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package p2ptest
import (
"math/rand"
"testing"
"time"
"github.com/gogo/protobuf/proto"
"github.com/stretchr/testify/require"
dbm "github.com/tendermint/tm-db"
"github.com/tendermint/tendermint/crypto"
"github.com/tendermint/tendermint/crypto/ed25519"
"github.com/tendermint/tendermint/libs/log"
"github.com/tendermint/tendermint/p2p"
)
// Network sets up an in-memory network that can be used for high-level P2P
// testing. It creates an arbitrary number of nodes that are connected to each
// other, and can open channels across all nodes with custom reactors.
type Network struct {
Nodes map[p2p.NodeID]*Node
logger log.Logger
memoryNetwork *p2p.MemoryNetwork
}
// MakeNetwork creates a test network with the given number of nodes and
// connects them to each other.
func MakeNetwork(t *testing.T, nodes int) *Network {
logger := log.TestingLogger()
network := &Network{
Nodes: map[p2p.NodeID]*Node{},
logger: logger,
memoryNetwork: p2p.NewMemoryNetwork(logger),
}
for i := 0; i < nodes; i++ {
node := MakeNode(t, network)
network.Nodes[node.NodeID] = node
}
return network
}
// Start starts the network by setting up a list of node addresses to dial in
// addition to creating a peer update subscription for each node. Finally, all
// nodes are connected to each other.
func (n *Network) Start(t *testing.T) {
// Set up a list of node addresses to dial, and a peer update subscription
// for each node.
dialQueue := []p2p.NodeAddress{}
subs := map[p2p.NodeID]*p2p.PeerUpdates{}
for _, node := range n.Nodes {
dialQueue = append(dialQueue, node.NodeAddress)
subs[node.NodeID] = node.PeerManager.Subscribe()
defer subs[node.NodeID].Close()
}
// For each node, dial the nodes that it still doesn't have a connection to
// (either inbound or outbound), and wait for both sides to confirm the
// connection via the subscriptions.
for i, sourceAddress := range dialQueue {
sourceNode := n.Nodes[sourceAddress.NodeID]
sourceSub := subs[sourceAddress.NodeID]
for _, targetAddress := range dialQueue[i+1:] { // nodes <i already connected
targetNode := n.Nodes[targetAddress.NodeID]
targetSub := subs[targetAddress.NodeID]
require.NoError(t, sourceNode.PeerManager.Add(targetAddress))
select {
case peerUpdate := <-sourceSub.Updates():
require.Equal(t, p2p.PeerUpdate{
NodeID: targetNode.NodeID,
Status: p2p.PeerStatusUp,
}, peerUpdate)
case <-time.After(time.Second):
require.Fail(t, "timed out waiting for peer", "%v dialing %v",
sourceNode.NodeID, targetNode.NodeID)
}
select {
case peerUpdate := <-targetSub.Updates():
require.Equal(t, p2p.PeerUpdate{
NodeID: sourceNode.NodeID,
Status: p2p.PeerStatusUp,
}, peerUpdate)
case <-time.After(time.Second):
require.Fail(t, "timed out waiting for peer", "%v accepting %v",
targetNode.NodeID, sourceNode.NodeID)
}
// Add the address to the target as well, so it's able to dial the
// source back if that's even necessary.
require.NoError(t, targetNode.PeerManager.Add(sourceAddress))
}
}
}
// NodeIDs returns the network's node IDs.
func (n *Network) NodeIDs() []p2p.NodeID {
ids := []p2p.NodeID{}
for id := range n.Nodes {
ids = append(ids, id)
}
return ids
}
// MakeChannels makes a channel on all nodes and returns them, automatically
// doing error checks and cleanups.
func (n *Network) MakeChannels(
t *testing.T,
chID p2p.ChannelID,
messageType proto.Message,
size int,
) map[p2p.NodeID]*p2p.Channel {
channels := map[p2p.NodeID]*p2p.Channel{}
for _, node := range n.Nodes {
channels[node.NodeID] = node.MakeChannel(t, chID, messageType, size)
}
return channels
}
// MakeChannelsNoCleanup makes a channel on all nodes and returns them,
// automatically doing error checks. The caller must ensure proper cleanup of
// all the channels.
func (n *Network) MakeChannelsNoCleanup(
t *testing.T,
chID p2p.ChannelID,
messageType proto.Message,
size int,
) map[p2p.NodeID]*p2p.Channel {
channels := map[p2p.NodeID]*p2p.Channel{}
for _, node := range n.Nodes {
channels[node.NodeID] = node.MakeChannelNoCleanup(t, chID, messageType, size)
}
return channels
}
// RandomNode returns a random node.
