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The Bouncy Castle Crypto package is a Java implementation of cryptographic algorithms. This jar contains JCE provider and lightweight API for the Bouncy Castle Cryptography APIs for JDK 1.5 to JDK 1.8.
package org.bouncycastle.crypto.test;
import org.bouncycastle.crypto.BlockCipher;
import org.bouncycastle.crypto.Mac;
import org.bouncycastle.crypto.engines.DESEngine;
import org.bouncycastle.crypto.macs.CBCBlockCipherMac;
import org.bouncycastle.crypto.macs.CFBBlockCipherMac;
import org.bouncycastle.crypto.paddings.PKCS7Padding;
import org.bouncycastle.crypto.params.KeyParameter;
import org.bouncycastle.crypto.params.ParametersWithIV;
import org.bouncycastle.util.encoders.Hex;
import org.bouncycastle.util.test.SimpleTest;
/**
* MAC tester - vectors from
* FIP 81 and
* FIP 113.
*/
public class MacTest
extends SimpleTest
{
static byte[] keyBytes = Hex.decode("0123456789abcdef");
static byte[] ivBytes = Hex.decode("1234567890abcdef");
static byte[] input1 = Hex.decode("37363534333231204e6f77206973207468652074696d6520666f7220");
static byte[] output1 = Hex.decode("f1d30f68");
static byte[] output2 = Hex.decode("58d2e77e");
static byte[] output3 = Hex.decode("cd647403");
//
// these aren't NIST vectors, just for regression testing.
//
static byte[] input2 = Hex.decode("3736353433323120");
static byte[] output4 = Hex.decode("3af549c9");
static byte[] output5 = Hex.decode("188fbdd5");
static byte[] output6 = Hex.decode("7045eecd");
public MacTest()
{
}
public void performTest()
{
KeyParameter key = new KeyParameter(keyBytes);
BlockCipher cipher = new DESEngine();
Mac mac = new CBCBlockCipherMac(cipher);
//
// standard DAC - zero IV
//
mac.init(key);
mac.update(input1, 0, input1.length);
byte[] out = new byte[4];
mac.doFinal(out, 0);
if (!areEqual(out, output1))
{
fail("Failed - expected " + new String(Hex.encode(output1)) + " got " + new String(Hex.encode(out)));
}
//
// mac with IV.
//
ParametersWithIV param = new ParametersWithIV(key, ivBytes);
mac.init(param);
mac.update(input1, 0, input1.length);
out = new byte[4];
mac.doFinal(out, 0);
if (!areEqual(out, output2))
{
fail("Failed - expected " + new String(Hex.encode(output2)) + " got " + new String(Hex.encode(out)));
}
//
// CFB mac with IV - 8 bit CFB mode
//
param = new ParametersWithIV(key, ivBytes);
mac = new CFBBlockCipherMac(cipher);
mac.init(param);
mac.update(input1, 0, input1.length);
out = new byte[4];
mac.doFinal(out, 0);
if (!areEqual(out, output3))
{
fail("Failed - expected " + new String(Hex.encode(output3)) + " got " + new String(Hex.encode(out)));
}
//
// word aligned data - zero IV
//
mac.init(key);
mac.update(input2, 0, input2.length);
out = new byte[4];
mac.doFinal(out, 0);
if (!areEqual(out, output4))
{
fail("Failed - expected " + new String(Hex.encode(output4)) + " got " + new String(Hex.encode(out)));
}
//
// word aligned data - zero IV - CBC padding
//
mac = new CBCBlockCipherMac(cipher, new PKCS7Padding());
mac.init(key);
mac.update(input2, 0, input2.length);
out = new byte[4];
mac.doFinal(out, 0);
if (!areEqual(out, output5))
{
fail("Failed - expected " + new String(Hex.encode(output5)) + " got " + new String(Hex.encode(out)));
}
//
// non-word aligned data - zero IV - CBC padding
//
mac.reset();
mac.update(input1, 0, input1.length);
out = new byte[4];
mac.doFinal(out, 0);
if (!areEqual(out, output6))
{
fail("Failed - expected " + new String(Hex.encode(output6)) + " got " + new String(Hex.encode(out)));
}
//
// non-word aligned data - zero IV - CBC padding
//
mac.init(key);
mac.update(input1, 0, input1.length);
out = new byte[4];
mac.doFinal(out, 0);
if (!areEqual(out, output6))
{
fail("Failed - expected " + new String(Hex.encode(output6)) + " got " + new String(Hex.encode(out)));
}
}
public String getName()
{
return "Mac";
}
public static void main(
String[] args)
{
runTest(new MacTest());
}
}