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A number of students want to get into sections for a class, some are already signed up for one section but want to change section, so they all get on the wait lists. A student can get into a new section only if someone drops from that section. No students are willing to drop a section they are already in unless that can be sure to get into a section they are waiting for. The wait list for each section is first come first serve.

Get as many students into their desired sections as you can.

The stated problem can quickly devolve to a gridlock scenario. My question is; are there known solutions to this problem?


One trivial solution would be to take each section in turn and force the first student from the waiting list into the section and then check if someone end up dropping out when things are resolved (O(n) or more on the number of section). This would work for some cases but I think that there might be better options involving forcing more than one student into a section (O(n) or more on the student count) and/or operating on more than one section at a time (O(bad) :-)

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Haha O(bad) <-- lovely. –  Filip Ekberg Jan 9 '09 at 21:40
    
Marked as 'homework'. This may not be your homework, but it could be someone's at some point, since I had this very question in college a few years ago. –  George Stocker Jan 9 '09 at 21:41
    
changed to not-my-homework to better reflect reality –  BCS Jan 9 '09 at 21:44
    
hahah "Not-my-homework". So if i were to find an answer for "my homework" this actually says that it's not MY homework? :/ Oh god.. I'm lost.. –  Filip Ekberg Jan 9 '09 at 21:45
    
The tag is meant to describe the question, not its owner. –  George Stocker Jan 9 '09 at 21:48

3 Answers 3

Well, this just comes down to finding cycles in the directed graph of classes right? each link is a student that wants to go from one node to another, and any time you find a cycle, you delete it, because those students can resolve their needs with each other. You're finished when you're out of cycles.

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Not quite because of the requirement that a student get into a new class if they drop an old one and the Queue aspect of the wait list. Where should the edge point from the /second/ person in the list? –  BCS Jan 9 '09 at 21:52
    
oh yes, I read the question too fast. oh second thought, I probably don't understand it. Why can't you just drop the cycle, unless you're saying "dropping a cycle requires the first dropper to be in a class-less limbo until the cycle is resolved, and that isn't an option"? –  Jimmy Jan 9 '09 at 21:56
    
The problem is the cycles are very large and every student must appear twice in the cycle. If x, y, and z want to swap, you can only do it if x, y, and z are first on the waiting list. If a is before y on list 2, you have to move a or find a loop include x, y, z and a. –  jmucchiello Jan 9 '09 at 22:35
    
instead of making each edge a student, make it a sorted linked list of students, if you "delete" the cycle, just pop the first student of each edge, and only delete it if there's no more students in the queue. –  krusty.ar Jan 10 '09 at 13:08

Ok, lets try. We have 8 students (1..8) and 4 sections. Each student is in a section and each section has room for 2 students. Most students want to switch but not all.

In the table below, we see the students their current section, their required section and the position on the queue (if any).

+------+-----+-----+-----+
| stud | now | req | que |
+------+-----+-----+-----+
|    1 |   A |   D |   2 |
|    2 |   A |   D |   1 |
|    3 |   B |   B |   - |
|    4 |   B |   A |   2 |
|    5 |   C |   A |   1 |
|    6 |   C |   C |   - |
|    7 |   D |   C |   1 |
|    8 |   D |   B |   1 |
+------+-----+-----+-----+

We can present this information in a graph:

+-----+           +-----+           +-----+
|  C  |---[5]--->1|  A  |2<---[4]---|  B  |
+-----+           +-----+           +-----+
   1               |   |               1
   ^               |   |               ^
   |              [1] [2]              |
   |               |   |               |
  [7]              |   |              [8]
   |               V   V               |
   |               2   1               |
   |              +-----+              |
   \--------------|  D  |--------------/
                  +-----+

We try to find a section with a vacancy, but we find none. So because all sections are full, we need a dirty trick. So lets take a random section with a non empty queue. In this case section A and assume, it has an extra position. This means student 5 can enter section A, leaving a vacancy at section C which is taken by student 7. This leaves a vacancy in section D which is taken by student 2. We now have a vacancy at section A. But we assumed that section A has an extra position, so we can remove this assumption and have gained a simpler graph.

If the path never returned to section A, undo the moves and mark A as an invalid startingpoint. Retry with another section. If there are no valid sections left we are finished.

Right now we have the following situation:

+-----+           +-----+           +-----+
|  C  |           |  A  |1<---[4]---|  B  |
+-----+           +-----+           +-----+
                   |                   1
                   |                   ^
                  [1]                  |
                   |                   |
                   |                  [8]
                   V                   |
                   1                   |
                  +-----+              |
                  |  D  |--------------/
                  +-----+

We repeat the trick with another random section, and this solves the graph.

If you start with several students currently not assigned, you add an extra dummy section as their startingpoint. Of course, this means that there must be vacancies in any sections or the problem is not solvable.

Note that due to the order in the queue, it can be possible that there is no solution.

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Good answer. but I'm still not shure that it will always work. To show that it most be shown that if any solution exist at all then you can reduce the problem by adding ONE student to some section. You might be able to find a case where to get ant reduction you need to force in 2 or more students. –  BCS Jan 9 '09 at 23:15
    
I can imagine that there are situations that can only be solved by reshuffling the queues. The goal is to maximize collective happiness, not individual happiness so queue order can be ignored if there are no other solutions. –  Toon Krijthe Mar 24 '11 at 7:34
    
If the queue is interpreted as weighted edges, then the problem can be cast to finding the least weight per edge cycle and rotating it. OTOH you can construct a case that this finds a solution that moves the ideal number of people but jumps the queue and I can't convince myself that it won't also be less than ideal in some cases. –  BCS Mar 24 '11 at 12:01

This is actually a Graph problem. You can think of each of these waiting list dependencies as edges on a directed graph. If this graph has a cycle, then you have one of the situations you described. Once you have identified a cycle, you can chose any point to "break" the cycle by "over filling" one of the classes, and you will know that things will settle correctly because there was a cycle in the graph.

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See my comment to Jimmy –  BCS Jan 9 '09 at 21:53

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