package stmgr import ( "bytes" "context" "encoding/binary" "runtime" "sort" "sync" "time" "github.com/filecoin-project/go-state-types/rt" "github.com/filecoin-project/go-address" "github.com/filecoin-project/go-state-types/abi" "github.com/filecoin-project/go-state-types/big" "github.com/filecoin-project/go-state-types/network" "github.com/filecoin-project/lotus/build" "github.com/filecoin-project/lotus/chain/actors/adt" "github.com/filecoin-project/lotus/chain/actors/builtin" init_ "github.com/filecoin-project/lotus/chain/actors/builtin/init" "github.com/filecoin-project/lotus/chain/actors/builtin/multisig" "github.com/filecoin-project/lotus/chain/state" "github.com/filecoin-project/lotus/chain/store" "github.com/filecoin-project/lotus/chain/types" "github.com/filecoin-project/lotus/chain/vm" bstore "github.com/filecoin-project/lotus/lib/blockstore" "github.com/filecoin-project/lotus/lib/bufbstore" builtin0 "github.com/filecoin-project/specs-actors/actors/builtin" miner0 "github.com/filecoin-project/specs-actors/actors/builtin/miner" multisig0 "github.com/filecoin-project/specs-actors/actors/builtin/multisig" power0 "github.com/filecoin-project/specs-actors/actors/builtin/power" "github.com/filecoin-project/specs-actors/actors/migration/nv3" adt0 "github.com/filecoin-project/specs-actors/actors/util/adt" "github.com/filecoin-project/specs-actors/v2/actors/migration/nv4" "github.com/filecoin-project/specs-actors/v2/actors/migration/nv7" "github.com/filecoin-project/specs-actors/v3/actors/migration/nv10" "github.com/ipfs/go-cid" cbor "github.com/ipfs/go-ipld-cbor" "golang.org/x/xerrors" ) // MigrationCache can be used to cache information used by a migration. This is primarily useful to // "pre-compute" some migration state ahead of time, and make it accessible in the migration itself. type MigrationCache interface { Write(key string, value cid.Cid) error Read(key string) (bool, cid.Cid, error) Load(key string, loadFunc func() (cid.Cid, error)) (cid.Cid, error) } // MigrationFunc is a migration function run at every upgrade. // // - The cache is a per-upgrade cache, pre-populated by pre-migrations. // - The oldState is the state produced by the upgrade epoch. // - The returned newState is the new state that will be used by the next epoch. // - The height is the upgrade epoch height (already executed). // - The tipset is the tipset for the last non-null block before the upgrade. Do // not assume that ts.Height() is the upgrade height. type MigrationFunc func( ctx context.Context, sm *StateManager, cache MigrationCache, cb ExecCallback, oldState cid.Cid, height abi.ChainEpoch, ts *types.TipSet, ) (newState cid.Cid, err error) // PreMigrationFunc is a function run _before_ a network upgrade to pre-compute part of the network // upgrade and speed it up. type PreMigrationFunc func( ctx context.Context, sm *StateManager, cache MigrationCache, oldState cid.Cid, height abi.ChainEpoch, ts *types.TipSet, ) error // PreMigration describes a pre-migration step to prepare for a network state upgrade. Pre-migrations // are optimizations, are not guaranteed to run, and may be canceled and/or run multiple times. type PreMigration struct { // PreMigration is the pre-migration function to run at the specified time. This function is // run asynchronously and must abort promptly when canceled. PreMigration PreMigrationFunc // StartWithin specifies that this pre-migration should be started at most StartWithin // epochs before the upgrade. StartWithin abi.ChainEpoch // DontStartWithin specifies that this pre-migration should not be started DontStartWithin // epochs before the final upgrade epoch. // // This should be set such that the pre-migration is likely to complete before StopWithin. DontStartWithin abi.ChainEpoch // StopWithin specifies that this pre-migration should be stopped StopWithin epochs of the // final upgrade epoch. StopWithin abi.ChainEpoch } type Upgrade struct { Height abi.ChainEpoch Network network.Version Expensive bool Migration MigrationFunc // PreMigrations specifies a set of pre-migration functions to run at the indicated epochs. // These functions should fill the given cache with information that can speed up the // eventual full migration at the upgrade epoch. PreMigrations []PreMigration } type UpgradeSchedule []Upgrade type migrationLogger struct{} func (ml migrationLogger) Log(level rt.LogLevel, msg string, args ...interface{}) { switch level { case rt.DEBUG: log.Debugf(msg, args...) case rt.INFO: log.Infof(msg, args...) case rt.WARN: log.Warnf(msg, args...) case rt.ERROR: