Hash Table is a data structure to map key to values (also called Table or Map Abstract Data Type/ADT). It uses a hash function to map large or even non-Integer keys into a small range of Integer indices (typically [0..hash_table_size-1]).
The probability of two distinct keys colliding into the same index is relatively high and each of this potential collision needs to be resolved to maintain data integrity.
There are several collision resolution strategies that will be highlighted in this visualization: Open Addressing (Linear Probing, Quadratic Probing, and Double Hashing) and Closed Addressing (Separate Chaining). Try clicking
for a sample animation of searching a specific value 7 in a randomly created Hash Table using Separate Chaining technique (duplicates are allowed).Hashing is an algorithm (via a hash function) that maps large data sets of variable length, called keys, not necessarily Integers, into smaller Integer data sets of a fixed length.
A Hash Table is a data structure that uses a hash function to efficiently map keys to values (Table or Map ADT), for efficient search/retrieval, insertion, and/or removals.
Hash Table is widely used in many kinds of computer software, particularly for associative arrays, database indexing, caches, and sets.
In this e-Lecture, we will digress to Table ADT, the basic ideas of Hashing, the discussion of Hash Functions before going into the details of Hash Table data structure itself.
A Table ADT must support at least the following three operations as efficient as possible:
Hash Table is one possible good implementation for this Table ADT (the other one is this).
PS1: For two weaker implementations of Table ADT, you can click the respective link: unsorted array or a sorted array to read the detailed discussions.
PS2: In live class, you may want to compare the requirements of Table ADT vs List ADT.
When the range of the Integer keys is small, e.g., [0..M-1], we can use an initially empty (Boolean) array A of size M and implement the following Table ADT operations directly:
That's it, we use the small Integer key itself to determine the address in array A, hence the name Direct Addressing. It is clear that all three major Table ADT operations are O(1).
PS: This idea is also used elsewhere, e.g., in Counting Sort.
In Singapore (as of Apr 2023), bus routes are numbered from [2..991].
Not all integers between [2..991] are currently used, e.g., there is no bus route 989 — Search(989) should return false. A new bus route x may be introduced, i.e., Insert(x) or an existing bus route y may be discontinued, i.e., Remove(y).
As the range of possible bus routes is small, to record the data whether a bus route number exists or not, we can use a DAT with a Boolean array of size 1000 (generally, it is useful to give a few extra buffer cells on top of the current largest bus number of 991).
Notice that we can always add satellite data instead of just using a Boolean array to record the existence of the keys.
For example, we can use an associative String array A instead to map a bus route number to its operator name, e.g.,
A[2] = "Go-Ahead Singapore",
A[10] = "SBS Transit",
A[183] = "Tower Transit Singapore",
A[188] = "SMRT Buses", etc.
Discussion: Can you think of a few other real-life DAT examples?
The keys must be (or can be easily mapped to) non-negative Integer values. Note that basic DAT has problem in the full version of the example in the previous few slides as there are actually variations of bus route numbers in Singapore, e.g., 96B, 151A, NR10, etc.
The range of keys must be small.
The memory usage will be (insanely) large if we have (insanely) large range.
The keys must be dense, i.e., not many gaps in the key values.
DAT will contain too many empty (and wasted) cells otherwise.
We will overcome these restrictions with hashing.
Using hashing, we can:
For example, we have N = 400 Singapore phone numbers (Singapore phone number has 8 digits, so there are up to 10^8 = 100M possible phone numbers in Singapore).
Instead of using a DAT and use a gigantic array up to size M = 100 Million, we can use the following simple hash function h(v) = v%997.
This way, we map 8 digits phone numbers 6675 2378 and 6874 4483 into up to 3 digits h(6675 2378) = 237 and h(6874 4483) = 336, respectively. Therefore, we only need to prepare an array of size M = 997 (997 is a prime) instead of M = 100 Million.
