Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I'm a little bit confused how to use AES and HMAC (based on SHA-256) in a proper way when transmitting the encrypted message from server to client or vice versa

Correct me please if the following method is wrong:

  1. Take the secure key from the key file (for example we suggest to use the AES-256 and we already have a valid 256 bit length key)
  2. Generate random IV for AES-256 to be sure that the same plain text will have different encryption output.
  3. Calculate HMAC-SHA-256 using the plain text and secure key. (The first question: should I use IV for HMAC calculation? For example append to secure key?)
  4. Encrypt the plain text using AES-256.
  5. Compose message for client as following: HMAC + IV+ ENCRYPTED_MESSAGE

The biggest question is: is it possible somehow not to send IV to client but instead generate it the same way and still be crypto safe? Or is it ok to send the IV too?

I've end up with random IV generation, because it is needed that the same plain text will end up in different encryption results.

share|improve this question

2 Answers 2

up vote 7 down vote accepted

Don't send hmac(message),aes(message). If you send the same message twice, anyone can tell. Moreover, you need to mac the cipher-text to prevent attacks such as the padding oracle attack.

IV: In general, the easy way to deal with the iv is to prepend it, since it's fixed length, to the cipher text.You can then just read off those bytes before decrypting. IV's can be public, but they must be random.

HMAC: Easiest way, if your library supports it, is to use AES in GCM mode (or, less preferably EAX). This is not actually an HMAC, but it provides authenticated encryption which is just as good.If these are not supported :

You do need to compute the hmac over both the iv and the cipher text. if || is concatenation ( which you could do with say array copy if dealing with byte arrays) then you want

CipherText = iv|| aes(key1,iv,message)  
tag = hmac(key2,ciphertext)

And then send (tag,CipherText). On the other end, you run the same hmac call to regenerate the tag and the compare the received tag with the computed one. Compare the sha1 or sha256 hashes of the tags instead of directly so you don't leak where the comparison fails.

You should use a different key for the hmac. In practice tacking the sha1 sum of your encryption key is good enough.

share|improve this answer
    
And what operation mode would you recommend? CBC has its overhead and we should deal with padding. I think my choice ic OFB/CFB. –  Valentin Apr 30 '12 at 12:05
    
From a security point of view,they are all the same (except ECB, don't use that). Just make sure you use a fresh IV if the system takes an IV. If you want to save yourself some effort, there are authenticated modes which do not need an hmac. GCM is the best of them. What language are you using ? –  imichaelmiers Apr 30 '12 at 15:20
    
I wouldn’t recommend taking the SHA1 sum of the first key as the second key. Instead you can derive two different keys with different parameters and PBKDF2 from a passphrase. The best thing is to have two independent keys and not to rely upon a (probably) weak passphrase. –  Rafael May 17 '12 at 9:18
    
@Rafael Why would you advise against taking the SHA1 sum of the first key? I know that it would seem to have some relation there, but is there any specific reason why that's bad? Also, why do you require two separate keys, one for the AES and one for the HMAC? I can see that it might be dangerous, but any specific references on this one? –  Matt Mc Jul 19 '13 at 4:51

C# code for AES HMAC

using System;
using System.Collections.Generic;
using System.IO;
using System.Linq;
using System.Security.Cryptography;
using System.Text;
using System.Threading.Tasks;

namespace CryptoTests.Ciphers
{
    public class AesHmac : IEncryptor
    {
        private readonly RandomNumberGenerator Random = RandomNumberGenerator.Create();

        //Preconfigured Encryption Parameters
        private readonly int BlockBitSize = 128;
        private byte[] cryptoKey;
        private byte[] authKey;
        private CryptoTests.Ciphers.Aes aes;

        public string GetName()
        {
            string name;
            if (cryptoKey!=null)
                name = String.Format("AES{0}-HMACSHA256", (cryptoKey.Length * 8));
            else
                name = String.Format("AES-HMACSHA256");
            return name;
        }

        public void Init(byte[] cryptoKey)
        {

            this.cryptoKey = cryptoKey;
            this.authKey = cryptoKey; // we're using the same key for the hmac hmac
            aes = new CryptoTests.Ciphers.Aes();
            aes.Init(cryptoKey);
        }

        // encrypted = LSByte [ AddtnlAuthData || IV || cipher || hmac ] MSByte
        public byte[] Encrypt(byte[] secretMessage, byte[] iv = null, byte[] AddtnlAuthData = null)
        {
            if (iv != null)
                throw new Exception("AesHmac generates IV internally, set IV to null in Init");

            //Assemble encrypted message and add authentication
            using (var hmacSha256 = new HMACSHA256(authKey))
            using (var encryptedStream = new MemoryStream())
            {
                using (var binaryWriter = new BinaryWriter(encryptedStream))
                {
                    // Encrypt message using AES
                    var ivCipherText = aes.Encrypt(secretMessage, iv, AddtnlAuthData);

                    //Write IV + Ciphertext
                    binaryWriter.Write(ivCipherText);
                    binaryWriter.Flush();

                    //Authenticate all data
                    var hmac = hmacSha256.ComputeHash(ivCipherText);
                    //Postpend hmac
                    binaryWriter.Write(hmac);
                }
                return encryptedStream.ToArray();
            }
        }

        public byte[] Decrypt(byte[] encryptedMessage, int IVLength=0, int AddtnlAuthDataLength=0)
        {
            if (IVLength != 0)
                throw new Exception("Aes knows IVLength internally, remove or set IVLength to 0 in call");

            if (encryptedMessage == null)
                throw new ArgumentException("Encrypted Message Required!", "encryptedMessage");

            using (var hmac = new HMACSHA256(authKey))
            {
                //if message length is to small just return null
                var ivLength = (BlockBitSize / 8);
                var sentHmac = new byte[hmac.HashSize / 8];
                if (encryptedMessage.Length < sentHmac.Length + AddtnlAuthDataLength + ivLength)
                    return null;

