Classic ASP
Classic ASP
Diffie-Hellman Key Exchange (DH)
See more Diffie-Hellman Examples
Diffie-Hellman key exchange (DH) is a cryptographic protocol that allows two parties that have no prior knowledge of each other to jointly establish a shared secret key.This example demonstrates how two parties (Alice and Bob) can compute an N-bit shared secret key without the key ever being transmitted.
Chilkat Classic ASP Downloads
<html>
<head>
<meta http-equiv="Content-Type" content="text/html; charset=utf-8">
</head>
<body>
<%
success = 0
' This example requires the Chilkat API to have been previously unlocked.
' See Global Unlock Sample for sample code.
' Create two separate instances of the DH object.
set dhBob = Server.CreateObject("Chilkat.Dh")
set dhAlice = Server.CreateObject("Chilkat.Dh")
' The DH algorithm begins with a large prime, P, and a generator, G.
' These don't have to be secret, and they may be transmitted over an insecure channel.
' The generator is a small integer and typically has the value 2 or 5.
' The Chilkat DH component provides the ability to use known
' "safe" primes, as well as a method to generate new safe primes.
' This example will use a known safe prime. Generating
' new safe primes is a time-consuming CPU intensive task
' and is normally done offline.
' Bob will choose to use the 2nd of our 8 pre-chosen safe primes.
' It is the Prime for the 2nd Oakley Group (RFC 2409) --
' 1024-bit MODP Group. Generator is 2.
' The prime is: 2^1024 - 2^960 - 1 + 2^64 * { [2^894 pi] + 129093 }
dhBob.UseKnownPrime 2
' The computed shared secret will be equal to the size of the prime (in bits).
' In this case the prime is 1024 bits, so the shared secret will be 128 bytes (128 * 8 = 1024).
' However, the result is returned as an SSH1-encoded bignum in hex string format.
' The SSH1-encoding prepends a 2-byte count, so the result is going to be 2 bytes
' longer: 130 bytes. This results in a hex string that is 260 characters long (two chars
' per byte for the hex encoding).
' Bob will now send P and G to Alice.
p = dhBob.P
g = dhBob.G
' Alice calls SetPG to set P and G. SetPG checks
' the values to make sure it's a safe prime and will
' return 0 if not.
success = dhAlice.SetPG(p,g)
If (success <> 1) Then
Response.Write "<pre>" & Server.HTMLEncode( "P is not a safe prime") & "</pre>"
Response.End
End If
' Each side begins by generating an "E"
' value. The CreateE method has one argument: numBits.
' It should be set to twice the size of the number of bits
' in the session key.
' Let's say we want to generate a 128-bit session key
' for AES encryption. The shared secret generated by the Diffie-Hellman
' algorithm will be longer, so we'll hash the result to arrive at the
' desired session key length. However, the length of the session
' key we'll utlimately produce determines the value that should be
' passed to the CreateE method.
' In this case, we'll be creating a 128-bit session key, so pass 256 to CreateE.
' This setting is for security purposes only -- the value
' passed to CreateE does not change the length of the shared secret
' that is produced by Diffie-Hellman.
' Also, there is no need to pass in a value larger
' than 2 times the expected session key length. It suffices to
' pass exactly 2 times the session key length.
' Bob generates a random E (which has the mathematical
' properties required for DH).
eBob = dhBob.CreateE(256)
' Alice does the same:
eAlice = dhAlice.CreateE(256)
' The "E" values are sent over the insecure channel.
' Bob sends his "E" to Alice, and Alice sends her "E" to Bob.
' Each side computes the shared secret by calling FindK.
' "K" is the shared-secret.
' Bob computes the shared secret from Alice's "E":
kBob = dhBob.FindK(eAlice)
' Alice computes the shared secret from Bob's "E":
kAlice = dhAlice.FindK(eBob)
' Amazingly, kBob and kAlice are identical and the expected
' length (260 characters). The strings contain the hex encoded bytes of
' our shared secret:
Response.Write "<pre>" & Server.HTMLEncode( "Bob's shared secret:") & "</pre>"
Response.Write "<pre>" & Server.HTMLEncode( kBob) & "</pre>"
Response.Write "<pre>" & Server.HTMLEncode( "Alice's shared secret (should be equal to Bob's)") & "</pre>"
Response.Write "<pre>" & Server.HTMLEncode( kAlice) & "</pre>"
' To arrive at a 128-bit session key for AES encryption, Bob and Alice should
' both transform the raw shared secret using a hash algorithm that produces
' the size of session key desired. MD5 produces a 16-byte (128-bit) result, so
' this is a good choice for 128-bit AES.
' To produce the session key:
set crypt = Server.CreateObject("Chilkat.Crypt2")
crypt.EncodingMode = "hex"
crypt.HashAlgorithm = "md5"
sessionKey = crypt.HashStringENC(kBob)
Response.Write "<pre>" & Server.HTMLEncode( "128-bit Session Key:") & "</pre>"
Response.Write "<pre>" & Server.HTMLEncode( sessionKey) & "</pre>"
' Encrypt something...
crypt.CryptAlgorithm = "aes"
crypt.KeyLength = 128
crypt.CipherMode = "cbc"
' Use an IV that is the MD5 hash of the session key...
iv = crypt.HashStringENC(sessionKey)
' AES uses a 16-byte IV:
Response.Write "<pre>" & Server.HTMLEncode( "Initialization Vector:") & "</pre>"
Response.Write "<pre>" & Server.HTMLEncode( iv) & "</pre>"
crypt.SetEncodedKey sessionKey,"hex"
crypt.SetEncodedIV iv,"hex"
' Encrypt some text:
crypt.EncodingMode = "base64"
cipherText64 = crypt.EncryptStringENC("The quick brown fox jumps over the lazy dog")
Response.Write "<pre>" & Server.HTMLEncode( cipherText64) & "</pre>"
plainText = crypt.DecryptStringENC(cipherText64)
Response.Write "<pre>" & Server.HTMLEncode( plainText) & "</pre>"
%>
</body>
</html>