neoneo-go/pkg/core/notary_test.go
2022-03-30 19:00:53 +03:00

751 lines
27 KiB
Go

package core_test
import (
"errors"
"fmt"
"math/big"
"math/rand"
"path"
"path/filepath"
"sync"
"testing"
"time"
"github.com/nspcc-dev/neo-go/pkg/config"
"github.com/nspcc-dev/neo-go/pkg/config/netmode"
"github.com/nspcc-dev/neo-go/pkg/core"
"github.com/nspcc-dev/neo-go/pkg/core/block"
"github.com/nspcc-dev/neo-go/pkg/core/mempool"
"github.com/nspcc-dev/neo-go/pkg/core/native/nativenames"
"github.com/nspcc-dev/neo-go/pkg/core/transaction"
"github.com/nspcc-dev/neo-go/pkg/crypto/hash"
"github.com/nspcc-dev/neo-go/pkg/crypto/keys"
"github.com/nspcc-dev/neo-go/pkg/interop/native/roles"
"github.com/nspcc-dev/neo-go/pkg/io"
"github.com/nspcc-dev/neo-go/pkg/neotest"
"github.com/nspcc-dev/neo-go/pkg/neotest/chain"
"github.com/nspcc-dev/neo-go/pkg/network"
"github.com/nspcc-dev/neo-go/pkg/network/payload"
"github.com/nspcc-dev/neo-go/pkg/services/notary"
"github.com/nspcc-dev/neo-go/pkg/smartcontract"
"github.com/nspcc-dev/neo-go/pkg/util"
"github.com/nspcc-dev/neo-go/pkg/vm/opcode"
"github.com/nspcc-dev/neo-go/pkg/vm/stackitem"
"github.com/nspcc-dev/neo-go/pkg/wallet"
"github.com/stretchr/testify/require"
"go.uber.org/zap/zaptest"
)
func getTestNotary(t *testing.T, bc *core.Blockchain, walletPath, pass string, onTx func(tx *transaction.Transaction) error) (*wallet.Account, *notary.Notary, *mempool.Pool) {
mainCfg := config.P2PNotary{
Enabled: true,
UnlockWallet: config.Wallet{
Path: filepath.Join(notaryModulePath, walletPath),
Password: pass,
},
}
cfg := notary.Config{
MainCfg: mainCfg,
Chain: bc,
Log: zaptest.NewLogger(t),
}
mp := mempool.New(10, 1, true)
ntr, err := notary.NewNotary(cfg, netmode.UnitTestNet, mp, onTx)
require.NoError(t, err)
w, err := wallet.NewWalletFromFile(path.Join(notaryModulePath, walletPath))
require.NoError(t, err)
require.NoError(t, w.Accounts[0].Decrypt(pass, w.Scrypt))
return w.Accounts[0], ntr, mp
}
// dupNotaryRequest duplicates notary request by serializing/deserializing it. Use
// it to avoid data races when reusing the same payload. Normal OnNewRequest handler
// never receives the same (as in the same pointer) payload multiple times, even if
// the contents is the same it would be a separate buffer.
