package core import ( "errors" "math/big" "math/rand" "testing" "time" "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/interop/interopnames" "github.com/nspcc-dev/neo-go/pkg/core/mempool" "github.com/nspcc-dev/neo-go/pkg/core/native" "github.com/nspcc-dev/neo-go/pkg/core/state" "github.com/nspcc-dev/neo-go/pkg/core/storage" "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/internal/testchain" "github.com/nspcc-dev/neo-go/pkg/io" "github.com/nspcc-dev/neo-go/pkg/smartcontract" "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/opcode" "github.com/nspcc-dev/neo-go/pkg/vm/stackitem" "github.com/nspcc-dev/neo-go/pkg/wallet" "github.com/stretchr/testify/assert" "github.com/stretchr/testify/require" ) func TestVerifyHeader(t *testing.T) { bc := newTestChain(t) defer bc.Close() prev := bc.topBlock.Load().(*block.Block).Header() t.Run("Invalid", func(t *testing.T) { t.Run("Hash", func(t *testing.T) { h := prev.Hash() h[0] = ^h[0] hdr := newBlock(bc.config, 1, h).Header() require.True(t, errors.Is(bc.verifyHeader(hdr, prev), ErrHdrHashMismatch)) }) t.Run("Index", func(t *testing.T) { hdr := newBlock(bc.config, 3, prev.Hash()).Header() require.True(t, errors.Is(bc.verifyHeader(hdr, prev), ErrHdrIndexMismatch)) }) t.Run("Timestamp", func(t *testing.T) { hdr := newBlock(bc.config, 1, prev.Hash()).Header() hdr.Timestamp = 0 require.True(t, errors.Is(bc.verifyHeader(hdr, prev), ErrHdrInvalidTimestamp)) }) }) t.Run("Valid", func(t *testing.T) { hdr := newBlock(bc.config, 1, prev.Hash()).Header() require.NoError(t, bc.verifyHeader(hdr, prev)) }) } func TestAddHeaders(t *testing.T) { bc := newTestChain(t) defer bc.Close() lastBlock := bc.topBlock.Load().(*block.Block) h1 := newBlock(bc.config, 1, lastBlock.Hash()).Header() h2 := newBlock(bc.config, 2, h1.Hash()).Header() h3 := newBlock(bc.config, 3, h2.Hash()).Header() require.NoError(t, bc.AddHeaders()) require.NoError(t, bc.AddHeaders(h1, h2)) require.NoError(t, bc.AddHeaders(h2, h3)) assert.Equal(t, h3.Index, bc.HeaderHeight()) assert.Equal(t, uint32(0), bc.BlockHeight()) assert.Equal(t, h3.Hash(), bc.CurrentHeaderHash()) // Add them again, they should not be added. require.NoError(t, bc.AddHeaders(h3, h2, h1)) assert.Equal(t, h3.Index, bc.HeaderHeight()) assert.Equal(t, uint32(0), bc.BlockHeight()) assert.Equal(t, h3.Hash(), bc.CurrentHeaderHash()) h4 := newBlock(bc.config, 4, h3.Hash().Reverse()).Header() h5 := newBlock(bc.config, 5, h4.Hash()).Header() assert.Error(t, bc.AddHeaders(h4, h5)) assert.Equal(t, h3.Index, bc.HeaderHeight()) assert.Equal(t, uint32(0), bc.BlockHeight()) assert.Equal(t, h3.Hash(), bc.CurrentHeaderHash()) h6 := newBlock(bc.config, 4, h3.Hash()).Header() h6.Script.InvocationScript = nil assert.Error(t, bc.AddHeaders(h6)) assert.Equal(t, h3.Index, bc.HeaderHeight()) assert.Equal(t, uint32(0), bc.BlockHeight()) assert.Equal(t, h3.Hash(), bc.CurrentHeaderHash()) } func TestAddBlock(t *testing.T) { const size = 3 bc := newTestChain(t) blocks, err := bc.genBlocks(size) require.NoError(t, err) lastBlock := blocks[len(blocks)-1] assert.Equal(t, lastBlock.Index, bc.HeaderHeight()) assert.Equal(t, lastBlock.Hash(), bc.CurrentHeaderHash()) // This one tests persisting blocks, so it does need to persist() require.NoError(t, bc.persist()) for _, block := range blocks { key := storage.AppendPrefix(storage.DataBlock, block.Hash().BytesLE()) _, err := bc.dao.Store.Get(key) require.NoErrorf(t, err, "block %s not