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Why does this code using random strings print “hello world”?

The following print statement would print "hello world". Could anyone explain this?

``````System.out.println(randomString(-229985452) + " " + randomString(-147909649));
``````

And `randomString()` looks like this:

``````public static String randomString(int i)
{
Random ran = new Random(i);
StringBuilder sb = new StringBuilder();
while (true)
{
int k = ran.nextInt(27);
if (k == 0)
break;

sb.append((char)('`' + k));
}

return sb.toString();
}
``````
-
Well, those particular seeds just so happen to work out perfectly. Random is not truly random, it is pseudorandom. – Doorknob Mar 3 '13 at 4:41
It works, as others have said, because random isn't. To me, a more interesting question would be did the person that wrote that, brute force it, or is there an easy way to predict what random would generate for the next N values for a given seed. Brute forcing is easy and with modern hardware shouldn't take too long, so that was ceertain a viable way of doing it. Given that it is static, you could even easily distribute the search across a network. – jmoreno Mar 3 '13 at 5:31
I wonder the purpose of `n` in `for (int n = 0; ; n++)`. They could use `for(;;)` or `while(true)` instead! – Eng.Fouad Mar 3 '13 at 6:50
In a truly random sequence every possible string will eventually appear. In a high quality pseudo random sequence on can reasonable expect every possible string of length (log_s(N) - n) bits (where N is the number of bits in the PRNGs internal state and n is a small number, lets pick 8 for convenience) to appear in the cycle. This code gets some help from the use of a freely chosen hardcoded start point (the value of the character backtick) which gets almost the whole 8 bits back. – dmckee Mar 4 '13 at 0:13
winner of the weirdest way to print "hello world" – osdamv Mar 4 '13 at 19:51

When an instance of `java.util.Random` is constructed with a specific seed parameter (in this case `-229985452` or `-147909649`), it follows the random number generation algorithm beginning with that seed value.

Every `Random` constructed with the same seed will generate the same pattern of numbers every time.

-
@Vulcan - the javadoc says that the seed is 48 bits. docs.oracle.com/javase/7/docs/api/java/util/Random.html. And besides, the actual seeds are 32 bit values. – Stephen C Mar 3 '13 at 4:58
Each element of the random number sequence is taken modulo 27, and there are 6 elements in each of `"hello\0"` and `"world\0"`. If you assumed a truly random generator, the odds would be 1 in 27^6 (387,420,489) of getting the sequence you were looking for -- so it's pretty impressive but not quite mind-blowing! – Russell Borogove Mar 3 '13 at 7:48
@RussellBorogove: But with those odds, and 2^64 possible seeds, there are an expected 47.6 billion seed values that give that sequence. It's just a matter of finding one. – dan04 Mar 3 '13 at 17:54
@dan04 -- I wasn't quite willing to make that estimate; depending on the implementation of the PRNG, the size of the seed word might not equal the size of the state, and sequence paths might not be evenly distributed. But still, the odds are definitely good, and if you couldn't find a pair you could try again with different casing (`"Hello"` `"World"`), or using `122-k` instead of `96+k`, or... – Russell Borogove Mar 3 '13 at 18:15
@ThorbjørnRavnAndersen The Javadoc specifies that "particular algorithms are specified for the class Random. Java implementations must use all the algorithms shown here for the class Random, for the sake of absolute portability of Java code." – Vulcan Aug 27 '13 at 3:05

The other answers explain why, but here is how:

``````new Random(-229985452).nextInt(27)
``````

The first 6 numbers that the above random generates are:

``````8
5
12
12
15
0
``````

and the first 6 numbers that `new Random(-147909649).nextInt(27)` generates are:

``````23
15
18
12
4
0
``````

Then just add those numbers to the integer representation of the character ``` (which is 96):

``````8  + 96 = 104 --> h
5  + 96 = 101 --> e
12 + 96 = 108 --> l
12 + 96 = 108 --> l
15 + 96 = 111 --> o

23 + 96 = 119 --> w
15 + 96 = 111 --> o
18 + 96 = 114 --> r
12 + 96 = 108 --> l
4  + 96 = 100 --> d
``````
-
Pedantically, `new Random(-229985452).nextInt(27)` always returns 8. – immibis Mar 12 '15 at 2:16