                // 1. Authenticate data
                var calcTag = hmac.ComputeHash(encryptedMessage, 0, encryptedMessage.Length - sentHmac.Length);
                //    Grab Sent hmac
                Array.Copy(encryptedMessage, encryptedMessage.Length - sentHmac.Length, sentHmac, 0, sentHmac.Length);
                //    Compare hmac with Constant time comparison
                var auth = true;
                for (var i = 0; i < sentHmac.Length; i++)
                    auth = auth & sentHmac[i] == calcTag[i]; //uses non-shortcircuit and (&)
                //    if message doesn't authenticate return null
                if (!auth)
                    return null;

                // 2. Decrypt encrypted message after stripping off HMAC
                // encrypted = LSByte [ AddtnlAuthData || IV || cipher || hmac ] MSByte
                long msgIvLen = encryptedMessage.Length - sentHmac.Length;
                var encMsgNoHmac = new byte[msgIvLen];
                Array.Copy(encryptedMessage, encMsgNoHmac, msgIvLen);
                return aes.Decrypt(encMsgNoHmac, 0, AddtnlAuthDataLength);
            }
        }
    }
}

AES class

using System;
using System.Collections.Generic;
using System.IO;
using System.Linq;
using System.Security.Cryptography;
using System.Text;
using System.Threading.Tasks;

namespace CryptoTests.Ciphers
{
    public class Aes : IEncryptor
    {
        private readonly RandomNumberGenerator Random = RandomNumberGenerator.Create();

        private int BlockBitSize = 128;
        private byte[] aesKey;

        public string GetName()
        {
            string name;
            if (aesKey != null)
                name = String.Format("AES{0}", (aesKey.Length * 8));
            else
                name = String.Format("AES");
            return name;
        }

        public void Init(byte[] cryptoKey)
        {
            this.aesKey = cryptoKey;
        }

        // encrypted = LSByte [ AddtnlAuthData || IV || cipher ] MSByte
        //             WARNING: AddtnlAuthData is NOT authenticated in plain AES!!
        public byte[] Encrypt(byte[] secretMessage, byte[] iv = null, byte[] AddtnlAuthData = null)
        {
            if (iv != null)
                throw new Exception("Aes generates IV internally, set IV to null");

            if (secretMessage == null)
                throw new ArgumentException("Secret Message Required!", "secretMessage");

            //non-secret payload optional
            AddtnlAuthData = AddtnlAuthData ?? new byte[] { };

            byte[] cipherText;
            byte[] IV;

            using (var aes = new AesManaged
            {
                KeySize = (aesKey.Length*8),
                BlockSize = BlockBitSize,
                Mode = CipherMode.CBC,
                Padding = PaddingMode.PKCS7
            })
            {

                ////Use random IV
                //aes.GenerateIV();
                IV = aes.IV;

                using (var encrypter = aes.CreateEncryptor(aesKey, aes.IV))
                using (var cipherStream = new MemoryStream())
                {
                    using (var tCryptoStream = new CryptoStream(cipherStream, encrypter, CryptoStreamMode.Write))
                    using (var tBinaryWriter = new BinaryWriter(tCryptoStream))
                    {
                        //Encrypt Data
                        tBinaryWriter.Write(secretMessage);
                    }

                    cipherText = cipherStream.ToArray();
                }
            }

            //Assemble encrypted message + IV
            using (var encryptedStream = new MemoryStream())
            {
                using (var binaryWriter = new BinaryWriter(encryptedStream))
                {
                    //Prepend non-secret payload if any
                    binaryWriter.Write(AddtnlAuthData);
                    //Prepend IV
                    binaryWriter.Write(IV);
                    //Write Ciphertext
                    binaryWriter.Write(cipherText);
                    binaryWriter.Flush();
                }
                return encryptedStream.ToArray();
            }
        }

        public byte[] Decrypt(byte[] message, int IVLength=0, int AddtnlAuthDataLength = 0)
        {
            if (IVLength != 0)
                throw new Exception("Aes knows IVLength internally, remove or set IVLength to 0 in call");

            if (message == null)
                throw new ArgumentException("Encrypted Message Required!", "encryptedMessage");

            using (var aes = new AesManaged
            {
                KeySize = (aesKey.Length * 8),
                BlockSize = BlockBitSize,
                Mode = CipherMode.CBC,
                Padding = PaddingMode.PKCS7
            })
            {
                var ivLength = (BlockBitSize / 8);

                //Grab IV from message
                var iv = new byte[ivLength];
                Array.Copy(message, AddtnlAuthDataLength, iv, 0, iv.Length);

                using (var decrypter = aes.CreateDecryptor(aesKey, iv))
                using (var plainTextStream = new MemoryStream())
                {
                    using (var decrypterStream = new CryptoStream(plainTextStream, decrypter, CryptoStreamMode.Write))
                    using (var binaryWriter = new BinaryWriter(decrypterStream))
                    {
                        //Decrypt Cipher Text from Message
                        binaryWriter.Write(
                            message,
                            AddtnlAuthDataLength + iv.Length,
                            message.Length - AddtnlAuthDataLength - iv.Length
                        );
                    }
                    //Return Plain Text
                    return plainTextStream.ToArray();
                }
            }
        } // end of Decrypt
    }
}
share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.