# hash function for string

I'm working on hash table in C language and I'm testing hash function for string.

The first function I've tried is to add ascii code and use modulo (%100) but i've got poor results with the first test of data: 40 collisions for 130 words.

The final input data will contain 8 000 words (it's a dictionnary stores in a file). The hash table is declared as int table and contains the position of the word in a txt file.

The first question is which is the best algorithm for hashing string ? and how to determinate the size of hash table ?

:-)

• If your hash table has 10K entries, why would you use modulo 100? Getting 40 collisions out of 130 words isn't surprising with such a small modulus. – Carey Gregory Oct 5 '11 at 19:24
• See burtleburtle.net/bob/hash/evahash.html and partow.net/programming/hashfunctions for which are resources about various hashing (from general to string to crypto). – user166390 Oct 5 '11 at 19:33
• To clarify @CareyGregory: You do realize that, as a basic mathematical truth, 130 items in 100 buckets (i.e., mod 100) must produce 30 collisions (where collision is counted as each time a second, third, etc. item is put in a bucket), correct? So you're only a little above that. – derobert Oct 5 '11 at 19:34
• @lilawood: OK, that's what I figured, but to be a better test you should use 80 words with a hash table of 100 entries. That would give you the same proportions as your live data and wouldn't force collisions. – Carey Gregory Oct 5 '11 at 21:29
• Possible duplicate of Good Hash Function for Strings – M.J. Rayburn Sep 2 '17 at 1:01

I've had nice results with `djb2` by Dan Bernstein.

``````unsigned long
hash(unsigned char *str)
{
unsigned long hash = 5381;
int c;

while (c = *str++)
hash = ((hash << 5) + hash) + c; /* hash * 33 + c */

return hash;
}
``````
• the page linked in the answer is very interesting. – Adrien Plisson Oct 5 '11 at 19:31
• how the program runs out of the while loop?? =S – Daniel N. May 19 '15 at 1:30
• @danfly09 When c is zero. The equivalent of while(c = *str++) would be (0 != (c = *str++)) – rxantos Jul 5 '15 at 19:58
• @Josepas the hash function should ideally return a `size_t` or other such unsigned value (such as the unsigned long in this code). The caller is responsible for taking modulo of the result to fit it to the hash table. The caller controls the table slot being hashed to; not the function. It just returns some unsigned number. – WhozCraig Aug 18 '16 at 6:58
• amazing. this algorithm beat the hell out of Murmur hash, FNV variants hashes and many others! +1 – David Haim Sep 4 '16 at 14:40

First, you generally do not want to use a cryptographic hash for a hash table. An algorithm that's very fast by cryptographic standards is still excruciatingly slow by hash table standards.

Second, you want to ensure that every bit of the input can/will affect the result. One easy way to do that is to rotate the current result by some number of bits, then XOR the current hash code with the current byte. Repeat until you reach the end of the string. Note that you generally do not want the rotation to be an even multiple of the byte size either.

For example, assuming the common case of 8 bit bytes, you might rotate by 5 bits:

``````int hash(char const *input) {
int result = 0x55555555;

while (*input) {
result ^= *input++;
result = rol(result, 5);
}
}
``````

Edit: Also note that 10000 slots is rarely a good choice for a hash table size. You usually want one of two things: you either want a prime number as the size (required to ensure correctness with some types of hash resolution) or else a power of 2 (so reducing the value to the correct range can be done with a simple bit-mask).

