package native import ( "context" "crypto/elliptic" "encoding/binary" "errors" "fmt" "math/big" "sort" "strings" "github.com/nspcc-dev/neo-go/pkg/config" "github.com/nspcc-dev/neo-go/pkg/core/dao" "github.com/nspcc-dev/neo-go/pkg/core/interop" "github.com/nspcc-dev/neo-go/pkg/core/interop/runtime" istorage "github.com/nspcc-dev/neo-go/pkg/core/interop/storage" "github.com/nspcc-dev/neo-go/pkg/core/native/nativenames" "github.com/nspcc-dev/neo-go/pkg/core/state" "github.com/nspcc-dev/neo-go/pkg/core/storage" "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/bigint" "github.com/nspcc-dev/neo-go/pkg/io" "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/manifest" "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/stackitem" ) // NEO represents NEO native contract. type NEO struct { nep17TokenNative GAS *GAS Policy *Policy // Configuration and standby keys are set in constructor and then // only read from. cfg config.ProtocolConfiguration standbyKeys keys.PublicKeys } type NeoCache struct { // gasPerBlock represents the history of generated gas per block. gasPerBlock gasRecord registerPrice int64 votesChanged bool nextValidators keys.PublicKeys // newEpochNextValidators contains cached next block newEpochNextValidators. This list is updated once // per dBFT epoch in PostPersist of the last block in the epoch if candidates // votes ratio has been changed or register/unregister operation was performed // within the last processed epoch. The updated value is being persisted // following the standard layered DAO persist rules, so that external users // will get the proper value with upper Blockchain's DAO (but this value is // relevant only by the moment of first epoch block creation). newEpochNextValidators keys.PublicKeys // committee contains cached committee members and their votes. // It is updated once in a while depending on committee size // (every 28 blocks for mainnet). It's value // is always equal to the value stored by `prefixCommittee`. committee keysWithVotes // newEpochCommittee contains cached committee members updated once per dBFT // epoch in PostPersist of the last block in the epoch. newEpochCommittee keysWithVotes // committeeHash contains the script hash of the committee. committeeHash util.Uint160 // newEpochCommitteeHash contains the script hash of the newEpochCommittee. newEpochCommitteeHash util.Uint160 // gasPerVoteCache contains the last updated value of GAS per vote reward for candidates. // It is set in state-modifying methods only and read in `PostPersist`, thus is not protected // by any mutex. gasPerVoteCache map[string]big.Int } const ( neoContractID = -5 // NEOTotalSupply is the total amount of NEO in the system. NEOTotalSupply = 100000000 // DefaultRegisterPrice is the default price for candidate register. DefaultRegisterPrice = 1000 * GASFactor // prefixCandidate is a prefix used to store validator's data. prefixCandidate = 33 // prefixVotersCount is a prefix for storing total amount of NEO of voters. prefixVotersCount = 1 // prefixVoterRewardPerCommittee is a prefix for storing committee GAS reward. prefixVoterRewardPerCommittee = 23 // voterRewardFactor is a factor by which voter reward per committee is multiplied // to make calculations more precise. voterRewardFactor = 100_000_000 // prefixGASPerBlock is a prefix for storing amount of GAS generated per block. prefixGASPerBlock = 29 // prefixRegisterPrice is a prefix for storing candidate register price. prefixRegisterPrice = 13 // effectiveVoterTurnout represents minimal ratio of total supply to total amount voted value // which is require to use non-standby validators. effectiveVoterTurnout = 5 // neoHolderRewardRatio is a percent of generated GAS that is distributed to NEO holders. neoHolderRewardRatio = 10 // neoHolderRewardRatio is a percent of generated GAS that is distributed to committee. committeeRewardRatio = 10 // neoHolderRewardRatio is a percent of generated GAS that is distributed to voters. voterRewardRatio = 80 // maxGetCandidatesRespLen is the maximum number of candidates to return from the // getCandidates method. maxGetCandidatesRespLen = 256 ) var ( // prefixCommittee is a key used to store committee. prefixCommittee = []byte{14} bigCommitteeRewardRatio = big.NewInt(committeeRewardRatio) bigVoterRewardRatio = big.NewInt(voterRewardRatio) bigVoterRewardFactor = big.NewInt(voterRewardFactor) bigEffectiveVoterTurnout = big.NewInt(effectiveVoterTurnout) big100 = big.NewInt(100) ) var ( _ interop.Contract = (*NEO)(nil) _ dao.NativeContractCache = (*NeoCache)(nil) ) // Copy implements NativeContractCache interface. func (c *NeoCache) Copy() dao.NativeContractCache { cp := &NeoCache{} copyNeoCache(c, cp) return cp } func copyNeoCache(src, dst *NeoCache) { dst.votesChanged = src.votesChanged // Can safely omit copying because the new array is created each time // newEpochNextValidators list, nextValidators and committee are updated. dst.nextValidators = src.nextValidators dst.committee = src.committee dst.committeeHash = src.committeeHash dst.newEpochNextValidators = src.newEpochNextValidators