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package raft
import (
"bytes"
"fmt"
"io"
"io/ioutil"
"os"
"reflect"
"sync"
"testing"
"time"
"github.com/hashicorp/go-hclog"
"github.com/hashicorp/go-msgpack/codec"
)
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var (
userSnapshotErrorsOnNoData = true
)
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// Return configurations optimized for in-memory
func inmemConfig ( t * testing . T ) * Config {
conf := DefaultConfig ( )
conf . HeartbeatTimeout = 50 * time . Millisecond
conf . ElectionTimeout = 50 * time . Millisecond
conf . LeaderLeaseTimeout = 50 * time . Millisecond
conf . CommitTimeout = 5 * time . Millisecond
conf . Logger = newTestLeveledLogger ( t )
return conf
}
// MockFSM is an implementation of the FSM interface, and just stores
// the logs sequentially.
//
// NOTE: This is exposed for middleware testing purposes and is not a stable API
type MockFSM struct {
sync . Mutex
logs [ ] [ ] byte
configurations [ ] Configuration
}
// NOTE: This is exposed for middleware testing purposes and is not a stable API
type MockFSMConfigStore struct {
FSM
}
// NOTE: This is exposed for middleware testing purposes and is not a stable API
type WrappingFSM interface {
Underlying ( ) FSM
}
func getMockFSM ( fsm FSM ) * MockFSM {
switch f := fsm . ( type ) {
case * MockFSM :
return f
case * MockFSMConfigStore :
return f . FSM . ( * MockFSM )
case WrappingFSM :
return getMockFSM ( f . Underlying ( ) )
}
return nil
}
// NOTE: This is exposed for middleware testing purposes and is not a stable API
type MockSnapshot struct {
logs [ ] [ ] byte
maxIndex int
}
var _ ConfigurationStore = ( * MockFSMConfigStore ) ( nil )
// NOTE: This is exposed for middleware testing purposes and is not a stable API
func ( m * MockFSM ) Apply ( log * Log ) interface { } {
m . Lock ( )
defer m . Unlock ( )
m . logs = append ( m . logs , log . Data )
return len ( m . logs )
}
// NOTE: This is exposed for middleware testing purposes and is not a stable API
func ( m * MockFSM ) Snapshot ( ) ( FSMSnapshot , error ) {
m . Lock ( )
defer m . Unlock ( )
return & MockSnapshot { m . logs , len ( m . logs ) } , nil
}
// NOTE: This is exposed for middleware testing purposes and is not a stable API
func ( m * MockFSM ) Restore ( inp io . ReadCloser ) error {
m . Lock ( )
defer m . Unlock ( )
defer inp . Close ( )
hd := codec . MsgpackHandle { }
dec := codec . NewDecoder ( inp , & hd )
m . logs = nil
return dec . Decode ( & m . logs )
}
// NOTE: This is exposed for middleware testing purposes and is not a stable API
func ( m * MockFSM ) Logs ( ) [ ] [ ] byte {
m . Lock ( )
defer m . Unlock ( )
return m . logs
}
// NOTE: This is exposed for middleware testing purposes and is not a stable API
func ( m * MockFSMConfigStore ) StoreConfiguration ( index uint64 , config Configuration ) {
mm := m . FSM . ( * MockFSM )
mm . Lock ( )
defer mm . Unlock ( )
mm . configurations = append ( mm . configurations , config )
}
// NOTE: This is exposed for middleware testing purposes and is not a stable API
func ( m * MockSnapshot ) Persist ( sink SnapshotSink ) error {
hd := codec . MsgpackHandle { }
enc := codec . NewEncoder ( sink , & hd )
if err := enc . Encode ( m . logs [ : m . maxIndex ] ) ; err != nil {
sink . Cancel ( )
return err
}
sink . Close ( )
return nil
}
// NOTE: This is exposed for middleware testing purposes and is not a stable API
func ( m * MockSnapshot ) Release ( ) {
}
// This can be used as the destination for a logger and it'll
// map them into calls to testing.T.Log, so that you only see
// the logging for failed tests.
