package main import ( "context" "encoding/json" "fmt" "io/ioutil" "math/bits" "os" "path/filepath" "sort" "strconv" "strings" "time" "github.com/docker/go-units" "github.com/fatih/color" "github.com/google/uuid" "github.com/mitchellh/go-homedir" "github.com/urfave/cli/v2" "golang.org/x/xerrors" "github.com/filecoin-project/go-address" "github.com/filecoin-project/go-bitfield" "github.com/filecoin-project/go-state-types/abi" "github.com/filecoin-project/lotus/api" "github.com/filecoin-project/lotus/api/v0api" "github.com/filecoin-project/lotus/chain/types" lcli "github.com/filecoin-project/lotus/cli" "github.com/filecoin-project/lotus/lib/tablewriter" "github.com/filecoin-project/lotus/storage/paths" sealing "github.com/filecoin-project/lotus/storage/pipeline" "github.com/filecoin-project/lotus/storage/sealer/fsutil" "github.com/filecoin-project/lotus/storage/sealer/storiface" ) const metaFile = "sectorstore.json" var storageCmd = &cli.Command{ Name: "storage", Usage: "manage sector storage", Description: `Sectors can be stored across many filesystem paths. These commands provide ways to manage the storage the miner will used to store sectors long term for proving (references as 'store') as well as how sectors will be stored while moving through the sealing pipeline (references as 'seal').`, Subcommands: []*cli.Command{ storageAttachCmd, storageListCmd, storageFindCmd, storageCleanupCmd, storageLocks, }, } var storageAttachCmd = &cli.Command{ Name: "attach", Usage: "attach local storage path", Description: `Storage can be attached to the miner using this command. The storage volume list is stored local to the miner in $LOTUS_MINER_PATH/storage.json. We do not recommend manually modifying this value without further understanding of the storage system. Each storage volume contains a configuration file which describes the capabilities of the volume. When the '--init' flag is provided, this file will be created using the additional flags. Weight A high weight value means data will be more likely to be stored in this path Seal Data for the sealing process will be stored here Store Finalized sectors that will be moved here for long term storage and be proven over time `, Flags: []cli.Flag{ &cli.BoolFlag{ Name: "init", Usage: "initialize the path first", }, &cli.Uint64Flag{ Name: "weight", Usage: "(for init) path weight", Value: 10, }, &cli.BoolFlag{ Name: "seal", Usage: "(for init) use path for sealing", }, &cli.BoolFlag{ Name: "store", Usage: "(for init) use path for long-term storage", }, &cli.StringFlag{ Name: "max-storage", Usage: "(for init) limit storage space for sectors (expensive for very large paths!)", }, &cli.StringSliceFlag{ Name: "groups", Usage: "path group names", }, &cli.StringSliceFlag{ Name: "allow-to", Usage: "path groups allowed to pull data from this path (allow all if not specified)", }, }, Action: func(cctx *cli.Context) error { nodeApi, closer, err := lcli.GetStorageMinerAPI(cctx) if err != nil { return err } defer closer() ctx := lcli.ReqContext(cctx) if !cctx.Args().Present() { return xerrors.Errorf("must specify storage path to attach") } p, err := homedir.Expand(cctx.Args().First()) if err != nil { return xerrors.Errorf("expanding path: %w", err) } if cctx.Bool("init") { if err := os.MkdirAll(p, 0755); err != nil { if !os.IsExist(err) { return err } } _, err := os.Stat(filepath.Join(p, metaFile)) if !os.IsNotExist(err) { if err == nil { return xerrors.Errorf("path is already initialized") } return err } var maxStor int64 if cctx.IsSet("max-storage") { maxStor, err = units.RAMInBytes(cctx.String("max-storage")) if err != nil { return xerrors.Errorf("parsing max-storage: %w", err) } } cfg := &paths.LocalStorageMeta{ ID: storiface.ID(uuid.New().String()), Weight: cctx.Uint64("weight"), CanSeal: cctx.Bool("seal"), CanStore: cctx.Bool("store"), MaxStorage: uint64(maxStor), Groups: cctx.StringSlice("groups"), AllowTo: cctx.StringSlice("allow-to"), } if !