package node import ( "encoding/binary" "errors" "github.com/ethereum/go-ethereum/common" "github.com/ethereum/go-ethereum/rlp" "github.com/harmony-one/bls/ffi/go/bls" "github.com/harmony-one/harmony/block" "github.com/harmony-one/harmony/core" "github.com/harmony-one/harmony/core/types" bls_cosi "github.com/harmony-one/harmony/crypto/bls" "github.com/harmony-one/harmony/internal/ctxerror" "github.com/harmony-one/harmony/internal/utils" ) // ProcessHeaderMessage verify and process Node/Header message into crosslink when it's valid func (node *Node) ProcessHeaderMessage(msgPayload []byte) { if node.NodeConfig.ShardID == 0 { var headers []*block.Header err := rlp.DecodeBytes(msgPayload, &headers) if err != nil { utils.Logger().Error(). Err(err). Msg("[ProcessingHeader] Crosslink Headers Broadcast Unable to Decode") return } // Try to reprocess all the pending cross links node.pendingClMutex.Lock() crossLinkHeadersToProcess := node.pendingCrossLinks node.pendingCrossLinks = []*block.Header{} node.pendingClMutex.Unlock() firstCrossLinkBlock := core.EpochFirstBlock(node.Blockchain().Config().CrossLinkEpoch) for _, header := range headers { if header.Number().Cmp(firstCrossLinkBlock) >= 0 { // Only process cross link starting from FirstCrossLinkBlock utils.Logger().Debug().Msgf("[ProcessHeaderMessage] Add Pending CrossLink, shardID %d, blockNum %d", header.ShardID(), header.Number()) crossLinkHeadersToProcess = append(crossLinkHeadersToProcess, header) } } utils.Logger().Debug(). Msgf("[ProcessingHeader] number of crosslink headers to propose %d, firstCrossLinkBlock %d", len(crossLinkHeadersToProcess), firstCrossLinkBlock) headersToQuque := []*block.Header{} for _, header := range crossLinkHeadersToProcess { if len(headersToQuque) > crossLinkBatchSize { break } exist, err := node.Blockchain().ReadCrossLink(header.ShardID(), header.Number().Uint64(), false) if err == nil && exist != nil { utils.Logger().Debug(). Msgf("[ProcessingHeader] Cross Link already exists, pass. Block num: %d, shardID %d", header.Number(), header.ShardID()) continue } if header.Number().Cmp(firstCrossLinkBlock) > 0 { // Directly trust the first cross-link // Sanity check on the previous link with the new link previousLink, err := node.Blockchain().ReadCrossLink(header.ShardID(), header.Number().Uint64()-1, false) if err != nil { previousLink, err = node.Blockchain().ReadCrossLink(header.ShardID(), header.Number().Uint64()-1, true) if err != nil { headersToQuque = append(headersToQuque, header) utils.Logger().Error().Err(err). Msgf("[ProcessingHeader] ReadCrossLink cannot read previousLink with number %d, shardID %d", header.Number().Uint64()-1, header.ShardID()) continue } } err = node.VerifyCrosslinkHeader(previousLink.Header(), header) if err != nil { utils.Logger().Error(). Err(err). Msgf("[ProcessingHeader] Failed to verify new cross link header for shardID %d, blockNum %d", header.ShardID(), header.Number()) continue } } crossLink := types.NewCrossLink(header) utils.Logger().Debug(). Msgf("[ProcessingHeader] committing for shardID %d, blockNum %d", header.ShardID(), header.Number().Uint64()) node.Blockchain().WriteCrossLinks(types.CrossLinks{crossLink}, true) } // Queue up the cross links that's in the future node.pendingClMutex.Lock() node.pendingCrossLinks = append(node.pendingCrossLinks, headersToQuque...) node.pendingClMutex.Unlock() } } func (node *Node) verifyIncomingReceipts(block *types.Block) error { m := make(map[common.Hash]bool) cxps := block.IncomingReceipts() for _, cxp := range cxps { if err := cxp.IsValidCXReceiptsProof(); err != nil { return ctxerror.New("[verifyIncomingReceipts] verification failed").WithCause(err) } if node.Blockchain().IsSpent(cxp) { return ctxerror.New("[verifyIncomingReceipts] Double Spent!") } hash := cxp.MerkleProof.BlockHash // ignore duplicated receipts if _, ok := m[hash]; ok { return ctxerror.New("[verifyIncomingReceipts] Double Spent!") } m[hash] = true if err := node.compareCrosslinkWithReceipts(cxp); err != nil { return err } } incomingReceiptHash := types.EmptyRootHash if len(cxps) > 0 { incomingReceiptHash = types.DeriveSha(cxps) } if incomingReceiptHash != block.Header().IncomingReceiptHash() { return ctxerror.New("[verifyIncomingReceipts] Invalid IncomingReceiptHash in block header") } return nil } func (node *Node) compareCrosslinkWithReceipts(cxp *types.CXReceiptsProof) error { var hash, outgoingReceiptHash common.Hash shardID := cxp.MerkleProof.ShardID blockNum := cxp.MerkleProof.BlockNum.Uint64() beaconChain := node.Beaconchain() if shardID == 0 { block := beaconChain.GetBlockByNumber(blockNum) if block == nil { return ctxerror.New("[compareCrosslinkWithReceipts] Cannot get beaconchain header", "blockNum", blockNum, "shardID", shardID) } hash = block.Hash() outgoingReceiptHash = block.OutgoingReceiptHash() } else { crossLink, err := beaconChain.ReadCrossLink(shardID, blockNum, false) if err != nil { return ctxerror.New("[compareCrosslinkWithReceipts] Cannot get crosslink", "blockNum", blockNum, "shardID", shardID).WithCause(err) } hash = crossLink.ChainHeader.Hash() outgoingReceiptHash = crossLink.ChainHeader.OutgoingReceiptHash() } // verify the source block hash is from a finalized block if hash == cxp.MerkleProof.BlockHash && outgoingReceiptHash == cxp.MerkleProof.CXReceiptHash { return nil } return ErrCrosslinkVerificationFail } // VerifyCrosslinkHeader verifies the header is valid against the prevHeader. func (node *Node) VerifyCrosslinkHeader(prevHeader, header *block.Header) error { // TODO: add fork choice rule parentHash := header.ParentHash() if prevHeader.Hash() != parentHash { return ctxerror.New("[CrossLink] Invalid cross link header - parent hash mismatch", "shardID", header.ShardID(), "blockNum", header.Number()) } // Verify signature of the new cross link header shardState, err := node.Blockchain().ReadShardState(prevHeader.Epoch()) committee := shardState.FindCommitteeByID(prevHeader.ShardID()) if err != nil || committee == nil { return ctxerror.New("[CrossLink] Failed to read shard state for cross link header", "shardID", header.ShardID(), "blockNum", header.Number()).WithCause(err) } var committerKeys []*bls.PublicKey parseKeysSuccess := true for _, member := range committee.NodeList { committerKey := new(bls.PublicKey) err = member.BlsPublicKey.ToLibBLSPublicKey(committerKey) if err != nil { parseKeysSuccess = false break } committerKeys = append(committerKeys, committerKey) } if !parseKeysSuccess { return ctxerror.New("[CrossLink] cannot convert BLS public key", "shardID", header.ShardID(), "blockNum", header.Number()).WithCause(err) } if header.Number().Uint64() > 1 { // First block doesn't have last sig mask, err := bls_cosi.NewMask(committerKeys, nil) if err != nil { return ctxerror.New("cannot create group sig mask", "shardID", header.ShardID(), "blockNum", header.Number()).WithCause(err) } if err := mask.SetMask(header.LastCommitBitmap()); err != nil { return ctxerror.New("cannot set group sig mask bits", "shardID", header.ShardID(), "blockNum", header.Number()).WithCause(err) } aggSig := bls.Sign{} sig := header.LastCommitSignature() err = aggSig.Deserialize(sig[:]) if err != nil { return ctxerror.New("unable to deserialize multi-signature from payload").WithCause(err) } blockNumBytes := make([]byte, 8) binary.LittleEndian.PutUint64(blockNumBytes, header.Number().Uint64()-1) commitPayload := append(blockNumBytes, parentHash[:]...) if !aggSig.VerifyHash(mask.AggregatePublic, commitPayload) { return ctxerror.New("Failed to verify the signature for cross link header ", "shardID", header.ShardID(), "blockNum", header.Number()) } } return nil } // ProposeCrossLinkDataForBeaconchain propose cross links for beacon chain new block func (node *Node) ProposeCrossLinkDataForBeaconchain() (types.CrossLinks, error) { utils.Logger().Info(). Uint64("blockNum", node.Blockchain().CurrentBlock().NumberU64()+1). Msg("Proposing cross links ...") curBlock := node.Blockchain().CurrentBlock() numShards := core.ShardingSchedule.InstanceForEpoch(curBlock.Header().Epoch()).NumShards() shardCrossLinks := make([]types.CrossLinks, numShards) firstCrossLinkBlock := core.EpochFirstBlock(node.Blockchain().Config().CrossLinkEpoch) for i := 0; i < int(numShards); i++ { curShardID := uint32(i) lastLink, err := node.Blockchain().ReadShardLastCrossLink(curShardID) lastLinkblockNum := firstCrossLinkBlock blockNumoffset := 0 if err == nil && lastLink != nil { blockNumoffset = 1 lastLinkblockNum = lastLink.BlockNum() } for true { link, err := node.Blockchain().ReadCrossLink(curShardID, lastLinkblockNum.Uint64()+uint64(blockNumoffset), true) if err != nil || link == nil { break } if link.BlockNum().Cmp(firstCrossLinkBlock) > 0 { if lastLink == nil { utils.Logger().Error(). Err(err). Msgf("[CrossLink] Haven't received the first cross link %d", link.BlockNum().Uint64()) break } else { err := node.VerifyCrosslinkHeader(lastLink.Header(), link.Header()) if err != nil { utils.Logger().Error(). Err(err). Msgf("[CrossLink] Failed verifying temp cross link %d", link.BlockNum().Uint64()) break } } } shardCrossLinks[i] = append(shardCrossLinks[i], *link) lastLink = link blockNumoffset++ } } crossLinksToPropose := types.CrossLinks{} for _, crossLinks := range shardCrossLinks { crossLinksToPropose = append(crossLinksToPropose, crossLinks...) } if len(crossLinksToPropose) != 0 { crossLinksToPropose.Sort() return crossLinksToPropose, nil } return types.CrossLinks{}, errors.New("No cross link to propose") } // ProcessReceiptMessage store the receipts and merkle proof in local data store func (node *Node) ProcessReceiptMessage(msgPayload []byte) { cxp := types.CXReceiptsProof{} if err := rlp.DecodeBytes(msgPayload, &cxp); err != nil { utils.Logger().Error().Err(err).Msg("[ProcessReceiptMessage] Unable to Decode message Payload") return } if err := cxp.IsValidCXReceiptsProof(); err != nil { utils.Logger().Error().Err(err).Msg("[ProcessReceiptMessage] Invalid CXReceiptsProof") return } utils.Logger().Debug().Interface("cxp", cxp).Msg("[ProcessReceiptMessage] Add CXReceiptsProof to pending Receipts") // TODO: integrate with txpool node.AddPendingReceipts(&cxp) }