neoneo-go/pkg/neotest/basic.go
Anna Shaleva 6b105e6d10 neotest: use validators account instead of committee to pay the bills
GAS and NEO tokens are sent to validators account (not the committee's
one). For single-node chain they are the same, but for four-nodes chain
they are different. Thus, use validators multisig address to create new
accounts and to deploy contracts.

Also, allow to provide desired account balance while creating new
account.
2022-01-13 19:12:20 +03:00

368 lines
13 KiB
Go

package neotest
import (
"encoding/json"
"fmt"
"math/big"
"strings"
"testing"
"github.com/nspcc-dev/neo-go/pkg/config/netmode"
"github.com/nspcc-dev/neo-go/pkg/core/block"
"github.com/nspcc-dev/neo-go/pkg/core/blockchainer"
"github.com/nspcc-dev/neo-go/pkg/core/fee"
"github.com/nspcc-dev/neo-go/pkg/core/native"
"github.com/nspcc-dev/neo-go/pkg/core/native/nativenames"
"github.com/nspcc-dev/neo-go/pkg/core/state"
"github.com/nspcc-dev/neo-go/pkg/core/transaction"
"github.com/nspcc-dev/neo-go/pkg/io"
"github.com/nspcc-dev/neo-go/pkg/smartcontract/callflag"
"github.com/nspcc-dev/neo-go/pkg/smartcontract/trigger"
"github.com/nspcc-dev/neo-go/pkg/util"
"github.com/nspcc-dev/neo-go/pkg/vm"
"github.com/nspcc-dev/neo-go/pkg/vm/emit"
"github.com/nspcc-dev/neo-go/pkg/vm/stackitem"
"github.com/nspcc-dev/neo-go/pkg/wallet"
"github.com/stretchr/testify/require"
)
// Executor is a wrapper over chain state.
type Executor struct {
Chain blockchainer.Blockchainer
Validator Signer
Committee Signer
CommitteeHash util.Uint160
Contracts map[string]*Contract
}
// NewExecutor creates new executor instance from provided blockchain and committee.
func NewExecutor(t *testing.T, bc blockchainer.Blockchainer, validator, committee Signer) *Executor {
checkMultiSigner(t, validator)
checkMultiSigner(t, committee)
return &Executor{
Chain: bc,
Validator: validator,
Committee: committee,
CommitteeHash: committee.ScriptHash(),
Contracts: make(map[string]*Contract),
}
}
// TopBlock returns block with the highest index.
func (e *Executor) TopBlock(t *testing.T) *block.Block {
b, err := e.Chain.GetBlock(e.Chain.GetHeaderHash(int(e.Chain.BlockHeight())))
require.NoError(t, err)
return b
}
// NativeHash returns native contract hash by name.
func (e *Executor) NativeHash(t *testing.T, name string) util.Uint160 {
h, err := e.Chain.GetNativeContractScriptHash(name)
require.NoError(t, err)
return h
}
// NativeID returns native contract ID by name.
func (e *Executor) NativeID(t *testing.T, name string) int32 {
h := e.NativeHash(t, name)
cs := e.Chain.GetContractState(h)
require.NotNil(t, cs)
return cs.ID
}
// NewUnsignedTx creates new unsigned transaction which invokes method of contract with hash.
func (e *Executor) NewUnsignedTx(t *testing.T, hash util.Uint160, method string, args ...interface{}) *transaction.Transaction {
w := io.NewBufBinWriter()
emit.AppCall(w.BinWriter, hash, method, callflag.All, args...)
require.NoError(t, w.Err)
script := w.Bytes()
tx := transaction.New(script, 0)
tx.Nonce = Nonce()
tx.ValidUntilBlock = e.Chain.BlockHeight() + 1
return tx
}
// NewTx creates new transaction which invokes contract method.