(cfg.CanStore || cfg.CanSeal) { return xerrors.Errorf("must specify at least one of --store or --seal") } b, err := json.MarshalIndent(cfg, "", " ") if err != nil { return xerrors.Errorf("marshaling storage config: %w", err) } if err := ioutil.WriteFile(filepath.Join(p, metaFile), b, 0644); err != nil { return xerrors.Errorf("persisting storage metadata (%s): %w", filepath.Join(p, metaFile), err) } } return nodeApi.StorageAddLocal(ctx, p) }, } var storageListCmd = &cli.Command{ Name: "list", Usage: "list local storage paths", Flags: []cli.Flag{ &cli.BoolFlag{ Name: "color", Usage: "use color in display output", DefaultText: "depends on output being a TTY", }, }, Subcommands: []*cli.Command{ storageListSectorsCmd, }, Action: func(cctx *cli.Context) error { if cctx.IsSet("color") { color.NoColor = !cctx.Bool("color") } nodeApi, closer, err := lcli.GetStorageMinerAPI(cctx) if err != nil { return err } defer closer() ctx := lcli.ReqContext(cctx) st, err := nodeApi.StorageList(ctx) if err != nil { return err } local, err := nodeApi.StorageLocal(ctx) if err != nil { return err } type fsInfo struct { storiface.ID sectors []storiface.Decl stat fsutil.FsStat } sorted := make([]fsInfo, 0, len(st)) for id, decls := range st { st, err := nodeApi.StorageStat(ctx, id) if err != nil { sorted = append(sorted, fsInfo{ID: id, sectors: decls}) continue } sorted = append(sorted, fsInfo{id, decls, st}) } sort.Slice(sorted, func(i, j int) bool { if sorted[i].stat.Capacity != sorted[j].stat.Capacity { return sorted[i].stat.Capacity > sorted[j].stat.Capacity } return sorted[i].ID < sorted[j].ID }) for _, s := range sorted { var cnt [3]int for _, decl := range s.sectors { for i := range cnt { if decl.SectorFileType&(1< 98: percCol = color.FgRed case usedPercent > 90: percCol = color.FgYellow } set := (st.Capacity - st.FSAvailable) * barCols / st.Capacity used := (st.Capacity - (st.FSAvailable + st.Reserved)) * barCols / st.Capacity reserved := set - used bar := safeRepeat("#", int(used)) + safeRepeat("*", int(reserved)) + safeRepeat(" ", int(barCols-set)) desc := "" if st.Max > 0 { desc = " (filesystem)" } fmt.Printf("\t[%s] %s/%s %s%s\n", color.New(percCol).Sprint(bar), types.SizeStr(types.NewInt(uint64(st.Capacity-st.FSAvailable))), types.SizeStr(types.NewInt(uint64(st.Capacity))), color.New(percCol).Sprintf("%d%%", usedPercent), desc) } // optional configured limit bar if st.Max > 0 { usedPercent := st.Used * 100 / st.Max percCol := color.FgGreen switch { case usedPercent > 98: percCol = color.FgRed case usedPercent > 90: percCol = color.FgYellow } set := st.Used * barCols / st.Max used := (st.Used + st.Reserved) * barCols / st.Max reserved := set - used bar := safeRepeat("#", int(used)) + safeRepeat("*", int(reserved)) + safeRepeat(" ", int(barCols-set)) fmt.Printf("\t[%s] %s/%s %s (limit)\n", color.New(percCol).Sprint(bar), types.SizeStr(types.NewInt(uint64(st.Used))), types.SizeStr(types.NewInt(uint64(st.Max))), color.New(percCol).Sprintf("%d%%", usedPercent)) } fmt.Printf("\t%s; %s; %s; Reserved: %s\n", color.YellowString("Unsealed: %d", cnt[0]), color.GreenString("Sealed: %d", cnt[1]), color.BlueString("Caches: %d", cnt[2]), types.SizeStr(types.NewInt(uint64(st.Reserved)))) si, err := nodeApi.StorageInfo(ctx, s.ID) if err != nil { return err } fmt.Print("\t") if si.CanSeal || si.CanStore { fmt.Printf("Weight: %d; Use: ", si.Weight) if si.CanSeal { fmt.Print(color.MagentaString("Seal ")) } if si.CanStore { fmt.Print(color.CyanString("Store")) } } else { fmt.Print(color.HiYellowString("Use: ReadOnly")) } fmt.Println() if len(si.Groups) > 0 { fmt.Printf("\tGroups: %s\n", strings.Join(si.Groups, ", ")) } if len(si.AllowTo) > 0 { fmt.Printf("\tAllowTo: %s\n", strings.Join(si.AllowTo, ", ")) } if len(si.AllowTypes) > 0 || len(si.DenyTypes) > 0 { denied := storiface.FTAll.SubAllowed(si.AllowTypes, si.DenyTypes) allowed := storiface.FTAll ^ denied switch { case bits.OnesCount64(uint64(allowed)) == 0: fmt.Printf("\tAllow Types: %s\n", color.RedString("None")) case bits.OnesCount64(uint64(allowed)) < bits.OnesCount64(uint64(denied)): fmt.Printf("\tAllow Types: %s\n", color.GreenString(strings.Join(allowed.Strings(), " "))) default: fmt.Printf("\tDeny Types: %s\n", color.RedString(strings.Join(denied.Strings(), " "))) } } if localPath, ok := local[s.ID]; ok { fmt.Printf("\tLocal: %s\n", color.GreenString(localPath)) } for i, l := range si.URLs { var rtt string if _, ok := local[s.ID]; !ok && i == 0 { rtt = " (latency: " + ping.Truncate(time.Microsecond*100).String() + ")" } fmt.Printf("\tURL: %s%s\n", l, rtt) // TODO; try pinging maybe?? print latency? } fmt.Println() } return nil }, } type storedSector struct { id storiface.ID store storiface.SectorStorageInfo unsealed, sealed, cache bool update, updatecache bool } var storageFindCmd = &cli.Command{ Name: "find", Usage: "find sector in the storage system", ArgsUsage: "[sector number]", Action: func(cctx *cli.Context) error { nodeApi, closer, err := lcli.GetStorageMinerAPI(cctx) if err != nil { return err } defer closer() ctx := lcli.ReqContext(cctx) ma, err := nodeApi.ActorAddress(ctx) if err != nil { return err } mid, err := address.IDFromAddress(ma) if err != nil { return err } if !cctx.Args().Present() { return xerrors.New("Usage: lotus-miner storage find [sector number]") } snum, err := strconv.ParseUint(cctx.Args().First(), 10, 64) if err != nil { return err } sid := abi.SectorID{ Miner: abi.ActorID(mid), Number: abi.SectorNumber(snum), } u, err := nodeApi.StorageFindSector(ctx, sid, storiface.FTUnsealed, 0, false) if err != nil { return xerrors.Errorf("finding unsealed: %w", err) } s, err := nodeApi.StorageFindSector(ctx, sid, storiface.FTSealed, 0, false) if err != nil { return xerrors.Errorf("finding sealed: %w", err) } c, err := nodeApi.StorageFindSector(ctx, sid, storiface.FTCache, 0, false) if err != nil { return xerrors.Errorf("finding cache: %w", err) } us, err := nodeApi.StorageFindSector(ctx, sid, storiface.FTUpdate, 0, false) if err != nil { return xerrors.Errorf("finding sealed: %w", err) } uc, err := nodeApi.StorageFindSector(ctx, sid, storiface.FTUpdateCache, 0, false) if err != nil { return xerrors.Errorf("finding cache: %w", err) } byId := map[storiface.ID]*storedSector{} for _, info := range u { sts, ok := byId[info.ID] if !ok { sts = &storedSector{ id: info.ID, store: info, } byId[info.ID] = sts } sts.unsealed = true } for _, info := range s { sts, ok := byId[info.ID] if !ok { sts = &storedSector{ id: info.ID, store: info, } byId[info.ID] = sts } sts.sealed = true } for _, info := range c { sts, ok := byId[info.ID] if !ok { sts = &storedSector{ id: info.ID, store: info, } byId[info.ID] = sts } sts.cache = true } for _, info := range us { sts, ok := byId[info.ID] if !ok { sts = &storedSector{ id: info.ID, store: info, } byId[info.ID] = sts } sts.update = true } for _, info := range uc { sts, ok := byId[info.ID] if !ok { sts = &storedSector{ id: info.ID, store: info, } byId[info.ID] = sts } sts.updatecache = true } local, err := nodeApi.StorageLocal(ctx) if err != nil { return err } var out []*storedSector for _, sector := range byId { out = append(out, sector) } sort.Slice(out, func(i, j int) bool { return out[i].id < out[j].id }) for _, info := range out { var types string if info.unsealed { types += "Unsealed, " } if info.sealed { types += "Sealed, " } if info.cache { types += "Cache, " } if info.update { types += "Update, " } if info.updatecache { types += "UpdateCache, " } fmt.Printf("In %s (%s)\n", info.id, types[:len(types)-2]) fmt.Printf("\tSealing: %t; Storage: %t\n", info.store.CanSeal, info.store.CanStore) if localPath, ok := local[info.id]; ok { fmt.Printf("\tLocal (%s)\n", localPath) } else { fmt.Printf("\tRemote\n") } for _, l := range