// Copyright 2018 The go-ethereum Authors // This file is part of the go-ethereum library. // // The go-ethereum library is free software: you can redistribute it and/or modify // it under the terms of the GNU Lesser General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // The go-ethereum library is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU Lesser General Public License for more details. // // You should have received a copy of the GNU Lesser General Public License // along with the go-ethereum library. If not, see . package stream import ( "context" crand "crypto/rand" "fmt" "io" "os" "sync" "testing" "time" "github.com/ethereum/go-ethereum/common" "github.com/ethereum/go-ethereum/log" "github.com/ethereum/go-ethereum/node" "github.com/ethereum/go-ethereum/p2p" "github.com/ethereum/go-ethereum/p2p/discover" "github.com/ethereum/go-ethereum/p2p/simulations/adapters" "github.com/ethereum/go-ethereum/swarm/network" "github.com/ethereum/go-ethereum/swarm/network/simulation" "github.com/ethereum/go-ethereum/swarm/pot" "github.com/ethereum/go-ethereum/swarm/state" "github.com/ethereum/go-ethereum/swarm/storage" mockdb "github.com/ethereum/go-ethereum/swarm/storage/mock/db" ) const testMinProxBinSize = 2 const MaxTimeout = 600 type synctestConfig struct { addrs [][]byte hashes []storage.Address idToChunksMap map[discover.NodeID][]int chunksToNodesMap map[string][]int addrToIDMap map[string]discover.NodeID } //This test is a syncing test for nodes. //One node is randomly selected to be the pivot node. //A configurable number of chunks and nodes can be //provided to the test, the number of chunks is uploaded //to the pivot node, and we check that nodes get the chunks //they are expected to store based on the syncing protocol. //Number of chunks and nodes can be provided via commandline too. func TestSyncingViaGlobalSync(t *testing.T) { //if nodes/chunks have been provided via commandline, //run the tests with these values if *nodes != 0 && *chunks != 0 { log.Info(fmt.Sprintf("Running test with %d chunks and %d nodes...", *chunks, *nodes)) testSyncingViaGlobalSync(t, *chunks, *nodes) } else { var nodeCnt []int var chnkCnt []int //if the `longrunning` flag has been provided //run more test combinations if *longrunning { chnkCnt = []int{1, 8, 32, 256, 1024} nodeCnt = []int{16, 32, 64, 128, 256} } else { //default test chnkCnt = []int{4, 32} nodeCnt = []int{32, 16} } for _, chnk := range chnkCnt { for _, n := range nodeCnt { log.Info(fmt.Sprintf("Long running test with %d chunks and %d nodes...", chnk, n)) testSyncingViaGlobalSync(t, chnk, n) } } } } func TestSyncingViaDirectSubscribe(t *testing.T) { //if nodes/chunks have been provided via commandline, //run the tests with these values if *nodes != 0 && *chunks != 0 { log.Info(fmt.Sprintf("Running test with %d chunks and %d nodes...", *chunks, *nodes)) err := testSyncingViaDirectSubscribe(*chunks, *nodes) if err != nil { t.Fatal(err) } } else { var nodeCnt []int var chnkCnt []int //if the `longrunning` flag has been provided //run more test combinations if *longrunning { chnkCnt = []int{1, 8, 32, 256, 1024} nodeCnt = []int{32, 16} } else { //default test chnkCnt = []int{4, 32} nodeCnt = []int{32, 16} } for _, chnk := range chnkCnt { for _, n := range nodeCnt { log.Info(fmt.Sprintf("Long running test with %d chunks and %d nodes...", chnk, n)) err := testSyncingViaDirectSubscribe(chnk, n) if err != nil { t.Fatal(err) } } } } } func testSyncingViaGlobalSync(t *testing.T, chunkCount int, nodeCount int) { sim := simulation.New(map[string]simulation.ServiceFunc{ "streamer": func(ctx *adapters.ServiceContext, bucket *sync.Map) (s node.Service, cleanup func(), err error) { id := ctx.Config.ID addr := network.NewAddrFromNodeID(id) store, datadir, err := createTestLocalStorageForID(id, addr) if err != nil { return nil, nil, err } bucket.Store(bucketKeyStore, store) cleanup = func() { os.RemoveAll(datadir) store.Close() } localStore := store.