log.Errorf(msg, args...) } } func DefaultUpgradeSchedule() UpgradeSchedule { var us UpgradeSchedule updates := []Upgrade{{ Height: build.UpgradeBreezeHeight, Network: network.Version1, Migration: UpgradeFaucetBurnRecovery, }, { Height: build.UpgradeSmokeHeight, Network: network.Version2, Migration: nil, }, { Height: build.UpgradeIgnitionHeight, Network: network.Version3, Migration: UpgradeIgnition, }, { Height: build.UpgradeRefuelHeight, Network: network.Version3, Migration: UpgradeRefuel, }, { Height: build.UpgradeActorsV2Height, Network: network.Version4, Expensive: true, Migration: UpgradeActorsV2, }, { Height: build.UpgradeTapeHeight, Network: network.Version5, Migration: nil, }, { Height: build.UpgradeLiftoffHeight, Network: network.Version5, Migration: UpgradeLiftoff, }, { Height: build.UpgradeKumquatHeight, Network: network.Version6, Migration: nil, }, { Height: build.UpgradeCalicoHeight, Network: network.Version7, Migration: UpgradeCalico, }, { Height: build.UpgradePersianHeight, Network: network.Version8, Migration: nil, }, { Height: build.UpgradeOrangeHeight, Network: network.Version9, Migration: nil, }, { Height: build.UpgradeActorsV3Height, Network: network.Version10, Migration: UpgradeActorsV3, PreMigrations: []PreMigration{{ PreMigration: PreUpgradeActorsV3, StartWithin: 120, DontStartWithin: 60, StopWithin: 35, }, { PreMigration: PreUpgradeActorsV3, StartWithin: 30, DontStartWithin: 15, StopWithin: 5, }}, Expensive: true, }} for _, u := range updates { if u.Height < 0 { // upgrade disabled continue } us = append(us, u) } return us } func (us UpgradeSchedule) Validate() error { // Make sure each upgrade is valid. for _, u := range us { if u.Network <= 0 { return xerrors.Errorf("cannot upgrade to version <= 0: %d", u.Network) } for _, m := range u.PreMigrations { if m.StartWithin <= 0 { return xerrors.Errorf("pre-migration must specify a positive start-within epoch") } if m.DontStartWithin < 0 || m.StopWithin < 0 { return xerrors.Errorf("pre-migration must specify non-negative epochs") } if m.StartWithin <= m.StopWithin { return xerrors.Errorf("pre-migration start-within must come before stop-within") } // If we have a dont-start-within. if m.DontStartWithin != 0 { if m.DontStartWithin < m.StopWithin { return xerrors.Errorf("pre-migration dont-start-within must come before stop-within") } if m.StartWithin <= m.DontStartWithin { return xerrors.Errorf("pre-migration start-within must come after dont-start-within") } } } if !sort.SliceIsSorted(u.PreMigrations, func(i, j int) bool { return u.PreMigrations[i].StartWithin > u.PreMigrations[j].StartWithin //nolint:scopelint,gosec }) { return xerrors.Errorf("pre-migrations must be sorted by start epoch") } } // Make sure the upgrade order makes sense. for i := 1; i < len(us); i++ { prev := &us[i-1] curr := &us[i] if !(prev.Network <= curr.Network) { return xerrors.Errorf("cannot downgrade from version %d to version %d", prev.Network, curr.Network) } // Make sure the heights make sense. if prev.Height < 0 { // Previous upgrade was disabled. continue } if !(prev.Height < curr.Height) { return xerrors.Errorf("upgrade heights must be strictly increasing: upgrade %d was at height %d, followed by upgrade %d at height %d", i-1, prev.Height, i, curr.Height) } } return nil } func (sm *StateManager) handleStateForks(ctx context.Context, root cid.Cid, height abi.ChainEpoch, cb ExecCallback, ts *types.TipSet) (cid.Cid, error) { retCid := root var err error u := sm.stateMigrations[height] if u != nil && u.upgrade != nil { startTime := time.Now() log.Warnw("STARTING migration", "height", height, "from", root) // Yes, we clone the cache, even for the final upgrade epoch. Why? Reverts. We may // have to migrate multiple times. tmpCache := u.cache.Clone() retCid, err = u.upgrade(ctx, sm, tmpCache, cb, root, height, ts) if err != nil { log.Errorw("FAILED migration", "height", height, "from", root, "error", err) return cid.Undef, err } // Yes, we update the cache, even for the final upgrade epoch. Why? Reverts. This // can save us a _lot_ of time because very few actors will have changed if we // do a small revert then need to re-run the migration. u.cache.Update(tmpCache) log.Warnw("COMPLETED migration", "height", height, "from", root, "to", retCid, "duration", time.Since(startTime), ) } return retCid, nil } func (sm *StateManager) hasExpensiveFork(ctx context.Context, height abi.ChainEpoch) bool { _, ok := sm.expensiveUpgrades[height] return ok } func runPreMigration(ctx context.Context, sm *StateManager, fn PreMigrationFunc, cache *nv10.MemMigrationCache, ts *types.TipSet) { height := ts.Height() parent := ts.ParentState() startTime := time.Now() log.Warn("STARTING pre-migration") // Clone the cache so we don't actually _update_ it // till we're done. Otherwise, if we fail, the next // migration to use the cache may assume that // certain blocks exist, even if they don't. tmpCache := cache.Clone() err := fn(ctx, sm, tmpCache, parent, height, ts) if err != nil { log.Errorw("FAILED pre-migration", "error", err) return } // Finally, if everything worked, update the cache. cache.Update(tmpCache) log.Warnw("COMPLETED pre-migration", "duration", time.Since(startTime)) } func (sm *StateManager) preMigrationWorker(ctx context.Context) { defer close(sm.shutdown) ctx, cancel := context.WithCancel(ctx) defer cancel() type op struct { after abi.ChainEpoch notAfter abi.ChainEpoch run func(ts *types.TipSet) } var wg sync.WaitGroup defer wg.Wait() // Turn each pre-migration into an operation in a schedule. var schedule []op for upgradeEpoch, migration := range sm.stateMigrations { cache := migration.cache for _, prem := range migration.preMigrations { preCtx, preCancel := context.WithCancel(ctx) migrationFunc := prem.PreMigration afterEpoch := upgradeEpoch - prem.StartWithin notAfterEpoch := upgradeEpoch - prem.DontStartWithin stopEpoch := upgradeEpoch - prem.StopWithin // We can't start after we stop. if notAfterEpoch > stopEpoch { notAfterEpoch = stopEpoch - 1 } // Add an op to start a pre-migration. schedule = append(schedule, op{ after: afterEpoch, notAfter: notAfterEpoch, // TODO: are these values correct? run: func(ts *types.TipSet) { wg.Add(1) go func() { defer wg.Done() runPreMigration(preCtx, sm, migrationFunc, cache, ts) }() }, }) // Add an op to cancel the pre-migration if it's still running. schedule = append(schedule, op{ after: stopEpoch, notAfter: -1, run: func(ts *types.TipSet) { preCancel() }, }) } } // Then sort by epoch. sort.Slice(schedule, func(i, j int) bool { return schedule[i].after < schedule[j].after }) // Finally, when the head changes, see if there's anything we need to do. // // We're intentionally ignoring reorgs as they don't matter for our purposes. for change := range sm.cs.SubHeadChanges(ctx) { for _, head := range change { for len(schedule) > 0 { op := &schedule[0] if head.Val.Height() < op.after { break } // If we haven't passed the pre-migration height... if op.notAfter < 0 || head.Val.Height() < op.notAfter { op.run(head.Val) } schedule = schedule[1:] } } } } func doTransfer(tree types.StateTree, from, to address.Address, amt abi.TokenAmount, cb func(trace types.ExecutionTrace)) error { fromAct, err := tree.GetActor(from) if err != nil { return xerrors.Errorf("failed to get 'from' actor for transfer: %w", err) } fromAct.Balance = types.BigSub(fromAct.Balance, amt) if fromAct.Balance.Sign() < 0 { return xerrors.Errorf("(sanity) deducted more funds from target account than it had (%s, %s)", from, types.FIL(amt)) } if err := tree.SetActor(from, fromAct); err != nil { return xerrors.Errorf("failed to persist from actor: %w", err) } toAct, err := tree.GetActor(to) if err != nil { return xerrors.Errorf("failed to get 'to' actor for transfer: %w", err) } toAct.Balance = types.BigAdd(toAct.Balance, amt) if err := tree.SetActor(to, toAct); err != nil { return xerrors.Errorf("failed to persist to actor: %w", err) } if cb != nil { // record the transfer in execution traces fakeMsg := &types.Message{ From: from, To: to, Value: amt, } fakeRct := &types.MessageReceipt{ ExitCode: 0, Return: nil, GasUsed: 0, } cb(types.ExecutionTrace{ Msg: fakeMsg, MsgRct: fakeRct, Error: "", Duration: 0, GasCharges: nil, Subcalls: nil, }) } return nil } func UpgradeFaucetBurnRecovery(ctx context.Context, sm *StateManager, _ MigrationCache, cb ExecCallback, root cid.Cid, epoch abi.ChainEpoch, ts *types.TipSet) (cid.Cid, error) { // Some initial parameters FundsForMiners := types.FromFil(1_000_000) LookbackEpoch := abi.ChainEpoch(32000) AccountCap := types.FromFil(0) BaseMinerBalance := types.FromFil(20) DesiredReimbursementBalance := types.FromFil(5_000_000) isSystemAccount := func(addr address.Address) (bool, error) { id, err := address.IDFromAddress(addr) if err != nil { return false, xerrors.Errorf("id address: %w", err) } if id < 1000 { return true, nil } return false, nil } minerFundsAlloc := func(pow, tpow abi.StoragePower) abi.TokenAmount { return types.BigDiv(types.BigMul(pow, FundsForMiners), tpow) } // Grab lookback state for account checks lbts, err := sm.ChainStore().GetTipsetByHeight(ctx, LookbackEpoch, ts, false) if err != nil { return