info.store.URLs { fmt.Printf("\tURL: %s\n", l) } } return nil }, } var storageListSectorsCmd = &cli.Command{ Name: "sectors", Usage: "get list of all sector files", Flags: []cli.Flag{ &cli.BoolFlag{ Name: "color", Usage: "use color in display output", DefaultText: "depends on output being a TTY", }, }, Action: func(cctx *cli.Context) error { if cctx.IsSet("color") { color.NoColor = !cctx.Bool("color") } nodeApi, closer, err := lcli.GetStorageMinerAPI(cctx) if err != nil { return err } defer closer() napi, closer2, err := lcli.GetFullNodeAPIV1(cctx) if err != nil { return err } defer closer2() ctx := lcli.ReqContext(cctx) sectors, err := nodeApi.SectorsList(ctx) if err != nil { return xerrors.Errorf("listing sectors: %w", err) } maddr, err := nodeApi.ActorAddress(ctx) if err != nil { return err } aid, err := address.IDFromAddress(maddr) if err != nil { return err } mi, err := napi.StateMinerInfo(ctx, maddr, types.EmptyTSK) if err != nil { return err } sid := func(sn abi.SectorNumber) abi.SectorID { return abi.SectorID{ Miner: abi.ActorID(aid), Number: sn, } } allParts, err := getAllPartitions(ctx, maddr, napi) if err != nil { return xerrors.Errorf("getting partition states: %w", err) } type entry struct { id abi.SectorNumber storage storiface.ID ft storiface.SectorFileType urls string primary, copy, main, seal, store bool state api.SectorState faulty bool } var list []entry for _, sector := range sectors { st, err := nodeApi.SectorsStatus(ctx, sector, false) if err != nil { return xerrors.Errorf("getting sector status for sector %d: %w", sector, err) } fault, err := allParts.FaultySectors.IsSet(uint64(sector)) if err != nil { return xerrors.Errorf("checking if sector is faulty: %w", err) } for _, ft := range storiface.PathTypes { si, err := nodeApi.StorageFindSector(ctx, sid(sector), ft, mi.SectorSize, false) if err != nil { return xerrors.Errorf("find sector %d: %w", sector, err) } for _, info := range si { list = append(list, entry{ id: sector, storage: info.ID, ft: ft, urls: strings.Join(info.URLs, ";"), primary: info.Primary, copy: !info.Primary && len(si) > 1, main: !info.Primary && len(si) == 1, // only copy, but not primary seal: info.CanSeal, store: info.CanStore, state: st.State, faulty: fault, }) } } } sort.Slice(list, func(i, j int) bool { if list[i].store != list[j].store { return list[i].store } if list[i].storage != list[j].storage { return list[i].storage < list[j].storage } if list[i].id != list[j].id { return list[i].id < list[j].id } return list[i].ft < list[j].ft }) tw := tablewriter.New( tablewriter.Col("Storage"), tablewriter.Col("Sector"), tablewriter.Col("Type"), tablewriter.Col("State"), tablewriter.Col("Faulty"), tablewriter.Col("Primary"), tablewriter.Col("Path use"), tablewriter.Col("URLs"), ) if len(list) == 0 { return nil } lastS := list[0].storage sc1, sc2 := color.FgBlue, color.FgCyan for _, e := range list { if e.storage != lastS { lastS = e.storage sc1, sc2 = sc2, sc1 } m := map[string]interface{}{ "Storage": color.New(sc1).Sprint(e.storage), "Sector": e.id, "Type": e.ft.String(), "State": color.New(stateOrder[sealing.SectorState(e.state)].col).Sprint(e.state), "Primary": maybeStr(e.primary, color.FgGreen, "primary") + maybeStr(e.copy, color.FgBlue, "copy") + maybeStr(e.main, color.FgRed, "main"), "Path use": maybeStr(e.seal, color.FgMagenta, "seal ") + maybeStr(e.store, color.FgCyan, "store"), "URLs": e.urls, } if e.faulty { // only set when there is a fault, so the column is hidden with no faults m["Faulty"] = color.RedString("faulty") } tw.Write(m) } return tw.Flush(os.Stdout) }, } func getAllPartitions(ctx context.Context, maddr address.Address, napi api.FullNode) (api.Partition, error) { deadlines, err := napi.StateMinerDeadlines(ctx, maddr, types.EmptyTSK) if err != nil { return api.Partition{}, xerrors.Errorf("getting deadlines: %w", err) } out := api.Partition{ AllSectors: bitfield.New(), FaultySectors: bitfield.New(), RecoveringSectors: bitfield.New(), LiveSectors: bitfield.New(), ActiveSectors: bitfield.New(), } for dlIdx := range deadlines { partitions, err := napi.StateMinerPartitions(ctx, maddr, uint64(dlIdx), types.EmptyTSK) if err != nil { return api.Partition{}, xerrors.Errorf("getting partitions for deadline %d: %w", dlIdx, err) } for _, partition := range partitions { out.AllSectors, err = bitfield.MergeBitFields(out.AllSectors, partition.AllSectors) if err != nil { return api.Partition{}, err } out.FaultySectors, err = bitfield.MergeBitFields(out.FaultySectors, partition.FaultySectors) if err != nil { return api.Partition{}, err } out.RecoveringSectors, err = bitfield.MergeBitFields(out.RecoveringSectors, partition.RecoveringSectors) if err != nil { return api.Partition{}, err } out.LiveSectors, err = bitfield.MergeBitFields(out.LiveSectors, partition.LiveSectors) if err != nil { return api.Partition{}, err } out.ActiveSectors, err = bitfield.MergeBitFields(out.ActiveSectors, partition.ActiveSectors) if err != nil { return api.Partition{}, err } } } return out, nil } func maybeStr(c bool, col color.Attribute, s string) string { if !c { return "" } return color.New(col).Sprint(s) } var storageCleanupCmd = &cli.Command{ Name: "cleanup", Usage: "trigger cleanup actions", Flags: []cli.Flag{ &cli.BoolFlag{ Name: "removed", Usage: "cleanup remaining files from removed sectors", Value: true, }, }, Action: func(cctx *cli.Context) error { api, closer, err := lcli.GetStorageMinerAPI(cctx) if err != nil { return err } defer closer() napi, closer2, err := lcli.GetFullNodeAPI(cctx) if err != nil { return err } defer closer2() ctx := lcli.ReqContext(cctx) if cctx.Bool("removed") { if err := cleanupRemovedSectorData(ctx, api, napi); err != nil { return err } } // TODO: proving sectors in sealing storage return nil }, } func cleanupRemovedSectorData(ctx context.Context, api api.StorageMiner, napi v0api.FullNode) error { sectors, err := api.SectorsList(ctx) if err != nil { return err } maddr, err := api.ActorAddress(ctx) if err != nil { return err } aid, err := address.IDFromAddress(maddr) if err != nil { return err } sid := func(sn abi.SectorNumber) abi.SectorID { return abi.SectorID{ Miner: abi.ActorID(aid), Number: sn, } } mi, err := napi.StateMinerInfo(ctx, maddr, types.EmptyTSK) if err != nil { return err } toRemove := map[abi.SectorNumber]struct{}{} for _, sector := range sectors { st, err := api.SectorsStatus(ctx, sector, false) if err != nil { return xerrors.Errorf("getting sector status for sector %d: %w", sector, err) } if sealing.SectorState(st.State) != sealing.Removed { continue } for _, ft := range storiface.PathTypes { si, err := api.StorageFindSector(ctx, sid(sector), ft, mi.SectorSize, false) if err != nil { return xerrors.Errorf("find sector %d: %w", sector, err) } if len(si) > 0 { toRemove[sector] = struct{}{} } } } for sn := range toRemove { fmt.Printf("cleaning up data for sector %d\n", sn) err := api.SectorRemove(ctx, sn) if err != nil { log.Error(err) } } return nil } var storageLocks = &cli.Command{ Name: "locks", Usage: "show active sector locks", Action: func(cctx *cli.Context) error { api, closer, err := lcli.GetStorageMinerAPI(cctx) if err != nil { return err } defer closer() ctx := lcli.ReqContext(cctx) locks, err := api.StorageGetLocks(ctx) if err != nil { return err } for _, lock := range locks.Locks { st, err := api.SectorsStatus(ctx, lock.Sector.Number, false) if err != nil { return xerrors.Errorf("getting sector status(%d): %w", lock.Sector.Number, err) } lockstr := fmt.Sprintf("%d\t%s\t", lock.Sector.Number, color.New(stateOrder[sealing.SectorState(st.State)].col).Sprint(st.State)) for i := 0; i < storiface.FileTypes; i++ { if lock.Write[i] > 0 { lockstr += fmt.Sprintf("%s(%s) ", storiface.SectorFileType(1< 0 { lockstr += fmt.Sprintf("%s(%s:%d) ", storiface.SectorFileType(1<