package types import ( "bytes" "errors" "fmt" amino "github.com/tendermint/go-amino" abci "github.com/tendermint/tendermint/abci/types" "github.com/tendermint/tendermint/crypto/merkle" "github.com/tendermint/tendermint/crypto/tmhash" cmn "github.com/tendermint/tendermint/libs/common" ) // Tx is an arbitrary byte array. // NOTE: Tx has no types at this level, so when wire encoded it's just length-prefixed. // Might we want types here ? type Tx []byte // Hash computes the TMHASH hash of the wire encoded transaction. func (tx Tx) Hash() []byte { return tmhash.Sum(tx) } // String returns the hex-encoded transaction as a string. func (tx Tx) String() string { return fmt.Sprintf("Tx{%X}", []byte(tx)) } // Txs is a slice of Tx. type Txs []Tx // Hash returns the Merkle root hash of the transaction hashes. // i.e. the leaves of the tree are the hashes of the txs. func (txs Txs) Hash() []byte { // These allocations will be removed once Txs is switched to [][]byte, // ref #2603. This is because golang does not allow type casting slices without unsafe txBzs := make([][]byte, len(txs)) for i := 0; i < len(txs); i++ { txBzs[i] = txs[i].Hash() } return merkle.SimpleHashFromByteSlices(txBzs) } // Index returns the index of this transaction in the list, or -1 if not found func (txs Txs) Index(tx Tx) int { for i := range txs { if bytes.Equal(txs[i], tx) { return i } } return -1 } // IndexByHash returns the index of this transaction hash in the list, or -1 if not found func (txs Txs) IndexByHash(hash []byte) int { for i := range txs { if bytes.Equal(txs[i].Hash(), hash) { return i } } return -1 } // Proof returns a simple merkle proof for this node. // Panics if i < 0 or i >= len(txs) // TODO: optimize this! func (txs Txs) Proof(i int) TxProof { l := len(txs) bzs := make([][]byte, l) for i := 0; i < l; i++ { bzs[i] = txs[i].Hash() } root, proofs := merkle.SimpleProofsFromByteSlices(bzs) return TxProof{ RootHash: root, Data: txs[i], Proof: *proofs[i], } } // TxProof represents a Merkle proof of the presence of a transaction in the Merkle tree. type TxProof struct { RootHash cmn.HexBytes Data Tx Proof merkle.SimpleProof } // Leaf returns the hash(tx), which is the leaf in the merkle tree which this proof refers to. func (tp TxProof) Leaf() []byte { return tp.Data.Hash() } // Validate verifies the proof. It returns nil if the RootHash matches the dataHash argument, // and if the proof is internally consistent. Otherwise, it returns a sensible error. func (tp TxProof) Validate(dataHash []byte) error { if !bytes.Equal(dataHash, tp.RootHash) { return errors.New("Proof matches different data hash") } if tp.Proof.Index < 0 { return errors.New("Proof index cannot be negative") } if tp.Proof.Total <= 0 { return errors.New("Proof total must be positive") } valid := tp.Proof.Verify(tp.RootHash, tp.Leaf()) if valid != nil { return errors.New("Proof is not internally consistent") } return nil } // TxResult contains results of executing the transaction. // // One usage is indexing transaction results. type TxResult struct { Height int64 `json:"height"` Index uint32 `json:"index"` Tx Tx `json:"tx"` Result abci.ResponseDeliverTx `json:"result"` } // ComputeAminoOverhead calculates the overhead for amino encoding a transaction. // The overhead consists of varint encoding the field number and the wire type // (= length-delimited = 2), and another varint encoding the length of the // transaction. // The field number can be the field number of the particular transaction, or // the field number of the parenting struct that contains the transactions []Tx // as a field (this field number is repeated for each contained Tx). // If some []Tx are encoded directly (without a parenting struct), the default // fieldNum is also 1 (see BinFieldNum in amino.MarshalBinaryBare). func ComputeAminoOverhead(tx Tx, fieldNum int) int64 { fnum := uint64(fieldNum) typ3AndFieldNum := (uint64(fnum) << 3) | uint64(amino.Typ3_ByteLength) return int64(amino.UvarintSize(typ3AndFieldNum)) + int64(amino.UvarintSize(uint64(len(tx)))) }