package app import ( "encoding/json" "math/rand" "time" "github.com/cosmos/cosmos-sdk/codec" "github.com/cosmos/cosmos-sdk/crypto/keys/secp256k1" "github.com/cosmos/cosmos-sdk/simapp" "github.com/cosmos/cosmos-sdk/types/module" authtypes "github.com/cosmos/cosmos-sdk/x/auth/types" stakingtypes "github.com/cosmos/cosmos-sdk/x/staking/types" "github.com/evmos/ethermint/encoding" ethermint "github.com/evmos/ethermint/types" evmtypes "github.com/evmos/ethermint/x/evm/types" "github.com/cosmos/cosmos-sdk/crypto/keys/ed25519" sdk "github.com/cosmos/cosmos-sdk/types" simtypes "github.com/cosmos/cosmos-sdk/types/simulation" "github.com/ethereum/go-ethereum/common" "github.com/ethereum/go-ethereum/crypto" "github.com/evmos/ethermint/crypto/ethsecp256k1" abci "github.com/tendermint/tendermint/abci/types" "github.com/tendermint/tendermint/libs/log" tmproto "github.com/tendermint/tendermint/proto/tendermint/types" tmtypes "github.com/tendermint/tendermint/types" dbm "github.com/tendermint/tm-db" ) // DefaultConsensusParams defines the default Tendermint consensus params used in // EthermintApp testing. var DefaultConsensusParams = &abci.ConsensusParams{ Block: &abci.BlockParams{ MaxBytes: 200000, MaxGas: -1, // no limit }, Evidence: &tmproto.EvidenceParams{ MaxAgeNumBlocks: 302400, MaxAgeDuration: 504 * time.Hour, // 3 weeks is the max duration MaxBytes: 10000, }, Validator: &tmproto.ValidatorParams{ PubKeyTypes: []string{ tmtypes.ABCIPubKeyTypeEd25519, }, }, } // Setup initializes a new EthermintApp. A Nop logger is set in EthermintApp. func Setup(isCheckTx bool, patchGenesis func(*EthermintApp, simapp.GenesisState) simapp.GenesisState) *EthermintApp { db := dbm.NewMemDB() app := NewEthermintApp(log.NewNopLogger(), db, nil, true, map[int64]bool{}, DefaultNodeHome, 5, encoding.MakeConfig(ModuleBasics), simapp.EmptyAppOptions{}) if !isCheckTx { // init chain must be called to stop deliverState from being nil genesisState := NewDefaultGenesisState() if patchGenesis != nil { genesisState = patchGenesis(app, genesisState) } stateBytes, err := json.MarshalIndent(genesisState, "", " ") if err != nil { panic(err) } // Initialize the chain app.InitChain( abci.RequestInitChain{ ChainId: "ethermint_9000-1", Validators: []abci.ValidatorUpdate{}, ConsensusParams: DefaultConsensusParams, AppStateBytes: stateBytes, }, ) } return app } // RandomGenesisAccounts is used by the auth module to create random genesis accounts in simulation when a genesis.json is not specified. // In contrast, the default auth module's RandomGenesisAccounts implementation creates only base accounts and vestings accounts. func RandomGenesisAccounts(simState *module.SimulationState) authtypes.GenesisAccounts { emptyCodeHash := crypto.Keccak256(nil) genesisAccs := make(authtypes.GenesisAccounts, len(simState.Accounts)) for i, acc := range simState.Accounts { bacc := authtypes.NewBaseAccountWithAddress(acc.Address) ethacc := ðermint.EthAccount{ BaseAccount: bacc, CodeHash: common.BytesToHash(emptyCodeHash).String(), } genesisAccs[i] = ethacc } return genesisAccs } // RandomAccounts creates random accounts with an ethsecp256k1 private key // TODO: replace secp256k1.GenPrivKeyFromSecret() with similar function in go-ethereum func RandomAccounts(r *rand.Rand, n int) []simtypes.Account { accs := make([]simtypes.Account, n) for i := 0; i < n; i++ { // don't need that much entropy for simulation privkeySeed := make([]byte, 15) _, _ = r.Read(privkeySeed) prv := secp256k1.GenPrivKeyFromSecret(privkeySeed) ethPrv := ðsecp256k1.PrivKey{} _ = ethPrv.UnmarshalAmino(prv.Bytes()) // UnmarshalAmino simply copies the bytes and assigns them to ethPrv.Key accs[i].PrivKey = ethPrv accs[i].PubKey = accs[i].PrivKey.PubKey() accs[i].Address = sdk.AccAddress(accs[i].PubKey.Address()) accs[i].ConsKey = ed25519.GenPrivKeyFromSecret(privkeySeed) } return accs } // StateFn returns the initial application state using a genesis or the simulation parameters. // It is a wrapper of simapp.AppStateFn to replace evm param EvmDenom with staking param BondDenom. func StateFn(cdc codec.JSONCodec, simManager *module.SimulationManager) simtypes.AppStateFn { return func(r *rand.Rand, accs []simtypes.Account, config simtypes.Config, ) (appState json.RawMessage, simAccs []simtypes.Account, chainID string, genesisTimestamp time.Time) { appStateFn := simapp.AppStateFn(cdc, simManager) appState, simAccs, chainID, genesisTimestamp = appStateFn(r, accs, config) rawState := make(map[string]json.RawMessage) err := json.Unmarshal(appState, &rawState) if err != nil { panic(err) } stakingStateBz, ok := rawState[stakingtypes.ModuleName] if !ok { panic("staking genesis state is missing") } stakingState := new(stakingtypes.GenesisState) cdc.MustUnmarshalJSON(stakingStateBz, stakingState) // we should get the BondDenom and make it the evmdenom. // thus simulation accounts could have positive amount of gas token. bondDenom := stakingState.Params.BondDenom evmStateBz, ok := rawState[evmtypes.ModuleName] if !ok { panic("staking genesis state is missing") } evmState := new(evmtypes.GenesisState) cdc.MustUnmarshalJSON(evmStateBz, evmState) // we should replace the EvmDenom with BondDenom evmState.Params.EvmDenom = bondDenom // change appState back rawState[evmtypes.ModuleName] = cdc.MustMarshalJSON(evmState) // replace appstate appState, err = json.Marshal(rawState) if err != nil { panic(err) } return appState, simAccs, chainID, genesisTimestamp } }