dst.newEpochCommittee = src.newEpochCommittee dst.newEpochCommitteeHash = src.newEpochCommitteeHash dst.registerPrice = src.registerPrice // Can't omit copying because gasPerBlock is append-only, thus to be able to // discard cache changes in case of FAULTed transaction we need a separate // container for updated gasPerBlock values. dst.gasPerBlock = make(gasRecord, len(src.gasPerBlock)) copy(dst.gasPerBlock, src.gasPerBlock) dst.gasPerVoteCache = make(map[string]big.Int) for k, v := range src.gasPerVoteCache { dst.gasPerVoteCache[k] = v } } // makeValidatorKey creates a key from the account script hash. func makeValidatorKey(key *keys.PublicKey) []byte { b := key.Bytes() // Don't create a new buffer. b = append(b, 0) copy(b[1:], b[0:]) b[0] = prefixCandidate return b } // newNEO returns NEO native contract. func newNEO(cfg config.ProtocolConfiguration) *NEO { n := &NEO{} defer n.BuildHFSpecificMD(n.ActiveIn()) nep17 := newNEP17Native(nativenames.Neo, neoContractID) nep17.symbol = "NEO" nep17.decimals = 0 nep17.factor = 1 nep17.incBalance = n.increaseBalance nep17.balFromBytes = n.balanceFromBytes n.nep17TokenNative = *nep17 err := n.initConfigCache(cfg) if err != nil { panic(fmt.Errorf("failed to initialize NEO config cache: %w", err)) } desc := newDescriptor("unclaimedGas", smartcontract.IntegerType, manifest.NewParameter("account", smartcontract.Hash160Type), manifest.NewParameter("end", smartcontract.IntegerType)) md := newMethodAndPrice(n.unclaimedGas, 1<<17, callflag.ReadStates) n.AddMethod(md, desc) desc = newDescriptor("registerCandidate", smartcontract.BoolType, manifest.NewParameter("pubkey", smartcontract.PublicKeyType)) md = newMethodAndPrice(n.registerCandidate, 0, callflag.States) n.AddMethod(md, desc) desc = newDescriptor("unregisterCandidate", smartcontract.BoolType, manifest.NewParameter("pubkey", smartcontract.PublicKeyType)) md = newMethodAndPrice(n.unregisterCandidate, 1<<16, callflag.States) n.AddMethod(md, desc) desc = newDescriptor("vote", smartcontract.BoolType, manifest.NewParameter("account", smartcontract.Hash160Type), manifest.NewParameter("voteTo", smartcontract.PublicKeyType)) md = newMethodAndPrice(n.vote, 1<<16, callflag.States) n.AddMethod(md, desc) desc = newDescriptor("getCandidates", smartcontract.ArrayType) md = newMethodAndPrice(n.getCandidatesCall, 1<<22, callflag.ReadStates) n.AddMethod(md, desc) desc = newDescriptor("getAllCandidates", smartcontract.InteropInterfaceType) md = newMethodAndPrice(n.getAllCandidatesCall, 1<<22, callflag.ReadStates) n.AddMethod(md, desc) desc = newDescriptor("getCandidateVote", smartcontract.IntegerType, manifest.NewParameter("pubKey", smartcontract.PublicKeyType)) md = newMethodAndPrice(n.getCandidateVoteCall, 1<<15, callflag.ReadStates) n.AddMethod(md, desc) desc = newDescriptor("getAccountState", smartcontract.ArrayType, manifest.NewParameter("account", smartcontract.Hash160Type)) md = newMethodAndPrice(n.getAccountState, 1<<15, callflag.ReadStates) n.AddMethod(md, desc) desc = newDescriptor("getCommittee", smartcontract.ArrayType) md = newMethodAndPrice(n.getCommittee, 1<<16, callflag.ReadStates) n.AddMethod(md, desc) desc = newDescriptor("getCommitteeAddress", smartcontract.Hash160Type) md = newMethodAndPrice(n.getCommitteeAddress, 1<<16, callflag.ReadStates, config.HFCockatrice) n.AddMethod(md, desc) desc = newDescriptor("getNextBlockValidators", smartcontract.ArrayType) md = newMethodAndPrice(n.getNextBlockValidators, 1<<16, callflag.ReadStates) n.AddMethod(md, desc) desc = newDescriptor("getGasPerBlock", smartcontract.IntegerType) md = newMethodAndPrice(n.getGASPerBlock, 1<<15, callflag.ReadStates) n.AddMethod(md, desc) desc = newDescriptor("setGasPerBlock", smartcontract.VoidType, manifest.NewParameter("gasPerBlock", smartcontract.IntegerType)) md = newMethodAndPrice(n.setGASPerBlock, 1<<15, callflag.States) n.AddMethod(md, desc) desc = newDescriptor("getRegisterPrice", smartcontract.IntegerType) md = newMethodAndPrice(n.getRegisterPrice, 1<<15, callflag.ReadStates) n.AddMethod(md, desc) desc = newDescriptor("setRegisterPrice", smartcontract.VoidType, manifest.NewParameter("registerPrice", smartcontract.IntegerType)) md = newMethodAndPrice(n.setRegisterPrice, 1<<15, callflag.States) n.AddMethod(md, desc) eDesc := newEventDescriptor("CandidateStateChanged", manifest.NewParameter("pubkey", smartcontract.PublicKeyType), manifest.NewParameter("registered", smartcontract.BoolType), manifest.NewParameter("votes", smartcontract.IntegerType), ) eMD := newEvent(eDesc) n.AddEvent(eMD) eDesc = newEventDescriptor("Vote", manifest.NewParameter("account", smartcontract.Hash160Type), manifest.NewParameter("from", smartcontract.PublicKeyType), manifest.NewParameter("to", smartcontract.PublicKeyType), manifest.NewParameter("amount", smartcontract.IntegerType), ) eMD = newEvent(eDesc) n.AddEvent(eMD) eDesc = newEventDescriptor("CommitteeChanged", manifest.NewParameter("old", smartcontract.ArrayType), manifest.NewParameter("new", smartcontract.ArrayType), ) eMD = newEvent(eDesc, config.HFCockatrice) n.AddEvent(eMD) return n } // Initialize initializes