java.security.SecureRandom Maven / Gradle / Ivy
/*
* Licensed to the Apache Software Foundation (ASF) under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The ASF licenses this file to You under the Apache License, Version 2.0
* (the "License"); you may not use this file except in compliance with
* the License. You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package java.security;
import java.nio.ByteOrder;
import java.util.Random;
import libcore.io.Memory;
import libcore.io.SizeOf;
import org.apache.harmony.security.fortress.Engine;
import org.apache.harmony.security.fortress.Services;
import org.apache.harmony.security.provider.crypto.SHA1PRNG_SecureRandomImpl;
/**
* This class generates cryptographically secure pseudo-random numbers.
*
* It is best to invoke {@code SecureRandom} using the default constructor.
* This will provide an instance of the most cryptographically strong
* provider available:
*
* SecureRandom sr = new SecureRandom();
* byte[] output = new byte[16];
* sr.nextBytes(output);
*
* The default algorithm is defined by the first {@code SecureRandomSpi}
* provider found in the installed security providers. Use {@link Security}
* to install custom {@link SecureRandomSpi} providers.
*
*
Note that the output of a {@code SecureRandom} instance should never
* be relied upon to be deterministic. For deterministic output from a given
* input, see {@link MessageDigest} which provides one-way hash functions.
* For deriving keys from passwords, see
* {@link javax.crypto.SecretKeyFactory}.
*
*
Seeding {@code SecureRandom} may be
* insecure
* A seed is an array of bytes used to bootstrap random number generation.
* To produce cryptographically secure random numbers, both the seed and the
* algorithm must be secure.
*
* By default, instances of this class will generate an initial seed using
* an internal entropy source, such as {@code /dev/urandom}. This seed is
* unpredictable and appropriate for secure use.
*
*
Using the {@link #SecureRandom(byte[]) seeded constructor} or calling
* {@link #setSeed} may completely replace the cryptographically strong
* default seed causing the instance to return a predictable sequence of
* numbers unfit for secure use. Due to variations between implementations
* it is not recommended to use {@code setSeed} at all.
*/
public class SecureRandom extends Random {
private static final long serialVersionUID = 4940670005562187L;
// The service name.
private static final String SERVICE = "SecureRandom";
// Used to access common engine functionality
private static final Engine ENGINE = new Engine(SERVICE);
private final Provider provider;
private final SecureRandomSpi secureRandomSpi;
private final String algorithm;
// Internal SecureRandom used for getSeed(int)
private static volatile SecureRandom internalSecureRandom;
/**
* Constructs a new {@code SecureRandom} that uses the default algorithm.
*/
public SecureRandom() {
super(0);
Provider.Service service = Services.getSecureRandomService();
if (service == null) {
this.provider = null;
this.secureRandomSpi = new SHA1PRNG_SecureRandomImpl();
this.algorithm = "SHA1PRNG";
} else {
try {
this.provider = service.getProvider();
this.secureRandomSpi = (SecureRandomSpi)service.newInstance(null);
this.algorithm = service.getAlgorithm();
} catch (Exception e) {
throw new RuntimeException(e);
}
}
}
/**
* Constructs a new seeded {@code SecureRandom} that uses the default
* algorithm. Seeding {@code SecureRandom} may be
* insecure.
*/
public SecureRandom(byte[] seed) {
this();
setSeed(seed);
}
/**
* Constructs a new instance of {@code SecureRandom} using the given
* implementation from the specified provider.
*
* @param secureRandomSpi
* the implementation.
* @param provider
* the security provider.
*/
protected SecureRandom(SecureRandomSpi secureRandomSpi,
Provider provider) {
this(secureRandomSpi, provider, "unknown");
}
// Constructor
private SecureRandom(SecureRandomSpi secureRandomSpi,
Provider provider,
String algorithm) {
super(0);
this.provider = provider;
this.algorithm = algorithm;
this.secureRandomSpi = secureRandomSpi;
}
/**
* Returns a new instance of {@code SecureRandom} that utilizes the
* specified algorithm.
*
* @param algorithm
* the name of the algorithm to use.
* @return a new instance of {@code SecureRandom} that utilizes the
* specified algorithm.
* @throws NoSuchAlgorithmException
* if the specified algorithm is not available.
* @throws NullPointerException
* if {@code algorithm} is {@code null}.
*/
public static SecureRandom getInstance(String algorithm) throws NoSuchAlgorithmException {
if (algorithm == null) {
throw new NullPointerException("algorithm == null");
}
Engine.SpiAndProvider sap = ENGINE.getInstance(algorithm, null);
return new SecureRandom((SecureRandomSpi) sap.spi, sap.provider,
algorithm);
}
/**
* Returns a new instance of {@code SecureRandom} that utilizes the
* specified algorithm from the specified provider.