func dupNotaryRequest(t *testing.T, p *payload.P2PNotaryRequest) *payload.P2PNotaryRequest {
b, err := p.Bytes()
require.NoError(t, err)
r, err := payload.NewP2PNotaryRequestFromBytes(b)
require.NoError(t, err)
return r
}
func TestNotary(t *testing.T) {
bc, validators, committee := chain.NewMultiWithCustomConfig(t, func(c *config.ProtocolConfiguration) {
c.P2PSigExtensions = true
})
e := neotest.NewExecutor(t, bc, validators, committee)
notaryHash := e.NativeHash(t, nativenames.Notary)
designationSuperInvoker := e.NewInvoker(e.NativeHash(t, nativenames.Designation), validators, committee)
gasValidatorInvoker := e.ValidatorInvoker(e.NativeHash(t, nativenames.Gas))
var (
nonce uint32
nvbDiffFallback uint32 = 20
)
mtx := sync.RWMutex{}
completedTxes := make(map[util.Uint256]*transaction.Transaction)
var unluckies []*payload.P2PNotaryRequest
var (
finalizeWithError bool
choosy bool
)
setFinalizeWithError := func(v bool) {
mtx.Lock()
finalizeWithError = v
mtx.Unlock()
}
setChoosy := func(v bool) {
mtx.Lock()
choosy = v
mtx.Unlock()
}
onTransaction := func(tx *transaction.Transaction) error {
mtx.Lock()
defer mtx.Unlock()
if !choosy {
if completedTxes[tx.Hash()] != nil {
panic("transaction was completed twice")
}
if finalizeWithError {
return errors.New("error while finalizing transaction")
}
completedTxes[tx.Hash()] = tx
return nil
}
for _, unl := range unluckies {
if tx.Hash().Equals(unl.FallbackTransaction.Hash()) {
return errors.New("error while finalizing transaction")
}
}
completedTxes[tx.Hash()] = tx
return nil
}
getCompletedTx := func(t *testing.T, waitForNonNil bool, h util.Uint256) *transaction.Transaction {
if !waitForNonNil {
mtx.RLock()
defer mtx.RUnlock()
return completedTxes[h]
}
var completedTx *transaction.Transaction
require.Eventually(t, func() bool {
mtx.RLock()
defer mtx.RUnlock()
completedTx = completedTxes[h]
return completedTx != nil
}, time.Second*3, time.Millisecond*50, errors.New("main transaction expected to be completed"))
return completedTx
}
acc1, ntr1, mp1 := getTestNotary(t, bc, "./testdata/notary1.json", "one", onTransaction)
acc2, _, _ := getTestNotary(t, bc, "./testdata/notary2.json", "two", onTransaction)
randomAcc, err := keys.NewPrivateKey()
require.NoError(t, err)
bc.SetNotary(ntr1)
bc.RegisterPostBlock(func(f func(*transaction.Transaction, *mempool.Pool, bool) bool, pool *mempool.Pool, b *block.Block) {
ntr1.PostPersist()
})
mp1.RunSubscriptions()
ntr1.Start()
t.Cleanup(func() {
ntr1.Shutdown()
mp1.StopSubscriptions()
})
notaryNodes := []interface{}{acc1.PrivateKey().PublicKey().Bytes(), acc2.PrivateKey().PublicKey().Bytes()}
designationSuperInvoker.Invoke(t, stackitem.Null{}, "designateAsRole",
int64(roles.P2PNotary), notaryNodes)
type requester struct {
accounts []*wallet.Account
m int
typ notary.RequestType
}
createFallbackTx := func(requester *wallet.Account, mainTx *transaction.Transaction, nvbIncrement ...uint32) *transaction.Transaction {
fallback := transaction.New([]byte{byte(opcode.RET)}, 2000_0000)
fallback.Nonce = nonce
nonce++
fallback.SystemFee = 1_0000_0000
fallback.ValidUntilBlock = bc.BlockHeight() + 2*nvbDiffFallback
fallback.Signers = []transaction.Signer{
{
Account: bc.GetNotaryContractScriptHash(),
Scopes: transaction.None,
},
{
Account: requester.PrivateKey().PublicKey().GetScriptHash(),
Scopes: transaction.None,
},
}
nvb := bc.BlockHeight() + nvbDiffFallback
if len(nvbIncrement) != 0 {
nvb += nvbIncrement[0]
}
fallback.Attributes = []transaction.Attribute{
{
Type: transaction.NotaryAssistedT,
Value: &transaction.NotaryAssisted{NKeys: 0},
},
{
Type: transaction.NotValidBeforeT,
