Wie Laden des öffentlichen RSA-Schlüssels aus Datei in C #

Ich muss den folgenden öffentlichen RSA-Schlüssel aus einer Datei zur Verwendung mit der RSACryptoServiceProvider-class laden. Wie kann ich das machen?

-----BEGIN PUBLIC KEY----- XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX/syEKqEkMtQL0+d XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX+izR KbGMRtur2TYklnyVkjeeHfAggo8vWQmWesnOG55vQYHbOOFoJbk0EkwEr5R/PbKm byXPPN8zwnS5/XXXXXXXXXXXX -----END PUBLIC KEY----- 

Dieser Code funktioniert mit meinem Pub-Schlüssel: http://www.jensign.com/opensslkey/

Hier ist der Code, den ich verwende

  static string RSA(string input) { RSACryptoServiceProvider rsa = DecodeX509PublicKey(Convert.FromBase64String(GetKey())); return (Convert.ToBase64String(rsa.Encrypt(Encoding.ASCII.GetBytes(input), false))); } static string GetKey() { return File.ReadAllText("master.pub").Replace("-----BEGIN PUBLIC KEY-----", "").Replace("-----END PUBLIC KEY-----", ""); //.Replace("\n", ""); } private static bool CompareBytearrays(byte[] a, byte[] b) { if (a.Length != b.Length) return false; int i = 0; foreach (byte c in a) { if (c != b[i]) return false; i++; } return true; } public static RSACryptoServiceProvider DecodeX509PublicKey(byte[] x509key) { // encoded OID sequence for PKCS #1 rsaEncryption szOID_RSA_RSA = "1.2.840.113549.1.1.1" byte[] SeqOID = { 0x30, 0x0D, 0x06, 0x09, 0x2A, 0x86, 0x48, 0x86, 0xF7, 0x0D, 0x01, 0x01, 0x01, 0x05, 0x00 }; byte[] seq = new byte[15]; // --------- Set up stream to read the asn.1 encoded SubjectPublicKeyInfo blob ------ MemoryStream mem = new MemoryStream(x509key); BinaryReader binr = new BinaryReader(mem); //wrap Memory Stream with BinaryReader for easy reading byte bt = 0; ushort twobytes = 0; try { twobytes = binr.ReadUInt16(); if (twobytes == 0x8130) //data read as little endian order (actual data order for Sequence is 30 81) binr.ReadByte(); //advance 1 byte else if (twobytes == 0x8230) binr.ReadInt16(); //advance 2 bytes else return null; seq = binr.ReadBytes(15); //read the Sequence OID if (!CompareBytearrays(seq, SeqOID)) //make sure Sequence for OID is correct return null; twobytes = binr.ReadUInt16(); if (twobytes == 0x8103) //data read as little endian order (actual data order for Bit String is 03 81) binr.ReadByte(); //advance 1 byte else if (twobytes == 0x8203) binr.ReadInt16(); //advance 2 bytes else return null; bt = binr.ReadByte(); if (bt != 0x00) //expect null byte next return null; twobytes = binr.ReadUInt16(); if (twobytes == 0x8130) //data read as little endian order (actual data order for Sequence is 30 81) binr.ReadByte(); //advance 1 byte else if (twobytes == 0x8230) binr.ReadInt16(); //advance 2 bytes else return null; twobytes = binr.ReadUInt16(); byte lowbyte = 0x00; byte highbyte = 0x00; if (twobytes == 0x8102) //data read as little endian order (actual data order for Integer is 02 81) lowbyte = binr.ReadByte(); // read next bytes which is bytes in modulus else if (twobytes == 0x8202) { highbyte = binr.ReadByte(); //advance 2 bytes lowbyte = binr.ReadByte(); } else return null; byte[] modint = { lowbyte, highbyte, 0x00, 0x00 }; //reverse byte order since asn.1 key uses big endian order int modsize = BitConverter.ToInt32(modint, 0); byte firstbyte = binr.ReadByte(); binr.BaseStream.Seek(-1, SeekOrigin.Current); if (firstbyte == 0x00) { //if first byte (highest order) of modulus is zero, don't include it binr.ReadByte(); //skip this null byte modsize -= 1; //reduce modulus buffer size by 1 } byte[] modulus = binr.ReadBytes(modsize); //read the modulus bytes if (binr.ReadByte() != 0x02) //expect an Integer for the exponent data return null; int expbytes = (int)binr.ReadByte(); // should only need one byte for actual exponent data (for all useful values) byte[] exponent = binr.ReadBytes(expbytes); // ------- create RSACryptoServiceProvider instance and initialize with public key ----- RSACryptoServiceProvider RSA = new RSACryptoServiceProvider(); RSAParameters RSAKeyInfo = new RSAParameters(); RSAKeyInfo.Modulus = modulus; RSAKeyInfo.Exponent = exponent; RSA.ImportParameters(RSAKeyInfo); return RSA; } catch (Exception) { return null; } finally { binr.Close(); } } 

