go-waku/waku/v2/protocol/rln/rln_relay_test.go

198 lines
6.3 KiB
Go

package rln
import (
"context"
"crypto/rand"
"testing"
"time"
r "github.com/status-im/go-rln/rln"
"github.com/status-im/go-waku/tests"
"github.com/status-im/go-waku/waku/v2/protocol/pb"
"github.com/status-im/go-waku/waku/v2/protocol/relay"
"github.com/status-im/go-waku/waku/v2/utils"
"github.com/stretchr/testify/suite"
)
const RLNRELAY_PUBSUB_TOPIC = "waku/2/rlnrelay/proto"
const RLNRELAY_CONTENT_TOPIC = "waku/2/rlnrelay/proto"
func TestWakuRLNRelaySuite(t *testing.T) {
suite.Run(t, new(WakuRLNRelaySuite))
}
type WakuRLNRelaySuite struct {
suite.Suite
}
func (s *WakuRLNRelaySuite) TestOffchainMode() {
port, err := tests.FindFreePort(s.T(), "", 5)
s.NoError(err)
host, err := tests.MakeHost(context.Background(), port, rand.Reader)
s.NoError(err)
relay, err := relay.NewWakuRelay(context.Background(), host, nil, 0, utils.Logger())
defer relay.Stop()
s.NoError(err)
params, err := parametersKeyBytes()
s.NoError(err)
groupKeyPairs, root, err := r.CreateMembershipList(100, params)
s.NoError(err)
var groupIDCommitments []r.IDCommitment
for _, c := range groupKeyPairs {
groupIDCommitments = append(groupIDCommitments, c.IDCommitment)
}
// index indicates the position of a membership key pair in the static list of group keys i.e., groupKeyPairs
// the corresponding key pair will be used to mount rlnRelay on the current node
// index also represents the index of the leaf in the Merkle tree that contains node's commitment key
index := r.MembershipIndex(5)
wakuRLNRelay, err := RlnRelayStatic(context.TODO(), relay, groupIDCommitments, groupKeyPairs[index], index, RLNRELAY_PUBSUB_TOPIC, RLNRELAY_CONTENT_TOPIC, nil, utils.Logger())
s.NoError(err)
// get the root of Merkle tree which is constructed inside the mountRlnRelay proc
calculatedRoot, err := wakuRLNRelay.RLN.GetMerkleRoot()
s.NoError(err)
// Checks whether the Merkle tree is constructed correctly inside the mountRlnRelay func
// this check is done by comparing the tree root resulted from mountRlnRelay i.e., calculatedRoot
// against the root which is the expected root
s.Equal(root[:], calculatedRoot[:])
}
func (s *WakuRLNRelaySuite) TestUpdateLogAndHasDuplicate() {
rlnRelay := &WakuRLNRelay{
nullifierLog: make(map[r.Epoch][]r.ProofMetadata),
}
epoch := r.GetCurrentEpoch()
// create some dummy nullifiers and secret shares
var nullifier1, nullifier2, nullifier3 r.Nullifier
var shareX1, shareX2, shareX3 r.MerkleNode
var shareY1, shareY2, shareY3 r.MerkleNode
for i := 0; i < 32; i++ {
nullifier1[i] = 1
nullifier2[i] = 2
nullifier3[i] = nullifier1[i]
shareX1[i] = 1
shareX2[i] = 2
shareX3[i] = 3
shareY1[i] = 1
shareY2[i] = shareX2[i]
shareY3[i] = shareX3[i]
}
wm1 := &pb.WakuMessage{RateLimitProof: &pb.RateLimitProof{Epoch: epoch[:], Nullifier: nullifier1[:], ShareX: shareX1[:], ShareY: shareY1[:]}}
wm2 := &pb.WakuMessage{RateLimitProof: &pb.RateLimitProof{Epoch: epoch[:], Nullifier: nullifier2[:], ShareX: shareX2[:], ShareY: shareY2[:]}}
wm3 := &pb.WakuMessage{RateLimitProof: &pb.RateLimitProof{Epoch: epoch[:], Nullifier: nullifier3[:], ShareX: shareX3[:], ShareY: shareY3[:]}}
