// VulcanizeDB // Copyright © 2019 Vulcanize // This program is free software: you can redistribute it and/or modify // it under the terms of the GNU Affero General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // This program 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 Affero General Public License for more details. // You should have received a copy of the GNU Affero General Public License // along with this program. If not, see . package super_node import ( "errors" "sync" "sync/atomic" "time" log "github.com/sirupsen/logrus" "github.com/vulcanize/vulcanizedb/libraries/shared/storage/utils" "github.com/vulcanize/vulcanizedb/pkg/super_node/config" "github.com/vulcanize/vulcanizedb/pkg/super_node/shared" ) const ( DefaultMaxBatchSize uint64 = 100 defaultMaxBatchNumber int64 = 10 ) // BackFillInterface for filling in gaps in the super node type BackFillInterface interface { // Method for the super node to periodically check for and fill in gaps in its data using an archival node FillGaps(wg *sync.WaitGroup, quitChan <-chan bool) } // BackFillService for filling in gaps in the super node type BackFillService struct { // Interface for converting payloads into IPLD object payloads Converter shared.PayloadConverter // Interface for publishing the IPLD payloads to IPFS Publisher shared.IPLDPublisher // Interface for indexing the CIDs of the published IPLDs in Postgres Indexer shared.CIDIndexer // Interface for searching and retrieving CIDs from Postgres index Retriever shared.CIDRetriever // Interface for fetching payloads over at historical blocks; over http Fetcher shared.PayloadFetcher // Check frequency GapCheckFrequency time.Duration // Size of batch fetches BatchSize uint64 } // NewBackFillService returns a new BackFillInterface func NewBackFillService(settings *config.SuperNode) (BackFillInterface, error) { publisher, err := NewIPLDPublisher(settings.Chain, settings.IPFSPath) if err != nil { return nil, err } indexer, err := NewCIDIndexer(settings.Chain, settings.DB) if err != nil { return nil, err } converter, err := NewPayloadConverter(settings.Chain) if err != nil { return nil, err } retriever, err := NewCIDRetriever(settings.Chain, settings.DB) if err != nil { return nil, err } fetcher, err := NewPaylaodFetcher(settings.Chain, settings.HTTPClient) if err != nil { return nil, err } batchSize := settings.BatchSize if batchSize == 0 { batchSize = DefaultMaxBatchSize } return &BackFillService{ Indexer: indexer, Converter: converter, Publisher: publisher, Retriever: retriever, Fetcher: fetcher, GapCheckFrequency: settings.Frequency, BatchSize: batchSize, }, nil } // FillGaps periodically checks for and fills in gaps in the super node db // this requires a core.RpcClient that is pointed at an archival node with the StateDiffAt method exposed func (bfs *BackFillService) FillGaps(wg *sync.WaitGroup, quitChan <-chan bool) { ticker := time.NewTicker(bfs.GapCheckFrequency) wg.Add(1) go func() { for { select { case <-quitChan: log.Info("quiting FillGaps process") wg.Done() return case <-ticker.C: log.Info("searching for gaps in the super node database") startingBlock, err := bfs.Retriever.RetrieveFirstBlockNumber() if err != nil { log.Error(err) continue } if startingBlock != 1 { log.Info("found gap at the beginning of the sync") bfs.fillGaps(1, uint64(startingBlock-1)) } gaps, err := bfs.Retriever.RetrieveGapsInData() if err != nil { log.Error(err) continue } for _, gap := range gaps { if err := bfs.fillGaps(gap.Start, gap.Stop); err != nil { log.Error(err) } } } } }() log.Info("fillGaps goroutine successfully spun up") } func (bfs *BackFillService) fillGaps(startingBlock, endingBlock uint64) error { log.Infof("going to fill in gap from %d to %d", startingBlock, endingBlock) errChan := make(chan error) done := make(chan bool) err := bfs.backFill(startingBlock, endingBlock, errChan, done) if err != nil { return err } for { select { case err := <-errChan: log.Error(err) case <-done: log.Infof("finished filling in gap from %d to %d", startingBlock, endingBlock) return nil } } } // backFill fetches, processes, and returns utils.StorageDiffs over a range of blocks // It splits a large range up into smaller chunks, batch fetching and processing those chunks concurrently func (bfs *BackFillService) backFill(startingBlock, endingBlock uint64, errChan chan error, done chan bool) error { if endingBlock < startingBlock { return errors.New("backfill: ending block number needs to be greater than starting block number") } // // break the range up into bins of smaller ranges blockRangeBins, err := utils.GetBlockHeightBins(startingBlock, endingBlock, bfs.BatchSize) if err != nil { return err } // int64 for atomic incrementing and decrementing to track the number of active processing goroutines we have var activeCount int64 // channel for processing goroutines to signal when they are done processingDone := make(chan [2]uint64) forwardDone := make(chan bool) // for each block range bin spin up a goroutine to batch fetch and process state diffs for that range go func() { for _, blockHeights := range blockRangeBins { // if we have reached our limit of active goroutines // wait for one to finish before starting the next if atomic.AddInt64(&activeCount, 1) > defaultMaxBatchNumber { // this blocks until a process signals it has finished <-forwardDone } go func(blockHeights []uint64) { payloads, err := bfs.Fetcher.FetchAt(blockHeights) if err != nil { errChan <- err } for _, payload := range payloads { ipldPayload, err := bfs.Converter.Convert(payload) if err != nil { errChan <- err continue } // make backfiller a part of super_node service and forward these // ipldPayload the the regular publishAndIndex and screenAndServe channels // this would allow us to stream backfilled data to subscribers cidPayload, err := bfs.Publisher.Publish(ipldPayload) if err != nil { errChan <- err continue } if err := bfs.Indexer.Index(cidPayload); err != nil { errChan <- err } } // when this goroutine is done, send out a signal processingDone <- [2]uint64{blockHeights[0], blockHeights[len(blockHeights)-1]} }(blockHeights) } }() // goroutine that listens on the processingDone chan // keeps track of the number of processing goroutines that have finished // when they have all finished, sends the final signal out go func() { goroutinesFinished := 0 for { select { case doneWithHeights := <-processingDone: atomic.AddInt64(&activeCount, -1) select { // if we are waiting for a process to finish, signal that one has case forwardDone <- true: default: } log.Infof("finished filling in gap sub-bin from %d to %d", doneWithHeights[0], doneWithHeights[1]) goroutinesFinished++ if goroutinesFinished >= len(blockRangeBins) { done <- true return } } } }() return nil }