You can regard this problem as a graph problem: covering a bipartite graph by a set of disjoint subgraphs while respecting the two partitions (students, groups) and maximising the cover of one partition (students)
I'm thinking of this heuristic:
- start with an empty solution
- while there are unassigned students and open (less than six members) groups:
- sort the unassigned students by the order of free slots
- pick six students from the top of the list (read the list from the top until you find a group that six students can attend) and use them as a group.
- If you cannot pick six students, pick the largest amount you can.
- If you cannot find three students that form a group, but you have two:
- Find a third studend for that group that is currently assigned to a group that you can take from (more than three people), and use him to fill the group. Prefer groups that can be refilled from the unassigned set
- If you cannot find a third person, take one from a different 3-member group. Recurse the search for his replacement in that group (or give up). You can attempt to remove from different three-member groups in parallel.
- If you only have one student, see if you can fill any of his groups by two other people from other groups. If needed, replace them recursively or give up.
- If you have a student whose all candidate groups are already full, look for a person in any of these group that can't be moved to a non-full group. If all replacement groups are already full, recurse.
- If you can't find a way to shift people around to satisfy any unassigned student, finish
Note that this boils down to this:
Quickly find a solution that satisfies the most people (you could stop here). Then try to insert students by finding a chain of pairings that:
- alternates between used and unused pairings
- starts at the student
- ends at a class
Note this is isomorphic to finding an alternating path in a bipartite graph, and can be optimised as such.
Note that this may still fail to find the optimal solution, as it never replaces more than one person in a single group to satisfy a person.
The pseudocode above instructs to resort the list of students at each step. Instead, you could track the changes to this list and update the sorting order while making the updates.
Update: I didn't notice you wanted to assign teachers as well.
In this case, you need to assign a teacher to a group when you assign students to it. This will prevent creation of some groups, but if there is no free teacher, you can take teachers from different groups if you can assign a different teacher to that group. Again, it's just searching for an alternating graph, this time in the teacher-group subgraph - shuffling students around to free up a teacher doesn't seem viable.
The entire graph that you want to cover now has three partitions: students, teachers, groups. Teachers and students don't interact, so there are two layers: students-groups, groups-teachers. These two layers are independent except they must cover the same set of groups.