Value: &transaction.NotValidBefore{Height: nvb},
},
{
Type: transaction.ConflictsT,
Value: &transaction.Conflicts{Hash: mainTx.Hash()},
},
}
fallback.Scripts = []transaction.Witness{
{
InvocationScript: append([]byte{byte(opcode.PUSHDATA1), 64}, make([]byte, 64)...),
VerificationScript: []byte{},
},
}
err = requester.SignTx(netmode.UnitTestNet, fallback)
require.NoError(t, err)
return fallback
}
createMixedRequest := func(requesters []requester, NVBincrements ...uint32) []*payload.P2PNotaryRequest {
mainTx := *transaction.New([]byte{byte(opcode.RET)}, 11000000)
mainTx.Nonce = nonce
nonce++
mainTx.SystemFee = 100000000
mainTx.ValidUntilBlock = bc.BlockHeight() + 2*nvbDiffFallback
signers := make([]transaction.Signer, len(requesters)+1)
var (
nKeys uint8
verificationScripts [][]byte
)
for i := range requesters {
var script []byte
switch requesters[i].typ {
case notary.Signature:
script = requesters[i].accounts[0].PrivateKey().PublicKey().GetVerificationScript()
nKeys++
case notary.MultiSignature:
pubs := make(keys.PublicKeys, len(requesters[i].accounts))
for j, r := range requesters[i].accounts {
pubs[j] = r.PrivateKey().PublicKey()
}
script, err = smartcontract.CreateMultiSigRedeemScript(requesters[i].m, pubs)
require.NoError(t, err)
nKeys += uint8(len(requesters[i].accounts))
}
signers[i] = transaction.Signer{
Account: hash.Hash160(script),
Scopes: transaction.None,
}
verificationScripts = append(verificationScripts, script)
}
signers[len(signers)-1] = transaction.Signer{
Account: bc.GetNotaryContractScriptHash(),
Scopes: transaction.None,
}
mainTx.Signers = signers
mainTx.Attributes = []transaction.Attribute{
{
Type: transaction.NotaryAssistedT,
Value: &transaction.NotaryAssisted{NKeys: nKeys},
},
}
payloads := make([]*payload.P2PNotaryRequest, nKeys)
plIndex := 0
// we'll collect only m signatures out of n (so only m payloads are needed), but let's create payloads for all requesters (for the next tests)
for i, r := range requesters {
for _, acc := range r.accounts {
cp := mainTx
main := &cp
main.Scripts = make([]transaction.Witness, len(requesters))
for j := range main.Scripts {
main.Scripts[j].VerificationScript = verificationScripts[j]
if i == j {
main.Scripts[j].InvocationScript = append([]byte{byte(opcode.PUSHDATA1), 64}, acc.PrivateKey().SignHashable(uint32(netmode.UnitTestNet), main)...)
}
}
main.Scripts = append(main.Scripts, transaction.Witness{}) // empty Notary witness
_ = main.Size() // for size update test
var fallback *transaction.Transaction
if len(NVBincrements) == int(nKeys) {
fallback = createFallbackTx(acc, main, NVBincrements[plIndex])
} else {
fallback = createFallbackTx(acc, main)
}
_ = fallback.Size() // for size update test
payloads[plIndex] = &payload.P2PNotaryRequest{
MainTransaction: main,
FallbackTransaction: fallback,
}
plIndex++
}
}
return payloads
}
checkMainTx := func(t *testing.T, requesters []requester, requests []*payload.P2PNotaryRequest, sentCount int, shouldComplete bool) {
nSigs := 0
for _, r := range requesters {
switch r.typ {
case notary.Signature:
nSigs++
case notary.MultiSignature:
nSigs += r.m
}
}
nSigners := len(requesters) + 1
if sentCount >= nSigs && shouldComplete {
completedTx := getCompletedTx(t, true, requests[0].MainTransaction.Hash())
require.Equal(t, nSigners, len(completedTx.Signers))
require.Equal(t, nSigners, len(completedTx.Scripts))
// check that tx size was updated
require.Equal(t, io.GetVarSize(completedTx), completedTx.Size())
for i := 0; i < len(completedTx.Scripts)-1; i++ {
_, err := bc.VerifyWitness(completedTx.Signers[i].Account, completedTx, &completedTx.Scripts[i], -1)
require.NoError(t, err)
