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planner.go
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planner.go
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/*
Copyright 2016 The Kubernetes Authors.
Licensed under the Apache License, Version 2.0 (the "License");
you may not use this file except in compliance with the License.
You may obtain a copy of the License at
http://www.apache.org/licenses/LICENSE-2.0
Unless required by applicable law or agreed to in writing, software
distributed under the License is distributed on an "AS IS" BASIS,
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
See the License for the specific language governing permissions and
limitations under the License.
*/
package planner
import (
"hash/fnv"
"sort"
fedapi "k8s.io/kubernetes/federation/apis/federation"
)
// Planner decides how many out of the given replicas should be placed in each of the
// federated clusters.
type Planner struct {
preferences *fedapi.FederatedReplicaSetPreferences
}
type namedClusterReplicaSetPreferences struct {
clusterName string
hash uint32
fedapi.ClusterReplicaSetPreferences
}
type byWeight []*namedClusterReplicaSetPreferences
func (a byWeight) Len() int { return len(a) }
func (a byWeight) Swap(i, j int) { a[i], a[j] = a[j], a[i] }
// Preferences are sorted according by decreasing weight and increasing hash (built on top of cluster name and rs name).
// Sorting is made by a hash to avoid assigning single-replica rs to the alphabetically smallest cluster.
func (a byWeight) Less(i, j int) bool {
return (a[i].Weight > a[j].Weight) || (a[i].Weight == a[j].Weight && a[i].hash < a[j].hash)
}
func NewPlanner(preferences *fedapi.FederatedReplicaSetPreferences) *Planner {
return &Planner{
preferences: preferences,
}
}
// Distribute the desired number of replicas among the given cluster according to the planner preferences.
// The function tries its best to assign each cluster the preferred number of replicas, however if
// sum of MinReplicas for all cluster is bigger thant replicasToDistribute then some cluster will not
// have all of the replicas assigned. In such case a cluster with higher weight has priority over
// cluster with lower weight (or with lexicographically smaller name in case of draw).
// It can also use the current replica count and estimated capacity to provide better planning and
// adhere to rebalance policy. To avoid prioritization of clusters with smaller lexicographical names
// a semi-random string (like replica set name) can be provided.
// Two maps are returned:
// * a map that contains information how many replicas will be possible to run in a cluster.
// * a map that contains information how many extra replicas would be nice to schedule in a cluster so,
// if by chance, they are scheduled we will be closer to the desired replicas layout.
func (p *Planner) Plan(replicasToDistribute int64, availableClusters []string, currentReplicaCount map[string]int64,
estimatedCapacity map[string]int64, replicaSetKey string) (map[string]int64, map[string]int64) {
preferences := make([]*namedClusterReplicaSetPreferences, 0, len(availableClusters))
plan := make(map[string]int64, len(preferences))
overflow := make(map[string]int64, len(preferences))
named := func(name string, pref fedapi.ClusterReplicaSetPreferences) *namedClusterReplicaSetPreferences {
// Seems to work better than addler for our case.
hasher := fnv.New32()
hasher.Write([]byte(name))
hasher.Write([]byte(replicaSetKey))
return &namedClusterReplicaSetPreferences{
clusterName: name,
hash: hasher.Sum32(),
ClusterReplicaSetPreferences: pref,
}
}
for _, cluster := range availableClusters {
if localRSP, found := p.preferences.Clusters[cluster]; found {
preferences = append(preferences, named(cluster, localRSP))
} else {
if localRSP, found := p.preferences.Clusters["*"]; found {
preferences = append(preferences, named(cluster, localRSP))
} else {
plan[cluster] = int64(0)
}
}
}
sort.Sort(byWeight(preferences))
remainingReplicas := replicasToDistribute
// Assign each cluster the minimum number of replicas it requested.
