// Copyright (C) 2019 Storj Labs, Inc. // See LICENSE for copying information. package gracefulexit_test import ( "context" "io" "strconv" "testing" "time" "github.com/stretchr/testify/require" "github.com/zeebo/errs" "go.uber.org/zap" "go.uber.org/zap/zaptest" "golang.org/x/sync/errgroup" "storj.io/common/errs2" "storj.io/common/identity" "storj.io/common/memory" "storj.io/common/pb" "storj.io/common/rpc/rpcstatus" "storj.io/common/signing" "storj.io/common/storj" "storj.io/common/sync2" "storj.io/common/testcontext" "storj.io/common/testrand" "storj.io/storj/private/testplanet" "storj.io/storj/satellite" "storj.io/storj/satellite/metabase" "storj.io/storj/satellite/metainfo" "storj.io/storj/satellite/overlay" "storj.io/storj/storagenode" "storj.io/storj/storagenode/blobstore/testblobs" "storj.io/storj/storagenode/gracefulexit" ) const numObjects = 6 const numMultipartObjects = 6 // exitProcessClient is used so we can pass the graceful exit process clients regardless of implementation. type exitProcessClient interface { Send(*pb.StorageNodeMessage) error Recv() (*pb.SatelliteMessage, error) } func TestSuccess(t *testing.T) { testTransfers(t, numObjects, numMultipartObjects, func(t *testing.T, ctx *testcontext.Context, nodeFullIDs map[storj.NodeID]*identity.FullIdentity, satellite *testplanet.Satellite, processClient exitProcessClient, exitingNode *storagenode.Peer, numPieces int) { var pieceID storj.PieceID failedCount := 0 deletedCount := 0 for { response, err := processClient.Recv() if errs.Is(err, io.EOF) { // Done break } require.NoError(t, err) switch m := response.GetMessage().(type) { case *pb.SatelliteMessage_TransferPiece: require.NotNil(t, m) // pick the first one to fail if pieceID.IsZero() { pieceID = m.TransferPiece.OriginalPieceId } if failedCount > 0 || pieceID != m.TransferPiece.OriginalPieceId { pieceReader, err := exitingNode.Storage2.Store.Reader(ctx, satellite.ID(), m.TransferPiece.OriginalPieceId) require.NoError(t, err) header, err := pieceReader.GetPieceHeader() require.NoError(t, err) orderLimit := header.OrderLimit originalPieceHash := &pb.PieceHash{ PieceId: orderLimit.PieceId, Hash: header.GetHash(), PieceSize: pieceReader.Size(), Timestamp: header.GetCreationTime(), Signature: header.GetSignature(), } newPieceHash := &pb.PieceHash{ PieceId: m.TransferPiece.AddressedOrderLimit.Limit.PieceId, Hash: originalPieceHash.Hash, PieceSize: originalPieceHash.PieceSize, Timestamp: time.Now(), } receivingNodeID := nodeFullIDs[m.TransferPiece.AddressedOrderLimit.Limit.StorageNodeId] require.NotNil(t, receivingNodeID) signer := signing.SignerFromFullIdentity(receivingNodeID) signedNewPieceHash, err := signing.SignPieceHash(ctx, signer, newPieceHash) require.NoError(t, err) success := &pb.StorageNodeMessage{ Message: &pb.StorageNodeMessage_Succeeded{ Succeeded: &pb.TransferSucceeded{ OriginalPieceId: m.TransferPiece.OriginalPieceId, OriginalPieceHash: originalPieceHash, OriginalOrderLimit: &orderLimit, ReplacementPieceHash: signedNewPieceHash, }, }, } err = processClient.Send(success) require.NoError(t, err) } else { failedCount++ failed := &pb.StorageNodeMessage{ Message: &pb.StorageNodeMessage_Failed{ Failed: &pb.TransferFailed{ OriginalPieceId: m.TransferPiece.OriginalPieceId, Error: pb.TransferFailed_UNKNOWN, }, }, } err = processClient.Send(failed) require.NoError(t, err) } case *pb.SatelliteMessage_DeletePiece: deletedCount++ case *pb.SatelliteMessage_ExitCompleted: signee := signing.SigneeFromPeerIdentity(satellite.Identity.PeerIdentity()) err = signing.VerifyExitCompleted(ctx, signee, m.ExitCompleted) require.NoError(t, err) default: require.FailNow(t, "should not reach this case: %#v", m) } } // check that the exit has completed and we have the correct transferred/failed values progress, err := satellite.DB.GracefulExit().GetProgress(ctx, exitingNode.ID()) require.NoError(t, err) require.EqualValues(t, numPieces, progress.PiecesTransferred) require.EqualValues(t, numPieces, deletedCount) // even though we failed 1, it eventually succeeded, so the count should be 0 require.EqualValues(t, 0, progress.PiecesFailed) }) } func TestConcurrentConnections(t *testing.T) { successThreshold := 4 testplanet.Run(t, testplanet.Config{ SatelliteCount: 1, StorageNodeCount: successThreshold + 1, UplinkCount: 1, Reconfigure: testplanet.Reconfigure{ Satellite: testplanet.ReconfigureRS(2, 3, successThreshold, successThreshold), }, }, func(t *testing.T, ctx *testcontext.Context, planet *testplanet.Planet) { uplinkPeer := planet.Uplinks[0] satellite := planet.Satellites[0] satellite.GracefulExit.Chore.Loop.Pause() err := uplinkPeer.Upload(ctx, satellite, "testbucket", "test/path1", testrand.Bytes(5*memory.KiB)) require.NoError(t, err) // check that there are no exiting nodes. exitingNodeIDs, err := satellite.DB.OverlayCache().GetExitingNodes(ctx) require.NoError(t, err) require.Len(t, exitingNodeIDs, 0) exitingNode, err := findNodeToExit(ctx, planet, 2) require.NoError(t, err) var group errgroup.Group concurrentCalls := 4 var mainStarted sync2.Fence defer mainStarted.Release() for i := 0; i < concurrentCalls; i++ { group.Go(func() (err error) { // connect to satellite so we initiate the exit. conn, err := exitingNode.Dialer.DialNodeURL(ctx, satellite.NodeURL()) require.NoError(t, err) defer func() { err = errs.Combine(err, conn.Close()) }() client := pb.NewDRPCSatelliteGracefulExitClient(conn) if !mainStarted.Wait(ctx) { return ctx.Err() } c, err := client.Process(ctx) require.NoError(t, err) defer func() { err = errs.Combine(err, c.Close()) }() _, err = c.Recv() require.Error(t, err) require.True(t, errs2.IsRPC(err, rpcstatus.Aborted)) return nil }) } // connect to satellite so we initiate the exit ("main" call) conn, err := exitingNode.Dialer.DialNodeURL(ctx, satellite.NodeURL()) require.NoError(t, err) defer ctx.Check(conn.Close) client := pb.NewDRPCSatelliteGracefulExitClient(conn) { // this connection will immediately return since graceful exit has not been initiated yet c, err := client.Process(ctx) require.NoError(t, err) response, err := c.Recv() require.NoError(t, err) switch m := response.GetMessage().