}
require.Equal(t, transaction.Witness{
InvocationScript: append([]byte{byte(opcode.PUSHDATA1), 64}, acc1.PrivateKey().SignHashable(uint32(netmode.UnitTestNet), requests[0].MainTransaction)...),
VerificationScript: []byte{},
}, completedTx.Scripts[len(completedTx.Scripts)-1])
} else {
completedTx := getCompletedTx(t, false, requests[0].MainTransaction.Hash())
require.Nil(t, completedTx, fmt.Errorf("main transaction shouldn't be completed: sent %d out of %d requests", sentCount, nSigs))
}
}
checkFallbackTxs := func(t *testing.T, requests []*payload.P2PNotaryRequest, shouldComplete bool) {
for i, req := range requests {
if shouldComplete {
completedTx := getCompletedTx(t, true, req.FallbackTransaction.Hash())
require.Equal(t, 2, len(completedTx.Signers))
require.Equal(t, 2, len(completedTx.Scripts))
require.Equal(t, transaction.Witness{
InvocationScript: append([]byte{byte(opcode.PUSHDATA1), 64}, acc1.PrivateKey().SignHashable(uint32(netmode.UnitTestNet), req.FallbackTransaction)...),
VerificationScript: []byte{},
}, completedTx.Scripts[0])
// check that tx size was updated
require.Equal(t, io.GetVarSize(completedTx), completedTx.Size())
_, err := bc.VerifyWitness(completedTx.Signers[1].Account, completedTx, &completedTx.Scripts[1], -1)
require.NoError(t, err)
} else {
completedTx := getCompletedTx(t, false, req.FallbackTransaction.Hash())
require.Nil(t, completedTx, fmt.Errorf("fallback transaction for request #%d shouldn't be completed", i))
}
}
}
checkCompleteStandardRequest := func(t *testing.T, nKeys int, shouldComplete bool, nvbIncrements ...uint32) ([]*payload.P2PNotaryRequest, []requester) {
requesters := make([]requester, nKeys)
for i := range requesters {
acc, _ := wallet.NewAccount()
requesters[i] = requester{
accounts: []*wallet.Account{acc},
typ: notary.Signature,
}
}
requests := createMixedRequest(requesters, nvbIncrements...)
sendOrder := make([]int, nKeys)
for i := range sendOrder {
sendOrder[i] = i
}
rand.Shuffle(nKeys, func(i, j int) {
sendOrder[j], sendOrder[i] = sendOrder[i], sendOrder[j]
})
for i := range requests {
ntr1.OnNewRequest(requests[sendOrder[i]])
checkMainTx(t, requesters, requests, i+1, shouldComplete)
completedCount := len(completedTxes)
// check that the same request won't be processed twice
ntr1.OnNewRequest(dupNotaryRequest(t, requests[sendOrder[i]]))
checkMainTx(t, requesters, requests, i+1, shouldComplete)
require.Equal(t, completedCount, len(completedTxes))
}
return requests, requesters
}
checkCompleteMultisigRequest := func(t *testing.T, nSigs int, nKeys int, shouldComplete bool) ([]*payload.P2PNotaryRequest, []requester) {
accounts := make([]*wallet.Account, nKeys)
for i := range accounts {
accounts[i], _ = wallet.NewAccount()
}
requesters := []requester{
{
accounts: accounts,
m: nSigs,
typ: notary.MultiSignature,
},
}
requests := createMixedRequest(requesters)
sendOrder := make([]int, nKeys)
for i := range sendOrder {
sendOrder[i] = i
}
rand.Shuffle(nKeys, func(i, j int) {
sendOrder[j], sendOrder[i] = sendOrder[i], sendOrder[j]
})
var submittedRequests []*payload.P2PNotaryRequest
// sent only nSigs (m out of n) requests - it should be enough to complete min tx
for i := 0; i < nSigs; i++ {
submittedRequests = append(submittedRequests, requests[sendOrder[i]])
ntr1.OnNewRequest(requests[sendOrder[i]])
checkMainTx(t, requesters, submittedRequests, i+1, shouldComplete)
// check that the same request won't be processed twice
ntr1.OnNewRequest(dupNotaryRequest(t, requests[sendOrder[i]]))
checkMainTx(t, requesters, submittedRequests, i+1, shouldComplete)
}
