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I encounter a problem when coding an integer linear program in pyomo. The model I want to implement is supposed to find the optimal schedule for a set of tasks. Specifically, we want to schedule employees' trainings for a number of periods ahead.

One key constraint to consider is that there is not an unlimited number of trainers/coaches available each period to give the respective trainings. I.e. we have to impose a capacity constraint in each period. To guarantee that the solver can always find a solution, I also include a slack variable for the capacity constraint and penalize for it in the objective. A small, replicable example is included below.

Problem: profiling the code below revealed that, when building the model, pyomo spends most of the time required to build the model in building the capacity constraint (the last constraint in the code snippet below). When scaling this up to the size of the actual application, the time to build just that constraint becomes prohibitive. That is, excluding the time spend on solving the problem, just building the model takes several (read: >8) hours. Excluding the capacity constraint brings this down to less than ten minutes.

Questions: 1. Is there an obvious reason why the build time for that constraint is so much higher than for any of the others? I am confused by the fact that, for my application the number of employees (E below) is going to be ~2,000, while the number of departments ~5 and the number periods ~30. Therefore, the number of rows added by the first and second constraint to the overall constraint matrix is much higher than by the capacity constraint. Admittedly, the capacity constraint has to sum over a large number of elements, but that I expect to be a cheap operation. Am I wrong? 2. Is there a more efficient syntax to code that constraint? 2a. Would it help to move to an AbstractModel() ? 2b. Would it help if I moved K (python dictionary) to some kind of Pyomo Set?

Here is a small example, which I hope helps inspecting the issue:

Replicable example:

from pyomo.environ import *

#set of employees
E = ['emp0', 'emp1']
#set of trainings per employee
J = ['train0', 'train1']
#periods in our planning horizon
T = [0, 1, 2]
#departments that have to provide trainers
DP = ['dept1', 'dept2']


#value for the company from each employee taking a training in particular period (want to maximize the sum over this)
v = {('emp0', 'train0', 0): 3,
     ('emp0', 'train0', 1): 0,
     ('emp0', 'train0', 2): 3,
     ('emp0', 'train1', 0): 9,
     ('emp0', 'train1', 1): 4,
     ('emp0', 'train1', 2): 8,
     ('emp1', 'train0', 0): 3,
     ('emp1', 'train0', 1): 0,
     ('emp1', 'train0', 2): 8,
     ('emp1', 'train1', 0): 7,
     ('emp1', 'train1', 1): 0,
     ('emp1', 'train1', 2): 7}

#M is a penalty for using the slack variable that leads the algorithm to violate the capacity constraint
M = 50000

#departments capacity in each period
K = {('dept1', 0): 10000,
     ('dept1', 1): 10000,
     ('dept1', 2): 10000,
     ('dept2', 0): 10000,
     ('dept2', 1): 10000,
     ('dept2', 2): 10000}

#number of coaches neeeded per employee-training-department-period capacity needed
a = {('emp0', 'train0', 'dept1', 0): 2,
     ('emp0', 'train0', 'dept2', 0): 2,
     ('emp0', 'train0', 'dept1', 1): 2,
     ('emp0', 'train0', 'dept2', 1): 1,
     ('emp0', 'train0', 'dept1', 2): 0,
     ('emp0', 'train0', 'dept2', 2): 2,
     ('emp0', 'train1', 'dept1', 0): 0,
     ('emp0', 'train1', 'dept2', 0): 1,
     ('emp0', 'train1', 'dept1', 1): 1,
     ('emp0', 'train1', 'dept2', 1): 0,
     ('emp0', 'train1', 'dept1', 2): 0,
     ('emp0', 'train1', 'dept2', 2): 1,
     ('emp1', 'train0', 'dept1', 0): 2,
     ('emp1', 'train0', 'dept2', 0): 1,
     ('emp1', 'train0', 'dept1', 1): 2,
     ('emp1', 'train0', 'dept2', 1): 0,
     ('emp1', 'train0', 'dept1', 2): 1,
     ('emp1', 'train0', 'dept2', 2): 0,
     ('emp1', 'train1', 'dept1', 0): 0,
     ('emp1', 'train1', 'dept2', 0): 1,
     ('emp1', 'train1', 'dept1', 1): 2,
     ('emp1', 'train1', 'dept2', 1): 1,
     ('emp1', 'train1', 'dept1', 2): 2,
     ('emp1', 'train1', 'dept2', 2): 2}

#duration of training per employee
D = {('emp0', 'train0'): 4,
     ('emp0', 'train1'): 4,
     ('emp1', 'train0'): 4,
     ('emp1', 'train1'): 3}

# Model setup:
model = ConcreteModel() 

model.J = Set(initialize = J)
model.E = Set(initialize = E)
model.T = Set(initialize = T)
model.EJ = Set(initialize = model.E*model.J)
model.EJT = Set(initialize = model.EJ*model.T)

model.x = Var(model.EJT, within=Binary)
model.y = Var(model.EJT, within=Binary)
model.R = Var(T, DP, within = NonNegativeIntegers, initialize = 0)

