laconicd-deprecated/app/ante/eth.go

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package ante
import (
"fmt"
"math/big"
sdk "github.com/cosmos/cosmos-sdk/types"
sdkerrors "github.com/cosmos/cosmos-sdk/types/errors"
"github.com/cosmos/cosmos-sdk/x/auth"
authante "github.com/cosmos/cosmos-sdk/x/auth/ante"
"github.com/cosmos/cosmos-sdk/x/auth/types"
emint "github.com/cosmos/ethermint/types"
evmtypes "github.com/cosmos/ethermint/x/evm/types"
ethcore "github.com/ethereum/go-ethereum/core"
)
// EthSetupContextDecorator sets the infinite GasMeter in the Context and wraps
// the next AnteHandler with a defer clause to recover from any downstream
// OutOfGas panics in the AnteHandler chain to return an error with information
// on gas provided and gas used.
// CONTRACT: Must be first decorator in the chain
// CONTRACT: Tx must implement GasTx interface
type EthSetupContextDecorator struct{}
// NewEthSetupContextDecorator creates a new EthSetupContextDecorator
func NewEthSetupContextDecorator() EthSetupContextDecorator {
return EthSetupContextDecorator{}
}
// AnteHandle sets the infinite gas meter to done to ignore costs in AnteHandler checks.
// This is undone at the EthGasConsumeDecorator, where the context is set with the
// ethereum tx GasLimit.
func (escd EthSetupContextDecorator) AnteHandle(ctx sdk.Context, tx sdk.Tx, simulate bool, next sdk.AnteHandler) (newCtx sdk.Context, err error) {
ctx = ctx.WithBlockGasMeter(sdk.NewInfiniteGasMeter())
// all transactions must implement GasTx
gasTx, ok := tx.(authante.GasTx)
if !ok {
return ctx, sdkerrors.Wrap(sdkerrors.ErrTxDecode, "Tx must be GasTx")
}
// Decorator will catch an OutOfGasPanic caused in the next antehandler
// AnteHandlers must have their own defer/recover in order for the BaseApp
// to know how much gas was used! This is because the GasMeter is created in
// the AnteHandler, but if it panics the context won't be set properly in
// runTx's recover call.
defer func() {
if r := recover(); r != nil {
switch rType := r.(type) {
case sdk.ErrorOutOfGas:
log := fmt.Sprintf(
"out of gas in location: %v; gasLimit: %d, gasUsed: %d",
rType.Descriptor, gasTx.GetGas(), ctx.GasMeter().GasConsumed(),
)
err = sdkerrors.Wrap(sdkerrors.ErrOutOfGas, log)
default:
panic(r)
}
}
}()
return next(ctx, tx, simulate)
}
// EthMempoolFeeDecorator validates that sufficient fees have been provided that
// meet a minimum threshold defined by the proposer (for mempool purposes during CheckTx).
type EthMempoolFeeDecorator struct{}
// NewEthMempoolFeeDecorator creates a new EthMempoolFeeDecorator
func NewEthMempoolFeeDecorator() EthMempoolFeeDecorator {
return EthMempoolFeeDecorator{}
}
// AnteHandle verifies that enough fees have been provided by the
// Ethereum transaction that meet the minimum threshold set by the block
// proposer.
//
// NOTE: This should only be run during a CheckTx mode.
func (emfd EthMempoolFeeDecorator) AnteHandle(ctx sdk.Context, tx sdk.Tx, simulate bool, next sdk.AnteHandler) (newCtx sdk.Context, err error) {
if !ctx.IsCheckTx() {
return next(ctx, tx, simulate)
}
msgEthTx, ok := tx.(evmtypes.MsgEthereumTx)
if !ok {
return ctx, sdkerrors.Wrapf(sdkerrors.ErrUnknownRequest, "invalid transaction type: %T", tx)
}
// fee = GP * GL
fee := sdk.NewInt64DecCoin(emint.DenomDefault, msgEthTx.Fee().Int64())
minGasPrices := ctx.MinGasPrices()
allGTE := true
for _, v := range minGasPrices {
if !fee.IsGTE(v) {
allGTE = false
}
}
// it is assumed that the minimum fees will only include the single valid denom
if !ctx.MinGasPrices().IsZero() && !allGTE {
// reject the transaction that does not meet the minimum fee
return ctx, sdkerrors.Wrap(
sdkerrors.ErrInsufficientFee,
fmt.Sprintf("insufficient fee, got: %q required: %q", fee, ctx.MinGasPrices()),
)
}
return next(ctx, tx, simulate)
}
// EthSigVerificationDecorator validates an ethereum signature
type EthSigVerificationDecorator struct{}
// NewEthSigVerificationDecorator creates a new EthSigVerificationDecorator
func NewEthSigVerificationDecorator() EthSigVerificationDecorator {
return EthSigVerificationDecorator{}
}
// AnteHandle validates the signature and returns sender address
