters parameters) { if (!(parameters is KeyParameter)) throw new ArgumentException("Invalid parameters passed to Noekeon init - " + BestHTTP.SecureProtocol.Org.BouncyCastle.Utilities.Platform.GetTypeName(parameters), "parameters"); KeyParameter p = (KeyParameter) parameters; byte[] key = p.GetKey(); if (key.Length != 16) throw new ArgumentException("Key length not 128 bits."); Pack.BE_To_UInt32(key, 0, k, 0, 4); if (!forEncryption) { // theta(k, new uint[]{ 0x00, 0x00, 0x00, 0x00 }); { uint a0 = k[0], a1 = k[1], a2 = k[2], a3 = k[3]; uint t02 = a0 ^ a2; t02 ^= Integers.RotateLeft(t02, 8) ^ Integers.RotateLeft(t02, 24); uint t13 = a1 ^ a3; t13 ^= Integers.RotateLeft(t13, 8) ^ Integers.RotateLeft(t13, 24); a0 ^= t13; a1 ^= t02; a2 ^= t13; a3 ^= t02; k[0] = a0; k[1] = a1; k[2] = a2; k[3] = a3; } } this._forEncryption = forEncryption; this._initialised = true; } public virtual int ProcessBlock( byte[] input, int inOff, byte[] output, int outOff) { if (!_initialised) throw new InvalidOperationException(AlgorithmName + " not initialised"); Check.DataLength(input, inOff, Size, "input buffer too short"); Check.OutputLength(output, outOff, Size, "output buffer too short"); return _forEncryption ? EncryptBlock(input, inOff, output, outOff) : DecryptBlock(input, inOff, output, outOff); } public virtual void Reset() { } private int EncryptBlock(byte[] input, int inOff, byte[] output, int outOff) { uint a0 = Pack.BE_To_UInt32(input, inOff); uint a1 = Pack.BE_To_UInt32(input, inOff + 4); uint a2 = Pack.BE_To_UInt32(input, inOff + 8); uint a3 = Pack.BE_To_UInt32(input, inOff + 12); uint k0 = k[0], k1 = k[1], k2 = k[2], k3 = k[3]; int round = 0; for (;;) { a0 ^= RoundConstants[round]; // theta(a, k); { uint t02 = a0 ^ a2; t02 ^= Integers.RotateLeft(t02, 8) ^ Integers.RotateLeft(t02, 24); a0 ^= k0; a1 ^= k1; a2 ^= k2; a3 ^= k3; uint t13 = a1 ^ a3; t13 ^= Integers.RotateLeft(t13, 8) ^ Integers.RotateLeft(t13, 24); a0 ^= t13; a1 ^= t02; a2 ^= t13; a3 ^= t02; } if (++round > Size) break; // pi1(a); { a1 = Integers.RotateLeft(a1, 1); a2 = Integers.RotateLeft(a2, 5); a3 = Integers.RotateLeft(a3, 2); } // gamma(a); { uint t = a3; a1 ^= a3 | a2; a3 = a0 ^ (a2 & ~a1); a2 = t ^ ~a1 ^ a2 ^ a3; a1 ^= a3 | a2; a0 = t ^ (a2 & a1); } // pi2(a); { a1 = Integers.RotateLeft(a1, 31); a2 = Integers.RotateLeft(a2, 27); a3 = Integers.RotateLeft(a3, 30); } } Pack.UInt32_To_BE(a0, output, outOff); Pack.UInt32_To_BE(a1, output, outOff + 4); Pack.UInt32_To_BE(a2, output, outOff + 8); Pack.UInt32_To_BE(a3, output, outOff + 12); return Size; } private int DecryptBlock(byte[] input, int inOff, byte[] output, int outOff) { uint a0 = Pack.BE_To_UInt32(input, inOff); uint a1 = Pack.BE_To_UInt32(input, inOff + 4); uint a2 = Pack.BE_To_UInt32(input, inOff + 8); uint a3 = Pack.BE_To_UInt32(input, inOff + 12); uint k0 = k[0], k1 = k[1], k2 = k[2], k3 = k[3]; int round = Size; for (;;) { // theta(a, k); { uint t02 = a0 ^ a2; t02 ^= Integers.RotateLeft(t02, 8) ^ Integers.RotateLeft(t02, 24); a0 ^= k0; a1 ^= k1; a2 ^= k2; a3 ^= k3; uint t13 = a1 ^ a3; t13 ^= Integers.RotateLeft(t13, 8) ^ Integers.RotateLeft(t13, 24); a0 ^= t13; a1 ^= t02; a2 ^= t13; a3 ^= t02; } a0 ^= RoundConstants[round]; if (--round < 0) break; // pi1(a); { a1 = Integers.RotateLeft(a1, 1); a2 = Integers.RotateLeft(a2, 5); a3 = Integers.RotateLeft(a3, 2); } // gamma(a); { uint t = a3; a1 ^= a3 | a2; a3 = a0 ^ (a2 & ~a1); a2 = t ^ ~a1 ^ a2 ^ a3; a1 ^= a3 | a2; a0 = t ^ (a2 & a1); } // pi2(a); { a1 = Integers.RotateLeft(a1, 31); a2 = Integers.RotateLeft(a2, 27); a3 = Integers.RotateLeft(a3, 30); } } Pack.UInt32_To_BE(a0, output, outOff); Pack.UInt32_To_BE(a1, output, outOff + 4); Pack.UInt32_To_BE(a2, output, outOff + 8); Pack.UInt32_To_BE(a3, output, outOff + 12); return Size; } } } #pragma warning restore #endif