I'll just leave it here. Whoever has a lot of (CPU) time to spare, feel free to experiment :) Also, if you have mastered some fork-join-fu to make this thing burn all CPU cores (just threads are boring, right?), please share your code. I would greatly appreciate it.

``````public static void main(String[] args) {
long time = System.currentTimeMillis();
generate("stack");
generate("over");
generate("flow");
generate("rulez");

System.out.println("Took " + (System.currentTimeMillis() - time) + " ms");
}

private static void generate(String goal) {
long[] seed = generateSeed(goal, Long.MIN_VALUE, Long.MAX_VALUE);
System.out.println(seed[0]);
System.out.println(randomString(seed[0], (char) seed[1]));
}

public static long[] generateSeed(String goal, long start, long finish) {
char[] input = goal.toCharArray();
char[] pool = new char[input.length];
label:
for (long seed = start; seed < finish; seed++) {
Random random = new Random(seed);

for (int i = 0; i < input.length; i++)
pool[i] = (char) random.nextInt(27);

if (random.nextInt(27) == 0) {
int base = input[0] - pool[0];
for (int i = 1; i < input.length; i++) {
if (input[i] - pool[i] != base)
continue label;
}
return new long[]{seed, base};
}

}

throw new NoSuchElementException("Sorry :/");
}

public static String randomString(long i, char base) {
System.out.println("Using base: '" + base + "'");
Random ran = new Random(i);
StringBuilder sb = new StringBuilder();
for (int n = 0; ; n++) {
int k = ran.nextInt(27);
if (k == 0)
break;

sb.append((char) (base + k));
}

return sb.toString();
}
``````

Output:

``````-9223372036808280701
Using base: 'Z'
stack
-9223372036853943469
Using base: 'b'
over
-9223372036852834412
Using base: 'e'
flow
-9223372036838149518
Using base: 'd'
rulez
Took 7087 ms
``````
-
@OneTwoThree `nextInt(27)` means within the range `[0, 26]`. – Eng.Fouad Mar 3 '13 at 21:48
@Vulcan Most seeds are very close to the maximum value, just like if you select random numbers between 1 and 1000, most numbers you end up picking will have three digits. It's not surprising, when you think about it :) – Thomas Mar 3 '13 at 22:28
@Vulcan In fact if you do the math you'll see they are about as close to the maximum value as to zero (I suppose the seed is being interpreted as an unsigned in the generation code). But because the number of digits grow only logarithmically with the actual value, the number looks really close when it really isn't. – Thomas Mar 3 '13 at 22:36
An interesting and related rule is Benford's Law, stating that in many natural data sources, the leading numbers "1" and "2" appear much more frequently, for a similar reason: to go from 9 to 10 takes a much smaller factor than from 10 to 20. In this case, to go from `0` to `int.max/10` takes much less than to go from `int.max/10` to `int.max`. – FeepingCreature Mar 4 '13 at 14:03
@Marek: I don't think gods of pseudo random would approve of such behaviour. – Denis Tulskiy Mar 11 '13 at 8:43

Everyone here did a great job of explaining how the code works and showing how you can construct your own examples, but here's an information theoretical answer showing why we can reasonably expect a solution to exist that the brute force search will eventually find.

The 26 different lower-case letters form our alphabet `Σ`. To allow generating words of different lengths, we further add a terminator symbol `⊥` to yield an extended alphabet `Σ' := Σ ∪ {⊥}`.

Let `α` be a symbol and X a uniformly distributed random variable over `Σ'`. The probability of obtaining that symbol, `P(X = α)`, and its information content, `I(α)`, are given by:

P(X = α) = 1/|Σ'| = 1/27

I(α) = -log₂[P(X = α)] = -log₂(1/27) = log₂(27)

For a word `ω ∈ Σ*` and its `⊥-`terminated counterpart `ω' := ω · ⊥ ∈ (Σ')*`, we have

I(ω) := I(ω') = |ω'| * log₂(27) = (|ω| + 1) * log₂(27)

Since the Pseudorandom Number Generator (PRNG) is initialized with a 32-bit seed, we can expect most words of length up to

λ = floor[32/log₂(27)] - 1 = 5

to be generated by at least one seed. Even if we were to search for a 6-character word, we would still be successful about 41.06% of the time. Not too shabby.