(*storage.LocalStore) db := storage.NewDBAPI(localStore) kad := network.NewKademlia(addr.Over(), network.NewKadParams()) delivery := NewDelivery(kad, db) r := NewRegistry(addr, delivery, db, state.NewInmemoryStore(), &RegistryOptions{ DoSync: true, SyncUpdateDelay: 3 * time.Second, }) bucket.Store(bucketKeyRegistry, r) return r, cleanup, nil }, }) defer sim.Close() log.Info("Initializing test config") conf := &synctestConfig{} //map of discover ID to indexes of chunks expected at that ID conf.idToChunksMap = make(map[discover.NodeID][]int) //map of overlay address to discover ID conf.addrToIDMap = make(map[string]discover.NodeID) //array where the generated chunk hashes will be stored conf.hashes = make([]storage.Address, 0) err := sim.UploadSnapshot(fmt.Sprintf("testing/snapshot_%d.json", nodeCount)) if err != nil { t.Fatal(err) } ctx, cancelSimRun := context.WithTimeout(context.Background(), 1*time.Minute) defer cancelSimRun() result := sim.Run(ctx, func(ctx context.Context, sim *simulation.Simulation) error { nodeIDs := sim.UpNodeIDs() for _, n := range nodeIDs { //get the kademlia overlay address from this ID a := network.ToOverlayAddr(n.Bytes()) //append it to the array of all overlay addresses conf.addrs = append(conf.addrs, a) //the proximity calculation is on overlay addr, //the p2p/simulations check func triggers on discover.NodeID, //so we need to know which overlay addr maps to which nodeID conf.addrToIDMap[string(a)] = n } //get the the node at that index //this is the node selected for upload node := sim.RandomUpNode() item, ok := sim.NodeItem(node.ID, bucketKeyStore) if !ok { return fmt.Errorf("No localstore") } lstore := item.(*storage.LocalStore) hashes, err := uploadFileToSingleNodeStore(node.ID, chunkCount, lstore) if err != nil { return err } conf.hashes = append(conf.hashes, hashes...) mapKeysToNodes(conf) if _, err := sim.WaitTillHealthy(ctx, 2); err != nil { return err } // File retrieval check is repeated until all uploaded files are retrieved from all nodes // or until the timeout is reached. allSuccess := false var gDir string var globalStore *mockdb.GlobalStore if *useMockStore { gDir, globalStore, err = createGlobalStore() if err != nil { return fmt.Errorf("Something went wrong; using mockStore enabled but globalStore is nil") } defer func() { os.RemoveAll(gDir) err := globalStore.Close() if err != nil { log.Error("Error closing global store! %v", "err", err) } }() } for !allSuccess { for _, id := range nodeIDs { //for each expected chunk, check if it is in the local store localChunks := conf.idToChunksMap[id] localSuccess := true for _, ch := range localChunks { //get the real chunk by the index in the index array chunk := conf.hashes[ch] log.Trace(fmt.Sprintf("node has chunk: %s:", chunk)) //check if the expected chunk is indeed in the localstore var err error if *useMockStore { //use the globalStore if the mockStore should be used; in that case, //the complete localStore stack is bypassed for getting the chunk _, err = globalStore.Get(common.BytesToAddress(id.Bytes()), chunk) } else { //use the actual localstore item, ok := sim.NodeItem(id, bucketKeyStore) if !ok { return fmt.Errorf("Error accessing localstore") } lstore := item.(*storage.LocalStore) _, err = lstore.Get(ctx, chunk) } if err != nil { log.Warn(fmt.Sprintf("Chunk %s NOT found for id %s", chunk, id)) localSuccess = false } else { log.Debug(fmt.Sprintf("Chunk %s IS FOUND for id %s", chunk, id)) } } allSuccess = localSuccess } } if !allSuccess { return fmt.Errorf("Not all chunks succeeded!") } return nil }) if result.Error != nil { t.Fatal(result.Error) } } /* The test generates the given number of chunks For every chunk generated, the nearest node addresses are identified, we verify that the nodes closer to the chunk addresses actually do have the chunks in their local stores. The test loads a snapshot file to construct the swarm network, assuming that the snapshot