cid.Undef, xerrors.Errorf("failed to get tipset at lookback height: %w", err) } lbtree, err := sm.ParentState(lbts) if err != nil { return cid.Undef, xerrors.Errorf("loading state tree failed: %w", err) } tree, err := sm.StateTree(root) if err != nil { return cid.Undef, xerrors.Errorf("getting state tree: %w", err) } type transfer struct { From address.Address To address.Address Amt abi.TokenAmount } var transfers []transfer subcalls := make([]types.ExecutionTrace, 0) transferCb := func(trace types.ExecutionTrace) { subcalls = append(subcalls, trace) } // Take all excess funds away, put them into the reserve account err = tree.ForEach(func(addr address.Address, act *types.Actor) error { switch act.Code { case builtin0.AccountActorCodeID, builtin0.MultisigActorCodeID, builtin0.PaymentChannelActorCodeID: sysAcc, err := isSystemAccount(addr) if err != nil { return xerrors.Errorf("checking system account: %w", err) } if !sysAcc { transfers = append(transfers, transfer{ From: addr, To: builtin.ReserveAddress, Amt: act.Balance, }) } case builtin0.StorageMinerActorCodeID: var st miner0.State if err := sm.ChainStore().Store(ctx).Get(ctx, act.Head, &st); err != nil { return xerrors.Errorf("failed to load miner state: %w", err) } var available abi.TokenAmount { defer func() { if err := recover(); err != nil { log.Warnf("Get available balance failed (%s, %s, %s): %s", addr, act.Head, act.Balance, err) } available = abi.NewTokenAmount(0) }() // this panics if the miner doesnt have enough funds to cover their locked pledge available = st.GetAvailableBalance(act.Balance) } if !available.IsZero() { transfers = append(transfers, transfer{ From: addr, To: builtin.ReserveAddress, Amt: available, }) } } return nil }) if err != nil { return cid.Undef, xerrors.Errorf("foreach over state tree failed: %w", err) } // Execute transfers from previous step for _, t := range transfers { if err := doTransfer(tree, t.From, t.To, t.Amt, transferCb); err != nil { return cid.Undef, xerrors.Errorf("transfer %s %s->%s failed: %w", t.Amt, t.From, t.To, err) } } // pull up power table to give miners back some funds proportional to their power var ps power0.State powAct, err := tree.GetActor(builtin0.StoragePowerActorAddr) if err != nil { return cid.Undef, xerrors.Errorf("failed to load power actor: %w", err) } cst := cbor.NewCborStore(sm.ChainStore().Blockstore()) if err := cst.Get(ctx, powAct.Head, &ps); err != nil { return cid.Undef, xerrors.Errorf("failed to get power actor state: %w", err) } totalPower := ps.TotalBytesCommitted var transfersBack []transfer // Now, we return some funds to places where they are needed err = tree.ForEach(func(addr address.Address, act *types.Actor) error { lbact, err := lbtree.GetActor(addr) if err != nil { if !xerrors.Is(err, types.ErrActorNotFound) { return xerrors.Errorf("failed to get actor in lookback state") } } prevBalance := abi.NewTokenAmount(0) if lbact != nil { prevBalance = lbact.Balance } switch act.Code { case builtin0.AccountActorCodeID, builtin0.MultisigActorCodeID, builtin0.PaymentChannelActorCodeID: nbalance := big.Min(prevBalance, AccountCap) if nbalance.Sign() != 0 { transfersBack = append(transfersBack, transfer{ From: builtin.ReserveAddress, To: addr, Amt: nbalance, }) } case builtin0.StorageMinerActorCodeID: var st miner0.State if err := sm.ChainStore().Store(ctx).Get(ctx, act.Head, &st); err != nil { return xerrors.Errorf("failed to load miner state: %w", err) } var minfo miner0.MinerInfo if err := cst.Get(ctx, st.Info, &minfo); err != nil { return xerrors.Errorf("failed to get miner info: %w", err) } sectorsArr, err := adt0.AsArray(sm.ChainStore().Store(ctx), st.Sectors) if err != nil { return xerrors.Errorf("failed to load sectors array: %w", err) } slen := sectorsArr.Length() power := types.BigMul(types.NewInt(slen), types.NewInt(uint64(minfo.SectorSize))) mfunds := minerFundsAlloc(power, totalPower) transfersBack = append(transfersBack, transfer{ From: builtin.ReserveAddress, To: minfo.Worker, Amt: mfunds, }) // Now make sure to give each miner who had power at the lookback some FIL lbact, err := lbtree.GetActor(addr) if err == nil { var lbst miner0.State if err := sm.ChainStore().Store(ctx).Get(ctx, lbact.Head, &lbst); err != nil { return xerrors.Errorf("failed to load miner state: %w", err) } lbsectors, err := adt0.AsArray(sm.ChainStore().Store(ctx), lbst.Sectors) if err != nil { return xerrors.Errorf("failed to load lb sectors array: %w", err) } if lbsectors.Length() > 0 { transfersBack = append(transfersBack, transfer{ From: builtin.ReserveAddress, To: