BinPackedMaxMin with piston capping

schedulers/bpMaxMinPistonCapping.go

@@ -0,0 +1,421 @@
+package schedulers
+
+import (
+	"bitbucket.org/sunybingcloud/electron/constants"
+	"bitbucket.org/sunybingcloud/electron/def"
+	"bitbucket.org/sunybingcloud/electron/rapl"
+	"errors"
+	"fmt"
+	"github.com/golang/protobuf/proto"
+	mesos "github.com/mesos/mesos-go/mesosproto"
+	"github.com/mesos/mesos-go/mesosutil"
+	sched "github.com/mesos/mesos-go/scheduler"
+	"log"
+	"math"
+	"os"
+	"sort"
+	"strings"
+	"sync"
+	"time"
+)
+
+// Decides if to take an offer or not
+func (s *BPMaxMinPistonCapping) takeOffer(offer *mesos.Offer, task def.Task) bool {
+
+	cpus, mem, watts := OfferAgg(offer)
+
+	//TODO: Insert watts calculation here instead of taking them as a parameter
+
+	if cpus >= task.CPU && mem >= task.RAM && watts >= task.Watts {
+		return true
+	}
+
+	return false
+}
+
+type BPMaxMinPistonCapping struct {
+	base         //Type embedding to inherit common functions
+	tasksCreated int
+	tasksRunning int
+	tasks        []def.Task
+	metrics      map[string]def.Metric
+	running      map[string]map[string]bool
+	taskMonitor  map[string][]def.Task
+	totalPower   map[string]float64
+	ignoreWatts  bool
+	ticker       *time.Ticker
+	isCapping    bool
+
+	// First set of PCP values are garbage values, signal to logger to start recording when we're
+	// about to schedule a new task
+	RecordPCP bool
+
+	// This channel is closed when the program receives an interrupt,
+	// signalling that the program should shut down.
+	Shutdown chan struct{}
+	// This channel is closed after shutdown is closed, and only when all
+	// outstanding tasks have been cleaned up
+	Done chan struct{}
+
+	// Controls when to shutdown pcp logging
+	PCPLog chan struct{}
+
+	schedTrace *log.Logger
+}
+
+// New electron scheduler
+func NewBPMaxMinPistonCapping(tasks []def.Task, ignoreWatts bool, schedTracePrefix string) *BPMaxMinPistonCapping {
+	sort.Sort(def.WattsSorter(tasks))
+
+	logFile, err := os.Create("./" + schedTracePrefix + "_schedTrace.log")
+	if err != nil {
+		log.Fatal(err)
+	}
+
+	s := &BPMaxMinPistonCapping{
+		tasks:       tasks,
+		ignoreWatts: ignoreWatts,
+		Shutdown:    make(chan struct{}),
+		Done:        make(chan struct{}),
+		PCPLog:      make(chan struct{}),
+		running:     make(map[string]map[string]bool),
+		taskMonitor: make(map[string][]def.Task),
+		totalPower:  make(map[string]float64),
+		RecordPCP:   false,
+		ticker:      time.NewTicker(5 * time.Second),
+		isCapping:   false,
+		schedTrace:  log.New(logFile, "", log.LstdFlags),
+	}
+	return s
+
+}
+
+func (s *BPMaxMinPistonCapping) newTask(offer *mesos.Offer, task def.Task) *mesos.TaskInfo {
+	taskName := fmt.Sprintf("%s-%d", task.Name, *task.Instances)
+	s.tasksCreated++
+
+	// Start recording only when we're creating the first task
+	if !s.RecordPCP {
+		// Turn on logging
+		s.RecordPCP = true
+		time.Sleep(1 * time.Second) // Make sure we're recording by the time the first task starts
+	}
+
+	// If this is our first time running into this Agent
+	if _, ok := s.running[offer.GetSlaveId().GoString()]; !ok {
+		s.running[offer.GetSlaveId().GoString()] = make(map[string]bool)
+	}
+
+	// Add task to list of tasks running on node
+	s.running[offer.GetSlaveId().GoString()][taskName] = true
+
+	// Setting the task ID to the task. This is done so that we can consider each task to be different
+	// even though they have the same parameters.
