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I have to write an algorithm for Assigning Contiguous seats in a seat map.For example: allocating seats in a stadium. The seat map can be viewed as a 2d array of N rows and M columns. The system must assign contiguous seats for bookings that are made together. Since no seat map is presented to the user, the system should automatically assign the available seats corresponding to each purchase. In addition to this, it should do this in such a fashion such that the holes/gaps in the seats are minimized.

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Does "I have to" mean that this is homework? Also, what's the question? And you have it tagged as both Java and C...they're quite different languages. –  AusCBloke Nov 6 '11 at 8:22
    
Do you know all the bookings in advance, or dou you receive them one by one and assign them on the fly? –  JB Nizet Nov 6 '11 at 8:26
    
Its not a howework but I am looking for an algorithm to solve this problem. The problem is that we have a seat map containing N rows and M columns. The seats should be assigned contiguously for bookings that are made together. This means that tif user ask for 3 seats then 3 seats should be contiguous. And this seat allocation should also be done in a fashion such that the holes or gaps in the seat map are minimized. –  imsinha Nov 6 '11 at 8:30
    
No, we dont know all the bookings in advance. We assign them one by one. Its similar to the case of booking theatre seats for a movie.The users come and asks for a number of seats and system allocates the seats to them. –  imsinha Nov 6 '11 at 8:33
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3 Answers 3

up vote 2 down vote accepted

Finding a perfect solution is NP-hard. Look at the equivalent language problem:
L={((x1,x2,...,xk),n,m)} where xi are the number of co-booked tickets, and n,m are the stadium sizes.

We will show Partition <=(P) L, and thus this problem is NP-Hard, and there is no known polynomial solution for it.

Proof
let S=(x1,x2,..,xk) be the input for a partition problem, and let sum=x1+...+xk
Look at the following reduction:

Input: S=(x1,...,xk)
Output:((x1,...,xk),sum/2,2)

Correctness: If S has a partition, let it be S1=(x_i1,x_i2,...,x_it), then by definition of partition, x_i1+...+x_it=sum/2, and thus we can insert x_i1,..,x_it in the first row, and the rest in the second row, and so ((x1,...,xk),sum/2,2) is in L
If ((x1,...,xk),sum/2,2) is in L, then by definition there are t bookings such that x_i1,x_i2,...,x_it form a perfect first line, and thus x_i1+x_i2+...+x_it=sum/2, and thus it is a valid partition and S is in Partition problem

Conclusion:
Since L is NP-Hard, and the problem you seek is the optimization problem for this language, there is no known polynomial solution for it. For an exact solution you can use backtracking [check all possibilities, and choose the best], but it will take a lot of time, or you can sattle for a heuristic solution, such as greedy, but it will not be optimized.

EDIT: Backtracking solution [pseudocode]:

solve(X,n,m):
   global bestVal <- infinity
   global bestSol <- null
   solve(X,new Solution(n,m))
solve(X,solution):
   if (X is empty):
       gaps <- solution.numGaps()
       if (gaps < bestVal):
            bestVal <- gaps
            bestSol <- solution
       return
   temp <- X.first
   X.removeFirst()
   for i from 0 to m:
       solution.addToLine(i,temp)
       solve(X,solution)
       solution.removeFromLine(i,temp)
   X.addFirst(temp)

Assuming Solution is an implemented class, and for an illegal solution [i.e. too many people in one row] numGaps() == infinity

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Note

This is usually not a real problem, because if you are able to sell all your tickets - the last buyers will either compromise and break their bookings into separate bookings, or withdraw, and allow other buyers with different booking-size requirements to buy the remaining seats.

Moreover, people like to select their seats. If you want to ban this option - they may select not to buy tickets at all.

Note that if the buyers have no control over their seats, you may as well given them a code, and translate this code into a specific seat once all the tickets are sold.

Answer for the posed problem:

Each row has m seats. We will assume that the largest booking-size is m (otherwise, we'll have to break it into several bookings).

First, we should model the discrete probability distribution function for the booking-size. This can be constructed based on data from previous events. (A more advanced model may consider the event-type, event-time etc.). Let us call this function f(b)

It is trivial that the best strategy would be to fill rows from left to right (or from right to left), and not leaving empty gaps - which would only force more constrains.

Let us suppose that the stadium contains a single row. We can calculate the probability of filling the whole row, by enumerating all possible booking-sizes. We can use the method suggested here for the enumeration, multiplying each bookings-size with its probability, and summing it up.

Now, assume that there are 2 rows in the stadium, and that the first booking-size was 3. Now there is a row with m empty seats, and another row with m-3 empty seats. The second booking size is 4. Now we can compare the probability of filling a (m-4) seats row, and the probability filling a (m-3-4) seats row. We will assign seats for the current booking accordingly.

Of course, the probability of filling an empty row is 1, and once filled it should be removed from the non-filled rows list.

In general, for each booking, we can assign it to the row that the probability for filling it (after the assignment) would be maximized.

Note that given f(b), all these probabilities can be calculated in advance for any constant between 1 and m.

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You should look at memory allocation algorithms for operating systems. This best models your problem. you should focus on algorithms that minimize fragmentation.

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