package example.localplugin; import gridsim.dcworms.DCWormsTags; import java.util.ArrayList; import java.util.HashMap; import java.util.List; import java.util.Map; import schedframe.events.scheduling.SchedulingEvent; import schedframe.resources.ResourceStatus; import schedframe.resources.computing.ComputingResource; import schedframe.resources.computing.Processor; import schedframe.resources.units.ProcessingElements; import schedframe.resources.units.ResourceUnit; import schedframe.resources.units.ResourceUnitName; import schedframe.resources.units.StandardResourceUnitName; import schedframe.scheduling.manager.resources.ClusterResourceManager; import schedframe.scheduling.manager.resources.ResourceManager; import schedframe.scheduling.manager.tasks.JobRegistry; import schedframe.scheduling.plan.SchedulingPlanInterface; import schedframe.scheduling.plan.impl.SchedulingPlan; import schedframe.scheduling.plugin.grid.ModuleList; import schedframe.scheduling.queue.TaskQueue; import schedframe.scheduling.queue.TaskQueueList; import schedframe.scheduling.tasks.TaskInterface; public class FCFSBF_DFSClusterPlugin extends BaseLocalSchedulingPlugin { List allocatedCPUs; public FCFSBF_DFSClusterPlugin () { allocatedCPUs = new ArrayList(); } public SchedulingPlanInterface schedule(SchedulingEvent event, TaskQueueList queues, JobRegistry jobRegistry, ResourceManager resManager, ModuleList modules) { ClusterResourceManager resourceManager = (ClusterResourceManager) resManager; SchedulingPlan plan = new SchedulingPlan(); // our tasks are placed only in first queue (see // BaseLocalPlugin.placeJobsInQueues() method) TaskQueue q = queues.get(0); // chose the events types to serve. // Different actions for different events are possible. switch (event.getType()) { case START_TASK_EXECUTION: case TASK_FINISHED: // check all tasks in queue for (int i = 0; i < q.size(); i++) { TaskInterface task = q.get(i); // if status of the tasks in READY if (task.getStatus() == DCWormsTags.READY) { Map choosenResources = chooseResourcesForExecution(resourceManager, task); if (choosenResources != null) { addToSchedulingPlan(plan, task, choosenResources); } } } adjustFrequency(resourceManager.getProcessors()); } return plan; } private Map chooseResourcesForExecution( ClusterResourceManager resourceManager, TaskInterface task) { Map map = new HashMap(); int cpuRequest; try { cpuRequest = Double.valueOf(task.getCpuCntRequest()).intValue(); } catch (NoSuchFieldException e) { cpuRequest = 1; } if (cpuRequest != 0) { List choosenResources = null; List processors = resourceManager.getProcessors(); processors.removeAll(allocatedCPUs); if (processors.size() < cpuRequest) { // log.warn("Task requires more cpus than is availiable in this resource."); return null; } choosenResources = new ArrayList(); for (int i = 0; i < processors.size() && cpuRequest > 0; i++) { if (processors.get(i).getStatus() == ResourceStatus.FREE) { choosenResources.add(processors.get(i)); cpuRequest--; } } if (cpuRequest > 0) { // log.info("Task " + task.getJobId() + "_" + task.getId() + // " requires more cpus than is availiable in this moment."); return null; } ProcessingElements result = new ProcessingElements(); result.addAll(choosenResources); map.put(StandardResourceUnitName.PE, result); } return map; } private void adjustFrequency(List processors){ for(Processor cpu: processors){ if(cpu.getStatus() == ResourceStatus.FREE) { if(cpu.getPowerInterface().getSupportedPStates().containsKey("P3")) cpu.getPowerInterface().setPState("P3"); } else{ if(cpu.getPowerInterface().getSupportedPStates().containsKey("P0")) cpu.getPowerInterface().setPState("P0"); } } } }