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Proactive Clusterwide Capping with BinPackedSortedWattsClassToWatts

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Pradyumna Kaushik 2017-01-06 16:01:18 -08:00
parent d5860a91ae
commit 678c113f0a
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schedulers/bpswClassMapWattsProacCC.go Normal file
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package schedulers
import (
"bitbucket.org/sunybingcloud/electron/constants"
"bitbucket.org/sunybingcloud/electron/def"
"bitbucket.org/sunybingcloud/electron/pcp"
"bitbucket.org/sunybingcloud/electron/rapl"
"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"
"strings"
"sync"
"time"
"sort"
)
// Decides if to take an offer or not
func (*BPSWClassMapWattsProacCC) takeOffer(offer *mesos.Offer, task def.Task) bool {
cpus, mem, watts := OfferAgg(offer)
// TODO: Insert watts calculation here instead of taking them as parameter
if cpus >= task.CPU && mem >= task.RAM && watts >= task.Watts {
return true
}
return false
}
type BPSWClassMapWattsProacCC struct {
tasksCreated int
tasksRunning int
tasks []def.Task
metrics map[string]def.Metric
running map[string]map[string]bool
taskMonitor map[string][]def.Task
availablePower map[string]float64
totalPower map[string]float64
ignoreWatts bool
capper *pcp.ClusterwideCapper
ticker *time.Ticker
recapTicker *time.Ticker
isCapping bool // indicate whether we are currently performing cluster-wide capping.
isRecapping bool // indicate whether we are currently performing cluster-wide recapping.
// 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{}
}
// New electron scheduler
func NewBPSWClassMapWattsProacCC(tasks []def.Task, ignoreWatts bool) *BPSWClassMapWattsProacCC {
sort.Sort(def.WattsSorter(tasks))
s := &BPSWClassMapWattsProacCC{
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),
availablePower: make(map[string]float64),
totalPower: make(map[string]float64),
RecordPCP: false,
capper: pcp.GetClusterwideCapperInstance(),
ticker: time.NewTicker(10 * time.Second),
recapTicker: time.NewTicker(20 * time.Second),
isCapping: false,
isRecapping: false,
}
return s
}
// mutex
var bpswClassMapWattsProacCCMutex sync.Mutex
func (s *BPSWClassMapWattsProacCC) newTask(offer *mesos.Offer, task def.Task, newTaskClass string) *mesos.TaskInfo {
taskName := fmt.Sprintf("%s-%d", task.Name, *task.Instances)
s.tasksCreated++
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)
}
// 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 the list of tasks running on the node.
s.running[offer.GetSlaveId().GoString()][taskName] = true
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.ClassToWatts[newTaskClass]))
}
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 *BPSWClassMapWattsProacCC) Registered(
_ sched.SchedulerDriver,
frameworkID *mesos.FrameworkID,
masterInfo *mesos.MasterInfo) {
log.Printf("Framework %s registered with master %s", frameworkID, masterInfo)
}
func (s *BPSWClassMapWattsProacCC) Reregistered(_ sched.SchedulerDriver, masterInfo *mesos.MasterInfo) {
log.Printf("Framework re-registered with master %s", masterInfo)
}
func (s *BPSWClassMapWattsProacCC) Disconnected(sched.SchedulerDriver) {
// Need to stop the capping process
s.ticker.Stop()
s.recapTicker.Stop()
bpswClassMapWattsProacCCMutex.Lock()
s.isCapping = false
bpswClassMapWattsProacCCMutex.Unlock()
log.Println("Framework disconnected with master")
}
// go routine to cap the entire cluster in regular intervals of time.
var bpswClassMapWattsCapValue = 0.0 // initial value to indicate that we haven't capped the cluster yet.
func (s *BPSWClassMapWattsProacCC) startCapping() {
go func() {
for {
select {
case <-s.ticker.C:
// Need to cap the cluster to the bpswClassMapWattsCapValue.
bpswClassMapWattsProacCCMutex.Lock()
if bpswClassMapWattsCapValue > 0.0 {
for _, host := range constants.Hosts {
// Rounding capValue to nearest int.