(type) { case *pb.SatelliteMessage_NotReady: default: require.FailNow(t, "should not reach this case: %#v", m) } require.NoError(t, c.Close()) } // wait for initial loop to start so we have pieces to transfer satellite.GracefulExit.Chore.Loop.TriggerWait() { // this connection should not close immediately, since there are pieces to transfer c, err := client.Process(ctx) require.NoError(t, err) _, err = c.Recv() require.NoError(t, err) // deferring here to ensure that the other connections see the in-use connection. defer ctx.Check(c.Close) } // start receiving from concurrent connections mainStarted.Release() err = group.Wait() require.NoError(t, err) }) } func TestRecvTimeout(t *testing.T) { successThreshold := 4 testplanet.Run(t, testplanet.Config{ SatelliteCount: 1, StorageNodeCount: successThreshold + 1, UplinkCount: 1, Reconfigure: testplanet.Reconfigure{ StorageNodeDB: func(index int, db storagenode.DB, log *zap.Logger) (storagenode.DB, error) { return testblobs.NewSlowDB(log.Named("slowdb"), db), nil }, Satellite: testplanet.Combine( func(log *zap.Logger, index int, config *satellite.Config) { // This config value will create a very short timeframe allowed for receiving // data from storage nodes. This will cause context to cancel with timeout. config.GracefulExit.RecvTimeout = 10 * time.Millisecond }, testplanet.ReconfigureRS(2, 3, successThreshold, successThreshold), ), StorageNode: func(index int, config *storagenode.Config) { config.GracefulExit = gracefulexit.Config{ ChoreInterval: 2 * time.Minute, NumWorkers: 2, NumConcurrentTransfers: 2, MinBytesPerSecond: 128, MinDownloadTimeout: 2 * time.Minute, } }, }, }, func(t *testing.T, ctx *testcontext.Context, planet *testplanet.Planet) { satellite := planet.Satellites[0] ul := planet.Uplinks[0] satellite.GracefulExit.Chore.Loop.Pause() err := ul.Upload(ctx, satellite, "testbucket", "test/path1", testrand.Bytes(5*memory.KiB)) require.NoError(t, err) exitingNode, err := findNodeToExit(ctx, planet, 1) require.NoError(t, err) exitingNode.GracefulExit.Chore.Loop.Pause() exitStatusReq := overlay.ExitStatusRequest{ NodeID: exitingNode.ID(), ExitInitiatedAt: time.Now(), } _, err = satellite.Overlay.DB.UpdateExitStatus(ctx, &exitStatusReq) require.NoError(t, err) // run the satellite chore to build the transfer queue. satellite.GracefulExit.Chore.Loop.TriggerWait() satellite.GracefulExit.Chore.Loop.Pause() // check that the satellite knows the storage node is exiting. exitingNodes, err := satellite.DB.OverlayCache().GetExitingNodes(ctx) require.NoError(t, err) require.Len(t, exitingNodes, 1) require.Equal(t, exitingNode.ID(), exitingNodes[0].NodeID) queueItems, err := satellite.DB.GracefulExit().GetIncomplete(ctx, exitingNode.ID(), 10, 0) require.NoError(t, err) require.Len(t, queueItems, 1) storageNodeDB := exitingNode.DB.(*testblobs.SlowDB) // make uploads on storage node slower than the timeout for transferring bytes to another node delay := 200 * time.Millisecond storageNodeDB.SetLatency(delay) // run the SN chore again to start processing transfers. worker := gracefulexit.NewWorker(zaptest.NewLogger(t), exitingNode.GracefulExit.Service, exitingNode.PieceTransfer.Service, exitingNode.Dialer, satellite.NodeURL(), exitingNode.Config.GracefulExit) err = worker.Run(ctx) require.Error(t, err) require.True(t, errs2.IsRPC(err, rpcstatus.DeadlineExceeded)) }) } func TestInvalidStorageNodeSignature(t *testing.T) { testTransfers(t, 1, 0, func(t *testing.T, ctx *testcontext.Context, nodeFullIDs map[storj.NodeID]*identity.FullIdentity, satellite *testplanet.Satellite, processClient exitProcessClient, exitingNode *storagenode.Peer, numPieces int) { response, err := processClient.Recv() require.NoError(t, err) switch m := response.GetMessage().(type) { case *pb.SatelliteMessage_TransferPiece: require.NotNil(t, m) pieceReader, err := exitingNode.Storage2.Store.Reader(ctx, satellite.ID(), m.TransferPiece.OriginalPieceId) require.NoError(t, err) header, err := pieceReader.GetPieceHeader() require.NoError(t, err) orderLimit := header.OrderLimit originalPieceHash := &pb.PieceHash{ PieceId: orderLimit.PieceId, Hash: header.GetHash(), PieceSize: pieceReader.Size(), Timestamp: header.GetCreationTime(), Signature: header.GetSignature(), } newPieceHash := &pb.PieceHash{ PieceId: m.TransferPiece.AddressedOrderLimit.Limit.PieceId, Hash: originalPieceHash.Hash, PieceSize: originalPieceHash.PieceSize, Timestamp: time.Now(), } wrongSigner := signing.SignerFromFullIdentity(exitingNode.Identity) signedNewPieceHash, err := signing.SignPieceHash(ctx, wrongSigner, newPieceHash) require.NoError(t, err) message := &pb.StorageNodeMessage{ Message: &pb.StorageNodeMessage_Succeeded{ Succeeded: &pb.TransferSucceeded{ OriginalPieceId: m.TransferPiece.OriginalPieceId, OriginalPieceHash: originalPieceHash, OriginalOrderLimit: &orderLimit, ReplacementPieceHash: signedNewPieceHash, }, }, } err = processClient.Send(message) require.NoError(t, err) default: require.FailNow(t, "should not reach this case: %#v", m) } response, err = processClient.Recv() require.NoError(t, err) switch m := response.GetMessage().(type) { case *pb.SatelliteMessage_ExitFailed: require.NotNil(t, m) require.NotNil(t, m.ExitFailed) require.Equal(t, m.ExitFailed.Reason, pb.ExitFailed_VERIFICATION_FAILED) node, err := satellite.DB.OverlayCache().Get(ctx, m.ExitFailed.NodeId) require.NoError(t, err) require.NotNil(t, node.Disqualified) default: require.FailNow(t, "should not reach this case: %#v", m) } // check that the exit has completed and we have the correct transferred/failed values progress, err := satellite.DB.GracefulExit().GetProgress(ctx, exitingNode.ID()) require.NoError(t, err) require.Equal(t, int64(0), progress.PiecesTransferred) require.Equal(t, int64(1), progress.PiecesFailed) }) } func TestExitDisqualifiedNodeFailOnStart(t *testing.T) { testplanet.Run(t, testplanet.Config{ SatelliteCount: 1, StorageNodeCount: 2, UplinkCount: 1, }, func(t *testing.T, ctx *testcontext.Context, planet *testplanet.Planet) { satellite := planet.Satellites[0] exitingNode := planet.StorageNodes[0] _, err := satellite.DB.OverlayCache().DisqualifyNode(ctx, exitingNode.ID(), time.Now(), overlay.DisqualificationReasonUnknown) require.NoError(t, err) conn, err := exitingNode.Dialer.DialNodeURL(ctx, satellite.NodeURL()) require.NoError(t, err) defer ctx.Check(conn.Close) client := pb.NewDRPCSatelliteGracefulExitClient(conn) processClient, err := client.Process(ctx) require.NoError(t, err) // Process endpoint should return immediately if node is disqualified response, err := processClient.Recv() require.True(t, errs2.IsRPC(err, rpcstatus.FailedPrecondition)) require.Nil(t, response) require.NoError(t, processClient.Close()) // disqualified node should fail graceful exit exitStatus, err := satellite.Overlay.DB.GetExitStatus(ctx, exitingNode.ID()) require.NoError(t, err) require.NotNil(t, exitStatus.ExitFinishedAt) require.False(t, exitStatus.ExitSuccess) }) } func TestExitDisqualifiedNodeFailEventually(t *testing.T) { testTransfers(t, numObjects, numMultipartObjects, func(t *testing.T, ctx *testcontext.Context, nodeFullIDs map[storj.NodeID]*identity.FullIdentity, satellite *testplanet.Satellite, processClient exitProcessClient, exitingNode *storagenode.Peer, numPieces int) { var disqualifiedError error isDisqualified := false for { response, err := processClient.Recv() if errs.Is(err, io.EOF) { // Done break } if errs2.IsRPC(err, rpcstatus.FailedPrecondition) { disqualifiedError = err break } if !isDisqualified { _, err := satellite.DB.OverlayCache().DisqualifyNode(ctx, exitingNode.ID(), time.Now(), overlay.DisqualificationReasonUnknown) require.NoError(t, err) } switch m := response.GetMessage().(type) { case *pb.SatelliteMessage_TransferPiece: require.NotNil(t, m) pieceReader, err := exitingNode.Storage2.Store.Reader(ctx, satellite.ID(), m.TransferPiece.OriginalPieceId) require.NoError(t, err) header, err := pieceReader.GetPieceHeader() require.NoError(t, err) orderLimit := header.OrderLimit originalPieceHash := &pb.PieceHash{ PieceId: orderLimit.PieceId, Hash: header.GetHash(), PieceSize: pieceReader.Size(), Timestamp: header.GetCreationTime(), Signature: header.GetSignature(), } newPieceHash := &pb.PieceHash{ PieceId: m.TransferPiece.AddressedOrderLimit.Limit.PieceId, Hash: originalPieceHash.Hash, PieceSize: originalPieceHash.PieceSize, Timestamp: time.Now(), } receivingNodeID := nodeFullIDs[m.TransferPiece.AddressedOrderLimit.Limit.StorageNodeId] require.NotNil(t, receivingNodeID) signer := signing.SignerFromFullIdentity(receivingNodeID) signedNewPieceHash, err := signing.SignPieceHash(ctx, signer, newPieceHash) require.NoError(t, err) success := &pb.StorageNodeMessage{ Message: &pb.StorageNodeMessage_Succeeded{ Succeeded: &pb.TransferSucceeded{ OriginalPieceId: m.TransferPiece.OriginalPieceId, OriginalPieceHash: originalPieceHash, OriginalOrderLimit: &orderLimit, ReplacementPieceHash: signedNewPieceHash, }, }, } err = processClient.Send(success) require.NoError(t, err) case *pb.SatelliteMessage_DeletePiece: continue default: require.FailNow(t, "should not reach this case: %#v", m) } } // check that the exit has failed due to node has been disqualified require.True(t, errs2.IsRPC(disqualifiedError, rpcstatus.FailedPrecondition)) // check that the exit has completed and we have the correct transferred/failed values progress, err := satellite.DB.GracefulExit().GetProgress(ctx, exitingNode.ID()) require.NoError(t, err) require.EqualValues(t, numPieces, progress.PiecesTransferred) // disqualified node should fail graceful exit exitStatus, err := satellite.Overlay.DB.GetExitStatus(ctx, exitingNode.ID()) require.NoError(t, err) require.NotNil(t, exitStatus.ExitFinishedAt) require.False(t, exitStatus.ExitSuccess) }) } func TestFailureHashMismatch(t *testing.T) { testTransfers(t, 1, 0, testFailureHashMismatch) } func TestFailureHashMismatchMultipart(t *testing.T) { testTransfers(t, 0, 1, testFailureHashMismatch) } func testFailureHashMismatch(t *testing.T, ctx *testcontext.Context, nodeFullIDs map[storj.NodeID]*identity.FullIdentity, satellite *testplanet.Satellite, processClient exitProcessClient, exitingNode *storagenode.Peer, numPieces int) { response, err := processClient.Recv() require.NoError(t, err) switch m := response.GetMessage().(type) { case *pb.SatelliteMessage_TransferPiece: require.NotNil(t, m) pieceReader, err := exitingNode.Storage2.Store.Reader(ctx, satellite.ID(), m.TransferPiece.OriginalPieceId) require.NoError(t, err) header, err := pieceReader.GetPieceHeader() require.NoError(t, err) orderLimit := header.OrderLimit originalPieceHash := &pb.PieceHash{ PieceId: orderLimit.PieceId, Hash: header.GetHash(), PieceSize: pieceReader.Size(), Timestamp: header.GetCreationTime(), Signature: header.GetSignature(), } newPieceHash := &pb.PieceHash{ PieceId: m.TransferPiece.AddressedOrderLimit.Limit.PieceId, Hash: originalPieceHash.Hash[:1], PieceSize: originalPieceHash.PieceSize, Timestamp: time.Now(), } receivingNodeID := nodeFullIDs[m.TransferPiece.AddressedOrderLimit.Limit.StorageNodeId] require.NotNil(t, receivingNodeID) signer := signing.SignerFromFullIdentity(receivingNodeID) signedNewPieceHash, err := signing.SignPieceHash(ctx, signer, newPieceHash) require.NoError(t, err) message := &pb.StorageNodeMessage{ Message: &pb.StorageNodeMessage_Succeeded{ Succeeded: &pb.TransferSucceeded{ OriginalPieceId: m.TransferPiece.OriginalPieceId, OriginalPieceHash: originalPieceHash, OriginalOrderLimit: &orderLimit, ReplacementPieceHash: signedNewPieceHash, }, }, } err = processClient.Send(message) require.NoError(t, err) default: require.FailNow(t, "should not reach this case: %#v", m) } response, err = processClient.Recv() require.NoError(t, err) switch m := response.GetMessage().(type) { case *pb.SatelliteMessage_ExitFailed: require.NotNil(t, m) require.NotNil(t, m.ExitFailed) require.Equal(t, m.ExitFailed.Reason, pb.ExitFailed_VERIFICATION_FAILED) node, err := satellite.DB.OverlayCache().Get(ctx, m.ExitFailed.NodeId) require.NoError(t, err) require.NotNil(t, node.Disqualified) default: require.FailNow(t, "should not reach this case: %#v", m) } // check that the exit has completed and we have the correct transferred/failed values progress, err := satellite.DB.GracefulExit().GetProgress(ctx, exitingNode.ID()) require.NoError(t, err) require.Equal(t, int64(0), progress.PiecesTransferred) require.Equal(t, int64(1), progress.PiecesFailed) } func TestFailureUnknownError(t *testing.T) { testTransfers(t, 1, 0, func(t *testing.T, ctx *testcontext.Context, nodeFullIDs map[storj.NodeID]*identity.FullIdentity, satellite *testplanet.Satellite, processClient exitProcessClient, exitingNode *storagenode.Peer, numPieces int) { response, err := processClient.Recv() require.NoError(t, err) switch m := response.GetMessage().