Tag Archive for: PEM

Convert RSA public/private key from XML to PEM format (.NET) (Part 2)

In my previous post I’ve shown how to convert the public key of an XML formatted RSA key to the more widely used PEM format. The only limitation of the solution was that since it utilizes the Cryptographic Next Generation (CNG) algorithms it is usable only on Windows 7 and Windows Server 2008 R2.

So bellow I’ll demonstrate a solution that works under all operating systems. Also as an extra the solution bellow can convert the private key as well 😉 Both the public and the private keys exported by the functions bellow are parsed by OpenSSL!

You can find the compiled source here.

Enjoy!

C#

private static byte[] RSA_OID = 
{ 0x30, 0xD, 0x6, 0x9, 0x2A, 0x86, 0x48, 0x86, 0xF7, 0xD, 0x1, 0x1, 0x1, 0x5, 0x0 }; // Object ID for RSA

// Corresponding ASN identification bytes
const byte INTEGER = 0x2;
const byte SEQUENCE = 0x30;
const byte BIT_STRING = 0x3;
const byte OCTET_STRING = 0x4;

private static string ConvertPublicKey(RSAParameters param)
{
    List<byte> arrBinaryPublicKey = new List<byte>();

    arrBinaryPublicKey.InsertRange(0, param.Exponent);
    arrBinaryPublicKey.Insert(0, (byte)arrBinaryPublicKey.Count);
    arrBinaryPublicKey.Insert(0, INTEGER);

    arrBinaryPublicKey.InsertRange(0, param.Modulus);
    AppendLength(ref arrBinaryPublicKey, param.Modulus.Length);
    arrBinaryPublicKey.Insert(0, INTEGER);

    AppendLength(ref arrBinaryPublicKey, arrBinaryPublicKey.Count);
    arrBinaryPublicKey.Insert(0, SEQUENCE);

    arrBinaryPublicKey.Insert(0, 0x0); // Add NULL value

    AppendLength(ref arrBinaryPublicKey, arrBinaryPublicKey.Count);

    arrBinaryPublicKey.Insert(0, BIT_STRING);
    arrBinaryPublicKey.InsertRange(0, RSA_OID);

    AppendLength(ref arrBinaryPublicKey, arrBinaryPublicKey.Count);

    arrBinaryPublicKey.Insert(0, SEQUENCE);

    return System.Convert.ToBase64String(arrBinaryPublicKey.ToArray());
}

private static string ConvertPrivateKey(RSAParameters param)
{
    List<byte> arrBinaryPrivateKey = new List<byte>();

    arrBinaryPrivateKey.InsertRange(0, param.InverseQ);
    AppendLength(ref arrBinaryPrivateKey, param.InverseQ.Length);
    arrBinaryPrivateKey.Insert(0, INTEGER);

    arrBinaryPrivateKey.InsertRange(0, param.DQ);
    AppendLength(ref arrBinaryPrivateKey, param.DQ.Length);
    arrBinaryPrivateKey.Insert(0, INTEGER);

    arrBinaryPrivateKey.InsertRange(0, param.DP);
    AppendLength(ref arrBinaryPrivateKey, param.DP.Length);
    arrBinaryPrivateKey.Insert(0, INTEGER);

    arrBinaryPrivateKey.InsertRange(0, param.Q);
    AppendLength(ref arrBinaryPrivateKey, param.Q.Length);
    arrBinaryPrivateKey.Insert(0, INTEGER);

    arrBinaryPrivateKey.InsertRange(0, param.P);
    AppendLength(ref arrBinaryPrivateKey, param.P.Length);
    arrBinaryPrivateKey.Insert(0, INTEGER);

    arrBinaryPrivateKey.InsertRange(0, param.D);
    AppendLength(ref arrBinaryPrivateKey, param.D.Length);
    arrBinaryPrivateKey.Insert(0, INTEGER);

    arrBinaryPrivateKey.InsertRange(0, param.Exponent);
    AppendLength(ref arrBinaryPrivateKey, param.Exponent.Length);
    arrBinaryPrivateKey.Insert(0, INTEGER);

    arrBinaryPrivateKey.InsertRange(0, param.Modulus);
    AppendLength(ref arrBinaryPrivateKey, param.Modulus.Length);
    arrBinaryPrivateKey.Insert(0, INTEGER);

    arrBinaryPrivateKey.Insert(0, 0x00);
    AppendLength(ref arrBinaryPrivateKey, 1);
    arrBinaryPrivateKey.Insert(0, INTEGER);

