use of org.cpsolver.studentsct.heuristics.selection.CriticalStandardSelection in project cpsolver by UniTime.
the class StudentSctNeighbourSelection method setup.
public void setup(Solver<Request, Enrollment> solver) {
if (iMPP)
registerSelection(new AssignInitialSelection(solver.getProperties()));
if (iPriorityStudentsFirstSelection && iPriorityStudentsFirstAllIn) {
if (iUseCriticalCoursesSelection) {
for (StudentPriority sp : StudentPriority.values()) {
if (sp == StudentPriority.Normal)
break;
for (int pr = 0; pr < iPriorityRounds; pr++) {
// last round >> include all students up to the selected priority
boolean includeHigherPriority = (iPriorityLastRoundAllStudents && sp.ordinal() > 0 && (pr + 1 == iPriorityRounds));
StudentFilter filter = new PriortyStudentFilter(sp, includeHigherPriority);
for (RequestPriority rp : RequestPriority.values()) {
for (int cr = 0; cr < iCriticalRounds; cr++) {
registerSelection(new CriticalCoursesBranchAndBoundSelection(solver.getProperties(), rp).withFilter(filter));
registerSelection(new CriticalBacktrackSelection(solver.getProperties(), rp).withFilter(filter));
registerSelection(new CriticalStandardSelection(solver.getProperties(), new UnassignedRequestSelection().withFilter(filter), getValueSelection(), rp));
registerSelection(new CriticalBacktrackSelection(solver.getProperties(), rp).withFilter(filter));
}
}
}
}
} else {
for (StudentPriority sp : StudentPriority.values()) {
if (sp == StudentPriority.Normal)
break;
for (int pr = 0; pr < iPriorityRounds; pr++) {
// last round >> include all students up to the selected priority
boolean includeHigherPriority = (iPriorityLastRoundAllStudents && sp.ordinal() > 0 && (pr + 1 == iPriorityRounds));
StudentFilter filter = new PriortyStudentFilter(sp, includeHigherPriority);
registerSelection(new BranchBoundSelection(solver.getProperties()).withFilter(filter));
registerSelection(new BacktrackSelection(solver.getProperties()).withFilter(filter));
registerSelection(new StandardSelection(solver.getProperties(), new UnassignedRequestSelection().withFilter(filter), getValueSelection()));
registerSelection(new BacktrackSelection(solver.getProperties()).withFilter(filter));
}
}
}
}
if (iUseCriticalCoursesSelection) {
for (RequestPriority rp : RequestPriority.values()) {
if (rp == RequestPriority.Normal)
break;
for (int cr = 0; cr < iCriticalRounds; cr++) {
registerSelection(new CriticalCoursesBranchAndBoundSelection(solver.getProperties(), rp));
registerSelection(new CriticalBacktrackSelection(solver.getProperties(), rp));
registerSelection(new CriticalStandardSelection(solver.getProperties(), getValueSelection(), rp));
registerSelection(new CriticalBacktrackSelection(solver.getProperties(), rp));
}
}
}
if (iPriorityStudentsFirstSelection && !iPriorityStudentsFirstAllIn) {
for (StudentPriority sp : StudentPriority.values()) {
if (sp == StudentPriority.Normal)
break;
if (((StudentSectioningModel) solver.currentSolution().getModel()).getNbrStudents(sp) == 0)
continue;
for (int pr = 0; pr < iPriorityRounds; pr++) {
// last round >> include all students up to the selected priority
boolean includeHigherPriority = (iPriorityLastRoundAllStudents && sp.ordinal() > 0 && (pr + 1 == iPriorityRounds));
StudentFilter filter = new PriortyStudentFilter(sp, includeHigherPriority);
registerSelection(new BranchBoundSelection(solver.getProperties()).withFilter(filter));
registerSelection(new BacktrackSelection(solver.getProperties()).withFilter(filter));
registerSelection(new StandardSelection(solver.getProperties(), new UnassignedRequestSelection().withFilter(filter), getValueSelection()));
registerSelection(new BacktrackSelection(solver.getProperties()).withFilter(filter));
}
}
}
if (iUseMinCreditSelection)
registerSelection(new MinCreditBranchAndBoundSelection(solver.getProperties()));
// Phase 1: section all students using incremental branch & bound (no
// unassignments)
registerSelection(iUseConstruction && !iUseMinCreditSelection ? new PriorityConstructionSelection(solver.getProperties()) : new BranchBoundSelection(solver.getProperties()));
// Phase 2: pick a student (one by one) with an incomplete schedule, try
// to find an improvement
registerSelection(new SwapStudentSelection(solver.getProperties()));
// Phase 3A: use backtrack neighbour selection
registerSelection(new BacktrackSelection(solver.getProperties()));
// Phase 3B: enrollment swap selection
registerSelection(new StudentEnrollmentSwapSelection(solver.getProperties()));
// Phase 4: use standard value selection for some time
registerSelection(new StandardSelection(solver.getProperties(), getVariableSelection(), getValueSelection()));
// Phase 5: pick a student (one by one) with an incomplete schedule, try
// to find an improvement, identify problematic students
SwapStudentSelection swapStudentSelection = new SwapStudentSelection(solver.getProperties());
registerSelection(swapStudentSelection);
// Phase 6: random unassignment of some problematic students
registerSelection(new RndUnProblStudSelection(solver.getProperties(), swapStudentSelection));
// Phase 7: resection incomplete students
registerSelection(new ResectionIncompleteStudentsSelection(solver.getProperties()));
// Phase 8: resection of students that were unassigned in step 6
registerSelection(new ResectionUnassignedStudentsSelection(solver.getProperties()));
// Phase 9: pick a student (one by one) with an incomplete schedule, try
// to find an improvement
registerSelection(new SwapStudentSelection(solver.getProperties()));
// Phase 10: use standard value selection for some time
registerSelection(new StandardSelection(solver.getProperties(), new RouletteWheelRequestSelection(solver.getProperties()), getValueSelection()));
// Phase 11: pick a student (one by one) with an incomplete schedule,
// try to find an improvement
registerSelection(new SwapStudentSelection(solver.getProperties()));
// Phase 12A: enrollment swap selection
registerSelection(new StudentEnrollmentSwapSelection(solver.getProperties()));
// Phase 12B: use backtrack neighbour selection
registerSelection(new BacktrackSelection(solver.getProperties()));
if (iShuffleStudentsSelection) {
// Phase 13: try shuffling students around request groups
registerSelection(new ShuffleStudentsSelection(solver.getProperties()));
// Phase 14: use backtrack neighbour selection to fix unassignments from the previous phase
registerSelection(new BacktrackSelection(solver.getProperties()));
}
// Phase 15: reset to best if no improvement has been done in the last cycle
registerSelection(new RestoreBestSolution(solver.getProperties()));
// Phase 16: use backtrack neighbour selection
registerSelection(new BacktrackSelection(solver.getProperties()));
// Phase 17: section all students using incremental branch & bound
registerSelection(new BranchBoundSelection(solver.getProperties()));
// Phase 18: random unassignment of some students
registerSelection(new RandomUnassignmentSelection(solver.getProperties()));
}
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