/* See https://github.com/ethereum/tests/wiki/Blockchain-Tests-II Whether a block is valid or not is a bit subtle, it's defined by presence of blockHeader, transactions and uncleHeaders fields. If they are missing, the block is invalid and we must verify that we do not accept it. Since some tests mix valid and invalid blocks we need to check this for every block. If a block is invalid it does not necessarily fail the test, if it's invalidness is expected we are expected to ignore it and continue processing and then validate the post state. */ func (t *BlockTest) TryBlocksInsert(chainManager *core.ChainManager) error { // insert the test blocks, which will execute all transactions for _, b := range t.Json.Blocks { cb, err := mustConvertBlock(b) if err != nil { if b.BlockHeader == nil { continue // OK - block is supposed to be invalid, continue with next block } else { return fmt.Errorf("Block RLP decoding failed when expected to succeed: %v", err) } } // RLP decoding worked, try to insert into chain: _, err = chainManager.InsertChain(types.Blocks{cb}) if err != nil { if b.BlockHeader == nil { continue // OK - block is supposed to be invalid, continue with next block } else { return fmt.Errorf("Block insertion into chain failed: %v", err) } } if b.BlockHeader == nil { return fmt.Errorf("Block insertion should have failed") } err = t.validateBlockHeader(b.BlockHeader, cb.Header()) if err != nil { return fmt.Errorf("Block header validation failed: %v", err) } } return nil }
/* See https://github.com/ethereum/tests/wiki/Blockchain-Tests-II Whether a block is valid or not is a bit subtle, it's defined by presence of blockHeader, transactions and uncleHeaders fields. If they are missing, the block is invalid and we must verify that we do not accept it. Since some tests mix valid and invalid blocks we need to check this for every block. If a block is invalid it does not necessarily fail the test, if it's invalidness is expected we are expected to ignore it and continue processing and then validate the post state. */ func (t *BlockTest) TryBlocksInsert(chainManager *core.ChainManager) ([]btBlock, error) { validBlocks := make([]btBlock, 0) // insert the test blocks, which will execute all transactions for _, b := range t.Json.Blocks { cb, err := mustConvertBlock(b) if err != nil { if b.BlockHeader == nil { continue // OK - block is supposed to be invalid, continue with next block } else { return nil, fmt.Errorf("Block RLP decoding failed when expected to succeed: %v", err) } } // RLP decoding worked, try to insert into chain: _, err = chainManager.InsertChain(types.Blocks{cb}) if err != nil { if b.BlockHeader == nil { continue // OK - block is supposed to be invalid, continue with next block } else { return nil, fmt.Errorf("Block insertion into chain failed: %v", err) } } if b.BlockHeader == nil { return nil, fmt.Errorf("Block insertion should have failed") } // validate RLP decoding by checking all values against test file JSON if err = validateHeader(b.BlockHeader, cb.Header()); err != nil { return nil, fmt.Errorf("Deserialised block header validation failed: %v", err) } validBlocks = append(validBlocks, b) } return validBlocks, nil }
func ImportChain(chainmgr *core.ChainManager, fn string) error { fmt.Printf("importing blockchain '%s'\n", fn) fh, err := os.OpenFile(fn, os.O_RDONLY, os.ModePerm) if err != nil { return err } defer fh.Close() chainmgr.Reset() stream := rlp.NewStream(fh, 0) var i, n int batchSize := 2500 blocks := make(types.Blocks, batchSize) for ; ; i++ { var b types.Block if err := stream.Decode(&b); err == io.EOF { break } else if err != nil { return fmt.Errorf("at block %d: %v", i, err) } blocks[n] = &b n++ if n == batchSize { if _, err := chainmgr.InsertChain(blocks); err != nil { return fmt.Errorf("invalid block %v", err) } n = 0 blocks = make(types.Blocks, batchSize) } } if n > 0 { if _, err := chainmgr.InsertChain(blocks[:n]); err != nil { return fmt.Errorf("invalid block %v", err) } } fmt.Printf("imported %d blocks\n", i) return nil }
func ImportChain(chain *core.ChainManager, fn string) error { // Watch for Ctrl-C while the import is running. // If a signal is received, the import will stop at the next batch. interrupt := make(chan os.Signal, 1) stop := make(chan struct{}) signal.Notify(interrupt, os.Interrupt) defer signal.Stop(interrupt) defer close(interrupt) go func() { if _, ok := <-interrupt; ok { glog.Info("caught interrupt during import, will stop at next batch") } close(stop) }() checkInterrupt := func() bool { select { case <-stop: return true default: return false } } glog.Infoln("Importing blockchain", fn) fh, err := os.Open(fn) if err != nil { return err } defer fh.Close() stream := rlp.NewStream(fh, 0) // Run actual the import. blocks := make(types.Blocks, importBatchSize) n := 0 for batch := 0; ; batch++ { // Load a batch of RLP blocks. if checkInterrupt() { return fmt.Errorf("interrupted") } i := 0 for ; i < importBatchSize; i++ { var b types.Block if err := stream.Decode(&b); err == io.EOF { break } else if err != nil { return fmt.Errorf("at block %d: %v", n, err) } blocks[i] = &b n++ } if i == 0 { break } // Import the batch. if checkInterrupt() { return fmt.Errorf("interrupted") } if hasAllBlocks(chain, blocks[:i]) { glog.Infof("skipping batch %d, all blocks present [%x / %x]", batch, blocks[0].Hash().Bytes()[:4], blocks[i-1].Hash().Bytes()[:4]) continue } if _, err := chain.InsertChain(blocks[:i]); err != nil { return fmt.Errorf("invalid block %d: %v", n, err) } } return nil }