(type) { case *pb.SatelliteMessage_TransferPiece: require.NotNil(t, m) message := &pb.StorageNodeMessage{ Message: &pb.StorageNodeMessage_Failed{ Failed: &pb.TransferFailed{ Error: pb.TransferFailed_UNKNOWN, OriginalPieceId: m.TransferPiece.OriginalPieceId, }, }, } err = processClient.Send(message) require.NoError(t, err) default: require.FailNow(t, "should not reach this case: %#v", m) } response, err = processClient.Recv() require.NoError(t, err) switch m := response.GetMessage().(type) { case *pb.SatelliteMessage_TransferPiece: require.NotNil(t, m) default: require.FailNow(t, "should not reach this case: %#v", m) } // check that the exit has completed and we have the correct transferred/failed values progress, err := satellite.DB.GracefulExit().GetProgress(ctx, exitingNode.ID()) require.NoError(t, err) require.Equal(t, int64(0), progress.PiecesTransferred) require.Equal(t, int64(0), progress.PiecesFailed) }) } func TestFailureUplinkSignature(t *testing.T) { testTransfers(t, 1, 0, func(t *testing.T, ctx *testcontext.Context, nodeFullIDs map[storj.NodeID]*identity.FullIdentity, satellite *testplanet.Satellite, processClient exitProcessClient, exitingNode *storagenode.Peer, numPieces int) { response, err := processClient.Recv() require.NoError(t, err) switch m := response.GetMessage().(type) { case *pb.SatelliteMessage_TransferPiece: require.NotNil(t, m) pieceReader, err := exitingNode.Storage2.Store.Reader(ctx, satellite.ID(), m.TransferPiece.OriginalPieceId) require.NoError(t, err) header, err := pieceReader.GetPieceHeader() require.NoError(t, err) orderLimit := header.OrderLimit orderLimit.UplinkPublicKey = storj.PiecePublicKey{} originalPieceHash := &pb.PieceHash{ PieceId: orderLimit.PieceId, Hash: header.GetHash(), PieceSize: pieceReader.Size(), Timestamp: header.GetCreationTime(), Signature: header.GetSignature(), } newPieceHash := &pb.PieceHash{ PieceId: m.TransferPiece.AddressedOrderLimit.Limit.PieceId, Hash: originalPieceHash.Hash, PieceSize: originalPieceHash.PieceSize, Timestamp: time.Now(), } receivingNodeID := nodeFullIDs[m.TransferPiece.AddressedOrderLimit.Limit.StorageNodeId] require.NotNil(t, receivingNodeID) signer := signing.SignerFromFullIdentity(receivingNodeID) signedNewPieceHash, err := signing.SignPieceHash(ctx, signer, newPieceHash) require.NoError(t, err) message := &pb.StorageNodeMessage{ Message: &pb.StorageNodeMessage_Succeeded{ Succeeded: &pb.TransferSucceeded{ OriginalPieceId: m.TransferPiece.OriginalPieceId, OriginalPieceHash: originalPieceHash, OriginalOrderLimit: &orderLimit, ReplacementPieceHash: signedNewPieceHash, }, }, } err = processClient.Send(message) require.NoError(t, err) default: require.FailNow(t, "should not reach this case: %#v", m) } response, err = processClient.Recv() require.NoError(t, err) switch m := response.GetMessage().(type) { case *pb.SatelliteMessage_ExitFailed: require.NotNil(t, m) require.NotNil(t, m.ExitFailed) require.Equal(t, m.ExitFailed.Reason, pb.ExitFailed_VERIFICATION_FAILED) node, err := satellite.DB.OverlayCache().Get(ctx, m.ExitFailed.NodeId) require.NoError(t, err) require.NotNil(t, node.Disqualified) default: require.FailNow(t, "should not reach this case: %#v", m) } // check that the exit has completed and we have the correct transferred/failed values progress, err := satellite.DB.GracefulExit().GetProgress(ctx, exitingNode.ID()) require.NoError(t, err) require.Equal(t, int64(0), progress.PiecesTransferred) require.Equal(t, int64(1), progress.PiecesFailed) }) } func TestSuccessSegmentUpdate(t *testing.T) { testTransfers(t, 1, 0, testSuccessSegmentUpdate) } func TestSuccessSegmentUpdateMultipart(t *testing.T) { testTransfers(t, 0, 1, testSuccessSegmentUpdate) } func testSuccessSegmentUpdate(t *testing.T, ctx *testcontext.Context, nodeFullIDs map[storj.NodeID]*identity.FullIdentity, satellite *testplanet.Satellite, processClient exitProcessClient, exitingNode *storagenode.Peer, numPieces int) { var recNodeID storj.NodeID response, err := processClient.Recv() require.NoError(t, err) switch m := response.GetMessage().(type) { case *pb.SatelliteMessage_TransferPiece: require.NotNil(t, m) pieceReader, err := exitingNode.Storage2.Store.Reader(ctx, satellite.ID(), m.TransferPiece.OriginalPieceId) require.NoError(t, err) header, err := pieceReader.GetPieceHeader() require.NoError(t, err) orderLimit := header.OrderLimit originalPieceHash := &pb.PieceHash{ PieceId: orderLimit.PieceId, Hash: header.GetHash(), PieceSize: pieceReader.Size(), Timestamp: header.GetCreationTime(), Signature: header.GetSignature(), } newPieceHash := &pb.PieceHash{ PieceId: m.TransferPiece.AddressedOrderLimit.Limit.PieceId, Hash: originalPieceHash.Hash, PieceSize: originalPieceHash.PieceSize, Timestamp: time.Now(), } receivingIdentity := nodeFullIDs[m.TransferPiece.AddressedOrderLimit.Limit.StorageNodeId] require.NotNil(t, receivingIdentity) // get the receiving node piece count before processing recNodeID = receivingIdentity.ID signer := signing.SignerFromFullIdentity(receivingIdentity) signedNewPieceHash, err := signing.SignPieceHash(ctx, signer, newPieceHash) require.NoError(t, err) success := &pb.StorageNodeMessage{ Message: &pb.StorageNodeMessage_Succeeded{ Succeeded: &pb.TransferSucceeded{ OriginalPieceId: m.TransferPiece.OriginalPieceId, OriginalPieceHash: originalPieceHash, OriginalOrderLimit: &orderLimit, ReplacementPieceHash: signedNewPieceHash, }, }, } err = processClient.Send(success) require.NoError(t, err) default: require.FailNow(t, "did not get a TransferPiece message") } response, err = processClient.Recv() require.NoError(t, err) switch response.GetMessage().(type) { case *pb.SatelliteMessage_DeletePiece: // expect the delete piece message default: require.FailNow(t, "did not get a DeletePiece message") } // check that the exit has completed and we have the correct transferred/failed values progress, err := satellite.DB.GracefulExit().GetProgress(ctx, exitingNode.ID()) require.NoError(t, err) require.EqualValues(t, numPieces, progress.PiecesTransferred) // even though we failed 1, it eventually succeeded, so the count should be 0 require.EqualValues(t, 0, progress.PiecesFailed) segments, err := satellite.Metabase.DB.TestingAllSegments(ctx) require.NoError(t, err) require.Len(t, segments, 1) found := 0 require.True(t, len(segments[0].Pieces) > 0) for _, piece := range segments[0].Pieces { require.NotEqual(t, exitingNode.ID(), piece.StorageNode) if piece.StorageNode == recNodeID { found++ } } require.Equal(t, 1, found) } func TestUpdateSegmentFailure_DuplicatedNodeID(t *testing.T) { testTransfers(t, 1, 0, testUpdateSegmentFailureDuplicatedNodeID) } func TestUpdateSegmentFailure_DuplicatedNodeIDMultipart(t *testing.T) { testTransfers(t, 0, 1, testUpdateSegmentFailureDuplicatedNodeID) } func testUpdateSegmentFailureDuplicatedNodeID(t *testing.T, ctx *testcontext.Context, nodeFullIDs map[storj.NodeID]*identity.FullIdentity, satellite *testplanet.Satellite, processClient exitProcessClient, exitingNode *storagenode.Peer, numPieces int) { response, err := processClient.Recv() require.NoError(t, err) var firstRecNodeID storj.NodeID var pieceID storj.PieceID switch m := response.GetMessage().