laconicd/app/ante.go
Austin Abell a6d21e651e
Cosmos SDK version update (#60)
* Wip converting to updated Cosmos SDK version

* Fixed test failures from updating SDK

* cleaned and verified changes

* Wip converting to updated Cosmos SDK version

* Fixed test failures from updating SDK

* cleaned and verified changes

* wip - updating to version 0.36.0

* Switched supply keeper to dummy for testing

* Formatting fixes

* Changed relative dependency of cosmos SDK to specific commit
2019-07-04 15:46:54 -04:00

323 lines
10 KiB
Go
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

package app
import (
"fmt"
"math/big"
sdk "github.com/cosmos/cosmos-sdk/types"
"github.com/cosmos/cosmos-sdk/x/auth"
"github.com/cosmos/cosmos-sdk/x/auth/exported"
"github.com/cosmos/cosmos-sdk/x/auth/types"
"github.com/cosmos/ethermint/crypto"
emint "github.com/cosmos/ethermint/types"
evmtypes "github.com/cosmos/ethermint/x/evm/types"
ethcmn "github.com/ethereum/go-ethereum/common"
ethcore "github.com/ethereum/go-ethereum/core"
tmcrypto "github.com/tendermint/tendermint/crypto"
)
const (
memoCostPerByte sdk.Gas = 3
secp256k1VerifyCost uint64 = 21000
)
// NewAnteHandler returns an ante handler responsible for attempting to route an
// Ethereum or SDK transaction to an internal ante handler for performing
// transaction-level processing (e.g. fee payment, signature verification) before
// being passed onto it's respective handler.
//
// NOTE: The EVM will already consume (intrinsic) gas for signature verification
// and covering input size as well as handling nonce incrementing.
func NewAnteHandler(ak auth.AccountKeeper, sk types.SupplyKeeper) sdk.AnteHandler {
return func(
ctx sdk.Context, tx sdk.Tx, sim bool,
) (newCtx sdk.Context, res sdk.Result, abort bool) {
switch castTx := tx.(type) {
case auth.StdTx:
return sdkAnteHandler(ctx, ak, sk, castTx, sim)
case *evmtypes.EthereumTxMsg:
return ethAnteHandler(ctx, castTx, ak)
default:
return ctx, sdk.ErrInternal(fmt.Sprintf("transaction type invalid: %T", tx)).Result(), true
}
}
}
// ----------------------------------------------------------------------------
// SDK Ante Handler
func sdkAnteHandler(
ctx sdk.Context, ak auth.AccountKeeper, sk types.SupplyKeeper, stdTx auth.StdTx, sim bool,
) (newCtx sdk.Context, res sdk.Result, abort bool) {
// Ensure that the provided fees meet a minimum threshold for the validator,
// if this is a CheckTx. This is only for local mempool purposes, and thus
// is only ran on check tx.
if ctx.IsCheckTx() && !sim {
res := auth.EnsureSufficientMempoolFees(ctx, stdTx.Fee)
if !res.IsOK() {
return newCtx, res, true
}
}
newCtx = auth.SetGasMeter(sim, ctx, stdTx.Fee.Gas)
// 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", rType.Descriptor)
res = sdk.ErrOutOfGas(log).Result()
res.GasWanted = stdTx.Fee.Gas
res.GasUsed = newCtx.GasMeter().GasConsumed()
abort = true
default:
panic(r)
}
}
}()
if err := stdTx.ValidateBasic(); err != nil {
return newCtx, err.Result(), true
}
newCtx.GasMeter().ConsumeGas(memoCostPerByte*sdk.Gas(len(stdTx.GetMemo())), "memo")
// stdSigs contains the sequence number, account number, and signatures.
// When simulating, this would just be a 0-length slice.
signerAddrs := stdTx.GetSigners()
signerAccs := make([]exported.Account, len(signerAddrs))
isGenesis := ctx.BlockHeight() == 0
// fetch first signer, who's going to pay the fees
signerAccs[0], res = auth.GetSignerAcc(newCtx, ak, signerAddrs[0])
if !res.IsOK() {
return newCtx, res, true
}
// the first signer pays the transaction fees
if !stdTx.Fee.Amount.IsZero() {
// Testing error is in DeductFees
res = auth.DeductFees(sk, newCtx, signerAccs[0], stdTx.Fee.Amount)
if !res.IsOK() {
return newCtx, res, true
}
// Reload account after fees deducted
signerAccs[0] = ak.GetAccount(newCtx, signerAccs[0].GetAddress())
}
stdSigs := stdTx.GetSignatures()
for i := 0; i < len(stdSigs); i++ {
// skip the fee payer, account is cached and fees were deducted already
if i != 0 {
signerAccs[i], res = auth.GetSignerAcc(newCtx, ak, signerAddrs[i])
if !res.IsOK() {
return newCtx, res, true
}
}
// check signature, return account with incremented nonce
signBytes := auth.GetSignBytes(newCtx.ChainID(), stdTx, signerAccs[i], isGenesis)
signerAccs[i], res = processSig(newCtx, signerAccs[i], stdSigs[i], signBytes, sim)
if !res.IsOK() {
return newCtx, res, true
}
ak.SetAccount(newCtx, signerAccs[i])
}
return newCtx, sdk.Result{GasWanted: stdTx.Fee.Gas}, false
}
// processSig verifies the signature and increments the nonce. If the account
// doesn't have a pubkey, set it.
func processSig(
ctx sdk.Context, acc auth.Account, sig auth.StdSignature, signBytes []byte, sim bool,
) (updatedAcc auth.Account, res sdk.Result) {
pubKey, res := auth.ProcessPubKey(acc, sig, sim)
if !res.IsOK() {
return nil, res
}
err := acc.SetPubKey(pubKey)
if err != nil {