• This isn't c, but I would be interested in your thoughts to this related answer: stackoverflow.com/a/31440118/3681880 – Suragch Jul 15 '15 at 21:24
• @Suragch: Since I wrote this, quite a few processors have started to include either special hardware to accelerate SHA computation, which has made it much more competitive. That said, I doubt your code is quite as safe as you think--for example, IEEE floating point numbers have two different bit patterns (0 and -0) that should produce the same hashes (they'll compare as equal to each other). – Jerry Coffin Jul 15 '15 at 22:02
• @Jerry Coffin which library do I need for the rol() function? – thanos.a Mar 28 at 15:50
• @thanos.a: I'm not aware of it being in a library, but rolling your own only takes a line or two of code. Shift one chunk left, the other chunk right, and or them together. – Jerry Coffin Mar 29 at 4:40

Wikipedia shows a nice string hash function called Jenkins One At A Time Hash. It also quotes improved versions of this hash.

``````uint32_t jenkins_one_at_a_time_hash(char *key, size_t len)
{
uint32_t hash, i;
for(hash = i = 0; i < len; ++i)
{
hash += key[i];
hash += (hash << 10);
hash ^= (hash >> 6);
}
hash += (hash << 3);
hash ^= (hash >> 11);
hash += (hash << 15);
return hash;
}
``````

There are a number of existing hashtable implementations for C, from the C standard library hcreate/hdestroy/hsearch, to those in the APR and glib, which also provide prebuilt hash functions. I'd highly recommend using those rather than inventing your own hashtable or hash function; they've been optimized heavily for common use-cases.

If your dataset is static, however, your best solution is probably to use a perfect hash. gperf will generate a perfect hash for you for a given dataset.

• hsearch searches by comparing the strings or string ptr address? I think it is just checking the ptr address? I tried using different pointers but same string calue. hsearch fails stating no elements found – mk.. Jul 5 '16 at 13:45

djb2 has 317 collisions for this 466k english dictionary while MurmurHash has none for 64 bit hashes, and 21 for 32 bit hashes (around 25 is to be expected for 466k random 32 bit hashes). My recommendation is using MurmurHash if available, it is very fast, because it takes in several bytes at a time. But if you need a simple and short hash function to copy and paste to your project I'd recommend using murmurs one-byte-at-a-time version:

``````uint32_t inline MurmurOAAT32 ( const char * key)
{
uint32_t h(3323198485ul);
for (;*key;++key) {
h ^= *key;
h *= 0x5bd1e995;
h ^= h >> 15;
}
return h;
}

uint64_t inline MurmurOAAT64 ( const char * key)
{
uint64_t h(525201411107845655ull);
for (;*key;++key) {
h ^= *key;
h *= 0x5bd1e9955bd1e995;
h ^= h >> 47;
}
return h;
}
``````

The optimal size of a hash table is - in short - as large as possible while still fitting into memory. Because we don't usually know or want to look up how much memory we have available, and it might even change, the optimal hash table size is roughly 2x the expected number of elements to be stored in the table. Allocating much more than that will make your hash table faster but at rapidly diminishing returns, making your hash table smaller than that will make it exponentially slower. This is because there is a non-linear trade-off between space and time complexity for hash tables, with an optimal load factor of 2-sqrt(2) = 0.58... apparently.

First, is 40 collisions for 130 words hashed to 0..99 bad? You can't expect perfect hashing if you are not taking steps specifically for it to happen. An ordinary hash function won't have fewer collisions than a random generator most of the time.

A hash function with a good reputation is MurmurHash3.

Finally, regarding the size of the hash table, it really depends what kind of hash table you have in mind, especially, whether buckets are extensible or one-slot. If buckets are extensible, again there is a choice: you choose the average bucket length for the memory/speed constraints that you have.

• The expected number of hash collisions is `n - m * (1 - ((m-1)/m)^n) = 57.075...`. 40 collisions is better than what could be expected by chance (46 to 70 at a p-score of 0.999). The hash function in question is more uniform than if it were random or we are witnessing a very rare event. – Wolfgang Brehm Jan 24 at 10:54

Though `djb2`, as presented on stackoverflow by cnicutar, is almost certainly better, I think it's worth showing the K&R hashes too:

1) Apparently a terrible hash algorithm, as presented in K&R 1st edition (source)

``````unsigned long hash(unsigned char *str)
{
unsigned int hash = 0;
int c;

while (c = *str++)
hash += c;

return hash;
}
``````

