# Can a non-empty string have a hashcode of zero?

By "non-empty", I mean in this question a string which contains at least one non-zero character.

For reference, here's the `hashCode` implementation :

``````1493    public int hashCode() {
1494        int h = hash;
1495        if (h == 0) {
1496            int off = offset;
1497            char val[] = value;
1498            int len = count;
1499
1500            for (int i = 0; i < len; i++) {
1501                h = 31*h + val[off++];
1502            }
1503            hash = h;
1504        }
1505        return h;
1506    }
``````

and the algorithm is specified in the documentation.

Before an integer overflow occurs, the answer is easy: it's no. But what I'd like to know is if, due to integer overflow, it's possible for a non-empty string to have a hashcode of zero? Can you construct one?

What I'm looking for would ideally be a mathematical demonstration (or a link to one) or a construction algorithm.

• What do you mean by null hashcode? The type is `int`? Sep 11, 2013 at 16:22
• also not sure what "long" you're referring to. hashCode() method deals in ints and chars. Sep 11, 2013 at 16:23
• I guess it might be possible. but finding an exact case will be a headache. Sep 11, 2013 at 16:25
• How can this question be "too broad" ? Sep 11, 2013 at 16:32
• @JoopEggen Please read the question until the first sentence... Sep 11, 2013 at 16:37

Sure. The string f5a5a608 for example has a hashcode of zero.

I found that through a simple brute force search:

``````public static void main(String[] args){
long i = 0;
loop: while(true){
String s = Long.toHexString(i);
if(s.hashCode() == 0){
System.out.println("Found: '"+s+"'");
break loop;
}
if(i % 1000000==0){
System.out.println("checked: "+i);
}
i++;
}
}
``````

Edit: Joseph Darcy, who worked on the JVM, even wrote a program that can construct a string with a given hashcode (to test the implementation of Strings in switch/case statements) by basically running the hash algorithm in reverse.

• `Incentively, my dear, I don't tessellate a derangement.` Hashcodes to zero. There are a lot of them. Think of it this way, you have roughly a 2^-64 chance a String will hash to zero. Then think of how many possible Strings there are. Sep 11, 2013 at 16:46
• @Obicere I wasn't at all sure that the overflows were able to lead to a zero value. Sep 11, 2013 at 16:48
• @Obicere: It's not necessarily true that a hash function will use all hash values with equal likelihood (or at all), though of course you'd expect that from a good hash function. Sep 11, 2013 at 16:50
• @MichaelBorgwardt Of course, but the more characters the better the distribution. When approaching infinite characters, it should approach that value. Also, with the more characters, the less significance the 1-or-2 character strings impact the results, due to the exponential gain of string permutations. Sep 11, 2013 at 16:53
• I don't think the unhash function can work for this purpose. It would only find the string made of zero chars. Sep 11, 2013 at 16:53

just be care of that `int h;`. It may overflow, every string that satisfy `h % 2^31 == 0` may lead to this.

``````public class HelloWorld {
public static void main(String []args) {
System.out.println("\u0001!qbygvW".hashCode());
System.out.println("9 \$Ql(0".hashCode());
System.out.println(" #t(}lrl".hashCode());
System.out.println(" !!#jbw}a".hashCode());
System.out.println(" !!#jbw|||".hashCode());
System.out.println(" !!!!Se|aaJ".hashCode());
System.out.println(" !!!!\"xurlls".hashCode());
}
}
``````

A lot of strings...

Here's code to find and print strings of any desired `hashCode` value:

``````public static int findIntInverse(int x) {
// find the number y such that as an int (after overflow) x*y = 1
// assumes x is odd, because without that it isn't possible.
// works by computing x ** ((2 ** 32) - 1)
int retval = 1;
for (int i = 0; i < 31; i++) {
retval *= retval;
retval *= x;
}
return retval;
}

public static void findStrings(
int targetHash,
Iterable<String> firstParts,
Iterable<String> midParts,
Iterable<String> lastParts) {
Map<Integer, String> firstHashes = new HashMap<>();
for (String firstPart : firstParts) {
firstHashes.put(firstPart.hashCode(), firstPart);
}
int maxlastlen = 0;
int maxmidlen = 0;
for (String midPart : midParts) {
maxmidlen = Math.max(midPart.length(), maxmidlen);
}
for (String lastPart : lastParts) {
maxlastlen = Math.max(lastPart.length(), maxlastlen);
}
List<Integer> hashmuls = new ArrayList<>();
String baseStr = "\u0001";
for (int i = 0; i <= maxmidlen + maxlastlen; i++) {
baseStr += "\0";
}
// now change each hashmuls into its negative "reciprocal"
for (int i = 0; i < hashmuls.size(); i++) {
hashmuls.set(i, -findIntInverse(hashmuls.get(i)));
}
for (String lastPart : lastParts) {
for (String midPart : midParts) {
String tail = midPart + lastPart;
Integer target = hashmuls.get(tail.length()) * (tail.hashCode() - targetHash);
if (firstHashes.containsKey(target)) {
System.out.print(firstHashes.get(target));
System.out.println(tail);
}
}
}
}
``````

Some interesting finds found by using a list of common English words to seed each part:

``````sand nearby chair
king concentration feeling
childhood dish tight
war defensive to
ear account virus
``````

Using just `Arrays.asList(" ")` as `midParts` and a large English word list for `firstParts` and `lastParts`, we find the well-known `pollinating sandboxes` as well as `revolvingly admissable`, `laccaic dephase`, `toxity fizzes`, etc.

Note that if you give `findStrings` a large list of size N for both `firstParts` and `lastParts` and a short fixed list for `midParts`, it runs in O(N) time.