*
* @param algorithm
* the name of the algorithm to use.
* @param provider
* the name of the provider.
* @return a new instance of {@code SecureRandom} that utilizes the
* specified algorithm from the specified provider.
* @throws NoSuchAlgorithmException
* if the specified algorithm is not available.
* @throws NoSuchProviderException
* if the specified provider is not available.
* @throws NullPointerException
* if {@code algorithm} is {@code null}.
* @throws IllegalArgumentException if {@code provider == null || provider.isEmpty()}
*/
public static SecureRandom getInstance(String algorithm, String provider)
throws NoSuchAlgorithmException, NoSuchProviderException {
if (provider == null || provider.isEmpty()) {
throw new IllegalArgumentException();
}
Provider p = Security.getProvider(provider);
if (p == null) {
throw new NoSuchProviderException(provider);
}
return getInstance(algorithm, p);
}
/**
* Returns a new instance of {@code SecureRandom} that utilizes the
* specified algorithm from the specified provider.
*
* @param algorithm
* the name of the algorithm to use.
* @param provider
* the security provider.
* @return a new instance of {@code SecureRandom} that utilizes the
* specified algorithm from the specified provider.
* @throws NoSuchAlgorithmException
* if the specified algorithm is not available.
* @throws NullPointerException
* if {@code algorithm} is {@code null}.
* @throws IllegalArgumentException if {@code provider == null}
*/
public static SecureRandom getInstance(String algorithm, Provider provider)
throws NoSuchAlgorithmException {
if (provider == null) {
throw new IllegalArgumentException("provider == null");
}
if (algorithm == null) {
throw new NullPointerException("algorithm == null");
}
Object spi = ENGINE.getInstance(algorithm, provider, null);
return new SecureRandom((SecureRandomSpi) spi, provider, algorithm);
}
/**
* Returns the provider associated with this {@code SecureRandom}.
*
* @return the provider associated with this {@code SecureRandom}.
*/
public final Provider getProvider() {
return provider;
}
/**
* Returns the name of the algorithm of this {@code SecureRandom}.
*
* @return the name of the algorithm of this {@code SecureRandom}.
*/
public String getAlgorithm() {
return algorithm;
}
/**
* Seeds this {@code SecureRandom} instance with the specified {@code
* seed}. Seeding {@code SecureRandom} may be
* insecure.
*/
public synchronized void setSeed(byte[] seed) {
secureRandomSpi.engineSetSeed(seed);
}
/**
* Seeds this {@code SecureRandom} instance with the specified eight-byte
* {@code seed}. Seeding {@code SecureRandom} may
* be insecure.
*/
@Override
public void setSeed(long seed) {
if (seed == 0) { // skip call from Random
return;
}
byte[] byteSeed = new byte[SizeOf.LONG];
Memory.pokeLong(byteSeed, 0, seed, ByteOrder.BIG_ENDIAN);
setSeed(byteSeed);
}
/**
* Generates and stores random bytes in the given {@code byte[]} for each
* array element.
*
* @param bytes
* the {@code byte[]} to be filled with random bytes.
*/
@Override
public synchronized void nextBytes(byte[] bytes) {
secureRandomSpi.engineNextBytes(bytes);
}
/**
* Generates and returns an {@code int} containing the specified number of
* random bits (right justified, with leading zeros).
*
* @param numBits
* number of bits to be generated. An input value should be in
* the range [0, 32].
* @return an {@code int} containing the specified number of random bits.
*/
@Override
protected final int next(int numBits) {
if (numBits < 0) {
numBits = 0;
} else {
if (numBits > 32) {
numBits = 32;
}
}
int bytes = (numBits+7)/8;
byte[] next = new byte[bytes];
int ret = 0;
nextBytes(next);
for (int i = 0; i < bytes; i++) {
ret = (next[i] & 0xFF) | (ret << 8);
}
ret = ret >>> (bytes*8 - numBits);
return ret;
}
/**
* Generates and returns the specified number of seed bytes, computed using
* the seed generation algorithm used by this {@code SecureRandom}.
*
* @param numBytes
* the number of seed bytes.
* @return the seed bytes
*/
public static byte[] getSeed(int numBytes) {
SecureRandom result = internalSecureRandom;
if (result == null) {
// single-check idiom
internalSecureRandom = result = new SecureRandom();
}
return result.generateSeed(numBytes);
}
/**
* Generates and returns the specified number of seed bytes, computed using
* the seed generation algorithm used by this {@code SecureRandom}.
*
* @param numBytes
* the number of seed bytes.
* @return the seed bytes.
*/
public byte[] generateSeed(int numBytes) {
return secureRandomSpi.engineGenerateSeed(numBytes);
}
}