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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 with debug enabled.
package org.bouncycastle.jcajce.provider.drbg;
import java.security.AccessController;
import java.security.PrivilegedAction;
import java.security.Provider;
import java.security.SecureRandom;
import java.security.SecureRandomSpi;
import java.util.concurrent.atomic.AtomicBoolean;
import java.util.concurrent.atomic.AtomicInteger;
import java.util.concurrent.atomic.AtomicReference;
import org.bouncycastle.crypto.digests.SHA512Digest;
import org.bouncycastle.crypto.macs.HMac;
import org.bouncycastle.crypto.prng.EntropySource;
import org.bouncycastle.crypto.prng.EntropySourceProvider;
import org.bouncycastle.crypto.prng.SP800SecureRandom;
import org.bouncycastle.crypto.prng.SP800SecureRandomBuilder;
import org.bouncycastle.jcajce.provider.config.ConfigurableProvider;
import org.bouncycastle.jcajce.provider.symmetric.util.ClassUtil;
import org.bouncycastle.jcajce.provider.util.AsymmetricAlgorithmProvider;
import org.bouncycastle.util.Arrays;
import org.bouncycastle.util.Pack;
import org.bouncycastle.util.Strings;
public class DRBG
{
private static final String PREFIX = DRBG.class.getName();
// {"Provider class name","SecureRandomSpi class name"}
private static final String[][] initialEntropySourceNames = new String[][]
{
// Normal JVM
{"sun.security.provider.Sun", "sun.security.provider.SecureRandom"},
// Apache harmony
{"org.apache.harmony.security.provider.crypto.CryptoProvider", "org.apache.harmony.security.provider.crypto.SHA1PRNG_SecureRandomImpl"},
// Android.
{"com.android.org.conscrypt.OpenSSLProvider", "com.android.org.conscrypt.OpenSSLRandom"},
{"org.conscrypt.OpenSSLProvider", "org.conscrypt.OpenSSLRandom"},
};
private static final Object[] initialEntropySourceAndSpi = findSource();
// Cascade through providers looking for match.
private final static Object[] findSource()
{
for (int t = 0; t < initialEntropySourceNames.length; t++)
{
String[] pair = initialEntropySourceNames[t];
try
{
Object[] r = new Object[]{Class.forName(pair[0]).newInstance(), Class.forName(pair[1]).newInstance()};
return r;
}
catch (Throwable ex)
{
continue;
}
}
return null;
}
private static class CoreSecureRandom
extends SecureRandom
{
CoreSecureRandom()
{
super((SecureRandomSpi)initialEntropySourceAndSpi[1], (Provider)initialEntropySourceAndSpi[0]);
}
}
// unfortunately new SecureRandom() can cause a regress and it's the only reliable way of getting access
// to the JVM's seed generator.
private static SecureRandom createInitialEntropySource()
{
boolean hasGetInstanceStrong = AccessController.doPrivileged(new PrivilegedAction()
{
public Boolean run()
{
try
{
Class def = SecureRandom.class;
return def.getMethod("getInstanceStrong") != null;
}
catch (Exception e)
{
return false;
}
}
});
if (hasGetInstanceStrong)
{
return AccessController.doPrivileged(new PrivilegedAction()
{
public SecureRandom run()
{
try
{
return (SecureRandom)SecureRandom.class.getMethod("getInstanceStrong").invoke(null);
}
catch (Exception e)
{
return createCoreSecureRandom();
}
}
});
}
else
{
return createCoreSecureRandom();
}
}
private static SecureRandom createCoreSecureRandom()
{
if (initialEntropySourceAndSpi != null)
{
return new CoreSecureRandom();
}
else
{
return new SecureRandom(); // we're desperate, it's worth a try.