// sent the rest (n-m) out of n requests: main tx is already collected, so only fallbacks should be applied
completedCount := len(completedTxes)
for i := nSigs; i < nKeys; i++ {
submittedRequests = append(submittedRequests, requests[sendOrder[i]])
ntr1.OnNewRequest(requests[sendOrder[i]])
checkMainTx(t, requesters, submittedRequests, i+1, shouldComplete)
require.Equal(t, completedCount, len(completedTxes))
}
return submittedRequests, requesters
}
checkCompleteMixedRequest := func(t *testing.T, nSigSigners int, shouldComplete bool) ([]*payload.P2PNotaryRequest, []requester) {
requesters := make([]requester, nSigSigners)
for i := range requesters {
acc, _ := wallet.NewAccount()
requesters[i] = requester{
accounts: []*wallet.Account{acc},
typ: notary.Signature,
}
}
multisigAccounts := make([]*wallet.Account, 3)
for i := range multisigAccounts {
multisigAccounts[i], _ = wallet.NewAccount()
}
requesters = append(requesters, requester{
accounts: multisigAccounts,
m: 2,
typ: notary.MultiSignature,
})
requests := createMixedRequest(requesters)
for i := range requests {
ntr1.OnNewRequest(requests[i])
checkMainTx(t, requesters, requests, i+1, shouldComplete)
completedCount := len(completedTxes)
// check that the same request won't be processed twice
ntr1.OnNewRequest(dupNotaryRequest(t, requests[i]))
checkMainTx(t, requesters, requests, i+1, shouldComplete)
require.Equal(t, completedCount, len(completedTxes))
}
return requests, requesters
}
// OnNewRequest: missing account
ntr1.UpdateNotaryNodes(keys.PublicKeys{randomAcc.PublicKey()})
r, _ := checkCompleteStandardRequest(t, 1, false)
checkFallbackTxs(t, r, false)
// set account back for the next tests
ntr1.UpdateNotaryNodes(keys.PublicKeys{acc1.PrivateKey().PublicKey()})
// OnNewRequest: signature request
for _, i := range []int{1, 2, 3, 10} {
r, _ := checkCompleteStandardRequest(t, i, true)
checkFallbackTxs(t, r, false)
}
// OnNewRequest: multisignature request
r, _ = checkCompleteMultisigRequest(t, 1, 1, true)
checkFallbackTxs(t, r, false)
r, _ = checkCompleteMultisigRequest(t, 1, 2, true)
checkFallbackTxs(t, r, false)
r, _ = checkCompleteMultisigRequest(t, 1, 3, true)
checkFallbackTxs(t, r, false)
r, _ = checkCompleteMultisigRequest(t, 3, 3, true)
checkFallbackTxs(t, r, false)
r, _ = checkCompleteMultisigRequest(t, 3, 4, true)
checkFallbackTxs(t, r, false)
r, _ = checkCompleteMultisigRequest(t, 3, 10, true)
checkFallbackTxs(t, r, false)
// OnNewRequest: mixed request
r, _ = checkCompleteMixedRequest(t, 1, true)
checkFallbackTxs(t, r, false)
r, _ = checkCompleteMixedRequest(t, 2, true)
checkFallbackTxs(t, r, false)
r, _ = checkCompleteMixedRequest(t, 3, true)
checkFallbackTxs(t, r, false)
// PostPersist: missing account
setFinalizeWithError(true)
r, requesters := checkCompleteStandardRequest(t, 1, false)
checkFallbackTxs(t, r, false)
ntr1.UpdateNotaryNodes(keys.PublicKeys{randomAcc.PublicKey()})
setFinalizeWithError(false)
e.AddNewBlock(t)
checkMainTx(t, requesters, r, 1, false)
checkFallbackTxs(t, r, false)
// set account back for the next tests
ntr1.UpdateNotaryNodes(keys.PublicKeys{acc1.PrivateKey().PublicKey()})
// PostPersist: complete main transaction, signature request
setFinalizeWithError(true)
requests, requesters := checkCompleteStandardRequest(t, 3, false)
// check PostPersist with finalisation error
setFinalizeWithError(true)
e.AddNewBlock(t)
checkMainTx(t, requesters, requests, len(requests), false)
// check PostPersist without finalisation error
setFinalizeWithError(false)
e.AddNewBlock(t)
checkMainTx(t, requesters, requests, len(requests), true)
// PostPersist: complete main transaction, multisignature account
setFinalizeWithError(true)
