This site is the archived OWASP Foundation Wiki and is no longer accepting Account Requests.
To view the new OWASP Foundation website, please visit https://owasp.org

Using the Java Cryptographic Extensions

From OWASP
Revision as of 20:32, 15 November 2012 by David Abalco (talk | contribs)

Jump to: navigation, search

Note:

The code included in this article has not been reviewed and should not be used without proper analysis. If you have reviewed the included code (or portions of it), please post your findings back to this page or to: stephen [at] corsaire.com.

Overview

Java Cryptographic Extensions (JCE) is a set of Java API's which provides cryptographic services such as encryption, secret Key Generation, Message Authentication code and Key Agreement. The ciphers supported by JCE include symmetric, asymmetric, block and stream ciphers. JCE was an optional package to JDK v 1.2.x and 1.3.x. JCE has been integrated into JDK v1.4.

JCE API's are implemented by Cryptographic Service Providers. Each of these cryptographic service providers implements the Service Provider Interface which specifies the functionalities which needs to be implemented by the service providers. Programmers can plugin any Service Providers for performing cryptographic functionalities provided by JCE. J2SE comes with a default provider named SunJCE.

Symmetric Encryption Algorithms provided by SunJCE

  1. DES - default keylength of 56 bits
  2. AES -
  3. RC2, RC4 and RC5
  4. IDEA
  5. Triple DES – default keylength 112 bits
  6. Blowfish – default keylength 56 bits
  7. PBEWithMD5AndDES
  8. PBEWithHmacSHA1AndDESede
  9. DES ede

Modes of Encryption

  1. ECB
  2. CBC
  3. CFB
  4. OFB
  5. PCBC

Asymmetric Encryption Algorithms implemented by SunJCE

  1. RSA
  2. Diffie-Hellman – default keylength 1024 bits

Hashing / Message Digest Algorithms implemented by SunJCE

  1. MD5 – default size 64 bytes
  2. SHA1 - default size 64 bytes

Examples

SecureRandom

SecureRandom class is used to generate a cryptographically strong pseudo random number by using a PRNG Algorithm. The following are the advantages of using SecureRandom over Random. 1. SecureRandom produces a cryptographically strong pseudo random number generator. 2. SecureRandom produces cryptographically strong sequences as described in RFC 1750: Randomness Recommendations for Security

package org.owasp.java.crypto;

import java.security.SecureRandom;
import java.security.NoSuchAlgorithmException;

import sun.misc.BASE64Encoder;

/**
 * @author Joe Prasanna Kumar
 * This program provides the functionality for Generating a Secure Random Number.
 *  
 * There are 2 ways to generate a  Random number through SecureRandom.
 * 1. By calling nextBytes method to generate Random Bytes
 * 2. Using setSeed(byte[]) to reseed a Random object
 * 
 */


public class SecureRandomGen {

	/**
	 * @param args
	 */
	public static void main(String[] args) {
		try {
	        // Initialize a secure random number generator
	        SecureRandom secureRandom = SecureRandom.getInstance("SHA1PRNG");
	    
	        // Method 1 - Calling nextBytes method to generate Random Bytes
	        byte[] bytes = new byte[512];
	        secureRandom.nextBytes(bytes); 
	        
	        // Printing the SecureRandom number by calling secureRandom.nextDouble()
	        System.out.println(" Secure Random # generated by calling nextBytes() is " + secureRandom.nextDouble());
	    
	        // Method 2 - Using setSeed(byte[]) to reseed a Random object
	        int seedByteCount = 10;
	        byte[] seed = secureRandom.generateSeed(seedByteCount);   
	        
	        // TBR System.out.println(" Seed value is " + new BASE64Encoder().encode(seed));
	    
	        secureRandom.setSeed(seed);
	        
	        System.out.println(" Secure Random # generated using setSeed(byte[]) is  " + secureRandom.nextDouble());
	        
	    } catch (NoSuchAlgorithmException noSuchAlgo)
		{
			System.out.println(" No Such Algorithm exists " + noSuchAlgo);
		}
	}

}

AES Encryption and Decryption

package org.owasp.java.crypto;

import javax.crypto.KeyGenerator;
import javax.crypto.SecretKey;
import javax.crypto.Cipher;

import java.security.NoSuchAlgorithmException;
import java.security.InvalidKeyException;
import java.security.InvalidAlgorithmParameterException;
import javax.crypto.NoSuchPaddingException;
import javax.crypto.BadPaddingException;
import javax.crypto.IllegalBlockSizeException;

import sun.misc.BASE64Encoder;

/**
 * @author Joe Prasanna Kumar
 * This program provides the following cryptographic functionalities
 * 1. Encryption using AES
 * 2. Decryption using AES
 * 
 * High Level Algorithm :
 * 1. Generate a DES key (specify the Key size during this phase) 
 * 2. Create the Cipher 
 * 3. To Encrypt : Initialize the Cipher for Encryption
 * 4. To Decrypt : Initialize the Cipher for Decryption
 * 
 * 
 */

public class AES {
	public static void main(String[] args) {
		
		String strDataToEncrypt = new String();
		String strCipherText = new String();
		String strDecryptedText = new String();
		
		try{
		/**
		 *  Step 1. Generate an AES key using KeyGenerator
		 *  		Initialize the keysize to 128 
		 * 
		 */
		KeyGenerator keyGen = KeyGenerator.getInstance("AES");
		keyGen.init(128);
		SecretKey secretKey = keyGen.generateKey();
		
