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https://gitee.com/milvus-io/milvus.git
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a2502bde75
issue: #30647 - ReplicaManager manage read only node now, and always do persistent of node distribution of replica. - All segment/channel checker using ReplicaManager to get read-only node or read-write node, but not ResourceManager. - ReplicaManager promise that only apply unique querynode to one replica in same collection now (replicas in same collection never hold same querynode at same time). - ReplicaManager promise that fairly node count assignment policy if multi replicas of collection is assigned to one resource group. - Move some parameters check into ReplicaManager to avoid data race. - Allow transfer replica to resource group that already load replica of same collection - Allow transfer node between resource groups that load replica of same collection --------- Signed-off-by: chyezh <chyezh@outlook.com>
273 lines
9.5 KiB
Go
273 lines
9.5 KiB
Go
package meta
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import (
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"sort"
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"github.com/milvus-io/milvus/pkg/util/typeutil"
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)
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// collectionAssignmentHelper is a helper to manage the replica assignment in same collection.
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type collectionAssignmentHelper struct {
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collectionID typeutil.UniqueID
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resourceGroupToReplicas map[string]*replicasInSameRGAssignmentHelper
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}
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// newCollectionAssignmentHelper creates a new collectionAssignmentHelper.
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func newCollectionAssignmentHelper(
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collectionID typeutil.UniqueID,
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rgToReplicas map[string][]*Replica,
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rgs map[string]typeutil.UniqueSet,
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) *collectionAssignmentHelper {
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resourceGroupToReplicas := make(map[string]*replicasInSameRGAssignmentHelper)
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for rgName, replicas := range rgToReplicas {
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resourceGroupToReplicas[rgName] = newReplicaAssignmentHelper(rgName, replicas, rgs[rgName])
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}
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helper := &collectionAssignmentHelper{
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collectionID: collectionID,
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resourceGroupToReplicas: resourceGroupToReplicas,
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}
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helper.updateIncomingNodesAndExpectedNode()
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return helper
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}
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// updateIncomingNodesAndExpectedNode updates the incoming nodes for all resource groups.
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// An incoming node is a node that not used by current collection but in resource group.
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func (h *collectionAssignmentHelper) updateIncomingNodesAndExpectedNode() {
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// incoming nodes should be compared with all node of replica in same collection, even not in same resource group.
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for _, helper := range h.resourceGroupToReplicas {
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// some node in current resource group may load other replica data of same collection in other resource group.
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// those node cannot be used right now.
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newIncomingNodes := helper.nodesInRG.Clone()
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currentUsedNodeCount := newIncomingNodes.Len()
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h.RangeOverReplicas(func(rgName string, assignment *replicaAssignmentInfo) {
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assignment.RangeOverAllNodes(func(nodeID int64) {
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if newIncomingNodes.Contain(nodeID) {
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newIncomingNodes.Remove(nodeID)
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if rgName != helper.rgName {
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// Node is still used by other replica of same collection in other resource group, cannot be used right now.
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// filter it out to calculate the expected node count to avoid node starve of some replica in same resource group.
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currentUsedNodeCount--
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}
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}
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})
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})
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helper.incomingNodes = newIncomingNodes
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helper.updateExpectedNodeCountForReplicas(currentUsedNodeCount)
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}
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}
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// RangeOverResourceGroup iterate resource groups
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func (h *collectionAssignmentHelper) RangeOverResourceGroup(f func(helper *replicasInSameRGAssignmentHelper)) {
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for _, helper := range h.resourceGroupToReplicas {
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f(helper)
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}
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}
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// RangeOverReplicas iterate replicas
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func (h *collectionAssignmentHelper) RangeOverReplicas(f func(rgName string, assignment *replicaAssignmentInfo)) {
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for _, helper := range h.resourceGroupToReplicas {
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for _, assignment := range helper.replicas {
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f(helper.rgName, assignment)
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}
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}
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}
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// newReplicaAssignmentHelper creates a new replicaAssignmentHelper.