func (esvd EthSigVerificationDecorator) AnteHandle(ctx sdk.Context, tx sdk.Tx, simulate bool, next sdk.AnteHandler) (newCtx sdk.Context, err error) {
msgEthTx, ok := tx.(evmtypes.MsgEthereumTx)
if !ok {
return ctx, sdkerrors.Wrapf(sdkerrors.ErrUnknownRequest, "invalid transaction type: %T", tx)
}
// parse the chainID from a string to a base-10 integer
chainID, ok := new(big.Int).SetString(ctx.ChainID(), 10)
if !ok {
return ctx, sdkerrors.Wrap(emint.ErrInvalidChainID, ctx.ChainID())
}
// validate sender/signature
// NOTE: signer is retrieved from the transaction on the next AnteDecorator
_, err = msgEthTx.VerifySig(chainID)
if err != nil {
2020-04-22 17:39:09 +00:00
return ctx, sdkerrors.Wrap(sdkerrors.ErrUnauthorized, "signature verification failed")
}
return next(ctx, msgEthTx, simulate)
}
// AccountVerificationDecorator validates an account balance checks
type AccountVerificationDecorator struct {
ak auth.AccountKeeper
}
// NewAccountVerificationDecorator creates a new AccountVerificationDecorator
func NewAccountVerificationDecorator(ak auth.AccountKeeper) AccountVerificationDecorator {
return AccountVerificationDecorator{
ak: ak,
}
}
// AnteHandle validates the signature and returns sender address
func (avd AccountVerificationDecorator) AnteHandle(ctx sdk.Context, tx sdk.Tx, simulate bool, next sdk.AnteHandler) (newCtx sdk.Context, err error) {
if !ctx.IsCheckTx() {
return next(ctx, tx, simulate)
}
msgEthTx, ok := tx.(evmtypes.MsgEthereumTx)
if !ok {
return ctx, sdkerrors.Wrapf(sdkerrors.ErrUnknownRequest, "invalid transaction type: %T", tx)
}
// sender address should be in the tx cache
address := msgEthTx.From()
if address == nil {
panic("sender address is nil")
}
acc := avd.ak.GetAccount(ctx, address)
if acc == nil {
return ctx, fmt.Errorf("account %s is nil", address)
}
// on InitChain make sure account number == 0
if ctx.BlockHeight() == 0 && acc.GetAccountNumber() != 0 {
return ctx, sdkerrors.Wrapf(
sdkerrors.ErrInvalidSequence,
"invalid account number for height zero (got %d)", acc.GetAccountNumber(),
)
}
// validate sender has enough funds
balance := acc.GetCoins().AmountOf(emint.DenomDefault)
if balance.BigInt().Cmp(msgEthTx.Cost()) < 0 {
return ctx, sdkerrors.Wrapf(
sdkerrors.ErrInsufficientFunds,
"%s < %s%s", balance.String(), msgEthTx.Cost().String(), emint.DenomDefault,
)
}
return next(ctx, tx, simulate)
}
// NonceVerificationDecorator that the nonce matches
type NonceVerificationDecorator struct {
ak auth.AccountKeeper
}
// NewNonceVerificationDecorator creates a new NonceVerificationDecorator
func NewNonceVerificationDecorator(ak auth.AccountKeeper) NonceVerificationDecorator {
return NonceVerificationDecorator{
ak: ak,
}
}
// AnteHandle validates that the transaction nonce is valid (equivalent to the sender accounts
// current nonce).
func (nvd NonceVerificationDecorator) AnteHandle(ctx sdk.Context, tx sdk.Tx, simulate bool, next sdk.AnteHandler) (newCtx sdk.Context, err error) {
msgEthTx, ok := tx.(evmtypes.MsgEthereumTx)
if !ok {
return ctx, sdkerrors.Wrapf(sdkerrors.ErrUnknownRequest, "invalid transaction type: %T", tx)
}
// sender address should be in the tx cache
address := msgEthTx.From()
if address == nil {
panic("sender address is nil")
}
acc := nvd.ak.GetAccount(ctx, address)
if acc == nil {
return ctx, fmt.Errorf("account %s is nil", address)
}
seq := acc.GetSequence()
if msgEthTx.Data.AccountNonce != seq {
return ctx, sdkerrors.Wrap(
sdkerrors.ErrInvalidSequence,
fmt.Sprintf("invalid nonce; got %d, expected %d", msgEthTx.Data.AccountNonce, seq),
)
}
return next(ctx, tx, simulate)
}
// EthGasConsumeDecorator validates enough intrinsic gas for the transaction and
// gas consumption.
type EthGasConsumeDecorator struct {
ak auth.AccountKeeper
sk types.SupplyKeeper
}
// NewEthGasConsumeDecorator creates a new EthGasConsumeDecorator
func NewEthGasConsumeDecorator(ak auth.AccountKeeper, sk types.SupplyKeeper) EthGasConsumeDecorator {
return EthGasConsumeDecorator{
ak: ak,
sk: sk,
}
}
// AnteHandle validates that the Ethereum tx message has enough to cover intrinsic gas
// (during CheckTx only) and that the sender has enough balance to pay for the gas cost.
