package core_test import ( "encoding/binary" "errors" "fmt" "math/big" "path/filepath" "strings" "testing" "time" "github.com/nspcc-dev/neo-go/internal/basicchain" "github.com/nspcc-dev/neo-go/internal/contracts" "github.com/nspcc-dev/neo-go/internal/random" "github.com/nspcc-dev/neo-go/internal/testchain" "github.com/nspcc-dev/neo-go/pkg/compiler" "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/dao" "github.com/nspcc-dev/neo-go/pkg/core/fee" "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/native/nativenames" "github.com/nspcc-dev/neo-go/pkg/core/native/nativeprices" "github.com/nspcc-dev/neo-go/pkg/core/native/noderoles" "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/storage/dbconfig" "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/encoding/address" "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/smartcontract" "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/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/vm/vmstate" "github.com/nspcc-dev/neo-go/pkg/wallet" "github.com/stretchr/testify/assert" "github.com/stretchr/testify/require" ) func newLevelDBForTestingWithPath(t testing.TB, dbPath string) (storage.Store, string) { if dbPath == "" { dbPath = t.TempDir() } dbOptions := dbconfig.LevelDBOptions{ DataDirectoryPath: dbPath, } newLevelStore, err := storage.NewLevelDBStore(dbOptions) require.Nil(t, err, "NewLevelDBStore error") return newLevelStore, dbPath } func TestBlockchain_StartFromExistingDB(t *testing.T) { ps, path := newLevelDBForTestingWithPath(t, "") customConfig := func(c *config.Blockchain) { c.StateRootInHeader = true // Need for P2PStateExchangeExtensions check. c.P2PSigExtensions = true // Need for basic chain initializer. } bc, validators, committee, err := chain.NewMultiWithCustomConfigAndStoreNoCheck(t, customConfig, ps) require.NoError(t, err) go bc.Run() e := neotest.NewExecutor(t, bc, validators, committee) basicchain.Init(t, "../../", e) require.True(t, bc.BlockHeight() > 5, "ensure that basic chain is correctly initialised") // Information for further tests. h := bc.BlockHeight() cryptoLibHash, err := bc.GetNativeContractScriptHash(nativenames.CryptoLib) require.NoError(t, err) cryptoLibState := bc.GetContractState(cryptoLibHash) require.NotNil(t, cryptoLibState) var ( managementID = -1 managementContractPrefix = 8 ) bc.Close() // Ensure persist is done and persistent store is properly closed. newPS := func(t *testing.T) storage.Store { ps, _ = newLevelDBForTestingWithPath(t, path) t.Cleanup(func() { require.NoError(t, ps.Close()) }) return ps } t.Run("mismatch storage version", func(t *testing.T) { ps = newPS(t) cache := storage.NewMemCachedStore(ps) // Extra wrapper to avoid good DB corruption. d := dao.NewSimple(cache, bc.GetConfig().StateRootInHeader) d.PutVersion(dao.Version{ Value: "0.0.0", }) _, err := d.Persist() // Persist to `cache` wrapper. require.NoError(t, err) _, _, _, err = chain.NewMultiWithCustomConfigAndStoreNoCheck(t, customConfig, cache) require.Error(t, err) require.True(t, strings.Contains(err.Error(), "storage version mismatch"), err) }) t.Run("mismatch StateRootInHeader", func(t *testing.T) { ps = newPS(t) _, _, _, err := chain.NewMultiWithCustomConfigAndStoreNoCheck(t, func(c *config.Blockchain) { customConfig(c) c.StateRootInHeader = false }, ps) require.Error(t, err) require.True(t, strings.Contains(err.Error(), "StateRootInHeader setting mismatch"), err) }) t.Run("mismatch P2PSigExtensions", func(t *testing.T) { ps = newPS(t) _, _, _, err := chain.NewMultiWithCustomConfigAndStoreNoCheck(t, func(c *config.Blockchain) { customConfig(c) c.P2PSigExtensions = false }, ps) require.Error(t, err) require.True(t, strings.Contains(err.Error(), "P2PSigExtensions setting mismatch"), err) }) t.Run("mismatch P2PStateExchangeExtensions", func(t *testing.T) { ps = newPS(t) _, _, _, err := chain.NewMultiWithCustomConfigAndStoreNoCheck(t, func(c *config.Blockchain) { customConfig(c) c.StateRootInHeader = true c.P2PStateExchangeExtensions = true }, ps) require.Error(t, err) require.True(t, strings.Contains(err.Error(), "P2PStateExchangeExtensions setting mismatch"), err) }) t.Run("mismatch KeepOnlyLatestState", func(t *testing.T) { ps = newPS(t) _, _, _, err := chain.NewMultiWithCustomConfigAndStoreNoCheck(t, func(c *config.Blockchain) { customConfig(c) c.Ledger.KeepOnlyLatestState = true }, ps) require.Error(t, err) require.True(t, strings.Contains(err.Error(), "KeepOnlyLatestState setting mismatch"), err) }) t.Run("Magic mismatch", func(t *testing.T) { ps = newPS(t) _, _, _, err := chain.NewMultiWithCustomConfigAndStoreNoCheck(t, func(c *config.Blockchain) { customConfig(c) c.Magic = 100500 }, ps) require.Error(t, err) require.True(t, strings.Contains(err.Error(), "protocol configuration Magic mismatch"), err) }) t.Run("corrupted headers", func(t *testing.T) { ps = newPS(t) // Corrupt headers hashes batch. cache := storage.NewMemCachedStore(ps) // Extra wrapper to avoid good DB corruption. // Make the chain think we're at 2000+ which will trigger page 0 read. buf := io.NewBufBinWriter() buf.WriteBytes(util.Uint256{}.BytesLE()) buf.WriteU32LE(2000) cache.Put([]byte{byte(storage.SYSCurrentHeader)}, buf.Bytes()) _, _, _, err := chain.NewMultiWithCustomConfigAndStoreNoCheck(t, customConfig, cache) require.Error(t, err) require.True(t, strings.Contains(err.Error(), "failed to retrieve header hash page"), err) }) t.Run("corrupted current header height", func(t *testing.T) { ps = newPS(t) // Remove current header. cache := storage.NewMemCachedStore(ps) // Extra wrapper to avoid good DB corruption. cache.Delete([]byte{byte(storage.SYSCurrentHeader)}) _, _, _, err := chain.NewMultiWithCustomConfigAndStoreNoCheck(t, customConfig, cache) require.Error(t, err) require.True(t, strings.Contains(err.Error(), "failed to retrieve current header"), err) }) t.Run("missing last batch of 2000 headers and missing last header", func(t *testing.T) { ps = newPS(t) // Remove latest headers hashes batch and current header. cache := storage.NewMemCachedStore(ps) // Extra wrapper to avoid good DB corruption. cache.Delete([]byte{byte(storage.IXHeaderHashList)}) currHeaderInfo, err := cache.Get([]byte{byte(storage.SYSCurrentHeader)}) require.NoError(t, err) currHeaderHash, err := util.Uint256DecodeBytesLE(currHeaderInfo[:32]) require.NoError(t, err) cache.Delete(append([]byte{byte(storage.DataExecutable)}, currHeaderHash.BytesBE()...)) _, _, _, err = chain.NewMultiWithCustomConfigAndStoreNoCheck(t, customConfig, cache) require.Error(t, err) require.True(t, strings.Contains(err.Error(), "could not get header"), err) }) t.Run("missing last block", func(t *testing.T) { ps = newPS(t) // Remove current block from storage. cache := storage.NewMemCachedStore(ps) // Extra wrapper to avoid good DB corruption. cache.Delete([]byte{byte(storage.SYSCurrentBlock)}) _, _, _, err := chain.NewMultiWithCustomConfigAndStoreNoCheck(t, customConfig, cache) require.Error(t, err) require.True(t, strings.Contains(err.Error(), "failed to retrieve current block height"), err) }) t.Run("missing last stateroot", func(t *testing.T) { ps = newPS(t) // Remove latest stateroot from storage. cache := storage.NewMemCachedStore(ps) // Extra wrapper to avoid good DB corruption. key := make([]byte, 5) key[0] = byte(storage.DataMPTAux) binary.BigEndian.PutUint32(key[1:], h) cache.Delete(key) _, _, _, err := chain.NewMultiWithCustomConfigAndStoreNoCheck(t, customConfig, cache) require.Error(t, err) require.True(t, strings.Contains(err.Error(), "can't init MPT at height"), err) }) /* See #2801 t.Run("failed native Management initialisation", func(t *testing.T) { ps = newPS(t) // Corrupt serialised CryptoLib state. cache := storage.NewMemCachedStore(ps) // Extra wrapper to avoid good DB corruption. key := make([]byte, 1+4+1+20) key[0] = byte(storage.STStorage) binary.LittleEndian.PutUint32(key[1:], uint32(managementID)) key[5] = byte(managementContractPrefix) copy(key[6:], cryptoLibHash.BytesBE()) cache.Put(key, []byte{1, 2, 3}) _, _, _, err := chain.NewMultiWithCustomConfigAndStoreNoCheck(t, customConfig, cache) require.Error(t, err) require.True(t, strings.Contains(err.Error(), "can't init cache for Management native contract"), err) }) */ t.Run("invalid native contract activation", func(t *testing.T) { ps = newPS(t) // Remove CryptoLib from storage. cache := storage.NewMemCachedStore(ps) // Extra wrapper to avoid good DB corruption. key := make([]byte, 1+4+1+20) key[0] = byte(storage.STStorage) binary.LittleEndian.PutUint32(key[1:], uint32(managementID)) key[5] = byte(managementContractPrefix) copy(key[6:], cryptoLibHash.BytesBE()) cache.Delete(key) _, _, _, err := chain.NewMultiWithCustomConfigAndStoreNoCheck(t, customConfig, cache) require.Error(t, err) require.True(t, strings.Contains(err.Error(), fmt.Sprintf("native contract %s is not stored, but should be active at height %d according to config", nativenames.CryptoLib, h)), err) }) t.Run("stored and autogenerated native contract's states mismatch", func(t *testing.T) { ps = newPS(t) // Change stored CryptoLib state. cache := storage.NewMemCachedStore(ps) // Extra wrapper to avoid good DB corruption. key := make([]byte, 1+4+1+20) key[0] = byte(storage.STStorage) binary.LittleEndian.PutUint32(key[1:], uint32(managementID)) key[5] = byte(managementContractPrefix) copy(key[6:], cryptoLibHash.BytesBE()) cs := *cryptoLibState cs.ID = -123 csBytes, err := stackitem.SerializeConvertible(&cs) require.NoError(t, err) cache.Put(key, csBytes) _, _, _, err = chain.NewMultiWithCustomConfigAndStoreNoCheck(t, customConfig, cache) require.Error(t, err) require.True(t, strings.Contains(err.Error(), fmt.Sprintf("native %s: version mismatch (stored contract state differs from autogenerated one)", nativenames.CryptoLib)), err) }) t.Run("good", func(t *testing.T) { ps = newPS(t) _, _, _, err := chain.NewMultiWithCustomConfigAndStoreNoCheck(t, customConfig, ps) require.NoError(t, err) }) } // TestBlockchain_InitializeNeoCache_Bug3181 is aimed to reproduce and check situation // when panic occures on native Neo cache initialization due to access to native Policy // cache when it's not yet initialized to recalculate candidates. func TestBlockchain_InitializeNeoCache_Bug3181(t *testing.T) { ps, path := newLevelDBForTestingWithPath(t, "") bc, validators, committee, err := chain.NewMultiWithCustomConfigAndStoreNoCheck(t, nil, ps) require.NoError(t, err) go bc.Run() e := neotest.NewExecutor(t, bc, validators, committee) // Add at least one registered candidate to enable candidates Policy check. acc := e.NewAccount(t, 10000_0000_0000) // block #1 neo := e.NewInvoker(e.NativeHash(t, nativenames.Neo), acc) neo.Invoke(t, true, "registerCandidate", acc.