func (n *Network) RandomNode() *Node {
nodes := make([]*Node, 0, len(n.Nodes))
for _, node := range n.Nodes {
nodes = append(nodes, node)
}
return nodes[rand.Intn(len(nodes))] // nolint:gosec
}
// Peers returns a node's peers (i.e. everyone except itself).
func (n *Network) Peers(id p2p.NodeID) []*Node {
peers := make([]*Node, 0, len(n.Nodes)-1)
for _, peer := range n.Nodes {
if peer.NodeID != id {
peers = append(peers, peer)
}
}
return peers
}
// Remove removes a node from the network, stopping it and waiting for all other
// nodes to pick up the disconnection.
func (n *Network) Remove(t *testing.T, id p2p.NodeID) {
require.Contains(t, n.Nodes, id)
node := n.Nodes[id]
delete(n.Nodes, id)
subs := []*p2p.PeerUpdates{}
for _, peer := range n.Nodes {
sub := peer.PeerManager.Subscribe()
defer sub.Close()
subs = append(subs, sub)
}
require.NoError(t, node.Transport.Close())
if node.Router.IsRunning() {
require.NoError(t, node.Router.Stop())
}
node.PeerManager.Close()
for _, sub := range subs {
RequireUpdate(t, sub, p2p.PeerUpdate{
NodeID: node.NodeID,
Status: p2p.PeerStatusDown,
})
}
}
// Node is a node in a Network, with a Router and a PeerManager.
type Node struct {
NodeID p2p.NodeID
NodeInfo p2p.NodeInfo
NodeAddress p2p.NodeAddress
PrivKey crypto.PrivKey
Router *p2p.Router
PeerManager *p2p.PeerManager
Transport *p2p.MemoryTransport
}
// MakeNode creates a new Node.
func MakeNode(t *testing.T, network *Network) *Node {
privKey := ed25519.GenPrivKey()
nodeID := p2p.NodeIDFromPubKey(privKey.PubKey())
nodeInfo := p2p.NodeInfo{
NodeID: nodeID,
ListenAddr: "0.0.0.0:0", // FIXME: We have to fake this for now.
Moniker: string(nodeID),
}
transport := network.memoryNetwork.CreateTransport(nodeID)
require.Len(t, transport.Endpoints(), 1, "transport not listening on 1 endpoint")
peerManager, err := p2p.NewPeerManager(nodeID, dbm.NewMemDB(), p2p.PeerManagerOptions{
MinRetryTime: 10 * time.Millisecond,
MaxRetryTime: 100 * time.Millisecond,
RetryTimeJitter: time.Millisecond,
})
require.NoError(t, err)
router, err := p2p.NewRouter(network.logger, nodeInfo, privKey, peerManager,
[]p2p.Transport{transport}, p2p.RouterOptions{})
require.NoError(t, err)
require.NoError(t, router.Start())
t.Cleanup(func() {
if router.IsRunning() {
require.NoError(t, router.Stop())
}
peerManager.Close()
require.NoError(t, transport.Close())
})
return &Node{
NodeID: nodeID,
NodeInfo: nodeInfo,
NodeAddress: transport.Endpoints()[0].NodeAddress(nodeID),
PrivKey: privKey,
Router: router,
PeerManager: peerManager,
Transport: transport,
}
}
// MakeChannel opens a channel, with automatic error handling and cleanup. On
// test cleanup, it also checks that the channel is empty, to make sure
// all expected messages have been asserted.
func (n *Node) MakeChannel(t *testing.T, chID p2p.ChannelID, messageType proto.Message, size int) *p2p.Channel {
channel, err := n.Router.OpenChannel(chID, messageType, size)
require.NoError(t, err)
t.Cleanup(func() {
RequireEmpty(t, channel)
channel.Close()
})
return channel
}
// MakeChannelNoCleanup opens a channel, with automatic error handling. The
// caller must ensure proper cleanup of the channel.
func (n *Node) MakeChannelNoCleanup(
t *testing.T,
chID p2p.ChannelID,
messageType proto.Message,
size int,
) *p2p.Channel {
channel, err := n.Router.OpenChannel(chID, messageType, size)
require.NoError(t, err)
return channel
}
// MakePeerUpdates opens a peer update subscription, with automatic cleanup.
// It checks that all updates have been consumed during cleanup.
func (n *Node) MakePeerUpdates(t *testing.T) *p2p.PeerUpdates {
sub := n.PeerManager.Subscribe()
t.Cleanup(func() {
RequireNoUpdates(t, sub)
sub.Close()
})
return sub
}