// Transaction is signed with signer.
func (e *Executor) NewTx(t *testing.T, signers []Signer,
hash util.Uint160, method string, args ...interface{}) *transaction.Transaction {
tx := e.NewUnsignedTx(t, hash, method, args...)
return e.SignTx(t, tx, -1, signers...)
}
// SignTx signs a transaction using provided signers.
func (e *Executor) SignTx(t *testing.T, tx *transaction.Transaction, sysFee int64, signers ...Signer) *transaction.Transaction {
for _, acc := range signers {
tx.Signers = append(tx.Signers, transaction.Signer{
Account: acc.ScriptHash(),
Scopes: transaction.Global,
})
}
addNetworkFee(e.Chain, tx, signers...)
addSystemFee(e.Chain, tx, sysFee)
for _, acc := range signers {
require.NoError(t, acc.SignTx(e.Chain.GetConfig().Magic, tx))
}
return tx
}
// NewAccount returns new signer holding 100.0 GAS (or given amount is specified).
// This method advances the chain by one block with a transfer transaction.
func (e *Executor) NewAccount(t *testing.T, expectedGASBalance ...int64) Signer {
acc, err := wallet.NewAccount()
require.NoError(t, err)
amount := int64(100_0000_0000)
if len(expectedGASBalance) != 0 {
amount = expectedGASBalance[0]
}
tx := e.NewTx(t, []Signer{e.Validator},
e.NativeHash(t, nativenames.Gas), "transfer",
e.Validator.ScriptHash(), acc.Contract.ScriptHash(), amount, nil)
e.AddNewBlock(t, tx)
e.CheckHalt(t, tx.Hash())
return NewSingleSigner(acc)
}
// DeployContract compiles and deploys contract to bc. It also checks that
// precalculated contract hash matches the actual one.
// data is an optional argument to `_deploy`.
// Returns hash of the deploy transaction.
func (e *Executor) DeployContract(t *testing.T, c *Contract, data interface{}) util.Uint256 {
tx := e.NewDeployTx(t, e.Chain, c, data)
e.AddNewBlock(t, tx)
e.CheckHalt(t, tx.Hash())
// Check that precalculated hash matches the real one.
e.CheckTxNotificationEvent(t, tx.Hash(), -1, state.NotificationEvent{
ScriptHash: e.NativeHash(t, nativenames.Management),
Name: "Deploy",
Item: stackitem.NewArray([]stackitem.Item{
stackitem.NewByteArray(c.Hash.BytesBE()),
}),
})
return tx.Hash()
}
// DeployContractCheckFAULT compiles and deploys contract to bc. It checks that deploy
// transaction FAULTed with the specified error.
func (e *Executor) DeployContractCheckFAULT(t *testing.T, c *Contract, data interface{}, errMessage string) {
tx := e.NewDeployTx(t, e.Chain, c, data)
e.AddNewBlock(t, tx)
e.CheckFault(t, tx.Hash(), errMessage)
}
// InvokeScript adds transaction with the specified script to the chain and
// returns its hash. It does no faults check.
func (e *Executor) InvokeScript(t *testing.T, script []byte, signers []Signer) util.Uint256 {
tx := transaction.New(script, 0)
tx.Nonce = Nonce()
tx.ValidUntilBlock = e.Chain.BlockHeight() + 1
e.SignTx(t, tx, -1, signers...)
e.AddNewBlock(t, tx)
return tx.Hash()
}
// InvokeScriptCheckHALT adds transaction with the specified script to the chain
// and checks it's HALTed with the specified items on stack.
func (e *Executor) InvokeScriptCheckHALT(t *testing.T, script []byte, signers []Signer, stack ...stackitem.Item) {
hash := e.InvokeScript(t, script, signers)
e.CheckHalt(t, hash, stack...)
