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Delphi ActiveX Examples

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(Delphi ActiveX) Generate Encryption Key

Discusses symmetric encryption key generation techniques for block encryption algorithms such as AES, Blowfish, and Twofish, or for other algorithms such as ChaCha20.

Chilkat for Delphi Downloads

Chilkat ActiveX DLL for Delphi

Chilkat non-ActiveX DLL for Delphi

* The examples here use the ActiveX DLL.

uses
    Winapi.Windows, Winapi.Messages, System.SysUtils, System.Variants, System.Classes, Vcl.Graphics,
    Vcl.Controls, Vcl.Forms, Vcl.Dialogs, Vcl.StdCtrls, Chilkat_TLB;

...

procedure TForm1.Button1Click(Sender: TObject);
var
success: Integer;
crypt: TChilkatCrypt2;
prng: TChilkatPrng;
secretKeyHex: WideString;

begin
// Symmetric encryption algorithms are such that the encryptor and decryptor
// share a pre-known secret key.  This could be a "single-use" key that is 
// derived from a secure key exchange algorithm using RSA, ECC, or Diffie-Hellman,
// or it could be a password known to both sides, or
// it could simply be the binary bytes of the secret key known in advance on both
// sides.

// A secret key has no structure.  It's nothing more than N bytes of data.
// It should typically be random data, or bytes that resemble random data such
// as the hash of a password.

// The number of bytes in the secret key defines the bit-strength of an encryption
// algorithm.  For example, AES with a 32-byte key is 256-bit AES.  Most algorithms
// define restrictions on key sizes.  For example, AES has 3 choices: 128-bit, 192-bit,
// or 256-bit.  In the ChaCha20 algorithm, the key size must always be 256-bits (32-bytes).

// Both sides (encryptor and decryptor) must be in possession of the same secret key
// in order to communicate.   Whichever side generates the key, it must somehow
// deliver the key to the other side beforehand.  Key exchange algorithms, such as RSA, ECC,
// and Diffie-Hellman define secure ways of exchanging symmetric encryption keys.
// They do so using asymmetric encryption algorithms (public/private keys).  It is not
// required to use a key exchange algorithm to achieve the goal of having both sides
// in possession of the same secret key.  A long-living secret key could be exchanged
// via any secure out-of-band means.  For example, exchanging the information over a secure
// TLS (HTTPS) or SSH connection...

// This example assumes the Chilkat API to have been previously unlocked.
// See Global Unlock Sample for sample code.

crypt := TChilkatCrypt2.Create(Self);
crypt.CryptAlgorithm := 'aes';
crypt.KeyLength := 256;

// Generate a 32-byte random secret key,
// and use it in the crypt object.
prng := TChilkatPrng.Create(Self);
secretKeyHex := prng.GenRandom(32,'hex');
// It is important that the number of bytes in the secret key
// matches the value specified in the KeyLength property (above).
crypt.SetEncodedKey(secretKeyHex,'hex');
Memo1.Lines.Add('randomly generated key: ' + secretKeyHex);

// Alternatively, a password could be hashed using a hash algorithm
// the results in the desired key length.  Our desired key length
// in this case is 32 bytes, so we wouldn't want MD5 (16 bytes),
// nor would we want to use SHA-1 (20 bytes).  SHA256 would be the
// hash of choice because it results in 32-bytes of random-looking
// key material.
crypt.HashAlgorithm := 'SHA256';
crypt.EncodingMode := 'hex';
secretKeyHex := crypt.HashStringENC('mypassword');
crypt.SetEncodedKey(secretKeyHex,'hex');
Memo1.Lines.Add('password-based key: ' + secretKeyHex);
end;

 

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