# Hash algorithm for string of characters using XOR and bit shift

I was given this algorithm to write a hash function:

BEGIN Hash (string)
UNSIGNED INTEGER key = 0;
FOR_EACH character IN string
key = ((key << 5) + key) ^ character;
END FOR_EACH
RETURN key;
END Hash

The `<<`operator refers to shift bits to the left. The `^` refers to the XOR operation and the character refers to the ASCII value of the character. Seems pretty straightforward.

Below is my code

``````unsigned int key = 0;
for (int i = 0; i < data.length(); i++) {
key = ((key<<5) + key) ^ (int)data[i];
}
return key;
``````

However, I keep getting ridiculous positive and negative huge numbers when i should actually get a hash value from 0 - `n`. `n` is a value set by the user beforehand. I'm not sure where things went wrong but I'm thinking it could be the `XOR` operation.

Any suggestions or opinions will be greatly appreciated. Thanks!

• First of all, you should not have to cast the character to an `int`, C++ automatically promotes `char` to `int` in arithmetic expressions. Secondly, you might want to split up the big expression into its sub-expressions, and perform them separately, then step through the code, line by line, in a debugger to see what really happens and what all values of the sub-expressions are. Aug 13, 2014 at 7:12
• And you say you get negative values? From an unsigned variable? Maybe you just print it as a signed value? Or assign it to an unsigned variable? Please show us how you check the returned value. Aug 13, 2014 at 7:15
• As an aside, `key` is unsigned, so why are you explicitly casting your data to a signed int? Aug 13, 2014 at 7:36
• Here's my suggestion: don't ever use hashing for anything. Aug 13, 2014 at 16:18

The output of this code is a 32-bit (or 64-bit or however wide your `unsigned int` is) unsigned integer. To restrict it to the range from 0 to n−1, simply reduce it modulo n, using the `%` operator:

``````unsigned int hash = key % n;
``````

(It should be obvious that your code, as written, cannot return "a hash value from 0 - `n`", since `n` does not appear anywhere in your code.)

In fact, there's a good reason not to reduce the hash value modulo n too soon: if you ever need to grow your hash, storing the unreduced hash codes of your strings saves you the effort of recalculating them whenever n changes.

Finally, a few general notes on your hash function:

• As Joachim Pileborg comments above, the explicit `(int)` cast is unnecessary. If you want to keep it for clarity, it really should say `(unsigned int)` to match the type of `key`, since that's what the value actually gets converted into.

• For unsigned integer types, `((key<<5) + key)` is equal to `33 * key` (since shifting left by 5 bits is the same as multiplying by 25 = 32). On modern CPUs, using multiplication is almost certainly faster; on old or very low-end processors with slow multiplication, it's likely that any decent compiler will optimize multiplication by a constant into a combination of shifts and adds anyway. Thus, either way, expressing the operation as a multiplication is IMO preferable.

• You don't want to call `data.length()` on every iteration of the loop. Call it once before the loop and store the result in a variable.

• Initializing `key` to zero means that your hash value is not affected by any leading zero bytes in the string. The original version of your hash function, due to Dan Bernstein, uses a (more or less random) initial value of 5381 instead.