file identifies a healthy kademlia network. The snapshot should have 'streamer' in its service list. */ func testSyncingViaDirectSubscribe(chunkCount int, nodeCount int) error { sim := simulation.New(map[string]simulation.ServiceFunc{ "streamer": func(ctx *adapters.ServiceContext, bucket *sync.Map) (s node.Service, cleanup func(), err error) { id := ctx.Config.ID addr := network.NewAddrFromNodeID(id) store, datadir, err := createTestLocalStorageForID(id, addr) if err != nil { return nil, nil, err } bucket.Store(bucketKeyStore, store) cleanup = func() { os.RemoveAll(datadir) store.Close() } localStore := store.(*storage.LocalStore) db := storage.NewDBAPI(localStore) kad := network.NewKademlia(addr.Over(), network.NewKadParams()) delivery := NewDelivery(kad, db) r := NewRegistry(addr, delivery, db, state.NewInmemoryStore(), nil) bucket.Store(bucketKeyRegistry, r) fileStore := storage.NewFileStore(storage.NewNetStore(localStore, nil), storage.NewFileStoreParams()) bucket.Store(bucketKeyFileStore, fileStore) return r, cleanup, nil }, }) defer sim.Close() ctx, cancelSimRun := context.WithTimeout(context.Background(), 1*time.Minute) defer cancelSimRun() conf := &synctestConfig{} //map of discover ID to indexes of chunks expected at that ID conf.idToChunksMap = make(map[discover.NodeID][]int) //map of overlay address to discover ID conf.addrToIDMap = make(map[string]discover.NodeID) //array where the generated chunk hashes will be stored conf.hashes = make([]storage.Address, 0) err := sim.UploadSnapshot(fmt.Sprintf("testing/snapshot_%d.json", nodeCount)) if err != nil { return err } result := sim.Run(ctx, func(ctx context.Context, sim *simulation.Simulation) error { nodeIDs := sim.UpNodeIDs() for _, n := range nodeIDs { //get the kademlia overlay address from this ID a := network.ToOverlayAddr(n.Bytes()) //append it to the array of all overlay addresses conf.addrs = append(conf.addrs, a) //the proximity calculation is on overlay addr, //the p2p/simulations check func triggers on discover.NodeID, //so we need to know which overlay addr maps to which nodeID conf.addrToIDMap[string(a)] = n } var subscriptionCount int filter := simulation.NewPeerEventsFilter().Type(p2p.PeerEventTypeMsgRecv).Protocol("stream").MsgCode(4) eventC := sim.PeerEvents(ctx, nodeIDs, filter) for j, node := range nodeIDs { log.Trace(fmt.Sprintf("Start syncing subscriptions: %d", j)) //start syncing! item, ok := sim.NodeItem(node, bucketKeyRegistry) if !ok { return fmt.Errorf("No registry") } registry := item.(*Registry) var cnt int cnt, err = startSyncing(registry, conf) if err != nil { return err } //increment the number of subscriptions we need to wait for //by the count returned from startSyncing (SYNC subscriptions) subscriptionCount += cnt } for e := range eventC { if e.Error != nil { return e.Error } subscriptionCount-- if subscriptionCount == 0 { break } } //select a random node for upload node := sim.RandomUpNode() item, ok := sim.NodeItem(node.ID, bucketKeyStore) if !ok { return fmt.Errorf("No localstore") } lstore := item.(*storage.LocalStore) hashes, err := uploadFileToSingleNodeStore(node.ID, chunkCount, lstore) if err != nil { return err } conf.hashes = append(conf.hashes, hashes...) mapKeysToNodes(conf) if _, err := sim.WaitTillHealthy(ctx, 2); err != nil { return err } var gDir string var globalStore *mockdb.GlobalStore if *useMockStore { gDir, globalStore, err = createGlobalStore() if err != nil { return fmt.Errorf("Something went wrong; using mockStore enabled but globalStore is nil") } defer os.RemoveAll(gDir) } // File retrieval check is repeated until all uploaded files are retrieved from all nodes // or until the timeout is reached. allSuccess := false for !allSuccess { for _, id := range nodeIDs { //for each expected chunk, check if it is in the local store localChunks := conf.idToChunksMap[id] localSuccess := true for _, ch := range localChunks { //get the real chunk by the index in the index array chunk := conf.hashes[ch] log.Trace(fmt.Sprintf("node has chunk: %s:", chunk)) //check if the expected chunk is indeed in the localstore var err error if *useMockStore { //use the globalStore if the mockStore should be used; in that case, //the complete localStore stack is bypassed for getting the chunk _, err = globalStore.Get(common.BytesToAddress(id.Bytes()), chunk) } else { //use the actual localstore item, ok := sim.NodeItem(id, bucketKeyStore) if !ok { return fmt.Errorf("Error accessing localstore") } lstore := item.