}
// InvokeScriptCheckFAULT adds transaction with the specified script to the
// chain and checks it's FAULTed with the specified error.
func (e *Executor) InvokeScriptCheckFAULT(t *testing.T, script []byte, signers []Signer, errMessage string) {
hash := e.InvokeScript(t, script, signers)
e.CheckFault(t, hash, errMessage)
}
// CheckHalt checks that transaction persisted with HALT state.
func (e *Executor) CheckHalt(t *testing.T, h util.Uint256, stack ...stackitem.Item) *state.AppExecResult {
aer, err := e.Chain.GetAppExecResults(h, trigger.Application)
require.NoError(t, err)
require.Equal(t, vm.HaltState, aer[0].VMState, aer[0].FaultException)
if len(stack) != 0 {
require.Equal(t, stack, aer[0].Stack)
}
return &aer[0]
}
// CheckFault checks that transaction persisted with FAULT state.
// Raised exception is also checked to contain s as a substring.
func (e *Executor) CheckFault(t *testing.T, h util.Uint256, s string) {
aer, err := e.Chain.GetAppExecResults(h, trigger.Application)
require.NoError(t, err)
require.Equal(t, vm.FaultState, aer[0].VMState)
require.True(t, strings.Contains(aer[0].FaultException, s),
"expected: %s, got: %s", s, aer[0].FaultException)
}
// CheckTxNotificationEvent checks that specified event was emitted at the specified position
// during transaction script execution. Negative index corresponds to backwards enumeration.
func (e *Executor) CheckTxNotificationEvent(t *testing.T, h util.Uint256, index int, expected state.NotificationEvent) {
aer, err := e.Chain.GetAppExecResults(h, trigger.Application)
require.NoError(t, err)
l := len(aer[0].Events)
if index < 0 {
index = l + index
}
require.True(t, 0 <= index && index < l, fmt.Errorf("notification index is out of range: want %d, len is %d", index, l))
require.Equal(t, expected, aer[0].Events[index])
}
// CheckGASBalance ensures that provided account owns specified amount of GAS.
func (e *Executor) CheckGASBalance(t *testing.T, acc util.Uint160, expected *big.Int) {
actual := e.Chain.GetUtilityTokenBalance(acc)
require.Equal(t, expected, actual, fmt.Errorf("invalid GAS balance: expected %s, got %s", expected.String(), actual.String()))
}
// NewDeployTx returns new deployment tx for contract signed by committee.
func (e *Executor) NewDeployTx(t *testing.T, bc blockchainer.Blockchainer, c *Contract, data interface{}) *transaction.Transaction {
rawManifest, err := json.Marshal(c.Manifest)
require.NoError(t, err)
neb, err := c.NEF.Bytes()
require.NoError(t, err)
buf := io.NewBufBinWriter()
emit.AppCall(buf.BinWriter, bc.ManagementContractHash(), "deploy", callflag.All, neb, rawManifest, data)
require.NoError(t, buf.Err)
tx := transaction.New(buf.Bytes(), 100*native.GASFactor)
tx.Nonce = Nonce()
tx.ValidUntilBlock = bc.BlockHeight() + 1
tx.Signers = []transaction.Signer{{
Account: e.Validator.ScriptHash(),
Scopes: transaction.Global,
}}
addNetworkFee(bc, tx, e.Validator)
require.NoError(t, e.Validator.SignTx(netmode.UnitTestNet, tx))
return tx
}
func addSystemFee(bc blockchainer.Blockchainer, tx *transaction.Transaction, sysFee int64) {
if sysFee >= 0 {
tx.SystemFee = sysFee
return
}
v, _ := TestInvoke(bc, tx) // ignore error to support failing transactions
tx.SystemFee = v.GasConsumed()
}
func addNetworkFee(bc blockchainer.Blockchainer, tx *transaction.Transaction, signers ...Signer) {
baseFee := bc.GetPolicer().GetBaseExecFee()
size := io.GetVarSize(tx)
for _, sgr := range signers {
netFee, sizeDelta := fee.Calculate(baseFee, sgr.Script())
tx.NetworkFee += netFee
size += sizeDelta
}
tx.NetworkFee += int64(size) * bc.FeePerByte()
}
// NewUnsignedBlock creates new unsigned block from txs.
