// // System.Security.Cryptography SymmetricAlgorithm Class implementation // // Authors: // Thomas Neidhart (tome@sbox.tugraz.at) // Sebastien Pouliot // // Portions (C) 2002, 2003 Motus Technologies Inc. (http://www.motus.com) // Copyright (C) 2004-2005 Novell, Inc (http://www.novell.com) // // Permission is hereby granted, free of charge, to any person obtaining // a copy of this software and associated documentation files (the // "Software"), to deal in the Software without restriction, including // without limitation the rights to use, copy, modify, merge, publish, // distribute, sublicense, and/or sell copies of the Software, and to // permit persons to whom the Software is furnished to do so, subject to // the following conditions: // // The above copyright notice and this permission notice shall be // included in all copies or substantial portions of the Software. // // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, // EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF // MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND // NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE // LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION // OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION // WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. // using System.Globalization; using System.Runtime.InteropServices; using Mono.Security.Cryptography; namespace System.Security.Cryptography { #if NET_2_0 [ComVisible (true)] #endif public abstract class SymmetricAlgorithm : IDisposable { protected int BlockSizeValue; protected int FeedbackSizeValue; protected byte[] IVValue; protected int KeySizeValue; protected byte[] KeyValue; protected KeySizes[] LegalBlockSizesValue; protected KeySizes[] LegalKeySizesValue; protected CipherMode ModeValue; protected PaddingMode PaddingValue; private bool m_disposed; public SymmetricAlgorithm () { ModeValue = CipherMode.CBC; PaddingValue = PaddingMode.PKCS7; m_disposed = false; } ~SymmetricAlgorithm () { Dispose (false); } public void Clear() { Dispose (true); } void IDisposable.Dispose () { Dispose (true); GC.SuppressFinalize (this); // Finalization is now unnecessary } protected virtual void Dispose (bool disposing) { if (!m_disposed) { // always zeroize keys if (KeyValue != null) { // Zeroize the secret key and free Array.Clear (KeyValue, 0, KeyValue.Length); KeyValue = null; } // dispose unmanaged managed objects if (disposing) { // dispose managed objects } m_disposed = true; } } public virtual int BlockSize { get { return this.BlockSizeValue; } set { if (!KeySizes.IsLegalKeySize (this.LegalBlockSizesValue, value)) { throw new CryptographicException ( Locale.GetText ("block size not supported by algorithm")); } this.BlockSizeValue = value; } } public virtual int FeedbackSize { get { return this.FeedbackSizeValue; } set { #if NET_2_0 if ((value <= 0) || (value > this.BlockSizeValue)) { #else if (value > this.BlockSizeValue) { #endif throw new CryptographicException ( Locale.GetText ("feedback size larger than block size")); } this.FeedbackSizeValue = value; } } public virtual byte[] IV { get { if (this.IVValue == null) GenerateIV(); return (byte[]) this.IVValue.Clone (); } set { if (value == null) throw new ArgumentNullException ("IV"); #if NET_2_0 // 2.0 is stricter for IV length - which is bad for IV-less stream ciphers like RC4 if ((value.Length << 3) != this.BlockSizeValue) { throw new CryptographicException ( Locale.GetText ("IV length is different than block size")); } #else if ((value.Length << 3) > this.BlockSizeValue) { throw new CryptographicException ( Locale.GetText ("IV length cannot be larger than block size")); } #endif this.IVValue = (byte[]) value.Clone (); } } public virtual byte[] Key { get { if (this.KeyValue == null) GenerateKey(); return (byte[]) this.KeyValue.Clone (); } set { if (value == null) throw new ArgumentNullException ("Key"); int length = (value.Length << 3); if (!KeySizes.IsLegalKeySize (this.LegalKeySizesValue, length)) { throw new CryptographicException ( Locale.GetText ("Key size not supported by algorithm")); } this.KeySizeValue = length; this.KeyValue = (byte[]) value.Clone (); } } public virtual int KeySize { get { return this.KeySizeValue; } set { if (!KeySizes.IsLegalKeySize (this.LegalKeySizesValue, value)) { throw new CryptographicException ( Locale.GetText ("Key size not supported by algorithm")); } this.KeyValue = null; this.KeySizeValue = value; } } public virtual KeySizes[] LegalBlockSizes { get { return this.LegalBlockSizesValue; } } public virtual KeySizes[] LegalKeySizes { get { return this.LegalKeySizesValue; } } public virtual CipherMode Mode { get { return this.ModeValue; } set { if (!Enum.IsDefined (ModeValue.GetType (), value)) { throw new CryptographicException ( Locale.GetText ("Cipher mode not available")); } this.ModeValue = value; } } public virtual PaddingMode Padding { get { return this.PaddingValue; } set { if (!Enum.IsDefined (PaddingValue.GetType (), value)) { throw new CryptographicException ( Locale.GetText ("Padding mode not available")); } this.PaddingValue = value; } } public virtual ICryptoTransform CreateDecryptor () { return CreateDecryptor (Key, IV); } public abstract ICryptoTransform CreateDecryptor (byte[] rgbKey, byte[] rgbIV); public virtual ICryptoTransform CreateEncryptor() { return CreateEncryptor (Key, IV); } public abstract ICryptoTransform CreateEncryptor (byte[] rgbKey, byte[] rgbIV); public abstract void GenerateIV (); public abstract void GenerateKey (); public bool ValidKeySize (int bitLength) { return KeySizes.IsLegalKeySize (LegalKeySizesValue, bitLength); } // LAMESPEC: Default is Rijndael - not TripleDES public static SymmetricAlgorithm Create () { return Create ("System.Security.Cryptography.SymmetricAlgorithm"); } public static SymmetricAlgorithm Create (string algName) { return (SymmetricAlgorithm) CryptoConfig.CreateFromName (algName); } } }