path: root/accounts/abi/bind/backends/simulated.go

// Copyright 2015 The go-ethereum Authors
// This file is part of the go-ethereum library.
//
// The go-ethereum library is free software: you can redistribute it and/or modify
// it under the terms of the GNU Lesser General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// The go-ethereum library is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU Lesser General Public License for more details.
//
// You should have received a copy of the GNU Lesser General Public License
// along with the go-ethereum library. If not, see <http://www.gnu.org/licenses/>.

package backends

import (
    "context"
    "errors"
    "fmt"
    "math/big"
    "sync"

    "github.com/ethereum/go-ethereum"
    "github.com/ethereum/go-ethereum/accounts/abi/bind"
    "github.com/ethereum/go-ethereum/common"
    "github.com/ethereum/go-ethereum/common/math"
    "github.com/ethereum/go-ethereum/core"
    "github.com/ethereum/go-ethereum/core/state"
    "github.com/ethereum/go-ethereum/core/types"
    "github.com/ethereum/go-ethereum/core/vm"
    "github.com/ethereum/go-ethereum/ethdb"
    "github.com/ethereum/go-ethereum/event"
    "github.com/ethereum/go-ethereum/params"
    "github.com/ethereum/go-ethereum/pow"
)

// Default chain configuration which sets homestead phase at block 0 (i.e. no frontier)
var chainConfig = &params.ChainConfig{HomesteadBlock: big.NewInt(0), EIP150Block: new(big.Int), EIP158Block: new(big.Int)}

// This nil assignment ensures compile time that SimulatedBackend implements bind.ContractBackend.
var _ bind.ContractBackend = (*SimulatedBackend)(nil)

var errBlockNumberUnsupported = errors.New("SimulatedBackend cannot access blocks other than the latest block")

// SimulatedBackend implements bind.ContractBackend, simulating a blockchain in
// the background. Its main purpose is to allow easily testing contract bindings.
type SimulatedBackend struct {
    database   ethdb.Database   // In memory database to store our testing data
    blockchain *core.BlockChain // Ethereum blockchain to handle the consensus

    mu           sync.Mutex
    pendingBlock *types.Block   // Currently pending block that will be imported on request
    pendingState *state.StateDB // Currently pending state that will be the active on on request

    config *params.ChainConfig
}

// NewSimulatedBackend creates a new binding backend using a simulated blockchain
// for testing purposes.
func NewSimulatedBackend(accounts ...core.GenesisAccount) *SimulatedBackend {
    database, _ := ethdb.NewMemDatabase()
    core.WriteGenesisBlockForTesting(database, accounts...)
    blockchain, _ := core.NewBlockChain(database, chainConfig, new(pow.FakePow), new(event.TypeMux), vm.Config{})
    backend := &SimulatedBackend{database: database, blockchain: blockchain}
    backend.rollback()
    return backend
}

// Commit imports all the pending transactions as a single block and starts a
// fresh new state.
func (b *SimulatedBackend) Commit() {
    b.mu.Lock()
    defer b.mu.Unlock()

    if _, err := b.blockchain.InsertChain([]*types.Block{b.pendingBlock}); err != nil {
        panic(err) // This cannot happen unless the simulator is wrong, fail in that case
    }
    b.rollback()
}

// Rollback aborts all pending transactions, reverting to the last committed state.
func (b *SimulatedBackend) Rollback() {
    b.mu.Lock()
    defer b.mu.Unlock()

    b.rollback()
}

func (b *SimulatedBackend) rollback() {
    blocks, _ := core.GenerateChain(chainConfig, b.blockchain.CurrentBlock(), b.database, 1, func(int, *core.BlockGen) {})
    b.pendingBlock = blocks[0]
    b.pendingState, _ = state.New(b.pendingBlock.Root(), b.database)
}

// CodeAt returns the code associated with a certain account in the blockchain.
func (b *SimulatedBackend) CodeAt(ctx context.Context, contract common.Address, blockNumber *big.Int) ([]byte, error) {
    b.mu.Lock()
    defer b.mu.Unlock()

    if blockNumber != nil && blockNumber.Cmp(b.blockchain.CurrentBlock().Number()) != 0 {
        return nil, errBlockNumberUnsupported
    }
    statedb, _ := b.blockchain.State()
    return statedb.GetCode(contract), nil
}

