//stm: #integration package itests import ( "context" "testing" "time" prooftypes "github.com/filecoin-project/go-state-types/proof" "github.com/filecoin-project/go-state-types/builtin" minertypes "github.com/filecoin-project/go-state-types/builtin/v8/miner" "github.com/filecoin-project/go-address" "github.com/filecoin-project/go-bitfield" "github.com/filecoin-project/go-state-types/crypto" "github.com/filecoin-project/go-state-types/dline" "github.com/filecoin-project/lotus/api" "github.com/filecoin-project/lotus/build" "github.com/filecoin-project/lotus/chain/actors" "github.com/filecoin-project/lotus/chain/types" "github.com/filecoin-project/lotus/itests/kit" "github.com/stretchr/testify/require" ) func TestWindowPostDispute(t *testing.T) { //stm: @CHAIN_SYNCER_LOAD_GENESIS_001, @CHAIN_SYNCER_FETCH_TIPSET_001, //stm: @CHAIN_SYNCER_START_001, @CHAIN_SYNCER_SYNC_001, @BLOCKCHAIN_BEACON_VALIDATE_BLOCK_VALUES_01 //stm: @CHAIN_SYNCER_COLLECT_CHAIN_001, @CHAIN_SYNCER_COLLECT_HEADERS_001, @CHAIN_SYNCER_VALIDATE_TIPSET_001 //stm: @CHAIN_SYNCER_NEW_PEER_HEAD_001, @CHAIN_SYNCER_VALIDATE_MESSAGE_META_001, @CHAIN_SYNCER_STOP_001 //stm: @CHAIN_INCOMING_HANDLE_INCOMING_BLOCKS_001, @CHAIN_INCOMING_VALIDATE_BLOCK_PUBSUB_001, @CHAIN_INCOMING_VALIDATE_MESSAGE_PUBSUB_001 kit.Expensive(t) kit.QuietMiningLogs() blocktime := 2 * time.Millisecond ctx, cancel := context.WithCancel(context.Background()) defer cancel() var ( client kit.TestFullNode chainMiner kit.TestMiner evilMiner kit.TestMiner ) // First, we configure two miners. After sealing, we're going to turn off the first miner so // it doesn't submit proofs. // // Then we're going to manually submit bad proofs. opts := []kit.NodeOpt{kit.WithAllSubsystems()} ens := kit.NewEnsemble(t, kit.MockProofs()). FullNode(&client, opts...). Miner(&chainMiner, &client, opts...). Miner(&evilMiner, &client, append(opts, kit.PresealSectors(0))...). Start() defaultFrom, err := client.WalletDefaultAddress(ctx) require.NoError(t, err) // Mine with the _second_ node (the good one). ens.InterconnectAll().BeginMining(blocktime, &chainMiner) // Give the chain miner enough sectors to win every block. chainMiner.PledgeSectors(ctx, 10, 0, nil) // And the evil one 1 sector. No cookie for you. evilMiner.PledgeSectors(ctx, 1, 0, nil) // Let the evil miner's sectors gain power. evilMinerAddr, err := evilMiner.ActorAddress(ctx) require.NoError(t, err) //stm: @CHAIN_STATE_MINER_CALCULATE_DEADLINE_001 di, err := client.StateMinerProvingDeadline(ctx, evilMinerAddr, types.EmptyTSK) require.NoError(t, err) t.Logf("Running one proving period\n") waitUntil := di.PeriodStart + di.WPoStProvingPeriod*2 + 1 t.Logf("End for head.Height > %d", waitUntil) ts := client.WaitTillChain(ctx, kit.HeightAtLeast(waitUntil)) t.Logf("Now head.Height = %d", ts.Height()) //stm: @CHAIN_STATE_MINER_POWER_001 p, err := client.StateMinerPower(ctx, evilMinerAddr, types.EmptyTSK) require.NoError(t, err) ssz, err := evilMiner.ActorSectorSize(ctx, evilMinerAddr) require.NoError(t, err) // make sure it has gained power. require.Equal(t, p.MinerPower.RawBytePower, types.NewInt(uint64(ssz))) //stm: @MINER_SECTOR_LIST_001 evilSectors, err := evilMiner.SectorsList(ctx) require.NoError(t, err) evilSectorNo := evilSectors[0] // only one. //stm: @CHAIN_STATE_SECTOR_PARTITION_001 evilSectorLoc, err := client.StateSectorPartition(ctx, evilMinerAddr, evilSectorNo, types.EmptyTSK) require.NoError(t, err) t.Log("evil miner stopping") // Now stop the evil miner, and start manually submitting bad proofs. require.NoError(t, evilMiner.Stop(ctx)) t.Log("evil miner stopped") // Wait until we need to prove our sector. for { //stm: @CHAIN_STATE_MINER_CALCULATE_DEADLINE_001 di, err = client.StateMinerProvingDeadline(ctx, evilMinerAddr, types.EmptyTSK) require.NoError(t, err) if di.Index == evilSectorLoc.Deadline && di.CurrentEpoch-di.PeriodStart > 1 { break } build.Clock.Sleep(blocktime) } err = submitBadProof(ctx, client, evilMiner.OwnerKey.Address, evilMinerAddr, di, evilSectorLoc.Deadline, evilSectorLoc.Partition) require.NoError(t, err, "evil proof not accepted") // Wait until after the proving period. for { //stm: @CHAIN_STATE_MINER_CALCULATE_DEADLINE_001 di, err = client.StateMinerProvingDeadline(ctx, evilMinerAddr, types.EmptyTSK) require.NoError(t, err) if di.Index != evilSectorLoc.Deadline { break } build.Clock.Sleep(blocktime) } t.Log("accepted evil proof") //stm: @CHAIN_STATE_MINER_POWER_001 // Make sure the evil node didn't lose any power. p, err = client.StateMinerPower(ctx, evilMinerAddr, types.EmptyTSK) require.NoError(t, err) require.Equal(t, p.MinerPower.RawBytePower, types.NewInt(uint64(ssz))) // OBJECTION! The good miner files a DISPUTE!!!! { params := &minertypes.DisputeWindowedPoStParams{ Deadline: evilSectorLoc.Deadline, PoStIndex: 0, } enc, aerr := actors.SerializeParams(params) require.NoError(t, aerr) msg := &types.Message{ To: evilMinerAddr, Method: builtin.MethodsMiner.DisputeWindowedPoSt, Params: enc, Value: types.NewInt(0), From: defaultFrom, } sm, err := client.MpoolPushMessage(ctx, msg, nil) require.NoError(t, err) t.Log("waiting dispute") //stm: @CHAIN_STATE_WAIT_MSG_001 rec, err := client.StateWaitMsg(ctx, sm.Cid(), build.MessageConfidence, api.LookbackNoLimit, true) require.NoError(t, err) require.Zero(t, rec.Receipt.ExitCode, "dispute not accepted: %s", rec.Receipt.ExitCode.Error()) } //stm: @CHAIN_STATE_MINER_POWER_001 // Objection SUSTAINED! // Make sure the evil node lost power. p, err = client.StateMinerPower(ctx, evilMinerAddr, types.EmptyTSK) require.NoError(t, err) require.True(t, p.MinerPower.RawBytePower.IsZero()) // Now we begin the redemption arc. require.True(t, p.MinerPower.RawBytePower.IsZero()) // First, recover the sector. { //stm: @CHAIN_STATE_MINER_INFO_001 minerInfo, err := client.StateMinerInfo(ctx, evilMinerAddr, types.EmptyTSK) require.NoError(t, err) params := &minertypes.DeclareFaultsRecoveredParams{ Recoveries: []minertypes.RecoveryDeclaration{{ Deadline: evilSectorLoc.Deadline, Partition: evilSectorLoc.Partition, Sectors: bitfield.NewFromSet([]uint64{uint64(evilSectorNo)}), }}, } enc, aerr := actors.SerializeParams(params) require.NoError(t, aerr) msg := &types.Message{ To: evilMinerAddr, Method: builtin.MethodsMiner.DeclareFaultsRecovered, Params: enc, Value: types.FromFil(30), // repay debt. From: minerInfo.Owner, } sm, err := client.MpoolPushMessage(ctx, msg, nil) require.NoError(t, err) //stm: @CHAIN_STATE_WAIT_MSG_001 rec, err := client.StateWaitMsg(ctx, sm.Cid(), build.MessageConfidence, api.LookbackNoLimit, true) require.NoError(t, err) require.Zero(t, rec.Receipt.ExitCode, "recovery not accepted: %s", rec.Receipt.ExitCode.Error()) } // Then wait for the deadline. for { //stm: @CHAIN_STATE_MINER_CALCULATE_DEADLINE_001 di, err = client.StateMinerProvingDeadline(ctx, evilMinerAddr, types.EmptyTSK) require.NoError(t, err) if di.Index == evilSectorLoc.Deadline { break } build.Clock.Sleep(blocktime) } // Now try to be evil again err = submitBadProof(ctx, client, evilMiner.OwnerKey.Address, evilMinerAddr, di, evilSectorLoc.Deadline, evilSectorLoc.Partition) require.Error(t, err) require.Equal(t, 16, err) // It didn't work because we're recovering. } func TestWindowPostDisputeFails(t *testing.T) { //stm: @CHAIN_SYNCER_LOAD_GENESIS_001, @CHAIN_SYNCER_FETCH_TIPSET_001, //stm: @CHAIN_SYNCER_START_001, @CHAIN_SYNCER_SYNC_001, @BLOCKCHAIN_BEACON_VALIDATE_BLOCK_VALUES_01 //stm: @CHAIN_SYNCER_COLLECT_CHAIN_001, @CHAIN_SYNCER_COLLECT_HEADERS_001, @CHAIN_SYNCER_VALIDATE_TIPSET_001 //stm: @CHAIN_SYNCER_NEW_PEER_HEAD_001, @CHAIN_SYNCER_VALIDATE_MESSAGE_META_001, @CHAIN_SYNCER_STOP_001 //stm: @CHAIN_STATE_MINER_GET_DEADLINES_001 kit.Expensive(t) kit.QuietMiningLogs() blocktime := 2 * time.Millisecond ctx, cancel := context.WithCancel(context.Background()) defer cancel() client, miner, ens := kit.EnsembleMinimal(t, kit.MockProofs()) ens.InterconnectAll().BeginMining(blocktime) defaultFrom, err := client.WalletDefaultAddress(ctx) require.NoError(t, err) maddr, err := miner.ActorAddress(ctx) require.NoError(t, err) build.Clock.Sleep(time.Second) miner.PledgeSectors(ctx, 10, 0, nil) //stm: @CHAIN_STATE_MINER_CALCULATE_DEADLINE_001 di, err := client.StateMinerProvingDeadline(ctx, maddr, types.EmptyTSK) require.NoError(t, err) t.Log("Running one proving period") waitUntil := di.PeriodStart + di.WPoStProvingPeriod*2 + 1 t.Logf("End for head.Height > %d", waitUntil) ts := client.WaitTillChain(ctx, kit.HeightAtLeast(waitUntil)) t.Logf("Now head.Height = %d", ts.Height()) ssz, err := miner.ActorSectorSize(ctx, maddr) require.NoError(t, err) expectedPower := types.NewInt(uint64(ssz) * (kit.DefaultPresealsPerBootstrapMiner + 10)) //stm: @CHAIN_STATE_MINER_POWER_001 p, err := client.StateMinerPower(ctx, maddr, types.EmptyTSK) require.NoError(t, err) // make sure it has gained power. require.Equal(t, p.MinerPower.RawBytePower, expectedPower) // Wait until a proof has been submitted. var targetDeadline uint64 waitForProof: for { deadlines, err := client.StateMinerDeadlines(ctx, maddr, types.EmptyTSK) require.NoError(t, err) for dlIdx, dl := range deadlines { nonEmpty, err := dl.PostSubmissions.IsEmpty() require.NoError(t, err) if nonEmpty { targetDeadline = uint64(dlIdx) break waitForProof } } build.Clock.Sleep(blocktime) } for { //stm: @CHAIN_STATE_MINER_CALCULATE_DEADLINE_001 di, err := client.StateMinerProvingDeadline(ctx, maddr, types.EmptyTSK) require.NoError(t, err) // wait until the deadline finishes. if di.Index == ((targetDeadline + 1) % di.WPoStPeriodDeadlines) { break } build.Clock.Sleep(blocktime) } // Try to object to the proof. This should fail. { params := &minertypes.DisputeWindowedPoStParams{ Deadline: targetDeadline, PoStIndex: 0, } enc, aerr := actors.SerializeParams(params) require.NoError(t, aerr) msg := &types.Message{ To: maddr, Method: builtin.MethodsMiner.DisputeWindowedPoSt, Params: enc, Value: types.NewInt(0), From: defaultFrom, } _, err := client.MpoolPushMessage(ctx, msg, nil) require.Error(t, err) require.Equal(t, err, 16) } } func submitBadProof( ctx context.Context, client api.FullNode, owner address.Address, maddr address.Address, di *dline.Info, dlIdx, partIdx uint64, ) error { head, err := client.ChainHead(ctx) if err != nil { return err } //stm: @CHAIN_STATE_MINER_INFO_001 minerInfo, err := client.StateMinerInfo(ctx, maddr, head.Key()) if err != nil { return err } //stm: @CHAIN_STATE_GET_RANDOMNESS_FROM_TICKETS_001 commEpoch := di.Open commRand, err := client.StateGetRandomnessFromTickets( ctx, crypto.DomainSeparationTag_PoStChainCommit, commEpoch, nil, head.Key(), ) if err != nil { return err } params := &minertypes.SubmitWindowedPoStParams{ ChainCommitEpoch: commEpoch, ChainCommitRand: commRand, Deadline: dlIdx, Partitions: []minertypes.PoStPartition{{Index: partIdx}}, Proofs: []prooftypes.PoStProof{{ PoStProof: minerInfo.WindowPoStProofType, ProofBytes: []byte("I'm soooo very evil."), }}, } enc, aerr := actors.SerializeParams(params) if aerr != nil { return aerr } msg := &types.Message{ To: maddr, Method: builtin.MethodsMiner.SubmitWindowedPoSt, Params: enc, Value: types.NewInt(0), From: owner, } sm, err := client.MpoolPushMessage(ctx, msg, nil) if err != nil { return err } //stm: @CHAIN_STATE_WAIT_MSG_001 rec, err := client.StateWaitMsg(ctx, sm.Cid(), build.MessageConfidence, api.LookbackNoLimit, true) if err != nil { return err } if rec.Receipt.ExitCode.IsError() { return rec.Receipt.ExitCode } return nil }