if err := rapl.Cap(host, "rapl", int(math.Floor(bpswClassMapWattsCapValue+0.5))); err != nil {
log.Println(err)
}
}
log.Printf("Capped the cluster to %d", int(math.Floor(bpswClassMapWattsCapValue+0.5)))
}
bpswClassMapWattsProacCCMutex.Unlock()
}
}
}()
}
// go routine to recap the entire cluster in regular intervals of time.
var bpswClassMapWattsRecapValue = 0.0 // The cluster-wide cap value when recapping
func (s *BPSWClassMapWattsProacCC) startRecapping() {
go func() {
for {
select {
case <-s.recapTicker.C:
bpswClassMapWattsProacCCMutex.Lock()
// If stopped performing cluster wide capping, then we need to recap
if s.isRecapping && bpswClassMapWattsRecapValue > 0.0 {
for _, host := range constants.Hosts {
// Rounding capValue to the nearest int
if err := rapl.Cap(host, "rapl", int(math.Floor(bpswClassMapWattsRecapValue+0.5))); err != nil {
log.Println(err)
}
}
log.Printf("Recapping the cluster to %d", int(math.Floor(bpswClassMapWattsRecapValue+0.5)))
}
// Setting recapping to false
s.isRecapping = false
bpswClassMapWattsProacCCMutex.Unlock()
}
}
}()
}
// Stop cluster wide capping
func (s *BPSWClassMapWattsProacCC) stopCapping() {
if s.isCapping {
log.Println("Stopping the cluster-wide capping.")
s.ticker.Stop()
bpswClassMapWattsProacCCMutex.Lock()
s.isCapping = false
s.isRecapping = true
bpswClassMapWattsProacCCMutex.Unlock()
}
}
// Stop the cluster wide recapping
func (s *BPSWClassMapWattsProacCC) stopRecapping() {
// If not capping, then definitely recapping.
if !s.isCapping && s.isRecapping {
log.Println("Stopping the cluster-wide re-capping.")
s.recapTicker.Stop()
bpswClassMapWattsProacCCMutex.Lock()
s.isRecapping = false
bpswClassMapWattsProacCCMutex.Unlock()
}
}
func (s *BPSWClassMapWattsProacCC) ResourceOffers(driver sched.SchedulerDriver, offers []*mesos.Offer) {
log.Printf("Received %d resource offers", len(offers))
// retrieving the available power for all the hosts in the offers.
for _, offer := range offers {
_, _, offerWatts := OfferAgg(offer)
s.availablePower[*offer.Hostname] = offerWatts
// setting total power if the first time
if _, ok := s.totalPower[*offer.Hostname]; !ok {
s.totalPower[*offer.Hostname] = offerWatts
}
}
for host, tpower := range s.totalPower {
log.Printf("TotalPower[%s] = %f", host, tpower)
}
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{}
offerCPU, offerRAM, offerWatts := OfferAgg(offer)
taken := false
totalWatts := 0.0
totalCPU := 0.0
totalRAM := 0.0
for i, task := range s.tasks {
// Check host if it exists
if task.Host != "" {
// Don't take offer it it doesn't match our task's host requirement.
if strings.HasPrefix(*offer.Hostname, task.Host) {
continue
}
}
for *task.Instances > 0 {
var nodeClass string
for _, attr := range offer.GetAttributes() {
if attr.GetName() == "class" {
nodeClass = attr.GetText().GetValue()
}
}
// Does the task fit
// OR Lazy evaluation. If ignore watts is set to true, second statement won't
// be evaluated.