(*storage.LocalStore) _, err = lstore.Get(ctx, chunk) } if err != nil { log.Warn(fmt.Sprintf("Chunk %s NOT found for id %s", chunk, id)) localSuccess = false } else { log.Debug(fmt.Sprintf("Chunk %s IS FOUND for id %s", chunk, id)) } } allSuccess = localSuccess } } if !allSuccess { return fmt.Errorf("Not all chunks succeeded!") } return nil }) if result.Error != nil { return result.Error } log.Info("Simulation terminated") return nil } //the server func to start syncing //issues `RequestSubscriptionMsg` to peers, based on po, by iterating over //the kademlia's `EachBin` function. //returns the number of subscriptions requested func startSyncing(r *Registry, conf *synctestConfig) (int, error) { var err error kad, ok := r.delivery.overlay.(*network.Kademlia) if !ok { return 0, fmt.Errorf("Not a Kademlia!") } subCnt := 0 //iterate over each bin and solicit needed subscription to bins kad.EachBin(r.addr.Over(), pof, 0, func(conn network.OverlayConn, po int) bool { //identify begin and start index of the bin(s) we want to subscribe to histRange := &Range{} subCnt++ err = r.RequestSubscription(conf.addrToIDMap[string(conn.Address())], NewStream("SYNC", FormatSyncBinKey(uint8(po)), true), histRange, Top) if err != nil { log.Error(fmt.Sprintf("Error in RequestSubsciption! %v", err)) return false } return true }) return subCnt, nil } //map chunk keys to addresses which are responsible func mapKeysToNodes(conf *synctestConfig) { kmap := make(map[string][]int) nodemap := make(map[string][]int) //build a pot for chunk hashes np := pot.NewPot(nil, 0) indexmap := make(map[string]int) for i, a := range conf.addrs { indexmap[string(a)] = i np, _, _ = pot.Add(np, a, pof) } //for each address, run EachNeighbour on the chunk hashes pot to identify closest nodes log.Trace(fmt.Sprintf("Generated hash chunk(s): %v", conf.hashes)) for i := 0; i < len(conf.hashes); i++ { pl := 256 //highest possible proximity var nns []int np.EachNeighbour([]byte(conf.hashes[i]), pof, func(val pot.Val, po int) bool { a := val.([]byte) if pl < 256 && pl != po { return false } if pl == 256 || pl == po { log.Trace(fmt.Sprintf("appending %s", conf.addrToIDMap[string(a)])) nns = append(nns, indexmap[string(a)]) nodemap[string(a)] = append(nodemap[string(a)], i) } if pl == 256 && len(nns) >= testMinProxBinSize { //maxProxBinSize has been reached at this po, so save it //we will add all other nodes at the same po pl = po } return true }) kmap[string(conf.hashes[i])] = nns } for addr, chunks := range nodemap { //this selects which chunks are expected to be found with the given node conf.idToChunksMap[conf.addrToIDMap[addr]] = chunks } log.Debug(fmt.Sprintf("Map of expected chunks by ID: %v", conf.idToChunksMap)) conf.chunksToNodesMap = kmap } //upload a file(chunks) to a single local node store func uploadFileToSingleNodeStore(id discover.NodeID, chunkCount int, lstore *storage.LocalStore) ([]storage.Address, error) { log.Debug(fmt.Sprintf("Uploading to node id: %s", id)) fileStore := storage.NewFileStore(lstore, storage.NewFileStoreParams()) size := chunkSize var rootAddrs []storage.Address for i := 0; i < chunkCount; i++ { rk, wait, err := fileStore.Store(context.TODO(), io.LimitReader(crand.Reader, int64(size)), int64(size), false) if err != nil { return nil, err } err = wait(context.TODO()) if err != nil { return nil, err } rootAddrs = append(rootAddrs, (rk)) } return rootAddrs, nil }