Java 随机数生成器 Random & SecureRandom 原理分析

文章目录
java.util.Random
java.Security.SecureRandom
/dev/random 与 /dev/urandom
资料

Java 里提供了一些用于生成随机数的工具类，这里分析一下其实现原理，以及他们之间的区别、使用场景。
java.util.Random
Random 是比较常用的随机数生成类，它的基本信息在类的注释里都写到了，下面是 JDK8 里该类的注释：

/**

• An instance of this class is used to generate a stream of
• pseudorandom numbers. The class uses a 48-bit seed, which is
• modified using a linear congruential formula. (See Donald Knuth,
• The Art of Computer Programming, Volume 2, Section 3.2.1.)
• If two instances of {@code Random} are created with the same
• seed, and the same sequence of method calls is made for each, they
• will generate and return identical sequences of numbers. In order to
• guarantee this property, particular algorithms are specified for the
• class {@code Random}. Java implementations must use all the algorithms
• shown here for the class {@code Random}, for the sake of absolute
• portability of Java code. However, subclasses of class {@code Random}
• are permitted to use other algorithms, so long as they adhere to the
• general contracts for all the methods.
• The algorithms implemented by class {@code Random} use a
• {@code protected} utility method that on each invocation can supply
• up to 32 pseudorandomly generated bits.
• Many applications will find the method {@link Math#random} simpler to use.

• Instances of {@code java.util.Random} are threadsafe.

• However, the concurrent use of the same {@code java.util.Random}
• instance across threads may encounter contention and consequent
• poor performance. Consider instead using
• {@link java.util.concurrent.ThreadLocalRandom} in multithreaded
• designs.

• Instances of {@code java.util.Random} are not cryptographically

• secure. Consider instead using {@link java.security.SecureRandom} to
• get a cryptographically secure pseudo-random number generator for use
• by security-sensitive applications.
• @author Frank Yellin
• @since 1.0
  */
  翻译一下，主要有以下几点：

Random 类使用线性同余法 linear congruential formula 来生成伪随机数。
两个 Random 实例，如果使用相同的种子 seed，那他们产生的随机数序列也是一样的。
Random 是线程安全的，你的程序如果对性能要求比较高的话，推荐使用 ThreadLocalRandom。
Random 不是密码学安全的，加密相关的推荐使用 SecureRandom。
Random 的基本用法如下所示：

Random random = new Random();
int r = random.nextInt(); // 生成一个随机数
从下面的源码中可以看到，Random 的默认使用当前系统时钟来生成种子 seed。

private static final AtomicLong seedUniquifier = new AtomicLong(8682522807148012L);
public Random() {
    this(seedUniquifier() ^ System.nanoTime());
}

public Random(long seed) {
    if (getClass() == Random.class)
        this.seed = new AtomicLong(initialScramble(seed));
    else {
        // subclass might have overriden setSeed
        this.seed = new AtomicLong();
        setSeed(seed);
    }
}

private static long seedUniquifier() {
    for (;;) {
        long current = seedUniquifier.get();
        long next = current * 181783497276652981L;
        if (seedUniquifier.compareAndSet(current, next))
            return next;
    }
} 

java.Security.SecureRandom
介绍 Random 类时提到过，要生成加密基本的随机数应该使用 SecureRandom 类，该类信息如下所示：

/**

• This class provides a cryptographically strong random number
• generator (RNG).

• A cryptographically strong random number

• minimally complies with the statistical random number generator tests
• specified in

FIPS 140-2, Security Requirements for Cryptographic Modules, section 4.9.1. Additionally, SecureRandom must produce non-deterministic output. Therefore any seed material passed to a SecureRandom object must be unpredictable, and all SecureRandom output sequences must be cryptographically strong, as described in RFC 1750: Randomness Recommendations for Security.

A caller obtains a SecureRandom instance via the

no-argument constructor or one of the {@code getInstance} methods:

 SecureRandom random = new SecureRandom();

Many SecureRandom implementations are in the form of a pseudo-random

number generator (PRNG), which means they use a deterministic algorithm to produce a pseudo-random sequence from a true random seed. Other implementations may produce true random numbers, and yet others may use a combination of both techniques.