    AppendLength(ref arrBinaryPrivateKey, arrBinaryPrivateKey.Count);
    arrBinaryPrivateKey.Insert(0, SEQUENCE);

    return System.Convert.ToBase64String(arrBinaryPrivateKey.ToArray());
}

private static void AppendLength(ref List<byte> arrBinaryData, int nLen)
{
    if (nLen <= byte.MaxValue)
    {
        arrBinaryData.Insert(0, Convert.ToByte(nLen));
        arrBinaryData.Insert(0, 0x81); //This byte means that the length fits in one byte
    }
    else
    {
        arrBinaryData.Insert(0, Convert.ToByte(nLen % (byte.MaxValue + 1)));
        arrBinaryData.Insert(0, Convert.ToByte(nLen / (byte.MaxValue + 1)));
        arrBinaryData.Insert(0, 0x82); //This byte means that the length fits in two byte
    }

}

Convert RSA public key from XML to PEM format (.NET) (Part 1)

Probably the people working with asymmetric cryptography have struggled for a way to convert the XML format of the RSA public key to the more widely used PEM format. Although there is a solution for the reverse transformation (from PEM to XML) on the following address http://www.jensign.com/opensslkey/opensslkey.cs I have not found anywhere a solution to this problem.

So after a bit of reading and examining the code in the above mentioned link I’ve come up with a small code that does the conversion and the resulting key is parsed OK from OpenSSL.

NOTE: You will need to download and use the assemblies from http://clrsecurity.codeplex.com/
NOTE2: The code bellow only works under Windows 7 and Windows Server 2008 R2, because it uses the Cryptographic Next Generation (CNG) that were added only to those operating systems.

C#:

using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
using Security.Cryptography;
using System.Security.Cryptography.X509Certificates;
using System.IO;

namespace ConsoleApplication1
{
    class Program
    {
        static void Main(string[] args)
        {
            RSACng rsa = new RSACng();
            X509Certificate2 cert;
            List<byte> arrBinaryPublicKey = new List<byte>();

            byte[] oid = 
            { 0x30, 0xD, 0x6, 0x9, 0x2A, 0x86, 0x48, 0x86, 0xF7, 0xD, 0x1, 0x1, 0x1, 0x5, 0x0 }; // Object ID for RSA

            //rsa.FromXmlString(xmlFormatedRSAKey);

            cert = rsa.Key.CreateSelfSignedCertificate(new X500DistinguishedName("CN=something"));

            //Transform the public key to PEM Base64 Format
            arrBinaryPublicKey = cert.PublicKey.EncodedKeyValue.RawData.ToList();
            arrBinaryPublicKey.Insert(0, 0x0); // Add NULL value

            CalculateAndAppendLength(ref arrBinaryPublicKey);

            arrBinaryPublicKey.Insert(0, 0x3);
            arrBinaryPublicKey.InsertRange(0, oid);

            CalculateAndAppendLength(ref arrBinaryPublicKey);

            arrBinaryPublicKey.Insert(0, 0x30);
            //End Transformation

            Console.WriteLine();
            Console.WriteLine("-----BEGIN PUBLIC KEY-----");
            Console.WriteLine(System.Convert.ToBase64String(arrBinaryPublicKey.ToArray()));
            Console.WriteLine("-----END PUBLIC KEY-----");

        }

        private static void CalculateAndAppendLength(ref List<byte> arrBinaryData)
        {
            int nLen;
            nLen = arrBinaryData.Count;
            if (nLen <= byte.MaxValue)
            {
                arrBinaryData.Insert(0, Convert.ToByte(nLen));
                arrBinaryData.Insert(0, 0x81); //This byte means that the length fits in one byte
            }
            else
            {
                arrBinaryData.Insert(0, Convert.ToByte(nLen % (byte.MaxValue + 1)));
                arrBinaryData.Insert(0, Convert.ToByte(nLen / (byte.MaxValue + 1)));
                arrBinaryData.Insert(0, 0x82); //This byte means that the length fits in two byte
            }

        }

    }
}

Compiled source available here