+	task.SetTaskID(*proto.String("electron-" + taskName))
+	// Add task to list of tasks running on node
+	if len(s.taskMonitor[*offer.Hostname]) == 0 {
+		s.taskMonitor[*offer.Hostname] = []def.Task{task}
+	} else {
+		s.taskMonitor[*offer.Hostname] = append(s.taskMonitor[*offer.Hostname], task)
+	}
+
+	resources := []*mesos.Resource{
+		mesosutil.NewScalarResource("cpus", task.CPU),
+		mesosutil.NewScalarResource("mem", task.RAM),
+	}
+
+	if !s.ignoreWatts {
+		resources = append(resources, mesosutil.NewScalarResource("watts", task.Watts))
+	}
+
+	return &mesos.TaskInfo{
+		Name: proto.String(taskName),
+		TaskId: &mesos.TaskID{
+			Value: proto.String("electron-" + taskName),
+		},
+		SlaveId:   offer.SlaveId,
+		Resources: resources,
+		Command: &mesos.CommandInfo{
+			Value: proto.String(task.CMD),
+		},
+		Container: &mesos.ContainerInfo{
+			Type: mesos.ContainerInfo_DOCKER.Enum(),
+			Docker: &mesos.ContainerInfo_DockerInfo{
+				Image:   proto.String(task.Image),
+				Network: mesos.ContainerInfo_DockerInfo_BRIDGE.Enum(), // Run everything isolated
+			},
+		},
+	}
+}
+
+func (s *BPMaxMinPistonCapping) Disconnected(sched.SchedulerDriver) {
+	// Need to stop the capping process
+	s.ticker.Stop()
+	bpMaxMinPistonCappingMutex.Lock()
+	s.isCapping = false
+	bpMaxMinPistonCappingMutex.Unlock()
+	log.Println("Framework disconnected with master")
+}
+
+// mutex
+var bpMaxMinPistonCappingMutex sync.Mutex
+
+// go routine to cap each node in the cluster at regular intervals of time
+var bpMaxMinPistonCappingCapValues = make(map[string]float64)
+
+// Storing the previous cap value for each host so as to not repeatedly cap the nodes to the same value. (reduces overhead)
+var bpMaxMinPistonCappingPreviousRoundedCapValues = make(map[string]int)
+
+func (s *BPMaxMinPistonCapping) startCapping() {
+	go func() {
+		for {
+			select {
+			case <-s.ticker.C:
+				// Need to cap each node
+				bpMaxMinPistonCappingMutex.Lock()
+				for host, capValue := range bpMaxMinPistonCappingCapValues {
+					roundedCapValue := int(math.Floor(capValue + 0.5))
+					// has the cap value changed
+					if previousRoundedCap, ok := bpMaxMinPistonCappingPreviousRoundedCapValues[host]; ok {
+						if previousRoundedCap != roundedCapValue {
+							if err := rapl.Cap(host, "rapl", roundedCapValue); err != nil {
+								log.Println(err)
+							} else {
+								log.Printf("Capped [%s] at %d", host, int(math.Floor(capValue)))
+							}
+							bpMaxMinPistonCappingPreviousRoundedCapValues[host] = roundedCapValue
+						}
+					} else {
+						if err := rapl.Cap(host, "rapl", roundedCapValue); err != nil {
+							log.Println(err)
+						} else {
+							log.Printf("Capped [%s] at %d", host, int(math.Floor(capValue+0.5)))
+						}
+						bpMaxMinPistonCappingPreviousRoundedCapValues[host] = roundedCapValue
+					}
+				}
+				bpMaxMinPistonCappingMutex.Unlock()
+			}
+		}
+	}()
+
+}
+
+// Stop the capping
+func (s *BPMaxMinPistonCapping) stopCapping() {
+	if s.isCapping {
+		log.Println("Stopping the capping.")
+		s.ticker.Stop()
+		bpMaxMinPistonCappingMutex.Lock()
+		s.isCapping = false
+		bpMaxMinPistonCappingMutex.Unlock()
+	}
+}
+
+// Determine if the remaining sapce inside of the offer is enough for
+// the task we need to create. If it is, create a TaskInfo and return it.