//
// Intrinsic gas for a transaction is the amount of gas
// that the transaction uses before the transaction is executed. The gas is a
// constant value of 21000 plus any cost inccured by additional bytes of data
// supplied with the transaction.
func (egcd EthGasConsumeDecorator) AnteHandle(ctx sdk.Context, tx sdk.Tx, simulate bool, next sdk.AnteHandler) (newCtx sdk.Context, err error) {
msgEthTx, ok := tx.(evmtypes.MsgEthereumTx)
if !ok {
return ctx, sdkerrors.Wrapf(sdkerrors.ErrUnknownRequest, "invalid transaction type: %T", tx)
}
// sender address should be in the tx cache
address := msgEthTx.From()
if address == nil {
panic("sender address is nil")
}
// Fetch sender account from signature
senderAcc, err := auth.GetSignerAcc(ctx, egcd.ak, address)
if err != nil {
return ctx, err
}
if senderAcc == nil {
return ctx, fmt.Errorf("sender account %s is nil", address)
}
gasLimit := msgEthTx.GetGas()
gas, err := ethcore.IntrinsicGas(msgEthTx.Data.Payload, msgEthTx.To() == nil, true)
if err != nil {
return ctx, sdkerrors.Wrap(err, "failed to compute intrinsic gas cost")
}
// intrinsic gas verification during CheckTx
if ctx.IsCheckTx() && gasLimit < gas {
return ctx, fmt.Errorf("intrinsic gas too low: %d < %d", gasLimit, gas)
}
// Charge sender for gas up to limit
if gasLimit != 0 {
// Cost calculates the fees paid to validators based on gas limit and price
cost := new(big.Int).Mul(msgEthTx.Data.Price, new(big.Int).SetUint64(gasLimit))
feeAmt := sdk.NewCoins(
sdk.NewCoin(emint.DenomDefault, sdk.NewIntFromBigInt(cost)),
)
err = auth.DeductFees(egcd.sk, ctx, senderAcc, feeAmt)
if err != nil {
return ctx, err
}
}
// Set gas meter after ante handler to ignore gaskv costs
newCtx = auth.SetGasMeter(simulate, ctx, gasLimit)
newCtx.GasMeter().ConsumeGas(gas, "eth intrinsic gas")
return next(newCtx, tx, simulate)
}
// IncrementSenderSequenceDecorator increments the sequence of the signers. The
// main difference with the SDK's IncrementSequenceDecorator is that the MsgEthereumTx
// doesn't implement the SigVerifiableTx interface.
//
// CONTRACT: must be called after msg.VerifySig in order to cache the sender address.
type IncrementSenderSequenceDecorator struct {
ak auth.AccountKeeper
}
// NewIncrementSenderSequenceDecorator creates a new IncrementSenderSequenceDecorator.
func NewIncrementSenderSequenceDecorator(ak auth.AccountKeeper) IncrementSenderSequenceDecorator {
return IncrementSenderSequenceDecorator{
ak: ak,
}
}
// AnteHandle handles incrementing the sequence of the sender.
func (issd IncrementSenderSequenceDecorator) AnteHandle(ctx sdk.Context, tx sdk.Tx, simulate bool, next sdk.AnteHandler) (sdk.Context, error) {
// no need to increment sequence on RecheckTx
if ctx.IsReCheckTx() && !simulate {
return next(ctx, tx, simulate)
}
// get and set account must be called with an infinite gas meter in order to prevent
// additional gas from being deducted.
oldCtx := ctx.WithBlockGasMeter(sdk.NewInfiniteGasMeter())
msgEthTx, ok := tx.(evmtypes.MsgEthereumTx)
if !ok {
return ctx, sdkerrors.Wrapf(sdkerrors.ErrUnknownRequest, "invalid transaction type: %T", tx)
}
// increment sequence of all signers
for _, addr := range msgEthTx.GetSigners() {
acc := issd.ak.GetAccount(oldCtx, addr)
if err := acc.SetSequence(acc.GetSequence() + 1); err != nil {
panic(err)
}
issd.ak.SetAccount(oldCtx, acc)
}
return next(ctx, tx, simulate)
}