# Allocating and scheduling tasks into rooms with conditions - optimization algorithm

I need to find a suitable method to be based on, for developing an optimization algorithm which does the following:

Let's say we have N tasks to do, and we have M rooms that each one of them contains some specific number of infrastructure/conditions. Each task demands using room with a suitable conditions for the task.

For example, to get task A done we need to use water tap and gas piping, so we can only use rooms that contain those ones.

Also, for each task we have a predefined due date.

I hope I've explained it well enough.

So, I need to develop an algorithm which can allocate the tasks for each room in a proper scheduling, so I could do all of the tasks at the minimum total time and without exceeding deadline times (and if exceeding is inevitable, then getting the least worst answer).

What are an existing methods or algorithm I can get based on and learn from them? I though about 'Job Shop', but I wonder if there are other suitable algorithms that can handle problems like that.

This is not an algorithm but a Mixed Integer Programming model. I am not sure if this is what you are looking for.

Assumptions: only one job can execute at the same time in a room. Jobs in different rooms can execute in parallel. Also, to keep things simple, I assume the problem is feasible (the model will detect infeasible problems but we don't return a solution if this is the case).

So we introduce a number of decision variables:

``````assign(i,j) = 1 if task i is assigned to room j
0 otherwise

finish(i) = time job i is done processing

makespan = finishing time of the last job
``````

With this we can formulate the MIP model: The following data is used:

``````Length(i) = processing time of job i
M = a large enough constant (say the planning horizon)
DueDate(i) = time job i must be finished
Allowed(i,j) = Yes if job i can be executed in room j
``````

Importantly, I assume jobs are ordered by due date. The first constraint says: if job i runs in room j then it finishes just after the previous jobs running in that room. The second constraint is a bound: a job must finish before its due date. The third constraint says: each job must be assigned to exactly one room where it is allowed to execute. Finally, the makespan is the last finish time.

To test this, I generated some random data:

``````----     37 SET use  resource usage

resource1   resource2   resource3   resource4   resource5

----     37 SET avail  resource availability

resource1   resource2   resource3   resource4   resource5

room1                     YES         YES         YES         YES
room2                                 YES         YES
room3                                             YES         YES
room4         YES         YES         YES                     YES
room5         YES                     YES         YES         YES
``````

The set `Allowed` is calculated from `use(i,r)` and `avail(j,r)` data:

``````----     41 SET allowed  task is allowed to be executed in room

room1       room2       room3       room4       room5

task1          YES         YES         YES         YES         YES
task4          YES         YES         YES         YES         YES
task6          YES         YES         YES         YES         YES
task8          YES         YES         YES         YES         YES
task10         YES         YES         YES         YES         YES
task18         YES         YES         YES         YES         YES
task19         YES         YES         YES         YES         YES
task22         YES         YES         YES         YES         YES
task27         YES         YES         YES         YES         YES
task29         YES         YES         YES         YES         YES
task30         YES         YES         YES         YES         YES
``````

We also have random due dates and processing times:

``````----     33 PARAMETER length  job length

----     33 PARAMETER due  job due dates

``````

When I run this model, I get as results:

``````----    129 PARAMETER results

start      length      finish     duedate

``````

Detail: based on the assignment I recalculated the start and finish times. The model can allow some slack here and there as long as it does not interfere with the objective and the due dates. To get rid of any possible slacks, I just execute all jobs as early as possible. Just back-to-back execution of jobs in the same room using the job ordering (remember I sorted jobs according to due date).

This model with 30 jobs and 10 rooms took 20 seconds using Cplex. Gurobi was about the same.

Augmenting the model to handle infeasible models is not very difficult. Allow jobs to violate the due date but at a price. A penalty term needs to be added to the objective. The due date constraint is in the above example a hard constraint, and with this technique, we make it a soft constraint.

• Thank you so much for the detailed answer. I'm definitely gonna use this method and learn it deeply. One thing I'm not sure is, is this a model you've just defined at Cplex and ran it? Or is it based on some existing method? I'd like to know the source of the methods I'm getting based on, and not just developing something and that's it. Thank you so much again. – Snir May 8 at 7:57
• Cplex is a commercial solver for LP, MIP (and some quadratic) models. It is based on the simplex and interior-point method for LPs and branch-and-bound for MIPs. However, any reasonable MIP solver will do. They are readily available (both open source and commercial). – Erwin Kalvelagen May 8 at 12:42

Within CPLEX you can rely on MIP but you could also use CPOptimizer scheduling.