// BalanceAt returns the wei balance of a certain account in the blockchain.
func (b *SimulatedBackend) BalanceAt(ctx context.Context, contract common.Address, blockNumber *big.Int) (*big.Int, error) {
    b.mu.Lock()
    defer b.mu.Unlock()

    if blockNumber != nil && blockNumber.Cmp(b.blockchain.CurrentBlock().Number()) != 0 {
        return nil, errBlockNumberUnsupported
    }
    statedb, _ := b.blockchain.State()
    return statedb.GetBalance(contract), nil
}

// NonceAt returns the nonce of a certain account in the blockchain.
func (b *SimulatedBackend) NonceAt(ctx context.Context, contract common.Address, blockNumber *big.Int) (uint64, error) {
    b.mu.Lock()
    defer b.mu.Unlock()

    if blockNumber != nil && blockNumber.Cmp(b.blockchain.CurrentBlock().Number()) != 0 {
        return 0, errBlockNumberUnsupported
    }
    statedb, _ := b.blockchain.State()
    return statedb.GetNonce(contract), nil
}

// StorageAt returns the value of key in the storage of an account in the blockchain.
func (b *SimulatedBackend) StorageAt(ctx context.Context, contract common.Address, key common.Hash, blockNumber *big.Int) ([]byte, error) {
    b.mu.Lock()
    defer b.mu.Unlock()

    if blockNumber != nil && blockNumber.Cmp(b.blockchain.CurrentBlock().Number()) != 0 {
        return nil, errBlockNumberUnsupported
    }
    statedb, _ := b.blockchain.State()
    val := statedb.GetState(contract, key)
    return val[:], nil
}

// TransactionReceipt returns the receipt of a transaction.
func (b *SimulatedBackend) TransactionReceipt(ctx context.Context, txHash common.Hash) (*types.Receipt, error) {
    return core.GetReceipt(b.database, txHash), nil
}

// PendingCodeAt returns the code associated with an account in the pending state.
func (b *SimulatedBackend) PendingCodeAt(ctx context.Context, contract common.Address) ([]byte, error) {
    b.mu.Lock()
    defer b.mu.Unlock()

    return b.pendingState.GetCode(contract), nil
}

// CallContract executes a contract call.
func (b *SimulatedBackend) CallContract(ctx context.Context, call ethereum.CallMsg, blockNumber *big.Int) ([]byte, error) {
    b.mu.Lock()
    defer b.mu.Unlock()

    if blockNumber != nil && blockNumber.Cmp(b.blockchain.CurrentBlock().Number()) != 0 {
        return nil, errBlockNumberUnsupported
    }
    state, err := b.blockchain.State()
    if err != nil {
        return nil, err
    }
    rval, _, err := b.callContract(ctx, call, b.blockchain.CurrentBlock(), state)
    return rval, err
}

// PendingCallContract executes a contract call on the pending state.
func (b *SimulatedBackend) PendingCallContract(ctx context.Context, call ethereum.CallMsg) ([]byte, error) {
    b.mu.Lock()
    defer b.mu.Unlock()
    defer b.pendingState.RevertToSnapshot(b.pendingState.Snapshot())

    rval, _, err := b.callContract(ctx, call, b.pendingBlock, b.pendingState)
    return rval, err
}

// PendingNonceAt implements PendingStateReader.PendingNonceAt, retrieving
// the nonce currently pending for the account.
func (b *SimulatedBackend) PendingNonceAt(ctx context.Context, account common.Address) (uint64, error) {
    b.mu.Lock()
    defer b.mu.Unlock()

    return b.pendingState.GetOrNewStateObject(account).Nonce(), nil
}

// SuggestGasPrice implements ContractTransactor.SuggestGasPrice. Since the simulated
// chain doens't have miners, we just return a gas price of 1 for any call.
func (b *SimulatedBackend) SuggestGasPrice(ctx context.Context) (*big.Int, error) {
    return big.NewInt(1), nil
}