#objective: maximize the total value of trainings minus the penalty for violating the capacity constraint
def obj_rule(m):
    return sum(v[e,j,t]*m.x[e,j,t] for e in E for j in J for t in T) \
            - sum(m.R[t,dp] for dp in DP for t in T)*M 
model.obj = Objective(rule=obj_rule, sense = maximize)

#start each employee-training once
def one_per_emp_rule(m, e, j, t):
    return sum(m.x[e,j,t] for t in m.T)==1
model.one_per_emp_rule = Constraint(E, J, T, rule=one_per_emp_rule)

#for the duration of each training keep y=1
def y1_for_duration(m, e, j, t):
    return m.y[e,j,t] == sum(m.x[e,j,t] for t in T[max((t-D[e,j]+1), 0):t+1])         
model.y1_for_duration = Constraint(E, J, T, rule=y1_for_duration)    

# sum up all the consumed capacity across all employees per period, to check if departments can handle it
def period_capacity_dept(m, e, j, t, dp):
    return sum(a[e, j, dp, t]*m.y[e,j,t] for (e,j) in model.EJ)<= K[dp,t] + m.R[t,dp] 
model.period_capacity_dept = Constraint(E, J, T, DP, rule=period_capacity_dept)

# hand over to solver:

opt = SolverFactory('glpk')
results = opt.solve(model, tee=True)
results.write()
model.solutions.load_from(results)

for v in model.component_objects(Var, active=True):
    print ("Variable",v)
    varobject = getattr(model, str(v))
    for index in varobject:
        print ("   ",index, varobject[index].value)
  • 1
    @Norbs Welcome to Stack Overflow! I wonder whether this question would be a better fit for Code Review? I don't think it's off topic here, but it's also not a common type of question here. – jpaugh Sep 20 at 21:56
0

In the equation

def period_capacity_dept(m, e, j, t, dp):
    return sum(a[e, j, dp, t]*m.y[e,j,t] for (e,j) in model.EJ)<= K[dp,t] + m.R[t,dp] 
model.period_capacity_dept = Constraint(E, J, T, DP, rule=period_capacity_dept)

you should drop the function arguments e, j. Now you repeat the same constraint many times. You can see this by executing model.period_capacity_dept.pprint(). This shows:

