neo-go/pkg/network/discovery_test.go
Roman Khimov 38a22b44b2 network: try connecting to seeds indefinitely, use them with 0 pool
If the node is to start with seeds unavailable it will try connecting to each
of them three times, blacklist them and then sit forever waiting for
something. It's not a good behavior, it should always try connecting to seeds
if nothing else works.
2020-10-13 19:02:10 +03:00

192 lines
5 KiB
Go

package network
import (
"errors"
"sort"
"sync/atomic"
"testing"
"time"
"github.com/nspcc-dev/neo-go/pkg/network/capability"
"github.com/stretchr/testify/assert"
"github.com/stretchr/testify/require"
)
type fakeTransp struct {
retFalse int32
dialCh chan string
}
func (ft *fakeTransp) Dial(addr string, timeout time.Duration) error {
ft.dialCh <- addr
if atomic.LoadInt32(&ft.retFalse) > 0 {
return errors.New("smth bad happened")
}
return nil
}
func (ft *fakeTransp) Accept() {
}
func (ft *fakeTransp) Proto() string {
return ""
}
func (ft *fakeTransp) Address() string {
return ""
}
func (ft *fakeTransp) Close() {
}
func TestDefaultDiscoverer(t *testing.T) {
ts := &fakeTransp{}
ts.dialCh = make(chan string)
d := NewDefaultDiscovery(nil, time.Second/2, ts)
var set1 = []string{"1.1.1.1:10333", "2.2.2.2:10333"}
sort.Strings(set1)
// Added addresses should end up in the pool and in the unconnected set.
// Done twice to check re-adding unconnected addresses, which should be
// a no-op.
for i := 0; i < 2; i++ {
d.BackFill(set1...)
assert.Equal(t, len(set1), d.PoolCount())
set1D := d.UnconnectedPeers()
sort.Strings(set1D)
assert.Equal(t, 0, len(d.GoodPeers()))
assert.Equal(t, 0, len(d.BadPeers()))
require.Equal(t, set1, set1D)
}
// Request should make goroutines dial our addresses draining the pool.
d.RequestRemote(len(set1))
dialled := make([]string, 0)
for i := 0; i < len(set1); i++ {
select {
case a := <-ts.dialCh:
dialled = append(dialled, a)
case <-time.After(time.Second):
t.Fatalf("timeout expecting for transport dial")
}
}
// Updated asynchronously.
if len(d.UnconnectedPeers()) != 0 {
time.Sleep(time.Second)
}
sort.Strings(dialled)
assert.Equal(t, 0, d.PoolCount())
assert.Equal(t, 0, len(d.UnconnectedPeers()))
assert.Equal(t, 0, len(d.BadPeers()))
assert.Equal(t, 0, len(d.GoodPeers()))
require.Equal(t, set1, dialled)
// Registered good addresses should end up in appropriate set.
for _, addr := range set1 {
d.RegisterGoodAddr(addr, capability.Capabilities{
{
Type: capability.FullNode,
Data: &capability.Node{StartHeight: 123},
},
})
}
gAddrWithCap := d.GoodPeers()
gAddrs := make([]string, len(gAddrWithCap))
for i, addr := range gAddrWithCap {
require.Equal(t, capability.Capabilities{
{
Type: capability.FullNode,
Data: &capability.Node{StartHeight: 123},
},
}, addr.Capabilities)
gAddrs[i] = addr.Address
}
sort.Strings(gAddrs)
assert.Equal(t, 0, d.PoolCount())
assert.Equal(t, 0, len(d.UnconnectedPeers()))
assert.Equal(t, 0, len(d.BadPeers()))
require.Equal(t, set1, gAddrs)
// Re-adding connected addresses should be no-op.
d.BackFill(set1...)
assert.Equal(t, 0, len(d.UnconnectedPeers()))
assert.Equal(t, 0, len(d.BadPeers()))
assert.Equal(t, len(set1), len(d.GoodPeers()))
require.Equal(t, 0, d.PoolCount())
// Unregistering connected should work.
for _, addr := range set1 {
d.UnregisterConnectedAddr(addr)
}
assert.Equal(t, 0, len(d.UnconnectedPeers()))
assert.Equal(t, 0, len(d.BadPeers()))
assert.Equal(t, len(set1), len(d.GoodPeers()))
require.Equal(t, 0, d.PoolCount())
// Now make Dial() fail and wait to see addresses in the bad list.
atomic.StoreInt32(&ts.retFalse, 1)
d.BackFill(set1...)
assert.Equal(t, len(set1), d.PoolCount())
set1D := d.UnconnectedPeers()
sort.Strings(set1D)
assert.Equal(t, 0, len(d.BadPeers()))
require.Equal(t, set1, set1D)
dialledBad := make([]string, 0)
d.RequestRemote(len(set1))
for i := 0; i < connRetries; i++ {
for j := 0; j < len(set1); j++ {
select {
case a := <-ts.dialCh:
dialledBad = append(dialledBad, a)
case <-time.After(time.Second):
t.Fatalf("timeout expecting for transport dial; i: %d, j: %d", i, j)
}
}
}
require.Equal(t, 0, d.PoolCount())
sort.Strings(dialledBad)
for i := 0; i < len(set1); i++ {
for j := 0; j < connRetries; j++ {
assert.Equal(t, set1[i], dialledBad[i*connRetries+j])
}
}
// Updated asynchronously.
if len(d.BadPeers()) != len(set1) {
time.Sleep(time.Second)
}
assert.Equal(t, len(set1), len(d.BadPeers()))
assert.Equal(t, 0, len(d.GoodPeers()))
assert.Equal(t, 0, len(d.UnconnectedPeers()))
// Re-adding bad addresses is a no-op.
d.BackFill(set1...)
assert.Equal(t, 0, len(d.UnconnectedPeers()))
assert.Equal(t, len(set1), len(d.BadPeers()))
assert.Equal(t, 0, len(d.GoodPeers()))
require.Equal(t, 0, d.PoolCount())
// Close should work and subsequent RequestRemote is a no-op.
d.Close()
d.RequestRemote(42)
}
func TestSeedDiscovery(t *testing.T) {
var seeds = []string{"1.1.1.1:10333", "2.2.2.2:10333"}
ts := &fakeTransp{}
ts.dialCh = make(chan string)
atomic.StoreInt32(&ts.retFalse, 1) // Fail all dial requests.
sort.Strings(seeds)
d := NewDefaultDiscovery(seeds, time.Second/10, ts)
d.RequestRemote(len(seeds))
dialled := make([]string, 0)
for i := 0; i < connRetries*2; i++ {
for range seeds {
select {
case a := <-ts.dialCh:
dialled = append(dialled, a)
case <-time.After(time.Second):
t.Fatalf("timeout expecting for transport dial")
}
}
}
}