func (e *Executor) NewUnsignedBlock(t *testing.T, txs ...*transaction.Transaction) *block.Block {
lastBlock := e.TopBlock(t)
b := &block.Block{
Header: block.Header{
NextConsensus: e.Validator.ScriptHash(),
Script: transaction.Witness{
VerificationScript: e.Validator.Script(),
},
Timestamp: lastBlock.Timestamp + 1,
},
Transactions: txs,
}
if e.Chain.GetConfig().StateRootInHeader {
b.StateRootEnabled = true
b.PrevStateRoot = e.Chain.GetStateModule().CurrentLocalStateRoot()
}
b.PrevHash = lastBlock.Hash()
b.Index = e.Chain.BlockHeight() + 1
b.RebuildMerkleRoot()
return b
}
// AddNewBlock creates a new block from provided transactions and adds it on bc.
func (e *Executor) AddNewBlock(t *testing.T, txs ...*transaction.Transaction) *block.Block {
b := e.NewUnsignedBlock(t, txs...)
e.SignBlock(b)
require.NoError(t, e.Chain.AddBlock(b))
return b
}
// GenerateNewBlocks adds specified number of empty blocks to the chain.
func (e *Executor) GenerateNewBlocks(t *testing.T, count int) {
for i := 0; i < count; i++ {
e.AddNewBlock(t)
}
}
// SignBlock add validators signature to b.
func (e *Executor) SignBlock(b *block.Block) *block.Block {
invoc := e.Validator.SignHashable(uint32(e.Chain.GetConfig().Magic), b)
b.Script.InvocationScript = invoc
return b
}
// AddBlockCheckHalt is a convenient wrapper over AddBlock and CheckHalt.
func (e *Executor) AddBlockCheckHalt(t *testing.T, txs ...*transaction.Transaction) *block.Block {
b := e.AddNewBlock(t, txs...)
for _, tx := range txs {
e.CheckHalt(t, tx.Hash())
}
return b
}
// TestInvoke creates a test VM with dummy block and executes transaction in it.
func TestInvoke(bc blockchainer.Blockchainer, tx *transaction.Transaction) (*vm.VM, error) {
lastBlock, err := bc.GetBlock(bc.GetHeaderHash(int(bc.BlockHeight())))
if err != nil {
return nil, err
}
b := &block.Block{
Header: block.Header{
Index: bc.BlockHeight() + 1,
Timestamp: lastBlock.Timestamp + 1,
},
}
// `GetTestVM` as well as `Run` can use transaction hash which will set cached value.
// This is unwanted behaviour so we explicitly copy transaction to perform execution.
ttx := *tx
v, f := bc.GetTestVM(trigger.Application, &ttx, b)
defer f()
v.LoadWithFlags(tx.Script, callflag.All)
err = v.Run()
return v, err
}
// GetTransaction returns transaction and its height by the specified hash.
func (e *Executor) GetTransaction(t *testing.T, h util.Uint256) (*transaction.Transaction, uint32) {
tx, height, err := e.Chain.GetTransaction(h)
require.NoError(t, err)
return tx, height
}
// GetBlockByIndex returns block by the specified index.
func (e *Executor) GetBlockByIndex(t *testing.T, idx int) *block.Block {
h := e.Chain.GetHeaderHash(idx)
require.NotEmpty(t, h)
b, err := e.Chain.GetBlock(h)
require.NoError(t, err)
return b
}
// GetTxExecResult returns application execution results for the specified transaction.
func (e *Executor) GetTxExecResult(t *testing.T, h util.Uint256) *state.AppExecResult {
aer, err := e.Chain.GetAppExecResults(h, trigger.Application)
require.NoError(t, err)
require.Equal(t, 1, len(aer))
return &aer[0]
}