minfo.Worker, Amt: BaseMinerBalance, }) } } else { log.Warnf("failed to get miner in lookback state: %s", err) } } return nil }) if err != nil { return cid.Undef, xerrors.Errorf("foreach over state tree failed: %w", err) } for _, t := range transfersBack { if err := doTransfer(tree, t.From, t.To, t.Amt, transferCb); err != nil { return cid.Undef, xerrors.Errorf("transfer %s %s->%s failed: %w", t.Amt, t.From, t.To, err) } } // transfer all burnt funds back to the reserve account burntAct, err := tree.GetActor(builtin0.BurntFundsActorAddr) if err != nil { return cid.Undef, xerrors.Errorf("failed to load burnt funds actor: %w", err) } if err := doTransfer(tree, builtin0.BurntFundsActorAddr, builtin.ReserveAddress, burntAct.Balance, transferCb); err != nil { return cid.Undef, xerrors.Errorf("failed to unburn funds: %w", err) } // Top up the reimbursement service reimbAddr, err := address.NewFromString("t0111") if err != nil { return cid.Undef, xerrors.Errorf("failed to parse reimbursement service address") } reimb, err := tree.GetActor(reimbAddr) if err != nil { return cid.Undef, xerrors.Errorf("failed to load reimbursement account actor: %w", err) } difference := types.BigSub(DesiredReimbursementBalance, reimb.Balance) if err := doTransfer(tree, builtin.ReserveAddress, reimbAddr, difference, transferCb); err != nil { return cid.Undef, xerrors.Errorf("failed to top up reimbursement account: %w", err) } // Now, a final sanity check to make sure the balances all check out total := abi.NewTokenAmount(0) err = tree.ForEach(func(addr address.Address, act *types.Actor) error { total = types.BigAdd(total, act.Balance) return nil }) if err != nil { return cid.Undef, xerrors.Errorf("checking final state balance failed: %w", err) } exp := types.FromFil(build.FilBase) if !exp.Equals(total) { return cid.Undef, xerrors.Errorf("resultant state tree account balance was not correct: %s", total) } if cb != nil { // record the transfer in execution traces fakeMsg := &types.Message{ From: builtin.SystemActorAddr, To: builtin.SystemActorAddr, Value: big.Zero(), Nonce: uint64(epoch), } fakeRct := &types.MessageReceipt{ ExitCode: 0, Return: nil, GasUsed: 0, } if err := cb(fakeMsg.Cid(), fakeMsg, &vm.ApplyRet{ MessageReceipt: *fakeRct, ActorErr: nil, ExecutionTrace: types.ExecutionTrace{ Msg: fakeMsg, MsgRct: fakeRct, Error: "", Duration: 0, GasCharges: nil, Subcalls: subcalls, }, Duration: 0, GasCosts: nil, }); err != nil { return cid.Undef, xerrors.Errorf("recording transfers: %w", err) } } return tree.Flush(ctx) } func UpgradeIgnition(ctx context.Context, sm *StateManager, _ MigrationCache, cb ExecCallback, root cid.Cid, epoch abi.ChainEpoch, ts *types.TipSet) (cid.Cid, error) { store := sm.cs.Store(ctx) if build.UpgradeLiftoffHeight <= epoch { return cid.Undef, xerrors.Errorf("liftoff height must be beyond ignition height") } nst, err := nv3.MigrateStateTree(ctx, store, root, epoch) if err != nil { return cid.Undef, xerrors.Errorf("migrating actors state: %w", err) } tree, err := sm.StateTree(nst) if err != nil { return cid.Undef, xerrors.Errorf("getting state tree: %w", err) } err = setNetworkName(ctx, store, tree, "ignition") if err != nil { return cid.Undef, xerrors.Errorf("setting network name: %w", err) } split1, err := address.NewFromString("t0115") if err != nil { return cid.Undef, xerrors.Errorf("first split address: %w", err) } split2, err := address.NewFromString("t0116") if err != nil { return cid.Undef, xerrors.Errorf("second split address: %w", err) } err = resetGenesisMsigs0(ctx, sm, store, tree, build.UpgradeLiftoffHeight) if err != nil { return cid.Undef, xerrors.Errorf("resetting genesis msig start epochs: %w", err) } err = splitGenesisMultisig0(ctx, cb, split1, store, tree, 50, epoch) if err != nil { return cid.Undef, xerrors.Errorf("splitting first msig: %w", err) } err = splitGenesisMultisig0(ctx, cb, split2, store, tree, 50, epoch) if err != nil { return cid.Undef, xerrors.Errorf("splitting second msig: %w", err) } err = nv3.CheckStateTree(ctx, store, nst, epoch, builtin0.TotalFilecoin) if err != nil { return cid.Undef, xerrors.Errorf("sanity check after ignition upgrade failed: %w", err) } return tree.Flush(ctx) } func UpgradeRefuel(ctx context.Context, sm *StateManager, _ MigrationCache, cb ExecCallback, root cid.Cid, epoch abi.ChainEpoch, ts *types.TipSet) (cid.Cid, error) { store := sm.cs.Store(ctx) tree, err := sm.StateTree(root) if err != nil { return cid.Undef, xerrors.Errorf("getting state tree: %w", err) } err = resetMultisigVesting0(ctx, store, tree, builtin.SaftAddress, 0, 0, big.Zero()) if