persisted", block.Hash()) } assert.Equal(t, lastBlock.Index, bc.BlockHeight()) assert.Equal(t, lastBlock.Hash(), bc.CurrentHeaderHash()) } func TestAddBadBlock(t *testing.T) { bc := newTestChain(t) defer bc.Close() // It has ValidUntilBlock == 0, which is wrong tx := transaction.New(netmode.UnitTestNet, []byte{byte(opcode.PUSH1)}, 0) tx.Signers = []transaction.Signer{{ Account: testchain.MultisigScriptHash(), Scopes: transaction.None, }} require.NoError(t, signTx(bc, tx)) b1 := bc.newBlock(tx) require.Error(t, bc.AddBlock(b1)) bc.config.VerifyTransactions = false require.NoError(t, bc.AddBlock(b1)) b2 := bc.newBlock() b2.PrevHash = util.Uint256{} require.Error(t, bc.AddBlock(b2)) bc.config.VerifyBlocks = false require.NoError(t, bc.AddBlock(b2)) tx = transaction.New(netmode.UnitTestNet, []byte{byte(opcode.PUSH1)}, 0) tx.ValidUntilBlock = 128 tx.Signers = []transaction.Signer{{ Account: testchain.MultisigScriptHash(), Scopes: transaction.None, }} require.NoError(t, signTx(bc, tx)) require.NoError(t, bc.PoolTx(tx)) bc.config.VerifyTransactions = true bc.config.VerifyBlocks = true b3 := bc.newBlock(tx) require.NoError(t, bc.AddBlock(b3)) } func TestGetHeader(t *testing.T) { bc := newTestChain(t) tx := transaction.New(netmode.UnitTestNet, []byte{byte(opcode.PUSH1)}, 0) tx.ValidUntilBlock = bc.BlockHeight() + 1 addSigners(tx) assert.Nil(t, signTx(bc, tx)) block := bc.newBlock(tx) err := bc.AddBlock(block) assert.Nil(t, err) // Test unpersisted and persisted access for i := 0; i < 2; i++ { hash := block.Hash() header, err := bc.GetHeader(hash) require.NoError(t, err) assert.Equal(t, block.Header(), header) b2 := bc.newBlock() _, err = bc.GetHeader(b2.Hash()) assert.Error(t, err) assert.NoError(t, bc.persist()) } } func TestGetBlock(t *testing.T) { bc := newTestChain(t) blocks, err := bc.genBlocks(100) require.NoError(t, err) // Test unpersisted and persisted access for j := 0; j < 2; j++ { for i := 0; i < len(blocks); i++ { block, err := bc.GetBlock(blocks[i].Hash()) require.NoErrorf(t, err, "can't get block %d: %s, attempt %d", i, err, j) assert.Equal(t, blocks[i].Index, block.Index) assert.Equal(t, blocks[i].Hash(), block.Hash()) } assert.NoError(t, bc.persist()) } } func (bc *Blockchain) newTestTx(h util.Uint160, script []byte) *transaction.Transaction { tx := transaction.New(testchain.Network(), script, 1_000_000) tx.Nonce = rand.Uint32() tx.ValidUntilBlock = 100 tx.Signers = []transaction.Signer{{ Account: h, Scopes: transaction.CalledByEntry, }} tx.NetworkFee = int64(io.GetVarSize(tx)+200 /* witness */) * bc.FeePerByte() tx.NetworkFee += 1_000_000 // verification cost return tx } func TestVerifyTx(t *testing.T) { bc := newTestChain(t) defer bc.Close() accs := make([]*wallet.Account, 5) for i := range accs { var err error accs[i], err = wallet.NewAccount() require.NoError(t, err) } oracleAcc := accs[2] oraclePubs := keys.PublicKeys{oracleAcc.PrivateKey().PublicKey()} require.NoError(t, oracleAcc.ConvertMultisig(1, oraclePubs)) neoHash := bc.contracts.NEO.Hash gasHash := bc.contracts.GAS.Hash w := io.NewBufBinWriter() for _, sc := range []util.Uint160{neoHash, gasHash} { for _, a := range accs { amount := int64(1_000_000) if sc.Equals(gasHash) { amount = 1_000_000_000 } emit.AppCallWithOperationAndArgs(w.BinWriter, sc, "transfer", neoOwner, a.Contract.ScriptHash(), amount) emit.Opcodes(w.BinWriter, opcode.ASSERT) } } emit.AppCallWithOperationAndArgs(w.BinWriter, gasHash, "transfer", neoOwner, testchain.CommitteeScriptHash(), int64(1_000_000_000)) emit.Opcodes(w.BinWriter, opcode.ASSERT) require.NoError(t, w.Err) txMove := bc.newTestTx(neoOwner, w.Bytes()) txMove.SystemFee = 1_000_000_000 require.NoError(t, signTx(bc, txMove)) b := bc.newBlock(txMove) require.NoError(t, bc.AddBlock(b)) aer, err := bc.GetAppExecResult(txMove.Hash()) require.NoError(t, err) require.Equal(t, aer.VMState, vm.HaltState) res, err := invokeNativePolicyMethod(bc, "blockAccount", accs[1].PrivateKey().GetScriptHash().BytesBE()) require.NoError(t, err) checkResult(t, res, stackitem.NewBool(true)) checkErr := func(t *testing.T, expectedErr error, tx *transaction.Transaction) { err := bc.VerifyTx(tx) require.True(t, errors.Is(err, expectedErr), "expected: %v, got: %v", expectedErr, err) } testScript := []byte{byte(opcode.PUSH1)} h := accs[0].PrivateKey().GetScriptHash() t.Run("Expired", func(t *testing.T) { tx := bc.newTestTx(h, testScript) tx.ValidUntilBlock = 1 require.NoError(t, accs[0].SignTx(tx)) checkErr(t, ErrTxExpired, tx) }) t.Run("BlockedAccount", func(t *testing.T) { tx := bc.newTestTx(accs[1].PrivateKey().GetScriptHash(), testScript) require.NoError(t, accs[1].SignTx(tx)) err := bc.VerifyTx(tx) require.True(t, errors.Is(err, ErrPolicy)) }) t.Run("InsufficientGas", func(t *testing.T) { balance := bc.GetUtilityTokenBalance(h) tx := bc.newTestTx(h, testScript) tx.SystemFee = balance.Int64() + 1 require.NoError(t, accs[0].SignTx(tx)) checkErr(t, ErrInsufficientFunds, tx) }) t.Run("TooBigTx", func(t *testing.T) { script := make([]byte, transaction.MaxTransactionSize) tx := bc.newTestTx(h, script) require.NoError(t, accs[0].SignTx(tx)) checkErr(t, ErrTxTooBig, tx) }) t.Run("NetworkFee", func(t *testing.T) { t.Run("SmallNetworkFee", func(t *testing.T) { tx := bc.newTestTx(h, testScript) tx.NetworkFee = 1 require.NoError(t, accs[0].SignTx(tx)) checkErr(t, ErrTxSmallNetworkFee, tx) }) t.Run("AlmostEnoughNetworkFee", func(t *testing.T) { tx := bc.newTestTx(h, testScript) verificationNetFee, calcultedScriptSize := CalculateNetworkFee(accs[0].Contract.Script) expectedSize := io.GetVarSize(tx) + calcultedScriptSize calculatedNetFee := verificationNetFee + int64(expectedSize)*bc.FeePerByte() tx.NetworkFee = calculatedNetFee - 1 require.NoError(t, accs[0].SignTx(tx)) require.Equal(t, expectedSize, io.GetVarSize(tx)) checkErr(t, ErrVerificationFailed, tx) }) t.Run("EnoughNetworkFee", func(t *testing.T) { tx := bc.newTestTx(h, testScript) verificationNetFee, calcultedScriptSize := CalculateNetworkFee(accs[0].Contract.Script) expectedSize := io.GetVarSize(tx) + calcultedScriptSize calculatedNetFee := verificationNetFee + int64(expectedSize)*bc.FeePerByte() tx.NetworkFee = calculatedNetFee require.NoError(t, accs[0].SignTx(tx)) require.Equal(t, expectedSize, io.GetVarSize(tx)) require.NoError(t, bc.VerifyTx(tx)) }) t.Run("CalculateNetworkFee, signature script", func(t *testing.T) { tx := bc.newTestTx(h, testScript) expectedSize := io.GetVarSize(tx) verificationNetFee, calculatedScriptSize := CalculateNetworkFee(accs[0].Contract.Script) expectedSize += calculatedScriptSize expectedNetFee := verificationNetFee + int64(expectedSize)*bc.FeePerByte() tx.NetworkFee = expectedNetFee require.NoError(t, accs[0].SignTx(tx)) actualSize := io.GetVarSize(tx) require.Equal(t, expectedSize, actualSize) interopCtx := bc.newInteropContext(trigger.Verification, bc.dao, nil, tx) gasConsumed, err := bc.verifyHashAgainstScript(h, &tx.Scripts[0], interopCtx, -1) require.NoError(t, err) require.Equal(t, verificationNetFee, gasConsumed) require.Equal(t, expectedNetFee, bc.FeePerByte()*int64(actualSize)+gasConsumed) }) t.Run("CalculateNetworkFee, multisignature script", func(t *testing.T) { multisigAcc := accs[4] pKeys := keys.PublicKeys{multisigAcc.PrivateKey().PublicKey()} require.NoError(t, multisigAcc.ConvertMultisig(1, pKeys)) multisigHash := hash.Hash160(multisigAcc.Contract.Script) tx := bc.newTestTx(multisigHash, testScript) verificationNetFee, calculatedScriptSize := CalculateNetworkFee(multisigAcc.Contract.Script) expectedSize := io.GetVarSize(tx) + calculatedScriptSize expectedNetFee := verificationNetFee + int64(expectedSize)*bc.FeePerByte() tx.NetworkFee = expectedNetFee require.NoError(t, multisigAcc.SignTx(tx)) actualSize := io.GetVarSize(tx) require.Equal(t, expectedSize, actualSize) interopCtx := bc.newInteropContext(trigger.Verification, bc.dao, nil, tx) gasConsumed, err := bc.verifyHashAgainstScript(multisigHash, &tx.Scripts[0], interopCtx, -1) require.NoError(t, err) require.Equal(t, verificationNetFee, gasConsumed) require.Equal(t, expectedNetFee, bc.FeePerByte()*int64(actualSize)+gasConsumed) }) }) t.Run("Conflict", func(t *testing.T) { balance := bc.GetUtilityTokenBalance(h).Int64() tx := bc.newTestTx(h, testScript) tx.NetworkFee = balance / 2 require.NoError(t, accs[0].SignTx(tx)) require.NoError(t, bc.PoolTx(tx)) tx2 := bc.newTestTx(h, testScript) tx2.NetworkFee = balance / 2 require.NoError(t, accs[0].SignTx(tx2)) err := bc.PoolTx(tx2) require.True(t, errors.Is(err, ErrMemPoolConflict)) }) t.Run("NotEnoughWitnesses", func(t *testing.T) { tx := bc.newTestTx(h, testScript) checkErr(t, ErrTxInvalidWitnessNum, tx) }) t.Run("InvalidWitnessHash", func(t *testing.T) { tx := bc.newTestTx(h, testScript) require.NoError(t, accs[0].SignTx(tx)) tx.Scripts[0].VerificationScript = []byte{byte(opcode.PUSHT)} checkErr(t, ErrWitnessHashMismatch, tx) }) t.Run("InvalidWitnessSignature", func(t *testing.T) { tx := bc.newTestTx(h, testScript) require.NoError(t, accs[0].SignTx(tx)) tx.Scripts[0].InvocationScript[10] = ^tx.Scripts[0].InvocationScript[10] checkErr(t, ErrVerificationFailed, tx) }) t.Run("InsufficientNetworkFeeForSecondWitness", func(t *testing.T) { tx := bc.newTestTx(h, testScript) tx.Signers = append(tx.Signers, transaction.Signer{ Account: accs[3].PrivateKey().GetScriptHash(), Scopes: transaction.Global, }) require.NoError(t, accs[0].SignTx(tx)) require.NoError(t, accs[3].SignTx(tx)) checkErr(t, ErrVerificationFailed, tx) }) t.Run("OldTX", func(t *testing.T) { tx := bc.newTestTx(h, testScript) require.NoError(t, accs[0].SignTx(tx)) b := bc.newBlock(tx) require.NoError(t, bc.AddBlock(b)) err := bc.VerifyTx(tx) require.True(t, errors.Is(err, ErrAlreadyExists)) }) t.Run("MemPooledTX", func(t *testing.T) { tx := bc.newTestTx(h, testScript) require.NoError(t, accs[0].SignTx(tx)) require.NoError(t, bc.PoolTx(tx)) err := bc.PoolTx(tx) require.True(t, errors.Is(err, ErrAlreadyExists)) }) t.Run("MemPoolOOM", func(t *testing.T) { bc.memPool = mempool.New(1) tx1 := bc.newTestTx(h, testScript) tx1.NetworkFee += 10000 // Give it more priority. require.NoError(t, accs[0].SignTx(tx1)) require.NoError(t, bc.PoolTx(tx1)) tx2 := bc.newTestTx(h, testScript) require.NoError(t, accs[0].SignTx(tx2)) err := bc.PoolTx(tx2) require.True(t, errors.Is(err, ErrOOM)) }) t.Run("Attribute", func(t *testing.T) { t.Run("InvalidHighPriority", func(t *testing.T) { tx := bc.newTestTx(h, testScript) tx.Attributes = append(tx.Attributes, transaction.Attribute{Type: transaction.HighPriority}) require.NoError(t, accs[0].SignTx(tx)) checkErr(t, ErrInvalidAttribute, tx) }) t.Run("ValidHighPriority", func(t *testing.T) { tx := bc.newTestTx(h, testScript) tx.Attributes = append(tx.Attributes, transaction.Attribute{Type: transaction.HighPriority}) tx.NetworkFee += 4_000_000 // multisig check tx.Signers = []transaction.Signer{{ Account: testchain.CommitteeScriptHash(), Scopes: transaction.None, }} rawScript := testchain.CommitteeVerificationScript() require.NoError(t, err) size := io.GetVarSize(tx) netFee, sizeDelta := CalculateNetworkFee(rawScript) tx.NetworkFee += netFee tx.NetworkFee += int64(size+sizeDelta) * bc.FeePerByte() data := tx.GetSignedPart() tx.Scripts = []transaction.Witness{{ InvocationScript: testchain.SignCommittee(data), VerificationScript: rawScript, }} require.NoError(t, bc.VerifyTx(tx)) }) t.Run("Oracle", func(t *testing.T) { orc := bc.contracts.Oracle req := &native.OracleRequest{GasForResponse: 1000_0000} require.NoError(t, orc.PutRequestInternal(1, req, bc.dao)) oracleScript, err := smartcontract.CreateMajorityMultiSigRedeemScript(oraclePubs) require.NoError(t, err) oracleHash := hash.Hash160(oracleScript) // We need to create new transaction, // because hashes are cached after signing. getOracleTx := func(t *testing.T) *transaction.Transaction { tx := bc.newTestTx(h, native.GetOracleResponseScript()) resp := &transaction.OracleResponse{ ID: 1, Code: transaction.Success, Result: []byte{1, 2, 3}, } tx.Attributes = []transaction.Attribute{{ Type: transaction.OracleResponseT, Value: resp, }} tx.NetworkFee += 4_000_000 // multisig check tx.SystemFee = int64(req.GasForResponse - uint64(tx.NetworkFee)) tx.Signers = []transaction.Signer{{ Account: oracleHash, Scopes: transaction.None, }} size := io.GetVarSize(tx) netFee, sizeDelta := CalculateNetworkFee(oracleScript) tx.NetworkFee += netFee tx.NetworkFee += int64(size+sizeDelta) * bc.FeePerByte() return tx } t.Run("NoOracleNodes", func(t *testing.T) { tx := getOracleTx(t) require.NoError(t, oracleAcc.SignTx(tx)) checkErr(t, ErrInvalidAttribute, tx) }) txSetOracle := transaction.New(netmode.UnitTestNet, []byte{}, 0) setSigner(txSetOracle, testchain.CommitteeScriptHash()) txSetOracle.Scripts = []transaction.Witness{{ InvocationScript: testchain.SignCommittee(txSetOracle.GetSignedPart()), VerificationScript: testchain.CommitteeVerificationScript(), }} ic := bc.newInteropContext(trigger.All, bc.dao, nil, txSetOracle) ic.SpawnVM() ic.VM.LoadScript([]byte{byte(opcode.RET)}) require.NoError(t, bc.contracts.Designate.DesignateAsRole(ic, native.RoleOracle, oraclePubs)) require.NoError(t, bc.contracts.Designate.OnPersistEnd(ic.DAO)) _, err = ic.DAO.Persist() require.NoError(t, err) t.Run("Valid", func(t *testing.T) { tx := getOracleTx(t) require.NoError(t, oracleAcc.SignTx(tx)) require.NoError(t, bc.VerifyTx(tx)) }) t.Run("InvalidRequestID", func(t *testing.T) { tx := getOracleTx(t) tx.Attributes[0].Value.