Rufen Sie einfach die Methode “RSA” mit dem Text auf, den Sie verschlüsseln möchten, und schon sind Sie fertig.

    Sie können RSACryptoServiceProvider aus einer PEM-Datei mit der folgenden class abrufen (GetRSAProviderFromPemFile-Methode). Copyright (c) 2000 JavaScience Beratung, Michel Gallant

    Verwendung:

     RSACryptoServiceProvider provider = PemKeyUtils.GetRSAProviderFromPemFile( @"public_key.pem" ); public class PemKeyUtils { const String pemprivheader = "-----BEGIN RSA PRIVATE KEY-----"; const String pemprivfooter = "-----END RSA PRIVATE KEY-----"; const String pempubheader = "-----BEGIN PUBLIC KEY-----"; const String pempubfooter = "-----END PUBLIC KEY-----"; const String pemp8header = "-----BEGIN PRIVATE KEY-----"; const String pemp8footer = "-----END PRIVATE KEY-----"; const String pemp8encheader = "-----BEGIN ENCRYPTED PRIVATE KEY-----"; const String pemp8encfooter = "-----END ENCRYPTED PRIVATE KEY-----"; static bool verbose = false; public static RSACryptoServiceProvider GetRSAProviderFromPemFile( String pemfile ) { bool isPrivateKeyFile = true; string pemstr = File.ReadAllText( pemfile ).Trim(); if (pemstr.StartsWith( pempubheader ) && pemstr.EndsWith( pempubfooter )) isPrivateKeyFile = false; byte[] pemkey; if (isPrivateKeyFile) pemkey = DecodeOpenSSLPrivateKey( pemstr ); else pemkey = DecodeOpenSSLPublicKey( pemstr ); if (pemkey == null) return null; if (isPrivateKeyFile) return DecodeRSAPrivateKey( pemkey ); else return DecodeX509PublicKey( pemkey ); } //-------- Get the binary RSA PUBLIC key -------- static byte[] DecodeOpenSSLPublicKey( String instr ) { const String pempubheader = "-----BEGIN PUBLIC KEY-----"; const String pempubfooter = "-----END PUBLIC KEY-----"; String pemstr = instr.Trim(); byte[] binkey; if (!pemstr.StartsWith( pempubheader ) || !pemstr.EndsWith( pempubfooter )) return null; StringBuilder sb = new StringBuilder( pemstr ); sb.Replace( pempubheader, "" ); //remove headers/footers, if present sb.Replace( pempubfooter, "" ); String pubstr = sb.ToString().Trim(); //get string after removing leading/trailing whitespace try { binkey = Convert.FromBase64String( pubstr ); } catch (System.FormatException) { //if can't b64 decode, data is not valid return null; } return binkey; } static RSACryptoServiceProvider DecodeX509PublicKey(byte[] x509Key) { // encoded OID sequence for PKCS #1 rsaEncryption szOID_RSA_RSA = "1.2.840.113549.1.1.1" byte[] seqOid = { 0x30, 0x0D, 0x06, 0x09, 0x2A, 0x86, 0x48, 0x86, 0xF7, 0x0D, 0x01, 0x01, 0x01, 0x05, 0x00 }; // --------- Set up stream to read the asn.1 encoded SubjectPublicKeyInfo blob ------ using (var mem = new MemoryStream(x509Key)) { using (var binr = new BinaryReader(mem)) //wrap Memory Stream with BinaryReader for easy reading { try { var twobytes = binr.ReadUInt16(); switch (twobytes) { case 0x8130: binr.ReadByte(); //advance 1 byte break; case 0x8230: binr.ReadInt16(); //advance 2 bytes break; default: return null; } var seq = binr.ReadBytes(15); if (!CompareBytearrays(seq, seqOid)) //make sure Sequence for OID is correct return null; twobytes = binr.ReadUInt16(); if (twobytes == 0x8103) //data read as little endian order (actual data order for Bit String is 03 81) binr.ReadByte(); //advance 1 byte else if (twobytes == 0x8203) binr.ReadInt16(); //advance 2 bytes else return null; var bt = binr.ReadByte(); if (bt != 0x00) //expect null byte next return null; twobytes = binr.ReadUInt16(); if (twobytes == 0x8130) //data read as little endian order (actual data order for Sequence is 30 81) binr.ReadByte(); //advance 1 byte else if (twobytes == 0x8230) binr.ReadInt16(); //advance 2 bytes else return null; twobytes = binr.ReadUInt16(); byte lowbyte = 0x00; byte