A hash table provides a way to insert and retrieve data efficiently (usually in constant/O(1)) time. For this we use an very large array to store the the target values and a hash function which usually maps the target values, into hash values which is nothing else but the valid indices in this large array. A hash function which perfectly hashes a values to be stored into a unique key (or index in the table) is known as a perfect hash function. But in practice to store such values for which there is no known way to obtain unique hash values (indices in the table) we usually use a hash function which can map each value to particular index so that collision can be kept minimum. Here collision means that two or more items to be stored in the hash table map to the same hash value.
Now coming at the original questions, which is:
"Design a Hash-table, You can use any data-structure you can want. I would like to see how you implement the O(1) look up time". Finally he said It's more like simulating a Hash-table via another Data-structure."
Look up is possible in exactly O(1) time, in case we can design a perfect hash function. The underlying data-structure is still an array. But it depends upon the values to be stored, whether we can design a perfect hash function or not. For example consider strings to English alphabet. Since there is no known hash function which can map each valid English word to a unique int (32 bit) (or long long int 64 bit) value, so there will always be some collisions. To deal with collision we can use separate chaining method of collision handling in which each hash table slot stores a pointer to the linked list, which actually stores all the item hashing to that particular slot or index. For example consider a hash function which considers each English alphabet string as a number on base 26 (because there are 26 characters in English alphabet), This can be coded as:
unsigned int hash(const std::string& word)
std::transform(word.begin(), word.end(), word.begin(), ::tolower);
unsigned int key=0;
key = (key<<4) + (key<<3)+(key<<2) + word[i];
key = key% tableSize;
Where tableSize is an appropriately chosen prime number just greater than the total number of English dictionary words targeted to be stored in the hash table.
Following are the results with dictionary of size 144554, and table of size = 144563:
[Items mapping to same cell --> Number of such slots in the hash table ] =======>
[ 0 --> 53278 ]
[1 --> 52962 ]
[2 --> 26833 ]
[3 --> 8653 ]
[4 --> 2313 ]
[5 --> 437 ]
[6 --> 78 ]
[7 --> 9 ]
In this case to search the items which have been mapped to cells containing only one item, the lookup will be O(1), but in case it maps to a cell which has more than 1 items, then we have to iterate through this linked list which might contain 2 to 7 nodes and then we will be able to find out that element. So its not constant in this case.
So it depends upon the availability of perfect hash function only, whether we the lookup can be performed in O(1) constraint. Otherwise it will not be exactly O(1) but very close to it.