err != nil { return cid.Undef, xerrors.Errorf("tweaking msig vesting: %w", err) } err = resetMultisigVesting0(ctx, store, tree, builtin.ReserveAddress, 0, 0, big.Zero()) if err != nil { return cid.Undef, xerrors.Errorf("tweaking msig vesting: %w", err) } err = resetMultisigVesting0(ctx, store, tree, builtin.RootVerifierAddress, 0, 0, big.Zero()) if err != nil { return cid.Undef, xerrors.Errorf("tweaking msig vesting: %w", err) } return tree.Flush(ctx) } func UpgradeActorsV2(ctx context.Context, sm *StateManager, _ MigrationCache, cb ExecCallback, root cid.Cid, epoch abi.ChainEpoch, ts *types.TipSet) (cid.Cid, error) { buf := bufbstore.NewTieredBstore(sm.cs.Blockstore(), bstore.NewTemporarySync()) store := store.ActorStore(ctx, buf) info, err := store.Put(ctx, new(types.StateInfo0)) if err != nil { return cid.Undef, xerrors.Errorf("failed to create new state info for actors v2: %w", err) } newHamtRoot, err := nv4.MigrateStateTree(ctx, store, root, epoch, nv4.DefaultConfig()) if err != nil { return cid.Undef, xerrors.Errorf("upgrading to actors v2: %w", err) } newRoot, err := store.Put(ctx, &types.StateRoot{ Version: types.StateTreeVersion1, Actors: newHamtRoot, Info: info, }) if err != nil { return cid.Undef, xerrors.Errorf("failed to persist new state root: %w", err) } // perform some basic sanity checks to make sure everything still works. if newSm, err := state.LoadStateTree(store, newRoot); err != nil { return cid.Undef, xerrors.Errorf("state tree sanity load failed: %w", err) } else if newRoot2, err := newSm.Flush(ctx); err != nil { return cid.Undef, xerrors.Errorf("state tree sanity flush failed: %w", err) } else if newRoot2 != newRoot { return cid.Undef, xerrors.Errorf("state-root mismatch: %s != %s", newRoot, newRoot2) } else if _, err := newSm.GetActor(builtin0.InitActorAddr); err != nil { return cid.Undef, xerrors.Errorf("failed to load init actor after upgrade: %w", err) } { from := buf to := buf.Read() if err := vm.Copy(ctx, from, to, newRoot); err != nil { return cid.Undef, xerrors.Errorf("copying migrated tree: %w", err) } } return newRoot, nil } func UpgradeLiftoff(ctx context.Context, sm *StateManager, _ MigrationCache, cb ExecCallback, root cid.Cid, epoch abi.ChainEpoch, ts *types.TipSet) (cid.Cid, error) { tree, err := sm.StateTree(root) if err != nil { return cid.Undef, xerrors.Errorf("getting state tree: %w", err) } err = setNetworkName(ctx, sm.cs.Store(ctx), tree, "mainnet") if err != nil { return cid.Undef, xerrors.Errorf("setting network name: %w", err) } return tree.Flush(ctx) } func UpgradeCalico(ctx context.Context, sm *StateManager, _ MigrationCache, cb ExecCallback, root cid.Cid, epoch abi.ChainEpoch, ts *types.TipSet) (cid.Cid, error) { store := sm.cs.Store(ctx) var stateRoot types.StateRoot if err := store.Get(ctx, root, &stateRoot); err != nil { return cid.Undef, xerrors.Errorf("failed to decode state root: %w", err) } if stateRoot.Version != types.StateTreeVersion1 { return cid.Undef, xerrors.Errorf( "expected state root version 1 for calico upgrade, got %d", stateRoot.Version, ) } newHamtRoot, err := nv7.MigrateStateTree(ctx, store, stateRoot.Actors, epoch, nv7.DefaultConfig()) if err != nil { return cid.Undef, xerrors.Errorf("running nv7 migration: %w", err) } newRoot, err := store.Put(ctx, &types.StateRoot{ Version: stateRoot.Version, Actors: newHamtRoot, Info: stateRoot.Info, }) if err != nil { return cid.Undef, xerrors.Errorf("failed to persist new state root: %w", err) } // perform some basic sanity checks to make sure everything still works. if newSm, err := state.LoadStateTree(store, newRoot); err != nil { return cid.Undef, xerrors.Errorf("state tree sanity load failed: %w", err) } else if newRoot2, err := newSm.Flush(ctx); err != nil { return cid.Undef, xerrors.Errorf("state tree sanity flush failed: %w", err) } else if newRoot2 != newRoot { return cid.Undef, xerrors.Errorf("state-root mismatch: %s != %s", newRoot, newRoot2) } else if _, err := newSm.GetActor(builtin0.InitActorAddr); err != nil { return cid.Undef, xerrors.Errorf("failed to load init actor after upgrade: %w", err) } return newRoot, nil } func UpgradeActorsV3(ctx context.Context, sm *StateManager, cache MigrationCache, cb ExecCallback, root cid.Cid, epoch abi.ChainEpoch, ts *types.TipSet) (cid.Cid, error) { // Use all the CPUs except 3. workerCount := runtime.NumCPU() - 3 if workerCount <= 0 { workerCount = 1 } config := nv10.Config{ MaxWorkers: uint(workerCount), JobQueueSize: 1000, ResultQueueSize: 100, ProgressLogPeriod: 10 * time.Second, } newRoot, err := upgradeActorsV3Common(ctx, sm, cache, root, epoch, ts, config) if err != nil { return cid.Undef, xerrors.Errorf("migrating actors v3 state: %w", err) } // perform some basic sanity checks to make sure everything still works. store := store.ActorStore(ctx, sm.ChainStore().Blockstore()) if newSm, err := state.LoadStateTree(store, newRoot); err != nil { return cid.Undef, xerrors.Errorf("state tree sanity load failed: %w", err) } else if newRoot2, err := newSm.Flush(ctx); err != nil { return cid.Undef, xerrors.Errorf("state tree sanity flush failed: %w", err) } else if newRoot2 != newRoot { return cid.Undef, xerrors.Errorf("state-root mismatch: %s != %s", newRoot, newRoot2) } else if _, err := newSm.GetActor(init_.Address); err != nil { return cid.Undef, xerrors.Errorf("failed to load init actor after upgrade: %w", err) } return newRoot, nil } func PreUpgradeActorsV3(ctx context.Context, sm *StateManager, cache MigrationCache, root cid.Cid, epoch abi.ChainEpoch, ts *types.TipSet) error { // Use half the CPUs for pre-migration, but leave at least 3. workerCount := runtime.NumCPU() if workerCount <= 4 { workerCount = 1 } else { workerCount /= 2 } config := nv10.Config{MaxWorkers: uint(workerCount)} _, err := upgradeActorsV3Common(ctx, sm, cache, root, epoch, ts, config) return err } func upgradeActorsV3Common( ctx context.Context, sm *StateManager, cache MigrationCache, root cid.Cid, epoch abi.ChainEpoch, ts *types.TipSet, config nv10.Config, ) (cid.Cid, error) { buf := bufbstore.NewTieredBstore(sm.cs.Blockstore(), bstore.NewTemporarySync()) store := store.ActorStore(ctx, buf) // Load the state root. var stateRoot types.StateRoot if err := store.Get(ctx, root, &stateRoot); err != nil { return cid.Undef, xerrors.Errorf("failed to decode state root: %w", err) } if stateRoot.Version != types.StateTreeVersion1 { return cid.Undef, xerrors.Errorf( "expected state root version 1 for actors v3 upgrade, got %d", stateRoot.Version, ) } // Perform the migration newHamtRoot, err := nv10.MigrateStateTree(ctx, store, stateRoot.Actors, epoch, config, migrationLogger{}, cache) if err != nil { return cid.Undef, xerrors.Errorf("upgrading to actors v2: %w", err) } // Persist the result. newRoot, err := store.Put(ctx, &types.StateRoot{ Version: types.StateTreeVersion2, Actors: newHamtRoot, Info: stateRoot.Info, }) if err != nil { return cid.Undef, xerrors.Errorf("failed to persist new state root: %w", err) } // Persist the new tree. { from := buf to := buf.Read() if err := vm.Copy(ctx, from, to, newRoot); err != nil { return cid.Undef, xerrors.Errorf("copying migrated tree: %w", err) } } return newRoot, nil } func setNetworkName(ctx context.Context, store adt.Store, tree *state.StateTree, name string) error { ia, err := tree.GetActor(builtin0.InitActorAddr) if err != nil { return xerrors.Errorf("getting init actor: %w", err) } initState, err := init_.Load(store, ia) if err != nil { return xerrors.Errorf("reading init state: %w", err) } if err := initState.SetNetworkName(name); err != nil { return xerrors.Errorf("setting network name: %w", err) } ia.Head, err = store.Put(ctx, initState) if err != nil { return xerrors.Errorf("writing new init state: %w", err) } if err := tree.SetActor(builtin0.InitActorAddr, ia); err != nil { return xerrors.Errorf("setting init actor: %w", err) } return nil } func splitGenesisMultisig0(ctx context.Context, cb ExecCallback, addr address.Address, store adt0.Store, tree *state.StateTree, portions uint64, epoch abi.ChainEpoch) error { if portions < 1 { return xerrors.Errorf("cannot split into 0 portions") } mact, err := tree.GetActor(addr) if err != nil { return xerrors.Errorf("getting msig actor: %w", err) } mst, err := multisig.Load(store, mact) if err != nil { return xerrors.Errorf("getting msig state: %w", err) } signers, err := mst.Signers() if err != nil { return xerrors.Errorf("getting msig signers: %w", err) } thresh, err := mst.Threshold() if err != nil { return xerrors.Errorf("getting msig threshold: %w", err) } ibal, err := mst.InitialBalance() if err != nil { return xerrors.Errorf("getting msig initial balance: %w", err) } se, err := mst.StartEpoch() if err != nil { return xerrors.Errorf("getting msig start epoch: %w", err) } ud, err := mst.UnlockDuration() if err != nil { return xerrors.Errorf("getting msig unlock duration: %w", err) } pending, err := adt0.MakeEmptyMap(store).Root() if err != nil { return xerrors.Errorf("failed to create empty map: %w", err) } newIbal := big.Div(ibal, types.NewInt(portions)) newState := &multisig0.State{ Signers: signers, NumApprovalsThreshold: thresh, NextTxnID: 