(neotest.SingleSigner).Account().PublicKey().Bytes()) // block #2 // Put some empty blocks to reach N-1 block height, so that newEpoch cached // values of native Neo contract require an update on the subsequent cache // initialization. for i := 0; i < len(bc.GetConfig().StandbyCommittee)-1-2; i++ { e.AddNewBlock(t) } bc.Close() // Ensure persist is done and persistent store is properly closed. ps, _ = newLevelDBForTestingWithPath(t, path) t.Cleanup(func() { require.NoError(t, ps.Close()) }) // Start chain from the existing database that should trigger an update of native // Neo newEpoch* cached values during initializaition. This update requires candidates // list recalculation and policies checks, thus, access to native Policy cache // that is not yet initialized by that moment. require.NotPanics(t, func() { _, _, _, err = chain.NewMultiWithCustomConfigAndStoreNoCheck(t, nil, ps) require.NoError(t, err) }) } // This test enables Notary native contract at non-zero height and checks that no // Notary cache initialization is performed before that height on node restart. /* func TestBlockchain_InitializeNativeCacheWrtNativeActivations(t *testing.T) { const notaryEnabledHeight = 3 ps, path := newLevelDBForTestingWithPath(t, "") customConfig := func(c *config.Blockchain) { c.P2PSigExtensions = true c.NativeUpdateHistories = make(map[string][]uint32) for _, n := range []string{ nativenames.Neo, nativenames.Gas, nativenames.Designation, nativenames.Management, nativenames.CryptoLib, nativenames.Ledger, nativenames.Management, nativenames.Oracle, nativenames.Policy, nativenames.StdLib, nativenames.Notary, } { if n == nativenames.Notary { c.NativeUpdateHistories[n] = []uint32{notaryEnabledHeight} } else { c.NativeUpdateHistories[n] = []uint32{0} } } } bc, validators, committee, err := chain.NewMultiWithCustomConfigAndStoreNoCheck(t, customConfig, ps) require.NoError(t, err) go bc.Run() e := neotest.NewExecutor(t, bc, validators, committee) e.AddNewBlock(t) bc.Close() // Ensure persist is done and persistent store is properly closed. ps, _ = newLevelDBForTestingWithPath(t, path) // If NativeActivations are not taken into account during native cache initialization, // bs.init() will panic on Notary cache initialization as it's not deployed yet. require.NotPanics(t, func() { bc, _, _, err = chain.NewMultiWithCustomConfigAndStoreNoCheck(t, customConfig, ps) require.NoError(t, err) }) go bc.Run() defer bc.Close() e = neotest.NewExecutor(t, bc, validators, committee) h := e.Chain.BlockHeight() // Notary isn't initialized yet, so accessing Notary cache should return error. _, err = e.Chain.GetMaxNotValidBeforeDelta() require.Error(t, err) // Ensure Notary will be properly initialized and accessing Notary cache works // as expected. for i := 0; i < notaryEnabledHeight; i++ { require.NotPanics(t, func() { e.AddNewBlock(t) }, h+uint32(i)+1) } _, err = e.Chain.GetMaxNotValidBeforeDelta() require.NoError(t, err) } */ func TestBlockchain_AddHeaders(t *testing.T) { bc, acc := chain.NewSingleWithCustomConfig(t, func(c *config.Blockchain) { c.StateRootInHeader = true }) e := neotest.NewExecutor(t, bc, acc, acc) newHeader := func(t *testing.T, index uint32, prevHash util.Uint256, timestamp uint64) *block.Header { b := e.NewUnsignedBlock(t) b.Index = index b.PrevHash = prevHash b.PrevStateRoot = util.Uint256{} b.Timestamp = timestamp e.SignBlock(b) return &b.Header } b1 := e.NewUnsignedBlock(t) h1 := &e.SignBlock(b1).Header h2 := newHeader(t, h1.Index+1, h1.Hash(), h1.Timestamp+1) h3 := newHeader(t, h2.Index+1, h2.Hash(), h2.Timestamp+1) 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()) h4Bad := newHeader(t, h3.Index+1, h3.Hash().Reverse(), h3.Timestamp+1) h5Bad := newHeader(t, h4Bad.Index+1, h4Bad.Hash(), h4Bad.Timestamp+1) assert.Error(t, bc.AddHeaders(h4Bad, h5Bad)) assert.Equal(t, h3.Index, bc.HeaderHeight()) assert.Equal(t, uint32(0), bc.BlockHeight()) assert.Equal(t, h3.Hash(), bc.CurrentHeaderHash()) h4Bad2 := newHeader(t, h3.Index+1, h3.Hash().Reverse(), h3.Timestamp+1) h4Bad2.Script.InvocationScript = []byte{} assert.Error(t, bc.AddHeaders(h4Bad2)) assert.Equal(t, h3.Index, bc.HeaderHeight()) assert.Equal(t, uint32(0), bc.BlockHeight()) assert.Equal(t, h3.Hash(), bc.CurrentHeaderHash()) } func TestBlockchain_AddBlockStateRoot(t *testing.T) { bc, acc := chain.NewSingleWithCustomConfig(t, func(c *config.Blockchain) { c.StateRootInHeader = true }) e := neotest.NewExecutor(t, bc, acc, acc) sr, err := bc.GetStateModule().GetStateRoot(bc.BlockHeight()) require.NoError(t, err) b := e.NewUnsignedBlock(t) b.StateRootEnabled = false b.PrevStateRoot = util.Uint256{} e.SignBlock(b) err = bc.AddBlock(b) require.ErrorIs(t, err, core.ErrHdrStateRootSetting) u := sr.Root u[0] ^= 0xFF b = e.NewUnsignedBlock(t) b.PrevStateRoot = u e.SignBlock(b) err = bc.AddBlock(b) require.ErrorIs(t, err, core.ErrHdrInvalidStateRoot) b = e.NewUnsignedBlock(t) e.SignBlock(b) require.NoError(t, bc.AddBlock(b)) } func TestBlockchain_AddHeadersStateRoot(t *testing.T) { bc, acc := chain.NewSingleWithCustomConfig(t, func(c *config.Blockchain) { c.StateRootInHeader = true }) e := neotest.NewExecutor(t, bc, acc, acc) b := e.NewUnsignedBlock(t) e.SignBlock(b) h1 := b.Header r := bc.GetStateModule().CurrentLocalStateRoot() // invalid stateroot h1.PrevStateRoot[0] ^= 0xFF require.ErrorIs(t, bc.AddHeaders(&h1), core.ErrHdrInvalidStateRoot) // valid stateroot h1.PrevStateRoot = r require.NoError(t, bc.AddHeaders(&h1)) // unable to verify stateroot (stateroot is computed for block #0 only => can // verify stateroot of header #1 only) => just store the header b = e.NewUnsignedBlock(t) b.PrevHash = h1.Hash() b.Timestamp = h1.Timestamp + 1 b.PrevStateRoot = util.Uint256{} b.Index = h1.Index + 1 e.SignBlock(b) require.NoError(t, bc.AddHeaders(&b.Header)) } func TestBlockchain_AddBadBlock(t *testing.T) { check := func(t *testing.T, b *block.Block, cfg func(c *config.Blockchain)) { bc, _ := chain.NewSingleWithCustomConfig(t, cfg) err := bc.AddBlock(b) if cfg == nil { require.Error(t, err) } else { require.NoError(t, err) } } bc, acc := chain.NewSingle(t) e := neotest.NewExecutor(t, bc, acc, acc) neoHash := e.NativeHash(t, nativenames.Neo) tx := e.NewUnsignedTx(t, neoHash, "transfer", acc.ScriptHash(), util.Uint160{1, 2, 3}, 1, nil) tx.ValidUntilBlock = 0 // Intentionally make the transaction invalid. e.SignTx(t, tx, -1, acc) b := e.NewUnsignedBlock(t, tx) e.SignBlock(b) check(t, b, nil) check(t, b, func(c *config.Blockchain) { c.SkipBlockVerification = true }) b = e.NewUnsignedBlock(t) b.PrevHash = util.Uint256{} // Intentionally make block invalid. e.SignBlock(b) check(t, b, nil) check(t, b, func(c *config.Blockchain) { c.SkipBlockVerification = true }) tx = e.NewUnsignedTx(t, neoHash, "transfer", acc.ScriptHash(), util.Uint160{1, 2, 3}, 1, nil) // Check the good tx. e.SignTx(t, tx, -1, acc) b = e.NewUnsignedBlock(t, tx) e.SignBlock(b) check(t, b, func(c *config.Blockchain) { c.VerifyTransactions = true c.SkipBlockVerification = false }) } func TestBlockchain_GetHeader(t *testing.T) { bc, acc := chain.NewSingle(t) e := neotest.NewExecutor(t, bc, acc, acc) block := e.AddNewBlock(t) hash := block.Hash() header, err := bc.GetHeader(hash) require.NoError(t, err) assert.Equal(t, &block.Header, header) b2 := e.NewUnsignedBlock(t) _, err = bc.GetHeader(b2.Hash()) assert.Error(t, err) } func TestBlockchain_GetBlock(t *testing.T) { bc, acc := chain.NewSingle(t) e := neotest.NewExecutor(t, bc, acc, acc) blocks := e.GenerateNewBlocks(t, 10) neoValidatorInvoker := e.ValidatorInvoker(e.NativeHash(t, nativenames.Neo)) for i := 0; i < len(blocks); i++ { block, err := bc.GetBlock(blocks[i].Hash()) require.NoErrorf(t, err, "can't get block %d: %s", i, err) assert.Equal(t, blocks[i].Index, block.Index) assert.Equal(t, blocks[i].Hash(), block.Hash()) } t.Run("store only header", func(t *testing.T) { t.Run("non-empty block", func(t *testing.T) { tx := neoValidatorInvoker.PrepareInvoke(t, "transfer", acc.ScriptHash(), util.Uint160{1, 2, 3}, 1, nil) b := e.NewUnsignedBlock(t, tx) e.SignBlock(b) require.NoError(t, bc.AddHeaders(&b.Header)) _, err := bc.GetBlock(b.Hash()) require.Error(t, err) _, err = bc.GetHeader(b.Hash()) require.NoError(t, err) require.NoError(t, bc.AddBlock(b)) _, err = bc.GetBlock(b.Hash()) require.NoError(t, err) }) t.Run("empty block", func(t *testing.T) { b := e.NewUnsignedBlock(t) e.SignBlock(b) require.NoError(t, bc.AddHeaders(&b.Header)) _, err := bc.GetBlock(b.Hash()) require.NoError(t, err) }) }) } func TestBlockchain_VerifyHashAgainstScript(t *testing.T) { bc, acc := chain.NewSingle(t) e := neotest.NewExecutor(t, bc, acc, acc) cs, csInvalid := contracts.GetTestContractState(t, pathToInternalContracts, 0, 1, acc.ScriptHash()) c1 := &neotest.Contract{ Hash: cs.Hash, NEF: &cs.NEF, Manifest: &cs.Manifest, } c2 := &neotest.Contract{ Hash: csInvalid.Hash, NEF: &csInvalid.NEF, Manifest: &csInvalid.Manifest, } e.DeployContract(t, c1, nil) e.DeployContract(t, c2, nil) gas := bc.GetMaxVerificationGAS() t.Run("Contract", func(t *testing.T) { t.Run("Missing", func(t *testing.T) { newH := cs.Hash newH[0] = ^newH[0] w := &transaction.Witness{InvocationScript: []byte{byte(opcode.PUSH4)}} _, err := bc.VerifyWitness(newH, nil, w, gas) require.ErrorIs(t, err, core.ErrUnknownVerificationContract) }) t.Run("Invalid", func(t *testing.T) { w := &transaction.Witness{InvocationScript: []byte{byte(opcode.PUSH4)}} _, err := bc.VerifyWitness(csInvalid.Hash, nil, w, gas) require.ErrorIs(t, err, core.ErrInvalidVerificationContract) }) t.Run("ValidSignature", func(t *testing.T) { w := &transaction.Witness{InvocationScript: []byte{byte(opcode.PUSH4)}} _, err := bc.VerifyWitness(cs.Hash, nil, w, gas) require.NoError(t, err) }) t.Run("InvalidSignature", func(t *testing.T) { w := &transaction.Witness{InvocationScript: []byte{byte(opcode.PUSH3)}} _, err := bc.VerifyWitness(cs.Hash, nil, w, gas) require.ErrorIs(t, err, core.