a NEO contract. func (n *NEO) Initialize(ic *interop.Context, hf *config.Hardfork, newMD *interop.HFSpecificContractMD) error { if hf != n.ActiveIn() { return nil } if err := n.nep17TokenNative.Initialize(ic); err != nil { return err } _, totalSupply := n.nep17TokenNative.getTotalSupply(ic.DAO) if totalSupply.Sign() != 0 { return errors.New("already initialized") } cache := &NeoCache{ gasPerVoteCache: make(map[string]big.Int), votesChanged: true, } // We need cache to be present in DAO before the subsequent call to `mint`. ic.DAO.SetCache(n.ID, cache) committee0 := n.standbyKeys[:n.cfg.GetCommitteeSize(ic.Block.Index)] cvs := toKeysWithVotes(committee0) err := n.updateCache(cache, cvs, ic.BlockHeight()) if err != nil { return err } ic.DAO.PutStorageItem(n.ID, prefixCommittee, cvs.Bytes(ic.DAO.GetItemCtx())) h, err := getStandbyValidatorsHash(ic) if err != nil { return err } n.mint(ic, h, big.NewInt(NEOTotalSupply), false) var index uint32 value := big.NewInt(5 * GASFactor) n.putGASRecord(ic.DAO, index, value) gr := &gasRecord{{Index: index, GASPerBlock: *value}} cache.gasPerBlock = *gr ic.DAO.PutStorageItem(n.ID, []byte{prefixVotersCount}, state.StorageItem{}) setIntWithKey(n.ID, ic.DAO, []byte{prefixRegisterPrice}, DefaultRegisterPrice) cache.registerPrice = int64(DefaultRegisterPrice) var numOfCNs = n.cfg.GetNumOfCNs(ic.Block.Index + 1) err = n.updateCachedNewEpochValues(ic.DAO, cache, ic.BlockHeight(), numOfCNs) if err != nil { return fmt.Errorf("failed to update next block newEpoch* cache: %w", err) } return nil } // InitializeCache initializes all NEO cache with the proper values from the storage. // Cache initialization should be done apart from Initialize because Initialize is // called only when deploying native contracts. InitializeCache implements the Contract // interface. func (n *NEO) InitializeCache(blockHeight uint32, d *dao.Simple) error { cache := &NeoCache{ gasPerVoteCache: make(map[string]big.Int), votesChanged: true, } var committee = keysWithVotes{} si := d.GetStorageItem(n.ID, prefixCommittee) if err := committee.DecodeBytes(si); err != nil { return fmt.Errorf("failed to decode committee: %w", err) } if err := n.updateCache(cache, committee, blockHeight); err != nil { return fmt.Errorf("failed to update cache: %w", err) } cache.gasPerBlock = n.getSortedGASRecordFromDAO(d) cache.registerPrice = getIntWithKey(n.ID, d, []byte{prefixRegisterPrice}) // Update newEpoch* cache for external users. It holds values for the previous // dBFT epoch if the current one isn't yet finished. if n.cfg.ShouldUpdateCommitteeAt(blockHeight + 1) { var numOfCNs = n.cfg.GetNumOfCNs(blockHeight + 1) err := n.updateCachedNewEpochValues(d, cache, blockHeight, numOfCNs) if err != nil { return fmt.Errorf("failed to update next block newEpoch* cache: %w", err) } } else { // nextValidators, committee and committee hash are filled in by this moment // via n.updateCache call. cache.newEpochNextValidators = cache.nextValidators.Copy() cache.newEpochCommittee = make(keysWithVotes, len(cache.committee)) copy(cache.newEpochCommittee, cache.committee) cache.newEpochCommitteeHash = cache.committeeHash } d.SetCache(n.ID, cache) return nil } // ActiveIn implements the Contract interface. func (n *NEO) ActiveIn() *config.Hardfork { return nil } func (n *NEO) initConfigCache(cfg config.ProtocolConfiguration) error { var err error n.cfg = cfg n.standbyKeys, err = keys.NewPublicKeysFromStrings(n.cfg.StandbyCommittee) return err } func (n *NEO) updateCache(cache *NeoCache, cvs keysWithVotes, blockHeight uint32) error { cache.committee = cvs var committee = getCommitteeMembers(cache.committee) script, err := smartcontract.CreateMajorityMultiSigRedeemScript(committee.Copy()) if err != nil { return err } cache.committeeHash = hash.Hash160(script) nextVals := committee[:n.cfg.GetNumOfCNs(blockHeight+1)].Copy() sort.Sort(nextVals) cache.nextValidators = nextVals return nil } // updateCachedNewEpochValues sets newEpochNextValidators, newEpochCommittee and // newEpochCommitteeHash cache that will be used by external users to retrieve // next block validators list of the next dBFT epoch that wasn't yet started and // will be used by corresponding values initialisation on the next epoch start. // The updated new epoch cached values computed using the persisted blocks state // of the latest epoch. func (n *NEO) updateCachedNewEpochValues(d *dao.Simple, cache *NeoCache, blockHeight uint32, numOfCNs int) error { committee, cvs, err := n.computeCommitteeMembers(blockHeight, d) if err != nil { return fmt.Errorf("failed to compute committee members: %w", err) } cache.newEpochCommittee = cvs script, err := smartcontract.CreateMajorityMultiSigRedeemScript(committee.Copy()) if err != nil { return err } cache.newEpochCommitteeHash = hash.Hash160(script) nextVals := committee[:numOfCNs].Copy() sort.Sort(nextVals) cache.newEpochNextValidators = nextVals return nil } // OnPersist implements the Contract interface. func (n *NEO) OnPersist(ic *interop.Context) error { if n.cfg.ShouldUpdateCommitteeAt(ic.Block.Index) { cache := ic.DAO.GetRWCache(n.ID).