period_capacity_dept : Size=24, Index=period_capacity_dept_index, Active=True
    Key                            : Lower : Body                                                                                                   : Upper : Active
    ('emp0', 'train0', 0, 'dept1') :  -Inf :                                         2*y[emp1,train0,0] + 2*y[emp0,train0,0] - (10000 + R[0,dept1]) :   0.0 :   True
    ('emp0', 'train0', 0, 'dept2') :  -Inf :     y[emp0,train1,0] + y[emp1,train0,0] + y[emp1,train1,0] + 2*y[emp0,train0,0] - (10000 + R[0,dept2]) :   0.0 :   True
    ('emp0', 'train0', 1, 'dept1') :  -Inf : y[emp0,train1,1] + 2*y[emp1,train0,1] + 2*y[emp1,train1,1] + 2*y[emp0,train0,1] - (10000 + R[1,dept1]) :   0.0 :   True
    ('emp0', 'train0', 1, 'dept2') :  -Inf :                                             y[emp1,train1,1] + y[emp0,train0,1] - (10000 + R[1,dept2]) :   0.0 :   True
    ('emp0', 'train0', 2, 'dept1') :  -Inf :                                           y[emp1,train0,2] + 2*y[emp1,train1,2] - (10000 + R[2,dept1]) :   0.0 :   True
    ('emp0', 'train0', 2, 'dept2') :  -Inf :                      y[emp0,train1,2] + 2*y[emp1,train1,2] + 2*y[emp0,train0,2] - (10000 + R[2,dept2]) :   0.0 :   True
    ('emp0', 'train1', 0, 'dept1') :  -Inf :                                         2*y[emp1,train0,0] + 2*y[emp0,train0,0] - (10000 + R[0,dept1]) :   0.0 :   True
    ('emp0', 'train1', 0, 'dept2') :  -Inf :     y[emp0,train1,0] + y[emp1,train0,0] + y[emp1,train1,0] + 2*y[emp0,train0,0] - (10000 + R[0,dept2]) :   0.0 :   True
    ('emp0', 'train1', 1, 'dept1') :  -Inf : y[emp0,train1,1] + 2*y[emp1,train0,1] + 2*y[emp1,train1,1] + 2*y[emp0,train0,1] - (10000 + R[1,dept1]) :   0.0 :   True
    ('emp0', 'train1', 1, 'dept2') :  -Inf :                                             y[emp1,train1,1] + y[emp0,train0,1] - (10000 + R[1,dept2]) :   0.0 :   True
    ('emp0', 'train1', 2, 'dept1') :  -Inf :                                           y[emp1,train0,2] + 2*y[emp1,train1,2] - (10000 + R[2,dept1]) :   0.0 :   True
    ('emp0', 'train1', 2, 'dept2') :  -Inf :                      y[emp0,train1,2] + 2*y[emp1,train1,2] + 2*y[emp0,train0,2] - (10000 + R[2,dept2]) :   0.0 :   True
    ('emp1', 'train0', 0, 'dept1') :  -Inf :                                         2*y[emp1,train0,0] + 2*y[emp0,train0,0] - (10000 + R[0,dept1]) :   0.0 :   True
    ('emp1', 'train0', 0, 'dept2') :  -Inf :     y[emp0,train1,0] + y[emp1,train0,0] + y[emp1,train1,0] + 2*y[emp0,train0,0] - (10000 + R[0,dept2]) :   0.0 :   True
    ('emp1', 'train0', 1, 'dept1') :  -Inf : y[emp0,train1,1] + 2*y[emp1,train0,1] + 2*y[emp1,train1,1] + 2*y[emp0,train0,1] - (10000 + R[1,dept1]) :   0.0 :   True
    ('emp1', 'train0', 1, 'dept2') :  -Inf :                                             y[emp1,train1,1] + y[emp0,train0,1] - (10000 + R[1,dept2]) :   0.0 :   True
    ('emp1', 'train0', 2, 'dept1') :  -Inf :                                           y[emp1,train0,2] + 2*y[emp1,train1,2] - (10000 + R[2,dept1]) :   0.0 :   True
    ('emp1', 'train0', 2, 'dept2') :  -Inf :                      y[emp0,train1,2] + 2*y[emp1,train1,2] + 2*y[emp0,train0,2] - (10000 + R[2,dept2]) :   0.0 :   True
    ('emp1', 'train1', 0, 'dept1') :  -Inf :                                         2*y[emp1,train0,0] + 2*y[emp0,train0,0] - (10000 + R[0,dept1]) :   0.0 :   True
    ('emp1', 'train1', 0, 'dept2') :  -Inf :     y[emp0,train1,0] + y[emp1,train0,0] + y[emp1,train1,0] + 2*y[emp0,train0,0] - (10000 + R[0,dept2]) :   0.0 :   True
    ('emp1', 'train1', 1, 'dept1') :  -Inf : y[emp0,train1,1] + 2*y[emp1,train0,1] + 2*y[emp1,train1,1] + 2*y[emp0,train0,1] - (10000 + R[1,dept1]) :   0.0 :   True
    ('emp1', 'train1', 1, 'dept2') :  -Inf :                                             y[emp1,train1,1] + y[emp0,train0,1] - (10000 + R[1,dept2]) :   0.0 :   True
    ('emp1', 'train1', 2, 'dept1') :  -Inf :                                           y[emp1,train0,2] + 2*y[emp1,train1,2] - (10000 + R[2,dept1]) :   0.0 :   True
    ('emp1', 'train1', 2, 'dept2') :  -Inf :                      y[emp0,train1,2] + 2*y[emp1,train1,2] + 2*y[emp0,train0,2] - (10000 + R[2,dept2]) :   0.0 :   True

If we use:

def period_capacity_dept(m, t, dp):
    return sum(a[e, j, dp, t]*m.y[e,j,t] for (e,j) in model.EJ)<= K[dp,t] + m.R[t,dp] 
model.period_capacity_dept = Constraint(T, DP, rule=period_capacity_dept)

you will see:

period_capacity_dept : Size=6, Index=period_capacity_dept_index, Active=True
    Key          : Lower : Body                                                                                                   : Upper : Active
    (0, 'dept1') :  -Inf :                                         2*y[emp1,train0,0] + 2*y[emp0,train0,0] - (10000 + R[0,dept1]) :   0.0 :   True
    (0, 'dept2') :  -Inf :     y[emp1,train0,0] + y[emp0,train1,0] + 2*y[emp0,train0,0] + y[emp1,train1,0] - (10000 + R[0,dept2]) :   0.0 :   True
    (1, 'dept1') :  -Inf : 2*y[emp1,train0,1] + y[emp0,train1,1] + 2*y[emp0,train0,1] + 2*y[emp1,train1,1] - (10000 + R[1,dept1]) :   0.0 :   True
    (1, 'dept2') :  -Inf :                                             y[emp0,train0,1] + y[emp1,train1,1] - (10000 + R[1,dept2]) :   0.0 :   True
    (2, 'dept1') :  -Inf :                                           y[emp1,train0,2] + 2*y[emp1,train1,2] - (10000 + R[2,dept1]) :   0.0 :   True
    (2, 'dept2') :  -Inf :                      y[emp0,train1,2] + 2*y[emp0,train0,2] + 2*y[emp1,train1,2] - (10000 + R[2,dept2]) :   0.0 :   True

Now all the duplicate constraints are omitted.

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