(type) { case *pb.SatelliteMessage_TransferPiece: firstRecNodeID = m.TransferPiece.AddressedOrderLimit.Limit.StorageNodeId pieceID = m.TransferPiece.OriginalPieceId pieceReader, err := exitingNode.Storage2.Store.Reader(ctx, satellite.ID(), pieceID) require.NoError(t, err) header, err := pieceReader.GetPieceHeader() require.NoError(t, err) orderLimit := header.OrderLimit originalPieceHash := &pb.PieceHash{ PieceId: orderLimit.PieceId, Hash: header.GetHash(), PieceSize: pieceReader.Size(), Timestamp: header.GetCreationTime(), Signature: header.GetSignature(), } newPieceHash := &pb.PieceHash{ PieceId: m.TransferPiece.AddressedOrderLimit.Limit.PieceId, Hash: originalPieceHash.Hash, PieceSize: originalPieceHash.PieceSize, Timestamp: time.Now(), } receivingNodeIdentity := nodeFullIDs[m.TransferPiece.AddressedOrderLimit.Limit.StorageNodeId] require.NotNil(t, receivingNodeIdentity) signer := signing.SignerFromFullIdentity(receivingNodeIdentity) signedNewPieceHash, err := signing.SignPieceHash(ctx, signer, newPieceHash) require.NoError(t, err) success := &pb.StorageNodeMessage{ Message: &pb.StorageNodeMessage_Succeeded{ Succeeded: &pb.TransferSucceeded{ OriginalPieceId: pieceID, OriginalPieceHash: originalPieceHash, OriginalOrderLimit: &orderLimit, ReplacementPieceHash: signedNewPieceHash, }, }, } // update segment to include the new receiving node before responding to satellite segments, err := satellite.Metabase.DB.TestingAllSegments(ctx) require.NoError(t, err) require.Len(t, segments, 1) require.True(t, len(segments[0].Pieces) > 0) pieceToRemove := make(metabase.Pieces, 1) pieceToAdd := make(metabase.Pieces, 1) pieces := segments[0].Pieces for _, piece := range pieces { if pieceToRemove[0] == (metabase.Piece{}) && piece.StorageNode != exitingNode.ID() { pieceToRemove[0] = piece continue } } pieceToAdd[0] = metabase.Piece{ Number: pieceToRemove[0].Number, StorageNode: firstRecNodeID, } err = satellite.GracefulExit.Endpoint.UpdatePiecesCheckDuplicates(ctx, segments[0], pieceToAdd, pieceToRemove, false) require.NoError(t, err) err = processClient.Send(success) require.NoError(t, err) default: require.FailNow(t, "should not reach this case: %#v", m) } response, err = processClient.Recv() require.NoError(t, err) switch m := response.GetMessage().(type) { case *pb.SatelliteMessage_TransferPiece: // validate we get a new node to transfer too require.True(t, m.TransferPiece.OriginalPieceId == pieceID) require.True(t, m.TransferPiece.AddressedOrderLimit.Limit.StorageNodeId != firstRecNodeID) default: require.FailNow(t, "should not reach this case: %#v", m) } // check exiting node is still in the segment segments, err := satellite.Metabase.DB.TestingAllSegments(ctx) require.NoError(t, err) require.Len(t, segments, 1) require.True(t, len(segments[0].Pieces) > 0) pieces := segments[0].Pieces pieceMap := make(map[storj.NodeID]int) for _, piece := range pieces { pieceMap[piece.StorageNode]++ } exitingNodeID := exitingNode.ID() count, ok := pieceMap[exitingNodeID] require.True(t, ok) require.Equal(t, 1, count) count, ok = pieceMap[firstRecNodeID] require.True(t, ok) require.Equal(t, 1, count) } func TestExitDisabled(t *testing.T) { testplanet.Run(t, testplanet.Config{ SatelliteCount: 1, StorageNodeCount: 2, UplinkCount: 1, Reconfigure: testplanet.Reconfigure{ Satellite: func(log *zap.Logger, index int, config *satellite.Config) { config.GracefulExit.Enabled = false }, }, }, func(t *testing.T, ctx *testcontext.Context, planet *testplanet.Planet) { satellite := planet.Satellites[0] exitingNode := planet.StorageNodes[0] require.Nil(t, satellite.GracefulExit.Chore) require.Nil(t, satellite.GracefulExit.Endpoint) conn, err := exitingNode.Dialer.DialNodeURL(ctx, satellite.NodeURL()) require.NoError(t, err) defer ctx.Check(conn.Close) client := pb.NewDRPCSatelliteGracefulExitClient(conn) processClient, err := client.Process(ctx) require.NoError(t, err) // Process endpoint should return immediately if GE is disabled response, err := processClient.Recv() require.Error(t, err) // drpc will return "Unknown" require.True(t, errs2.IsRPC(err, rpcstatus.Unknown)) require.Nil(t, response) }) } func TestSegmentChangedOrDeleted(t *testing.T) { successThreshold := 4 testplanet.Run(t, testplanet.Config{ SatelliteCount: 1, StorageNodeCount: successThreshold + 1, UplinkCount: 1, Reconfigure: testplanet.Reconfigure{ Satellite: testplanet.ReconfigureRS(2, 3, successThreshold, successThreshold), }, }, func(t *testing.T, ctx *testcontext.Context, planet *testplanet.Planet) { uplinkPeer := planet.Uplinks[0] satellite := planet.Satellites[0] satellite.GracefulExit.Chore.Loop.Pause() err := uplinkPeer.Upload(ctx, satellite, "testbucket", "test/path0", testrand.Bytes(5*memory.KiB)) require.NoError(t, err) err = uplinkPeer.Upload(ctx, satellite, "testbucket", "test/path1", testrand.Bytes(5*memory.KiB)) require.NoError(t, err) // check that there are no exiting nodes. exitingNodes, err := satellite.DB.OverlayCache().GetExitingNodes(ctx) require.NoError(t, err) require.Len(t, exitingNodes, 0) exitingNode, err := findNodeToExit(ctx, planet, 2) require.NoError(t, err) exitRequest := &overlay.ExitStatusRequest{ NodeID: exitingNode.ID(), ExitInitiatedAt: time.Now(), } _, err = satellite.DB.OverlayCache().UpdateExitStatus(ctx, exitRequest) require.NoError(t, err) err = satellite.DB.GracefulExit().IncrementProgress(ctx, exitingNode.ID(), 0, 0, 0) require.NoError(t, err) exitingNodes, err = satellite.DB.OverlayCache().GetExitingNodes(ctx) require.NoError(t, err) require.Len(t, exitingNodes, 1) require.Equal(t, exitingNode.ID(), exitingNodes[0].NodeID) // trigger the metainfo loop chore so we can get some pieces to transfer satellite.GracefulExit.Chore.Loop.TriggerWait() // make