type testLoggerAdapter struct {
t * testing . T
prefix string
}
func ( a * testLoggerAdapter ) Write ( d [ ] byte ) ( int , error ) {
if d [ len ( d ) - 1 ] == '\n' {
d = d [ : len ( d ) - 1 ]
}
if a . prefix != "" {
l := a . prefix + ": " + string ( d )
if testing . Verbose ( ) {
fmt . Printf ( "testLoggerAdapter verbose: %s\n" , l )
}
a . t . Log ( l )
return len ( l ) , nil
}
a . t . Log ( string ( d ) )
return len ( d ) , nil
}
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func newTestLogger ( t * testing . T ) hclog . Logger {
return hclog . New ( & hclog . LoggerOptions {
Output : & testLoggerAdapter { t : t } ,
Level : hclog . DefaultLevel ,
} )
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}
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func newTestLoggerWithPrefix ( t * testing . T , prefix string ) hclog . Logger {
return hclog . New ( & hclog . LoggerOptions {
Output : & testLoggerAdapter { t : t , prefix : prefix } ,
Level : hclog . DefaultLevel ,
} )
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}
func newTestLeveledLogger ( t * testing . T ) hclog . Logger {
return hclog . New ( & hclog . LoggerOptions {
Name : "" ,
Output : & testLoggerAdapter { t : t } ,
} )
}
func newTestLeveledLoggerWithPrefix ( t * testing . T , prefix string ) hclog . Logger {
return hclog . New ( & hclog . LoggerOptions {
Name : prefix ,
Output : & testLoggerAdapter { t : t , prefix : prefix } ,
} )
}
type cluster struct {
dirs [ ] string
stores [ ] * InmemStore
fsms [ ] FSM
snaps [ ] * FileSnapshotStore
trans [ ] LoopbackTransport
rafts [ ] * Raft
t * testing . T
observationCh chan Observation
conf * Config
propagateTimeout time . Duration
longstopTimeout time . Duration
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logger hclog . Logger
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startTime time . Time
failedLock sync . Mutex
failedCh chan struct { }
failed bool
}
func ( c * cluster ) Merge ( other * cluster ) {
c . dirs = append ( c . dirs , other . dirs ... )
c . stores = append ( c . stores , other . stores ... )
c . fsms = append ( c . fsms , other . fsms ... )
c . snaps = append ( c . snaps , other . snaps ... )
c . trans = append ( c . trans , other . trans ... )
c . rafts = append ( c . rafts , other . rafts ... )
}
// notifyFailed will close the failed channel which can signal the goroutine
// running the test that another goroutine has detected a failure in order to
// terminate the test.
func ( c * cluster ) notifyFailed ( ) {
c . failedLock . Lock ( )
defer c . failedLock . Unlock ( )
if ! c . failed {
c . failed = true
close ( c . failedCh )
}
}
// Failf provides a logging function that fails the tests, prints the output
// with microseconds, and does not mysteriously eat the string. This can be
// safely called from goroutines but won't immediately halt the test. The
// failedCh will be closed to allow blocking functions in the main thread to
// detect the failure and react. Note that you should arrange for the main
// thread to block until all goroutines have completed in order to reliably
// fail tests using this function.
func ( c * cluster ) Failf ( format string , args ... interface { } ) {
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c . logger . Error ( fmt . Sprintf ( format , args ... ) )
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c . t . Fail ( )
c . notifyFailed ( )
}
// FailNowf provides a logging function that fails the tests, prints the output
// with microseconds, and does not mysteriously eat the string. FailNowf must be
// called from the goroutine running the test or benchmark function, not from
// other goroutines created during the test. Calling FailNowf does not stop
// those other goroutines.
func ( c * cluster ) FailNowf ( format string , args ... interface { } ) {
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c . logger . Error ( fmt . Sprintf ( format , args ... ) )
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c . t . FailNow ( )
}
// Close shuts down the cluster and cleans up.
func ( c * cluster ) Close ( ) {
var futures [ ] Future
for _ , r := range c . rafts {
futures = append ( futures , r . Shutdown ( ) )
}
// Wait for shutdown
limit := time . AfterFunc ( c . longstopTimeout , func ( ) {
// We can't FailNowf here, and c.Failf won't do anything if we
// hang, so panic.
