# Hashing to Calculate Frequencies can be improved?

I'm currently working on building a hash table in order to calculate the frequencies, depending on the running time of the data structure. O(1) insertion, O(n) worse look up time etc.

I've asked a few people the difference between std::map and the hash table and I've received an answer as;

"std::map adds the element as a binary tree thus causes O(log n) where with the hash table you implement it will be O(n)."

Thus I've decided to implement a hash table using the array of linked lists (for separate chaining) structure. In the code below I've assigned two values for the node, one being the key(the word) and the other being the value(frequency). It works as; when the first node is added if the index is empty it is directly inserted as the first element of linked list with the frequency of 0. If it is already in the list (which unfortunately takes O(n) time to search) increment its frequency by 1. If not found simply add it to the beginning of the list.

I know there are a lot of flows in the implementation thus I would like to ask the experienced people in here, in order to calculate frequencies efficiently, how can this implementation be improved?

Code I've written so far;

#include <iostream>
#include <stdio.h>

using namespace std;

struct Node {
string word;
int frequency;
Node *next;
};

{
private:
friend class hashTable;
Node *firstPtr;
Node *lastPtr;
int size;
public:
{
firstPtr=lastPtr=NULL;
size=0;
}
void insert(string word,int frequency)
{
Node* newNode=new Node;
newNode->word=word;
newNode->frequency=frequency;

if(firstPtr==NULL)
firstPtr=lastPtr=newNode;
else {
newNode->next=firstPtr;
firstPtr=newNode;
}

size++;
}
int sizeOfList()
{
return size;
}
void print()
{
if(firstPtr!=NULL)
{
Node *temp=firstPtr;
while(temp!=NULL)
{
cout<<temp->word<<" "<<temp->frequency<<endl;
temp=temp->next;
}
}
else
printf("%s","List is empty");
}
};

class hashTable
{
private:
int index,sizeOfTable;
public:
hashTable(int size) //Forced initalizer
{
sizeOfTable=size;
}
int hash(string key)
{
int hashVal=0;

for(int i=0;i<key.length();i++)
hashVal=37*hashVal+key[i];

hashVal=hashVal%sizeOfTable;
if(hashVal<0)
hashVal+=sizeOfTable;

return hashVal;
}
void insert(string key)
{
index=hash(key);
if(arr[index].sizeOfList()<1)
arr[index].insert(key, 0);
else {
//Search for the index throughout the linked list.
//If found, increment its value +1
}
}

};
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#include <tr1/unordered_map> if you are on c++03, #include <unordered_map if you are on c++11... –  gha.st Apr 21 '12 at 18:07
@dionadar Does 'unordered_map' support collision? –  Ali Apr 21 '12 at 18:11
if you need a multimap instead of a map, consider using <unordered_multimap :) –  gha.st Apr 21 '12 at 18:24
Array of linked lists? Too slow. Use an array of arrays. And yes, std::unordered_map does support collisions. –  Konrad Rudolph Apr 21 '12 at 18:43
@KonradRudolph Thank you so much for the illuminating answer. However considering k most frequent words, is 'unordered_map' a reasonable choice? trie structure has been proposed before but I think it is too complicated to implement for this type of question. –  Ali Apr 21 '12 at 18:47

Do you care about the worst case? If no, use an std::unordered_map (it handles collisions and you don't want a multimap) or a trie/critbit tree (depending on the keys, it may be more compact than a hash, which may lead to better caching behavior). If yes, use an std::set or a trie.

If you want, e.g., online top-k statistics, keep a priority queue in addition to the dictionary. Each dictionary value contains the number of occurrences and whether the word belongs to the queue. The queue duplicates the top-k frequency/word pairs but keyed by frequency. Whenever you scan another word, check whether it's both (1) not already in the queue and (2) more frequent than the least element in the queue. If so, extract the least queue element and insert the one you just scanned.

You can implement your own data structures if you like, but the programmers who work on STL implementations tend to be pretty sharp. I would make sure that's where the bottleneck is first.

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1- The complexity time for search in std::map and std::set is O(log(n)). And, the amortize time complexity for std::unordered_map and std::unordered_set is O(n). However, the constant time for hashing could be very large and for small numbers become more than log(n). I always consider this face.

2- if you want to use std::unordered_map, you need to make sure that std::hash is defined for you type. Otherwise you should define it.

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