For 7 letters we're looking at closer to 1.52%, but I hadn't realized that before giving it a try:

``````#include <iostream>
#include <random>

int main()
{
std::mt19937 rng(631647094);
std::uniform_int_distribution<char> dist('a', 'z' + 1);

char alpha;
while ((alpha = dist(rng)) != 'z' + 1)
{
std::cout << alpha;
}
}
``````

See the output: http://ideone.com/JRGb3l

-
+1 for the theory, but really wish I could +1 again for the fitting reference in your code output! – Ben Lee Mar 5 '13 at 20:20
my information theory is kind of weak but I love this proof. can someone explain the lambda line to me, clearly we're dividing the information content of one with the other, but why does this give us our word-length? as I said I'm kinda rusty so apologies for asking the obvious (N.B. is it something to do with the shannon limit -from code output) – Mike H-R Apr 10 '13 at 13:40
@MikeH-R The lambda line is the `I(⍵)` equation rearranged.`I(⍵)` is 32 (bits) and `|⍵|` turns out to be 5 (symbols). – iceman Sep 10 '15 at 4:42

I wrote a quick program to find these seeds:

``````import java.lang.*;
import java.util.*;
import java.io.*;

public class RandomWords {
public static void main (String[] args) {
Set<String> wordSet = new HashSet<String>();
String fileName = (args.length > 0 ? args[0] : "/usr/share/dict/words");
findRandomWords(wordSet);
}

private static void readWordMap (Set<String> wordSet, String fileName) {
try {
String line;
line = line.trim().toLowerCase();
}
}
catch (IOException e) {
System.err.println("Error reading from " + fileName + ": " + e);
}
}

private static boolean isLowerAlpha (String word) {
char[] c = word.toCharArray();
for (int i = 0; i < c.length; i++) {
if (c[i] < 'a' || c[i] > 'z') return false;
}
return true;
}

private static void findRandomWords (Set<String> wordSet) {
char[] c = new char[256];
Random r = new Random();
for (long seed0 = 0; seed0 >= 0; seed0++) {
for (int sign = -1; sign <= 1; sign += 2) {
long seed = seed0 * sign;
r.setSeed(seed);
int i;
for (i = 0; i < c.length; i++) {
int n = r.nextInt(27);
if (n == 0) break;
c[i] = (char)((int)'a' + n - 1);
}
String s = new String(c, 0, i);
if (wordSet.contains(s)) {
System.out.println(s + ": " + seed);
wordSet.remove(s);
}
}
}
}
}
``````

I have it running in the background now, but it's already found enough words for a classic pangram:

``````import java.lang.*;
import java.util.*;

public class RandomWordsTest {
public static void main (String[] args) {
long[] a = {-73, -157512326, -112386651, 71425, -104434815,
-128911, -88019, -7691161, 1115727};
for (int i = 0; i < a.length; i++) {
Random r = new Random(a[i]);
StringBuilder sb = new StringBuilder();
int n;
while ((n = r.nextInt(27)) > 0) sb.append((char)('`' + n));
System.out.println(sb);
}
}
}
``````

Ps. `-727295876, -128911, -1611659, -235516779`.

-

Most random number generators are, in fact, "pseudo random." They are Linear Congruential Generators, or LCGs (http://en.wikipedia.org/wiki/Linear_congruential_generator)

LCGs are quite predictable given a fixed seed. Basically, use a seed that gives you your first letter, then write an app that continues to generate the next int (char) until you hit the next letter in your target string and write down how many times you had to invoke the LCG. Continue until you've generated each and every letter.

-

I was intrigued by this, I ran this random word generator on a dictionary word list. Range: Integer.MIN_VALUE to Integer.MAX_VALUE

I got 15131 hits.

``````int[] arrInt = {-2146926310, -1885533740, -274140519,
-2145247212, -1845077092, -2143584283,
-2147483454, -2138225126, -2147375969};

for(int seed : arrInt){
System.out.print(randomString(seed) + " ");
}
``````

Prints

``````the quick browny fox jumps over a lazy dog
``````
-
You made my day man :D I tried it with Long.Min/Max and search for names of my colleagues and only found peter : ( peter 4611686018451441623 peter 24053719 peter -4611686018403334185 peter -9223372036830722089 peter -4611686017906248127 peter 521139777 peter 4611686018948527681 peter -9223372036333636031 peter -4611686017645756173 peter 781631731 peter 4611686019209019635 peter -9223372036073144077 peter -4611686017420317288 peter 1007070616 peter -9223372035847705192 ) – Marcel 2 days ago

Random always return the same sequence. It's used for shuffling arrays and other operations as permutations.

To get different sequences, it's necessary initialize the sequence in some position, called "seed".