(*NeoCache) // Cached newEpoch* values always have proper value set (either by PostPersist // during the last epoch block handling or by initialization code). var oldCommittee, newCommittee stackitem.Item for i := 0; i < len(cache.committee); i++ { if cache.newEpochCommittee[i].Key != cache.committee[i].Key || (i == 0 && len(cache.newEpochCommittee) != len(cache.committee)) { oldCommittee, newCommittee = cache.committee.toNotificationItem(), cache.newEpochCommittee.toNotificationItem() break } } cache.nextValidators = cache.newEpochNextValidators cache.committee = cache.newEpochCommittee cache.committeeHash = cache.newEpochCommitteeHash cache.votesChanged = false // We need to put in storage anyway, as it affects dumps ic.DAO.PutStorageItem(n.ID, prefixCommittee, cache.committee.Bytes(ic.DAO.GetItemCtx())) if oldCommittee != nil { ic.AddNotification(n.Hash, "CommitteeChanged", stackitem.NewArray([]stackitem.Item{ oldCommittee, newCommittee, })) } } return nil } // PostPersist implements the Contract interface. func (n *NEO) PostPersist(ic *interop.Context) error { gas := n.GetGASPerBlock(ic.DAO, ic.Block.Index) cache := ic.DAO.GetROCache(n.ID).(*NeoCache) pubs := getCommitteeMembers(cache.committee) committeeSize := n.cfg.GetCommitteeSize(ic.Block.Index) index := int(ic.Block.Index) % committeeSize committeeReward := new(big.Int).Mul(gas, bigCommitteeRewardRatio) n.GAS.mint(ic, pubs[index].GetScriptHash(), committeeReward.Div(committeeReward, big100), false) var isCacheRW bool if n.cfg.ShouldUpdateCommitteeAt(ic.Block.Index) { var voterReward = new(big.Int).Set(bigVoterRewardRatio) voterReward.Mul(voterReward, gas) voterReward.Mul(voterReward, big.NewInt(voterRewardFactor*int64(committeeSize))) var validatorsCount = n.cfg.GetNumOfCNs(ic.Block.Index) voterReward.Div(voterReward, big.NewInt(int64(committeeSize+validatorsCount))) voterReward.Div(voterReward, big100) var ( cs = cache.committee key = make([]byte, 34) ) for i := range cs { if cs[i].Votes.Sign() > 0 { var tmp = new(big.Int) if i < validatorsCount { tmp.Set(intTwo) } else { tmp.Set(intOne) } tmp.Mul(tmp, voterReward) tmp.Div(tmp, cs[i].Votes) key = makeVoterKey([]byte(cs[i].Key), key) r := n.getLatestGASPerVote(ic.DAO, key) tmp.Add(tmp, &r) if !isCacheRW { cache = ic.DAO.GetRWCache(n.ID).(*NeoCache) isCacheRW = true } cache.gasPerVoteCache[cs[i].Key] = *tmp ic.DAO.PutBigInt(n.ID, key, tmp) } } } // Update newEpoch cache for external users and further committee, committeeHash // and nextBlockValidators cache initialisation if committee should be updated in // the next block. if n.cfg.ShouldUpdateCommitteeAt(ic.Block.Index + 1) { var ( h = ic.Block.Index // consider persisting block as stored to get _next_ block newEpochNextValidators numOfCNs = n.cfg.GetNumOfCNs(h + 1) ) if cache.votesChanged || numOfCNs != len(cache.newEpochNextValidators) || n.cfg.GetCommitteeSize(h+1) != len(cache.newEpochCommittee) { if !isCacheRW { cache = ic.DAO.GetRWCache(n.ID).(*NeoCache) } err := n.updateCachedNewEpochValues(ic.DAO, cache, h, numOfCNs) if err != nil { return fmt.Errorf("failed to update next block newEpoch* cache: %w", err) } } } return nil } func (n *NEO) getLatestGASPerVote(d *dao.Simple, key []byte) big.Int { var g big.Int cache := d.GetROCache(n.ID).(*NeoCache) if g, ok := cache.gasPerVoteCache[string(key[1:])]; ok { return g } item := d.GetStorageItem(n.ID, key) if item == nil { g = *big.NewInt(0) } else { g = *bigint.FromBytes(item) } return g } func (n *NEO) increaseBalance(ic *interop.Context, h util.Uint160, si *state.StorageItem, amount *big.Int, checkBal *big.Int) (func(), error) { var postF func() acc, err := state.NEOBalanceFromBytes(*si) if err != nil { return nil, err } if (amount.Sign() == -1 && acc.Balance.CmpAbs(amount) == -1) || (amount.Sign() == 0 && checkBal != nil && acc.Balance.Cmp(checkBal) == -1) { return nil, errors.New("insufficient funds") } newGas, err := n.distributeGas(ic, acc) if err != nil { return nil, err } if newGas != nil { // Can be if it was already distributed in the same block. postF = func() { n.GAS.mint(ic, h, newGas, true) } } if amount.Sign() == 0 { *si = acc.Bytes(ic.DAO.GetItemCtx()) return postF, nil } if err := n.ModifyAccountVotes(acc, ic.DAO, amount, false); err != nil { return nil, err } if acc.VoteTo != nil { if err := n.modifyVoterTurnout(ic.DAO, amount); err != nil { return nil, err } } acc.Balance.Add(&acc.Balance, amount) if acc.Balance.Sign() != 0 { *si = acc.Bytes(ic.DAO.GetItemCtx()) } else { *si = nil } return postF, nil } func (n *NEO) balanceFromBytes(si *state.StorageItem) (*big.Int, error) { acc, err := state.NEOBalanceFromBytes(*si) if err != nil { return nil, err } return &acc.Balance, err } func (n *NEO) distributeGas(ic *interop.Context, acc *state.NEOBalance) (*big.Int, error) { if ic.Block == nil || ic.Block.Index == 0 || ic.Block.Index == acc.BalanceHeight { return nil, nil } gen, err := n.calculateBonus(ic.DAO, acc, ic.Block.Index) if err != nil { return nil, err } acc.BalanceHeight = ic.Block.Index if acc.VoteTo != nil { latestGasPerVote := n.getLatestGASPerVote(ic.DAO, makeVoterKey(acc.VoteTo.Bytes())) acc.LastGasPerVote = latestGasPerVote } return gen, nil } func (n *NEO) unclaimedGas(ic *interop.Context, args []stackitem.Item) stackitem.Item { u := toUint160(args[0]) end := uint32(toBigInt(args[1]).Int64()) gen, err := n.CalculateBonus(ic, u, end) if err != nil { panic(err) } return stackitem.NewBigInteger(gen) } func (n *NEO) getGASPerBlock(ic *interop.Context, _ []stackitem.Item) stackitem.Item { gas := n.GetGASPerBlock(ic.DAO, ic.Block.Index) return stackitem.NewBigInteger(gas) } func (n *NEO) getSortedGASRecordFromDAO(d *dao.Simple) gasRecord { var gr = make(gasRecord, 0) d.Seek(n.ID, storage.SeekRange{Prefix: []byte{prefixGASPerBlock}}, func(k, v []byte) bool { gr = append(gr, gasIndexPair{ Index: binary.BigEndian.Uint32(k), GASPerBlock: *bigint.FromBytes(v), }) return true }) return gr } // GetGASPerBlock returns gas generated for block with provided index. func (n *NEO) GetGASPerBlock(d *dao.Simple, index uint32) *big.Int { cache := d.GetROCache(n.ID).(*NeoCache) gr := cache.gasPerBlock for i := len(gr) - 1; i >= 0; i-- { if gr[i].Index <= index { g := gr[i].GASPerBlock return &g } } panic("NEO cache not initialized") } // GetCommitteeAddress returns address of the committee. func (n *NEO) GetCommitteeAddress(d *dao.Simple) util.Uint160 { cache := d.GetROCache(n.ID).(*NeoCache) return cache.committeeHash } func (n *NEO) checkCommittee(ic *interop.Context) bool { ok, err := runtime.CheckHashedWitness(ic, n.GetCommitteeAddress(ic.DAO)) if err != nil { panic(err) } return ok } func (n *NEO) setGASPerBlock(ic *interop.Context, args []stackitem.Item) stackitem.Item { gas := toBigInt(args[0]) err := n.SetGASPerBlock(ic, ic.Block.Index+1, gas) if err != nil { panic(err) } return stackitem.Null{} } // SetGASPerBlock sets gas generated for blocks after index. func (n *NEO) SetGASPerBlock(ic *interop.Context, index uint32, gas *big.Int) error { if gas.Sign() == -1 || gas.Cmp(big.NewInt(10*GASFactor)) == 1 { return errors.New("invalid value for GASPerBlock") } if !n.checkCommittee(ic) { return errors.New("invalid committee signature") } n.putGASRecord(ic.DAO, index, gas) cache := ic.DAO.GetRWCache(n.ID).(*NeoCache) cache.gasPerBlock = append(cache.gasPerBlock, gasIndexPair{ Index: index, GASPerBlock: *gas, }) return nil } func (n *NEO) getRegisterPrice(ic *interop.Context, _ []stackitem.Item) stackitem.Item { return stackitem.NewBigInteger(big.NewInt(n.getRegisterPriceInternal(ic.DAO))) } func (n *NEO) getRegisterPriceInternal(d *dao.Simple) int64 { cache := d.GetROCache(n.ID).(*NeoCache) return cache.registerPrice } func (n *NEO) setRegisterPrice(ic *interop.Context, args []stackitem.Item) stackitem.Item { price := toBigInt(args[0]) if price.Sign() <= 0 || !price.IsInt64() { panic("invalid register price") } if !n.checkCommittee(ic) { panic("invalid committee signature") } setIntWithKey(n.ID, ic.DAO, []byte{prefixRegisterPrice}, price.Int64()) cache := ic.DAO.GetRWCache(n.ID).(*NeoCache) cache.registerPrice = price.Int64() return stackitem.Null{} } func (n *NEO) dropCandidateIfZero(d *dao.Simple, cache *NeoCache, pub *keys.PublicKey, c *candidate) bool { if c.Registered || c.Votes.Sign() != 0 { return false } d.DeleteStorageItem(n.ID, makeValidatorKey(pub)) voterKey := makeVoterKey(pub.Bytes()) d.DeleteStorageItem(n.ID, voterKey) delete(cache.gasPerVoteCache, string(voterKey)) return true } func makeVoterKey(pub []byte, prealloc ...[]byte) []byte { var key []byte if len(prealloc) != 0 { key = prealloc[0] } else { key = make([]byte, 34) } key[0] = prefixVoterRewardPerCommittee copy(key[1:], pub) return key } // CalculateBonus calculates amount of gas generated for holding value NEO from start to end block // and having voted for active committee member. func (n *NEO) CalculateBonus(ic *interop.Context, acc util.Uint160, end uint32) (*big.Int, error) { if ic.Block == nil || end != ic.Block.Index { return nil, errors.New("can't calculate bonus of height unequal (BlockHeight + 1)") } key := makeAccountKey(acc) si := ic.DAO.GetStorageItem(n.ID, key) if si == nil { return nil, storage.ErrKeyNotFound } st, err := state.NEOBalanceFromBytes(si) if err != nil { return nil, err } return n.calculateBonus(ic.DAO, st, end) } func (n *NEO) calculateBonus(d *dao.Simple, acc *state.NEOBalance, end uint32) (*big.Int, error) { r, err := n.CalculateNEOHolderReward(d, &acc.Balance, acc.BalanceHeight, end) if err != nil || acc.VoteTo == nil { return r, err } var key = makeVoterKey(acc.VoteTo.Bytes()) var reward = n.getLatestGASPerVote(d, key) var tmp = big.NewInt(0).Sub(&reward, &acc.LastGasPerVote) tmp.Mul(tmp, &acc.Balance) tmp.Div(tmp, bigVoterRewardFactor) tmp.Add(tmp, r) return tmp, nil } // CalculateNEOHolderReward return GAS reward for holding `value` of NEO from start to end block. func (n *NEO) CalculateNEOHolderReward(d *dao.Simple, value *big.Int, start, end uint32) (*big.Int, error) { if value.Sign() == 0 || start >= end { return big.NewInt(0), nil } else if value.Sign() < 0 { return nil, errors.New("negative value") } cache := d.GetROCache(n.ID).