		/**
		 *  Step2. Create a Cipher by specifying the following parameters
		 * 			a. Algorithm name - here it is AES
		 */
		
		Cipher aesCipher = Cipher.getInstance("AES");
		
		/**
		 *  Step 3. Initialize the Cipher for Encryption 
		 */
		
		aesCipher.init(Cipher.ENCRYPT_MODE,secretKey);
		
		/**
		 *  Step 4. Encrypt the Data
		 *  		1. Declare / Initialize the Data. Here the data is of type String
		 *  		2. Convert the Input Text to Bytes
		 *  		3. Encrypt the bytes using doFinal method 
		 */
		strDataToEncrypt = "Hello World of Encryption using AES ";
		byte[] byteDataToEncrypt = strDataToEncrypt.getBytes();
		byte[] byteCipherText = aesCipher.doFinal(byteDataToEncrypt); 
		strCipherText = new BASE64Encoder().encode(byteCipherText);
		System.out.println("Cipher Text generated using AES is " +strCipherText);
		
		/**
		 *  Step 5. Decrypt the Data
		 *  		1. Initialize the Cipher for Decryption 
		 *  		2. Decrypt the cipher bytes using doFinal method 
		 */
		aesCipher.init(Cipher.DECRYPT_MODE,secretKey,aesCipher.getParameters());
		byte[] byteDecryptedText = aesCipher.doFinal(byteCipherText);
		strDecryptedText = new String(byteDecryptedText);
		System.out.println(" Decrypted Text message is " +strDecryptedText);
		}
		
		catch (NoSuchAlgorithmException noSuchAlgo)
		{
			System.out.println(" No Such Algorithm exists " + noSuchAlgo);
		}
		
			catch (NoSuchPaddingException noSuchPad)
			{
				System.out.println(" No Such Padding exists " + noSuchPad);
			}
		
				catch (InvalidKeyException invalidKey)
				{
					System.out.println(" Invalid Key " + invalidKey);
				}
				
				catch (BadPaddingException badPadding)
				{
					System.out.println(" Bad Padding " + badPadding);
				}
				
				catch (IllegalBlockSizeException illegalBlockSize)
				{
					System.out.println(" Illegal Block Size " + illegalBlockSize);
				}
				
				catch (InvalidAlgorithmParameterException invalidParam)
				{
					System.out.println(" Invalid Parameter " + invalidParam);
				}
	}

}

Des Encryption and Decryption

package org.owasp.crypto;

import javax.crypto.KeyGenerator;
import javax.crypto.SecretKey;
import javax.crypto.Cipher;

import java.security.NoSuchAlgorithmException;
import java.security.InvalidKeyException;
import java.security.InvalidAlgorithmParameterException;
import javax.crypto.NoSuchPaddingException;
import javax.crypto.BadPaddingException;
import javax.crypto.IllegalBlockSizeException;

import sun.misc.BASE64Encoder;

/**
 * @author Joe Prasanna Kumar
 * This program provides the following cryptographic functionalities
 * 1. Encryption using DES
 * 2. Decryption using DES
 * 
 * The following modes of DES encryption are supported by SUNJce provider 
 * 1. ECB (Electronic code Book) - Every plaintext block is encrypted separately 
 * 2. CBC (Cipher Block Chaining) - Every plaintext block is XORed with the previous ciphertext block
 * 3. PCBC (Propogating Cipher Block Chaining) - 
 * 4. CFB (Cipher Feedback Mode) - The previous ciphertext block is encrypted and this enciphered block is XORed with the plaintext block to produce the corresponding ciphertext block 
 * 5. OFB (Output Feedback Mode) - 
 *
 *	High Level Algorithm :
 * 1. Generate a DES key
 * 2. Create the Cipher (Specify the Mode and Padding)
 * 3. To Encrypt : Initialize the Cipher for Encryption
 * 4. To Decrypt : Initialize the Cipher for Decryption
 * 
 * Need for Padding :
 * Block ciphers operates on data blocks on fixed size n. 
 * Since the data to be encrypted might not always be a multiple of n, the remainder of the bits are padded.
 * PKCS#5 Padding is what will be used in this program 
 * 
 */

public class DES {
	public static void main(String[] args) {
		
		String strDataToEncrypt = new String();
		String strCipherText = new String();
		String strDecryptedText = new String();
		
		try{
		/**
		 *  Step 1. Generate a DES key using KeyGenerator 
		 * 
		 */
		KeyGenerator keyGen = KeyGenerator.getInstance("DES");
		SecretKey secretKey = keyGen.generateKey();
		