+func (s *BPMaxMinPistonCapping) CheckFit(i int,
+	task def.Task,
+	offer *mesos.Offer,
+	totalCPU *float64,
+	totalRAM *float64,
+	totalWatts *float64,
+	partialLoad *float64) (bool, *mesos.TaskInfo) {
+
+	offerCPU, offerRAM, offerWatts := OfferAgg(offer)
+
+	// Does the task fit
+	if (s.ignoreWatts || (offerWatts >= (*totalWatts + task.Watts))) &&
+		(offerCPU >= (*totalCPU + task.CPU)) &&
+		(offerRAM >= (*totalRAM + task.RAM)) {
+
+		*totalWatts += task.Watts
+		*totalCPU += task.CPU
+		*totalRAM += task.RAM
+		log.Println("Co-Located with: ")
+		coLocated(s.running[offer.GetSlaveId().GoString()])
+
+		taskToSchedule := s.newTask(offer, task)
+
+		fmt.Println("Inst: ", *task.Instances)
+		s.schedTrace.Print(offer.GetHostname() + ":" + taskToSchedule.GetTaskId().GetValue())
+		*task.Instances--
+		*partialLoad += ((task.Watts * constants.CapMargin) / s.totalPower[*offer.Hostname]) * 100
+
+		if *task.Instances <= 0 {
+			// All instances of task have been scheduled, remove it
+			s.tasks = append(s.tasks[:i], s.tasks[i+1:]...)
+
+			if len(s.tasks) <= 0 {
+				log.Println("Done scheduling all tasks")
+				close(s.Shutdown)
+			}
+		}
+
+		return true, taskToSchedule
+	}
+
+	return false, nil
+}
+
+func (s *BPMaxMinPistonCapping) ResourceOffers(driver sched.SchedulerDriver, offers []*mesos.Offer) {
+	log.Printf("Received %d resource offers", len(offers))
+
+	for _, offer := range offers {
+		select {
+		case <-s.Shutdown:
+			log.Println("Done scheduling tasks: declining offer on [", offer.GetHostname(), "]")
+			driver.DeclineOffer(offer.Id, longFilter)
+
+			log.Println("Number of tasks still running: ", s.tasksRunning)
+			continue
+		default:
+		}
+
+		tasks := []*mesos.TaskInfo{}
+
+		offerTaken := false
+		totalWatts := 0.0
+		totalCPU := 0.0
+		totalRAM := 0.0
+		// Store the partialLoad for host corresponding to this offer
+		// Once we can't fit any more tasks, we update the capValue for this host using partialLoad and then launch the fit tasks.
+		partialLoad := 0.0
+
+		// Assumes s.tasks is ordered in non-decreasing median max peak order
+
+		// Attempt to schedule a single instance of the heaviest workload available first
+		// Start from the back until one fits
+		for i := len(s.tasks) - 1; i >= 0; i-- {
+
+			task := s.tasks[i]
+			// Check host if it exists
+			if task.Host != "" {
+				// Don't take offer if it doesn't match our task's host requirement
+				if !strings.HasPrefix(*offer.Hostname, task.Host) {
+					continue
+				}
+			}
+
+			// TODO: Fix this so index doesn't need to be passed
+			taken, taskToSchedule := s.CheckFit(i, task, offer, &totalCPU, &totalRAM, &totalWatts, &partialLoad)
+
+			if taken {
+				offerTaken = true
+				tasks = append(tasks, taskToSchedule)
+				break
+			}
+		}
+
+		// Pack the rest of the offer with the smallest tasks
+		for i, task := range s.tasks {
+
+			// Check host if it exists
+			if task.Host != "" {
+				// Don't take offer if it doesn't match our task's host requirement
+				if !strings.HasPrefix(*offer.Hostname, task.Host) {
+					continue
+				}
+			}
+
+			for *task.Instances > 0 {
+				// TODO: Fix this so index doesn't need to be passed
+				taken, taskToSchedule := s.CheckFit(i, task, offer, &totalCPU, &totalRAM, &totalWatts, &partialLoad)
+
+				if taken {
+					offerTaken = true