// check whether hasDuplicate correctly finds records with the same nullifiers but different secret shares
// no duplicate for wm1 should be found, since the log is empty
result1, err := rlnRelay.HasDuplicate(wm1)
s.NoError(err)
s.False(result1) // No duplicate is found
// Add it to the log
added, err := rlnRelay.UpdateLog(wm1)
s.NoError(err)
s.True(added)
// no duplicate for wm2 should be found, its nullifier differs from wm1
result2, err := rlnRelay.HasDuplicate(wm2)
s.NoError(err)
s.False(result2) // No duplicate is found
// Add it to the log
added, err = rlnRelay.UpdateLog(wm2)
s.NoError(err)
s.True(added)
// wm3 has the same nullifier as wm1 but different secret shares, it should be detected as duplicate
result3, err := rlnRelay.HasDuplicate(wm3)
s.NoError(err)
s.True(result3) // It's a duplicate
}
func (s *WakuRLNRelaySuite) TestValidateMessage() {
params, err := parametersKeyBytes()
s.NoError(err)
groupKeyPairs, _, err := r.CreateMembershipList(100, params)
s.NoError(err)
var groupIDCommitments []r.IDCommitment
for _, c := range groupKeyPairs {
groupIDCommitments = append(groupIDCommitments, c.IDCommitment)
}
// index indicates the position of a membership key pair in the static list of group keys i.e., groupKeyPairs
// the corresponding key pair will be used to mount rlnRelay on the current node
// index also represents the index of the leaf in the Merkle tree that contains node's commitment key
index := r.MembershipIndex(5)
// Create a RLN instance
rlnInstance, err := r.NewRLN(params)
s.NoError(err)
added := rlnInstance.AddAll(groupIDCommitments)
s.True(added)
rlnRelay := &WakuRLNRelay{
membershipIndex: index,
membershipKeyPair: groupKeyPairs[index],
RLN: rlnInstance,
nullifierLog: make(map[r.Epoch][]r.ProofMetadata),
log: utils.Logger(),
}
//get the current epoch time
now := time.Now()
// create some messages from the same peer and append rln proof to them, except wm4
wm1 := &pb.WakuMessage{Payload: []byte("Valid message")}
err = rlnRelay.AppendRLNProof(wm1, now)
s.NoError(err)
// another message in the same epoch as wm1, it will break the messaging rate limit
wm2 := &pb.WakuMessage{Payload: []byte("Spam")}
err = rlnRelay.AppendRLNProof(wm2, now)
s.NoError(err)
// wm3 points to the next epoch
wm3 := &pb.WakuMessage{Payload: []byte("Valid message")}
err = rlnRelay.AppendRLNProof(wm3, now.Add(time.Second*time.Duration(r.EPOCH_UNIT_SECONDS)))
s.NoError(err)
wm4 := &pb.WakuMessage{Payload: []byte("Invalid message")}
// valid message
msgValidate1, err := rlnRelay.ValidateMessage(wm1, &now)
s.NoError(err)
// wm2 is published within the same Epoch as wm1 and should be found as spam
msgValidate2, err := rlnRelay.ValidateMessage(wm2, &now)
s.NoError(err)
// a valid message should be validated successfully
msgValidate3, err := rlnRelay.ValidateMessage(wm3, &now)
s.NoError(err)
// wm4 has no rln proof and should not be validated
msgValidate4, err := rlnRelay.ValidateMessage(wm4, &now)
s.NoError(err)
s.Equal(MessageValidationResult_Valid, msgValidate1)
s.Equal(MessageValidationResult_Spam, msgValidate2)
s.Equal(MessageValidationResult_Valid, msgValidate3)
s.Equal(MessageValidationResult_Invalid, msgValidate4)
}