return nil, sdk.ErrInternal("failed to set PubKey on signer account").Result()
}
consumeSigGas(ctx.GasMeter(), pubKey)
if !sim && !pubKey.VerifyBytes(signBytes, sig.Signature) {
return nil, sdk.ErrUnauthorized("signature verification failed").Result()
}
err = acc.SetSequence(acc.GetSequence() + 1)
if err != nil {
return nil, sdk.ErrInternal("failed to set account nonce").Result()
}
return acc, res
}
func consumeSigGas(meter sdk.GasMeter, pubkey tmcrypto.PubKey) {
switch pubkey.(type) {
case crypto.PubKeySecp256k1:
meter.ConsumeGas(secp256k1VerifyCost, "ante verify: secp256k1")
default:
panic("Unrecognized signature type")
}
}
// ----------------------------------------------------------------------------
// Ethereum Ante Handler
// ethAnteHandler defines an internal ante handler for an Ethereum transaction
// ethTxMsg. During CheckTx, the transaction is passed through a series of
// pre-message execution validation checks such as signature and account
// verification in addition to minimum fees being checked. Otherwise, during
// DeliverTx, the transaction is simply passed to the EVM which will also
// perform the same series of checks. The distinction is made in CheckTx to
// prevent spam and DoS attacks.
func ethAnteHandler(
ctx sdk.Context, ethTxMsg *evmtypes.EthereumTxMsg, ak auth.AccountKeeper,
) (newCtx sdk.Context, res sdk.Result, abort bool) {
if ctx.IsCheckTx() {
// Only perform pre-message (Ethereum transaction) execution validation
// during CheckTx. Otherwise, during DeliverTx the EVM will handle them.
if res := validateEthTxCheckTx(ctx, ak, ethTxMsg); !res.IsOK() {
return newCtx, res, true
}
}
return ctx, sdk.Result{}, false
}
func validateEthTxCheckTx(
ctx sdk.Context, ak auth.AccountKeeper, ethTxMsg *evmtypes.EthereumTxMsg,
) sdk.Result {
// parse the chainID from a string to a base-10 integer
chainID, ok := new(big.Int).SetString(ctx.ChainID(), 10)
if !ok {
return emint.ErrInvalidChainID(fmt.Sprintf("invalid chainID: %s", ctx.ChainID())).Result()
}
// Validate sufficient fees have been provided that meet a minimum threshold
// defined by the proposer (for mempool purposes during CheckTx).
if res := ensureSufficientMempoolFees(ctx, ethTxMsg); !res.IsOK() {
return res
}
// validate enough intrinsic gas
if res := validateIntrinsicGas(ethTxMsg); !res.IsOK() {
return res
}
// validate sender/signature
signer, err := ethTxMsg.VerifySig(chainID)
if err != nil {
return sdk.ErrUnauthorized("signature verification failed").Result()
}
// validate account (nonce and balance checks)
if res := validateAccount(ctx, ak, ethTxMsg, signer); !res.IsOK() {
return res
}
return sdk.Result{}
}
// validateIntrinsicGas validates that the Ethereum tx message has enough to
// cover intrinsic gas. 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 validateIntrinsicGas(ethTxMsg *evmtypes.EthereumTxMsg) sdk.Result {
gas, err := ethcore.IntrinsicGas(ethTxMsg.Data.Payload, ethTxMsg.To() == nil, false)
if err != nil {
return sdk.ErrInternal(fmt.Sprintf("failed to compute intrinsic gas cost: %s", err)).Result()
}
if ethTxMsg.Data.GasLimit < gas {
return sdk.ErrInternal(
fmt.Sprintf("intrinsic gas too low; %d < %d", ethTxMsg.Data.GasLimit, gas),
).Result()
}
return sdk.Result{}
}
// validateAccount validates the account nonce and that the account has enough
// funds to cover the tx cost.
func validateAccount(
ctx sdk.Context, ak auth.AccountKeeper, ethTxMsg *evmtypes.EthereumTxMsg, signer ethcmn.Address,
) sdk.Result {
acc := ak.GetAccount(ctx, sdk.AccAddress(signer.Bytes()))
// on InitChain make sure account number == 0
if ctx.BlockHeight() == 0 && acc.GetAccountNumber() != 0 {
return sdk.ErrInternal(
fmt.Sprintf(
"invalid account number for height zero; got %d, expected 0", acc.GetAccountNumber(),
)).Result()
}
// Validate the transaction nonce is valid (equivalent to the sender accounts
// current nonce).
seq := acc.GetSequence()
if ethTxMsg.Data.AccountNonce != seq {
return sdk.ErrInvalidSequence(
fmt.Sprintf("nonce too low; got %d, expected %d", ethTxMsg.Data.AccountNonce, seq)).Result()
}
// validate sender has enough funds
balance := acc.GetCoins().AmountOf(emint.DenomDefault)
if balance.BigInt().Cmp(ethTxMsg.Cost()) < 0 {
return sdk.ErrInsufficientFunds(
fmt.Sprintf("insufficient funds: %s < %s", balance, ethTxMsg.Cost()),
).Result()
}
return sdk.Result{}
}
// ensureSufficientMempoolFees 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 ran during a CheckTx mode.
func ensureSufficientMempoolFees(ctx sdk.Context, ethTxMsg *evmtypes.EthereumTxMsg) sdk.Result {
// fee = GP * GL
fee := sdk.NewDecCoinFromCoin(sdk.NewInt64Coin(emint.DenomDefault, ethTxMsg.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 sdk.ErrInsufficientFee(
fmt.Sprintf("insufficient fee, got: %q required: %q", fee, ctx.MinGasPrices()),
).Result()
}
return sdk.Result{}
}