// EstimateGas executes the requested code against the currently pending block/state and
// returns the used amount of gas.
func (b *SimulatedBackend) EstimateGas(ctx context.Context, call ethereum.CallMsg) (*big.Int, error) {
    b.mu.Lock()
    defer b.mu.Unlock()

    // Binary search the gas requirement, as it may be higher than the amount used
    var lo, hi uint64
    if call.Gas != nil {
        hi = call.Gas.Uint64()
    } else {
        hi = b.pendingBlock.GasLimit().Uint64()
    }
    for lo+1 < hi {
        // Take a guess at the gas, and check transaction validity
        mid := (hi + lo) / 2
        call.Gas = new(big.Int).SetUint64(mid)

        snapshot := b.pendingState.Snapshot()
        _, gas, err := b.callContract(ctx, call, b.pendingBlock, b.pendingState)
        b.pendingState.RevertToSnapshot(snapshot)

        // If the transaction became invalid or used all the gas (failed), raise the gas limit
        if err != nil || gas.Cmp(call.Gas) == 0 {
            lo = mid
            continue
        }
        // Otherwise assume the transaction succeeded, lower the gas limit
        hi = mid
    }
    return new(big.Int).SetUint64(hi), nil
}

// callContract implemens common code between normal and pending contract calls.
// state is modified during execution, make sure to copy it if necessary.
func (b *SimulatedBackend) callContract(ctx context.Context, call ethereum.CallMsg, block *types.Block, statedb *state.StateDB) ([]byte, *big.Int, error) {
    // Ensure message is initialized properly.
    if call.GasPrice == nil {
        call.GasPrice = big.NewInt(1)
    }
    if call.Gas == nil || call.Gas.Sign() == 0 {
        call.Gas = big.NewInt(50000000)
    }
    if call.Value == nil {
        call.Value = new(big.Int)
    }
    // Set infinite balance to the fake caller account.
    from := statedb.GetOrNewStateObject(call.From)
    from.SetBalance(math.MaxBig256)
    // Execute the call.
    msg := callmsg{call}

    evmContext := core.NewEVMContext(msg, block.Header(), b.blockchain)
    // Create a new environment which holds all relevant information
    // about the transaction and calling mechanisms.
    vmenv := vm.NewEVM(evmContext, statedb, chainConfig, vm.Config{})
    gaspool := new(core.GasPool).AddGas(math.MaxBig256)
    ret, gasUsed, _, err := core.NewStateTransition(vmenv, msg, gaspool).TransitionDb()
    return ret, gasUsed, err
}

// SendTransaction updates the pending block to include the given transaction.
// It panics if the transaction is invalid.
func (b *SimulatedBackend) SendTransaction(ctx context.Context, tx *types.Transaction) error {
    b.mu.Lock()
    defer b.mu.Unlock()

    sender, err := types.Sender(types.HomesteadSigner{}, tx)
    if err != nil {
        panic(fmt.Errorf("invalid transaction: %v", err))
    }
    nonce := b.pendingState.GetNonce(sender)
    if tx.Nonce() != nonce {
        panic(fmt.Errorf("invalid transaction nonce: got %d, want %d", tx.Nonce(), nonce))
    }

    blocks, _ := core.GenerateChain(chainConfig, b.blockchain.CurrentBlock(), b.database, 1, func(number int, block *core.BlockGen) {
        for _, tx := range b.pendingBlock.Transactions() {
            block.AddTx(tx)
        }
        block.AddTx(tx)
    })
    b.pendingBlock = blocks[0]
    b.pendingState, _ = state.New(b.pendingBlock.Root(), b.database)
    return nil
}

// callmsg implements core.Message to allow passing it as a transaction simulator.
type callmsg struct {
    ethereum.CallMsg
}

func (m callmsg) From() common.Address { return m.CallMsg.From }
func (m callmsg) Nonce() uint64        { return 0 }
func (m callmsg) CheckNonce() bool     { return false }
func (m callmsg) To() *common.Address  { return m.CallMsg.To }
func (m callmsg) GasPrice() *big.Int   { return m.CallMsg.GasPrice }
func (m callmsg) Gas() *big.Int        { return m.CallMsg.Gas }
func (m callmsg) Value() *big.Int      { return m.CallMsg.Value }
func (m callmsg) Data() []byte         { return m.CallMsg.Data }