highbyte = 0x00; if (twobytes == 0x8102) //data read as little endian order (actual data order for Integer is 02 81) lowbyte = binr.ReadByte(); // read next bytes which is bytes in modulus else if (twobytes == 0x8202) { highbyte = binr.ReadByte(); //advance 2 bytes lowbyte = binr.ReadByte(); } else return null; byte[] modint = { lowbyte, highbyte, 0x00, 0x00 }; //reverse byte order since asn.1 key uses big endian order int modsize = BitConverter.ToInt32(modint, 0); byte firstbyte = binr.ReadByte(); binr.BaseStream.Seek(-1, SeekOrigin.Current); if (firstbyte == 0x00) { //if first byte (highest order) of modulus is zero, don't include it binr.ReadByte(); //skip this null byte modsize -= 1; //reduce modulus buffer size by 1 } byte[] modulus = binr.ReadBytes(modsize); //read the modulus bytes if (binr.ReadByte() != 0x02) //expect an Integer for the exponent data return null; int expbytes = binr.ReadByte(); // should only need one byte for actual exponent data (for all useful values) byte[] exponent = binr.ReadBytes(expbytes); // We don't really need to print anything but if we insist to... //showBytes("\nExponent", exponent); //showBytes("\nModulus", modulus); // ------- create RSACryptoServiceProvider instance and initialize with public key ----- RSACryptoServiceProvider rsa = new RSACryptoServiceProvider(); RSAParameters rsaKeyInfo = new RSAParameters { Modulus = modulus, Exponent = exponent }; rsa.ImportParameters(rsaKeyInfo); return rsa; } catch (Exception) { return null; } } } } //------- Parses binary ans.1 RSA private key; returns RSACryptoServiceProvider --- static RSACryptoServiceProvider DecodeRSAPrivateKey( byte[] privkey ) { byte[] MODULUS, E, D, P, Q, DP, DQ, IQ; // --------- Set up stream to decode the asn.1 encoded RSA private key ------ MemoryStream mem = new MemoryStream( privkey ); BinaryReader binr = new BinaryReader( mem ); //wrap Memory Stream with BinaryReader for easy reading byte bt = 0; ushort twobytes = 0; int elems = 0; try { twobytes = binr.ReadUInt16(); if (twobytes == 0x8130) //data read as little endian order (actual data order for Sequence is 30 81) binr.ReadByte(); //advance 1 byte else if (twobytes == 0x8230) binr.ReadInt16(); //advance 2 bytes else return null; twobytes = binr.ReadUInt16(); if (twobytes != 0x0102) //version number return null; bt = binr.ReadByte(); if (bt != 0x00) return null; //------ all private key components are Integer sequences ---- elems = GetIntegerSize( binr ); MODULUS = binr.ReadBytes( elems ); elems = GetIntegerSize( binr ); E = binr.ReadBytes( elems ); elems = GetIntegerSize( binr ); D = binr.ReadBytes( elems ); elems = GetIntegerSize( binr ); P = binr.ReadBytes( elems ); elems = GetIntegerSize( binr ); Q = binr.ReadBytes( elems ); elems = GetIntegerSize( binr ); DP = binr.ReadBytes( elems ); elems = GetIntegerSize( binr ); DQ = binr.ReadBytes( elems ); elems = GetIntegerSize( binr ); IQ = binr.ReadBytes( elems ); Console.WriteLine( "showing components .." ); if (verbose) { showBytes( "\nModulus", MODULUS ); showBytes( "\nExponent", E ); showBytes( "\nD", D ); showBytes( "\nP", P ); showBytes( "\nQ", Q ); showBytes( "\nDP", DP ); showBytes( "\nDQ", DQ ); showBytes( "\nIQ", IQ ); } // ------- create RSACryptoServiceProvider instance and initialize with public key ----- RSACryptoServiceProvider RSA = new RSACryptoServiceProvider(); RSAParameters RSAparams = new RSAParameters(); RSAparams.Modulus = MODULUS; RSAparams.Exponent = E; RSAparams.D = D; RSAparams.P = P; RSAparams.Q = Q; RSAparams.DP = DP; RSAparams.DQ = DQ; RSAparams.InverseQ = IQ; RSA.ImportParameters( RSAparams ); return RSA; } catch (Exception) { return null; } finally { binr.Close(); } } private static int GetIntegerSize( BinaryReader