requests, requesters = checkCompleteMultisigRequest(t, 3, 4, false)
checkFallbackTxs(t, requests, false)
// check PostPersist with finalisation error
setFinalizeWithError(true)
e.AddNewBlock(t)
checkMainTx(t, requesters, requests, len(requests), false)
checkFallbackTxs(t, requests, false)
// check PostPersist without finalisation error
setFinalizeWithError(false)
e.AddNewBlock(t)
checkMainTx(t, requesters, requests, len(requests), true)
checkFallbackTxs(t, requests, false)
// PostPersist: complete fallback, signature request
setFinalizeWithError(true)
requests, requesters = checkCompleteStandardRequest(t, 3, false)
checkFallbackTxs(t, requests, false)
// make fallbacks valid
e.GenerateNewBlocks(t, int(nvbDiffFallback))
require.NoError(t, err)
// check PostPersist for valid fallbacks with finalisation error
e.AddNewBlock(t)
checkMainTx(t, requesters, requests, len(requests), false)
checkFallbackTxs(t, requests, false)
// check PostPersist for valid fallbacks without finalisation error
setFinalizeWithError(false)
e.AddNewBlock(t)
checkMainTx(t, requesters, requests, len(requests), false)
checkFallbackTxs(t, requests, true)
// PostPersist: complete fallback, multisignature request
nSigs, nKeys := 3, 5
// check OnNewRequest with finalization error
setFinalizeWithError(true)
requests, requesters = checkCompleteMultisigRequest(t, nSigs, nKeys, false)
checkFallbackTxs(t, requests, false)
// make fallbacks valid
e.GenerateNewBlocks(t, int(nvbDiffFallback))
require.NoError(t, err)
// check PostPersist for valid fallbacks with finalisation error
e.AddNewBlock(t)
checkMainTx(t, requesters, requests, len(requests), false)
checkFallbackTxs(t, requests, false)
// check PostPersist for valid fallbacks without finalisation error
setFinalizeWithError(false)
e.AddNewBlock(t)
checkMainTx(t, requesters, requests, len(requests), false)
checkFallbackTxs(t, requests[:nSigs], true)
// the rest of fallbacks should also be applied even if the main tx was already constructed by the moment they were sent
checkFallbackTxs(t, requests[nSigs:], true)
// PostPersist: partial fallbacks completion due to finalisation errors
setFinalizeWithError(true)
requests, requesters = checkCompleteStandardRequest(t, 5, false)
checkFallbackTxs(t, requests, false)
// make fallbacks valid
e.GenerateNewBlocks(t, int(nvbDiffFallback))
require.NoError(t, err)
// some of fallbacks should fail finalisation
unluckies = []*payload.P2PNotaryRequest{requests[0], requests[4]}
lucky := requests[1:4]
setChoosy(true)
// check PostPersist for lucky fallbacks
e.AddNewBlock(t)
checkMainTx(t, requesters, requests, len(requests), false)
checkFallbackTxs(t, lucky, true)
checkFallbackTxs(t, unluckies, false)
// reset finalisation function for unlucky fallbacks to finalise without an error
setChoosy(false)
setFinalizeWithError(false)
// check PostPersist for unlucky fallbacks
e.AddNewBlock(t)
checkMainTx(t, requesters, requests, len(requests), false)
checkFallbackTxs(t, lucky, true)
checkFallbackTxs(t, unluckies, true)
// PostPersist: different NVBs
// check OnNewRequest with finalization error and different NVBs
setFinalizeWithError(true)
requests, requesters = checkCompleteStandardRequest(t, 5, false, 1, 2, 3, 4, 5)
checkFallbackTxs(t, requests, false)
// generate blocks to reach the most earlier fallback's NVB
e.GenerateNewBlocks(t, int(nvbDiffFallback))
require.NoError(t, err)
// check PostPersist for valid fallbacks without finalisation error
// Add block before allowing tx to finalize to exclude race condition when
// main transaction is finalized between `finalizeWithError` restore and adding new block.