With hashing, we can now implement the following Table ADT operations using Integer array (instead of Boolean array) as follows:
If we have keys that map to satellite data and we want to record the original keys too, we can implement the Hash Table using pair of (Integer, satellite-data-type) array as follows:
However, by now you should notice that something is incomplete...
A hash function may, and quite likely, map different keys (Integer or not) into the same Integer slot, i.e., a many-to-one mapping instead of one-to-one mapping.
For example, h(6675 2378) = 237 from three slides earlier and if we want to insert another phone number 6675 4372, we will have a problem as h(6675 4372) = 237 too.
This situation is called a collision, i.e., two (or more) keys have the same hash value.
The Birthday (von Mises) Paradox asks: 'How many people (number of keys) must be in a room (Hash Table) of size 365 seats (cells) before the probability that some person share a birthday (collision, two keys are hashed to the same cell), ignoring the leap years (i.e., all years have 365 days), becomes > 50 percent (i.e., more likely than not)?'
The answer, which maybe surprising for some of us, is .
Let's do some calculation.
Let Q(n) be the probability of unique birthday for n people in a room.
Q(n) = 365/365 × 364/365 × 363/365 × ... × (365-n+1)/365,
i.e., the first person's birthday can be any of the 365 days, the second person's birthday can be any of the 365 days except the first person's birthday, and so on.
Let P(n) be the probability of same birthday (collision) for n people in a room.
P(n) = 1-Q(n).
We compute that P(23) = 0.507 > 0.5 (50%).
Thus, we only need 23 people (a small amount of keys) in the room (Hash Table) of size 365 seats (cells) for a (more than) 50% chance collision to happen (the birthday of two different people in that room is one of 365 days/slots).
Issue 1: We have seen a simple hash function like the h(v) = v%997 used in Phone Numbers example that maps large range of Integer keys into a smaller range of Integer keys, but how about non Integer keys? How to do such hashing efficiently?
Issue 2: We have seen that by hashing, or mapping, large range into smaller range, there will very likely be a collision. How to deal with them?
How to create a good hash function with these desirable properties?
Suppose we have a hash table of size M where keys are used to identify the satellite-data and a specific hash function is used to compute a hash value.
A hash value/hash code of key v is computed from the key v with the use of a hash function to get an Integer in the range 0 to M-1. This hash value is used as the base/home index/address of the Hash Table entry for the satellite-data.
Using the Phone Numbers example, if we we define h(v) = floor(v/1 000 000),
i.e., we select the first two digits a phone number.
h(66 75 2378) = 66
h(68 74 4483) = 68
Discuss: What happen when you use that hash function? Hint: See this.
Before discussing the reality, let's discuss the ideal case: perfect hash functions.
A perfect hash function is a one-to-one mapping between keys and hash values, i.e., no collision at all. It is possible if all keys are known beforehand. For example, a compiler/interpreter search for reserved keywords. However, such cases are rare.
A minimal perfect hash function is achieved when the table size is the same as the number of keywords supplied. This case is even rarer.
If you are interested, you can explore GNU gperf, a freely available perfect hash function generator written in C++ that automatically constructs perfect functions (a C++ program) from a user supplied list of keywords.
People has tried various ways to hash a large range of Integers into a smaller range of Integers as uniformly as possible. In this e-Lecture, we jump directly to one of the best and most popular version: h(v) = v%M, i.e., map v into Hash Table of size M slots. The (%) is a modulo operator that gives the remainder after division. This is clearly fast, i.e., O(1) assuming that v does not exceed the natural Integer data type limit.
The Hash Table size M is set to be a reasonably large prime not near a power of 2, about 2+ times larger than the expected number of keys N that will ever be used in the Hash Table. This way, the load factor α = N/M < 0.5 — we shall see later that having low load factor, thereby sacrificing empty spaces, help improving Hash Table performance.
Discuss: What if we set M to be a power of 10 (decimal) or power of 2 (binary)?
