Golang util.GetReplicaCountForReplicaSets函数代码示例

// calculateStatus calculates the latest status for the provided deployment by looking into the provided replica sets.
func calculateStatus(allRSs []*extensions.ReplicaSet, newRS *extensions.ReplicaSet, deployment *extensions.Deployment) extensions.DeploymentStatus {
	availableReplicas := deploymentutil.GetAvailableReplicaCountForReplicaSets(allRSs)
	totalReplicas := deploymentutil.GetReplicaCountForReplicaSets(allRSs)
	unavailableReplicas := totalReplicas - availableReplicas
	// If unavailableReplicas is negative, then that means the Deployment has more available replicas running than
	// desired, eg. whenever it scales down. In such a case we should simply default unavailableReplicas to zero.
	if unavailableReplicas < 0 {
		unavailableReplicas = 0
	}

	status := extensions.DeploymentStatus{
		// TODO: Ensure that if we start retrying status updates, we won't pick up a new Generation value.
		ObservedGeneration:  deployment.Generation,
		Replicas:            deploymentutil.GetActualReplicaCountForReplicaSets(allRSs),
		UpdatedReplicas:     deploymentutil.GetActualReplicaCountForReplicaSets([]*extensions.ReplicaSet{newRS}),
		AvailableReplicas:   availableReplicas,
		UnavailableReplicas: unavailableReplicas,
	}

	// Copy conditions one by one so we won't mutate the original object.
	conditions := deployment.Status.Conditions
	for i := range conditions {
		status.Conditions = append(status.Conditions, conditions[i])
	}

	if availableReplicas >= *(deployment.Spec.Replicas)-deploymentutil.MaxUnavailable(*deployment) {
		minAvailability := deploymentutil.NewDeploymentCondition(extensions.DeploymentAvailable, v1.ConditionTrue, deploymentutil.MinimumReplicasAvailable, "Deployment has minimum availability.")
		deploymentutil.SetDeploymentCondition(&status, *minAvailability)
	} else {
		noMinAvailability := deploymentutil.NewDeploymentCondition(extensions.DeploymentAvailable, v1.ConditionFalse, deploymentutil.MinimumReplicasUnavailable, "Deployment does not have minimum availability.")
		deploymentutil.SetDeploymentCondition(&status, *noMinAvailability)
	}

	return status
}

func (dc *DeploymentController) calculateStatus(allRSs []*extensions.ReplicaSet, newRS *extensions.ReplicaSet, deployment *extensions.Deployment) extensions.DeploymentStatus {
	availableReplicas := deploymentutil.GetAvailableReplicaCountForReplicaSets(allRSs)
	totalReplicas := deploymentutil.GetReplicaCountForReplicaSets(allRSs)

	return extensions.DeploymentStatus{
		// TODO: Ensure that if we start retrying status updates, we won't pick up a new Generation value.
		ObservedGeneration:  deployment.Generation,
		Replicas:            deploymentutil.GetActualReplicaCountForReplicaSets(allRSs),
		UpdatedReplicas:     deploymentutil.GetActualReplicaCountForReplicaSets([]*extensions.ReplicaSet{newRS}),
		AvailableReplicas:   availableReplicas,
		UnavailableReplicas: totalReplicas - availableReplicas,
	}
}

func (dc *DeploymentController) calculateStatus(allRSs []*extensions.ReplicaSet, newRS *extensions.ReplicaSet, deployment *extensions.Deployment) (extensions.DeploymentStatus, error) {
	availableReplicas, err := dc.getAvailablePodsForReplicaSets(deployment, allRSs)
	if err != nil {
		return deployment.Status, fmt.Errorf("failed to count available pods: %v", err)
	}
	totalReplicas := deploymentutil.GetReplicaCountForReplicaSets(allRSs)

	return extensions.DeploymentStatus{
		// TODO: Ensure that if we start retrying status updates, we won't pick up a new Generation value.
		ObservedGeneration:  deployment.Generation,
		Replicas:            deploymentutil.GetActualReplicaCountForReplicaSets(allRSs),
		UpdatedReplicas:     deploymentutil.GetActualReplicaCountForReplicaSets([]*extensions.ReplicaSet{newRS}),
		AvailableReplicas:   availableReplicas,
		UnavailableReplicas: totalReplicas - availableReplicas,
	}, nil
}

func (dc *DeploymentController) calculateStatus(allRSs []*extensions.ReplicaSet, newRS *extensions.ReplicaSet, deployment *extensions.Deployment) extensions.DeploymentStatus {
	availableReplicas := deploymentutil.GetAvailableReplicaCountForReplicaSets(allRSs)
	totalReplicas := deploymentutil.GetReplicaCountForReplicaSets(allRSs)