(*transaction.OracleResponse).ID = 2 require.NoError(t, oracleAcc.SignTx(tx)) checkErr(t, ErrInvalidAttribute, tx) }) t.Run("InvalidScope", func(t *testing.T) { tx := getOracleTx(t) tx.Signers[0].Scopes = transaction.Global require.NoError(t, oracleAcc.SignTx(tx)) checkErr(t, ErrInvalidAttribute, tx) }) t.Run("InvalidScript", func(t *testing.T) { tx := getOracleTx(t) tx.Script[0] = ^tx.Script[0] require.NoError(t, oracleAcc.SignTx(tx)) checkErr(t, ErrInvalidAttribute, tx) }) t.Run("InvalidSigner", func(t *testing.T) { tx := getOracleTx(t) tx.Signers[0].Account = accs[0].Contract.ScriptHash() require.NoError(t, accs[0].SignTx(tx)) checkErr(t, ErrInvalidAttribute, tx) }) t.Run("SmallFee", func(t *testing.T) { tx := getOracleTx(t) tx.SystemFee = 0 require.NoError(t, oracleAcc.SignTx(tx)) checkErr(t, ErrInvalidAttribute, tx) }) }) }) } func TestVerifyHashAgainstScript(t *testing.T) { bc := newTestChain(t) defer bc.Close() cs, csInvalid := getTestContractState() ic := bc.newInteropContext(trigger.Verification, bc.dao, nil, nil) require.NoError(t, ic.DAO.PutContractState(cs)) require.NoError(t, ic.DAO.PutContractState(csInvalid)) gas := bc.contracts.Policy.GetMaxVerificationGas(ic.DAO) t.Run("Contract", func(t *testing.T) { t.Run("Missing", func(t *testing.T) { newH := cs.ScriptHash() newH[0] = ^newH[0] w := &transaction.Witness{InvocationScript: []byte{byte(opcode.PUSH4)}} _, err := bc.verifyHashAgainstScript(newH, w, ic, gas) require.True(t, errors.Is(err, ErrUnknownVerificationContract)) }) t.Run("Invalid", func(t *testing.T) { w := &transaction.Witness{InvocationScript: []byte{byte(opcode.PUSH4)}} _, err := bc.verifyHashAgainstScript(csInvalid.ScriptHash(), w, ic, gas) require.True(t, errors.Is(err, ErrInvalidVerificationContract)) }) t.Run("ValidSignature", func(t *testing.T) { w := &transaction.Witness{InvocationScript: []byte{byte(opcode.PUSH4)}} _, err := bc.verifyHashAgainstScript(cs.ScriptHash(), w, ic, gas) require.NoError(t, err) }) t.Run("InvalidSignature", func(t *testing.T) { w := &transaction.Witness{InvocationScript: []byte{byte(opcode.PUSH3)}} _, err := bc.verifyHashAgainstScript(cs.ScriptHash(), w, ic, gas) require.True(t, errors.Is(err, ErrVerificationFailed)) }) }) t.Run("NotEnoughGas", func(t *testing.T) { verif := []byte{byte(opcode.PUSH1)} w := &transaction.Witness{ InvocationScript: []byte{byte(opcode.NOP)}, VerificationScript: verif, } _, err := bc.verifyHashAgainstScript(hash.Hash160(verif), w, ic, 1) require.True(t, errors.Is(err, ErrVerificationFailed)) }) t.Run("NoResult", func(t *testing.T) { verif := []byte{byte(opcode.DROP)} w := &transaction.Witness{ InvocationScript: []byte{byte(opcode.PUSH1)}, VerificationScript: verif, } _, err := bc.verifyHashAgainstScript(hash.Hash160(verif), w, ic, gas) require.True(t, errors.Is(err, ErrVerificationFailed)) }) t.Run("BadResult", func(t *testing.T) { verif := make([]byte, 66) verif[0] = byte(opcode.PUSHDATA1) verif[1] = 64 w := &transaction.Witness{ InvocationScript: []byte{byte(opcode.NOP)}, VerificationScript: verif, } _, err := bc.verifyHashAgainstScript(hash.Hash160(verif), w, ic, gas) require.True(t, errors.Is(err, ErrVerificationFailed)) }) t.Run("TooManyResults", func(t *testing.T) { verif := []byte{byte(opcode.NOP)} w := &transaction.Witness{ InvocationScript: []byte{byte(opcode.PUSH1), byte(opcode.PUSH1)}, VerificationScript: verif, } _, err := bc.verifyHashAgainstScript(hash.Hash160(verif), w, ic, gas) require.True(t, errors.Is(err, ErrVerificationFailed)) }) } func TestMemPoolRemoval(t *testing.T) { const added = 16 const notAdded = 32 bc := newTestChain(t) defer bc.Close() addedTxes := make([]*transaction.Transaction, added) notAddedTxes := make([]*transaction.Transaction, notAdded) for i := range addedTxes { addedTxes[i] = bc.newTestTx(testchain.MultisigScriptHash(), []byte{byte(opcode.PUSH1)}) require.NoError(t, signTx(bc, addedTxes[i])) require.NoError(t, bc.PoolTx(addedTxes[i])) } for i := range notAddedTxes { notAddedTxes[i] = bc.newTestTx(testchain.MultisigScriptHash(), []byte{byte(opcode.PUSH1)}) require.NoError(t, signTx(bc, notAddedTxes[i])) require.NoError(t, bc.PoolTx(notAddedTxes[i])) } b := bc.newBlock(addedTxes...) require.NoError(t, bc.AddBlock(b)) mempool := bc.GetMemPool() for _, tx := range addedTxes { require.False(t, mempool.ContainsKey(tx.Hash())) } for _, tx := range notAddedTxes { require.True(t, mempool.ContainsKey(tx.Hash())) } } func TestHasBlock(t *testing.T) { bc := newTestChain(t) blocks, err := bc.genBlocks(50) require.NoError(t, err) // Test unpersisted and persisted access for j := 0; j < 2; j++ { for i := 0; i < len(blocks); i++ { assert.True(t, bc.HasBlock(blocks[i].Hash())) } newBlock := bc.newBlock() assert.False(t, bc.HasBlock(newBlock.Hash())) assert.NoError(t, bc.persist()) } } func TestGetTransaction(t *testing.T) { bc := newTestChain(t) tx1 := transaction.New(netmode.UnitTestNet, []byte{byte(opcode.PUSH1)}, 0) tx1.ValidUntilBlock = 16 tx1.Signers = []transaction.Signer{{ Account: testchain.MultisigScriptHash(), Scopes: transaction.CalledByEntry, }} tx2 := transaction.New(netmode.UnitTestNet, []byte{byte(opcode.PUSH2)}, 0) tx2.ValidUntilBlock = 16 tx2.Signers = []transaction.Signer{{ Account: testchain.MultisigScriptHash(), Scopes: transaction.CalledByEntry, }} require.NoError(t, signTx(bc, tx1, tx2)) b1 := bc.newBlock(tx1) assert.Nil(t, bc.AddBlock(b1)) block := bc.newBlock(tx2) txSize := io.GetVarSize(tx2) assert.Nil(t, bc.AddBlock(block)) // Test unpersisted and persisted access for j := 0; j < 2; j++ { tx, height, err := bc.GetTransaction(block.Transactions[0].Hash()) require.Nil(t, err) assert.Equal(t, block.Index, height) assert.Equal(t, txSize, tx.Size()) assert.Equal(t, block.Transactions[0], tx) assert.Equal(t, 1, io.GetVarSize(tx.Attributes)) assert.Equal(t, 1, io.GetVarSize(tx.Scripts)) assert.NoError(t, bc.persist()) } } func TestGetClaimable(t *testing.T) { bc := newTestChain(t) defer bc.Close() _, err := bc.genBlocks(10) require.NoError(t, err) t.Run("first generation period", func(t *testing.T) { amount := bc.CalculateClaimable(big.NewInt(1), 0, 2) require.EqualValues(t, big.NewInt(1), amount) }) } func TestClose(t *testing.T) { defer func() { r := recover() assert.NotNil(t, r) }() bc := newTestChain(t) _, err := bc.genBlocks(10) require.NoError(t, err) bc.Close() // It's a hack, but we use internal knowledge of MemoryStore // implementation which makes it completely unusable (up to panicing) // after Close(). _ = bc.dao.Store.Put([]byte{0}, []byte{1}) // This should never be executed. assert.Nil(t, t) } func TestSubscriptions(t *testing.T) { // We use buffering here as a substitute for reader goroutines, events // get queued up and we read them one by one here. const chBufSize = 16 blockCh := make(chan *block.Block, chBufSize) txCh := make(chan *transaction.Transaction, chBufSize) notificationCh := make(chan *state.NotificationEvent, chBufSize) executionCh := make(chan *state.AppExecResult, chBufSize) bc := newTestChain(t) defer bc.Close() bc.SubscribeForBlocks(blockCh) bc.SubscribeForTransactions(txCh) bc.SubscribeForNotifications(notificationCh) bc.SubscribeForExecutions(executionCh) assert.Empty(t, notificationCh) assert.Empty(t, executionCh) assert.Empty(t, blockCh) assert.Empty(t, txCh) blocks, err := bc.genBlocks(1) require.NoError(t, err) require.Eventually(t, func() bool { return len(blockCh) != 0 }, time.Second, 10*time.Millisecond) assert.Len(t, notificationCh, 1) // validator bounty assert.Len(t, executionCh, 2) assert.Empty(t, txCh) b := <-blockCh assert.Equal(t, blocks[0], b) assert.Empty(t, blockCh) aer := <-executionCh assert.Equal(t, b.Hash(), aer.TxHash) aer = <-executionCh assert.Equal(t, b.Hash(), aer.TxHash) notif := <-notificationCh require.Equal(t, bc.UtilityTokenHash(), notif.ScriptHash) script := io.NewBufBinWriter() emit.Bytes(script.BinWriter, []byte("yay!")) emit.Syscall(script.BinWriter, interopnames.SystemRuntimeNotify) require.NoError(t, script.Err) txGood1 := transaction.New(netmode.UnitTestNet, script.Bytes(), 0) txGood1.Signers = []transaction.Signer{{Account: neoOwner}} txGood1.Nonce = 1 txGood1.ValidUntilBlock = 100500 require.NoError(t, signTx(bc, txGood1)) // Reset() reuses the script buffer and we need to keep scripts. script = io.NewBufBinWriter() emit.Bytes(script.BinWriter, []byte("nay!")) emit.Syscall(script.BinWriter, interopnames.SystemRuntimeNotify) emit.Opcodes(script.BinWriter, opcode.THROW) require.NoError(t, script.Err) txBad := transaction.New(netmode.UnitTestNet, script.Bytes(), 0) txBad.Signers = []transaction.Signer{{Account: neoOwner}} txBad.Nonce = 2 txBad.ValidUntilBlock = 100500 require.NoError(t, signTx(bc, txBad)) script = io.NewBufBinWriter() emit.Bytes(script.BinWriter, []byte("yay! yay! yay!")) emit.Syscall(script.BinWriter, interopnames.SystemRuntimeNotify) require.NoError(t, script.Err) txGood2 := transaction.New(netmode.UnitTestNet, script.Bytes(), 0) txGood2.Signers = []transaction.Signer{{Account: neoOwner}} txGood2.Nonce = 3 txGood2.ValidUntilBlock = 100500 require.NoError(t, signTx(bc, txGood2)) invBlock := newBlock(bc.config, bc.BlockHeight()+1, bc.CurrentHeaderHash(), txGood1, txBad, txGood2) require.NoError(t, bc.AddBlock(invBlock)) require.Eventually(t, func() bool { return len(blockCh) != 0 && len(txCh) != 0 && len(notificationCh) != 0 && len(executionCh) != 0 }, time.Second, 10*time.Millisecond) b = <-blockCh require.Equal(t, invBlock, b) assert.Empty(t, blockCh) exec := <-executionCh require.Equal(t, b.Hash(), exec.TxHash) require.Equal(t, exec.VMState, vm.HaltState) // 3 burn events for every tx and 1 mint for primary node require.True(t, len(notificationCh) >= 4) for i := 0; i < 4; i++ { notif := <-notificationCh require.Equal(t, bc.contracts.GAS.Hash, notif.ScriptHash) } // Follow in-block transaction order. for _, txExpected := range invBlock.Transactions { tx := <-txCh require.Equal(t, txExpected, tx) exec := <-executionCh require.Equal(t, tx.Hash(), exec.TxHash) if exec.VMState == vm.HaltState { notif := <-notificationCh require.Equal(t, hash.Hash160(tx.Script), notif.ScriptHash) } } assert.Empty(t, txCh) assert.Len(t, notificationCh, 1) assert.Len(t, executionCh, 1) notif = <-notificationCh require.Equal(t, bc.UtilityTokenHash(), notif.ScriptHash) exec = <-executionCh require.Equal(t, b.Hash(), exec.TxHash) require.Equal(t, exec.VMState, vm.HaltState) bc.UnsubscribeFromBlocks(blockCh) bc.UnsubscribeFromTransactions(txCh) bc.UnsubscribeFromNotifications(notificationCh) bc.UnsubscribeFromExecutions(executionCh) // Ensure that new blocks are processed correctly after unsubscription. _, err = bc.genBlocks(2 * chBufSize) require.NoError(t, err) }