panic ( "timed out waiting for shutdown" )
} )
defer limit . Stop ( )
for _ , f := range futures {
if err := f . Error ( ) ; err != nil {
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c . FailNowf ( "shutdown future err: %v" , err )
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}
}
for _ , d := range c . dirs {
os . RemoveAll ( d )
}
}
// WaitEventChan returns a channel which will signal if an observation is made
// or a timeout occurs. It is possible to set a filter to look for specific
// observations. Setting timeout to 0 means that it will wait forever until a
// non-filtered observation is made.
func ( c * cluster ) WaitEventChan ( filter FilterFn , timeout time . Duration ) <- chan struct { } {
ch := make ( chan struct { } )
go func ( ) {
defer close ( ch )
var timeoutCh <- chan time . Time
if timeout > 0 {
timeoutCh = time . After ( timeout )
}
for {
select {
case <- timeoutCh :
return
case o , ok := <- c . observationCh :
if ! ok || filter == nil || filter ( & o ) {
return
}
}
}
} ( )
return ch
}
// WaitEvent waits until an observation is made, a timeout occurs, or a test
// failure is signaled. It is possible to set a filter to look for specific
// observations. Setting timeout to 0 means that it will wait forever until a
// non-filtered observation is made or a test failure is signaled.
func ( c * cluster ) WaitEvent ( filter FilterFn , timeout time . Duration ) {
select {
case <- c . failedCh :
c . t . FailNow ( )
case <- c . WaitEventChan ( filter , timeout ) :
}
}
// WaitForReplication blocks until every FSM in the cluster has the given
// length, or the long sanity check timeout expires.
func ( c * cluster ) WaitForReplication ( fsmLength int ) {
limitCh := time . After ( c . longstopTimeout )
CHECK :
for {
ch := c . WaitEventChan ( nil , c . conf . CommitTimeout )
select {
case <- c . failedCh :
c . t . FailNow ( )
case <- limitCh :
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c . FailNowf ( "timeout waiting for replication" )
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case <- ch :
for _ , fsmRaw := range c . fsms {
fsm := getMockFSM ( fsmRaw )
fsm . Lock ( )
num := len ( fsm . logs )
fsm . Unlock ( )
if num != fsmLength {
continue CHECK
}
}
return
}
}
}
// pollState takes a snapshot of the state of the cluster. This might not be
// stable, so use GetInState() to apply some additional checks when waiting
// for the cluster to achieve a particular state.
func ( c * cluster ) pollState ( s RaftState ) ( [ ] * Raft , uint64 ) {
var highestTerm uint64
in := make ( [ ] * Raft , 0 , 1 )
for _ , r := range c . rafts {
if r . State ( ) == s {
in = append ( in , r )
}
term := r . getCurrentTerm ( )
if term > highestTerm {
highestTerm = term
}
}
return in , highestTerm
}
// GetInState polls the state of the cluster and attempts to identify when it has
// settled into the given state.
func ( c * cluster ) GetInState ( s RaftState ) [ ] * Raft {
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c . logger . Info ( "starting stability test" , "raft-state" , s )
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limitCh := time . After ( c . longstopTimeout )
// An election should complete after 2 * max(HeartbeatTimeout, ElectionTimeout)
// because of the randomised timer expiring in 1 x interval ... 2 x interval.
// We add a bit for propagation delay. If the election fails (e.g. because
// two elections start at once), we will have got something through our
// observer channel indicating a different state (i.e. one of the nodes
// will have moved to candidate state) which will reset the timer.
//
// Because of an implementation peculiarity, it can actually be 3 x timeout.
timeout := c . conf . HeartbeatTimeout
if timeout < c . conf . ElectionTimeout {
timeout = c . conf . ElectionTimeout
}
timeout = 2 * timeout + c . conf . CommitTimeout
timer := time . NewTimer ( timeout )
defer timer . Stop ( )
// Wait until we have a stable instate slice. Each time we see an
// observation a state has changed, recheck it and if it has changed,
// restart the timer.
var pollStartTime = time . Now ( )
for {
inState , highestTerm := c . pollState ( s )
inStateTime := time . Now ( )
// Sometimes this routine is called very early on before the
// rafts have started up. We then timeout even though no one has
// even started an election. So if the highest term in use is
// zero, we know there are no raft processes that have yet issued
// a RequestVote, and we set a long time out. This is fixed when
// we hear the first RequestVote, at which point we reset the
// timer.
if highestTerm == 0 {
timer . Reset ( c . longstopTimeout )
} else {
timer . Reset ( timeout )
}
// Filter will wake up whenever we observe a RequestVote.
