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Is it possible to have same hashcode for different strings using java's hashcode function?or if it is possible then what is the % of its possibility?

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8 Answers 8

up vote 26 down vote accepted

A Java hash code is 32bits. The number of possible strings it hashes is infinite.

So yes, there will be collisions. The percentage is meaningless - there is an infinite number of items (strings) and a finite number of possible hashes.

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So, can i say that it can produce 2^32 different hashes and after that it will repeat the hashcodes?? –  Zara Apr 11 '12 at 8:31
    
If you manage to identify 2^32 strings that all have a different hashcode, then yes, any other string not in that list will have the same hashcode as one in that list. –  Mat Apr 11 '12 at 8:32
6  
On a side note, this is called the pigeonhole principle en.wikipedia.org/wiki/Pigeonhole_principle –  cypressious Apr 11 '12 at 22:07
4  
You'd probably go through much fewer than 2^32 strings (around 2^16 strings) before hitting a collision. The reason why is related to the birthday paradox: betterexplained.com/articles/understanding-the-birthday-paradox –  Xavi May 30 '13 at 23:16
3  
"The number of possible strings it hashes is infinite." Strings in Java have a maximum size because they use a char array and arrays in Java (using the standard JVM) have a maximum size. Therefore the number of possible strings is not infinite. –  Flow Oct 9 '14 at 17:41

if it is possible then what is the % of its possibility?

That is not a particularly meaningful question.

However, unless there is some systemic bias in the hashcode function, the probability that any two different (non-equal) Strings have the same hash code will be 1 in 2^32.

This assumes that the Strings are chosen randomly from the set of all possible String values. If you restrict the set in various ways, the probability will vary from the above number. (For instance, the existence of the "FB" / "Ea" collision means that the probability of a collision in the set of all 2 letter strings is higher than the norm.)


Another thing to note is that the chance of 2^32 different strings chosen at random (from a much larger unbiased set of strings) having no hash collisions is vanishingly small. To understand why, read the Wikipedia page on the Birthday Paradox. In reality, the only way you are going to get no hash collisions in a set of 2^32 different strings is if you select or generate the strings. (And even forming the set by selecting randomly generated strings is going to be computationally expensive.)

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So, can i say that for 2^32 different strings, the hashcode function will always produce different hashcode? –  Zara Apr 11 '12 at 9:18
    
@Zara - no you can't. 1 in 2^32 is a measure of probability. Think about it. Suppose that you populated your set of 2^32 strings with strings that all have the same hashcode ... –  Stephen C Apr 11 '12 at 10:46
    
@Zara Actually it even says quite the opposite! Having 2^32 different strings you will most likely have a collision (or even several..). –  jorey Apr 12 '12 at 1:20
    
@jory - yes you are right. It's an example of the birthday paradox. (It is not entirely impossible that 2^32 different randomly generated strings will all have different hashcodes. Just vanishingly improbable.) –  Stephen C Apr 12 '12 at 2:04

YES. A lot.

Look at following pair

  • "FB" and "Ea"

can return same hash code even though the characters in it are not same.

Basically it is the sum of characters in a string multiplied by an integer.

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3  
That is incorrect. Each character is multiplied by a different number so anagrams would not necessarily return the same value. –  assylias Apr 11 '12 at 8:27
    
Sorry my bad! Corrected with a common example. –  titogeo Apr 11 '12 at 8:33
    
Why same hashcode for them? They are two different strings... :S –  Zara Apr 11 '12 at 9:26
    
@Zara refer String.hashcode() method posted by adarshr below –  titogeo Apr 11 '12 at 9:47

This wouldn't directly answer your question, but I hope it helps.

The below is from the source code of java.lang.String.

/**
 * Returns a hash code for this string. The hash code for a
 * <code>String</code> object is computed as
 * <blockquote><pre>
 * s[0]*31^(n-1) + s[1]*31^(n-2) + ... + s[n-1]
 * </pre></blockquote>
 * using <code>int</code> arithmetic, where <code>s[i]</code> is the
 * <i>i</i>th character of the string, <code>n</code> is the length of
 * the string, and <code>^</code> indicates exponentiation.
 * (The hash value of the empty string is zero.)
 *
 * @return  a hash code value for this object.
 */
public int hashCode() {
    int h = hash;
    int len = count;
    if (h == 0 && len > 0) {
    int off = offset;
    char val[] = value;

        for (int i = 0; i < len; i++) {
            h = 31*h + val[off++];
        }
        hash = h;
    }
    return h;
}
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Yes, it is possible for two Strings to have the same hashcode - If you take a look at the Wikipedia article, you will see that both "FB" and "Ea" have the same hashcode. There is nothing in the method contract saying a hashCode() should be used to compare for equality, you want to use equals() for that.

Since Java 1.2, String implements hashCode() by using a product sum algorithm over the entire text of the string.

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Yes, by definition of the pigeon-hole concept, two different strings can produce the same hashcode and code should always be written to cater for such conditions (typically, by not breaking.)

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Yes, it is entirely possible. The probability of a string (or some other object type -- just assuming you'll be using strings in this example) having the same hashcode as some other string in a collection, depends on the size of that collection (assuming that all strings in that collection are unique). The probabilities are distributed as follows:

  • With a set of size ~9,000, you'll have a 1% chance of two strings colliding with a hash in the set
  • With a set of size ~30,000, you'll have a 10% chance of two strings colliding with a hash in the set
  • With a set of size ~77,000, you'll have a 50% chance of two strings colliding with a hash in the set

The assumptions made, are:

  • The hashCode function has no bias
  • Each string in the aforementioned set is unique

This site explains it clearly: http://eclipsesource.com/blogs/2012/09/04/the-3-things-you-should-know-about-hashcode/ (Look at "the second thing you should know")

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The percentage of collisions for random strings should be minimal. However, if you hash strings from external sources, an attacker could easily create hundreds of thousands of strings having the same hashcode. In a java HashMap these would all map to the same bucket and effectively turn the map into a linked list. Access times to the map would then be proportional to the map size instead of constant, leading to a denial of service attack.

See this page on Effective DoS attacks against Web Application Plattforms for further information links to the presentation.

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