(*NeoCache) gr := cache.gasPerBlock var sum, tmp big.Int for i := len(gr) - 1; i >= 0; i-- { if gr[i].Index >= end { continue } else if gr[i].Index <= start { tmp.SetInt64(int64(end - start)) tmp.Mul(&tmp, &gr[i].GASPerBlock) sum.Add(&sum, &tmp) break } tmp.SetInt64(int64(end - gr[i].Index)) tmp.Mul(&tmp, &gr[i].GASPerBlock) sum.Add(&sum, &tmp) end = gr[i].Index } res := new(big.Int).Mul(value, &sum) res.Mul(res, tmp.SetInt64(neoHolderRewardRatio)) res.Div(res, tmp.SetInt64(100*NEOTotalSupply)) return res, nil } func (n *NEO) registerCandidate(ic *interop.Context, args []stackitem.Item) stackitem.Item { pub := toPublicKey(args[0]) ok, err := runtime.CheckKeyedWitness(ic, pub) if err != nil { panic(err) } else if !ok { return stackitem.NewBool(false) } if !ic.VM.AddGas(n.getRegisterPriceInternal(ic.DAO)) { panic("insufficient gas") } err = n.RegisterCandidateInternal(ic, pub) return stackitem.NewBool(err == nil) } // RegisterCandidateInternal registers pub as a new candidate. func (n *NEO) RegisterCandidateInternal(ic *interop.Context, pub *keys.PublicKey) error { var emitEvent = true key := makeValidatorKey(pub) si := ic.DAO.GetStorageItem(n.ID, key) var c *candidate if si == nil { c = &candidate{Registered: true} } else { c = new(candidate).FromBytes(si) emitEvent = !c.Registered c.Registered = true } err := putConvertibleToDAO(n.ID, ic.DAO, key, c) if emitEvent { cache := ic.DAO.GetRWCache(n.ID).(*NeoCache) cache.votesChanged = true ic.AddNotification(n.Hash, "CandidateStateChanged", stackitem.NewArray([]stackitem.Item{ stackitem.NewByteArray(pub.Bytes()), stackitem.NewBool(c.Registered), stackitem.NewBigInteger(&c.Votes), })) } return err } func (n *NEO) unregisterCandidate(ic *interop.Context, args []stackitem.Item) stackitem.Item { pub := toPublicKey(args[0]) ok, err := runtime.CheckKeyedWitness(ic, pub) if err != nil { panic(err) } else if !ok { return stackitem.NewBool(false) } err = n.UnregisterCandidateInternal(ic, pub) return stackitem.NewBool(err == nil) } // UnregisterCandidateInternal unregisters pub as a candidate. func (n *NEO) UnregisterCandidateInternal(ic *interop.Context, pub *keys.PublicKey) error { var err error key := makeValidatorKey(pub) si := ic.DAO.GetStorageItem(n.ID, key) if si == nil { return nil } cache := ic.DAO.GetRWCache(n.ID).(*NeoCache) // Not only current committee/validators cache is interested in votesChanged, but also // newEpoch cache, thus, modify votesChanged to update the latter. cache.votesChanged = true c := new(candidate).FromBytes(si) emitEvent := c.Registered c.Registered = false ok := n.dropCandidateIfZero(ic.DAO, cache, pub, c) if !ok { err = putConvertibleToDAO(n.ID, ic.DAO, key, c) } if emitEvent { ic.AddNotification(n.Hash, "CandidateStateChanged", stackitem.NewArray([]stackitem.Item{ stackitem.NewByteArray(pub.Bytes()), stackitem.NewBool(c.Registered), stackitem.NewBigInteger(&c.Votes), })) } return err } func (n *NEO) vote(ic *interop.Context, args []stackitem.Item) stackitem.Item { acc := toUint160(args[0]) var pub *keys.PublicKey if _, ok := args[1].(stackitem.Null); !ok { pub = toPublicKey(args[1]) } err := n.VoteInternal(ic, acc, pub) return stackitem.NewBool(err == nil) } // VoteInternal votes from account h for validarors specified in pubs. func (n *NEO) VoteInternal(ic *interop.Context, h util.Uint160, pub *keys.PublicKey) error { ok, err := runtime.CheckHashedWitness(ic, h) if err != nil { return err } else if !ok { return errors.New("invalid signature") } key := makeAccountKey(h) si := ic.DAO.GetStorageItem(n.ID, key) if si == nil { return errors.New("invalid account") } acc, err := state.NEOBalanceFromBytes(si) if err != nil { return err } // we should put it in storage anyway as it affects dumps ic.DAO.PutStorageItem(n.ID, key, si) if pub != nil { valKey := makeValidatorKey(pub) valSi := ic.DAO.GetStorageItem(n.ID, valKey) if valSi == nil { return errors.New("unknown validator") } cd := new(candidate).FromBytes(valSi) // we should put it in storage anyway as it affects dumps ic.DAO.PutStorageItem(n.ID, valKey, valSi) if !cd.Registered { return errors.New("validator must be registered") } } if (acc.VoteTo == nil) != (pub == nil) { val := &acc.Balance if pub == nil { val = new(big.Int).Neg(val) } if err := n.modifyVoterTurnout(ic.DAO, val); err != nil { return err } } newGas, err := n.distributeGas(ic, acc) if err != nil { return err } if err := n.ModifyAccountVotes(acc, ic.DAO, new(big.Int).Neg(&acc.Balance), false); err != nil { return err } if pub != nil && pub != acc.VoteTo { acc.LastGasPerVote = n.getLatestGASPerVote(ic.DAO, makeVoterKey(pub.Bytes())) } oldVote := acc.VoteTo acc.VoteTo = pub if err := n.ModifyAccountVotes(acc, ic.DAO, &acc.Balance, true); err != nil { return err } if pub == nil { acc.LastGasPerVote = *big.NewInt(0) } ic.DAO.PutStorageItem(n.ID, key, acc.Bytes(ic.DAO.GetItemCtx())) ic.AddNotification(n.Hash, "Vote", stackitem.NewArray([]stackitem.Item{ stackitem.NewByteArray(h.BytesBE()), keyToStackItem(oldVote), keyToStackItem(pub), stackitem.NewBigInteger(&acc.Balance), })) if newGas != nil { // Can be if it was already distributed in the same block. n.GAS.mint(ic, h, newGas, true) } return nil } func keyToStackItem(k *keys.PublicKey) stackitem.Item { if k == nil { return stackitem.Null{} } return stackitem.NewByteArray(k.Bytes()) } // ModifyAccountVotes modifies votes of the specified account by value (can be negative). // typ specifies if this modify is occurring during transfer or vote (with old or new validator). func (n *NEO) ModifyAccountVotes(acc *state.NEOBalance, d *dao.Simple, value *big.Int, isNewVote bool) error { cache := d.GetRWCache(n.ID).