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topology.go
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topology.go
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package gocql
import (
"fmt"
"strconv"
"strings"
)
type placementStrategy interface {
replicaMap(hosts []*HostInfo, tokens []hostToken) map[token][]*HostInfo
replicationFactor(dc string) int
}
func getReplicationFactorFromOpts(keyspace string, val interface{}) int {
// TODO: dont really want to panic here, but is better
// than spamming
switch v := val.(type) {
case int:
if v <= 0 {
panic(fmt.Sprintf("invalid replication_factor %d. Is the %q keyspace configured correctly?", v, keyspace))
}
return v
case string:
n, err := strconv.Atoi(v)
if err != nil {
panic(fmt.Sprintf("invalid replication_factor. Is the %q keyspace configured correctly? %v", keyspace, err))
} else if n <= 0 {
panic(fmt.Sprintf("invalid replication_factor %d. Is the %q keyspace configured correctly?", n, keyspace))
}
return n
default:
panic(fmt.Sprintf("unkown replication_factor type %T", v))
}
}
func getStrategy(ks *KeyspaceMetadata) placementStrategy {
switch {
case strings.Contains(ks.StrategyClass, "SimpleStrategy"):
return &simpleStrategy{rf: getReplicationFactorFromOpts(ks.Name, ks.StrategyOptions["replication_factor"])}
case strings.Contains(ks.StrategyClass, "NetworkTopologyStrategy"):
dcs := make(map[string]int)
for dc, rf := range ks.StrategyOptions {
if dc == "class" {
continue
}
dcs[dc] = getReplicationFactorFromOpts(ks.Name+":dc="+dc, rf)
}
return &networkTopology{dcs: dcs}
default:
// TODO: handle unknown replicas and just return the primary host for a token
panic(fmt.Sprintf("unsupported strategy class: %v", ks.StrategyClass))
}
}
type simpleStrategy struct {
rf int
}
func (s *simpleStrategy) replicationFactor(dc string) int {
return s.rf
}
func (s *simpleStrategy) replicaMap(_ []*HostInfo, tokens []hostToken) map[token][]*HostInfo {
tokenRing := make(map[token][]*HostInfo, len(tokens))
for i, th := range tokens {
replicas := make([]*HostInfo, 0, s.rf)
for j := 0; j < len(tokens) && len(replicas) < s.rf; j++ {
// TODO: need to ensure we dont add the same hosts twice
h := tokens[(i+j)%len(tokens)]
replicas = append(replicas, h.host)
}
tokenRing[th.token] = replicas
}
return tokenRing
}
type networkTopology struct {
dcs map[string]int
}
func (n *networkTopology) replicationFactor(dc string) int {
return n.dcs[dc]
}
func (n *networkTopology) haveRF(replicaCounts map[string]int) bool {
if len(replicaCounts) != len(n.dcs) {
return false
}
for dc, rf := range n.dcs {
if rf != replicaCounts[dc] {
return false
}
}
return true
}
func (n *networkTopology) replicaMap(hosts []*HostInfo, tokens []hostToken) map[token][]*HostInfo {
dcRacks := make(map[string]map[string]struct{})
for _, h := range hosts {
dc := h.DataCenter()
rack := h.Rack()
racks, ok := dcRacks[dc]
if !ok {
racks = make(map[string]struct{})
dcRacks[dc] = racks
}
racks[rack] = struct{}{}
}
tokenRing := make(map[token][]*HostInfo, len(tokens))
var totalRF int
for _, rf := range n.dcs {
totalRF += rf
}
for i, th := range tokens {
// number of replicas per dc
// TODO: recycle these
replicasInDC := make(map[string]int, len(n.dcs))
// dc -> racks
seenDCRacks := make(map[string]map[string]struct{}, len(n.dcs))
// skipped hosts in a dc
skipped := make(map[string][]*HostInfo, len(n.dcs))
replicas := make([]*HostInfo, 0, totalRF)
for j := 0; j < len(tokens) && !n.haveRF(replicasInDC); j++ {
// TODO: ensure we dont add the same host twice
h := tokens[(i+j)%len(tokens)].host
dc := h.DataCenter()
rack := h.Rack()
rf, ok := n.dcs[dc]
if !ok {
// skip this DC, dont know about it
continue
} else if replicasInDC[dc] >= rf {
if replicasInDC[dc] > rf {
panic(fmt.Sprintf("replica overflow. rf=%d have=%d in dc %q", rf, replicasInDC[dc], dc))
}
// have enough replicas in this DC
continue
} else if _, ok := dcRacks[dc][rack]; !ok {
// dont know about this rack
continue
} else if len(replicas) >= totalRF {
if replicasInDC[dc] > rf {
panic(fmt.Sprintf("replica overflow. total rf=%d have=%d", totalRF, len(replicas)))
}
// we now have enough replicas
break
}
racks := seenDCRacks[dc]
if _, ok := racks[rack]; ok && len(racks) == len(dcRacks[dc]) {
// we have been through all the racks and dont have RF yet, add this
replicas = append(replicas, h)
replicasInDC[dc]++
} else if !ok {
if racks == nil {
racks = make(map[string]struct{}, 1)
seenDCRacks[dc] = racks
}
// new rack
racks[rack] = struct{}{}
replicas = append(replicas, h)
replicasInDC[dc]++
if len(racks) == len(dcRacks[dc]) {
// if we have been through all the racks, drain the rest of the skipped
// hosts until we have RF. The next iteration will skip in the block
// above
skippedHosts := skipped[dc]
var k int
for ; k < len(skippedHosts) && replicasInDC[dc] < rf; k++ {
sh := skippedHosts[k]
replicas = append(replicas, sh)
replicasInDC[dc]++
}
skipped[dc] = skippedHosts[k:]
}
} else {
// already seen this rack, keep hold of this host incase
// we dont get enough for rf
skipped[dc] = append(skipped[dc], h)
}
}
if len(replicas) == 0 || replicas[0] != th.host {
panic("first replica is not the primary replica for the token")
}
tokenRing[th.token] = replicas
}
if len(tokenRing) != len(tokens) {
panic(fmt.Sprintf("token map different size to token ring: got %d expected %d", len(tokenRing), len(tokens)))
}
return tokenRing
}