sure all the pieces are in the transfer queue incomplete, err := satellite.DB.GracefulExit().GetIncomplete(ctx, exitingNode.ID(), 10, 0) require.NoError(t, err) require.Len(t, incomplete, 2) // updating the first object and deleting the second. this will cause a root piece ID change which will result in // a successful graceful exit instead of a request to transfer pieces since the root piece IDs will have changed. err = uplinkPeer.Upload(ctx, satellite, "testbucket", "test/path0", testrand.Bytes(5*memory.KiB)) require.NoError(t, err) err = uplinkPeer.DeleteObject(ctx, satellite, "testbucket", "test/path1") require.NoError(t, err) // reconnect to the satellite. conn, err := exitingNode.Dialer.DialNodeURL(ctx, satellite.NodeURL()) require.NoError(t, err) defer ctx.Check(conn.Close) client := pb.NewDRPCSatelliteGracefulExitClient(conn) c, err := client.Process(ctx) require.NoError(t, err) defer ctx.Check(c.CloseSend) response, err := c.Recv() require.NoError(t, err) // we expect an exit completed b/c there is nothing to do here switch m := response.GetMessage().(type) { case *pb.SatelliteMessage_ExitCompleted: signee := signing.SigneeFromPeerIdentity(satellite.Identity.PeerIdentity()) err = signing.VerifyExitCompleted(ctx, signee, m.ExitCompleted) require.NoError(t, err) exitStatus, err := satellite.DB.OverlayCache().GetExitStatus(ctx, exitingNode.ID()) require.NoError(t, err) require.NotNil(t, exitStatus.ExitFinishedAt) require.True(t, exitStatus.ExitSuccess) default: require.FailNow(t, "should not reach this case: %#v", m) } queueItems, err := satellite.DB.GracefulExit().GetIncomplete(ctx, exitingNode.ID(), 2, 0) require.NoError(t, err) require.Len(t, queueItems, 0) }) } func TestSegmentChangedOrDeletedMultipart(t *testing.T) { successThreshold := 4 testplanet.Run(t, testplanet.Config{ SatelliteCount: 1, StorageNodeCount: successThreshold + 1, UplinkCount: 1, Reconfigure: testplanet.Reconfigure{ Satellite: testplanet.ReconfigureRS(2, 3, successThreshold, successThreshold), }, }, func(t *testing.T, ctx *testcontext.Context, planet *testplanet.Planet) { uplinkPeer := planet.Uplinks[0] satellite := planet.Satellites[0] project, err := uplinkPeer.GetProject(ctx, satellite) require.NoError(t, err) defer func() { require.NoError(t, project.Close()) }() satellite.GracefulExit.Chore.Loop.Pause() _, err = project.EnsureBucket(ctx, "testbucket") require.NoError(t, err) // TODO: activate when an object part can be overwritten // info0, err := multipart.NewMultipartUpload(ctx, project, "testbucket", "test/path0", nil) // require.NoError(t, err) // _, err = multipart.PutObjectPart(ctx, project, "testbucket", "test/path0", info0.StreamID, 1, // etag.NewHashReader(bytes.NewReader(testrand.Bytes(5*memory.KiB)), sha256.New())) // require.NoError(t, err) info1, err := project.BeginUpload(ctx, "testbucket", "test/path1", nil) require.NoError(t, err) upload, err := project.UploadPart(ctx, "testbucket", "test/path1", info1.UploadID, 1) require.NoError(t, err) _, err = upload.Write(testrand.Bytes(5 * memory.KiB)) require.NoError(t, err) require.NoError(t, upload.Commit()) // check that there are no exiting nodes. exitingNodes, err := satellite.DB.OverlayCache().GetExitingNodes(ctx) require.NoError(t, err) require.Len(t, exitingNodes, 0) exitingNode, err := findNodeToExit(ctx, planet, 2) require.NoError(t, err) exitRequest := &overlay.ExitStatusRequest{ NodeID: exitingNode.ID(), ExitInitiatedAt: time.Now(), } _, err = satellite.DB.OverlayCache().UpdateExitStatus(ctx, exitRequest) require.NoError(t, err) err = satellite.DB.GracefulExit().IncrementProgress(ctx, exitingNode.ID(), 0, 0, 0) require.NoError(t, err) exitingNodes, err = satellite.DB.OverlayCache().GetExitingNodes(ctx) require.NoError(t, err) require.Len(t, exitingNodes, 1) require.Equal(t, exitingNode.ID(), exitingNodes[0].NodeID) // trigger the metainfo loop chore so we can get some pieces to transfer satellite.GracefulExit.Chore.Loop.TriggerWait() // make sure all the pieces are in the transfer queue incomplete, err := satellite.DB.GracefulExit().GetIncomplete(ctx, exitingNode.ID(), 10, 0) require.NoError(t, err) require.Len(t, incomplete, 1) // TODO: change to this when an object part can be overwritten // require.Len(t, incomplete, 2) // updating the first object and deleting the second. this will cause a root piece ID change which will result in // a successful graceful exit instead of a request to transfer pieces since the root piece IDs will have changed. // TODO: activate when an object part can be overwritten // _, err = multipart.PutObjectPart(ctx, project, "testbucket", "test/path0", info0.StreamID, 1, bytes.NewReader(testrand.Bytes(5*memory.KiB))) // require.NoError(t, err) err = project.AbortUpload(ctx, "testbucket", "test/path1", info1.UploadID) require.NoError(t, err) // reconnect to the satellite. conn, err := exitingNode.Dialer.DialNodeURL(ctx, satellite.NodeURL()) require.NoError(t, err) defer ctx.Check(conn.Close) client := pb.NewDRPCSatelliteGracefulExitClient(conn) c, err := client.Process(ctx) require.NoError(t, err) defer ctx.Check(c.CloseSend) response, err := c.Recv() require.NoError(t, err) // we expect an exit completed b/c there is nothing to do here switch m := response.GetMessage().(type) { case *pb.SatelliteMessage_ExitCompleted: signee := signing.SigneeFromPeerIdentity(satellite.Identity.PeerIdentity()) err = signing.VerifyExitCompleted(ctx, signee, m.ExitCompleted) require.NoError(t, err) exitStatus, err := satellite.DB.OverlayCache().GetExitStatus(ctx, exitingNode.ID()) require.NoError(t, err) require.NotNil(t, exitStatus.ExitFinishedAt) require.True(t, exitStatus.ExitSuccess) default: require.FailNow(t, "should not reach this case: %#v", m) } queueItems, err := satellite.DB.GracefulExit().GetIncomplete(ctx, exitingNode.ID(), 2, 0) require.NoError(t, err) require.Len(t, queueItems, 0) }) } func TestFailureNotFound(t *testing.T) { testTransfers(t, 1, 0, func(t *testing.T, ctx *testcontext.Context, nodeFullIDs map[storj.NodeID]*identity.FullIdentity, satellite *testplanet.Satellite, processClient exitProcessClient, exitingNode *storagenode.Peer, numPieces int) { response, err := processClient.Recv() require.NoError(t, err) switch m := response.GetMessage().