for _, preference := range preferences {
min := minInt64(preference.MinReplicas, remainingReplicas)
if capacity, hasCapacity := estimatedCapacity[preference.clusterName]; hasCapacity {
min = minInt64(min, capacity)
}
remainingReplicas -= min
plan[preference.clusterName] = min
}
// This map contains information how many replicas were assigned to
// the cluster based only on the current replica count and
// rebalance=false preference. It will be later used in remaining replica
// distribution code.
preallocated := make(map[string]int64)
if p.preferences.Rebalance == false {
for _, preference := range preferences {
planned := plan[preference.clusterName]
count, hasSome := currentReplicaCount[preference.clusterName]
if hasSome && count > planned {
target := count
if preference.MaxReplicas != nil {
target = minInt64(*preference.MaxReplicas, target)
}
if capacity, hasCapacity := estimatedCapacity[preference.clusterName]; hasCapacity {
target = minInt64(capacity, target)
}
extra := minInt64(target-planned, remainingReplicas)
if extra < 0 {
extra = 0
}
remainingReplicas -= extra
preallocated[preference.clusterName] = extra
plan[preference.clusterName] = extra + planned
}
}
}
modified := true
// It is possible single pass of the loop is not enough to distribute all replicas among clusters due
// to weight, max and rounding corner cases. In such case we iterate until either
// there is no replicas or no cluster gets any more replicas or the number
// of attempts is less than available cluster count. If there is no preallocated pods
// every loop either distributes all remainingReplicas or maxes out at least one cluster.
// If there are preallocated then the replica spreading may take longer.
// We reduce the number of pending preallocated replicas by at least half with each iteration so
// we may need log(replicasAtStart) iterations.
// TODO: Prove that clusterCount * log(replicas) iterations solves the problem or adjust the number.
// TODO: This algorithm is O(clusterCount^2 * log(replicas)) which is good for up to 100 clusters.
// Find something faster.
for trial := 0; modified && remainingReplicas > 0; trial++ {
modified = false
weightSum := int64(0)
for _, preference := range preferences {
weightSum += preference.Weight
}
newPreferences := make([]*namedClusterReplicaSetPreferences, 0, len(preferences))
distributeInThisLoop := remainingReplicas
for _, preference := range preferences {
if weightSum > 0 {
start := plan[preference.clusterName]
// Distribute the remaining replicas, rounding fractions always up.
extra := (distributeInThisLoop*preference.Weight + weightSum - 1) / weightSum
extra = minInt64(extra, remainingReplicas)
// Account preallocated.
prealloc := preallocated[preference.clusterName]
usedPrealloc := minInt64(extra, prealloc)
preallocated[preference.clusterName] = prealloc - usedPrealloc
extra = extra - usedPrealloc
if usedPrealloc > 0 {
modified = true
}
// In total there should be the amount that was there at start plus whatever is due
// in this iteration
total := start + extra
// Check if we don't overflow the cluster, and if yes don't consider this cluster
// in any of the following iterations.
full := false
if preference.MaxReplicas != nil && total > *preference.MaxReplicas {
total = *preference.MaxReplicas
full = true
}
if capacity, hasCapacity := estimatedCapacity[preference.clusterName]; hasCapacity && total > capacity {
overflow[preference.clusterName] = total - capacity
total = capacity
full = true
}
if !full {
newPreferences = append(newPreferences, preference)
}
// Only total-start replicas were actually taken.
remainingReplicas -= (total - start)
plan[preference.clusterName] = total
// Something extra got scheduled on this cluster.
if total > start {
modified = true
}
} else {
break
}
}
preferences = newPreferences
}
if p.preferences.Rebalance {
return plan, overflow
} else {
// If rebalance = false then overflow is trimmed at the level
// of replicas that it failed to place somewhere.
newOverflow := make(map[string]int64)
for key, value := range overflow {
value = minInt64(value, remainingReplicas)
if value > 0 {
newOverflow[key] = value
}
}
return plan, newOverflow
}
}
func minInt64(a int64, b int64) int64 {
if a < b {
return a
}
return b
}