package types import ( "crypto/ecdsa" "fmt" "math/big" "sync/atomic" sdk "github.com/cosmos/cosmos-sdk/types" "github.com/cosmos/cosmos-sdk/wire" ethcmn "github.com/ethereum/go-ethereum/common" ethtypes "github.com/ethereum/go-ethereum/core/types" ethcrypto "github.com/ethereum/go-ethereum/crypto" ethsha "github.com/ethereum/go-ethereum/crypto/sha3" "github.com/ethereum/go-ethereum/rlp" "github.com/pkg/errors" ) var _ sdk.Tx = (*Transaction)(nil) const ( // TypeTxEthereum reflects an Ethereum Transaction type. TypeTxEthereum = "Ethereum" ) type ( // Transaction implements the Ethereum transaction structure as an exact // replica. It implements the Cosmos sdk.Tx interface. Due to the private // fields, it must be replicated here and cannot be embedded or used // directly. // // Note: The transaction also implements the sdk.Msg interface to perform // basic validation that is done in the BaseApp. Transaction struct { Data TxData // caches hash atomic.Value size atomic.Value from atomic.Value } // TxData defines internal Ethereum transaction information TxData struct { AccountNonce uint64 `json:"nonce"` Price sdk.Int `json:"gasPrice"` GasLimit uint64 `json:"gas"` Recipient *ethcmn.Address `json:"to"` // nil means contract creation Amount sdk.Int `json:"value"` Payload []byte `json:"input"` Signature *EthSignature `json:"signature"` // hash is only used when marshaling to JSON Hash *ethcmn.Hash `json:"hash"` } // EthSignature reflects an Ethereum signature. We wrap this in a structure // to support Amino serialization of transactions. EthSignature struct { v, r, s *big.Int } ) // NewEthSignature returns a new instantiated Ethereum signature. func NewEthSignature(v, r, s *big.Int) *EthSignature { return &EthSignature{v, r, s} } func (es *EthSignature) sanitize() { if es.v == nil { es.v = new(big.Int) } if es.r == nil { es.r = new(big.Int) } if es.s == nil { es.s = new(big.Int) } } // MarshalAmino defines a custom encoding scheme for a EthSignature. func (es EthSignature) MarshalAmino() ([3]string, error) { es.sanitize() return ethSigMarshalAmino(es) } // UnmarshalAmino defines a custom decoding scheme for a EthSignature. func (es *EthSignature) UnmarshalAmino(raw [3]string) error { es.sanitize() return ethSigUnmarshalAmino(es, raw) } // NewTransaction mimics ethereum's NewTransaction function. It returns a // reference to a new Ethereum Transaction. func NewTransaction( nonce uint64, to ethcmn.Address, amount sdk.Int, gasLimit uint64, gasPrice sdk.Int, payload []byte, ) Transaction { if len(payload) > 0 { payload = ethcmn.CopyBytes(payload) } txData := TxData{ Recipient: &to, AccountNonce: nonce, Payload: payload, GasLimit: gasLimit, Amount: amount, Price: gasPrice, Signature: NewEthSignature(new(big.Int), new(big.Int), new(big.Int)), } return Transaction{Data: txData} } // Sign calculates a secp256k1 ECDSA signature and signs the transaction. It // takes a private key and chainID to sign an Ethereum transaction according to // EIP155 standard. It mutates the transaction as it populates the V, R, S // fields of the Transaction's Signature. func (tx *Transaction) Sign(chainID sdk.Int, priv *ecdsa.PrivateKey) { h := rlpHash([]interface{}{ tx.Data.AccountNonce, tx.Data.Price.BigInt(), tx.Data.GasLimit, tx.Data.Recipient, tx.Data.Amount.BigInt(), tx.Data.Payload, chainID.BigInt(), uint(0), uint(0), }) sig, err := ethcrypto.Sign(h[:], priv) if err != nil { panic(err) } if len(sig) != 65 { panic(fmt.Sprintf("wrong size for signature: got %d, want 65", len(sig))) } r := new(big.Int).SetBytes(sig[:32]) s := new(big.Int).SetBytes(sig[32:64]) var v *big.Int if chainID.Sign() == 0 { v = new(big.Int).SetBytes([]byte{sig[64] + 27}) } else { v = big.NewInt(int64(sig[64] + 35)) chainIDMul := new(big.Int).Mul(chainID.BigInt(), big.NewInt(2)) v.Add(v, chainIDMul) } tx.Data.Signature.v = v tx.Data.Signature.r = r tx.Data.Signature.s = s } // Type implements the sdk.Msg interface. It returns the type of the // Transaction. func (tx Transaction) Type() string { return TypeTxEthereum } // ValidateBasic implements the sdk.Msg interface. It performs basic validation // checks of a Transaction. If returns an sdk.Error if validation fails. func (tx Transaction) ValidateBasic() sdk.Error { if tx.Data.Price.Sign() != 1 { return ErrInvalidValue(DefaultCodespace, "price must be positive") } if tx.Data.Amount.Sign() != 1 { return ErrInvalidValue(DefaultCodespace, "amount must be positive") } return nil } // GetSignBytes performs a no-op and should not be used. It implements the // sdk.Msg Interface func (tx Transaction) GetSignBytes() (sigBytes []byte) { return } // GetSigners performs a no-op and should not be used. It implements the // sdk.Msg Interface // // CONTRACT: The transaction must already be signed. func (tx Transaction) GetSigners() (signers []sdk.AccAddress) { return } // GetMsgs returns a single message containing the Transaction itself. It // implements the Cosmos sdk.Tx interface. func (tx Transaction) GetMsgs() []sdk.Msg { return []sdk.Msg{tx} } // ConvertTx attempts to converts a Transaction to a new Ethereum transaction // with the signature set. The signature if first recovered and then a new // Transaction is created with that signature. If setting the signature fails, // a panic will be triggered. // // TODO: To be removed in #470 func (tx Transaction) ConvertTx(chainID *big.Int) ethtypes.Transaction { gethTx := ethtypes.NewTransaction( tx.Data.AccountNonce, *tx.Data.Recipient, tx.Data.Amount.BigInt(), tx.Data.GasLimit, tx.Data.Price.BigInt(), tx.Data.Payload, ) sig := recoverEthSig(tx.Data.Signature, chainID) signer := ethtypes.NewEIP155Signer(chainID) gethTx, err := gethTx.WithSignature(signer, sig) if err != nil { panic(errors.Wrap(err, "failed to convert transaction with a given signature")) } return *gethTx } // TxDecoder returns an sdk.TxDecoder that given raw transaction bytes, // attempts to decode them into a valid sdk.Tx. func TxDecoder(codec *wire.Codec) sdk.TxDecoder { return func(txBytes []byte) (sdk.Tx, sdk.Error) { if len(txBytes) == 0 { return nil, sdk.ErrTxDecode("txBytes are empty") } var tx sdk.Tx // The given codec should have all the appropriate message types // registered. err := codec.UnmarshalBinary(txBytes, &tx) if err != nil { return nil, sdk.ErrTxDecode("failed to decode tx").TraceSDK(err.Error()) } return tx, nil } } // recoverEthSig recovers a signature according to the Ethereum specification. func recoverEthSig(es *EthSignature, chainID *big.Int) []byte { var v byte r, s := es.r.Bytes(), es.s.Bytes() sig := make([]byte, 65) copy(sig[32-len(r):32], r) copy(sig[64-len(s):64], s) if chainID.Sign() == 0 { v = byte(es.v.Uint64() - 27) } else { chainIDMul := new(big.Int).Mul(chainID, big.NewInt(2)) V := new(big.Int).Sub(es.v, chainIDMul) v = byte(V.Uint64() - 35) } sig[64] = v return sig } func rlpHash(x interface{}) (h ethcmn.Hash) { hasher := ethsha.NewKeccak256() rlp.Encode(hasher, x) hasher.Sum(h[:0]) return h } func ethSigMarshalAmino(es EthSignature) (raw [3]string, err error) { vb, err := es.v.MarshalText() if err != nil { return raw, err } rb, err := es.r.MarshalText() if err != nil { return raw, err } sb, err := es.s.MarshalText() if err != nil { return raw, err } raw[0], raw[1], raw[2] = string(vb), string(rb), string(sb) return raw, err } func ethSigUnmarshalAmino(es *EthSignature, raw [3]string) (err error) { if err = es.v.UnmarshalText([]byte(raw[0])); err != nil { return } if err = es.r.UnmarshalText([]byte(raw[1])); err != nil { return } if err = es.s.UnmarshalText([]byte(raw[2])); err != nil { return } return }