neo-go/pkg/network/discovery_test.go

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package network
import (
"errors"
"sort"
"sync/atomic"
"testing"
"time"
"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) Close() {
}
func TestDefaultDiscoverer(t *testing.T) {
ts := &fakeTransp{}
ts.dialCh = make(chan string)
d := NewDefaultDiscovery(time.Second, 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)
}
gAddrs := d.GoodPeers()
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, len(set1), 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, len(set1), len(d.GoodPeers()))
require.Equal(t, 0, d.PoolCount())
// Close should work and subsequent RequestRemote is a no-op.
d.Close()
d.RequestRemote(42)
}