2) Probably a pretty decent hash algorithm, as presented in K&R version 2 (verified by me on pg. 144 of the book); NB: be sure to remove `% HASHSIZE` from the return statement if you plan on doing the modulus sizing-to-your-array-length outside the hash algorithm. Also, I recommend you make the return and "hashval" type `unsigned long` instead of the simple `unsigned` (int).

``````unsigned hash(char *s)
{
unsigned hashval;

for (hashval = 0; *s != '\0'; s++)
hashval = *s + 31*hashval;
return hashval % HASHSIZE;
}
``````

Note that it's clear from the two algorithms that one reason the 1st edition hash is so terrible is because it does NOT take into consideration string character order, so `hash("ab")` would therefore return the same value as `hash("ba")`. This is not so with the 2nd edition hash, however, which would (much better!) return two different values for those strings.

The GCC C++11 hashing functions used for `unordered_map` (a hash table template) and `unordered_set` (a hash set template) appear to be as follows.

Code:

``````// Implementation of Murmur hash for 32-bit size_t.
size_t _Hash_bytes(const void* ptr, size_t len, size_t seed)
{
const size_t m = 0x5bd1e995;
size_t hash = seed ^ len;
const char* buf = static_cast<const char*>(ptr);

// Mix 4 bytes at a time into the hash.
while (len >= 4)
{
k *= m;
k ^= k >> 24;
k *= m;
hash *= m;
hash ^= k;
buf += 4;
len -= 4;
}

// Handle the last few bytes of the input array.
switch (len)
{
case 3:
hash ^= static_cast<unsigned char>(buf) << 16;
[[gnu::fallthrough]];
case 2:
hash ^= static_cast<unsigned char>(buf) << 8;
[[gnu::fallthrough]];
case 1:
hash ^= static_cast<unsigned char>(buf);
hash *= m;
};

// Do a few final mixes of the hash.
hash ^= hash >> 13;
hash *= m;
hash ^= hash >> 15;
return hash;
}
``````

I have tried these hash functions and got the following result. I have about 960^3 entries, each 64 bytes long, 64 chars in different order, hash value 32bit. Codes from here.

``````Hash function    | collision rate | how many minutes to finish
==============================================================
MurmurHash3      |           6.?% |                      4m15s
Jenkins One..    |           6.1% |                      6m54s
Bob, 1st in link |          6.16% |                      5m34s
SuperFastHash    |            10% |                      4m58s
bernstein        |            20% |       14s only finish 1/20
one_at_a_time    |          6.16% |                       7m5s
crc              |          6.16% |                      7m56s
``````

One strange things is that almost all the hash functions have 6% collision rate for my data.

• While this link may answer the question, it is better to include the essential parts of the answer here and provide the link for reference. Link-only answers can become invalid if the linked page changes. – thewaywewere Jun 29 '17 at 9:22
• Upvoted for a good table, put posting the source code for each of those hashes in your answer is essential too. Otherwise, the links may break and we are out of luck. – Gabriel Staples Aug 11 '17 at 17:57
• The expected number of collisions should be 9.112499989700318E+7 or 0.103 * 960³ if the hashes were truly random, so I would not have been surprised if they were all around that value, but 0.0616 * 960³ seems a bit off, almost as if the hashes are more evenly distributed than what would be expected by chance, and at 64 bytes length this limit should definitely be approached. Can you share the set of strings that you hashed so I can try to reproduce it? – Wolfgang Brehm Jan 20 at 22:47

One thing I've used with good results is the following (I don't know if its mentioned already because I can't remember its name).

You precompute a table T with a random number for each character in your key's alphabet [0,255]. You hash your key 'k0 k1 k2 ... kN' by taking T[k0] xor T[k1] xor ... xor T[kN]. You can easily show that this is as random as your random number generator and its computationally very feasible and if you really run into a very bad instance with lots of collisions you can just repeat the whole thing using a fresh batch of random numbers.

• If I'm not mistaken this suffers from the same problem as K&R 1st in Gabriel's answer; i.e. "ab" and "ba" will hash to the same value. – Johann Oskarsson Sep 15 '19 at 8:07