The randomSting get the random number in the i position (seed = -229985452) of the "random" sequence. Then uses the ASCII code for the next 27 character in the sequence after the seed position until this value are equal to 0. This return the "hello". The same operation is done for "world".

I think that the code did not work for any other words. The guy that programmed that knows the random sequence very well.

It's very great geek code!

-
I doubt if he "knows the Random sequence very well". More likely, he just tried billions of possible seeds until finding one that worked. – dan04 Mar 4 '13 at 1:23
@dan04 Real programmers don't merely use the PRNG, they remember the whole period by heart and enumerate values as needed. – Thomas Mar 4 '13 at 23:56

As multi-threading is very easy with Java, here is a variant that searches for a seed using all cores available: http://ideone.com/ROhmTA

``````import java.util.ArrayList;
import java.util.Random;
import java.util.concurrent.Callable;
import java.util.concurrent.ExecutorService;
import java.util.concurrent.Executors;

public class SeedFinder {

static class SearchTask implements Callable<Long> {

private final char[] goal;
private final long start, step;

public SearchTask(final String goal, final long offset, final long step) {
final char[] goalAsArray = goal.toCharArray();
this.goal = new char[goalAsArray.length + 1];
System.arraycopy(goalAsArray, 0, this.goal, 0, goalAsArray.length);
this.start = Long.MIN_VALUE + offset;
this.step = step;
}

@Override
public Long call() throws Exception {
final long LIMIT = Long.MAX_VALUE - this.step;
final Random random = new Random();
int position, rnd;
long seed = this.start;

while ((Thread.interrupted() == false) && (seed < LIMIT)) {
random.setSeed(seed);
position = 0;
rnd = random.nextInt(27);
while (((rnd == 0) && (this.goal[position] == 0))
|| ((char) ('`' + rnd) == this.goal[position])) {
++position;
if (position == this.goal.length) {
return seed;
}
rnd = random.nextInt(27);
}
seed += this.step;
}

throw new Exception("No match found");
}
}

public static void main(String[] args) {
final String GOAL = "hello".toLowerCase();
final int NUM_CORES = Runtime.getRuntime().availableProcessors();

for (int i = 0; i < NUM_CORES; ++i) {
}

@Override
result.setDaemon(false);
return result;
}
});
try {
System.out.println("Seed for \"" + GOAL + "\" found: " + result);
} catch (Exception ex) {
System.err.println("Calculation failed: " + ex);
} finally {
executor.shutdownNow();
}
}
}
``````
-

Derived from Denis Tulskiy's answer, this method generates the seed.

``````public static long generateSeed(String goal, long start, long finish) {
char[] input = goal.toCharArray();
char[] pool = new char[input.length];
label:
for (long seed = start; seed < finish; seed++) {
Random random = new Random(seed);

for (int i = 0; i < input.length; i++)
pool[i] = (char) (random.nextInt(27)+'`');

if (random.nextInt(27) == 0) {
for (int i = 0; i < input.length; i++) {
if (input[i] != pool[i])
continue label;
}
return seed;
}

}

throw new NoSuchElementException("Sorry :/");
}
``````
-

From the Java docs, this is an intentional feature when specifying a seed value for the Random class.

If two instances of 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 Random. Java implementations must use all the algorithms shown here for the class Random, for the sake of absolute portability of Java code.

http://docs.oracle.com/javase/1.4.2/docs/api/java/util/Random.html

Odd though, you would think there are implicit security issues in having predictable 'random' numbers.

-
That is why the default constructor of `Random` "sets the seed of the random number generator to a value very likely to be distinct from any other invocation of this constructor" (javadoc). In the current implementation this is a combination of the current time and a counter. – martin Mar 6 '13 at 14:22
Indeed. Presumably there are practical use-cases for specifying the initial seed value, then. I guess that's the operating principle of those pseudorandom keyfobs you can get (RSA ones?) – deed02392 Mar 6 '13 at 15:02
@deed02392 Of course there are practical use-cases for specifying a seed value. If you're simulating data to use some sort of monte carlo approach to solving a problem then it's a good thing to be able to reproduce your results. Setting an initial seed is the easiest way to do that. – Dason Mar 10 '13 at 4:11

The principal is the Random Class constructed with the same seed will generate the same pattern of numbers every time.

-

It is about "seed". Same seeds give the same result.

-

protected by Richard J. Ross IIIMar 4 '13 at 15:32

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