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func newReplicaAssignmentHelper(rgName string, replicas []*Replica, nodeInRG typeutil.UniqueSet) *replicasInSameRGAssignmentHelper {
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assignmentInfos := make([]*replicaAssignmentInfo, 0, len(replicas))
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for _, replica := range replicas {
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assignmentInfos = append(assignmentInfos, newReplicaAssignmentInfo(replica, nodeInRG))
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}
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h := &replicasInSameRGAssignmentHelper{
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rgName: rgName,
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nodesInRG: nodeInRG,
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replicas: assignmentInfos,
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}
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return h
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}
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// replicasInSameRGAssignmentHelper is a helper to manage the replica assignment in same rg.
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type replicasInSameRGAssignmentHelper struct {
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rgName string
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nodesInRG typeutil.UniqueSet
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incomingNodes typeutil.UniqueSet // nodes that not used by current replicas in resource group.
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replicas []*replicaAssignmentInfo
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}
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func (h *replicasInSameRGAssignmentHelper) AllocateIncomingNodes(n int) []int64 {
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nodeIDs := make([]int64, 0, n)
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h.incomingNodes.Range(func(nodeID int64) bool {
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if n > 0 {
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nodeIDs = append(nodeIDs, nodeID)
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n--
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} else {
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return false
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}
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return true
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})
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h.incomingNodes.Remove(nodeIDs...)
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return nodeIDs
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}
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// RangeOverReplicas iterate replicas.
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func (h *replicasInSameRGAssignmentHelper) RangeOverReplicas(f func(*replicaAssignmentInfo)) {
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for _, info := range h.replicas {
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f(info)
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}
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}
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// updateExpectedNodeCountForReplicas updates the expected node count for all replicas in same resource group.
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func (h *replicasInSameRGAssignmentHelper) updateExpectedNodeCountForReplicas(currentUsageNodesCount int) {
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minimumNodeCount := currentUsageNodesCount / len(h.replicas)
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maximumNodeCount := minimumNodeCount
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remainder := currentUsageNodesCount % len(h.replicas)
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if remainder > 0 {
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maximumNodeCount += 1
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}
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// rule:
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// 1. make minimumNodeCount <= expectedNodeCount <= maximumNodeCount
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// 2. expectedNodeCount should be closed to len(assignedNodes) for each replica as much as possible to avoid unnecessary node transfer.
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sorter := make(replicaAssignmentInfoSorter, 0, len(h.replicas))
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for _, info := range h.replicas {
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sorter = append(sorter, info)
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}
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sort.Sort(sort.Reverse(replicaAssignmentInfoSortByAvailableAndRecoverable{sorter}))
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for _, info := range sorter {
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if remainder > 0 {
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info.expectedNodeCount = maximumNodeCount
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remainder--
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} else {
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info.expectedNodeCount = minimumNodeCount
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}
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}
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}
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// newReplicaAssignmentInfo creates a new replicaAssignmentInfo.
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func newReplicaAssignmentInfo(replica *Replica, nodeInRG typeutil.UniqueSet) *replicaAssignmentInfo {
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// node in replica can be split into 3 part.
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rwNodes := make(typeutil.UniqueSet, replica.RWNodesCount())
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newRONodes := make(typeutil.UniqueSet, replica.RONodesCount())
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unrecoverableRONodes := make(typeutil.UniqueSet, replica.RONodesCount())
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recoverableRONodes := make(typeutil.UniqueSet, replica.RONodesCount())
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replica.RangeOverRWNodes(func(nodeID int64) bool {
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if nodeInRG.Contain(nodeID) {
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rwNodes.Insert(nodeID)
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} else {
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newRONodes.Insert(nodeID)
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}
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return true
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})
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replica.RangeOverRONodes(func(nodeID int64) bool {
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if nodeInRG.Contain(nodeID) {
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recoverableRONodes.Insert(nodeID)
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} else {
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unrecoverableRONodes.Insert(nodeID)
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}
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return true
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})
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return &replicaAssignmentInfo{
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replicaID: replica.GetID(),
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expectedNodeCount: 0,
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rwNodes: rwNodes,
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newRONodes: newRONodes,
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recoverableRONodes: recoverableRONodes,
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unrecoverableRONodes: unrecoverableRONodes,
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}
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}
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type replicaAssignmentInfo struct {
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replicaID typeutil.UniqueID
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expectedNodeCount int // expected node count for each replica.