	if availableReplicas >= *(deployment.Spec.Replicas)-deploymentutil.MaxUnavailable(*deployment) {
		minAvailability := deploymentutil.NewDeploymentCondition(extensions.DeploymentAvailable, v1.ConditionTrue, deploymentutil.MinimumReplicasAvailable, "Deployment has minimum availability.")
		deploymentutil.SetDeploymentCondition(&deployment.Status, *minAvailability)
	} else {
		noMinAvailability := deploymentutil.NewDeploymentCondition(extensions.DeploymentAvailable, v1.ConditionFalse, deploymentutil.MinimumReplicasUnavailable, "Deployment does not have minimum availability.")
		deploymentutil.SetDeploymentCondition(&deployment.Status, *noMinAvailability)
	}

	return extensions.DeploymentStatus{
		// TODO: Ensure that if we start retrying status updates, we won't pick up a new Generation value.
		ObservedGeneration:  deployment.Generation,
		Replicas:            deploymentutil.GetActualReplicaCountForReplicaSets(allRSs),
		UpdatedReplicas:     deploymentutil.GetActualReplicaCountForReplicaSets([]*extensions.ReplicaSet{newRS}),
		AvailableReplicas:   availableReplicas,
		UnavailableReplicas: totalReplicas - availableReplicas,
		Conditions:          deployment.Status.Conditions,
	}
}

// scale scales proportionally in order to mitigate risk. Otherwise, scaling up can increase the size
// of the new replica set and scaling down can decrease the sizes of the old ones, both of which would
// have the effect of hastening the rollout progress, which could produce a higher proportion of unavailable
// replicas in the event of a problem with the rolled out template. Should run only on scaling events or
// when a deployment is paused and not during the normal rollout process.
func (dc *DeploymentController) scale(deployment *extensions.Deployment, newRS *extensions.ReplicaSet, oldRSs []*extensions.ReplicaSet) error {
	// If there is only one active replica set then we should scale that up to the full count of the
	// deployment. If there is no active replica set, then we should scale up the newest replica set.
	if activeOrLatest := deploymentutil.FindActiveOrLatest(newRS, oldRSs); activeOrLatest != nil {
		if *(activeOrLatest.Spec.Replicas) == *(deployment.Spec.Replicas) {
			return nil
		}
		_, _, err := dc.scaleReplicaSetAndRecordEvent(activeOrLatest, *(deployment.Spec.Replicas), deployment)
		return err
	}

	// If the new replica set is saturated, old replica sets should be fully scaled down.
	// This case handles replica set adoption during a saturated new replica set.
	if deploymentutil.IsSaturated(deployment, newRS) {
		for _, old := range controller.FilterActiveReplicaSets(oldRSs) {
			if _, _, err := dc.scaleReplicaSetAndRecordEvent(old, 0, deployment); err != nil {
				return err
			}
		}
		return nil
	}

	// There are old replica sets with pods and the new replica set is not saturated.
	// We need to proportionally scale all replica sets (new and old) in case of a
	// rolling deployment.
	if deploymentutil.IsRollingUpdate(deployment) {
		allRSs := controller.FilterActiveReplicaSets(append(oldRSs, newRS))
		allRSsReplicas := deploymentutil.GetReplicaCountForReplicaSets(allRSs)

		allowedSize := int32(0)
		if *(deployment.Spec.Replicas) > 0 {
			allowedSize = *(deployment.Spec.Replicas) + deploymentutil.MaxSurge(*deployment)
		}

		// Number of additional replicas that can be either added or removed from the total
		// replicas count. These replicas should be distributed proportionally to the active
		// replica sets.
		deploymentReplicasToAdd := allowedSize - allRSsReplicas

		// The additional replicas should be distributed proportionally amongst the active
		// replica sets from the larger to the smaller in size replica set. Scaling direction
		// drives what happens in case we are trying to scale replica sets of the same size.
		// In such a case when scaling up, we should scale up newer replica sets first, and
		// when scaling down, we should scale down older replica sets first.
		var scalingOperation string
		switch {
		case deploymentReplicasToAdd > 0:
			sort.Sort(controller.ReplicaSetsBySizeNewer(allRSs))
			scalingOperation = "up"

		case deploymentReplicasToAdd < 0:
			sort.Sort(controller.ReplicaSetsBySizeOlder(allRSs))
			scalingOperation = "down"
		}

		// Iterate over all active replica sets and estimate proportions for each of them.
		// The absolute value of deploymentReplicasAdded should never exceed the absolute
		// value of deploymentReplicasToAdd.
		deploymentReplicasAdded := int32(0)
		nameToSize := make(map[string]int32)
		for i := range allRSs {
			rs := allRSs[i]

			// Estimate proportions if we have replicas to add, otherwise simply populate
			// nameToSize with the current sizes for each replica set.
			if deploymentReplicasToAdd != 0 {
				proportion := deploymentutil.GetProportion(rs, *deployment, deploymentReplicasToAdd, deploymentReplicasAdded)

				nameToSize[rs.Name] = *(rs.Spec.Replicas) + proportion
				deploymentReplicasAdded += proportion
			} else {
				nameToSize[rs.Name] = *(rs.Spec.Replicas)
			}
		}