e.AddNewBlock(t)
mtx.RLock()
start := len(completedTxes)
mtx.RUnlock()
setFinalizeWithError(false)
for i := range requests {
if i != 0 {
e.AddNewBlock(t)
}
require.Eventually(t, func() bool {
mtx.RLock()
defer mtx.RUnlock()
return len(completedTxes)-start >= i+1
}, time.Second*3, time.Millisecond)
checkMainTx(t, requesters, requests, len(requests), false)
checkFallbackTxs(t, requests[:i+1], true)
checkFallbackTxs(t, requests[i+1:], false)
}
// OnRequestRemoval: missing account
// check OnNewRequest with finalization error
setFinalizeWithError(true)
requests, requesters = checkCompleteStandardRequest(t, 4, false)
checkFallbackTxs(t, requests, false)
// make fallbacks valid and remove one fallback
e.GenerateNewBlocks(t, int(nvbDiffFallback))
require.NoError(t, err)
ntr1.UpdateNotaryNodes(keys.PublicKeys{randomAcc.PublicKey()})
ntr1.OnRequestRemoval(requests[3])
// non of the fallbacks should be completed
setFinalizeWithError(false)
e.AddNewBlock(t)
checkMainTx(t, requesters, requests, len(requests), false)
checkFallbackTxs(t, requests, false)
// set account back for the next tests
ntr1.UpdateNotaryNodes(keys.PublicKeys{acc1.PrivateKey().PublicKey()})
// OnRequestRemoval: signature request, remove one fallback
// check OnNewRequest with finalization error
setFinalizeWithError(true)
requests, requesters = checkCompleteStandardRequest(t, 4, false)
checkFallbackTxs(t, requests, false)
// make fallbacks valid and remove one fallback
e.GenerateNewBlocks(t, int(nvbDiffFallback))
require.NoError(t, err)
unlucky := requests[3]
ntr1.OnRequestRemoval(unlucky)
// rest of the fallbacks should be completed
setFinalizeWithError(false)
e.AddNewBlock(t)
checkMainTx(t, requesters, requests, len(requests), false)
checkFallbackTxs(t, requests[:3], true)
require.Nil(t, completedTxes[unlucky.FallbackTransaction.Hash()])
// OnRequestRemoval: signature request, remove all fallbacks
setFinalizeWithError(true)
requests, requesters = checkCompleteStandardRequest(t, 4, false)
// remove all fallbacks
e.GenerateNewBlocks(t, int(nvbDiffFallback))
require.NoError(t, err)
for i := range requests {
ntr1.OnRequestRemoval(requests[i])
}
// then the whole request should be removed, i.e. there are no completed transactions
setFinalizeWithError(false)
e.AddNewBlock(t)
checkMainTx(t, requesters, requests, len(requests), false)
checkFallbackTxs(t, requests, false)
// OnRequestRemoval: signature request, remove unexisting fallback
ntr1.OnRequestRemoval(requests[0])
e.AddNewBlock(t)
checkMainTx(t, requesters, requests, len(requests), false)
checkFallbackTxs(t, requests, false)
// OnRequestRemoval: multisignature request, remove one fallback
nSigs, nKeys = 3, 5
// check OnNewRequest with finalization error
setFinalizeWithError(true)
requests, requesters = checkCompleteMultisigRequest(t, nSigs, nKeys, false)
checkMainTx(t, requesters, requests, len(requests), false)
checkFallbackTxs(t, requests, false)