		/**
		 *  Step2. Create a Cipher by specifying the following parameters
		 * 			a. Algorithm name - here it is DES
		 * 			b. Mode - here it is CBC
		 * 			c. Padding - PKCS5Padding
		 */
		
		Cipher desCipher = Cipher.getInstance("DES/CBC/PKCS5Padding");
		
		/**
		 *  Step 3. Initialize the Cipher for Encryption 
		 */
		
		desCipher.init(Cipher.ENCRYPT_MODE,secretKey);
		
		/**
		 *  Step 4. Encrypt the Data
		 *  		1. Declare / Initialize the Data. Here the data is of type String
		 *  		2. Convert the Input Text to Bytes
		 *  		3. Encrypt the bytes using doFinal method 
		 */
		strDataToEncrypt = "Hello World of Encryption using DES ";
		byte[] byteDataToEncrypt = strDataToEncrypt.getBytes();
		byte[] byteCipherText = desCipher.doFinal(byteDataToEncrypt); 
		strCipherText = new BASE64Encoder().encode(byteCipherText);
		System.out.println("Cipher Text generated using DES with CBC mode and PKCS5 Padding is " +strCipherText);
		
		/**
		 *  Step 5. Decrypt the Data
		 *  		1. Initialize the Cipher for Decryption 
		 *  		2. Decrypt the cipher bytes using doFinal method 
		 */
		desCipher.init(Cipher.DECRYPT_MODE,secretKey,desCipher.getParameters());
		 //desCipher.init(Cipher.DECRYPT_MODE,secretKey);
		byte[] byteDecryptedText = desCipher.doFinal(byteCipherText);
		strDecryptedText = new String(byteDecryptedText);
		System.out.println(" Decrypted Text message is " +strDecryptedText);
		}
		
		catch (NoSuchAlgorithmException noSuchAlgo)
		{
			System.out.println(" No Such Algorithm exists " + noSuchAlgo);
		}
		
			catch (NoSuchPaddingException noSuchPad)
			{
				System.out.println(" No Such Padding exists " + noSuchPad);
			}
		
				catch (InvalidKeyException invalidKey)
				{
					System.out.println(" Invalid Key " + invalidKey);
				}
				
				catch (BadPaddingException badPadding)
				{
					System.out.println(" Bad Padding " + badPadding);
				}
				
				catch (IllegalBlockSizeException illegalBlockSize)
				{
					System.out.println(" Illegal Block Size " + illegalBlockSize);
				}
				
				catch (InvalidAlgorithmParameterException invalidParam)
				{
					System.out.println(" Invalid Parameter " + invalidParam);
				}
	}

}

Uso de las Extensiones Criptográficas de Java

Contenido

1 Nota: 2 Descripción general 2.1 Algoritmos de cifrado simétrico proporcionados por SunJCE 2.2 Modos de cifrado 2.3 Algoritmos de cifrado asimétricos implementadas por SunJCE 2,4 hashing / Message Digest algoritmos implementados por SunJCE 3 Ejemplos 3.1 Seguridad Randómica 3.2 AES de cifrado y descifrado 3.3 DES cifrado y descifrado

Nota:

El código incluido en este artículo no ha sido revisado y no se debe utilizar sin un análisis adecuado. Si ha revisado el código incluido (o partes de ellos), por favor enviar sus conclusiones a esta página o a: stephen [at] corsaire.com. Descripción General

Extensiones Criptográficas Java (JCE) es un conjunto de API’s de Java, que proporciona servicios criptográficos como el cifrado, la generación de claves secretas, código de autenticación de mensajes y el Acuerdo clave. Los sistemas de cifrado soportados por JCE incluyen simetría, asimetría, bloque y cifrado de flujos. JCE fue un paquete opcional para JDK v 1.2.x y 1.3.x. JCE ha sido integrado en JDK v1.4.

JCE API’s se implementan los proveedores de servicios criptográficos. Cada uno de estos proveedores de servicios criptográficos implementa la interfaz del proveedor de servicio que especifican las funcionalidades que deben ser implementadas por los proveedores de servicios. Los programadores pueden obtener los plugin de cualquier proveedor de servicios para la realización de funcionalidades criptográficas proporcionadas por JCE. J2SE viene con un proveedor predeterminado, llamado SunJCE.

Algoritmos simétricos de cifrado proporcionadas por SunJCE

1. DES - KeyLength predeterminado de 56 bits (longitud) 2. AES 3. RC2, RC4 y RC5 4. IDEA 5. Triple DES - KeyLength por defecto 112 bits 6. Blowfish - KeyLength defecto 56 bits 7. PBE con MD5 y DES 8. PBE con HmacSHA1 y DESede 9. DES ede

Modos de Encriptación

1. BCE 2. CBC 3. CFB 4. OFB 5. PCBC

Algoritmos de cifrado asimétricos implementados por SunJCE

1. RSA 2. Diffie-Hellman - KeyLength defecto 1024 bits

Hashing / Message Digest algoritmos implementados por SunJCE

1. MD5 - por defecto 64 bytes de tamaño 2. SHA1 - por defecto 64 bytes de tamaño