(*NeoCache) cache.votesChanged = true if acc.VoteTo != nil { key := makeValidatorKey(acc.VoteTo) si := d.GetStorageItem(n.ID, key) if si == nil { return errors.New("invalid validator") } cd := new(candidate).FromBytes(si) cd.Votes.Add(&cd.Votes, value) if !isNewVote { ok := n.dropCandidateIfZero(d, cache, acc.VoteTo, cd) if ok { return nil } } return putConvertibleToDAO(n.ID, d, key, cd) } return nil } func (n *NEO) getCandidates(d *dao.Simple, sortByKey bool, max int) ([]keyWithVotes, error) { arr := make([]keyWithVotes, 0) buf := io.NewBufBinWriter() d.Seek(n.ID, storage.SeekRange{Prefix: []byte{prefixCandidate}}, func(k, v []byte) bool { c := new(candidate).FromBytes(v) emit.CheckSig(buf.BinWriter, k) if c.Registered && !n.Policy.IsBlocked(d, hash.Hash160(buf.Bytes())) { arr = append(arr, keyWithVotes{Key: string(k), Votes: &c.Votes}) } buf.Reset() return !sortByKey || max > 0 && len(arr) < max }) if !sortByKey { // sortByKey assumes to sort by serialized key bytes (that's the way keys // are stored and retrieved from the storage by default). Otherwise, need // to sort using big.Int comparator. sort.Slice(arr, func(i, j int) bool { // The most-voted validators should end up in the front of the list. cmp := arr[i].Votes.Cmp(arr[j].Votes) if cmp != 0 { return cmp > 0 } // Ties are broken with deserialized public keys. // Sort by ECPoint's (X, Y) components: compare X first, and then compare Y. cmpX := strings.Compare(arr[i].Key[1:], arr[j].Key[1:]) if cmpX != 0 { return cmpX == -1 } // The case when X components are the same is extremely rare, thus we perform // key deserialization only if needed. No error can occur. ki, _ := keys.NewPublicKeyFromBytes([]byte(arr[i].Key), elliptic.P256()) kj, _ := keys.NewPublicKeyFromBytes([]byte(arr[j].Key), elliptic.P256()) return ki.Y.Cmp(kj.Y) == -1 }) } return arr, nil } // GetCandidates returns current registered validators list with keys // and votes. func (n *NEO) GetCandidates(d *dao.Simple) ([]state.Validator, error) { kvs, err := n.getCandidates(d, true, maxGetCandidatesRespLen) if err != nil { return nil, err } arr := make([]state.Validator, len(kvs)) for i := range kvs { arr[i].Key, err = keys.NewPublicKeyFromBytes([]byte(kvs[i].Key), elliptic.P256()) if err != nil { return nil, err } arr[i].Votes = kvs[i].Votes } return arr, nil } func (n *NEO) getCandidatesCall(ic *interop.Context, _ []stackitem.Item) stackitem.Item { validators, err := n.getCandidates(ic.DAO, true, maxGetCandidatesRespLen) if err != nil { panic(err) } arr := make([]stackitem.Item, len(validators)) for i := range validators { arr[i] = stackitem.NewStruct([]stackitem.Item{ stackitem.NewByteArray([]byte(validators[i].Key)), stackitem.NewBigInteger(validators[i].Votes), }) } return stackitem.NewArray(arr) } func (n *NEO) getCommitteeAddress(ic *interop.Context, _ []stackitem.Item) stackitem.Item { return stackitem.NewByteArray(n.GetCommitteeAddress(ic.DAO).BytesBE()) } func (n *NEO) getAllCandidatesCall(ic *interop.Context, _ []stackitem.Item) stackitem.Item { ctx, cancel := context.WithCancel(context.Background()) prefix := []byte{prefixCandidate} buf := io.NewBufBinWriter() keep := func(kv storage.KeyValue) bool { c := new(candidate).FromBytes(kv.Value) emit.CheckSig(buf.BinWriter, kv.Key) if c.Registered && !n.Policy.IsBlocked(ic.DAO, hash.Hash160(buf.Bytes())) { buf.Reset() return true } buf.Reset() return false } seekres := ic.DAO.SeekAsync(ctx, n.ID, storage.SeekRange{Prefix: prefix}) filteredRes := make(chan storage.KeyValue) go func() { for kv := range seekres { if keep(kv) { filteredRes <- kv } } close(filteredRes) }() opts := istorage.FindRemovePrefix | istorage.FindDeserialize | istorage.FindPick1 item := istorage.NewIterator(filteredRes, prefix, int64(opts)) ic.RegisterCancelFunc(func() { cancel() for range seekres { //nolint:revive //empty-block } }) return stackitem.NewInterop(item) } func (n *NEO) getCandidateVoteCall(ic *interop.Context, args []stackitem.Item) stackitem.Item { pub := toPublicKey(args[0]) key := makeValidatorKey(pub) si := ic.DAO.GetStorageItem(n.ID, key) if si == nil { return stackitem.NewBigInteger(big.NewInt(-1)) } c := new(candidate).FromBytes(si) if !c.Registered { return stackitem.NewBigInteger(big.NewInt(-1)) } return stackitem.NewBigInteger(&c.Votes) } func (n *NEO) getAccountState(ic *interop.Context, args []stackitem.Item) stackitem.Item { key := makeAccountKey(toUint160(args[0])) si := ic.DAO.GetStorageItem(n.ID, key) if len(si) == 0 { return stackitem.Null{} } item, err := stackitem.Deserialize(si) if err != nil { panic(err) // no errors are expected but we better be sure } return item } // ComputeNextBlockValidators computes an actual list of current validators that is // relevant for the latest processed dBFT epoch and based on the changes made by // register/unregister/vote calls during the latest epoch. // Note: this method isn't actually "computes" new committee list and calculates // new validators list from it. Instead, it uses cache, and the cache itself is // updated during the PostPersist of the last block of every epoch. func (n *NEO) ComputeNextBlockValidators(d *dao.Simple) keys.PublicKeys { // It should always be OK with RO cache if using lower-layered DAO with proper // cache set. cache := d.GetROCache(n.ID).