// make fallbacks valid and remove the last fallback
e.GenerateNewBlocks(t, int(nvbDiffFallback))
require.NoError(t, err)
unlucky = requests[nSigs-1]
ntr1.OnRequestRemoval(unlucky)
// then (m-1) out of n fallbacks should be completed
setFinalizeWithError(false)
e.AddNewBlock(t)
checkMainTx(t, requesters, requests, len(requests), false)
checkFallbackTxs(t, requests[:nSigs-1], true)
require.Nil(t, completedTxes[unlucky.FallbackTransaction.Hash()])
// the rest (n-(m-1)) out of n fallbacks should also be completed even if main tx has been collected by the moment they were sent
checkFallbackTxs(t, requests[nSigs:], true)
// OnRequestRemoval: multisignature request, remove all fallbacks
setFinalizeWithError(true)
requests, requesters = checkCompleteMultisigRequest(t, nSigs, nKeys, false)
// make fallbacks valid and then remove all of them
e.GenerateNewBlocks(t, int(nvbDiffFallback))
require.NoError(t, err)
for i := range requests {
ntr1.OnRequestRemoval(requests[i])
}
// then the whole request should be removed, i.e. there are no completed transactions
setFinalizeWithError(false)
e.AddNewBlock(t)
checkMainTx(t, requesters, requests, len(requests), false)
checkFallbackTxs(t, requests, false)
// // OnRequestRemoval: multisignature request, remove unexisting fallbac, i.e. there still shouldn't be any completed transactions after this
ntr1.OnRequestRemoval(requests[0])
e.AddNewBlock(t)
checkMainTx(t, requesters, requests, len(requests), false)
checkFallbackTxs(t, requests, false)
// Subscriptions test
setFinalizeWithError(false)
requester1, _ := wallet.NewAccount()
requester2, _ := wallet.NewAccount()
amount := int64(100_0000_0000)
gasValidatorInvoker.Invoke(t, true, "transfer", e.Validator.ScriptHash(), bc.GetNotaryContractScriptHash(), amount, []interface{}{requester1.PrivateKey().PublicKey().GetScriptHash(), int64(bc.BlockHeight() + 50)})
e.CheckGASBalance(t, notaryHash, big.NewInt(amount))
gasValidatorInvoker.Invoke(t, true, "transfer", e.Validator.ScriptHash(), bc.GetNotaryContractScriptHash(), amount, []interface{}{requester2.PrivateKey().PublicKey().GetScriptHash(), int64(bc.BlockHeight() + 50)})
e.CheckGASBalance(t, notaryHash, big.NewInt(2*amount))
// create request for 2 standard signatures => main tx should be completed after the second request is added to the pool
requests = createMixedRequest([]requester{
{
accounts: []*wallet.Account{requester1},
typ: notary.Signature,
},
{
accounts: []*wallet.Account{requester2},
typ: notary.Signature,
},
})
feer := network.NewNotaryFeer(bc)
require.NoError(t, mp1.Add(requests[0].FallbackTransaction, feer, requests[0]))
require.NoError(t, mp1.Add(requests[1].FallbackTransaction, feer, requests[1]))
require.Eventually(t, func() bool {
mtx.RLock()
defer mtx.RUnlock()
return completedTxes[requests[0].MainTransaction.Hash()] != nil
}, 3*time.Second, 100*time.Millisecond)
checkFallbackTxs(t, requests, false)
}