binr ) { byte bt = 0; byte lowbyte = 0x00; byte highbyte = 0x00; int count = 0; bt = binr.ReadByte(); if (bt != 0x02) //expect integer return 0; bt = binr.ReadByte(); if (bt == 0x81) count = binr.ReadByte(); // data size in next byte else if (bt == 0x82) { highbyte = binr.ReadByte(); // data size in next 2 bytes lowbyte = binr.ReadByte(); byte[] modint = { lowbyte, highbyte, 0x00, 0x00 }; count = BitConverter.ToInt32( modint, 0 ); } else { count = bt; // we already have the data size } while (binr.ReadByte() == 0x00) { //remove high order zeros in data count -= 1; } binr.BaseStream.Seek( -1, SeekOrigin.Current ); //last ReadByte wasn't a removed zero, so back up a byte return count; } //----- Get the binary RSA PRIVATE key, decrypting if necessary ---- static byte[] DecodeOpenSSLPrivateKey( String instr ) { const String pemprivheader = "-----BEGIN RSA PRIVATE KEY-----"; const String pemprivfooter = "-----END RSA PRIVATE KEY-----"; String pemstr = instr.Trim(); byte[] binkey; if (!pemstr.StartsWith( pemprivheader ) || !pemstr.EndsWith( pemprivfooter )) return null; StringBuilder sb = new StringBuilder( pemstr ); sb.Replace( pemprivheader, "" ); //remove headers/footers, if present sb.Replace( pemprivfooter, "" ); String pvkstr = sb.ToString().Trim(); //get string after removing leading/trailing whitespace try { // if there are no PEM encryption info lines, this is an UNencrypted PEM private key binkey = Convert.FromBase64String( pvkstr ); return binkey; } catch (System.FormatException) { //if can't b64 decode, it must be an encrypted private key //Console.WriteLine("Not an unencrypted OpenSSL PEM private key"); } StringReader str = new StringReader( pvkstr ); //-------- read PEM encryption info. lines and extract salt ----- if (!str.ReadLine().StartsWith( "Proc-Type: 4,ENCRYPTED" )) return null; String saltline = str.ReadLine(); if (!saltline.StartsWith( "DEK-Info: DES-EDE3-CBC," )) return null; String saltstr = saltline.Substring( saltline.IndexOf( "," ) + 1 ).Trim(); byte[] salt = new byte[saltstr.Length / 2]; for (int i = 0; i < salt.Length; i++) salt[i] = Convert.ToByte( saltstr.Substring( i * 2, 2 ), 16 ); if (!(str.ReadLine() == "")) return null; //------ remaining b64 data is encrypted RSA key ---- String encryptedstr = str.ReadToEnd(); try { //should have b64 encrypted RSA key now binkey = Convert.FromBase64String( encryptedstr ); } catch (System.FormatException) { // bad b64 data. return null; } //------ Get the 3DES 24 byte key using PDK used by OpenSSL ---- SecureString despswd = GetSecPswd( "Enter password to derive 3DES key==>" ); //Console.Write("\nEnter password to derive 3DES key: "); //String pswd = Console.ReadLine(); byte[] deskey = GetOpenSSL3deskey( salt, despswd, 1, 2 ); // count=1 (for OpenSSL implementation); 2 iterations to get at least 24 bytes if (deskey == null) return null; //showBytes("3DES key", deskey) ; //------ Decrypt the encrypted 3des-encrypted RSA private key ------ byte[] rsakey = DecryptKey( binkey, deskey, salt ); //OpenSSL uses salt value in PEM header also as 3DES IV if (rsakey != null) return rsakey; //we have a decrypted RSA private key else { Console.WriteLine( "Failed to decrypt RSA private key; probably wrong password." ); return null; } } // ----- Decrypt the 3DES encrypted RSA private key ---------- static byte[] DecryptKey( byte[] cipherData, byte[] desKey, byte[] IV ) { MemoryStream memst = new MemoryStream(); TripleDES alg = TripleDES.Create(); alg.Key = desKey; alg.IV = IV; try { CryptoStream cs = new CryptoStream( memst, alg.CreateDecryptor(), CryptoStreamMode.Write ); cs.Write( cipherData, 0, cipherData.Length ); cs.Close(); } catch (Exception exc) { Console.WriteLine( exc.Message ); return null; } byte[] decryptedData = memst.ToArray(); return decryptedData; } //----- OpenSSL PBKD uses only one hash cycle (count); miter is number of iterations required to build sufficient bytes --- static byte[] GetOpenSSL3deskey( byte[] salt, SecureString secpswd, int count, int miter ) { IntPtr unmanagedPswd = IntPtr.Zero; int HASHLENGTH = 16; //MD5 bytes byte[] keymaterial = new byte[HASHLENGTH * miter]; //to store contatenated Mi hashed results byte[] psbytes = new byte[secpswd.Length]; unmanagedPswd = Marshal.SecureStringToGlobalAllocAnsi( secpswd ); Marshal.Copy( unmanagedPswd, psbytes, 0, psbytes.Length ); Marshal.ZeroFreeGlobalAllocAnsi( unmanagedPswd ); //UTF8Encoding utf8 = new UTF8Encoding(); //byte[] psbytes = utf8.GetBytes(pswd); // --- contatenate salt and pswd bytes into fixed data array --- byte[] data00 = new byte[psbytes.Length + salt.Length]; Array.Copy( psbytes, data00, psbytes.Length ); //copy the pswd bytes Array.Copy( salt, 0, data00, psbytes.Length, salt.Length ); //concatenate the salt bytes // ---- do multi-hashing and contatenate results D1, D2 ... into keymaterial bytes ---- MD5 md5 = new MD5CryptoServiceProvider(); byte[] result = null; byte[] hashtarget = new byte[HASHLENGTH + data00.Length]; //fixed length initial hashtarget for (int j = 0; j < miter; j++) { // ---- Now hash consecutively for count times ------ if (j == 0) result = data00; //initialize else { Array.Copy( result, hashtarget, result.Length ); Array.Copy( data00, 0, hashtarget, result.Length, data00.Length ); result = hashtarget; //Console.WriteLine("Updated new initial hash target:") ; //showBytes(result) ; } for (int i = 0; i < count; i++) result = md5.ComputeHash( result ); Array.Copy( result, 0, keymaterial, j * HASHLENGTH, result.Length ); //contatenate to keymaterial } //showBytes("Final key material", keymaterial); byte[] deskey = new byte[24]; Array.Copy( keymaterial, deskey, deskey.Length ); Array.Clear( psbytes, 0, psbytes.Length ); Array.Clear( data00, 0, data00.Length ); Array.Clear( result, 0, result.Length ); Array.Clear( hashtarget, 0, hashtarget.Length ); Array.Clear( keymaterial, 0, keymaterial.Length ); return deskey; } static SecureString GetSecPswd( String prompt ) { SecureString password = new SecureString(); Console.ForegroundColor = ConsoleColor.Gray; Console.Write( prompt ); Console.ForegroundColor = ConsoleColor.Magenta; while (true) { ConsoleKeyInfo cki = Console.ReadKey( true ); if (cki.Key == ConsoleKey.Enter) { Console.ForegroundColor = ConsoleColor.Gray; Console.WriteLine(); return password; } else if (cki.Key == ConsoleKey.Backspace) { // remove the last asterisk from the screen... if (password.Length > 0) { Console.SetCursorPosition( Console.CursorLeft - 1, Console.CursorTop ); Console.Write( " " ); Console.SetCursorPosition( Console.CursorLeft - 1, Console.CursorTop ); password.RemoveAt( password.Length - 1 ); } } else if (cki.Key == ConsoleKey.Escape) { Console.ForegroundColor = ConsoleColor.Gray; Console.WriteLine(); return password; } else if (Char.IsLetterOrDigit( cki.KeyChar ) || Char.IsSymbol( cki.KeyChar )) { if (password.Length < 20) { password.AppendChar( cki.KeyChar ); Console.Write( "*" ); } else { Console.Beep(); } } else { Console.Beep(); } } } static bool CompareBytearrays( byte[] a, byte[] b ) { if (a.Length != b.Length) return false; int i = 0; foreach (byte c in a) { if (c != b[i]) return false; i++; } return true; } static void showBytes( String info, byte[] data ) { Console.WriteLine( "{0} [{1} bytes]", info, data.Length ); for (int i = 1; i <= data.Length; i++) { Console.Write( "{0:X2} ", data[i - 1] ); if (i % 16 == 0) Console.WriteLine(); } Console.WriteLine( "\n\n" ); } } 