filter := func ( ob * Observation ) bool {
switch ob . Data . ( type ) {
case RaftState :
return true
case RequestVoteRequest :
return true
default :
return false
}
}
select {
case <- c . failedCh :
c . t . FailNow ( )
case <- limitCh :
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c . FailNowf ( "timeout waiting for stable %s state" , s )
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case <- c . WaitEventChan ( filter , 0 ) :
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c . logger . Debug ( "resetting stability timeout" )
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case t , ok := <- timer . C :
if ! ok {
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c . FailNowf ( "timer channel errored" )
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}
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c . logger . Info ( fmt . Sprintf ( "stable state for %s reached at %s (%d nodes), %s from start of poll, %s from cluster start. Timeout at %s, %s after stability" ,
s , inStateTime , len ( inState ) , inStateTime . Sub ( pollStartTime ) , inStateTime . Sub ( c . startTime ) , t , t . Sub ( inStateTime ) ) )
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return inState
}
}
}
// Leader waits for the cluster to elect a leader and stay in a stable state.
func ( c * cluster ) Leader ( ) * Raft {
leaders := c . GetInState ( Leader )
if len ( leaders ) != 1 {
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c . FailNowf ( "expected one leader: %v" , leaders )
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}
return leaders [ 0 ]
}
// Followers waits for the cluster to have N-1 followers and stay in a stable
// state.
func ( c * cluster ) Followers ( ) [ ] * Raft {
expFollowers := len ( c . rafts ) - 1
followers := c . GetInState ( Follower )
if len ( followers ) != expFollowers {
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c . FailNowf ( "timeout waiting for %d followers (followers are %v)" , expFollowers , followers )
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}
return followers
}
// FullyConnect connects all the transports together.
func ( c * cluster ) FullyConnect ( ) {
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c . logger . Debug ( "fully connecting" )
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for i , t1 := range c . trans {
for j , t2 := range c . trans {
if i != j {
t1 . Connect ( t2 . LocalAddr ( ) , t2 )
t2 . Connect ( t1 . LocalAddr ( ) , t1 )
}
}
}
}
// Disconnect disconnects all transports from the given address.
func ( c * cluster ) Disconnect ( a ServerAddress ) {
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c . logger . Debug ( "disconnecting" , "address" , a )
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for _ , t := range c . trans {
if t . LocalAddr ( ) == a {
t . DisconnectAll ( )
} else {
t . Disconnect ( a )
}
}
}
// Partition keeps the given list of addresses connected but isolates them
// from the other members of the cluster.
func ( c * cluster ) Partition ( far [ ] ServerAddress ) {
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c . logger . Debug ( "partitioning" , "addresses" , far )
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// Gather the set of nodes on the "near" side of the partition (we
// will call the supplied list of nodes the "far" side).
near := make ( map [ ServerAddress ] struct { } )
OUTER :
for _ , t := range c . trans {
l := t . LocalAddr ( )
for _ , a := range far {
if l == a {
continue OUTER
}
}
near [ l ] = struct { } { }
}
// Now fixup all the connections. The near side will be separated from
// the far side, and vice-versa.
for _ , t := range c . trans {
l := t . LocalAddr ( )
if _ , ok := near [ l ] ; ok {
for _ , a := range far {
t . Disconnect ( a )
}
} else {
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for a := range near {
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t . Disconnect ( a )
}
}
}
}
// IndexOf returns the index of the given raft instance.
func ( c * cluster ) IndexOf ( r * Raft ) int {
for i , n := range c . rafts {
if n == r {
return i
}
}
return - 1
}
// EnsureLeader checks that ALL the nodes think the leader is the given expected
// leader.
func ( c * cluster ) EnsureLeader ( t * testing . T , expect ServerAddress ) {
// We assume c.Leader() has been called already; now check all the rafts
// think the leader is correct
fail := false
for _ , r := range c . rafts {
leader := ServerAddress ( r . Leader ( ) )
if leader != expect {
if leader == "" {
leader = "[none]"
}
if expect == "" {
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c . logger . Error ( "peer sees incorrect leader" , "peer" , r , "leader" , leader , "expected-leader" , "[none]" )
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} else {
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c . logger . Error ( "peer sees incorrect leader" , "peer" , r , "leader" , leader , "expected-leader" , expect )
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}
fail = true
}
}
if fail {
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c . FailNowf ( "at least one peer has the wrong notion of leader" )
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}
}
// EnsureSame makes sure all the FSMs have the same contents.