		// Update all replica sets
		for i := range allRSs {
			rs := allRSs[i]

			// Add/remove any leftovers to the largest replica set.
			if i == 0 && deploymentReplicasToAdd != 0 {
				leftover := deploymentReplicasToAdd - deploymentReplicasAdded
				nameToSize[rs.Name] = nameToSize[rs.Name] + leftover
				if nameToSize[rs.Name] < 0 {
					nameToSize[rs.Name] = 0
				}
			}

			// TODO: Use transactions when we have them.
			if _, err := dc.scaleReplicaSet(rs, nameToSize[rs.Name], deployment, scalingOperation); err != nil {
				// Return as soon as we fail, the deployment is requeued
				return err
			}
		}
	}
//.........这里部分代码省略.........

func (dc *DeploymentController) reconcileOldReplicaSets(allRSs []*extensions.ReplicaSet, oldRSs []*extensions.ReplicaSet, newRS *extensions.ReplicaSet, deployment *extensions.Deployment) (bool, error) {
	oldPodsCount := deploymentutil.GetReplicaCountForReplicaSets(oldRSs)
	if oldPodsCount == 0 {
		// Can't scale down further
		return false, nil
	}

	allPodsCount := deploymentutil.GetReplicaCountForReplicaSets(allRSs)
	glog.V(4).Infof("New replica set %s/%s has %d available pods.", newRS.Namespace, newRS.Name, newRS.Status.AvailableReplicas)
	maxUnavailable := deploymentutil.MaxUnavailable(*deployment)

	// Check if we can scale down. We can scale down in the following 2 cases:
	// * Some old replica sets have unhealthy replicas, we could safely scale down those unhealthy replicas since that won't further
	//  increase unavailability.
	// * New replica set has scaled up and it's replicas becomes ready, then we can scale down old replica sets in a further step.
	//
	// maxScaledDown := allPodsCount - minAvailable - newReplicaSetPodsUnavailable
	// take into account not only maxUnavailable and any surge pods that have been created, but also unavailable pods from
	// the newRS, so that the unavailable pods from the newRS would not make us scale down old replica sets in a further
	// step(that will increase unavailability).
	//
	// Concrete example:
	//
	// * 10 replicas
	// * 2 maxUnavailable (absolute number, not percent)
	// * 3 maxSurge (absolute number, not percent)
	//
	// case 1:
	// * Deployment is updated, newRS is created with 3 replicas, oldRS is scaled down to 8, and newRS is scaled up to 5.
	// * The new replica set pods crashloop and never become available.
	// * allPodsCount is 13. minAvailable is 8. newRSPodsUnavailable is 5.
	// * A node fails and causes one of the oldRS pods to become unavailable. However, 13 - 8 - 5 = 0, so the oldRS won't be scaled down.
	// * The user notices the crashloop and does kubectl rollout undo to rollback.
	// * newRSPodsUnavailable is 1, since we rolled back to the good replica set, so maxScaledDown = 13 - 8 - 1 = 4. 4 of the crashlooping pods will be scaled down.
	// * The total number of pods will then be 9 and the newRS can be scaled up to 10.
	//
	// case 2:
	// Same example, but pushing a new pod template instead of rolling back (aka "roll over"):
	// * The new replica set created must start with 0 replicas because allPodsCount is already at 13.
	// * However, newRSPodsUnavailable would also be 0, so the 2 old replica sets could be scaled down by 5 (13 - 8 - 0), which would then
	// allow the new replica set to be scaled up by 5.
	minAvailable := *(deployment.Spec.Replicas) - maxUnavailable
	newRSUnavailablePodCount := *(newRS.Spec.Replicas) - newRS.Status.AvailableReplicas
	maxScaledDown := allPodsCount - minAvailable - newRSUnavailablePodCount
	if maxScaledDown <= 0 {
		return false, nil
	}

	// Clean up unhealthy replicas first, otherwise unhealthy replicas will block deployment
	// and cause timeout. See https://github.com/kubernetes/kubernetes/issues/16737
	oldRSs, cleanupCount, err := dc.cleanupUnhealthyReplicas(oldRSs, deployment, maxScaledDown)
	if err != nil {
		return false, nil
	}
	glog.V(4).Infof("Cleaned up unhealthy replicas from old RSes by %d", cleanupCount)

	// Scale down old replica sets, need check maxUnavailable to ensure we can scale down
	allRSs = append(oldRSs, newRS)
	scaledDownCount, err := dc.scaleDownOldReplicaSetsForRollingUpdate(allRSs, oldRSs, deployment)
	if err != nil {
		return false, nil
	}
	glog.V(4).Infof("Scaled down old RSes of deployment %s by %d", deployment.Name, scaledDownCount)

	totalScaledDown := cleanupCount + scaledDownCount
	return totalScaledDown > 0, nil
}