People has also tried various ways to hash Strings into a small range of Integers as uniformly as possible. In this e-Lecture, we jump directly to one of the best and most popular version, shown below:
int hash_function(string v) { // assumption 1: v uses ['A'..'Z'] only
int sum = 0; // assumption 2: v is a short string
for (auto& c : v) // for each character c in v
sum = ((sum*26)%M + (c-'A'+1))%M; // M is table size
return sum;
}
Interactive (M = ∞), i.e., the modulo operation has no effect
v = , = 0.
Discussion: In real life class, discuss the components of the hash function above, e.g., why loop through all characters?, will that be slower than O(1)?, why multiply with 26?, what if the string v uses more than just UPPERCASE chars?, etc.
There are two major ideas: Closed Addressing versus Open Addressing method.
In Closed Addressing, the Hash Table looks like an Adjacency List (a graph data structure). The hash code of a key gives its fixed/closed base address. Collision is resolved by appending the collided keys inside an auxiliary data structure (usually any form of List ADT) identified by the base address.
In Open Addressing, all hashed keys are located in a single array. The hash code of a key gives its base address. Collision is resolved by checking/probing multiple alternative addresses (hence the name open) in the table based on a certain rule.
Separate Chaining (SC) collision resolution technique is simple. We use M copies of auxiliary data structures, usually Doubly Linked Lists. If two keys a and b both have the same hash value i, both will be appended to the (front/back) of Doubly Linked List i (in this visualization, we append to the back in O(1) with help of tail pointer). That's it, where the keys will be slotted in is completely dependent on the hash function itself, hence we also call Separate Chaining as Closed Addressing collision resolution technique.
If we use Separate Chaining, the load factor α = N/M is the average length of the M lists (unlike in Open Addressing, α can be "slightly over 1.0") and it will determine the performance of Search(v) as we may have to explore α elements on average. As Remove(v) also requires Search(v), its performance is similar as Search(v). Insert(v) is clearly O(1).
If we can bound α to be a small constant (true if we know the expected largest N in our Hash Table application so that we can set up M accordingly), then all Search(v), Insert(v), and Remove(v) operations using Separate Chaining will be O(1).
There are three Open Addressing (OA) collision resolution techniques discussed in this visualization: Linear Probing (LP), Quadratic Probing (QP), and Double Hashing (DH).
To switch between the three modes, please click on the respective header.
Let:
M = HT.length = the current hash table size,
base = (key%HT.length),
step = the current probing step,
secondary = smaller_prime - key%smaller_prime (to avoid zero — elaborated soon)
We will soon see that the probing sequences of the three modes are:
Linear Probing: i=(base+step*1) % M,
Quadratic Probing: i=(base+step*step) % M, and
Double Hashing: i=(base+step*secondary) % M.
All three OA techniques require that the load factor α = N/M < 1.0 (otherwise no more insertion is possible). If we can bound α to be a small constant (true if we know the expected largest N in our Hash Table application so that we can set up M accordingly, preferably < 0.5 for most OA variants), then all Search(v), Insert(v), and Remove(v) operations using Open Addressing will be O(1) — details omitted.
View the visualization of Hash Table above.
In this visualization, we allow the insertion of duplicate keys (i.e., a multiset). Since a multiset is more general than a set, simply just insert distinct integers in this visualization if you want to see how Hash Table works on distict integer keys only.
Due to limited screen space, we switch from default (1.0x) scale to 0.5x scale whenever you want to visualize Hash Table size M ∈ [46..90] for OA techniques. The limit is a bit lower, i.e., M ∈ [20..31] for SC technique.
The Hash Table is visualized horizontally like an array where index 0 is placed at the leftmost of the first row and index M-1 is placed at the rightmost of the last row but the details are different when we are visualizing Separate Chaining (only the top row) versus Open Addressing (usually spans multiple rows) collision resolution techniques.
For Separate Chaining (SC) collision resolution technique, the first row contains the M "H" (Head) pointers of M Doubly Linked Lists.