+					tasks = append(tasks, taskToSchedule)
+				} else {
+					break // Continue on to next task
+				}
+			}
+		}
+
+		if offerTaken {
+			// Updating the cap value for offer.Hostname
+			bpMaxMinPistonCappingMutex.Lock()
+			bpMaxMinPistonCappingCapValues[*offer.Hostname] += partialLoad
+			bpMaxMinPistonCappingMutex.Unlock()
+			log.Printf("Starting on [%s]\n", offer.GetHostname())
+			driver.LaunchTasks([]*mesos.OfferID{offer.Id}, tasks, defaultFilter)
+		} else {
+
+			// If there was no match for the task
+			fmt.Println("There is not enough resources to launch a task:")
+			cpus, mem, watts := OfferAgg(offer)
+
+			log.Printf("<CPU: %f, RAM: %f, Watts: %f>\n", cpus, mem, watts)
+			driver.DeclineOffer(offer.Id, defaultFilter)
+		}
+	}
+}
+
+// Remove finished task from the taskMonitor
+func (s *BPMaxMinPistonCapping) deleteFromTaskMonitor(finishedTaskID string) (def.Task, string, error) {
+	hostOfFinishedTask := ""
+	indexOfFinishedTask := -1
+	found := false
+	var finishedTask def.Task
+
+	for host, tasks := range s.taskMonitor {
+		for i, task := range tasks {
+			if task.TaskID == finishedTaskID {
+				hostOfFinishedTask = host
+				indexOfFinishedTask = i
+				found = true
+			}
+		}
+		if found {
+			break
+		}
+	}
+
+	if hostOfFinishedTask != "" && indexOfFinishedTask != -1 {
+		finishedTask = s.taskMonitor[hostOfFinishedTask][indexOfFinishedTask]
+		log.Printf("Removing task with TaskID [%s] from the list of running tasks\n",
+			s.taskMonitor[hostOfFinishedTask][indexOfFinishedTask].TaskID)
+		s.taskMonitor[hostOfFinishedTask] = append(s.taskMonitor[hostOfFinishedTask][:indexOfFinishedTask],
+			s.taskMonitor[hostOfFinishedTask][indexOfFinishedTask+1:]...)
+	} else {
+		return finishedTask, hostOfFinishedTask, errors.New("Finished Task not present in TaskMonitor")
+	}
+	return finishedTask, hostOfFinishedTask, nil
+}
+
+func (s *BPMaxMinPistonCapping) StatusUpdate(driver sched.SchedulerDriver, status *mesos.TaskStatus) {
+	log.Printf("Received task status [%s] for task [%s]", NameFor(status.State), *status.TaskId.Value)
+
+	if *status.State == mesos.TaskState_TASK_RUNNING {
+		bpMaxMinPistonCappingMutex.Lock()
+		s.tasksRunning++
+		bpMaxMinPistonCappingMutex.Unlock()
+	} else if IsTerminal(status.State) {
+		delete(s.running[status.GetSlaveId().GoString()], *status.TaskId.Value)
+		// Deleting the task from the taskMonitor
+		finishedTask, hostOfFinishedTask, err := s.deleteFromTaskMonitor(*status.TaskId.Value)
+		if err != nil {
+			log.Println(err)
+		}
+
+		// Need to update the cap values for host of the finishedTask
+		bpMaxMinPistonCappingMutex.Lock()
+		bpMaxMinPistonCappingCapValues[hostOfFinishedTask] -= ((finishedTask.Watts * constants.CapMargin) / s.totalPower[hostOfFinishedTask]) * 100
+		// Checking to see if the cap value has become 0, in which case we uncap the host.
+		if int(math.Floor(bpMaxMinPistonCappingCapValues[hostOfFinishedTask]+0.5)) == 0 {
+			bpMaxMinPistonCappingCapValues[hostOfFinishedTask] = 100
+		}
+		s.tasksRunning--
+		bpMaxMinPistonCappingMutex.Unlock()
+
+		if s.tasksRunning == 0 {
+			select {
+			case <-s.Shutdown:
+				s.stopCapping()
+				close(s.Done)
+			default:
+			}
+		}
+	}
+	log.Printf("DONE: Task status [%s] for task [%s]", NameFor(status.State), *status.TaskId.Value)
+
+}