Typical callers of SecureRandom invoke the following methods

to retrieve random bytes:

 SecureRandom random = new SecureRandom();

 byte bytes[] = new byte[20];

 random.nextBytes(bytes);

Callers may also invoke the {@code generateSeed} method

to generate a given number of seed bytes (to seed other random number generators, for example):

 byte seed[] = random.generateSeed(20);

Note: Depending on the implementation, the {@code generateSeed} and {@code nextBytes} methods may block as entropy is being gathered, for example, if they need to read from /dev/random on various Unix-like operating systems.
*/
主要有以下几点：

该类提供了能满足加密要求的强随机数生成器。
传递给 SecureRandom 种子必须是不可预测的，seed 使用不当引发的安全漏洞可以看看 比特币电子钱包漏洞。
一般使用默认的种子生成策略就行，对应 Linux 里面就是 /dev/random 和 /dev/urandom。其实现原理是：操作系统收集了一些随机事件，比如鼠标点击，键盘点击等等，SecureRandom 使用这些随机事件作为种子。
使用 /dev/random 来生成种子时，可能会因为熵不够而阻塞，性能比较差。
SecureRandom 用法如下所示：

SecureRandom random = new SecureRandom();
byte[] data = random.nextBytes(16);
1
2
下面我们看看其内部实现：

synchronized public void nextBytes(byte[] bytes) {
    secureRandomSpi.engineNextBytes(bytes);
}
public SecureRandom() {
    super(0);
    getDefaultPRNG(false, null);
}
private void getDefaultPRNG(boolean setSeed, byte[] seed) {
    String prng = getPrngAlgorithm();
    if (prng == null) {
        // bummer, get the SUN implementation
        prng = "SHA1PRNG";
        this.secureRandomSpi = new sun.security.provider.SecureRandom();
        this.provider = Providers.getSunProvider();
        if (setSeed) {
            this.secureRandomSpi.engineSetSeed(seed);
        }
    } else {
        try {
            SecureRandom random = SecureRandom.getInstance(prng);
            this.secureRandomSpi = random.getSecureRandomSpi();
            this.provider = random.getProvider();
            if (setSeed) {
                this.secureRandomSpi.engineSetSeed(seed);
            }
        } catch (NoSuchAlgorithmException nsae) {
            // never happens, because we made sure the algorithm exists
            throw new RuntimeException(nsae);
        }
    }
    if (getClass() == SecureRandom.class) {
        this.algorithm = prng;
    }
} 

在 mac 环境下使用 JDK8 测试时发现，默认使用了 NativePRNG 而非 SHA1PRNG，但是 NativePRNG 其实还是在 sun.security.provider.SecureRandom 的基础上做了一些封装。

在 sun.security.provider.SeedGenerator 类里，可以看到 seed 是利用 /dev/random 或 /dev/urandom 来生成的，启动应用程序时可以通过参数 -Djava.security.egd=file:/dev/urandom 来指定 seed 源。

static {
    String var0 = SunEntries.getSeedSource();
    if (!var0.equals("file:/dev/random") && !var0.equals("file:/dev/urandom")) {
        if (var0.length() != 0) {
            try {
                instance = new SeedGenerator.URLSeedGenerator(var0);
                if (debug != null) {
                    debug.println("Using URL seed generator reading from " + var0);
                }
            } catch (IOException var2) {
                if (debug != null) {
                    debug.println("Failed to create seed generator with " + var0 + ": " + var2.toString());
                }
            }
        }
    } else {
        try {
            instance = new NativeSeedGenerator(var0);
            if (debug != null) {
                debug.println("Using operating system seed generator" + var0);
            }
        } catch (IOException var3) {
            if (debug != null) {
                debug.println("Failed to use operating system seed generator: " + var3.toString());
            }
        }
    }

    if (instance == null) {
        if (debug != null) {
            debug.println("Using default threaded seed generator");
        }

        instance = new SeedGenerator.ThreadedSeedGenerator();
    }

} 

在 Random 类里，多个实例设置相同的seed，产生的随机数序列也是一样的。而 SecureRandom 则不同，运行下面的代码：

public class RandomTest {
public static void main(String[] args) {
byte[] seed = "hello".getBytes();
for (int i = 0; i < 10; ++i) {
SecureRandom secureRandom = new SecureRandom(seed);
System.out.println(secureRandom.nextInt());
}
}
}
输出如下所示，每次运行产生的随机数都不一样。