Then, each Doubly Linked List i contains all keys that are hashed into i in arbitrary order (in 0.5x scale, the vertex label is displayed on top of the smaller black dot). Mathematically, all keys that can be expressed as i (mod M) — including all duplicates of i — are hashed into DLL i. Again, we do not store any satellite data in this visualization.
There are three Open Addressing collision resolution techniques discussed in this visualization: Linear Probing (LP), Quadratic Probing (QP), and Double Hashing (DH).
For all three techniques, each Hash Table cell is displayed as a vertex with cell value of [0..99] displayed as the vertex label (in 0.5x scale, the vertex label is displayed on top of the smaller black dot). Without loss of generality, we do not show any satellite data in this visualization as we concentrate only on the arrangement of the keys. We reserve value -1 to indicate an 'EMPTY cell' (visualized as a blank vertex) and -2 to indicate a 'DELETED cell' (visualized as a vertex with abbreviated label "DEL"). The cell indices ranging from [0..M-1] are shown as red label below each vertex (rows of 15 indices in 1.0x scale or rows of 25 indices in 0.5x scale).
Try
to see how Insert(v) operation works if we use Separate Chaining as collision resolution technique. On such random insertions, the performance is good and each insertion is clearly O(1).However if we try
, notice that all Integers {68,90} are 2 (modulo 11) so all of them will be appended into the (back of) Doubly Linked List 2. We will have a long chain in that list. Note that due to the screen limitation, we limit the length of each Doubly Linked List to be at maximum 6.Try
to see that Search(v) can be made to run in O(1+α).Try
to see that Remove(v) can be made to run in O(1+α) too.If α is large, Separate Chaining performance is not really O(1). However, if we roughly know the potential maximum number of keys N that our application will ever use, then we can set table size M accordingly such that α = N/M is a very low positive (floating-point) number, thereby making Separate Chaining performances to be expected O(1).
In Linear Probing collision resolution technique, we scan forwards one index at a time for the next empty/deleted slot (wrapping around when we have reached the last slot) whenever there is a collision.
For example, let's assume we start with an empty Hash Table HT with table size M = HT.length = 7 as shown above that uses index 0 to M-1 = 7-1 = 6. Notice that 7 is a prime number. The (primary) hash function is simple, h(v) = v%M.
This walk-through will show you the steps taken by Insert(v), Search(v), and Remove(v) operations when using Linear Probing as collision resolution technique.
Now click
— three individual insertions in one command.Recap (to be shown after you click the button above).
Formally, we describe Linear Probing index i as i = (base+step*1) % M where base is the (primary) hash value of key v, i.e., h(v) and step is the Linear Probing step starting from 1.
Tips: To do a quick mental calculation of a (small) Integer V modulo M, we simply subtract V with the largest multiple of M ≤ V, e.g., 18%7 = 18-14 = 4, as 14 is the largest multiple of 7 that is ≤ 18.
Now click
(on top of the first three values inserted in the previous slide).Recap (to be shown after you click the button above)
Now we illustrate Search(v) operation while using Linear Probing as collision resolution technique. The steps taken are very similar as with Insert(v) operation, i.e., we start from the (primary) hash key value and check if we have found v, otherwise we move one index forward at a time (wrapping around if necessary) and recheck on whether we have found v. We stop when we encounter an empty cell which implies that v is not in Hash Table at all (as earlier Insert(v) operation would have placed v there otherwise).
Now click
— you should see probing sequence [0,1,2,3 (key 35 found)].Now click
— [1,2,3,4, 5 (empty cell, so key 8 is not found in the Hash Table)].Now let's discuss Remove(v) operation.
If we just set HT[i] = EMPTY cell straightaway where i is the index that contains v (after linear probing if necessary), do you realize that we will cause a problem? Why?
Hint: Review the past three slides on how Insert(v) and Search(v) behave.