}
}
private static EntropySourceProvider createEntropySource()
{
final String sourceClass = System.getProperty("org.bouncycastle.drbg.entropysource");
return AccessController.doPrivileged(new PrivilegedAction()
{
public EntropySourceProvider run()
{
try
{
Class clazz = ClassUtil.loadClass(DRBG.class, sourceClass);
return (EntropySourceProvider)clazz.newInstance();
}
catch (Exception e)
{
throw new IllegalStateException("entropy source " + sourceClass + " not created: " + e.getMessage(), e);
}
}
});
}
private static SecureRandom createBaseRandom(boolean isPredictionResistant)
{
if (System.getProperty("org.bouncycastle.drbg.entropysource") != null)
{
EntropySourceProvider entropyProvider = createEntropySource();
EntropySource initSource = entropyProvider.get(16 * 8);
byte[] personalisationString = isPredictionResistant ? generateDefaultPersonalizationString(initSource.getEntropy())
: generateNonceIVPersonalizationString(initSource.getEntropy());
return new SP800SecureRandomBuilder(entropyProvider)
.setPersonalizationString(personalisationString)
.buildHash(new SHA512Digest(), Arrays.concatenate(initSource.getEntropy(), initSource.getEntropy()), isPredictionResistant);
}
else
{
SecureRandom randomSource = new HybridSecureRandom(); // needs to be done late, can't use static
byte[] personalisationString = isPredictionResistant ? generateDefaultPersonalizationString(randomSource.generateSeed(16))
: generateNonceIVPersonalizationString(randomSource.generateSeed(16));
return new SP800SecureRandomBuilder(randomSource, true)
.setPersonalizationString(personalisationString)
.buildHash(new SHA512Digest(), randomSource.generateSeed(32), isPredictionResistant);
}
}
public static class Default
extends SecureRandomSpi
{
private static final SecureRandom random = createBaseRandom(true);
public Default()
{
}
protected void engineSetSeed(byte[] bytes)
{
random.setSeed(bytes);
}
protected void engineNextBytes(byte[] bytes)
{
random.nextBytes(bytes);
}
protected byte[] engineGenerateSeed(int numBytes)
{
return random.generateSeed(numBytes);
}
}
public static class NonceAndIV
extends SecureRandomSpi
{
private static final SecureRandom random = createBaseRandom(false);
public NonceAndIV()
{
}
protected void engineSetSeed(byte[] bytes)
{
random.setSeed(bytes);
}
protected void engineNextBytes(byte[] bytes)
{
random.nextBytes(bytes);
}
protected byte[] engineGenerateSeed(int numBytes)
{
return random.generateSeed(numBytes);
}
}
public static class Mappings
extends AsymmetricAlgorithmProvider
{
public Mappings()
{
}
public void configure(ConfigurableProvider provider)
{
provider.addAlgorithm("SecureRandom.DEFAULT", PREFIX + "$Default");
provider.addAlgorithm("SecureRandom.NONCEANDIV", PREFIX + "$NonceAndIV");
}
}
private static byte[] generateDefaultPersonalizationString(byte[] seed)
{
return Arrays.concatenate(Strings.toByteArray("Default"), seed,
Pack.longToBigEndian(Thread.currentThread().getId()), Pack.longToBigEndian(System.currentTimeMillis()));
}
private static byte[] generateNonceIVPersonalizationString(byte[] seed)
{
return Arrays.concatenate(Strings.toByteArray("Nonce"), seed,
Pack.longToLittleEndian(Thread.currentThread().getId()), Pack.longToLittleEndian(System.currentTimeMillis()));
}
private static class HybridSecureRandom
extends SecureRandom
{
private final AtomicBoolean seedAvailable = new AtomicBoolean(false);
private final AtomicInteger samples = new AtomicInteger(0);
private final SecureRandom baseRandom = createInitialEntropySource();
private final SP800SecureRandom drbg;
HybridSecureRandom()
{
super(null, null);
drbg = new SP800SecureRandomBuilder(new EntropySourceProvider()
{
public EntropySource get(final int bitsRequired)
{
return new SignallingEntropySource(bitsRequired);
}
})
.setPersonalizationString(Strings.toByteArray("Bouncy Castle Hybrid Entropy Source"))
.buildHMAC(new HMac(new SHA512Digest()), baseRandom.generateSeed(32), false); // 32 byte nonce
}
public void setSeed(byte[] seed)
{
if (drbg != null)
{
drbg.setSeed(seed);
}
}
public void setSeed(long seed)
{
if (drbg != null)
{
drbg.setSeed(seed);
}
}
public byte[] generateSeed(int numBytes)
{
byte[] data = new byte[numBytes];
// after 20 samples we'll start to check if there is new seed material.
if (samples.getAndIncrement() > 20)
{
if (seedAvailable.getAndSet(false))
{
samples.set(0);
drbg.reseed((byte[])null); // need for Java 1.9
}
}
drbg.nextBytes(data);
return data;
}
private class SignallingEntropySource
implements EntropySource
{
private final int byteLength;
private final AtomicReference entropy = new AtomicReference();
private final AtomicBoolean scheduled = new AtomicBoolean(false);
SignallingEntropySource(int bitsRequired)
{
this.byteLength = (bitsRequired + 7) / 8;
}
public boolean isPredictionResistant()
{
return true;
}
public byte[] getEntropy()
{
byte[] seed = (byte[])entropy.getAndSet(null);
if (seed == null || seed.length != byteLength)
{
seed = baseRandom.generateSeed(byteLength);
}
else
{
scheduled.set(false);
}
if (!scheduled.getAndSet(true))
{
new Thread(new EntropyGatherer(byteLength)).start();
}
return seed;
}
public int entropySize()
{
return byteLength * 8;
}
private class EntropyGatherer
implements Runnable
{
private final int numBytes;
EntropyGatherer(int numBytes)
{
this.numBytes = numBytes;
}
public void run()
{
entropy.set(baseRandom.generateSeed(numBytes));
seedAvailable.set(true);
}
}
}
}
}
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