RC2CryptoServiceProvider.cs source code in C# .NET

Source code for the .NET framework in C#

                        
Code:

                         / FX-1434 / FX-1434 / 1.0 / untmp / whidbey / REDBITS / ndp / clr / src / BCL / System / Security / Cryptography / RC2CryptoServiceProvider.cs / 1 / RC2CryptoServiceProvider.cs
                        

                        
                            // ==++== 
//
//   Copyright (c) Microsoft Corporation.  All rights reserved.
//
// ==--== 

// 
// RC2CryptoServiceProvider.cs 
//
 
namespace System.Security.Cryptography {

    using System.Globalization;
 
    [System.Runtime.InteropServices.ComVisible(true)]
    public sealed class RC2CryptoServiceProvider : RC2 { 
        private bool m_use40bitSalt = false; 

        private static  KeySizes[] s_legalKeySizes = { 
            new KeySizes(40, 128, 8)  // cryptoAPI implementation only goes up to 128
        };

        // 
        // public constructors
        // 
 
        public RC2CryptoServiceProvider () {
            if (Utils.FipsAlgorithmPolicy == 1) 
                throw new InvalidOperationException(Environment.GetResourceString("Cryptography_NonCompliantFIPSAlgorithm"));
            if (!Utils.HasAlgorithm(Constants.CALG_RC2, 0))
                throw new CryptographicException(Environment.GetResourceString("Cryptography_CSP_AlgorithmNotAvailable"));
 
            // Acquire a Type 1 provider. This will be the Enhanced provider if available, otherwise
            // it will be the base provider. 
            LegalKeySizesValue = s_legalKeySizes; 

            // Since the CSP only supports a CFB feedback of 8, make that the default 
            FeedbackSizeValue = 8;
        }

        // 
        // public methods
        // 
 
        public override int EffectiveKeySize {
            get { 
                return KeySizeValue;
            }
            set {
                if (value != KeySizeValue) 
                    throw new CryptographicUnexpectedOperationException(Environment.GetResourceString("Cryptography_RC2_EKSKS2"));
            } 
        } 

        [System.Runtime.InteropServices.ComVisible(false)] 
        public bool UseSalt {
            get {
                return m_use40bitSalt;
            } 
            set {
                m_use40bitSalt = value; 
            } 
        }
 
        public override ICryptoTransform CreateEncryptor (byte[] rgbKey, byte[] rgbIV) {
            return _NewEncryptor(rgbKey, ModeValue, rgbIV, EffectiveKeySizeValue,
                                 FeedbackSizeValue, CryptoAPITransformMode.Encrypt);
        } 

        public override ICryptoTransform CreateDecryptor (byte[] rgbKey, byte[] rgbIV) { 
            return _NewEncryptor(rgbKey, ModeValue, rgbIV, EffectiveKeySizeValue, 
                                 FeedbackSizeValue, CryptoAPITransformMode.Decrypt);
        } 

        public override void GenerateKey () {
            KeyValue = new byte[KeySizeValue/8];
            Utils.StaticRandomNumberGenerator.GetBytes(KeyValue); 
        }
 
        public override void GenerateIV () { 
            // block size is always 64 bits so IV is always 64 bits == 8 bytes
            IVValue = new byte[8]; 
            Utils.StaticRandomNumberGenerator.GetBytes(IVValue);
        }

        // 
        // private methods
        // 
 
        private ICryptoTransform _NewEncryptor (byte[] rgbKey, CipherMode mode, byte[] rgbIV,
                                                int effectiveKeySize, int feedbackSize, CryptoAPITransformMode encryptMode) { 
            int cArgs = 0;
            int[] rgArgIds = new int[10];
            Object[] rgArgValues = new Object[10];
 
            // Check for bad values
            // 1) we don't support OFB mode in RC2_CSP 
            if (mode == CipherMode.OFB) 
                throw new CryptographicException(Environment.GetResourceString("Cryptography_CSP_OFBNotSupported"));
            // 2) we only support CFB with a feedback size of 8 bits 
            if ((mode == CipherMode.CFB) && (feedbackSize != 8))
                throw new CryptographicException(Environment.GetResourceString("Cryptography_CSP_CFBSizeNotSupported"));

            if (rgbKey == null) { 
                rgbKey = new byte[KeySizeValue/8];
                Utils.StaticRandomNumberGenerator.GetBytes(rgbKey); 
            } 

            // Check the rgbKey size 
            int keySizeValue = rgbKey.Length * 8;
            if (!ValidKeySize(keySizeValue))
                throw new CryptographicException(Environment.GetResourceString("Cryptography_InvalidKeySize"));
 
            // Deal with effective key length questions
            rgArgIds[cArgs] = Constants.KP_EFFECTIVE_KEYLEN; 
            if (EffectiveKeySizeValue == 0) { 
                rgArgValues[cArgs] = keySizeValue;
            } else { 
                rgArgValues[cArgs] = effectiveKeySize;
            }
            cArgs += 1;
 
            // Set the mode for the encryptor (defaults to CBC)
            if (mode != CipherMode.CBC) { 
                rgArgIds[cArgs] = Constants.KP_MODE; 
                rgArgValues[cArgs] = mode;
                cArgs += 1; 
            }

            // If not ECB mode -- pass in an IV
            if (mode != CipherMode.ECB) { 
                if (rgbIV == null) {
                    rgbIV = new byte[8]; 
                    Utils.StaticRandomNumberGenerator.GetBytes(rgbIV); 
                }
 
                //
                // We truncate IV's that are longer than the block size to 8 bytes : this is
                // done to maintain backward compatibility with the behavior shipped in V1.x.
                // The call to set the IV in CryptoAPI will ignore any bytes after the first 8 
                // bytes. We'll still reject IV's that are shorter than the block size though.
                // 
                if (rgbIV.Length < 8) 
                    throw new CryptographicException(Environment.GetResourceString("Cryptography_InvalidIVSize"));
 
                rgArgIds[cArgs] = Constants.KP_IV;
                rgArgValues[cArgs] = rgbIV;
                cArgs += 1;
            } 

            // If doing OFB or CFB, then we need to set the feed back loop size 
            if ((mode == CipherMode.OFB) || (mode == CipherMode.CFB)) { 
                rgArgIds[cArgs] = Constants.KP_MODE_BITS;
                rgArgValues[cArgs] = feedbackSize; 
                cArgs += 1;
            }

            if (!Utils.HasAlgorithm(Constants.CALG_RC2, keySizeValue)) 
                throw new CryptographicException(String.Format(CultureInfo.CurrentCulture, Environment.GetResourceString("Cryptography_CSP_AlgKeySizeNotAvailable"), keySizeValue));
 
            //  Create the encryptor/decryptor object 
            return new CryptoAPITransform(Constants.CALG_RC2, cArgs, rgArgIds,
                                          rgArgValues, rgbKey, PaddingValue, 
                                          mode, BlockSizeValue, feedbackSize, m_use40bitSalt,
                                          encryptMode);
        }
    } 
}

Link Menu

Network programming in C#, Network Programming in VB.NET, Network Programming in .NET
This book is available now!
Buy at Amazon US or
Buy at Amazon UK