func ( c * cluster ) EnsureSame ( t * testing . T ) {
limit := time . Now ( ) . Add ( c . longstopTimeout )
first := getMockFSM ( c . fsms [ 0 ] )
CHECK :
first . Lock ( )
for i , fsmRaw := range c . fsms {
fsm := getMockFSM ( fsmRaw )
if i == 0 {
continue
}
fsm . Lock ( )
if len ( first . logs ) != len ( fsm . logs ) {
fsm . Unlock ( )
if time . Now ( ) . After ( limit ) {
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c . FailNowf ( "FSM log length mismatch: %d %d" ,
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len ( first . logs ) , len ( fsm . logs ) )
} else {
goto WAIT
}
}
for idx := 0 ; idx < len ( first . logs ) ; idx ++ {
if bytes . Compare ( first . logs [ idx ] , fsm . logs [ idx ] ) != 0 {
fsm . Unlock ( )
if time . Now ( ) . After ( limit ) {
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c . FailNowf ( "FSM log mismatch at index %d" , idx )
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} else {
goto WAIT
}
}
}
if len ( first . configurations ) != len ( fsm . configurations ) {
fsm . Unlock ( )
if time . Now ( ) . After ( limit ) {
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c . FailNowf ( "FSM configuration length mismatch: %d %d" ,
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len ( first . logs ) , len ( fsm . logs ) )
} else {
goto WAIT
}
}
for idx := 0 ; idx < len ( first . configurations ) ; idx ++ {
if ! reflect . DeepEqual ( first . configurations [ idx ] , fsm . configurations [ idx ] ) {
fsm . Unlock ( )
if time . Now ( ) . After ( limit ) {
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c . FailNowf ( "FSM configuration mismatch at index %d: %v, %v" , idx , first . configurations [ idx ] , fsm . configurations [ idx ] )
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} else {
goto WAIT
}
}
}
fsm . Unlock ( )
}
first . Unlock ( )
return
WAIT :
first . Unlock ( )
c . WaitEvent ( nil , c . conf . CommitTimeout )
goto CHECK
}
// getConfiguration returns the configuration of the given Raft instance, or
// fails the test if there's an error
func ( c * cluster ) getConfiguration ( r * Raft ) Configuration {
future := r . GetConfiguration ( )
if err := future . Error ( ) ; err != nil {
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c . FailNowf ( "failed to get configuration: %v" , err )
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return Configuration { }
}
return future . Configuration ( )
}
// EnsureSamePeers makes sure all the rafts have the same set of peers.
func ( c * cluster ) EnsureSamePeers ( t * testing . T ) {
limit := time . Now ( ) . Add ( c . longstopTimeout )
peerSet := c . getConfiguration ( c . rafts [ 0 ] )
CHECK :
for i , raft := range c . rafts {
if i == 0 {
continue
}
otherSet := c . getConfiguration ( raft )
if ! reflect . DeepEqual ( peerSet , otherSet ) {
if time . Now ( ) . After ( limit ) {
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c . FailNowf ( "peer mismatch: %+v %+v" , peerSet , otherSet )
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} else {
goto WAIT
}
}
}
return
WAIT :
c . WaitEvent ( nil , c . conf . CommitTimeout )
goto CHECK
}
// NOTE: This is exposed for middleware testing purposes and is not a stable API
type MakeClusterOpts struct {
Peers int
Bootstrap bool
Conf * Config
ConfigStoreFSM bool
MakeFSMFunc func ( ) FSM
LongstopTimeout time . Duration
}
// makeCluster will return a cluster with the given config and number of peers.
