/// <summary> /// Initializes encryption keys based on given <paramref name="password"/>. /// </summary> /// <param name="password">The password.</param> protected void InitializePassword(string password) { #if NETCF_1_0 keys = new uint[] { 0x12345678, 0x23456789, 0x34567890 }; byte[] rawPassword = ZipConstants.ConvertToArray(password); for (int i = 0; i < rawPassword.Length; ++i) { UpdateKeys((byte)rawPassword[i]); } #else PkzipClassicManaged pkManaged = new PkzipClassicManaged(); byte[] key = PkzipClassic.GenerateKeys(ZipConstants.ConvertToArray(password)); cryptoTransform_ = pkManaged.CreateEncryptor(key, null); #endif }
Stream CreateAndInitDecryptionStream(Stream baseStream, ZipEntry entry) { CryptoStream result = null; if ( (entry.Version < ZipConstants.VersionStrongEncryption) || (entry.Flags & (int)GeneralBitFlags.StrongEncryption) == 0) { PkzipClassicManaged classicManaged = new PkzipClassicManaged(); OnKeysRequired(entry.Name); if (HaveKeys == false) { throw new ZipException("No password available for encrypted stream"); } result = new CryptoStream(baseStream, classicManaged.CreateDecryptor(key, null), CryptoStreamMode.Read); CheckClassicPassword(result, entry); } else { #if !NET_1_1 && !NETCF_2_0 if (entry.Version == ZipConstants.VERSION_AES) { // OnKeysRequired(entry.Name); if (HaveKeys == false) { throw new ZipException("No password available for AES encrypted stream"); } int saltLen = entry.AESSaltLen; byte[] saltBytes = new byte[saltLen]; int saltIn = baseStream.Read(saltBytes, 0, saltLen); if (saltIn != saltLen) throw new ZipException("AES Salt expected " + saltLen + " got " + saltIn); // byte[] pwdVerifyRead = new byte[2]; baseStream.Read(pwdVerifyRead, 0, 2); int blockSize = entry.AESKeySize / 8; // bits to bytes ZipAESTransform decryptor = new ZipAESTransform(rawPassword_, saltBytes, blockSize, false); byte[] pwdVerifyCalc = decryptor.PwdVerifier; if (pwdVerifyCalc[0] != pwdVerifyRead[0] || pwdVerifyCalc[1] != pwdVerifyRead[1]) throw new Exception("Invalid password for AES"); result = new ZipAESStream(baseStream, decryptor, CryptoStreamMode.Read); } else #endif { throw new ZipException("Decryption method not supported"); } } return result; }
Stream CreateAndInitEncryptionStream(Stream baseStream, ZipEntry entry) { CryptoStream result = null; if ( (entry.Version < ZipConstants.VersionStrongEncryption) || (entry.Flags & (int)GeneralBitFlags.StrongEncryption) == 0) { PkzipClassicManaged classicManaged = new PkzipClassicManaged(); OnKeysRequired(entry.Name); if (HaveKeys == false) { throw new ZipException("No password available for encrypted stream"); } // Closing a CryptoStream will close the base stream as well so wrap it in an UncompressedStream // which doesnt do this. result = new CryptoStream(new UncompressedStream(baseStream), classicManaged.CreateEncryptor(key, null), CryptoStreamMode.Write); if ( (entry.Crc < 0) || (entry.Flags & 8) != 0) { WriteEncryptionHeader(result, entry.DosTime << 16); } else { WriteEncryptionHeader(result, entry.Crc); } } return result; }
/// <summary> /// Perform the initial read on an entry which may include /// reading encryption headers and setting up inflation. /// </summary> /// <param name="destination">The destination to fill with data read.</param> /// <param name="offset">The offset to start reading at.</param> /// <param name="count">The maximum number of bytes to read.</param> /// <returns>The actual number of bytes read.</returns> int InitialRead(byte[] destination, int offset, int count) { if ( !CanDecompressEntry ) { throw new ZipException("Library cannot extract this entry. Version required is (" + entry.Version.ToString() + ")"); } // Handle encryption if required. if (entry.IsCrypted) { #if NETCF_1_0 throw new ZipException("Encryption not supported for Compact Framework 1.0"); #else if (password == null) { throw new ZipException("No password set."); } // Generate and set crypto transform... PkzipClassicManaged managed = new PkzipClassicManaged(); byte[] key = PkzipClassic.GenerateKeys(ZipConstants.ConvertToArray(password)); inputBuffer.CryptoTransform = managed.CreateDecryptor(key, null); byte[] cryptbuffer = new byte[ZipConstants.CryptoHeaderSize]; inputBuffer.ReadClearTextBuffer(cryptbuffer, 0, ZipConstants.CryptoHeaderSize); if (cryptbuffer[ZipConstants.CryptoHeaderSize - 1] != entry.CryptoCheckValue) { throw new ZipException("Invalid password"); } if (csize >= ZipConstants.CryptoHeaderSize) { csize -= ZipConstants.CryptoHeaderSize; } else if ( (entry.Flags & (int)GeneralBitFlags.Descriptor) == 0 ) { throw new ZipException(string.Format("Entry compressed size {0} too small for encryption", csize)); } #endif } else { #if !NETCF_1_0 inputBuffer.CryptoTransform = null; #endif } if ((csize > 0) || ((flags & (int)GeneralBitFlags.Descriptor) != 0)) { if ((method == (int)CompressionMethod.Deflated) && (inputBuffer.Available > 0)) { inputBuffer.SetInflaterInput(inf); } internalReader = new ReadDataHandler(BodyRead); return BodyRead(destination, offset, count); } else { internalReader = new ReadDataHandler(ReadingNotAvailable); return 0; } }