if (s.ignoreWatts || (offerWatts >= (totalWatts + task.ClassToWatts[nodeClass]))) &&
(offerCPU >= (totalCPU + task.CPU)) &&
(offerRAM >= (totalRAM + task.RAM)) {
// Capping the cluster if haven't yet started
if !s.isCapping {
bpswClassMapWattsProacCCMutex.Lock()
s.isCapping = true
bpswClassMapWattsProacCCMutex.Unlock()
s.startCapping()
}
fmt.Println("Watts being used: ", task.ClassToWatts[nodeClass])
tempCap, err := s.capper.FCFSDeterminedCap(s.totalPower, &task)
if err == nil {
bpswClassMapWattsProacCCMutex.Lock()
bpswClassMapWattsCapValue = tempCap
bpswClassMapWattsProacCCMutex.Unlock()
} else {
log.Println("Failed to determine new cluster-wide cap:")
log.Println(err)
}
taken = true
totalWatts += task.ClassToWatts[nodeClass]
totalCPU += task.CPU
totalRAM += task.RAM
log.Println("Co-Located with: ")
coLocated(s.running[offer.GetSlaveId().GoString()])
tasks = append(tasks, s.newTask(offer, task, nodeClass))
fmt.Println("Inst: ", *task.Instances)
*task.Instances--
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.")
// Need to stop the cluster wide capping as there aren't any more tasks to schedule.
s.stopCapping()
s.startRecapping() // Load changes after every task finishes and hence, we need to change the capping of the cluster.
close(s.Shutdown)
}
}
} else {
break // Continue on to the next task
}
}
}
if taken {
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)
}
}
}
func (s *BPSWClassMapWattsProacCC) 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 {
s.tasksRunning++
} else if IsTerminal(status.State) {
delete(s.running[status.GetSlaveId().GoString()], *status.TaskId.Value)
// Need to remove the task from the window
s.capper.TaskFinished(*status.TaskId.Value)
// Determining the new cluster wide recap value
tempCap, err := s.capper.Recap(s.totalPower, s.taskMonitor, *status.TaskId.Value)
//tempCap, err := s.capper.CleverRecap(s.totalPower, s.taskMonitor, *status.TaskId.Value)
if err == nil {
// If new determined cap value is different from the current recap value, then we need to recap
if int(math.Floor(tempCap+0.5)) != int(math.Floor(bpswClassMapWattsRecapValue+0.5)) {
bpswClassMapWattsRecapValue = tempCap
bpswClassMapWattsProacCCMutex.Lock()
s.isRecapping = true
bpswClassMapWattsProacCCMutex.Unlock()
log.Printf("Determined re-cap value: %f\n", bpswClassMapWattsRecapValue)
} else {
bpswClassMapWattsProacCCMutex.Lock()
s.isRecapping = false
bpswClassMapWattsProacCCMutex.Unlock()
}
} else {
log.Println(err)
}
s.tasksRunning--
if s.tasksRunning == 0 {
select {
case <-s.Shutdown:
// Need to stop the cluster-wide recapping
s.stopRecapping()
close(s.Done)
default:
}
}
}
log.Printf("DONE: Task status [%s] for task[%s]", NameFor(status.State), *status.TaskId.Value)
}
func (s *BPSWClassMapWattsProacCC) FrameworkMessage(
driver sched.SchedulerDriver,
executorID *mesos.ExecutorID,
slaveID *mesos.SlaveID,
message string) {
log.Println("Getting a framework message: ", message)
log.Printf("Received framework message from some unknown source: %s", *executorID.Value)
}
func (s *BPSWClassMapWattsProacCC) OfferRescinded(_ sched.SchedulerDriver, offerID *mesos.OfferID) {
log.Printf("Offer %s rescinded", offerID)
}
func (s *BPSWClassMapWattsProacCC) SlaveLost(_ sched.SchedulerDriver, slaveID *mesos.SlaveID) {
log.Printf("Slave %s lost", slaveID)
}
func (s *BPSWClassMapWattsProacCC) ExecutorLost(_ sched.SchedulerDriver, executorID *mesos.ExecutorID, slaveID *mesos.SlaveID, status int) {
log.Printf("Executor %s on slave %s was lost", executorID, slaveID)
}
func (s *BPSWClassMapWattsProacCC) Error(_ sched.SchedulerDriver, err string) {
log.Printf("Receiving an error: %s", err)
}