Ejemplo n.º 1
0
// CalculateSpreadPriority spreads pods by minimizing the number of pods belonging to the same service
// on the same machine.
func (s *ServiceSpread) CalculateSpreadPriority(pod *api.Pod, podLister algorithm.PodLister, minionLister algorithm.MinionLister) (algorithm.HostPriorityList, error) {
	var maxCount int
	var nsServicePods []*api.Pod

	services, err := s.serviceLister.GetPodServices(pod)
	if err == nil {
		// just use the first service and get the other pods within the service
		// TODO: a separate predicate can be created that tries to handle all services for the pod
		selector := labels.SelectorFromSet(services[0].Spec.Selector)
		pods, err := podLister.List(selector)
		if err != nil {
			return nil, err
		}
		// consider only the pods that belong to the same namespace
		for _, nsPod := range pods {
			if nsPod.Namespace == pod.Namespace {
				nsServicePods = append(nsServicePods, nsPod)
			}
		}
	}

	minions, err := minionLister.List()
	if err != nil {
		return nil, err
	}

	counts := map[string]int{}
	if len(nsServicePods) > 0 {
		for _, pod := range nsServicePods {
			counts[pod.Spec.NodeName]++
			// Compute the maximum number of pods hosted on any minion
			if counts[pod.Spec.NodeName] > maxCount {
				maxCount = counts[pod.Spec.NodeName]
			}
		}
	}

	result := []algorithm.HostPriority{}
	//score int - scale of 0-10
	// 0 being the lowest priority and 10 being the highest
	for _, minion := range minions.Items {
		// initializing to the default/max minion score of 10
		fScore := float32(10)
		if maxCount > 0 {
			fScore = 10 * (float32(maxCount-counts[minion.Name]) / float32(maxCount))
		}
		result = append(result, algorithm.HostPriority{Host: minion.Name, Score: int(fScore)})
	}
	return result, nil
}
Ejemplo n.º 2
0
// MapPodsToMachines obtains a list of pods and pivots that list into a map where the keys are host names
// and the values are the list of pods running on that host.
func MapPodsToMachines(lister algorithm.PodLister) (map[string][]*api.Pod, error) {
	machineToPods := map[string][]*api.Pod{}
	// TODO: perform more targeted query...
	pods, err := lister.List(labels.Everything())
	if err != nil {
		return map[string][]*api.Pod{}, err
	}
	pods = filterNonRunningPods(pods)
	for _, scheduledPod := range pods {
		host := scheduledPod.Spec.NodeName
		machineToPods[host] = append(machineToPods[host], scheduledPod)
	}
	return machineToPods, nil
}
Ejemplo n.º 3
0
// CalculateAntiAffinityPriority spreads pods by minimizing the number of pods belonging to the same service
// on machines with the same value for a particular label.
// The label to be considered is provided to the struct (ServiceAntiAffinity).
func (s *ServiceAntiAffinity) CalculateAntiAffinityPriority(pod *api.Pod, podLister algorithm.PodLister, minionLister algorithm.MinionLister) (algorithm.HostPriorityList, error) {
	var nsServicePods []*api.Pod

	services, err := s.serviceLister.GetPodServices(pod)
	if err == nil {
		// just use the first service and get the other pods within the service
		// TODO: a separate predicate can be created that tries to handle all services for the pod
		selector := labels.SelectorFromSet(services[0].Spec.Selector)
		pods, err := podLister.List(selector)
		if err != nil {
			return nil, err
		}
		// consider only the pods that belong to the same namespace
		for _, nsPod := range pods {
			if nsPod.Namespace == pod.Namespace {
				nsServicePods = append(nsServicePods, nsPod)
			}
		}
	}

	minions, err := minionLister.List()
	if err != nil {
		return nil, err
	}

	// separate out the minions that have the label from the ones that don't
	otherMinions := []string{}
	labeledMinions := map[string]string{}
	for _, minion := range minions.Items {
		if labels.Set(minion.Labels).Has(s.label) {
			label := labels.Set(minion.Labels).Get(s.label)
			labeledMinions[minion.Name] = label
		} else {
			otherMinions = append(otherMinions, minion.Name)
		}
	}

	podCounts := map[string]int{}
	for _, pod := range nsServicePods {
		label, exists := labeledMinions[pod.Spec.NodeName]
		if !exists {
			continue
		}
		podCounts[label]++
	}

	numServicePods := len(nsServicePods)
	result := []algorithm.HostPriority{}
	//score int - scale of 0-10
	// 0 being the lowest priority and 10 being the highest
	for minion := range labeledMinions {
		// initializing to the default/max minion score of 10
		fScore := float32(10)
		if numServicePods > 0 {
			fScore = 10 * (float32(numServicePods-podCounts[labeledMinions[minion]]) / float32(numServicePods))
		}
		result = append(result, algorithm.HostPriority{Host: minion, Score: int(fScore)})
	}
	// add the open minions with a score of 0
	for _, minion := range otherMinions {
		result = append(result, algorithm.HostPriority{Host: minion, Score: 0})
	}

	return result, nil
}