    Sprechen Sie über Zertifikate, die in einer Datei gespeichert sind?

    Wenn Sie ein Objekt haben wie:

     X509Certificate2 certificate; 

    Sie können folgenden Code verwenden:

     RSACryptoServiceProvider rsaprovider = (RSACryptoServiceProvider)certificate.PublicKey.Key; 

    Verwenden Sie dann die class RSACryptoServiceProvider (siehe http://msdn.microsoft.com/en-us/library/system.security.cryptography.rsacrptoserviceprovider.aspx ).

    Um ein X509Certificate2 zu laden, verwenden Sie seinen Konstruktor (siehe http://msdn.microsoft.com/en-us/library/system.security.cryptography.x509certificates.x509certificate2.aspx ).

    Dieses Programm funktioniert gut für mich:

      static void Main(string[] args) { try { X509Certificate2 certificate = new X509Certificate2(""); RSACryptoServiceProvider rsaprovider = (RSACryptoServiceProvider)certificate.PublicKey.Key; } catch(Exception e) { } } 

    Wenn Sie über ein X509-Zertifikat sprechen:

     FileStream fs = new FileStream("your_cert_file.crt", FileMode.Open); byte[] certBytes = new byte[fs.Length]; fs.Read(certBytes, 0, (Int32)fs.Length); fs.Close(); System.Security.Cryptography.X509Certificates.X509Certificate x509cert = new X509Certificate(certBytes); Console.WriteLine(x509cert.GetPublicKey()); Console.WriteLine(x509cert.GetPublicKeyString()); 

    BEARBEITET nach dem Kommentar von @hkproj in “7/16/2012 15:04:58 Z” gemacht:

    Als ich mich hier umsah, fand ich ” Lesen von PEM RSA Public Key nur mit Hüpfburg “. Ich denke, was du willst ist das:

     using (StreamReader reader = File.OpenText(@"c:\RSA.txt")) { Org.BouncyCastle.OpenSsl.PemReader pr = new Org.BouncyCastle.OpenSsl.PemReader(reader); Org.BouncyCastle.Utilities.IO.Pem.PemObject po = pr.ReadPemObject(); Console.WriteLine("PemObject, Type: " + po.Type); Console.WriteLine("PemObject, Length: " + po.Content.Length); } 

    Mit Ihrer Datei erhalte ich jedoch einen Fehler: System.IO.IOException : base64 data appears to be truncated .

    Also ändere deine Datei in etwas wie:

     -----BEGIN PUBLIC KEY----- XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX/syEKqEkMtQL0+d XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX+izR KbGMRtur2TYklnyVkjeeHfAggo8vWQmWesnOG55vQYHbOOFoJbk0EkwEr5R/PbKm byXPPN8zwnS5/XXXXXXXXXXXXZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZ -----END PUBLIC KEY----- 

    Das Ergebnis ist:

     PemObject, Type: PUBLIC KEY PemObject, Length: 192