(*NeoCache) if vals := cache.newEpochNextValidators; vals != nil { return vals.Copy() } // It's a caller's program error to call ComputeNextBlockValidators not having // the right value in lower cache. With the current scheme of handling // newEpochNextValidators cache this code is expected to be unreachable, but // let's have this panic here just in case. panic("bug: unexpected external call to newEpochNextValidators cache") } func (n *NEO) getCommittee(ic *interop.Context, _ []stackitem.Item) stackitem.Item { pubs := n.GetCommitteeMembers(ic.DAO) sort.Sort(pubs) return pubsToArray(pubs) } func (n *NEO) modifyVoterTurnout(d *dao.Simple, amount *big.Int) error { key := []byte{prefixVotersCount} si := d.GetStorageItem(n.ID, key) if si == nil { return errors.New("voters count not found") } votersCount := bigint.FromBytes(si) votersCount.Add(votersCount, amount) d.PutBigInt(n.ID, key, votersCount) return nil } // GetCommitteeMembers returns public keys of nodes in committee using cached value. func (n *NEO) GetCommitteeMembers(d *dao.Simple) keys.PublicKeys { cache := d.GetROCache(n.ID).(*NeoCache) return getCommitteeMembers(cache.committee) } func getCommitteeMembers(cvs keysWithVotes) keys.PublicKeys { var committee = make(keys.PublicKeys, len(cvs)) var err error for i := range committee { committee[i], err = cvs[i].PublicKey() if err != nil { panic(err) } } return committee } func toKeysWithVotes(pubs keys.PublicKeys) keysWithVotes { ks := make(keysWithVotes, len(pubs)) for i := range pubs { ks[i].UnmarshaledKey = pubs[i] ks[i].Key = string(pubs[i].Bytes()) ks[i].Votes = big.NewInt(0) } return ks } // computeCommitteeMembers returns public keys of nodes in committee. func (n *NEO) computeCommitteeMembers(blockHeight uint32, d *dao.Simple) (keys.PublicKeys, keysWithVotes, error) { key := []byte{prefixVotersCount} si := d.GetStorageItem(n.ID, key) if si == nil { return nil, nil, errors.New("voters count not found") } votersCount := bigint.FromBytes(si) // votersCount / totalSupply must be >= 0.2 votersCount.Mul(votersCount, bigEffectiveVoterTurnout) _, totalSupply := n.getTotalSupply(d) voterTurnout := votersCount.Div(votersCount, totalSupply) count := n.cfg.GetCommitteeSize(blockHeight + 1) // Can be sorted and/or returned to outside users, thus needs to be copied. sbVals := keys.PublicKeys(n.standbyKeys[:count]).Copy() cs, err := n.getCandidates(d, false, -1) if err != nil { return nil, nil, err } if voterTurnout.Sign() != 1 || len(cs) < count { kvs := make(keysWithVotes, count) for i := range kvs { kvs[i].UnmarshaledKey = sbVals[i] kvs[i].Key = string(sbVals[i].Bytes()) votes := big.NewInt(0) for j := range cs { if cs[j].Key == kvs[i].Key { votes = cs[j].Votes break } } kvs[i].Votes = votes } return sbVals, kvs, nil } pubs := make(keys.PublicKeys, count) for i := range pubs { pubs[i], err = cs[i].PublicKey() if err != nil { return nil, nil, err } } return pubs, cs[:count], nil } func (n *NEO) getNextBlockValidators(ic *interop.Context, _ []stackitem.Item) stackitem.Item { result := n.GetNextBlockValidatorsInternal(ic.DAO) return pubsToArray(result) } // GetNextBlockValidatorsInternal returns next block validators. func (n *NEO) GetNextBlockValidatorsInternal(d *dao.Simple) keys.PublicKeys { cache := d.GetROCache(n.ID).(*NeoCache) return cache.nextValidators.Copy() } // BalanceOf returns native NEO token balance for the acc. func (n *NEO) BalanceOf(d *dao.Simple, acc util.Uint160) (*big.Int, uint32) { key := makeAccountKey(acc) si := d.GetStorageItem(n.ID, key) if si == nil { return big.NewInt(0), 0 } st, err := state.NEOBalanceFromBytes(si) if err != nil { panic(fmt.Errorf("failed to decode NEO balance state: %w", err)) } return &st.Balance, st.BalanceHeight } func pubsToArray(pubs keys.PublicKeys) stackitem.Item { arr := make([]stackitem.Item, len(pubs)) for i := range pubs { arr[i] = stackitem.NewByteArray(pubs[i].Bytes()) } return stackitem.NewArray(arr) } func toPublicKey(s stackitem.Item) *keys.PublicKey { buf, err := s.TryBytes() if err != nil { panic(err) } pub := new(keys.PublicKey) if err := pub.DecodeBytes(buf); err != nil { panic(err) } return pub } // putGASRecord is a helper which creates key and puts GASPerBlock value into the storage. func (n *NEO) putGASRecord(dao *dao.Simple, index uint32, value *big.Int) { key := make([]byte, 5) key[0] = prefixGASPerBlock binary.BigEndian.PutUint32(key[1:], index) dao.PutBigInt(n.ID, key, value) }