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.VerifyWitness(hash.Hash160(verif), nil, w, 1) require.ErrorIs(t, err, core.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.VerifyWitness(hash.Hash160(verif), nil, w, gas) require.ErrorIs(t, err, core.ErrVerificationFailed) }) t.Run("BadResult", func(t *testing.T) { verif := make([]byte, keys.SignatureLen+2) verif[0] = byte(opcode.PUSHDATA1) verif[1] = keys.SignatureLen w := &transaction.Witness{ InvocationScript: []byte{byte(opcode.NOP)}, VerificationScript: verif, } _, err := bc.VerifyWitness(hash.Hash160(verif), nil, w, gas) require.ErrorIs(t, err, core.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.VerifyWitness(hash.Hash160(verif), nil, w, gas) require.ErrorIs(t, err, core.ErrVerificationFailed) }) } func TestBlockchain_IsTxStillRelevant(t *testing.T) { bc, acc := chain.NewSingleWithCustomConfig(t, func(c *config.Blockchain) { c.P2PSigExtensions = true }) e := neotest.NewExecutor(t, bc, acc, acc) mp := bc.GetMemPool() t.Run("small ValidUntilBlock", func(t *testing.T) { tx := e.PrepareInvocation(t, []byte{byte(opcode.PUSH1)}, []neotest.Signer{acc}, bc.BlockHeight()+1) require.True(t, bc.IsTxStillRelevant(tx, nil, false)) e.AddNewBlock(t) require.False(t, bc.IsTxStillRelevant(tx, nil, false)) }) t.Run("tx is already persisted", func(t *testing.T) { tx := e.PrepareInvocation(t, []byte{byte(opcode.PUSH1)}, []neotest.Signer{acc}, bc.BlockHeight()+2) require.True(t, bc.IsTxStillRelevant(tx, nil, false)) e.AddNewBlock(t, tx) require.False(t, bc.IsTxStillRelevant(tx, nil, false)) }) t.Run("tx with Conflicts attribute", func(t *testing.T) { tx1 := e.PrepareInvocation(t, []byte{byte(opcode.PUSH1)}, []neotest.Signer{acc}, bc.BlockHeight()+5) tx2 := transaction.New([]byte{byte(opcode.PUSH1)}, 0) tx2.Nonce = neotest.Nonce() tx2.ValidUntilBlock = e.Chain.BlockHeight() + 5 tx2.Attributes = []transaction.Attribute{{ Type: transaction.ConflictsT, Value: &transaction.Conflicts{Hash: tx1.Hash()}, }} e.SignTx(t, tx2, -1, acc) require.True(t, bc.IsTxStillRelevant(tx1, mp, false)) require.NoError(t, bc.PoolTx(tx2)) require.False(t, bc.IsTxStillRelevant(tx1, mp, false)) }) t.Run("NotValidBefore", func(t *testing.T) { tx3 := transaction.New([]byte{byte(opcode.PUSH1)}, 0) tx3.Nonce = neotest.Nonce() tx3.Attributes = []transaction.Attribute{{ Type: transaction.NotValidBeforeT, Value: &transaction.NotValidBefore{Height: bc.BlockHeight() + 1}, }} tx3.ValidUntilBlock = bc.BlockHeight() + 2 e.SignTx(t, tx3, -1, acc) require.False(t, bc.IsTxStillRelevant(tx3, nil, false)) e.AddNewBlock(t) require.True(t, bc.IsTxStillRelevant(tx3, nil, false)) }) t.Run("contract witness check fails", func(t *testing.T) { src := fmt.Sprintf(`package verify import ( "github.com/nspcc-dev/neo-go/pkg/interop/contract" "github.com/nspcc-dev/neo-go/pkg/interop/lib/address" ) func Verify() bool { addr := address.ToHash160("`+address.Uint160ToString(e.NativeHash(t, nativenames.Ledger))+`") currentHeight := contract.Call(addr, "currentIndex", contract.ReadStates) return currentHeight.(int) < %d }`, bc.BlockHeight()+2) // deploy + next block c := neotest.CompileSource(t, acc.ScriptHash(), strings.NewReader(src), &compiler.Options{ Name: "verification_contract", }) e.DeployContract(t, c, nil) tx := transaction.New([]byte{byte(opcode.PUSH1)}, 0) tx.Nonce = neotest.Nonce() tx.ValidUntilBlock = bc.BlockHeight() + 2 tx.Signers = []transaction.Signer{ { Account: c.Hash, Scopes: transaction.None, }, } tx.NetworkFee += 10_000_000 tx.Scripts = []transaction.Witness{{}} require.True(t, bc.IsTxStillRelevant(tx, mp, false)) e.AddNewBlock(t) require.False(t, bc.IsTxStillRelevant(tx, mp, false)) }) } func TestBlockchain_MemPoolRemoval(t *testing.T) { const added = 16 const notAdded = 32 bc, acc := chain.NewSingle(t) e := neotest.NewExecutor(t, bc, acc, acc) addedTxes := make([]*transaction.Transaction, added) notAddedTxes := make([]*transaction.Transaction, notAdded) for i := range addedTxes { addedTxes[i] = e.PrepareInvocation(t, []byte{byte(opcode.PUSH1)}, []neotest.Signer{acc}, 100) require.NoError(t, bc.PoolTx(addedTxes[i])) } for i := range notAddedTxes { notAddedTxes[i] = e.PrepareInvocation(t, []byte{byte(opcode.PUSH1)}, []neotest.Signer{acc}, 100) require.NoError(t, bc.PoolTx(notAddedTxes[i])) } mempool := bc.GetMemPool() e.AddNewBlock(t, addedTxes...) for _, tx := range addedTxes { require.False(t, mempool.ContainsKey(tx.Hash())) } for _, tx := range notAddedTxes { require.True(t, mempool.ContainsKey(tx.Hash())) } } func TestBlockchain_HasBlock(t *testing.T) { bc, acc := chain.NewSingle(t) e := neotest.NewExecutor(t, bc, acc, acc) blocks := e.GenerateNewBlocks(t, 10) for i := 0; i < len(blocks); i++ { assert.True(t, bc.HasBlock(blocks[i].Hash())) } newBlock := e.NewUnsignedBlock(t) assert.False(t, bc.HasBlock(newBlock.Hash())) } func TestBlockchain_GetTransaction(t *testing.T) { bc, acc := chain.NewSingle(t) e := neotest.NewExecutor(t, bc, acc, acc) tx1 := e.PrepareInvocation(t, []byte{byte(opcode.PUSH1)}, []neotest.Signer{acc}) e.AddNewBlock(t, tx1) tx2 := e.PrepareInvocation(t, []byte{byte(opcode.PUSH2)}, []neotest.Signer{acc}) tx2Size := io.GetVarSize(tx2) b := e.AddNewBlock(t, tx2) tx, height, err := bc.GetTransaction(tx2.Hash()) require.Nil(t, err) assert.Equal(t, b.Index, height) assert.Equal(t, tx2Size, tx.Size()) assert.Equal(t, b.Transactions[0], tx) } func TestBlockchain_GetClaimable(t *testing.T) { bc, acc := chain.NewSingle(t) t.Run("first generation period", func(t *testing.T) { amount, err := bc.CalculateClaimable(acc.ScriptHash(), 1) require.NoError(t, err) require.EqualValues(t, big.NewInt(5*native.GASFactor/10), amount) }) } func TestBlockchain_Close(t *testing.T) { st := storage.NewMemoryStore() bc, acc := chain.NewSingleWithCustomConfigAndStore(t, nil, st, false) e := neotest.NewExecutor(t, bc, acc, acc) go bc.Run() e.GenerateNewBlocks(t, 10) bc.Close() // It's a hack, but we use internal knowledge of MemoryStore // implementation which makes it completely unusable (up to panicing) // after Close(). require.Panics(t, func() { _ = st.PutChangeSet(map[string][]byte{"0": {1}}, nil) }) } func TestBlockchain_Subscriptions(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.ContainedNotificationEvent, chBufSize) executionCh := make(chan *state.AppExecResult, chBufSize) bc, acc := chain.NewSingle(t) e := neotest.NewExecutor(t, bc, acc, acc) nativeGASHash := e.NativeHash(t, nativenames.Gas) 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) generatedB := e.AddNewBlock(t) 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, generatedB, b) assert.Empty(t, blockCh) aer := <-executionCh assert.Equal(t, b.Hash(), aer.Container) aer = <-executionCh assert.Equal(t, b.Hash(), aer.Container) 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 := e.PrepareInvocation(t, script.Bytes(), []neotest.Signer{acc}) // 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 := e.PrepareInvocation(t, script.Bytes(), []neotest.Signer{acc}) script = io.NewBufBinWriter() emit.Bytes(script.BinWriter, []byte("yay! yay! yay!")) emit.Syscall(script.BinWriter, interopnames.SystemRuntimeNotify) require.NoError(t, script.Err) txGood2 := e.PrepareInvocation(t, script.Bytes(), []neotest.Signer{acc}) invBlock := e.AddNewBlock(t, txGood1, txBad, txGood2) 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.Container) require.Equal(t, exec.VMState, vmstate.Halt) // 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, nativeGASHash, 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.Container) if exec.VMState == vmstate.Halt { 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.Container) require.Equal(t, exec.VMState, vmstate.Halt) bc.UnsubscribeFromBlocks(blockCh) bc.UnsubscribeFromTransactions(txCh) bc.UnsubscribeFromNotifications(notificationCh) bc.UnsubscribeFromExecutions(executionCh) // Ensure that new blocks are processed correctly after unsubscription. e.GenerateNewBlocks(t, 2*chBufSize) } func TestBlockchain_RemoveUntraceable(t *testing.T) { neoCommitteeKey := []byte{0xfb, 0xff, 0xff, 0xff, 0x0e} check := func(t *testing.T, bc *core.Blockchain, tHash, bHash, sHash util.Uint256, errorExpected bool) { _, _, err := bc.GetTransaction(tHash) if errorExpected { require.Error(t, err) } else { require.NoError(t, err) } _, err = bc.GetAppExecResults(tHash, trigger.Application) if errorExpected { require.Error(t, err) } else { require.NoError(t, err) } _, err = bc.GetBlock(bHash) if errorExpected { require.Error(t, err) } else { require.NoError(t, err) } _, err = bc.GetHeader(bHash) require.NoError(t, err) if !sHash.Equals(util.Uint256{}) { sm := bc.GetStateModule() _, err = sm.GetState(sHash, neoCommitteeKey) if errorExpected { require.Error(t, err) } else { require.NoError(t, err) } } } t.Run("P2PStateExchangeExtensions off", func(t *testing.T) { bc, acc := chain.NewSingleWithCustomConfig(t, func(c *config.Blockchain) { c.MaxTraceableBlocks = 2 c.Ledger.GarbageCollectionPeriod = 2 c.Ledger.RemoveUntraceableBlocks = true }) e := neotest.NewExecutor(t, bc, acc, acc) neoValidatorInvoker := e.ValidatorInvoker(e.NativeHash(t, nativenames.Neo)) tx1Hash := neoValidatorInvoker.Invoke(t, true, "transfer", acc.ScriptHash(), util.Uint160{1, 2, 3}, 1, nil) tx1Height := bc.BlockHeight() b1 := e.TopBlock(t) sRoot, err := bc.GetStateModule().GetStateRoot(tx1Height) require.NoError(t, err) neoValidatorInvoker.Invoke(t, true, "transfer", acc.ScriptHash(), util.Uint160{1, 2, 3}, 1, nil) _, h1, err := bc.GetTransaction(tx1Hash) require.NoError(t, err) require.Equal(t, tx1Height, h1) check(t, bc, tx1Hash, b1.Hash(), sRoot.Root, false) e.GenerateNewBlocks(t, 4) sm := bc.GetStateModule() require.Eventually(t, func() bool { _, err = sm.GetState(sRoot.Root, neoCommitteeKey) return err != nil }, 2*bcPersistInterval, 10*time.Millisecond) check(t, bc, tx1Hash, b1.Hash(), sRoot.Root, true) }) t.Run("P2PStateExchangeExtensions on", func(t *testing.T) { bc, acc := chain.NewSingleWithCustomConfig(t, func(c *config.Blockchain) { c.MaxTraceableBlocks = 2 c.Ledger.GarbageCollectionPeriod = 2 c.Ledger.RemoveUntraceableBlocks = true c.P2PStateExchangeExtensions = true c.StateSyncInterval = 2 c.StateRootInHeader = true }) e := neotest.NewExecutor(t, bc, acc, acc) neoValidatorInvoker := e.ValidatorInvoker(e.NativeHash(t, nativenames.Neo)) tx1Hash := neoValidatorInvoker.Invoke(t, true, "transfer", acc.ScriptHash(), util.Uint160{1, 2, 3}, 1, nil) tx1Height := bc.BlockHeight() b1 := e.TopBlock(t) sRoot, err := bc.GetStateModule().GetStateRoot(tx1Height) require.NoError(t, err) tx2Hash := neoValidatorInvoker.Invoke(t, true, "transfer", acc.ScriptHash(), util.Uint160{1, 2, 3}, 1, nil) tx2Height := bc.BlockHeight() b2 := e.TopBlock(t) _, h1, err := bc.GetTransaction(tx1Hash) require.NoError(t, err) require.Equal(t, tx1Height, h1) e.GenerateNewBlocks(t, 3) check(t, bc, tx1Hash, b1.Hash(), sRoot.Root, false) check(t, bc, tx2Hash, b2.Hash(), sRoot.Root, false) e.AddNewBlock(t) check(t, bc, tx1Hash, b1.Hash(), util.Uint256{}, true) check(t, bc, tx2Hash, b2.Hash(), util.Uint256{}, false) _, h2, err := bc.GetTransaction(tx2Hash) require.NoError(t, err) require.Equal(t, tx2Height, h2) }) } func TestBlockchain_InvalidNotification(t *testing.T) { bc, acc := chain.NewSingle(t) e := neotest.NewExecutor(t, bc, acc, acc) cs, _ := contracts.GetTestContractState(t, pathToInternalContracts, 0, 1, acc.ScriptHash()) e.DeployContract(t, &neotest.Contract{ Hash: cs.Hash, NEF: &cs.NEF, Manifest: &cs.Manifest, }, nil) cValidatorInvoker := e.ValidatorInvoker(cs.Hash) cValidatorInvoker.InvokeAndCheck(t, func(t testing.TB, stack []stackitem.Item) { require.Equal(t, 1, len(stack)) require.Nil(t, stack[0]) }, "invalidStack1") cValidatorInvoker.Invoke(t, stackitem.NewInterop(nil), "invalidStack2") } // Test that deletion of non-existent doesn't result in error in tx or block addition. func TestBlockchain_MPTDeleteNoKey(t *testing.T) { bc, acc := chain.NewSingle(t) e := neotest.NewExecutor(t, bc, acc, acc) cs, _ := contracts.GetTestContractState(t, pathToInternalContracts, 0, 1, acc.ScriptHash()) e.DeployContract(t, &neotest.Contract{ Hash: cs.Hash, NEF: &cs.NEF, Manifest: &cs.Manifest, }, nil) cValidatorInvoker := e.ValidatorInvoker(cs.Hash) cValidatorInvoker.Invoke(t, stackitem.Null{}, "delValue", "non-existent-key") } // Test that all default configurations are loadable. func TestConfig_LoadDefaultConfigs(t *testing.T) { var prefixPath = filepath.Join("..", "..", "config") check := func(t *testing.T, cfgFileSuffix any) { cfgPath := filepath.Join(prefixPath, fmt.Sprintf("protocol.%s.yml", cfgFileSuffix)) _, err := config.LoadFile(cfgPath) require.NoError(t, err, fmt.Errorf("failed to load %s", cfgPath)) } testCases := []any{ netmode.MainNet, netmode.PrivNet, netmode.TestNet, netmode.UnitTestNet, "privnet.docker.one", "privnet.docker.two", "privnet.docker.three", "privnet.docker.four", "privnet.docker.single", "unit_testnet.single", } for _, tc := range testCases { t.Run(fmt.Sprintf("%s", tc), func(t *testing.T) { check(t, tc) }) } } func TestBlockchain_VerifyTx(t *testing.T) { bc, validator, committee := chain.NewMultiWithCustomConfig(t, func(c *config.Blockchain) { c.P2PSigExtensions = true c.ReservedAttributes = true }) e := neotest.NewExecutor(t, bc, validator, committee) accs := make([]*wallet.Account, 5) for i := range accs { var err error accs[i], err = wallet.NewAccount() require.NoError(t, err) } notaryServiceFeePerKey := bc.GetNotaryServiceFeePerKey() oracleAcc := accs[2] oraclePubs := keys.PublicKeys{oracleAcc.PublicKey()} require.NoError(t, oracleAcc.ConvertMultisig(1, oraclePubs)) neoHash := e.NativeHash(t, nativenames.Neo) gasHash := e.NativeHash(t, nativenames.Gas) policyHash := e.NativeHash(t, nativenames.Policy) designateHash := e.NativeHash(t, nativenames.Designation) notaryHash := e.NativeHash(t, nativenames.Notary) oracleHash := e.NativeHash(t, nativenames.Oracle) neoValidatorsInvoker := e.ValidatorInvoker(neoHash) gasValidatorsInvoker := e.ValidatorInvoker(gasHash) policySuperInvoker := e.NewInvoker(policyHash, validator, committee) designateSuperInvoker := e.NewInvoker(designateHash, validator, committee) neoOwner := validator.ScriptHash() neoAmount := int64(1_000_000) gasAmount := int64(1_000_000_000) txs := make([]*transaction.Transaction, 0, 2*len(accs)+2) for _, a := range accs { txs = append(txs, neoValidatorsInvoker.PrepareInvoke(t, "transfer", neoOwner, a.Contract.ScriptHash(), neoAmount, nil)) txs = append(txs, gasValidatorsInvoker.PrepareInvoke(t, "transfer", neoOwner, a.Contract.ScriptHash(), gasAmount, nil)) } txs = append(txs, neoValidatorsInvoker.PrepareInvoke(t, "transfer", neoOwner, committee.ScriptHash(), neoAmount, nil)) txs = append(txs, gasValidatorsInvoker.PrepareInvoke(t, "transfer", neoOwner, committee.ScriptHash(), gasAmount, nil)) e.AddNewBlock(t, txs...) for _, tx := range txs { e.CheckHalt(t, tx.Hash(), stackitem.NewBool(true)) } policySuperInvoker.Invoke(t, true, "blockAccount", accs[1].PrivateKey().GetScriptHash().BytesBE()) checkErr := func(t *testing.T, expectedErr error, tx *transaction.Transaction) { err := bc.VerifyTx(tx) require.ErrorIs(t, err, expectedErr) } testScript := []byte{byte(opcode.PUSH1)} newTestTx := func(t *testing.T, signer util.Uint160, script []byte) *transaction.Transaction { tx := transaction.New(script, 1_000_000) tx.Nonce = neotest.Nonce() tx.ValidUntilBlock = e.Chain.BlockHeight() + 5 tx.Signers = []transaction.Signer{{ Account: signer, Scopes: transaction.CalledByEntry, }} tx.NetworkFee = int64(io.GetVarSize(tx)+200 /* witness */) * bc.FeePerByte() tx.NetworkFee += 1_000_000 // verification cost return tx } h := accs[0].PrivateKey().GetScriptHash() t.Run("Expired", func(t *testing.T) { tx := newTestTx(t, h, testScript) tx.ValidUntilBlock = 1 require.NoError(t, accs[0].SignTx(netmode.UnitTestNet, tx)) checkErr(t, core.ErrTxExpired, tx) }) t.Run("BlockedAccount", func(t *testing.T) { tx := newTestTx(t, accs[1].PrivateKey().GetScriptHash(), testScript) require.NoError(t, accs[1].SignTx(netmode.UnitTestNet, tx)) checkErr(t, core.ErrPolicy, tx) }) t.Run("InsufficientGas", func(t *testing.T) { balance := bc.GetUtilityTokenBalance(h) tx := newTestTx(t, h, testScript) tx.SystemFee = balance.Int64() + 1 require.NoError(t, accs[0].SignTx(netmode.UnitTestNet, tx)) checkErr(t, core.ErrInsufficientFunds, tx) }) t.Run("TooBigSystemFee", func(t *testing.T) { tx := newTestTx(t, h, testScript) tx.SystemFee = bc.GetConfig().MaxBlockSystemFee + 100500 require.NoError(t, accs[0].SignTx(netmode.UnitTestNet, tx)) checkErr(t, core.ErrPolicy, tx) }) t.Run("TooBigTx", func(t *testing.T) { script := make([]byte, transaction.MaxTransactionSize) tx := newTestTx(t, h, script) require.NoError(t, accs[0].SignTx(netmode.UnitTestNet, tx)) checkErr(t, core.ErrTxTooBig, tx) }) t.Run("NetworkFee", func(t *testing.T) { t.Run("SmallNetworkFee", func(t *testing.T) { tx := newTestTx(t, h, testScript) tx.NetworkFee = 1 require.NoError(t, accs[0].SignTx(netmode.UnitTestNet, tx)) checkErr(t, core.ErrTxSmallNetworkFee, tx) }) t.Run("AlmostEnoughNetworkFee", func(t *testing.T) { tx := newTestTx(t, h, testScript) verificationNetFee, calcultedScriptSize := fee.Calculate(bc.GetBaseExecFee(), 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(netmode.UnitTestNet, tx)) require.Equal(t, expectedSize, io.GetVarSize(tx)) checkErr(t, core.ErrVerificationFailed, tx) }) t.Run("EnoughNetworkFee", func(t *testing.T) { tx := newTestTx(t, h, testScript) verificationNetFee, calcultedScriptSize := fee.Calculate(bc.GetBaseExecFee(), accs[0].Contract.Script) expectedSize := io.GetVarSize(tx) + calcultedScriptSize calculatedNetFee := verificationNetFee + int64(expectedSize)*bc.FeePerByte() tx.NetworkFee = calculatedNetFee require.NoError(t, accs[0].SignTx(netmode.UnitTestNet, tx)) require.Equal(t, expectedSize, io.GetVarSize(tx)) require.NoError(t, bc.VerifyTx(tx)) }) t.Run("CalculateNetworkFee, signature script", func(t *testing.T) { tx := newTestTx(t, h, testScript) expectedSize := io.GetVarSize(tx) verificationNetFee, calculatedScriptSize := fee.Calculate(bc.GetBaseExecFee(), accs[0].Contract.Script) expectedSize += calculatedScriptSize expectedNetFee := verificationNetFee + int64(expectedSize)*bc.FeePerByte() tx.NetworkFee = expectedNetFee require.NoError(t, accs[0].SignTx(netmode.UnitTestNet, tx)) actualSize := io.GetVarSize(tx) require.Equal(t, expectedSize, actualSize) gasConsumed, err := bc.VerifyWitness(h, tx, &tx.Scripts[0], -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.PublicKey()} require.NoError(t, multisigAcc.ConvertMultisig(1, pKeys)) multisigHash := hash.Hash160(multisigAcc.Contract.Script) tx := newTestTx(t, multisigHash, testScript) verificationNetFee, calculatedScriptSize := fee.Calculate(bc.GetBaseExecFee(), multisigAcc.Contract.Script) expectedSize := io.GetVarSize(tx) + calculatedScriptSize expectedNetFee := verificationNetFee + int64(expectedSize)*bc.FeePerByte() tx.NetworkFee = expectedNetFee require.NoError(t, multisigAcc.SignTx(netmode.UnitTestNet, tx)) actualSize := io.GetVarSize(tx) require.Equal(t, expectedSize, actualSize) gasConsumed, err := bc.VerifyWitness(multisigHash, tx, &tx.Scripts[0], -1) require.NoError(t, err) require.Equal(t, verificationNetFee, gasConsumed) require.Equal(t, expectedNetFee, bc.FeePerByte()*int64(actualSize)+gasConsumed) }) }) t.Run("InvalidTxScript", func(t *testing.T) { tx := newTestTx(t, h, testScript) tx.Script = append(tx.Script, 0xff) require.NoError(t, accs[0].SignTx(netmode.UnitTestNet, tx)) checkErr(t, core.ErrInvalidScript, tx) }) t.Run("InvalidVerificationScript", func(t *testing.T) { tx := newTestTx(t, h, testScript) verif := []byte{byte(opcode.JMP), 3, 0xff, byte(opcode.PUSHT)} tx.Signers = append(tx.Signers, transaction.Signer{ Account: hash.Hash160(verif), Scopes: transaction.Global, }) tx.NetworkFee += 1000000 require.NoError(t, accs[0].SignTx(netmode.UnitTestNet, tx)) tx.Scripts = append(tx.Scripts, transaction.Witness{ InvocationScript: []byte{}, VerificationScript: verif, }) checkErr(t, core.ErrInvalidVerificationScript, tx) }) t.Run("InvalidInvocationScript", func(t *testing.T) { tx := newTestTx(t, h, testScript) verif := []byte{byte(opcode.PUSHT)} tx.Signers = append(tx.Signers, transaction.Signer{ Account: hash.Hash160(verif), Scopes: transaction.Global, }) tx.NetworkFee += 1000000 require.NoError(t, accs[0].SignTx(netmode.UnitTestNet, tx)) tx.Scripts = append(tx.Scripts, transaction.Witness{ InvocationScript: []byte{byte(opcode.JMP), 3, 0xff}, VerificationScript: verif, }) checkErr(t, core.ErrInvalidInvocationScript, tx) }) t.Run("Conflict", func(t *testing.T) { balance := bc.GetUtilityTokenBalance(h).Int64() tx := newTestTx(t, h, testScript) tx.NetworkFee = balance / 2 require.NoError(t, accs[0].SignTx(netmode.UnitTestNet, tx)) require.NoError(t, bc.PoolTx(tx)) tx2 := newTestTx(t, h, testScript) tx2.NetworkFee = balance / 2 require.NoError(t, accs[0].SignTx(netmode.UnitTestNet, tx2)) err := bc.PoolTx(tx2) require.ErrorIs(t, err, core.ErrMemPoolConflict) }) t.Run("InvalidWitnessHash", func(t *testing.T) { tx := newTestTx(t, h, testScript) require.NoError(t, accs[0].SignTx(netmode.UnitTestNet, tx)) tx.Scripts[0].VerificationScript = []byte{byte(opcode.PUSHT)} checkErr(t, core.ErrWitnessHashMismatch, tx) }) t.Run("InvalidWitnessSignature", func(t *testing.T) { tx := newTestTx(t, h, testScript) require.NoError(t, accs[0].SignTx(netmode.UnitTestNet, tx)) tx.Scripts[0].InvocationScript[10] = ^tx.Scripts[0].InvocationScript[10] checkErr(t, core.ErrVerificationFailed, tx) }) t.Run("InsufficientNetworkFeeForSecondWitness", func(t *testing.T) { tx := newTestTx(t, h, testScript) tx.Signers = append(tx.Signers, transaction.Signer{ Account: accs[3].PrivateKey().GetScriptHash(), Scopes: transaction.Global, }) require.NoError(t, accs[0].SignTx(netmode.UnitTestNet, tx)) require.NoError(t, accs[3].SignTx(netmode.UnitTestNet, tx)) checkErr(t, core.ErrVerificationFailed, tx) }) t.Run("OldTX", func(t *testing.T) { tx := newTestTx(t, h, testScript) require.NoError(t, accs[0].SignTx(netmode.UnitTestNet, tx)) e.AddNewBlock(t, tx) checkErr(t, core.ErrAlreadyExists, tx) }) t.Run("MemPooledTX", func(t *testing.T) { tx := newTestTx(t, h, testScript) require.NoError(t, accs[0].SignTx(netmode.UnitTestNet, tx)) require.NoError(t, bc.PoolTx(tx)) err := bc.PoolTx(tx) require.ErrorIs(t, err, core.ErrAlreadyInPool) }) t.Run("MemPoolOOM", func(t *testing.T) { mp := mempool.New(1, 0, false, nil) tx1 := newTestTx(t, h, testScript) tx1.NetworkFee += 10000 // Give it more priority. require.NoError(t, accs[0].SignTx(netmode.UnitTestNet, tx1)) require.NoError(t, bc.PoolTx(tx1, mp)) tx2 := newTestTx(t, h, testScript) require.NoError(t, accs[0].SignTx(netmode.UnitTestNet, tx2)) err := bc.PoolTx(tx2, mp) require.ErrorIs(t, err, core.ErrOOM) }) t.Run("Attribute", func(t *testing.T) { t.Run("InvalidHighPriority", func(t *testing.T) { tx := newTestTx(t, h, testScript) tx.Attributes = append(tx.Attributes, transaction.Attribute{Type: transaction.HighPriority}) require.NoError(t, accs[0].SignTx(netmode.UnitTestNet, tx)) checkErr(t, core.ErrInvalidAttribute, tx) }) t.Run("ValidHighPriority", func(t *testing.T) { tx := newTestTx(t, h, testScript) tx.Attributes = append(tx.Attributes, transaction.Attribute{Type: transaction.HighPriority}) tx.NetworkFee += 4_000_000 // multisig check tx.Signers = []transaction.Signer{{ Account: committee.ScriptHash(), Scopes: transaction.None, }} rawScript := committee.Script() size := io.GetVarSize(tx) netFee, sizeDelta := fee.Calculate(bc.GetBaseExecFee(), rawScript) tx.NetworkFee += netFee tx.NetworkFee += int64(size+sizeDelta) * bc.FeePerByte() tx.Scripts = []transaction.Witness{{ InvocationScript: committee.SignHashable(uint32(netmode.UnitTestNet), tx), VerificationScript: rawScript, }} require.NoError(t, bc.VerifyTx(tx)) }) t.Run("Oracle", func(t *testing.T) { cs := contracts.GetOracleContractState(t, pathToInternalContracts, validator.ScriptHash(), 0) e.DeployContract(t, &neotest.Contract{ Hash: cs.Hash, NEF: &cs.NEF, Manifest: &cs.Manifest, }, nil) cInvoker := e.ValidatorInvoker(cs.Hash) const gasForResponse int64 = 10_000_000 cInvoker.Invoke(t, stackitem.Null{}, "requestURL", "https://get.1234", "", "handle", []byte{}, gasForResponse) oracleScript, err := smartcontract.CreateMajorityMultiSigRedeemScript(oraclePubs) require.NoError(t, err) oracleMultisigHash := hash.Hash160(oracleScript) respScript := native.CreateOracleResponseScript(oracleHash) // We need to create new transaction, // because hashes are cached after signing. getOracleTx := func(t *testing.T) *transaction.Transaction { tx := transaction.New(respScript, 1000_0000) tx.Nonce = neotest.Nonce() tx.ValidUntilBlock = bc.BlockHeight() + 1 resp := &transaction.OracleResponse{ ID: 0, 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 = gasForResponse - tx.NetworkFee tx.Signers = []transaction.Signer{{ Account: oracleMultisigHash, Scopes: transaction.None, }} size := io.GetVarSize(tx) netFee, sizeDelta := fee.Calculate(bc.GetBaseExecFee(), 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(netmode.UnitTestNet, tx)) checkErr(t, core.ErrInvalidAttribute, tx) }) keys := make([]any, 0, len(oraclePubs)) for _, p := range oraclePubs { keys = append(keys, p.Bytes()) } designateSuperInvoker.Invoke(t, stackitem.Null{}, "designateAsRole", int64(noderoles.Oracle), keys) t.Run("Valid", func(t *testing.T) { tx := getOracleTx(t) require.NoError(t, oracleAcc.SignTx(netmode.UnitTestNet, tx)) require.NoError(t, bc.VerifyTx(tx)) t.Run("NativeVerify", func(t *testing.T) { tx.Signers = append(tx.Signers, transaction.Signer{ Account: oracleHash, Scopes: transaction.None, }) tx.Scripts = append(tx.Scripts, transaction.Witness{}) t.Run("NonZeroVerification", func(t *testing.T) { w := io.NewBufBinWriter() emit.Opcodes(w.BinWriter, opcode.ABORT) emit.Bytes(w.BinWriter, util.Uint160{}.BytesBE()) emit.Int(w.BinWriter, 0) emit.String(w.BinWriter, nativenames.Oracle) tx.Scripts[len(tx.Scripts)-1].VerificationScript = w.Bytes() err := bc.VerifyTx(tx) require.ErrorIs(t, err, core.ErrNativeContractWitness) }) t.Run("Good", func(t *testing.T) { tx.Scripts[len(tx.Scripts)-1].VerificationScript = nil 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(netmode.UnitTestNet, tx)) checkErr(t, core.ErrInvalidAttribute, tx) }) t.Run("InvalidScope", func(t *testing.T) { tx := getOracleTx(t) tx.Signers[0].Scopes = transaction.Global require.NoError(t, oracleAcc.SignTx(netmode.UnitTestNet, tx)) checkErr(t, core.ErrInvalidAttribute, tx) }) t.Run("InvalidScript", func(t *testing.T) { tx := getOracleTx(t) tx.Script = append(tx.Script, byte(opcode.NOP)) require.NoError(t, oracleAcc.SignTx(netmode.UnitTestNet, tx)) checkErr(t, core.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(netmode.UnitTestNet, tx)) checkErr(t, core.ErrInvalidAttribute, tx) }) t.Run("SmallFee", func(t *testing.T) { tx := getOracleTx(t) tx.SystemFee = 0 require.NoError(t, oracleAcc.SignTx(netmode.UnitTestNet, tx)) checkErr(t, core.ErrInvalidAttribute, tx) }) }) t.Run("NotValidBefore", func(t *testing.T) { getNVBTx := func(e *neotest.Executor, height uint32) *transaction.Transaction { tx := newTestTx(t, h, testScript) tx.Attributes = append(tx.Attributes, transaction.Attribute{Type: transaction.NotValidBeforeT, Value: &transaction.NotValidBefore{Height: height}}) tx.NetworkFee += 4_000_000 // multisig check tx.Signers = []transaction.Signer{{ Account: e.Validator.ScriptHash(), Scopes: transaction.None, }} size := io.GetVarSize(tx) rawScript := e.Validator.Script() netFee, sizeDelta := fee.Calculate(e.Chain.GetBaseExecFee(), rawScript) tx.NetworkFee += netFee tx.NetworkFee += int64(size+sizeDelta) * e.Chain.FeePerByte() tx.Scripts = []transaction.Witness{{ InvocationScript: e.Validator.SignHashable(uint32(netmode.UnitTestNet), tx), VerificationScript: rawScript, }} return tx } t.Run("Disabled", func(t *testing.T) { // check that NVB attribute is not an extension anymore. bcBad, validatorBad, committeeBad := chain.NewMultiWithCustomConfig(t, func(c *config.Blockchain) { c.P2PSigExtensions = false c.ReservedAttributes = false }) eBad := neotest.NewExecutor(t, bcBad, validatorBad, committeeBad) tx := getNVBTx(eBad, bcBad.BlockHeight()) err := bcBad.VerifyTx(tx) require.NoError(t, err) }) t.Run("Enabled", func(t *testing.T) { t.Run("NotYetValid", func(t *testing.T) { tx := getNVBTx(e, bc.BlockHeight()+1) require.ErrorIs(t, bc.VerifyTx(tx), core.ErrInvalidAttribute) }) t.Run("positive", func(t *testing.T) { tx := getNVBTx(e, bc.BlockHeight()) require.NoError(t, bc.VerifyTx(tx)) }) }) }) t.Run("Reserved", func(t *testing.T) { getReservedTx := func(e *neotest.Executor, attrType transaction.AttrType) *transaction.Transaction { tx := newTestTx(t, h, testScript) tx.Attributes = append(tx.Attributes, transaction.Attribute{Type: attrType, Value: &transaction.Reserved{Value: []byte{1, 2, 3}}}) tx.NetworkFee += 4_000_000 // multisig check tx.Signers = []transaction.Signer{{ Account: e.Validator.ScriptHash(), Scopes: transaction.None, }} rawScript := e.Validator.Script() size := io.GetVarSize(tx) netFee, sizeDelta := fee.Calculate(e.Chain.GetBaseExecFee(), rawScript) tx.NetworkFee += netFee tx.NetworkFee += int64(size+sizeDelta) * e.Chain.FeePerByte() tx.Scripts = []transaction.Witness{{ InvocationScript: e.Validator.SignHashable(uint32(netmode.UnitTestNet), tx), VerificationScript: rawScript, }} return tx } t.Run("Disabled", func(t *testing.T) { bcBad, validatorBad, committeeBad := chain.NewMultiWithCustomConfig(t, func(c *config.Blockchain) { c.P2PSigExtensions = false c.ReservedAttributes = false }) eBad := neotest.NewExecutor(t, bcBad, validatorBad, committeeBad) tx := getReservedTx(eBad, transaction.ReservedLowerBound+3) err := bcBad.VerifyTx(tx) require.Error(t, err) require.True(t, strings.Contains(err.Error(), "invalid attribute: attribute of reserved type was found, but ReservedAttributes are disabled")) }) t.Run("Enabled", func(t *testing.T) { tx := getReservedTx(e, transaction.ReservedLowerBound+3) require.NoError(t, bc.VerifyTx(tx)) }) }) t.Run("Conflicts", func(t *testing.T) { getConflictsTx := func(e *neotest.Executor, hashes ...util.Uint256) *transaction.Transaction { tx := newTestTx(t, h, testScript) tx.Attributes = make([]transaction.Attribute, len(hashes)) for i, h := range hashes { tx.Attributes[i] = transaction.Attribute{ Type: transaction.ConflictsT, Value: &transaction.Conflicts{ Hash: h, }, } } tx.NetworkFee += 4_000_000 // multisig check tx.Signers = []transaction.Signer{{ Account: e.Validator.ScriptHash(), Scopes: transaction.None, }} rawScript := e.Validator.Script() size := io.GetVarSize(tx) netFee, sizeDelta := fee.Calculate(e.Chain.GetBaseExecFee(), rawScript) tx.NetworkFee += netFee tx.NetworkFee += int64(size+sizeDelta) * e.Chain.FeePerByte() tx.Scripts = []transaction.Witness{{ InvocationScript: e.Validator.SignHashable(uint32(netmode.UnitTestNet), tx), VerificationScript: rawScript, }} return tx } t.Run("disabled", func(t *testing.T) { // check that Conflicts attribute is not an extension anymore. bcBad, validatorBad, committeeBad := chain.NewMultiWithCustomConfig(t, func(c *config.Blockchain) { c.P2PSigExtensions = false c.ReservedAttributes = false }) eBad := neotest.NewExecutor(t, bcBad, validatorBad, committeeBad) tx := getConflictsTx(eBad, util.Uint256{1, 2, 3}) err := bcBad.VerifyTx(tx) require.NoError(t, err) }) t.Run("enabled", func(t *testing.T) { t.Run("dummy on-chain conflict", func(t *testing.T) { t.Run("on-chain conflict signed by malicious party", func(t *testing.T) { tx := newTestTx(t, h, testScript) require.NoError(t, accs[0].SignTx(netmode.UnitTestNet, tx)) conflicting := transaction.New([]byte{byte(opcode.RET)}, 1000_0000) conflicting.ValidUntilBlock = bc.BlockHeight() + 1 conflicting.Signers = []transaction.Signer{ { Account: validator.ScriptHash(), Scopes: transaction.CalledByEntry, }, } conflicting.Attributes = []transaction.Attribute{ { Type: transaction.ConflictsT, Value: &transaction.Conflicts{ Hash: tx.Hash(), }, }, } conflicting.NetworkFee = 1000_0000 require.NoError(t, validator.SignTx(netmode.UnitTestNet, conflicting)) e.AddNewBlock(t, conflicting) // We expect `tx` to pass verification, because on-chained `conflicting` doesn't have // `tx`'s payer in the signers list, thus, `conflicting` should be considered as // malicious conflict. require.NoError(t, bc.VerifyTx(tx)) }) t.Run("multiple on-chain conflicts signed by malicious parties", func(t *testing.T) { m1 := e.NewAccount(t) m2 := e.NewAccount(t) m3 := e.NewAccount(t) good := e.NewAccount(t) // txGood doesn't conflict with anyone and signed by good signer. txGood := newTestTx(t, good.ScriptHash(), testScript) require.NoError(t, good.SignTx(netmode.UnitTestNet, txGood)) // txM1 conflicts with txGood and signed by two malicious signers. txM1 := newTestTx(t, m1.ScriptHash(), testScript) txM1.Signers = append(txM1.Signers, transaction.Signer{Account: m2.ScriptHash()}) txM1.Attributes = []transaction.Attribute{ { Type: transaction.ConflictsT, Value: &transaction.Conflicts{ Hash: txGood.Hash(), }, }, } txM1.NetworkFee = 1_000_0000 require.NoError(t, m1.SignTx(netmode.UnitTestNet, txM1)) require.NoError(t, m2.SignTx(netmode.UnitTestNet, txM1)) e.AddNewBlock(t, txM1) // txM2 conflicts with txGood and signed by one malicious signer. txM2 := newTestTx(t, m3.ScriptHash(), testScript) txM2.Attributes = []transaction.Attribute{ { Type: transaction.ConflictsT, Value: &transaction.Conflicts{ Hash: txGood.Hash(), }, }, } txM2.NetworkFee = 1_000_0000 require.NoError(t, m3.SignTx(netmode.UnitTestNet, txM2)) e.AddNewBlock(t, txM2) // We expect `tx` to pass verification, because on-chained `conflicting` doesn't have // `tx`'s payer in the signers list, thus, `conflicting` should be considered as // malicious conflict. require.NoError(t, bc.VerifyTx(txGood)) // After that txGood can be added to the chain normally. e.AddNewBlock(t, txGood) // And after that ErrAlreadyExist is expected on verification. require.ErrorIs(t, bc.VerifyTx(txGood), core.ErrAlreadyExists) }) t.Run("multiple on-chain conflicts signed by [valid+malicious] parties", func(t *testing.T) { m1 := e.NewAccount(t) m2 := e.NewAccount(t) m3 := e.NewAccount(t) good := e.NewAccount(t) // txGood doesn't conflict with anyone and signed by good signer. txGood := newTestTx(t, good.ScriptHash(), testScript) require.NoError(t, good.SignTx(netmode.UnitTestNet, txGood)) // txM1 conflicts with txGood and signed by one malicious and one good signers. txM1 := newTestTx(t, m1.ScriptHash(), testScript) txM1.Signers = append(txM1.Signers, transaction.Signer{Account: good.ScriptHash()}) txM1.Attributes = []transaction.Attribute{ { Type: transaction.ConflictsT, Value: &transaction.Conflicts{ Hash: txGood.Hash(), }, }, } txM1.NetworkFee = 1_000_0000 require.NoError(t, m1.SignTx(netmode.UnitTestNet, txM1)) require.NoError(t, good.SignTx(netmode.UnitTestNet, txM1)) e.AddNewBlock(t, txM1) // txM2 conflicts with txGood and signed by two malicious signers. txM2 := newTestTx(t, m2.ScriptHash(), testScript) txM2.Signers = append(txM2.Signers, transaction.Signer{Account: m3.ScriptHash()}) txM2.Attributes = []transaction.Attribute{ { Type: transaction.ConflictsT, Value: &transaction.Conflicts{ Hash: txGood.Hash(), }, }, } txM2.NetworkFee = 1_000_0000 require.NoError(t, m2.SignTx(netmode.UnitTestNet, txM2)) require.NoError(t, m3.SignTx(netmode.UnitTestNet, txM2)) e.AddNewBlock(t, txM2) // We expect `tx` to fail verification, because one of the on-chained `conflicting` // transactions has common signers with `tx`, thus, `conflicting` should be // considered as a valid conflict. require.ErrorIs(t, bc.VerifyTx(txGood), core.ErrHasConflicts) }) t.Run("multiple on-chain conflicts signed by [malicious+valid] parties", func(t *testing.T) { m1 := e.NewAccount(t) m2 := e.NewAccount(t) m3 := e.NewAccount(t) good := e.NewAccount(t) // txGood doesn't conflict with anyone and signed by good signer. txGood := newTestTx(t, good.ScriptHash(), testScript) require.NoError(t, good.SignTx(netmode.UnitTestNet, txGood)) // txM2 conflicts with txGood and signed by two malicious signers. txM2 := newTestTx(t, m2.ScriptHash(), testScript) txM2.Signers = append(txM2.Signers, transaction.Signer{Account: m3.ScriptHash()}) txM2.Attributes = []transaction.Attribute{ { Type: transaction.ConflictsT, Value: &transaction.Conflicts{ Hash: txGood.Hash(), }, }, } txM2.NetworkFee = 1_000_0000 require.NoError(t, m2.SignTx(netmode.UnitTestNet, txM2)) require.NoError(t, m3.SignTx(netmode.UnitTestNet, txM2)) e.AddNewBlock(t, txM2) // txM1 conflicts with txGood and signed by one malicious and one good signers. txM1 := newTestTx(t, m1.ScriptHash(), testScript) txM1.Signers = append(txM1.Signers, transaction.Signer{Account: good.ScriptHash()}) txM1.Attributes = []transaction.Attribute{ { Type: transaction.ConflictsT, Value: &transaction.Conflicts{ Hash: txGood.Hash(), }, }, } txM1.NetworkFee = 1_000_0000 require.NoError(t, m1.SignTx(netmode.UnitTestNet, txM1)) require.NoError(t, good.SignTx(netmode.UnitTestNet, txM1)) e.AddNewBlock(t, txM1) // We expect `tx` to fail verification, because one of the on-chained `conflicting` // transactions has common signers with `tx`, thus, `conflicting` should be // considered as a valid conflict. require.ErrorIs(t, bc.VerifyTx(txGood), core.ErrHasConflicts) }) t.Run("multiple on-chain conflicts signed by [valid + malicious + valid] parties", func(t *testing.T) { m1 := e.NewAccount(t) m2 := e.NewAccount(t) m3 := e.NewAccount(t) good := e.NewAccount(t) // txGood doesn't conflict with anyone and signed by good signer. txGood := newTestTx(t, good.ScriptHash(), testScript) require.NoError(t, good.SignTx(netmode.UnitTestNet, txGood)) // txM1 conflicts with txGood and signed by one malicious and one good signers. txM1 := newTestTx(t, m1.ScriptHash(), testScript) txM1.Signers = append(txM1.Signers, transaction.Signer{Account: good.ScriptHash()}) txM1.Attributes = []transaction.Attribute{ { Type: transaction.ConflictsT, Value: &transaction.Conflicts{ Hash: txGood.Hash(), }, }, } txM1.NetworkFee = 1_000_0000 require.NoError(t, m1.SignTx(netmode.UnitTestNet, txM1)) require.NoError(t, good.SignTx(netmode.UnitTestNet, txM1)) e.AddNewBlock(t, txM1) // txM2 conflicts with txGood and signed by two malicious signers. txM2 := newTestTx(t, m2.ScriptHash(), testScript) txM2.Signers = append(txM2.Signers, transaction.Signer{Account: m3.ScriptHash()}) txM2.Attributes = []transaction.Attribute{ { Type: transaction.ConflictsT, Value: &transaction.Conflicts{ Hash: txGood.Hash(), }, }, } txM2.NetworkFee = 1_000_0000 require.NoError(t, m2.SignTx(netmode.UnitTestNet, txM2)) require.NoError(t, m3.SignTx(netmode.UnitTestNet, txM2)) e.AddNewBlock(t, txM2) // txM3 conflicts with txGood and signed by one good and one malicious signers. txM3 := newTestTx(t, good.ScriptHash(), testScript) txM3.Signers = append(txM3.Signers, transaction.Signer{Account: m1.ScriptHash()}) txM3.Attributes = []transaction.Attribute{ { Type: transaction.ConflictsT, Value: &transaction.Conflicts{ Hash: txGood.Hash(), }, }, } txM3.NetworkFee = 1_000_0000 require.NoError(t, good.SignTx(netmode.UnitTestNet, txM3)) require.NoError(t, m1.SignTx(netmode.UnitTestNet, txM3)) e.AddNewBlock(t, txM3) // We expect `tx` to fail verification, because one of the on-chained `conflicting` // transactions has common signers with `tx`, thus, `conflicting` should be // considered as a valid conflict. require.ErrorIs(t, bc.VerifyTx(txGood), core.ErrHasConflicts) }) t.Run("on-chain conflict signed by single valid sender", func(t *testing.T) { tx := newTestTx(t, h, testScript) tx.Signers = []transaction.Signer{{Account: validator.ScriptHash()}} require.NoError(t, validator.SignTx(netmode.UnitTestNet, tx)) conflicting := transaction.New([]byte{byte(opcode.RET)}, 1000_0000) conflicting.ValidUntilBlock = bc.BlockHeight() + 1 conflicting.Signers = []transaction.Signer{ { Account: validator.ScriptHash(), Scopes: transaction.CalledByEntry, }, } conflicting.Attributes = []transaction.Attribute{ { Type: transaction.ConflictsT, Value: &transaction.Conflicts{ Hash: tx.Hash(), }, }, } conflicting.NetworkFee = 1000_0000 require.NoError(t, validator.SignTx(netmode.UnitTestNet, conflicting)) e.AddNewBlock(t, conflicting) // We expect `tx` to fail verification, because on-chained `conflicting` has // `tx`'s payer as a signer. require.ErrorIs(t, bc.VerifyTx(tx), core.ErrHasConflicts) }) }) t.Run("attribute