-2105877601
1151182748
1329080810
-617594950
2094315881
-1649759687
-1360561033
-653424535
-927058354
-1577199965
为什么呢？因为 engineSetSeed 方法设置 seed 时调用的是静态实例 INSTANCE 的 implSetSeed 方法，该方法通过 getMixedRandom 得到的 SecureRandom 来设置 seed，而这个 SecureRandom 初始化种子是系统的。

private static final NativePRNG.RandomIO INSTANCE;
// in NativePRNG
protected void engineSetSeed(byte[] var1) {
    INSTANCE.implSetSeed(var1);
}
	
    private void implSetSeed(byte[] var1) {
        Object var2 = this.LOCK_SET_SEED;
        synchronized(this.LOCK_SET_SEED) {
            if (!this.seedOutInitialized) {
                this.seedOutInitialized = true;
                this.seedOut = (OutputStream)AccessController.doPrivileged(new PrivilegedAction<OutputStream>() {
                    public OutputStream run() {
                        try {
                            return new FileOutputStream(RandomIO.this.seedFile, true);
                        } catch (Exception var2) {
                            return null;
                        }
                    }
                });
            }

            if (this.seedOut != null) {
                try {
                    this.seedOut.write(var1);
                } catch (IOException var5) {
                    throw new ProviderException("setSeed() failed", var5);
                }
            }

            this.getMixRandom().engineSetSeed(var1);
        }
    }

    private SecureRandom getMixRandom() {
        SecureRandom var1 = this.mixRandom;
        if (var1 == null) {
            Object var2 = this.LOCK_GET_BYTES;
            synchronized(this.LOCK_GET_BYTES) {
                var1 = this.mixRandom;
                if (var1 == null) {
                    var1 = new SecureRandom();

                    try {
                        byte[] var3 = new byte[20];
                        readFully(this.nextIn, var3);
                        var1.engineSetSeed(var3);
                    } catch (IOException var5) {
                        throw new ProviderException("init failed", var5);
                    }

                    this.mixRandom = var1;
                }
            }
        }

        return var1;
    } 

在 sun.security.provider.SecureRandom.engineSetSeed 方法里，新种子的生成不仅和刚设置的 seed 有关，也和原来的种子（系统产生的 seed）有关。

// in sun.security.provider.SecureRandom 
public synchronized void engineSetSeed(byte[] var1) {
    if (this.state != null) {
        this.digest.update(this.state);

        for(int var2 = 0; var2 < this.state.length; ++var2) {
            this.state[var2] = 0;
        }
    }

    this.state = this.digest.digest(var1);
} 

/dev/random 与 /dev/urandom
在 Linux 操作系统中，有一个特殊的设备文件 /dev/random，可以用作随机数发生器或伪随机数发生器。

在读取时，/dev/random 设备会返回小于熵池噪声总数的随机字节。/dev/random 可生成高随机性的公钥或一次性密码本。若熵池空了，对/dev/random的读操作将会被阻塞，直到从别的设备中收集到了足够的环境噪声为止。

当然你也可以设置成不堵塞，当你在 open 的时候设置参数 O_NONBLOCK， 但是当你read 的时候，如果熵池空了，会返回 -1。

/dev/random 的一个副本是 /dev/urandom （“unlocked”，非阻塞的随机数发生器），它会重复使用熵池中的数据以产生伪随机数据。这表示对/dev/urandom的读取操作不会产生阻塞，但其输出的熵可能小于 /dev/random 的。它可以作为生成较低强度密码的伪随机数生成器，不建议用于生成高强度长期密码。