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rwNodes typeutil.UniqueSet // rw nodes is used by current replica. (rw -> rw)
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newRONodes typeutil.UniqueSet // new ro nodes for these replica. (rw -> ro)
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recoverableRONodes typeutil.UniqueSet // recoverable ro nodes for these replica (ro node can be put back to rw node if it's in current resource group). (may ro -> rw)
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unrecoverableRONodes typeutil.UniqueSet // unrecoverable ro nodes for these replica (ro node can't be put back to rw node if it's not in current resource group). (ro -> ro)
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}
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// GetReplicaID returns the replica id for these replica.
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func (s *replicaAssignmentInfo) GetReplicaID() typeutil.UniqueID {
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return s.replicaID
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}
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// GetNewRONodes returns the new ro nodes for these replica.
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func (s *replicaAssignmentInfo) GetNewRONodes() []int64 {
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newRONodes := make([]int64, 0, s.newRONodes.Len())
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// not in current resource group must be set ro.
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for nodeID := range s.newRONodes {
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newRONodes = append(newRONodes, nodeID)
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}
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// too much node is occupied by current replica, then set some node to ro.
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if s.rwNodes.Len() > s.expectedNodeCount {
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cnt := s.rwNodes.Len() - s.expectedNodeCount
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s.rwNodes.Range(func(node int64) bool {
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if cnt > 0 {
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newRONodes = append(newRONodes, node)
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cnt--
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} else {
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return false
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}
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return true
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})
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}
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return newRONodes
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}
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// GetRecoverNodesAndIncomingNodeCount returns the recoverable ro nodes and incoming node count for these replica.
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func (s *replicaAssignmentInfo) GetRecoverNodesAndIncomingNodeCount() (recoverNodes []int64, incomingNodeCount int) {
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recoverNodes = make([]int64, 0, s.recoverableRONodes.Len())
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incomingNodeCount = 0
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if s.rwNodes.Len() < s.expectedNodeCount {
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incomingNodeCount = s.expectedNodeCount - s.rwNodes.Len()
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s.recoverableRONodes.Range(func(node int64) bool {
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if incomingNodeCount > 0 {
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recoverNodes = append(recoverNodes, node)
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incomingNodeCount--
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} else {
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return false
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}
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return true
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})
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}
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return recoverNodes, incomingNodeCount
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}
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// RangeOverAllNodes iterate all nodes in replica.
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func (s *replicaAssignmentInfo) RangeOverAllNodes(f func(nodeID int64)) {
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ff := func(nodeID int64) bool {
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f(nodeID)
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return true
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}
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s.rwNodes.Range(ff)
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s.newRONodes.Range(ff)
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s.recoverableRONodes.Range(ff)
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s.unrecoverableRONodes.Range(ff)
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}
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type replicaAssignmentInfoSorter []*replicaAssignmentInfo
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func (s replicaAssignmentInfoSorter) Len() int {
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return len(s)
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}
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func (s replicaAssignmentInfoSorter) Swap(i, j int) {
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s[i], s[j] = s[j], s[i]
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}
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type replicaAssignmentInfoSortByAvailableAndRecoverable struct {
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replicaAssignmentInfoSorter
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}
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func (s replicaAssignmentInfoSortByAvailableAndRecoverable) Less(i, j int) bool {
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left := s.replicaAssignmentInfoSorter[i].rwNodes.Len() + s.replicaAssignmentInfoSorter[i].recoverableRONodes.Len()
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right := s.replicaAssignmentInfoSorter[j].rwNodes.Len() + s.replicaAssignmentInfoSorter[j].recoverableRONodes.Len()
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// Reach stable sort result by replica id.
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// Otherwise unstable assignment may cause unnecessary node transfer.
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return left < right || (left == right && s.replicaAssignmentInfoSorter[i].replicaID < s.replicaAssignmentInfoSorter[j].replicaID)
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}
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