Now let's see the complete Remove(v). If we find v at index i (after Linear Probing if necessary), we have to set HT[i] = DELETED (abbreviated as DEL in this visualization) where DEL is a special symbol (generally you should only use a symbol that is not used in your application) to indicate that cell can be by-passed if necessary by future Search(v), but can be overwritten by future Insert(w). This strategy is called Lazy Deletion.
Now click
— [0,1 (key 21 found and we set H[1] = DEL)].Afterwards, please continue the discussion in the next slide.
Now click
— [0,1 (bypassing that DELETED cell), 2,3 (found key 35)].Imagine what would have happened if we wrongly set H[1] = EMPTY.
Now click
— you should see probing sequence [0,1 (found a cell with DEL symbol)], so it is actually can be overwritten with a new value without affecting the correctness of future Search(v). Therefore, we put 28 in index 1.Although we can resolve collision with Linear Probing, it is not the most effective way.
We define a cluster to be a collection of consecutive occupied slots. A cluster that covers the base address of a key is called the primary cluster of the key.
Now notice that Linear Probing can create large primary clusters that will increase the running time of Search(v)/Insert(v)/Remove(v) operations beyond the advertised O(1).
See an example above with M = 31 and we have inserted 15 keys [0..14] so that they occupy cells [0..14] (α = 15/31 < 0.5). Now see how 'slow'
(the 16th key) is.The probe sequence of Linear Probing can be formally described as follows:
h(v) // base address
(h(v) + 1*1) % M // 1st probing step if there is a collision
(h(v) + 2*1) % M // 2nd probing step if there is still a collision
(h(v) + 3*1) % M // 3rd probing step if there is still a collision
...
(h(v) + k*1) % M // k-th probing step, etc...
During Insert(v), if there is a collision but there is an empty (or DEL) slot remains in the Hash Table, we are sure to find it after at most M Linear Probing steps, i.e., in O(M). And when we do, the collision will be resolved, but the primary cluster of the key v is expanded as a result and future Hash Table operations will get slower too. Try the slow
on the same Hash Table as in the previous slide but with many DEL markers (suppose {4, 5, 8, 9, 10, 12, 14} have just been deleted).In the previous slide (Primary Clustering, Part 1), we break the assumption that the hash function should uniformly distribute keys around [0..M-1]. In the next example, we will show that the problem of primary clustering can still happen even if the hash function distribute the keys into several relatively short primary clusters around [0..M-1].
On screen, you see M = 31 with 15 random integers between [0..99] inserted (there are several random but short primary clusters). If we then insert these next 4 keys {2, 9, 12, 1}, the first three keys will "plug" the three empty cells and accidentally annex (or combine) those neighboring (but previously disjointed) clusters into a (very) long primary cluster. So the next insertion of a key 1 that lands at (the beginning of) this long primary cluster will end up performing almost O(M) probing steps just to find an empty cell. Try
.To reduce primary clustering, we can modify the probe sequence to:
h(v) // base address
(h(v) + 1*1) % M // 1st probing step if there is a collision
(h(v) + 2*2) % M // 2nd probing step if there is still a collision
(h(v) + 3*3) % M // 3rd probing step if there is still a collision
...
(h(v) + k*k) % M // k-th probing step, etc...
That's it, the probe jumps quadratically, wrapping around the Hash Table as necessary.
A very common mistake as this is a different kind of Quadratic Probing:
Doing h(v), (h(v)+1) % M, (h(v)+1+4) % M, (h(v)+1+4+9) % M, ...
Assume that we have called Insert(18) and Insert(10) into an initially empty Hash Table of size M = HT.length = 7. As 18%7 = 4 and 10%7 = 3, 18 and 3 do not collide and both reside in index 4 and 3 respectively as shown above.
Now, let's click
.Recap (to be shown after you click the button above).
Remove(x) and Search(y) operations are defined similarly. Just that this time we use Quadratic Probing instead of Linear Probing.