0, InitialBalance: newIbal, StartEpoch: se, UnlockDuration: ud, PendingTxns: pending, } scid, err := store.Put(ctx, newState) if err != nil { return xerrors.Errorf("storing new state: %w", err) } newActor := types.Actor{ Code: builtin0.MultisigActorCodeID, Head: scid, Nonce: 0, Balance: big.Zero(), } i := uint64(0) subcalls := make([]types.ExecutionTrace, 0, portions) transferCb := func(trace types.ExecutionTrace) { subcalls = append(subcalls, trace) } for i < portions { keyAddr, err := makeKeyAddr(addr, i) if err != nil { return xerrors.Errorf("creating key address: %w", err) } idAddr, err := tree.RegisterNewAddress(keyAddr) if err != nil { return xerrors.Errorf("registering new address: %w", err) } err = tree.SetActor(idAddr, &newActor) if err != nil { return xerrors.Errorf("setting new msig actor state: %w", err) } if err := doTransfer(tree, addr, idAddr, newIbal, transferCb); err != nil { return xerrors.Errorf("transferring split msig balance: %w", err) } i++ } if cb != nil { // record the transfer in execution traces fakeMsg := &types.Message{ From: builtin.SystemActorAddr, To: addr, Value: big.Zero(), Nonce: uint64(epoch), } fakeRct := &types.MessageReceipt{ ExitCode: 0, Return: nil, GasUsed: 0, } if err := cb(fakeMsg.Cid(), fakeMsg, &vm.ApplyRet{ MessageReceipt: *fakeRct, ActorErr: nil, ExecutionTrace: types.ExecutionTrace{ Msg: fakeMsg, MsgRct: fakeRct, Error: "", Duration: 0, GasCharges: nil, Subcalls: subcalls, }, Duration: 0, GasCosts: nil, }); err != nil { return xerrors.Errorf("recording transfers: %w", err) } } return nil } func makeKeyAddr(splitAddr address.Address, count uint64) (address.Address, error) { var b bytes.Buffer if err := splitAddr.MarshalCBOR(&b); err != nil { return address.Undef, xerrors.Errorf("marshalling split address: %w", err) } if err := binary.Write(&b, binary.BigEndian, count); err != nil { return address.Undef, xerrors.Errorf("writing count into a buffer: %w", err) } if err := binary.Write(&b, binary.BigEndian, []byte("Ignition upgrade")); err != nil { return address.Undef, xerrors.Errorf("writing fork name into a buffer: %w", err) } addr, err := address.NewActorAddress(b.Bytes()) if err != nil { return address.Undef, xerrors.Errorf("create actor address: %w", err) } return addr, nil } // TODO: After the Liftoff epoch, refactor this to use resetMultisigVesting func resetGenesisMsigs0(ctx context.Context, sm *StateManager, store adt0.Store, tree *state.StateTree, startEpoch abi.ChainEpoch) error { gb, err := sm.cs.GetGenesis() if err != nil { return xerrors.Errorf("getting genesis block: %w", err) } gts, err := types.NewTipSet([]*types.BlockHeader{gb}) if err != nil { return xerrors.Errorf("getting genesis tipset: %w", err) } cst := cbor.NewCborStore(sm.cs.Blockstore()) genesisTree, err := state.LoadStateTree(cst, gts.ParentState()) if err != nil { return xerrors.Errorf("loading state tree: %w", err) } err = genesisTree.ForEach(func(addr address.Address, genesisActor *types.Actor) error { if genesisActor.Code == builtin0.MultisigActorCodeID { currActor, err := tree.GetActor(addr) if err != nil { return xerrors.Errorf("loading actor: %w", err) } var currState multisig0.State if err := store.Get(ctx, currActor.Head, &currState); err != nil { return xerrors.Errorf("reading multisig state: %w", err) } currState.StartEpoch = startEpoch currActor.Head, err = store.Put(ctx, &currState) if err != nil { return xerrors.Errorf("writing new multisig state: %w", err) } if err := tree.SetActor(addr, currActor); err != nil { return xerrors.Errorf("setting multisig actor: %w", err) } } return nil }) if err != nil { return xerrors.Errorf("iterating over genesis actors: %w", err) } return nil } func resetMultisigVesting0(ctx context.Context, store adt0.Store, tree *state.StateTree, addr address.Address, startEpoch abi.ChainEpoch, duration abi.ChainEpoch, balance abi.TokenAmount) error { act, err := tree.GetActor(addr) if err != nil { return xerrors.Errorf("getting actor: %w", err) } if !builtin.IsMultisigActor(act.Code) { return xerrors.Errorf("actor wasn't msig: %w", err) } var msigState multisig0.State if err := store.Get(ctx, act.Head, &msigState); err != nil { return xerrors.Errorf("reading multisig state: %w", err) } msigState.StartEpoch = startEpoch msigState.UnlockDuration = duration msigState.InitialBalance = balance act.Head, err = store.Put(ctx, &msigState) if err != nil { return xerrors.Errorf("writing new multisig state: %w", err) } if err := tree.SetActor(addr, act); err != nil { return xerrors.Errorf("setting multisig actor: %w", err) } return nil }