on-chain conflict", func(t *testing.T) { tx := neoValidatorsInvoker.Invoke(t, stackitem.NewBool(true), "transfer", neoOwner, neoOwner, 1, nil) txConflict := getConflictsTx(e, tx) require.Error(t, bc.VerifyTx(txConflict)) }) t.Run("positive", func(t *testing.T) { tx := getConflictsTx(e, random.Uint256()) require.NoError(t, bc.VerifyTx(tx)) }) }) }) t.Run("NotaryAssisted", func(t *testing.T) { notary, err := wallet.NewAccount() require.NoError(t, err) designateSuperInvoker.Invoke(t, stackitem.Null{}, "designateAsRole", int64(noderoles.P2PNotary), []any{notary.PublicKey().Bytes()}) txSetNotary := transaction.New([]byte{byte(opcode.RET)}, 0) txSetNotary.Signers = []transaction.Signer{ { Account: committee.ScriptHash(), Scopes: transaction.Global, }, } txSetNotary.Scripts = []transaction.Witness{{ InvocationScript: e.Committee.SignHashable(uint32(netmode.UnitTestNet), txSetNotary), VerificationScript: e.Committee.Script(), }} getNotaryAssistedTx := func(e *neotest.Executor, signaturesCount uint8, serviceFee int64) *transaction.Transaction { tx := newTestTx(t, h, testScript) tx.Attributes = append(tx.Attributes, transaction.Attribute{Type: transaction.NotaryAssistedT, Value: &transaction.NotaryAssisted{ NKeys: signaturesCount, }}) tx.NetworkFee += serviceFee // additional fee for NotaryAssisted attribute tx.NetworkFee += 4_000_000 // multisig check tx.Signers = []transaction.Signer{{ Account: e.CommitteeHash, Scopes: transaction.None, }, { Account: notaryHash, Scopes: transaction.None, }, } rawScript := committee.Script() size := io.GetVarSize(tx) netFee, sizeDelta := fee.Calculate(e.Chain.GetBaseExecFee(), rawScript) tx.NetworkFee += netFee tx.NetworkFee += int64(size+sizeDelta) * e.Chain.FeePerByte() tx.Scripts = []transaction.Witness{ { InvocationScript: committee.SignHashable(uint32(netmode.UnitTestNet), tx), VerificationScript: rawScript, }, { InvocationScript: append([]byte{byte(opcode.PUSHDATA1), keys.SignatureLen}, notary.PrivateKey().SignHashable(uint32(netmode.UnitTestNet), tx)...), }, } return tx } t.Run("Disabled", func(t *testing.T) { bcBad, validatorBad, committeeBad := chain.NewMultiWithCustomConfig(t, func(c *config.Blockchain) { c.P2PSigExtensions = false c.ReservedAttributes = false }) eBad := neotest.NewExecutor(t, bcBad, validatorBad, committeeBad) tx := transaction.New(testScript, 1_000_000) tx.Nonce = neotest.Nonce() tx.ValidUntilBlock = e.Chain.BlockHeight() + 5 tx.Attributes = append(tx.Attributes, transaction.Attribute{Type: transaction.NotaryAssistedT, Value: &transaction.NotaryAssisted{NKeys: 0}}) tx.NetworkFee = 1_0000_0000 eBad.SignTx(t, tx, 1_0000_0000, eBad.Committee) err := bcBad.VerifyTx(tx) require.Error(t, err) require.True(t, strings.Contains(err.Error(), "invalid attribute: NotaryAssisted attribute was found, but P2PSigExtensions are disabled")) }) t.Run("Enabled, insufficient network fee", func(t *testing.T) { tx := getNotaryAssistedTx(e, 1, 0) require.Error(t, bc.VerifyTx(tx)) }) t.Run("Test verify", func(t *testing.T) { t.Run("no NotaryAssisted attribute", func(t *testing.T) { tx := getNotaryAssistedTx(e, 1, (1+1)*notaryServiceFeePerKey) tx.Attributes = []transaction.Attribute{} tx.Signers = []transaction.Signer{ { Account: committee.ScriptHash(), Scopes: transaction.None, }, { Account: notaryHash, Scopes: transaction.None, }, } tx.Scripts = []transaction.Witness{ { InvocationScript: committee.SignHashable(uint32(netmode.UnitTestNet), tx), VerificationScript: committee.Script(), }, { InvocationScript: append([]byte{byte(opcode.PUSHDATA1), keys.SignatureLen}, notary.PrivateKey().SignHashable(uint32(netmode.UnitTestNet), tx)...), }, } require.Error(t, bc.VerifyTx(tx)) }) t.Run("no deposit", func(t *testing.T) { tx := getNotaryAssistedTx(e, 1, (1+1)*notaryServiceFeePerKey) tx.Signers = []transaction.Signer{ { Account: notaryHash, Scopes: transaction.None, }, { Account: committee.ScriptHash(), Scopes: transaction.None, }, } tx.Scripts = []transaction.Witness{ { InvocationScript: append([]byte{byte(opcode.PUSHDATA1), keys.SignatureLen}, notary.PrivateKey().SignHashable(uint32(netmode.UnitTestNet), tx)...), }, { InvocationScript: committee.SignHashable(uint32(netmode.UnitTestNet), tx), VerificationScript: committee.Script(), }, } require.Error(t, bc.VerifyTx(tx)) }) t.Run("bad Notary signer scope", func(t *testing.T) { tx := getNotaryAssistedTx(e, 1, (1+1)*notaryServiceFeePerKey) tx.Signers = []transaction.Signer{ { Account: committee.ScriptHash(), Scopes: transaction.None, }, { Account: notaryHash, Scopes: transaction.CalledByEntry, }, } tx.Scripts = []transaction.Witness{ { InvocationScript: committee.SignHashable(uint32(netmode.UnitTestNet), tx), VerificationScript: committee.Script(), }, { InvocationScript: append([]byte{byte(opcode.PUSHDATA1), keys.SignatureLen}, notary.PrivateKey().SignHashable(uint32(netmode.UnitTestNet), tx)...), }, } require.Error(t, bc.VerifyTx(tx)) }) t.Run("not signed by Notary", func(t *testing.T) { tx := getNotaryAssistedTx(e, 1, (1+1)*notaryServiceFeePerKey) tx.Signers = []transaction.Signer{ { Account: committee.ScriptHash(), Scopes: transaction.None, }, } tx.Scripts = []transaction.Witness{ { InvocationScript: committee.SignHashable(uint32(netmode.UnitTestNet), tx), VerificationScript: committee.Script(), }, } require.Error(t, bc.VerifyTx(tx)) }) t.Run("bad Notary node witness", func(t *testing.T) { tx := getNotaryAssistedTx(e, 1, (1+1)*notaryServiceFeePerKey) tx.Signers = []transaction.Signer{ { Account: committee.ScriptHash(), Scopes: transaction.None, }, { Account: notaryHash, Scopes: transaction.None, }, } acc, err := keys.NewPrivateKey() require.NoError(t, err) tx.Scripts = []transaction.Witness{ { InvocationScript: committee.SignHashable(uint32(netmode.UnitTestNet), tx), VerificationScript: committee.Script(), }, { InvocationScript: append([]byte{byte(opcode.PUSHDATA1), keys.SignatureLen}, acc.SignHashable(uint32(netmode.UnitTestNet), tx)...), }, } require.Error(t, bc.VerifyTx(tx)) }) t.Run("missing payer", func(t *testing.T) { tx := getNotaryAssistedTx(e, 1, (1+1)*notaryServiceFeePerKey) tx.Signers = []transaction.Signer{ { Account: notaryHash, Scopes: transaction.None, }, } tx.Scripts = []transaction.Witness{ { InvocationScript: append([]byte{byte(opcode.PUSHDATA1), keys.SignatureLen}, notary.PrivateKey().SignHashable(uint32(netmode.UnitTestNet), tx)...), }, } require.Error(t, bc.VerifyTx(tx)) }) t.Run("positive", func(t *testing.T) { tx := getNotaryAssistedTx(e, 1, (1+1)*notaryServiceFeePerKey) require.NoError(t, bc.VerifyTx(tx)) }) }) }) }) t.Run("Partially-filled transaction", func(t *testing.T) { getPartiallyFilledTx := func(nvb uint32, validUntil uint32) *transaction.Transaction { tx := newTestTx(t, h, testScript) tx.ValidUntilBlock = validUntil tx.Attributes = []transaction.Attribute{ { Type: transaction.NotValidBeforeT, Value: &transaction.NotValidBefore{Height: nvb}, }, { Type: transaction.NotaryAssistedT, Value: &transaction.NotaryAssisted{NKeys: 0}, }, } tx.Signers = []transaction.Signer{ { Account: notaryHash, Scopes: transaction.None, }, { Account: validator.ScriptHash(), Scopes: transaction.None, }, } size := io.GetVarSize(tx) netFee, sizeDelta := fee.Calculate(bc.GetBaseExecFee(), validator.Script()) tx.NetworkFee = netFee + // multisig witness verification price int64(size)*bc.FeePerByte() + // fee for unsigned size int64(sizeDelta)*bc.FeePerByte() + // fee for multisig size 66*bc.FeePerByte() + // fee for Notary signature size (66 bytes for Invocation script and 0 bytes for Verification script) 2*bc.FeePerByte() + // fee for the length of each script in Notary witness (they are nil, so we did not take them into account during `size` calculation) notaryServiceFeePerKey + // fee for Notary attribute fee.Opcode(bc.GetBaseExecFee(), // Notary verification script opcode.PUSHDATA1, opcode.RET, // invocation script opcode.PUSH0, opcode.SYSCALL, opcode.RET) + // Neo.Native.Call nativeprices.NotaryVerificationPrice*bc.GetBaseExecFee() // Notary witness verification price tx.Scripts = []transaction.Witness{ { InvocationScript: append([]byte{byte(opcode.PUSHDATA1), keys.SignatureLen}, make([]byte, keys.SignatureLen)...), VerificationScript: []byte{}, }, { InvocationScript: validator.SignHashable(uint32(netmode.UnitTestNet), tx), VerificationScript: validator.Script(), }, } return tx } mp := mempool.New(10, 1, false, nil) verificationF := func(tx *transaction.Transaction, data any) error { if data.(int) > 5 { return errors.New("bad data") } return nil } t.Run("failed pre-verification", func(t *testing.T) { tx := getPartiallyFilledTx(bc.BlockHeight(), bc.BlockHeight()+1) require.Error(t, bc.PoolTxWithData(tx, 6, mp, bc, verificationF)) // here and below let's use `bc` instead of proper NotaryFeer for the test simplicity. }) t.Run("GasLimitExceeded during witness verification", func(t *testing.T) { tx := getPartiallyFilledTx(bc.BlockHeight(), bc.BlockHeight()+1) tx.NetworkFee-- // to check that NetworkFee was set correctly in getPartiallyFilledTx tx.Scripts = []transaction.Witness{ { InvocationScript: append([]byte{byte(opcode.PUSHDATA1), keys.SignatureLen}, make([]byte, keys.SignatureLen)...), VerificationScript: []byte{}, }, { InvocationScript: validator.SignHashable(uint32(netmode.UnitTestNet), tx), VerificationScript: validator.Script(), }, } require.Error(t, bc.PoolTxWithData(tx, 5, mp, bc, verificationF)) }) t.Run("bad NVB: too big", func(t *testing.T) { maxNVB, err := bc.GetMaxNotValidBeforeDelta() require.NoError(t, err) tx := getPartiallyFilledTx(bc.BlockHeight()+maxNVB+1, bc.BlockHeight()+1) require.ErrorIs(t, bc.PoolTxWithData(tx, 5, mp, bc, verificationF), core.ErrInvalidAttribute) }) t.Run("bad ValidUntilBlock: too small", func(t *testing.T) { maxNVB, err := bc.GetMaxNotValidBeforeDelta() require.NoError(t, err) tx := getPartiallyFilledTx(bc.BlockHeight(), bc.BlockHeight()+maxNVB+1) require.ErrorIs(t, bc.PoolTxWithData(tx, 5, mp, bc, verificationF), core.ErrInvalidAttribute) }) t.Run("good", func(t *testing.T) { tx := getPartiallyFilledTx(bc.BlockHeight(), bc.BlockHeight()+1) require.NoError(t, bc.PoolTxWithData(tx, 5, mp, bc, verificationF)) }) }) } func TestBlockchain_Bug1728(t *testing.T) { bc, acc := chain.NewSingle(t) e := neotest.NewExecutor(t, bc, acc, acc) managementInvoker := e.ValidatorInvoker(e.NativeHash(t, nativenames.Management)) src := `package example import "github.com/nspcc-dev/neo-go/pkg/interop/runtime" func init() { if true { } else { } } func _deploy(_ any, isUpdate bool) { runtime.Log("Deploy") }` c := neotest.CompileSource(t, acc.ScriptHash(), strings.NewReader(src), &compiler.Options{Name: "TestContract"}) managementInvoker.DeployContract(t, c, nil) } func TestBlockchain_ResetStateErrors(t *testing.T) { chainHeight := 3 checkResetErr := func(t *testing.T, cfg func(c *config.Blockchain), h uint32, errText string) { db, path := newLevelDBForTestingWithPath(t, t.TempDir()) bc, validators, committee := chain.NewMultiWithCustomConfigAndStore(t, cfg, db, false) e := neotest.NewExecutor(t, bc, validators, committee) go bc.Run() for i := 0; i < chainHeight; i++ { e.AddNewBlock(t) // get some height } bc.Close() db, _ = newLevelDBForTestingWithPath(t, path) defer db.Close() bc, _, _ = chain.NewMultiWithCustomConfigAndStore(t, cfg, db, false) err := bc.Reset(h) if errText != "" { require.Error(t, err) require.True(t, strings.Contains(err.Error(), errText), err) } else { require.NoError(t, err) } } t.Run("large height", func(t *testing.T) { checkResetErr(t, nil, uint32(chainHeight+1), "can't reset state to height 4") }) t.Run("already at height", func(t *testing.T) { checkResetErr(t, nil, uint32(chainHeight), "") }) t.Run("KeepOnlyLatestState is enabled", func(t *testing.T) { checkResetErr(t, func(c *config.Blockchain) { c.Ledger.KeepOnlyLatestState = true }, uint32(chainHeight-1), "KeepOnlyLatestState is enabled") }) t.Run("some blocks where removed", func(t *testing.T) { checkResetErr(t, func(c *config.Blockchain) { c.Ledger.RemoveUntraceableBlocks = true c.MaxTraceableBlocks = 2 }, uint32(chainHeight-3), "RemoveUntraceableBlocks is enabled, a necessary batch of traceable blocks has already been removed") }) } // TestBlockchain_ResetState is based on knowledge about basic chain transactions, // it performs basic chain reset and checks that reset chain has proper state. func TestBlockchain_ResetState(t *testing.T) { // Create the DB. db, path := newLevelDBForTestingWithPath(t, t.TempDir()) bc, validators, committee := chain.NewMultiWithCustomConfigAndStore(t, func(cfg *config.Blockchain) { cfg.P2PSigExtensions = true }, db, false) go bc.Run() e := neotest.NewExecutor(t, bc, validators, committee) basicchain.Init(t, "../../", e) // Gather some reference information. resetBlockIndex := uint32(15) staleID := basicchain.NFSOContractID // NEP11 rublesH := e.ContractHash(t, basicchain.RublesContractID) nnsH := e.ContractHash(t, basicchain.NNSContractID) staleH := e.ContractHash(t, staleID) gasH := e.NativeHash(t, nativenames.Gas) neoH := e.NativeHash(t, nativenames.Neo) gasID := e.NativeID(t, nativenames.Gas) neoID := e.NativeID(t, nativenames.Neo) resetBlockHash := bc.GetHeaderHash(resetBlockIndex) resetBlockHeader, err := bc.GetHeader(resetBlockHash) require.NoError(t, err) topBlockHeight := bc.BlockHeight() topBH := bc.GetHeaderHash(bc.BlockHeight()) staleBH := bc.GetHeaderHash(resetBlockIndex + 1) staleB, err := bc.GetBlock(staleBH) require.NoError(t, err) staleTx := staleB.Transactions[0] _, err = bc.GetAppExecResults(staleTx.Hash(), trigger.Application) require.NoError(t, err) sr, err := bc.GetStateModule().GetStateRoot(resetBlockIndex) require.NoError(t, err) staleSR, err := bc.GetStateModule().GetStateRoot(resetBlockIndex + 1) require.NoError(t, err) rublesKey := []byte("testkey") rublesStaleKey := []byte("aa") rublesStaleValue := bc.GetStorageItem(basicchain.RublesContractID, rublesKey) // check value is there require.Equal(t, []byte(basicchain.RublesNewTestvalue), []byte(rublesStaleValue)) acc0 := e.Validator.(neotest.MultiSigner).Single(2) // priv0 index->order and order->index conversion priv0ScriptHash := acc0.ScriptHash() var ( expectedNEP11t []*state.NEP11Transfer expectedNEP17t []*state.NEP17Transfer ) require.NoError(t, bc.ForEachNEP11Transfer(priv0ScriptHash, resetBlockHeader.Timestamp, func(t *state.NEP11Transfer) (bool, error) { if t.Block <= resetBlockIndex { expectedNEP11t = append(expectedNEP11t, t) } return true, nil })) require.NoError(t, bc.ForEachNEP17Transfer(priv0ScriptHash, resetBlockHeader.Timestamp, func(t *state.NEP17Transfer) (bool, error) { if t.Block <= resetBlockIndex { expectedNEP17t = append(expectedNEP17t, t) } return true, nil })) // checkProof checks that some stale proof is reachable checkProof := func() { rublesStaleFullKey := make([]byte, 4) binary.LittleEndian.PutUint32(rublesStaleFullKey, uint32(basicchain.RublesContractID)) rublesStaleFullKey = append(rublesStaleFullKey, rublesStaleKey...) proof, err := bc.GetStateModule().GetStateProof(staleSR.Root, rublesStaleFullKey) require.NoError(t, err) require.NotEmpty(t, proof) } checkProof() // Ensure all changes were persisted. bc.Close() // Start new chain with existing DB, but do not run it. db, _ = newLevelDBForTestingWithPath(t, path) bc, _, _ = chain.NewMultiWithCustomConfigAndStore(t, func(cfg *config.Blockchain) { cfg.P2PSigExtensions = true }, db, false) defer db.Close() require.Equal(t, topBlockHeight, bc.BlockHeight()) // ensure DB was properly initialized. // Reset state. require.NoError(t, bc.Reset(resetBlockIndex)) // Check that state was properly reset. require.Equal(t, resetBlockIndex, bc.BlockHeight()) require.Equal(t, resetBlockIndex, bc.HeaderHeight()) require.Equal(t, resetBlockHash, bc.CurrentHeaderHash()) require.Equal(t, resetBlockHash, bc.CurrentBlockHash()) require.Equal(t, resetBlockIndex, bc.GetStateModule().CurrentLocalHeight()) require.Equal(t, sr.Root, bc.GetStateModule().CurrentLocalStateRoot()) require.Equal(t, uint32(0), bc.GetStateModule().CurrentValidatedHeight()) // Try to get the latest block\header. bh := bc.GetHeaderHash(resetBlockIndex) require.Equal(t, resetBlockHash, bh) h, err := bc.GetHeader(bh) require.NoError(t, err) require.Equal(t, resetBlockHeader, h) actualRublesHash, err := bc.GetContractScriptHash(basicchain.RublesContractID) require.NoError(t, err) require.Equal(t, rublesH, actualRublesHash) // Check that stale blocks/headers/txs/aers/sr are not reachable. for i := resetBlockIndex + 1; i <= topBlockHeight; i++ { hHash := bc.GetHeaderHash(i) require.Equal(t, util.Uint256{}, hHash) _, err = bc.GetStateRoot(i) require.Error(t, err) } for _, h := range []util.Uint256{staleBH, topBH} { _, err = bc.GetHeader(h) require.Error(t, err) _, err = bc.GetHeader(h) require.Error(t, err) } _, _, err = bc.GetTransaction(staleTx.Hash()) require.Error(t, err) _, err = bc.GetAppExecResults(staleTx.Hash(), trigger.Application) require.Error(t, err) // However, proofs and everything related to stale MPT nodes still should work properly, // because we don't remove stale MPT nodes. checkProof() // Check NEP-compatible contracts. nep11 := bc.GetNEP11Contracts() require.Equal(t, 1, len(nep11)) // NNS require.Equal(t, nnsH, nep11[0]) nep17 := bc.GetNEP17Contracts() require.Equal(t, 3, len(nep17)) // Neo, Gas, Rubles require.ElementsMatch(t, []util.Uint160{gasH, neoH, rublesH}, nep17) // Retrieve stale contract. cs := bc.GetContractState(staleH) require.Nil(t, cs) // Retrieve stale storage item. rublesValue := bc.GetStorageItem(basicchain.RublesContractID, rublesKey) require.Equal(t, []byte(basicchain.RublesOldTestvalue), []byte(rublesValue)) // the one with historic state require.Nil(t, bc.GetStorageItem(basicchain.RublesContractID, rublesStaleKey)) // the one that was added after target reset block db.Seek(storage.SeekRange{ Prefix: []byte{byte(storage.STStorage)}, // no items with old prefix }, func(k, v []byte) bool { t.Fatal("no stale items must be left in storage") return false }) // Check transfers. var ( actualNEP11t []*state.NEP11Transfer actualNEP17t []*state.NEP17Transfer ) require.NoError(t, bc.ForEachNEP11Transfer(priv0ScriptHash, e.TopBlock(t).Timestamp, func(t *state.NEP11Transfer) (bool, error) { actualNEP11t = append(actualNEP11t, t) return true, nil })) require.NoError(t, bc.ForEachNEP17Transfer(priv0ScriptHash, e.TopBlock(t).Timestamp, func(t *state.NEP17Transfer) (bool, error) { actualNEP17t = append(actualNEP17t, t) return true, nil })) assert.Equal(t, expectedNEP11t, actualNEP11t) assert.Equal(t, expectedNEP17t, actualNEP17t) lub, err := bc.GetTokenLastUpdated(priv0ScriptHash) require.NoError(t, err) expectedLUB := map[int32]uint32{ // this information is extracted from basic chain initialization code basicchain.NNSContractID: resetBlockIndex - 1, // `neo.com` registration basicchain.RublesContractID: 6, // transfer of 123 RUR to priv1 gasID: resetBlockIndex, // fee for `1.2.3.4` A record registration neoID: 4, // transfer of 1000 NEO to priv1 } require.Equal(t, expectedLUB, lub) } func TestBlockchain_GenesisTransactionExtension(t *testing.T) { priv0 := testchain.PrivateKeyByID(0) acc0 := wallet.NewAccountFromPrivateKey(priv0) require.NoError(t, acc0.ConvertMultisig(1, []*keys.PublicKey{priv0.PublicKey()})) from := acc0.ScriptHash() to := util.Uint160{1, 2, 3} amount := 1 script := io.NewBufBinWriter() emit.Bytes(script.BinWriter, from.BytesBE()) emit.Syscall(script.BinWriter, interopnames.SystemRuntimeCheckWitness) emit.Bytes(script.BinWriter, to.BytesBE()) emit.Syscall(script.BinWriter, interopnames.SystemRuntimeCheckWitness) emit.AppCall(script.BinWriter, state.CreateNativeContractHash(nativenames.Neo), "transfer", callflag.All, from, to, amount, nil) emit.Opcodes(script.BinWriter, opcode.ASSERT) var sysFee int64 = 1_0000_0000 bc, acc := chain.NewSingleWithCustomConfig(t, func(blockchain *config.Blockchain) { blockchain.Genesis.Transaction = &config.GenesisTransaction{ Script: script.Bytes(), SystemFee: sysFee, } }) e := neotest.NewExecutor(t, bc, acc, acc) b := e.GetBlockByIndex(t, 0) tx := b.Transactions[0] e.CheckHalt(t, tx.Hash(), stackitem.NewBool(true), stackitem.NewBool(false)) e.CheckGASBalance(t, e.Validator.ScriptHash(), big.NewInt(core.DefaultInitialGAS-sysFee)) actualNeo, lub := e.Chain.GetGoverningTokenBalance(to) require.Equal(t, int64(amount), actualNeo.Int64()) require.Equal(t, 0, int(lub)) }