For example, assume that we have called Remove(18) after the previous slide and we mark HT[4] = DEL. If we then call
, we will use the same Quadratic Probing sequence as with previous slide, but passing through HT[4] which marked as DELETED.In a glance, Quadratic Probing that jumps +1, +4, +9, +16, ... quadratically seems able to solve the primary clustering issue that we have with Linear Probing earlier, but is it the perfect collision resolution technique?
Try
.Do you realized what has just happened?
We can insert 12 easily as h(12) = 12%7 = 5 was empty previously (see above).
However we have major problem inserting key 17 even if we still have 3 empty slots as:
h(17) = 17%7 = 3 is already occupied by key 10,
(3+1*1) % 7 = 4 is already occupied by key 18,
(3+2*2) % 7 = 0 is already occupied by key 38,
(3+3*3) % 7 = 5 is already occupied by key 12,
(3+4*4) % 7 = 5 again is already occupied by key 12,
(3+5*5) % 7 = 0 again is already occupied by key 38,
(3+6*6) % 7 = 4 again is already occupied by key 18,
(3+7*7) % 7 = 3 again is already occupied by key 10,
it will cycle forever if we continue the Quadratic Probing...
Although we still have a few (3) empty cells, we are unable to insert this new value 17 into the Hash Table...
If α < 0.5 and M is a prime (> 3), then we can always find an empty slot using (this form of) Quadratic Probing. Recall: α is the load factor and M is the Hash Table size (HT.length).
If the two requirements above are satisfied, we can prove that the first M/2 Quadratic Probing indices, including the base address h(v) are all distinct and unique.
But there is no such guarantee beyond that. Hence if we want to use Quadratic Probing, we need to ensure that α < 0.5 (not enforced in this visualization but we do break the loop after M steps to prevent infinite loop).
We will use proof by contradiction. We first assume that two Quadratic Probing steps:
x and y, x != y (let's say x < y), can yield the same address modulo M.
h(v) + x*x = h(v) + y*y (mod M)
x*x = y*y (mod M) // strike out h(v) from both sides
x*x - y*y = 0 (mod M) // move y*y to LHS
(x-y)*(x+y) = 0 (mod M) // rearrange the formula
Now, either (x-y) or (x+y) has to be equal to zero.
As our assumption says x != y, then (x-y) cannot be 0.
As 0 ≤ x < y ≤ (M/2) and M is a prime > 3 (an odd Integer),
then (x+y) also cannot be 0 modulo M.
Contradiction!
So the first M/2 Quadratic Probing steps cannot yield the same address modulo M
(if we set M to be a prime number greater than 3).
Discussion: Can we make Quadratic Probing able to use the other ~50% of the table cells?
In Quadratic Probing, clusters are formed along the path of probing, instead of around the base address like in Linear Probing. These clusters are called Secondary Clusters and it is 'less visible' compared to the Primary Clusters that plagued the Linear Probing.
Secondary clusters are formed as a result of using the same pattern in probing by colliding keys, i.e., if two distinct keys have the same base address, their Quadratic Probing sequences are going to be the same.
To illustrate this, see the screen with M = 31. We have populated this Hash Table with only 10 keys (so load factor α = 10/31 ≤ 0.5) and the Hash Table looks 'sparse enough' (no visibly big primary cluster). However, if we then insert
, despite the fact that there are many (31-10 = 21) empty cells and 62 != 93 (different keys that ends up hashed into index 0), we end up doing 10 probing steps along this 'less visible' secondary cluster (notice that both {62, 93} follow similar Quadratic Probing sequences).Secondary clustering in Quadratic Probing is not as bad as primary clustering in Linear Probing as a good hash function should theoretically disperse the keys into different base addresses ∈ [0..M-1] in the first place.
To reduce primary and secondary clustering, we can modify the probe sequence to:
h(v) // base address
(h(v) + 1*h2(v)) % M // 1st probing step if there is a collision
(h(v) + 2*h2(v)) % M // 2nd probing step if there is still a collision
(h(v) + 3*h2(v)) % M // 3rd probing step if there is still a collision
...