(type) { case *pb.SatelliteMessage_TransferPiece: require.NotNil(t, m) message := &pb.StorageNodeMessage{ Message: &pb.StorageNodeMessage_Failed{ Failed: &pb.TransferFailed{ OriginalPieceId: m.TransferPiece.OriginalPieceId, Error: pb.TransferFailed_NOT_FOUND, }, }, } err = processClient.Send(message) require.NoError(t, err) default: require.FailNow(t, "should not reach this case: %#v", m) } response, err = processClient.Recv() require.NoError(t, err) switch m := response.GetMessage().(type) { case *pb.SatelliteMessage_ExitFailed: require.NotNil(t, m) require.NotNil(t, m.ExitFailed) require.Equal(t, m.ExitFailed.Reason, pb.ExitFailed_OVERALL_FAILURE_PERCENTAGE_EXCEEDED) node, err := satellite.DB.OverlayCache().Get(ctx, m.ExitFailed.NodeId) require.NoError(t, err) require.NotNil(t, node.Disqualified) default: require.FailNow(t, "should not reach this case: %#v", m) } // check that node is no longer in the segment segments, err := satellite.Metabase.DB.TestingAllSegments(ctx) require.NoError(t, err) require.Len(t, segments, 1) for _, piece := range segments[0].Pieces { require.NotEqual(t, piece.StorageNode, exitingNode.ID()) } // check that the exit has completed and we have the correct transferred/failed values progress, err := satellite.DB.GracefulExit().GetProgress(ctx, exitingNode.ID()) require.NoError(t, err) require.Equal(t, int64(0), progress.PiecesTransferred) require.Equal(t, int64(1), progress.PiecesFailed) }) } func TestFailureStorageNodeIgnoresTransferMessages(t *testing.T) { var maxOrderLimitSendCount = 3 testplanet.Run(t, testplanet.Config{ SatelliteCount: 1, StorageNodeCount: 5, UplinkCount: 1, Reconfigure: testplanet.Reconfigure{ Satellite: testplanet.Combine( func(log *zap.Logger, index int, config *satellite.Config) { // We don't care whether a node gracefully exits or not in this test, // so we set the max failures percentage extra high. config.GracefulExit.OverallMaxFailuresPercentage = 101 config.GracefulExit.MaxOrderLimitSendCount = maxOrderLimitSendCount }, testplanet.ReconfigureRS(2, 3, 4, 4), ), }, }, func(t *testing.T, ctx *testcontext.Context, planet *testplanet.Planet) { uplinkPeer := planet.Uplinks[0] satellite := planet.Satellites[0] satellite.GracefulExit.Chore.Loop.Pause() nodeFullIDs := make(map[storj.NodeID]*identity.FullIdentity) for _, node := range planet.StorageNodes { nodeFullIDs[node.ID()] = node.Identity } err := uplinkPeer.Upload(ctx, satellite, "testbucket", "test/path", testrand.Bytes(5*memory.KiB)) require.NoError(t, err) // check that there are no exiting nodes. exitingNodes, err := satellite.DB.OverlayCache().GetExitingNodes(ctx) require.NoError(t, err) require.Len(t, exitingNodes, 0) exitingNode, err := findNodeToExit(ctx, planet, 1) require.NoError(t, err) // connect to satellite so we initiate the exit. conn, err := exitingNode.Dialer.DialNodeURL(ctx, satellite.NodeURL()) require.NoError(t, err) defer ctx.Check(conn.Close) client := pb.NewDRPCSatelliteGracefulExitClient(conn) c, err := client.Process(ctx) require.NoError(t, err) response, err := c.Recv() require.NoError(t, err) // should get a NotReady since the metainfo loop would not be finished at this point. switch m := response.GetMessage().(type) { case *pb.SatelliteMessage_NotReady: // now check that the exiting node is initiated. exitingNodes, err := satellite.DB.OverlayCache().GetExitingNodes(ctx) require.NoError(t, err) require.Len(t, exitingNodes, 1) require.Equal(t, exitingNode.ID(), exitingNodes[0].NodeID) default: require.FailNow(t, "should not reach this case: %#v", m) } // close the old client require.NoError(t, c.CloseSend()) // trigger the metainfo loop chore so we can get some pieces to transfer satellite.GracefulExit.Chore.Loop.TriggerWait() // make sure all the pieces are in the transfer queue _, err = satellite.DB.GracefulExit().GetIncomplete(ctx, exitingNode.ID(), 1, 0) require.NoError(t, err) var messageCount int // We need to label this outer loop so that we're able to exit it from the inner loop. // The outer loop is for sending the request from node to satellite multiple times. // The inner loop is for reading the response. MessageLoop: for { var unknownMsgSent bool c, err := client.Process(ctx) require.NoError(t, err) for { response, err := c.Recv() if unknownMsgSent { require.Error(t, err) break } else { require.NoError(t, err) } switch m := response.GetMessage().(type) { case *pb.SatelliteMessage_ExitCompleted: break MessageLoop case *pb.SatelliteMessage_TransferPiece: messageCount++ unknownMsgSent = true // We send an unknown message because we want to fail the // transfer message request we get from the satellite. // This allows us to keep the conn open but repopulate // the pending queue. err = c.Send(&pb.StorageNodeMessage{}) require.NoError(t, err) require.NoError(t, c.CloseSend()) default: require.FailNow(t, "should not reach this case: %#v", m) } } } require.Equal(t, messageCount, maxOrderLimitSendCount) // make sure not responding piece not in queue incompletes, err := satellite.DB.GracefulExit().GetIncomplete(ctx, exitingNode.ID(), 10, 0) require.NoError(t, err) require.Len(t, incompletes, 0) // check that the exit has completed and we have the correct transferred/failed values progress, err := satellite.DB.GracefulExit().GetProgress(ctx, exitingNode.ID()) require.NoError(t, err) require.EqualValues(t, 1, progress.PiecesFailed) status, err := satellite.DB.OverlayCache().GetExitStatus(ctx, exitingNode.ID()) require.NoError(t, err) require.NotNil(t, status.ExitFinishedAt) }) } func TestIneligibleNodeAge(t *testing.T) { testplanet.Run(t, testplanet.Config{ SatelliteCount: 1, StorageNodeCount: 5, UplinkCount: 1, Reconfigure: testplanet.Reconfigure{ Satellite: testplanet.Combine( func(log *zap.Logger, index int, config *satellite.Config) { // Set the required node age to 1 month. config.GracefulExit.NodeMinAgeInMonths = 1 }, testplanet.ReconfigureRS(2, 3, 4, 4), ), }, }, func(t *testing.T, ctx *testcontext.Context, planet *testplanet.Planet) { uplinkPeer := planet.Uplinks[0] satellite := planet.Satellites[0] satellite.GracefulExit.Chore.Loop.Pause() nodeFullIDs := make(map[storj.NodeID]*identity.FullIdentity) for _, node := range planet.StorageNodes { nodeFullIDs[node.ID()] = node.Identity } err := uplinkPeer.Upload(ctx, satellite, "testbucket", "test/path", testrand.Bytes(5*memory.KiB)) require.NoError(t, err) // check that there are no exiting nodes. exitingNodes, err := satellite.DB.OverlayCache().GetExitingNodes(ctx) require.NoError(t, err) require.Len(t, exitingNodes, 0) exitingNode, err := findNodeToExit(ctx, planet, 1) require.NoError(t, err) // connect to satellite so we initiate the exit. conn, err := exitingNode.Dialer.DialNodeURL(ctx, satellite.NodeURL()) require.NoError(t, err) defer ctx.Check(conn.Close) client := pb.NewDRPCSatelliteGracefulExitClient(conn) c, err := client.Process(ctx) require.NoError(t, err) _, err = c.Recv() // expect the node ineligible error here require.Error(t, err) require.True(t, errs2.IsRPC(err, rpcstatus.FailedPrecondition)) // check that there are still no exiting nodes exitingNodes, err = satellite.DB.OverlayCache().GetExitingNodes(ctx) require.NoError(t, err) require.Len(t, exitingNodes, 0) // close the old client require.NoError(t, c.CloseSend()) }) } func testTransfers(t *testing.T, objects int, multipartObjects int, verifier func(t *testing.T, ctx *testcontext.Context, nodeFullIDs map[storj.NodeID]*identity.FullIdentity, satellite *testplanet.Satellite, processClient exitProcessClient, exitingNode *storagenode.Peer, numPieces int)) { const successThreshold = 4 testplanet.Run(t, testplanet.Config{ SatelliteCount: 1, StorageNodeCount: successThreshold + 1, UplinkCount: 1, Reconfigure: testplanet.Reconfigure{ Satellite: testplanet.ReconfigureRS(2, 3, successThreshold, successThreshold), }, }, func(t *testing.T, ctx *testcontext.Context, planet *testplanet.Planet) { uplinkPeer := planet.Uplinks[0] satellite := planet.Satellites[0] project, err := uplinkPeer.GetProject(ctx, satellite) require.NoError(t, err) defer func() { require.NoError(t, project.Close()) }() _, err = project.EnsureBucket(ctx, "testbucket") require.NoError(t, err) satellite.GracefulExit.Chore.Loop.Pause() nodeFullIDs := make(map[storj.NodeID]*identity.FullIdentity) for _, node := range planet.StorageNodes { nodeFullIDs[node.ID()] = node.Identity } for i := 0; i < objects; i++ { err := uplinkPeer.Upload(ctx, satellite, "testbucket", "test/path"+strconv.Itoa(i), testrand.Bytes(5*memory.KiB)) require.NoError(t, err) } for i := 0; i < multipartObjects; i++ { objectName := "test/multipart" + strconv.Itoa(i) info, err := project.BeginUpload(ctx, "testbucket", objectName, nil) require.NoError(t, err) upload, err := project.UploadPart(ctx, "testbucket", objectName, info.UploadID, 1) require.NoError(t, err) _, err = upload.Write(testrand.Bytes(5 * memory.KiB)) require.NoError(t, err) require.NoError(t, upload.Commit()) } // check that there are no exiting nodes. exitingNodes, err := satellite.DB.OverlayCache().GetExitingNodes(ctx) require.NoError(t, err) require.Len(t, exitingNodes, 0) exitingNode, err := findNodeToExit(ctx, planet, objects) require.NoError(t, err) // connect to satellite so we initiate the exit. conn, err := exitingNode.Dialer.DialNodeURL(ctx, satellite.NodeURL()) require.NoError(t, err) defer ctx.Check(conn.Close) client := pb.NewDRPCSatelliteGracefulExitClient(conn) c, err := client.Process(ctx) require.NoError(t, err) response, err := c.Recv() require.NoError(t, err) // should get a NotReady since the metainfo loop would not be finished at this point. switch m := response.GetMessage().(type) { case *pb.SatelliteMessage_NotReady: // now check that the exiting node is initiated. exitingNodes, err := satellite.DB.OverlayCache().GetExitingNodes(ctx) require.NoError(t, err) require.Len(t, exitingNodes, 1) require.Equal(t, exitingNode.ID(), exitingNodes[0].NodeID) default: require.FailNow(t, "should not reach this case: %#v", m) } // close the old client require.NoError(t, c.CloseSend()) // trigger the metainfo loop chore so we can get some pieces to transfer satellite.GracefulExit.Chore.Loop.TriggerWait() // make sure all the pieces are in the transfer queue incompleteTransfers, err := satellite.DB.GracefulExit().GetIncomplete(ctx, exitingNode.ID(), objects+multipartObjects, 0) require.NoError(t, err) // connect to satellite again to start receiving transfers c, err = client.Process(ctx) require.NoError(t, err) defer ctx.Check(c.CloseSend) verifier(t, ctx, nodeFullIDs, satellite, c, exitingNode.Peer, len(incompleteTransfers)) }) } func findNodeToExit(ctx context.Context, planet *testplanet.Planet, objects int) (*testplanet.StorageNode, error) { satellite := planet.Satellites[0] pieceCountMap := make(map[storj.NodeID]int, len(planet.StorageNodes)) for _, node := range planet.StorageNodes { pieceCountMap[node.ID()] = 0 } segments, err := satellite.Metabase.DB.TestingAllSegments(ctx) if err != nil { return nil, err } for _, segment := range segments { for _, piece := range segment.Pieces { pieceCountMap[piece.StorageNode]++ } } var exitingNodeID storj.NodeID maxCount := 0 for k, v := range pieceCountMap { if exitingNodeID.IsZero() { exitingNodeID = k maxCount = v continue } if v > maxCount { exitingNodeID = k maxCount = v } } return planet.FindNode(exitingNodeID), nil } func TestUpdatePiecesCheckDuplicates(t *testing.T) { testplanet.Run(t, testplanet.Config{ SatelliteCount: 1, StorageNodeCount: 3, UplinkCount: 1, Reconfigure: testplanet.Reconfigure{ Satellite: testplanet.ReconfigureRS(1, 1, 3, 3), }, }, func(t *testing.T, ctx *testcontext.Context, planet *testplanet.Planet) { satellite := planet.Satellites[0] uplinkPeer := planet.Uplinks[0] path := "test/path" err := uplinkPeer.Upload(ctx, satellite, "test1", path, testrand.Bytes(5*memory.KiB)) require.NoError(t, err) segments, err := satellite.Metabase.DB.TestingAllSegments(ctx) require.NoError(t, err) require.Len(t, segments, 1) pieces := segments[0].Pieces require.False(t, hasDuplicates(pieces)) // Remove second piece in the list and replace it with // a piece on the first node. // This way we can ensure that we use a valid piece num. removePiece := metabase.Piece{ Number: pieces[1].Number, StorageNode: pieces[1].StorageNode, } addPiece := metabase.Piece{ Number: pieces[1].Number, StorageNode: pieces[0].StorageNode, } // test no duplicates err = satellite.GracefulExit.Endpoint.UpdatePiecesCheckDuplicates(ctx, segments[0], metabase.Pieces{addPiece}, metabase.Pieces{removePiece}, true) require.True(t, metainfo.ErrNodeAlreadyExists.Has(err)) }) } func hasDuplicates(pieces metabase.Pieces) bool { nodePieceCounts := make(map[storj.NodeID]int) for _, piece := range pieces { nodePieceCounts[piece.StorageNode]++ } for _, count := range nodePieceCounts { if count > 1 { return true } } return false }