In OPL your model would look like

``````using CP;

int N = 30; // nbTasks
int M = 10; // rooms

range Rooms = 1..M;

int possible[j in Tasks][m in Rooms] = (rand(10)>=8);

dvar interval itvs[j in Tasks][o in Rooms] optional in 0..100 size taskDuration[j] ;
dvar sequence rooms[m in Rooms] in all(j in Tasks) itvs[j][m];

execute {
cp.param.FailLimit = 10000;
}

subject to {
// alternative

// one room is for one task at most at the same time
forall (m in Rooms)
noOverlap(rooms[m]);

// due dates

}
``````

and give I used a small variant of Alex's OPL CP Optimizer model on the data and it finds the optimal solution (makespan=19.432) within a couple of seconds and proves optimality in about 5s on my laptop. I think a big advantage of a CP Optimizer model is that it would scale to much larger instances and easily produce good quality solutions even if, for large instances, proving optimality may be challenging of course.

Here is my version of the CP Optimizer model:

``````using CP;

int N = 30; // Number of tasks
int M = 5;  // Number of rooms
int Length [1..N] = ...; // Task length
int DueDate[1..N] = ...; // Task due date
{int} Rooms[1..N] = ...; // Possible rooms for task

tuple Alloc { int job; int room; }
{Alloc} Allocs = {<i,r> | i in 1..N, r in Rooms[i]};

dvar interval task[i in 1..N] in 0..DueDate[i] size Length[i];
dvar interval alloc[a in Allocs] optional;

subject to {
forall(i in 1..N) { alternative(task[i], all(r in Rooms[i]) alloc[<i,r>]); }
forall(r in 1..M) { noOverlap(all(a in Allocs: a.room==r) alloc[a]); }
}
``````

Note also that the MIP model exploits a problem specific dominance rule that the tasks allocated to a particular room can be ordered by increasing due-date. While this is perfectly true for this simple version of the problem, this assumption may not hold anymore in the presence of additional constraints (as for instance a minimal start time for the tasks). The CP Optimizer formulation does not make this assumption.

In Pyomo Erwin's MIP can be implemented like:

``````        ################################################################################
# Sets
################################################################################

model.I = Set(initialize=self.resource_usage.keys(), doc='jobs to run')
model.J = Set(initialize=self.resource_availability.keys(), doc='rooms')
model.ok = Set(initialize=self.ok.keys())

################################################################################
# Params put at model
################################################################################

model.length = Param(model.I, initialize=self.length)
model.due_date = Param(model.I, initialize=self.due_date)

################################################################################
# Var
################################################################################

model.x = Var(model.I, model.J, domain=Boolean, initialize=0, doc='job i is assigned to room j')
model.finish = Var(model.I, domain=NonNegativeReals, initialize=0, doc='finish time of job i')
model.makespan = Var(domain=NonNegativeReals, initialize=0)

################################################################################
# Constraints
################################################################################

M = 100

def all_jobs_assigned_c(model, i):
return sum(model.x[ii, jj] for (ii, jj) in model.ok if ii == i) == 1

model.all_jobs_assigned_c = Constraint(model.I, rule=all_jobs_assigned_c)

def finish1_c(model, i, j):
return sum(
model.length[ii] * model.x[ii, jj] for (ii, jj) in model.ok if jj == j and ii <= i
) - M * (1 - model.x[i, j]) <= model.finish[i]

model.finish1_c = Constraint(model.I, model.J, rule=finish1_c)

model.finish2_c = Constraint(
model.I, rule=lambda model, i: model.finish[i] <= model.due_date[i]
)

model.makespan_c = Constraint(
model.I, rule=lambda model, i: model.makespan >= model.finish[i]
)

################################################################################
# Objective
################################################################################
def obj_profit(model):
return model.makespan

model.objective = Objective(rule=obj_profit, sense=minimize)
``````

Solving with CBC took with 4 cores about 2min and results in: 