Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

There seems to be a large amount of information about Cyclic (or "Rotating") Workforce Scheduling problems. I am searching for an algorithm that will help generate a schedule of employee shifts that does not care what the previous week's schedule looked like. From my research, this sounds like a non-cyclic workforce scheduling problem.

Essentially, I have the employee's availability, their min/max hours, and their requested time off. With that information, I want to create an optimized schedule that caters to the employee's desired availability while also meeting the number of required shifts for each day.

Does anyone have tips on a good algorithm for this purpose? Thanks!

share|improve this question
Did you find more details on this question ? – kursus May 31 '15 at 22:18
The project was put on hold, but I'm going to be revisiting it soon. The answer below really does provide the best information. You're either stuck with a suboptimal greedy algorithm, or constraint programming. – Luke Sapan May 31 '15 at 22:23
up vote 1 down vote accepted

For problems like employee scheduling where there are a lot of constraints on the solution, I prefer approaches that never violate any constraints, or as near as possible. (Some approaches such as genetic crossover will violate constraints and then perform additional operations to fix the solution - this is also a valid approach, but you need to beware of going down a blind alley.)

Two approaches are based on using a greedy algorithm.

The first is to use a semi random greedy algorithm; if you have two choices then ordinarily you would always select the locally optimal choice, but with a semi random greedy approach you introduce the possibility of selecting the choice that isn't locally optimal. For example choice one has a weight of 5 and choice two has a weight of 2; ordinarily you would select choice one, but in this case you would use a random number generator and select choice one if rand(5 + 2) is less than 5, else select choice two. Now run the algorithm several times and take the "best" solution.

The second option is to start with a greedy or semi random greedy solution, and to use a local search algorithm to reassign employee slots in an attempt to improve the solution. For example, if an employee has fewer than their desired hours then bump an employee occupying a slot that's legal for the sub optimal employee and assign the sub optimal emoloyee to it, continuing the search to reassign the bumped employee if need be. Unlike the first solution, this one may not terminate if you're not careful.

The two approaches can be combined, generating several solutions with the semi random greedy approach and then conducting local searches to improve the best results.

share|improve this answer
Thank you for your answer, it is very insightful. I've been doing some research into using constraint programming. Unfortunately most of the resources online seem very over complicated. Ideally though, would you agree constraint programming would yield the best solution (potentially with even easier code)? – Luke Sapan Aug 9 '13 at 22:37
@Luke Sapan If you're willing to make the investment, then constraint programming is an excellent approach for this type of problem, and there are numerous libraries that are available. The nice thing about constraint programming when applied to real world problems is that if a constraint is added or removed then you usually don't have to completely rework everything, whereas changing the constraints in something like a genetic algorithm can be a lot more complicated. – Zim-Zam O'Pootertoot Aug 9 '13 at 22:47

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.