// If bootstrap is true, the servers will know about each other before starting,
// otherwise their transports will be wired up but they won't yet have configured
// each other.
func makeCluster ( t * testing . T , opts * MakeClusterOpts ) * cluster {
if opts . Conf == nil {
opts . Conf = inmemConfig ( t )
}
c := & cluster {
observationCh : make ( chan Observation , 1024 ) ,
conf : opts . Conf ,
// Propagation takes a maximum of 2 heartbeat timeouts (time to
// get a new heartbeat that would cause a commit) plus a bit.
propagateTimeout : opts . Conf . HeartbeatTimeout * 2 + opts . Conf . CommitTimeout ,
longstopTimeout : 5 * time . Second ,
logger : newTestLoggerWithPrefix ( t , "cluster" ) ,
failedCh : make ( chan struct { } ) ,
}
if opts . LongstopTimeout > 0 {
c . longstopTimeout = opts . LongstopTimeout
}
c . t = t
var configuration Configuration
// Setup the stores and transports
for i := 0 ; i < opts . Peers ; i ++ {
dir , err := ioutil . TempDir ( "" , "raft" )
if err != nil {
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c . FailNowf ( "err: %v" , err )
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}
store := NewInmemStore ( )
c . dirs = append ( c . dirs , dir )
c . stores = append ( c . stores , store )
if opts . ConfigStoreFSM {
c . fsms = append ( c . fsms , & MockFSMConfigStore {
FSM : & MockFSM { } ,
} )
} else {
var fsm FSM
if opts . MakeFSMFunc != nil {
fsm = opts . MakeFSMFunc ( )
} else {
fsm = & MockFSM { }
}
c . fsms = append ( c . fsms , fsm )
}
dir2 , snap := FileSnapTest ( t )
c . dirs = append ( c . dirs , dir2 )
c . snaps = append ( c . snaps , snap )
addr , trans := NewInmemTransport ( "" )
c . trans = append ( c . trans , trans )
localID := ServerID ( fmt . Sprintf ( "server-%s" , addr ) )
if opts . Conf . ProtocolVersion < 3 {
localID = ServerID ( addr )
}
configuration . Servers = append ( configuration . Servers , Server {
Suffrage : Voter ,
ID : localID ,
Address : addr ,
} )
}
// Wire the transports together
c . FullyConnect ( )
// Create all the rafts
c . startTime = time . Now ( )
for i := 0 ; i < opts . Peers ; i ++ {
logs := c . stores [ i ]
store := c . stores [ i ]
snap := c . snaps [ i ]
trans := c . trans [ i ]
peerConf := opts . Conf
peerConf . LocalID = configuration . Servers [ i ] . ID
peerConf . Logger = newTestLeveledLoggerWithPrefix ( t , string ( configuration . Servers [ i ] . ID ) )
if opts . Bootstrap {
err := BootstrapCluster ( peerConf , logs , store , snap , trans , configuration )
if err != nil {
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c . FailNowf ( "BootstrapCluster failed: %v" , err )
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}
}
raft , err := NewRaft ( peerConf , c . fsms [ i ] , logs , store , snap , trans )
if err != nil {
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c . FailNowf ( "NewRaft failed: %v" , err )
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}
raft . RegisterObserver ( NewObserver ( c . observationCh , false , nil ) )
if err != nil {
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c . FailNowf ( "RegisterObserver failed: %v" , err )
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}
c . rafts = append ( c . rafts , raft )
}
return c
}
// NOTE: This is exposed for middleware testing purposes and is not a stable API
func MakeCluster ( n int , t * testing . T , conf * Config ) * cluster {
return makeCluster ( t , & MakeClusterOpts {
Peers : n ,
Bootstrap : true ,
Conf : conf ,
} )
}
// NOTE: This is exposed for middleware testing purposes and is not a stable API
func MakeClusterNoBootstrap ( n int , t * testing . T , conf * Config ) * cluster {
return makeCluster ( t , & MakeClusterOpts {
Peers : n ,
Conf : conf ,
} )
}
// NOTE: This is exposed for middleware testing purposes and is not a stable API
func MakeClusterCustom ( t * testing . T , opts * MakeClusterOpts ) * cluster {
return makeCluster ( t , opts )
}
// NOTE: This is exposed for middleware testing purposes and is not a stable API
func FileSnapTest ( t * testing . T ) ( string , * FileSnapshotStore ) {
// Create a test dir
dir , err := ioutil . TempDir ( "" , "raft" )
if err != nil {
t . Fatalf ( "err: %v " , err )
}
snap , err := NewFileSnapshotStoreWithLogger ( dir , 3 , newTestLogger ( t ) )
if err != nil {
t . Fatalf ( "err: %v" , err )
}
return dir , snap
}