(h(v) + k*h2(v)) % M // k-th probing step, etc...
That's it, the probe jumps according to the value of the second hash function h2(v), wrapping around the Hash Table as necessary.
If h2(v) = 1, then Double Hashing works exactly the same as Linear Probing.
So we generally wants h2(v) > 1 to avoid primary clustering.
If h2(v) = 0, then Double Hashing does not work for an obvious reason as any probing step multiplied by 0 remains 0, i.e. we stay at the base address forever during a collision. We need to avoid this.
Usually (for Integer keys), h2(v) = M' - v%M' where M' is a smaller prime than M.
This makes h2(v) ∈ [1..M'], which is diverse enough to avoid secondary clustering.
The usage of the secondary hash function makes it theoretically hard to have either primary or secondary clustering issue.
Click
to insert 35 and then 42 to the current Hash Table above.Recap (to be shown after you click the button above).
Remove(x) and Search(y) operations are defined similarly. Just that this time we use Double Hashing instead of Linear Probing or Quadratic Probing.
For example, assume that we have called Remove(17) after the previous slide and we mark HT[3] = DEL. If we then call
, we will use the same Double Hashing sequence as with previous slide, but passing through HT[3] which marked as DELETED.In summary, a good Open Addressing collision resolution technique needs to:
Now, let's see the same test case that plagues Quadratic Probing earlier. Now try again. Although h(62) = h(93) = 0 and their collide with 31 that already occupy index 0, their probing steps are not the same: h2(62) = 29-62%29 = 25 is not the same as h2(93) = 29-93%29 = 23.
Discussion: Double Hashing seems to fit the bill. But... Is Double Hashing strategy flexible enough to be used as the default library implementation of a Hash Table? Or in a more general sense, which of the two collision resolution technique (Separate Chaining versus Open Addressing: Double Hashing) is the better one?
You have reached the end of the basic stuffs of this Hash Table data structure and we encourage you to explore further in the Exploration Mode.
However, we still have a few more interesting Hash Table challenges for you that are outlined in this section.
The performance of Hash Table degrades when the load factor α gets higher. For (standard) Quadratic Probing collision resolution technique, insertions might fail when the Hash Table has α > 0.5.
If that happens, we can rehash. We build another Hash Table about twice as big with a new hash function. We go through all keys in the original Hash Table, recompute the new hash values, and re-insert the keys (with their satellite-data) into the new, bigger Hash Table, before finally we delete the older, smaller Hash Table.
A rule of thumb is to rehash when α ≥ 0.5 if using Open Addressing and when α > small constant (close to 1.0, as per requirement) if using Separate Chaining.
If we know the maximum number of total possible keys, we can always influence α to be a low number.
However, if you ever need to implement a Hash Table in C++, Python, or Java, and your keys are either Integers or Strings, you can use the built-in C++ STL, Python standard library, or Java API, respectively. They already have good built-in implementation of default hash functions for Integers or Strings.
See C++ STL std::unordered_map, std::unordered_set, Python dict, set, or Java HashMap, HashSet.
For C++, note that the std::multimap/std::multiset implementations are also exist where duplicate keys are allowed.
For OCaml, we can use Hashtbl.
However, here is our take of a simple Separate Chaining implementation: HashTableDemo.cpp | py | java.
Hash Table is an extremely good data structure to implement Table ADT if the (Integer or String) keys only need to be mapped to satellite-data, with O(1) performance for Search(v), Insert(v), and Remove(v) operations if the Hash Table is set up properly.
However, if we need to do much more with the keys, we may need to use an alternative data structure.
For a few more interesting questions about this data structure, please practice on Hash Table training module (no login is required, but short and of medium difficulty setting only).
However, for registered users, you should login and then go to the Main Training Page to officially clear this module and such achievement will be recorded in your user account.
Try to solve a few basic programming problems that somewhat requires the usage of Hash Table (especially if the input size is much larger):